CN109780909B - Method for sharing heat energy among multiple family stations - Google Patents

Abstract

The invention belongs to the field of energy transmission, and discloses a method for sharing heat energy among multiple household stations, wherein the multiple household stations are communicated in a heat conduction manner, the method also comprises an energy storage station, the energy storage station is communicated with each household station in a heat conduction manner, and the method comprises the following steps: acquiring first request heat energy required by a first home station; acquiring the available heat energy and the position of other household stations; and determining a home station or an energy storage station or both the home station and the energy storage station for supplying the first home station with heat energy according to the first requested heat energy and the available heat energy and positions of other home stations. According to the heat energy demand of the home stations, scheduling is carried out by combining the heat energy supply conditions of other home stations so as to meet the demand, energy flow among a plurality of home stations is realized, and when the energy mutually supplied by the home stations is insufficient, the energy is supplemented by the energy storage station. The overall utilization efficiency of energy is improved, and the energy-saving and environment-friendly effects are achieved.

Description

Method for sharing heat energy among multiple family stations

Technical Field

The invention relates to the technical field of energy transmission, in particular to a method for sharing heat energy among multiple family stations.

Background

In a general home environment, there are a plurality of home appliances, and the plurality of types of home appliances often have different functions and are all related to heat conversion. For example, an air conditioner needs to refrigerate, on the other hand, heat can be dissipated, and similarly, a refrigerator needs to consume electric energy or dissipate heat during refrigeration, and on the other hand, a water heater needs to heat hot water and consume electric energy; in winter, the air conditioner needs to heat and can release part of cold energy. Some need heat, some give off heat, some need cold volume, some give off cold volume, and the heat and the cold volume that give off are all not effectively utilized, have caused very big energy waste. Therefore, how to uniformly schedule and utilize the heat and the cold emitted by the electric appliance, reduce energy consumption and waste, and realize energy conservation and emission reduction is a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a method for sharing heat energy among multiple household stations, which aims to solve the problem of how to uniformly schedule and utilize the heat energy and the cold energy emitted by electric appliances. The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview and is intended to neither identify key/critical elements nor delineate the scope of such embodiments. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

According to a first aspect of embodiments of the present invention, there is provided a method of sharing thermal energy between multiple home stations.

In some optional embodiments, the plurality of home stations are in thermal conduction communication with each other, and further comprising an energy storage station in thermal conduction communication with each of the home stations, respectively, the method comprising:

acquiring first request heat energy required by a first home station;

acquiring the available heat energy and the position of other household stations;

and determining a home station or an energy storage station or both the home station and the energy storage station for supplying the first home station with heat energy according to the first requested heat energy and the available heat energy and positions of other home stations.

In some optional embodiments, the first requested thermal energy is a difference between an average used thermal energy of the first home station for the first period of time and a current and current thermal energy margin.

In some optional embodiments, the average heat energy used in the first period of time is an average daily heat energy used, or an average monthly heat energy used.

In some optional embodiments, the determining a home station, or an energy storage station, or a home station and an energy storage station, which supply thermal energy to the first home station, according to the first requested thermal energy and the suppliable thermal energy and the location of the other home stations, includes:

determining a second home station group which can supply the first request heat energy with the heat energy larger than the set proportion in other home stations;

and determining the household station or the energy storage station or the household station and the energy storage station for supplying the first household station with the heat energy according to the first request heat energy and the available heat energy and the position of each household station in the second household station group.

In some optional embodiments, the set ratio is a ratio of a minimum value of a first requested thermal energy available for transfer to the first requested thermal energy.

In some alternative embodiments, the set proportion is a multiple of the first requested heat energy.

In some alternative embodiments, the set proportion is the inverse of the number of equal parts of the first requested thermal energy.

In some optional embodiments, the determining a home station or an energy storage station or a home station and an energy storage station that supply thermal energy to the first home station according to the first requested thermal energy and the suppliable thermal energy and the location of each home station in the second home station group includes:

determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy;

determining that the first home station is supplied with thermal energy by all home stations and energy storage stations in the second group of home stations when the total available thermal energy in the second group of home stations is less than the first requested thermal energy.

In some optional embodiments, determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy comprises:

acquiring heat conduction loss of each home station in the second home station group and heat energy transmitted by the first home station;

and selecting the household stations in the second household station group according to the sequence of the heat conduction losses from small to large until the sum of the supplied heat energy of the selected household stations is larger than or equal to the first requested heat energy.

In some alternative embodiments, the home station comprises a heat output device, a cold output device, a heat consuming device, and a cold consuming device;

the energy storage station comprises a heat storage device and a cold storage device;

the input end of the heat consumption equipment is communicated with the output end of the heat storage device in a heat conduction mode, the input end of the cold consumption equipment is communicated with the output end of the cold storage device in a heat conduction mode, the output end of the heat output equipment is communicated with the input end of the heat storage device in a heat conduction mode, and the output end of the cold output equipment is communicated with the input end of the cold storage device in a heat conduction mode;

the heat consumption equipment is connected with the heat storage device, or the heat storage device is connected with the heat output equipment, or the cold consumption equipment is connected with the cold storage device, or the cold output equipment is connected with the cold storage device in a heat conduction mode through the transfer heat exchanger.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

according to the heat energy demand of the home stations, scheduling is carried out by combining the heat energy supply conditions of other home stations so as to meet the demand, the heat energy flow among a plurality of home stations is realized, and when the heat energy mutually supplied by the home stations is insufficient, the heat energy is supplemented by the energy storage station. The overall utilization efficiency of heat energy is improved, and the energy-saving and environment-friendly effects are achieved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

FIG. 1 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 2 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 3 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 4 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 5 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 6 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 7 is a schematic diagram illustrating the structure of an energy storage station in accordance with an exemplary embodiment;

FIG. 8 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 9 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 10 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 11 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 12 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 13 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 14 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 15 is a schematic diagram of a construction of a relay heat exchanger according to an exemplary embodiment;

FIG. 16 is a schematic diagram illustrating the construction of an energy station according to an exemplary embodiment;

FIG. 17 is a schematic diagram illustrating a configuration of an energy station according to an exemplary embodiment;

fig. 18 is a schematic diagram illustrating a configuration of an energy station according to an exemplary embodiment.

Detailed Description

The following description and the drawings sufficiently illustrate specific embodiments herein to enable those skilled in the art to practice them.

Example 1

As shown in fig. 1, in an energy storage station 10, an energy absorbing terminal 101 of the energy storage station 10 is used for absorbing energy of a temperature adjusting device (absorbing terminal temperature adjusting device 1011) capable of generating corresponding energy, and an energy releasing terminal 102 is used for releasing energy to a temperature adjusting device (releasing terminal temperature adjusting device 1021) requiring corresponding energy.

Herein, the temperature adjusting device refers to a device which can bring about a change in temperature of itself or the environment when the device is operated, such as a refrigerator, an air conditioner, an air energy compressor, a solar heat collection and temperature adjustment device, a mobile robot heat release charger, a water heater, a heating and temperature adjustment device, a heating device, a compressor, a cold collection and temperature adjustment device, and a freezer.

The specific form of the energy storage station 10 is not limited, and the main function is to store energy, and the energy storage station 10 is provided with an energy storage material which can store energy and ensure the heat insulation of the energy storage station 10. The energy storage station 10 may be a thermally insulated tank filled with energy storage material. Or a storage pool dug on the ground, and the inner wall of the storage pool is subjected to heat insulation treatment.

The energy storage station 10 of the embodiment of the present invention may be applied to a single household, and may also be applied to one cell or community. The application scenarios are different, the number of temperature regulating devices is different, and the storage capacity of the energy storage station 10 is different. For example, when applied in a single household setting, the number of temperature conditioning devices is limited, typically not exceeding 10. When the energy storage station is applied to a cell or even a larger community, the number of the external temperature adjustment devices is huge, and the energy storage amount of the energy storage station 10 needs to be large. The energy storage station, when having an application, may be determined only by the actual situation.

In the energy storage station 10 according to the embodiment of the present invention, the stored energy may be divided into heat and cold, i.e., heat energy, according to the temperature of the energy. Therefore, the heat and the cold are relative concepts, and the division is only required according to a set limit (such as a temperature limit). Thus, in an alternative embodiment, the energy storage station 10 of an embodiment of the present invention may be a heat storage device (heat storage station) 11 or a cold storage device (cold storage station) 12.

