SOLID OXIDE FUEL CELL SYSTEM

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention pertains to a solid oxide fuel cell system, and more particularly to a solid oxide fuel cell system for generating variable electrical power in response to power demand.

2. Description of the Related Art

Solid oxide fuel cells (“SOFCs” below) are fuel cells which operate at relatively high temperatures in which, using an oxide ion-conducting solid electrolyte as electrolyte, with electrodes attached to both sides thereof, fuel gas is supplied to one side thereof and an oxidizer (air, oxygen, or the like) is supplied to the other side thereof.

In such SOFCs, steam or CO₂is produced by the reaction between oxygen ions passed through an oxide ion-conducting solid electrolyte and fuel, thereby generating electrical and thermal energy. The electrical energy is removed from the SOFC, where it is used for various electrical purposes. On the other hand, thermal energy is used to raise the temperature of the fuel, the reformer, the water, the oxidant, and the like.

Unexamined Patent Application 2010-92836 (Patent Document 1) sets forth a fuel cell device. This fuel cell device is a solid oxide fuel cell system of the type which changes generated power in response to power demand; operation is disclosed whereby the fuel utilization rate is reduced more in the low load region than in the high power generation load region. That is, in Patent Document 1, the proportion of supplied fuel used for power generation is reduced when generated power is in a low state, but on the other hand fuel used to heat the fuel cell module and not used to generate electricity is not greatly reduced, and a large fraction of the fuel is used to heat the fuel cell module, so the fuel cell module is made thermally independent, and a temperature at which generation can occur is maintained.

Specifically, in the low generated power region, electrical generation heat occurring in the fuel cell unit associated with electrical generation declines, so there is a tendency for the temperature inside the fuel cell module to decline, therefore if a certain fuel utilization rate is maintained even in the low power generation region, a reduction in the temperature inside the fuel cell module is induced, and it becomes difficult to maintain a temperature at which power can be generated, therefore fuel used to heat the fuel cell module is increased to enable thermal independence, even at the sacrifice of the fuel utilization rate.

In the fuel cell device set forth in Unexamined Patent Application 2010-92836, in order to resolve these problems the fuel utilization rate is reduced in the low load region where electrical generation is small, preventing an excessive temperature reduction in the fuel cell module while stably maintaining a fixed high temperature state.

Published Unexamined Patent Application 2009-104886 (Patent Document 2), on the other hand, sets forth a method of operation during increasing load on a fuel cell system. In this operating method, when increasing the amount of electrical generation in a fuel cell system, the amount of air supplied is first increased; then, after increasing the amounts of water and fuel in that order, the amount of electrical power extracted is increased. In this fuel cell system operating method, air depletion, carbon deposition, and fuel depletion are prevented from occurring by increasing supply amounts in the order described.

In addition, the operating temperature of a solid oxide fuel cell is generally high, necessitating that fuel cell cells be kept at a high operating temperature when generating. Therefore reducing the heat dispersed into the outside atmosphere from the fuel cells and reducing the fuel required to maintain temperature is an important factor for increasing the overall energy efficiency of a fuel cell system. It is therefore desirable that fuel cells be housed in a chassis with good heat insulating properties.

Published Unexamined Patent Application 2010-205670 (Patent Document 3), on the other hand, sets an operating method for a fuel cell system and fuel cell. In this fuel cell system, an integral value for the electrical load on the fuel cell is obtained, and the fuel utilization rate is controlled based on this obtained integral value. Control of the fuel utilization rate is performed by estimating the fuel cell temperature based on the integral value of the fuel cell electrical load, then controlling the fuel utilization rate based on the estimated result. The fuel cell can therefore be operated in a thermally independent manner without use of a temperature sensor. When the integral value of the electrical load is at or above a predetermined value, the controller corrects the fuel utilization rate to a value equal to or greater than a reference value at which the fuel cell can operate with thermal independence. In this case, because of the fact that the flow chart temperature is rising, the flow chart has residual heat, and thermally self-sustaining operation can be maintained even if the fuel utilization rate is corrected to a value equal to or greater than the reference value at which thermal self-sustaining operation is possible. The system efficiency of the fuel cell system is thus improved.

3. Prior Art References

Patent Documents:

Patent Document 1—Published Unexamined Patent Application 2010-92836

Patent Document 2—Published Unexamined Patent Application 2009-104886

Patent Document 3—Published Unexamined Patent Application 2010-205670

SUMMARY OF THE INVENTION

There is a problem, however, in that notwithstanding efforts toward thermal self-sustaining operation, reducing fuel utilization rate in the manner described above results in an increase in fuel not contributing to power generation, such that operations reducing the fuel utilization rate lead to a reduction in the overall energy efficiency of the solid oxide fuel cell system. Since overall energy efficiency is reduced in proportion to the length of operation in the reduced fuel utilization rate state, this can also lead to a loss in the advantage of solid oxide fuel cells (SOFC), which are generally deemed to have a higher energy efficiency than polymer membrane (PEFC) fuel cells.

In particular, assuming the solid oxide fuel cell system is for residential use, circumstances in which the solid oxide fuel cell system is used in a low power generation state during predetermined hours of the day, such as during the night when occupants are asleep, etc., are certain to occur; this greatly decreases the overall energy efficiency of the solid oxide fuel cell system, leading to a call for solid oxide fuel cell system with superior technology capable of operating at a high fuel utilization rate even in such low power generation states.

On the other hand, by increasing thermal insulation on the chassis in which the fuel cell or the like is housed, residual fuel supplied to the fuel cells and not used for power generation heats up the chassis, causing the problem of excessive temperature rise inside the chassis. Damage to the fuel cells, reformer, and the like inside the chassis can occur when the temperature inside the chassis rises excessively. It is not easy to reduce excessively rising temperatures to an appropriate temperature, since the chassis has high thermal insulation characteristics and extremely high thermal capacity.

If the fuel cell system is operated at a fixed generated power, then even when thermal insulating characteristics of the chassis are high, excessive temperature rises can be avoided by setting the amount of fuel supplied to a fixed amount so that thermal balance is maintained under those high thermal insulating conditions. However, in a fuel cell in which variable generated power is produced according to power demand, the amount of fuel supplied must be changed to match generated power. When increasing generated power in fuel cell systems in which generated power is varied, the generated power extracted from the fuel cells must be increased by first increasing the amount of fuel supplied then increasing the power extracted from the fuel cell, as in the invention set forth in Published Unexamined Patent Application 2009-104886. Therefore in fuel cell systems in which generated power is varied, when generated power is increased or decreased there is an increase in residual fuel not contributing to power generation, which becomes a cause for excessive temperature rises. Also, if the delay up until power is extracted from the fuel cells is reduced in order to reduce residual fuel when increasing or decreasing power generation, the fuel cells are exposed to the risk of fuel depletion.

In response, Published Unexamined Patent Application 2010-205670 describes utilizing residual heat accumulated in the fuel cell system to increase the fuel utilization rate. When an excessive temperature rise occurs in a fuel cell system, much of the residual heat is accumulated, so it is conceivable that a temperature rise can be suppressed by increasing the fuel utilization rate and consuming the residual heat. However, in the invention set forth in Published Unexamined Patent Application 2010-205670, the amount of stored residual heat is obtained from the integral value of the electrical load, therefore the increase in residual fuel caused by increasing extracted generated power at a delay after increasing the fuel supply amount cannot be known whatsoever. It is therefore difficult to apply the invention of Published Unexamined Patent Application 2010-205670 to the suppression of excessive temperature rises caused by power delays.

Specifically, in the invention set forth in Published Unexamined Patent Application 2010-205670, the heat of generation (joule heat) arising when power is generated in a fuel cell is estimated based on the amount of generated power; by this means residual heat is in turn estimated. Since heat generated by delaying power generation in a fuel cell is combustion heat generated by the combustion of residual fuel not used for power generation, the amount of heat stored in the startup process when using the technology disclosed in Published Unexamined Patent Application 2010-205670 cannot be estimated.

The present invention has the object of providing an extremely practical solid oxide fuel cell system capable of improving overall energy efficiency while maintaining thermal self-sufficiency and operating in a stable manner.

The present invention has the further object of providing a solid oxide fuel cell system capable of preventing excessive temperature rises while increasing overall energy efficiency.

In order to resolve the above-described problems, the present invention is a solid oxide fuel cell system for producing variable generated power in accordance with power demand, comprising: a fuel cell module that generates power using supplied fuel; a fuel supply device that supplies fuel to the fuel cell module; a generating oxidant gas supply device that supplies oxidant gas for electrical generation to the fuel cell module; a heat storage material that stores heat produced within the fuel cell module; a demand power detection device that detects power demand; and a controller programmed to control the fuel supply device based on the demand power detected by the demand power detection device so that the fuel utilization rate increases when generated power is large and decreases when generated power is small, wherein the controller is programmed to change the electrical power actually output from the fuel cell module with a delay after changing the fuel supply amount based on changes in demand power; wherein the controller comprises a stored heat estimating circuit that estimates the amount of surplus heat based on fuel supplied by the fuel supply device and on the power output at a delay relative to fuel supply, and wherein when the stored heat estimating circuit estimates that a utilizable amount of heat has accumulated in the storage material, the controller reduces the fuel supply amount so that the fuel utilization rate for the same generated power is increased relative to the case when a utilizable amount of heat has not accumulated.

In the present invention thus constituted, the fuel supply device and generating oxidant gas supply device respectively supply fuel and generating oxidant gas to the fuel cell module. The fuel cell module generates electricity using the supplied fuel and generating oxidant gas, and the heat produced is stored in the heat storage material. Based on the demand power detected using the demand power detection device, the controller controls the fuel supply device so that the fuel utilization rate is high when the generated power is large, and the fuel utilization rate is low when the generated power is small. In addition, the controller changes the power actually output from the fuel cell module at a delay after changing the fuel supply amount in response to changes in power demand. The stored heat amount estimating circuit estimates a surplus heat amount based on the fuel supply and on the power output at a delay relative to the supply of fuel. When it is estimated by the stored heat estimating circuit that a utilizable amount of heat is stored in the storage material, the controller reduces the fuel supply amount so that the fuel utilization rate is higher for a generated power than when a utilizable amount of heat is not stored.

In general, in solid oxide fuel cell system electrical generation heat declines when generated power is small, facilitating a decline in the temperature of the fuel cell module. Therefore at times of low power generation, the fuel utilization rate is reduced and fuel not used in generating electricity is combusted to heat up the fuel cell module and prevent excessive temperature drops. In particular, in solid oxide fuel cell system of the type in which a reformer is disposed within the fuel cell module, an endothermic reaction occurs inside the reformer, facilitating an even further reduction in temperature. In the present invention thus constituted, when it is estimated by the stored heat estimating circuit that a utilizable amount of heat is stored in the storage material, the fuel supply amount is reduced in order to increase the fuel utilization rate. This enables the overall energy efficiency of the solid oxide fuel cell system to be improved while maintaining thermal self-sufficiency of the solid oxide fuel cell system and avoiding excessive drops in temperature.

Also, in the present invention thus constituted, surplus heat amounts are estimated based on the fuel supplied by the fuel supply device and on power output at a delay relative to the supply of fuel, so the accumulated heat amount can also be accurately estimated by having the controller change the fuel supply amount then, at a delay, change the output power. Therefore the amount of heat stored in the heat storage material can be sufficiently exploited while reliably avoiding the risk of sudden temperature drops in the fuel cell module. In addition, in fuel cells of the type in which output power is varied at a delay after changing the fuel supply amount, there is a risk that frequent increases and decreases of output power will cause an excessive rise in temperature within the fuel cell module, but according the present invention constituted as described above, stored heat caused by surplus fuel produced as described above can be accurately known. In general, excessive temperature rise caused by surplus heat is suppressed by inserting a cooling rod body into the fuel cell module, but using the present invention the amount of heat resulting from surplus fuel can be accurately known, and can therefore be effectively used to suppress excessive temperature rises. By this means the amount of cooling medium inserted to reduce the temperature can be reduced, thereby improving the overall energy efficiency of the solid oxide fuel cell system.

In the present invention, the controller preferably greatly raises the fuel utilization rate as the stored heat amount estimated by the stored heat estimating circuit increases.

In the present invention thus constituted, stored heat is used in large quantity when the estimated stored heat is large, and is not much used when the stored heat amount is small, therefore stored heat can be effectively exploited, and the risk of temperature drops can be reliably avoided.

In the present invention, the controller preferably makes much greater changes in the fuel utilization rate relative to changes in the estimated stored heat amount in the region where the amount of stored heat estimated by the stored heat estimating circuit is large than in the region where the estimated stored heat amount is small.

In the present invention thus constituted, when the estimated stored heat amount is large, large amounts of stored heat are used to avoid excessive temperature rises, while when the estimated stored heat amount is small, small amount of stored heat are used at a time to prevent overcooling.

In the present invention, the stored heat estimating circuit preferably estimates a stored heat amount by summing addition and subtraction values reflecting the surplus heat amount caused by the output of power at a delay relative to fuel supply.

In the present invention thus constituted, the stored heat amount is estimated by summing addition and subtraction values reflecting a surplus heat amount, therefore the stored heat amount resulting from the storage of produced surplus heat can be precisely estimated.

In the present invention, the addition and subtraction values are preferably determined based on the temperature inside the fuel cell module, the surplus heat amount calculated using the relationship between fuel supply amount and generated power, the amount of increase/decrease in generated power, or the number of times generated power is increased/decreased per hour.

In the present invention thus constituted, addition and subtraction values are determined based on the temperature inside the fuel cell module, the surplus heat amount calculated using the relationship between the fuel supply amount and generated power, the amount of increase/decrease in generated power, or the number of times generated power is increased/decreased per hour, therefore the stored heat produced by delaying the produced electrical power can be accurately estimated.

In the present invention, the controller preferably controls the fuel supply device so that when a utilizable amount of heat has not accumulated in the heat storage material, a greater amount of heat is stored in the heat storage material in a region greater than a predetermined medium generated power, so that heat amounts accumulated during large power generation can be utilized during small power generation.

In the present invention thus constituted, a larger heat amount is stored in the heat storage material in a region above medium generated power, therefore by actively storing heat in a region above the medium electrical generation level where the fuel utilization rate can be increased, this heat can be consumed during low power generation when the fuel cell module temperature is relatively low and self-sustaining is difficult, thus reliably enabling high efficiency operation at a high fuel utilization rate with effective use of the stored heat amount.

In the present invention, the controller preferably controls the fuel supply device so that a larger amount of heat is stored in the heat storage material in the region where generated power is greater than the middle value of the generated power range.

In the present invention thus constituted, a larger amount of heat is stored in the heat storage material in the region where generated power is greater than in the middle value of the generated power range. Therefore in the vicinity of the middle value of the frequently used generated power range, the amount of stored surplus heat is suppressed, and a large amount of heat is stored in the heat storage material during power demand peaks. Thus when a solid oxide fuel cell system is used in a residence, excessive fuel consumption to store large heat amounts is suppressed during the periods of most frequent power demand amounts, being the medium level power demand amounts occurring during the day, etc., while on the other hand large heat amounts are stored during time periods with peak power demand, such as evening hours, so that heat amounts stored in the evening hours are immediately consumed in the follow-on late night period; wasteful storage of heat amounts over long periods is eliminated, and a high efficiency operation can be achieved to reliably take effective advantage of stored heat during the late night period when generated power is greatly reduced.

In the present invention, the controller preferably increases the fuel utilization rate when the stored heat amount estimated by the stored heat estimating circuit is equal to or greater than a predetermined change execution stored heat amount.

In the present invention thus constituted, the stored heat amount in the heat storage material is estimated by the stored heat estimating circuit, therefore changes to increase the fuel utilization rate can be stably executed, and a change is executed when the estimated stored heat amount is equal to or greater than a predetermined change-execution stored heat amount, so that overcooling can be more reliably prevented.

In the present invention, the controller preferably determines a predetermined change execution period based on the stored heat amount estimated by the stored heat estimating circuit at the start of high efficiency control at an increased fuel utilization rate, and executes high efficiency control within this change execution period.

In the present invention thus constituted, changes are executed within the change execution period determined based on the stored heat amount estimated by the stored heat estimating circuit, so that high efficiency control utilizing stored heat can be effected using a simpler control.

The present invention preferably further comprises a change period extension circuit for suppressing decreases in the amount of heat stored in the heat storage material to extend the period of execution of high efficiency control during execution of high efficiency control at an increased fuel utilization rate.

The present invention thus constituted is furnished with a change period extension circuit for extending the period for executing high efficiency control, therefore the stored heat amount can be effectively utilized in accordance with conditions.

In the present invention, the change period extension circuit preferably decreases the fuel utilization rate in proportion to the lengthening of the period during which the high efficiency control is executed, in conjunction with the decrease in the amount of stored heat stored in the heat storage material.

In the present invention thus constituted, the amount of change in high efficiency control is reduced with the decrease in stored heat amount, therefore the period during which the fuel utilization rate is increased can be extended without inducing excessive temperature drops in the fuel cell module, degradation of performance, or the like.

In the present invention, the change period extension circuit preferably decreases the fuel utilization rate in proportion to the decrease in generated power.

In the present invention thus constituted, because the change amount under high efficiency control is reduced more as generated power decreases, there is a decrease in the change amount during low power generation, in which the amount of stored heat utilized increases, and the period during which the fuel utilization rate is increased can be extended while reliably avoiding excessive temperature drops in the fuel cell module, degradation of performance, or the like.

In the present invention, the change period extension circuit preferably controls the generating oxidant gas supply device to reduce oxidant gas for generation supplied to the fuel cell module while high efficiency control is being executed.

In the present invention thus constituted, generating oxidant gas supplied to the fuel cell module is reduced during change execution, therefore the carrying off of the heat amount stored in the heat storage material by oxidant gas can be suppressed, and stored heat can be effectively used over a longer time period.

The present invention preferably further comprises an overcooling prevention circuit that prevents overcooling of the fuel cell module when the stored heat amount in the heat storage material is small.

The present invention thus constituted is furnished with an overcooling prevention circuit, therefore overcooling caused by increasing the fuel utilization rate can be reliably prevented in a state in which the amount of stored heat has declined.

In the present invention, during execution of high efficiency control with an increased fuel utilization rate, the overcooling prevention circuit preferably improves the fuel supply amount following characteristics of the fuel supply device more than during normal operation.

In the present invention thus constituted, the fuel supply amount following characteristics are improved during the period when high efficiency control is being executed, therefore the fuel supply amount can be quickly increased when the fuel utilization rate drops with a decline in the stored heat amount. Overcooling of the fuel cell module due to delays in response which cause an increase in the fuel supply amount can thus be prevented.

The present invention preferably further comprises a combustion portion for heating the fuel cell module by combusting residual fuel, which is remaining fuel supplied by the fuel supply device and not used for power generation; wherein the controller further includes: a power extraction delay circuit which, when generated power is increased, increases the fuel supply amount supplied to the fuel cell module, then increases the power extracted from the fuel cell module after a delay; an excess temperature rise estimating circuit that estimates the occurrence of excessive temperature rises inside the fuel cell module; a temperature rise suppression circuit which, when the occurrence of an excessive temperature rise is estimated by the excess temperature rise estimating circuit, suppresses temperature rises in the fuel cell module while continuing power generation by reducing the residual fuel produced by the delay of output power provided by the power extraction delay circuit; and a forced cooling circuit for lowering the temperature inside the fuel cell module by causing a cooling fluid to flow into the fuel cell module when further temperature rise suppression is required after executing temperature rise suppression using the temperature rise suppression circuit.

In the present invention thus constituted, the fuel supply device and generating oxidant gas supply device respectively supply fuel and generating oxidant gas to the fuel cell module. The fuel cell module generates electricity using the supplied fuel and generating oxidant gas, and residual fuel unused for generation and remaining is combusted in a combustion portion such that the inside of the fuel cell module is heated. The controller controls the fuel supply device based on a demand power detected by a demand power detection device. Also, the power extraction delay circuit with which the controller is furnished changes the power actually output from the fuel cell module at a delay after changing the fuel supply amount in response to changes in power demand. The temperature rise suppression circuit with which the controller is provided suppresses temperature rises in the fuel cell module while continuing power generation by reducing the residual fuel produced by the output at a delay of electrical power by the power extraction delay circuit when the occurrence of an excessive temperature rise is estimated by the excess temperature rise estimating circuit. Moreover, the forced cooling circuit with which the controller is provided reduces the temperature inside the fuel cell module by causing a cooling fluid to flow into the fuel cell module when further temperature rise suppression is required after executing temperature rise suppression using the temperature rise suppression circuit.

