KR20220116739A - Liquid air energy storage system having carbon capture and storage function - Google Patents

Abstract

The present invention relates to a liquefied air energy storage system, comprising: a multi-stage structured air compressor which compresses air introduced from the outside; a plurality of compressor heat exchangers absorbing a compression heat generated from the multi-stage structured air compressor; a liquefied carbon dioxide separator disposed between a first compressor heat exchanger out of the plurality of compressor heat exchangers and a first air compressor out of multi-stage structured air compressors, and separating liquefied carbon dioxide from the air introduced from the first compressor heat exchanger; and a liquefied carbon dioxide tank storing the liquefied carbon dioxide separated through the liquefied carbon dioxide separator. The liquefied air energy storage system is capable of capturing and storing carbon dioxide in the air by utilizing the multi-stage structured air compressor and a thermal oil storage system.

Description

Liquefied air energy storage system capable of capturing and storing carbon dioxide {LIQUID AIR ENERGY STORAGE SYSTEM HAVING CARBON CAPTURE AND STORAGE FUNCTION}

The present invention relates to a liquefied air energy storage system, and more particularly, to a liquefied air energy storage system capable of capturing and storing carbon dioxide in the atmosphere.

Liquid Air Energy Storage System (LAES) is a technology that absorbs ambient air and converts compressed energy into state energy of liquefied air through a compression and cooling process and stores it.

Liquefied air energy storage system (LAES) is emerging as an eco-friendly energy storage system because energy is stored in a liquefied state, energy density is significantly higher than that of other storage systems, and the working fluid is air. In addition, the liquefied air energy storage system (LAES) is applicable to power generation systems such as industrial waste heat power generation, nuclear power generation, etc. because of high energy density, no geographical restrictions, and large size.

1 is a view for explaining the operation of a general liquefied air energy storage system (LAES). As shown in Figure 1, the general operation of the liquefied air energy storage system (LAES) is a charging (charging) process that converts air in the atmosphere to liquefied air by compressing / cooling / expanding, and storing the liquefied air in a tank It consists of a (storage) process and a discharging process that compresses/evaporates/expands the liquefied air stored in the tank to produce electric power.

Air used as the working fluid of this liquefied air energy storage system (LAES) is nitrogen (N ₂ , 78%), oxygen (O ₂ , 21%), argon (Ar, 0.93%), carbon dioxide (CO ₂ , 0.04%). ) and other various molecules, since the melting points of the molecules are different, molecules with high melting points such as water vapor (H ₂ O) and carbon dioxide (CO ₂ ) must be separated before the air compression and cooling process. Accordingly, in the existing liquefied air energy storage system (LAES), carbon dioxide and some water vapor are separated using a separation filtration membrane before air is compressed. The product has a short lifespan and has to be replaced frequently. Therefore, there is a need for a technique for effectively capturing carbon dioxide in the atmosphere.

SUMMARY OF THE INVENTION The present invention aims to solve the above and other problems. Another object of the present invention is to provide a liquefied air energy storage system capable of capturing and storing carbon dioxide in the atmosphere using a multi-stage air compressor and a heat oil storage system.

According to an aspect of the present invention in order to achieve the above or other object, the air compressor having a multi-stage structure for compressing air introduced from the outside; a plurality of compressor heat exchangers for absorbing compression heat generated in the multi-stage air compressor; It is disposed between the heat exchanger for a first compressor among the heat exchangers for the plurality of compressors and the first air compressor of the multi-stage air compressor to separate liquefied carbon dioxide from the air introduced from the heat exchanger for the first compressor. carbon dioxide separator; And it provides a liquefied air energy storage system comprising a liquefied carbon dioxide tank for storing the liquefied carbon dioxide separated through the liquefied carbon dioxide separator.

More preferably, the liquefied carbon dioxide separator is characterized in that the liquid carbon dioxide is separated from the gaseous air by using a difference in the melting point of molecules constituting the air.

More preferably, the liquefied air energy storage system further comprises a water vapor remover for removing water vapor contained in the air before compressing the air introduced from the outside.

More preferably, the liquefied air energy storage system comprises: a 3-way heat exchanger for cooling the air from which liquefied carbon dioxide has been removed using a predetermined heat transfer medium; a low-temperature turbine for expanding the air introduced from the 3-way heat exchanger; and a liquefied air separator for separating liquefied air from the air introduced from the low temperature turbine. and a liquefied air tank for storing the liquefied air separated through the liquefied air separator.

