The present invention relates to systems and methods for generating heat using biomass energy and, more specifically, to systems and methods adapted to transfer heat obtained from solid biofuels to water for domestic use.
The term “biomass energy” is used herein to refer to energy obtain from solid biofuels such as wood, sawdust, wood chips, grass cuttings, domestic refused, charcoal, agricultural waste, energy crops, and dried manure. To release biomass energy, solid biofuels are typically burned in a fireplace, stove, or furnace to create heat. Certain solid biofuels, such as wood (e.g., firewood) can be burned directly; other solid biofuels, such as sawdust and wood chips, may be processed into pellets, cubes, pucks, or the like to facilitate burning. The heat generated by burning solid biofuels may be used directly or may be transferred to another medium to facilitate distribution of the heat throughout a dwelling.
In general, the market for biomass reduction systems may be divided into commercial furnaces and residential stoves, fireplaces, and furnaces. The present invention is of particular significance in the context of furnaces designed for use in a residential setting. Commercial furnaces are typically relatively large, and the biofuels used in a commercial furnace typically have a predetermined form factor and composition. For example, commercial furnaces are designed to use densified pellets to facilitate handling of the biofuels and to allow the furnace to be designed for a biofuel having a known energy density. Commercial devices are further typically designed to run continuously and at high utilization or demand and do not operate efficiently at low utilization or demand.
In contrast, in residential or domestic settings, biofuels are commonly burned in a stove or fireplace, and the generated heat is transferred as radiant heat energy to the surrounding environment. Residential stoves and fireplaces are typically relatively inefficient, resulting in incomplete burning of the biofuel and thus the discharge of soot, ash, and gasses through the smokestack or chimney.
Additionally, in North America, biofuels burned in a residential setting most commonly take the form of firewood. Firewood is typically obtained from trees of different species and comes in different shapes, sizes, and moisture content; the form factor and composition of firewood is thus typically not known in advance.
The need exists for biomass reduction furnaces designed for residential settings that do not require biofuels having a known form factor and composition, that transfer heat energy to water for use in domestic purposes (e.g., heating domestic hot water or radiant heating systems), and that result in complete burning of the biofuel.
The present invention may be embodied as a biofuel heating system for converting biofuel to heat energy to be delivered to a load comprising a combustion chamber defining a combustion zone, an under-fire zone, and an over-fire zone. A plurality of under-fire ports is arranged adjacent to the under-fire zone of the combustion chamber. A plurality of over-fire ports is arranged adjacent to the over-fire zone of the combustion chamber. The combustion zone is adapted to receive the biofuel. The under-fire zone is below the combustion zone, and the over-fire zone is above the combustion zone. A plurality of over-fire ports is arranged adjacent to the over-fire zone of the combustion chamber. A burn-out port is arranged to allow fluid to flow out of the over-fire zone of the combustion chamber and into a burn-out chamber. A heat exchange port is arranged to allow fluid to flow out of the burn-out chamber and into a heat exchange chamber. An exhaust port arranged to allow fluid to flow out of the heat exchange chamber. A heat exchange system is arranged at least partly within the heat exchange chamber, and a working fluid is circulated between the heat exchange system and the load. An under-fire damper is configured to inhibit flow of fluid through the under-fire ports. An over-fire damper is configured to inhibit flow of fluid through the over-fire ports. A fan is arranged to cause fluid to flow out of the heat exchange chamber through the exhaust port. At least one sensor is configured to sense an operating parameter. A controller operates at least one of the fan, the under-fire damper, and the over-fire damper based on the operating parameter such that air flows along a flow path extending from at least one of the under-fire port and the over-fire port, through the combustion chamber, through burn-out port, through the burn-out chamber, through the heat exchange port, through the heat exchange chamber, and out of the exhaust port. The heat exchange system transfers heat energy from air flowing through the heat exchange chamber to the working fluid.
