SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED AIR ENERGY WITH CONSTANT VOLUME HEATING

专利摘要:
The invention relates to a system and method for storage and energy recovery by compressed gas, of the AACAES type. The system and method according to the invention implement a constant volume heating Q of the stored compressed gas, which makes it possible to increase the pressure of the stored compressed gas.
公开号:FR3034813A1
申请号:FR1553200
申请日:2015-04-13
公开日:2016-10-14
发明作者:David Teixeira
申请人:IFP Energies Nouvelles IFPEN；
IPC主号:

专利说明:

[0001] The field of the present invention relates to Compressed Air Energy Storage (CAES). In particular, the present invention relates to an AACAES (Advanced Adiabatic Compressed Air Energy Storage) system in which is provided the storage of air and the storage of the heat generated.
[0002] The political will to reduce greenhouse gases, or the desire to reduce energy dependence on fossil fuels leads to an increase in the share of renewable energy in the energy mix. These renewable energies can be wind and / or solar systems (photovoltaic or thermodynamic). The main defects of these systems are their fluctuations over time as well as the independence between production and need. For wind, for example, wind can be present when there is no need for consumption and absent when needed. It is also possible that the wind varies around a value and leads to fluctuating electrical production problematic for the power grid. The introduction of intermittent renewables into the energy mix is not a problem if the grid is robust, and the uncontrollable intermittent energy is only a small part of the energy. In the case of a high rate of intermittent energies, means of emergency energy production must be present on the network. But these means of relief are, for economic reasons, often systems producing greenhouse gases. If the share of intermittent energies becomes large, fluctuations may occur in the network and a time imbalance between supply and demand may occur. This imbalance is due to the fact that, even if the annual consumption is satisfied by the production, there may be a gap between the moment of production of energy and the need for consumption. To overcome this difficulty, several solutions have been proposed, including energy storage. The goal is to store the electricity when it is produced, then to restore it when needed. Since electricity can not be stored directly, it must first be transformed. This transformation can be chemical, electrochemical or mechanical. For example, this transformation may be a transformation into mechanical energy in the form of compressed air and / or heat. In a compressed air energy storage system (CAES), energy, which is to be used at another time, is stored as compressed air. For storage, energy, especially electrical, drives air compressors, and for destocking, the compressed air drives turbines, which can be connected to an electric generator. The yield of this solution is not optimal because part of the energy of the compressed air is in the form of heat which is not used. In fact, in the CAES processes, only the mechanical energy of the air is used, that is to say that all the heat produced during the compression is rejected. In addition, the efficiency of a CAES system is not optimal, because the system requires heating the stored air to achieve the relaxation of the air.
[0003] Indeed, by way of example, if the air is stored at 8 MPa (80 bar) and at room temperature and if it is desired to recover the energy by a relaxation, the decompression of the air will follow a curve. isentropic from the initial storage conditions (about 8 MPa and 300 K). The air is cooled to unrealistic temperatures (83 K or -191 ° C). It is therefore necessary to heat it, which can be done using a gas burner or other fuel. Several variants of this CAES system currently exist. Systems and methods include: Adaabatic Compressed Air Energy Storage (ACAES) in which air is stored adiabatically at the temperature due to compression. However, this type of system requires a large and expensive specific storage system. - AACAES (Advanced Adiabatic Compressed Air Energy Storage) in which air is stored at room temperature, and the heat due to compression is also stored in a TES heat storage system (of the English "Thermal 20 Energy Storage"). The heat stored in the TES is used to heat the air before it is released. When the implementation of compressed air energy storage has several compression stages, it is conceivable to store the heat of the intermediate stages of compression in a system dedicated to heat; and storing hot air at the outlet of the last compressor in a pressurized tank. This provides an implementation between ACAES and AACAES. Improvements in the AACAES systems have focused on the realization of the TES heat storage system by means of a fixed storage tank of heat storage material. Another solution envisaged for the TES heat storage system is the use of a heat transfer fluid for storing the heat resulting from compression to return it to air before expansion by means of heat exchangers. For example, patent application EP 2447501 describes an AACAES system in which oil, used as heat transfer fluid circulates in closed circuit to exchange heat with air.
[0004] Furthermore, the patent applications EP 2530283 and WO 2011053411 describe an AACAES system, in which the heat exchanges are carried out by a heat transfer fluid circulating in a closed circuit, the closed circuit comprising a heat transfer fluid reservoir.
[0005] 3034813 3 The compression and expansion means are not perfect. Therefore, the performance of these compression and expansion devices implies that it is not possible to recover, on relaxation, all of the energy introduced to the compression.
