CN220895634U - Optical storage filling inspection container - Google Patents

Abstract

The utility model relates to the technical field of charging and power generation, in particular to an optical storage and charging detection container, which comprises a container body, a cooling assembly and an optical storage and charging assembly, wherein the cooling assembly and the optical storage and charging assembly are arranged in an inner cavity of the container body; the cooling assembly comprises a water cooling unit, a fan housing and a water cooling pipe; the air inlet end of the air cover is connected with a cold air port of the water cooling unit, and the air outlet end of the air cover faces the light storage and filling assembly; the water cooling pipe is connected into a cold coil pipe of the water cooling unit and is used for carrying out heat exchange with the optical storage and filling component. The utility model can effectively cool and dehumidify the inner cavity environment of the box body so as to ensure the normal operation of the optical storage and filling assembly.

Description

Optical storage filling inspection container

Technical Field

The utility model relates to the technical field of charging and power generation, in particular to an optical storage charging and detecting container.

Background

The lithium battery energy storage technology is a large power aid for electric vehicle popularization, professional and rapid charging and after-sale maintenance service are necessary conditions for electric vehicle marketing popularization, and the construction of an optical storage, charging and inspection integrated intelligent charging station is an optimal solution. The intelligent charging station with integrated optical storage, charging and inspection uses an advanced lithium iron phosphate battery, and an intelligent platform product with three functions of energy storage service, electric vehicle charging service and electric vehicle detection service, is compatible with renewable energy access, and enables a power grid, renewable energy, an energy storage system and a charging facility to truly form an intelligent micro-grid system under the control and management of a function management system. The traditional optical storage filling inspection container has poorer cooling and dehumidifying capacities in the container body, and the optical storage filling assembly under high-temperature and high-humidity environment operation is easy to generate fire and has certain potential safety hazard.

Disclosure of utility model

The technical problems to be solved by the utility model are as follows: the utility model provides a light stores up fills and examines container can carry out effectual cooling dehumidification to the inner chamber environment of box to guarantee the normal operation of light storage and filling subassembly.

In order to solve the technical problems, the utility model adopts the following technical scheme: an optical storage filling and checking container comprises a container body, a cooling component and an optical storage filling component, wherein the cooling component and the optical storage filling component are arranged in an inner cavity of the container body;

The cooling assembly comprises a water cooling unit, a fan housing and a water cooling pipe; the air inlet end of the air cover is connected with a cold air port of the water cooling unit, and the air outlet end of the air cover faces the light storage and filling assembly;

The water cooling pipe is connected into a cold coil pipe of the water cooling unit and is used for carrying out heat exchange with the optical storage and filling component.

Further, the inner cavity of the box body is provided with a partition wall, the partition wall divides the inner cavity of the box body into a cooling bin and a light storage and filling bin, the water cooling unit is arranged in the cooling bin, and the light storage and filling assembly is arranged in the light storage and filling bin.

Further, the light stores up the subassembly and includes battery package and the equipment group of mutual electricity connection, the light stores up the bin and divide into battery compartment and equipment storehouse through the partition wall, the battery package sets up in the battery compartment, the equipment group sets up in the equipment storehouse.

Further, a mounting frame, a second support and a third support for mounting the battery pack are arranged in the battery compartment, the second support and the third support are welded or locked on the mounting frame, the front end of the battery pack is locked and fixed with the second support, and two sides of the battery pack are limited through the third support.

Further, the water cooling pipe comprises two paths, one path of the water cooling pipe extends to the battery compartment, and the other path of the water cooling pipe extends to the equipment compartment; the water cooling pipe comprises a main pipe and branch pipes which are communicated, the main pipe is positioned above the light storage and filling assembly, and the branch pipes extend to all equipment needing heat dissipation.

Further, the box body is provided with a grounding copper bar, and the grounding copper bar is respectively connected with the water cooling unit and the mounting frame through wiring harnesses.

Further, the bottom of water-cooling unit is connected with the bottom of box, the top of water-cooling unit is provided with first support, first support is connected with the partition wall.

