CN218919748U - Energy storage cabinet with temperature control structure - Google Patents
Energy storage cabinet with temperature control structure Download PDFInfo
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- CN218919748U CN218919748U CN202223187525.XU CN202223187525U CN218919748U CN 218919748 U CN218919748 U CN 218919748U CN 202223187525 U CN202223187525 U CN 202223187525U CN 218919748 U CN218919748 U CN 218919748U
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- air outlet
- branch pipe
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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Abstract
The application provides an energy storage cabinet with control by temperature change structure belongs to energy storage cabinet technical field. The energy storage cabinet with the temperature control structure comprises an energy storage cabinet part and a temperature control assembly. The cabinet door is hinged to the front face of the cabinet body; the refrigerator is characterized in that the installation box is fixed on one side of the cabinet body, the refrigerator is installed in the installation box, the air outlet main pipe is communicated with the air outlet end of the refrigerator, the other end of the air outlet main pipe penetrates through the installation box and the side face of the cabinet body in a sealing mode and is communicated with the air outlet branch pipe piece, the air outlet branch pipe piece is evenly arranged on the rear side wall of the cabinet body, the temperature sensor and the control switch are respectively installed on the inner top wall of the cabinet body, and the control switch is respectively electrically connected with the temperature sensor and the refrigerator. Through refrigerator, temperature sensor and control switch's setting, the realization can dispel the heat according to the internal actual temperature of cabinet, avoids the internal high temperature of cabinet.
Description
Technical Field
The application relates to the field of energy storage cabinets, and particularly relates to an energy storage cabinet with a temperature control structure.
Background
The capacitor energy storage is a technology for storing electric energy by using a capacitor, the mechanism of the capacitor energy storage is an electric double layer capacitor and a Faraday capacitor, the main form of the capacitor energy storage is super capacitor energy storage, and the super capacitor energy storage device mainly comprises a super capacitor group, a bidirectional DC/DC converter and a corresponding control circuit.
A domestic energy storage cabinet with a Chinese publication number of CN211456727U realizes that each battery pack can be controlled independently, prevents the paralysis of the energy storage cabinet caused by consistency problems of the battery packs, and has easy selection of configuration, easy repair of faults and large capacity combination. However, when the cabinet body is used, heat dissipation inside the device is difficult, so that the temperature is too high after long-time use, and the performance is affected.
Disclosure of Invention
In order to make up the defects, the application provides an energy storage cabinet with a temperature control structure, which aims to solve the problem that heat is difficult to dissipate in the device, so that the performance is influenced due to overhigh temperature after long-time use.
The embodiment of the application provides an energy storage cabinet with a temperature control structure, which comprises an energy storage cabinet part and a temperature control assembly.
The energy storage cabinet part comprises a cabinet body and a cabinet door, and the cabinet door is hinged to the front surface of the cabinet body; the temperature control assembly comprises an installation box, a refrigerator, an air outlet main pipe, an air outlet branch pipe fitting, a temperature sensor and a control switch, wherein the installation box is fixed on one side of the cabinet body, the refrigerator is installed in the installation box, the air outlet main pipe is communicated with the air outlet end of the refrigerator, the other end of the air outlet main pipe penetrates through the installation box in a sealing mode, the side face of the cabinet body is communicated with the air outlet branch pipe fitting, the air outlet branch pipe fitting is evenly arranged on the rear side wall of the cabinet body, the temperature sensor and the control switch are respectively installed on the inner top wall of the cabinet body, and the control switch is respectively electrically connected with the temperature sensor and the refrigerator.
In the realization process, when the temperature in the cabinet body is too high, the temperature sensor is transmitted to the control switch, the control switch controls the refrigerator to start, cold air generated by the operation of the refrigerator is output into the air outlet branch pipe piece through the air outlet main pipe, enters into the cabinet body for heat dissipation, and after the temperature in the cabinet body is reduced, the temperature sensor is transmitted to the control switch, the control switch controls the refrigerator to be closed, and the refrigeration is finished. Through refrigerator, temperature sensor and control switch's setting, the realization can dispel the heat according to the internal actual temperature of cabinet, avoids the internal high temperature of cabinet. Through the setting of air-out branch pipe spare for the quick even dispersion of air conditioning is internal at the cabinet, can improve radiating efficiency.
