SYSTEM AND METHOD FOR COMPRESSED GAS ENERGY STORAGE AND RESTITUTION

专利摘要:
- System and method for storing and restoring energy by compressed gas. The system comprises at least one gas compression means (12), at least one compressed gas storage means (13), at least one expansion means (14) of said compressed gas for generating energy, and at least one means heat storage device (1), characterized in that said heat storage means (1) comprises a stepped arrangement formed of at least two fixed beds of heat storage particles and at least one discontinuity means of the thermal gradient between two adjacent beds. - Application including storage and energy return by compressed air.
公开号:FR3044750A1
申请号:FR1561875
申请日:2015-12-04
公开日:2017-06-09
发明作者:Elena Sanz；Willi Nastoll；Guillaume Vinay；Cecile Plais
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), the energy, which one wishes to use later, is stored in the form of 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 423 K (about 150 ° C), but is cooled before 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 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 currently exist for this system. Systems and methods include: • Adiabatic Compressed Air Energy Storage (ACAES) in which air is stored at the temperature due to compression. However, this type of system requires a specific storage system, bulky and expensive because it requires thermal insulation over the entire storage volume of the air. • 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 the heat (without displacement of the storage material). 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.
The patent application FR 3014182 describes an AACAES system in which the heat storage and return system comprises a plurality of staged heat storage means at the output of each compression stage, each storage means having a storage temperature of clean heat. This system, if it allows a satisfactory control of the thermal gradient, is, because of the multiplicity of storage means, relatively expensive and has a lower operability.
To overcome these disadvantages, while allowing control of the thermal gradient, the present invention relates to a system and a method for storing and restoring energy by compressed gas (for example of the AACAES type, that is to say involving wherein the heat storage means is formed of a stepped arrangement of at least two fixed beds of heat storage particles, and comprises at least one means for inducing at least one discontinuity of the thermal gradient between two adjacent beds. This implementation can allow controlled thermal stratification within said heat storage means, and in particular to avoid the formation of cold pockets that affect the efficiency of the system. In addition, this objective can be achieved within one and the same heat storage means, which gives the system according to the invention a better operability, and at a lower cost, compared to the prior art. Thus, the system according to the invention makes it possible to increase the overall efficiency of the storage and the energy recovery by compressed gas.
The system and the method according to the invention
Thus, the present invention relates to a system for storing and restoring compressed gas energy comprising at least one gas compression means, at least one means for storing the compressed gas, at least one means for expanding said compressed gas to generate an energy, and at least one heat storage means, characterized in that said heat storage means comprises a stepped arrangement formed of at least two fixed beds of heat storage particles, and at least one means to form a discontinuity of the thermal gradient between at least two adjacent beds.
Advantageously, said two fixed beds can be separated by a wall permeable to said gas.
According to one embodiment of the invention, one of said discontinuity means of said thermal gradient may comprise a layer formed of a thermally insulating material, said layer separating at least two of said fixed beds.
According to one embodiment of the invention, one of said discontinuity means of said thermal gradient can be formed by at least two of said fixed beds comprising particles of phase change material.
Advantageously, said at least two fixed beds may comprise particles of phase change material of different melting temperature and may each be located near one end of said heat exchange means.
Preferably, said at least two fixed beds may comprise particles of phase change material of different melting temperature and may be located in second position of said arrangement by counting from an end of said heat exchange means.
According to one embodiment of the invention, a mainly axial passage of said compressed gas through said fixed beds may be induced by means for injecting and withdrawing compressed gas placed axially with respect to said storage means.
Advantageously, said storage means may comprise means for injecting and withdrawing complementary gases located at at least one stage of said staggered arrangement of fixed beds of storage particles.
According to one embodiment of the invention, said complementary compressed gas injection and withdrawal means may comprise a distribution grid interposed between said beds constituting said stage.
Advantageously, a layer formed of a thermally insulating material may be contiguous on one of the faces of said grid.
