CN217522110U - Distributed air guide and drainage device of energy storage container system - Google Patents

Abstract

The utility model provides a wind-guiding and drainage device of a distributed energy-storage container system, which comprises a box body and a wind-guiding and drainage air duct; wind-guiding drainage wind channel installs on the box top, and wind-guiding drainage wind channel is provided with the air intake and installs the cooling air conditioner with the air intake intercommunication on the box, and wind-guiding drainage wind channel is connected with a plurality of blast pipes that stretch into the box inside, and the position all is provided with energy storage battery frame between two arbitrary adjacent blast pipes that lie in the box, and the blast pipe is close to energy storage battery frame one side and has seted up the air outlet. The utility model discloses can satisfy the requirement of energy storage container system to the wind-guiding drainage, inside temperature field and the flow field of whole energy storage container can rationally be controlled to distributing type wind-guiding drainage device, improves energy storage container system stability of performance effectively.

Description

Distributed air guide and drainage device of energy storage container system

Technical Field

The utility model relates to an energy storage technical field especially relates to a distributing type energy storage container system wind-guiding drainage device.

Background

The existing energy storage container has high integration level and large heat productivity, and a heat dissipation air duct can be designed in order to ensure the normal operation of energy storage equipment. The heat exchange treatment mode is mostly that a heat dissipation air duct is additionally arranged in the container box body, the heat dissipation air duct adopts a variable-caliber air duct or is additionally provided with an auxiliary fan, so that the heat dissipation efficiency is improved. However, the air ducts of the existing device are respectively uneven, the temperature difference of the batteries in the energy storage container is large, and the requirement of the energy storage container on the temperature uniformity of the batteries cannot be met.

SUMMERY OF THE UTILITY MODEL

Based on the technical problem who exists among the background art, the utility model provides a distributing type energy storage container system wind-guiding drainage device.

The utility model provides a distributed energy storage container system wind-guiding and drainage device, which comprises a box body and a wind-guiding and drainage air duct; wind-guiding drainage wind channel installs on the box top, and wind-guiding drainage wind channel is provided with the air intake and installs the cooling air conditioner with the air intake intercommunication on the box, and wind-guiding drainage wind channel is connected with a plurality of blast pipes that stretch into the box inside, and the position all is provided with energy storage battery frame between two arbitrary adjacent blast pipes that lie in the box, and the blast pipe is close to energy storage battery frame one side and has seted up the air outlet.

Preferably, a plurality of baffles are installed at intervals along the length direction in the air guide drainage air duct, the plurality of baffles divide the air guide drainage air duct into a plurality of air guide drainage cavities and a plurality of air guide drainage cavities, the air guide drainage cavities are respectively arranged in one-to-one correspondence with the plurality of energy storage battery racks, a plurality of air inlets and a plurality of air inlets are arranged on the air guide drainage air duct and are respectively communicated with the plurality of air guide drainage cavities, and the plurality of air inlets are respectively communicated with the plurality of cooling air conditioners.

Preferably, the air guide drainage cavity is communicated with at least one air supply pipe.

Preferably, the box body and the corresponding positions of the energy storage battery racks are provided with openings, the box doors are installed at the openings in a matched mode, the cooling air conditioners are installed on the box doors respectively, and under the closing state of the box doors, outlets of the cooling air conditioners are communicated with the air inlets of the air guide and drainage air ducts correspondingly.

Preferably, the blast pipe is arranged vertically, and a plurality of air outlets are formed in the side, close to the energy storage battery rack, of the blast pipe at intervals in the vertical direction.

Preferably, the energy storage battery rack comprises an outer frame, two inner rectangular frames which are arranged in parallel with the air supply pipe are arranged in the outer frame, the two inner rectangular frames divide the inside of the outer frame into three energy storage areas, and a plurality of battery pack mounting plates are arranged on two sides of each energy storage area at intervals in the vertical direction.

The utility model provides a distributing type energy storage container system wind-guiding drainage device adopts distributing type wind-guiding drainage wind channel, and wind channel simple structure, and with container box top welding processing, firm reliable improves production efficiency; the air guide drainage air duct is provided with an air supply pipe, an air outlet is formed in the air supply pipe, cold energy is directly supplied to each layer of energy storage battery pack, the cold energy generated by the air conditioner is directly supplied to each layer of energy storage battery pack, heat generated by each layer of battery pack in the working process is balanced, and energy loss caused by cold energy diffusion is avoided. The utility model discloses can satisfy the requirement of energy storage container system to the wind-guiding drainage, inside temperature field of whole energy storage container and flow field can rationally be controlled to distributing type wind-guiding drainage device, improves energy storage container system performance stability effectively.

Drawings

Fig. 1 is a schematic structural view of a distributed energy storage container system wind guiding and guiding device provided by the present invention;

fig. 2 is a schematic structural view of a wind guiding and guiding duct in the wind guiding and guiding device of the distributed energy storage container system according to the present invention;

fig. 3 is the utility model provides a structural schematic diagram of energy storage battery holder among distributing type energy storage container system wind-guiding drainage device.

Detailed Description

Referring to fig. 1 to 3, the utility model provides a wind-guiding and drainage device of a distributed energy-storage container system, which comprises a box body 1 and a wind-guiding and drainage air duct 2; wherein:

wind-guiding drainage wind channel 2 is installed on 1 top of box, wind-guiding drainage wind channel 2 is provided with air intake 3 and installs the cooling air conditioner 8 with 3 intercommunications of air intake on the box 1, wind-guiding drainage wind channel 2 is connected with a plurality of blast pipes 4 that stretch into 1 inside of box, it all is provided with energy storage battery frame 5 to lie in the box 1 interior position between arbitrary two adjacent blast pipes 4, blast pipe 4 is vertical to be arranged, blast pipe 4 is close to 5 one side of energy storage battery frame and is equipped with a plurality of air outlets 6 at vertical direction interval.

