CN211476352U - Multi-purpose underground energy storage system with layered structure characteristics - Google Patents

Abstract

The utility model relates to the technical field of energy storage, in particular to a multipurpose underground energy storage system with a layered structure, which comprises an energy storage body, an underground energy storage cavity, a heat preservation layer and a heat exchanger; the buried energy storage cavity is arranged in the energy storage body, and the insulating layer covers the energy storage body and the upper part of the buried energy storage cavity; bury the energy storage chamber and divide into steam chamber, liquid chamber and heat transfer chamber on footpath, the heat transfer chamber has the sub-chamber of multilayer heat exchanger in the axial, and the sub-chamber bottom both sides of heat exchanger of bottommost are equipped with the liquid outlet respectively, and one of them liquid outlet communicates with the steam chamber, and another communicates with the liquid chamber, and the liquid outlet with the liquid chamber intercommunication all sets up in the lower part of every layer of heat exchanger sub-chamber all the other, and every layer of heat exchanger sub-chamber is equipped with the steam outlet with the steam chamber intercommunication. The utility model discloses can effectively overcome the heat accumulation phenomenon that exists among the underground energy storage system and annotate the adverse effect of ability and energy storage process to the system, both can realize layering intermittent type energy storage and also can realize that the intermediate level concentrates the energy storage function.

Description

Multi-purpose underground energy storage system with layered structure characteristics

Technical Field

The utility model relates to an energy storage technology field, more specifically say so, relate to a multipurpose underground energy storage system with hierarchical structure characteristic.

Background

In recent years, underground energy storage systems are receiving wide attention at home and abroad due to good economic effects and wide application prospects of energy storage technologies. Underground energy storage systems can be divided into active and passive types according to different system driving modes (phase change and water pump) and different circulating heat exchange media (phase change and non-phase change). Among them, active underground energy storage systems have been widely used, including: underground aquifer energy storage (ATES), buried pipe energy storage (BTES), Water Tank Energy Storage (WTES), gravel-water energy storage (GWES) and the like. Nevertheless, active underground energy storage also exposes problems in practice, such as: the system completely drives a circulating working medium to flow through an underground space by a water pump to perform heat exchange and energy storage, so that the driving power consumption is high, and the energy storage energy efficiency ratio (the ratio of the energy storage to the energy storage power consumption) is low; meanwhile, the circulating working medium in the system is a non-phase-change working medium, and the underground heat exchange and energy storage process is completed in a sensible heat exchange mode, so that the heat exchange and energy storage efficiency is lower, the effective utilization rate of a cold and heat source at the supply side is low, the energy consumption of the system is further increased, and the energy storage energy efficiency ratio is further reduced. In this context, the concept of passive underground energy storage systems is emerging.

The passive underground energy storage system mainly utilizes the phase change drive of a phase change working medium to complete the energy storage process, and can complete the underground heat exchange energy storage process without the drive of a water pump, so the drive power consumption of the system is greatly reduced, and the energy storage energy efficiency ratio is greatly improved; meanwhile, the latent heat exchange mode is adopted to complete the underground energy storage and heat exchange process, so that the energy storage and heat exchange efficiency is greatly improved compared with that of an active system. However, the current passive underground energy storage system still has a plurality of technical problems to be solved due to the structural limitation and the lack of theoretical guidance.

Firstly, because the thermal diffusion coefficient of the underground energy storage body is small, the underground energy storage system with an active mode or a passive mode has a remarkable thermal accumulation effect in the energy storage process. If the energy injected into the underground energy storage body is accumulated in a local area around the heat exchange surface for a long time and cannot be effectively and quickly diffused, the heat exchange temperature difference on two sides of a heat exchange interface is greatly reduced. Under the condition that the heat exchange area and the heat exchange coefficient are not changed, the heat exchange amount of the underground energy storage system is greatly attenuated compared with the initial time period, which is one of direct reasons for the low energy storage efficiency of the current active/passive underground energy storage system and one of main reasons for restricting the large-scale popularization of the underground energy storage system.

