CN220382219U - Container temperature control door of high-power energy storage system - Google Patents

Abstract

The utility model discloses a container temperature control door of a high-power energy storage system, which is applied to the field of containers and comprises two box doors, wherein batteries and connecting shells are respectively arranged on the back surfaces of the box doors, and a fixing shell is bolted to one side of the interior of each battery; by arranging two refrigeration plates and two fans on the two box doors, the cold end refrigeration fans of the refrigeration plates blow air to reduce the temperature of the air and blow the air into the container, so that uniform refrigeration in the container can be satisfied, the number of the refrigeration plates is reduced, the use and maintenance cost is reduced, and the hot end of the refrigeration plates can not directly release heat to the container to influence the refrigeration effect; the inside of connecting the shell is separated through setting up the baffle to set up air exit and exhaust pipe, after the fan bloies, wind passes through tuber pipe and bloies the mouth and gets into the container, under container confined environment, wind can drive the inside moisture of container and get into the connecting the shell through the air exit then discharge to the external world through the exhaust pipe.

Description

Container temperature control door of high-power energy storage system

Technical Field

The utility model relates to the field of containers, in particular to a container temperature control door of a high-power energy storage system.

Background

The energy storage container takes the container as a good carrier to better provide uninterrupted power supply for various devices. The energy storage container mainly comprises two parts, namely an electric bin and a battery bin, and different accessories are arranged in the two parts, such as a container type machine room, a battery pack, a battery management system, an energy storage converter, an auxiliary control system and the like.

At present, the Chinese utility model with the bulletin number of CN216071487U discloses an energy storage system container temperature control door, which comprises a box door, a battery box, a first wire and a refrigerating plate, wherein the battery box is fixedly arranged in the middle of the box door, the surface of the battery box is connected with the first wire, the side surface of the first wire is connected with the refrigerating plate, the refrigerating plate is connected with an adjacent refrigerating plate through a second wire, a connecting block is fixedly arranged at the rear side of the refrigerating plate, a connecting block at the leftmost side of the box door is fixedly connected with the box door, a limiting plate is fixedly arranged at the top end of the connecting block at the leftmost side of the box door, a connecting shaft is rotatably arranged on the surface of the refrigerating plate, and a telescopic bracket is rotatably connected at the outer side of the connecting shaft. The energy storage system container temperature control door evenly adjusts the position of the refrigerating plate through the synchronous telescopic structure inside the device, so that the adjustability of the device is improved, and meanwhile, the device can automatically compress and seal after closing the door through the sealing structure inside the movable groove.

In summary, the above-mentioned existing temperature control door is only suitable for containers for transporting goods, and cannot meet the requirement of using an energy storage system (container for storing electric equipment);

the container temperature control door in the prior art has the advantages that the application of a plurality of refrigeration plates can meet the refrigeration requirement, but the use cost and the maintenance cost are too high, the two sides of the refrigeration plates are respectively a cold end and a hot end, and the heat of the hot ends of the refrigeration plates can be directly released in the container to influence the refrigeration effect;

and upper and lower current control by temperature change door can't satisfy the demand of taking a breath in to the container, can't discharge to the moisture that refrigeration can produce, when using energy storage system container, moisture can corrode a plurality of power equipment in the energy storage system, causes energy storage system life-span to receive the influence.

In order to solve the problems, we propose a container temperature control door of a high-power energy storage system.

Disclosure of Invention

The utility model aims to provide a container temperature control door of a high-power energy storage system, which has the advantages of low use cost and capability of ventilating containers.

The technical aim of the utility model is realized by the following technical scheme: the container temperature control door of the high-power energy storage system comprises two door doors, wherein a battery and a connecting shell are respectively arranged on the back surfaces of the door doors, a fixing shell is bolted to one side of the inside of the battery, a refrigerating plate is embedded in the fixing shell, an air pipe is communicated with the top of the fixing shell, a connecting pipe is communicated with the surface of the air pipe, a fan arranged on the door is communicated with the top of the air pipe, and an air blowing port is formed in the connecting shell; the inside of connection shell has still seted up the air exit, the inside of chamber door is embedded to have the exhaust pipe, the inside of connection shell is embedded to have the baffle.

Adopt above-mentioned technical scheme, through setting up refrigeration board, fixed shell, tuber pipe, fan and connecting pipe, adopt refrigeration board cold junction refrigeration, the mode that the fan was bloied can blow cold wind to inside whole container to realize refrigeration, through setting up air exit, baffle and exhaust pipe, can blow the mode that the inside gas of container cooperated the fan, thereby realize taking a breath to the container through air exit and exhaust pipe discharge with the wind, discharge the moisture.

