CN219267766U - Air-cooled energy storage container air conditioner air duct system and air-cooled energy storage container - Google Patents

Abstract

The utility model relates to an air-cooled energy storage container air conditioner air duct system and an air-cooled energy storage container, comprising a primary air duct, a secondary air duct, a wind direction and pressure regulating plate, a hinge and a locking piece; the primary air duct is in a tubular shape with one end open and the other end sealed, the primary air duct is vertically connected with a plurality of secondary air ducts, one end of each secondary air duct is communicated with the primary air duct, the other end of each secondary air duct is sealed, and a plurality of secondary air duct air outlets are formed in the secondary air ducts; one end of the wind direction and wind pressure regulating plate is connected with a hinge, the other end of the wind direction and wind pressure regulating plate is connected with a locking piece, and the hinge is connected to the bottom of the opening end of the primary air duct; a notch is formed in one sealed end of the primary air duct, and the locking piece penetrates through the notch; when the locking piece slides up and down along the notch, the wind direction and wind pressure adjusting plate can be driven to rotate around the hinge, and then the wind direction and the wind pressure of wind entering from the opening end of the primary air channel are adjusted. The advantages are that: the integrated level is high, the installation is simple, the flexibility and the adjustability are realized, and the air quantity balance is high.

Description

Air-cooled energy storage container air conditioner air duct system and air-cooled energy storage container

Technical Field

The utility model relates to the technical field of air-cooled energy storage containers, in particular to a wind direction and wind pressure adjusting device and an air-cooled energy storage container.

Background

At present, the technology for solving the problem of temperature equalization of the battery cells in the energy storage container comprises the following steps: air cooling heat dissipation, liquid cooling heat dissipation and phase change material heat dissipation, wherein air cooling heat dissipation is still the mainstream cell temperature equalization technology.

The main composition structure of the air-cooling heat dissipation system is that an industrial air conditioner is used as a cold source, a primary air duct (main air duct), a secondary air duct (cluster-level air duct), a battery cell module fan and a control loop are configured, and the heat of the battery cell is taken away by flowing of cold air in an air duct circulation loop, so that the battery cell is ensured to run in a proper temperature environment.

One end of the primary air channel is open, the other end of the primary air channel is closed, the open end is connected with the cold air outlet of the industrial air conditioner, because the primary air channel is longer, the air flow direction is perpendicular to the secondary air inlet, and the distances between different battery clusters and the cold air outlet of the air conditioner are different, the wind direction and wind pressure wind shield is usually fixed in the primary air channel, so that the purposes of adjusting the wind direction and balancing the air quantity are achieved, and the primary air channel has obvious heat dissipation effect, is manufactured and formed at one time, cannot change in position direction, and cannot achieve ideal effects.

Disclosure of Invention

The utility model aims to provide an air-cooled energy storage container air conditioner air duct system and an air-cooled energy storage container.

The utility model provides an air-cooled energy storage container air conditioner air duct system which comprises a primary air duct, a secondary air duct, a wind direction and pressure adjusting plate, a hinge and a locking piece, wherein the primary air duct is connected with the primary air duct; the primary air duct is in a tubular shape with one end open and the other end sealed, the primary air duct is vertically connected with a plurality of secondary air ducts, one end of each secondary air duct is communicated with the primary air duct, the other end of each secondary air duct is sealed, and a plurality of secondary air duct air outlets are formed in each secondary air duct; one end of the wind direction and pressure regulating plate is connected with the hinge, the other end of the wind direction and pressure regulating plate is connected with the locking piece, and the hinge is connected to the bottom of the opening end of the primary air duct; a notch is formed in one sealed end of the primary air duct, and the locking piece penetrates through the notch; when the locking piece slides up and down along the notch, the wind direction and wind pressure adjusting plate is driven to rotate around the hinge, and then wind direction and wind pressure of wind entering from the opening end of the primary air channel are adjusted.

Further, the primary air duct comprises a bottom plate, a top plate, a front end plate, a rear end plate and a sealing plate; the long sides of the bottom plate, the top plate, the front end plate and the rear end plate are sequentially and vertically connected to form a square pipe, and an opening at one end of the square pipe is connected with the sealing plate for sealing the opening; the notch is arranged on the sealing plate, and the hinge is hinged on the bottom plate; the short side of the wind direction and wind pressure regulating plate is parallel to the bottom plate, and the short side of the wind direction and wind pressure regulating plate is perpendicular to the front end plate.

