DE3929876A1 - METHOD AND DEVICE FOR GENERATING ELECTRICAL ENERGY - Google Patents

Abstract

The system is for generating electricity in space without release of water. A hydrogen-and-oxygen-burning gas generator 12, having a porous wall (36) (Fig.2) through which water may pass from a space 40, produces a steam exhaust. A turbogenerator 14, 16 is driven by hydrogen conveyed via lines 50a, 50c, 52, 50d, 58 to its turbine 16. The hydrogen is heated in a heat exchanger 20 by the gas generator's steam exhaust 60a which is subsequently condensed to water 60c in the heat exchanger 20 and a further condenser 22. The condensed water passes via a line 60c to a heat exchanger 23 to impart heat to liquid oxygen supplied via line 48a. The heated oxygen then passes via line 48b to the gas generator 12. A portion of the condensed water is passed via lines 60d, 60e and turbopump 24 to the gas generator which is cooled by injecting such water into the combustion region thereof. Any remaining (unused) water is passed via lines, 60f, 60g and a pressure regulator valve 26, to a tank 28. <IMAGE>

Description

The invention relates generally to the elec generation tric energy and in particular on a method and Device for generating electricity in space.

Existing systems for spacecraft electricity (a finally missiles, space station, satellites and the like) have been found to be unsuitable for certain applications proven. Batteries and solar energy systems cannot large amounts of electricity (i.e., greater than about 1 kilowatt) Deliver without compromising on size and weight. Turbogenerators driven by gas generators cannot Generate electricity without emitting water into the room.

It can be foreseen that future spatial operations will occur Electrical power generation system will require that large amounts of electricity without the release of water in the Can provide space. For example, fabrications can be heavy loose on board a space station orbiting the earth Amounts of electricity require while performing weather observation cameras on board the space station deteriorate would be tert if water was a by-product of energy generation system of the space station would be released.

It is an object of the invention, a method and a front Direction for generating large amounts of electricity in space to accomplish. This is meant to be an alternative to using core energy can be used. Furthermore, no water should be in the Space to be released.  

According to a first embodiment, the device contains to generate electricity according to the invention a what hydrogen and oxygen-burning gas generator, a turbo generator, a device for transporting hydrogen to the entrance area of the gas generator and for transportation from hydrogen to the turbine of the turbogenerator and an on Direction for transporting oxygen to the entrance area of the gas generator. The device also includes a mecha heat exchange between the hot exhaust gas (a finally steam) of the gas generator and the hydrogen which has been transported to the turbine of the turbogenerator. The The device further includes a mechanism for condensing after essentially all of the exhaust gas vapor to water the exhaust gas has exchanged heat with the hydrogen, which is used for Turbine was transported. The device also contains a device for transporting at least one part of the condensed water to the combustion area of the gas gene rators and for storing residual condensed water.

In another embodiment, the device includes for generating electrical energy according to the invention a Hydrogen and oxygen burning gas generator, one Turbo generator, a condenser, a heat exchanger, one Tank and a transport device. The transport device contains means for transporting oxygen to the one Corridor area of the gas generator and means for transport from hydrogen to the condenser. The transport device ent also holds means for transporting hydrogen the condenser and the gas generator inlet, between the condensate sor and the heat exchanger and between the heat exchanger and the turbine of the turbogenerator. Also includes transportation device means for transporting exhaust gas between the Outlet of the gas generator and the heat exchanger, between the Heat exchanger and the condenser and between the condenser and the combustion area of the gas generator and between the con densor and the tank.  

In an alternative embodiment, the device contains device for generating electricity according to the invention a Hydrogen and oxygen burning gas generator, one Turbogenerator, a condenser, first and second heat exchangers, a tank and a transport device. The transport facility device contains means for transporting oxygen to the first heat exchanger and means of transporting water fabric to the condenser. The transport device also contains Means for transporting oxygen between the condenser and the gas generator input, between the condenser and the second heat exchanger and between the second heat exchanger and the turbine of the turbogenerator. The transport device also contains means for transporting oxygen between the first heat exchanger and the gas generator input. Additional Lich the transport device contains means for transporting of the exhaust gas between the gas generator outlet and the second Heat exchanger, between the second heat exchanger and the condenser sor, between the condenser and the first heat exchanger, between the first heat exchanger and the combustion area of the gas generator and between the first heat exchanger and the Tank.