Further, the optical storage filling inspection container further comprises a fire protection system, the fire protection system comprises a combustible gas detector and an exhaust device electrically connected with the combustible gas detector, the combustible gas detector is arranged in the battery bin, and the exhaust device comprises a fire protection air inlet valve and a fire protection air outlet valve which are arranged on two opposite side walls of the container body.

Further, the fire control air inlet valve comprises a first shutter, a first sealing plate and a first driving device; the first shutter is embedded on the side wall of the box body, the first sealing plate is hinged at the window of the first shutter, the movable end of the first driving device is hinged with the first sealing plate, and the first driving device is electrically connected with the combustible gas detector; the fire control air outlet valve comprises a second shutter, a second sealing plate, a fan and a second driving device; the second shutter is embedded on the side wall of the box body, the second sealing plate is hinged to a window of the second shutter, the fan fans towards the direction of the second shutter, the movable end of the second driving device is hinged to the second sealing plate, and the second driving device is electrically connected with the combustible gas detector.

Further, the fire protection system also comprises a photoelectric smoke-sensing fire detector and a fire protection cabinet; the photoelectric smoke-sensing fire detector is arranged in the battery compartment, the fire-fighting cabinet is arranged in the equipment compartment, the water outlet end of the fire-fighting cabinet is connected with a water drain pipe, and the water outlet end of the water drain pipe extends into the battery compartment.

The utility model has the beneficial effects that: the cooling component is additionally arranged in the inner cavity of the box body, and the water cooling unit of the cooling component blows low-temperature dry air to the light storage and filling component through the fan housing, so that the light storage and filling component is prevented from operating in a high-temperature environment, condensed water is prevented from being generated, and the safe use of the light storage and filling component is further ensured. Meanwhile, the water cooling pipe is connected to the cold coil pipe of the water cooling unit, so that low-temperature cooling liquid in the cooling system of the water cooling unit can be led to the optical storage and filling assembly for heat exchange, and the optical storage and filling assembly is further cooled.

Drawings

FIG. 1 is a schematic diagram of a layout structure of a cooling module of a light storage and filling inspection container according to an embodiment of the present utility model in a top view of an inner cavity of a container body;

FIG. 2 is a schematic diagram of a water-cooled tube layout of a cooling assembly of an optical storage filling inspection container according to an embodiment of the present utility model in a top view of an interior cavity of the container body;

FIG. 3 is a schematic diagram of a layout structure of a water cooling unit and an optical storage and filling assembly in a top view of an inner cavity of a container body of an optical storage and filling inspection container according to an embodiment of the present utility model;

FIG. 4 is a schematic side view of a battery pack of an inner cavity of a container body of a light storage and charge inspection container according to an embodiment of the present utility model;

FIG. 5 is a schematic view of a mounting structure of a battery pack of an optical storage and charge container on a mounting frame according to an embodiment of the present utility model;

FIG. 6 is a schematic diagram of a fire control air intake valve of an optical storage filling inspection container according to the embodiment of the present utility model;

FIG. 7 is a schematic diagram II of a fire control air intake valve of an optical storage filling and detecting container according to the embodiment of the utility model;

FIG. 8 is a schematic diagram of a fire control air outlet valve of an optical storage and filling inspection container according to the embodiment of the utility model;

FIG. 9 is a schematic diagram II of a fire control air outlet valve of an optical storage and filling inspection container according to the embodiment of the utility model;

FIG. 10 is a schematic diagram of the external structure of an optical storage and filling inspection container according to an embodiment of the present utility model;

description of the reference numerals:

1. a case; 11. partition walls; 12. a mounting frame; 121. a third bracket; 122. a fourth bracket;

2. A cooling assembly; 21. a water cooling unit; 211. a first bracket; 22. a fan housing; 221. an air duct; 23. a main pipe; 24. a branch pipe;

3. A light storage and filling assembly; 31. a battery pack; 311. a second bracket; 32. a device group;

4. A combustible gas detector;

5. An exhaust device; 51. a fire control air inlet valve; 511. a first shutter; 512. a first sealing plate; 513. a first driving device;

52. A fire control air outlet valve; 521. a second shutter; 522. a second sealing plate; 523. a fan; 524. a second driving device;

6. photoelectric smoke detector; 7. a fire-fighting cabinet; 8. a boss; 9. a fire hydrant.

