CN219180600U - Heat radiation structure of energy storage module and energy storage module - Google Patents

Abstract

The utility model discloses a heat dissipation mechanism of an energy storage module and the energy storage module, wherein the heat dissipation mechanism is used for dissipating heat of at least two electric units distributed along a first direction, and comprises a fixing module, a box body and a fan, wherein the fixing module is arranged at two ends of each electric unit along a second direction and is attached to two ends of each electric unit along the second direction; the box body is suitable for accommodating the electric units and the fixing modules, and side plates perpendicular to the first direction are respectively arranged on two sides of each electric unit along the first direction; a plurality of radiating hole groups are arranged on the side plates along the second direction, and the wind passing area of the radiating hole groups positioned at the two ends of each radiating hole group is larger than that of the radiating hole group positioned in the middle; the fan is arranged at one end of the box body along the second direction outside the fixed module, and the fan is opposite to the air passage and the axis extends along the second direction. The energy storage module adopts the heat dissipation structure. According to the heat radiation structure of the energy storage module and the energy storage module, the air quantity of each electric part is basically balanced, and the temperature uniformity is good.

Description

Heat radiation structure of energy storage module and energy storage module

Technical Field

The utility model relates to the technical field of energy storage, in particular to a heat dissipation structure of an energy storage module and the energy storage module.

Background

At present, the application aspects of the lithium battery energy storage technology such as distributed micro-grid energy storage, grid peak regulation and frequency modulation and user peak clipping and valley filling become one of the most rapidly developed energy storage technologies, and along with the large-scale application of the lithium battery energy storage system, the large capacity and high multiplying power of the system are important development trends in the future. The temperature has great influence on the performance and safety of the battery, such as capacity, power, safety and the like, so that the consistency of the battery is reduced, the uneven heat dissipation of the battery also causes overhigh local temperature and overlarge temperature difference in the module, the performance of a battery system is further influenced, the consistency of the battery is further influenced, and thermal runaway can be caused when the battery is serious, so that safety accidents such as fire and explosion are caused. The energy storage module generally adopts air cooling to dissipate heat electrically, natural air cooling is easy to cause the problem of uneven air quantity distribution, and after long-time use, the local temperature is too high, so that the electric temperature is unbalanced and scrapped.

Disclosure of Invention

The utility model aims to overcome the defects or problems in the prior art and provide a heat dissipation structure of an energy storage module and the energy storage module, wherein the air quantity of each electric component is basically balanced, and the temperature uniformity is good.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

according to the technical scheme, the heat dissipation structure of the energy storage module is used for dissipating heat of at least two electric units distributed along a first direction, an air passage extending along a second direction perpendicular to the first direction is formed between two adjacent electric units, each electric unit comprises a plurality of electric pieces distributed along the second direction, and a heat dissipation air passage extending along the first direction is formed between two adjacent electric pieces, and the heat dissipation structure is characterized by comprising a fixing module, wherein the fixing module is arranged at two ends of each electric unit along the second direction and is attached to two ends of each electric unit along the second direction; the box body is suitable for accommodating the electric units and the fixing modules, and side plates perpendicular to the first direction are respectively arranged on two sides of each electric unit along the first direction; a plurality of radiating hole groups are arranged on the side plate along the second direction, and the wind passing area of the radiating hole groups at two ends of each radiating hole group is larger than that of the radiating hole groups at the middle part; and the fan is arranged at one end of the box body along the second direction outside the fixed module, is opposite to the air passage and has an axis extending along the second direction.

Based on the first technical scheme, a second technical scheme is further provided, in the second technical scheme, the number of the radiating hole groups on each side plate is equal to the number of the radiating air channels of the single electric unit, and the radiating hole groups are opposite to the radiating air channels.

Based on the second technical scheme, still be equipped with the third technical scheme, in the third technical scheme, every louvre group includes a plurality of louvres of laying along the third direction of perpendicular to first direction and second direction, the louvre extends along the second direction.

