SOLID OXIDE FUEL CELL MODULAR HYBRID POWERTRAIN FOR SMALL UNMANNED AIRCRAFT SYSTEM (UAS)

Abstract

A hybrid power system for an unmanned aerial system (UAS) having a liquid fuel engine and a solid oxide fuel cell coupled to the exhaust of the engine for generating electricity that is used by the electric motors of the UAS to create lift and control flight. A conventional remote control (r/c) liquid fuel engine may be used generate exhaust gases including hydrogen and carbon monoxide that are used by a SOFC coupled to the exhaust of the r/c engine to generate electricity. The electric motors of the UAS may thus be powered by the electricity generated by the SOFC.

Claims

1. A hybrid powertrain for an unmanned aerial system, comprising: a liquid fueled engine having an exhaust that can expel hydrogen and carbon monoxide; a solid oxide fuel cell coupled to the exhaust of the engine and configured to generate electricity using the hydrogen and carbon monoxide; and at least one electric motor coupled to the solid oxide fuel cell and powering the unmanned aerial system.

2. The powertrain of claim 1, further comprising an electrical generator coupled to a shaft of the liquid fueled engine.

3. The powertrain of claim 2, further comprising a battery interconnected between the solid oxide fuel cell and the at least one electric motor.

4. The powertrain of claim 3, wherein the solid oxide fuel cell comprises a micro-tubular flame-assisted fuel cell.

5. The powertrain of claim 4, wherein the micro-tubular flame-assisted fuel cell comprises a plurality of micro-tubular fuel cells coupled to the exhaust.

6. The powertrain of claim 5, wherein each of the plurality of micro-tubular fuel cells comprises a tubular anode surrounded by an electrolyte and a catalyst.

7. The powertrain of claim 6, further comprising a liquid fuel source coupled to the liquid fueled engine.

8. The powertrain of claim 7, wherein the liquid fuel source comprises a mixture of nitromethane and methanol.

9. The powertrain of claim 8, wherein the mixture comprise 30 percent nitromethane and 70 percent methanol.

10. A method of delivering power to an unmanned aerial system, comprising the steps of: providing a hybrid powertrain having a liquid fueled engine and an exhaust, a solid oxide fuel cell coupled to the exhaust of the engine, and at least one electric motor coupled to the solid oxide fuel cell; operating the liquid fueled engine to produce an exhaust including hydrogen and carbon monoxide; delivering the exhaust to the solid oxide fuel cell such that electricity is generated by the solid oxide fuel cell; and powering at least one electric motor using the electricity generated by the solid oxide fuel cell.

11. The method of claim 10, wherein the hybrid powertrain further includes an electrical generator coupled to a shaft of the liquid fueled engine.

12. The method of claim 11, further comprising a battery interconnected between the solid oxide fuel cell and the at least one electric motor.

13. The method of claim 12, wherein the solid oxide fuel cell is a micro-tubular flame-assisted fuel cell.

14. The method of claim 13, further comprising the step of delivering a liquid fuel to the liquid fueled engine.

15. The method of claim 14, wherein the liquid fuel comprises a mixture of nitromethane and methanol.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

[0006] The present invention will be more fully understood and appreciated by reading the following Detailed Description in conjunction with the accompanying drawings, in which:

[0007] FIG. 1 is a schematic of a hybrid power system for an unmanned aerial system according to the present invention;

[0008] FIG. 2 is a schematic of a micro-tubular Flame-assisted Fuel Cell (FFC) for use in the present invention;

[0009] FIG. 3 is a pair of graphs of solid oxide fuel cell performance and thermal cycling curves;

[0010] FIG. 4 is a graph of CEA adiabatic flame temperatures; and

[0011] FIG. 5 is a graph of SOFC performance in engine exhaust.

DETAILED DESCRIPTION OF THE INVENTION

[0012] Referring to the figures, wherein like numeral refer to like parts throughout, there is seen in FIG. 1 a hybrid power train system 10 that can be implemented onto a UAS. The UAS may have fixed wing or multi-rotor under 20 lb. The hybrid power train system may comprise a traditional r/c engine 12 and a solid oxide fuel cell (SOFC) stack 14, as well as a small battery 16 to form a modular hybrid powertrain system that can power one or more motors 18 that provide flight and flight control for the UAS. The battery may be at least an order of magnitude smaller than those lithium polymer battery packs currently used in powering conventional UAS and will only be used for the engine starting procedure, as well as transient power balancing.