Further, a plurality of primary air channel air outlets are arranged on the front end plate near the edge opening of the top plate, and the primary air channel air outlets are arranged in a row; the primary air duct air outlet is connected with the secondary air duct in a sealing way.

Further, the air-cooled energy storage container air-conditioning air duct system also comprises an air-conditioning air outlet connector; the air conditioner air outlet connector is connected with one end of the square pipe, which is far away from the sealing plate.

Further, the locking piece comprises a bolt, a locking nut and an adjusting handle; one end of the bolt is connected to one end, far away from the hinge, of the wind direction and wind pressure adjusting plate, the other end of the bolt is connected with the adjusting handle, and the locking nut is sleeved on the bolt in a matched mode; the lock nut is located outside the seal plate when the bolt passes through the slot.

Further, a seal is provided at the edge of the slot.

The utility model also provides an air-cooled energy storage container, which comprises the air-cooled energy storage container air conditioner air duct system.

Further, the primary air duct is fixed at the top of the container, and an opening at one end of the primary air duct is connected with an air outlet of the air conditioner; the secondary duct is mounted on the back of the battery cluster in the container.

Further, the secondary air duct air outlet is opposite to the battery plug box in the battery cluster.

According to the air-cooled energy storage container air-conditioning air duct system, the wind direction and the wind pressure in the primary air duct can be dynamically adjusted through the design that the wind direction and the wind pressure adjusting plate rotate around the hinge, so that the temperature balance of the whole battery cell in the energy storage container is improved; meanwhile, the system has simple structure, does not need indirect medium and is easy to install; the wind direction and wind pressure regulating plate in the primary air channel has high integration degree and simple installation, and compared with the traditional wind direction and wind pressure wind shield in the primary air channel, the wind direction and wind pressure wind shield in the primary air channel has flexible and adjustable relative fixed positions, and the air quantity balance of the air inlet of the secondary air channel is improved.

Drawings

Fig. 1 is a schematic structural diagram of an air-cooled energy storage container air-conditioning duct system according to an embodiment of the present utility model.

Fig. 2 is a schematic structural diagram of a primary air duct of the air conditioning duct system of the wind cooling energy storage container of fig. 1.

Fig. 3 is a schematic diagram of a structure of a primary air duct of the air conditioning duct system of the wind cold energy storage container of fig. 1 from another view.

Fig. 4 is a schematic diagram of a cut-away structure of a primary air duct of the air conditioning duct system of the wind cold energy storage container of fig. 1.

Fig. 5 is a schematic structural diagram of a wind direction and pressure adjusting plate of the air conditioning duct system of the wind cooling energy storage container in fig. 1.

Fig. 6 is an enlarged view of a portion a of fig. 5.

Fig. 7 is an enlarged view of a portion B of fig. 5.

Reference numerals and components referred to in the drawings are as follows:

1. primary air duct 11, notch 12 and bottom plate

13. Top plate 14, front end plate 15, rear end plate

16. Sealing plate 17, square tube 18 and primary air duct air outlet

2. Secondary air duct 21, secondary air duct air outlet 3, wind direction and wind pressure regulating plate

4. Hinge 5, locking member 51 and bolt

52. Lock nut 53, adjusting handle 6 and air conditioner air outlet connector

7. Sealing element

Detailed Description

The following describes in further detail the embodiments of the present utility model with reference to the drawings and examples. The following examples are illustrative of the utility model and are not intended to limit the scope of the utility model.

The terms first, second, third, fourth and the like in the description and in the claims, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

Example 1

Fig. 1 is a schematic structural diagram of an air-cooled energy-storage container air-conditioning air duct system according to an embodiment of the present utility model, fig. 2 is a schematic structural diagram of a primary air duct of the air-cooled energy-storage container air-conditioning air duct system in fig. 1, fig. 3 is a schematic structural diagram of another view angle of the primary air duct of the air-cooled energy-storage container air-conditioning air duct system in fig. 1, and fig. 4 is a schematic sectional structural diagram of the primary air duct of the air-cooled energy-storage container air-conditioning air duct system in fig. 1. Referring to fig. 1, 2, 3 and 4, the air-cooled energy-storage container air-conditioning duct system provided by the embodiment of the utility model comprises a primary duct 1, a secondary duct 2, a wind direction and pressure adjusting plate 3, a hinge 4 and a locking piece 5; the primary air duct 1 is in a tubular shape with one end open and the other end sealed, the primary air duct 1 is vertically connected with a plurality of secondary air ducts 2, one end of each secondary air duct 2 is communicated with the primary air duct 1, the other end of each secondary air duct is sealed, and a plurality of secondary air duct air outlets 21 are formed in each secondary air duct 2; one end of the wind direction and pressure regulating plate 3 is connected with the hinge 4, the other end is connected with the locking piece 5, and the hinge 4 is connected to the bottom of the opening end of the primary air duct 1; a notch 11 is formed in the sealed end of the primary air duct 1, and the locking piece 5 penetrates through the notch 11;

when the locking piece 5 slides up and down along the notch 11, the wind direction and wind pressure adjusting plate 3 is driven to rotate around the hinge 4, so that the wind direction and the wind pressure of wind entering from the opening end of the primary air duct 1 are adjusted.