The energy absorbing end 101 of the heat storage device 11 is a heat absorbing end 111 for absorbing heat of the first temperature adjusting device 1111 capable of generating heat, and the energy releasing end 102 is a heat releasing end 112 for releasing heat to the second temperature adjusting device 1121 requiring heat. For example, the first temperature adjusting device may be a refrigerator, an outdoor unit of an air conditioner during air conditioning, an air energy compressor, a solar heat collecting temperature adjusting device, a heat releasing charger of a mobile robot, and the like. The second temperature adjusting device can be a water heater, a heating air conditioner, a heating temperature adjusting device, a heating device and the like.

The energy absorbing terminal 101 of the cold storage device 12 is a cold absorbing terminal 121 (i.e., a heat releasing terminal) for absorbing cold of the third temperature adjusting apparatus 1211 capable of generating cold, and the energy releasing terminal 102 is a cold releasing terminal 122 (i.e., a heat absorbing terminal) for releasing cold to the fourth temperature adjusting apparatus 1221 requiring cold. For example, the third temperature adjusting device may be an outdoor unit of an air conditioner, a compressor, a cooling and temperature adjusting device, or the like, when the air conditioner is heating. The fourth temperature regulating device may be a refrigerator, an ice chest, a refrigerated air conditioner, or the like.

The energy storage station 10 of embodiments of the present invention may include one or more thermal storage devices 11, and one or more cold storage devices 12. The specific number and types of the settings can be determined according to the set application scene.

In the embodiment of the present invention, the energy storage station 10 described below may be referred to as a heat storage station 11 or a cold storage station 12, unless otherwise specified. When the energy storage station 10 is operating as the heat storage station 11, the energy absorbing terminal 101 is a heat absorbing terminal and the energy discharging terminal 102 is a heat discharging terminal. When the energy storage station 10 is operating as a cold storage station 12, the energy absorbing terminal 101 is a cold absorbing terminal and the energy discharging terminal 102 is a cold discharging terminal.

In the embodiment of the present invention, the energy storage station 10 can absorb energy generated by one or more temperature control devices at the same time, and can also release energy to one or more temperature control devices at the same time, so that according to the actual situation of the external temperature control device, one or more energy absorption terminals 101 and one or more energy release terminals 102 can be provided, and the specific number is determined according to the actual situation.

In the energy storage station 10 according to the embodiment of the present invention, the energy absorption end 101 is used for absorbing energy of the temperature adjustment device 1011 (the first temperature adjustment device 1111 and the third temperature adjustment device 1211) capable of generating corresponding energy, and the absorption modes are various, for example, when a fluid medium is used as a carrier, the energy absorption end 101 is communicated with a heat exchange device at the side of the temperature adjustment device 1011 at the absorption end through a pipeline by using a heat exchange device, and a medium circulation path is formed between the energy storage station 10 and the temperature adjustment device. The fluid medium absorbs the energy generated by the temperature adjusting device side and then flows to the energy absorption end 101 of the energy storage station 10, the energy storage material in the energy storage station 10 absorbs and stores the energy of the medium at the energy absorption end 101, the fluid medium after releasing the energy flows out to the heat exchange device at the temperature adjusting device side to absorb the energy generated by the temperature adjusting device side, and the circulation is carried out, so that the energy storage of the energy storage station 10 is completed.

In an alternative embodiment, the energy absorbing terminals 101 of the energy storage station 10 are one or more, each energy absorbing terminal 101 being independently located. For example, the energy absorption end 101 of the energy storage station 10 comprises one (as shown in fig. 5) or more first heat exchange devices (as shown in fig. 4), the first heat exchange device has an inlet pipe 141 and an outlet pipe 142 (i.e., a group of communicating pipes 14), and is communicated with the heat exchange device on the side of the absorption end temperature regulation device 1011 through two pipes, and energy conversion is performed between the temperature regulation devices (the first temperature regulation device 1111 and the third temperature regulation device 1211) and the energy storage station 10 through respective medium circulation paths. For another example, as shown in fig. 3, the energy absorption end 101 is a first heat exchange device, and the liquid inlet end of the first heat exchange device is connected to a plurality of liquid inlet pipes 141, and the liquid outlet end is connected to a plurality of liquid outlet pipes 142. One liquid inlet pipe 141 and one liquid outlet pipe 142 are used as a communicating pipe group 14 to form a plurality of independently arranged communicating pipe groups, and the communicating pipe groups are communicated with the terminal heat exchange device on the side of the external temperature regulating equipment. The energy absorption device is suitable for a scene that a plurality of external temperature adjustment devices input energy to the energy absorption end 101 at the same time. The flow control devices are arranged at the positions of the liquid inlet pipes at the liquid inlet end and the liquid outlet pipes at the liquid outlet end of the first heat exchange device, so that energy generated by one or more temperature adjusting devices can be absorbed simultaneously by controlling the flow control devices, the flow of media in a medium circulation pipeline of each temperature adjusting device is adjusted, and different heat exchange efficiencies are realized. In a further alternative embodiment, the energy absorption end 101 of the energy storage station 10 may further include a plurality of terminal heat exchangers, each terminal heat exchanger having a terminal liquid inlet pipe and a terminal liquid outlet pipe, which are respectively connected to the second liquid outlet pipe and the liquid inlet pipe of the first heat exchanger through two pipes. The terminal heat exchange device is arranged on the side of the temperature adjusting equipment 1011 at the absorption end and used for absorbing energy generated by the temperature adjusting equipment. The first heat exchanger and the terminal heat exchanger form a medium circulation path, and the energy generated by the temperature adjusting device is converted into the energy storage station 10 through a fluid medium. When the energy storage station 10 is the heat storage station 11, the terminal heat exchange device is arranged on the side of the first temperature regulating device 1111. When the energy storage station 10 is the cold storage station 12, the terminal heat exchanger is disposed on the third temperature control device 1211 side.

In another alternative embodiment, the energy absorbing end 101 of the energy storage station 10 is multiple, and the conduits of the multiple energy absorbing ends 101 are interconnected. The communication is performed in many ways as long as the heat exchange device on the temperature adjusting device side and the energy absorbing end 101 can form a medium circulation path. For example, as shown in fig. 6, the energy absorption terminals 101 are communicated with the liquid outlet transit line 152 through the liquid inlet transit line 151, the liquid inlet pipe 141 of each energy absorption terminal 101 is communicated with the liquid inlet transit line 151, and the liquid outlet pipe 142 of each energy absorption terminal 101 is communicated with the liquid outlet transit line 152. And then the liquid inlet transit pipeline 151 and the liquid outlet transit pipeline 152 are used as a group of communicating pipeline group, and are communicated with a terminal heat exchange device at the side of the temperature adjusting equipment through two pipelines, and energy conversion is carried out between the temperature adjusting equipment (the first temperature adjusting equipment and the third temperature adjusting equipment) and the energy storage station 10 through respective medium circulation passages. That is, the liquid inlets of the energy absorption ports 101 (the first heat exchange devices) are communicated, and the liquid outlets are communicated. The flow control devices are arranged at the communication ports of the inlet liquid transfer pipeline 151 and the outlet liquid transfer pipeline 152, so that the energy generated by one or more temperature adjusting devices can be absorbed simultaneously, and the energy can be transmitted to one or more energy absorption ends 101.

Similarly, the energy releasing end 102 is used for releasing energy to the temperature adjusting equipment needing corresponding energy. For example, when a fluid medium is used as a carrier, the energy releasing end 102 is connected with the heat exchange device on the equipment side through a pipeline by using a heat exchange device, and a medium circulation path is formed between the energy storage station 10 and the releasing end temperature adjusting equipment 1021 (the second temperature adjusting equipment 1121 and the fourth temperature adjusting equipment 1221). The fluid medium absorbs the energy in the energy storage material of the energy storage station 10 in the energy release end 102 and then flows to the terminal heat exchange device at the side of the temperature regulating device 1021, the temperature regulating device side absorbs the energy in the fluid medium, the fluid medium after the energy release flows back to the energy release end 102 of the energy storage station 10, and the cycle is repeated, so that the energy release of the energy storage station 10 is completed.

