WO2012143272A1 - Heat exchanger arrangement and method for heating a working gas - Google Patents

Abstract

The invention relates to a heat exchanger arrangement (100) for heating a working gas for a turbine (130) of a compressed air energy storage power plant (120). The heat exchanger arrangement (100) comprises a first gas inlet (101) that can be coupled to a pressure chamber (160) of the compressed air energy storage power plant (120), so that a working gas having a first inlet temperature (T_E1) can be fed from the pressure chamber (160) to the heat exchanger arrangement (100). The heat exchanger arrangement (100) further comprises a first gas outlet (111) that can be coupled to the turbine (130) so that the working gas can be fed from the heat exchanger arrangement (100) to the turbine (130) at a first outlet temperature (T_A1). The heat exchanger arrangement (100) further comprises a second gas inlet (102) that can be coupled to the turbine (130) so that the working gas can be fed from the turbine (130) to the heat exchanger arrangement (100) at a second inlet temperature (T_E2). The heat exchanger arrangement (100) further comprises a second gas outlet (112) that can be coupled to the turbine (130) so that the working gas can be fed from the heat exchanger arrangement (100) to the turbine (130) at a second outlet temperature (T_A2). A heating agent can be introduced such that the working gas can be heated from the first inlet temperature (T_E1) to the first outlet temperature (T_A1) and that the working gas can be heated from the second inlet temperature (T_E2) to the second outlet temperature (T_A2).

Description

 HEAT TRANSFER ARRANGEMENT AND METHOD FOR HEATING

 A WORKING GAS

Technical area

The present invention relates to a ^{Wärmeübertrageranord ¬} tion for heating a working gas for a turbine of a compressed air storage power plant.

Furthermore, the present invention relates to a compressed air storage power plant.

Furthermore, the present invention relates to a method for heating a working gas for a turbine of a compressed air ^¬ memory power plant.

Background of the invention

The total power requirement of many countries is increasingly covered by renewable energy sources, such as by solar energy or wind energy ^¬. This leads to a ^large number ^¬ smaller decentralized power plants, which are operated with regenerati ^¬ ven energy sources. The power generated by power plants using renewable energy sources, for example, fluctuates due to the effects of weather, such as Windän ^¬ alteration or fluctuating sunshine durations.

Therefore, with an increasing number of power plants operated with regenerative energy sources, the use of storage power plants is required. In storage power plants, a surplus of energy produced is temporarily stored and, if necessary, retrieved for power generation. Known storage power plant types are, for example, pumped storage power plants and compressed air storage power plants. In a pumped storage power plant, water is pumped with the surplus energy generated in a high-level reservoir. When energy is needed, the water is removed from the high-level NEN memory via downpipes further downstream turbines supplied to operate a power generator.

A compressed air storage (CAES) power plant operates with the excess energy a compressor that pumps in compressed air in a pressure space, such as an underground cavern. If there is a higher power demand, the compressed air from the pressure space is used to operate a turbine, which in turn operates a coupled power generator.

In order to reduce a loss at an intermediate storage of energy in storage power plants, it is necessary, the storage power plants with high efficiency bereitzustel ^¬ len. Typically, in compressed air storage power plants to increase the efficiency of the working fluid is heated before entering a turbine. In Fig. 5, a conventional process of a compressed air storage ^¬ cherkraftwerks is shown. The working fluid, for example compressed air, is supplied to a conventional heat exchanger 500 from a pressure chamber 501, such as an underground cavity, before entering a turbine 502. The working fluid, when entering the heat exchanger 500, has a first inlet temperature T _E i. The heat exchanger 500 is a first heat energy Q _to , i supplied. By means of the heat energy Q _to, i is heated, the working fluid to a first temperature T _A from ^¬ let i. With this first outlet temperature T _A i, the working fluid is supplied to the turbine 502 at a first turbine stage. The excess heat energy in the heat exchanger 500 is the first waste heat Q _ab , i abge ^¬ leads. In the turbine 502, the working fluid relaxes and according to a conventional gas turbine process, this generates mechanical work with which a generator 503 is operable to generate electricity. Presentation of the invention

It is an object of the present invention to provide a compressed air storage power plant with a high efficiency.

The object is achieved by a heat exchanger arrangement for heating a working gas for a turbine of a compressed air ^¬ memory power plant, by a compressed air storage power plant and by a method for heating a working gas for a turbine of a compressed air storage power plant according to the inde pendent ^¬ claims.