The present invention may also be embodied as a method of converting biofuel to heat energy to be delivered to a load comprising the following steps. A combustion chamber defining a combustion zone, an under-fire zone, and an over-fire zone is provided. The under-fire zone is below the combustion zone, and the over-fire zone is above the combustion zone. A plurality of under-fire ports is adjacent to the under-fire zone of the combustion chamber. A plurality of over-fire ports is arranged adjacent to the over-fire zone of the combustion chamber. A burn-out port is arranged to allow fluid to flow out of the over-fire zone of the combustion chamber and into a burn-out chamber. A heat exchange port is arranged to allow fluid to flow out of the burn-out chamber and into a heat exchange chamber. An exhaust port is arranged to allow fluid to flow out of the heat exchange chamber. A working fluid is circulated through the load. An under-fire damper is arranged to inhibit flow of fluid through the under-fire ports. An over-fire damper is arranged to inhibit flow of fluid through the over-fire ports. A fan is arranged to cause fluid to flow out of the heat exchange chamber through the exhaust port. The biofuel is arranged in the combustion zone and ignited. At least one operating parameter is sensed. At least one of the fan, the under-fire damper, and the over-fire damper is operated based on the operating parameter such that air flows along a flow path extending from at least one of the under-fire port and the over-fire port, through the combustion chamber, through burn-out port, through the burn-out chamber, through the heat exchange port, through the heat exchange chamber, and out of the exhaust port. Heat energy is transferred from air flowing through the heat exchange chamber to the working fluid.
Depicted in
The example biofuel 22 is formed by individual pieces of firewood of different sizes, shapes, and composition. Additionally, other forms of biofuels may be used in addition to or instead of firewood. The example biofuel heating system 20 is configured such that the precise size, shape, composition, and moisture content of the example biofuel 22 need not be known in advance.
The load 24 represents a demand for thermal energy and will typically comprise a domestic hot water system and/or a space heating system such as in-floor radiant heating. The precise nature of the load 24 need not be known in advance.
The example biofuel heating system 20 comprises a furnace assembly 30 (
At any particular point in time, the temperature of the working fluid reflects the heat energy being generated by the heating system 20 and the demand by the load 24. The demand by the load 24 is, with certain exceptions discussed below, assumed to be outside of the control of the heating system 20. The temperature of the working fluid is thus primarily controlled by continually controlling the heat energy produced by the heating system 20.
To allow the heat energy produced by the heating system 20 to be controlled, a set point temperature (set point) of the working fluid sufficient to satisfy the operating conditions of the load 24 is defined. The set point is typically lower than the boiling point of the working fluid; if water is used as the working fluid, the set point is typically approximately 172° F. but in any event is typically in a first range of 160° F.-180° F. and in any event should be within a second range of 150° F.-200° F. The set point can be increased or decreased based on external environmental conditions such as season, outside temperatures, and the like.
In general, the control system 32 controls the heat energy produced by the heating system 20 by controlling a flow of gasses along the flow path 36. More specifically, the control system 32 alters gas flow along the flow path 36 based on at least one temperature within the furnace assembly and/or the temperature of the working fluid. The control system 32 may further be configured to alter gas flow along the flow path 36 based on at least one pressure associated with the working fluid and an oxygen content of the gasses flowing along the flow path 36.
With the foregoing general understanding of the present invention in mind, the details of the example biogas heating system 20 will now be described in further detail.
The example furnace assembly 30 defines a combustion chamber 40, a burn-out chamber 44, and a heat exchange chamber 46. The combustion chamber 40 defines a combustion zone 50, an under-fire zone 52, and an over-fire zone 54. The under-fire zone 52 is arranged below the combustion zone 50, and the over-fire zone 54 is arranged above the combustion zone 50. The example heat exchange chamber 46 defines a heat exchange zone 56 and an exhaust zone 58.
The example furnace assembly 30 further defines an under-fire inlet 60, an under-fire chamber 62, a plurality of under-fire openings 64, a plurality of under-slots 66, and a plurality of under-fire ports 68. Air may be allowed to flow from the exterior of the heating system 20 into the under-fire zone 52 along an under-fire portion of the flow path 36 extending through the under-fire inlet 60, through the under-fire chamber 62, through the under-fire openings 64, through the under-fire grooves 66, and through the under-fire ports 68.