In addition, the invention relates to a method for storing and restoring energy by compressed gas, wherein the following steps are performed: a) a gas is compressed; b) said compressed gas is cooled by heat exchange in a heat storage means; c) storing said cooled gas; d) heating said cooled compressed gas by returning heat to said heat storage means; and e) said heated compressed gas is expanded to generate energy, characterized in that for storing and returning heat, said gas passes through said heat storage means, said means comprising a staggered arrangement of at least two fixed beds of heat storage particles, and at least one means for forming a discontinuity of the thermal gradient between at least two adjacent beds.
According to one embodiment of the invention, said gas can be injected and withdrawn at the ends of said heat storage means.
Advantageously, said gas can be injected and withdrawn at the level of at least one intermediate fixed bed.
According to one embodiment of the invention, the following steps can be implemented: i. storing the heat 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. the heat of said first and / or second portion is returned by heat exchange with said gas.
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.
Figures 2 and 3 illustrate a heat storage system according to one embodiment of the invention, respectively during the charging and discharging of the heat storage means. Figures 2 and 3 further represent the temperature gradients within the heat storage means.
FIG. 4 illustrates a heat storage system according to one embodiment of the invention, during the charging of the heat storage means. Figure 4 further shows the temperature gradient within the heat storage means.
FIG. 5 illustrates a heat storage system according to one embodiment of the invention, during the charging of the heat storage means.
Figure 6 illustrates a heat storage system according to one embodiment of the invention.
Figures 7a, 7b and 7c show a means of storing heat according to one embodiment of the invention, respectively for three consecutive charges. Figures 7a, 7b and 7c further represent the temperature gradients within the heat storage means.
FIGS. 8a, 8b and 8c show a means of storing heat according to one embodiment of the invention, respectively for three consecutive discharges. Figures 8a, 8b and 8c further represent the temperature gradients within the heat storage means.
FIG. 9 schematically illustrates the temperature gradients between two instants in a heat storage means according to the embodiment of FIG. 4.
Detailed description of the invention
The present invention relates to a system for storing and restoring energy by compressed gas equipped with a means for storing heat (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; at least one means of storing the heat, allowing the storage of the heat resulting from the compressed gas during the energy storage phase, and making it possible to restore the heat stored in the compressed gas during the phase of the recovery of 'energy. According to the invention, the heat storage means comprises a stepped arrangement formed of at least two fixed beds, each fixed bed being formed of heat storage particles. The particles forming each of the fixed beds exchange heat with the gas during the storage and energy recovery phases, this heat being stored in the particles between these two phases. A fixed bed is a set of heat storage particles in which the particles are immobile. A tiered arrangement of beds is called beds that are superimposed on one another. According to the invention, said heat storage means comprises at least one means for forming a discontinuity of the thermal gradient between at least two adjacent beds. By discontinuous thermal gradient is meant a thermal gradient with slope breaks, that is to say that the derivative of the curve representing the change in temperature in the heat storage means according to the invention is not continuously differentiable.
The terms "stepped compression means" (respectively "stepped expansion means") are used when a plurality of compression (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 relaxation) then passes into 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 storing and restoring energy 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 (e.g., about 180 ° C).
FIG. 1 illustrates a non-limiting exemplary embodiment of a system for storing and restoring compressed gas energy according to the invention, such as an AACAES system. 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 the restitution of the energy (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 comprises at least one means for forming a discontinuity of the thermal gradient between at least two adjacent beds. A discontinuity of the thermal gradient within the storage means makes it possible to limit the natural convection movements within the heat storage means, potentially generators of thermally inhomogeneous zones (formation of cold pockets) which are detrimental to the efficiency of the system. thus avoided. Thus the heat storage means of the compressed gas storage and energy recovery system according to the invention allows the control of the thermal gradient, and this, within one and the same heat storage means. Thus, the system according to the invention offers good operability in operation as well as an advantageous cost, all allowing storage and a return of optimized energy.