More preferably, the liquefied air energy storage system comprises: a cryogenic pump for compressing the working fluid flowing from the liquefied air tank; a 2-way heat exchanger for heating the working fluid flowing in from the cryopump; and an air turbine having a multi-stage structure for generating energy based on a working fluid introduced from the 2-way heat exchanger.

More preferably, the liquefied air energy storage system includes: a high-temperature heat oil tank for storing heat oil in a high-temperature state that has absorbed compression heat while passing through a plurality of compressor heat exchangers; a plurality of turbine heat exchangers for transferring the heat stored in the high-temperature heat oil tank to a working fluid input to the air turbine having a multi-stage structure; And it characterized in that it further comprises a low-temperature heat oil tank for storing the heat oil in a low-temperature state from which heat is taken through the plurality of turbine heat exchangers.

The effect of the liquefied air energy storage system according to embodiments of the present invention will be described as follows.

According to at least one of the embodiments of the present invention, carbon dioxide in the atmosphere can be completely separated without using a conventional separation filtration membrane by simply collecting carbon dioxide in the atmosphere using a multi-stage air compressor and a heat oil storage system, As a result, there is an advantage in that it is possible to effectively prevent global warming caused by air pollution.

In addition, according to at least one of the embodiments of the present invention, liquefied air generated by compressing/cooling/expanding external air is stored in a liquefied air tank, and the liquefied air stored in the liquefied air tank is compressed/heated/expanded to add By using it for power generation, it has the advantages of being eco-friendly, there are no geographical restrictions, and that energy can be efficiently stored.

However, the effects that can be achieved by the liquefied air energy storage system according to the embodiments of the present invention are not limited to those mentioned above, and other effects not mentioned are common in the technical field to which the present invention belongs from the description below. It can be clearly understood by those with the knowledge of

1 is a view for explaining the operation of a general liquefied air energy storage system (LAES);
2 is an overall configuration diagram of a liquefied air energy storage system (LAES) according to an embodiment of the present invention;
3 is an enlarged view of the process of separating carbon dioxide from the atmosphere in the liquefied air energy storage system (LAES) of FIG. 2 ;
4 is a view showing a charging process of a liquefied air energy storage system (LAES) according to an embodiment of the present invention;
5 is a view showing a discharge process of the liquefied air energy storage system (LAES) according to an embodiment of the present invention.

In describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in the present specification, the detailed description thereof will be omitted. In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed herein is not limited by the accompanying drawings, and all changes included in the spirit and scope of the present invention , should be understood to include equivalents or substitutes.

On the other hand, when a component is referred to as "connected" or "connected" to another component in the present specification, it may be directly connected or connected to the other component, but other components in the middle It should be understood that there may be On the other hand, when an element is referred to as being “directly connected” or “in direct contact with” another element, it should be understood that no other element is present in the middle. Other expressions for describing the relationship between elements, that is, expressions such as "between" and "immediately between" or "adjacent to" and "directly adjacent to", should be interpreted similarly.

In addition, the terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. As used herein, terms such as “comprises” or “have” are intended to designate the presence of an embodied feature, number, step, operation, component, part, or combination thereof, and include one or more other features or numbers, It should be understood that the possibility of the presence or addition of steps, operations, components, parts or combinations thereof is not precluded in advance.

The present invention proposes a liquefied air energy storage system (LAES) capable of capturing and storing carbon dioxide in the atmosphere by using a multi-stage air compressor and a heat oil storage system.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the drawings.

2 is an overall configuration diagram of a liquefied air energy storage system (LAES) according to an embodiment of the present invention.

Referring to FIG. 2 , the liquefied air energy storage system (LAES, 100) according to an embodiment of the present invention includes a water vapor eliminator 101, air compressors 102, 103, 104 having a multi-stage structure, and a heat oil storage system 105 to 115), liquefied carbon dioxide separator 116, liquefied carbon dioxide tank 117, heat exchange system 118-121, low temperature turbine 122, liquefied air separator 123, liquefied air tank 124, cryogenic pump 125 ), air turbines 126 and 127 of a multi-stage structure and a generator 128 may be included. On the other hand, although not shown in the drawing, the liquefied air energy storage system (LAES, 100) further includes a control device that can control the overall operation of the devices 101 to 128 constituting the system 100. can do.