When the wind direction and pressure adjusting plate 3 rotates toward the secondary air duct 2, the air pressure in the primary air duct 1 increases, and conversely, the air pressure decreases.

According to the air-cooled energy storage container air-conditioning air duct system, the wind direction and the wind pressure in the primary air duct 1 can be dynamically adjusted through the design that the wind direction and the wind pressure adjusting plate 3 rotates around the hinge 4, so that the temperature balance of the whole battery cell in the energy storage container is improved; meanwhile, the system has simple structure, does not need indirect medium and is easy to install; the wind direction and wind pressure regulating plate 3 in the primary air channel 1 has high integration degree and simple installation, and compared with the traditional wind direction and wind pressure wind shield in the primary air channel 1, the wind direction and wind pressure wind shield is flexibly adjustable in relative fixed position, and the air quantity balance of the air inlet of the secondary air channel is improved.

With further reference to fig. 2, 3 and 4, the primary air duct 1 of the present utility model includes a bottom plate 12, a top plate 13, a front end plate 14, a rear end plate 15 and a sealing plate 16; the long sides of the bottom plate 12, the top plate 13, the front end plate 14 and the rear end plate 15 are sequentially and vertically connected to form a square pipe 17, and an opening at one end of the square pipe 17 is connected with the sealing plate 16 for sealing the opening; the notch 11 is arranged on the sealing plate 16, and the hinge 4 is connected to the bottom plate 12; the short side of the wind direction and pressure regulating plate 3 is parallel to the bottom plate 12, and the short side of the wind direction and pressure regulating plate 3 is perpendicular to the front end plate 14. A plurality of primary air duct air outlets 18 are arranged on the front end plate 14 near the edge opening of the top plate 13, and the primary air duct air outlets 18 are arranged in a row; the primary air duct air outlet 18 is connected with the secondary air duct 2 in a sealing way.

With further reference to fig. 2, 3 and 4, the air-cooled energy storage container air-conditioning duct system of the present utility model further includes an air-conditioning outlet connector 6; the air-conditioning outlet connector 6 is connected with a port of the square pipe 17, which is far away from the sealing plate 16. It should be noted that, the design of the air conditioner air outlet connector 6 is convenient for connecting the primary air duct 1 with the air conditioner air outlet.

Fig. 5 is a schematic structural diagram of a wind direction and pressure adjusting plate of the air conditioning duct system of the wind cooling energy storage container in fig. 1, fig. 6 is an enlarged view of a portion a in fig. 5, and fig. 7 is an enlarged view of a portion B in fig. 5. The locking member 5 of the present utility model includes a bolt 51, a lock nut 52 and an adjustment handle 53; one end of the bolt 51 is connected to one end of the wind direction and pressure adjusting plate 3, which is far away from the hinge 4, the other end of the bolt 51 is connected with the adjusting handle 53, and the locking nut 52 is sleeved on the bolt 51 in a matching way; when the bolt 51 passes through the notch 11, the lock nut 52 is located outside the sealing plate 16.

It should be noted that, when the wind direction and wind pressure adjusting plate 3 needs to be rotated, only the adjusting handle 53 needs to be pulled up or pushed down; meanwhile, when the position of the wind direction and wind pressure adjusting plate 3 is required to be locked, the locking nut 52 is only required to be rotated, so that the locking nut 52 compresses the sealing plate 16.

With further reference to fig. 1, the sealing element 7 is arranged at the edge of the notch 11, so that the tightness of the air duct is further ensured.

The utility model also provides an air-cooled energy storage container, and the air-cooled energy storage container air-conditioning duct system. Specifically, the primary air duct 1 is fixed at the top of the container, and one end opening of the primary air duct 1 is connected with an air outlet of the air conditioner; the secondary air duct 2 is arranged at the back of a battery cluster in the container; the secondary air duct air outlet 21 is opposite to the battery plug box in the battery cluster, so that the cooling effect is improved.

