JP2001197790A - Hybrid generating set - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently generate by effectively utilizing hydrogen generated by electrolysis of water. SOLUTION: The hydrogen generated by the electrolysis of water is compressed, and a turbine generator is driven by the compressed hydrogen. The hydrogen discharged from the generator is supplied to a fuel cell or a hydrogen engine generator as a fuel. Thus, power generated by the cell or the engine generator and the power generated by the turbine generator are stored in a secondary cell.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hybrid power generator in which a turbine generator, a fuel cell or a hydrogen engine generator is combined.

[0002]

2. Description of the Related Art In recent years, a fuel cell or a hydrogen engine generator that generates power using hydrogen as a fuel has been used as a clean power generator without exhaust gas used for a motor power supply of an electric vehicle or a general household power supply.

Conventionally, as this type of power generator, a power generator has been developed which stores hydrogen generated by the electrolysis of water and supplies the stored hydrogen to a fuel cell as needed to generate power. (Japanese Unexamined Patent Publication No. Hei 8-6422)
No. 0).

[0004]

The problem to be solved is that merely generating hydrogen by supplying hydrogen generated by electrolysis of water to a fuel cell is insufficient in power generation efficiency.

[0005]

SUMMARY OF THE INVENTION A hybrid power generation apparatus according to the present invention pressurizes hydrogen generated by water electrolysis in order to efficiently use the hydrogen generated by water electrolysis to perform efficient power generation. The pressurized hydrogen drives the turbine generator and supplies the hydrogen released from the turbine generator as a fuel to a fuel cell or a hydrogen engine generator, and the fuel cell or the hydrogen engine generator The secondary battery is configured to store the generated power and the generated power of the first turbine generator.

The hybrid power generator according to the present invention pressurizes the oxygen generated by the water electrolysis to improve the power generation efficiency by effectively utilizing the oxygen generated by the water electrolysis. Another turbine generator is driven by the oxygen thus generated, and the electric power generated by the turbine generator is stored in the secondary battery. Then, the oxygen released from the turbine generator is used as an oxidizing agent for a fuel cell or an engine auxiliary agent for a hydrogen engine generator.

[0007]

FIG. 1 shows a basic configuration of a hybrid power generator according to the present invention.

It is a water splitting apparatus 1 for electrolyzing water.
The hydrogen generated in the above is pressurized by the pressure valve 2, the predetermined pressurized hydrogen is sent to the gas turbine 3 to drive it, and the high-pressure hydrogen released from the gas turbine 3 is depressurized by the pressure reducing valve 5. Onboard hydrogen engine generator 6
Generator 4 driven by the gas turbine 3
The power generated by the hydrogen engine generator 6 is stored in the secondary battery 7.

[0009] Instead of the hydrogen engine generator 6,
A fuel cell may be used.

In the hybrid power generator, the oxygen generated in the water splitter 1 is pressurized by a pressurizing valve 8, and the pressurized oxygen is sent to a gas turbine 9 to drive it. The high-pressure oxygen released from the gas turbine 9 is depressurized by the pressure reducing valve 11 and then supplied to the hydrogen engine generator 6 as an engine auxiliary agent, and the power generated by the generator 10 driven by the gas turbine 9 is stored in the secondary battery 7. It is configured to be.

When a fuel cell is used in place of the hydrogen engine generator 6, oxygen released from the gas turbine 9 and decompressed by the pressure reducing valve 11 is supplied to the fuel cell as an oxidant to improve the power generation efficiency. Will be.

Oxygen can be released into the atmosphere after driving the gas turbine 9.

In the water splitting apparatus 1, reference numeral 1a denotes a threshold plate, 1b denotes a cathode plate, and 1c denotes an anode plate.

The pressure valve 2 automatically opens when the internal pressure on the cathode side of the water splitter 1 reaches a predetermined pressure due to an increase in the amount of generated hydrogen. The pressure valve 8 automatically opens when the internal pressure on the anode side of the water splitter 1 reaches a predetermined pressure due to an increase in the amount of generated oxygen. Needless to say, a compressor may be used instead of each of the pressurizing valves 2 and 8.

As the secondary battery 7, for example, a superconducting battery having a high storage efficiency is used.

FIG. 2 shows a specific embodiment of the hybrid power generator according to the present invention.

In this case, the solar cell 12 is used as a power source of the water splitting device 1.

