CN206541888U - Battery modules - Google Patents
Battery modules Download PDFInfo
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- CN206541888U CN206541888U CN201720278833.3U CN201720278833U CN206541888U CN 206541888 U CN206541888 U CN 206541888U CN 201720278833 U CN201720278833 U CN 201720278833U CN 206541888 U CN206541888 U CN 206541888U
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- heat
- conducting
- thermosphere
- rigid
- battery modules
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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Abstract
The application is related to energy storage device technical field, more particularly to a kind of battery modules, it includes battery core, cooling structure, heat sink, elastic conducting thermosphere and rigid heat-conducting part, cooling structure has cooling duct, heat sink is in contact with battery core, elastic conducting thermosphere is in contact with cooling structure, and heat sink, elastic conducting thermosphere, cooling structure sequentially form heat-transfer path;Rigid heat-conducting part is arranged between heat sink and cooling structure, and at least a portion of rigid heat-conducting part is in contact with elastic conducting thermosphere, and in the assembling stroke of battery core, rigid heat-conducting part can be in contact with heat sink.In the assembling stroke of battery core, rigid heat-conducting part can be in contact with heat sink, the active force that heat sink applies to elastic conducting thermosphere can just be limited by the rigid heat-conducting part, so that the elastic conducting thermosphere is not easy excessive deformation occur during battery core is assembled, and then improving the heat-conducting effect of elastic conducting thermosphere so that the radiating effect of whole battery modules is more preferable.
Description
Technical field
The application is related to energy storage device technical field, more particularly to a kind of battery modules.
Background technology
The heat that battery modules are produced when working will produce large effect to the performance of battery, therefore in order to ensure battery
The performance of module, it usually needs radiator structure is set in battery modules, is shed the heat produced in battery modules with this,
Then object defined above is reached.
In a kind of conventional art, the battery core in cooled plate, battery modules can be set to be pasted with heat sink in battery modules
Together, the heat sink is contacted with cooled plate again.Cooling duct is formed in cooled plate, coolant circulates in cooled plate, so that it may
To take away the heat in battery modules.But in such a structure, effective contact area of heat sink and cooled plate than relatively limited, and
And cooled plate is easily extruded in assembling process, cause cooled plate severe crush to deform and heat conduction path can not be effectively formed, lead
Heat exchanger effectiveness between cause heat sink and cooled plate is relatively low, and radiating effect is bad.
In another conventional art, the heat sink added in battery modules in elastic conducting thermosphere, battery modules passes through this
Elastic conducting thermosphere is contacted with cooled plate, can be increased the heat exchange efficiency between heat sink and cooled plate by elastic conducting thermosphere, be entered
And lift the radiating effect of battery modules.However, during assembling battery modules, heat sink can apply active force to elastic conducting thermosphere,
Thickness will diminish after elastic conducting thermosphere is squeezed, and directly be contacted with cooled plate nearly equivalent to heat sink, cause battery modules
Radiating effect is poor.
Utility model content
This application provides a kind of battery modules, with this poor problem of the radiating effect for solving battery modules.
The battery modules that the application is provided include battery core, cooling structure, heat sink, elastic conducting thermosphere and rigid heat-conducting part,
The cooling structure has cooling duct, and the heat sink is in contact with the battery core, the elastic conducting thermosphere and the cooling
Structure is in contact, and the heat sink, the elastic conducting thermosphere, the cooling structure sequentially form heat-transfer path;
The rigid heat-conducting part is arranged between the heat sink and the cooling structure, and the rigid heat-conducting part is at least
It is a part of to be in contact with the elastic conducting thermosphere, in the assembling stroke of the battery core, the rigid heat-conducting part can with it is described
Heat sink is in contact.
Preferably, the rigid heat-conducting part is set to multiple, and each rigid heat-conducting part is both secured to the cooling structure
On, each rigid heat-conducting part is spaced, and is formed between the adjacent rigid heat-conducting part and is accommodated interval, the elastic heat conducting
Layer is arranged at described accommodate in interval.
Preferably, the rigid heat-conducting part is list structure, and the bearing of trend of each rigid heat-conducting part is parallel to each other.