In addition, the existing active or passive underground energy storage system almost adopts the technical means of direct energy injection and energy storage. The important characteristics of direct energy injection and energy storage are that the energy of cold and heat sources at the supply side is injected and stored in the whole underground energy storage body in a uniform mode through a buried pipe and the like. The disadvantages of this energy injection and storage are significant, especially given the cold and heat sources on the supply side. In this way, the energy storage quality of the underground energy storage system basically depends only on the thermophysical conditions of the underground energy storage body, so that the energy storage quality cannot be dynamically adjusted according to the requirements of a demand side. This also results in the underground energy storage system adopting direct energy injection and storage lacking flexibility and expansibility of energy storage application, limiting its further popularization and application.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the technical defect who exists among the prior art, and provide a multipurpose underground energy storage system with layered structure characteristic, can effectively solve "hot pile up" phenomenon that underground energy storage system exists, both can realize "layering intermittent type energy storage" and also can realize that "the intermediate level concentrates the energy storage" function, satisfies the different demands of demand side to energy storage "volume" or energy storage "matter".

In order to achieve the aim, the scheme provides a multipurpose underground energy storage system with a layered structure characteristic, which comprises an energy storage body, an underground energy storage cavity, a heat preservation layer and a heat exchanger; the buried energy storage cavity is arranged in the energy storage body, and the insulating layer covers the energy storage body and the upper part of the buried energy storage cavity; the underground energy storage cavity is divided into three mutually independent areas in the diameter, namely a steam cavity, a liquid cavity and a heat exchange cavity, the heat exchange cavity is provided with a plurality of layers of heat exchanger sub-cavities in the axial direction, two sides of the bottom of the heat exchanger sub-cavity at the bottommost layer are respectively provided with a liquid outlet, one liquid outlet is communicated with the steam cavity, the other liquid outlet is communicated with the liquid cavity, the lower parts of the other layers of heat exchanger sub-cavities are provided with liquid outlets communicated with the liquid cavity, and each layer of heat exchanger sub-cavity is provided with a steam outlet communicated with the steam cavity;

a first working medium interface of the heat exchanger is connected with one end of a first fluid pipe, the other end of the first fluid pipe penetrates through the upper end of the underground energy storage cavity and enters the steam cavity, the end face of a pipe orifice of the first fluid pipe is positioned at the upper part of the steam cavity and is higher than the steam outlet of the heat exchange sub-cavity at the uppermost layer, a first fluid pipe electromagnetic valve is arranged on the first fluid pipe, a second fluid pipe is connected to the upper part of the first fluid pipe electromagnetic valve, the other end of the second fluid pipe penetrates through the upper end of the underground energy storage cavity and enters and penetrates through each layer of heat exchanger sub-cavity, a second fluid pipe branch pipe is arranged in each heat exchange sub-cavity of the second fluid pipe, and the;

a second working medium interface of the heat exchanger is connected with one end of a third fluid pipe, a third fluid pipe main pipe electromagnetic valve is installed on the third fluid pipe, a variable frequency working medium pump is connected in parallel on a bypass pipeline of the third fluid pipe main pipe electromagnetic valve, the other end of the third fluid pipe penetrates through the upper end of the underground energy storage cavity to enter and penetrate through each layer of heat exchanger sub-cavity, a third fluid pipe branch pipe is arranged in each heat exchange sub-cavity, an outlet is positioned at the lower part of each heat exchanger sub-cavity, and a third fluid pipe electromagnetic valve is installed on each third fluid pipe branch pipe;

energy storage body temperature sensors are respectively arranged at the middle positions of the energy storage bodies corresponding to the sub-cavities of each layer of heat exchanger, and liquid level sensors are respectively arranged in the sub-cavities of each layer of heat exchanger;

the first fluid pipe electromagnetic valve, the second fluid pipe electromagnetic valve, the third fluid pipe electromagnetic valve, the variable frequency working medium pump, the energy storage body temperature sensor and the liquid level sensor are respectively connected with the controller through signal lines.

Preferably, the volume of the space below the liquid outlet of each heat exchange sub-cavity is not less than one half of the filling amount of the system working medium.

Preferably, the upper part of the heat exchanger is provided with a heat exchanger inlet and a heat exchanger outlet.

Preferably, the steam outlet is located above the side of each layer of heat exchanger subcavities.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses can effectively overcome ubiquitous "heat pile up" phenomenon among the underground energy storage system and annotate the adverse effect of ability and energy storage process to the system, both can realize "layering intermittent type energy storage" and also can realize "the intermediate level and concentrate the energy storage" function. The layered intermittent energy storage can greatly reduce the power consumption of the system under the condition of required energy storage or greatly improve the energy storage efficiency of the system under the condition of given energy injection; and the energy storage grade and the energy density of the energy storage body can be greatly improved by 'the middle layer concentrates energy storage'. Therefore, the utility model discloses both can realize promoting the application purpose of energy storage "volume", also can be applied to promoting the application purpose of energy storage "matter", effectively promoted the flexibility ratio and the expansibility that underground energy storage system used.