In the present invention, the temperature rise suppression circuit preferably controls temperature rise inside the fuel cell module by increasing the fuel utilization rate; and wherein the controller determines whether or not to execute a temperature rise suppression by the forced cooling circuit based on changes in the temperature inside the fuel cell module after a temperature rise suppression has been executed by the temperature rise suppression circuit.

In the present invention thus constituted, the temperature rise suppression circuit increases the fuel utilization rate, therefore the amount of heat stored inside the fuel cell module can be consumed without loss of energy efficiency; cooling by the forced cooling circuit is then executed based on temperature changes in the fuel cell module after execution of the temperature rise suppression circuit, therefore use of the forced cooling circuit causing a decrease in energy efficiency can be kept to the minimum required.

In the present invention, the temperature rise suppression circuit increases the fuel utilization rate and suppresses temperature rises in the fuel cell module by reducing the frequency with which generated power is increased and decreased when following fluctuations in demand power.

In the present invention thus constituted, the fuel utilization rate is improved and the frequency of increases/decreases in generated power is reduced, so the stored heat amount is consumed and the production of residual fuel is suppressed, such that excess temperature rises can be quickly eliminated.

In the present invention, the forced cooling circuit increases the flow amount of oxidant gas supplied by the generating oxidant gas supply device and utilizes the additional oxidant gas as a fluid body for cooling.

In the present invention thus constituted, generating oxidant gas is increased when excess temperature rises cannot be sufficiently suppressed by the temperature rise suppression circuit, therefore temperature rises can be quickly suppressed without negatively affecting cells inside the fuel cell module or the like.

The present invention preferably further comprises a combustion portion for heating the fuel cell module by combusting residual fuel, which is remaining fuel supplied by the fuel supply device and not used for power generation; and a temperature detection device for detecting the temperature of the fuel cell module; wherein the stored heat estimating circuit estimates the stored heat amount stored in the heat storage material based on the detected temperature detected by the temperature detection device; wherein the controller includes a power extraction delay circuit that increases the generated power output from the fuel cell module at a delay after increasing the fuel supply amount supplied to the fuel cell module when increasing generated power; wherein the controller includes a fuel supply amount change circuit that executes high efficiency control to reduce the fuel supply amount so that the fuel utilization rate rises, thereby causing the heat amount stored in the heat storage material to be consumed; and wherein the controller includes a temperature rise suppression circuit that suppresses temperature rises by reducing the upper limit value in a variable range of power generated by the fuel cell module.

In the present invention thus constituted, the fuel supply device and generating oxidant gas supply device respectively supply fuel and generating oxidant gas to the fuel cell module. The fuel cell module generates electricity using the supplied fuel and generating oxidant gas, and residual fuel unused for generation and remaining is combusted in a combustion portion such that the inside of the fuel cell module is heated. The controller controls the fuel supply device based on a demand power detected by a demand power detection device. Also, the power extraction delay circuit with which the controller is furnished changes the power actually output from the fuel cell module at a delay after changing the fuel supply amount in response to changes in power demand. Furthermore, the stored heat estimating circuit estimates the amount of stored heat stored in the heat storage material based on the temperature detected by the temperature detection device. When the estimated stored heat amount is large and occurrence of an excessive temperature rise in the fuel cell module is foreseen, the fuel supply amount change circuit increases the fuel utilization rate and performs high efficiency control to cause the heat amount stored in the heat storage material to be consumed. In addition, the temperature rise suppression circuit suppresses temperature rises by lowering the upper limit value in the variable range of power generated by the fuel cell module.

In the present invention thus constituted, output power can be changed after changing the fuel supply using the power extraction delay circuit to secure a safe period of time for fuel to be dispersed, therefore the risk of damage to cells inside the fuel cell module due to fuel depletion can be avoided. In addition, residual fuel is increased by delaying the output of power, and this residual fuel heats the interior of the fuel cell module. When the heat insulating characteristics of the fuel cell module are high and there is a requirement to implement excessive load following characteristics in which output power is frequently increased and decreased, it can occur that excessive temperature rises are induced in the fuel cell module. In general, the amount of generating oxidant gas as cooling medium is increased in order to reduce the temperature inside the fuel cell module, but because the drop in temperature caused by injecting a cooling medium is achieved by discharging useful amounts of heat in the fuel cell module together with exhaust, overall energy efficiency declines. The solid oxide fuel cell system of the present invention suppresses excessive temperature rises by reducing the introduced fuel supply amount so that excessively accumulated surplus heat is utilized as a thermal self-sustaining state is maintained, while simultaneously achieving a high fuel utilization rate. In order to achieve this, in the present invention the stored heat estimating circuit estimates the stored heat amount based on detected temperature, therefore the effects of stored heat caused by residual fuel resulting from a delay in the output of electrical power from the start of fuel supply can be accurately accounted for and estimated. Excessive temperature rises occurring at times of excessive load following can thus be reliably prevented while energy efficiency is increased. Furthermore, the temperature rise suppression circuit is constituted to reduce the upper limit value of the variable range of generated power. The amount of heat emission associated with electrical generation is thus suppressed, therefore further increases in the stored heat amount are suppressed, and since the range of variability in electrical power caused by load following is also suppressed, the occurrence of further heat amounts caused by residual fuel is suppressed, and excessive temperature rises can be quickly reduced. Moreover, since fuel utilization rates are high to begin with in high electrical generation states, the amount of consumption of stored heat caused by raising the fuel utilization rate is small, and suppression of excessive temperature rises takes a long period of time. There is also a risk of inducing further excessive temperature rises during this time period. The present invention, by forcibly reducing the upper limit of generated power, increases the stored heat carried off by increasing the fuel utilization rate so that surplus heat amounts can be actively consumed in a short time period, therefore excess temperature rises can be reliably and promptly resolved.

EFFECT OF THE INVENTION

Using the solid oxide fuel cell system of the present invention, overall energy efficiency can be improved while maintaining thermal self-sufficiency and stable operation.

Using the solid oxide fuel cell system of the present invention, excessive temperature rises can be prevented while increasing overall energy efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an overview diagram showing a fuel cell device according to an embodiment of the present invention.

FIG. 2 is a front elevation cross section showing a fuel cell module in a fuel cell device according to an embodiment of the present invention.

FIG. 3 is a sectional diagram along line III-III in FIG. 2.

FIG. 4 is a partial cross section showing a fuel cell unit in a fuel cell device according to an embodiment of the present invention.

FIG. 5 is an oblique view showing a fuel cell stack in a fuel cell device according to an embodiment of the present invention.

FIG. 6 is a block diagram showing a fuel cell device according to an embodiment of the present invention.

FIG. 7 is a timing chart showing the operation when a fuel cell device is started, according to an embodiment of the present invention.

FIG. 8 is a timing chart showing the operation when a fuel cell device is stopped, according to an embodiment of the present invention.

FIG. 9 is a graph showing the relationship between output current and fuel supply amount in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 10 is a graph showing the relationship between output current and amount of heat produced by supplied fuel in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 11 is a control flow chart of the fuel supply amount in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 12 is a stored heat amount estimate table used to estimate the amount of heat accumulated in a heat storing material in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 13 is a graph of the stored heat amount estimate table in FIG. 12.

FIG. 14 is a graph showing the value of a first modifying coefficient relative to output current in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 15 is a graph showing the value of a second modifying coefficient relative to output current in the solid oxide fuel cell system of the first embodiment of the present invention.

FIG. 16 is a flowchart for changing correction amounts when the fuel cell module has degraded.

FIGS. 17(
a) and 17(b) are graphs schematically showing changes in power demand over a day in a typical residence.

FIG. 18 is a graph showing the value of a current modifying coefficient in a variant example of the first embodiment of the present invention.

FIG. 19 is a graph schematically showing the relationship between changes in power demand, fuel supply amount, and current actually extracted from a fuel cell module.

FIG. 20 is a graph showing an example of the relationship between generating air supply amount, water supply amount, fuel supply amount, and current actually extracted from a fuel cell module.

FIG. 21 is a flowchart showing the order in which generating air supply amount, water supply amount, and fuel supply amount are determined based on detected temperature Td.

FIG. 22 is a graph showing appropriate fuel cell stack temperature versus generating current.

FIG. 23 is a graph showing fuel utilization rate determined according to integral value.

FIG. 24 is a graph showing the range of fuel utilization rates which can be determined relative to each generating current.

FIG. 25 is a graph showing air utilization rates determined according to integral value.

FIG. 26 is a graph showing the range of air utilization rates which can be determined relative to each generating current.

FIG. 27 is a graph for determining water supply amounts versus a determined air supply utilization rate.

FIG. 28 is a graph showing appropriate fuel cell module generating voltage versus generating current.

FIG. 29 is a flowchart showing the procedure for limiting the range of power produced by the fuel cell module in a second embodiment of the present invention.

FIG. 30 is a map showing current limits versus generating current and detected temperature.

FIG. 31 is a timing chart showing an example of the effect of the second embodiment of the present invention.

FIG. 32 is a graph showing an example of the relationship between temperature inside the fuel cell module and maximum generatable power.

FIG. 33 is a flow chart showing a procedure for calculating a first add/subtract value based on temperatures detected by multiple temperature sensors.

FIG. 34 is a flow chart showing the procedure for calculating an add/subtract value according to a variant example of the second embodiment of the present invention.

FIG. 35 is a flow chart showing the procedure for calculating an add/subtract value according to a variant example of the second embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Next, referring to the attached drawings, we discuss a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.

FIG. 1 is an overview diagram showing a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention. As shown in FIG. 1, the solid oxide fuel cell system (SOFC) of this embodiment of the present invention is furnished with a fuel cell module 2 and an auxiliary unit 4.

The fuel cell module 2 is furnished with a housing 6; a sealed space 8 is formed within the housing 6, mediated by an insulating material 7. A fuel cell assembly 12 for carrying out the electrical generating reaction between fuel gas and oxidizer (air) is disposed in the generating chamber 10 at the lower portion of this sealed space 8. This fuel cell assembly 12 is furnished with ten fuel cell stacks 14 (see FIG. 5), and a fuel cell stack 14 comprises 16 fuel cell units 16 (see FIG. 4). Thus, the fuel cell assembly 12 has 160 fuel cell units 16, all of which are serially connected.

A combustion chamber 18 is formed above the aforementioned generating chamber 10 in the fuel cell module 2 sealed space 8; residual fuel gas and residual oxidizer (air) not used in the electrical generation reaction are burned in this combustion chamber 18 and produce exhaust gas.

A reformer 20 for reforming fuel gas is disposed at the top of the combustion chamber 18; the reformer 20 is heated by the heat of residual gas combustion to a temperature at which the reforming reaction can take place. Furthermore, an air heat exchanger 22 is disposed on the top of this reformer 20 for receiving heat from the reformer 20 and heating air so as to restrain temperature drops in the reformer 20.

Next, the auxiliary unit 4 is furnished with a pure water tank 26 for holding water from a municipal or other water supply source 24 and filtering it into pure water, and a water flow regulator unit 28 (a “water pump” or the like driven by a motor) for regulating the flow volume of water supplied from the reservoir tank. The auxiliary tank 4 is further furnished with a gas shutoff valve 32 for shutting off the fuel gas supply from a fuel supply source 30 such as municipal gas or the like, and a fuel flow regulator unit 38 (a “fuel pump” or the like driven by a motor) for regulating the flow volume of fuel gas. Furthermore, an auxiliary unit 4 is furnished with an electromagnetic valve 42 for shutting off air serving as an oxidizer and supplied from an air supply source 40, a reforming air flow regulator unit 44 and oxidant gas supply device 45 (“air blower” or the like driven by a motor) for regulating air flow volume, a first heater 46 for heating reforming air supplied to the reformer 20, and a second heater 48 for heating generating air supplied to the generating chamber. This first heater 46 and second heater 48 are provided in order to efficiently raise the temperature at startup, and may be omitted.

Next, a hot-water producing device 50 supplied with exhaust gas is connected to the fuel cell module 2. Municipal water from a water supply source 24 is supplied to this hot-water producing device 50; this water is turned into hot water by the heat of the exhaust gas, and is supplied to a hot water reservoir tank in an external water heater, not shown.

A control box 52 for controlling the amount of fuel gas supplied, etc., is connected to the fuel cell module 2.

Furthermore, an inverter 54 serving as an electrical power extraction unit (electrical power conversion unit) for supplying electrical power generated by the fuel cell module to the outside is connected to the fuel cell module 2.

Next, the internal structure of the solid oxide fuel cell system (SOFC) fuel cell module of this embodiment of the present invention is explained using FIGS. 2 and 3. FIG. 2 is a side elevation sectional diagram showing a fuel cell module in a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention; FIG. 3 is a sectional diagram along line III-III of FIG. 2.

As shown in FIGS. 2 and 3, starting from the bottom in the sealed space 8 within the fuel cell module 2 housing 6, a fuel cell assembly 12, a reformer 20, and an air heat exchanger 22 are arranged in sequence, as described above.

A pure water guide pipe 60 for introducing pure water on the upstream end of the reformer 20, and a reform gas guide pipe 62 for introducing the fuel gas and reforming air to be reformed, are attached to the reformer 20; a vaporizing section 20a and a reforming section 20b are formed in sequence starting from the upstream side within the reformer 20, and the steam generating section 20a reforming section 20b is filled with a reforming catalyst. Fuel gas and air blended with the steam (pure water) introduced into the reformer 20 is reformed by the reforming catalyst used to fill in the reformer 20. Appropriate reforming catalysts are used, such as those in which nickel is imparted to the surface of aluminum spheres, or ruthenium is imparted to aluminum spheres.

A fuel gas supply line 64 is connected to the downstream end of the reformer 20; this fuel gas supply line 64 extends downward, then further extends horizontally within a manifold formed under the fuel cell assembly 12. Multiple fuel supply holes 64b are formed on the bottom surface of a horizontal portion 64a of the fuel gas supply line 64; reformed fuel gas is supplied into the manifold 66 from these fuel supply holes 64b.

A lower support plate 68 provided with through holes for supporting the above-described fuel cell stack 14 is attached at the top of the manifold 66, and fuel gas in the manifold 66 is supplied into the fuel cell unit 16.

Next, an air heat exchanger 22 is provided over the reformer 20. This air heat exchanger 22 is furnished with an air concentration chamber 70 on the upstream side and two air distribution chambers 72 on the downstream side; this air concentration chamber 70 and the distribution chambers 72 are connected using six air flow conduits 74. Here, as shown in FIG. 3, three air flow conduits 74 form a set (74a, 74b, 74c, 74d, 74e, 74f); air in the air concentration chamber 70 flows from each set of the air flow conduits 74 to the respective air distribution chambers 72.

Air flowing in the six air flow conduits 74 of the air heat exchanger 22 is pre-heated by rising combustion exhaust gas from the combustion chamber 18.

Air guide pipes 76 are connected to each of the respective air distribution chambers 72; these air guide pipes 76 extend downward, communicating at the bottom end side with the lower space in the generating chamber 10, and introducing preheated air into the generating chamber 10.

Next, an exhaust gas chamber 78 is formed below the manifold 66. As shown in FIG. 3, an exhaust gas conduit 80 extending in the vertical direction is formed on the insides of the front surface 6a and the rear surface 6b which form the faces in the longitudinal direction of the housing 6; the top inside of the exhaust gas conduit 80 communicates with the space in which the air heat exchanger 22 is disposed, and the bottom end side communicates with the exhaust gas chamber 78. An exhaust gas discharge pipe 82 is connected at approximately the center of the bottom surface of the exhaust gas chamber 78; the downstream end of this exhaust gas discharge pipe 82 is connected to the above-described hot water producing device 50 shown in FIG. 1.

As shown in FIG. 2, an ignition device 83 for starting the combustion of fuel gas and air is disposed on the combustion chamber 18.

Next, referring to FIG. 4, we discuss the fuel cell unit 16. FIG. 4 is a partial section showing a solid oxide fuel cell system (SOFC) fuel cell unit according to an embodiment of the present invention.

As shown in FIG. 4, the fuel cell unit 16 is furnished with a fuel cell 84 and internal electrode terminals 86, respectively connected to the respective terminals at the top and bottom of the fuel cell 84.

The fuel cell 84 is a tubular structure extending in the vertical direction, furnished with a cylindrical internal electrode layer 90, on the inside of which is formed a fuel gas flow path 88, a cylindrical external electrode layer 92, and an electrolyte layer 94 between the internal electrode layer 90 and the external electrode layer 92. This internal electrode layer 90 is a fuel electrode through which fuel gas passes, and is a (−) pole, while the external electrode layer 92 is an air electrode which contacts the air, and is a (+) pole.

The internal electrode terminals 86 attached at the top end and bottom ends of the fuel cell device 16 have the same structure, therefore we will here discuss specifically the internal electrode terminal 86 attached at the top and side. The top portion 90a of the inside electrode layer 90 is furnished with an outside perimeter surface 90b and top end surface 90c, exposed to the electrolyte layer 94 and the outside electrode layer 92. The inside electrode terminal 86 is connected to the outer perimeter surface of the inside electrode layer 90 through a conductive seal material 96, and is electrically connected to the inside electrode layer 19 by making direct contact with the top end surface 90c of the inside electrode layer 90. A fuel gas flow path 98 communicating with the inside electrode layer 90 fuel gas flow path 88 is formed at the center portion of the inside electrode terminal 86.

The inside electrode layer 90 is formed, for example, from at least one of a mixture of Ni and zirconia doped with at least one type of rare earth element selected from Ca, Y, Sc, or the like; or a mixture of Ni and ceria doped with at least one type of rare earth element; or any mixture of Ni with lanthanum gallate doped with at least one element selected from among Sr, Mg, Co, Fe, or Cu.

The electrolyte layer 94 is formed, for example, from at least one of the following: zirconia doped with at least one type of rare earth element selected from among Y, Sc, or the like; ceria doped with at least one type of selected rare earth element; or lanthanum gallate doped with at least one element selected from among Sr or Mg.

The outside electrode layer 92 is formed, for example, from at least one of the following: lanthanum manganite doped with at least one element selected from among Sr or Ca; lanthanum ferrite doped with at least one element selected from among Sr, Co, Ni, or Cu; lanthanum cobaltite doped with at least one element selected from among Sr, Fe, Ni, or Cu; silver, or the like.

Next we discuss the fuel cell stack 14, referring to FIG. 5. FIG. 5 is a perspective view showing the fuel cell stack in a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.

As shown in FIG. 5, the fuel cell stack 14 is furnished with sixteen fuel cell units 16; the top inside and bottom inside of these fuel cell units 16 are respectively supported by a lower support plate 68 and upper support plate 100. Through holes 68a and 100a, through which the inside electrode terminal 86 can penetrate, are provided on this lower support plate 68 and outer support plate 100.

In addition, a collector 102 and an external terminal 104 are attached to the fuel cell unit 16. This collector 102 is integrally formed by a fuel electrode connecting portion 102a, which is electrically connected to the inside electrode terminal 86 attached to the inside electrode layer 90 serving as the fuel electrode, and by an air electrode connecting portion 102b, which is electrically connected to the entire external perimeter of the outside electrode layer 92 serving as the air electrode. The air electrode connecting portion 102b is formed of a vertical portion 102c extending vertically along the surface of the outside electrode layer 92, and multiple horizontal portions 102d extending in the horizontal direction from this vertical portion 102c along the surface of the outside electrode layer 92. The fuel electrode connecting portion 102a extends linearly in an upward or downward diagonal direction from the vertical portion 102c of the air electrode connecting portion 102b toward the inside electrode terminals 86 positioned in the upper and lower directions on the fuel cell unit 16.

Furthermore, electrode terminals 86 at the top and bottom ends of the two fuel cell units 16 positioned at the end of the fuel cell stack 14 (at the front and back sides on the left edge in FIG. 5) are respectively connected to the outside terminals 104. These external terminals 104 are connected to the external terminals 104 (not shown) at the ends of the adjacent fuel cell stack 14, and as described above, all of the 160 fuel cell units 16 are connected in series.