Preferably, the width of the elastic conducting thermosphere is more than where the width of the rigid heat-conducting part, both width
Direction is the orientation of each rigid heat-conducting part.
Preferably, the thickness of the elastic conducting thermosphere in its natural state is less than the depth for accommodating interval, the bullet
Property heat-conducting layer thickness where direction, the direction where the depth at the receiving interval be the cooling structure point to it is described
The direction of battery core.
Preferably, the battery core is set to multiple, and at least a portion battery core is sequentially stacked along its thickness direction,
Each rigid heat-conducting part is arranged in order along the thickness direction, or each rigid heat-conducting part is along perpendicular to the thickness
The direction in degree direction is arranged in order.
Preferably, the heat sink includes body and bends the auxiliary section for the edge for being arranged at the body, described
Auxiliary section is arc auxiliary section, and the arc auxiliary section compresses cooperation with the elastic conducting thermosphere.
Preferably, the rigid heat-conducting part is heat-conducting plate, and the heat-conducting plate covering is arranged on the elastic conducting thermosphere, and
The heat-conducting plate is located between the heat sink and the elastic conducting thermosphere.
Preferably, the heat sink includes body and bends the auxiliary section for the edge for being arranged at the body, described
Auxiliary section is to have deep-slotted chip breaker towards the side of the arc auxiliary section on arc auxiliary section, the heat-conducting plate, and the arc is matched somebody with somebody
Conjunction portion is located in the deep-slotted chip breaker.
Preferably, the edge of the body has arc-shaped curvature portion, and the auxiliary section is connected with the arc-shaped curvature portion.
Preferably, the cooling structure includes setting cooling duct, institute described at least two in cooled plate, the cooled plate
Cooled plate is stated for U-board, each battery core is incorporated in the inside of the cooled plate.
The technical scheme that the application is provided can reach following beneficial effect:
Battery modules provided herein add rigid heat-conducting part, in the assembling stroke of battery core, rigid heat-conducting part
It can be in contact with heat sink, the active force that heat sink applies to elastic conducting thermosphere can just be limited by the rigid heat-conducting part,
So that the elastic conducting thermosphere is not easy occur excessive deformation during battery core is assembled, and then improve leading for elastic conducting thermosphere
Thermal effect so that the radiating effect of whole battery modules is more preferable.
It should be appreciated that the general description of the above and detailed description hereinafter are only exemplary, this can not be limited
Application.
Brief description of the drawings
A kind of part-structure schematic diagram for battery modules that Fig. 1 is provided by the embodiment of the present application;
Fig. 2 be Fig. 1 shown in battery modules in, the stacked schematic diagram of each battery core;
Fig. 3 is the explosive view of the battery modules shown in Fig. 1;
Fig. 4 is the sectional view of battery modules in one of the states shown in Fig. 1;
Fig. 5 is the sectional view of battery modules in another state shown in Fig. 1;
The part-structure explosive view for another battery modules that Fig. 6 is provided by the embodiment of the present application;
The part-structure explosive view for another battery modules that Fig. 7 is provided by the embodiment of the present application;
Fig. 8 is the sectional view of the battery modules shown in Fig. 7;
In the battery modules that Fig. 9 is provided by the embodiment of the present application, the partial schematic diagram of rigid heat-conducting part;
In the battery modules that Figure 10 is provided by the embodiment of the present application, the partial sectional view of heat sink.
Reference:
11- battery cores;
12- cooling structures;
120- cooling ducts;
13- heat sinks;
130- bodies;
130a- arc-shaped curvature portions;
131- auxiliary sections;
14- elastic conducting thermospheres;
15- rigidity heat-conducting parts;
150- deep-slotted chip breakers.
Accompanying drawing herein is merged in specification and constitutes the part of this specification, shows the implementation for meeting the application
Example, and be used to together with specification to explain the principle of the application.
Embodiment
The application is described in further detail below by specific embodiment and with reference to accompanying drawing.
