The present disclosure generally relates to fuel cells. More specifically, the disclosure relates to thermal management of waste heat in fuel cells.
Fuel cells are electrochemical devices that can be used in a wide range of applications, including transportation, material handling, stationary, and portable power applications. Fuel cells use fuel and air to generate electricity by electrochemical reactions and release reaction products as exhaust. For example, the byproducts generated by methanol fuel cells are water vapor and carbon dioxide. In addition to electricity, some energy in the fuels is released as heat.
A cooling subsystem containing a heat exchanger attached to a fuel cell stack can help to dissipate some of the waste heat to prevent overheating of the fuel cell system. A large amount of waste heat that is generated during the operation of a typical high temperature polymer electrolyte membrane (HT-PEM) fuel cell is dissipated, requiring a significant amount of space and power to implement an air-cooled system. Recovering this waste heat can substantially improve the efficiency of a fuel cell and reduce the thermal load on existing cooling components.
In accordance with an embodiment, a cooling subsystem for a fuel cell system having a fuel cell stack is provided. The cooling subsystem includes an evaporator, a turbo generator, a condenser, and a pump. The evaporator is configured to receive working fluid heated by waste heat generated by the fuel cell stack. The evaporator is also configured to further heat the working fluid using the waste heat. The turbo generator is downstream of and configured to receive heated working fluid from the evaporator. The turbo generator is configured to generate electrical power from the heated working fluid. The working fluid that leaves the turbo generator has a lower temperature and a lower pressure than that of the heated working fluid received from the evaporator. The condenser is downstream of and configured to receive working fluid from the turbo generator and condense the working fluid to a liquid. The pump is downstream of and configured to receive the liquid from the condenser and raise the pressure of the liquid before pumping the liquid into the evaporator.
In accordance with another embodiment, a method is provided for recycling waste heat generated by a fuel cell stack. A closed loop cooling system is provided. The cooling system includes an evaporator, a turbo generator, a condenser, and a pump. A fuel cell stack is operated. Waste heat from the fuel cell stack is captured in working fluid and the working fluid is evaporated. The evaporated working fluid is fed to a turbo generator to produce electric power.
In accordance with yet another embodiment, a method is provided for generating electrical power using a cooling subsystem of a fuel cell assembly. A fluid in a condensed phase is pressurized and the fluid is evaporated in an evaporator. The fluid is then fed from the evaporator into an expansion turbine configured to provide rotary motion to drive an electric generator to produce electric power.
The invention, together with further objects and advantages thereof, may best be understood by reference to the following description taken in conjunction with the accompanying drawings in which:
The present invention relates generally to fuel cell systems. Embodiments of cooling subsystems of a fuel cell assembly are described herein. Like all powerplants, fuel cell systems must be cooled in order to operate. If fuel cell stacks are not cooled, then heat from inefficiencies in the fuel cell stack will cause temperatures to rise until damage occurs. As HT-PEM fuel cells generate substantial waste heat, recovering the waste heat can substantially improve the efficiency of a fuel cell and also reduce the thermal load on the cooling subsystem.
In embodiments described herein as examples, a HT-PEM fuel cell operates at a temperature in the range of about 160° C.-240° C. The fuel cell has a theoretical open circuit (Voc) of about 1.15V/cell and an operating voltage of roughly 0.6V/cell (Vcell). Those skilled in the art will understand that the power generation for the fuel cell stack is: Power(W)=0.6V×#cells×Current (I), while rejected heat Qstack(W)=(Voc−Vcell)×I. Therefore, the fuel cell power can be normalized to Vcell×I and stack heat can be normalized to (Voc−Vcell)×I.
For exemplary purposes, a fuel cell stack generating 1,000 W (or 1.0 kW) of heat is presented. The total electrical duty (W) of the fuel cell stack is heat plus power. Using the ratios above, the calculations below can be made:
Power=0.6×Duty
Heat=(1.15−0.6)/1.15×Duty=0.478×Duty
1,000 W=0.478×Duty
Duty=1,000/0.478=2091 W
FCPower=Duty−Heat=2091−1000=1091 W
Generator Power˜Q stack×20%
A simple electrical efficiency calculation shows that efficiency of the fuel cell is Power/Duty: 1091 W/2091 W=52.2%, which is exactly the same as Vcell/Voc.
In embodiments described herein, by adding a turbo generator 300 (
Embodiments described herein provide the ability for a fuel cell to run at very high power levels (i.e., to run the fuel cell at its peak power point of ˜0.45V/cell without a drop in overall net efficiency). When running the fuel cell at 0.45V/cell, it produces its peak power but at lower efficiency as discussed above. However, by adding a turbo generator 300, the waste heat generated by the fuel cell can be captured and used to generate additional power. The fuel cell system described above can be modified as follows:
The addition of the turbo generator 300 increases nominal efficiency from 52.2% to 61.7% (and reduced fuel consumption by 19%) and efficiency at peak power from 39.1% to 51.3% (and reduced fuel consumption by 31%.
