• 专利附录
  • 专利说明
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  • 类似技术
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    • 专利摘要:
    The present invention relates to a system and method for storage and energy recovery by compressed gas (for example of the AACAES type) in which the heat storage is implemented by a radial heat exchange between the gas (G) and heat storage particles (3).
    公开号:FR3044751A1
    申请号:FR1561878
    申请日:2015-12-04
    公开日:2017-06-09
    发明作者:Elena Sanz;Cecile Plais;Willi Nastoll;Guillaume Vinay
    申请人:IFP Energies Nouvelles IFPEN;
    IPC主号:
    专利说明:

    The field of the present invention relates to energy storage by compressed gas, in particular air (CAES Compressed Air Energy Storage). In particular, the present invention relates to an AACAES (Advanced Adiabatic Compressed Air Energy Storage) system in which the storage of the gas and the storage of the heat generated are provided.
    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 efficiency 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. For example, compressed air at 8 MPa (80 bar) heats during compression to about 150 ° C, but is cooled prior to storage. In addition, the efficiency of a CAES system is not optimal, because then the system requires heating the stored air to achieve the expansion of the air. Indeed, 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 again follows an isentropic curve, but this time from the initial storage conditions (about 8 MPa and 300 K). The air cools down 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 currently exist for this system. Systems and methods include: • Adiabatic Compressed Air Energy Storage (ACAES) in which air is stored at high temperature due to compression. However, this type of system requires a specific storage system (adiabatic storage), bulky and expensive. • AACAES (Advanced Adiabatic Compressed Air Energy Storage) in which air is stored at room temperature, and the heat due to compression is also stored separately in a TES heat storage system. "Thermal Energy Storage"). The heat stored in the TES is used to heat the air before it is released.
    A first solution envisaged for the TES heat storage system is the use of a heat transfer fluid for storing the heat resulting from the 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. Moreover, the patent applications EP 2530283 and WO 2011053411 describe an AACAES system, in which the heat exchanges are carried out by a coolant circulating in a closed circuit, the closed circuit comprising a single heat transfer fluid reservoir.
    However, the systems described in these patent applications require specific means of storage and circulation of the coolant. In addition, for these systems, significant pressure losses are generated by the heat exchangers used.
    A second solution envisaged for the TES heat storage system is based on a static storage of heat (without displacement of the heat storage particles or heat transfer fluid). In this case, a good maintenance of the thermal gradient in the heat storage means is required because it allows to maintain a constant cold temperature and a constant hot temperature, and thus to ensure a better heat transfer during charging and maintenance. discharge. This is particularly important with respect to maintaining the efficiency of the system during the various charging and discharging cycles. To meet this requirement, heat storage means in static solids have been proposed. To obtain this thermal stratification with a solid heat storage, it can be used a fixed bed of solid particles heat storage through which the fluid to be cooled passes. However, during the loading and the stacking of the particles, heterogeneities, responsible for a non-uniform porosity, can appear within the bed, which can generate preferential passages of fluid, and thus lead to a thermal gradient not homogeneous (presence of cold zones and hot zones at different places of the bed). This effect is, moreover, accentuated during the operation of the system because of the expansions of the particles during the passage of the hot fluid, greatly degrading the performance of storage and return of heat.
    Improvements in AACAES systems have focused on the realization of a TES heat storage system by means of a fixed storage tank of heat storage material. For example, patent application FR 3014182 describes an AACAES system in which the heat storage system comprises a plurality of heat storage means, each heat storage means having a clean storage temperature. Because of the plurality of heat storage means, this system is made complex and expensive. However, for all these static TES heat storage systems, it is necessary to manage the thermal gradient between two cycles, which makes the system complex.
    To overcome these drawbacks, and in particular to promote the maintenance of the thermal gradient, the present invention relates to a system and a method for storing and recovering energy by compressed gas (for example of the AACAES type) in which the heat storage is placed. implemented by a radial heat exchange between the gas and heat storage particles. This implementation maximizes exchanges while having good control of the thermal gradient. It also allows a better radial distribution of temperature and thus avoids the formation of cold pockets that affect the efficiency of the system. Thus, the heat exchange is improved, which increases the efficiency of the storage of heat, and therefore the storage and the return of energy.
    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 gas compression means, at least one compressed gas storage means, at least one means expanding said compressed gas to generate energy, and at least one heat storage means of substantially cylindrical shape. Said heat storage means comprises at least one fixed bed of heat storage particles, said heat storage means being configured for a radial passage of said compressed gas within said fixed bed.
    According to one embodiment of the invention, said heat storage means comprises a stepped arrangement formed of a plurality of fixed beds.
    According to an alternative embodiment, said fixed beds are separated by a layer of insulating material.
    According to an implementation of the invention, said fixed beds are formed by baskets of substantially annular shape, the walls of said baskets being formed by a grid and / or at least one perforated wall.
    Advantageously, at least one fixed bed comprises a system for absorbing the variation of the height of said bed.
    According to a design of the invention, said means for storing heat comprises means for injecting and withdrawing said gas at the ends of said heat storage means.
    According to one characteristic, said heat storage means comprises means for injecting and withdrawing said gas at at least one fixed bed of said stepped arrangement.
    Advantageously, said heat storage means comprises at least one valve allowing passage of said gas in a single direction.
    Preferably, at least one fixed bed comprises particles of phase change material.