As Figure 1-5, the embodiment of the present application provides a kind of battery modules, and the battery modules can be Soft Roll module,
It includes battery core 11, cooling structure 12, heat sink 13, elastic conducting thermosphere 14 and rigid heat-conducting part 15.Wherein:
Battery core 11 is usually arranged as multiple, and each battery core 11 can stack together along the thickness direction of itself, be carried with this
Rise the electric energy that battery modules can be provided.Specifically, all battery cores 11 in single battery module can be folded along a direction
Put, first can also stack together to form battery core group along the thickness direction of itself, then each battery core group is further along battery modules
Length direction arrangement, form the bigger battery modules of capacity.
Cooling structure 12 has cooling duct 120, and the cooling duct 120 is available for heat transferring medium to circulate, and then by battery mould
Heat in group is taken away.This heat transferring medium generally can be water.
Heat sink 13 is in contact with battery core 11, specifically, and heat sink 13 can be held between adjacent battery core 11, be
Prevent heat sink 13 from producing displacement relative to battery core 11, can be fixed to heat sink 13 and battery core 11 by way of bonding
Together.
Elastic conducting thermosphere 14 is in contact with cooling structure 12, and the elastic conducting thermosphere 14 both has certain capacity of heat transmission, again
It can deform, it can be specifically made of silica gel piece, now elastic conducting thermosphere 14 can be placed directly against cooling structure 12
On.
Above-mentioned heat sink 13, elastic conducting thermosphere 14, cooling structure 12 sequentially form heat-transfer path.That is, battery core 11
The heat of generation can be transferred to heat sink 13, and heat sink 13 transfers this heat to elastic conducting thermosphere 14, elastic conducting thermosphere 14
The heat transferring medium further transferred heat in cooling structure 12, cooling structure 12 can take away heat, and then cause electricity
The temperature of core 11 is kept in the reasonable scope.
Meanwhile, above-mentioned rigid heat-conducting part 15 can be made of rigid material, such as metal material so that rigid heat-conducting part
15 compared to the more difficult deformation of elastic conducting thermosphere 14.Rigid heat-conducting part 15 is arranged between heat sink 13 and cooling structure 12,
And at least a portion of rigid heat-conducting part 15 is in contact with elastic conducting thermosphere 14, in the assembling stroke of battery core 11, rigidly leads
Hot portion 15 can be in contact with heat sink 13.
Above-mentioned battery modules add rigid heat-conducting part 15, and this rigid heat-conducting part 15 has more compared to elastic conducting thermosphere 14
High intensity, in the assembling stroke of battery core 11, rigid heat-conducting part 15 can be in contact with heat sink 13 so that heat sink 13 with
Predeformation occurs after the rigid phase separation of heat-conducting part 15, and then heat sink 13 is limited to elastic conducting thermosphere by the rigid heat-conducting part 15
14 active forces applied so that the elastic conducting thermosphere 14 is not easy excessive deformation occur during battery core 11 is assembled, and enters
And improving the heat-conducting effect of elastic conducting thermosphere 14 so that the radiating effect of whole battery modules is more preferable.
In a kind of embodiment, rigid heat-conducting part 15 can be set to it is multiple, each rigid heat-conducting part 15 be both secured to cooling
In structure 12, each rigid heat-conducting part 15 is spaced, and is formed between adjacent rigid heat-conducting part and is accommodated interval, each elastic conducting thermosphere
14 are arranged in receiving interval.For example, rigid heat-conducting part 15 can be provided in multiple projections on cooling structure 12, work as elasticity
When heat-conducting layer 14 is assembled together with cooling structure 12, rigid heat-conducting part 15 can pass through elastic conducting thermosphere 14, and can be with dissipating
Hot plate 13 is contacted.
When assembling above-mentioned battery modules, elastic conducting thermosphere 14 is attached on cooling structure 12 first so that rigid heat conduction
Portion 15 can pass through elastic conducting thermosphere 14, then be assemblied together battery core 11 with heat sink 13, and the structure formed to both
Apply active force so that heat sink 13 is contacted with rigid heat-conducting part 15 first, and now heat sink 13 will deform, further to
The structure that battery core 11 and heat sink 13 are formed applies active force so that heat sink 13 slips over rigid heat-conducting part 15, and finally with
Elastic conducting thermosphere 14 is contacted, and now heat sink 13 can recover certain deformation so that heat sink and elastic conducting thermosphere 14 can be with
Fully contact, realizes the transmission of heat.Certainly, the assembling of battery core 11 is also not limited to such a order.