Next, referring to FIG. 6, we discuss the sensors attached to the solid oxide fuel cell system (SOFC) according to the present embodiment. FIG. 6 is a block diagram showing a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention.

As shown in FIG. 6, a solid oxide fuel cell system 1 is furnished with a control unit 110; an operating device 112 provided with operating buttons such as “ON” or “OFF” for user operation, a display device 114 for displaying various data such as a generator output value (Watts), and a notification device 116 for issuing warnings during abnormal states and the like are connected to this control unit 110. This notification device 116 may be connected to a remote control center to inform the control center of abnormal states.

Next, signals from the various sensors described below are input to the control unit 110.

First, a flammable gas detection sensor 120 detects gas leaks and is attached to the fuel cell module 2 and the auxiliary unit 4.

The purpose of the flammable gas detection sensor 120 is to detect leakage of CO in the exhaust gas, which is meant to be exhausted to the outside via the exhaust gas conduit 80, into the external housing (not shown) which covers the fuel cell module 2 and the auxiliary unit 4.

A water reservoir state detection sensor 124 detects the temperature and amount of hot water in a water heater (not shown).

An electrical power state detection sensor 126 detects current, voltage, and the like in the inverter 54 and in a distribution panel (not shown).

A generator air flow detection sensor 128 detects the flow volume of generator air supplied to the generating chamber 10.

A reforming air flow volume sensor 130 detects the volume of reforming air flow supplied to the reformer 20.

A fuel flow volume sensor 132 detects the flow volume of fuel gas supplied to the reformer 20.

A water flow volume sensor 134 detects the flow volume of pure water supplied to the reformer 20.

A water level sensor 136 detects the water level in pure water tank 26.

A pressure sensor 138 detects pressure on the upstream side outside the reformer 20.

An exhaust temperature sensor 140 detects the temperature of exhaust gas flowing into the hot water producing device 50.

As shown in FIG. 3, a generating chamber temperature sensor 142 is disposed on the front surface side and rear surface side around the fuel cell assembly 12, and detects the temperature around the fuel cell stack 14 in order to estimate the temperature of the fuel cell stack 14 (i.e., of the fuel cell 84 itself).

A combustion chamber temperature sensor 144 detects the temperature in combustion chamber 18.

An exhaust gas chamber temperature sensor 146 detects the temperature of exhaust gases in the exhaust gas chamber.

A reformer temperature sensor 148 detects the temperature of the reformer 20 and calculates the reformer 20 temperature from the intake and exit temperatures on the reformer 20.

If the solid oxide fuel cell system (SOFC) is placed outdoors, the outside temperature sensor 150 detects the temperature of the outside atmosphere. Sensors to detect outside atmospheric humidity and the like may also be provided.

Signals from these various sensor types are sent to the control unit 110; the control unit 110 sends control signals to the water flow regulator unit 28, the fuel flow regulator unit 38, the reforming air flow regulator unit 44, and the oxidant gas supply device 45 based on data from the sensors, and controls the flow volumes in each of these units.

Next, referring to FIG. 7, we discuss the operation of a solid oxide fuel cell system (SOFC) according to the present embodiment at the time of start up. FIG. 7 is a timing chart showing the operations of a solid oxide fuel cell system (SOFC) according to an embodiment of the present invention at the time of start up.

At the beginning, in order to warm up the fuel cell module 2, operation starts in a no-load state, i.e., with the circuit which includes the fuel cell module 2 in an open state. At this point current does not flow in the circuit, therefore the fuel cell module 2 does not generate electricity.

First, reforming air is supplied from the reforming air flow regulator unit 44 to the reformer 2 on the fuel cell module 2. At the same time, generating air is supplied from the oxidant gas supply device 45 to the fuel cell module 2 air heat exchanger 22, and this generating air reaches the generating chamber 10 and the combustion chamber 18.

Immediately thereafter, fuel gas is also supplied from the fuel flow regulator unit 38, and fuel gas into which reform area is blended passes through the reformer 20, the fuel cell stack 14, and the fuel cell unit 16 to reach the combustion chamber 18.

Next, ignition is brought about by the ignition device 83, and fuel gas and air (reforming air and generating air) supplied to the combustion chamber 18 is combusted. This combustion of fuel gas and air produces exhaust gas; the generating chamber 10 is warmed by this exhaust gas, and when the exhaust gas rises into the fuel cell module 2 sealed space 8, the fuel gas, which includes reforming air in the reformer 20 is warm, as is the generating air inside the air heat exchanger 22.

At this point, fuel gas into which reform area is blended is supplied to the reformer 20 by the fuel flow regulator unit 38 at the reforming air flow regulator unit 44, therefore the partial oxidation reforming reaction POX given by Expression (1) proceeds. This partial oxidation reforming reaction POX is an exothermic reaction, and therefore has favorable starting characteristics. The fuel gas whose temperature has risen is supplied from the fuel gas supply line 64 to the bottom of the fuel cell stack 14, and by this means the fuel cell stack 14 is heated from the bottom, and the combustion chamber 18 is also heated by the combustion of the fuel gas and air, so that the fuel stack 14 is also heated from above, enabling as a result an essentially uniform rise in temperature in the vertical direction of the fuel cell stack 14. Even though the partial oxidation reforming reaction POX is progressing, the ongoing combustion reaction between fuel gas and air is continued in the combustion chamber 18.

C_mH_n+xO₂→aCO₂+bCO+cH₂ (1)

When the reformer temperature sensor 148 detects that the reformer 20 has reached a predetermined temperature (e.g. 600° C.) after the start of the partial oxidation reforming reaction POX, a pre-blended gas of fuel gas, reforming air, and steam is applied to the reformer 20 by the water flow regulator unit 28, the fuel flow regulator unit 38, and the reforming air flow regulator unit 44. At this point an auto-thermal reforming reaction ATR, which makes use of both the aforementioned partial oxidation reforming reaction POX and the steam reforming reaction SR described below, proceeds in the reformer 20. This auto-thermal reforming reaction ATR can be internally thermally balanced, therefore the reaction proceeds in a thermally independent fashion inside the reformer 20. In other words, when there is a large amount of oxygen (air), heat emission by the partial oxidation reforming reaction POX dominates, and when there is a large amount of steam, the endothermic steam reforming reaction SR dominates. At this stage, the initial stage of startup has passed and some degree of elevated temperature has been achieved within the generating chamber 10, therefore even if the endothermic reaction is dominant, no major drop in temperature will be caused. Also, the combustion reaction continues within the combustion chamber 18 even as the auto-thermal reforming reaction ATR proceeds.

When the reformer temperature sensor 146 detects that the reformer 20 has reached a predetermined temperature (e.g., 700° C.) following the start of the auto-thermal reforming reaction ATR shown as Expression (2), the supply of reforming air by the reforming air flow regulator unit 44 is stopped, and the supply of steam by the water flow regulator unit 28 is increased. By this means, a gas containing no air and only containing fuel gas and steam is supplied to the reformer 20, where the steam reforming reaction SR of Expression (3) proceeds.

C_mH_n+xO₂+yH₂O→aCO₂+bCO+cH₂ (2)

C_mH_n+xH₂O→aCO₂+bCO+cH₂ (3)

This steam reforming reaction SR is an endothermic reaction, therefore the reaction proceeds as a thermal balance is maintained with the combustion heat from the combustion chamber 18. At this stage, the fuel cell module is in the final stages of startup, therefore the temperature has risen to a sufficiently high level within the generating chamber 10 so that no major temperature dropped is induced in the generating chamber 10 even though an endothermic reaction is proceeding. Also, the combustion reaction continues to proceed in the combustion chamber 18 even as the steam reforming reaction SR is proceeding.

Thus, after the fuel cell module 2 has been ignited by the ignition device 83, the temperature inside the generating chamber 10 gradually rises as a result of the partial oxidation reforming reaction POX, the auto-thermal reforming reaction ATR, and the steam reforming reaction SR which proceed in that sequence. Next, when the temperature inside the generating chamber 10 and the temperature of the fuel cell 84 reaches a predetermined generating temperature which is lower than the rated temperature at which the cell module 2 can be stably operated, the circuit which includes the fuel cell module 2 is closed, electrical generation by the fuel cell module 2 begins, and current then flows to the circuit. Generation of electricity by the fuel cell module 2 causes the fuel cell 84 itself to emit heat, such that the temperature of the fuel cell 84 rises. As a result, the rated temperature at which the fuel cell module 2 is operated becomes, for example, 600° C.-800° C.

Following this, a quantity of fuel gas and air greater than that consumed by the fuel cell 84 is applied in order to maintain the rated temperature and continue combustion inside the combustion chamber 18. Generation of electricity by the high reform-efficiency steam reforming reaction SR proceeds while electricity is being generated.

Next, referring to FIG. 8, we discuss the operation upon stopping the solid oxide fuel cell system (SOFC) of the present embodiment. FIG. 8 is a timing chart showing the operations which occur upon stopping the solid oxide fuel cell system (SOFC) of the present embodiment.

As shown in FIG. 8, when stopping the operation of the fuel cell module 2, the fuel flow regulator unit 38 and the water flow regulator unit 28 are first operated to reduce the quantity of fuel gas and steam being supplied to the reformer 20.

When stopping the operation of the fuel cell module 2, the quantity of generating air supplied by the reforming air flow regulator unit 44 into the fuel cell module 2 is being increased at the same time that the quantity of fuel gas and steam being supplied to the reformer 20 is being reduced; the fuel cell assembly 12 and the reformer 20 are air cooled to reduce their temperature. Thereafter, when the temperature of the generating chamber drops to, for example, 400° C., supply of the fuel gas and steam to the reformer 20 is stopped, and the steam reforming reaction SR in the reformer 20 ends. Supply of the generating air continues until the temperature in the reformer 20 reaches a predetermined temperature, e.g. 200° C.; when the predetermined temperature is reached, the supply of generating air from the oxidant gas supply device 45 is stopped.

Thus in the present embodiment, the steam reforming reaction SR by the reformer 20 and cooling by generating air are used in combination, therefore when the operation of the fuel cell module 2 is stopped, that operation can be stopped relatively quickly.

Next, referring to the FIG. 9 through 17, we discuss the control of a solid oxide fuel cell system 1 according to a first embodiment of the present invention.

FIG. 9 is graph showing the relationship between output current and fuel supply amount in the solid oxide fuel cell system 1 of the first embodiment of the present invention.

FIG. 10 is a graph showing the relationship between output current and the amount of heat produced by supplied fuel in the solid oxide fuel cell system 1 of the first embodiment of the present invention.

First, as shown by the solid line in FIG. 9, the solid oxide fuel cell system 1 of the present embodiment is capable of changing output at or below the rated output power of 700 W (output current 7 A) in response to power demand. The fuel supply amount (L/min) deemed necessary to output a required power is set by the Basic Fuel Supply Table shown by the solid line in FIG. 9. A control section 110, which serves as controller, determines a fuel supply amount based on the fuel supply amount table in response to the power demand detected by electrical power state detecting sensor 126, which serves as demand power detection circuit; the fuel flow regulator unit 38 serving as fuel supply device is controlled based on this.

The amount of fuel needed for generation is proportional to output power (output current), but as shown by the solid line in FIG. 9, the fuel supply amount set in the basic fuel supply amount table is not proportional to output current. This is because when the fuel supply amount is reduced in proportion to output power, it becomes impossible to maintain the fuel cell units 16 in the fuel cell module 2 at a temperature capable of generating electricity. Therefore in the present embodiment the basic fuel supply table is set at a fuel utilization rate of approximately 70% when generating a large power in the region of a 7 A output current, and is set at a fuel utilization rate of approximately 50% when generating a small power in the region of a 2 A output current. Thus by reducing the fuel utilization rate in the small power generation region and using the fuel not used for generation to combust and heat the reformer 20 and the like, temperature drops in the fuel cell units 16 can be suppressed, and an electrical generation temperature can be maintained in the fuel cell module 2.

However, reducing the fuel utilization rate causes an increase in fuel not contributing to electrical generation, so the energy efficiency of the solid oxide fuel cell system 1 declines in the small power generation region. In the solid oxide fuel cell system 1 of the present embodiment, a fuel table change circuit 110a built into the control section 110 changes or corrects the fuel supply amount set in the basic fuel supply table in response to predetermined conditions, reducing the fuel supply amount as shown by the dotted line in FIG. 9, so that the fuel utilization rate in the small power generation region is raised. The energy efficiency of the solid oxide fuel cell system 1 is thus improved.

FIG. 10 is a graph schematically showing the relationship between output current when fuel is supplied based on the basic fuel supply table versus amount of heat from the supplied fuel in the solid oxide fuel cell system 1 of the present embodiment. As shown by the dot-and-dash line in FIG. 10, the amount of heat needed to make the fuel cell module 2 thermally autonomous and to operate stably increases monotonically with the increase in output current. The solid line graph in FIG. 10 shows the heat amount when fuel is supplied according to the basic fuel supply table. In this embodiment, the necessary heat amount indicated by the dot-and-dash line and the amount of heat supplied based on the basic fuel supply table shown by the solid line are approximately matched in the region below an output current of 5 A, which corresponds to medium power generation.

Furthermore, in the region above an output current of 5 A, the heat amount shown by the solid line and supplied according to the basic fuel supply table is greater than the heat amount shown by the dot-and-dash line, which is the minimum requirement for thermal autonomy. The surplus heat amount between the solid line and the dotted line is accumulated in the insulating material 7 serving as heat storing material. There is also a correlation between the output current from the solid oxide fuel cell system 1 and the temperature of the fuel cell units 16 in the fuel cell module 2 when this current is being output in a steady state; since the temperature of the fuel cell units 16 must be raised in order to increase output current, the temperature of the fuel cell units 16 is high when in a high output current state. In the present embodiment an output current of 5 A corresponds to approximately 633° C., which is the stored heat temperature Th. Therefore in the solid oxide fuel cell system 1 of the present embodiment, a larger amount of heat is accumulated in the insulating material 7 when the output current is 5 A and the stored heat temperature Th=approximately 633° C. or above.

This stored heat temperature Th is set to a temperature corresponding to 500 W (an output current of 5 A), which is larger than the 350 W representing the midpoint value of the generated power range of 0 W-700 W. In the region of an output current of 5 A or below, the heat amount supplied based on the basic fuel supply table is set to be approximately the same as the minimum required heat amount for thermal autonomy (the heat amount in the basic fuel supply table is slightly higher). Therefore as shown by the dotted line example in FIG. 10, the heat amount needed for thermal autonomy is lacking when the fuel supply amount from the basic fuel supply table is corrected to reduce the fuel supply amount.

In the present embodiment, as described below, a correction is made in the small power generation region to temporarily reduce the fuel supply amount set by the basic fuel supply table and raise the fuel utilization rate. At the same time, the lacking heat amount caused by the reduction in the fuel supply amount from the basic fuel supply table is replenished by using the heat amount accumulated in the insulating material 7 while the fuel cell module 2 is operating in a region above the stored heat temperature Th. Note that in the present embodiment, because the heat capacity of the insulating material 7 is extremely high, the heat amount accumulated in the insulating material 7 can be used over a period of more than 2 hours when the fuel cell module 2 is operating in the small generated power region after operating for a predetermined time at high generated power, and the fuel utilization rate can be raised by performing a correction to reduce the fuel supply amount during this interval.

Also, in the present embodiment when the output current is 5 A and the stored heat temperature Th=approximately 633° C. or above, the basic fuel supply table is set so that a greater heat amount is accumulated in the insulating material 7, but the basic fuel supply table can also be set approximately the same as the minimum required heat amount for thermal autonomy, even in an output current region of 5 A or above. That is, in a region where the generated power is large, the operating temperature of the fuel cell module 2 is higher than when generated power is small, therefore even if the fuel supply amount is set for the minimum required heat amount for thermal autonomy, the usable heat amount during small power generation can be accumulated in the insulating material 7. As in this embodiment, the required heat amount can be reliably accumulated in the insulating material 7 during the short evening time period when power demand is at peak by actively setting the fuel supply amount to be high at times of high generated power.

Next, referring to the FIG. 11 through 17, we discuss the specific control of a solid oxide fuel cell system 1 according to the first embodiment of the present invention. FIG. 11 is a control flow chart of the fuel supply amount in the solid oxide fuel cell system of the first embodiment of the present invention. FIG. 12 is a stored heat amount estimate table used to estimate the amount of heat accumulated in the insulating material 7. FIG. 13 is a graph of the stored heat amount estimate table. FIG. 14 is a graph showing the values of first modifying coefficients relative to output current. FIG. 15 is a graph showing the values of second modifying coefficients relative to output current.

The flow chart shown in FIG. 11 is executed at predetermined time intervals in the control section 110 during generating operations of the solid oxide fuel cell system 1. First, as step S1 in FIG. 11, integration processing is executed based on the stored heat estimating table shown in FIG. 12. The integral value Ni calculated in step S1 is, as described below, a value which will serve as an index for a usable stored heat amount accumulated in the insulating material 7 or the like, and lies between 0 and 1.

Next, in step S2, a judgment is made as to whether the integral value Ni calculated in step S1 is a 0. If the integral value Ni is 0, the system proceeds to step S3; if other than 0, it proceeds to step S4.

When the integral value Ni is a 0, it is estimated that heat sufficient to be usable has not accumulated in the insulating material 7 or the like, therefore in step S3 the fuel supply amount is determined by the control section 110 based on the basic fuel supply table. The control section 110 sends a signal to the fuel flow regulator unit 38, and the determined fuel supply amount is supplied to the fuel cell module 2. Therefore in this case no correction is executed to raise the fuel utilization rate even if generated power is small. After step S3, one iteration of the processing in the flow chart of FIG. 11 is completed.

In step S4, on the other hand, the amount of change in the rate of utilization versus the fuel supply amount determined by the basic fuel supply table is determined based on the integral value Ni. That is, when the integral value Ni is 1, the fuel supply amount is reduced the most; the fuel utilization rate is improved, and the amount of reduction in fuel supply amount decreases as the integral value Ni decreases.

Next, in step S5, a first modifying coefficient is determined based on the graph shown in FIG. 14. As shown in FIG. 14, the first modifying coefficient is 1 in the small output current region, and goes to 0 when output current exceeds 4.5 A. That is, in the small generated power region, a correction is executed to reduce the fuel supply amount by using the heat amount accumulated in the insulating material 7, and the fuel utilization rate is improved, whereas no correction is executed in the large generated power region. This is because in the large generated power region operation can be conducted at a sufficiently high the fuel utilization rate using the basic fuel supply table, as well, and when the generated power is large, it is difficult to utilize the stored heat in the insulating material 7 due to the high temperature inside the fuel cell module 2.

Next, in step S6, a second modifying coefficient is determined based on the graph shown in FIG. 15. As shown in FIG. 15, the second modifying coefficient is 0.5 in the region where output current is 1 A or below, and grows linearly in the output current region of 1 to 1.5 A, reaching 1 at an output current of 1.5 or above. In other words, in the power generation region of 150 W or below, which is the utilization suppression generation amount, the absolute value of the fuel supply amount according to the basic fuel supply table is small, so there is a risk of damage to the fuel cell units 16 when a large correction is made resulting in a reduced fuel supply amount. Also, by keeping the amount of correction to the basic fuel supply table low, the heat amount accumulated in the insulating material 7 can be used a little at a time, making it possible to utilize the stored heat over a long period. Therefore the second modifying coefficient causes the amount of correction to the basic fuel supply table to be reduced to the degree that generated power is small, so that it functions as a change period extension circuit for extending the time period for changing or correcting the basic fuel supply table. This change period extension circuit operates so that the stored heat accumulated in the insulating material 7 is used after correction to the basic fuel supply table begins, therefore the stored heat amount gradually decreases as the length of time during which correction is being executed increases, and since the amount of correction to the fuel utilization rate declines when the stored heat amount declines, the period over which stored heat can be used is further extended.

Note that it is also acceptable not to modify the correction amount using the second modifying coefficient.