[0006] To increase the amount of energy recovered, the invention relates to a system and method for storage and energy recovery by compressed gas, of the AACAES type. The system and method of the invention utilize a constant volume heating of the stored compressed gas, thereby increasing the pressure of the stored compressed gas, which allows for improved efficiency of the system and process. The system and the method according to the invention The invention relates to a system for storage and energy recovery by compressed gas comprising at least one means for compressing said gas, a means for storing said compressed gas, at least one means for expansion of said compressed gas capable of generating energy, heat exchange means between said compressed gas and a heat transfer fluid. The system further comprises constant volume heating means of said stored compressed gas. According to the invention, said constant volume heating means comprise means for exchanging heat between said stored compressed gas and said coolant. According to an alternative embodiment of the invention, said means for storing said compressed gas comprises at least one substantially cylindrical reservoir comprising at least one inner and / or outer cylinder in which said heat transfer fluid circulates. Advantageously, said heat exchange means arranged between said compression means and said storage means of said compressed gas is a stepped heat exchanger able to store at least said coolant at different temperatures, said constant volume heating means being adapted to heat said compressed gas successively by said heat transfer fluid stored at different temperatures. According to one embodiment of the invention, said constant volume heating means are integrated in said compressed gas storage means. Alternatively, said constant volume heating means comprise at least one constant volume heating chamber, said heating chamber being external to the compressed gas storage means. According to one characteristic, said constant volume heating means 35 comprise heat exchange means with an external heat source.
[0007] In one aspect, said compressed gas storage means is comprised of a plurality of storage volumes connected to each other. According to one feature, said compression means is reversible for use as a detent.
[0008] Preferably, the system comprises a plurality of compression means between which are arranged heat exchange means, and a plurality of expansion means between which heat exchange means are arranged. Advantageously, said heat exchange means are means for heat exchange at constant pressure.
[0009] In addition, the invention relates to a method for storing and recovering energy by compressed gas, wherein the following steps are performed: a) compressing a gas; b) the compressed gas is cooled by heat exchange with a heat transfer fluid; C) the cooled compressed gas is stored; d) the stored compressed gas is heated to a constant volume; and e) the heated compressed gas is expanded to generate energy. According to the invention, the step of constant volume heating of the gas is carried out by means of said heat transfer fluid.
[0010] Advantageously, for the stage of constant volume heating of the gas, said heat transfer fluid is circulated in a substantially cylindrical compressed gas storage tank. According to one embodiment of the invention, the step of constant volume heating of the gas is carried out in a compressed gas storage means.
[0011] Alternatively, the constant volume heating stage of the gas is carried out in a constant volume heating chamber external to a compressed gas storage means. According to one characteristic, the step of constant volume heating of the gas is carried out at least partially by means of an external heat source.
[0012] According to one aspect of the invention, the method comprises a step of heating the compressed gas by means of a coolant before the expansion step. Preferably, the compression and cooling steps are repeated by means of a plurality of compression means and heat exchange means with said heat transfer fluid and in which the expansion step is repeated by means of a plurality of Expansion means and means for heat exchange with the coolant. Advantageously, said heat transfer fluid is stored.
[0013] According to an alternative embodiment, the compressed gas is staged in a staged manner by storing the heat transfer fluid at different temperatures, and the constant volume heating step is carried out by successive heat exchanges with the heat transfer fluid at different temperatures.
[0014] Other features and advantages of the method according to the invention will be clear from reading the description hereafter of nonlimiting examples of embodiments, with reference to the appended figures and described hereinafter.
[0015] Figure 1 illustrates a storage and energy recovery system according to one embodiment of the invention. FIG. 2 illustrates an embodiment of a compressed gas storage means according to one embodiment of the invention. FIG. 3 illustrates an alternative embodiment of the system of FIG. 1.
[0016] FIG. 4 shows a second embodiment of the system of FIG. 1. FIG. 5 illustrates a second embodiment according to the invention of the energy storage and recovery system. DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a compressed gas energy storage and recovery system equipped with a heat storage means (AACAES). In this implementation, the air is stored cold. This air can be stored at constant volume. The system according to the invention comprises: at least one gas compression means (or compressor), and preferably several stepped gas compression means. The gas compression means may be driven by a motor, in particular an electric motor, at least one means for storing the compressed gas (also called reservoir) by the gas compression means. The compressed gas storage means may be a natural reservoir or not (for example an underground cavity). The compressed gas storage means may be at