In a specific embodiment, the energy storage cabinet with the temperature control structure further comprises a heat dissipation component, a vent is arranged on the side face of the installation box, and the heat dissipation component is arranged on the vent on the side face of the installation box and dissipates heat of the refrigerator.
In the implementation process, the heat radiation component can radiate heat of the refrigerator, and the service life of the heat radiation component is prolonged.
In a specific embodiment, the heat dissipation assembly comprises a heat dissipation member and a heat dissipation fan, wherein the heat dissipation member is connected with the side surface of the refrigerator, the heat dissipation fan is installed at a vent of the installation box, and the heat dissipation fan is in contact with the outer side of the heat dissipation member.
In the implementation process, the heat radiating fan is started, heat generated by the refrigerator is effectively sucked out through the heat radiating piece, and then the heat radiating fan rapidly radiates the heat on the heat radiating piece.
In a specific embodiment, the heat dissipation member includes a heat conduction plate and heat dissipation fins, the heat conduction plate is connected with the side of the refrigerator, all the heat dissipation fins are equidistantly arranged on the side of the heat conduction plate, and all the heat dissipation fins are in contact with the heat dissipation fan.
In the implementation process, the heat conducting plate transfers the heat generated on the refrigerator, and then the heat radiating area is enlarged through the heat radiating fins, and the heat radiating fan rapidly radiates the heat on the heat radiating fins. And the heat dissipation effect is improved.
In a specific embodiment, a heat conducting silica gel layer is arranged on the side face of the refrigerator, and the heat conducting plate is adhered to the heat conducting silica gel layer.
In the implementation process, the heat conducting silica gel layer can improve the heat conducting effect of the heat conducting plate.
In a specific embodiment, the air outlet branch pipe piece comprises a first air outlet branch pipe, a second air outlet branch pipe and a third air outlet branch pipe, wherein the first air outlet branch pipe, the second air outlet branch pipe and the third air outlet branch pipe are equidistantly arranged on the rear side wall of the cabinet body, the first air outlet branch pipe is communicated with the other end of the air outlet main pipe, the first air outlet branch pipe, the second air outlet branch pipe and the third air outlet branch pipe are mutually communicated, and air outlets are equidistantly arranged on the second air outlet branch pipe and the third air outlet branch pipe.
In the realization process, the cold air generated by the refrigerator is input into the first air outlet branch pipe through the air outlet main pipe, enters into the second air outlet branch pipe and then enters into the third air outlet branch pipe, and then enters into the cabinet body through the air outlet, so that the area of cold air output is enlarged, and the efficiency of heat dissipation in the cabinet body is improved.
In a specific embodiment, an alarm is mounted on the top of the cabinet.
In the implementation process, when a fire disaster occurs, the alarm is used for alarming so that operators can find the disaster condition at the first time, and property loss and casualties are reduced.
In a specific embodiment, the side surface of the cabinet body is fixedly connected with a supporting plate, and the mounting box is mounted on the supporting plate.
In the implementation process, the mounting box is more stable in mounting through the supporting plate.
Compared with the prior art, the beneficial effect of this application:
1. through refrigerator, temperature sensor and control switch's setting, the realization can dispel the heat according to the internal actual temperature of cabinet, avoids the internal high temperature of cabinet.
Through the setting of air-out branch pipe spare for the quick even dispersion of air conditioning is internal at the cabinet, can improve radiating efficiency.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some examples of the present application and therefore should not be considered as limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
Fig. 1 is a schematic structural diagram of an energy storage cabinet with a temperature control structure according to an embodiment of the present application;
fig. 2 is a schematic structural diagram of a connection relationship between a cabinet body and a temperature control component according to an embodiment of the present application;
fig. 3 is a schematic structural diagram of a connection relationship between a mounting box and a refrigerator according to an embodiment of the present disclosure;
fig. 4 is a schematic structural diagram of a heat dissipating assembly according to an embodiment of the present application.
In the figure: 10-an energy storage cabinet part; 110-a cabinet body; 120-cabinet door; 20-a temperature control assembly; 210-mounting a box; 220-refrigerator; 230, an air outlet main pipe; 240-an air outlet branch pipe fitting; 241-first outlet branch; 2411-an air outlet; 242-second outlet branch pipe; 243-a third air outlet branch pipe; 250-temperature sensor; 260-control switch; 270-an alarm; 280-supporting plates; 30-a heat dissipating assembly; 310-heat sink; 311-a heat-conducting plate; 312-heat radiating fins; 320-cooling fan; 330-a thermally conductive silicone layer.