In an alternative embodiment, the energy release end 102 of the energy storage station 10 is one or more, and the piping of each energy release end 102 is independently arranged. For example, the energy discharging end 102 of the energy storage station 10 includes one (as shown in fig. 5) or a plurality of second heat exchanging devices (as shown in fig. 4), each of which has an inlet pipe 141 and an outlet pipe 142 (i.e., a group of communicating pipes 14), and is communicated with the terminal heat exchanging device at the temperature adjusting device 1021 side through two pipes, and energy is converted between the temperature adjusting devices (specifically, the second temperature adjusting device 1121 and the fourth temperature adjusting device 1221) and the energy storage station 10 through independent medium circulation paths. As another example, as shown in fig. 3, the energy releasing end 102 includes a second heat exchanging device, the liquid inlet end of the second heat exchanging device is connected to a plurality of liquid inlet pipes 141, and the liquid outlet end of the second heat exchanging device is connected to a plurality of liquid outlet pipes 142. One liquid inlet pipe 141 and one liquid outlet pipe 142 are used as a communicating pipe set 14 to form a plurality of independently arranged communicating pipe sets 14, and the independently arranged communicating pipe sets are respectively used for being communicated with a terminal heat exchange device at the side of the external release end temperature adjusting device 1021. The energy output scene of the energy release end 102 to a plurality of external temperature adjusting devices is adapted. The flow control devices are arranged at the liquid inlet pipes at the liquid inlet end and the liquid outlet pipes at the liquid outlet end of the second heat exchange device, and then the energy can be released to one or more temperature adjusting devices at the same time by controlling the flow control devices, the flow of media in a medium circulation pipeline of each temperature adjusting device is adjusted, and different heat exchange efficiencies are realized. In a further alternative embodiment, the energy discharging end 102 of the energy storage station 10 may further include a plurality of terminal heat exchanging devices, each having a terminal liquid inlet pipe and a terminal liquid outlet pipe, respectively connected to the liquid outlet pipe 142 and the liquid inlet pipe 141 of the second heat exchanging device through the two pipes. The terminal heat exchange device is arranged on the side of the temperature adjusting equipment and used for absorbing energy generated by the temperature adjusting equipment. The second heat exchange device and the terminal heat exchange device form a medium circulation path, and the energy in the energy storage station 10 is released to the temperature regulating equipment side through a fluid medium. When the energy storage station 10 is a heat storage station 11, the terminal heat exchange device is disposed at the side of the second temperature adjusting device 1121. When the energy storage station 10 is the cold storage station 12, the terminal heat exchange device is arranged on the fourth temperature regulating device 1221 side.

In another alternative embodiment, the energy release end 102 of the energy storage station 10 is multiple, and the multiple energy release ends 102 are interconnected. The communication mode is various, as long as the medium circulation path can be formed by the heat exchange device at the temperature adjusting device side and the energy releasing end 102. For example, as shown in fig. 6, the energy releasing ends 102 (the second heat exchange devices) are communicated with the outlet transit line 152 through the inlet transit line 151, the inlet pipe 141 of each energy releasing end 102 (each second heat exchange device) is communicated with the inlet transit line 151, and the outlet pipe 142 of each energy releasing end 102 (each second heat exchange device) is communicated with the outlet transit line 152. And then the liquid inlet transit pipeline 151 and the liquid outlet transit pipeline 152 are used as a group of communicating pipeline group, and are communicated with a heat exchange device at the side of the temperature adjusting equipment through two pipelines, and energy conversion is carried out between the temperature adjusting equipment (the first temperature adjusting equipment and the third temperature adjusting equipment) and the energy storage station 10 through respective medium circulation passages. That is, the liquid inlets of the energy release ends 102 (the second heat exchange devices) are communicated, and the liquid outlets are communicated. The flow control devices are arranged at the communication ports on the liquid inlet transfer pipeline and the liquid outlet transfer pipeline, so that energy can be released from one or more energy release ends 102 at the same time, and energy can be released to one or more temperature adjusting devices at the same time.

In the embodiment of the present invention, the heat exchange devices used for the energy absorption end 101 and the energy release end 102 of the energy storage station 10 may be plate heat exchangers, evaporators, condensers, heat exchange coils, and the like.

In the energy storage station 10 according to the embodiment of the present invention, the energy absorption end 101 and the energy release end 102 may be arranged in the same manner or in different manners.

In an alternative embodiment, the energy absorption end 101 and the energy release end 102 of the energy storage station 10 are identical in construction. Specifically, the energy storage station 10 includes the following four embodiments:

as shown in fig. 5, in the first energy storage station 10, the energy absorbing end 101 is a first heat exchange device, and is communicated with the heat exchange device on the temperature adjusting device side through a group of communicating pipelines. The energy releasing end 102 is a second heat exchange device, and is communicated with the heat exchange device at the side of the temperature adjusting device through a group of communicating pipelines. That is, the pipe of the energy-absorbing end 101 and the pipe of the energy-releasing end 102 are provided independently. That is, the energy absorbing end 101 of the first energy storage station 10 is a first heat exchange device having a set of independent communicating pipe sets, and the energy discharging end 102 is a second heat exchange device having a set of independent communicating pipe sets for communicating with the heat exchange device on the side of the temperature adjusting device.

As shown in fig. 6, in the second energy storage station 10, the energy absorption end 101 is a plurality of first heat exchange devices, and is communicated with the heat exchange device on the temperature adjustment device side through a communicating pipe set (composed of an inlet liquid transfer pipe 151 and an outlet liquid transfer pipe 152). The energy releasing end 102 is a plurality of second heat exchange devices, and is communicated with the heat exchange device at the side of the temperature adjusting device through a group of communicating pipeline sets (composed of a liquid inlet transit pipeline 151 and a liquid outlet transit pipeline 152). That is, the conduits of the plurality of energy absorbing ports 101 communicate with each other, and the conduits of the plurality of energy discharging ports 102 communicate with each other. That is, the energy storage station 10 of the second type has a plurality of energy absorption terminals 101, and the liquid inlet pipes and the liquid outlet pipes of the plurality of energy absorption terminals are communicated with each other and communicated with the heat exchanger on the temperature adjusting device side through a communicating pipe group. The energy release ends 102 are multiple, and liquid inlet pipes and liquid outlet pipes of the multiple energy release ends are mutually communicated and are communicated with a heat exchange device at the side of the temperature adjusting equipment through a group of communicating pipeline groups.

As shown in fig. 1 and 3, in the third energy storage station 10, the energy absorption end 101 is a first heat exchange device, and is communicated with the heat exchange device on the temperature adjusting device side through a plurality of communicating pipe sets. The energy releasing end 102 is a second heat exchange device and is communicated with the heat exchange device at the side of the temperature adjusting device through a plurality of communicating pipeline sets. The plurality of communicating pipe groups of one energy absorbing terminal 101 are independently provided, and the plurality of communicating pipe groups of one energy discharging terminal 102 are independently provided. That is, the third energy storage station 10 has one energy absorption end 101 having a plurality of sets of independently provided communication pipe groups, and one energy discharge end 102 having a plurality of sets of independently provided communication pipe groups.

As shown in fig. 4, in the fourth energy storage station 10, the energy absorption end 101 is a plurality of first heat exchange devices, and the communicating pipe group 14 formed by the liquid inlet pipe 141 and the liquid outlet pipe 142 of each heat exchange device is communicated with the heat exchange device on the temperature adjusting device side. The energy releasing end 102 is a plurality of second heat exchanging devices, and is communicated with the heat exchanging device on the side of the temperature adjusting device through a communicating pipeline group 14 formed by a liquid inlet pipe 141 and a liquid outlet pipe 142 of each heat exchanging device. The communicating tube group of each energy absorption port 101 is independently provided, and the communicating tube group of each energy release port 102 is independently provided. That is, the energy absorbing terminals 101 of the fourth energy storage station are plural, and the communicating pipe groups of each energy absorbing terminal 101 are independently arranged; the energy release end 102 of the energy storage station is multiple, and the communicating pipeline group of each energy release end 102 is independently arranged.

Of course, the energy absorbing end 101 and the energy discharging end 102 of the energy storage station 10 may be arranged differently. The specific setting mode is determined by combining according to the situation, and is not described in detail herein.