Drawings

FIG. 1 is a schematic diagram of a multi-purpose energy storage system featuring a layered structure according to the present invention;

fig. 2 shows a specific structure of the present invention;

FIG. 3 is a top plan view of an underground energy storage cavity;

FIG. 4 is a cross-sectional view of the buried energy storage chamber A-A;

figure 5 shows a cross-sectional view of the buried energy storage chamber B-B.

1. An energy storage body; 2. a heat-insulating layer; 3. an underground energy storage cavity; 4. a steam chamber; 5. a liquid chamber; 6. a heat exchange cavity; 7. a steam outlet; 8. a liquid outlet; 9. a first fluid tube; 10. a second fluid tube; 11. a third fluid pipe; 12. a second fluid tube solenoid valve; 13. a second fluid tube branch; 14. a third fluid tube solenoid valve; 15. a third fluid tube leg; 16. a first fluid tube solenoid valve; 17. a heat exchanger; 18. an inlet of the heat exchanger; 19. an outlet of the heat exchanger; 20. a variable frequency working medium pump; 21. a third fluid line trunk solenoid valve; 22. a controller; 23. working medium; 24. an energy storage body temperature sensor; 25. a liquid level sensor.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

The utility model discloses a multipurpose underground energy storage system with hierarchical structure characteristic schematic diagram is shown in fig. 1, a multipurpose underground energy storage system with hierarchical structure characteristic, including energy storage body 1, heat preservation 2, bury energy storage chamber 3, heat exchanger 4, fluid pipeline and corresponding control system. The energy storage body 1 is provided with a drill hole, the multiple layers of underground energy storage cavities 3 are arranged in the drill hole, and the upper parts of the energy storage body 1 and the underground energy storage cavities 3 are covered with heat preservation layers 2. The underground energy storage cavity 3 is divided into three mutually independent areas on the diameter, namely a steam cavity 4, a liquid cavity 5 and a heat exchange cavity 6. The heat exchange cavity 6 is provided with a multi-layer heat exchanger sub-cavity structure in the axial direction. Steam chamber 4 communicates with the liquid outlet 8 intercommunication that the heat exchanger of bottom was sub-chamber upper portion set up through the steam outlet 7 and the bottom set up, except that bottom heat exchanger chamber is sub-chamber, steam chamber 4 communicates with other heat exchanger sub-chambers through the steam outlet 7 that each layer was sub-chamber upper portion set up. Liquid chamber 5 and the liquid outlet 8 intercommunication that the sub-chamber bottom of bottom heat exchanger set up, except that the sub-chamber of bottom heat exchanger chamber, liquid chamber 5 and other heat exchanger sub-chambers lean on the liquid outlet 8 intercommunication that the upper position (non-bottom) set up through each sub-chamber lower part. The position of each heat exchange sub-cavity liquid outlet 8 is related to the volume of the working medium filled in the system, and the volume of the space below each heat exchange sub-cavity liquid outlet 8 is not less than one half of the filling amount of the working medium in the system. One end of the first fluid pipe 9 is connected with a first working medium interface of the heat exchanger 17, the other end of the first fluid pipe penetrates through the upper end of the underground energy storage cavity 3 to enter the interior of the steam cavity 4, and the end face of the pipe orifice is positioned at the upper part of the steam cavity 4 and higher than the steam outlet position of the uppermost heat exchange cavity. One end of the second fluid pipe 10 is connected into the first fluid pipe 9, the other end of the second fluid pipe passes through the upper end of the underground energy storage cavity 3 to enter and penetrate through each heat exchange cavity of the heat exchange cavity 6, and the second fluid pipe 10 is provided with a second fluid pipe branch pipe 13 in each heat exchange cavity, and the outlet of the second fluid pipe branch pipe is located at the upper part of each heat exchange cavity. Third fluid pipe 11 one end with the second working medium interface connection of heat exchanger 17, the other end passes bury energy storage cavity 3 upper end and get into and run through each heat transfer sub-chamber of heat transfer cavity 6, and third fluid pipe 11 all is equipped with third fluid pipe branch pipe 15 and export and is located the lower part of each heat transfer sub-chamber in each heat transfer sub-chamber. The first fluid pipe 9 is provided with a first fluid pipe electromagnetic valve 16 between the outlet of the steam cavity 4 and the inlet of the second fluid pipe 10, the tail end of the second fluid pipe branch 13 is provided with a second fluid pipe electromagnetic valve 12, and the tail end of the third fluid pipe branch 15 is provided with a third fluid pipe electromagnetic valve 14. And a third fluid pipe main electromagnetic valve 21 is arranged on the third fluid pipe main, and a frequency conversion working medium pump 20 is arranged on a bypass pipeline of the third fluid pipe main electromagnetic valve 21. The heat exchanger 17 upper portion is equipped with heat exchanger import 18 and heat exchanger export 19, each layer intermediate position department is provided with a plurality of energy storage body temperature sensor 24 in the energy storage body 1, be equipped with level sensor 25 in each sub-chamber of heat transfer chamber. The temperature sensor, the electromagnetic valve and the variable frequency working medium pump are all connected with the controller 22 through signal lines.