    Preferably, said fixed bed with particles of phase change material is located near the ends of said heat exchange means.
    According to one embodiment, the fixed bed located in the second position of said arrangement counting from one end of said heat exchange means comprises particles of phase change material.
    Advantageously, each fixed bed comprises particles of phase change material of different melting temperature.
    According to one embodiment of the invention, said heat storage means is configured for a radial passage of said compressed gas from the center to the periphery of said heat storage means and / or vice versa.
    Alternatively, said heat storage means is configured for radial passage of said compressed gas from one side to another of said heat storage means (1).
    In addition, the invention relates to a method for storing and recovering energy by compressed gas, wherein the following steps are performed: a) a gas is compressed; b) cooling said compressed gas by heat exchange in a substantially cylindrical heat storage means; c) storing said cooled gas; d) heating said cooled compressed gas by returning heat to said heat storage means; and e) expanding said heated compressed gas to generate energy, for storing and returning heat, said gas radially traverses at least one fixed bed of heat storage particles, said fixed bed being contained in said storage means of the heat.
    According to one embodiment, said gas passes through a stepped arrangement formed by a plurality of fixed beds contained in said heat storage means.
    Advantageously, said gas is injected and withdrawn at the ends of said heat storage means.
    Preferably, said gas is injected and withdrawn at at least one intermediate fixed bed.
    According to an alternative embodiment, the following steps are implemented: 1. the heat is stored on a first portion of said fixed beds by a first heat exchange with said gas; 2. the heat is stored on a second portion of said fixed beds by a second heat exchange with said gas; and 3. returning heat from said first and / or second portion by heat exchange with said gas.
    According to an alternative embodiment, said gas passes through said heat storage means from the center to the periphery of said heat storage means and / or vice versa.
    Alternatively, said gas passes through said heat storage means from one side to the other of said heat storage means.
    BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the system and method according to the invention will become apparent on reading the following description of nonlimiting examples of embodiments, with reference to the appended figures and described below.
    FIG. 1 illustrates a compressed gas storage and energy recovery system according to the invention.
    FIG. 2 illustrates a heat storage system according to a first embodiment of the invention, during the charging of the heat storage means.
    Figures 3a and 3b illustrate a heat storage system according to a second embodiment of the invention, respectively during the charging and discharging of the heat storage means.
    FIG. 4 schematically illustrates the temperature gradients between two instants in a heat storage means according to the embodiment of FIG. 2.
    Figures 5a and 5b show a heat storage means according to a third embodiment of the invention, respectively for two consecutive charges. Figures 5a and 5b further represent the temperature gradients within the heat storage means.
    FIG. 6 illustrates a heat storage means according to a fourth embodiment of the invention.
    Figure 7 illustrates a heat storage means according to a fifth embodiment of the invention.
    FIGS. 8a to 8c show diagrammatically the temperature gradients for a cycle of use of the system according to the invention, for the embodiment of the embodiment of FIG. 6.
    Detailed description of the invention
    The present invention relates to a system for storage and energy recovery by compressed gas equipped with a heat storage means (for example of the AACAES type). In this implementation, the pressurized gas (often air) is stored cold. The system according to the invention comprises: at least one gas compression means (or compressor), and preferably several staged gas compression means. The gas compression means may be driven by a motor, in particular an electric motor; - At least one compressed gas storage means (also called tank) by the gas compression means. The compressed gas storage means may be a natural reservoir (for example an underground cavity) or not. 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 multiple gas expansion means staged. The means of expansion of the gas makes it possible to generate an energy, in particular an electric energy by means of a generator; heat storage means for storing the heat from the compressed gas during the energy storage phase, and allowing the return of the stored heat to the compressed gas during the energy recovery phase; the heat storage means are preferably placed at the outlet of the compression means and at the inlet of the expansion means. According to the invention, the heat storage means comprises solid particles for storing heat. These solid particles exchange heat with the gas during the storage and energy recovery phases, this heat being stored in the particles between these two phases. According to the invention, the heat storage particles are distributed over at least one fixed bed. A fixed bed is an arrangement of heat storage particles in which the particles are immobile. The solid particles of heat storage allow the passage of gas in the fixed bed.
    The terms "stepped compression means" (respectively "stepped expansion means") are used when a plurality of compression means (respectively expansion means) are successively mounted one after the other in series: the compressed gas (respectively relaxed) at the output of the first compression means (respectively expansion) then passes in a second compression means (respectively 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, heat storage (exchange) means is disposed between each compression and / or expansion stage. Thus, the compressed gas is cooled between each compression, which optimizes the efficiency of the next compression, and the expanded gas is heated between each trigger, which optimizes the performance of the next trigger. The number of compression stages and the number of expansion stages can be between 2 and 10, preferably between 3 and 5. Preferably, the number of compression stages is identical to the number of expansion stages. Alternatively, the system for storage and energy recovery by compressed gas (for example of the AACAES type) according to the invention may contain a single compression means and a single expansion means.
    According to an alternative embodiment of the invention, the compression means, staggered or not, may be reversible, that is to say they can operate for both compression and 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.
    According to an alternative 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 alternative embodiment with compressed air, and its application AACAES will be described. However, the system and process are valid for any other gas.
    The heat storage 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 of the compressed gas. For example, the compressed gas may be passed from a temperature above 150 ° C (e.g., about 190 ° C) to a temperature below 80 ° C (e.g., about 50 ° C). The heat storage 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 (eg, about 50 ° C) to a temperature above 150 ° C (eg, about 180 ° C).