Based on the third technical scheme, a fourth technical scheme is further provided, in the fourth technical scheme, the fixing module comprises fixing units with the same number as the electric units, and each fixing unit comprises two fixing plates respectively attached to two ends of the electric units along the second direction; the box is still arranged along the second direction and is parallel to each other and relative first end plate and second end plate, the fan is installed on first end plate, the second end plate is equipped with a plurality of through-air holes corresponding each fixed plate.

Based on the fourth technical scheme, a fifth technical scheme is further provided, in the fifth technical scheme, the fan is an exhaust fan; each radiating hole group sequentially forms a first radiating unit and a second radiating unit along a second direction, the first radiating unit comprises at least two radiating hole groups, the quantity of radiating holes of the radiating hole group which is closer to the second radiating unit is smaller, and the second radiating unit comprises at least two radiating hole groups, and the quantity of radiating holes of the radiating hole group which is closer to the first radiating unit is smaller.

Based on the fifth technical scheme, a sixth technical scheme is further provided, in the sixth technical scheme, each wind through hole is distributed along the first direction, and the number of the wind through holes at two ends of the second end plate along the first direction is larger than that of the wind through holes at the middle part; the wind passing hole extends along a third direction.

According to the seventh technical scheme, the energy storage module comprises the heat dissipation structure and a plurality of electrical units accommodated in the box body, wherein each electrical unit is arranged along a first direction, an air passage extending along a second direction perpendicular to the first direction is formed between two adjacent electrical units, each electrical unit comprises a plurality of electrical parts arranged along the second direction, and a heat dissipation air passage extending along the first direction is formed between two adjacent electrical parts.

Based on the technical scheme seven, a technical scheme eight is further arranged, and the technical scheme eight further comprises a binding belt; the fixing module comprises fixing units with the same number as the electric units, each fixing unit comprises two fixing plates respectively attached to two ends of the electric units along the second direction, and the binding belts encircle the electric units and the fixing plates at two ends of the electric units.

Based on the eighth technical scheme, a ninth technical scheme is further provided, in the ninth technical scheme, the energy storage module further comprises a first partition board parallel to the air passage and a second partition board perpendicular to the second direction; the box body further comprises a supporting plate for supporting the electric unit and the fixing module; the first separator connects two adjacent electrical units away from the surface of the support plate, and the second separator connects two adjacent electrical units toward the surface of the second end plate.

From the above description of the present utility model, compared with the prior art, the present utility model has the following advantages:

1. in the first technical scheme, as the two ends of each electric unit are attached to the fixing module, the electric parts at the two ends in the electric units are adjacent to one heat dissipation air duct, in the embodiment, the air passing area of the heat dissipation hole groups at the two ends in each heat dissipation hole group is larger than the air passing area of the heat dissipation hole groups at the middle part, so that the defect of insufficient air passing amount of the electric parts at the two ends is overcome, the air passing amount of each electric part is basically balanced, and the temperature uniformity of the electric parts is ensured; the two ends of the electric units can be prevented from being extruded and deformed by the fixing module, and the fixing module and each electric unit can be combined into a whole in practical application, so that the installation is facilitated.

2. In the second technical scheme, the number of the radiating hole groups on each side plate is equal to that of the radiating air channels of the single electric unit, and the radiating hole groups are opposite to the radiating air channels, so that the air flow is more facilitated, and the radiating efficiency is higher.

3. In the third technical scheme, each radiating hole group comprises a plurality of radiating holes distributed along the third direction perpendicular to the first direction and the second direction, so that the ventilation quantity is guaranteed, the side plates are provided with certain protection performance, the radiating holes extend along the second direction because the distance between the radiating air channels is generally smaller, the radiating holes extend along the third direction, the air inlet quantity of the radiating air channels can be guaranteed to be large, sundries are prevented from rushing into the radiating air channels, besides the radiating air channels are just opposite to the radiating air channels, the radiating holes can also just face the electric components to take away the heat of the electric components, and the radiating efficiency is high.