According to a first aspect of the present invention, a heat exchanger arrangement for heating a working gas for a turbine of a storage power plant, in particular a compressed air storage power plant is described. Heat ^¬ trageranordnung has a first gas inlet, a first outlet, a second gas intake and a second gas outlet. The first gas inlet is coupled to a pressure chamber, so that a working gas with a first input ^¬ temperature from the pressure chamber to the heat exchanger assembly can be fed. The first gas outlet is LAD ^¬ Pelbar with the turbine, so that the working gas can be supplied with a first Auslasstempe ^¬ temperature of the heat exchanger arrangement to the turbine. The second gas inlet can be coupled to the turbine, so that the working gas can be supplied to the turbine of the heat exchanger arrangement with a second inlet temperature. The second gas outlet can be coupled to the turbine, so that the working gas can be supplied to the turbine with a second outlet temperature from the heat exchanger arrangement. A heating means can be supplied in such a way that the working gas can be heated from the first inlet temperature to the first outlet temperature. The working gas is further heated from the second input temperature to the second outlet temperature by means of a heating means. According to another aspect of the present invention, a compressed air storage power plant has a pressure space, a turbine and the above-described heat exchanger arrangement.

According to a further aspect of the present invention, a method for heating a working gas for a Turbi ^¬ ne of a compressed air energy storage power plant is described. According to the method, a first working gas having a first inlet temperature is supplied from a pressure space to a first gas inlet of a heat exchanger arrangement. The working gas is heated from the first inlet temperature to the first outlet temperature by means of a heating means in the heat exchanger assembly. The working gas is supplied to the turbine at a first outlet temperature from the heat exchanger assembly. Further, the working gas having a two ^¬ th input temperature of the turbine to a second heat exchanger arrangement of the gas inlet supplied. The working ^¬ gas is heated by the second input temperature to the second outlet by means of a heating medium. The Ar ^¬ gas is supplied with a second outlet temperature of the heat exchanger assembly to the turbine.

According to another exemplary embodiment, a compressed air storage power plant is described, which has the above-described pressure chamber, the turbine and the above-described heat exchanger arrangement.

The heat exchanger assembly may include one or more heat transfer devices (recuperators). A recuperator is used to preheat the working gas by means of a Wär ^¬ memittels or by several different heat medium.

In a compressed air storage power plant, a working gas from a pressure chamber, such as from a

underground cavity, conveyed and fed to the turbine. The working gas from the pressure chamber has a high pressure. In the turbine, the working gas relaxes, so that the energy of the working gas is converted into mechanical work becomes. The turbine in turn drives a power generator, which generates electricity. If less power is required, the working gas is fed into the pressure chamber, for example by means of a compressor, so that the pressure in the pressure chamber increases. In the pressure chamber, the working gas is stored under high pressure.

By expanding the working gas in the turbine, the working gas cools off sharply. The turbine has, for example egg ^¬ ne first turbine stage (resp. A first thermodynamic relaxation area), a second turbine stage (or a second thermodynamic relaxation area) or more additional turbine stages (or more thermodynamic Ent ^¬ voltage ranges) on. The second turbine stage is downstream of the first turbine stage with respect to a flow direction of the working gas in the turbine downstream of the first Turbi ^¬ ne or arranged.

In order to increase the efficiency, the working gas is heated in the heat exchanger assembly of the first input temperature (temperature of the working gas in the pressure chamber) to a first outlet temperature, which is higher than the first input Tempe ^¬ rature, by means of a heating means.

In addition, the working gas, for example after the first or the second turbine stage of the turbine, removed and fed to the second gas inlet of the heat exchanger assembly. The heat exchanger arrangement heated by the heat medium, the working gas from a second input temperature to a second outlet, which is higher than the second input temperature, and the door ^¬ bine supplies the working gas to again. This interim removal of the working gas from the turbine, the interim heating and the subsequent return of the working gas with the second outlet temperature ^¬ tur leads to an increase in the efficiency of the turbine. More specifically, the pressure of the working gas between the Ab ^¬ draw-off from the turbine, the supply to the second gas inlet and the supply of the heated working gas is in the second gas outlet, which in turn gekop ^¬ pelt with the turbine, kept almost constant. With such Zvi ^¬ rule warming the efficiency of the turbine is increased. The intermediate heating can be carried out at several turbine stages of the turbine.