The example furnace assembly 30 further defines at least one over-fire inlet 70, at least one over-fire chamber 72, and a plurality of over-fire ports 74. Air may also be allowed to flow from the exterior of the heating system 20 into the over-fire zone 54 along an over-fire portion of the flow path 36 extending through the over-fire inlet 70, through the over-fire chamber 72, and through the over-fire ports 74.
The example furnace assembly 30 further defines a burn-out inlet port 80 that allows heated exhaust to flow from the over-fire zone 54 of the combustion chamber 40 into the burn-out chamber 42. At this point, the exhaust contains heated under-fire air and/or over-fire air and other possibly gasses and particulates from combustion process within the combustion chamber 40. The furnace assembly 30 further defines a heat exchange inlet port 82 that allows exhaust to flow from the burn-out chamber 42 to the heat exchange zone 56 of the heat exchange chamber 44. An exhaust port 84 allows exhaust to flow from the exhaust zone 58 of the heat exchange chamber 44 out of the furnace assembly 30.
The example flow path 36 extends along one or both of the under-fire portion and the over-fire portion into the combustion chamber 40, through the burn-out inlet port 80 into the burn-out chamber 42, through the heat exchange port 82 into the heat exchange chamber 44, and out of the heating system 20 through the exhaust port 84.
More specifically, the under-fire ports 68 are arranged such that under-fire air flowing along the under-fire portion of the flow path 36 flows up into a plurality of discrete, spaced locations within the under-fire zone 52 of the combustion chamber 42. After flowing through the under-fire zone 52, the under-fire air continues to flow up through the combustion zone 50 of the combustion chamber 42; under-fire air flowing through the combustion zone 50 flows along the bottoms and around the sides of the biofuel 22 within the combustion zone 50 to encourage complete burning of the biofuel 22. After flowing through the combustion zone 50, the under-fire air separates from the biofuel 22 and continues to flow up along the under-fire portion of the flow path 36 and into the over-fire zone 54. Again, the under-fire air flowing into over-fire zone 54 is not concentrated in any portion of the combustion chamber 42.
Over-fire air flowing along the over-fire portion of the flow path 36 flows into the over-fire zone 54. In particular, the example over-fire ports 74 are arranged such that the over-fire air flows into the over-fire zone 54 from a plurality of discrete, spaced locations on opposite sides of the over-fire zone 54. Additionally, before the over-fire air enters the over-fire inlet(s) 70, the over-fire air flows within a heated air space defined by the furnace assembly 30 such that the over-fire air is pre-heated before entering the over-fire inlet(s) 70.
The under-fire air and over-fire air thus mix within the over-fire zone 54 to encourage continued burning of gasses and particulates rising from the combustion zone 50. However, as will be discussed in further detail below, the heating system 20 may operated in modes in which one or both of the under-fire air and the over-fire air are prevented from flowing along the over-fire and under-fire portions of the flow path 36; in such modes, the mixing of under-fire air and over-fire air will not occur within the over-fire zone 54.
After the under-fire air and/or over-fire air flow into the over-fire zone 54, the air and any entrained gasses and particulate material continue along the flow path 36 vertically upward out of a rear portion of the combustion chamber 40 into the burn-out chamber 42 through the burn-out port 80. The example burn-out port 80 is formed by two rectangular openings as perhaps best depicted in
After extending along the burn-out chamber, the example flow path 36 turns and extends vertically upwards again out of the burn-out chamber 42 and into the heat exchange chamber 44 through the heat exchange port 82. As perhaps best shown in
After passing through the heat exchange port 82, the example flow path 36 turns and extends horizontally again from a front portion (i.e., the heat exchange zone 56) of the heat exchange chamber 44 to a rear portion (i.e., the exhaust zone 58) of the heat exchange chamber 44. A significant portion of the heat energy carried by the air flowing through the heat exchange zone 56 is transferred to a working fluid within the heat transfer system 34 as will be described in further detail below. The air flowing along the flow path 36 into the exhaust zone 58 is significantly cooler and contains negligible gasses and particulates.
