WO2005056994A1 - Air-storage plant - Google Patents

Abstract

An air-storage plant (1) comprising a storage cavern (5), compressors (2a, 2b) for compressing air, and a turbine (8), which is connected to a generator (G1) via a shaft, is integrated with a steam turbine plant (10) by means of heat exchangers (20, 24, 30). The air compressed by the compressors (2a, 2b) is conducted through heat exchangers (20, 24) and cooled on pipes through which condensate from the condenser of the steam plant flows, whereby the condensate is heated. The waste gases from the turbine (8) are conducted through another heat exchanger (30), whereby feed-water flowing though the pipes is heated. The entire process of both plants is improved by their integration due to the fact that by cooling the air, the power consumption of the compressors (2a, 2b) is decreased, and the storable air volume is increased. In addition, by heating the condensate and/or feed-water, the need for extraction steam for heating water and steam is decreased and the efficiency of the steam plant (10) is increased.

Description

 Air storage power plant

Technical field

The invention relates to an air storage power plant and a steam power plant and method for operating the plants.

State of the art

Air storage power plants are generally known under the term CAES or "compressed air energy system". Such a power plant is disclosed, for example, in FIG. 1 of DE 10235 108. With such systems, air is compressed in a cavern during periods of low consumption (e.g. at night and on weekends) using a compressor and stored at a relatively high pressure. During times of high electricity demand, the air compressed there is first heated and then expanded in a turbine that drives a generator. These systems have the advantage that the turbines can be started by the stored air shortly, whereby practically all of the turbine power can be transferred to the generator without the turbine power having to be distributed to compressors and generators.

When filling the cavern, it is advantageous if the temperature of the air is warmed as little as possible, because on the one hand the power requirement of the compressor increases with increasing temperature and on the other hand a lower air temperature leads to better filling of the cavern due to the lower air density.

The cavern air is normally heated before it is fed into the turbines, it being possible for the cavern air to be warmed up, for example, by means of a recuperator, as shown in DE 102 35 108. However, such a recuperator must be designed for the large amounts of air and high pressures with the appropriate volume and wall thickness. An alternative is to directly heat the air in a combustion chamber. In terms of process technology, however, this solution is only of advantage if the hot exhaust gases continue to be used.

Presentation of the invention

It is the object of the present invention to improve the overall process of an air storage power plant, in particular with regard to the efficient heating of the air, the disadvantages of the prior art mentioned being avoided.

An air storage power plant has a storage cavern, one or more compressors, and one or more turbines, which is connected to a generator on a shaft. According to the invention, the air storage power plant is integrated with a steam power plant which has a water-steam cycle with a boiler, one or more turbines and a condensation and water treatment system. In particular, the air-gas cycle of the air storage power plant with the water-steam cycle is one

Steam power plant switched by means of one or more heat exchangers.

The one or more turbines of the air storage power plant are air and / or gas turbines, which may be preceded by a combustion chamber.

In a first embodiment, one or more heat exchangers are connected on the air side in each case between individual compressors and or between a compressor and the storage cavern and are connected on the water side in the water-steam cycle of the steam turbine power plant. The heat exchangers in the water treatment plant are preferably connected between a condenser and the boiler of the steam power plant.

During the compressor operation of the power plant, the compressed air is cooled by heat exchange with the condensate or feed water of the steam power plant flowing in pipes. The cooling of the compressed air has the advantage of a reduced power requirement of the compressors and one Increase in the air introduced into the storage cavern due to increased air density.

The heat exchanger mentioned is preferably connected in parallel with a condensate or feedwater preheater with respect to the water-steam circuit. This means that the preheater in question is relieved and less steam has to be removed from the steam turbine, which enables an increase in the turbine output.

Overall, the integration of the two power plants means an improvement in the efficiency of both plants.

In a variant of this first embodiment, the one or more heat exchangers are connected directly into the steam circuit of the steam power plant instead of parallel instead of parallel to the heat exchangers of the water treatment plant.

In a second embodiment of the invention, an exhaust pipe, which leads away from a turbine of the air storage system, is connected to a waste heat boiler which is connected on the water side to the water-steam circuit of the steam system. The waste heat boiler is used here to heat the feed water and / or condensate. Similar to the version mentioned above, the preheating of the feed water / condensate ^ is relieved, so that less steam has to be taken from the turbines and the turbine output is increased as a result.

In a variant of this embodiment, the waste heat boiler is connected directly to a steam turbine on the steam side. The waste heat boiler is used here to generate superheated steam.