Detailed Description

In order to describe the technical contents, the achieved objects and effects of the present utility model in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

The lithium battery energy storage technology is a large power aid for electric vehicle popularization, professional and rapid charging and after-sale maintenance service are necessary conditions for electric vehicle marketing popularization, and the construction of an optical storage, charging and inspection integrated intelligent charging station is an optimal solution. The intelligent charging station with integrated optical storage, charging and inspection uses an advanced lithium iron phosphate battery, and an intelligent platform product with three functions of energy storage service, electric vehicle charging service and electric vehicle detection service, is compatible with renewable energy access, and enables a power grid, renewable energy, an energy storage system and a charging facility to truly form an intelligent micro-grid system under the control and management of a function management system. The traditional optical storage filling inspection container has poorer cooling and dehumidifying capacities in the container body, and the optical storage filling assembly under high-temperature and high-humidity environment operation is easy to generate fire and has certain potential safety hazard.

Based on the above, the application provides the optical storage filling inspection container, which can solve the problem that the cooling and dehumidifying capacities of the inner cavity of the container body are poor.

Referring to fig. 1 to 3, the optical storage and filling inspection container of the present utility model includes a container body 1, a cooling assembly 2 and an optical storage and filling assembly 3 disposed in an inner cavity of the container body 1; the cooling assembly 2 comprises a water cooling unit 21, a fan housing 22 and a water cooling pipe; the air inlet end of the air cover 22 is connected with a cold air port of the water cooling unit 21, and the air outlet end of the air cover 22 faces the light storage and filling assembly 3; the water cooling pipe is connected into a cold coil pipe of the water cooling unit 21 and is used for carrying out heat exchange with the optical storage and filling component 3. Wherein, the top of preferred box 1 adopts the buckled plate, not only can strengthen the intensity of box 1, can avoid box 1 top ponding moreover.

From the above description, the beneficial effects of the utility model are as follows: the cooling component 2 is additionally arranged in the inner cavity of the box body 1, and the water cooling unit 21 of the cooling component 2 blows low-temperature dry air to the light storage and filling component 3 through the fan housing 22, so that the light storage and filling component 3 is prevented from operating in a high-temperature environment, condensed water is prevented from being generated, and the safe use of the light storage and filling component is further ensured. Meanwhile, a water cooling pipe is connected to the cold coil pipe of the water cooling unit 21, so that low-temperature cooling liquid in a cooling system of the water cooling unit 21 can be led to the optical storage and filling assembly 3 for heat exchange, and the optical storage and filling assembly 3 is further cooled.

Referring to fig. 1 to 3, further, a partition wall 11 is disposed in the inner cavity of the case 1, the partition wall 11 divides the inner cavity of the case 1 into a cooling chamber and a light storage and filling chamber, the water cooling unit 21 is disposed in the cooling chamber, and the light storage and filling assembly 3 is disposed in the light storage and filling chamber.

As can be seen from the above description, the partition wall 11 is used to divide the inner cavity of the box 1 into a cooling chamber for loading the water cooling unit 21 and a light storage and filling chamber for loading the light storage and filling assembly 3, so as to realize regional management, avoid mixing the circuits of the water cooling unit 21 in the circuits of the light storage and filling assembly 3, and increase the maintenance difficulty.

Referring to fig. 1 to 3, further, the optical storage and charging assembly 3 includes a battery pack 31 and an equipment set 32 electrically connected to each other, the optical storage and charging chamber is divided into a battery compartment and an equipment compartment by a partition wall 11, the battery pack 31 is disposed in the battery compartment, and the equipment set 32 is disposed in the equipment compartment.

As is clear from the above description, the partition wall 11 further divides the light storage and charging chambers, so as to realize the regional management of the battery pack 31 and the equipment set 32, and avoid the mixing of the lines of the battery pack 31 and the equipment set 32, thereby increasing the maintenance difficulty. Meanwhile, the battery pack 31 which is easy to fire is separated from the equipment set 32 through the partition wall 11, so that when the battery pack 31 fires, the fire is prevented from spreading to the equipment set 32, and related equipment of the equipment set 32 is damaged.