the surface or in the subsoil. In addition, it may be formed of a single volume or a plurality of volumes connected to each other or not, at least one gas expansion means (also called expansion valve or turbine) for relaxing the compressed gas and stored and Preferably, a plurality of staged gas expansion means. The gas expansion means 3034813 6 can generate an energy, in particular an electrical energy by means of a generator, heat exchange means, between the compressed gas and a coolant for cooling the compressed gas at the outlet of the medium. compressing gas 5 and / or for heating the compressed gas at the inlet of the gas expansion means. Preferably, the heat exchanges are carried out at constant pressure. In addition, the coolant can be liquid or gaseous, contain particles or not, and / or contain or not capsules of phase change material. The heat transfer fluid allows heat storage, constant volume heating means of the stored compressed gas to heat the stored compressed gas prior to its passage through the expansion means. The realization of the constant volume heating allows an increase in the temperature and pressure of the gas before the expansion (the induced increase in pressure can be deduced in particular from the law of the ideal gases), which allows an increase in energy recovered by the system and method according to the invention. Indeed, when it is desired to obtain mechanical energy from a hot gas under pressure through a turbine, it can be considered that the hot temperature corresponds to the available energy and that the high pressure corresponds to the possibility to recover the energy. Thus, constant volume heating (with increasing pressure) is more advantageous than constant pressure heating, as realized in a heat exchanger. In order to avoid heat losses, this constant volume heating is implemented just before the energy recovery during the expansion phase, which corresponds to the end of the storage of the compressed gas. The terms "staged compression or expansion means" are used when a plurality of compression or expansion means are successively mounted one after the other in series: the gas compressed or expanded at the outlet of the first compression or expansion means passes then in a second means of compression or relaxation and so on. A compression or expansion stage is then called a compression or expansion means for the plurality of staged compression or expansion means. Advantageously, when the system comprises a plurality of compression and / or expansion stages, a heat exchange means is disposed between each compression and / or expansion stage. Thus, the compressed air is cooled between each compression, which optimizes the efficiency of the next compression, and the expanded air is heated between each trigger, which optimizes the performance of the next trigger. The number of compression stages and the number of expansion stages 3034813 7 can be between 2 and 10, preferably between 3 and 5. Preferably, the number of compression stages is identical to the number of stages of compression. relaxation. Alternatively, the AACAES system according to the invention may contain a single compression means and a single means of relaxation. According to an alternative embodiment of the invention, the compression means can be reversible, that is to say they can function both for compression and for relaxation. Thus, it is possible to limit the number of devices used in the system according to the invention, which allows a gain in weight and volume of the system according to the invention. For this variant embodiment, the heat exchange means used between the compression stages may be those used between the expansion stages. The system according to the invention is suitable for any type of gas, especially for air. In this case, the inlet air used for the compression can be taken from the ambient air, and the exit air after the expansion can be released into the ambient air. In the remainder of the description, only the embodiment variant with compressed air will be described. However, the system and method are valid for any other gas. The heat exchange means make it possible, during the storage of the compressed gas (compression), to recover a maximum of heat resulting from the compression of the gas leaving the compressors and to reduce the temperature of the gas before the following compression or before storage. For example, the compressed gas may be passed from a temperature above 150 ° C, for example about 190 ° C to a temperature below 80 ° C, for example about 50 ° C. The heat exchange means make it possible, when the energy is restored, to restore a maximum of stored heat by increasing the temperature of the gas before passing to the next expansion. For example, the gas may pass from a temperature below 80 ° C, for example about 50 ° C, to a temperature above 150 ° C, for example about 180 ° C. According to a first embodiment of the invention, the constant volume heating means of the compressed gas are integrated in the storage means of the compressed gas. Thus, the constant volume heating is carried out directly in the storage tank of the compressed gas. It may be envisaged to heat a part (in which case the storage means are formed by a plurality of storage volumes) or the totality of the stored compressed gas. Constant volume heating can be achieved wholly or partly by the coolant used in the heat exchange means, and preferably by the coolant used in the heat exchanger disposed between the last compression stage and the medium. compressed gas storage. In addition, the constant volume heating may be carried out partially or completely by an external heat source, for example by means of a burner. Thus, it is possible to raise the temperature to a temperature higher than the temperature that can be provided by the heat transfer fluid alone. FIG. 1 illustrates a nonlimiting