On the exhaust gas side, the waste heat boiler is connected to the boiler of the steam turbine power plant. The hot exhaust gases are fed directly into the boiler and heat the combustion air of the boiler there.

In a further embodiment of the air storage power plant, the turbine is preceded by a combustion chamber which is used to heat the air before it is expanded in the turbine. A recuperator is not necessary here. With regard to the efficiency of the overall system, this is justifiable in the power plant according to the invention, since the energy of the exhaust gases from the combustion chamber ultimately used for heating feed water and the combustion air in the boiler.

In a method according to the invention for operating an air storage power plant, the air compressed in one or more compressors is fed via a line into a heat exchanger in which the compressed air is in heat exchange with condensate flowing through pipes from the steam turbine power plant, and the air cooled there is over a line is either routed into a downstream compressor or directly into the air storage cavern.

In a further process, the exhaust gases from the turbine are passed through a heat exchanger in which the exhaust gases are in heat exchange with feed water flowing through pipes from the water-steam circuit of the steam turbine system and are then passed into the boiler and / or via a chimney into the atmosphere ,

Brief description of the drawings

FIG. 1 shows a basic circuit diagram of an air storage power plant according to the invention integrated with a steam power plant with a waste heat coupling of the air storage plant into the condensate and feed water system of the steam power plant.

FIG. 2 shows a basic circuit diagram of an air storage power plant according to the invention integrated with a steam power plant with a variant of the waste heat coupling of the air storage plant into the lines of the condensate and feed water system of the steam power plant. Figure 3 shows a variant of the power plant according to the invention with a drive turbine for the compressor drive.

Figure 4 shows a further variant of the integrated power plants with an additional steam generator.

Implementation of the invention Figure 1 shows schematically a dashed line air storage power plant 1, as is known in the prior art and also a dashed line conventional steam power plant 10. The air storage plant 1 essentially has several compressors 2a and 2b connected in series, which by means of of a motor M are driven. (Only one compressor can be used). During the compressor operation, the compressors 2a and 2b compress air from the atmosphere 3 to a pressure of typically 60 to 100 bar. The compressed air is passed via a line 4 into a storage cavern 5. or expansion operation of the air storage power plant, the compressors 2a, 2b are not in operation. In turbine operation, the stored compressed air is fed from the cavern 5 via a line 6 into a combustion chamber 7, in which it is heated using fuel. The resulting hot gas is expanded in the turbine 8, which is connected to a generator G1 via a shaft 9, up to almost atmospheric pressure. Depending on the design of the system, the gas can also be reheated in an additional combustion chamber.

The steam power plant 10 is a conventional power plant of its kind with a boiler 11, high and low pressure steam turbines 12 and 13, which are connected via a shaft 17 to a generator G2, a condenser 15 and the condenser and feed water preheater 15 and 16 connected downstream of the condenser The preheaters 15 and 16 represent condensate and feed water preheaters, which can be present in different numbers depending on the application. A steam extraction line 18 and 19 each lead from the high-pressure and low-pressure turbines 12 and 13 to the preheaters 16 and 15, respectively.

As mentioned at the beginning, cooling of the air to be compressed and also of the compressed air is desirable since the power requirement of a compressor is favored at a lower temperature and larger amounts of air can be stored at lower temperatures. For the purpose of cooling the compressed air, according to the invention a heat exchanger 20 is connected between the two compressors 2a and 2b connected in series and after the second compressor 2b and in front of the storage cavern 5 another heat exchanger 24 which is connected upstream of the heat exchanger 20. The compressed air therefore first flows through the heat exchanger 20 and then through the heat exchanger 24. The heat exchangers 20, 24 are on the water side with the water-steam cycle Steam system by means of lines 25 and 26, preferably connected in parallel to the condensate preheater 15.

The heat exchangers 15 and 16 each have a multiplicity of tubes through which the condensate flows from the condenser 14 out of the steam system. The air from the compressor 2a is passed via the line 21 into the heat exchanger 20, in which it flows around the tubes and cools down, cooling being achieved, for example, in a temperature range from 100 to 400.degree. When the air cools down, the power requirement of the compressor is reduced in proportion to the absolute air temperature. The cooled air is then fed via line 22 to the subsequent compressor 2b. The compressed air from the compressor 2b is passed via line 23 for further cooling into the heat exchanger 24, which is connected upstream of the heat exchanger 20 on the water side, and after it has flowed through the line 4 into the storage cavern 5. The heat exchanger 24 is used for cooling to a temperature in the range from, for example, 400 ° C. to 70 ° C. This results in an increase in the amount of air to be stored in accordance with the ratio of the absolute air temperatures. As a result of the heat exchange, the condensate flowing through the tubes of the heat exchanger heats up, so that less for the heat exchanger 15

Extraction steam must be passed from the turbine 13. This has a positive effect on the efficiency of the turbine 13. The integration of the two power plants by means of the heat exchangers 21 and 24 provides an efficiency advantage for both plants during the compressor operation of the air storage system.