In an alternative embodiment, the cooling bin, the battery bin and the equipment bin are sequentially arranged along the length direction of the inner cavity of the box body 1, two water cooling units 21 are assembled in the cooling bin, one water cooling unit 21 cools and dehumidifies the battery bin, and the other water cooling unit 21 cools and dehumidifies the equipment bin. The cold air port of each water cooling unit 21 is connected with a fan cover 22, an air duct 221 crossing the battery compartment is arranged above the equipment compartment, and the air duct 221 is connected with the exhaust end of one fan cover 22.

In an alternative embodiment, the battery pack 31 is a water-cooled battery pack; in some embodiments, the cell module of the water-cooled battery pack may be immersed in a fluorinated fluid that ensures that sufficient fluid absorbs heat when the cell is thermally out of control, thereby avoiding fires and explosions caused by thermal runaway.

Referring to fig. 1, 3 and 4, further, a mounting rack 12 is disposed in the battery compartment of the case 1.

In an alternative embodiment, referring to fig. 4 and 5, the battery pack 31 of the light storage module 3 is partially disposed on the mounting frame 12 such that the mounting frame 12 is divided into an upper layer for mounting the battery pack and a lower layer for mounting the battery master from top to bottom. Specifically, the battery pack further comprises a second bracket 311 connected with the mounting frame 12, the second bracket 311 is welded or locked on the mounting frame 12, and the front end of the battery pack 31 is locked with the second bracket 311. Further, still include a plurality of third supports 121, third support 121 sets up the left and right sides at mounting bracket 12 to set up in proper order from outside to inside in battery package 31 mounted position department, third support 121 presses boss 8 at battery package 31 both sides limit, can guarantee the stability of battery package 31 on mounting bracket 12 through second support 311 and third support 121. Wherein, the heights of the bosses 8 at the two sides of the preferred battery pack 31 from the front end to the rear end of the battery pack 31 are sequentially reduced by 2mm, and the third brackets 121 on the mounting frame 12 are correspondingly adapted, so that the battery pack 31 can be conveniently mounted on the mounting frame 12. The lower layer of the mounting frame 12 is provided with a fourth bracket 122, and the battery master is locked to the mounting frame 12 through the fourth bracket 122.

Further, the box 1 is provided with a grounding copper bar (not shown in the figure), and the grounding copper bar is connected with the water cooling unit 21 and the mounting frame 12 through wire harnesses respectively. Wherein, the preferential ground copper bar passes through M10 screwed connection with box 1, and box 1 scribbles conductive paint with ground copper bar junction, guarantees box 1 ground connection. The part of the grounding copper bar extending out of the box body 1 is provided with two M10 tooth holes for grounding the outer side of the box body 1.

As is apparent from the above description, the use safety of the case 1 is ensured by the grounding copper bars.

Referring to fig. 1 to 3, further, the bottom of the water-cooling unit 21 is connected to the bottom of the box 1, and a first bracket 211 is disposed on the top of the water-cooling unit 21, and the first bracket 211 is connected to the partition wall 11.

As can be seen from the above description, when the box 1 is transported or hoisted, in order to avoid the water-cooling unit 21 from shaking in the box 1 to tear the fan housing 22, the bottom of the water-cooling unit 21 is connected to the bottom of the box 1, and the top of the water-cooling unit 21 is connected to the partition wall 11 through the first bracket 211, so as to ensure that the water-cooling unit 21 does not shake.

The water cooling pipes comprise two paths, one path of water cooling pipes extends to the battery bin to refrigerate the battery pack; the other path of water cooling pipe extends to the equipment bin to refrigerate DCDC, PCS and photovoltaic. Each group of the water cooling pipes comprises a main pipe 23 and branch pipes 24 which are communicated, the main pipe 23 is positioned above the light storage and filling assembly 3, and the branch pipes 24 respectively extend into each device needing heat dissipation.