The parameters of the example heating system 20 are predetermined to maintain a temperature of the air within the exhaust zone within pre-determined parameters to avoid condensation. Avoiding condensation slightly reduces the efficiency of the heating system but avoids the production of condensate, which is slightly acidic and would require the use of corrosion resistant materials and a condensate drainage system.
Referring now to
The controller 122 may thus control volume of flow along the flow path 36 by controlling a speed of the fan 130. The controller 122 may also allow air to flow into the under-fire zone 52 along the under-fire portion of the flow path 36 and/or into the over-fire zone 54 along the over-fire portion of the flow path 36. By closing one or both of the dampers 132 and 134, the controller 122 may prevent air from flowing into the under-fire zone 52 along the under-fire portion of the flow path 36 and/or into the over-fire zone 54 along the over-fire portion of the flow path 36.
The example controller 122 is further operatively connected to first and second temperature sensors 140 and 142. The first temperature sensor 140 is arranged to measure a temperature of air and other gasses within the combustion chamber 40. The example first temperature sensor 140 is arranged at a juncture between the combustion zone 50 and the over-fire zone 54 of the combustion chamber 40. The second temperature sensor 142 is arranged to measure a temperature of the exhaust within the burn-out chamber 42. The example second temperature sensor 142 is arranged at adjacent to heat exchange port 82 and is spaced from the burn-out port 80.
In one configuration, the example controller 122 may be configured to control generation of heat by the heating system 20 by controlling the fan 130 and the dampers 132 and 134 based on a relationship between the temperatures sensed by the first and second temperature sensors 140 and 142.
The example controller 122 is further operatively connected to a third temperature sensor 144. The third temperature sensor 144 is arranged to measure a temperature of the exhaust within the exhaust zone of the heat exchange chamber 44. At this point, much of the heat energy is removed from the exhaust. The example first temperature sensor 140 is arranged adjacent to the exhaust port 84.
In another configuration, the example controller 122 may be configured to control generation of heat by the heating system 20 by controlling the fan 130 and the dampers 132 and 134 based on relationships among the temperatures sensed by the first, second, and third temperature sensors 140, 142, and 144.
The example controller 122 is further operatively connected to fourth and fifth temperature sensors 146 and 148. The fourth temperature sensor 146 is arranged to measure a temperature of the working fluid flowing to the load 24. The fifth temperature sensor 148 is arranged to measure a temperature of the working fluid flowing back from the load 24.
In another configuration, the example controller 122 may be configured to control generation of heat by the heating system 20 by controlling the fan 130 and the dampers 132 and 134 based on relationships among the temperatures sensed by the first, second, fourth, and fifth temperature sensors 140, 142, 146, and 148. In yet another configuration, the example controller 122 may be configured to control generation of heat by the heating system 20 by controlling the fan 130 and the dampers 132 and 134 based on relationships among the temperatures sensed by the first, second, third, fourth, and fifth temperature sensors 140-148.
The example controller 122 is further operatively connected to sixth and seventh temperature sensors 150 and 152. The sixth temperature sensor 150 is arranged to measure a temperature of a refractory wall portion of the furnace assembly 130. The seventh temperature sensor 152 is arranged to measure a temperature of the control board 120. In any of the configurations described herein, the example controller 122 may further be configured to control generation of heat by the heating system 20 based on the temperature sensed by either or both of the sixth and seventh temperature sensors 150 and 152.
The example controller 122 is further operatively connected to first and second temperature sensors 160 and 162. The first pressure sensor 160 is arranged to measure a pressure of the working fluid flowing to the load 24. The second pressure sensor 162 is arranged to measure a pressure of the working fluid flowing back from the load 24. In any of the configurations described above, the example controller 122 may further be configured to control generation of heat by the heating system 20 based on the pressure sensed by either or both of the first and second pressure sensors 160 and 162.