    FIG. 1 illustrates a nonlimiting exemplary embodiment of an AACAES system according to the invention. In this figure, the arrows in continuous line illustrate the flow of gas during the compression steps (energy storage), and the dashed arrows illustrate the flow of gas during the relaxation steps (energy restitution). This figure illustrates an AACAES system comprising a single compression stage 12, a single expansion stage 14 and a heat storage system 1. The system comprises a storage tank 13 of the compressed gas. The heat storage system 1 is interposed between the compression / expansion stage 12 or 14 and the storage tank 13 of the compressed gas. Conventionally, in the energy storage phase (compression), the air is first compressed in the compressor 12, then cooled in the heat storage system 1. The compressed and cooled gas is stored in the tank 13. The heat storage particles of the heat storage system 1 are hot following the cooling of the compressed gas in the compression phase. During energy recovery (expansion), the stored compressed gas is heated in the heat storage system 1. Then, in a conventional manner, the gas passes through one or more expansion stages 14 (a floor according to the example illustrated in Figure 1).
    The system according to the invention 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 reversible means ensuring the compression and relaxation, etc.
    According to the invention, the heat storage means has a shape of revolution, that is to say having an axis of symmetry: cylindrical, conical, frustoconical, etc., preferably the means of storing heat is substantially cylindrical (column). According to the invention, the heat storage means is configured for radial passage of the compressed gas within at least one fixed bed of solid heat storage particles. According to one embodiment of the invention, the fixed bed of solid particles may have a substantially cylindrical or annular shape. The arrangement of the heat storage means imposes a circulation of the compressed gas in the radial direction within at least one fixed bed, in contrast to the conventional heat storage means for which the fluid to be cooled or heated circulates axially. . The radial direction, in which circulates the fluid to be heated or cooled is a direction orthogonal to the axis of the column. Generally, such a heat storage means, in the form of a column, can be positioned vertically: the axis of the column corresponds to the vertical axis and the radial direction is in a horizontal plane. This radial passage of the gas in the fixed bed allows a better radial distribution of the temperature within the heat storage system, which avoids the formation of cold pockets (case of the axial passage of the gas in the heat storage system) that undermine the effectiveness of the system. Thus, the storage and energy restitution of the AACAES system are optimized. In addition, such a heat storage means is particularly suitable for an AACAES system, especially in terms of operating temperatures, the possibility of heat exchange with the compressed gas (in particular compressed air). Within the fixed bed, the gas flows substantially in a centrifugal direction.
    According to one embodiment of the invention, the heat storage means may comprise a plurality of fixed beds of heat storage particles. These fixed beds can form a staged arrangement: the beds are then arranged one above the other. In this case, the heat storage means is arranged such that the gas passes through the radially fixed beds, and such that the gas passes from one stage to another by axial displacement outside the fixed beds. . The gas is thus obliged to follow a radial path in the particle beds, and an axial path from one stage to another (either at the periphery or in the axis of the tank, for example through distribution grids vertical). A multi-stage bed with a radial flow therefore has the following advantages: - a better redistribution of the fluid, because the spaces outside the fixed beds, which allow the axial displacement of the gas, allow a re-mixing of the fluid, - a section of passage of the gas which is decreased relative to an axial configuration, which limits the risk of maldistribution of the gas in each stage, and - homogeneous loading of the granular solid (particles) which is facilitated upstream with respect to a configuration without a stage.
    These advantages make it possible to ensure a radial distribution of the homogeneous temperature in the azimuthal and axial directions, essential for the proper functioning of the system.
    According to a design of the heat storage means, the fixed beds can be separated by sealed thermal insulation layers through which the gas can not flow. These thermal insulation layers make it possible to limit the diffusion of the temperature between each stage of particles and thus improve the control of the thermal gradient. The arrangement of the insulation layers also makes it possible to orient the gas in the fixed bed in the radial direction. This arrangement can consist of alternating fixed beds of particles and layers of insulation. The insulating material may be any material with very low thermal conductivity known, that is to say, more insulating than the fixed bed comprising the particles. It may be covered, from below, over and / or on both sides, with a metal plate or any other device that seals against the gas, in order to prevent displacement axial fluid.
    According to one embodiment of the invention, the heat storage particles can be placed in baskets, whose vertical walls are composed of grids, or whose walls are perforated, in order to improve the distribution of the fluid in the container. basket, allowing to control the pressure drop across the bed.
    According to one characteristic of the invention, each bed may comprise a system for absorbing the variation of the bed height. Indeed, during operation of the system, the initially charged bed of particles could settle, creating, above each bed, preferential passages of the gas that would not exchange its energy with the solid particles. To avoid this phenomenon, it is advantageous to place, above each bed, a sealing system that absorbs any variations in height of the bed. These known systems are used in other technical fields, such as chemical conversion reactors. An example is the "Texicap®" system, consisting of refractory fibers, which perfectly fits the top of the solid bed and advantageously replaces a metal assembly. This system can rest directly on the top of the bed of solid particles.