Next, in step S7, the first modifying coefficient determined in step S5 is multiplied by the second modifying coefficient determined in step S6 to determine a final utilization change rate. Moreover, the amount of correction to the water supply amount is determined according to the determined fuel supply amount, and the generating air supply amount is reduced 10% relative to the normal air supply amount. Also, the fuel supply amount control gain is increased by 10% relative to the control gain during normal operation, thereby improving following characteristics when changing the fuel supply amount.

Thus by increasing the fuel supply amount control gain when executing corrections to the basic fuel supply table and setting fuel supply amount following characteristics to a high level, the fuel supply amount can be quickly increased when the post-correction fuel utilization rate declines with the reduction in estimated stored heat amount. Excessive cooling of the fuel cell module 2 caused by delays in response to the increase in fuel supply amount can thus be prevented. Therefore the control to increase gain in step S7 acts as an overcooling prevention circuit. By reducing the secondary generating air amount by 10%, cooling of the of the cells, reformer, etc., inside fuel cell module 2 can be suppressed, thereby enabling the reduction in stored heat amount to be inhibited and permitting effective use of stored heat. As a result, control to reduce the secondary air by 10% also acts as an overcooling prevention circuit.

In step S8 the control section 110 sends a signal to the fuel flow regulator unit 38, the water flow regulator unit 28, and the generating air flow regulator unit 45, and the amounts of fuel, water, and generating air determined in step S7 are supplied to the fuel cell module 2. After step S8, one iteration of the processing in the flow chart of FIG. 11 is completed. When the integral value Ni declines as a result of executing a correction to the basic fuel supply table, processing shifts again from step S2 to step S3. Correction to the basic fuel supply table thus ends, and control of the fuel supply amount based on the basic fuel supply table is again executed.

Next, referring to FIGS. 12 and 13, we discuss estimation of the stored heat accumulated in the insulating material 7 or the like.

Estimation of stored heat is executed by a stored heat estimating circuit 110b (FIG. 6) built into the control section 110. When step S1 in the flow chart shown in FIG. 11 is executed, the stored heat estimating circuit 110b reads the temperature of the generating chamber from the generating chamber temperature sensor 142 serving as temperature detection device. Next, the stored heat estimating circuit 110b refers to the stored heat estimating table shown in FIG. 12 and determines an add/subtract value based on the generating chamber temperature sensor 142 detected temperature Td. For example, when the detected temperature Td is 645° C., the addition value is determined at 1/50,000, and this value is added to the integral value Ni. Integration of this type is executed at a predetermined time interval after startup of the solid oxide fuel cell system 1. In this embodiment, the flow chart in FIG. 11 is executed every 0.5 seconds, therefore an integration is executed once each 0.5 seconds. Therefore when the detected temperature Td is fixed at 645° C., for example, a value of 1/50,000 is integrated once each 0.5 seconds, and the integral value Ni grows.

This integral value Ni reflects the temperature history in the fuel cell module 2, and within the generating chamber, etc., and becomes a value serving as an index for showing the level of stored heat amount accumulated in the insulating material 7 or the like. This integral value Ni is limited to a range of 0 to 1; when the integral value Ni reaches 1, that value is held at 1 until the next subtraction occurs; when the integral value Ni has declined to 0, the value is held at 0 until the next addition takes place. In the present invention, it is assumed that the value serving as index for indicating the degree of the stored heat amount is an estimated value for the stored heat amount. Therefore in the present invention the stored heat amount is estimated based on the temperature of the fuel cell module 2.

The utilization change amount relative to the basic fuel supply table, which is calculated in step S4 of the flow chart shown in FIG. 11, is determined by multiplying a predetermined correction amount times the integral value Ni. Therefore the larger the integral value Ni serving as an estimated stored heat amount, the more the correction amount increases; the utilization change amount is at a maximum when the integral value Ni is a 1, and when the integral value Ni is a 0, no correction is executed (utilization change amount=0). That is, when the integral value Ni is 0, the stored heat amount estimated value is judged to be under the change-executable stored heat amount for executing corrections to the basic fuel supply table, and no correction to the fuel utilization rate is executed.

As shown in FIGS. 12 and 13, in the present embodiment integration is carried out as addition when the detected temperature Td is higher than the reference detected temperature Tcr of 635° C., and as subtraction when it is lower than same. That is, when the detected temperature Td is higher than the reference temperature Tcr, an amount of heat usable for increasing the fuel utilization rate in the insulating material 7 or the like is accumulated, and when lower than the change reference temperature Tcr, it is assumed that heat accumulated in the insulating material 7 or the like will be carried off, and the integral value Ni is calculated. Put another way, the integral value Ni corresponds to the time integral of the temperature deviation relative to the detected temperature Td change reference temperature Tcr, and the stored heat amount is estimated based on this integral value Ni.

Note that in this embodiment the change reference temperature Tcr which serves as reference for estimating the stored heat amount is set to be slightly higher than the stored heat temperature Th at which there is a large accumulation of heat (FIG. 10). For this reason the estimated value of the stored heat amount is estimated to be slightly less than actual. Therefore corrections to raise the fuel utilization rate are executed excessively based on the stored heat amount estimated higher than the actual, and inducement of excessive temperature drops in the fuel cell module 2 is avoided.

Therefore a correction is made to the basic fuel supply table when generated power decreases in a state whereby the detected temperature Td is higher than the change reference temperature Tcr. On the other hand, when the generated power has declined in a state whereby the detected temperature Td is lower than the change reference temperature Tcr, the amount of correction to the basic fuel supply table is reduced (by the decline in integral value Ni), or the correction is not executed (when integral value Ni is 0).

Specifically, as shown in FIGS. 12 and 13, when the detected temperature Td is below 580° C., there is a reduction of 20/50,000 from the integral value Ni. When the detected temperature Td is 580° C. or above and less than 620° C., there is a reduction from integral value Ni of 10/50,000×(620−Td)/(620−580). When the detected temperature Td is 620° C. or above and less than 630° C., there is a reduction from integral value Ni of 1/50,000. Thus the integral value Ni is rapidly decreased in proportion to the degree to which the detected temperature Td is less than change reference temperature Tcr, and with this the amount of correction to the fuel utilization rate is also rapidly reduced.

On the other hand, when the detected temperature Td is 650° C. or above, 1/50,000×(Td−650) is added to the integral value Ni. When the detected temperature Td is 640° C. or above and less than 650° C., 1/50,000 is added to the integral value Ni. Thus the integral value Ni is rapidly increased in proportion to the degree to which the detected temperature Td is more than change reference temperature Tcr, and with this the amount of correction to the fuel utilization rate is also rapidly increased.

Furthermore, between detected temperatures Td of 630° C. and 640° C., processing will differ between cases where the detected temperature Td is tending to increase versus those in which it is tending to decrease.

That is, when the detected temperature Td is between 630° C. and 632° C., an addition value of 0 is adopted (no add/subtract is performed) when the detected temperature Td is in a rising trend, whereas 1/50,000 is subtracted when it is in a declining trend. Thus when the detected temperature Td is less than the change reference temperature Tcr, and the difference between them is a minor deviation temperature of 5° C. or below, integral value Ni is more rapidly decreased when the detected temperature Td is on a decreasing trend than when it is on an increasing trend. Here, when the insulating material 7 or the like has an extremely high heat capacity, and the detected temperature Td has for the moment entered a decreasing trend, it can be anticipated that the temperature will continue to drop for a certain period of time. Therefore in such circumstances it is necessary to avoid the risk of a major temperature drop in the fuel cell module 2 by quickly reducing the integral value Ni and suppressing corrections raising the fuel utilization rate (reducing the fuel supply amount).

On the other hand, when the detected temperature Td is between 638° C. and 640° C., 1/50,000 is added when detected temperature Td is on an increasing trend, whereas an addition value of 0 is adopted (no add/subtract is performed) when it is in a declining trend. As described above, when the insulating material 7 or the like has an extremely high heat capacity, and the detected temperature Td has for the moment entered an increasing trend, it can be anticipated that the temperature will continue to rise for a certain period of time. Therefore in such circumstances stored heat is actively utilized to improve the fuel utilization rate by promoting correction to raise the fuel utilization rate (reduce the fuel supply amount) by quickly increasing the integral value Ni.

Different values for the add/subtract value relative to the integral value Ni are thus adopted in accordance with the state of change in the detected temperature Td. Therefore the relationship between the temperature deviation between the detected temperature Td and the change reference temperature Tcr, and the integral value Ni reflecting the stored heat amount, is changed in response to the state of change in the detected temperature Td.

Also, when the detected temperature Td is 632° C. or above and less than 638° C., the detected temperature Td is close to the change reference temperature Tcr of 635° C. and is deemed to be stable; 0 is used as the added value regardless of the detected temperature Td trend, and the current status is maintained.

Next, referring to FIG. 16, we explain processing when the fuel cell module 2 has degraded. FIG. 16 is a flowchart for changing correction amounts when the fuel cell module 2 has degraded.

When degradation of the fuel cell units 16 advances due to long years of use, the power extractable from a given fuel supply amount declines. In conjunction with this, the temperature of the fuel cell units 16 also rises for the same power produced. In the solid oxide fuel cell system 1 of the present embodiment, a determination of degradation of the fuel cell module 2 (the fuel cell units 16) is made based on the temperature of the fuel cell module 2 at a predetermined electrical generating time. Note that degradation of a fuel cell module can also be determined from the power or voltage, etc., which can be extracted from a predetermined fuel supply amount.

The flow chart shown in FIG. 16 is executed each predetermined period—for example several months to several years—by the control section 110. First, in step S21 of FIG. 16, a judgment is made as to whether the fuel cell units 16 have degraded. If it is determined that the fuel cell units 16 have not degraded, the processing of one iteration of the flow chart shown in FIG. 16 ends. If it is determined that the fuel cell units 16 have degraded, the system advances to step S22.

In step S22 the change reference temperature Tcr is changed to a value 5° C. higher, and the third modifying coefficient is set to 0.8, completing the processing of one iteration of the flowchart shown in FIG. 16. This change is made to match the temperature which serves as the reference for the fuel utilization rate correction, since when the fuel cell units 16 degrades, the operating temperature of the fuel cell module 2 as a whole shifts to the higher temperature side. The third modifying coefficient is multiplied times the amount of change in the utilization rate determined in step S4 of FIG. 11. A third modifying coefficient is set prior to the degradation of the fuel cell units 16, and when it is determined that degradation has occurred, it is changed to 0.8, and the utilization rate change amount is reduced by 20%. Promotion of degradation of the fuel cell units 16 caused by large corrections to the fuel utilization rate with the fuel cell units 16 in a degraded state is thus prevented. Note that once it is determined that the fuel cell module 2 has degraded, the threshold value for the temperature used to determine degradation is thereafter changed when determining the further advancement of degradation. It is therefore possible to determine the degree of advancement of degradation over a number of iterations. The value of the change reference temperature Ter is also changed each time a judgment of degradation occurs.

Next, referring to the FIG. 17, we discuss the operation of a solid oxide fuel cell system 1 according to a first embodiment of the present invention. FIG. 17(a) is a diagram conceptually showing the behavior of a solid oxide fuel cell system 1 according to the present embodiment; (b) schematically shows changes in power demand over a day in a typical residence. The upper graph in FIG. 17(a) conceptually illustrates the behavior when there is not a usable amount of heat accumulated in the insulating material 7; the middle and lower graphs respectively show the cases for small and large accumulated heat. When, as in the upper portion of FIG. 17(a), the time duration of operation with a large fuel supply amount is short, a usable amount of heat is not accumulated in the insulating material 7, therefore operation after generated power has declined is determined based on the basic fuel supply table, and an increase in the fuel utilization rate will not occur. When, on the other hand, a high power generation operation continues for a certain amount of time as in the middle portion of FIG. 17(a), operation subsequent to the reduction of generated power is carried out by utilizing the heat amount regulated in the insulating material 7 when power generation was large, therefore high-efficiency operation with a fuel supply amount reduced from that of the basic fuel supply table is carried out during the period that a usable amount of heat remains in the insulating material 7. Thus fuel corresponding to the shaded portion of the middle graph is saved. Furthermore, when a large generated power operation is carried out for a long period of time as shown in the bottom portion of FIG. 17(a), a large amount of heat is accumulated in the insulating material 7, therefore high-efficiency operation utilizing accumulated heat is carried out over a longer time, and even more fuel is saved.

Next, in FIG. 17(b) the power demand used in a residence is shown by the solid line, the power generated by the solid oxide fuel cell system 1 is shown by the dotted line, and the integral value Ni serving as an index of the stored heat amount is shown by the dot and dash line.

First, at time t0-t1 when household members are asleep, the demanded power used in the residence is small; at time t1 the occupants awake and the power demand increases. In conjunction with this, the generated power from the solid oxide fuel cell system 1 also increases, and that portion of the generated power exceeding the rated power of the fuel cell is supplied from the power grid. Since the state in which power use is small continues for approximately 6 to 8 hours during which the occupants are asleep, the accumulated heat (integral value Ni) estimated by the stored heat estimating circuit 110b is 0 or an extremely small value.

When, at time t1, generated power increases and the fuel cell module 2 is operating at a temperature higher than the stored heat temperature Th, the stored heat amount gradually increases, and at time t2 increases to approximately 1, which is the maximum integral value. Thereafter, power demand suddenly drops when occupants leave the house at time t3. Thus when generated power drops in a state whereby the stored heat amount is equal to or greater than the change execution stored heat amount, a correction to the basic fuel supply table by the fuel table change circuit 110a is executed, and the fuel utilization rate at low generated power is increased. When operated at a raised the fuel utilization rate, the heat amount accumulated in the insulating material 7 is utilized, therefore the integral value Ni also declines. In the embodiment, operation at an improved fuel utilization rate can be carried out for approximately 1 to 3 hours.

Next, when occupants return home at time t4, the power demand again increases. The integral value Ni increases with some delay (time t4-t5) after the increase in power demand at time t4 and again reaches the maximum value. Next, at time t6 the occupants retire, and an increased fuel utilization rate operation is conducted after the power demand has decreased (time t6 and later).

When the power demand at a residence changes in this manner, operation at an increased fuel utilization rate, in which the heat amount stored in the insulating material 7 is utilized, is carried out twice a day. This period of operation at heightened fuel utilization rate reaches as much as 20-50% of the small generated power period, and improves the overall energy efficiency of the solid oxide fuel cell system 1.

In conventional solid oxide fuel cell system, when generated power is small, generating heat drops, resulting in a tendency for the fuel cell module temperature to drop. The fuel utilization rate is therefore reduced at times of low generated power, and fuel not used for electrical generation heats the fuel cell module to prevent excessive temperature drops. In particular, in solid oxide fuel cell system of type in which the reformer is disposed within the fuel cell module, endothermic reactions occur inside the reformer, increasing the tendency toward temperature drops.

In the solid oxide fuel cell system 1 of the present invention, when generated power is small, if it is estimated by the stored heat estimating circuit 110b that a usable amount of heat has accumulated in the insulating material 7, the basic fuel supply table is temporarily corrected so that the fuel utilization rate increases (FIG. 11, step S7). Thermal autonomy of the solid oxide fuel cell system 1 is thus maintained and overall energy efficiency of the solid oxide fuel cell system 1 is improved, while excessive temperature drops are avoided.

Using the solid oxide fuel cell system 1 of the present embodiment, settings are made (FIG. 10) so that more heat is accumulated in the insulating material 7 in a temperature region above a predetermined stored heat temperature Th, therefore accumulated heat can be effectively utilized by actively accumulating heat in a region higher than the stored heat temperature Th at which the fuel utilization rate can be raised, consuming this heat at times of small power generation when the fuel cell module 2 temperature is comparatively low and stored heat is easy to utilize, thus effectively using the stored heat.

Using the solid oxide fuel cell system 1 of the present embodiment, the detected temperature Td detected by the generating chamber temperature sensor 142 reflects the heat amount stored in the insulating material 7, therefore the basic fuel supply table can be easily corrected using the relationship between detected temperature Td and change reference temperature Tcr.

Using the solid oxide fuel cell system 1 of the present embodiment, the change reference temperature Tcr is set higher than the stored heat temperature Th (FIG. 10), therefore stored heat will be used at or above the change reference temperature Tcr, which is higher than the stored heat temperature Th at which there is abundant heat stored in the insulating material 7, so the risk can be avoided of stored heat being used in a low stored heat amount state, causing an excessive temperature drop.

Using the solid oxide fuel cell system 1 of the present embodiment, the stored heat estimating circuit 110b estimates the stored heat amount based on the history of the detected temperature Td (FIG. 11, step S4, FIG. 13), therefore a more accurate estimate can be made compared to estimation of the stored heat amount using the current detected temperature Td alone, and stored heat can be more effectively used.

Using the solid oxide fuel cell system 1 of the present embodiment, the stored heat amount accumulated in the insulating material 7 is estimated by integrating temperature deviations over time (FIG. 11, step S4, FIG. 13); when the time of operation at a temperature higher than the stored heat temperature Th is long, the estimated stored heat amount is large; when that time is short, the estimated stored heat amount is small, and a more accurate estimation of the stored heat amount can be achieved. The risk of excessive temperature drops and the like due to utilization of stored heat can thus be reliably avoided.

Using the solid oxide fuel cell system 1 of the present embodiment, the amount of correction for raising the fuel utilization rate is increased as the stored heat amount increases (FIG. 11, step S4, FIG. 13), therefore correction can be performed to greatly improve the fuel utilization rate while reliably avoiding the risk of excessive temperature drops and the like.

Using the solid oxide fuel cell system 1 of the present embodiment, the correction amount is suddenly increased to the extent the detected temperature Td is high, while the correction amount suddenly decreases to the extent the detected temperature Td is low (FIG. 13), therefore a significant fuel utilization rate correction can be made when the detected temperature Td is high, and the compensation amount can be rapidly decreased when the detected temperature Td is low, so excessive temperature drops can be reliably prevented.

Using the solid oxide fuel cell system 1 of the present embodiment, the relationship between the estimated stored heat amount and the compensation amount are changed in response to the state of the detected temperature Td or generated power (FIG. 13, 630-640° C.; FIGS. 14, 15, 18), therefore the two goals of preventing excessive temperature drops and effectively utilizing stored heat can be met.

Using the solid oxide fuel cell system 1 of the present embodiment, the fuel table change circuit 110a reduces the compensation amount when the generated power is small (FIG. 15), therefore the amount of stored heat used declines, and the period during which stored heat can be used can be extended.

Using the solid oxide fuel cell system 1 of the present embodiment, the estimated value of the stored heat amount drops suddenly when the detected temperature Td is in a declining trend and the difference between the detected temperature Td and the change reference temperature Tcr is at or below a predetermined very small deviation temperature (FIG. 13, 630-632° C.), therefore the estimated value for the stored heat amount is rapidly reduced when the detected temperature Td is in a declining phase, and excessive temperature drops can be reliably prevented.

Using the solid oxide fuel cell system 1 of the present embodiment, the compensation amount for increasing the fuel utilization rate is changed in response to the state of the fuel cell module 2 (FIGS. 14, 15, 16), therefore corrections to the fuel utilization rate not conforming to the state of the fuel cell module 2 can be prevented.

Using the solid oxide fuel cell system 1 of the present embodiment, the change reference temperature Tcr is changed to a high value when the fuel cell module 2 degrades (FIG. 16), therefore the fuel utilization rate can be corrected without placing an excessive burden on the fuel cell module 2 when it has degraded and its operating temperature has risen.

Using the solid oxide fuel cell system 1 of the present embodiment, the compensation amount is reduced when the fuel cell module 2 degrades (FIG. 16, step S22), therefore promotion of degradation can be suppressed by correcting the fuel utilization rate.

Also, in the above-described first embodiment of the present invention, the calculated subtraction or addition value to the integral value Ni was being calculated based on only the detected temperature Td shown in the stored heat amount estimation table shown in FIG. 12, however as a variant example, the add/subtract value can also be determined by adding in output current. For example, the integral value Ni can be calculated by integrating the value obtained by multiplying the add/subtract value determined based on the FIG. 12 stored heat amount estimate table times the current correction coefficient shown in FIG. 18. As shown in FIG. 18, the current correction coefficient is determined as 1/7 for an output current of 3 A or below and at 1/12 for 4 A or above, and is linearly decreased from 1/7 to 1/12 between 3 and 4 A.