Detailed Description
The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.
For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some of the embodiments of the present application, but not all of the embodiments. All other embodiments, based on the embodiments herein, which would be apparent to one of ordinary skill in the art without undue burden are within the scope of the present application.
Referring to fig. 1-4, the present application provides an energy storage cabinet with a temperature control structure, which includes an energy storage cabinet portion 10 and a temperature control assembly 20.
Wherein, the energy storage cabinet portion 10 stores electric energy by using a capacitor, and the temperature control assembly 20 can cool the interior of the cabinet 110.
Referring to fig. 1 and 2, the energy storage cabinet portion 10 includes a cabinet body 110 and a cabinet door 120, wherein the cabinet door 120 is hinged to the front surface of the cabinet body 110, and specifically, the cabinet door 120 is hinged to the front surface of the cabinet body 110 through a hinge; the cabinet door 120 is opened first, then the battery module is installed inside the cabinet body 110, and then the cabinet door 120 is closed.
Referring to fig. 1, 2 and 3, the temperature control assembly 20 includes a mounting box 210, a refrigerator 220, an air outlet main pipe 230, an air outlet branch pipe 240, a temperature sensor 250 and a control switch 260, wherein the mounting box 210 is fixed on one side of the cabinet 110, and specifically, an air outlet is provided on the mounting box 210. The refrigerator 220 is mounted inside the mounting box 210, and specifically, the refrigerator 220 is mounted inside the mounting box 210 by bolts. The air-out main pipe 230 is communicated with the air-out end of the refrigerator 220, the other end of the air-out main pipe 230 penetrates through the side surfaces of the mounting box 210 and the cabinet body 110 in a sealing manner and is communicated with the air-out branch pipe piece 240, the air-out branch pipe piece 240 is uniformly arranged on the rear side wall of the cabinet body 110, the temperature sensor 250 and the control switch 260 are respectively arranged on the inner top wall of the cabinet body 110, the control switch 260 is respectively electrically connected with the temperature sensor 250 and the refrigerator 220, the circuit connection principle of the control switch 260 and the temperature sensor 250 and the refrigerator 220 is the prior art, detailed description is omitted, and meanwhile, the highest value and the lowest value of the temperature sensor 250 are set according to implementation requirements. When the temperature inside the cabinet 110 is too high, the temperature sensor 250 is transmitted to the control switch 260, the control switch 260 controls the refrigerator 220 to start, cold air generated by the operation of the refrigerator 220 is output into the air outlet branch pipe part 240 through the air outlet main pipe 230, enters into the cabinet 110 to dissipate heat, after the temperature inside the cabinet 110 is reduced, the temperature sensor 250 is transmitted to the control switch 260, the control switch 260 controls the refrigerator 220 to close, and the refrigeration is finished. Through the arrangement of the refrigerator 220, the temperature sensor 250 and the control switch 260, heat dissipation can be achieved according to the actual temperature inside the cabinet 110, and the temperature inside the cabinet 110 is prevented from being too high. Through the setting of air-out branch pipe 240 for the quick even dispersion of air conditioning is inside the cabinet body 110, can improve radiating efficiency.
In this embodiment, the air-out branch pipe member 240 includes a first air-out branch pipe 241, a second air-out branch pipe 242 and a third air-out branch pipe 243, where the first air-out branch pipe 241, the second air-out branch pipe 242 and the third air-out branch pipe 243 are equidistantly disposed on the rear side wall of the cabinet 110, the first air-out branch pipe 241 is communicated with the other end of the air-out main pipe 230, the first air-out branch pipe 241, the second air-out branch pipe 242 and the third air-out branch pipe 243 are mutually communicated, and air outlets 2411 are equidistantly disposed on the second air-out branch pipe 242 and the third air-out branch pipe 243 of the first air-out branch pipe 241, the second air-out branch pipe 242 and the third air-out branch pipe 243, and the first air-out branch pipe 241, the second air-out branch pipe 242 and the third air-out branch pipe 243 are square, so as to enlarge the heat dissipation effect of the cabinet on the rear side wall of the cabinet 110. The cool air generated by the refrigerator 220 is input into the first air outlet branch pipe 241 through the air outlet main pipe 230, enters the second air outlet branch pipe 242, then enters the third air outlet branch pipe 243, and then enters the cabinet 110 through the air outlet 2411, so as to enlarge the area of cool air output and improve the heat dissipation efficiency of the cabinet 110.