Because the turbo generator fuel cell system retains good efficiency at lower cell voltages, there is additional design flexibility. For example, those skilled in the art will understand that running a fuel cell at lower voltages yields a smaller fuel cell. However, this smaller and cheaper fuel cell has lower efficiency and hence leads to higher fuel consumption rates. The total cost of ownership is a combination of the fuel cell capital cost and the fuel usage. Therefore, fuel cell manufacturers tend to specify that peak power is only available for short bursts of time (such as accelerating a vehicle.) With the turbo generator fuel cell described herein, the fuel cell retains good efficiency even under lower cell voltages, and the cost and size of this fuel cell will be lower than existing systems, and will have higher efficiency.
Fuel cells are most often paired with a hybrid battery. The hybrid battery is sized to start up the fuel cell and provide power that is greater than what the fuel cell can deliver at any given time in the product duty cycle. If the fuel cell can deliver more power efficiently, then the battery can be made correspondingly smaller and cheaper.
Applications such as vehicle propulsion, stationary power, shipboard and aviation propulsion, and auxiliary power modules can benefit from the embodiments described herein. Described embodiments are suitable for fuel cell systems above 1 kW net power level due to the difficulty in manufacturing turbo generators below that power level. However, small turbines can be used to allow for lower power level usage.
In embodiments described herein, the Rankine Cycle, which is a thermodynamic cycle that converts heat into work, is integrated with a HT-PEMFC to recover waste heat in a fuel cell. The addition of a turbogenerator 300 to the closed fuel cell cooling subsystem loop allows for waste heat recovery.
The Rankine cycle utilizes the potential energy of a thermally pressurized fluid to generate electrical power. The fundamentals of the cycle are relatively straightforward. A fluid in the condensed phase is pressurized to a specific value, evaporated in a boiler or evaporator, and then is fed to an expansion turbine which in turn provides rotary motion to an electric generator from which useful electrical power is obtained. The fluid leaves the turbine as a lower pressured vapor, and is then condensed back to a fluid and pumped back to the evaporator to repeat the process. The theoretical maximum efficiency that can be obtained from this process is given by the Carnot efficiency, expressed by Equation (1) below:
where TH and TC respectively are the operating temperatures of the evaporator and condenser in units of Kelvin. From Equation (1), the dependence of the amount of energy that can be recovered on these temperatures is made clear, as is why the lower operating temperature of a PBI fuel cell is a limiting factor that is overcome substantially by the ion-pair membrane electrode assembly (MEA). As an illustrative example, substituting the typical operating range of a PBI fuel cell (165° C., 438.15K) and an ion-pair MEA (200° C., 473.15K) as TH, and the typical room temperature boiling point of water (100° C., 373K) as TC, ηCarnot comes out to be about 14.8% for PBI and 21.2% for the ion-pair MEA at these conditions, an increase in potential recovery of 6.4%. The Carnot efficiency assumes adiabatic operation, which provides a theoretical upper bound on the performance of any real system. Thermal energy recovery of 12-15% is a more realistic figure, which can possibly be further improved with the addition of regeneration cycles, or reducing the operating pressure of the condenser to slightly below ambient conditions. A preliminary simulation has been conducted utilizing DWSIM, an open-source chemical process simulation software, to provide further illustration and insight.
The simulation below assumes 1 kW of heat is generated from the fuel cell stack. Given a theoretical OCV of 1.15V (computed by Gibbs free energy calculations), an operating voltage of 0.6V and a target current density of 0.8 A/cm2 with the ion-pair MEA, 1 kW of heat rejection equates to about 1080 W of electricity generated for a 45 cm2 MEA, shown from a simple energy balance (Equation 2):
Q
rejected=(VOCV−VOp)i (2)
where VOCV, Vop, and i are the theoretical open circuit voltage, the operating voltage, and the load current, respectively.
As shown in
The working fluid then flows from the evaporator 200 into the turbogenerator or turbine 300. The turbo generator 300 generates electrical power from the heated working fluid, which is heated into a vapor (or steam in the case of water as the working fluid). As the vapor expands through turbine blades, it does mechanical work. In an embodiment, the turbo generator 300 is an expansion turbine, which provides rotary motion to drive an electric generator from which useful electrical power is obtained. The expansion of the vapor causes the vapor to lose pressure. Thus, when the working fluid leaves the turbo generator 300, it has a lower temperature and a lower pressure compared to when it entered the turbo generator 300.
The working fluid then flows into a condenser 400 downstream of the turbo generator 300 where it condenses the working fluid to a liquid. A pump 500 receives the condensed liquid from the condenser 400 and raises the pressure of the liquid before pumping the liquid back into heat exchanger 1 to capture more waste heat from the fuel cell stack 10 before it enters the evaporator 200.
It will be noted that in
A table providing the thermodynamic parameters of each stream in greater detail is provided below.
In step 440, the working fluid from the heat exchanger is evaporated into a vapor, which is then fed into to a turbo generator to produce electric power in Step 450. evaporated working fluid exiting the turbo generator is condensed into a liquid in Step 460. The liquid is then pressurized and then pumped back into the evaporator in Step 470.
In view of the foregoing, it should be apparent that the present embodiments are illustrative and not restrictive and the invention is not limited to the details given herein but may be modified within the scope and equivalents of the appended claims.
This application claims the benefit of U.S. Provisional Application No. 63/418,376, filed on Oct. 21, 2022. The foregoing application is hereby incorporated by reference herein for all purposes.
Number | Date | Country | |
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63418376 | Oct 2022 | US |