This invention is generally directed to power generation systems, and more particularly to combustion engine-fuel cell systems that include recirculation cycles which can improve the overall efficiency of power generation.
Fuel cells are electrochemical energy conversion devices that have demonstrated a potential for relatively high efficiency and low pollution in power generation. A fuel cell generally provides a direct current (dc) which may be converted to alternating current (ac) via, for example, an inverter. The dc or ac voltage can be used to power motors, lights, and any number of electrical devices and systems. Fuel cells may operate in stationary, semi-stationary, or portable applications.
Certain fuel cells, such as solid oxide fuel cells (SOFCs), may operate in large-scale power systems that provide electricity to satisfy industrial and municipal needs. Others may be useful for smaller portable applications such as for example, powering cars. Common types of fuel cells include phosphoric acid (PAFC), molten carbonate (MCFC), proton exchange membrane (PEMFC), and solid oxide (SOFC), all generally named after their electrolytes.
In practice, fuel cells are typically amassed in electrical series, in an assembly of fuel cells to produce power at useful voltages or currents. Therefore, interconnect structures may be used to connect or couple adjacent fuel cells in series or parallel. In general, components of a fuel cell include the electrolyte and two electrodes. The reactions that produce electricity generally take place at the electrodes where a catalyst is typically disposed to speed the reactions. The electrodes may be constructed as channels, porous layers, and the like, to increase the surface area for the chemical reactions to occur. The electrolyte carries electrically charged particles from one electrode to the other and is otherwise substantially impermeable to both fuel and oxidant.
The opportunity for a power generation system that can benefit greatly from the integration of a fuel cell and a combustion apparatus derives in large part from the electrochemistry of the fuel cell. Typically, the fuel cell converts hydrogen (fuel) and oxygen (oxidant) into water (byproduct) to produce electricity. The byproduct water may exit the fuel cell as steam in high-temperature operations.
The discharged steam (and other hot exhaust components) from the fuel cell may be utilized in turbines and other applications to generate additional electricity or power, providing increased efficiency of power generation. If air is employed as the oxidant, the nitrogen in the air is substantially inert and typically passes through the fuel cell. Hydrogen fuel may be provided via local reforming (e.g., on-site steam reforming) of carbon-based feedstocks, such as reforming of the more readily available natural gas and other hydrocarbon fuels and feedstocks. Examples of hydrocarbon fuels include natural gas, methane, ethane, propane, methanol, syngas, and other hydrocarbons.
The reforming of hydrocarbon fuel to produce hydrogen to feed the electrochemical reaction may be incorporated into the operation of the fuel cell. Moreover, such reforming may occur internal and/or external to the fuel cell. For reforming of hydrocarbons performed external to the fuel cell, the associated external reformer may be positioned remote from or adjacent to the fuel cell.
Fuel cell systems that can reform hydrocarbon internal and/or adjacent to the fuel cell may offer advantages, as described below. For example, the steam reforming reaction of hydrocarbons is typically endothermic, and therefore, internal reforming within the fuel cell or external reforming in an adjacent reformer may utilize the heat generated by the typically exothermic electrochemical reactions of the fuel cell. Furthermore, catalysts active in the electrochemical reaction of hydrogen and oxygen within the fuel cell to produce electricity may also facilitate internal reforming of hydrocarbon fuels. In SOFCs, for example, if a nickel catalyst is disposed at an electrode (e.g., an anode) to sustain the electrochemical reaction, the active nickel catalyst may also reform hydrocarbon fuel into hydrogen and carbon monoxide (CO). Moreover, both hydrogen and CO may be produced when reforming hydrocarbon feedstock. Thus, fuel cells, such as SOFCs that can utilize CO as fuel (in addition to hydrogen) are generally more attractive candidates for utilizing reformed hydrocarbon, and for internal and/or adjacent reforming of hydrocarbon fuel.
As described previously, the exhaust components from fuel cells that operate at high temperatures can be directed to turbines and other types of engines, as part of a general combined cycle system. While such a system can be an attractive method for power generation, there are still some drawbacks present, that can prevent wide-scale implementation. For example, the relatively low conversion efficiency of the fuel cell component can still diminish the value of the system. Some of the present day examples of fuel cells routinely achieve a conversion efficiency that is only about 50%.
It should thus be apparent that combined-cycle, power generation systems that incorporate fuel cells in a way that provides greater efficiency would be welcome in the art.
One embodiment of the invention is directed to a power generation system utilizing a fuel cell, comprising
a) a fuel cell that includes an anode configured to generate a tail gas, wherein the anode comprises an inlet and an outlet;
b) a fuel path configured to divert a first portion of the anode tail gas to the inlet of the anode; and a second portion of the anode tail gas to a reciprocating engine; and
c) a reciprocating engine that is at least partially powered by the second portion of the anode tail gas.