As is apparent from the above description, the coolant of the water-cooling unit 21 flows through the water-cooling plates of the optical storage-and-filling assembly 3 through the main pipe 23 and the branch pipe 24 to exchange heat.

Further, in the battery compartment, the battery packs 31 need to be connected in series/parallel, so that the branch pipe 24 is laid on one side of the battery packs 31, and the cable connected between the battery packs 31 is laid on the other side of the battery packs 31, so that water-electricity separation is realized, and the safety is ensured.

Referring to fig. 1 and 2, further, the optical storage and filling inspection container further includes a fire protection system, the fire protection system includes a flammable gas detector 4 and an exhaust device 5 electrically connected with the flammable gas detector 4, the flammable gas detector 4 is disposed in the battery compartment, and the exhaust device 5 includes a fire protection air inlet valve 51 and a fire protection air outlet valve 52 disposed on opposite side walls of the box 1.

As is apparent from the above description, the combustible gas concentration in the battery compartment is detected by the combustible gas detector 4, and when the combustible gas concentration in the battery compartment reaches the threshold value, the fire-fighting air inlet valve 51 and the fire-fighting air outlet valve 52 are opened to discharge the combustible gas in the battery compartment out of the battery compartment, thereby ensuring that the battery compartment does not fire due to high combustible gas concentration.

Referring to fig. 6 and 7, further, the fire control air intake valve 51 includes a first louver 511, a first sealing plate 512, and a first driving device 513; the first shutter 511 is embedded on the side wall of the box body 1, the first sealing plate 512 is hinged at a window of the first shutter 511, a movable end of the first driving device 513 is hinged with the first sealing plate 512, and the first driving device 513 is electrically connected with the combustible gas detector 4.

As can be seen from the above description, when the fire-fighting air outlet valve 52 is operated to discharge the combustible gas in the battery compartment, the first driving device 513 will jack up the first sealing plate 512, so that the external space can flow into the battery compartment through the first louver 511, so as to balance the pressure difference between the battery compartment and the outside, and thus the fire-fighting air outlet valve 52 can discharge the combustible gas in the battery compartment out of the battery compartment conveniently. In the normal operation process of the optical storage filling and detecting container, the first sealing plate 512 is positioned at the window of the first louver 511, so that foreign matters such as external dust can be prevented from entering the battery compartment from the first louver 511.

Referring to fig. 8 and 9, further, the fire-fighting air outlet valve 52 includes a second louver 521, a second sealing plate 522, a fan 523, and a second driving device 524; the second shutter 521 is embedded on the side wall of the box body 1, the second sealing plate 522 is hinged at a window of the second shutter 521, the fan 523 fans towards the direction of the second shutter 521, the movable end of the second driving device 524 is hinged with the second sealing plate 522, and the second driving device 524 is electrically connected with the combustible gas detector 4.

As can be seen from the above description, when the flammable gas detector 4 detects that the concentration of the flammable gas in the battery compartment reaches the threshold value, the second driving device 524 lifts the second sealing plate 522, and then the fan 523 is used to discharge the air in the battery compartment to the outside through the second louver 521. In the normal operation process of the optical storage filling and detecting container, the second sealing plate 522 is positioned at the window of the second shutter 521, so that foreign matters such as external dust can be prevented from entering the battery compartment from the second shutter 521.

Referring to fig. 1 to 3, further, the fire protection system further includes a photoelectric smoke detector 6 and a fire protection cabinet 7; the photoelectric smoke-sensing fire detector 6 is arranged in the battery compartment, the fire-fighting cabinet 7 is arranged in the equipment compartment, the water outlet end of the fire-fighting cabinet 7 is connected with a water drain pipe, and the water outlet end of the water drain pipe extends into the battery compartment. Wherein, the liquid discharged from the water outlet end of the fire-fighting cabinet 7 is heptafluoropropane.

As can be seen from the above description, since the electrical apparatus is generally placed in the equipment compartment, fire is not easy to occur, and therefore the fire-fighting cabinet 7 is disposed in the equipment compartment, when the photoelectric smoke fire detector 6 detects the fire occurring in the battery compartment, it can be ensured that the fire-fighting cabinet 7 cannot be normally used due to fire.