According to one embodiment of the invention, the heat storage means has a substantially cylindrical shape. For example, the heat storage means is in the form of a column, which may for example be positioned vertically, the axis of the column corresponding to the vertical axis. According to one embodiment of the invention, the fixed particle beds of the heat storage means are superimposed along the axis of revolution of the heat storage means.
According to one embodiment of the invention, the heat storage means comprises means for injecting and withdrawing compressed gas placed perpendicular to the direction of the stratification induced by the superposition of fixed beds of particles. Thus, the flow of compressed gas passes through the stepped arrangement of fixed beds in a predominantly axial direction with respect to this stepped arrangement. According to this embodiment, the flow of compressed gas passes through the fixed beds successively, one after the other, and, the heat storage means according to the invention comprising at least one means for forming a discontinuity of the thermal gradient between at least two adjacent beds, thermal stratification is induced within the storage means (with at least one discontinuity of the thermal gradient), the temperature being relatively homogeneous in a radial direction relative to the stack of beds.
According to one embodiment of the invention, a fixed bed comprises a gas-permeable wall, such as a grid, and a stack of heat storage particles on this wall. A staged arrangement of such fixed beds facilitates the upstream homogeneous loading of granular solid, and tends to allow a better radial homogeneity of the temperature, essential to the proper functioning of the system. This embodiment can be advantageously and not exclusively limited to the embodiments that will be described below in the description below.
The illustrative figures of embodiments of the present invention will subsequently be represented in a nonlimiting and non-exhaustive manner according to a heat storage means in the form of a column, the fixed particle beds of the heat storage means being superposed along the axis of revolution of the column, and the heat storage means comprising means for injecting and withdrawing gases perpendicular to the stratification induced by the stacking of fixed beds.
According to one embodiment of the invention, a discontinuity of the thermal gradient between at least two adjacent beds is obtained by separating said fixed beds by a layer comprising a thermally insulating material, through which the gas can circulate. The insulating material may be any material with very low thermal conductivity known to those skilled in the art. According to an embodiment in which the fixed beds comprise a gas-permeable wall, there is interposed between such fixed beds a layer free of solid particles (filled with air for example, the air being the thermally insulating material). The thermal insulation layers make it possible to limit the diffusion of the temperature from one fixed bed of particles to another. The use of thermally insulating layers thus makes it possible to obtain a thermal stratification (discontinuous thermal gradient) within the heat storage means and a better redistribution of the gas. Moreover, the fact of separating the fixed beds by layers of thermal insulation (with in addition an impermeable wall in the case of a solid-free insulating layer) allows a better distribution of the solid particles in the storage means and thus to limit hydrodynamic and thermal heterogeneities that affect the efficiency of the system.
According to one embodiment of the invention, a layer comprising a thermally insulating material is interposed between each fixed bed of particles forming the heat storage means. The thermal gradient within the heat storage means according to the invention is then a stepwise thermal gradient, which allows optimal exploitation of the compressed gas storage and energy recovery system according to the invention.
Figures 2 and 3 illustrate an embodiment of the heat storage means 1 of the system for storing and restoring energy by compressed gas, in the case of the storage phase (also called "charge" thereafter; Figure 2) and in the case of the restitution phase (also called "discharge" thereafter, Figure 3). According to this variant of the system according to the invention, the heat storage means 1 is in the form of a column and consists of five fixed beds 2 of particles 3 arranged one above the other, each bed being separated from the beds adjacent to each other by a layer of thermal insulation 4. Figures 2 and 3 also show the direction of the flow of compressed gas, printed by means of injection and withdrawal compressed gas 7 placed perpendicularly to the direction of the stratification induced by the two fixed beds of particles. In particular, the dark arrows represent the main direction of the hot gas while the clear arrows represent the main direction of the cold gas. During the charging of the heat storage means 1, illustrated in FIG. 3, the hot gas GC (at the outlet of the gas compression means) is injected by the upper end of the column 1. Thus, the arrangement of the heat storage means according to the invention requires a circulation of compressed gas in the axial direction relative to the fixed beds, that is to say that the fluid to be heated or cooled circulates from a bed to the other, in a direction perpendicular to the stack of fixed beds forming the heat storage means, in this case in the axial direction of the heat storage means (in this case the column). During the discharge of the heat storage means 1, illustrated in FIG. 3, the cold gas GF (at the outlet of the storage means for the compressed gas or an expansion stage) is injected by the lower end of the column. 