4. In the fourth technical scheme, the fixing module is arranged to enable the fixing unit and the electric unit to be combined into a whole in practical application, the fan is prevented from being shielded, and the fixing plate can prevent the electric parts at two ends from being deformed under pressure; the second end plate is provided with the wind through holes corresponding to the fixing plates, so that heat of electric parts far away from the fan can be timely dissipated, and the temperature uniformity is further improved.

5. In the fifth technical scheme, the induced draft fan drives cold air to flow into the heat dissipation air duct and the air passage from the air passing holes and the heat dissipation holes, the air passing quantity of the electric parts positioned in the middle of the electric unit is large, the heat dissipation efficiency is high, the number of the heat dissipation holes of the heat dissipation hole group which is closer to the second heat dissipation unit in the first heat dissipation unit is smaller, the number of the heat dissipation holes of the heat dissipation hole group which is closer to the first heat dissipation unit in the second heat dissipation unit is smaller, and the air passing quantity of each electric part in the electric unit can be balanced better, so that the temperature uniformity among the electric parts is improved.

6. In the sixth technical scheme, when the energy storage module is placed in the cabinet body, the air intake of the side edge of the energy storage module cannot meet the requirement, the number of the air through holes at the two ends of the second end plate along the first direction is larger than that of the air through holes at the middle part, and the air intake of the side plate can be supplemented, so that the heat dissipation efficiency is improved; the wind hole extends along the third direction, so that the wind supplementing effect is better, and the protection performance is good.

7. In a seventh technical scheme, the utility model also provides an energy storage module which has the same technical advantages as the technical scheme.

8. In the eighth technical scheme, the electric unit and the fixing unit can be combined into a whole by the ribbon, and the field installation or maintenance is facilitated.

9. In the ninth technical scheme, the arrangement of the first partition plate and the second partition plate enables the air passing channel to only be capable of entering air from the heat dissipation air channel, so that more cold air can take away heat of adjacent electric parts, and heat dissipation efficiency is higher.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required to be used in the description of the embodiments below are briefly introduced, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an energy storage module according to an embodiment of the utility model;

FIG. 2 is a schematic diagram of a second embodiment of an energy storage module;

FIG. 3 is a schematic diagram illustrating an internal structure of an energy storage module according to an embodiment of the present utility model;

fig. 4 is a schematic diagram of an internal schematic diagram of an energy storage module according to an embodiment of the utility model.

The main reference numerals illustrate:

an electrical unit 10; an electric component 11; an air passage 01; a heat radiation air duct 02; a fixing plate 21; a lifting hole 211; a case 30; a side plate 31; a heat radiation hole group 311; a heat radiation hole 3111; a first heat radiation unit 03; a second heat radiation unit 04; a first end plate 32; a second end plate 33; a wind passing hole 331; a support plate 34; a blower 40; a tie 50; a first separator 60; and a second separator 70.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It is to be understood that the described embodiments are preferred embodiments of the utility model and should not be taken as excluding other embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without creative efforts, are within the protection scope of the present utility model.

In the claims, specification and drawings hereof, unless explicitly defined otherwise, the terms "first," "second," or "third," etc. are used for distinguishing between different objects and not for describing a particular sequential order.

In the claims, specification and drawings of the present utility model, unless explicitly defined otherwise, references to orientation or positional relationship such as the terms "center", "lateral", "longitudinal", "horizontal", "vertical", "top", "bottom", "inner", "outer", "upper", "lower", "front", "rear", "left", "right", "clockwise", "counterclockwise", etc. are based on the orientation and positional relationship shown in the drawings and are merely for convenience of description and to simplify the description, and do not indicate or imply that the apparatus or element referred to must have a particular orientation or be constructed and operated in a particular orientation, nor should it be construed as limiting the particular scope of the utility model.