exemplary embodiment of this first embodiment according to the invention. This figure illustrates an AACAES system with stepped compression means, comprising two compression stages 11 and 12, and two heat exchangers 21 and 22. According to the illustrated example, the compression means 11 and 12 are reversible and serve also means of relaxation. In this figure, the circulation of air during energy storage (compression) is represented by a continuous arrow, and the circulation of air during the recovery of energy (relaxation) is represented by a 10 dotted arrow. The system includes a storage tank 30 for the compressed gas. A first heat exchanger 21 is interposed between the compression / expansion stages 11 and 12. A second heat exchanger 22 is interposed between the second compression stage (first expansion stage) and the reservoir 30. Classically, in the storage phase energy (compression), the air is first compressed in the first compressor 11, then cooled in the first heat exchanger 21, then compressed in the second compressor 12, and is then cooled in the second heat exchanger 22. The compressed and cooled gas is stored in the tank 30. The constant volume heating of the compressed gas is carried out in the storage tank 30, by means of a heat exchange Q with the heat transfer fluid of the second heat exchanger 22. The heat transfer fluid of the second heat exchanger 22 is hot following cooling of the compressed gas in the compression phase. During the recovery of the energy (expansion), the stored compressed gas is first heated at constant volume in the tank 30 by means of a heat exchange Q with the coolant of the second heat exchanger, then, can be heated in the heat exchanger 22 (especially if all the heat stored in the heat exchanger 22 is not used for constant volume heating). Then, in a conventional manner, the gas passes through one or more expansion stages (two stages according to the example illustrated in FIG. 1), with heating by the first heat exchanger 21 between the two expansion stages 12 and 11. The first embodiment is not limited to the example of FIG. 1. Other configurations may be envisaged: a different number of compression and / or expansion stages, the use of two separate circuits for compression and expansion, ... According to a tank design for this first embodiment of the invention, the storage tank for the compressed gas may be formed by at least one outer casing to resist the pressure of the compressed gas after reheating. In addition, the tank may have one or more heat transfer systems located at the periphery or in the heart of the air tank. FIG. 2 illustrates such an example of design of the compressed gas storage tank according to an axial section and a cross section. In this example, the air is stored in a substantially cylindrical reservoir 302. This cylinder may contain an inner cylinder 303 and / or an outer cylinder 301 in which circulates a heat transfer fluid (monophasic or multiphase) whose purpose is to bring the heat to the air. The walls of the tank allow to withstand the pressure and ideally to promote heat transfer. Finally, thermal insulation 304 may be added to minimize heat losses during heat transfer and after reheating. According to an alternative embodiment of this first embodiment of the invention, an additional cooler may be installed between a heat exchanger and the compressed gas storage tank. This cooler makes it possible to lower more significantly the storage temperature of the compressed gas; thus the pressure variation obtained during heating at constant volume is greater. FIG. 3 illustrates a nonlimiting exemplary embodiment of this variant embodiment of the first embodiment. The elements in common with the example of Figure 1 are not described in detail. The example of Figure 3 comprises a cooler 40 disposed between the second heat exchanger 22 and the storage tank 30 of the compressed gas. Thus, the compressed gas at the outlet of the second compressor is cooled a first time in the heat exchanger 22 by the coolant, then is cooled a second time by the cooler 40. At the outlet of the cooler 40, the compressed gas and cooled, is stored in the tank 30. During the recovery of energy (expansion), the stored compressed gas is first heated to constant volume in the tank 30 by means of a heat exchange Q with the coolant of the second heat exchanger, then can be heated in the heat exchanger 22. Then, conventionally, the gas passes through one or more expansion stages (two stages according to the example illustrated in Figure 3). This variant of the first embodiment is not limited to the example of FIG. 3, other configurations can be envisaged: a different number of stages of compression and / or relaxation, the use of two "circuits" This alternative embodiment can advantageously be combined with the design of the reservoir as illustrated in FIG. 2. According to another variant embodiment of this first embodiment, the exchanger of heat disposed between the last compression stage and the compressed gas storage tank is a stepped heat exchanger. A stepped heat exchanger allows the heat to be stored in several temperature stages. During the energy recovery (expansion) phase, the heat stored in each of these stages, from the coldest to the hottest, is used to heat the air in the tank (at constant volume). This embodiment allows a higher temperature rise of the gas stored in the tank. In order to obtain stages of quasi-fixed or fixed temperature, it is advantageous to use a coolant with capsules of phase change materials (PCM). It may also be advantageous for the fluid used to change phase (liquid / gas) during storage and removal of heat. FIG. 4 illustrates a nonlimiting exemplary embodiment of this variant embodiment of the first embodiment. The elements in common with the example of Figure 1, as well as the operation of the common elements of the system, are