In other words, according to the present invention, at a certain point in the expansion process of the working gas in the turbine, the working gas can be taken out and fed again to the heat exchanger arrangement. In the heat exchanger arrangement, the supplied working gas is heated after ^¬ and supplied as supply air back to the turbine. This increases the efficiency of the turbine. With the same degree of volatility of the heat exchanger arrangement, more heat can be drawn into the heat medium in the heat exchanger arrangement and thus an efficient heating of the working gas can be made possible.

The heating means can for example be taken from a heat-generating ^¬ the device. The heating means is for example an exhaust gas of a gas turbine. Further, the heat ^¬ memittel be a heated oil or heated water, which is warmed up, for example by solar power.

According to a further exemplary embodiment of the present invention, the heat exchanger arrangement further has a further second gas inlet, which can be coupled to the turbine, so that the working gas can be supplied to the heat exchanger arrangement with a further second inlet temperature from the turbine. Furthermore, the heat exchanger arrangement in a further second gas outlet which can be coupled with the turbine, so that the working gas with egg ^¬ ner further second outlet of the heat exchanger arrangement can be fed to the turbine. The heating means can be supplied in such a way that the working gas can be heated from the further second inlet temperature to the further second outlet temperature. According to the above embodiment, a plurality of taps at the turbine can be set at ^¬ play to tap working gas and supplied to the heat exchanger arrangement. The tapped working gas is heated in each case in the heat exchanger arrangement and then fed back to the turbine.

According to a further exemplary embodiment, the heat exchanger arrangement has a first heat exchanger device. The first heat transfer device has the first gas inlet, the first gas outlet and a first heat medium inlet. Furthermore, the heat exchanger arrangement has a second or a multiplicity of further second heat exchanger devices, which in each case has the second gas inlet, the second gas outlet and a second heat inlet. The first heat transfer device may be structurally separate from the second heat transfer device. Further, the first and the second Heat Transf ^¬ gervorrichtung Wärmeübertragervorrichtung may be co-located in a common housing.

According to a further exemplary embodiment, the first heat medium inlet and the second heat medium inlet can be coupled to a common heat-generating device. For example, the first and the second Wärmeübertragervorrichtung Wärmeübertragervorrichtung can share a common heat medium, which is heated by the common wärmeer ^¬ forming apparatus. For example, as a heat generating device, a gas turbine may supply hot exhaust gas to the first heat transfer device and the second heat transfer device.

According to a further exemplary embodiment, the first heat exchanger device has a heat medium outlet for discharging the heating medium with a first waste heat. The Wärmemittelauslass and the second heat medium inlet are coupled together such that the heating means with the first waste heat can be supplied to the second heat medium inlet. Thus, the graveness of the heat exchanger arrangement, in particular the first heat exchanger device and the second heat exchanger device is improved. The heat medium, which emerges with the first waste heat from the first heat ^¬ transmission device can efficiently be used as heat with ^¬ tel for the second Wärmeübertragervorrichtung the advertising. The overall efficiency of the heat exchanger assembly is thereby increased.

Additionally or alternatively, in another exemplary embodiment, the first heat medium inlet can be coupled to the heat-generating device and the second heat medium inlet can be coupled to a further heat-generating device. Thus, the first Wärmeübertragervorrichtung with a first heat medium and the second Wär ^¬ meübertragervorrichtung can for example be operated with a second heat medium.

As the first heating means, for example, the exhaust gas of a gas turbine can be used as a heat-generating device. As another heat medium, for example, exhaust gas of a white ^¬ direct gas turbine and / or hot oil or hot water may, for example, which has been heated more than wärmeer ^¬ generating device in a solar power plant, are used.

The first gas outlet of the heat exchanger arrangement is coupled to the turbine such that the working gas can be supplied to the first outlet temperature of the first turbine stage. The second gas outlet of the heat exchanger arrangement is coupled to the turbine such that the working gas with the second inlet temperature between the first turbine stage and the second turbine stage can be removed and the heat transfer ^¬ ranordnung can be fed. The second gas outlet of the heat exchanger assembly ^¬ is coupled to the turbine, that the working gas with the second outlet temperature before the second turbine stage can be fed. In an exemplary embodiment, the working gas may be mixed with the second exhaust Temperature can also be supplied to a subsequent, arranged after the second turbine stage, turbine stage.

