WO2018107926A1 - Indirect-contact liquid cooling/heating device and method for power battery pack - Google Patents

Abstract

Disclosed in the present invention are an indirect-contact liquid cooling/heating device and an indirect-contact liquid cooling/heating method for a power battery pack. A heat conductive sheet is bonded between each two packs of battery modules. The two ends of the heat conductive sheet are respectively connected to a heat conductive support. The two ends of the heat conductive support are respectively connected to a heat conductive pipe, in which there is a circularly flowing liquid medium. The heat conductive pipe is in communication with the pipe of an external heat exchanger or evaporator. The heat conductive sheet absorbs the heat generated during the operation of the battery modules, and transfers the heat to the heat conductive pipe via the heat conductive support. The liquid medium circularly flowing within the heat conductive pipe takes away the heat transferred by the heat conductive support. The control of the temperature of the battery modules is achieved by means of changing the flow rate and temperature of the liquid medium within the heat conductive pipe. The device has a compact structure and is light in weight, and is easy to assemble. The heat conductive support, the heat conductive sheet and the heat conductive pipe can be assembled in advance. When a battery cell is added, and positioned by the heat conductive sheet and the heat conductive support, the battery electrodes can be connected in series or in parallel, thereby making them easier to install.

Description

Indirect contact liquid cooling/heating device and method for power battery Technical field

The present invention relates to a cooling/heating device for a power battery pack, and more particularly to a power battery pack indirect contact liquid cooling/heating device and method.

Background technique

Lithium-ion batteries have occupied the majority market share of electric vehicle battery batteries due to their high energy density and power density, large specific energy, long cycle life, high energy conversion rate, low self-discharge rate and no memory effect. However, the performance of lithium-ion batteries is greatly affected by temperature. Lithium-ion batteries accumulate a large amount of heat during operation due to internal resistance heat generation and polarization reactions, and heat is more likely to accumulate in a compactly placed vehicle environment. If the heat cannot be discharged in time, the temperature of the battery pack will rise sharply and the temperature difference between the battery cells will increase, which will lead to a decrease in the overall performance of the battery pack and a shortened service life, and may even cause the battery pack to run out of control. A serious security incident. Therefore, a good battery thermal management system largely affects the performance and cycle life of the single battery and the entire battery pack, and is important for ensuring the performance and safety of the battery pack.

At present, the thermal management methods and thermal management structures for vehicle batteries are endless, but most of the research and applications basically adopt air-cooled thermal management methods. Although the structure is simple and easy to implement, the cost is low, but the cooling effect is not good and the battery The uniformity of the package is poor. Compared with gas, liquid has higher heat capacity and thermal conductivity. Therefore, at the same volume and flow rate, the liquid cooling effect is significantly better than air, the battery temperature distribution is relatively uniform, and the liquid medium is also low when the battery temperature is low. It can heat the battery and has good two-way regulation, which is beneficial to the thermal management of the power battery pack. At present, the application of liquid heat transfer in electric vehicles is increasing. However, when using liquids, sealing, insulation, and Reliability, and cost, etc., because once the liquid leaks, it may cause a short circuit inside the battery, causing a serious safety accident.

Summary of the invention

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-discussed shortcomings and deficiencies of the prior art and to provide an indirect contact liquid cooling/heating apparatus and method for a power battery pack. On the basis of providing good cooling/heating to the battery pack, the problem that the liquid leakage easily occurs in the prior art and the internal short circuit of the battery pack is caused is solved.

The invention is achieved by the following technical solutions:

An indirect contact liquid cooling/heating device for a power battery pack, comprising a plurality of battery modules 4 distributed from a battery cell array, wherein each of the battery modules 4 is bonded with a heat conducting sheet 2, and the heat conducting sheet 2 The two ends are respectively connected with the heat conducting bracket 3, and the two ends of the heat conducting bracket 3 are respectively connected to the heat conducting pipe 1, and the heat conducting pipe 1 has a circulating liquid medium therein.

The heat conducting pipe 1 communicates with an external heat exchanger or an evaporator pipe. The heat conducting sheet 2 absorbs heat generated during the operation of the battery module 4 and is transmitted to the heat conducting pipe 1 through the heat conducting bracket 3; The circulating liquid medium carries away the heat transferred from the heat conducting bracket 3;

The temperature control of the battery module 4 is achieved by changing the flow rate and temperature of the liquid medium in the heat transfer conduit 1.

The longitudinal direction of the heat conducting bracket 3 is perpendicular to the axis of the heat conducting duct 1; the longitudinal direction of the heat conducting bracket 3 is perpendicular to the longitudinal direction of the heat conducting sheet 2.

The heat conducting insulating material is coated between the battery module 4 and the heat conducting sheet 2; the inner side of the heat conducting pipe 1 is a boss structure 11 , and the two ends of the heat conducting bracket 3 are respectively connected to the heat conducting pipe 1 through the boss structure 11 .