not described in detail. The example of FIG. 4 comprises a second stepped heat exchanger, comprising the successive stages 22, 22 'and 22 "(the number of stages is non-limiting). During the energy storage phase (compression) the gas at the outlet of the second compressor 12 is cooled to a first temperature 122 by the first stage of the heat exchanger and is then cooled to a second temperature 122 'by the second stage of the heat exchanger 22', the temperature 122 'being lower than the temperature 122. Then, the gas is cooled to a temperature 122 "by the third stage 15 of the heat exchanger 22", the temperature 122 "being lower than the temperature 122'. At the outlet of the third stage 22 "of the heat exchanger, the compressed and cooled gas is stored in the tank 30. During the recovery of the energy (expansion), the compressed gas stored is first heated to constant volume in the tank 30 by means of a heat exchange Q "with the heat transfer fluid of the third stage 22" of the heat exchanger, then by means of a heat exchange Q 'with the heat transfer fluid of the second stage 22 of the heat exchanger, then by means of a heat exchange Q with the coolant of the first stage 22 of the heat exchanger, after which the compressed gas can be heated in the heat exchanger 22, 22 ', 22 ". Then, in a conventional manner, the gas passes through one or more expansion stages.
[0017] This variant of the first embodiment is not limited to the example of FIG. 4, other configurations may be envisaged: a different number of compression and / or expansion stages, the use of two "circuits This embodiment variant may advantageously be combined with the variant embodiment of FIG. 3 and / or the design of the reservoir as illustrated in FIG. embodiment of the invention, the constant volume heating of the gas is carried out outside the storage tank of the compressed gas, in particular in at least one constant volume heating chamber. The constant volume heating chamber is external to the storage tank of the compressed gas. This embodiment makes it possible to limit the volume of gas to be heated, and to simplify the design of the compressed gas storage tank, since it does not need to withstand an increase in the pressure related to this heating, alone. the heating chamber, of limited volume, must withstand this pressure. In order to achieve continuous energy recovery, the system may include a plurality of parallel heating chambers. Thus, while one portion of the gas is heated in a heating chamber, another portion of gas may be introduced into another heating chamber. The heating of the constant volume heating chamber may be carried out wholly or partly by the heat transfer fluid used in the heat exchange means, preferably by the coolant used in the heat exchanger disposed between the last compression stage. and the storage means of the compressed gas. In addition, the constant volume heating may be carried out partially or totally by an external heat source, for example by means of a burner. Thus, it is possible to raise the temperature to a temperature higher than the temperature that can be provided by the heat transfer fluid alone. FIG. 5 illustrates a nonlimiting exemplary embodiment of this second embodiment according to the invention. This figure illustrates an AACAES system with staged compression means, comprising two compression stages 11 and 12, and two heat exchangers 21 and 22. As illustrated, the compression means 11 and 12 are reversible and also serve as means of relaxation. For the illustrated example, the flow of air during energy storage (compression) is represented by a continuous arrow, and the circulation of air during the recovery of energy (expansion) is represented by a dotted arrow. The system includes a storage tank 30 for the compressed gas. The compression and expansion steps are identical to the conventional compression and expansion steps described in connection with FIG. 1. The constant volume heating of the compressed gas is carried out in a heating chamber 50, by means of a exchange of heat Q with the coolant of the second heat exchanger 22. The heating chamber 50 is disposed between the tank 30 and the second heat exchanger 22. The heat transfer fluid of the second heat exchanger 22 is hot following the cooling of the compressed gas in the compression phase. Upon recovery of the energy (expansion), some or all of the stored compressed gas is first transferred to the heating chamber 50. Then the gas is heated to constant volume in the heating chamber 50 by means of a heat exchange Q with the coolant of the second heat exchanger, and can then be heated in the heat exchanger 22. Then, in a conventional manner, the gas passes through one or more expansion stages. The second embodiment is not limited to the example of FIG. 5 and other configurations may be envisaged: a different number of compression and / or expansion stages, the use of two distinct "circuits" In addition, the constant-volume heating chamber may be of similar design to the embodiment variant of FIG. 2. In addition, the variant embodiments of the first embodiment, in particular the use of a cooler and a stepped heat exchanger, can be combined with the second embodiment according to the invention.