1. The cold gas GF axially passes through the fixed beds 2, one after the other. Then, the hot gas GC is extracted from the column 1 in the upper part to be directed to the expansion means of the system according to the invention. As an illustration, the evolution of the temperature curve T within the storage means according to this embodiment is represented artificially in these solid lines. It can be noted that the thermal gradient has many discontinuities, from one bed to another, the discontinuities being induced by the layers of thermal insulation interposed between two adjacent fixed beds.
According to another embodiment, a discontinuity of the thermal gradient between two adjacent fixed beds is obtained by using particles containing a phase change material (PCM) characterized by different melting temperatures for each of the fixed particles beds. question. The use of phase-change materials with different melting temperatures for the fixed beds of the heat storage means makes it possible to induce a stepped thermal gradient in the storage means, and thus to limit the thermal diffusion phenomena. a fixed bed of particles to another during the storage phases. Another advantage of these materials lies in the fact that they allow a reduction in the volume of the tank, allowing to 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 point is less than 130 °, salts which melt at temperatures above 300 ° C., mixtures (eutectics) which allow to have a wide range of melting temperature.
According to one embodiment of the invention, at least one fixed MCP particle bed is placed in the vicinity of the inlet of the heat storage means and / or a fixed MCP particle bed near the exit of the medium. heat storage. By input of the heat storage means is meant the place where the hot compressed gas is introduced into said means, and the outlet of the heat storage means is called the place where the hot compressed gas leaves said means. Note that the input and output of the heat storage means may vary during the operation of the compressed gas energy storage system according to the invention. This configuration allows the benefits of MCP to control the thermal gradient and reduce the volume of solid while reducing the overall cost, the MCP being mostly more expensive than heat sensitive materials. 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 °, more preferably between 5 and 200, and even more preferably between 10 and 100 ° C.
An example of this embodiment is shown in FIG. 4. In this example, the heat storage means 1 is in the form of a column, the hot side (respectively cold side) located at the top (respectively at the bottom) of the column, and is formed of six fixed beds 2 of particles, two of these beds 2 being formed of particles MCP 5, and the other four beds 2 being formed of particles with sensitive heat 3. According to this nonlimiting example of implementation of the invention, the MCP fixed particle beds 5 are placed in second position relative to the inlet and outlet of the compressed gas of the heat storage means. During the charge phase shown in FIG. 4, the hot gas GC (at the outlet of the compression means) is injected through the upper end of the column 1. The hot gas passes axially through the fixed beds 2, passing successively from the one to another. 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). The particulate beds MCP 5 thus placed in particular make it possible to ensure a good retention over time of the thermal bearings at the inlet and outlet of the heat storage means. As an illustration, the evolution of the temperature curve T within the storage means according to this embodiment is represented artificially in this figure in solid lines. It can be noted that the thermal gradient has many discontinuities, from one bed to another because of the use of MPC having different melting temperatures from one bed to another.
According to a particular mode of implementation of the invention, each of the fixed beds of particles of the storage means comprises particles containing a phase change material (PCM) characterized by different melting temperatures. The melting temperatures of the different phase change materials are chosen so as to provide a predetermined temperature gradient in the multi-stage bed. The temperature differences within each bed relative to the average of the bed in question are then very small, and the thermal gradient is then a stepwise thermal gradient, each level being very clearly differentiated from the neighbor, which allows a very high good control of the temperature gradient within the heat storage means. 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).