As shown in fig. 2, use to be equipped with 4 layers of heat transfer sub cavities in the heat transfer chamber 6 as an example, the utility model discloses a multipurpose underground energy storage system operation mode with layered structure characteristic divide into, and layering intermittent type is cold-storage, layering intermittent type heat-retaining, is concentrated and is stored up cold and concentrate four kinds of modes of heat-retaining, and the preferred energy storage strategy that further corresponds includes: the three types of the intermittent energy storage of the second heat exchange sub-cavity, the third heat exchange sub-cavity, the first heat exchange sub-cavity and the fourth heat exchange sub-cavity, the intermittent energy storage of the first heat exchange sub-cavity and the third heat exchange sub-cavity, and the concentrated energy storage of the second heat exchange sub-cavity and/or the third heat exchange sub-cavity are adopted.

The layered cold storage mode is as follows: because working medium 23 gathers in the bottom (fourth) heat transfer subchamber under the natural state, no matter be with "second, third heat transfer subchamber and first, fourth heat transfer subchamber intermittent heat storage" or "first, third heat transfer subchamber and second, fourth heat transfer subchamber intermittent heat storage" tactics operation, controller 22 all need send layering cold storage mode preparation instruction to the system at first. Take "second, third heat exchange subchamber and first, fourth heat exchange subchamber intermittent cold storage" as the example: the first fluid line solenoid valve 16 and the third fluid line solenoid valve 21 and the third fluid line solenoid valves 14-2 and 14-3 are first opened and the remaining solenoid valves are closed. Under the heating of heat in the energy storage body 1, the phase change working medium 23 gathered at the bottom of the underground energy storage cavity 3 absorbs heat in a pool boiling heat exchange mode, changes phase and evaporates into steam, the steam is gradually gathered in the upper space of the fourth heat exchange sub-cavity 6-4, enters the steam cavity 4 through the steam outlet 7-4 under the action of phase change force, and then enters the heat exchanger 17 through the first fluid pipe 9. The steam is condensed into liquid working medium by phase change under the cooling effect of the cold fluid at the inlet 18 of the heat exchanger, and the liquid working medium finally flows back to the second heat exchange subcavities and the third heat exchange subcavities under the action of gravity because only the electromagnetic valves 14-2 and 14-3 are opened on the third fluid pipe branch pipe 15. When the liquid level sensors 25-2 and 25-3 monitor that the liquid levels in the second heat exchange sub-cavity 6-2 and the third heat exchange sub-cavity 6-3 are close to be consistent and the fourth heat exchange sub-cavity 6-4 has no working medium basically, the first stage preparation process of 'intermittent cold storage of the second heat exchange sub-cavity and the third heat exchange sub-cavity and the first heat exchange sub-cavity and the fourth heat exchange sub-cavity' is completed. Then under the heating of heat in the energy storage body 1, the phase change working medium 23 gathered in the second and third heat exchange sub-cavities absorbs heat in a pool boiling heat exchange mode, undergoes phase change evaporation to form steam, the steam is