With the invention described above, various embodiments are explained in summary, with which the efficiency of a turbine in a compressed air ^{storage power ¬} plant is increased. According to a first exemplary embodiment, a working gas is taken on the one hand from the pressure chamber and heated in the heat exchanger assembly. In the same heat exchanger arrangement is also another

Working gas, which has been tapped from the turbine, led to ^¬ and heated in the same heat exchanger assembly.

In another exemplary embodiment, the heat exchanger arrangement is formed from, for example, two or more heat exchanger devices, with a first heat exchanger device (a first recuperator) allowing initial heating of the working gas. A wide ^¬ re Wärmeübertragervorrichtung (another recuperator) receives at the bled from the turbine working gas is heated and the turbine, this leads to the working gas again. In the case of the ^embodiment with different heat exchanger devices, this opens up the possibility of ^operating each heat exchanger device with an associated heat source (heat generating device). For example, the one heat ^¬ transmission ^device by means of a gas turbine and the other heat exchanger device by means of a solar power plant be ^¬ driven. In addition, this opens the possibility that the various heat transfer devices can operate at different temperature levels, since each heating means can have a different temperature.

According to a third embodiment of the present invention, the heat exchanger arrangement ^¬ may comprise a plurality of gas inlets which receive the working gas from the pressure space or from different turbine stages of the turbine to heat the working gas. It should be noted that the embodiments described herein represent only a limited selection of possible embodiments of the invention. Thus, it is possible to combine the features of individual embodiments in a suitable manner, so that for the person skilled in the art with the embodiments that are explicit here, a multiplicity of different embodiments are to be regarded as obviously disclosed.

Brief description of the drawings

In the following, for further explanation and for a better understanding of the present invention, embodiments will be described in detail with reference to the accompanying figures.

1 shows a schematic representation of a compressed-air storage power plant with a heat exchanger arrangement according to an exemplary embodiment of the present invention;

Fig. 2 shows air-storage power station is a schematic representation of a printer in which the voltage Wärmeübertrageranord ^¬ a plurality of second gas inlets and a plurality of second Gasausläs ^¬ se has guide of the present invention according to an exemplary off;

3 shows a schematic representation of a compressed air storage power plant with a heat exchanger arrangement, which has a first heat exchanger device and a second heat exchanger device according to an exemplary embodiment of the present invention;

4 shows a schematic representation of a compressed air storage power plant according to an exemplary exporting ^¬ approximate shape of the present invention wherein a heat exchanger arrangement a first Wärmeübertragervorrichtung and egg ne second heat transfer device, which are coupled together; and

FIG. 5 shows a schematic representation of a conventional heat exchanger arrangement for a turbine.

Detailed description of exemplary Ausführungsfor ^¬ men the same or similar components are designated in the figures with the same reference numerals. The illustrations in the figures are schematic and not to scale.

Fig. 1 shows a heat exchanger arrangement 100 for heating a working gas for a turbine 130 of a Druckluftspei ^¬ cherkraftwerks 120. A working gas can be taken from a pressure ^¬ space 160, such as an underground cavity and the heat exchanger arrangement 100 to a first gas inlet first with a Temperature T _E i be supplied. Further, the heat exchanger assembly 100 is coupled to a heat generating device 140. From the heat generating device 140, a first heat energy supply Q _zu , i can be provided. Specifically, a heat medium such as hot water or hot exhaust gas be ^¬ riding provided a gas turbine, the first heat medium inlet 103rd

The working gas passes first to the pressure chamber 160, the heat exchanger arrangement 100 and is discharged to a first training outlet temperature T _A i to the first gas outlet 111 of the heat ^¬ transmitter arrangement 100th The working gas is supplied to the turbine 130 at the first outlet temperature T _A i. The working gas passes through the individual turbine stages I to III in the direction of flow until it finally flows out of the turbine 130. In this case, the energy of the working gas is converted into mechanical ^¬ cal work by means of the turbine 130 and thereby a generator 150, in particular for power generation, operated. In order to increase the efficiency, the turbine 130 is at least partially removed from the working gas at the second inlet temperature T _E 2 and supplied to a second gas inlet 102 of the heat exchanger arrangement 100. The working gas passes through again ^¬ around the heat exchanger arrangement 100 and heated to a second outlet temperature T _A 2. From a second gas outlet 112, the working gas with the second outlet temperature TA2 of the turbine 130 is supplied again. This intermediate heating of the working gas increases the efficiency of the turbine 130.