In an alternative embodiment, the energy storage station 10 further comprises a plurality of flow control devices 13, the plurality of flow control devices 13 being arranged in the lines of the energy absorption end 101 and the energy release end 102 of the energy storage station 10, respectively. The flow control device has the function of adjusting the flow, including power action and throttling action. Where the power action is used to increase the flow and the throttling action is used to decrease the flow. In embodiments where energy exchange is performed by a fluid medium, the flow control device may be a power pump and solenoid valve, or an expansion valve, etc. The energy absorbing end 101 and the energy releasing end 102 of the energy storage station 10 exchange energy with external temperature adjusting devices through pipelines (liquid inlet pipe 141 and liquid outlet pipe 142), that is, one temperature adjusting device and the energy absorbing end 101 (or the energy releasing end 102) form a medium circulation pipeline, and the flow control device is arranged on the medium circulation pipeline corresponding to each temperature adjusting device. The flow rate of the medium in the medium circulation pipeline can be controlled and adjusted from zero to the maximum flow rate through the arrangement of the flow control devices, so that the storage amount or the release amount of the energy storage station 10 can be controlled and adjusted. In a specific embodiment, flow control devices are disposed at the interface of each inlet tube 141 and each outlet tube 142 of energy absorption end 101 and at the interface of each inlet tube 141 and each outlet tube 142 of energy discharge end 102, respectively.

In an embodiment of the present invention, a specific energy storage station 10 structure is provided, as shown in fig. 7, including one or more energy storage stacks 100, each energy storage stack 100 including,

an energy storage unit 110 for storing energy;

an absorption end heat exchange device 101 embedded in the energy storage stack 110;

a discharge side heat exchange device 102 embedded in the accumulator stack 110.

In the embodiment of the present invention, the energy storage unit 110 may use an existing energy storage material, such as molten salt, and may store heat. The molten salt is of various kinds, such as ceramic matrix molten salt. For another example, an ice bag can store cold. The shape of the energy storage unit is not limited, and the energy storage unit can be determined according to the physical properties of the energy storage material, for example, when molten salt is adopted, the energy storage unit adopts a rigid shell, the molten salt is packaged in the rigid shell, and a groove is formed in the rigid shell and used for embedding the absorption end heat exchange device and the release end heat exchange device.

Absorption side heat exchangers, i.e., energy absorption sides 101, can be provided in one or more of the energy storage stacks. The communicating pipelines of the absorption end heat exchange devices in the energy storage piles can be independently arranged and can also be communicated with each other. Reference is made to the foregoing.

The discharge end heat exchange devices, i.e., the energy discharge ends 102, may be provided with one or more discharge end heat exchange devices in each accumulator stack. The communicating pipelines of the heat exchange devices at the releasing ends in the energy storage piles can be independently arranged and can also be communicated with each other. Reference is made to the foregoing.

Of course, the energy storage station 10 further includes a heat-insulating housing for heat insulation and heat preservation, so as to prevent energy loss.

In this embodiment, the absorption end heat exchange device employs a first heat exchange coil; the heat exchange device at the releasing end adopts a second heat exchange coil. The coil pipe is adopted, so that the heat exchange area between the coil pipe and the heat storage unit is increased, and the storage or release efficiency is improved.

Further, the first heat exchange coil and the second heat exchange coil are arranged in the energy storage unit in a staggered mode.

When only one energy storage stack 100 is arranged in the energy storage station 10 of the present embodiment, the communication pipeline between the absorption side heat exchange device 101 and the release side heat exchange device 102 may be the structure of the first to fourth energy storage stations 10.

When a plurality of energy storage stacks 100 are arranged in the energy storage station 10 of the present embodiment, the communication pipeline of the absorption side heat exchange device 101 and the release side heat exchange device 102 in each energy storage stack 100 is arranged as shown in fig. 5 or fig. 6. And a total liquid inlet pipe and a total liquid outlet pipe are additionally arranged at the end of the absorption end heat exchange device 101, the liquid inlet pipe (141 or 151) of each absorption end heat exchange device 101 is communicated with the total liquid inlet pipe, and the liquid outlet pipe (142 or 152) of each absorption end heat exchange device 101 is communicated with the total liquid outlet pipe. Similarly, a total liquid inlet pipe and a total liquid outlet pipe are additionally arranged at the end of the release end heat exchange device 102, the liquid inlet pipe (141 or 151) of each release end heat exchange device 102 is communicated with the total liquid inlet pipe, and the liquid outlet pipe (142 or 152) of each release end heat exchange device 102 is communicated with the total liquid outlet pipe.

Example 2

In the present embodiment, the home station refers to the energy storage station 10 applied to a single home. As shown in fig. 2, the home station comprises a heat storage device 11 and a cold storage device 12. In this embodiment, the energy storage station refers to an energy storage station applied to a cell or a community, and a plurality of home stations in the cell or the community share the heat energy, including heat and cold, of the energy storage station.

The household stations are communicated with each other in a heat conduction mode, and the household stations are also communicated with the energy storage station in a heat conduction mode at the same time.

The communication mode can be various, for example, the heat release end of the household station is communicated with the heat absorption end of the energy storage station, the heat absorption end of the household station is communicated with the heat release end of the energy storage station, similarly, the cold release end of the household station is communicated with the cold absorption end of the energy storage station, and the cold absorption end of the household station is communicated with the cold release end of the energy storage station; by the connection mode, the heat storage device of the household station and the heat storage device of the energy storage station directly exchange heat; the cold storage device of the home station and the cold storage device of the energy storage station directly exchange heat. For another example, a first temperature regulating device of the home station is communicated with a heat absorbing end of the energy storage station, a second temperature regulating device of the home station is communicated with a heat releasing end of the energy storage station, similarly, a third temperature regulating device of the home station is communicated with a cold absorbing end of the energy storage station, and a fourth temperature regulating device of the home station is communicated with a cold releasing end of the energy storage station; through the connection mode, the first temperature regulating equipment and the second temperature regulating equipment of the household station directly exchange heat with the heat storage device of the energy storage station; and the third temperature regulating equipment and the fourth temperature regulating equipment of the household station directly exchange heat with the cold storage device of the energy storage station. Each communicating pipeline is provided with a flow control device for controlling heat energy transmission between the household station and the energy storage station.

The communication mode between the home stations can refer to the communication mode between the home stations and the energy storage station.

Example 3

This example is an improvement over example 2. Specifically, a first transfer heat exchanger is arranged between the heat storage device and the temperature adjusting equipment, between the cold storage device and the temperature adjusting equipment, between the heat storage device of the home station and the heat storage device of the energy storage station, and between the cold storage device of the home station and the cold storage device of the energy storage station, and plays a transfer role in transferring heat energy at two ends of the first transfer heat exchanger.

Specifically, the first intermediate heat exchanger 20 includes:

a heat absorption end 201 for absorbing heat energy of the energy storage station 10 or a temperature adjustment device (e.g., the first temperature adjustment device 1111 or the fourth temperature adjustment device 1221);

a heat releasing end 202 for releasing heat energy to the energy storage station 10 or a temperature adjusting device (e.g., the second temperature adjusting device 1121 or the third temperature adjusting device 1211).

In practical application, the number of the temperature adjusting devices is not fixed, and the number of the temperature adjusting devices can be one, two or even more; therefore, the energy storage station 10 according to the embodiment of the present invention has one or more heat absorbing ends 201 and one or more heat releasing ends 202, so as to realize one-way to multi-way, or multi-way to multi-way conversion, and can conveniently adjust the energy storage and release between the energy storage station 10 and the temperature adjusting device (the temperature adjusting device 1011 at the absorbing end or the temperature adjusting device 1021 at the releasing end), and the passage is convenient to control, and according to actual conditions, part of the passages can be conducted to perform energy exchange. And moreover, a communication pipeline between the energy storage station and the temperature regulating equipment can be simplified, the layout of the pipeline is convenient, and the cost is reduced.

In the intermediate heat exchanger 20 according to the embodiment of the present invention, when the heat absorption end 201 is communicated to the energy storage station 10, the heat release end 202 is communicated to the temperature adjustment device, and the energy storage station 10 supplies heat to the temperature adjustment device through the intermediate heat exchanger 20, or the temperature adjustment device supplies cold to the energy storage station through the intermediate heat exchanger 20. When the heat absorption end 201 is communicated with the temperature adjusting device, the heat release end 202 is communicated with the energy storage station 10, and the temperature adjusting device supplies heat to the energy storage station 10, or the energy storage station 10 supplies cold to the temperature adjusting device.