[0013] There is seen in FIG. 2 an acceptable embodiment of a micro-tubular flame-assisted fuel cell (FFC) 20. The operating principle of the FFC is based on the combination of a flame with a micro-tubular SOFC in a simple setup. The flame serves as fuel-flexible partial oxidation reformer which generates H2 and CO, while simultaneously providing the heat required for SOFC operation. In the combined system, the flame and fuel cell are inherently coupled and used to generate electricity from the exhaust of a liquid fueled r/c engine. More specifically, for fuel cell 20, a burner 22 is used to ignite a fuel and air mixture 24 in a combustion chamber 26. The exhaust from burner 22 is fed through a stack of micro-tubules 28, each one of which includes a tubular anode 30 surrounded by a electrolyte 32 and a cathode 34. Oxidation air 36 is supplied to cathode 34 and the resulting reaction produces the electrical voltage for use by battery 16 and/or motors 18.

[0014] Fuel cells provide a clean and versatile means to directly convert chemical energy to electricity. Among the many types of fuel cells, SOFCs have received attention due to their simplicity (no moving parts), fuel flexibility and use of inexpensive materials. In one embodiment of this invention, the SOFC utilizes H.sub.2 and CO to generate electricity. The operating temperature of an SOFC is about 500-1000° C. This operating temperature of the SOFC allows for internal reforming and promotes rapid kinetics without the need for precious materials. Instead of operating the fuel cell with a flame, the fuel reforming and heat source is be a nitromethane and methanol fueled r/c engine. R/c engines are inexpensive, reliable, and run on inexpensive widely available methanol based fuel.

[0015] Initial testing of an r/c engine operating under normal conditions without modification indicates that the r/c engines can generate syngas, H.sub.2, and CO. At the same time, the r/c engine will generate heat. The syngas can be utilized by the SOFC as a fuel source and the heat provides an operating temperature for the SOFC. From initial tests, between 11 and 15 percent of the exhaust gas can be immediately utilized as a fuel source for the SOFC, with a temperature high enough for proper operation of the SOFC. Further fuel mixture and engine tuning will allow for increased syngas production and therefore achieving optimal SOFC performance.

[0016] In order for a hybrid system to function properly for a small UAS, the system must be able to cycle without degradation. Accordingly, an SOFC stack was tested in combustion exhaust at a wide range of equivalence ratios and achieved a high power density (˜250 mW/cm.sup.2) that is comparable to performance achieved in many state-of-the-art fuel cell devices. The power and polarization curves for combustion equivalence ratios of 1.05, 1.10, 1.15, 1.2, 1.25 and 1.3 are shown in FIG. 3. After confirming the potential power, the stack was thermal cycled (i.e., the burner was turned on/and off allowing the fuel cell to heat up/cool during the on/off cycling) for 3,010 cycles. Achieving many thermal cycles without significant degradation indicates that an SOFC could be utilized for a UAS application, in which the system will be cycled on and off repeatedly throughout a service life. Temperature profiles for the flame, exhaust, and two of the fuel cells are also shown in FIG. 3. The recorded voltage is that of the 9 cell stack wired in series and accounts for the seemingly large voltage. The power density is reported per active area of the cathode.

[0017] A chemical equilibrium analysis was performed using NASA CEA software for mixtures of methanol and nitromethane to determine adiabatic flame temperature as well as a potential indication of syngas production. CEA analysis showed that nitromethane concentration had little effect on overall syngas production. Overall syngas production between the various fuel mixtures resulted in less than 5% variation. However, the adiabatic flame temperature, as seen in FIG. 4, varied significantly with nitromethane concentration. Increased nitromethane percentage increased adiabatic flame temperature significantly. High nitromethane concentration also maintained higher temperatures as the equivalence ratio increased. Therefore, the operating condition of the engine can be pushed to richer conditions for syngas production without compromising heat energy needed to operate a SOFC.

[0018] Testing was performed with a fuel mixture of 30% nitromethane, 70% methanol to prevent overheating and damage as the engine was being used for the first time. Operating at idle conditions with the carburetor tuned slightly rich produced a total of 14% syngas, indicating that the exhaust gas can be immediately utilized as a fuel source for the SOFC. The engine produced ˜70 L.min.sup.−1 of exhaust at idle with a composition of ˜12% CO and ˜1.5% hydrogen, resulting in a peak power density of ˜340 mW/cm.sup.2, as seen in FIG. 5.