gradually gathered in the upper spaces of the corresponding heat exchange sub-cavities, enters the steam cavity 4 through the steam outlets 7-2 and 7-3 under the action of phase change force, and then enters the heat exchanger 17 through the first fluid pipe 9. The steam is condensed into liquid working medium by phase change under the cooling effect of the 18 cold fluid at the inlet of the heat exchanger, and finally flows back to the second heat exchange sub-cavity 6-2 and the third heat exchange sub-cavity 6-3 under the action of gravity, so that the cold storage of the second heat exchange sub-cavity and the third heat exchange sub-cavity is completed. And when the difference between the average value monitored by the energy storage body temperature sensors 24-2 and 24-3 and the average value monitored by the energy storage body temperature sensors 24-1 and 24-4 exceeds 0.5-1 ℃, preparing for storing cold in the first heat exchange cavity and the fourth heat exchange cavity. At the moment, the electromagnetic valves 14-2 and 14-3 of the third fluid pipe are closed, 14-1 and 14-4 are opened, liquid working media flow back to the first heat exchange sub-cavity 6-1 and the fourth heat exchange sub-cavity 6-4 after heat exchange circulation, and when the liquid level sensors 25-1 and 25-4 monitor that the liquid levels in the first heat exchange sub-cavity 6-1 and the fourth heat exchange sub-cavity 6-4 are nearly consistent and no working media exists in the second heat exchange sub-cavity 6-2 and the third heat exchange sub-cavity 6-3, the second-stage preparation process of 'intermittent cold storage' of the second heat exchange sub-cavity, the third heat exchange sub-cavity and the first heat exchange sub-cavity and the fourth heat exchange sub-cavity is completed. Then, under the heating of heat in the energy storage body 1, the phase change working medium 23 gathered in the first heat exchange sub-cavity 6-1 and the fourth heat exchange sub-cavity 6-4 absorbs heat in a pool boiling heat exchange mode to be subjected to phase change evaporation to form steam, the steam is gradually gathered in the upper space of the heat exchange sub-cavities, enters the steam cavity 4 through the steam outlets 7-1 and 7-4 under the action of phase change force, and then enters the heat exchanger 17 through the first fluid pipe 9. The steam is condensed into liquid working medium through phase change under the cooling effect of the cold fluid at the inlet 18 of the heat exchanger, and finally flows back to the first heat exchange sub-cavity 6-1 and the fourth heat exchange sub-cavity 6-4 under the action of gravity, so that cold storage of the first heat exchange sub-cavity and the fourth heat exchange sub-cavity is completed. When the difference between the average value monitored by the energy storage body temperature sensors 24-1 and 24-4 and the average value monitored by the energy storage body temperature sensors 24-2 and 24-3 exceeds 0.5-1 ℃, the cold storage of the second heat exchange cavity and the third heat exchange cavity is carried out again. The process is repeated continuously, and finally the intermittent cold storage of the second heat exchange sub-cavity, the third heat exchange sub-cavity, the first heat exchange sub-cavity and the fourth heat exchange sub-cavity is finished. The "first and third heat exchange subchambers and the second and fourth heat exchange subchambers store cold intermittently" are similar and will not be described herein again.