As shown in FIG. 1, the turbine 130 includes a first turbine stage I, a second turbine stage II, and a third turbine stage III (or another plurality of turbine stages). The turbine stages I to III are each arranged successively in the flow direction of the working gas through the turbine 130. The working gas, which is partially removed from the pressure ^¬ space 160 and is provided after heating of the first gas outlet 111 with a first outlet temperature T _A i, is generally the first turbine stage I supplied. The tapping of the working gas and the supply to the second gas inlet 112 of the heat exchanger assembly 100 usually takes place in one of the following turbine stages II, III. For example, the working gas between see the first turbine stage I and the second Turbinenstu ^¬ Fe II taken and fed to the second gas inlet 102. After heating of the working gas from the second inlet temperature T _E 2 to the second outlet temperature T _A 2, the working gas is warmed ^¬ it provides to the second outlet 112 and again bereitge- the turbine 130 is supplied. In this case, the working gas with the second outlet temperature T _A 2 example, ^¬ near the place of removal, that is supplied in the above example between the first turbine stage I and the second turbine stage II. Alternatively, the heated working gas can also be supplied to a subsequent turbine stage, for example between the second turbine stage II and the third turbine stage III. The heating medium flows through the heat exchanger arrangement 100 and leaves it with a first waste heat Q _a b, i.

FIG. 2 shows a further exemplary embodiment of the present invention, in which the working gas is taken from the turbine 130 at several points and is heated up by means of the heat exchanger arrangement 100. As shown in FIG. 2, initially with the heat exchanger ^arrangement 100, the working gas having a first inlet temperature T _E i from the pressure chamber 160 is made available to the first gas inlet 101 of the heat exchanger arrangement 100. The heat exchanger arrangement 100 heated by the heating medium, the Ar ^¬ beitsgas to the first outlet temperature T _A i and makes the working gas ^¬ ses ready the first gas outlet 111th From the first gas outlet 111, the thus-heated working gas is supplied to the first turbine stage I.

The heating means is again provided by a heat generating ^device 140 and supplied to the heat medium inlet 103 with a first heat energy Qzu.

After the first turbine stage I, (part of) the working ^{gas is} taken from the turbine 130. This working gas is provided at a second inlet temperature T _E2 at the second gas inlet 102 of the heat exchanger arrangement 100 and heated therein. At a second gas outlet 112, the working gas has the second outlet temperature T _A2 , which is higher than the second inlet temperature T _E2 . The working gas is supplied to the turbine 130 at the second outlet temperature T _A2 . In particular, the thus heated working gas in the vicinity of the working gas sampling supplied, that is also between the first turbine stage I and the second turbine stage II. The pressure of the working gas is formed between the Ent ^¬ acquisition after the first turbine stage I and re Alloca- tion of the second turbine stage II kept almost constant, thus avoiding energy loss. Further, Fig. 2 shows a further removal (a part of) the working gas to the second turbine stage II. The working ^¬ gas is again drawn off after the second turbine stage II and supplied with a third inlet temperature T _E 3 the further second gas inlet 201 of the heat exchanger arrangement 100th The heating medium heats the working gas to the third outlet temperature T _A 3. From another second gas outlet 202, the working gas with the third outlet temperature T _A 3 between the second turbine stage II and the third turbine stage III is supplied.

Thus, a common heat means heat exchanger assembly 100 may inter-warm the working gas between a plurality of turbine stages I-III to thereby produce high turbine 130 efficiency. The heat medium leaving the heat exchanger arrangement 100 to a first waste heat Q _ab, i-, since the heat medium more passages of Ar ^¬ beitsgases through the heat exchanger arrangement 100 as shown in Fig. 2, heated, the heating means can more heat energy to the working gas Actions , so that thereby the effi ciency of the heat exchanger arrangement is increased ^¬ 100th

FIG. 3 shows a further exemplary embodiment of the present invention, in which the heat exchanger arrangement 100 has a first heat exchanger device 301 and a second heat exchanger device 302.

The first heat exchanger device draws the working gas with the first inlet temperature T _E i from the pressure chamber 160. Furthermore, a heat ^¬ medium with a first heat energy Q _to , i from the wärmeerzeu ^¬ ing device 140 at the first heat inlet 103. In the first heat transfer device 301, the working gas flows between the first gas inlet 101 to the first gas outlet 111 and is heated from the first input temperature T _E i by means of the heating means to the first outlet temperature T _A i. From the first gas outlet 111, the working fluid flows to the turbine 130 and in particular to the first turbine stage I, to operate the Turbi ^¬ ne 130th

After the heating means has heated the working gas to the first exhaust temperature T _A i, this is with a first Abwär ^¬ me Qab, removed i.