An exemplary embodiment of such an embodiment of the invention is shown in FIG. 5. In this example, the heat storage means 1 is in the form of a column, the hot side (respectively cold) being located at the top (respectively bottom) of the column, and is formed of six fixed beds 2 of particles MCP 5. The particles MCP 5 of each fixed bed 2 have a different melting temperature T1, T2, T3, T4, T5 and T6, with T6 <T5 <T4 <T3 <T2 <T1, the fixed bed with the MCPs having the melting temperature T1 being on the warm side (injection / withdrawal of the hot gas GC), and the fixed bed with the MCPs having the melting temperature T6 being on the cold side (injection / withdrawal of cold gas GF). During the charging phase shown in FIG. 5, the hot gas GC (at the outlet of the compression means) is injected through the upper end of the column 1. The hot gas passes axially through the fixed beds 2, passing successively from the one to another. 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). The main advantage of staggering MCP is an increased control of the thermal gradient, and thus an increased control of the input / output temperatures of the storage means during the charging / discharging cycles.
According to one embodiment of the invention, the heat storage means of the compressed gas storage and energy recovery system according to the invention may comprise at least one fixed bed or beds of MCP particles and a or layers comprising a thermally insulating material, a fixed bed comprising MCP particles that can for example be separated from another fixed bed, MCP or not, by a thermal insulation layer. These two means of maintaining a homogeneous temperature within the fixed beds, while allowing discontinuities of the thermal gradient, used in combination, make it possible to optimize the control of the temperature gradient of temperatures within the heat storage means.
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 on both the complete process and the type of material used for the fixed bed particles of the heat storage means.
In the configurations described above, the gas injection and withdrawal means are provided at the 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 previously described possible configurations of the heat storage means.
An advantage of this embodiment is that the injection system / racking stage reduces 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. For this embodiment, the thermal gradient is discontinuous between the fixed individual beds located between the complementary injection and withdrawal means used, that is to say the fixed beds storing or returning heat.
According to one embodiment of the invention, the additional injection and withdrawal means of the heat storage means comprise a distribution grid which is interposed between two fixed beds of particles. It should be noted that the flow of compressed gas induced by these complementary injection and withdrawal means comprises a local radial component (at the level of the grid and around the grid), but the flow of compressed gas through the beds of the Staggered arrangement still remains mainly axial. Preferably, a layer of thermal insulation is contiguous to one of the faces of the grid, so as to limit the heat exchange between the beds between which the distribution grid is contiguous. FIG. 6 shows a nonlimiting example of implementation of a storage means 1 comprising complementary injection and withdrawal means comprising a grid 6, as well as a thermal insulation layer 4, inserted between each stage of fixed beds 2 of particles.
In FIGS. 7a, 7b to 7c are illustrated (in a nonlimiting manner) three consecutive phases of charging of a heat storage system in the form of a column, the hot side (respectively cold) located at the top (respectively bottom) of the column, and consisting of seven floors of fixed beds of particles. The storage means of this embodiment comprises main injection means (dark arrows) and withdrawal (clear arrows) 7, and further, complementary injection means (dark arrows) and withdrawal (clear arrows) 8 installed on each floor, intercalated with a layer of thermal insulation. The axial temperature gradient T at the beginning of each of these phases is artificially represented in the multi-stage bed by a solid line. During the first charging phase (Figure 7a), the hot gas GC is injected from above 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 charge is made on three stages (FIG. 7a) at the same time, that is to say that the hot fluid passes through three stages before exiting the heat storage means by a first complementary withdrawal means. located between the third and fourth beds. When the charging temperature is reached in these stages, the injection is done by a complementary means 8 directly in one of the lower stages (FIGS. 7b and 7c). Thus, the load of such a system can be done sequentially, by stage, or group of stages, from the inlet to the outlet, which makes it possible to limit the pressure losses 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 storage means upwards. During this phase, the discharge can also be done on a different number of stages, as illustrated in FIGS. 8a to 8c where the discharge is done in groups of five or four stages.
Figure 9a 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, fluid of the heat storage means. The duty cycle comprises a first charging phase CH (energy storage) between times t0 and t1, then a second storage phase ST (energy storage) between times t1 and t2, and then a discharge phase. DE (energy restitution) between instants t2 and t3, and a waiting phase AT between instants t3 and t0.
FIGS. 9b and 9c 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. 9a. For this example, the heat storage means corresponds to the embodiment of FIG. 4, for which the heat storage means comprises two fixed beds with MCPs, each fixed bed of MCP having a different melting temperature 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. 9b corresponds to the charging phase CH of FIG. 9a, and FIG. 9c corresponds to the discharge phase DE of FIG. 9a.