The example controller 122 is further operatively connected to a fan speed sensor 170. The fan speed sensor 170 is arranged to measure a rotational speed of the fan 130. In any of the configurations described above, the example controller 122 may further be configured to control generation of heat by the heating system 20 based on the fan speed sensed by fan speed sensor 170.
The example controller 122 is further operatively connected to an oxygen sensor 172. The oxygen sensor 172 is arranged to measure the oxygen content of the exhaust within the exhaust zone 58 of the heat exchange chamber 44. In any of the configurations described above, the example controller 122 may further be configured to control generation of heat by the heating system 20 based on the oxygen content sensed by oxygen sensor 170.
The computer 124 depicted in
Referring now to
The heat exchanger 220 defines a heat exchanger input 240 and a heat exchanger output 242. The heat exchanger input 240 is connected to an input manifold 244, while the heat exchanger output 242 is connected to an output manifold. A plurality of heat transfer pipes 250 are connected between the input manifold 244 and the output manifold 246. Baffles 252 are arranged within the manifolds 244 and 246 to encourage flow of fluid within the heat exchanger 220 that optimizes transfer of heat from air and gasses flowing around the heat exchanger 220 to working fluid flowing through the heat transfer pipes 250.
The circulation system 222 comprises a pump 260 and first and second ball valves 262 and 264. The ball valves 262 and 264 are normally open such that operation of the pump 260 causes working fluid to flow in a loop through the conditioning system 224 and the heat exchanger 220. The ball valves 262 and 264 may be closed to facilitate removal and replacement of components of the heat transfer system 26.
The conditioning system 224 comprises a load conduit 270, a bypass conduit 272, a mixing valve 274, a supply tee 276, and a return tee 278. The supply tee 276 and return tee 278 are connected in series along the load conduit 270, and the bypass conduit 272 is connected in parallel with the supply tee 276 and a return tee 278. The mixing valve 274 is connected to a downstream junction between the load conduit 270 and bypass conduit 272. The supply tee 276 is connected to the supply conduit 230, and the return tee 278 is connected to the return conduit 232.
During normal operation of the heat transfer system 34, operation of the pump causes working fluid to flow through the heat exchanger input 240, into the input manifold 244, through the heat transfer pipes 250, into the output manifold 246, out of the heat exchanger output 242, through the load and bypass conduits 270 and 272, through the mixing valve 274, and back to the pump 260. The heat transfer system 34 thus defines a heat transfer loop that flows through the heat exchanger 220, the conditioning system 224, and the circulation system 222.
The load 24 contains a load circulation pump (not shown) that causes the working fluid to flow in a load loop from the load conduit 270, through the supply conduit 230, through the load 24, and back through the return conduit 232 into the load conduit 270.
When the heat transfer system 34 is connected to the load 24, the working fluid thus flows through two loops that are connected within the load conduit 270 between the supply tee 276 and the return tee 274. The working fluid in the heat transfer loop thus mixes with the working fluid in the load loop between the supply and return tees 276 and 278 to transfer heat from the heat transfer loop to the load loop.
As mentioned above, the construction and operation of the load 24 are unknown. The conditioning system 224 is configured to allow the heat transfer system 34 substantially to isolate the flow of fluid within the heat exchanger 220 and the circulation system 222 of the heat transfer system 34 from fluctuations in heat and pressure in the working fluid flowing through the load loop.
Referring for a moment back to the heat dump system 226 as depicted in
Referring now for a moment to
Referring to
In addition, the over-fire air first flows along the rear air gap 346 before entering the over-fire inlet(s) 70. Because the rear air gap 346 and over-fire channel(s) are adjacent to the refractory structure 328, radiant heat from the refractory structure 328 warms air within the rear air gap 346 and the over-fire channel(s) 72, thus preheating the over-fire air before the over-fire air enters the over-fire zone 54 of the combustion chamber 40.