Certainly, rigid heat-conducting part 15 can also use list structure or other structures in addition to can be using projection,
When rigid heat-conducting part 15 is arranged to list structure, the bearing of trend of each rigid heat-conducting part 15 can be parallel to each other, elastic conducting
Thermosphere 14 is also set to multiple, and each elastic conducting thermosphere 14 is arranged at multiple receivings of each rigid heat-conducting part 15 formation correspondingly
In interval.In this embodiment, each rigid heat-conducting part 15 can be wholely set with cooling structure 12, and overall is in dentalation.In addition,
Can also on rigid heat-conducting part 15 rounding, to prevent from occurring in the disassembly process of battery modules the stress collection of heat sink 13
In and it is impaired the problem of.This measure can not only simplify the structure of rigid heat-conducting part 15, can also increase rigid heat-conducting part 15 with dissipating
Active area between hot plate 13, and then preferably show the active force that heat sink 13 applies to elastic conducting thermosphere 14;Also, it is each
The bearing of trend of rigid heat-conducting part 15 is parallel to each other, and can be distributed the heat in battery modules more uniform, prevent battery mould
Group is damaged because amount of localized heat is too high.
Further, the width of elastic conducting thermosphere 14 can be more than where the width of rigid heat-conducting part 15, both width
Direction be each rigid heat-conducting part 15 orientation.Elastic heat conducting layer 14 can be made in rigid heat-conducting part by adopting the structure
Bigger space is occupied in 15 orientation, the radiating formed after heat sink 13 is contacted with elastic conducting thermosphere 14 is increased with this
Area, and then optimize the radiating effect of battery modules.
Specifically, elastic conducting thermosphere 14 can protrude relative to rigid heat-conducting part 15, but such a structure can cause radiating
The active force that plate 13 applies to elastic conducting thermosphere 14 is larger.Therefore, in order to further prevent effect that elastic conducting thermosphere 14 is subject to
Power is excessive, can adopt the following technical scheme that:The thickness of elastic conducting thermosphere 14 in its natural state is less than above-mentioned receiving interval
Depth, the direction where direction, the depth at receiving interval where the thickness of elastic conducting thermosphere 14 herein is cooling structure
12 point to the direction of battery core 11.After being arranged such, heat sink 13 slips over rigid heat conduction first in the assembling process of battery modules
Portion 15, before heat sink 13 is completely disengaged from rigid heat-conducting part 15, heat sink 13 is not contacted with elastic conducting thermosphere 14 substantially, when
When heat sink 13 is completely disengaged from rigid heat-conducting part 15, heat sink 13 recovers deformation, is then contacted with elastic conducting thermosphere 14.It is aobvious
So, such a structure causes heat sink 13 to be contacted again with elastic conducting thermosphere 14 after recovering certain deformation, then reduces elastic heat conducting
The active force that layer 14 is subject to.
For the arrangement mode of each rigid heat-conducting part 15, the embodiment of the present application provides two kinds of forms:The first, each rigidity is led
Thickness direction of the hot portion 15 along battery core 11 is arranged in order, i.e., the structure shown in Fig. 3;Second, each rigid heat-conducting part 15 along
Direction perpendicular to the thickness direction of battery core 11 is arranged in order, i.e., the structure shown in Fig. 6.Both modes can simplify whole electricity
The structure of pond module.
Certainly, the arrangement mode of each rigid heat-conducting part 15 is not limited to the above two mode cited by the application.
As shown in Figure 10, in order to more greatly lift the radiating effects of battery modules, above-mentioned heat sink 13 can include
Body 130 and bending are arranged at the auxiliary section 131 of the edge of the body 130, and the auxiliary section 131 is arc auxiliary section, should
Arc auxiliary section compresses cooperation with elastic conducting thermosphere 14.Auxiliary section 131 is set to after arcuate structure, itself and elastic conducting thermosphere
14 contact is even closer so that heat transfer area between the two increased, and the deformability of the auxiliary section 131 also can
Make moderate progress so that the deformation of heat sink 13 is more stablized.