[0018] The present invention also relates to a method for storage and recovery by compressed gas, wherein the following steps are carried out: a) a gas is compressed, in particular by means of an air compressor; b) the compressed gas is cooled by heat exchange with a coolant, in particular by means of a heat exchanger; C) the compressed compressed gas is stored, in particular by a compressed gas storage means; d) the stored compressed gas is heated to a constant volume; e) an optional step (implementation especially if, in step d), all the heat of the coolant is not used): the stored compressed gas is heated by heat exchange with the coolant; and f) the heated compressed gas is expanded to generate energy, for example by means of a turbine to generate electrical energy. According to one aspect of the invention, the method comprises several successive compression steps, by means of air compressors placed in series, also called stepped compressions. In this case, the steps a) and b) are repeated for each compression stage. Thus, the gas is compressed and cooled several times. According to one characteristic of the invention, the method comprises several successive expansion steps, by means of expansion placed in series, also called stepped detents. In this case, steps e) and f) are repeated for each expansion stage.
[0019] Thus, the gas is heated and relaxed several times. Step a) concerns the compression of a gas, for example air. It may include air taken from the environment. Step b) allows the compressed gas to be cooled after each compression step, which makes it possible to optimize the efficiency of the next compression and / or energy storage. Step b) is conventionally carried out by means of a heat exchanger. It can in particular be a heat exchanger in which the gas and heat transfer fluid circulate against the current. The heat exchange means make it possible, during the storage of the compressed gas (compression), to recover a maximum of heat resulting from the compression of the gas leaving the compressors and to reduce the temperature of the gas before the transition to the next compression. or before storage. For example, the compressed gas 3034813 13 may be passed from a temperature above 150 ° C, for example about 190 ° C to a temperature below 80 ° C, for example about 50 ° C. Step c) can be carried out in a compressed gas storage means, which can be a natural reservoir or not (for example an underground cavity). The compressed gas storage means may be at the surface or in the subsoil. In addition, it may be formed of a single volume or a plurality of volumes connected to each other or not. During storage, the means for storing the compressed gas are closed. The compressed gas is stored until the moment when it is desired to recover the stored energy. Step d) and the following are carried out at the moment when it is desired to recover the stored energy. Step d) makes it possible to heat the stored compressed gas before it passes through the expansion means. The realization of the constant volume heating allows an increase in the temperature and the pressure of the gas before the expansion (the induced increase in pressure can be deduced in particular from the ideal gas law), which allows an increase in the pressure of the gas. energy recovered by the system and method according to the invention. Indeed, when it is desired to obtain mechanical energy from a hot gas under pressure through a turbine, it can be considered that the hot temperature corresponds to the available energy and that the high pressure corresponds to the possibility to recover energy. Thus, constant volume heating (with increasing pressure) is more advantageous than constant pressure heating, as realized in a heat exchanger. In order to avoid heat losses, this constant volume heating is implemented just before the energy recovery during the expansion phase, which corresponds to the end of the storage of the compressed gas. Optional step e) allows the compressed air to be heated prior to each expansion, thereby optimizing the performance of the next trigger. Step e) is conventionally carried out by means of a heat exchanger which does not ensure a constant volume during the heat exchange. For step e), it is possible to use the coolant which is used to cool during step b). The heat exchange means make it possible, during the restitution of the energy, to restore a maximum of stored heat by increasing the temperature of the gas before passing to the next expansion. For example, the gas may pass from a temperature below 80 ° C, for example about 50 ° C, to a temperature above 150 ° C, for example about 180 ° C. In step f), the compressed gas is expanded. The expansion of the compressed gas makes it possible to generate an energy. This expansion can be achieved by means of a turbine which generates an electric energy. If the gas is air, the expanded air can be vented to the environment.
[0020] The constant volume heating may be carried out partially or completely by the coolant and / or by an external heat source, such as a burner. According to a first embodiment of the method according to the invention, this constant volume heating can be carried out within the storage tank of the compressed gas. In this case, the heat transfer fluid can be circulated within and / or around the compressed gas storage means so as to allow the exchange of heat. The gas can then be still. According to a second embodiment of the method according to the invention, this constant volume heating can be performed within a constant volume heating chamber, which is external to the storage tank of the compressed gas. In this case, it is possible to circulate the coolant within and / or around the heating chamber at a constant volume, so as to allow the exchange of heat. The gas can then be still. The method according to the invention can be implemented by the system according to any one of the variants of the invention described above: with or without the use of a complementary cooler to cool the compressed gas more significantly before storage and / or with or without use of a stepped heat exchanger for step heating of the compressed gas, and / or with or without the use of a cylindrical reservoir with an inner and / or outer cylinder in which the coolant circulates, for increase heat exchange.
[0021] The method and system according to the invention can be used for the storage of intermittent energy, such as wind or solar energy, in order to be able to use this energy at the desired time. 25

