PL236372B1 - Installation for storage of energy in condensed air and for recovery of energy, with the steam module - Google Patents

Description

Description of the invention

The subject of the invention is an adiabatic installation for energy storage in liquefied air and energy recovery with a steam module.

There are known liquefied air energy storage systems of the LEAS type (Liquid Air Energy Storage) with equipment for heat and cold recovery, equipped with installations for compressing air and passing it through heat exchangers for preliminary cooling. Then the air is expanded on the turbine, where it partially condenses, and it is also possible to recover some of the energy put into its compression. The condensed air is stored. When the storage is discharged, the condensed air gives off some of the coolness and then expands on the turbine, enabling energy to be recovered.

Patent application US2017016577 discloses a LEAS system with increased efficiency, in which at least two high and low pressure expanders integrated at the outlet with the installation for heat recovery from the exhaust air stream are used for energy recovery.

The patent application US2012151961 and US2015192065 describe LEAS systems integrated with gas turbines, with the possibility of connecting a steam generator to increase the efficiency of the system. In these solutions, air condensation and gasification processes are combined through heat exchangers and gas turbine installations in order to recover some of the energy necessary for the condensation process.

The patent application PL421441 describes an adiabatic installation for energy storage in liquefied air and energy recovery, having a multi-stage air compression and cooling installation consisting of compressors connected in series alternately with successive heat exchangers, and a multi-stream exchanger on the last stage of cooling. The multi-stream exchanger is connected at the outlet to a liquid phase and gas phase separator. The liquid phase is routed to the storage vessel and the gas phase is returned through the recirculation circuit to the first compression stage. The liquid phase regasification system has a regasification circuit connecting the storage vessel to the expansion gas turbine. Other heat exchangers are connected to the regasification circuit to optimize the heat flow between the regasification circuit and the multi-stream exchanger. The last heat exchanger of the regasification system, connected to the regasification circuit upstream of the gas turbine, is part of the heating circuit to which is connected the storage of hot and cold media flowing through the heat exchangers of the multi-stage cooling system. In this solution, an oxygen separation module was connected to the regasification system in order to increase the profitability of the investment.

The aim of the invention is to increase the efficiency of the adiabatic energy storage system in liquefied air by using an additional steam module.

Installation for energy storage in liquefied air and energy recovery with a steam module, having a multi-stage air compression and cooling installation consisting of compressors connected in series alternately with subsequent heat exchangers, a multi-stream exchanger on the last cooling stage connected at the outlet with a liquid phase and gas phase separator, a liquid phase storage tank, a gas phase recirculation circuit, a liquid phase regasification system with a regasification circuit connecting the storage vessel to the expansion turbine, and other heat exchangers to optimize the heat flow between the regasification circuit and the multi-stream exchanger, the last of these heat exchangers connected to the circuit Regasification before the expansion turbine, is part of the heating circuit connecting the hot and cold medium storage flowing through the heat exchangers of the multi-stage compression and cooling system, according to the invention, that the steam module consists of a steam mixer connected by a steam pipe to a steam generator powered by an external water source, the regasification circuit being connected to the expansion turbine via a steam mixer, and the steam generator heating circuit connected to the heating circuit between the hot medium store and the last exchanger heat of the regasification circuit.

In the solution according to the invention, air is condensed and re-gasified in one installation, with the possibility of a quick increase in the efficiency of the system by activating the steam module, increasing the amount of the medium expanded on the turbine.

The invention is elucidated by an embodiment in the drawing, in which Fig. 1 shows a flow diagram of the plant and Fig. 2 shows a block diagram of an adiabatic liquefied-air energy storage system with a steam module.

PL 236 372 B1

As shown in Fig. 1, energy storage in liquefied air consists of the process of condensing the air by pre-compressing, cooling and choking, and its storage in insulated tanks after the separation of the liquid phase from the gas phase. The gas phase is mixed with the intake air. The stored condensed air is used after regasification to generate electricity through expansion in an expansion turbine. In such a system, electricity is used to power the compressors. The turbine is connected to the generator and allows you to get electricity again at a convenient time. In order to increase the economic profitability of the system, an additional steam module was used, fed from an external source of pressurized water, which increases the amount of the medium expanded on the turbine and influences its thermodynamic parameters, which allows to significantly increase the efficiency of the energy storage.

The whole process can be divided into three phases: loading, storage and unloading. Charging starts outside of the hours of increased energy demand, especially when there is a surplus of energy in the grid and it is relatively cheap. The compressed and cooled gas goes to the throttle valve, where it cools down and partially condenses due to the negative Joule-Thomson effect. The liquid phase is stored. When the demand for electricity increases, the pressure of the liquid is increased by a cryogenic pump. In the discharge phase, the liquid phase is regasified by heating with the use of previously stored refrigerant operating in circulation with subsequent heat exchangers of the recirculation system. The gas is then directed to an expansion turbine connected to a generator to recover energy. A steam module was added to improve the economic efficiency of the warehouse. The steam is produced at the expense of the heat resulting from the initial compression of the air and then stored in the hot liquid working medium, for example in high-boiling oil. The steam is then mixed with the re-gasified air and the combined stream of air and steam is directed to the expansion turbine.