Based on the above description, the utility model has the advantages that:

1. according to the air-cooled energy storage container air-conditioning air duct system, the wind direction and the wind pressure in the primary air duct can be dynamically adjusted through the design that the wind direction and the wind pressure adjusting plate rotate around the hinge, so that the temperature balance of the whole battery cell in the energy storage container is improved;

2. the air-cooled energy storage container air-conditioning duct system provided by the utility model has the advantages of simple structure, no need of indirect medium and easiness in installation.

3. The wind direction and wind pressure regulating plate in the primary air channel has high integration degree and simple installation, and compared with the traditional wind direction and wind pressure wind shield in the primary air channel, the wind direction and wind pressure wind shield in the primary air channel has flexible and adjustable relative fixed position, and the air quantity balance of the air inlet of the secondary air channel is improved.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (9)

1. The air-cooled energy-storage container air-conditioning air duct system is characterized by comprising a primary air duct (1), a secondary air duct (2), a wind direction and wind pressure adjusting plate (3), a hinge (4) and a locking piece (5); the primary air duct (1) is in a tubular shape with one end open and the other end sealed, the primary air duct (1) is vertically connected with a plurality of secondary air ducts (2), one end of each secondary air duct (2) is communicated with the primary air duct (1) and the other end is sealed, and a plurality of secondary air duct air outlets (21) are formed in each secondary air duct (2);

one end of the wind direction and pressure adjusting plate (3) is connected with the hinge (4), the other end of the wind direction and pressure adjusting plate is connected with the locking piece (5), and the hinge (4) is connected to the bottom of the opening end of the primary air duct (1); a notch (11) is formed in the sealed end of the primary air duct (1), and the locking piece (5) penetrates through the notch (11);

when the locking piece (5) slides up and down along the notch (11), the wind direction and wind pressure adjusting plate (3) is driven to rotate around the hinge (4), and then the wind direction and the wind pressure of wind entering from the opening end of the primary air channel (1) are adjusted.

2. An air-cooled energy-storage container air-conditioning duct system according to claim 1, characterized in that the primary duct (1) comprises a bottom plate (12), a top plate (13), a front end plate (14), a rear end plate (15) and a sealing plate (16);

the long sides of the bottom plate (12), the top plate (13), the front end plate (14) and the rear end plate (15) are sequentially and vertically connected to form a square pipe (17), and an opening at one end of the square pipe (17) is connected with the sealing plate (16) for sealing the opening;

the notch (11) is arranged on the sealing plate (16), and the hinge (4) is connected to the bottom plate (12); the short side of the wind direction and pressure regulating plate (3) is parallel to the bottom plate (12), and the short side of the wind direction and pressure regulating plate (3) is perpendicular to the front end plate (14).

3. The air-cooled energy storage container air-conditioning duct system according to claim 2, wherein a plurality of primary air duct air outlets (18) are arranged on the front end plate (14) near the edge opening of the top plate (13), and the plurality of primary air duct air outlets (18) are arranged in a row; the primary air duct air outlet (18) is connected with the secondary air duct (2) in a sealing way.

4. An air-cooled energy storage container air conditioning duct system according to claim 2, characterized in that the air-cooled energy storage container air conditioning duct system further comprises an air-conditioner air outlet connector (6); the air conditioner air outlet connector (6) is connected with a port of the square pipe (17) far away from the sealing plate (16).

5. An air-cooled energy storage container air conditioning duct system according to claim 2, characterized in that the locking member (5) comprises a bolt (51), a locking nut (52) and an adjustment handle (53); one end of the bolt (51) is connected to one end, far away from the hinge (4), of the wind direction and wind pressure adjusting plate (3), the other end of the bolt (51) is connected with the adjusting handle (53), and the locking nut (52) is sleeved on the bolt (51) in a matching mode; the lock nut (52) is located outside the sealing plate (16) when the bolt (51) passes through the notch (11).

6. An air-cooled energy storage container air conditioning duct system according to claim 5, characterized in that a seal (7) is provided at the edge of the slot (11).

7. An air-cooled energy storage container, characterized by comprising an air-cooled energy storage container air conditioning duct system according to any of claims 1-6.

8. The air-cooled energy storage container according to claim 7, wherein the primary air duct (1) is fixed at the top of the container, and an opening at one end of the primary air duct (1) is connected with an air outlet of an air conditioner; the secondary air duct (2) is arranged at the back of the battery cluster in the container.

9. An air cooled energy storage container as claimed in claim 8, wherein the secondary duct air outlet (21) is directly opposite to a battery compartment within the battery cluster.

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