The number of heat exchangers for cooling the air is in itself arbitrary, whereby the number of devices must be weighed against the gain in performance.

During the turbine operation of the air storage system, the two systems are advantageously integrated by a further heat exchanger 30, more precisely a waste heat exchanger. This is connected on the water side in the water-steam circuit of the steam system via lines 31 and 32, preferably parallel to the preheater 16. In a variant of this embodiment, the condensate preheating is carried out exclusively via the heat exchangers 20 and 24. After their expansion in the turbine 8, the hot exhaust gases are passed via an exhaust gas line 33 into the waste heat exchanger 30, in which they flow around pipes through which the feed water of the steam system flows and is heated in the process. As a result, the need for extraction steam from the turbine 12 via the line 18 is reduced, the efficiency of the turbine 12 being increased accordingly. When using the waste heat from the turbine, approx. 40% of the turbine power can be injected into the water-steam cycle and used to preheat the water. The additional power achieved by the waste heat exchanger is comparatively high because the heat exchange takes place at a higher temperature level.

During turbine operation, the two plants can also be integrated by switching the waste heat exchanger in relation to the steam power plant. The waste heat exchanger and / or one of the heat exchangers for cooling the compressed air is used in this variant to generate superheated steam. Depending on the existing pressure level and the prevailing physical state after heating, the steam is fed via a line from the waste heat exchanger and / or heat exchanger for cooling the compressed air either upstream of the boiler superheater in the boiler 11 or directly in front of one of the turbines 12 or 13. This variant increases the generator power G2 by increasing the mass flow. After leaving the waste heat exchanger 30, the exhaust gases are passed via line 34 directly into the boiler 11, where they heat up the combustion air.

Figure 2 shows a variant of the integrated power plant shown in Figure 1. It differs from the system of FIG. 1 in the order of the air flow through the heat exchangers 20 and 24 used as air coolers. The order of the air flow through the heat exchangers 24 and 20 is therefore compared to the system in FIG. 1 in relation to the pressure level of the compressed air swapped by first passing compressed air from the compressor 2a through the heat exchanger 24 and then feeding it to the compressor 2b. The air compressed in compressor 2b is then passed to heat exchanger 20 for further cooling and finally into cavern 5. Since the compressor air is generally hotter than the air in line 21, this arrangement is thermodynamically more favorable for the heat exchange with the condensate and thus for the efficiency of the water-steam cycle. Figure 3 shows a further variant of the system of Figure 2, which has a drive turbine 27 instead of a motor for driving the compressor. The drive turbine is fed, for example, directly from the steam network of the water-steam cycle, with its exhaust steam being fed directly into the condenser. The tapping point for the required steam and the point of return of the exhaust steam are arbitrary per se and can be optimized depending on the system. The arrangement with the drive turbine achieves a higher overall efficiency, since at least the transmission losses of the electrical current required to drive the compressor motor are eliminated in the system from FIG. 2.

FIG. 4 shows a system according to FIG. 1, but which has an additional steam generator 38 to which a line 33 leads from the turbine 8. It is used for the direct generation of steam from the hot exhaust gases from the turbine 8. The directly generated steam is fed via line 40 into the live steam flow to the turbine 12 and / or via line 39 into the steam flow to the second turbine 13.

Power plants with different combinations of the variants shown here can also be implemented.

LIST OF REFERENCE NUMBERS

I Air storage power plant 2a, 2b compressors

3 air intake

4 Line to the storage cavern

5 storage caverns

6 line to combustion chamber 7 combustion chamber

8 turbine

9 wave

10 steam turbine power plant

I I boiler 12 high pressure turbine

13 low pressure turbine

14 capacitor

15 heat exchanger / condensate preheater

16 heat exchanger / feed water preheater 17 shaft

18 Extraction steam line

19 Extraction steam line

20 heat exchangers

21 line 22 line 23 line

24 heat exchangers

25 condensate line

26 condensate line 30 heat exchanger

31 feed water line

32 feed water line

33 Exhaust pipe

34 exhaust pipe 35 pipe

36 Chimney G1 generator G2 generator M motor T turbine to drive the compressors

Claims

claims

1. An air storage power plant (1) has an air-gas circuit with a storage cavern (5), one or more compressors (2a, 2b) and one or more turbines (8) which are connected via a shaft to a generator ( G1) are characterized in that the air storage power plant (1) is integrated with a steam turbine power plant (10), which has a water-steam cycle with a boiler (11), one or more turbines (12, 13), which are connected to a generator (G2) and have a water treatment system, the air-gas circuit of the air storage power plant (1) being connected to the water-steam circuit of the steam power plant (10) by means of one or more heat exchangers (20, 24 , 30) is switched.