In the embodiment of the present invention, the heat absorbing end 201 is used for absorbing heat of the energy storage station 10 (or the first temperature regulating device 1111), that is, the cold releasing end (cold releasing). The specific structure adopted is various, for example, a fluid medium is used as a carrier, the heat absorption end 201 is communicated with the heat exchange device of the heat release end 112 (or the first temperature adjusting device 1111) on the side of the heat storage station 11 by a pipeline by using a heat exchange device, the fluid medium absorbs the heat on the side of the heat storage station 11 (or the first temperature adjusting device 1111), the fluid medium flows to the heat absorption end 201, and the heat absorption end 201 exchanges heat with the medium fluid of the heat release end 202, so that the heat is converted to the heat release end 202. Or, the heat absorbing end 201 is communicated with the heat exchanging device of the cold absorbing end 121 of the cold storage station 12 (or the fourth temperature adjusting device 1221) through a pipeline by using a heat exchanging device, at this time, the heat absorbing end 201 can be understood as a cold releasing end 201, the fluid medium absorbs heat (absorbing heat, namely releasing cold) of the side of the cold storage station 12 (or the fourth temperature adjusting device 1221), the fluid medium flows to the heat absorbing end 201, and the heat absorbing end 201 exchanges heat with the medium fluid of the heat releasing end 202, so that the heat is converted to the heat releasing end 202.

Similarly, the heat releasing end 202 is used for releasing heat to the energy storage station 10 (or the second temperature adjusting device 1121), i.e., a cold absorbing end (cold absorption). The specific structure adopted is various, for example, a fluid medium is used as a carrier, the heat releasing end 202 is communicated with the heat absorbing end 111 (or the second temperature adjusting device 1121) on the side of the heat storage station 11 through a pipeline by using a heat exchanging device, the fluid medium absorbs the heat on the side of the heat storage station 11 (or the second temperature adjusting device 1121), the fluid medium flows to the heat releasing end 202, and the heat releasing end 202 exchanges heat with the medium fluid of the heat absorbing end 201, so that the heat is converted to the heat absorbing end 201. Alternatively, the heat releasing end 202 is communicated with the heat exchanging device of the cold energy releasing end 122 (or the third temperature adjusting device 1211) of the cold energy storage station 12 through a pipeline by using a heat exchanging device, the fluid medium releases heat (releases heat, i.e., absorbs cold energy) to the cold energy storage station 12 side (or the third temperature adjusting device 1211), the fluid medium flows to the heat releasing end 202, and the heat releasing end 202 exchanges heat with the medium fluid of the heat absorbing end 201, so that the heat is converted to the heat absorbing end 201.

That is, when the relay heat exchanger is applied to the cold storage device, the reverse process of the transfer of heat in the relay heat exchanger 20 is the cold transfer, that is, the heat absorption is the cold release.

In an alternative embodiment, the heat absorbing end 201 is embodied by a heat exchanging device, such as a plate heat exchanger, an evaporator, or a heat exchanging coil. The heat releasing end 202 is specifically a heat exchanging device, such as a plate heat exchanger, a condenser, or a heat exchanging coil.

In the first intermediate heat exchanger 20 according to the embodiment of the present invention, the number of the heat absorbing end 201 and the heat releasing end 202, and the arrangement of the external connection pipeline set of the heat absorbing end 201 and the heat releasing end 202 may be determined according to the number of the connection pipeline sets of the heat exchanging devices on the connection side (the energy storage station side and the temperature adjusting device side).

In an alternative embodiment, the heat absorbing end 201 of the first intermediate heat exchanger 20 of the embodiment of the present invention is one or more, and the piping of each heat absorbing end 201 is independently arranged. For example, the heat absorbing end 201 includes one (as shown in fig. 8, 9 and 13) or more (see the heat releasing end 202 of the relay heat exchanger 20 in fig. 11) third heat exchanging devices, each of which has a liquid inlet pipe 211 and a liquid outlet pipe 212 (i.e., a group of communicating pipe groups 21), and is communicated with the heat exchanging device on the side of the energy storage station 10 (or the first temperature adjusting device 1111 or the fourth temperature adjusting device 1221) through two pipes, and heat on the side of the energy storage station 10 (or the first temperature adjusting device 1111 or the fourth temperature adjusting device 1221) is transferred to the heat absorbing end 201 by using a fluid medium. That is, each third heat exchanging device is independently communicated with the energy storage station 10 (or the first temperature adjusting device 1111 or the fourth temperature adjusting device 1221). As shown in fig. 10 and 12, the heat absorbing end 201 is a third heat exchanging device, and the liquid inlet end of the third heat exchanging device is connected to a plurality of liquid inlet pipes 211, and the liquid outlet end is connected to a plurality of liquid outlet pipes 212. One liquid inlet pipe 211 and one liquid outlet pipe 222 are used as a communicating pipe group 21 to form a plurality of independent communicating pipe groups, and the plurality of independent communicating pipe groups are respectively communicated with a third heat exchange device at the side of the external temperature regulating equipment.

In another alternative embodiment, the heat absorbing end 201 is multiple, and the pipelines of the heat absorbing end 201 are communicated with each other. The communication may be performed in many ways as long as a plurality of heat absorbing terminals can be communicated with the energy storage station 10 (or the first temperature adjusting device 1111 or the fourth temperature adjusting device 1221). For example, as shown in fig. 11, a plurality of heat absorbing ends 201 are communicated with a liquid outlet transit pipeline 222 through a liquid inlet transit pipeline 221, a liquid inlet pipe 211 of each heat absorbing end 201 is communicated with the liquid inlet transit pipeline 221, and a liquid outlet pipe 212 of each heat absorbing end 201 is communicated with the liquid outlet transit pipeline 222. And then the liquid inlet transit pipeline 221 and the liquid outlet transit pipeline 222 are used as a group of communicating pipeline groups and are communicated with the heat exchange device at the side of the energy storage station 10 (or the first temperature adjusting device 1111 or the fourth temperature adjusting device 1221) through two pipelines.

Similarly, when there are one or more heat releasing ends 202, the pipeline of each heat releasing end 202 is independently arranged in the same manner as the heat absorbing end 201. When there are a plurality of heat releasing ends 202, the pipelines of the heat releasing ends 202 are communicated with each other in the same manner as the heat absorbing end 201. And will not be described in detail herein.

Therefore, the first intermediate heat exchanger according to the embodiment of the present invention has the following embodiments according to the arrangement of the pipelines at the heat absorption end 201 and the heat exchange end 202.

As shown in fig. 8, the first intermediate heat exchanger i has one heat absorption end 201 and is provided with a communication pipeline group; the number of the heat releasing ends 202 is plural, and the communicating pipe groups of the plural heat releasing ends 202 are independently provided. That is, the pipes of the heat absorbing end 201 and the heat radiating end 202 are independently provided. One path is converted into multiple paths.

As shown in fig. 9, the first intermediate heat exchanger ii has one heat absorption end 201 and is provided with a communication pipeline group; one heat radiating end 202 is provided, and one heat radiating end 202 has a plurality of communicating pipe groups arranged independently. That is, the pipes of the heat absorbing end 201 and the heat radiating end 202 are independently provided. One path is converted into multiple paths.

As shown in fig. 10, in the first intermediate heat exchanger iii, there is one heat absorption end 201, and one heat absorption end 201 has a plurality of independently arranged communication pipe sets; the heat release end 202 is one and has one communicating pipe group. That is, the pipes of the heat absorbing end 201 and the heat radiating end 202 are independently provided. And (4) converting the multiple paths into one path.

As shown in fig. 11, in the first intermediate-heat exchanger v, a plurality of heat absorption ends 201 are provided, and the plurality of heat absorption ends 201 are communicated with each other and communicated with a heat exchange device on the side of the energy storage station 10 (or the absorption end temperature adjusting device 1011) through a group of communicating pipe sets; the number of the heat releasing ends 202 is plural, and the communicating pipe groups of the plural heat releasing ends 202 are independently provided. That is, the pipes of the plurality of heat absorbing ends 201 communicate with each other, and the pipes of the plurality of heat radiating ends 202 are independently provided. One path is converted into multiple paths.