At this time, for example, the power generated by a 400 m ² silicon crystal type solar cell is about 40 KW, so that the amount of hydrogen generated by the electrolysis of water by the solid polymer electrolyte is 10 m ³ per hour. In the case of the hydrogen engine generator 6, since the combustion energy of hydrogen is about 2800 Kcal / m ³ , about 28000 Kcal combustion energy can be obtained.

When the power generated by the solar cell 12 cannot be sufficiently obtained at night or the like, the power of the secondary battery 7 is supplied to the water splitter 1.

In this case, the hydrogen generated by the water splitter 1 is pressurized by a compressor 13 and the pressurized hydrogen is supplied to a high-pressure tank 15 through a flow control valve 14.
And the stored high-pressure hydrogen is sent to the gas turbine 3 by opening the on-off valve 16 as necessary.

Similarly, oxygen generated by the water splitter 1 is pressurized by a compressor 17 and the pressurized oxygen is stored in a high-pressure tank 19 via a flow control valve 18. The on-off valve 20 is opened as required to send the gas to the gas turbine 9.

Instead of the high-pressure tanks 15 and 19, a hydrogen storage device made of a hydrogen storage alloy, a carbon nanotube,
It is possible to use a hydrogen or oxygen storage device using a carbon-based material such as carbon nanofiber or graphite nanofiber.

In addition, a compressor can be used instead of the gas turbines 3 and 9.

In this case, a heat exchanger 22 for cooling the hydrogen discharged from the gas turbine 3 and decompressed by the pressure reducing valve 5 is provided, and the cooled hydrogen is supplied to the hydrogen engine generator 6. In this way, the power generation efficiency is improved. Then, the heat generated in the heat exchanger 22 is added to the hydrogen generated from the water splitter 1 to increase the compression efficiency, thereby effectively utilizing waste heat.

Similarly, the heat exchanger 2 for cooling the oxygen discharged from the gas turbine 9 and decompressed by the pressure reducing valve 11
3 is provided to supply the cooled oxygen to the hydrogen engine generator 6 so as to improve the power generation efficiency. Then, the heat generated in the heat exchanger 23 is added to oxygen generated from the water splitter 1 to increase the compression efficiency, thereby effectively utilizing waste heat.

In this case, the cooled hydrogen is temporarily stored in the surge tank 24, and then the on-off valve 25 is opened to supply fuel to the hydrogen engine generator 6.

Similarly, after the cooled oxygen is once stored in the surge tank 26, the on-off valve 27 is opened to supply fuel to the hydrogen engine generator 6.

The flow control valves 14, 18, the high pressure tank 15,
19 open / close valves 16 and 20, pressure reducing valves (flow regulating valves) 5 and 1
1 and the on-off valves 25 and 27 of the surge tanks 24 and 26 are controlled by the controller 21.

In this case, in order to further improve the power generation efficiency of the hydrogen engine generator 6, a cooling device 28 for cooling the engine portion is provided.

Then, water generated by the hydrogen engine generator 6 (or fuel cell) is reduced to the water splitter 1.

FIG. 3 shows another embodiment of the hybrid power generator according to the present invention.

In this case, in particular, the hydrogen generated by the water splitter 1 is pressurized by the pressurizing valve 2, and the pressurized hydrogen is supplied to the first gas turbine 31 to be driven. After that, the high-pressure hydrogen released from the gas turbine 31 is stored in the high-pressure tank 15 while adjusting the flow rate by the flow control valve 14. Then, the on-off valve 16 of the high-pressure tank 15 is opened to supply high-pressure hydrogen to the second gas turbine 32.
And the gas turbines 31 and 3
Each output of the generators 41 and 42 driven by the power generator 2 is stored in the secondary battery 7.

Similarly, the oxygen generated by the water splitter 1 is pressurized by the pressurizing valve 8, and the pressurized oxygen is supplied to the first gas turbine 91 to drive the first gas turbine 91. The high-pressure oxygen released from the turbine 91 is stored in the high-pressure tank 19 while adjusting the flow rate by the flow control valve 18. Then, the on-off valve 20 of the high-pressure tank 19 is opened and high-pressure oxygen is supplied to the second gas turbine 92 to drive the second gas turbine 92, and each of the generators 101 and 102 driven by the gas turbines 91 and 92 respectively. The output is stored in the secondary battery 7.

Therefore, by driving the two gas turbines 31, 32 and 91, 92 based on the hydrogen and oxygen generated by the water splitter 1, the power generation efficiency can be greatly improved.

In this case, the high-pressure hydrogen discharged from the gas turbine 32 is depressurized by the pressure reducing valve 5, and is temporarily stored in the surge tank 24 while being cooled by the cooling device 28. The valve 25 is opened to supply the fuel to the fuel cell 29.