In this embodiment, an alarm 270 is mounted on top of the cabinet 110. When a fire disaster occurs, the alarm 270 gives an alarm to enable operators to find the disaster condition at the first time, so that property loss and casualties are reduced.
In this embodiment, the side of the cabinet 110 is fixedly connected with a support plate 280, specifically, the support plate 280 is welded and fixed on the side of the cabinet 110, and the lower surface of the support plate 280 is welded and fixed with a reinforcing rod, and the other end of the reinforcing rod is welded and fixed with the side of the cabinet 110. The mounting box 210 is mounted on the support plate 280, and in particular, the mounting box 210 is welded to the support plate 280. Wherein the mounting case 210 is more stable in mounting by the support plate 280.
Referring to fig. 1, 2, 3 and 4, the energy storage cabinet with the temperature control structure further includes a heat dissipation assembly 30, a ventilation opening is disposed on a side surface of the installation box 210, and the heat dissipation assembly 30 is disposed on the ventilation opening on the side surface of the installation box 210 and dissipates heat of the refrigerator 220. The heat dissipation assembly 30 can dissipate heat of the refrigerator 220, and service life of the heat dissipation assembly 30 is prolonged.
In this embodiment, the heat dissipating assembly 30 includes a heat dissipating member 310 and a heat dissipating fan 320, the heat dissipating member 310 is laterally connected to the refrigerator 220, the heat dissipating fan 320 is mounted at a vent of the mounting box 210, and specifically, the heat dissipating fan 320 is mounted at the vent of the mounting box 210 by bolts. And the heat dissipation fan 320 is in contact with the outside of the heat sink 310. The heat dissipation fan 320 is started, the heat generated by the refrigerator 220 is efficiently absorbed through the heat dissipation element 310, and then the heat dissipation fan 320 rapidly dissipates the heat on the heat dissipation element 310.
Further, the heat dissipation element 310 includes a heat conduction plate 311 and heat dissipation fins 312, the heat conduction plate 311 is connected with the side of the refrigerator 220, all the heat dissipation fins 312 are equidistantly arranged on the side of the heat conduction plate 311, and specifically, the heat conduction plate 311 and the heat dissipation fins 312 are integrally formed. All of the heat radiating fins 312 are in contact with the heat radiating fan 320. The heat conducting plate 311 transfers the heat generated on the refrigerator 220, and then the heat radiating area is enlarged through the heat radiating fins 312, and the heat radiating fan 320 rapidly radiates the heat on the heat radiating fins 312. And the heat dissipation effect is improved.
In this embodiment, a heat-conducting silica gel layer 330 is disposed on the side of the refrigerator 220, and a heat-conducting plate 311 is adhered to the heat-conducting silica gel layer 330. Wherein, the heat conducting silica gel layer 330 can improve the heat conducting effect of the heat conducting plate 311.
The working principle of the energy storage cabinet with the temperature control structure is as follows:
when the temperature inside the cabinet 110 is too high, the temperature sensor 250 is transmitted to the control switch 260, the control switch 260 controls the refrigerator 220 to start, cold air generated by the operation of the refrigerator 220 is output into the air outlet branch pipe part 240 through the air outlet main pipe 230 and enters the cabinet 110 to dissipate heat, and when the temperature inside the cabinet 110 is reduced, the temperature sensor 250 is transmitted to the control switch 260, and the control switch 260 controls the refrigerator 220 to be closed, and the refrigeration is finished. Through the arrangement of the refrigerator 220, the temperature sensor 250 and the control switch 260, heat dissipation can be achieved according to the actual temperature inside the cabinet 110, and the temperature inside the cabinet 110 is prevented from being too high. Through the setting of air-out branch pipe 240 for the quick even dispersion of air conditioning is inside the cabinet body 110, can improve radiating efficiency.
It should be noted that, specific model specifications of the refrigerator 220, the temperature sensor 250, the control switch 260 and the cooling fan 320 need to be determined by selecting a model according to actual specifications of the device, and a specific model selection calculation method adopts the prior art, so that detailed descriptions thereof are omitted.