    In addition, each fixed bed may comprise solid particles or particles containing a phase change material (PCM). For this, the particles may be in the form of capsules containing PCM. The use of phase change materials with different melting temperatures between each stage makes it possible to better control the thermal gradient in the tank and to limit the phenomena of temperature diffusion during the storage phases. These materials also allow a reduction in the volume of the tank, because they can store a large amount of energy in the form of latent heat. A compromise between efficiency and cost can also be found by mixing MCPs and sensible heat storage materials in a single bed. Among the phase-change materials, the following materials may be used: paraffins, whose melting temperature is below 130 ° C, salts which melt at temperatures above 300 ° C, (eutectic) mixtures which allow to have a wide range of melting temperature.
    The solid particles (whether or not with a phase change) may have all the known forms of conventional granular media (beads, cylinders, extrusions, trilobes, etc.), as well as any other shape that maximizes the surface area. exchange with gas. The particle size may vary between 0.5 mm and 10 cm, preferably between 2 and 50 mm and even more preferably between 5 and 20 mm.
    The temperature range over which the heat storage means can operate is between 0 ° and 500 ° C, more preferably between 100 and 400 ° C, and even more preferably between 100 and 350 ^ 0. The temperature levels depend both on the complete AACAES process and the type of material used for the particles of the heat storage means.
    According to a first variant of this embodiment, the gas can pass through the fixed beds from the center to the periphery of the heat storage means, and vice versa, from the periphery to the center of the heat storage means. Advantageously, the heat storage means may be configured so that the fluid circulates alternately in the fixed beds consecutive from the center to the periphery, then from the periphery to the center. This configuration allows ease of design, because of the symmetry.
    Alternatively, the gas can pass through the fixed beds from one side to the other of the heat storage means, and vice versa. Advantageously, the heat storage means may be arranged in such a way that the fluid circulates alternately in the consecutive fixed beds, from one side to the other (for example from left to right), then in direction reverse (for example from right to left). This configuration allows a longer passage of gas within the fixed beds.
    According to a first embodiment of the invention, the heat storage means is formed by a staged arrangement of fixed beds, the hot gas is introduced from above (during the storage phase) of the storage means and circulates in the fixed beds alternately from the center to the periphery of the heat storage means. For this embodiment, the hot side of the storage means is located at the top and the cold side at the bottom, in order to generate a stable stratification, which avoids exchanges by natural convection during the storage phase which could adversely affect the maintenance of the thermal gradient .
    An example of such a system is shown (in a non-limiting manner) in FIG. 2 during the charging phase (the hot air exchanges its heat with the solid particles and cold spring). In this figure, the passage of the gas is indicated by the arrows, the dark arrows indicating a hot gas while the clear arrows indicate a cold gas. For this example according to the first embodiment, the heat storage means 1, in the form of a column, comprises a plurality (here six) of fixed beds 2. Each fixed bed 2 comprises particles 3 for storing heat. The fixed bed is formed by a basket 6, the vertical walls are made by grids (or perforated walls). The baskets 6 have a substantially annular shape. Between each fixed bed 2, layers of thermally insulating material 4 are arranged. The layers of insulating material 4 may be covered with a layer of impermeable material 5. Column 1 comprises means for injecting and withdrawing gas 7 ends of the column 1. During the illustrated storage phase, the hot gas GC (at the outlet of the compression means) is injected by the upper end into the column 1. The hot gas flows radially through the fixed beds 2 alternately from the center of the column to the periphery, then from the periphery to the center. This path is repeated three times within the column. Then, the cooled gas GF is extracted from the column 1 in the lower part to be stored in the compressed gas storage means of the AACAES system, or to be injected into a new compression step. During the discharge (not shown) of the heat storage means 1, the gas travels the opposite path (entry of the cold gas from below and exit of the hot gas from above).
    According to a second configuration, the direction of gas flow is reversed with respect to the first embodiment. In this case, the hot side of the heat storage means is at the bottom and the cold side is at the top. For this configuration, the internal constitution of the heat exchange means is unchanged: the heat storage means is formed by a staged arrangement of fixed beds, the hot gas is introduced from above (during the storage phase) and circulates in fixed beds alternately from the center to the periphery of the heat storage means and from the periphery to the center. However, in this case, a system of valves is set up to avoid natural convection phenomena. The valves allow the passage of gas in one direction. Thus, the valves impose the direction of the passage of gas within the different beds. For this purpose, the valves are arranged at the periphery and / or in the center of the heat exchange means.
    An example of such a system is shown (in a non-limiting manner) in FIGS. 3a and 3b. Figure 3a corresponds to the charging phase (the hot air exchanges its heat with the solid particles and cold spring) and Figure 3b corresponds to the discharge phase (the solid particles exchange their heat with the cold gas, and the gas warm spring). In FIGS. 3a and 3b, the passage of the gas is indicated by the arrows, the dark arrows indicating a hot gas while the clear arrows indicate a cold gas. For this example according to the second embodiment, the heat storage means 1, in the form of a column, comprises a plurality (here six) of fixed beds 2. Each fixed bed 2 comprises particles 3 for storing heat. The fixed bed is formed by a basket, whose vertical walls are made by grids (or perforated walls). The baskets have a substantially annular shape. Between each fixed bed 2 are arranged layers of thermal insulating material 4. The layers of insulating material 4 may be covered with a layer of waterproof material. Column 1 comprises means for injecting and withdrawing the gas 7 at the ends of the column 1. Between the fixed beds are arranged a sealed valve system 8 which imposes the flow direction of the gas.