Furthermore, FIG. 3 shows a second heat transfer device 302. The heat transfer device 302 has the second gas inlet 102 and the second gas outlet 112. Of the

Turbine 130, the working gas can be tapped and provided by means of the second input temperature T _E 2 the second gas inlet 102. After heating the working gas to the second outlet temperature T _A 2, the working gas is provided to the second gas outlet 112 and supplied to the turbine 130 again.

According to FIG. 3, for example, the working gas is taken from the second turbine stage II and fed again to the subsequent third turbine stage III. The second heat ^¬ tragervorrichtung 302 may let through a second Wärmemittelein- 303, for example, the heating means with the first heat ^¬ power supply Q _to refer i from the heat generating device 140th In this embodiment, one and the same heat generating device 140 may supply a plurality of heat transfer devices 301, 302 with heat.

Alternatively or additionally, for example, a further heat-generating device 340 may be provided, which provides a further heat means with a second heat energy Q _to , 2 the further heat medium inlet. After heating the working gas from the second input temperature T _E 2 to the second outlet temperature T _A 2, the further heating means with a second waste heat Q _a b, 2 discharged from the second Wärmeübertrager- device 302.

With this embodiment, it is possible meh ^¬ rere different heat generating devices 140, 340th to use. By way of example, the heat-generating ^device 140 may represent a gas turbine and supply hot exhaust gas to the first heat exchanger device 301. The further heat generating device 340 may represent, for example a so ^¬ larkraftwerk, and by solar energy a further heating means, such as to heat for example water or oil, and this out as a second thermal energy input Q _to, 2 of the second Wärmeübertragervorrichtung 302nd

Fig. 4 shows a further exemplary embodiment, wel ^¬ che substantially the same features of the execution form of Fig. 3 has. The heat exchanger assembly 100 includes the first heat transfer device 301 and the second heat transfer device 302.

Additionally or alternatively to the exemplary embodiment of FIG. 3, the exemplary execution 4 shows form of FIG. A Wärmemittelauslass 401 of the first Wärmeübertragervorrichtung 301. About the Wärmemittelauslass 401, the heat medium after it heats the working gas in the first Wär ^¬ meübertragervorrichtung 301 with a first waste heat Qab, i dissipated. The Wärmemittelauslass 401 and the second heat medium inlet 303 are in such a manner gekop ^¬ pelt that the heating means with the first waste heat Q _ab, i the second heat medium inlet 303 is fed. The heating means with the first waste heat Q _a b, i from the first heat exchanger ^¬ device 301 is thus supplied as a heating means with a second heat energy Q _to , 2. Thus the heat with ^¬ tel is withdrawn more heat energy in the overall process and the unge ^¬ took advantage of waste heat reduces. The overall efficiency of the heat ^¬ transfer assembly 100 and thus the compressed air storage power ^¬ plant 120 is thereby increased.

In addition, it should be pointed out that "comprehensive" does not exclude any ^other elements or steps and "one" or "one" does not exclude a large number. Further thereon was hingewie ^¬ sen that features or steps which have been described with reference to one of the above embodiments, also be used in combination with other characteristics or steps of other exemplary embodiments described above Kgs ^¬ NEN. Reference signs in the claims are not to be considered as limiting.

Claims

claims

A heat exchanger assembly (100) for heating a working gas for a turbine (130) of a compressed air storage power plant (120) having the heat exchanger assembly (100)

a first gas inlet (101) which can be coupled to a pressure chamber (160) of the compressed air storage power plant (120) so that a working gas with a first input temperature (T _E i) from the pressure chamber (160) to the heat exchanger assembly (100) can be fed .

a first gas outlet (111) which can be coupled to the turbine (130) so that the working gas can be supplied to the turbine (130) from the heat exchanger arrangement (100) at a first outlet temperature (T _A i),

a second gas inlet (102) which can be coupled to the turbine (130) so that the working gas temperature to a second input _(E 2) of the turbine (130) to the heat ^¬ transmitter arrangement (100) can be fed,

 a second gas outlet (112) connected to the turbine

(130) is coupled, so that the working gas with a second outlet temperature (T ^) from the heat exchanger assembly (100) to the turbine (130) can be supplied,

 wherein a heating means is supplied in such a way that a) the working gas from the first inlet temperature

(T _E i) can be heated to the first outlet temperature (T _A i), and b) the working gas from the second input temperature (T _E 2) to the second outlet temperature (T ^) is heated.