By multiplying by the current correction coefficient set in this manner, the integral value Ni drops suddenly in the small generated power region, whereas increases and decreases in the integral value Ni in the medium generated power and greater region become gradual. Therefore by correcting the basic fuel supply table, the integral value Ni is gradually decreased during small power generation, which consumes large amounts of heat accumulated in the insulating material 7. The risk of inducing extraordinary temperature drops by overestimating the stored heat amount can thus be reliably avoided.

In the above-described embodiment the add/subtract value for addition or subtraction to the integral value Ni was determined by the detected temperature Td alone, as shown in FIG. 13, but the present invention can also be configured so that the add/subtract value is also dependent on output current. For example, at an output current of 3 A or below (an output power of 300 W), the change reference temperature Tcr can be raised about 2° C. and the entire FIG. 13 graph shifted about 2° C. In this manner the change reference temperature Tcr is changed to a high value when generated power is small, and the estimated stored heat amount is calculated as a small value. The compensation amount for increasing the fuel utilization rate is thus reduced, therefore the fuel utilization rate is greatly improved in the region where generated power is small and the absolute fuel supply amount is low, so that excessive drops in the fuel supply amount can be suppressed.

Next, referring to the FIG. 19 through 33, we discuss the operation of a solid oxide fuel cell system according to a second embodiment of the present invention.

In the solid oxide fuel cell system of the present embodiment, control by the control section 110 is different from that described above for the first embodiment. Therefore here we explain only the portions of the second embodiment of the invention which differ from the first embodiment, and we omit explanation of similar constitutions, operations, and effects.

In the above-described first embodiment the fuel supply amount was determined based on the basic fuel supply table in response to power demand, temporarily changing the determined fuel supply amount so that was reduced based on the heat amount accumulated in the insulating material 7, temporarily increasing the fuel utilization rate. Thus in the solid oxide fuel cell system of the second embodiment, no processing is conducted to determine the fuel supply amount based on the basic fuel supply table and change the fuel supply amount based on an estimated stored heat amount; rather, the fuel supply amount is directly calculated based on a detected temperature Td or the like. In the present embodiment, however, the fuel supply amount, directly determined based on the detected temperature Td or the like, includes the addition of the heat amount accumulated in the insulating material 7, etc., and the fuel utilization rate is improved by utilizing the stored heat in the state in which the stored heat amount is large, therefore the same technical concept as in the first embodiment can be achieved.

Next, in the above-described first embodiment the change to the fuel supply amount to increase the fuel utilization rate based on the estimated stored heat amount was accomplished by multiplying the change amount by a first correction coefficient (FIG. 11 step S5, FIG. 14), so it was primarily used when generated power was small (at or above a generated power of 4.5 A; first correction coefficient=0). In contrast, in the present embodiment no use is made of a coefficient corresponding to the first correction coefficient in the first embodiment. Therefore in the present embodiment, high efficiency control utilizing the heat amount accumulated in insulating material 7 is executed not only in the low generated power region, but also in the high generated power region. Therefore in the solid oxide fuel cell system of the present embodiment, not only the effect of improving the fuel utilization rate using stored heat, but also the effect of consuming the heat amount accumulated in the insulating material 7, and thereby suppressing temperature rises, is obtained when the fuel cell module 2 rises excessively. Note that in the above-described first embodiment, as well, the first modifying coefficient is omitted (the change amount is not multiplied by the first modifying coefficient), thereby providing the same effect.

FIG. 19 is a graph schematically showing the relationship between changes in power demand, fuel supply amount, and current actually extracted from a fuel cell module 2. FIG. 20 is a graph showing an example of the relationship between generating air supply amount, water supply amount, fuel supply amount, and current actually extracted from a fuel cell module 2.

As shown in FIG. 19, the fuel cell module 2 is controlled to produce power in accordance with the power demand shown in FIG. 19(i). Based on power demand, the control section 110 sets the fuel supply current value If, which is the target current to be produced by the fuel cell module 2, as shown in FIG. 19(ii). The fuel supply current value If is set to roughly follow changes in power demand, but since the speed of response by the fuel cell module 2 relative to changes in power demand is extremely sluggish, it is set to follow power demand gradually, and does not follow short cycle sudden changes in power demand. When power demand exceeds the maximum rated power of the solid oxide fuel cell system, the fuel supply current value If follows up to a current value corresponding to the maximum rated power, and does not get set to current values above that.

The control section 110 controls the fuel flow regulator unit 38 serving as fuel supply device in the manner shown in the FIG. 19(iii) graph, supplying the fuel cell module 2 with a fuel supply amount at a flow volume capable of producing power corresponding to the fuel supply current value If. Note that with a fixed fuel utilization rate, which is the fraction of the fuel supply amount actually used to generate electricity, the fuel supply current value If and the fuel supply current value Fr are proportional. In FIG. 19, the fuel supply current value If and fuel supply current value Fr are drawn as being proportional, but as described below, in actuality the fuel utilization rate is not fixed in this embodiment either.

Moreover, as shown in FIG. 19(iv), the control section 110 outputs a signal to the inverter 54 to output extractable current Iinv, which is the current value which can be extracted from the fuel cell module 2. The inverter 54 extracts current (power) from the fuel cell module 2 in the range of extractable current Iinv in response to the power demand, which changes rapidly from moment to moment. The portion of power demand exceeding the extractable current Iinv is supplied from the power grid. Here, as shown in FIG. 19, the extractable current Iinv instructed to the inverter 54 by the control section 110 is set to change at a predetermined time delay relative to changes in the fuel supply current value Fr when current is in a rising trend. For example, at time t10 in FIG. 19, the extractable current Iinv begins to increase at a delay after fuel supply current value If and fuel supply current value Fr start to rise. At time t12, as well, the extractable current Iinv starts to increase at a delay after the fuel supply current value If and fuel supply current value Fr increase. Thus delaying the timing at which power actually extracted from the fuel cell module 2 is increased following an increase in fuel supply current value Fr makes it is possible to deal with the time delay which occurs as fuel supplied to the fuel cell module 2 passes through the reformer 20, etc., to reach the individual fuel cell stack 14, and the time delay until the electrical generation reaction is actually possible after fuel reaches the individual fuel cell stack 14, and so forth. Therefore the occurrence of fuel cut-off in each of the fuel cell units 16 and the resulting damage to the fuel cell units 16 can be reliably prevented.

FIG. 20 shows in more detail the relationship between changes in the generating air supply amount, water supply amount, and fuel supply amount versus the extractable current Iinv. Note that the graphs of the generating air supply amount, water supply amount, and fuel supply amount shown in FIG. 20 are in each case converted to the current values corresponding to those supply amounts. In other words, assuming the supplied generating air, water, and fuel are all set to the supply amounts used for generating electricity without remainder, then each of the supply amount graphs is converted to overlap with the graph of extractable current Iinv. Therefore the amount of mismatch between each of the supply amount graphs and extractable current Iinv corresponds to the surplus portion in each of the supply amounts. The residual fuel remaining without being used for generating electricity is burned in the combustion chamber 18, which is the combustion section above the individual fuel cell stack 14, and is used to heat the interior of the fuel cell module 2.

As shown in FIG. 20, the generating air supply amount, water supply amount, and fuel supply amount are always above the extractable current Tiny; current exceeding the current producible using the respective supply amounts is extracted from the fuel cell module 2, preventing damage to the fuel cell units 16 by fuel cut-off, air cut-off, and the like. With respect to the fuel supply amounts supplied in excess of extractable current Iinv, the water supply amount is set to the supply amount at which all of the supplied fuel can be steam reformed. That is, in order that all the supplied fuel be steam-reformed, the water supply amount is set with consideration for the ratio S/C between the amount of steam needed for steam reforming and the amount of carbon contained in the fuel. Carbon deposition inside the reformer is thus prevented. In the FIG. 20 regions A and C, in which extractable current Iinv is on an increasing trend associated with the increase in power demand, the amount of margin in the fuel supply amount, etc., is set to be higher than in the B region, where extractable current Iinv is flat. When generated power is increased, the fuel supply amount supplied to the fuel cell module 2 is increased by a power extraction delay circuit 110c (FIG. 6) built into the control section 110, then after a delay the generated power output from the fuel cell module 2 is increased. That is, the power actually output from the fuel cell module 2 at a delay is changed after the fuel supply amount is changed in response to changes in power demand. In addition, when the extractable current Iinv is suddenly reduced in response to a drop in power demand (region C, beginning of region D), each supply amount is reduced after a predetermined delay time to a level below the extractable current Iinv. Therefore an extremely large amount of residual fuel occurs after a sudden reduction in extractable current Iinv. Thus in cases where the power demand suddenly drops, sudden reductions in extractable current Iinv of this type are implemented to prevent reverse current flow. Thus when increasing generated power and when decreasing generated power, more residual power is produced than when generated power is fixed, and this residual power is used to heat the fuel cell module 2. Therefore it is not only in cases where the fuel cell module 2 has been operated for long hours at high generated power, but also when generated power is frequently increased and decreased that the fuel cell module 2 is strongly heated, and a large amount of heat is accumulated in the insulating material 7.

In the solid oxide fuel cell system of the present embodiment, it is not only when generated power has declined after long operation at high generated power that stored heat is utilized; the heat amount being accumulated by increasing and decreasing generated power, etc., is successively utilized in response to conditions.

Next, referring to FIG. 21 through 28, we discuss a procedure for determining the generating air supply amount, water supply amount, and fuel supply amount based on the detected temperature Td.

FIG. 21 is a flowchart showing the order in which generating air supply amount, water supply amount, and fuel supply amount are determined based on detected temperature Td. FIG. 22 is a graph showing appropriate fuel cell stack 14 temperature versus generating current. FIG. 23 is a graph showing the fuel utilization rate determined according to integral value. FIG. 24 is a graph showing the range of the fuel utilization rates which can be determined relative to each generating current. FIG. 25 is a graph showing air utilization rate determined according to integral value. FIG. 26 is a graph showing the range of air utilization rates which can be determined relative to each generating current. FIG. 27 is a graph for determining water supply amounts versus a determined air supply utilization rate. FIG. 28 is a graph showing appropriate fuel cell module 2 generating voltage versus generating current.

As shown by the dot-and-dash line in FIG. 22, in this embodiment, an appropriate temperature Ts(I) for the individual fuel cell stack 14 is defined relative to the current to be produced by the fuel cell module 2. The control section 110 controls the fuel supply amount, etc., so that the temperature of the individual fuel cell stack 14 approaches the appropriate temperature Ts(I). Broadly speaking, that is, when the temperature of an individual fuel cell stack 14 is high relative to the generating current generating current (when the individual fuel cell stack 14 temperature is above the dot-and-dash line in FIG. 22), the fuel utilization rate is increased, the heat amount accumulated in the insulating material 7, etc., is actively consumed, and the temperature inside the fuel cell module 2 is reduced. Conversely, when the temperature of the individual fuel cell stack 14 is low relative to the generating current, the fuel utilization rate is reduced, and the temperature inside the fuel cell module 2 is prevented from dropping. Specifically, the fuel utilization rate is not determined simply based on the detected temperature Td alone; the fuel utilization rate is determined by calculating an amount reflecting stored heat by integrating an add/subtract value determined based on detected temperature Td, etc. The estimation value for the stored heat amount from this integration of add/subtract values is calculated by a stored heat estimating circuit 101b incorporated in the control section.

The flow chart shown in FIG. 21 determines the generating air supply amount, water supply amount, and fuel supply amount based on the detected temperature Td detected by the generating chamber temperature sensor 142 serving as temperature detection device, and is executed at a predetermined time interval.

First, in step S31 of FIG. 21, an first add/subtract value M1 is calculated based on the detected temperature Td and on FIG. 22. If the detected temperature Td is in a predetermined temperature range relative to the appropriate temperature Ts(I) (between the two solid lines in FIG. 22), the first add/subtract value M1 is set to 0. That is, when the detected temperature Td is within the range

Ts(I)−Te≦Td≦Ts(I)+Te,

the first add/subtract value M1 is set to 0. Here Te is the first add/subtract threshold temperature. Note that in the present embodiment, the first add/subtract threshold temperature Te is 3° C.

When the detected temperature Td is below the appropriate temperature Ts(I):

Td<Ts(I)−Te (4)

(below the bottom solid line in FIG. 22), the first add/subtract value M1 is calculated by:

M1=Ki×(Td−(Ts(I)−Te) (5)

At this point, first add/subtract value M1 is a negative value (a subtracting value). Note that Ki is a predetermined proportional constant.

When the detected temperature Td is above the appropriate temperature Ts(I):

Td>Ts(I)−Te (6)

(above the bottom solid line in FIG. 22), first add/subtract value M1 is calculated by:

M1=Ki×(Td−(Ts(I)+Te) (7)

At this point, first add/subtract value M1 is a positive value (an additive value). Thus first add/subtract value is determined based on generating current in addition to detected temperature Td, and the stored heat amount is estimated by integrating this. The appropriate temperature Ts(I), in other words, is set to differ according to generating current (power), and first add/subtract value M1 is determined to be a positive or negative value based on the value of (Ts(I)+Te) determined based on this appropriate temperature Ts(I), and on the value of (Ts(I)−Te).

Note that when the detected temperature Td exceeds (Ts(I)+Te), the first add/subtract value M1 becomes a positive value, and a change in fuel supply amount is carried out to raise the fuel utilization rate as described below, therefore in this Specification the temperature (Ts(I)+Te) relative to each generated power is referred to as the fuel utilization rate change temperature. By moving to high efficiency control with increased fuel utilization rate by exceeding the fuel utilization rate change temperature (Ts(I)+Te), the timing for restoration from high efficiency control to the target temperature region control at which the accumulated heat amount is not consumed is, as described below, the point at which first integral values N1id such as first addition/subtraction value M1 or the like decrease to 0. Therefore even after the detected temperature Td has dropped below the fuel utilization rate change temperature (Ts(I)+Te), the integral value first integral value N1id is maintained for a short time at a value greater than 0, and high efficiency control is implemented. Therefore the target temperature region control restore temperature when restored from high efficiency control to target temperature region control is lower than the fuel utilization rate change temperature.

Next, in step S32 of FIG. 21, a second add/subtract value M2 is calculated based on the latest detected temperature Td and the detected temperature Tdb detected one minute earlier. First, when the absolute value of the difference between the latest detected temperature Td and the detected temperature Tdb one minute prior is less than the second add/subtract value threshold value temperature, the second add/subtract value M2 is set to 0. Note that in the present embodiment, the second add/subtract threshold temperature is 1° C.

When the change temperature difference, which is the difference between the latest detected temperature Td and the detected temperature Tdb one minute prior, is equal to or greater than the second add/subtract value threshold value temperature, the second add/subtract value M2 is calculated as:

M2=Kd×(Td−Tdb) (8)

This second add/subtract value M2 is a positive value (additive value) when the temperature drops is in a rising trend, and a negative value (subtractive value) when the detected temperature Td is in a falling trend. Note that Kd is a predetermined proportional constant. Therefore in cases where the detected temperature Td is rising, in the region where the change temperature difference (Td−Tdb) is large the second add/subtract value M2, which is a quick response estimate value, is more significantly increased than in the region where the change temperature difference is small. Conversely, in cases where the detected temperature is falling in the region where the absolute value of the change temperature difference (Td−Tdb) is large, the second add/subtract value M2 is more significantly decreased than in the region where the absolute value of the change temperature difference is small.

Note than in the present embodiment the proportional constant Kd is a fixed value, but as a variant example, different proportional constants Kd could be used for the case where the change temperature difference is positive and the case where it is negative. For example, the proportional constant Kd can also be set high when the change temperature difference is negative. Thus the quick response estimate value is changed suddenly relative to the change temperature difference more when the detected temperature is falling then when the detected temperature is rising. As a variant example, the proportional constant Kd can also be set higher in the region where the absolute value of the change temperature difference is high than the region where it is low. This results in the quick response estimate value being more suddenly changed relative to the change temperature difference in the region where the absolute value of the change temperature difference is high than in the region where the absolute value of the change temperature difference is low. It is also possible to combine the change in proportional constant Kd based on whether the change temperature difference is positive or negative, with the change in proportional constant Kd based on the size of the absolute value of the change temperature difference.

Next, in step S33 of FIG. 21, the first add/subtract value M1 calculated in step S31 and the second add/subtract value M2 calculated in step S32 are added to the first integral value N1id. In the first integral value N1id, the usable stored heat amount accumulated in the insulating material 7 and the like is reflected by first add/subtract value M1, and recent changes in detected temperature Td are reflected by second add/subtract value M2. In other words, the first integral value N1id can be used as an estimated value of usable stored heat amount accumulated in insulating material 7 and the like. Integration occurs in a continuous manner after the start of operation of the solid oxide fuel cell system each time the FIG. 21 flow chart is executed; the first add/subtract value M1 and the second add/subtract value M2 are added or subtracted to the previously calculated first integral value N1id, and first integral value N1id is updated to a new value. The first integral value N1id is limited to a range of values between 0 and 4; when the first integral value N1id reaches 4, the value is held at 4 until the next subtraction occurs; when the first integral value N1id has declined to 0, the value is held at 0 until the next addition takes place.

Note that in step S33, the value of a second integral value N2id is also calculated, in addition to the first integral value N1id. As described below, the second integral value N2id is calculated in exactly the same way as the first integral value N1id until degradation occurs in the fuel cell module 2, and the same value as for first integral value N1id is taken.

Note that in this embodiment, as described above, an integral value is calculated by adding the sum of first add/subtract value M1 and second add/subtract value M2 to the first integral value N1id. That is, the first integral value N1id is calculated using:

N1id=N1id+M1+M2 (9)

As a variant example, an integral value can also be calculated by adding the product of the first add/subtract value M1 and the second add/subtract value M2. That is, in this variant example, first integral value N1id is calculated using:

N1id=N1id+Km×M1×M2 (10)

Here Km is a variable coefficient which is changed in response to predetermined conditions. In this variant example, when the absolute value of the difference between the latest detected temperature Td and the detected temperature Tdb one minute prior is less than the second add/subtract value threshold value temperature, the second add/subtract value M2 is set to 1.

Furthermore, in step S34 of FIG. 21, the fuel utilization rate is determined using the graphs in FIGS. 23 and 24, based on the calculated first integral value N1id.

FIG. 23 is a graph showing the setting value for the fuel utilization rate Uf relative to the calculated first integral value N1id. As shown by FIG. 23, when the first integral value N1id is 0, the fuel utilization rate Uf is set to the minimum value fuel utilization rate Ufmin. The fuel utilization rate Uf also increases with the increase in first integral value N1id, and at first integral value N1id=1, becomes the maximum value the fuel utilization rate Ufmax. During this interval the slope of the fuel utilization rate Uf is small in the region where first integral value N1id is small, and the slope increases as first integral value N1id approaches 1. In other words, the fuel utilization rate Uf is changed much more relative to change in the stored heat amount in the region where the estimated stored heat amount is large than in the region where the stored heat amount is small. That is, the fuel supply amount is reduced so as to greatly increase the fuel utilization rate Uf as the estimated stored heat amount increases. Furthermore, when the first integral value N1id is greater than 1, the fuel utilization rate Uf is fixed at maximum fuel utilization rate Ufmax. The specific values of these minimum fuel utilization rate Ufmin and maximum fuel utilization rate Ufmax are determined using the graph shown in FIG. 24, based on generating current. Thus when it is estimated that a usable amount of heat is accumulated in the heat storing material, the fuel supply amount is reduced so that the fuel utilization rate relative to the same generated power is higher than for the case when a usable amount of heat has not accumulated.

FIG. 24 is a graph showing the range of values obtainable for the fuel utilization rate Uf relative to each generating current; maximum and minimum values for the fuel utilization rate Uf are shown for each generating current. As shown in FIG. 24, the minimum fuel utilization rate Ufmin for each generating current is set to increase as generating current increases. That is, the setting is made so that the fuel utilization rate is high when generated power is large, and the fuel utilization rate is low when generated power is small. This minimum fuel utilization rate Ufmin straight line corresponds to the basic fuel supply table in FIG. 9 of the first embodiment; when set to a fuel utilization rate on this straight line, the fuel cell module 2 can be thermally autonomous without utilizing the heat amount accumulated in the insulating material 7 or the like.