权利要求:
Claims (21)
[0001]
CLAIMS1) System for storage and energy recovery by compressed gas comprising at least one means for compressing said gas (11, 12), a storage means for said compressed gas (30), at least one expansion means (11, 12 ) of said compressed gas capable of generating energy, heat exchange means (21, 22) between said compressed gas and a coolant, characterized in that the system further comprises constant volume heating means of said compressed gas stored.
[0002]
2) System according to claim 1, wherein said constant volume heating means comprise heat exchange means between said stored compressed gas and said heat transfer fluid.
[0003]
3) System according to claim 2, wherein said means for storing said compressed gas comprises at least one reservoir (302) of substantially cylindrical shape comprising at least one inner cylinder (303) and / or outer (301) in which circulates said fluid coolant.
[0004]
4) System according to claim 2 or 3, wherein said heat exchange means disposed between said compression means (12) and said storage means of said compressed gas (30) is a stepped heat exchanger able to store at least said coolant at different temperatures, said constant volume heating means being adapted to heat said compressed gas successively by said heat transfer fluid stored at different temperatures.
[0005]
5) System according to one of the preceding claims, wherein said constant volume heating means are integrated in said compressed gas storage means (30).
[0006]
6) System according to one of claims 1 to 4, wherein said constant volume heating means comprise at least one heating chamber (50) at constant volume, said heating chamber (50) being external to the storage means of the compressed gas (30).
[0007]
7) System according to one of the preceding claims, wherein said constant volume heating means comprise means for heat exchange with an external heat source. 3034813 16
[0008]
8) System according to one of the preceding claims, wherein said compressed gas storage means (30) consists of a plurality of storage volumes connected to each other. 5
[0009]
9) System according to one of the preceding claims, wherein said compression means (11, 12) is reversible to be used as expansion means (11, 12).
[0010]
10) System according to one of the preceding claims, wherein the system comprises 10 a plurality of compression means (11, 12) between which are arranged heat exchange means (21, 22), and a plurality of means detent (11, 12) between which are arranged heat exchange means (21, 22).
[0011]
11) System according to one of the preceding claims, wherein said means 15 for heat exchange (21, 22) are means for heat exchange at constant pressure.
[0012]
12) A method of storage and energy recovery by compressed gas, wherein the following steps are performed: a) a gas is compressed; b) the compressed gas is cooled by heat exchange with a heat transfer fluid; c) the cooled compressed gas is stored; d) the stored compressed gas is heated to a constant volume; and e) the heated compressed gas is expanded to generate energy. 25
[0013]
13) The method of claim 12, wherein the constant volume heating step of the gas is performed by means of said heat transfer fluid.
[0014]
14) The method of claim 13, wherein, for the step of constant volume heating of the gas, said heat transfer fluid is circulated in a storage tank (30) of the substantially cylindrical compressed gas.
[0015]
15) A method according to one of claims 12 to 14, wherein the constant volume heating step of the gas is carried out within a compressed gas storage means (30). 3034813 17
[0016]
16) Method according to one of claims 12 to 14, wherein the constant volume heating step of the gas is performed in a heating chamber (50) constant volume external to a compressed gas storage means (30). 5
[0017]
17) Method according to one of claims 12 to 16, wherein the constant volume heating step of the gas is carried out at least partially by means of an external heat source.
[0018]
18) Method according to one of claims 12 to 17, wherein the method comprises a step of heating the compressed gas by means of a heat transfer fluid before the expansion step.
[0019]
19) Method according to one of claims 12 to 18, wherein the compression and cooling steps are repeated by means of a plurality of compression means (11, 12) and means for heat exchange with said heat transfer fluid (21, 22) and wherein the expansion step is repeated by means of a plurality of expansion means (11, 12) and means for heat exchange with the coolant (21, 22).
[0020]
20) Method according to one of claims 12 to 19, wherein said heat transfer fluid is stored.
[0021]
21) A method according to one of claims 12 to 20, wherein the compressed gas is stepped cooled storing the coolant at different temperatures, and the step of constant volume heating is carried out by successive heat exchanges with 25 the coolant at different temperatures.