The water vapor remover 101 may perform a function of removing water vapor contained in the air before compressing the air introduced from the outside. For example, the water vapor remover 101 may evaporate water vapor in the air using recycle air branched from the liquefied air separator 123 . At this time, the recirculated air is converted into a hot gas state through the 3-way heat exchanger 118 and then passes through the water vapor remover 101 . The recirculated air converted into a hot gas state evaporates water vapor in the air introduced from the outside.

The dehydrated air passing through the water vapor remover 101 moves to the air compressors 102 , 103 , and 104 having a multi-stage structure, and the recirculated air passing through the water vapor remover 101 is discharged to the outside.

The air compressors 102 , 103 , and 104 having a multi-stage structure may perform a function of sequentially compressing air introduced from the water vapor remover 101 to a predetermined pressure. The air passing through the air compressors 102, 103, and 104 of the multi-stage structure passes through a plurality of compressor heat exchangers 105, 106, 107 and a liquefied carbon dioxide separator 116 to a heat exchange system, that is, a 3-way heat exchanger. (118). That is, the air introduced from the water vapor remover 101 is converted from an atmospheric pressure state to a high pressure state and moves to the 3-way heat exchanger 118 .

In the air compressors 102, 103, and 104 having such a multi-stage structure, the first and second air compressors 102 and 103 may be disposed between the water vapor remover 101 and the liquefied carbon dioxide separator 116, and the third air Compressor 104 may be disposed between liquefied carbon dioxide separator 116 and 3-way heat exchanger 118 .

As each of the air compressors 102 , 103 , and 104 , either an axial compressor or a centrifugal compressor may be used. In addition, each air compressor 102 , 103 , 104 may consist of one or more rotor blades that rotate to provide energy to the fluid and one or more stator blades that decelerate the fluid to increase the pressure.

On the other hand, in the present embodiment, although the air compressors 102 , 103 , 104 of the multi-stage structure are exemplified by three air compressors, it is not necessarily limited thereto, and the number of air more or less than three is It will be apparent to those skilled in the art that it can be configured as a compressor.

The heat oil storage systems 105 to 115 absorb heat generated in the process of compressing air through the air compressors 102, 103, and 104 of the multi-stage structure, store the heat in the thermal oil tank, and store the heat stored in the heat oil tank in the multi-stage structure. of the air turbine (126, 127) can perform the function of delivering to the working fluid (ie, air) for driving.

The heat oil storage system 105 to 115 includes a plurality of compressor heat exchangers 105 to 107 , a plurality of turbine heat exchangers 108 and 109 , a low temperature heat oil tank 110 , a high temperature heat oil tank 111 , the first and It may include second branch valves 112 and 113 and first and second combined valves 114 and 115 .

The plurality of compressor heat exchangers 105, 106, and 107 exchange heat between thermal oil discharged from the low-temperature heat oil tank 110 and the high-temperature compressed air discharged from the air compressors 102, 103, and 104 having a multi-stage structure. processing can be performed. That is, the plurality of compressor heat exchangers (105, 106, 107) absorb the heat of the high-temperature compressed air discharged from the air compressors (102, 103, 104) of the multi-stage structure, and transfer the absorbed heat to the low-temperature heat oil tank (110). ) can be transferred to the heat oil discharged from the

The plurality of compressor heat exchangers 105 , 106 , and 107 may be respectively disposed at output ends of the air compressors 102 , 103 , 104 connected in a multi-stage structure. In this case, the number of compressor heat exchangers 105 , 106 , 107 installed in the heat oil storage system corresponds to the number of air compressors 102 , 103 , 104 connected in a multi-stage structure.

For example, the heat exchanger 105 for the first compressor is connected to the output terminal of the first air compressor 102 , and the air that has passed through the heat exchanger 105 moves to the second air compressor 103 . The heat exchanger 106 for the second compressor is connected to the output terminal of the second air compressor 103 , and the air that has passed through the heat exchanger 106 moves to the liquefied carbon dioxide separator 116 . The heat exchanger 107 for the third compressor is connected to the output terminal of the third air compressor 104 , and the air passing through the heat exchanger 107 moves to the 3-way heat exchanger 118 . At this time, the air passing through each compressor heat exchanger (105, 106, 107) is converted from a high temperature/high pressure state to a room temperature/high pressure state.