In FIG. 9a, 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 state. 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 sensible heat storage equipment.
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. 9c, it is observed that the cold fluid enters the cold side and heats up, absorbing latent heat in the MCP2 stage 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 of storage and restitution by compressed gas, in which 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 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 two fixed beds of heat storage particles and at least one means for forming a discontinuity of the thermal gradient between at least two adjacent beds. This multistage arrangement of fixed beds of particles combined with means of discontinuity of the thermal gradient makes it possible to create a thermal stratification within the storage means, but also to better control the porosity in each of the beds, and thus to avoid the formation of cold pockets that affect the efficiency of the system. Thus, the storage and the return of energy 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 axial gas d from one bed to another, • injection and withdrawal of the gas at the ends of the heat storage means and / or at intermediate levels, • the heat storage particles may be phase change material particles these MCP particles can be placed in fixed beds located near the ends of the heat storage means, • a circulation of the hot gas from the upper part to the lower part of the column, or vice versa from the lower part to the lower part of the column, 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 (FIGS. 7 and 8), the process can comprise the following steps: i) the heat is stored on a first portion of fixed beds by a first heat exchange 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 (14)
[1" id="c-fr-0001]
1. Compressed gas storage and energy 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), characterized in that said heat storage means (1) comprises a stepped arrangement of at least two fixed beds (2). ) heat storage particles, and at least one means (4,5) for forming a discontinuity of the thermal gradient between at least two adjacent beds (2).
[0002]
2) System according to claim 1, wherein said two fixed beds (2) are separated by a wall permeable to said gas.
[0003]
3) System according to one of the preceding claims, wherein one of said discontinuity means of said thermal gradient comprises a layer formed of a thermally insulating material (4), said layer separating at least two of said fixed beds (2).
[0004]
4) System according to one of claims 1 to 3, wherein one of said discontinuity means of said thermal gradient is formed by at least two of said fixed beds (2) comprising particles of phase change material (5).
[0005]
5) System according to claim 4, wherein at least two of said fixed beds (2) comprise particles of phase change material (5) of different melting temperature and are each located near one of the ends of said intermediate means. heat exchange (1).
[0006]
6) System according to claim 4, wherein at least two of said fixed beds (2) comprise particles of phase change material (5) of different melting temperature and are located in second position of said arrangement by counting from an end of said heat exchange means (1).
[0007]
7) System according to one of the preceding claims, wherein a mainly axial passage of said compressed gas through said fixed beds (2) is induced by compressed gas injection and withdrawal means (7) placed perpendicularly to said tiered arrangement said beds (2).
[0008]
8) System according to claim 7, wherein said storage means (1) comprises means for injecting and withdrawing complementary gases (6) located at least one stage of said stationary fixed bed arrangement (2) of particles of storage.
[0009]
9) System according to claim 8, wherein said complementary compressed gas injection and withdrawal means (6) comprise a distribution grid interposed between said constituent beds (2) of said stage.
[0010]
10) System according to claim 9, wherein a layer formed of a thermally insulating material (4) is contiguous on one of the faces of said grid.
[0011]
11) Process for storing and restoring energy by compressed gas, in which the following steps are performed: f) a gas is compressed; g) said compressed gas is cooled by heat exchange in a heat storage means (1); h) storing said cooled gas; i) heating said cooled compressed gas by returning heat to said heat storage means (1); and j) said heated compressed gas is expanded to generate energy, characterized in that for storing and returning heat said gas passes through said heat storage means, said means comprising a stepped arrangement of at least two fixed beds (2) heat storage particles, and at least one means (4,5) for forming a thermal gradient discontinuity between at least two adjacent beds.
[0012]
12) The method of claim 10, wherein said gas is injected and withdrawn at the ends of said heat storage means.
[0013]
13) The method of claim 11, wherein said gas is injected and withdrawn at at least one intermediate fixed bed.
[0014]
14) The method of claim 12, wherein it implements the following steps: i) stores the heat 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.