The air containment structure 324 comprises a grate box 350 (
The refractory structure 328 is formed by a support plate 360 (
As best shown in
As best shown in
The refractory side walls 366 are supported such that the over-fire channels 72 formed therein are substantially aligned with the over-fire inlets 70 formed in the rear wall 352 of the air containment structure 324.
The example air containment structure 324 is assembled such that, during normal operation of the heating system 20 (with the door assembly 332 closed as shown in
The components of the example refractory structure 328 are made of refractory materials such as ceramics and/or vermiculite capable of maintaining the shapes of these components under the range of temperatures expected during normal operation of the heating system 20.
The insulation layers 322 and 326 are configured to inhibit the transfer of heat from the combustion chamber 40 to the exposed surfaces of the housing structure 320 such that these exposed surfaces do not present a burn or fire hazard during normal operation of the heating system 20.
The housing structure 320 is made of rigid materials assembled to support the weight of the biofuel 22, the air containment structure 324, the refractory structure 326, the heat transfer system 34, and any working fluid within the heat transfer system 34.
With the foregoing understanding of the furnace assembly 30 and heat transfer system 34, the following Table A describes in further detail the various sensors that may be used by the example control system 32.
The example biofuel heating system 20 operates in any one of a number of normal operating modes depending upon the state of the heating system 20, the state of the biofuel 22 within the heating system 20, the state of the heat transfer system 34, and the state of the load 24. In particular, the software control program running on the controller 122 operates in any one of a plurality of operating modes depending upon the various inputs to the control system 32.
The following tables describe, for each of a plurality of normal operating modes, the condition that triggers the control program to operate in any one of the normal operating modes, the states of the fan 130, under-fire damper 132, and over-fire damper 134 in these operating modes, and the control variables (sensor signals) used by control program running on the controller 122 when operating in the operating modes.
The purpose of the cold start mode is to reduce the time required to achieve the set point temperature when the temperature within the combustion chamber is below a predetermined start threshold value. In particular, the conditions within the furnace assembly 30 when the temperature within the combustion chamber is below the predetermined start threshold value require the biofuel 22 within the combustion chamber 40 to be reignited. To reduce the time required to achieve the set point temperature, the operating parameters of the control system 32 may be set such that the burn obtained in the cold start mode may be less clean than the burn obtained in other modes of operation as will be described below.
The purpose of the hot start mode is to reduce the time required to achieve the set point temperature yet maintain a clean burn. In particular, when the temperature within the combustion chamber is above the predetermined start threshold value, the conditions within the furnace assembly 30 allow the temperature of the working fluid within the supply conduit 230 to be quickly brought to the set point temperature while the control system 32 uses operating parameters conducive to a clean burn.
When new biofuel 22 such as firewood is initially introduced into the combustion chamber 40, the biofuel is exposed to high temperatures in the absence of significant quantities of oxygen (pyrolysis). During pyrolysis, the newly introduced biofuel produces gas, liquid, and/or particulate byproducts. After the newly introduced biofuel under goes pyrolysis for a sufficient period of time, however, the elimination of the gas and liquid byproducts transforms the biofuel into a solid residue rich in carbon content. At this point, the biofuel may be burned more efficiently for a longer period of time. The example heating system 20 thus operates in the steady state pre-char mode to eliminate gas and liquid byproducts from the biofuel 22.
After the example heating system 20 operates in the steady-state pre-char mode for a sufficient length of time, the trigger condition associated with steady state char mode is met (cross-over state), indicating that gas and liquid byproducts of the biofuel have been eliminated. When the cross-over state is achieved, the heating system 20 enters the steady state char mode for as long as sufficient biofuel 22 remains within the combustion chamber 40.
When the supply of biofuel 22 within the combustion chamber 40 begins to become depleted, the heating system 20 enters the steady state fuel out mode. In the steady state fuel out mode, the operating parameters of the heating system 20 are adjusted to extend the life of the remaining biofuel 22, possibly at the expense of reduced set point temperature.