Furthermore, a method for producing elec tric energy created that the transport of hydrogen and oxygen to the entrance area of a gas generator to a hot exhaust gas including steam from the outlet of the gas to generate generators, and the transportation of hydrogen too contains a turbine of a turbogenerator. It also contains Procedure for the exchange of heat between the exhaust gas generator and the hydrogen that goes to the Turbogen's turbine rators is transported, and condensing the whole Vapor from the exhaust gas to water after having a heat exchange the hydrogen has taken place to the turbine of the turbogenerator has been transported. In addition, the process includes Transport of at least part of the condensed water to the combustion area of the gas generator and storing  remaining condensed water.

Another embodiment of the method according to the invention is identical to the previously described method, except that the transport of hydrogen and oxygen to the gas generator entrance for the generation of hot exhaust gas including steam from the gas generator outlet is replaced by transportation a stoichiometric mixture of hydrogen and oxygen to a gas generator input to exhaust gas vapor from the gas generator to produce gate outlet.

The advantages that can be achieved with the invention are in particular in that the turbogenerator supplies large amounts of electricity. Furthermore, the gas generator is an alternative to the core energy. The closed water cycle prevents delivery of water into space. The stoichiometric hydrogen / Oxygen mixture uses the fuel efficiently out. The injection of water into the gas generator cools the Gas generator.

The invention will now have further features and advantages hand the description and drawing of exemplary embodiments explained in more detail.

Fig. 1 is a schematic representation of the device for generating electricity according to the invention.

FIG. 2 is a sectional view of the gas generator shown schematically in FIG. 1.

The device 10 for generating electricity according to an embodiment of the invention, as shown in FIG. 1, includes a hydrogen and oxygen burning gas generator 12 for generating a hot exhaust gas including (and preferably limited to) steam. Briefly summarized, the device also includes a turbogenerator 14 with a turbine 16 that drives a generator 18 to generate electricity. However, the turbine 16 is not driven by the exhaust gas from the gas generator 12 , as would be the case with a conventional system. Instead, the turbine 16 is driven by heated hydrogen, the hydrogen being heated in a second heat exchanger 20 by heat exchange with the exhaust gas from the gas generator. Essentially all of the water vapor in the exhaust gas is condensed to water in a condenser 22 and further cooled in a first heat exchanger 23 by a thermal exchange with oxygen which is transported to the gas generator 12 . At least a portion of the water pumped by a turbopump 24 is used to cool the gas generator 12 , and unused (residual) water 25 is transported through an inlet pressure control valve 26 to a storage tank 28 .

Furthermore, means 50 a to 50 e for transporting hydrogen (including liquid and / or gas), means 48 a and 48 b for transporting oxygen (including liquid and / or gas) and means 60 a to 60 g for transporting Ab gas (including steam saturated steam and / or water) before seen. These means preferably contain lines, distributors, channels, valves and the like for transporting, for example, hydrogen, oxygen or exhaust gas. Furthermore, the already mentioned heat exchangers and the condenser are means for exchanging heat and means for condensing into water and can be any heat exchanger in which / or heat exchange between the two substances does not contain any physical mixing, such as a device with two sets closely spaced numerous tubes, a device in which the one substance flows in a housing which is penetrated by numerous tubes with the second substance, and the like.

The hydrogen and oxygen burning gas generator 12 , as shown in detail in FIG. 2, has an input area 30 (to receive hydrogen and oxygen), a combustion area 32 (to ignite the hydrogen and oxygen and to receive the cooling water ) and an exhaust gas outlet 34 within a substantially bell-shaped porous inner wall 36 , where the inner wall 36 is surrounded by a substantially bell-shaped impermeable outer wall 38 , so as to form a substantially bell-shaped channel 40 therebetween, as is the case for a conventional hydrogen / oxygen - Rocket engine is known. While a conventional rocket engine is cooled by directing hydrogen into the channel, the hydrogen then flowing through the porous inner wall, the gas generator 12 according to the invention is cooled by having water in the channel 40 through a water inlet 42 in the outer wall 38 is injected, the water then flowing through the porous inner wall 36 into the combustion area 32 . The hydrogen and oxygen are ignited in the combustion region 32 by conventional means (not shown), thereby generating a hot exhaust gas including steam. When the hydrogen and oxygen are supplied in a stoichiometric ratio, only steam is generated.