2. The heat exchanger assembly (100) of claim 1, further comprising

a further second gas inlet (201) which can be coupled to the turbine (130), so that the working gas can be supplied to the heat exchanger arrangement (100) from the turbine (130) with a further second inlet temperature (T _E3 ), and

a second second gas outlet (202) which is coupled to the turbine (130), so that the working gas with a further second outlet temperature (ΤΆ ₂ ) from the heat exchanger assembly (100) to the turbine (130) can be fed, wherein the heating means is supplied such that c) the working gas from the further second input temperature (ΤΈ ₃ ) to the further second outlet temperature (T _A3 ) is heated.

3. The heat exchanger assembly (100) of claim 1 or 2, further comprising

a first Wärmeübertragervorrichtung (301) having the first gas inlet (101), the first gas outlet (111) and ei ^¬ NEN first heat medium inlet (103), and

 a second heat transfer device (302) having the second gas inlet (102), the second gas outlet (112) and a second heat medium inlet (303).

4. heat exchanger arrangement (100) according to claim 3,

 wherein the first heat medium inlet (103) and the second heat medium inlet (303) can be coupled to a heat-generating device (140).

5. heat exchanger assembly (100) according to claim 3 or 4, wherein the first heat transfer device (301) a

Wärmemittelauslass (401) for discharging the heating means with a first waste heat (Q _a b, i),

 wherein the Wärmemittelauslass (401) and the second

Heat medium inlet (303) are coupled to each other such that the heating means with the first waste heat (Q _ab , i) the second ^¬ th heat medium inlet (303) can be fed.

6. heat exchanger arrangement (100) according to claim 3,

wherein the first heat medium inlet (103) is coupled to a sea would ^¬ forming apparatus (140), and

 wherein the second heat medium inlet (303) can be coupled to a further heat-generating device (340).

7. Compressed air storage power plant (120), comprising

a pressure chamber (160), a turbine (130), and

 A heat exchanger assembly (100) according to any one of claims 1 to 6.

8. compressed air storage power plant (120) according to claim 7,

wherein the turbine (130) comprises a first turbine stage (I) and a second turbine stage (II), wherein the second turbine stage (II) with respect to a flow direction of the working ^¬ gas in the turbine (130) downstream of the first turbine nenstufe (I ) is arranged

wherein the first gas outlet (111) of the heat exchanger arrangement (100) is coupled to the turbine (130) such that the working gas can be supplied to the first outlet temperature (T _A i) of the first turbine stage (I),

 wherein the second gas inlet (102) of the heat exchanger assembly (100) is coupled to the turbine (130) such that the working gas at the second inlet temperature is removable between the first turbine stage (I) and the second turbine stage (II) and the heat exchanger assembly (100 ), and

 wherein the second gas outlet (112) of the heat exchanger assembly (100) is coupled to the turbine (130) such that the working gas at the second outlet temperature (T ^) of the second turbine stage (II) can be fed.

9. compressed air storage power plant (120) according to claim 7 or 8, wherein the pressure chamber (160) formed in an underground Kavit ity.

10. A method for heating a working gas for a turbine (130) of a compressed air storage power plant (120), the Ver ^¬ drive having

Supplying the working gas with a first inlet temperature (T _E i) from a pressure chamber (160) of the compressed air storage power plant (120) to a first gas inlet (101) of a heat exchanger arrangement (100), Heating the working gas from the first input Tempe ^¬ temperature (T _E i) to a first outlet temperature (T _A i) by means of ei ^¬ nes heat means,

Supplying the working gas at the first outlet temperature (T _A i) from the heat exchanger arrangement (100) to the turbine (130),

Supplying the working gas at a second inlet temperature ( _E2 ) from the turbine (130) to a second gas inlet (102) of the heat exchanger assembly (100),

Heating the working gas from the second input Tempe ^¬ temperature (T _E2 ) to a second outlet temperature (T ^) by means of the heating means, and

Supplying the working gas with the second Auslasstempe ^¬ temperature (T _A2) of the heat exchanger arrangement (100) to the turbine (130).