The plurality of turbine heat exchangers 108 and 109 may perform heat exchange processing between the heat oil discharged from the high-temperature heat oil tank 111 and the air input to the air turbines 126 and 127 having a multi-stage structure. That is, the plurality of turbine heat exchangers 108 absorb the heat of the heat oil discharged from the high-temperature heat oil tank 111 and transfer the absorbed heat to the air introduced into the inlets of the air turbines 126 and 127 having a multi-stage structure. can

The plurality of turbine heat exchangers 108 and 109 may be respectively disposed at input ends of the air turbines 126 and 127 connected in a multi-stage structure. At this time, the number of turbine heat exchangers 108 and 109 installed in the heat oil storage system corresponds to the number of air turbines 126 and 127 connected in a multi-stage structure.

For example, the first turbine heat exchanger 108 is connected to the output end of the 2-way heat exchanger 119 , and the air passing through the heat exchanger 108 moves to the first air turbine 126 . . The heat exchanger 109 for the second turbine is connected to the output end of the first air turbine 126 , and the air passing through the heat exchanger 109 moves to the second air turbine 127 . At this time, the air that has passed through each of the turbine heat exchangers 126 and 127 is converted from a low temperature state to a high temperature state.

The low-temperature heat oil tank 110 may store the low-temperature heat oil from which heat is taken through the plurality of turbine heat exchangers 108 and 109 . The high-temperature heat oil tank 111 may store the high-temperature heat oil that has absorbed heat while passing through the plurality of compressor heat exchangers 105 , 106 , and 107 .

The first branch valve 112 may branch the heat oil flowing from the low-temperature heat oil tank 110 in the direction of the plurality of compressor heat exchangers 105 , 106 , and 107 . The second branch valve 113 may branch the heat oil flowing from the high temperature heat oil tank 111 toward the plurality of turbine heat exchangers 108 and 109 .

The first merging valve 114 may perform a function of merging the heat oil flowing in from the plurality of compressor heat exchangers 105 , 106 , and 107 and providing it to the high temperature heat oil tank 111 . The second merging valve 115 may perform a function of merging the heat oil flowing in from the plurality of turbine heat exchangers 108 and 109 and providing it to the low-temperature heat oil tank 110 .

The heat oil used as the working fluid of such a heat oil storage system is a low temperature heat oil tank 110, a plurality of compressor heat exchangers 105, 106, 107, a high temperature heat oil tank 111, and a plurality of turbine heat exchangers 108, 109) to perform heat exchange treatment.

The liquefied carbon dioxide separator 116 is disposed between the heat exchanger 106 for the second compressor and the third air compressor 104, and separates the liquefied carbon dioxide from the air flowing in from the heat exchanger 106 for the second compressor. function can be performed.

More specifically, as shown in FIG. 3 , the air that has passed through one or more air compressors 102 and 103 is compressed and converted to a high temperature/high pressure state, and passes through one or more compressor heat exchangers 105 and 106 . One air is converted from high temperature/high pressure state to room temperature/high pressure state by absorbing heat. Through this compression process and heat exchange process, low-melting-point molecules such as nitrogen (N ₂ ) and oxygen (O ₂ ) in air remain in a gaseous state, and high-melting-point molecules such as carbon dioxide (CO ₂ ) in air will undergo a phase change from the gaseous state to the liquid state. Accordingly, the liquefied carbon dioxide separator 116 may separate the liquid carbon dioxide from the gaseous air by using the difference in the melting point of molecules constituting the air. Thereafter, the liquefied carbon dioxide separator 116 may provide the separated liquefied carbon dioxide to the liquefied carbon dioxide tank 117 .

The liquefied carbon dioxide tank 117 may perform a function of storing the liquefied carbon dioxide introduced from the liquefied carbon dioxide separator 116 . The liquid carbon dioxide stored in the liquid carbon dioxide tank 117 may be used for various purposes.

The heat exchange systems 118 to 121 use a heat transfer medium (ie, a refrigerant) to cool the air flowing in from the heat exchanger 107 for the third compressor and heat the liquefied air flowing in from the low temperature pump 125 . function can be performed. To this end, the heat exchange systems 118 to 121 may include a 3-way heat exchanger 118 , a 2-way heat exchanger 119 , a high temperature tank 120 , and a low temperature tank 121 .

The 3-way heat exchanger 118 may perform heat exchange treatment between the heat transfer medium discharged from the low temperature tank 121 and the compressed air flowing in from the heat exchanger 107 for the third compressor. That is, the 3-way heat exchanger 118 absorbs the heat of the compressed air flowing in from the heat exchanger 107 for the third compressor, and transfers the absorbed heat to the heat transfer medium discharged from the low-temperature tank 121 . have.