The means 48 a are provided to transport oxygen to the first heat exchanger 23 . Preferably, the oxygen is in the form of pressurized cold liquid oxygen, as is the case, for example, in a typical rocket engine. The oxygen leaves the first heat exchanger 23 as a pressurized oxygen gas, where means 48 b are easily seen to transport oxygen between the first heat exchanger 23 and the input region of the gas generator 12 .

The means 50 a are provided to transport hydrogen to the condenser 22 . Preferably, the hydrogen is in the form of a cold compressed gas, as is well known. The hydrogen leaves the condenser 22 as a warm gas under a higher pressure, means 50 b being provided to transport hydrogen between the condenser 22 and the input region of the gas generator 12 . For a start of the gas generator, additional valves and lines supply the hydrogen and oxygen to a burner igniter (all not shown), as is generally known in rocket engine technology.

The means 50 c are provided to transport hydrogen between the condenser 22 and the second heat exchanger 20 . The hydrogen leaves the second heat exchanger 20 as a highly compressed hot gas, means 50 d being provided for transporting hydrogen between the second heat exchanger 20 and the turbine 16 in order to drive the turbogenerator 14 for the generation of electricity. Preferably, the means 50 d have a pipeline 52 which starts from the second heat exchanger 20 and branches into two valves 54 and 56 , the one valve 54 being connected to the turbine 16 by a line 58 and the second valve 56 going to Can open space (at 59 a) . It should be noted that the spent hydrogen that emerges from the turbine is also released into space (at 59 b) .

Furthermore, means 60 a, 60 b and 60 c provided exchanger to the exhaust gas of the gas generator between the outlet 34 and the second Wär exchanger 20, between the second heat exchanger 20 and the condenser 22, and between the condenser 22 and the first heat 23 to transport. Preferably, the exhaust gas is completely steam when it enters the second heat exchanger 20 , saturated water vapor when it leaves the second heat exchanger 20 and enters the condenser 22 , and is hot water when it leaves the condenser 22 and in the first Heat exchanger 23 enters.

Furthermore, means 60 d and 60 e for transporting cold waste water between the first heat exchanger 23 and the pump section of the turbopump 24 and between the turbopump 24 and the combustion area of the gas generator 12 are provided. In order to drive the turbopump 24 , means 50 e are provided for transporting hydrogen between the condenser 22 and the turbine section 64 of the turbopump 24 . The spent hydrogen exiting turbine 64 is expelled into space (at 65 ). Means 60 f and 60 g are used further pressure control valve 26 of the tank and between the inlet pressure control valve 26 and the tank 28 for transport of cold waste water between the first heat exchanger 23 and the inlet. The setting of the inlet pressure control valve 26 determines what proportion of the waste water enters the tank 28 and what proportion is injected into the combustion area of the gas generator 12 .

The method of generating electricity according to the present invention involves transporting hydrogen and oxygen to the input region 30 of the gas generator 12 to generate a hot exhaust gas including steam from the outlet 34 of the gas generator 12 . Additional process steps include the trans port of hydrogen to a turbine 16 of a turbogenerator 18 , with heat being exchanged between the exhaust gas and the hydrogen that is transported to the turbine 16 . Other steps include condensing substantially all of the vapor from the exhaust gas into water after the exhaust gas has entered into heat exchange with the hydrogen supplied to the turbine 16 , transporting at least a portion of the condensed water to the Combustion area 32 of the gas generator 12 and the storage of residual condensed water. Preferably, a substantially stoichiometric mixture of hydrogen and oxygen is transported to the inlet region 30 of the gas generator in order to generate substantially output steam from the outlet 34 of the gas generator.

It should be noted that, for example, in another embodiment, if the device is operated so that any gas remains in the output flow behind the first heat exchanger 23 , the entire output flow from this heat exchanger 23 is transported to the inlet pressure control valve 26 and the tank 28 could be. The tank 28 would then include a gas separator (a hydrogen separator in the event that the device is operated so that hydrogen production in a predominantly vapor-containing exhaust gas is preferred) and a vent (both not shown) to the gas in the Deliver space. Means, not shown, would then also be provided in order to transport water from the tank 28 to the pump section 62 of the turbopump 24 . It is assumed that the method of operation of the device according to the invention is generally understandable for the person skilled in the art, and also the control of the device, such as, for example, the supply conditions for the hydrogen and oxygen, the setting of the inlet pressure control valve 26 , the setting of the hydrogen input 54 of the turbogenerator turbine and the bypass valves 56 etc., at this point require no further description.