The maximum fuel utilization rate Ufmax, on the other hand, is set to change in a curved line fashion relative to each generating current. Here the range of values which the fuel utilization rate Uf can assume relative to each generating current (the difference between the maximum fuel utilization rate Ufmax and the minimum fuel utilization rate Ufmin) is narrowest for the maximum generating current, and broadens as generating current declines. This is because in the vicinity of maximum generating current, the minimum fuel utilization rate Ufmin is high at which thermal autonomy is possible, and there is little margin for increasing the fuel utilization rate Uf (decreasing the fuel supply amount) even if stored heat is used. Moreover, because the minimum fuel utilization rate Ufmin at which thermal autonomy is possible declines as generating current declines, the margin for reducing the fuel supply amount by utilizing stored heat increases, and when there is a large amount of stored heat, the fuel utilization rate Uf can be greatly increased. Therefore the fuel utilization rate is changed over a larger range in the region where generated power is small than in the region where generated power is large.

In the region below a predetermined suppressed utilization rate generation amount IU at which generating current is extremely small, the range of values the fuel utilization rate Uf can assume is set to be smaller as generated power decreases. This means that in the region where generating current is small, the minimum fuel utilization rate Ufmin is low at which thermal autonomy is possible, and there is margin for improvement thereof. However in the region where generating current is small, the temperature inside the fuel cell module 2 is low, therefore when the fuel utilization rate Uf is greatly improved in this state and the stored heat amount accumulated in the insulating material 7 or the like is suddenly consumed, there is a risk of inducing excessive temperature drops inside the fuel cell module 2. Therefore in the region below, a predetermined suppressed utilization rate generation amount IU at which generating current is extremely small, the change amount for increasing the fuel utilization rate Uf is greatly suppressed as generated power declines. In other words, the amount of change causing a reduction in the fuel supply amount as the amount of generation by the fuel cell module 2 declines. The risk of sudden temperature drops can thus be avoided, and the accumulated heat amount can be utilized over a long time period.

In the present embodiment, the fuel supply amount is reduced by the fuel table change circuit 110a built into the control section 110 so that the fuel utilization rate Uf increases relative to the minimum fuel utilization rate Ufmin. This fuel table change circuit 110a does not change the basic fuel supply table, but acts to raise the fuel utilization rate by changing the fuel supply amount which serves as base, thereby raising the fuel utilization rate.

In step S34 of FIG. 21, the specific values of minimum fuel utilization rate Ufmin and maximum fuel utilization rate Ufmax are determined using the graph in FIG. 24 based on generating current. Next, applying the determined minimum fuel utilization rate Ufmin and maximum fuel utilization rate Ufmax to the FIG. 23 graph, the fuel utilization rate Uf is determined based on the first integral value N1id calculated in step S33.

Next, in step S35 of FIG. 21, an air utilization rate is determined using the FIGS. 25 and 26 graphs, based on a second integral value N2id.

FIG. 25 is a graph showing setting values for air utilization rate Ua relative to the calculated second integral value N2id. As shown in FIG. 25, when the second integral value N2id is 0 to 1, the air utilization rate Ua is set to maximum air utilization rate Uamax, which is the maximum value. In addition, as the second integral value N2id exceeds 1 and increases, the air utilization rate Ua declines, and at second integral value N2id=4 becomes the minimum air utilization rate Uamin, which is a minimum value. Thus the increased portion of air caused by reducing the air utilization rate Ua acts as a cooling fluid, therefore the setting of the air utilization rate Ua shown in FIG. 25 acts as a forced cooling circuit. The specific values of these minimum air utilization rate Uamin and maximum air utilization rate Uamax are determined using the graph shown in FIG. 26, based on generating current.

FIG. 26 is a graph showing the range of values obtainable for air utilization rate Ua relative to each generating current; the maximum and minimum values for the air utilization rate Ua are shown for each generating current. As shown in FIG. 26, the maximum air utilization rate Uamax for each generating current is set to increase by a very small amount as generating current increases. On the other hand, the minimum air utilization rate Uamin decreases as generating current increases. Reducing the air utilization rate Ua (increasing the fuel supply amount) more than the maximum air utilization rate Uamax results in the introduction of a larger amount of air into the fuel cell module 2 than is required for generation, causing the temperature inside the fuel cell module 2 to decline. Therefore the air utilization rate Ua is reduced when the temperature in the fuel cell module 2 rises excessively and it is necessary to reduce that temperature. In the present embodiment, reducing the minimum air utilization rate Uamin (increasing the air supply amount) with the rise in generating current causes the air supply amount corresponding to the minimum air utilization rate Uamin to exceed the maximum air supply amount for the generating air flow regulator unit 45 at a predetermined generating current. Therefore in the region in which the minimum air utilization rate Uamin is at or above the predetermined generating current shown by the dotted line in FIG. 26, there are cases when it is not possible to achieve the air utilization rate Ua set by the graph in FIG. 25. In such cases the air supply amount actually supplied is set to the maximum air supply amount for the generating air flow regulator unit 45, regardless of the set air utilization rate Ua. In conjunction with this, the air utilization rate Ua which is actually implemented increases at or above a predetermined generating current. When a generating air flow regulator unit with a larger maximum air supply amount is used, the minimum air utilization rate Uamin for the portion shown by the broken line in FIG. 26 can also be achieved. Note that the air utilization rate Ua defined by reaching the maximum air supply amount for the generating air flow regulator unit 45 is described as the limit minimum air utilization rate ULamin.

In step S35 of FIG. 21, the specific values of the minimum air utilization rate Uamin and maximum air utilization rate Uamax are determined using the graph in FIG. 26, based on generating current. Next, applying the determined minimum air utilization rate Uamin and maximum air utilization rate Uamax to the FIG. 25 graph, the air utilization rate Ua is determined based on the second integral value N2id calculated in step S33.

Next, in step S36 of FIG. 21, the ratio S/C of steam amount to carbon amount is determined using FIG. 27, based on the air utilization rate Ua determined in step S35.

FIG. 27 is a graph in which the horizontal axis shows the air utilization rate Ua and the vertical axis shows the ratio S/C of the supplied steam amount to the carbon amount contained in the fuel.

First, in the generating current region in which the air utilization rate Ua set in step S35 is not defined by the maximum air supply amount of the generating air flow regulator unit 45 (between Uamax and ULamin in FIG. 27), the value of the ratio S/C of the steam amount to the carbon amount is fixed at 2.5. Note that a steam amount to carbon amount ratio S/C=1 means that the entire amount of carbon contained in the supplied fuel is chemically steam reformed by the supplied water (steam), without excess or shortage. Therefore the statement that the steam amount to carbon amount ratio S/C=2.5 refers to the state in which steam (water) is supplied in an amount 2.5 times the minimum steam amount chemically needed to steam reform the fuel. In actuality, at the steam amount at which S/C=1, carbon deposition occurs inside the reformer 20, so a steam amount at which S/C=approximately 2.5 is the appropriate amount for steam reforming the fuel.

Next, in the generated current region in which the air utilization rate Ua set in step S35 is limited by the maximum air supply amount of the generating air flow regulator unit 45, the ratio S/C of the steam amount to the carbon amount is determined using the graph in FIG. 27. In FIG. 27 the horizontal axis is the air utilization rate Ua; the air supply amount declines as the air utilization rate Ua increases and approaches the maximum air utilization rate Uamax. When the air utilization rate Ua is reduced, on the other hand, and approaches the minimum air utilization rate Uamin (the dotted line in FIG. 26), the air supply amount reaches a limit, and the air utilization rate Ua goes to the limit minimum air utilization rate ULamin. As shown in FIG. 27, when the air utilization rate Ua is larger (air supply amount is low) than the limit minimum air utilization rate ULamin, the ratio of steam amount to carbon amount is set at S/C=2.5. Additionally, when the air utilization rate Ua determined in step S35 is smaller (air supply amount is large) than the limit minimum air utilization rate ULamin (between Uamin and ULamin in FIG. 27), the ratio S/C of steam amount to carbon amount increases as the air utilization rate Ua decreases, and at the minimum air utilization rate Uamin it is set to S/C=3.5. That is, when the air utilization rate Ua determined in step S35 cannot be achieved using the limit minimum air utilization rate ULamin (when the air utilization rate Ua is determined to be within the range of the sloped line in FIG. 26), the ratio of the steam amount to carbon amount S/C is increased, and the water supply amount is increased. Thus the temperature of the reformed fuel gas discharged from the reformer 20 is reduced, placing the temperature inside the fuel cell module 2 in a declining trend. Thus when the water supply amount is increased after reducing the air utilization rate Ua and increasing the air supply amount, the increased portion of water (steam) acts as a cooling fluid, so that setting the water supply amount shown in FIG. 27 acts as a forced cooling circuit.

In step S37 the specific fuel supply amount, air supply amount, and water supply amount are determined based on the fuel utilization rate Uf, air utilization rate Ua, and ratio S/C of steam amount to carbon amount respectively determined in steps S34, S35, and S36. In other words, the actual fuel supply amount is calculated by dividing the fuel supply amount—assuming the entire amount is used for electrical generation—by the determined fuel utilization rate Uf, and the actual air supply amount is calculated by dividing the air supply amount—assuming the entire amount is used for electrical generation—by the determined air utilization rate Ua. The water supply amount is calculated based on the calculated fuel supply amount and on the ratio S/C of the steam amount and carbon amount determined in step S36.

Next, in step S38, the control section 110 sends signals to the fuel flow regulator unit 38, the generating air flow regulator unit 45, and the water flow regulator unit 28 serving as water supply device, and supplies the amounts of fuel, air, and water calculated in step S37, thereby completing the processing of one iteration of the FIG. 21 flow chart.

Next, we discuss the time intervals at which the FIG. 21 flow chart is executed. In the present embodiment the FIG. 21 flow chart is executed every 0.5 seconds when the output current is large, and as output current falls, is executed at twice that amount or 1 second, 4 times that amount or every 2 seconds, and 8 times that amount or every 3 seconds. Thus when the first and second add/subtract values are a fixed value, the change in the first and second add/subtract values per unit time becomes more gradual as output current declines. That is, the stored heat estimating circuit 110b changes the estimated value of the stored heat amount per unit time more suddenly as output current (output power) increases. The estimate of the stored heat amount resulting from the integral value thus accurately reflects the actual stored heat amount.

Next, referring to FIG. 28, we discuss the procedure for determining the fuel supply amount, air supply amount, and water supply amount when the fuel cell module 2 has degraded. FIG. 28 is a diagram showing generated voltage relative to generated current by the fuel cell module 2. In general there is internal resistance present in the individual fuel cell stack 14, therefore as shown in FIG. 28, the voltage drops when the current output from the fuel cell module 2 increases. The dot-and-dash line shown in FIG. 28 shows the relationship between generated current and generated voltage when no degradation of the fuel cell module 2 has occurred. In contrast, when the fuel cell module 2 does degrade, internal resistance in the individual fuel cell stack 14 rises, so generated voltage declines relative to the same generated current.

In the solid oxide fuel cell system of the present embodiment, when the generated current drops by 10% or more relative to initial generated voltage, and the generated voltage enters the region below the solid line in FIG. 28, the fuel supply amount, air supply amount, and water supply amount are determined by processing in a manner suited to degradation.

That is, when the generated voltage is in the region below the solid line in FIG. 28, the integration of first integral value N1id is stopped at step S33 in FIG. 21, and only the integration of second integral value N2id is continued. The value of first integral value N1id used when referring to the FIG. 23 graph to determine the fuel utilization rate Uf is thus fixed at a constant value. The fuel utilization rate Uf is therefore fixed until the generated voltage gets out of the region below the solid line in FIG. 28. Thus changes to increase the fuel utilization rate Uf are reduced more after degradation of the fuel cell module 2 than prior to degradation of the fuel cell module 2. At the same time, the second integral value N2id used when referring to the FIG. 26 graph to determine the air utilization rate Ua is reduced as in the past, and increases and decreases in the air utilization rate Ua are continued. The fuel utilization rate Uf is changed based on degradation of the fuel cell module 2, in addition to the first and second addition values and power demand corresponding to estimated stored heat amount.

Next, we discuss the operation of a solid oxide fuel cell system implemented using the FIG. 21 flow chart.

First, when the value of the first integral value N1id calculated in step S33 is 0, the fuel utilization rate Uf determined in step S34 is set at the minimum fuel utilization rate Ufmin (fuel supply amount maximum) for that generated current. Thus even in a state in which the first integral value N1id is 0, and the stored heat accumulated in the insulating material 7 or the like is small, sufficient fuel is supplied for the fuel cell module 2 to achieve thermal autonomy. When the value of the second integral value N2id calculated in step S33 is 0, as for the first integral value N1id, the air utilization rate Ua determined in step S35 is set at the maximum air utilization rate (air supply amount minimum) for that generated current. Therefore cooling of the individual fuel cell stack 14 can be minimized by the generating air introduced into the fuel cell module 2, and the temperature of the individual fuel cell stack 14 can be placed on a rising trend.

Next, when the fuel cell module 2 is operated in a state whereby the detected temperature Td is higher than the appropriate temperature Ts(I), and Td>Ts(I)+Te, the value of the first add/subtract value M1 becomes positive, and the value of first integral value N1id becomes greater than 0. Thus in FIG. 23, a fuel utilization rate Uf higher than the minimum fuel utilization rate Ufmin is set and the fuel supply amount is reduced, and the amount of residual fuel remaining and not used to generate electricity is reduced. The fuel utilization rate Uf is greatly increased by the control section 110 as the value of the first integral value N1id corresponding to the estimated stored heat amount increases. By increasing the fuel utilization rate Uf, the fuel supply amount is reduced to below a supply amount at which thermal autonomy is possible, and high efficiency control utilizing the heat amount accumulated in the insulating material 7 and the like is executed. The amount of residual fuel is reduced and the heat amount accumulated in the insulating material 7 or the like is utilized, therefore the fuel table change circuit 110a suppresses the rise of the temperature in the fuel cell module 2 while continuing to generate electricity. When operation is continued in the Td>Ts(I)+Te state, addition of the positive value first add/subtract value M1 is repeated, and the value of the first integral value N1id also increases. When the first integral value N1id reaches 1, the fuel utilization rate Uf (fuel supply amount minimum) is set to the maximum fuel utilization rate Uafmax. Fuel supplied to the fuel cell module 2 is determined based on the past history of the detected temperature Td, which reflects the heat amount accumulated in the insulating material 7 or the like.

Even when the first integral value N1id further increases and exceeds 1, the fuel utilization rate Uf is maintained at the maximum fuel utilization rate Uafmax (fuel supply amount minimum), as shown in FIG. 23. On the other hand, when the second integral value N2id, which takes the same value as the first integral value N1id (when the fuel cell module 2 is not degraded), also exceeds 1, so the air utilization rate Ua declines (air supply amount increases) based on FIG. 25. Thus the inside of the fuel cell module 2 is placed in a cooling trend due to the increase of supplied air.

By contrast, when the fuel cell module 2 is operated in a state whereby the detected temperature Td is lower than the appropriate temperature Ts(I), and Td<Ts(I)−Te, the value of the first add/subtract value M1 becomes negative, and the value of first integral value N1id is reduced. The fuel utilization rate Uf is therefore maintained (first integral value N1id>1) or decreased (first integral value N1id≦1). Also, the air utilization rate Ua increases (second integral value N2id>1) or is maintained (second integral value N2id≦1). The temperature inside the fuel cell module 2 can thus be set on a rising trend.

The above describes the operation of a solid oxide fuel cell system focusing only on the first add/subtract value M1 calculated based on the history of the detected temperature Td, but first integral value N1id and second integral value N2id are also influenced by the second add/subtract value M2. The heat capacity of the fuel cell module 2, and in particular the individual fuel cell stack 14, is extremely large, and changes in the detected temperature Td thereof are extremely sluggish. Therefore once the detected temperature Td enters a rising trend, it is difficult to suppress that temperature rise in a short time period, and when the detected temperature Td enters a falling trend, as well, a long period of time is required to return it to a rising trend. Therefore a rising or falling trend appearing in the detected temperature Td requires an immediate response by modifying the first and second integral values.

That is, when the latest detected temperature Td is above the detected temperature Tdb one minute prior by an amount equal to or greater than the second add/subtract value threshold value temperature, the second add/subtract value M2 becomes a positive value, and the first and second integral values are increased. This allows the fact that the detected temperature Td is in a rising trend to be reflected in the first and second integral values. Similarly, when the latest detected temperature Td is above the detected temperature Tdb one minute prior by an amount equal or greater than the second add/subtract value threshold value temperature, the second add/subtract value M2 becomes a negative value, and the first and second integral values are decreased. In other words, the second add/subtract value M2, which is the quick response estimate value, is calculated by the change temperature difference, which is the difference between the latest detected temperature Td detected by the generating chamber temperature sensor 142 and the past detected temperature Tdb. Therefore when the detected temperature Td is suddenly dropping, the change amount increasing the fuel utilization rate Uf is more suppressed than when it is gradually dropping, and since in the region where generated power is below the suppressed utilization rate generation amount IU, the maximum fuel utilization rate Ufmax is also set low, and the change amount is greatly suppressed. This allows the fact that the detected temperature Td is in a falling trend to be reflected in the first and second integral values. Thus in the present embodiment, the stored heat amount is estimated based on an integral value for the add/subtract determined based on detected temperature, and on the differential value between the newly detected temperature and past detected temperatures. That is, in the present embodiment, the stored heat amount is estimated by the stored heat estimating circuit 110b based on the integral value of the first add/subtract value M1, which is a basic estimated value calculated based on the history of detected temperatures Td, and based on the second add/subtract value M2, which is a quick response estimate value calculated based on the rate of change in the detected temperature Td over a period of time shorter than history of the basic estimated value calculation. Thus in the present embodiment, the stored heat amount is estimated based on the sum of the basic estimated value and the quick response estimate value.

Note that temperature changes in the fuel cell module 2 are extremely slow compared to the 1 minute detection interval for detected temperatures Td and Tdb, so it is often the case that the second add/subtract value M2 is 0. Therefore the first and second integral values are primarily dominated by the first add/subtract value M1, and the second add/subtract value M2 acts to modify the values of the first and second integral values when a rising or falling trend appears in the detected temperature Td. Thus in addition to the detected temperature history, changes in recent detected temperatures Td are also added to the stored heat amount estimated value using the second add/subtract value M2. Therefore when the change in recent detected temperatures Td is large (a change equal to or larger than the second add/subtract value temperature recovery temperature) the second add/subtract value M2 has a value, but the stored heat amount estimated value is modified, and the fuel utilization rate Uf is greatly changed.

Next, referring to FIG. 29 through 32, we discuss limitations to the variable range of generated power.

As described above, in the solid oxide fuel cell system of the present embodiment, utilizing the heat amount accumulated in the insulating material 7 or the like allows the fuel utilization rate to be increased and the temperature inside the fuel cell module 2 to be controlled to an appropriate temperature by actively utilizing stored heat. As explained using FIGS. 19 and 20, frequent increases and decreases in the power produced by the fuel cell module 2 to match the power demand can cause the temperature inside the fuel cell module 2 to rise excessively. It is possible to suppress such excessive temperature rises by increasing the fuel utilization rate and actively utilizing the heat amount accumulated in the insulating material 7 or the like. As explained using FIG. 24, however, in the region where the power generated is large, the set minimum fuel utilization rate Ufmin is a large value, so there is little room for increasing the fuel utilization rate and utilizing stored heat. Therefore when generated power is large, it is difficult to effectively reduce an excessively raised temperature inside the fuel cell module 2 even by increasing the fuel utilization rate and utilizing stored heat. For this reason, when an excessive temperature rise occurs in the fuel cell module 2 in the present embodiment, the variable range in which generated power is made to follow power demand is restricted to a low level. Since this causes the fuel cell module 2 to be operated at a small generated power, the margin for utilizing stored heat increases, making it possible to effectively lower the temperature inside the fuel cell module 2. By narrowing the variable range in which generated power is made to follow power demand, temperature rises caused by frequent increases and decreases in generated power are suppressed.

Note that temperature rises inside the fuel cell module 2 caused by frequent increases and decreases in power demand, as explained in FIGS. 19 and 20, also occur in the solid oxide fuel cell system of the first embodiment of the present invention described above. Therefore, referring to FIG. 29 through 32, the limitation on the variable range of generated power explained below can be implemented in combination with the above-described first embodiment of the present invention.