Similarly, after the high-pressure oxygen released from the gas turbine 92 is depressurized by the pressure reducing valve 11, the hydrogen is temporarily stored in the surge tank 26 while being cooled by the cooling device 28, and the on-off valve 27 is opened. The fuel is supplied to the fuel cell 29.

[0037]

As described above, the hybrid power generator according to the present invention pressurizes hydrogen generated by electrolysis of water,
The turbine generator is driven by the pressurized hydrogen, and the hydrogen released from the turbine generator is supplied as fuel to a fuel cell or a hydrogen engine generator to generate electric power of the fuel cell or the hydrogen engine generator. And a configuration in which the electric power generated by the first turbine generator is stored in the secondary battery. This has the advantage that efficient power generation can be performed by effectively utilizing the hydrogen generated by the electrolysis of water. Have.

Further, the hybrid power generator according to the present invention pressurizes oxygen generated by the electrolysis of water, and drives another turbine generator by the pressurized oxygen. Generated electric power is stored in a secondary battery, and oxygen released from the turbine generator is used as an oxidizer for a fuel cell or an engine auxiliary agent for a hydrogen engine generator. There is an advantage that the power generation efficiency can be improved by effectively utilizing the oxygen thus generated.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a basic configuration of a hybrid power generation device according to the present invention.

FIG. 2 is a block diagram showing an embodiment of a hybrid power generator according to the present invention.

FIG. 3 is a block diagram showing another embodiment of the hybrid power generator according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Water decomposition apparatus 2 Pressure valve 3 Gas turbine 4 Generator 5 Pressure reducing valve 6 Hydrogen engine generator 7 Secondary battery 8 Pressure valve 9 Gas turbine 10 Generator 11 Pressure reducing valve 12 Solar cell 13 Compressor 15 High pressure tank 17 Compressor 19 High pressure tank 22 Heat exchanger 23 Heat exchanger 24 Surge tank 26 Surge tank 29 Fuel cell

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) // H02K 7/18 H02K 7/18 Z

Claims (13)

[Claims] 1. A water splitting apparatus for electrolyzing water, a first pressurizing means for pressurizing hydrogen generated by the electrolysis of water, and a first driving means driven by the pressurized hydrogen.
, A fuel cell or a hydrogen engine generator that generates hydrogen using fuel released from the turbine generator as fuel, an electric power generated by the fuel cell or the hydrogen engine generator, and an electric power generated by the first turbine generator And a secondary battery that respectively stores electricity. A second pressurizing means for pressurizing oxygen generated by the electrolysis of water; and a second turbine generator driven by the pressurized oxygen, wherein the generation of the turbine generator is performed. The hybrid power generator according to claim 1, wherein the electric power is stored in a secondary battery. 3. The hybrid power generator according to claim 2, wherein oxygen released from the second turbine generator is used as an oxidant for a fuel cell or an engine auxiliary agent for a hydrogen engine generator. . 4. A heat exchanger for cooling hydrogen released from the first turbine generator, wherein heat generated in the heat exchanger is added to hydrogen generated from the water splitting device. The hybrid power generator according to claim 1. 5. A heat exchanger for cooling oxygen released from the second turbine generator, wherein heat generated in the heat exchanger is added to oxygen generated from the water splitter. A hybrid power generator according to claim 2. 6. The method according to claim 1, wherein each of the first and second pressurizing means is a pressurizing valve that opens when the pressure on the input side becomes equal to or higher than a predetermined value. By hybrid power plant. 7. The hybrid power generator according to claim 1, wherein each of the first and second pressurizing means is a compressor. 8. The hybrid power generator according to claim 1, wherein the solar cell is used as a power source of the water splitter. 9. The hybrid power generator according to claim 1, wherein water generated by the fuel cell or the hydrogen engine generator is supplied to the water splitter. 10. The hybrid power generator according to claim 1, wherein the pressurized hydrogen is stored in a high-pressure tank and then supplied to the first turbine generator. 11. The hybrid power generator according to claim 2, wherein the pressurized oxygen is stored in a high-pressure tank and then supplied to a second turbine generator. 12. The hybrid power generation according to claim 1, wherein the hydrogen released from the first turbine generator is stored in a storage device and then supplied to a fuel cell or a hydrogen engine generator. apparatus. 13. The hybrid power generation according to claim 2, wherein oxygen released from the second turbine generator is stored in a storage device and then supplied to a fuel cell or a hydrogen engine generator. apparatus.