Claims (7)

1. Device for generating electricity, characterized by :

• (a) a hydrogen and oxygen-burning gas generator ( 12 ) for generating a hot exhaust gas including steam, the gas generator having an input region ( 30 ), a combustion region ( 32 ) and an exhaust gas outlet ( 34 ),
• (b) a turbogenerator ( 14 ) with a turbine ( 16 ),
• (c) means ( 50 b ) for transporting hydrogen to the input region ( 30 ) of the gas generator ( 12 ) and for transporting hydrogen to the turbine ( 16 ),
• (d) means ( 48 b ) for transporting oxygen to the input region ( 30 ) of the gas generator ( 12 ),
• (e) means ( 20 ) for exchanging heat between the exhaust gas and the hydrogen transported to the turbine ( 16 ),
• (f) means ( 22 ) for condensing substantially all of the vapor from the exhaust gas to water after heat exchange between the exhaust gas and the hydrogen transported to the turbine, and
• (g) means ( 24 , 28 ) for transporting at least part of the condensed water to the combustion area ( 32 ) of the gas generator ( 12 ) and for storing residual condensed water.

2. Device for generating electricity, characterized by:

• (a) a hydrogen and oxygen-burning gas generator ( 12 ) for generating a hot exhaust gas including steam, the gas generator having an input region ( 30 ), a combustion region ( 32 ) and an exhaust gas outlet ( 34 ),
• (b) means for transporting oxygen to the input area of the gas generator,
• (c) a condenser,
• (d) means for transporting hydrogen to the condenser,
• (e) a heat exchanger,
• (f) a turbogenerator with a turbine,
• (h) means for transporting hydrogen between the condenser and the input region of the gas generator, between the condenser and the heat exchanger and between the heat exchanger and the turbine,
• (i) a tank and
• (j) means for transporting the exhaust gas between the exhaust outlet and the heat exchanger, between the heat exchanger and the condenser, between the condenser and the combustion area of the gas generator, and between the condenser and the tank.

3. Device for generating electricity, characterized by:

• (a) a hydrogen and oxygen-burning gas generator ( 12 ) for generating a hot exhaust gas including steam, the gas generator having an input region ( 30 ), a combustion region ( 32 ) and an exhaust gas outlet ( 34 ),
• (b) a first heat exchanger,
• (c) means for transporting oxygen to the first heat exchanger,
• (d) a condenser,
• (e) means for transporting hydrogen to the condenser,
• (f) a second heat exchanger,
• (g) a turbogenerator with a turbine,
• (h) means for transporting hydrogen between the condenser and the input region of the gas generator, between the condenser and the second heat exchanger and between the second heat exchanger and the turbine,
• (i) means for transporting oxygen between the first heat exchanger and the input region of the gas generator,
• (j) a tank and
• (k) means for transporting the exhaust gas between the exhaust outlet and the second heat exchanger, between the second heat exchanger and the condenser, between the condenser and the first heat exchanger, between the first heat exchanger and the combustion area of the gas generator and between the first heat exchanger and the tank.

4. The device according to claim 3, characterized in that the the exhaust gas between the first heat exchanger and the combustion Transport range of the gas generator means Have turbopump, and that means for transporting Hydrogen is provided between the condenser and the pump are. 5. The device according to claim 4, characterized in that the Tank has an inlet pressure control valve, and the means the exhaust gas between the first heat exchanger and the tank transport, have means that the exhaust gas between  the first heat exchanger and the inlet pressure control valve trans port. 6. A method of generating electricity, characterized in that

• (a) hydrogen and oxygen are transported to an input area of a gas generator to generate hot exhaust gas including steam from the exhaust gas outlet of the gas generator,
• (b) hydrogen is transported to a turbine of a turbogenerator,
• (c) heat exchange is effected between the exhaust gas and the hydrogen transported to the turbine,
• (d) substantially all of the vapor from the exhaust gas is condensed to water after heat exchange with the hydrogen transported to the turbine is accomplished,
• (e) at least part of the condensed water is transported to a combustion area of the gas generator,
• (f) residual condensed water is stored.

7. The method according to claim 6, characterized in that an im essential stoichiometric mixture of hydrogen and Transport oxygen to the entrance area of the gas generator is made to a substantially vaporous exhaust gas to generate the exhaust outlet of the gas generator.