In addition, the 3-way heat exchanger 118 may perform a heat exchange process between the compressed air flowing in from the third compressor heat exchanger 107 and the air flowing in from the liquefied air separator 123 . That is, the 3-way heat exchanger 118 may absorb the heat of the compressed air flowing in from the heat exchanger 107 for the third compressor, and transfer the absorbed heat to the air flowing in from the liquefied air separator 123 . .

The compressed air introduced from the third compressor heat exchanger 107 is cooled to a cryogenic state while passing through the 3-way heat exchanger 118 and moves to the low temperature turbine 122 . The heat transfer medium introduced from the low-temperature tank 121 passes through the 3-way heat exchanger 118 to acquire heat and then moves to the high-temperature tank 120 . The air introduced from the liquefied air separator 123 passes through the 3-way heat exchanger 118 to obtain heat and then moves to the water vapor remover 101 .

The 2-way heat exchanger 119 may perform heat exchange treatment between the heat transfer medium discharged from the high temperature tank 120 and the working fluid (ie, air) flowing in from the low temperature pump 125 . That is, the 2-way heat exchanger 119 may absorb the heat of the heat transfer medium flowing from the high-temperature tank 120 , and transfer the absorbed heat to the working fluid flowing in from the low-temperature pump 125 .

The working fluid introduced from the low-temperature pump 125 is heated while passing through the 2-way heat exchanger 119 and moves to the first turbine heat exchanger 108, and the heat transfer medium introduced from the high-temperature tank 120 is It is cooled while passing through the 2-way heat exchanger 119 and moves to the low-temperature tank 121 .

The low-temperature tank 121 may store a heat transfer medium in a low-temperature state from which heat is deprived while passing through the 2-way heat exchanger 119 . The high temperature tank 120 may store a heat transfer medium in a high temperature state that has absorbed heat while passing through the 3-way heat exchanger 118 .

The heat transfer medium used as the working fluid of such a heat exchange system is subjected to heat exchange treatment while circulating the low temperature tank 121, the 3-way heat exchanger 118, the high temperature tank 120, and the 2-way heat exchanger 119. will perform As the heat transfer medium, a methane-based refrigerant, an ethane-based refrigerant, a propane-based refrigerant, etc. may be used, but is not necessarily limited thereto.

A cryogenic turbine 122 is disposed between the 3-way heat exchanger 118 and the liquefied air separator 123 to expand the high-pressure/cryogenic air introduced from the 3-way heat exchanger 118 . function can be performed. At this time, the low-temperature turbine 122 may liquefy about 85% or more of the air of the incoming air by changing the air introduced from the 3-way heat exchanger 118 from the high-pressure/cryogenic state to the low-pressure/cryogenic state. As such, the air that has passed through the low-temperature turbine 122 undergoes a phase change from a gaseous state to a liquid state.

The liquefied air separator 123 may be disposed between the low-temperature turbine 122 and the liquefied air tank 124 to perform a function of separating liquefied air from the air introduced from the low-temperature turbine 122 . The liquefied air separator 123 may provide the separated liquefied air to the liquefied air tank 124 , and provide the remaining gaseous air to the 3-way heat exchanger 118 .

The liquefied air tank 124 may perform a function of storing the liquefied air introduced from the liquefied air separator 123 .

A cryogenic pump 125 is disposed between the liquefied air tank 124 and the 2-way heat exchanger 119 to compress the working fluid (ie, liquefied air) flowing in from the liquefied air tank 124 . function can be performed.

That is, the low-temperature pump 125 pressurizes the liquefied air flowing in from the liquefied air tank 124 to a predetermined pressure (eg, 100 atm) or higher to change the air from a liquefied state to a vaporized state or a supercritical state. . At this time, the low-temperature pump 125 may change the liquefied air flowing in from the liquefied air tank 124 from a low pressure/cryogenic state to a high pressure/cryogenic state.

The working fluid passing through the low-temperature pump 125 is converted to a room temperature/high pressure state while passing through the 2-way heat exchanger 119 and then moves in the direction of the air turbines 126 and 127 having a multi-stage structure.