The power supply and the principle of the refrigerator 220, the temperature sensor 250, the control switch 260, and the heat radiation fan 320 will be apparent to those skilled in the art, and will not be described in detail herein.
The foregoing is merely exemplary embodiments of the present application and is not intended to limit the scope of the present application, and various modifications and variations may be suggested to one skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.
The foregoing is merely specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and the changes and substitutions are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.
Claims (8)
1. An energy storage cabinet with a temperature control structure, which is characterized by comprising
The energy storage cabinet part (10) comprises a cabinet body (110) and a cabinet door (120), wherein the cabinet door (120) is hinged to the front surface of the cabinet body (110);
the temperature control assembly (20) comprises an installation box (210), a refrigerator (220), an air outlet main pipe (230), an air outlet branch pipe fitting (240), a temperature sensor (250) and a control switch (260), wherein the installation box (210) is fixed on one side of the cabinet body (110), the refrigerator (220) is installed inside the installation box (210), the air outlet main pipe (230) is communicated with an air outlet end of the refrigerator (220), the other end of the air outlet main pipe (230) penetrates through the installation box (210) and the side face of the cabinet body (110) in a sealing mode and is communicated with the air outlet branch pipe fitting (240), the air outlet branch pipe fitting (240) is uniformly arranged on the rear side wall of the cabinet body (110), the temperature sensor (250) and the control switch (260) are respectively installed on the inner top wall of the cabinet body (110), and the control switch (260) are respectively electrically connected with the temperature sensor (250) and the refrigerator (220).
2. The energy storage cabinet with the temperature control structure according to claim 1, further comprising a heat dissipation assembly (30), wherein a vent is arranged on the side surface of the installation box (210), and the heat dissipation assembly (30) is arranged on the vent on the side surface of the installation box (210) and dissipates heat of the refrigerator (220).
3. The energy storage cabinet with the temperature control structure according to claim 2, wherein the heat dissipation assembly (30) comprises a heat dissipation member (310) and a heat dissipation fan (320), the heat dissipation member (310) is laterally connected with the refrigerator (220), the heat dissipation fan (320) is installed at a vent of the installation box (210), and the heat dissipation fan (320) is in contact with the outer side of the heat dissipation member (310).
4. A cabinet according to claim 3, characterized in that the heat sink (310) comprises a heat conducting plate (311) and heat radiating fins (312), the heat conducting plate (311) is connected to the side of the refrigerator (220), all the heat radiating fins (312) are equidistantly arranged on the side of the heat conducting plate (311), and all the heat radiating fins (312) are in contact with the heat radiating fan (320).
5. The energy storage cabinet with the temperature control structure according to claim 4, wherein a heat conducting silica gel layer (330) is arranged on the side face of the refrigerator (220), and the heat conducting plate (311) is adhered to the heat conducting silica gel layer (330).
6. The energy storage cabinet with the temperature control structure according to claim 1, wherein the air outlet branch pipe fitting (240) comprises a first air outlet branch pipe (241), a second air outlet branch pipe (242) and a third air outlet branch pipe (243), the first air outlet branch pipe (241), the second air outlet branch pipe (242) and the third air outlet branch pipe (243) are equidistantly arranged on the rear side wall of the cabinet body (110), the first air outlet branch pipe (241) is communicated with the other end of the air outlet main pipe (230), the first air outlet branch pipe (241), the second air outlet branch pipe (242) and the third air outlet branch pipe (243) are mutually communicated, and air outlets (2411) are equidistantly arranged on the first air outlet branch pipe (241) the second air outlet branch pipe (242) and the third air outlet branch pipe (243).
7. The energy storage cabinet with the temperature control structure according to claim 1, wherein an alarm (270) is installed on the top of the cabinet body (110).
8. The energy storage cabinet with the temperature control structure according to claim 1, wherein a supporting plate (280) is fixedly connected to the side surface of the cabinet body (110), and the installation box (210) is installed on the supporting plate (280).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202223187525.XU CN218919748U (en) | 2022-11-28 | 2022-11-28 | Energy storage cabinet with temperature control structure |
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CN202223187525.XU CN218919748U (en) | 2022-11-28 | 2022-11-28 | Energy storage cabinet with temperature control structure |
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CN218919748U true CN218919748U (en) | 2023-04-25 |
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CN202223187525.XU Active CN218919748U (en) | 2022-11-28 | 2022-11-28 | Energy storage cabinet with temperature control structure |
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