In the claims, specification and drawings of the present utility model, unless explicitly defined otherwise, the term "fixedly connected" or "fixedly connected" should be construed broadly, i.e. any connection between them without a displacement relationship or a relative rotation relationship, that is to say includes non-detachably fixedly connected, integrally connected and fixedly connected by other means or elements.

In the claims, specification and drawings of the present utility model, the terms "comprising," having, "and variations thereof as used herein, are intended to be" including but not limited to.

Referring to fig. 1-4, fig. 1-4 show an energy storage module, which includes a heat dissipation structure and a plurality of electrical units 10 accommodated in a box 30, wherein each electrical unit 10 is arranged along a first direction, an air passing channel 01 extending along a second direction perpendicular to the first direction is formed between two adjacent electrical units 10, each electrical unit 10 includes a plurality of electrical components 11 arranged along the second direction, a heat dissipation channel 02 extending along the first direction is formed between two adjacent electrical components 11, and in practical application, a supporting component can be placed between two adjacent electrical components 11 to prevent thermal expansion of the electrical components 11 to close the heat dissipation channel 02 after long-term use.

The heat dissipation structure is used for dissipating heat of each electrical unit 10, and in this embodiment, the number of electrical units 10 is two, but it should be understood that the number of electrical units 10 may be greater, and when the number of electrical units 10 is greater, the number of air passing channels 01 is also greater.

The heat dissipation structure includes a fixing module, a case 30, and a blower 40.

The fixing modules are arranged at two ends of each electrical unit 10 along the second direction and are attached to two ends of each electrical unit 10 along the second direction. In this embodiment, the fixing module includes fixing units equal in number to the electrical units 10, and each fixing unit includes two fixing plates 21 respectively attached to both ends of the electrical units 10 in the second direction. The fixing module is arranged such that the fixing unit and the electric unit 10 can be combined into a whole in practical application, and the fixing plates 21 can prevent the electric components 11 at two ends from being deformed by pressure, so that the fixing plates 21 at each end of each electric unit 10 are arranged at intervals, but it should be understood that the fixing module can also comprise only two fixing plates 21 in one piece. In this embodiment, the fixing plate 21 has a hollow structure, and the outer wall of the fixing plate may be provided with a hanging hole 211 for installation.

The box 30 is rectangular and is suitable for accommodating the electrical units 10 and the fixing modules, two sides of each electrical unit 10 along the first direction are respectively provided with a side plate 31 perpendicular to the first direction, the box 30 is also provided with a first end plate 32 and a second end plate 33 which are parallel and opposite to each other along the second direction, and the first end plate 32 and the second end plate 33 are also perpendicular to the second direction. In this embodiment, the width direction of the case 30 is a first direction, the length direction of the case 30 is a second direction, and the height direction of the case 30 is a third direction.

The side plates 31 are provided with the plurality of heat dissipation hole groups 311 along the second direction, and as the two ends of each electrical unit 10 are attached to the fixed modules, the electrical components 11 at the two ends of each electrical unit 10 are adjacent to one heat dissipation air duct 02, and in order to solve the difficulty, the air passing area of the heat dissipation hole groups 311 at the two ends of each heat dissipation hole group 311 is larger than the air passing area of the heat dissipation hole groups 311 at the middle part, so that the defect of insufficient air passing amount of the electrical components 11 at the two ends is overcome, and the air passing amount of each electrical component 11 is basically balanced, thereby ensuring the temperature uniformity of the electrical components 11.

The fan 40 is arranged at one end of the box 30 along the second direction outside the fixed module, which is opposite to the air duct 01, and the axis extends along the second direction, in this embodiment, the fan 40 is arranged on the first end plate 32, mainly embedded at the bottom end of the first end plate 32, and the fan 40 is an air draft fan 40, and in this embodiment, the number of fans 40 is one, but it should be understood that when the number of electrical units 10 is greater, the number of fans 40 should also be correspondingly increased, and the number of fans 40 is equal to the number of the air duct 01. Therefore, in the present embodiment, the second end plate 33 is provided with the air passing holes 331 corresponding to each fixing plate 21, so that the heat of the electric component 11 far from the fan 40 can be timely dissipated, and the temperature uniformity is further improved.