The air turbines 126 and 127 having a multi-stage structure expand the high-temperature/high-pressure air that has passed through the heat exchangers 108 and 109 for a plurality of turbines and apply an impulse or reaction force to the rotor blades of the turbine to convert thermal energy into mechanical energy. can be converted The mechanical energy obtained through the air turbines 126 and 127 of the multi-stage structure is supplied as energy required to produce electricity in the generator 128 .

In the air turbines 126 and 127 having such a multi-stage structure, the first air turbine 126 may be disposed at an output stage of the heat exchanger 108 for the first turbine, and the second air turbine 127 is the second turbine. It may be disposed at the output end of the heat exchanger (109). The air passing through the second air turbine 127 is discharged to the outside.

Each of the air turbines 126 and 127 has two types, axial flow and centrifugal, and their use is divided according to power generation capacity. In one embodiment, each of the air turbines 126 and 127 may be used, but is not necessarily limited thereto.

On the other hand, in the present embodiment, the air turbines 126 and 127 of the multi-stage structure are exemplified by two air turbines, but the present invention is not necessarily limited thereto. It will be apparent to those skilled in the art that it can be configured.

The generator 128 is connected to the air turbines 126 and 127 of the multi-stage structure by a rotating member and is rotationally driven. The generator 128 may generate electricity by converting the mechanical energy supplied from the air turbines 126 and 127 of the multi-stage structure into electrical energy. As the generator 128, any one of a DC generator and an AC generator may be used, and more preferably, an AC generator may be used.

As described above, the liquefied air energy storage system according to an embodiment of the present invention conveniently collects carbon dioxide in the atmosphere by using a multi-stage air compressor and a heat oil storage system, so that there is no need to use a conventional separation filtration membrane. Carbon dioxide can be completely separated, thereby effectively preventing global warming caused by air pollution. In addition, the liquefied air energy storage system stores liquefied air generated by compressing / cooling / expanding the surrounding atmosphere in a liquefied air tank, and compressing / heating / expanding the liquefied air stored in the liquefied air tank and using it for further power generation. , eco-friendly, has no geographical restrictions, and can store energy efficiently.

On the other hand, the overall operation of the liquefied air energy storage system (LAES, 100) is a charging process of producing and storing liquefied air by compressing the surrounding atmosphere, and a load response power is produced based on the liquefied air stored in the liquefied air tank. It consists of a discharging process.

4 is a diagram illustrating a charging process of a liquefied air energy storage system (LAES) according to an embodiment of the present invention. As shown in FIG. 4 , the air introduced from the outside passes through one or more air compressors 102 and 103 and one or more compressor heat exchangers 105 and 106 after the water vapor is completely removed through the steam eliminator 101 . will do

The air that has passed through the one or more air compressors 102 and 103 is compressed and converted to a high temperature/high pressure state, and the air that has passed through the heat exchangers 105 and 106 for one or more compressors absorbs heat to room temperature in a high temperature/high pressure state /converted to high pressure state. Through this compression process and heat exchange process, low-melting-point molecules (substances) such as nitrogen (N ₂ ) and oxygen (O ₂ ) in the air remain in a gaseous state, and are melted such as carbon dioxide (CO ₂ ) in the air. Molecules with high points undergo a phase transition from the gaseous state to the liquid state. Among them, the liquefied carbon dioxide is separated through the liquefied carbon dioxide separator 116 and stored in the liquefied carbon dioxide tank 117 . On the other hand, the gaseous air from which liquefied carbon dioxide has been removed sequentially passes through one or more air compressors 104 , one or more compressor heat exchangers 108 , a 3-way heat exchanger 118 , and a low temperature turbine 122 . .

The air that has passed through the one or more air compressors 104 is compressed and converted to a high temperature/high pressure state, and the air that has passed through the one or more compressor heat exchangers 107 absorbs heat from the high temperature/high pressure state to the room temperature/high pressure state. is converted And, the air that has passed through the 3-way heat exchanger 118 is cooled and converted from a room temperature/high pressure state to a cryogenic temperature/high pressure state, and the air that has passed through the low-temperature turbine 122 is expanded from a gaseous state to a liquid state. mutation will occur. Among them, the liquefied air is separated through the liquefied air separator 123 and stored in the liquefied air tank 124, and the remaining air excluding the liquefied air passes through the 3-way heat exchanger 118 and the water vapor remover 101 to the outside. is emitted with This series of operations is referred to as a charging process.