    During the storage phase shown in FIG. 3a, the hot gas GC (at the outlet of the compression means) is injected by the lower end into the column 1. The hot gas GC passes radially through the fixed beds 2, alternately passing center of the column towards the periphery, then from the periphery to the center, by means of the valves 8 oriented in this direction of circulation. This path is repeated three times within the column. Then, the cooled gas GF is extracted from the column 1 in the upper part, to be stored in the compressed gas storage means of the AACAES system, or to be injected into a new compression step.
    During the discharge of the heat storage means 1, the cold gas GF (at the outlet of the compressed gas storage means or an expansion stage) is injected by the upper end into the column 1. The cold gas GF radially crosses the fixed beds 2 passing alternately from the periphery to the center, then from the center of the column to the periphery, by means of the valves 8 oriented in this direction of circulation. This path is repeated three times within the column. Then, the hot gas GC is extracted from the column 1 in the lower part to be directed to the expansion means of the AACAES system. Thanks to the valves, the gas flow path during the discharge phase is different from the gas flow path during the charging phase. Between two beds, the gas can pass on the periphery during the charging phase, and in the center during the discharge phase, or vice versa.
    In the radial multi-stage bed, according to the invention, two thermal gradients are established: a main gradient in the longitudinal or axial direction (the one which makes it possible to keep the cold and hot temperatures of inlet and outlet) and a secondary gradient in the radial direction. FIG. 4 represents an example of temporal evolution of these two gradients, for the embodiment of FIG. 2. On the left part of the figure, the evolution of the temperature T as a function of the radius r, is indicated for two instants L (solid line) and t2 (dotted line) of the charging phase. In the same way, the right part of the figure shows the evolution of the temperature T as a function of a height h (corresponding to the distance, along the axis of revolution of the column) for the instants L (in continuous line) and t2 (dashed line).
    In the configurations described above, the gas injection and withdrawal means are provided at the upper and lower ends of the heat storage means. As a variant, additional means for injecting and withdrawing the gas may be provided at intermediate levels of the heat storage means. Thus, the system of the present invention may be provided with complementary injection and withdrawal points at each stage (at each fixed bed), which advantageously control the flow of fluid passing through each stage. This variant embodiment is compatible with all the possible configurations of the heat storage means.
    An advantage of this embodiment is that the injection system / racking stage reduces the pressure losses in the system and better control the temperature gradient in the fixed bed. In fact, the injections / withdrawals closer to the thermal gradient can limit the pressure losses (the number of crossed beds being reduced) while maintaining good thermal transfer performance. Thus, and as a function of the height of the thermal gradient with respect to the height of the bed, a very significant reduction in the pressure drop can be obtained.
    Thus, in FIGS. 5a and 5b are illustrated (in a nonlimiting manner) two consecutive charging phases of a heat storage system with a fixed bed of six stages of particles. The heat storage system shown corresponds to the configuration of FIG. 2: the heat storage means is formed by a staggered arrangement of fixed beds, the hot side of the reactor is at the top, and the cold side at the bottom . In addition, complementary injection means (continuous dark arrows) and withdrawal (clear dashed arrows) 9 are installed on each floor. The axial temperature gradient T is artificially represented in the multi-stage bed by a solid line. During the first charging phase (Figure 5a), the hot gas GC is injected and is distributed on one or more stages (the number of stages may vary depending on the flow rate for example). According to this example, the loading is done on three (Figure 5a) or four stages (Figure 5b) at the same time (the hot fluid passes through three or four stages before leaving the heat storage means). The number of stages crossed is variable because of the flow of the fluid (for example withdrawals only at the periphery of the reactor). When the charging temperature is reached in these stages, the injection is done by a complementary means (9) directly in one of the lower stages (Figure 5b). Thus, the loading of such a system can be done sequentially by stage or group of stages from the inlet to the outlet and makes it possible to limit the pressure drops since the gas does not cross the whole of the bed of particles.
    For this variant embodiment, the discharge process can also be done sequentially by group of stages from the bottom of the bed to the top of the bed. During this phase, the unloading can be done on a number of different floors.
    According to this third embodiment, and for the example of Figure 5a and 5b, only three or four stages out of six are traversed by the gas at any time, unlike the first embodiment illustrated in Figure 4. Thus for this load of the heat storage means, the pressure drop thus varies between one-half and two-thirds of that of the configuration of FIG. 4.
    According to a fourth embodiment of the invention (compatible with the embodiments described above), the fixed beds may comprise particles of phase change material (PCM) as heat storage particles. According to a variant of this embodiment, the heat storage means may comprise fixed beds with particles of phase change material having different melting temperatures. Advantageously, the MCP particles having the highest melting temperature are placed in at least one fixed bed on the hot side, close to the hot gas injection and withdrawal means, and the MCP particles having the highest melting temperature. are placed in at least one bed fixed cold side, near the injection means and cold gas withdrawal. For this variant, the melting temperatures of the two phase change materials are chosen so as to ensure a certain temperature level of the cold air towards the storage (cold side) and of the hot air towards the AACAES turbine ( hot side). Optionally, a fixed bed of sensible heat storage material particles may be placed prior to the hot side MCP fixed bed stage, and / or after the cold side MCP fixed bed stage, to absorb possible variations in the input temperature of the heat storage means (compressor output during charging, output of compressed air storage during discharge). At any time, the MCP stages contain a phase change front with a certain percentage of the mass in the solid state and the remainder in the liquid state.