The layered heat storage mode is as follows: because working medium 23 gathers in the bottom (fourth) heat exchange subchamber under natural state, no matter be with "second, third heat exchange subchamber and first, fourth heat exchange subchamber intermittent heat storage" or "first, third heat exchange subchamber and second, fourth heat exchange subchamber intermittent heat storage" tactics operation, controller 22 all need send layering heat storage mode preparation instruction to the system at first. Take "second, third heat exchanger subchamber and first, fourth heat exchanger subchamber intermittent heat-retaining" as the example: the second fluid line solenoid valves 12-2, 12-3 and the third fluid line solenoid valve 14-4 are opened, and the remaining solenoid valves remain closed. The variable frequency working medium pump 20 is started, under the driving of the variable frequency working medium pump 20, the phase change working medium 23 gathered at the bottom of the underground energy storage cavity 3 is rapidly pumped into the heat exchanger 17 and is subjected to the heating action of the hot fluid at the inlet 18 of the heat exchanger to absorb heat and evaporate in a phase change manner to form steam, then the steam enters the underground energy storage cavity 3 through the second fluid pipe 10, and the steam enters the second and third heat exchange sub-cavities through the second fluid pipe branch pipes 13-2 and 13-3 because only the second fluid pipe electromagnetic valves 12-2 and 12-3 are opened on the second fluid pipe. The steam entering the second heat exchange sub-cavity and the third heat exchange sub-cavity is subjected to phase change condensation under the cooling action of the wall surface of the underground energy storage cavity 3 to become liquid working media, and finally flows back to the bottoms of the second heat exchange sub-cavity and the third heat exchange sub-cavity under the action of gravity. When the liquid level sensors 25-2 and 25-3 monitor that the liquid levels in the second heat exchange sub-cavity and the third heat exchange sub-cavity are close to be consistent and the working medium in the fourth heat exchange sub-cavity is basically free of the working medium, the first stage preparation process of 'intermittent heat storage of the second heat exchange sub-cavity and the third heat exchange sub-cavity and the first heat exchange sub-cavity and the fourth heat exchange sub-cavity' is completed. Then closing the electromagnetic valve 14-4 of the third fluid pipe and opening 14-2 and 14-3, under the drive of the variable frequency working medium pump, phase change working medium 23 gathered at the bottom of the second and third heat exchange sub-chambers is pumped into the heat exchanger 17 and is heated by the hot fluid at the inlet 18 of the heat exchanger to absorb heat and undergo phase change evaporation to form steam, the steam enters the underground energy storage chamber 3 through the second fluid pipe 10, and enters the second and third heat exchange sub-chambers through the branch pipes 13-2 and 13-3 of the second fluid pipe respectively, then undergoes phase change condensation to form liquid working medium under the cooling action of the wall surface of the underground energy storage chamber 3, and finally flows back to the bottom of the second and third heat exchange sub-chambers under the action of gravity, and heat storage of the second and third heat exchange sub-chambers is completed. When the difference between the average value monitored by the energy storage body temperature sensors 24-2 and 24-3 and the average value monitored by the energy storage body temperature sensors 24-1 and 24-4 exceeds 0.5-1 ℃, the preparation of heat storage of the first heat exchange cavity and the fourth heat exchange cavity is carried out. At the moment, the second fluid pipe electromagnetic valves 12-2 and 12-3 are closed, 12-1 and 12-4 are opened, steam enters the first heat exchange sub-cavity and the fourth heat exchange sub-cavity after heat exchange circulation and undergoes phase change condensation, liquid working media flow back to the bottoms of the first heat exchange sub-cavity and the fourth heat exchange sub-cavity, and when the liquid level sensors 25-1 and 25-4 monitor that the liquid levels in the first heat exchange sub-cavity and the fourth heat exchange sub-cavity are close to the same and no working media exist in the second heat exchange sub-cavity and the third heat exchange sub-cavity, the second stage preparation process of' intermittent heat storage of the second heat exchange sub-cavity, the third heat exchange sub-cavity and the first heat exchange sub. Then, the electromagnetic valves 14-1 and 14-4 of the third fluid pipe are opened, 14-2 and 14-3 are closed, under the drive of the variable frequency working medium pump, the phase change working medium 23 gathered at the bottoms of the first and fourth heat exchange sub-chambers is pumped into the heat exchanger 17 and absorbs heat under the heating action of the hot fluid at the inlet 18 of the heat exchanger to undergo phase change evaporation to form steam, the steam enters the underground energy storage chamber 3 through the second fluid pipe 10 and enters the first and fourth heat exchange sub-chambers through the branch pipes 13-1 and 13-4 of the second fluid pipe respectively, then undergoes phase change condensation to form liquid working medium under the cooling action of the wall surface of the underground energy storage chamber 3, and finally flows back to the bottoms of the first and fourth heat exchange sub-chambers under the action of gravity, and heat storage of the first and fourth heat exchange sub-chambers is completed. When the difference between the average value monitored by the energy storage body temperature sensors 24-1 and 24-4 and the average value monitored by the energy storage body temperature sensors 24-2 and 24-3 exceeds 0.5-1 ℃, the preparation of heat storage of the second heat exchange cavity and the third heat exchange cavity is carried out again. The process is repeated continuously, and the intermittent heat storage of the second heat exchange sub-cavity, the third heat exchange sub-cavity, the first heat exchange sub-cavity and the fourth heat exchange sub-cavity is finally completed. The intermittent heat storage of the first heat exchange sub-cavity, the third heat exchange sub-cavity, the second heat exchange sub-cavity and the fourth heat exchange sub-cavity is similar, and the description is omitted here.