2. Air storage power plant (1) according to claim 1, characterized in that one or more heat exchangers (20, 24) on the water side in the water-steam circuit of the steam power plant (10) and on the air side in the air flow of the compressors (2a, 2b) for cooling compressed air are switched.

3. Air storage power plant (1) according to claim 2, characterized in that the one or more heat exchangers (20, 24) is a condensate or

Feed water preheater of the water-steam cycle is connected in parallel or is connected directly in the water-steam cycle.

4. Air storage power plant (1) according to claim 3, characterized in that a in the flow direction of the water-steam circuit of the steam power plant (10) first heat exchanger (24) on the air side between the outlet of a compressor (2b) and the storage cavern (5th ) is switched, and a in the flow direction of the water-steam circuit of the steam power plant (10) second heat exchanger (20) is connected on the air side between a first compressor (2a) and a second compressor (2b) in the direction of the air flow through the compressors (2a, 2b).

5. Air storage power plant (1) according to claim 3, characterized in that in the flow direction of the water-steam circuit of the steam power plant (10) first heat exchanger (24) on the air side between a first compressor (2a) and a second compressor (2b ) in the direction of the air flow through the

Compressors (2a, 2b) is connected, and a second heat exchanger (20) is connected on the air side between the outlet of a compressor (2b) and the storage cavern (5) in the flow direction of the water-steam circuit of the steam power plant (10).

6. Air storage power plant (1) according to claim 2, characterized in that the air storage power plant (1) has a motor (M) for driving the compressors (2a, 2b).

7. Air storage power plant (1) according to claim 2, characterized in that the air storage power plant (1) has a turbine (27) for driving the compressors (2a, 2b).

8. Air storage power plant (1) according to claim 1, characterized in that a heat exchanger (30) on the gas side in an exhaust pipe (33) between the outlet of a turbine (8) and the boiler (11) of the steam turbine power plant (10) and water side is switched to heat water in the water-steam cycle of the steam turbine.

Air storage power plant (1) according to claim 1 characterized in that a heat exchanger (30) on the gas side in an exhaust pipe (33) between the outlet of a turbine (8) and a boiler (11) of the steam turbine power plant (10) and on the steam side for generating superheated steam in the water-steam cycle the steam power plant is connected and is directly connected to a steam turbine (12, 13) of the steam power plant.

10. Air storage power plant (1) according to claim 8, characterized in that the heat exchanger (30) is a waste heat exchanger (30).

11. Air storage power plant (1) according to claim 9, characterized in that the waste heat exchanger (30) is connected in parallel to a feed water preheater (16) in the water-steam circuit of the steam power plant (10).

12. Air storage power plant (1) according to claim 2 or 8, characterized in that from the waste heat exchanger (30) and / or from a heat exchanger (20, 24) for cooling the compressed air, a line to the boiler (11) or to a turbine ( 12, 13) of the steam power plant (10) leads to superheated steam.

13. Air storage power plant (1) according to claim 1, characterized in that the one or more turbines (8) of the air storage power plant (1) is followed by a steam generator (38), one or more of which

Steam lines (39, 40) each lead to a turbine (12, 13) of the steam power plant (10).

14. The method for operating an air storage power plant (1) according to claim 1, characterized in that compressed and / or compressed air by heat exchange with in pipes flowing water from the water-steam cycle of a steam turbine power plant is cooled and water from the water-steam cycle is heated in this heat exchange.

15. The method for operating an air storage power plant (1) according to claim 1, characterized in that

Water or steam of the water-steam circuit of the steam power plant (10) is heated by heat exchange with exhaust gases from the turbine (8) and the exhaust gases of the combustion air in the boiler (11) of the steam power plant (10) are mixed.

16. The method for operating an air storage power plant (1) according to claim 1, characterized in that

Steam of the water-steam circuit of the steam power plant is overheated by heat exchange with exhaust gases from the turbine (8).