5 is a diagram illustrating a discharge process of a liquefied air energy storage system (LAES) according to an embodiment of the present invention. As shown in FIG. 5 , the liquefied air discharged from the liquefied air tank 124 sequentially passes through the low-temperature pump 125 and the 2-way heat exchanger 119 . The liquefied air that has passed through the low-temperature pump 125 is compressed and converted to a vaporized state or a supercritical state, and the air that has passed through the 2-way heat exchanger 119 is heated and converted into a gas at room temperature/high pressure.

The air passing through the 2-way heat exchanger 119 passes through one or more turbine heat exchangers 108 and 109 and is converted from a room temperature / high pressure state to a high temperature / high pressure state, and then the air turbines 126 and 127 of a multi-stage structure. is entered as The working fluid (ie, air) introduced from the one or more turbine heat exchangers 108 and 109 passes through the air turbines 126 and 127 having a multi-stage structure to generate additional power. This series of operations is referred to as a discharging process.

The charging and discharging processes of the liquefied air energy storage system (LAES, 100) may be alternately performed according to the output variability of the renewable energy source on the power system.

For example, the liquefied air energy storage system LAES 100 may perform a charging process of producing and storing liquefied air based on surplus energy on the power system when the first event occurs. In this case, the first event may be an excess power supply event that occurs according to the output variability of the renewable energy source on the power system.

On the other hand, the liquefied air energy storage system (LAES, 100), when the second event occurs, based on the liquefied air stored in the liquefied air tank may perform a discharging process for generating load corresponding power. In this case, the second event may be a power supply shortage event that occurs according to the output variability of the renewable energy source on the power system or an excessive power demand event that occurs according to the load variability of the consumer on the power system.

Meanwhile, although specific embodiments of the present invention have been described above, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the described embodiments, and should be defined by the following claims as well as the claims and equivalents.

100: liquefied air energy storage system 101: water vapor eliminator
102/103/104: air compressor 105/106/107: heat exchanger for compressor
108/109: heat exchanger for turbine 110: low-temperature heat oil tank
111: hot oil tank 112/113: branch valve
114/115: merge valve 116: liquefied carbon dioxide separator
117: liquefied carbon dioxide tank 118: 3-way heat exchanger
119: 2-way heat exchanger 120: hot tank
121 cold tank 122 cold turbine
123: liquefied air separator 124: liquefied air tank
125: cryogenic pump 126/127: air turbine
128: generator

Claims (6)

an air compressor having a multi-stage structure for compressing air introduced from the outside;
a plurality of compressor heat exchangers for absorbing compression heat generated in the multi-stage air compressor;
It is disposed between the heat exchanger for a first compressor among the heat exchangers for the plurality of compressors and the first air compressor among the air compressors having the multi-stage structure, and separates liquefied carbon dioxide from the air introduced from the heat exchanger for the first compressor. carbon dioxide separator; and
A liquefied air energy storage system comprising a liquefied carbon dioxide tank for storing the liquefied carbon dioxide separated through the liquefied carbon dioxide separator. According to claim 1,
The liquefied carbon dioxide separator separates the liquid carbon dioxide from the gaseous air by using a difference in the melting point of the molecules constituting the air. According to claim 1,
The liquefied air energy storage system further comprising a water vapor remover for removing water vapor contained in the air before compressing the air introduced from the outside. According to claim 1,
a 3-way heat exchanger for cooling the air from which the liquefied carbon dioxide has been removed using a predetermined heat transfer medium;
a low-temperature turbine for expanding the air introduced from the 3-way heat exchanger; and
a liquefied air separator for separating liquefied air from the air introduced from the low temperature turbine; and
The liquefied air energy storage system further comprising a liquefied air tank for storing the liquefied air separated through the liquefied air separator. 5. The method of claim 4,
a low-temperature pump for compressing the working fluid flowing in from the liquefied air tank;
a 2-way heat exchanger for heating the working fluid flowing in from the cryopump; and
The liquefied air energy storage system further comprising an air turbine having a multi-stage structure for generating energy based on the working fluid introduced from the 2-way heat exchanger. 6. The method of claim 5,
a high-temperature heat oil tank for storing heat oil in a high-temperature state that has absorbed compression heat while passing through the plurality of compressor heat exchangers;
a plurality of turbine heat exchangers for transferring the heat stored in the high-temperature heat oil tank to a working fluid input to the multi-stage air turbine; and
The liquefied air energy storage system further comprising a low-temperature heat oil tank for storing heat oil in a low-temperature state that has been deprived of heat while passing through the plurality of turbine heat exchangers.

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