The number of the heat dissipation hole groups 311 on each side plate 31 is equal to the number of the heat dissipation air channels 02 of the single electric unit 10, and the heat dissipation hole groups 311 are opposite to the heat dissipation air channels 02, so that the air flow is more facilitated, and the heat dissipation efficiency is higher; each radiating hole group comprises a plurality of radiating holes 3111 which are distributed along a third direction perpendicular to the first direction and the second direction, the radiating holes 3111 extend along the second direction, ventilation quantity is guaranteed, the side plates 31 are enabled to have certain protection performance, because the space between the radiating air channels 02 is generally smaller, the radiating holes 3111 extend along the second direction, compared with the radiating holes 3111 which extend along the third direction, the air inlet quantity of the radiating air channels 02 can be guaranteed, sundries are prevented from rushing into the radiating air channels 02, besides the radiating air channels 02 are enabled to be opposite to the electric components 11, heat of the electric components 11 is taken away, and radiating efficiency is high.

The air draft fan 40 drives cold air to flow into the heat dissipation air duct 02 and the air passage 01 from the air passing holes 331 and the heat dissipation holes 3111, the air passing quantity of the electric parts 11 located in the middle of the electric unit 10 is large, and the heat dissipation efficiency is high.

When the energy storage module is placed in the cabinet body, the air intake of the side edge of the energy storage module cannot meet the requirement, in this embodiment, the air through holes 331 are arranged along the first direction, the number of the air through holes 331 at two ends of the second end plate 33 along the first direction is greater than the number of the air through holes 331 at the middle part, and the air intake of the side plate 31 can be supplemented, so that the heat dissipation efficiency is improved; the wind through hole 331 extends along the third direction, and the wind supplementing effect is better, and the protection is good.

In a specific implementation, the energy storage module further includes a ribbon 50, a first separator 60 and a second separator 70, the ribbon 50 surrounds the electrical unit 10 and the fixing plates 21 at two ends of the electrical unit 10, and the ribbon 50 can make the electrical unit 10 and the fixing units combined into a whole, which is more beneficial to field installation or maintenance; the first separator 60 is perpendicular to the third direction, and the second separator 70 is perpendicular to the second direction; the case 30 further includes a support plate 34 supporting the electrical unit 10 and the fixing module; the first partition plate 60 connects the surfaces of two adjacent electric units 10 facing away from the support plate 34, the second partition plate 70 connects the surfaces of two adjacent electric units 10 facing toward the second end plate 33, and the arrangement of the first partition plate 60 and the second partition plate 70 enables the air passing duct 01 to only be capable of taking in air from the cooling air duct 02, so that more cold air can take away heat of adjacent electric components 11, and the cooling efficiency is higher.

The foregoing description of the embodiments and description is presented to illustrate the scope of the utility model, but is not to be construed as limiting the scope of the utility model. Modifications, equivalents, and other improvements to the embodiments of the utility model or portions of the features disclosed herein, as may occur to persons skilled in the art upon use of the utility model or the teachings of the embodiments, are intended to be included within the scope of the utility model, as may be desired by persons skilled in the art from a logical analysis, reasoning, or limited testing, in combination with the common general knowledge and/or knowledge of the prior art.

Claims (9)

1. A heat dissipation structure of an energy storage module is used for dissipating heat of at least two electrical units (10) distributed along a first direction, an air passage (01) extending along a second direction perpendicular to the first direction is formed between two adjacent electrical units (10), the electrical units (10) comprise a plurality of electrical components (11) distributed along the second direction, and a heat dissipation air passage (02) extending along the first direction is formed between two adjacent electrical components (11), and is characterized in that the heat dissipation structure comprises

The fixing modules are arranged at two ends of each electric unit (10) along the second direction and are attached to two ends of each electric unit (10) along the second direction;

the box body (30) is suitable for accommodating the electric units (10) and the fixing modules, and side plates (31) perpendicular to the first direction are respectively arranged on two sides of each electric unit (10) along the first direction; a plurality of radiating hole groups (311) are arranged on the side plate (31) along the second direction, and the wind passing area of the radiating hole groups (311) positioned at two ends of each radiating hole group (311) is larger than that of the radiating hole groups (311) positioned in the middle; and

and the fan (40) is arranged at one end of the box body (30) along the second direction outside the fixed module, is opposite to the air passage (01) and has an axis extending along the second direction.