FIG. 29 is a flowchart showing a procedure for limiting the range of power produced by the fuel cell module in the present embodiment. FIG. 30 is a map showing current limits versus generated current and detected temperature Td. FIG. 31 is a timing chart showing an example of the effect of the second embodiment of the present invention. FIG. 32 is a graph showing an example of the relationship between temperature inside the fuel cell module and maximum generatable power.

First, as shown by the solid line in FIG. 30, in the solid oxide fuel cell system of the present embodiment an appropriate temperature is set in the fuel cell module 2 for each generated current. This appropriate temperature corresponds to the dot-and-dash line in FIG. 22. As shown in FIG. 30, a current maintaining region is set in the region where the temperature is above the appropriate temperature. The minimum temperature in this current maintaining region is set to differ according to generated power from the fuel cell module 2, and the current maintaining region minimum temperature is set to increase as generated power increases. The minimum temperature in the current maintaining region with respect to each generated power is set so that the difference relative to the appropriate temperature for the fuel cell module 2 increases as generated power decreases. When the operating state of fuel cell module 2 enters this current maintaining region, the output current from the fuel cell module 2 is prohibited from increasing. Furthermore, a current reduction region is set in the region where the temperature is higher than the current maintaining region. When the operating state enters this current reduction region, the output current from the fuel cell module 2 is forcibly reduced. An air cooling region is set in the region where the temperature is above the current reduction region. When the operating state enters this air cooling region, the generating air supply amount is set to the maximum flow volume suppliable by the generating air flow regulator unit 45. A stop operation region is set in the region in which the temperature is higher than the air cooling region. When the operating state enters this stop operation region, power generation by the fuel cell module 2 is stopped to prevent malfunctioning of the solid oxide fuel cell system.

Moreover, when the detected temperature Td has risen suddenly, the temperature demarcating the current maintaining region is lowered as shown by the dot-and-dash line in FIG. 30. In such cases, the temperature demarcating a current reduction region is lowered as shown by the double dot-and-dash line in FIG. 30. Thus when the detected temperature Td suddenly rises, current limiting is quickly implemented, thereby reliably suppressing excessive temperature rises.

Next, referring to FIG. 29, we discuss the procedure for limiting current produced by the fuel cell module.

First, the detected temperature Td is read in step S411 of FIG. 29. Next, in step S42, the detected temperature Td read in step S41 and the detected temperature Td from a predetermined previous time are compared. If the difference between the detected temperature Td read in step s41 and the detected temperature Td from a predetermined previous time is at or below a predetermined threshold temperature, the system advances to step S43.

In step S43, the basic characteristics shown by the solid line in FIG. 30 are selected as a map for determining a temperature region. At the same time, if the difference between the latest detected temperature Td and the detected temperature Td at a predetermined previous time is larger than the predetermined threshold temperature, the system advances to S44; in step S44 the suddenly rising temperature characteristics shown by the dot-and-dash line and the double dot-and-dash line in FIG. 30 is selected as the map for determining the temperature region.

Next, in step S45, a judgment is made as to whether the detected temperature Td is within the stop operation region. In this embodiment, if the detected temperature Td is at or above 780° C., the temperature is judged to be in the stop operation region. When it is judged that the detected temperature Td is within the stop operation region, the system advances to step S46. In step S46, power generation by the fuel cell module 2 is stopped, and an emergency stop of the solid oxide fuel cell system is effected.

On the other hand, if it is judged in step S45 that the detected temperature Td is not within the stop operation region, the system advances to step S47. In step S47 a judgment is made as to whether the detected temperature Td is within the air cooling region. In the present embodiment when the detected temperature Td is 750° C. or greater, it is judged to be in the air cooling region. When it is judged that the detected temperature Td is within the air cooling region, the system advances to step S48.

In step S48, the generated current is fixed at the minimum current of 1 A; this current is consumed by the auxiliary unit 4 without being output to the inverter 54. The generating air supply amount is set to the maximum flow volume suppliable by the generating air flow regulator unit 45. The water supply amount is also increased and the steam and carbon amounts set to a ratio of S/C=4, completing the processing of one iteration in the FIG. 29 flow chart.

On the other hand, if it is judged in step S47 that the detected temperature Td is not within the air cooling region, the system advances to step S49. In step S49 a judgment is made of whether the detected temperature Td and the generated current are within the current reduction region; if within the current reduction region, the system advances to step S50.

In step S50, the generated current from the fuel cell module 2 is forced to 4 A or below. In other words, the upper limit value of the generated power from the fuel cell module 2 is reduced to a temperature rise-suppressing power (400 W), which is higher than ½ the maximum rated power of 700 W. Thereafter when power demand declines, the upper limit value of the generated power (current), following the power demand, is reduced, and generated current is maintained, not increased, even if power demand grows. One iteration of the processing in the flow chart of FIG. 29 is thus completed. This type of limitation on generated current continues until the detected temperature Td and generated current go outside the current reduction region.

On the other hand, if a judgment is made in step S49 that the detected temperature Td and the generated current are not within the current reduction region, the system advances to step S51. In step S51 a judgment is made of whether the detected temperature Td and the generated current are within the current maintain region; if within the current reduction region, the system advances to step S52.

In step S52, increases in the generated current are prohibited, and thereafter the generated current is maintained without increase, even if power demand grows. Subsequently when power demand declines, the upper limit value of generated current (power), following the drop in power demand, is reduced, and the upper limit of generated current (power) is maintained, not raised, even if power demand grows. This type of limitation on generated current continues until the detected temperature Td and generated current go outside the maintain current region and the excessive temperature rise of the fuel cell module 2 is resolved. One iteration of the processing in the flow chart of FIG. 29 is thus completed.

In the present embodiment, restrictions on generated power are started when the detected temperature Td exceeds the maintain current region minimum temperature for each of the generated currents, so the minimum temperature in the maintain current region relative to each generated current is referred to as the generated power restriction temperature (FIG. 30). This generated power restriction temperature is set in the present embodiment to be higher than the fuel utilization rate change temperature (Ts(I)+Te) (FIG. 2) at which a change to increase the fuel utilization rate is started.

On the other hand, if a judgment is made in step S51 that the detected temperature Td and the generated current are not within the maintain current region, the system advances to step S53. At step S53, limits on generated current are not executed, and control utilizing stored heat is executed.

Next, referring to FIG. 31, we discuss an example of a generated current limitation.

The timing chart shown in FIG. 31 schematically depicts, in order from the top, changes in detected temperature Td, target current, generated current, fuel supply amount, fuel utilization rate, and air supply amount. Target current here refers to the current obtained from power demand and generated voltage.

First, at time t20 in FIG. 31, the generated current is approximately 6 A, and the detected temperature Td is in a state slightly below the appropriate temperature at a generated current of 6 A (corresponding to t20 in FIG. 30).

Next, at times t20-t21, because of the repeated larger increases and decreases in power demand over a short period, target current also greatly increases and decreases, and generated current also increases and decreases to follow. By contrast, the fuel supply amount, as explained in FIG. 20, is held for a predetermined time after the generated current has declined, and is increased ahead of the increase in generated current, thus becoming excessive relative to generated current, resulting in a large amount of surplus fuel. This surplus fuel is used to heat the interior of the fuel cell module 2, therefore at times t20-t21 the detected temperature Td is in a rising trend.

Furthermore, at time t21 the detected temperature Td reaches the maintain current region temperature for a generated current of approximately 6 A (t21 in FIG. 30, corresponds the transition from step S51→S52 in FIG. 29). Step S52 in FIG. 29 is thus executed; thereafter increases in generated current are prohibited, and generated current is maintained. Therefore at times t21-t22 the target current is growing to approximately 7 A, but the generated current is maintained at approximately 6 A. By prohibiting increases in generated current, the upper limit value of the variable range of generated power is reduced, and the variable range is narrowed, causing the amount of residual fuel associated with changes in power demand to decline. Thus step S52 of FIG. 29, where the residual fuel amount is reduced while continuing electrical generation, is acting as a temperature rise suppressing circuit. Step S51 judges whether step S52, which acts as a temperature rise-suppressing circuit, is executed, and acts as an excess temperature rise estimating circuit for estimating the occurrence of excessive temperature rises in the fuel cell module 2.

At times t21-t22, moreover, the detected temperature Td rises, therefore the first add/subtract value M1 becomes a truly large value, and the first integral value N1id value also increases remarkably. The fuel supply amount is thus reduced to increase the fuel utilization rate Uf (FIG. 23). This increase in the fuel utilization rate Uf also acts to reduce the amount of residual fuel and lower the temperature inside the fuel cell module, thus acting as a temperature rise-suppression circuit. Note that at times t21-t22, the fuel utilization rate Uf is increased and the heat amount accumulated in the insulating material 7 or the like is actively consumed, but because the thermal capacity of the fuel cell module 2 is extremely large, the detected temperature Td continues to rise.

Next, at time t22, the increased fuel utilization rate Uf reaches the maximum fuel utilization rate Ufmax (=75%), which is the maximum fuel utilization rate at a generated current of approximately 6 A (first integral value N1id=1 in FIG. 23; FIG. 24). At time t22 the fuel utilization rate Uf is raised up to the maximum fuel utilization rate Ufmax, therefore at times t22-t23, the fuel utilization rate Uf is maintained at the maximum fuel utilization rate Ufmax. On the other hand at times t22-t23, the detected temperature Td is still continuing to rise, therefore the value of the second integral value N2id (same value as the first integral value N1id) also grows. Associated with this, the air utilization rate Ua is reduced (N2id in FIG. 25>1); i.e., the air supply amount is increased.

In addition, at time t23 the detected temperature Td reaches the current reduction region at a generated current of approximately 6 A (corresponding to step S49→S50 in FIG. 29). This causes step S50 in FIG. 29 to be executed, with the generated current suddenly reduced from approximately 6 A to 4 A (t23→t23′ in FIG. 30), the upper limit value of the generated power variable range further reduced, and the variable range further narrowed. Therefore the fuel utilization rate Uf is reduced very slightly from the maximum fuel utilization rate Ufmax at a generated current of 6 A to a maximum fuel utilization rate Ufmax at a generated current of 4 A (FIGS. 24, 31). Note that at time t23, the fuel utilization rate Uf is lowered, but since the generated current is reduced to 4 A, the absolute amount of the fuel supply amount and the absolute amount of the residual fuel are lowered. Since the fuel utilization rate Uf is maintained at a maximum fuel utilization rate Ufmax with the generated current in a reduced state, consumption of the accumulated heat amount is further promoted. By reducing generated current in this way, step S50 in FIG. 29, which reduces the amount of residual fuel while continuing generation, also acts as a temperature rise-suppression circuit. However detected temperature Td still rises at times t23-t24.

Next, at time t24 the detected temperature Td reaches the air cooling region temperature (step S47→S48 in FIG. 29, corresponding to t24 in FIG. 30). Step S48 in FIG. 29 is thus executed, and the air supply amount is increased to the maximum air supply amount for the generating air flow regulator unit 45. Generated current is gradually reduced from 4 A to 1 A. Thereafter, the generated current reduced to 1 A, which is the temperature rise-suppressing generation amount, is maintained at a fixed level until the detected temperature Td declines to a temperature below the current maintain region. The generated current which has been reduced to 1 A is entirely consumed by the auxiliary unit 4 and not output to the inverter 54. With the drop in generated current, the fuel utilization rate Uf is reduced from the maximum fuel utilization rate Ufmax at a generated current of 4 A to a maximum fuel utilization rate Ufmax (=50%) at a generated current of 1 A (FIG. 24).

Thus at step S50 in FIG. 29, which is the temperature rise-suppression circuit, temperature rises reducing the amount of residual fuel are suppressed, following which, when suppression of further temperature rises is required, supplied air is increased. The portion of air increased beyond the supply amount needed for electrical generation acts as a cooling fluid flowing into the fuel cell module 2, so step S48 in FIG. 29 functions as a forced cooling circuit.

On the other hand if by executing step S50, which is the temperature rise-suppression circuit for reducing the amount of residual fuel, the detected temperature Td drops without reaching the temperature of the air cooling region, cooling by step S48, which is the forced cooling circuit, is not executed. Therefore a determination of whether or not to execute a suppression of temperature rises by the forced cooling circuit is made based on temperature changes in the fuel cell module 2 after suppressing rises by the temperature rise-suppression circuit.

After time t24 the rise in detected temperature Td is continued, but at time t25 this shifts to a decline (t24→t25 in FIG. 30). Thereafter the detected temperature Td declines, and at time t26 declines to the upper limit temperature of the current reduction region (t25→t26 in FIG. 30). Reduction of the air supply amount is thus begun.

Next, at time t27, the temperature declines to the upper limit temperature of the maintain current region (t26→t27 in FIG. 30). The detected temperature Td continues to further decline, and at time t28 declines to the lower limit temperature of the maintain current region (t27→t28 in FIG. 30).

At time t28, when the temperature drops leaves the current maintain region, the generated current begins to increase in order to follow the target current. In conjunction with this, the fuel supply amount also increases. The fuel utilization rate Uf increases, adopting a maximum fuel utilization rate Ufmax corresponding to each generated current.

Note that in the above-described embodiment, temperature rises were suppressed by lowering the upper limit of the generated power variable range according to the temperature inside the fuel cell module 2, but it is also possible as a variant example to suppress temperature rises by lowering the frequency of increases and decreases in generated power. That is, when the temperature inside the fuel cell module 2 has risen, further temperature rises can be suppressed by reducing following of the rise in power demand and reducing following characteristics which increase generated power. When following characteristics relative to increases in power demand are reduced, generated power increases more sluggishly when power demand increases. Therefore when the power demand has increased and decreased often, the range of increase and decrease in generated power attempting to follow this becomes smaller, and the frequency of increases and decreases is also reduced, so that the amount of residual fuel occurring similarly declines. Therefore the decline in following characteristics relative to the increase in power demand continues until the excessive temperature rise inside the fuel cell module 2 is eliminated.

Alternatively, limits can also be placed on the frequency per unit time at which the generated power is increased to follow increases in the power demand. In this case a limitation is placed on the number of times per predetermined time unit which generated power can switch to a rising trend; when the number of times per predetermined time is large, generated power is controlled so as not to allow generated power to follow the increase in power demand.

In the above-described embodiment, the generated current upper limit was lowered to 4 A when the detected temperature Td reached the current reduction region, but it is also possible, as a variant example, to make variable the upper limit of the generated power. For example, the generated power upper limit value, which is reduced more as the temperature inside the fuel cell module 2 increases, can be set low.

Next, referring to FIG. 32, we discuss the relationship between the temperature inside the fuel cell module 2 and maximum generatable power.

As discussed above, there is a correlation between fuel cell module 2 generated power (current) and appropriate temperature inside the fuel cell module 2, and to obtain a large generated power requires raising the temperature inside the fuel cell module 2. However when the fuel cell module 2 is in a temperature region over 700° C., which is higher than the appropriate temperature relative to generated power, the characteristics of the individual fuel cell stack 14 are such that the potential produced by the fuel cell units 16 declines. Therefore when a large current is extracted from the individual fuel cell stack 14 in order to obtain a large power, the individual fuel cell stack 14 temperature further rises, and the potential produced falls, resulting in the phenomenon that output power does not increase even though current is increased. As a result, in the region in which the temperature in the fuel cell module 2 is high, the generatable maximum power actually declines when the temperature rises, as shown in FIG. 32. When an attempt is made to extract the maximum rated power from the fuel cell module 2 in this type of temperature region, current is increased in order to increase extracted power; this current rise further increases the temperature of the fuel cell module 2 and reduces the power extracted from same. When such a state continues, attempting to obtain a predetermined rated power tends to induce a thermal runaway causing a sudden temperature rise in the fuel cell module 2.

In the present embodiment, thermal runaways can be prevented in advance in the region where the temperature inside the fuel cell module 2 is higher than the appropriate temperature by maintaining or lowering the generated current even when the power demand has increased.

Next, referring to FIG. 33, we discuss measurement of the detected temperature Td in the present embodiment.

FIG. 33 is a flow chart showing a procedure for calculating a first add/subtract value M1 based on temperatures Td detected by multiple temperature sensors.

As shown in FIG. 3, in the present embodiment two generating chamber temperature sensors 142 are provided inside the generating chamber 10. Here, inside the fuel cell module 2 in the present embodiment, twenty fuel cell units 16 are arrayed in the width direction (FIG. 2) and eight fuel cell units 16 are arrayed in the depth direction (FIG. 3). Therefore a total of 160 fuel cell units 16 are arranged in a rectangle as seen in plan view. In this embodiment, of the two generating chamber temperature sensors 142, one is disposed adjacent to the vertex of the rectangle, and the other is disposed adjacent to the midpoint of the long side of the rectangle. Thus in the present embodiment, the two generating chamber temperature sensors 142 are disposed so that different temperatures are detected within the fuel cell module 2.

Therefore the temperature Td detected by the generating chamber temperature sensors 142 disposed adjacent to the rectangle vertices primarily reflect the temperature of the fuel cell units 16 disposed near the vertices of the rectangle, and the temperature Td detected by the generating chamber temperature sensors 142 disposed adjacent to the midpoint of the long side of the rectangle primarily reflect the temperature of the fuel cell units 16 disposed near the midpoint of the long side of the rectangle. The fuel cell units 16 disposed close to the vertices of the rectangle can easily be robbed of heat by the surrounding insulating material 7 or the like and are therefore at the lowest temperature; the fuel cell units 16 disposed near the midpoint of a long side of the rectangle reach a higher temperature than the fuel cell units 16 disposed near the vertices. In the present embodiment, the temperature differences between fuel cell units 16 may reach several tens of degrees. Note that it is believed that the fuel cell units 16 disposed near the intersection of the diagonals of the rectangle reach the highest temperature, and generating chamber temperature sensors may also be disposed so as to measure this temperature.

In step S61 of FIG. 33, detected temperatures Td are respectively read in from the two generating chamber temperature sensors 142. Next, in step S62, an average value for the read-in detected temperature Td is calculated and a judgment made of whether the averaged temperature is higher than the appropriate temperature Ts(I). When the averaged temperature is higher than the appropriate temperature Ts(I), the system advances to step S63; when it is lower than the appropriate temperature Ts(I), the system advances to step S64.

In step S63, a first add/subtract value M1 is calculated based on the higher of the two detected temperatures Td (the first add/subtract value M1 becomes a positive value or 0) and processing for one iteration of the FIG. 33 flow chart is completed. That is, the estimated amount of increase in the stored heat amount is determined based on the higher of the two detected temperatures Td. In step S64, on the other hand, a first add/subtract value M1 is calculated based on the lower of the two detected temperatures Td (the first add/subtract value M1 becomes a negative value or 0) and processing for one iteration of the FIG. 33 flow chart is completed. That is, the estimated amount of reduction in the stored heat amount is determined based on the lower of the two detected temperatures Td. Thus the detected temperature Td on the high temperature side is adopted when above the appropriate temperature Ts(I), whereas the low side detected temperature Td is adopted when below the appropriate temperature Ts(I). The stored heat amount is in this way estimated based on the temperature of the higher temperature fuel cell unit 16 when excessive temperature rise becomes a problem. When temperature reduction is a problem, the stored heat amount is estimated based on the low temperature individual fuel cell unit 16 (normally the fuel cell units positioned at vertices of the rectangle), therefore the stored heat amount can be estimated on the safe side even when the temperatures of each of the fuel cell units 16 differ.

Note that in the above-described embodiment the detected temperature Td on either the high temperature side or the low temperature side was selected and an integral value calculated based thereon, but it is also acceptable as a variant example to obtain the respective integral values for each detected temperature Td. That is, if stored heat amounts are estimated by determining add/subtract values for each of multiple detected temperatures and integrating the determined add/subtract values for each detected temperature to calculate multiple integral values, and if the largest numerical value of the multiple integral values is selected when all of the multiple integral values are increasing, and the smallest numerical value of the multiple integral values is selected when a portion of the multiple integral values are decreasing, this value may be used as the stored heat amount estimated value.