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE102008033527A1|2008-07-17|2010-01-21|Leithner, Reinhard, Prof. Dr. techn.|Heat reservoir, has endothermic fluid flowing through latent heat reservoir sections in opposite direction, where exothermic fluid and endothermic fluid flow in same tubes or channels, and sections are designed in pressure-resistant manner|

---

EP2450549A2|2010-11-04|2012-05-09|Theo Tietjen|Compression heat-storage power plant or energy storage method for temporarily storing energy in the form of pressure energy in a compressible medium in the form of heat energy|

---

WO2013131202A1|2012-03-07|2013-09-12|Airlight Energy Ip Sa|Pressurised energy storage system in which the heat accumulator is arranged in an overpressure zone|

---

WO2015150104A1|2014-04-03|2015-10-08|IFP Energies Nouvelles|System for heat storage using a fluidised bed|

---

JPS5757512B2|1980-10-29|1982-12-04|Kogyo Gijutsuin|

---

US7923112B2|2005-05-12|2011-04-12|Sgl Carbon Se|Latent heat storage material and process for manufacture of the latent heat storage material|

---

US8544275B2|2006-08-01|2013-10-01|Research Foundation Of The City University Of New York|Apparatus and method for storing heat energy|

---

US20110094231A1|2009-10-28|2011-04-28|Freund Sebastian W|Adiabatic compressed air energy storage system with multi-stage thermal energy storage|

---

US20110100010A1|2009-10-30|2011-05-05|Freund Sebastian W|Adiabatic compressed air energy storage system with liquid thermal energy storage|

---

US8739522B2|2010-10-29|2014-06-03|Nuovo Pignone S.P.A.|Systems and methods for pre-heating compressed air in advanced adiabatic compressed air energy storage systems|

---

GB2485836A|2010-11-27|2012-05-30|Alstom Technology Ltd|Turbine bypass system|

---

GB201104867D0|2011-03-23|2011-05-04|Isentropic Ltd|Improved thermal storage system|

---

EP2530283B1|2011-05-31|2013-09-11|Ed. Züblin Ag|Adiabatic pressurised air storage power plant|

---

US20130105106A1|2011-10-31|2013-05-02|Dharendra Yogi Goswami|Systems And Methods For Thermal Energy Storage|

---

GB201207114D0|2012-04-23|2012-06-06|Isentropic Ltd|Improved thermal energy storage apparatus|

---

ES2480765B1|2012-12-27|2015-05-08|Universitat Politècnica De Catalunya|Thermal energy storage system combining solid heat sensitive material and phase change material|

---

FR3014182B1|2013-11-29|2018-11-16|IFP Energies Nouvelles|ADVANCED SYSTEM FOR ENERGY STORAGE BY COMPRESSED AIR|

---

US10294861B2|2015-01-26|2019-05-21|Trent University|Compressed gas energy storage system|FR3069019A1|2017-07-12|2019-01-18|IFP Energies Nouvelles|SYSTEM AND METHOD FOR STORING AND RECOVERING COMPRESSED GAS ENERGY WITH EXCHANGE OF DIRECT HEAT BETWEEN GAS AND A FLUID|

---

WO2019097932A1|2017-11-16|2019-05-23|株式会社Ihi|Energy storage device|

---

FR3074276B1|2017-11-28|2019-10-18|IFP Energies Nouvelles|SYSTEM AND METHOD FOR HEAT STORAGE AND RESTITUTION WITH FLANGE|

---

EP3732420A1|2017-12-29|2020-11-04|Vito NV|Storage integrated heat exchanger|

---

FR3098287B1|2019-07-04|2021-06-11|Ifp Energies Now|A system and method for storing and recovering heat, comprising a radial passage through storage particles.|

法律状态:
2016-12-12| PLFP| Fee payment|Year of fee payment: 2 |

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2017-06-09| PLSC| Publication of the preliminary search report|Effective date: 20170609 |

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2017-12-14| PLFP| Fee payment|Year of fee payment: 3 |

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2018-12-19| PLFP| Fee payment|Year of fee payment: 4 |

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2020-10-16| ST| Notification of lapse|Effective date: 20200910 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1561875A|FR3044750B1|2015-12-04|2015-12-04|SYSTEM AND METHOD FOR COMPRESSED GAS ENERGY STORAGE AND RESTITUTION|FR1561875A| FR3044750B1|2015-12-04|2015-12-04|SYSTEM AND METHOD FOR COMPRESSED GAS ENERGY STORAGE AND RESTITUTION|

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PT16306489T| PT3176529T|2015-12-04|2016-11-15|System and method for storing and restoring energy by compressed gas|

---

ES16306489T| ES2711164T3|2015-12-04|2016-11-15|System and procedure for storage and restitution of energy by compressed gas|

---

EP16306489.2A| EP3176529B1|2015-12-04|2016-11-15|System and method for storing and restoring energy by compressed gas|

---

US15/366,978| US10294824B2|2015-12-04|2016-12-01|Compressed gas energy storage and restitution system and method|