As shown in Fig. 2, the installation for condensed air energy storage and energy recovery with a steam module E has, downstream of the air inlet 1, a multi-stage air compression and cooling system consisting of compressors 3, 5, 7 connected in series, alternating with heat exchangers 4, 6. 8. The last stage of cooling is a multi-stream exchanger 9 connected downstream to a liquid phase and gas phase separator 11. The liquid phase flows into the storage tank 15. The gas phase flows through the multi-stream exchanger 9 and then through the recirculation circuit 14 to the mixer 2 downstream of the air inlet 1 to the air circuit A, which includes a multi-stage air compression and cooling system.

The liquid phase regasification system has a regasification circuit 25 connecting the storage vessel 15 to the expansion turbine 21. Other heat exchangers are connected to the regasification circuit 25 to optimize the heat flow between the regasification circuit 25 and the multi-stream exchanger 9. The last heat exchanger 19, connected to the regasification circuit 25 before expansion turbine 21, is part of the heating circuit D connecting the hot medium storage 32 and the cold medium storage 33 with heat exchangers 4, 6, 8 of a multi-stage compression and cooling system. The steam module E consists of a steam mixer 20 connected by a steam pipe to a steam generator 29 supplied by an external water source. The regasification circuit 25 is connected to the expansion turbine 21 via a steam mixer 20 and the heating circuit of the steam generator 29 is connected to the heating circuit D between the hot medium store 32 and the last heat exchanger 19 of the regasification circuit 25. The heating circuit D connects the inlet and outlet sides of the heat exchangers 4, 6, 8, multi-stage air compression and cooling installation. These exchangers are part of the heating circuit D. The heating circuit D also includes a collective mixer 28 connecting the medium outlet streams from heat exchangers 4, 6, 8, and a divider 27 dividing the stream of cold medium from the store 33 into three streams directed to the first 4, the second 6 and a third heat exchanger 8. The hot medium from the bulk mixer 28 goes to the store 32, and then flows through the steam generator 29, where it gives off heat. Then, a part of the low-temperature heat of this stream is transferred to the air in the last heat exchanger 19, from where the fluid stream is directed to the cold fluid store 33.

The charging phase begins at the air inlet 1, where the atmospheric air is combined with the recirculation cycle stream 14 and is directed via the first mixer 2 to the first compressor 3, then to the first heat exchanger 4, where the air is cooled. Then, the air stream is directed to the second compressor 5, from which it goes to the second heat exchanger 6, and then to the third compressor 7 and the third heat exchanger 8. In the next step, the air stream goes to the multi-stream exchanger 9, where another cooling process takes place. From the exchanger

Due to the multi-jet 9, the air flow is directed to the throttle valve 10, where it partially condenses due to the Joule-Thompson effect. The resulting two-phase stream then enters the phase separator 11, where it is separated into a liquid and a gas phase. The gas phase is directed by the upper connector 13 to the multi-stream exchanger 9 where it is heated and then flows through the recirculation circuit 14 to the first mixer 2 of the air circulation A. The liquid phase is directed through the lower connector 12 to the storage tank 15. When the energy demand grows, the regasification process begins . The liquid air from the storage tank 15 is directed to the cryogenic pump 16, where it is pressurized and then heated in the fourth exchanger 17, then in the fifth exchanger 18, and then the last heat exchanger 19 upstream of the expansion turbine 21. The fourth heat exchanger 17 is part of the first refrigerating cycle B, which also includes the first cold medium tank 25, the multi-stream exchanger 9, and the first warm medium tank 26. The fifth exchanger 18 is part of the second refrigerating cycle C, which also includes the second cold medium tank 23, the multi-stream exchanger 9 and second hot medium tank 24. The air heated in the last heat exchanger 19 is directed to the expansion turbine 21 or mixed with the steam flow from the steam module E in the steam mixer 20. After the steam module E is started, the expansion turbine 21 receives combined streams of steam and air. The expansion turbine 21 is connected to an electric power generator. The steam and air stream from behind the turbine is discharged through the outlet 22.

Claims (1)

Patent claim 1. Installation for energy storage in liquefied air and energy recovery with a steam module, having a multi-stage air compression and cooling installation composed of compressors connected in series alternately with heat exchangers, a multi-stream exchanger on the last stage of cooling connected at the outlet with a liquid phase and gas phase separator , a liquid phase storage tank, a gas phase recirculation circuit, a liquid phase regasification system with a regasification circuit connecting the storage vessel to the expansion turbine, and other heat exchangers to optimize the heat flow between the regasification circuit and the multi-stream exchanger, the last of these heat exchangers connected to the regasification circuit before the expansion turbine is part of the heating circuit connecting the hot medium storage and the cold medium storage flowing through the heat exchangers of the multi-stage compression and cooling system, characterized in that the steam module (E) consists of a steam mixer (20) connected by a steam line to a steam generator (29) fed by an external water source, the regasification circuit (25) being connected to the expansion turbine (21) via the steam mixer (20) and the circuit a heating steam generator (29) is connected to a heating circuit (D) between the hot medium store (32) and the last heat exchanger (19) of the regasification circuit (25).