As shown in fig. 12, in the first intermediate heat exchanger iv, one heat absorption end 201 is provided, and one heat absorption end 201 has a plurality of independently arranged communication pipe sets; one heat radiating end 202 is provided, and one heat radiating end 202 has a plurality of communicating pipe groups arranged independently. That is, the pipes of the heat absorbing end 201 and the heat radiating end 202 are independently provided. And (4) multiplexing the multiple paths.

As shown in fig. 13, the first intermediate heat exchanger vi has one heat absorption end 201 and is provided with one communication line group; the heat release end 202 is one and has one communicating pipe group. That is, the pipes of the heat absorbing end 201 and the heat radiating end 202 are independently provided. One path is changed into another path.

Of course, the structure of the first intermediate heat exchanger according to the embodiment of the present invention is not limited to the above six, and the structures of the heat absorbing end 201 and the heat releasing end 202 may be interchanged and may be combined arbitrarily. And determining the structure of the adaptive transfer heat exchanger according to the number of the communicating pipeline groups of the heat exchange devices at the communicating sides (the energy storage station side and the temperature regulating equipment side). In addition, when the communicating pipe sets of the heat absorption end 201 (or the heat release end 202) of the first intermediate heat exchanger are multiple, the number is not limited, and the number is determined according to the number of the energy storage stations 10 or the temperature adjusting devices to be connected.

In the first intermediate heat exchanger 20 according to the embodiment of the present invention, the heat exchanging device at the heat absorbing end 201 and the heat exchanging device at the heat releasing end 202 may be separately arranged, for example, when a plate heat exchanger is used, the two heat exchanging devices are arranged oppositely (may be contacted or not contacted), so as to ensure the heat exchanging area to be maximized; when the heat exchange coil is adopted, the coil parts of the heat exchange coil and the heat exchange coil are arranged in a staggered mode (can be contacted or not contacted), and effective heat exchange is guaranteed. Alternatively, the heat exchange device of the heat absorption end 201 and the heat exchange device of the heat release end 202 are designed as a whole. The arrangement mode is not limited, and it is sufficient if the heat exchange device of the heat absorption end 201 and the heat exchange device of the heat release end 202 can perform heat transfer. As shown in fig. 8 to 13, the heat absorbing end 201 and the heat releasing end 202 are all in a contactless type heat exchanging device structure which is oppositely arranged, although the first intermediate heat exchanger according to the embodiment of the present invention is not limited to the structure shown in the drawings.

In an alternative embodiment, the intermediate heat exchanger 20 further includes a heat absorption valve 231 disposed in series on the pipeline of the heat absorption end 201; and/or, a heat release valve 232 is disposed in series on the line of the heat release end 202. The purpose of the valves is to control the opening or closing of the heat sink 201 and heat sink 202. In the specific embodiment, a heat absorption valve 231 is disposed on the liquid inlet pipe and the liquid outlet pipe of each heat absorption end 201 (each heat exchange device), and a heat release valve 232 is disposed on the liquid inlet pipe and the liquid outlet pipe of each heat release end 202 (each heat exchange device). The opening and closing of the communication pipelines of the heat releasing end 202 and the heat absorbing end 201 of the transfer heat exchanger 20 are controlled by controlling the valves, the energy transfer is adjusted, the energy release of part of the temperature adjusting equipment from the energy storage station 10 can be controlled according to the actual situation, and the energy storage of part of the temperature adjusting equipment box from the energy storage station 10 can also be controlled.

Referring to fig. 14 and 15, in an embodiment of the present invention, there is further provided a relay heat exchanger, a second relay heat exchanger 30, including:

a heat sink end 301 for communication to an energy storage station 10/temperature conditioning device (e.g., a first temperature conditioning device 1111 or a fourth temperature conditioning device 1221);

a heat release end 302 for communicating to a temperature regulating device (e.g., the second temperature regulating device 1121 or the third temperature regulating device 1211)/the energy storage station 10; and the combination of (a) and (b),

the one-way heat conducting device 31, the heat absorbing end 301 and the heat releasing end 302 are arranged at two ends of the one-way heat conducting device 31.

According to the second transfer heat exchanger 30 provided by the embodiment of the invention, by adding the unidirectional heat conduction device 31, accurate energy can be provided for the temperature regulation equipment when the energy storage station releases energy to the temperature regulation equipment at the release end. In addition, it is also applicable when energy transmission between the energy storage station 10 and the temperature control device (the absorption-side temperature control device 1011 or the release-side temperature control device 1021) cannot be performed in a set direction. Generally, when carrying out the heat transfer, can only be from the one end that the temperature is high to the one end that the temperature is low, if this height of temperature in the heat storage station is in the medium temperature of tempering equipment output, and at this moment, the heat storage station still has the capacity of many heat supply volume storages, can't carry out heat storage according to setting for the direction to the heat storage station this moment, can cause the heat loss of heat storage station on the contrary, plays opposite effect. The same problem is encountered when the heat storage station is used for heat release. Therefore, the second intermediate heat exchanger 30 is provided in the embodiment of the present invention, and the temperature of the medium guided from the temperature control device to the heat (or cold) storage station and the temperature of the medium guided from the heat (or cold) storage station to the device are adjusted by the one-way heat conduction device 31, so that it can provide accurate energy to the temperature control device at the releasing end, or the energy storage station 10 and the temperature control device can normally perform heat transfer in a set direction.

The second intermediate heat exchanger 30 according to the embodiment of the present invention is formed by adding a unidirectional heat conducting device 31 between the heat absorbing end and the heat releasing end on the basis of the first intermediate heat exchanger 20. Therefore, the structural arrangement of the absorption end 301 and the heat release end 302 of the second intermediate heat exchanger 30 and the functions thereof are the same as those of the heat absorption end 201 and the heat release end 202 of the first intermediate heat exchanger 20, and reference is made to the foregoing description, and the description thereof will not be repeated.

Therefore, according to the structures of the first relay heat exchanger i to the first relay heat exchanger vi as shown in fig. 8 to 13, the unidirectional heat conduction device 31 is added between the heat absorption end and the heat release end, so that the second relay heat exchanger i to the second relay heat exchanger vi with the heat absorption end and the heat release end corresponding to each other can be sequentially obtained. The second intermediate heat exchanger ii 30 shown in fig. 14 is obtained by adding the unidirectional heat transfer device 31 to the first intermediate heat exchanger ii 20, and the second intermediate heat exchanger vi 30 shown in fig. 15 is obtained by adding the unidirectional heat transfer device 31 to the first intermediate heat exchanger vi 20.

In the second intermediate heat exchanger 30 according to the embodiment of the present invention, the unidirectional heat conduction device 31 (forcibly) exchanges heat at the heat absorption end to the heat release end. Specifically, a refrigerant heat exchanger or a semiconductor temperature regulator may be used.

In an alternative embodiment, the refrigerant heat exchanger includes an evaporator 311, a compressor (not shown), a condenser 312 and an expansion valve (not shown), which are connected to form a heat exchange circuit. The second intermediate heat exchanger 30 includes two heat-absorbing chambers 303 and heat-releasing chambers 304 which are arranged in a heat-insulating manner; the evaporator 311 is disposed opposite to the heat absorbing end 301 of the second intermediate heat exchanger 30 and is disposed in the heat absorbing chamber 303; the condenser 312 is disposed opposite to the heat releasing end 302 of the second intermediate heat exchanger 30 and is disposed in the heat releasing chamber 304.

In another optional embodiment, the semiconductor temperature regulator comprises a semiconductor refrigeration piece, a first end heat exchanger arranged at a first end of the semiconductor refrigeration piece, a second end heat exchanger arranged at a second end of the semiconductor refrigeration piece, and a power supply device. The power supply device is used for supplying electric energy to the semiconductor refrigeration piece. By controlling the direction of the power supply current, the first end and the second end of the semiconductor refrigeration chip can be switched between two modes of heat generation and cold generation. For example, at a forward current, the first end is a cold end and the second end is a hot end; after the current direction is switched, the first end is switched to be the hot end, and the second end is switched to be the cold end. The second intermediate heat exchanger 30 includes two heat-absorbing chambers 303 and heat-releasing chambers 304 which are arranged in a heat-insulating manner; the first end heat exchanger is disposed opposite to the heat absorbing end 301 of the second intermediate heat exchanger 30 and is disposed in the heat absorbing chamber 303; the second end heat exchanger is disposed opposite to the heat releasing end 302 of the second intermediate heat exchanger 30 and is disposed in the heat releasing chamber 304. And determining that the first end heat exchanger is a hot end (or a cold end) and the second end heat exchanger is a cold end (or a hot end) according to actual conditions.