The concentrated cold storage mode is as follows: similarly, since the working medium 23 is collected in the bottommost (fourth) heat exchange sub-chamber in a natural state, the controller 22 needs to first issue a centralized cold storage mode preparation instruction to the system no matter whether the operation is performed by strategies such as "2 centralized cold storage", "3 centralized cold storage", or "2 and 3 centralized cold storage". Take "2 concentrated cold storage" as an example: the first fluid line solenoid valve 16 and the third fluid line solenoid valve 21 and the third fluid line solenoid valve 14-2 are first opened and the remaining solenoid valves are closed. Under the heating of heat in the energy storage body 1, the phase change working medium 23 gathered at the bottom of the underground energy storage cavity 3 absorbs heat in a pool boiling heat exchange mode, changes phase and evaporates into steam, the steam is gradually gathered in the upper space of the fourth heat exchange sub-cavity, enters the steam cavity 4 through the steam outlet 7-4 under the action of phase change force, and then enters the heat exchanger 17 through the first fluid pipe 9. The steam is condensed into liquid working medium through phase change under the cooling effect of cold fluid at the inlet 18 of the heat exchanger, and the liquid working medium finally flows back to the second heat exchange sub-cavity under the action of gravity because only the electromagnetic valve 14-2 is opened on the third fluid pipe branch pipe 15. When the liquid level sensors 25-2 and 25-4 monitor that the working medium completely enters the second heat exchange sub-cavity, the preparation process of '2 concentrated cold storage' is completed. And then under the heating of heat in the energy storage body 1, the phase-change working medium 23 gathered in the second heat exchange sub-cavity absorbs heat in a pool boiling heat exchange mode, undergoes phase-change evaporation to form steam, the steam is gradually gathered in the upper space of the corresponding heat exchange sub-cavity, enters the steam cavity 4 through the steam outlet 7-2 under the action of phase-change force, and enters the heat exchanger 17 through the first fluid pipe 9. Steam is subjected to phase change condensation under the cooling effect of 18 cold fluids at the inlet of the heat exchanger to form liquid working media, and finally flows back to the second heat exchange sub-cavity under the action of gravity, so that the concentrated cold storage of the second heat exchange sub-cavity is completed. The "third concentrated cold storage in the heat exchange subchamber" and the "second and third concentrated cold storage in the heat exchange subchamber" are similar and will not be described herein again.

The concentrated heat storage mode is as follows: similarly, since the working medium 23 is collected in the bottommost layer (fourth) heat exchange sub-chamber in a natural state, the controller 22 needs to send a preparation instruction of a concentrated heat storage mode to the system firstly no matter the operation is carried out by strategies such as "concentrated heat storage in the second heat exchange sub-chamber", "concentrated heat storage in the third heat exchange sub-chamber", or "concentrated heat storage in the second heat exchange sub-chamber and the third heat exchange sub-chamber". Take "2 concentrated heat storage" as an example: the second fluid line solenoid valve 12-2 and the third fluid line solenoid valve 14-4 are opened, and the remaining solenoid valves are maintained in a closed state. The variable frequency working medium pump 20 is started, under the driving of the variable frequency working medium pump 20, the phase change working medium 23 gathered at the bottom of the underground energy storage cavity 3 is pumped into the heat exchanger 17 and is heated by the hot fluid at the inlet 18 of the heat exchanger to absorb heat and evaporate in a phase change manner to form steam, then the steam enters the underground energy storage cavity 3 through the second fluid pipe 10, and the steam enters the second heat exchange sub-cavity through the second fluid pipe branch pipe 13-2 because only the second fluid pipe electromagnetic valve 12-2 on the second fluid pipe is opened. The steam entering the second heat exchange sub-cavity is subjected to phase change condensation under the cooling action of the wall surface of the underground energy storage cavity 3 to become liquid working medium, and finally flows back to the bottom of the second heat exchange sub-cavity under the action of gravity. When the liquid level sensor 25-2 monitors that all the working media enter the second heat exchange sub-cavity, the preparation process of 2 concentrated heat storage is completed. Then, the electromagnetic valve 14-4 of the third fluid pipe is closed and the electromagnetic valve 14-2 is opened, under the drive of the variable frequency working medium pump, the phase change working medium 23 gathered at the bottom of the second heat exchange sub-cavity is pumped into the heat exchanger 17 and absorbs heat under the heating action of the hot fluid at the inlet 18 of the heat exchanger to be phase change evaporated into steam, the steam enters the underground energy storage cavity 3 through the second fluid pipe 10 and enters the second heat exchange sub-cavity through the second fluid pipe branch pipe 13-2, then the phase change condensation is carried out under the cooling action of the wall surface of the underground energy storage cavity 3 to be liquid working medium, and finally the steam flows back to the bottom of the second heat exchange sub-cavity under the action of gravity, so that the concentrated heat. The concentrated heat storage of the third heat exchange sub-chamber and the concentrated heat storage of the second heat exchange sub-chamber and the third heat exchange sub-chamber are similar, and the description is omitted here.