The user may cause the biofuel heating system 20 to enter the load mode by pressing the load button 180 on the control panel 124. By actuating the load button 180, the user causes to the control system 32 to load mode initiates either the cold start mode or the hot start mode as described above. In the load mode, the heating system 20 is configured to receive a fresh load of the biofuel 22. The load status lights 182 indicate whether additional biofuel 22 may be placed within the combustion chamber 40.
The user may cause the biofuel heating system 20 to enter the door open mode by pressing the door open button 184. In the door open mode, the fan 130 and dampers 132 and 134 are operated substantially to prevent any smoke within the combustion chamber 40 from being drawn out of the furnace assembly 30 when the door assembly 332 is opened. The door open status lights 184 confirm to the user when the door assembly 332 may be opened.
In the various operating modes described above, the example control system 32 controls the under-fire damper 132 and the over-fire damper 134 in either an open (ON) or closed (OFF) configuration. In another form, the control system 32 may, however, be configured to control the dampers 132 and 134 in states between open and closed. The example control system 32 controls the rotational speed of the fan 130 based on a fan control program that implements a second-order differential equation predetermined for the particular configuration of the heating system 20. The fan control program thus regulates the fan speed and the rate of change of fan speed based the control variables listed for each of the various operating modes described above.
In addition to the normal operating modes described above, the example biofuel heating system 20 operates in any one of a number of fault modes depending upon the state of the heating system 20, the state of the heat transfer system 34, and the state of the load 24. The example system status lights 192 indicate whether the heating system is operating normally (NORMAL light energized), whether any of the sensors indicate a potential fault condition (WARNING light energized), or whether any of the sensor indicate a fault condition (ERROR light energized). When one or both of the WARNING light and the ERROR light are energized, the MODE lights indicate which of a plurality of predetermined fault conditions are present detected by the control system 32.
The following Table I contains a list of possible fault or error conditions that may be detected by the example control system 32 and the system parameter(s) associated with each of these error conditions. This list of Error Condition is an example only, and other Error Conditions may be detected by the control system 32. In addition to Error Conditions, the control system 32 may be configured to provide warnings of possible future Error Conditions so that proactive measure may be taken to avoid such possible future Error Conditions.
The precise shape, dimensions, and materials selected to form the example heating system 20 depend on the particular set of operating conditions and/or cost limitations for which the heating system 20 is designed. The example furnace assembly 30 is generally rectangular in shape and defines a substantially rectangular combustion chamber 40. The furnace assembly 30, and in particular the combustion chamber 40, may take other shapes and still perform the functions described above. For example, the combustion chamber 40 may be made oval or round and still perform the functions described above. In addition, the aspect ratio of the example furnace assembly 30 is relatively even, but tall and thin or short and wide aspect ratios may be used depending on the particular installation requirements of a particular biofuel heating system.
The example burn-out chamber 42 and the example heat exchange chamber 44 are rectangular with a short wide aspect ratios, but other shapes and aspect ratios may be employed.
The size, shape, and aspect ratios of the chambers 40, 42, and 44 will generally determine the size, shape, and aspect ratio of the overall housing structure 320, but it is possible, for example, to employ a round or oval combustion chamber 40, rectangular burn-out and heat exchange chambers 42 and 44, while providing a generally rectangular housing structure 320.
In this context, the Applicant has determined that, for an example set of operating conditions and cost limitations, the following Table J contains a set of physical characteristics suitable for implementing the principles of the present invention.
Given the foregoing, it should be apparent that the present invention may be embodied in forms other than those described above. The scope of the present invention should be determined by the claims appended hereto and not the following descriptions of examples of the invention.
This application, U.S. patent application Ser. No. 13/205,503 filed Aug. 8, 2011, claims benefit of U.S. Provisional Application Ser. No. 61/371,288, filed on Aug. 6, 2010. The contents of any related application listed in this section are incorporated herein by reference.
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