Another embodiment of the invention is directed to a power generation system, comprising:
a solid-oxide fuel cell that includes an anode configured to generate a tail gas, the anode comprising an inlet and an outlet;
at least one external fuel reforming system, configured to mix a hydrocarbon fuel with the fuel cell tail gas downstream of the fuel cell, and to partly or fully convert the hydrocarbon fuel into a reformed fuel mixture comprising hydrogen (H2) and carbon monoxide (CO);
a gas splitting mechanism configured to divide the reformed fuel mixture into two streams, each with substantially the same composition;
means for directing one of the reformed fuel mixture streams back to the inlet of the anode; and
an external or internal combustion engine that is capable of at least partly being powered by the other reformed fuel mixture stream.
The foregoing and other features, aspects and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
In some embodiments, fuel cell 4 includes an internal reformer. The reformer is depicted simply as feature 8 in
With continued reference to
The reforming action of the fuel cell partially or fully converts the fuel into a mixture comprising hydrogen (H2) and carbon monoxide (CO). These gases exit the anode of the fuel cell through any suitable pathway 52, and constitute at least a portion of the anode exhaust, often referred to as the anode “tail gas”. Those skilled in the art understand that electricity is also produced in the fuel cell reaction, and routed out of the fuel cell through an appropriate electrical circuit (not specifically shown here). Water is another byproduct, in steam- or liquid form. Thus, the anode exhaust may also include various other components in addition to hydrogen and carbon monoxide, such as water, steam, and carbon dioxide. While various factors might affect its composition, the anode exhaust is usually comprised of at least about 10% by volume of carbon monoxide and hydrogen, and in some embodiments, at least about 20% of carbon monoxide and hydrogen, e.g., up to about 40%.
As shown in
In most embodiments, first portion 54 is directed to a reciprocating engine 60, sometimes referred to as a “gas reciprocating engine” or a piston engine. Various types of reciprocating engines can be used, and most fall into three main categories: internal combustion engines, steam engines, and Stirling engines. Some non-limiting, specific examples include reciprocating 4-stroke engines, reciprocating 2-stroke engines, and opposed piston 2-stroke engines. (Power generation regions which rely in part on excess heat from an overall system are sometimes referred to as “bottoming cycles”, as mentioned below for other embodiments).
In some particular embodiments, internal combustion engines like the Jenbacher and Waukesha types are preferred. In addition to being supplied by anode exhaust portion 54, these types of engines can very efficiently operate on a variety of other, optional fuels, in addition to the traditional hydrocarbons like methane. Other fuel types include landfill gas, coal gas, bio-derived fuels, and the like. (The intake mechanism for the additional fuel is conventional, and not specifically depicted in
Reciprocating engine 60 may be employed in a number of functions. The engine may be used to perform conventional, mechanical work, e.g., by way of conventional mechanical motion. Alternatively (or in addition to that function), the engine may specifically serve to power generator 62, as depicted in
With continued reference to
As mentioned previously, the anode exhaust contains hydrogen and carbon monoxide. Recirculation of the hydrogen component to fuel cell 4 can enhance its efficiency considerably. Thus, the recirculation of the anode exhaust represents a second cycle in the power generation, i.e., in addition to the engine-based cycle fed by first anode exhaust portion 54.
Moreover, in most preferred embodiments, at least about 50 volume % of the total anode exhaust is recirculated to the anode, with most of all of the remainder (first portion 54) being directed to the reciprocating engine. In some preferred embodiments, at least about 75 volume % of the total anode exhaust is recirculated to the anode, and in some instances, the level is greater than about 85 volume %.
For the embodiment of
In this embodiment, the reformed fuel stream moving along pathway 102 is split into a first portion 104 and a second portion 106, at junction 108. Thus, a fraction 104 of the reformed fuel stream is diverted to the inlet of the fuel cell anode 13 via any suitable means, e.g., a return path/conduit 17. The combination of incoming fuel with at least a portion of the anode exhaust gas is an important feature for some embodiments. It contrasts with some systems in the art, wherein incoming fuel was combined only with water or steam present in a fuel cell/power plant system. The combination of fuel with the anode gas occurring prior to external reforming (and thus, prior to that exhaust gas splitting) represents another important feature for some embodiments.
The residual fraction of the reformed fuel stream is employed to drive an external or internal combustion engine 16. As described previously, engine 16 may comprise, for example, a reciprocating 4-stroke, reciprocating 2-stroke, or an opposed piston 2-stroke engine. The engine may also be any type of gas turbine.
In some (though not all) preferred embodiments, a recuperator 110, or another type of heat exchanger, is used to transfer heat that originates in the fuel cell, to the incoming fuel stream 11 (sometimes referred to herein as “fresh fuel”), prior to entry of the anode exhaust and the fuel 11 into reformer 14. Additionally, any type of suitable cooler 18 can be used to bring down the temperature of the reformed fuel (second portion 106 in
Thus, it should be emphasized that in some preferred embodiments for this type of configuration, using an external reformer, “fresh fuel”, as mentioned below, is added to the system, after the fuel cell stage, and before the reforming stage. After reforming, the recirculated gas (now containing both the anode exhaust and the reformed fuel) may contain at least about 35% by volume of hydrogen and carbon monoxide, e.g., about 40-45%. At least a portion of this gaseous mixture is recirculated back to the anode inlet.