The utility model discloses can effectively overcome "hot pile up" phenomenon that exists among the underground energy storage system and annotate the adverse effect of ability and energy storage process to the system, both can realize "layering intermittent type energy storage" and also can realize "the intermediate level concentrates the energy storage" function. The layered intermittent energy storage can greatly reduce the power consumption of the system under the condition of required energy storage or greatly improve the effective energy storage efficiency of the system under the condition of given energy injection, and the intermediate layer concentrated energy storage can greatly improve the energy storage grade and energy density of the energy storage body. Therefore, the utility model discloses both can realize promoting the application purpose of energy storage "volume", also can be applied to promoting the application purpose of energy storage "matter", effectively promoted the flexibility ratio and the expansibility that underground energy storage system used.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (4)

1. A multipurpose underground energy storage system with a layered structure characteristic comprises an energy storage body, an underground energy storage cavity, an insulating layer and a heat exchanger; the buried energy storage cavity is arranged in the energy storage body, and the insulating layer covers the energy storage body and the upper part of the buried energy storage cavity; the method is characterized in that: the underground energy storage cavity is divided into three mutually independent areas in the diameter, namely a steam cavity, a liquid cavity and a heat exchange cavity, the heat exchange cavity is provided with a plurality of layers of heat exchanger sub-cavities in the axial direction, two sides of the bottom of the heat exchanger sub-cavity at the bottommost layer are respectively provided with a liquid outlet, one liquid outlet is communicated with the steam cavity, the other liquid outlet is communicated with the liquid cavity, the lower parts of the other layers of heat exchanger sub-cavities are provided with liquid outlets communicated with the liquid cavity, and each layer of heat exchanger sub-cavity is provided with a steam outlet communicated with the steam cavity;

a first working medium interface of the heat exchanger is connected with one end of a first fluid pipe, the other end of the first fluid pipe penetrates through the upper end of the underground energy storage cavity and enters the steam cavity, the end face of a pipe orifice of the first fluid pipe is positioned at the upper part of the steam cavity and is higher than the steam outlet of the heat exchange sub-cavity at the uppermost layer, a first fluid pipe electromagnetic valve is arranged on the first fluid pipe, a second fluid pipe is connected to the upper part of the first fluid pipe electromagnetic valve, the other end of the second fluid pipe penetrates through the upper end of the underground energy storage cavity and enters and penetrates through each layer of heat exchanger sub-cavity, a second fluid pipe branch pipe is arranged in each heat exchange sub-cavity of the second fluid pipe, and the;

a second working medium interface of the heat exchanger is connected with one end of a third fluid pipe, a third fluid pipe main pipe electromagnetic valve is installed on the third fluid pipe, a variable frequency working medium pump is connected in parallel on a bypass pipeline of the third fluid pipe main pipe electromagnetic valve, the other end of the third fluid pipe penetrates through the upper end of the underground energy storage cavity to enter and penetrate through each layer of heat exchanger sub-cavity, a third fluid pipe branch pipe is arranged in each heat exchange sub-cavity, an outlet is positioned at the lower part of each heat exchanger sub-cavity, and a third fluid pipe electromagnetic valve is installed on each third fluid pipe branch pipe;

energy storage body temperature sensors are respectively arranged at the middle positions of the energy storage bodies corresponding to the sub-cavities of each layer of heat exchanger, and liquid level sensors are respectively arranged in the sub-cavities of each layer of heat exchanger;

the first fluid pipe electromagnetic valve, the second fluid pipe electromagnetic valve, the third fluid pipe electromagnetic valve, the variable frequency working medium pump, the energy storage body temperature sensor and the liquid level sensor are respectively connected with the controller through signal lines.

2. The multi-purpose underground energy storage system with a hierarchical structure feature of claim 1, wherein: the volume of the space below the liquid outlet of each heat exchange sub-cavity is not less than one half of the filling amount of the system working medium.

3. The multi-purpose underground energy storage system with a hierarchical structure feature of claim 1, wherein: and the upper part of the heat exchanger is provided with a heat exchanger inlet and a heat exchanger outlet.

4. The multi-purpose underground energy storage system with a hierarchical structure feature of claim 1, wherein: the steam outlet is positioned above the side part of each layer of the heat exchanger sub-cavity.

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