The utility model is further provided with: one end of the connecting pipe far away from the air pipe penetrates into the connecting shell, and the surface of the connecting pipe is fixedly sleeved with the connecting shell.

By adopting the technical scheme, through the arrangement of the connecting pipe, the air blown by the fan can enter the inside of the connecting shell through the air pipe, so that the heat at the hot end of the refrigerating plate is taken away and is discharged through the radiating pipe.

The utility model is further provided with: the electromagnetic valve I is specifically a one-way electromagnetic valve.

By adopting the technical scheme, the opening and closing of the connecting pipe can be controlled through the arrangement of the first electromagnetic valve, and the connecting pipe adopts the one-way electromagnetic valve, so that the backflow of outside air through the first electromagnetic valve can be avoided.

The utility model is further provided with: the surface of tuber pipe is fixed with the inside of coupling shell and cup joints, the bottom of tuber pipe runs through to the inside of coupling shell and with the fixed shell intercommunication.

By adopting the technical scheme, the surface of the air pipe is fixedly sleeved with the inside of the connecting shell, the bottom end of the air pipe penetrates through the inside of the connecting shell and is communicated with the fixing shell, and the air pipe is fixedly supported.

The utility model is further provided with: the inner part of the box door is embedded with a radiating pipe, and the radiating pipe is positioned at the top of the partition plate.

By adopting the technical scheme, the heat dissipation device is used for exhausting the heat of the side face of the refrigeration plate through the arrangement of the heat dissipation tube.

The utility model is further provided with: the exhaust pipe is internally provided with a second electromagnetic valve, the second electromagnetic valve is arranged in the box door, and the second electromagnetic valve is specifically a one-way electromagnetic valve.

By adopting the technical scheme, through the arrangement of the second electromagnetic valve, the ventilation and sealing of the exhaust pipe are controlled, and the backflow phenomenon of outside air is avoided.

In summary, the utility model has the following beneficial effects:

1. according to the utility model, the two refrigerating plates and the two fans are arranged on the two box doors, and the refrigerating fans at the cold ends of the refrigerating plates are used for blowing air to reduce the temperature of the air and blow the air into the container, so that uniform refrigeration in the container can be satisfied, the number of the refrigerating plates is reduced, the use and maintenance cost is reduced, and the hot ends of the refrigerating plates can not directly release heat to the container to influence the refrigerating effect;

2. according to the utility model, the inside of the connecting shell is separated by the partition plate, the air outlet and the air outlet pipe are arranged, after the fan blows air, the air enters the container through the air pipe and the air outlet, and under the closed environment of the container, the air drives moisture in the container to enter the connecting shell through the air outlet and then is discharged to the outside through the air outlet pipe.

Drawings

FIG. 1 is a perspective view of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the structure of the present utility model;

fig. 3 is an enlarged view of the structure of fig. 2 a according to the present utility model.

Reference numerals: 1. a door; 2. a battery; 3. a connection housing; 4. a fixed case; 5. a refrigeration plate; 6. an air duct; 7. a blower; 8. blowing an air port; 9. an air outlet; 10. an exhaust pipe; 11. a partition plate; 12. a connecting pipe; 13. a first electromagnetic valve; 14. a heat radiating pipe; 15. and a second electromagnetic valve.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings.

Example 1:

referring to fig. 1, 2 and 3, a container temperature control door of a high-power energy storage system comprises two door doors 1, wherein a battery 2 and a connecting shell 3 are respectively installed on the back surfaces of the door 1, one side of the inside of the battery 2 is bolted with a fixed shell 4, a refrigerating plate 5 is embedded in the fixed shell 4, the top of the fixed shell 4 is communicated with an air pipe 6, the air pipe 6 is not limited to be installed on the back surface of the door 1 only, can be installed on the front surface of the door 1 and penetrates to the back surface of the door 1 through the air pipe 6 to be communicated with the fixed shell 4, a connecting pipe 12 is communicated with the surface of the air pipe 6, the top end of the air pipe 6 is communicated with a fan 7 installed with the door 1, and an air blowing port 8 is formed in the connecting shell 3; an air outlet 9 is further formed in the connecting shell 3, an air exhaust pipe 10 is embedded in the box door 1, a partition plate 11 is embedded in the connecting shell 3, two refrigerating plates 5 and two fans 7 are arranged on the two box doors 1, the refrigerating fans 7 at the cold ends of the refrigerating plates 5 are used for blowing air to reduce the temperature of the air and blow the air into the container, uniform refrigeration in the container can be met, the number of the refrigerating plates 5 is reduced, the use and maintenance cost is reduced, and the hot ends of the refrigerating plates 5 can not directly release heat to the container; the inside of the connection shell 3 is separated by the partition plate 11, the air outlet 9 and the air outlet pipe 10 are arranged, after the fan 7 blows air, the air enters the container through the air pipe 6 and the air outlet 8, and under the closed environment of the container, the air can drive the moisture inside the container to enter the connection shell 3 through the air outlet 9 and then be discharged to the outside through the air outlet pipe 10.