In this embodiment, two reformers 120 and 122 are employed, as shown in the figure. The heat from the cathode 6 of the fuel cell is directed through a suitable conduit to reformer 120 (see the heat arrow generally depicted as element 100), and can assist in promoting a reforming reaction. Another portion of the anode exhaust is directed to reformer 122, which also promotes the reforming reaction. As compared to the single-reformer embodiment of
As in the previous embodiment, the reformed stream exiting reformer 122 is split into a first portion 104 and a second portion 106, at splitting junction 108. Portion 106 can be used to, completely or partially, power engine 16, as in the previous embodiment. Moreover, the system may optionally include recuperator 110 and cooler 18. It should also be noted that in some embodiments, reformers 120 and 122 can effectively be combined.
In this embodiment, the first portion 104 of the reformed stream is directed back to reformer 120, as shown in
With continued reference to
With continued reference to
According to one embodiment related to
The combined cycle power plant 30 further employs a recuperator 38 in many of these embodiments, as shown in
In contrast, for some of the embodiments of this invention (e.g., see
The combined cycle power plant 30 (e.g.,
Some fraction of the reformed fuel stream is diverted to the inlet of the fuel cell anode 13, via a return path 17. The residual fraction of the reformed fuel stream is employed to drive an external or internal combustion engine, as described above, subsequent to cooling. The cooling step can be carried out by way of the transfer of heat within a high temperature recuperator 9 to the incoming fuel stream 11, and then by means of a suitable cooler 18, and a low temperature fan 19.
With continued referenced to
For many of the embodiments described herein, an overall fuel utilization that is higher than 65% has been achieved, by recirculating flow from the anode exhaust back to the anode inlet. Furthermore, by including the reforming step in a recirculation loop, the reformer water requirements can be met using only the water contained in the anode exhaust flow, without having to introduce additional water to the overall system.
Moreover, the embodiments described herein, (i.e., those that use an external reformer), advantageously implement reforming downstream of the fuel cell anode 13. Because the reforming step occurs at a point between the fuel cell 12 exhaust and the bottoming cycle fuel inlet, some of the reformed fuel may be fed directly to the bottoming cycle. The reformer 14 (e.g.,
Moreover, as mentioned previously, some of the embodiments described herein advantageously employ a reciprocating gas engine as a bottoming cycle. Since reciprocating gas engines are traditionally more fuel-flexible than gas turbines, for example, they allow for more flexibility in the design of the reformer 14 than would be possible if a gas turbine were to be used as the bottoming cycle.
As a general summary, it should be noted that combined cycle fuel cell embodiments and their attendant advantages have been described herein. These embodiments each comprise a fuel cell (e.g., an SOFC) comprising an anode that generates a tail gas. Some of the variations involve the use of internal reforming, while others rely on the presence of an external reformer. In regard to the latter, a hydrocarbon fuel reforming system mixes a hydrocarbon fuel with the fuel cell tail-gas downstream of the fuel cell unit, so as to partly or fully convert the hydrocarbon fuel into hydrogen (H2) and carbon monoxide (CO). The reformed fuel is split into a first portion and a residual portion. A fuel path diverts the first portion of the reformed fuel to the inlet of the fuel cell anode. A cooling system such as a cooler or cooler/low-temperature fan combination is optionally configured to remove heat from the residual portion of the reformed fuel and to deliver the cooled residual portion of the reformed fuel to a bottoming cycle. The bottoming cycle can include a reciprocating gas engine that is driven in response to the cooled residual portion of the reformed fuel.
It should also be clear from this description that another embodiment of this invention is directed to a method for power generation, in which fuel is directed into a fuel cell to provide one source of electrical energy. The exhaust (reformed fuel) from the fuel cell is directed to any type of splitting device, for division into two portions. One portion of the exhaust is used to provide additional fuel for the fuel cell. Another portion of the exhaust is used to drive various types of engines or engine-generator sets, and can thereby provide another source of electrical energy.
The present invention has been described in terms of some specific embodiments. They are intended for illustration only, and should not be construed as being limiting in any way. Thus, it should be understood that modifications can be made thereto, which are within the scope of the invention and the appended claims. Furthermore, all of the patents, patent applications, articles, and texts which are mentioned above are incorporated herein by reference.
This Application is a Continuation-in-Part of U.S. application Ser. No. 13/077,066, filed on Mar. 31, 2011, which is herein incorporated in its entirety by reference.
Number | Date | Country | |
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Parent | 13077066 | Mar 2011 | US |
Child | 13722370 | US |