    Thus, for this embodiment, the temperature in a MCP material that is at the phase change temperature remains constant during the heat exchange, as long as the phase change occurs (latent heat exchange). The main advantage of this embodiment is therefore to ensure a constant input and output temperature of the heat storage system, which will not vary with the cycling if the quantity of PCM is correctly sized (it is necessary to that there are 2 solid / liquid phases at all times to ensure that the T is constant). Thus, the main advantage of this embodiment is the improvement of the control of the thermal gradient.
    The melting temperature of the MCP on the hot side may be between 50 and 500 ° C., more preferably between 100 and 400 ° C., and even more preferably between 100 and 350 ° C. The cold side MCP melting temperature is between 0 and 500 ° C, more preferably between 5 and 200, and even more preferably between 10 and 100 ° C.
    An example of such a system is shown (in a non-limiting manner) in FIG. 6 during the charging phase (the hot gas exchanges its heat with the solid particles and cold spring). For this example according to the fourth embodiment, the geometry of the heat storage system, as well as the path of the fluid in the heat storage system, correspond to the configuration of FIG. 2: the means of storing the heat comprises a plurality (here six) fixed beds, the fixed bed is formed by a basket having a substantially annular shape, and between each fixed bed 2, are arranged layers of insulating material, the column comprises means for injection and withdrawal of the gas 7 at the ends of the column ... In addition, for this embodiment, the column comprises two fixed beds 10 and 11 comprising particles of phase change material, called fixed beds of MCP thereafter. According to this embodiment, the MCP particles of the first MCP fixed bed 10 have a higher melting temperature than the MCP particles of the second MCP fixed bed 11. The first MCP fixed bed 10 is then placed on the warm side, as a second fixed bed from the injection and withdrawal means of the hot gas GC. The fixed MCP bed 11 is placed on the cold side, as the second fixed bed from the cold gas injection and withdrawal means GF. The fixed beds located between the fixed beds of MCP 10 and 11 and the injection and withdrawal means 7 comprise particles of sensible heat storage material (that is to say the fixed beds placed before the floor of the MCP fixed bed hot side 10, and / or after cold fixed MCP fixed bed stage 11) so as to absorb any variations in the inlet temperature of the heat storage means. During the depicted phase of storage, the hot gas GC (at the outlet of the compression means) is injected by the upper end into the column 1. The hot gas flows radially through the fixed beds 2, passing alternately from the center of the column to the the periphery, then from the periphery to the center. This path is repeated three times within the column. Then, the cooled gas GF is extracted from the column 1 in the lower part to be stored in the compressed gas storage means of the AACAES system, or to be injected into a new compression step. During the discharge (not shown) of the heat storage means 1, the gas travels the opposite path (entry of the cold fluid from below and exit of the hot fluid from above).
    According to a fifth configuration (compatible with the first three embodiments described), the system has fixed beds of heat storage particles with different MCPs, each having a different melting temperature. The melting temperatures of the different phase change materials are chosen so as to ensure a certain temperature gradient in the multi-stage bed. Optionally, a layer of sensible heat storage material may be placed before the first warm side MCP stage, and / or after the last cold side MCP stage, so as to absorb any variations in inlet temperature. of the TES (output of the compressor during charging, output of compressed air storage or an expansion stage during discharge). At any time, the MCP stages contain a phase change front with a certain percentage of the mass in the solid state and the remainder in the liquid state. For this variant, the melting temperatures of the two phase change materials are chosen so as to ensure a certain temperature level of the cold air to the storage or to another compression stage (cold side) and to the air hot to the AACAES system turbine (hot side). The main advantage of staging MCPs is to better control the thermal gradient and therefore the input / output temperatures during the charging / discharging cycles.
    An example of such a system is shown (in a non-limiting manner) in FIG. 7 during the charging phase (the hot air exchanges its heat with the solid particles and cold spring). For this example according to the fifth embodiment, the heat storage means corresponds to the configuration of FIG. 2: the heat storage means comprises a plurality (here six) of fixed beds, the fixed bed is formed by a basket having a substantially annular shape, between each fixed bed 2, are arranged layers of insulating material, the column comprises means for injecting and withdrawing the gas 7 at the ends of the column ... In addition, for this mode In fact, all the fixed beds comprise particles of PCM phase change material. The MCP particles of each fixed bed have a different melting temperature TF1 to TF6, with TF6 <TF5 <TF4 <TF3 <TF2 <TF1, the fixed bed with the MCP having the melting temperature TF1 being on the hot side (injection / withdrawal hot gas GC), and the fixed bed with the MCP having the melting temperature TF6 being on the cold side (injection / withdrawal of the cold gas GF). During the depicted phase of storage, the hot gas GC (at the outlet of the compression means) is injected through the upper end of the column 1. The hot gas flows radially through the fixed beds 2, passing alternately from the center of the column to the the periphery, then from the periphery to the center. This path is repeated three times within the column. Then, the cooled gas GF is extracted from the column 1 in the lower part to be stored in the compressed gas storage means of the AACAES system or to be injected into a new compression step. During the discharge (not shown) of the heat storage means 1, the gas travels the opposite path (entry of the cold fluid from below and exit of the hot fluid from above).
    Figure 8a illustrates an example of a cycle of use of an AACAES system. This figure corresponds to the variation of the inlet gas temperature of the hot side Tin ,, iuide of the heat storage means. The duty cycle comprises a first charging phase CFI (energy storage) between times t0 and t-ι, then a second storage phase ST (energy storage) between times t1 and t2, then a phase DE discharge (energy recovery) between instants t2 and t3, and a waiting phase AT between instants ta and to.