Further, the edge of above-mentioned body 130 can set arc-shaped curvature portion 130a, aforementioned cooperation portion and the arc
Shape bending section 130a is connected.After being arranged such, the deformability of body 130 is stronger, promotes heat sink 13 and elastic conducting thermosphere 14
Between contact it is even closer.
In another embodiment, as Figure 7-9, it is different from and is arranged at intervals each rigid heat-conducting part 15, can be by rigidity
Heat-conducting part 15 is set to integral structure.Specifically, rigid heat-conducting part 15 is heat-conducting plate, and heat-conducting plate covering is arranged at elastic conducting
On thermosphere 14 so that the big face of rigid heat-conducting part 15 is in contact with the big face of elastic conducting thermosphere 14, and heat-conducting plate is located at heat sink
Between 13 and elastic conducting thermosphere 14.Now, heat sink 13 is spaced apart by rigid heat-conducting part 15 with elastic conducting thermosphere 14, heat sink 13
Do not contacted directly with elastic conducting thermosphere 14, the heat transfer that heat sink 13 can produce battery core 11 gives rigid heat-conducting part 15, then
Elastic conducting thermosphere 14 and cooling structure 12 are passed to by rigid heat-conducting part 15 successively.This embodiment again may be by rigid heat conduction
The active force that the limitation heat sink 13 of portion 15 applies to elastic conducting thermosphere 14 so that elastic conducting thermosphere 14 is not easy to damage.And
And in this embodiment, the active area between rigid heat-conducting part 15 and elastic conducting thermosphere 14 is bigger, and heat-transfer effect is more preferable.
Further, as shown in Figure 10, above-mentioned heat sink 13 can include body 130 and bending is arranged at the body
The auxiliary section 131 of 130 edge, the auxiliary section 131 is the side towards the arc auxiliary section on arc auxiliary section, heat-conducting plate
With deep-slotted chip breaker 150, arc matching part is in the deep-slotted chip breaker 150.Because the deformability of rigid heat-conducting part 15 is smaller, therefore
Foregoing deep-slotted chip breaker 150 can be directly opened up on rigid heat-conducting part 15 so that heat sink 13 and rigid heat-conducting part 15 are more closely
Contact, and then make it that active area between the two is larger, improving radiating effect.
Further, the edge of above-mentioned body 130 can set arc-shaped curvature portion 130a, aforementioned cooperation portion and the arc
Shape bending section 130a is connected.After being arranged such, the deformability of body 130 is stronger, promotes heat sink 13 and elastic conducting thermosphere 14
Between contact it is even closer.
Alternatively, the cooling structure 12 that the embodiment of the present application is provided can specifically include setting in cooled plate, the cooled plate
At least two cooling ducts 120, this cooled plate is U-board, and each battery core 11 is incorporated in the inside of the cooled plate.That is, each battery core
11 can be assemblied in cooled plate from the open side of cooled plate, and now battery core 11 is water cooled three inwalls of plate and surrounded, and then
The radiating effect of the area of dissipation of cooled plate, further optimization battery modules.
The preferred embodiment of the application is the foregoing is only, the application is not limited to, for the skill of this area
For art personnel, the application can have various modifications and variations.It is all within spirit herein and principle, made any repair
Change, equivalent substitution, improvement etc., should be included within the protection domain of the application.
Claims (11)
1. a kind of battery modules, it is characterised in that including battery core, cooling structure, heat sink, elastic conducting thermosphere and rigid heat conduction
Portion, the cooling structure has cooling duct, and the heat sink is in contact with the battery core, the elastic conducting thermosphere with it is described cold
But structure is in contact, and the heat sink, the elastic conducting thermosphere, the cooling structure sequentially form heat-transfer path;
The rigid heat-conducting part is arranged between the heat sink and the cooling structure, at least one of the rigid heat-conducting part
Divide and be in contact with the elastic conducting thermosphere, in the assembling stroke of the battery core, the rigid heat-conducting part can be with the radiating
Plate is in contact.
2. battery modules according to claim 1, it is characterised in that the rigid heat-conducting part be set to it is multiple, it is each described
Rigid heat-conducting part is both secured on the cooling structure, and each rigid heat-conducting part is spaced, the adjacent rigid heat conduction
Formed between portion and accommodate interval, the elastic conducting thermosphere is arranged at described accommodate in interval.