When precise energy needs to be supplied to the releasing-end temperature adjusting device, or heat transfer cannot be carried out between the energy storage station 10 and the temperature adjusting device according to a set direction, the one-way heat conduction device 31 is started, heat of the heat absorbing end 301 is forcibly exchanged to the heat releasing end 302, and then the heat is transferred to the energy storage station 10 (or the absorbing-end temperature adjusting device 1011 or the releasing-end temperature adjusting device 1021) through the heat releasing end 302.

In a second aspect of an embodiment of the present invention, an energy storage station includes,

the energy storage station 10, the energy absorbing end 101 of the energy storage station 10 is used for absorbing the energy of the temperature adjusting device (absorbing end temperature adjusting device 1011) capable of generating corresponding energy, and the energy releasing end 102 is used for releasing the energy to the temperature adjusting device (releasing end temperature adjusting device 1021) needing corresponding energy. And the number of the first and second groups,

one or more of the aforementioned first intermediate heat exchangers 20 and/or one or more of the aforementioned second intermediate heat exchangers 30 are connected between the energy storage station 10 and the tempering device (absorption-side tempering device 1011 or discharge-side tempering device 1021) to the first intermediate heat exchanger 20 and/or the second intermediate heat exchanger 30.

In an alternative embodiment, when the first intermediate heat exchanger 20 and the second intermediate heat exchanger 30 are connected between the energy storage station 10 and the tempering device (the absorption-side tempering device 1011 or the release-side tempering device 1021), the first intermediate heat exchanger 20 and the second intermediate heat exchanger 30 are in one-to-one correspondence, and the second intermediate heat exchanger 20 is connected in parallel to the connecting line 24 between the first intermediate heat exchanger 20 and the energy storage station 10.

Namely, the energy storage station of the embodiment of the present invention has the following specific embodiments.

As shown in fig. 5, the first energy storage station includes an energy storage station 10 and a first intermediate heat exchanger 20, and the first intermediate heat exchanger 20 is connected between the energy storage station 10 and a temperature control device (an absorption side temperature control device 1011 or a release side temperature control device 1021). In the first energy storage station, in addition to the first intermediate heat exchanger ii shown in fig. 9, a first intermediate heat exchanger shown in fig. 1, 3, and 4 may also be used to implement one-way-to-multiple-way connection between the energy storage station 10 and a plurality of temperature adjustment devices. The first intermediate heat exchanger v which is used for multi-path to multi-path conversion as shown in fig. 5 may also be adopted, and when the first intermediate heat exchanger v is suitable for a plurality of energy storage stations 10, a plurality of communication pipelines of the heat absorption end 201 (or the heat release end 202) of the first intermediate heat exchanger are respectively communicated with the plurality of energy storage stations 10, so that the plurality of energy storage stations 10 release energy to the temperature regulating device at the same time, or the plurality of temperature regulating devices store energy to the plurality of energy storage stations 10 at the same time.

As shown in fig. 16, the second energy storage station comprises an energy storage station 10 and a second intermediate heat exchanger 30, and the second intermediate heat exchanger 30 is connected between the energy storage station 10 and a temperature control device (an absorption side temperature control device 1011 or a release side temperature control device 1021). In the second energy storage station, in addition to the second intermediate heat exchanger ii (shown in fig. 7) shown in fig. 10, a second intermediate heat exchanger i, a second intermediate heat exchanger iii, and a second intermediate heat exchanger iv may be used to implement the one-path-to-multiple-path connection between the energy storage station 10 and the plurality of temperature adjustment devices. The second intermediate heat exchanger v capable of switching from multiple paths to multiple paths can be adopted, and when the second intermediate heat exchanger v is suitable for being provided with a plurality of energy storage stations 10, a plurality of communication pipelines of the heat absorption end 201 (or the heat release end 202) of the first intermediate heat exchanger are respectively communicated with the plurality of energy storage stations 10, so that the plurality of energy storage stations 10 release energy to the temperature adjusting equipment at the same time, or the plurality of temperature adjusting equipment store energy to the plurality of energy storage stations 10 at the same time.

The third energy storage station comprises an energy storage station 10, a first intermediate heat exchanger 20 and a second intermediate heat exchanger 30, wherein the first intermediate heat exchanger 20 is connected between the energy storage station 10 and a part of temperature control equipment (an absorption end temperature control equipment 1011 or a release end temperature control equipment 1021), and the second intermediate heat exchanger 30 is connected between the energy storage station and another part of temperature control equipment.

As shown in fig. 18, the fourth energy storage station includes an energy storage station 10, a first intermediate heat exchanger 20 and a second intermediate heat exchanger 30, the first intermediate heat exchanger 20 and the second intermediate heat exchanger 30 correspond to each other one by one, the first intermediate heat exchanger 20 is connected between the energy storage station 10 and a temperature control device (an absorption-side temperature control device 1011 or a release-side temperature control device 1021), and the second intermediate heat exchanger 30 is connected in parallel to a connection pipeline between the first intermediate heat exchanger and the energy storage station 10. In the fourth energy storage station, except for the first transfer heat exchanger II and the second transfer heat exchanger VI, other five first transfer heat exchangers and second transfer heat exchangers can be adopted, and the arrangement can be set according to the number of the energy storage stations 10 in actual application, the number of the temperature adjusting devices and other factors.

The first to fourth energy storage stations are not limited to the first and second intermediate heat exchangers 20 and 30 used in fig. 13 to 18, and the intermediate heat exchangers having the heat absorbing terminals and the heat releasing terminals adapted to each other may be selected according to the structures of the energy absorbing terminals 101 and the energy releasing terminals 102 of the energy storage station 10, the number of the temperature control devices, and the like.

The fourth energy storage station further comprises a switching device, wherein the switching device is arranged at a connection interface of the second transfer heat exchanger 30 and the connecting pipeline 24, and the connection interface is connected in parallel and used for switching the communication between the energy storage station 10 and the temperature adjusting equipment through the first transfer heat exchanger or the second transfer heat exchanger. Specifically, the switching device is a control valve group, and includes two valves, a liquid inlet control valve 161 and a liquid return control valve 161, and the switching between the energy storage station 10 and the temperature adjusting device is realized through switching between a first state of blocking a parallel pipeline of the second intermediate heat exchanger 30 and a second state of blocking the connecting pipeline 24, and communicating through the first intermediate heat exchanger or communicating through the second intermediate heat exchanger.

In a further optional embodiment, the system further comprises a control device, wherein an output end of the control device is in control connection with a control end of the switching device; when it is determined that the heat exchange between the energy storage station 10 and the temperature adjusting device (the absorption-side temperature adjusting device 1011 or the release-side temperature adjusting device 1021) cannot be performed in the set direction, the switching means is controlled to switch the communication between the energy storage station 10 and the temperature adjusting device through the second relay heat exchanger 30.

Specifically, by detecting the first medium temperature on the energy storage station 10 side and the second medium temperature on the temperature adjusting device side, it is determined whether or not heat exchange between the energy storage station 10 and the temperature adjusting device (the absorption-side temperature adjusting device 1011 or the release-side temperature adjusting device 1021) is possible in a set direction by judging the relationship between the first medium temperature and the second medium temperature. For example, the energy storage station 10 is a heat storage station 11, the release-end temperature control device 1201 is a second temperature control device 1121, a first intermediate heat exchanger ii 20 is connected between the heat storage station 11 and the plurality of second temperature control devices 1121 (as shown in fig. 9), and a second intermediate heat exchanger ii 30 is connected in parallel to a connection pipeline between the first intermediate heat exchanger ii 20 and the heat storage station 11. The heat exchange direction is set to supply heat from the heat storage station 11 to the plurality of second temperature control devices 1121, and is implemented on the premise that the first medium temperature on the side of the heat storage station 11 is higher than the second medium temperature on the side of the second temperature control devices. Therefore, when the temperature of the first medium is lower than that of the second medium, the heat storage station 11 and the plurality of second temperature adjusting devices 1121 cannot exchange heat in a set direction, and at this time, the switching device is controlled to switch the communication between the heat storage station 11 and the second temperature adjusting devices 1121 through the second intermediate heat exchanger ii 30. By analogy, the control principle of the switching between the heat storage station 11 and the first tempering devices 1111 (absorption-side tempering devices) is the same and will not be described again here.