In the above-described present embodiment, we adopted the high temperature side of the detected temperature in step S63 and the low temperature side of the detected temperature in step S64, but is also possible as a variant example to calculate the first add/subtract value M1 based on a weighted average of the two detected temperatures as a way of estimating the stored heat amount. For example, in step S63 the first add/subtract value M1 can be calculated based on a value obtained by adding a value 0.7 times the detected temperature on the high temperature side to a value 0.3 times the detected temperature on the low temperature side, then in step S63 the first add/subtract value M1 can be calculated based on a value obtained by adding a value 0.3 times the detected temperature on the high temperature side to a value 0.7 times the detected temperature on the low temperature side. Thus in step S63, where the detected temperature Td is high and the estimated value of the stored heat amount is increased (first add/subtract value M1 is positive or 0) the highest of the multiple detected temperatures Td is used as the most heavily weighted factor for estimating the stored heat amount, whereas in step S64, where the estimated value of the stored heat amount is decreased (first add/subtract value M1 is negative or 0) the lowest temperature is used as the most heavily weighted factor for estimating the stored heat amount.

It is also possible to at all times calculate the first add/subtract value M1 from the simple average of each detected temperature Td, without weighting each of the detected temperatures Td.

When the temperature of fuel cell units positioned at vertices of the rectangle has dropped to or below a predetermined usage-suppressing cell unit temperature, the first add/subtract value M1 can be determined in a way which suppresses increases in the fuel utilization rate Uf.

Next, referring to FIG. 34, we discuss calculation of an add/subtract value according to a variant example of the present embodiment. Note that calculation of the add/subtract value according to this variant example may be used together with the processing in FIG. 33, or may be applied on its own. When applying the present variant example on its own, it is acceptable to have one generating chamber temperature sensor 142.

FIG. 34 is a flow chart showing the procedure for calculating a first add/subtract value M1 based on the detected temperature from the reformer temperature sensor 148, which is another temperature detection device in addition to the generating chamber temperature sensors 142 serving as temperature detection device.

First, in step S71 of FIG. 34, detected temperatures are read in from the reformer temperature sensor 148. In the present embodiment, there are reformer temperature sensors 148 attached at two locations, on the entrance side and the exit side of the reformer 20, so that temperatures in the vicinity of the entrance and exit of the reformer 20 are measured. Normally the temperature of the reformer 20 is low on the entrance side where the endothermic steam reforming reaction occurs abundantly, and high on the exit side.

Next, in step S72 each detected temperature in the reformer 20 is compared to a predetermined usage-suppressing reformer temperature. First, if the lower detected temperature of the two reformer 20 detected temperatures is lower than a low temperature-side usage-suppressing reformer temperature Tr0, and the higher of the detected temperatures is lower than high temperature-side usage-suppressing reformer temperature Tr1, the system advances to step S73. On the other hand if the higher detected temperature of the two reformer 20 detected temperatures is higher than a high temperature-side usage-suppressing reformer temperature Tr1, and the lower detected temperature is higher than low temperature-side usage-suppressing reformer temperature Tr0, the system advances to step S75. When neither of these is the case, the system advances to step S74.

In step S73, because the temperature of the reformer 20 is lower than each of the usage-suppressing reformer temperatures, the first add/subtract value M1 is corrected so that the fuel utilization rate Uf falls (the fuel supply amount increases). That is, a value obtained by subtracting 10% of the absolute value of first addition/subtraction value M1 calculated based on the temperature Td detected by the generating chamber temperature sensors 142 is used for integration. The first integral value N1id, which is the estimated value of the stored heat amount, thus decreases (its increase is suppressed), placing the fuel utilization rate Uf on a decreasing trend (the increase in the fuel utilization rate is suppressed), raising the temperature of the reformer 20.

In step S75, on the other hand, because the temperature of the reformer 20 is higher than each of the usage-suppressing reformer temperatures, the first add/subtract value M1 is corrected so that the fuel utilization rate Uf rises (the fuel supply amount decreases). That is, a value obtained by adding to the first addition/subtraction value M1 10% of the absolute value of first addition/subtraction value M1 calculated based on the temperature Td detected by generating chamber temperature sensors 142 is used as the first addition/subtraction value M1 for integration. The first integral value N1id, which is the estimated value of the stored heat amount, thus increases (its decrease is suppressed), placing the fuel utilization rate Uf in a rising trend, so that the temperature of the reformer 20 is decreased. Damage to the reformer 20 caused by excessive rise in the reformer 20 temperature is thus prevented.

In step S74, because the reformer 20 is in the appropriate temperature range, no correction is made to the first add/subtract value M1, and processing of one iteration of the FIG. 34 flow chart is completed. (Since the two detected reformer 20 temperatures are correlated, a state in which the lower detected temperature is lower than low temperature-side usage-suppressing reformer temperature and the higher of the detected temperatures is higher than high temperature-side usage-suppressing reformer temperature normally does not occur.)

Note that in the present embodiment the fuel utilization rate may also be corrected by averaging the temperatures detected by the two reformer temperature sensors 148 and comparing the averaged detected temperature to one or two of the usage-suppressing reformer temperatures. When the change rate is high in response to the rate of change per unit time in the temperatures detected by the reformer temperature sensors 148, the amount of correction to the fuel utilization rate may be increased.

Next, referring to FIG. 35, we discuss calculation of an add/subtract value according to a variant example of the present embodiment. Note that calculation of the add/subtract value according to this variant example may be used together with the processing in FIGS. 33 and 34, or may be applied on its own. When applying the present variant example on its own, it is acceptable to use one generating chamber temperature sensor 142.

FIG. 35 is a flow chart showing the procedure for calculating a first add/subtract value M1 based on the detected temperature from an exhaust temperature sensor 140, which is another temperature detection device in addition to the generating chamber temperature sensors 142 serving as temperature detection device.

First, in step S81 of FIG. 35, detected temperatures are read in from the reformer temperature sensor 148. In the present embodiment, the exhaust temperature sensor 140 is disposed to measure the temperature of exhaust gas combusted in the combustion chamber 18 and discharged after passing through an exhaust gas discharge pipe 82.

Next, in step S82, the detected temperature of the exhaust gas is compared to a predetermined usage-suppressing exhaust gas temperature. First, if the detected exhaust gas temperature is below a predetermined low temperature side usage-suppressing exhaust temperature Tem0, the system advances to step S83. On the other hand, if the detected exhaust gas temperature is above a predetermined high temperature side usage-suppressing exhaust temperature Tem1, the system advances to step S85. If the exhaust gas detected temperature is below the high temperature side usage-suppressing exhaust temperature Tem1 and above the low temperature side usage-suppressing exhaust temperature Tem0, the system advances to step S84.

In step S83, since the temperature of the exhaust gas is lower than the appropriate temperature, the first add/subtract value M1 is corrected so that the fuel utilization rate Uf decreases (the fuel supply amount increases). That is, a value obtained by subtracting from the first addition/subtraction value M1 10% of the absolute value of first addition/subtraction value M1 calculated based on the temperature Td detected by generating chamber temperature sensors 142 is used as the first addition/subtraction value M1 for integration. The first integral value N1id, which is the estimated value of the stored heat amount, thus decreases (its increase is suppressed), placing the fuel utilization rate Uf on a decreasing trend (the increase in the fuel utilization rate Uf is suppressed), so that the temperature of the exhaust gas is raised.

In step S85, on the other hand, since the temperature of the exhaust gas is higher than the appropriate temperature, the first add/subtract value M1 is corrected so that the fuel utilization rate Uf increases (the fuel supply amount decreases). That is, a value obtained by adding to the first addition/subtraction value M1 10% of the absolute value of first addition/subtraction value M1 calculated based on the temperature Td detected by generating chamber temperature sensors 142 is used as the first addition/subtraction value M1 for integration. The first integral value N1id, which is the estimated value of the stored heat amount, thus increases (its decrease is suppressed), placing the fuel utilization rate Uf in a rising trend, so that the temperature of the exhaust gas is decreased. The temperature inside the fuel cell module 2 is by this means made appropriate.

In step S84, because the exhaust gas is in the appropriate temperature range, no correction is made to the first add/subtract value M1, and processing for one iteration of the FIG. 35 flow chart is completed.

Note that in this variant example, when the change rate is high according to the rate of change per unit time in the temperatures detected by the exhaust temperature sensor 140, the range of correction to the fuel utilization rate may be increased.

We have explained above preferred embodiments of the present invention above, but various changes may be made to the above-described embodiments. In particular, in the above-described embodiments the thermal capacity of thermal insulating material was fixed, but a variant example fuel cell module can also be constituted in which thermal capacity is variable. In such cases, an additional thermal capacity member with a large thermal capacity is placed in such a way as to be connectable and disconnectable from the fuel cell module. In a state requiring increased thermal capacity, the additional heat capacity member is thermally connected to the fuel cell module; in a state requiring decreased thermal capacity, the additional heat capacity member is thermally disconnected from the fuel cell module. For example, at the time of solid oxide fuel cell system startup, thermal capacity is reduced by disconnecting the additional heat capacity member, and the fuel cell module temperature rise is sped up. On the other hand, when it is anticipated that a solid oxide fuel cell system will operate for long hours at high generated power, the additional heat capacity member is connected so that the fuel cell module can store a larger surplus heat amount.

The following constitutions of the present invention are also possible preferred embodiments.

1. A solid oxide fuel cell system for producing a variable generated power in accordance with power demand, having: a fuel cell module for generating electricity using supplied fuel; a generating oxidant gas supply device for supplying generating oxidant gas to a fuel cell module; a heat storage material for storing heat produced by the fuel cell module; a demand power detection circuit for detecting power demand; a controller for determining a fuel supply amount by referring to a basic fuel supply table set so that the fuel utilization rate is high when generated power is large and the fuel utilization rate is low when generated power is small, based on demand power detected by the demand power detection device, and controlling the fuel supply device so that the determined fuel supply amount is supplied; and a fuel table change circuit for changing the basic fuel supply table so that when generated power is small, the fuel utilization rate temporarily increases during the time when a utilizable heat amount stored during high generated power is stored in the heat storage material, thereby reducing the fuel supply amount.

In the present invention constituted as in 1 above, the fuel supply device and generating oxidant gas supply device respectively supply fuel and generating oxidant gas to the fuel cell module. The fuel cell module generates electricity using the supplied fuel and generating oxidant gas, and heat produced in the fuel cell module is stored by the heat storage material. Based on the demand power detected using the demand power detection device, the controller refers to the basic fuel supply table, set so that the fuel utilization rate is high when generated power is large and the fuel utilization rate is low when generated power is small, to determine a fuel supply amount and control the fuel supply device. When generated power is small, the fuel table change circuit changes the basic fuel supply table to temporarily increase the fuel utilization rate during the period when the utilizable heat amount stored during high generated power is being stored in the heat storage material, thereby reducing the fuel supply amount.

Generally in solid oxide fuel cell system when generated power is small, electrical generation heat declines, making it easier to induce a decline in the temperature of the fuel cell module. Therefore at times of low power generation, the fuel utilization rate is reduced and fuel not used for generating electricity is combusted to heat up the fuel cell module and prevent excessive temperature drops. In particular, in solid oxide fuel cell system of the type in which a reformer is disposed within the fuel cell module, an endothermic reaction occurs inside the reformer, facilitating an even further reduction in temperature. In the present invention thus constituted, the heat amount stored in the heat storage material during high generated power is actively utilized during low generated power, thus enabling a control which raises the fuel utilization rate only during temporary periods during which temperature drops can be suppressed, so that overall energy efficiency of the solid oxide fuel cell system can be improved while maintaining thermal self-sufficiency and avoiding excessive temperature drops.

2. In the present invention constituted as described in 1, the fuel table change circuit preferably temporarily executes a change to the basic fuel supply table, reducing the fuel supply amount when generated power is low, then completes the change, and the controller controls the fuel supply device based on the original fuel supply table.

In the present invention constituted as described in 2 above, the fuel table change circuit temporarily executes a change to the basic fuel supply table, reducing the fuel supply amount when generated power is low, then completes the change; thereafter the fuel supply device is controlled based on the basic fuel supply table, thereby reliably avoiding the risk that the heat amount stored in the heat storage material will be excessively reduced so as to cause an extraordinary temperature drop.

3. In the present invention constituted as described in 2 above, the basic fuel supply table is preferably set so that at a predetermined middle level generated power, a greater heat amount is stored in the heat storage material, such that heat amounts stored during high generated power can be utilized during low generated power.

In the present invention constituted as described in 3 above, the basic fuel supply table is set so that in a region above medium generated power, a larger heat amount is stored in the heat storage material, therefore by actively storing heat in a region above the medium electrical generation level where the fuel utilization rate can be increased, this heat can be consumed during low power generation when the fuel cell module temperature is relatively low and self-sustaining is difficult, so that high efficiency operation at a high fuel utilization rate with effective use of the stored heat amount can be reliably carried out.

4. In the present invention constituted as described in 3 above, the basic fuel supply table is preferably set so that in a region in which the generated power is higher than the middle value of the generated power range, a larger heat amount is stored in the heat storage material.

In the present invention constituted as described in 4 above, a larger amount of heat is stored in the heat storage material in the region where generated power is greater than the middle value of the generated power range. Therefore in the vicinity of the middle value of the frequently used generated power range, the amount of stored surplus heat is suppressed, and a large amount of heat is stored in the heat storage material during power demand peaks. Thus when a solid oxide fuel cell system is used in a residence, excessive fuel consumption to store large heat amounts is suppressed during the periods of most frequent power demand amounts, being the medium level power demand amounts occurring during the day, etc., while on the other hand large heat amounts are stored during time periods with peak power demand, such as evening hours, so that heat amounts stored in the evening hours are immediately consumed in the follow-on late night period; hence wasteful storage of heat amounts over long periods is eliminated, and a high efficiency operation can be achieved to reliably take effective advantage of stored heat during the late night period when generated power is greatly reduced.

5. In the present invention constituted as described in 3 above, there is preferably furthermore a stored heat estimating circuit for estimating the amount of stored heat in the heat storage material, and the fuel table change circuit executes changes to the basic fuel supply table when the stored heat amount estimated by the stored heat estimating circuit is equal to or greater than a predetermined change-executed stored heat amount, and does not change the basic fuel supply table when the estimated stored heat amount is less than the change-executed stored heat amount.

In the present invention constituted as described in 5 above, the stored heat amount in the heat storage material is estimated by the stored heat estimating circuit, therefore changes to increase the fuel utilization rate can be stably executed, and a change is executed when the estimated stored heat amount is equal to or greater than a predetermined change-execution stored heat amount, so that overcooling can be more reliably prevented.

6. In the present invention constituted as described in 5 above, the fuel table change circuit preferably increases the amount of change in the basic fuel supply table, reducing the fuel supply amount more as the stored heat amount estimated by the stored heat estimating circuit increases.

In the present invention constituted as described in 6 above, the fuel utilization rate is greatly improved as the estimated stored heat amount increases, therefore overall energy efficiency can be more safely and greatly improved.

7. In the present invention constituted as described in 6 above, the fuel table change circuit, based on the stored heat amount estimated by the stored heat estimating circuit, preferably selects and executes at least one of either a change in the period over which basic fuel supply table changes are executed, or a change in the amount of change to the basic fuel supply table.

In the present invention constituted as described in 7 above, a change is made in either the period over which change is executed to the basic fuel supply table or the amount of change thereof, therefore overall energy efficiency can be reliably improved.

8. In the present invention constituted as described in 5 above, the stored heat estimating circuit preferably estimates the amount of stored heat in the heat storage material based on the temperature of the fuel cell module.

In the present invention constituted as described in 8 above, the stored heat amount is estimated based on the temperature of the fuel cell module, which is strongly correlated with the amount of stored heat, therefore the stored heat amount can be relatively accurately estimated without provision of particular sensors, and fuel cell module performance degradation, excessive temperature drops, and the like can be reliably avoided.

9. In the present invention constituted as described in 5 above, the stored heat estimating circuit preferably estimates the amount of stored heat in the heat storage material based on the past operating history of the fuel cell module.

In the present invention constituted as described in 9 above, the stored heat amount is estimated based on operating history prior to the start of changes to the basic fuel supply table, therefore compared to a control based on instantaneous current temperature alone, a more accurate control based on residual stored heat amounts is possible, so that a safer, simpler, and more accurate estimate of the stored heat amount can be made.

10. In the present invention constituted as described in 9 above, the stored heat estimating circuit estimates the stored heat amount in the heat storage material based on the past generated power of the fuel cell module, and on the time over which it was operated at that generated power.

In the present invention constituted as described in 10 above, the stored heat amount is estimated based on fuel cell module generated power and the time thereof, therefore the stored heat amount can be accurately estimated without provision of any special sensors.

11. In the present invention constituted as described in 5 above, the fuel table change circuit determines a predetermined change execution period based on stored heat estimated by the stored heat estimating circuit at the commencement of change in the basic fuel supply table, and executes a change within this change execution period.

In the present invention constituted as described in 11 above, changes are executed within a change execution period determined based on a stored heat amount estimated by the stored heat estimating circuit, therefore changes in the basic fuel supply table utilizing stored heat can be effected using a simpler control.

12. In the present invention constituted as described in 3 above, there is preferably a change period extension circuit for extending the period in which, during the execution of a change to the basic fuel supply table by the fuel table change circuit, a reduction in stored heat in the heat storage material is suppressed, and the period over which changes in the basic fuel supply table are executed is extended.

The present invention constituted as described in 12 above is furnished with a change period extension circuit for extending the period for executing changes to the basic fuel supply table, therefore the stored heat amount can be effectively utilized in accordance with conditions.

13. In the present invention constituted as described in 12 above, the change period extension circuit preferably reduces the change amount in the basic fuel supply table as the period over which changes to the basic fuel supply table are executed lengthens, in conjunction with decreases in the amount of heat stored in the heat storage material.

In the present invention constituted as described in 13 above, the amount of change relative to the basic fuel supply table is reduced with the decrease in stored heat amount, therefore the period during which the fuel utilization rate is increased can be extended without inducing excessive temperature drops in the fuel cell module, degradation of performance, or the like.

14. In the present invention constituted as described in 12 above, the change period extension circuit preferably reduces the basic fuel supply table change amount more as generated power decreases.

In the present invention constituted as described in 14 above, because the change amount relative to the basic fuel supply table is reduced more as generated power decreases, there is a decrease in the change amount during low power generation, in which the amount of stored heat utilized increases, and the period during which the fuel utilization rate is increased can be extended while reliably avoiding excessive temperature drops in the fuel cell module, degradation of performance, or the like.

15. In the present invention constituted as described in 12 above, during the execution of changes to the basic fuel supply table the change period extension circuit controls the generating oxidant gas supply device to reduce oxidant gas for generation supplied to the fuel cell module.

In the present invention constituted as described in 15 above, generating oxidant gas supplied to the fuel cell module is reduced during change execution, therefore the carrying off of the heat amount stored in the heat storage material by oxidant gas can be suppressed, and stored heat can be effectively used over a longer time period.

16. The present invention constituted as described in 3 above furthermore preferably has an overcooling prevention circuit for preventing overcooling of the fuel cell module when the amount of stored heat in the heat storage material is small.

The present invention constituted as described in 3 above is furnished with an overcooling prevention circuit, therefore overcooling caused by increasing the fuel utilization rate can be reliably prevented in a state in which the amount of stored heat has declined.

17. In the present invention constituted as described in 16 above, during the period when changes in the fuel supply amount are being executed by the fuel table change circuit, the overcooling prevention circuit preferably improves the fuel supply amount following characteristics by the fuel supply device more than the following characteristics during normal operation.

In the present invention constituted as described in 17 above, fuel supply amount following characteristics are improved during the period when changes in the fuel supply amount are being executed, therefore the fuel supply amount can be quickly increased when the fuel utilization rate drops in conjunction with a decline in the stored heat amount. Overcooling of the fuel cell module caused by delays in response which cause an increase in the fuel supply amount can thus be prevented.

Number	Date	Country	Kind
2010-218366	Sep 2010	JP	national
2011-078888	Mar 2011	JP	national
2011-078889	Mar 2011	JP	national
2011-079464	Mar 2011	JP	national

	Number	Date	Country
Parent	PCT/JP2011/072330	Sep 2011	US
Child	13852364		US

SOLID OXIDE FUEL CELL SYSTEM

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