In an alternative embodiment, referring to fig. 10, the fire protection system further includes a smoke detector, an audible and visual alarm, and a hydrant 9, where the smoke detector is disposed in the equipment cabin, and the audible and visual alarm is electrically connected to the smoke detector, the combustible gas detector 4, and the photoelectric smoke fire detector 6, respectively, and when the detector senses an abnormality in the cabin, the audible and visual alarm sends out an alarm message, thereby reminding the field personnel. The arrangement of the hydrant 9 can extinguish fire by being connected to an external fire hose.

Example 1

Referring to fig. 1 to 3, an optical storage and filling container includes a container body 1, a cooling assembly 2 and an optical storage and filling assembly 3 disposed in an inner cavity of the container body 1; the cooling assembly 2 comprises a water cooling unit 21, a fan housing 22 and a water cooling pipe; the air inlet end of the air cover 22 is connected with a cold air port of the water cooling unit 21, and the air outlet end of the air cover 22 faces the light storage and filling assembly 3; the water cooling pipe is connected into a cold coil pipe of the water cooling unit 21 and is used for carrying out heat exchange with the optical storage and filling component 3. The light stores up subassembly 3 including mutual electricity connection's battery package 31 and equipment group 32, the inner chamber of box 1 is provided with partition wall 11, partition wall 11 divide into cooling bin, battery compartment and equipment storehouse with the inner chamber of box 1, water-cooling unit 21 sets up in the cooling bin, battery package 31 sets up in the battery compartment, equipment group 32 sets up in the equipment storehouse.

Example two

The present embodiment further defines a cooling structure of the cooling pipe joint of the cooling module 2 with respect to the optical storage and filling module 3 on the basis of the first embodiment, specifically as follows:

Referring to fig. 4 and 5, a mounting frame 12 for mounting the optical storage and filling assembly 3 is disposed in the inner cavity of the box 1, and a cable of the optical storage and filling assembly 3 is laid on one side surface of the mounting frame 12; the water cooling pipe comprises a main pipe 23 and a branch pipe 24 which are communicated, the main pipe 23 is positioned above the light storage and filling assembly 3, and the branch pipe 24 is laid on one side surface of the mounting frame 12, which is far away from the light storage and filling assembly 3 and is used for laying cables.

Example III

The present embodiment further defines the installation structure of the water-cooling unit 21 in the case 1 based on the first embodiment, specifically as follows:

Referring to fig. 1 to 3, the bottom of the water-cooling unit 21 is connected to the bottom of the box 1, and a first bracket 211 is disposed on the top of the water-cooling unit 21, and the first bracket 211 is connected to the partition wall 11.

Example IV

The embodiment further defines that the optical storage and filling inspection container further comprises a fire-fighting system based on the first embodiment, and the optical storage and filling inspection container comprises the following concrete steps:

Referring to fig. 1, 2 and 6-9, the fire protection system includes a fuel gas detector 4, an exhaust device 5, a photoelectric smoke detector 6 and a fire protection cabinet 7, wherein the fuel gas detector 4 is disposed in the battery compartment, and the exhaust device 5 includes a fire protection air inlet valve 51 and a fire protection air outlet valve 52 disposed on two opposite side walls of the box 1. The fire control air intake valve 51 includes a first louver 511, a first sealing plate 512, and a first driving device 513; the first shutter 511 is embedded on the side wall of the box body 1, the first sealing plate 512 is hinged at a window of the first shutter 511, a movable end of the first driving device 513 is hinged with the first sealing plate 512, and the first driving device 513 is electrically connected with the combustible gas detector 4. The fire air outlet valve 52 comprises a second louver 521, a second sealing plate 522, a fan 523 and a second driving device 524; the second shutter 521 is embedded on the side wall of the box body 1, the second sealing plate 522 is hinged at a window of the second shutter 521, the fan 523 fans towards the direction of the second shutter 521, the movable end of the second driving device 524 is hinged with the second sealing plate 522, and the second driving device 524 is electrically connected with the combustible gas detector 4. The photoelectric smoke-sensing fire detector 6 is arranged in the battery compartment, the fire-fighting cabinet 7 is arranged in the equipment compartment, the water outlet end of the fire-fighting cabinet 7 is connected with a water drain pipe, and the water outlet end of the water drain pipe extends into the battery compartment.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent changes made by the specification and drawings of the present utility model, or direct or indirect application in the relevant art, are included in the scope of the present utility model.