In the energy storage station according to the embodiment of the present invention, the number of the relay heat exchangers (the first relay heat exchanger and/or the second relay heat exchanger) connected between the energy storage station 10 and the temperature control device (the absorption-side temperature control device 1011 or the release-side temperature control device 1021) is not limited to fig. 5 or one of fig. 16 to 17, and may be connected in plural. For example, when the energy storage station is applied to a household, the number of temperature regulating devices is limited, and only one transfer heat exchanger is connected. When the energy storage station is applied to large-scale scenes such as communities and communities, the number of temperature adjusting devices is large, and the energy required to be stored is also large, so that the temperature adjusting devices can be grouped (for example, one group in one household), a plurality of energy storage stations 10 can also be arranged, each group of temperature adjusting devices exchanges energy with the energy storage stations 10 through one transfer heat exchanger, and also exchanges energy with the plurality of energy storage stations 10, and at this time, a plurality of transfer heat exchangers are connected. The determination is carried out according to specific conditions.

Example 4

The embodiment provides a method for sharing heat energy among multiple household stations, which comprises the following steps:

acquiring first request heat energy required by a first home station;

acquiring the available heat energy and the position of other household stations;

and determining a home station or an energy storage station or both the home station and the energy storage station for supplying the first home station with heat energy according to the first requested heat energy and the available heat energy and positions of other home stations.

By adopting the technical scheme, the energy supply conditions of other household stations are combined to carry out scheduling to meet the requirements according to the energy requirements of the household stations, the energy flow among the household stations is realized, and when the energy supplied by the household stations is insufficient, the energy is supplemented by the energy storage station. The overall utilization efficiency of energy is improved, and the energy-saving and environment-friendly effects are achieved.

In some optional embodiments, the first requested thermal energy is a difference between the first period average used thermal energy of the first home station and the current and current thermal energy margins. Specifically, the average heat energy used for the first period of time may be: average daily use of thermal energy, or average monthly use of thermal energy. The average daily use heat energy and the average monthly use heat energy can be obtained by the prior art, such as the technology disclosed in the chinese patent application with publication number CN 107864183A.

In some optional embodiments, the determining a home station, or an energy storage station, or a home station and an energy storage station, which supply thermal energy to the first home station, according to the first requested thermal energy and the suppliable thermal energy and the location of the other home stations, includes:

determining a second home station group which can supply the first request heat energy with the heat energy larger than the set proportion in other home stations;

and determining the household station or the energy storage station or the household station and the energy storage station for supplying the first household station with the heat energy according to the first request heat energy and the available heat energy and the position of each household station in the second household station group.

By adopting the technical scheme, the family stations which can supply the first request heat energy with the heat energy larger than the set proportion are found out and divided into the second family station group. The home stations that can supply the first requested thermal energy having the thermal energy less than or equal to the set ratio are not considered. Setting the proportion according to different scenes and requirements, and selecting a second family station group with different heat energy values.

The set ratio may be selected in consideration of requirements of various practical situations, for example, the set ratio is a ratio of a minimum value of the first requested thermal energy to be transmitted to the first requested thermal energy, and when the first requested thermal energy with thermal energy lower than the ratio can be supplied, the thermal conduction loss may be relatively large; for example, the ratio is set to be a multiple of the first requested heat energy, in which case other home stations with sufficient heat energy are prioritized; also for example said set ratio is the inverse of the number of equal parts of the first requested thermal energy, in which case there is a reference to choosing the number of other home stations that can supply thermal energy, for example the first requested thermal energy is equally divided by 5, the set ratio is 1/5, and at least 5 other home stations can be chosen to supply thermal energy to the first home station.

In some optional embodiments, the determining a home station or an energy storage station or a home station and an energy storage station that supply thermal energy to the first home station according to the first requested thermal energy and the suppliable thermal energy and the location of each home station in the second home station group includes:

determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy;

determining that the first home station is supplied with thermal energy by all home stations and energy storage stations in the second group of home stations when the total available thermal energy in the second group of home stations is less than the first requested thermal energy.

By adopting the technical scheme, the heat energy transmission among the household stations is preferentially carried out, and when the energy supplied by the household stations is insufficient, the energy is supplemented by the energy storage station. The overall utilization efficiency of energy is improved, and the energy-saving and environment-friendly effects are achieved.

In some optional embodiments, determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy comprises:

acquiring heat conduction loss of each home station in the second home station group and heat energy transmitted by the first home station;

and selecting the household stations in the second household station group according to the sequence of the heat conduction losses from small to large until the sum of the supplied heat energy of the selected household stations is larger than or equal to the first requested heat energy.

The present invention is not limited to the structures that have been described above and shown in the drawings, and various modifications and changes can be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (9)

1. A method of sharing thermal energy among a plurality of home stations, the plurality of home stations being in thermal conductive communication with one another, further comprising an energy storage station, the energy storage station being in thermal conductive communication with each of the home stations, respectively, the method comprising: the method comprises the following steps:

acquiring first request heat energy required by a first home station;

acquiring the available heat energy and the position of other household stations;

determining a home station or an energy storage station or a home station and an energy storage station for supplying heat energy to the first home station according to the first request heat energy and the available heat energy and positions of other home stations;

the home station comprises heat output equipment, cold output equipment, heat consumption equipment and cold consumption equipment; the energy storage station comprises a heat storage device and a cold storage device; the heat consumption equipment is connected with the heat storage device, or the heat storage device is connected with the heat output equipment, or the cold consumption equipment is connected with the cold storage device, or the cold output equipment is connected with the cold storage device in a heat conduction mode through the transfer heat exchanger.

2. A method of sharing thermal energy between multiple home stations according to claim 1, wherein: the first requested thermal energy is a difference between an average usage thermal energy of the first home station for a first period of time and a current thermal energy margin.

3. A method of sharing thermal energy between multiple home stations according to claim 2, wherein: the average heat energy used in the first time period is daily average heat energy used or monthly average heat energy used.

4. A method of sharing thermal energy between multi-family stations according to any one of claims 1 to 3, characterized in that: the determining of the home station or the energy storage station or the home station and the energy storage station supplying the first home station with the heat energy according to the first requested heat energy and the available positions of other home stations comprises:

determining a second home station group which can supply the first request heat energy with the heat energy larger than the set proportion in other home stations;

and determining the household station or the energy storage station or the household station and the energy storage station which supply the heat energy for the first household station according to the first requested heat energy and the available heat energy and the position of each household station in the second household station group.

5. The method of sharing thermal energy between multiple home stations of claim 4, wherein: the set proportion is the ratio of the minimum value of the first request heat energy which can be transmitted to the first request heat energy.

6. The method of sharing thermal energy between multiple home stations of claim 4, wherein: the set proportion is a multiple of the first requested heat energy.

7. The method of sharing thermal energy between multiple home stations of claim 4, wherein: and setting the set proportion according to the proportion of each requested heat energy to the first requested heat energy after the first requested heat energy is equally divided.

8. The method of sharing thermal energy between multiple home stations of claim 4, wherein: the determining a home station or an energy storage station or a home station and an energy storage station supplying heat energy to the first home station according to the first requested heat energy and the available heat energy and the location of each home station in the second home station group includes:

determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy;

determining that the first home station is supplied with thermal energy by all home stations and energy storage stations in the second group of home stations when the total available thermal energy in the second group of home stations is less than the first requested thermal energy.

9. The method of sharing thermal energy between multiple home stations of claim 8, wherein: determining that the first home station is supplied with thermal energy by one or more home stations in the second group of home stations when the total available thermal energy in the second group of home stations is equal to or greater than the first requested thermal energy, comprising:

acquiring heat conduction loss of each home station in the second home station group and heat energy transmitted by the first home station;

and selecting the household stations in the second household station group according to the sequence of the heat conduction losses from small to large until the sum of the supplied heat energy of the selected household stations is larger than or equal to the first requested heat energy.

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