2. A heat dissipating structure of an energy storage module according to claim 1, wherein the number of heat dissipating hole groups (311) on each side plate (31) is equal to the number of heat dissipating air channels (02) of a single electric unit (10), said heat dissipating hole groups (311) being opposite to said heat dissipating air channels (02).

3. A heat dissipating structure of an energy storage module according to claim 2, wherein each heat dissipating hole group (311) comprises a plurality of heat dissipating holes (3111) arranged along a third direction perpendicular to the first direction and the second direction, the heat dissipating holes (3111) extending along the second direction.

4. A heat radiation structure of an energy storage module according to claim 3, characterized in that the fixing module comprises fixing units equal in number to the electric units (10), each fixing unit comprising two fixing plates (21) respectively attached to both ends of the electric units (10) in the second direction; the box body (30) is further provided with a first end plate (32) and a second end plate (33) which are parallel and opposite to each other along the second direction, the fan (40) is arranged on the first end plate (32), and the second end plate (33) is provided with a plurality of air passing holes (331) corresponding to each fixed plate (21).

5. A heat dissipating structure of an energy storage module according to claim 4, wherein said fan (40) is an air extraction fan (40); each radiating hole group (311) sequentially forms a first radiating unit (03) and a second radiating unit (04) along a second direction, the first radiating unit (03) comprises at least two radiating hole groups (311) and the smaller the number of radiating holes (3111) of the radiating hole group (311) close to the second radiating unit (04), and the second radiating unit (04) comprises at least two radiating hole groups (311) and the smaller the number of radiating holes (3111) of the radiating hole group (311) close to the first radiating unit (03).

6. A heat dissipation structure of an energy storage module as defined in claim 5, wherein the number of the air passing holes (331) at both ends of the second end plate (33) in the first direction is larger than the number of the air passing holes (331) at the middle part; the wind through hole (331) extends in a third direction.

7. An energy storage module, characterized by comprising the heat dissipation structure as claimed in any one of claims 1-6 and a plurality of electrical units (10) accommodated in a box body (30), wherein each electrical unit (10) is arranged along a first direction, an air passage (01) extending along a second direction perpendicular to the first direction is formed between two adjacent electrical units (10), the electrical units (10) comprise a plurality of electrical components (11) arranged along the second direction, and a heat dissipation air passage (02) extending along the first direction is formed between two adjacent electrical components (11).

8. An energy storage module as claimed in claim 7, further comprising a tie (50); the fixing module comprises fixing units which are equal to the electric units (10), each fixing unit comprises two fixing plates (21) which are respectively attached to two ends of the electric units (10) along the second direction, and the binding belts (50) encircle the electric units (10) and the fixing plates (21) at two ends of the electric units (10).

9. An energy storage module according to claim 8, further comprising a first partition (60) parallel to the through air duct (01) and a second partition (70) perpendicular to the second direction; the box body (30) further comprises a supporting plate (34) for supporting the electric unit (10) and the fixing module, the box body (30) is further provided with a first end plate (32) and a second end plate (33) which are parallel and opposite to each other along a second direction, the fan (40) is arranged on the first end plate (32), and the second end plate (33) is provided with a plurality of air passing holes (331) corresponding to each fixing plate (21); the first separator (60) connects two adjacent electrical units (10) facing away from the surface of the support plate (34), and the second separator (70) connects two adjacent electrical units (10) facing toward the surface of the second end plate (33).

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