Claims (10)

1. The utility model provides a light stores up fills and examines container which characterized in that: comprises a box body, a cooling component and a light storage and filling component which are arranged in the inner cavity of the box body;

The cooling assembly comprises a water cooling unit, a fan housing and a water cooling pipe; the air inlet end of the air cover is connected with a cold air port of the water cooling unit, and the air outlet end of the air cover faces the light storage and filling assembly;

The water cooling pipe is connected into a cold coil pipe of the water cooling unit and is used for carrying out heat exchange with the optical storage and filling component.

2. The optical storage filling container according to claim 1, wherein: the inner cavity of the box body is provided with a partition wall, the partition wall divides the inner cavity of the box body into a cooling bin and a light storage and filling bin, the water cooling unit is arranged in the cooling bin, and the light storage and filling assembly is arranged in the light storage and filling bin.

3. The optical storage filling container according to claim 2, wherein: the light stores up the subassembly and includes battery package and the equipment group of mutual electricity connection, light stores up the bin and divide into battery compartment and equipment storehouse through the partition wall, the battery package sets up in the battery compartment, the equipment group sets up in the equipment storehouse.

4. A light storage and retrieval container according to claim 3, wherein: the battery pack is characterized in that a mounting frame, a second support and a third support for mounting the battery pack are arranged in the battery compartment, the second support and the third support are welded or locked on the mounting frame, the front end of the battery pack is fixed with the second support in a locking mode, and two sides of the battery pack are limited through the third support.

5. A light storage and retrieval container according to claim 3, wherein: the water cooling pipe comprises two paths, one path of the water cooling pipe extends to the battery compartment, and the other path of the water cooling pipe extends to the equipment compartment; the water cooling pipe comprises a main pipe and branch pipes which are communicated, the main pipe is positioned above the light storage and filling assembly, and the branch pipes extend to all equipment needing heat dissipation.

6. A light storage and retrieval container according to claim 3, wherein: the box is provided with a grounding copper bar, and the grounding copper bar is respectively connected with the water cooling unit and the mounting frame through wiring harnesses.

7. The optical storage filling container according to claim 2, wherein: the bottom of the water cooling unit is connected with the bottom of the box body, and a first support is arranged at the top of the water cooling unit and connected with the partition wall.

8. The optical storage filling container according to claim 6, wherein: the fire-fighting system comprises a combustible gas detector and an exhaust device electrically connected with the combustible gas detector, wherein the combustible gas detector is arranged in the battery bin, and the exhaust device comprises a fire-fighting air inlet valve and a fire-fighting air outlet valve which are arranged on two opposite side walls of the box body.

9. The optical storage filling container according to claim 8, wherein: the fire control air inlet valve comprises a first shutter, a first sealing plate and a first driving device; the first shutter is embedded on the side wall of the box body, the first sealing plate is hinged at the window of the first shutter, the movable end of the first driving device is hinged with the first sealing plate, and the first driving device is electrically connected with the combustible gas detector; the fire control air outlet valve comprises a second shutter, a second sealing plate, a fan and a second driving device; the second shutter is embedded on the side wall of the box body, the second sealing plate is hinged to a window of the second shutter, the fan fans towards the direction of the second shutter, the movable end of the second driving device is hinged to the second sealing plate, and the second driving device is electrically connected with the combustible gas detector.

10. The optical storage filling container according to claim 8, wherein: the fire-fighting system also comprises a photoelectric smoke-sensing fire detector and a fire-fighting cabinet; the photoelectric smoke-sensing fire detector is arranged in the battery compartment, the fire-fighting cabinet is arranged in the equipment compartment, the water outlet end of the fire-fighting cabinet is connected with a water drain pipe, and the water outlet end of the water drain pipe extends into the battery compartment.