In this embodiment, as shown in fig. 2, a plurality of partition plates 7 are installed at intervals along the length direction in the air guide and drainage duct 2, the plurality of partition plates 7 divide the interior of the air guide and drainage duct 2 into a plurality of air guide and drainage cavities, the plurality of air guide and drainage cavities are respectively arranged in one-to-one correspondence with the plurality of energy storage battery racks 5, and the air guide and drainage cavities are at least communicated with the air supply pipe 4. The air guide drainage air duct 2 is provided with a plurality of air inlets 3, the air inlets 3 are respectively communicated with the air guide drainage cavities, and the air inlets 3 are respectively communicated with the cooling air conditioners 8.

Further, as shown in fig. 1, the box body 1 and each energy storage battery rack 5 are provided with openings corresponding to each other, and the box doors 9 are installed at the openings in a matching manner, the plurality of cooling air conditioners 8 are installed on the plurality of box doors 9 respectively, and in a state that the box doors 9 are closed, outlets of the cooling air conditioners 8 are correspondingly communicated with the air inlets 3 of the air guide and drainage air ducts 2.

Further, as shown in fig. 3, the energy storage battery rack 5 includes an outer frame 51, two inner rectangular frames 52 arranged in parallel with the blower pipe 4 are provided in the outer frame 51, the two inner rectangular frames 52 divide the inside of the outer frame 51 into three energy storage regions, a plurality of battery pack mounting plates 5 are installed on two sides of each energy storage region at intervals in the vertical direction, the plurality of battery pack mounting plates 53 on two sides are arranged in a one-to-one correspondence manner, and the two corresponding battery pack mounting plates 53 are used for mounting a battery pack a.

The utility model adopts the distributed wind guide and drainage wind channel 2, the wind channel has simple structure, is welded and processed with the top of the container body 1, is firm and reliable, and improves the production efficiency; the air guide and drainage air duct 2 is provided with an air supply pipe 4, an air outlet 6 is formed in the air supply pipe 4, cold energy is directly supplied to each layer of energy storage battery pack a, the cold energy generated by the air conditioner 8 is directly supplied to each layer of energy storage battery pack a, heat generated by each layer of battery pack a in the working process is balanced, and energy loss caused by cold energy diffusion is avoided. The utility model discloses can satisfy the requirement of energy storage container system to the wind-guiding drainage, inside temperature field and the flow field of whole energy storage container can rationally be controlled to distributing type wind-guiding drainage device, improves energy storage container system stability of performance effectively.

The above, only be the embodiment of the preferred of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, which are designed to be replaced or changed equally, all should be covered within the protection scope of the present invention.

Claims (6)

1. A distributed energy storage container system wind-guiding and drainage device is characterized by comprising a box body (1) and a wind-guiding and drainage air duct (2); wind-guiding drainage wind channel (2) are installed on box (1) top, wind-guiding drainage wind channel (2) are provided with air intake (3) and box (1) on install with air intake (3) intercommunication cooling air conditioner (8), wind-guiding drainage wind channel (2) are connected with a plurality of blast pipes (4) that stretch into box (1) inside, it all is provided with energy storage battery rack (5) to lie in the position between arbitrary adjacent two blast pipes (4) in box (1), blast pipe (4) are close to energy storage battery rack (5) one side and have seted up air outlet (6).

2. The air guide and drainage device of the distributed energy storage container system as claimed in claim 1, wherein a plurality of partition plates (7) are installed at intervals along the length direction in the air guide and drainage air duct (2), the plurality of partition plates (7) divide the interior of the air guide and drainage air duct (2) into a plurality of air guide and drainage cavities, the air guide and drainage cavities are respectively arranged in one-to-one correspondence with the plurality of energy storage battery racks (5), a plurality of air inlets (3) are formed in the air guide and drainage air duct (2), the plurality of air inlets (3) are respectively communicated with the plurality of air guide and drainage cavities, and the plurality of air inlets (3) are respectively communicated with the plurality of cooling air conditioners (8).

3. The air guide and drainage device of the distributed energy storage container system as claimed in claim 2, wherein the air guide and drainage cavity is communicated with at least one air supply pipe (4).

4. The air guide and flow guide device of the distributed energy storage container system as claimed in claim 2, wherein the box body (1) is provided with an opening corresponding to each energy storage battery rack (5), the box door (9) is installed at the opening in a matching manner, the plurality of cooling air conditioners (8) are installed on the plurality of box doors (9), and in a closed state of the box doors (9), outlets of the cooling air conditioners (8) are correspondingly communicated with the air inlet (3) of the air guide and flow guide air duct (2).

5. The air guide and flow guide device of the distributed energy storage container system as claimed in any one of claims 1 to 4, wherein the air supply pipe (4) is arranged vertically, and a plurality of air outlets (6) are formed in one side of the air supply pipe (4) close to the energy storage battery rack (5) at intervals in the vertical direction.

6. The air guide and drainage device of the distributed energy storage container system as claimed in any one of claims 1-4, wherein the energy storage battery rack (5) comprises an outer frame (51), two inner rectangular frames (52) arranged in parallel with the blast pipe (4) are arranged in the outer frame (51), the two inner rectangular frames (52) divide the inside of the outer frame (51) into three energy storage areas, and a plurality of battery pack mounting plates (53) are vertically installed on two sides of each energy storage area at intervals.

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