    FIGS. 8b and 8c show the temporal evolution of the axial profile (that is to say along the axis of revolution of the heat storage means, h being the distance taken along this axis) of the temperature T in the fixed beds, during the charging and discharging phases for the cycle of use of FIG. 8a. For this example, the heat storage means corresponds to the embodiment of FIG. 6, for which the heat storage means comprises two fixed beds with MCPs, each fixed bed of MCP having a different melting point and being placed in proximity (in second position) of the ends of the heat storage means. In these figures, the vertical lines delimit the fixed beds comprising the particles MCP. FIG. 8b corresponds to the charging phase CH of FIG. 8a, and FIG. 8c corresponds to the discharge phase DE of FIG. 8a.
    In FIG. 8a, it is indicated that at the beginning of the cycle (at t0), the fixed bed with the MCP1 particles on the hot side of the heat storage means contains 50% of the mass in the solid state and 50% of the solid mass. liquid state. During charging, the hot gas passes through the heat storage means on the warm side. The liquid fraction increases, latent heat being stored in the MCP1 stage. The temperature is kept constant (and equal to the melting temperature of MCP1). At the end of the charge, 90% of the MCP1 is in the liquid state.
    The temperature gradient is established in the part of the TES that is filled with heat storage equipment using sensible heat.
    On the cold side, the MCP2 stage initially contains 10% liquid and 90% solids. During charging, its temperature is kept constant (and equal to the melting temperature of MCP2). At the end of the charge, 50% of the MCP2 is in the liquid state.
    The process is reversed during the discharge phase between t2 and t3. In FIG. 8c, it is observed that the cold fluid enters the cold side and heats up, absorbing latent heat in the stage MCP2 and decreasing the proportion of the liquid in this stage (which goes from 50% to 10% again ). The temperature is kept constant (and equal to the melting temperature of MCP2).
    A new temperature gradient is established in the portion of the TES that is filled with sensible heat storage material. On the warm side, in the MCP1 stage, the quantity of liquid decreases as the fluid passes and goes from 90% to 50%, keeping its temperature constant (and equal to the melting temperature of the MCP1).
    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 a compressor; b) the compressed gas is cooled by heat exchange, in particular in a substantially cylindrical heat storage means; c) the compressed compressed gas is stored, in particular by a compressed gas storage means; d) heating the stored compressed gas, by heat exchange, in the heat storage means; and e) the heated compressed gas is expanded to generate energy, for example by means of a turbine to generate electrical energy.
    According to the invention, the heat storage means comprises at least one fixed bed of solid particles for storing heat. The fixed bed of solid particles may have substantially a cylindrical or annular shape. In addition, for the process according to the invention, the gas passes radially through the fixed bed (s). This radial passage of the gas in the fixed bed allows a better radial distribution of the temperature within the heat storage system, which avoids the formation of cold pockets (case of the axial passage of the gas in the heat storage system) that undermine the effectiveness of the system. Thus, the storage and energy recovery of the AACAES process are optimized.
    According to one aspect of the invention, the method comprises several successive compression stages, by means of compressors placed in series, also called staged 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 d) and e) are repeated for each expansion stage. 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) makes it possible to cool the compressed gas after each compression step, which makes it possible to optimize the efficiency of the following compression and / or energy storage. The heat storage 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 next compression step or before storage. For example, the compressed gas may pass 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 compressed air before each relaxation, which makes it possible to optimize the performance of the following relaxation. For step d), it is possible to use the heat storage particles which were used to cool during step b). The heat storage 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 e), 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 electrical energy. If the gas is air, the expanded air can be vented to the environment.
    The method according to the invention can be implemented by the system according to any one of the variants of the invention described above (alone or in combination). The method according to the invention may in particular comprise a step of storing and / or restoring the heat comprising one or more of the following characteristics: • a heat exchange in a plurality of fixed beds, • a circulation of the gas of the center to the periphery, or from one side to the other of the heat storage means, • an injection and a withdrawal of the gas at the ends of the heat storage means and / or at intermediate levels, • the particles of heat storage can be particles of phase change material, these MCP particles can be placed in fixed beds near the ends of the heat storage means, • a circulation of the hot gas from the top to the lower part of the column, or conversely from the lower part to the upper part of the column ...
    According to an alternative embodiment of the method, the charging and discharging of the heat storage means can be sequential. In particular, for the embodiment, for which the gas is injected and / or withdrawn at intermediate levels (FIG. 5), the method may comprise the following steps: i) the heat is stored on a first portion of the fixed beds by a first exchange of heat with said gas, for example with the upper fixed beds of the heat storage means, the hot gas being injected into the heat storage means by injection and withdrawal means located in the upper part of the heat storage means, and the cold gas being withdrawn from the heat storage means by injection and withdrawal means located at an intermediate level of the heat storage means; ii) the heat is stored on a second portion of the fixed beds by a second heat exchange with said gas, for example with the lower fixed beds of the heat storage means, the hot gas being injected into the storage means of the heat by injection and withdrawal means located in the intermediate portion of the heat storage means, and the cold gas being withdrawn from the heat storage means by means of injection and withdrawal located at an intermediate level or in the lower part of the heat storage means; and iii) returning the heat of said first and / or second portion by heat exchange with said gas, the cold gas being injected into the heat storage means by injection and withdrawal means located in the lower part. heat storage means, and the hot gas being withdrawn from the heat storage means by means of injection and withdrawal located at an intermediate level, or in the upper part of the heat storage means.