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同族专利:

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公开号 | 公开日

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EP3283734B1|2019-03-27|

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ES2729063T3|2019-10-30|

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US20180094581A1|2018-04-05|

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US10480409B2|2019-11-19|

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EP3283734A1|2018-02-21|

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PT3283734T|2019-06-21|

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TR201908380T4|2019-06-21|

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FR3034813B1|2019-06-28|

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WO2016166095A1|2016-10-20|

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WO2020160635A1|2019-02-08|2020-08-13|Hydrostor Inc.|A compressed gas energy storage system|

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法律状态:
2016-04-21| PLFP| Fee payment|Year of fee payment: 2 |

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2016-10-14| PLSC| Publication of the preliminary search report|Effective date: 20161014 |

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2017-04-26| PLFP| Fee payment|Year of fee payment: 3 |

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2018-04-13| PLFP| Fee payment|Year of fee payment: 4 |

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2019-04-25| PLFP| Fee payment|Year of fee payment: 5 |

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2020-04-29| PLFP| Fee payment|Year of fee payment: 6 |

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2022-01-07| ST| Notification of lapse|Effective date: 20211205 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1553200|2015-04-13|

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FR1553200A|FR3034813B1|2015-04-13|2015-04-13|SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED AIR ENERGY WITH CONSTANT VOLUME HEATING|FR1553200A| FR3034813B1|2015-04-13|2015-04-13|SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED AIR ENERGY WITH CONSTANT VOLUME HEATING|

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ES16717316T| ES2729063T3|2015-04-13|2016-04-12|Compressed air storage and energy recovery system and procedure with constant volume heating|

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TR2019/08380T| TR201908380T4|2015-04-13|2016-04-12|System and process for energy storage and recovery via compressed air with constant volume heating.|

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PT16717316T| PT3283734T|2015-04-13|2016-04-12|System and method for compressed air energy storage and recovery with constant volume heating|

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US15/566,614| US10480409B2|2015-04-13|2016-04-12|Compressed air energy storage and recovery system and method with constant volume heating|

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PCT/EP2016/058001| WO2016166095A1|2015-04-13|2016-04-12|System and method for compressed air energy storage and recovery with constant volume heating|

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EP16717316.0A| EP3283734B1|2015-04-13|2016-04-12|System and method for compressed air energy storage and recovery with constant volume heating|