3. battery modules according to claim 2, it is characterised in that the rigid heat-conducting part is list structure, each described
The bearing of trend of rigid heat-conducting part is parallel to each other.
4. battery modules according to claim 3, it is characterised in that the width of the elastic conducting thermosphere is more than the rigidity
The width of heat-conducting part, the direction where both width is the orientation of each rigid heat-conducting part.
5. battery modules according to claim 2, it is characterised in that the thickness of the elastic conducting thermosphere in its natural state
Less than the depth for accommodating interval, the depth place in direction, the receiving interval where the thickness of the elastic conducting thermosphere
Direction be direction that the cooling structure points to the battery core.
6. battery modules according to claim 2, it is characterised in that the battery core is set to multiple, at least a portion institute
State battery core to be sequentially stacked along its thickness direction, each rigid heat-conducting part is arranged in order along the thickness direction, or
Each rigid heat-conducting part is arranged in order along perpendicular to the direction of the thickness direction.
7. battery modules according to claim 2, it is characterised in that the heat sink includes body and bending is arranged at
The auxiliary section of the edge of the body, the auxiliary section is arc auxiliary section, the arc auxiliary section and the elastic heat conducting
Layer compresses cooperation.
8. battery modules according to claim 1, it is characterised in that the rigid heat-conducting part is heat-conducting plate, the heat conduction
Plate covering is arranged on the elastic conducting thermosphere, and the heat-conducting plate is located between the heat sink and the elastic conducting thermosphere.
9. battery modules according to claim 8, it is characterised in that the heat sink includes body and bending is arranged at
The auxiliary section of the edge of the body, the auxiliary section is towards arc cooperation on arc auxiliary section, the heat-conducting plate
The side in portion has deep-slotted chip breaker, and the arc matching part is in the deep-slotted chip breaker.
10. the battery modules according to claim 7 or 9, it is characterised in that the edge of the body has arc-shaped bend
Portion, the auxiliary section is connected with the arc-shaped curvature portion.
11. the battery modules according to any one of claim 1-9, it is characterised in that the cooling structure includes water cooling
Cooling duct described at least two is set in plate, the cooled plate, and the cooled plate is U-board, and each battery core is incorporated in
The inside of the cooled plate.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201720278833.3U CN206541888U (en) | 2017-03-21 | 2017-03-21 | Battery modules |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201720278833.3U CN206541888U (en) | 2017-03-21 | 2017-03-21 | Battery modules |
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Publication Number | Publication Date |
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CN206541888U true CN206541888U (en) | 2017-10-03 |
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ID=59943162
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CN201720278833.3U Active CN206541888U (en) | 2017-03-21 | 2017-03-21 | Battery modules |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107887670A (en) * | 2017-12-07 | 2018-04-06 | 江苏索尔新能源科技股份有限公司 | The radiator structure of battery component |
CN110197935A (en) * | 2018-02-27 | 2019-09-03 | 格朗吉斯铝业(上海)有限公司 | A kind of water-cooled plate for battery modules |
CN110277515A (en) * | 2018-03-16 | 2019-09-24 | 郑州深澜动力科技有限公司 | A kind of battery modules and its temperature control frame |
CN114361647A (en) * | 2021-12-31 | 2022-04-15 | 美的集团(上海)有限公司 | Battery pack |
-
2017
- 2017-03-21 CN CN201720278833.3U patent/CN206541888U/en active Active
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107887670A (en) * | 2017-12-07 | 2018-04-06 | 江苏索尔新能源科技股份有限公司 | The radiator structure of battery component |
CN110197935A (en) * | 2018-02-27 | 2019-09-03 | 格朗吉斯铝业(上海)有限公司 | A kind of water-cooled plate for battery modules |
CN110197935B (en) * | 2018-02-27 | 2021-11-12 | 格朗吉斯铝业(上海)有限公司 | Water cooling plate for battery module |
CN110277515A (en) * | 2018-03-16 | 2019-09-24 | 郑州深澜动力科技有限公司 | A kind of battery modules and its temperature control frame |
CN114361647A (en) * | 2021-12-31 | 2022-04-15 | 美的集团(上海)有限公司 | Battery pack |
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