Further, one end of the connecting pipe 12 far away from the air pipe 6 penetrates into the connecting shell 3, and the surface of the connecting pipe 12 is fixedly sleeved with the connecting shell 3.

Further, the first electromagnetic valve 13 is installed inside the connecting pipe 12, and the first electromagnetic valve 13 is specifically a one-way electromagnetic valve.

Further, the surface of the air pipe 6 is fixedly sleeved with the inside of the connecting shell 3, and the bottom end of the air pipe 6 penetrates through the inside of the connecting shell 3 and is communicated with the fixed shell 4.

Further, a radiating pipe 14 is embedded in the box door 1, and the radiating pipe 14 is located at the top of the partition 11.

Further, the exhaust pipe 10 is internally provided with a second electromagnetic valve 15, the second electromagnetic valve 15 is arranged in the box door 1, and the second electromagnetic valve 15 is specifically a one-way electromagnetic valve.

The use process is briefly described: when the temperature control door and the energy storage container are installed in use, when the interior of the container is required to be refrigerated, the battery 2 provides electric energy for the temperature control door, the refrigeration plate 5 is started, one side of the refrigeration plate 5, which is close to the air blowing port 8, is a cold end, cold energy is generated at the cold end, the fan 7 is started to generate air, the air enters the interior of the fixed shell 4 through the air pipe 6 to drive the cold energy of the refrigeration plate 5 to form cold air, the cold air is blown into the interior of the container through the air blowing port 8, refrigeration work of the interior of the container is realized, meanwhile, the electromagnetic valve I13 is started, and heat, which enters the interior of the connecting shell 3 through the connecting pipe 12 and is provided with the hot end of the refrigeration plate 5, is discharged through the radiating pipe 14;

when the air exchange is needed, the electromagnetic valve II 15 and the fan 7 are started, the fan 7 is started to generate air, the air enters the fixed shell 4 through the air blowing port 8 and is discharged into the container, and because of the closed environment inside the container, the air can drive moisture inside the container to enter the connecting shell 3 through the only air outlet 9 capable of flowing after filling the container, and then the air is discharged outside through the air discharging pipe 10, so that the air exchange is completed.

The present embodiment is only for explanation of the present utility model and is not to be construed as limiting the present utility model, and modifications to the present embodiment, which may not creatively contribute to the present utility model as required by those skilled in the art after reading the present specification, are all protected by patent laws within the scope of claims of the present utility model.

Claims (6)

1. The utility model provides a high-power energy storage system container accuse temperature door, includes two chamber doors (1), its characterized in that, battery (2) and junction housing (3) are installed respectively to the back of chamber door (1), one side bolt inside battery (2) has fixed shell (4), the inside of fixed shell (4) is embedded to have refrigeration board (5), the top intercommunication of fixed shell (4) has tuber pipe (6), the surface intercommunication of tuber pipe (6) has connecting pipe (12), the top intercommunication of tuber pipe (6) has fan (7) with chamber door (1) installation, blowing mouth (8) have been seted up to the inside of junction housing (3); an air outlet (9) is further formed in the connecting shell (3), an air exhaust pipe (10) is embedded in the box door (1), and a partition plate (11) is embedded in the connecting shell (3).

2. The container temperature control door of the high-power energy storage system according to claim 1, wherein one end of the connecting pipe (12) far away from the air pipe (6) penetrates into the connecting shell (3), and the surface of the connecting pipe (12) is fixedly sleeved with the connecting shell (3).

3. The container temperature control door of the high-power energy storage system according to claim 1, wherein the first electromagnetic valve (13) is installed in the connecting pipe (12), and the first electromagnetic valve (13) is specifically a one-way electromagnetic valve.

4. The high-power energy storage system container temperature control door according to claim 1, wherein the surface of the air pipe (6) is fixedly sleeved with the inside of the connecting shell (3), and the bottom end of the air pipe (6) penetrates through the inside of the connecting shell (3) and is communicated with the fixed shell (4).

5. The high-power energy storage system container temperature control door according to claim 1, wherein a radiating pipe (14) is embedded in the box door (1), and the radiating pipe (14) is located at the top of the partition plate (11).

6. The container temperature control door of the high-power energy storage system according to claim 1, wherein a second electromagnetic valve (15) is installed in the exhaust pipe (10), the second electromagnetic valve (15) is installed in the container door (1), and the second electromagnetic valve (15) is specifically a one-way electromagnetic valve.