    This embodiment makes it possible to limit the pressure drops within the heat storage means.
    Advantageously, steps i) and ii) may be repeated for other portions of the fixed beds of the heat storage means.
    According to a variant, it is possible to restore the heat for only a portion of the fixed beds of the heat storage means.
    The method and system according to the invention can be used for storage of intermittent energy, such as wind or solar energy, in order to use this energy at the desired time.
    权利要求:
    Claims (21)
    [1" id="c-fr-0001]
    1) compressed gas energy storage and recovery system comprising at least one gas compression means (12), at least one compressed gas storage means (13), at least one expansion means (14) said compressed gas for generating energy, and at least one heat storage means (1) having substantially a revolution form, characterized in that said heat storage means (1) comprises at least one fixed bed (2). ) of heat storage particles, said heat storage means (1) being configured for radial circulation of said compressed gas within said fixed bed.
    [0002]
    2) System according to claim 1, wherein said heat storage means (1) comprises a stepped arrangement formed of a plurality of fixed beds (2).
    [0003]
    3) System according to claim 2, wherein said fixed beds are separated by a layer of insulating material (4).
    [0004]
    4) System according to one of claims 2 or 3, wherein said fixed beds are formed by baskets (6) substantially annular shape, the walls of said baskets being formed by a grid and / or at least one perforated wall.
    [0005]
    5) System according to one of claims 2 to 4, wherein at least one fixed bed (2) comprises a system for absorbing the variation of the height of said bed.
    [0006]
    6) System according to one of claims 2 to 5, wherein said means for storing heat (1) comprises means for injecting and withdrawing (7) said gas at the ends of said heat storage means.
    [0007]
    7) storage system according to claim 6, wherein said means for storing heat (1) comprises means for injecting and withdrawing (9) said gas at at least one fixed bed of said staggered arrangement.
    [0008]
    8) System according to one of claims 2 to 7, wherein said means for storing heat comprises at least one valve (8) allowing the passage of said gas in one direction.
    [0009]
    9) System according to one of the preceding claims, wherein at least one fixed bed (2) comprises particles of phase change material.
    [0010]
    The system of claim 9, wherein said fixed bed (2) with particles of phase change material is located near the ends of said heat exchange means (1).
    [0011]
    The system according to claim 10, wherein the fixed bed (10, 11) located in the second position of said arrangement counting from one end of said heat exchange means (1) comprises particles of material to be changed. phase.
    [0012]
    The system of claim 11, wherein each fixed bed (10, 11) comprises particles of phase change material of different melting temperature.
    [0013]
    13) System according to one of the preceding claims, wherein said means for storing heat (1) is configured for a radial passage of said compressed gas from the center to the periphery of said heat storage means (1) and / or Conversely.
    [0014]
    14) System according to one of claims 1 to 12, wherein said means for storing heat is configured for a radial passage of said compressed gas from one side to another of said heat storage means (1).
    [0015]
    15) Process for storage and energy recovery by compressed gas, wherein the following steps are performed: a) a gas is compressed; b) cooling said compressed gas by heat exchange in a substantially cylindrical heat storage means (1); c) storing said cooled gas; d) heating said cooled compressed gas by returning heat to said heat storage means (1); and e) said heated compressed gas is expanded to generate energy, characterized in that for storing and returning heat said gas passes radially through at least one fixed bed (2) of heat storage particles, said fixed bed (2 ) being contained in said heat storage means (1).
    [0016]
    The method of claim 15, wherein said gas passes through a stepped arrangement formed by a plurality of fixed beds (2) contained in said heat storage means (1).
    [0017]
    17) The method of claim 16, wherein said gas is injected and withdrawn at the ends of said heat storage means.
    [0018]
    18) The method of claim 17, wherein said gas is injected and withdrawn at at least one intermediate fixed bed.
    [0019]
    19) The method of claim 18, wherein the following steps are implemented: i) the heat is stored on a first portion of said fixed beds by a first heat exchange with said gas; ii) storing the heat on a second portion of said fixed beds by a second heat exchange with said gas; and iii) returning the heat of said first and / or second portion by heat exchange with said gas.
    [0020]
    20) Method according to one of claims 15 to 18, wherein said gas passes through said heat storage means from the center to the periphery of said heat storage means (1) and / or vice versa.
    [0021]
    21) Method according to one of claims 15 to 18, wherein said gas passes through said means for storing heat from one side to the other of said heat storage means (1).
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    同族专利:
    公开号 | 公开日
    FR3044751B1|2017-12-15|
    引用文献:
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    法律状态:
    2016-12-12| PLFP| Fee payment|Year of fee payment: 2 |
    2017-06-09| PLSC| Publication of the preliminary search report|Effective date: 20170609 |
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    2019-12-23| PLFP| Fee payment|Year of fee payment: 5 |
    2020-12-29| PLFP| Fee payment|Year of fee payment: 6 |
    2021-12-27| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1561878A|FR3044751B1|2015-12-04|2015-12-04|SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED GAS ENERGY WITH RADIAL HEAT EXCHANGE|FR1561878A| FR3044751B1|2015-12-04|2015-12-04|SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED GAS ENERGY WITH RADIAL HEAT EXCHANGE|
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