The liquid medium is water, heat transfer oil or water-ethylene glycol.

The heat conductive sheet 2 has a thickness of 0.3 mm to 1.5 mm and is made of metal aluminum or aluminum oxide; the heat conductive sheet 2 is designed to completely conform to the outer surface of the battery module, and the area is equal to or larger than the battery cell or the module. The area of the central heating area.

The joints of the two ends of the heat conducting sheet 2 and the heat conducting bracket 3 are bonded by welding or thermal conductive adhesive.

The joint between the two ends of the heat-conducting bracket 3 and the heat-conducting pipe 1 is bonded by welding or thermal conductive adhesive.

The cross-sectional shape of the heat transfer pipe 1 is rectangular or circular.

An indirect contact liquid cooling/heating method for a power battery pack, comprising the steps of:

Battery module cooling step

The two ports of the heat conducting pipe 1 are respectively connected in series with the pipes of the external evaporator, and when the temperature of the battery module is higher than the set value, the evaporator is started;

The heat conducting sheet 2 absorbs heat generated during the operation of the battery module 4, and is transmitted to the wall of the heat conducting pipe 5 through the heat conducting bracket 3; and then transferred to the cooled liquid medium circulating in the heat conducting pipe 5 by the pipe wall, and then The heat generated during the operation of the battery module 4 is taken away;

Battery module heating step

The two ports of the heat conducting pipe 1 are respectively connected in series with the pipes of the external heat exchanger, and when the temperature of the battery module is lower than the set value, the heat exchanger is started;

The heated liquid medium circulating in the heat conducting pipe 1 transfers heat to the heat conducting bracket 3 and the heat conducting sheet 2 through the pipe wall of the heat conducting pipe 1; the heat transfer piece 2 transfers heat to the battery cells in the battery module 4;

The temperature control of the battery module 4 is achieved by changing the flow rate and temperature of the liquid medium in the heat transfer conduit 1.

Compared with the prior art, the present invention has the following advantages and effects:

Each of the battery modules 4 of the present invention is bonded with a heat conducting sheet 2, and two ends of the heat conducting sheet 2 are respectively connected with the heat conducting bracket 3, and two ends of the heat conducting bracket 3 are respectively connected to the heat conducting pipe 1, and the heat conducting pipe 1 has a circulating liquid. medium. The heat conducting pipe 1 communicates with an external heat exchanger or a pipe of the evaporator, and the heat conducting sheet 2 absorbs heat generated during the operation of the battery module 4 and is transferred to the heat conducting through the heat conducting bracket 3. Pipe 1; the liquid medium circulating in the heat pipe 1 carries away the heat transferred from the heat conducting bracket 3; the temperature control of the battery module 4 is realized by changing the flow rate and temperature of the liquid medium in the heat conducting pipe 1. The invention realizes heat exchange of the battery module through the heat transfer function of the heat conduction pipeline, thereby avoiding direct contact between the liquid and the battery, and reducing the probability of occurrence of liquid leakage and causing internal short circuit of the battery.

The heat conduction pipe of the invention realizes the bidirectional temperature control of the battery module through the control of the valve, and realizes the bidirectional temperature control of the battery module, that is, when the temperature of the battery pack is overheated, the low temperature liquid cooled by the evaporator is used for the battery mode. The group performs cooling; when the temperature of the battery module is too cold, the battery module is heated by the high temperature liquid heated by the heat exchanger, and the temperature of the liquid can be controlled to achieve reasonable control of the temperature of the battery pack.

The heat conducting pipe of the heat conducting bracket of the invention is fixed to the heat conducting pipe which exchanges heat with the outside, and the middle part is fixed with the heat conducting piece, and the heat absorbed by the heat conducting piece is transmitted to the heat conducting pipe. The two sides of the heat-conducting sheet are directly fixed to the heat-conducting bracket, and the heat-conducting sheet is designed to completely conform to the outer surface of the battery, tightly wrapping the central heating area of the battery module, and quickly transferring the heat generated by the operation of the battery module to Thermal support bracket.

The heat conducting sheet, the heat conducting bracket and the heat conducting pipe of the invention are fixed to each other by welding or heat conducting insulating bonding material, thereby reducing the collision and slip between the battery cell and the heat conducting pipeline caused by the electric vehicle running, thereby improving the battery. The mechanical strength of the thermal management system.

The invention adopts the way that the heat conducting sheet, the heat conducting bracket and the heat conducting pipe are fixedly connected, the heat conducting component is closely attached to the central surface of the battery module, and the air between the battery module and the heat conducting pipeline is excluded as much as possible, so that the interface thermal resistance is greatly reduced To facilitate rapid heat exchange of the battery. At the same time, because the thermal conductive sheet is in close contact with the central area of the battery module and has a large contact area, and the high thermal conductivity of the thermal conductive sheet, the battery has a good heat dissipation effect, and also contributes to improving the overall uniformity of the temperature of the battery module.

The invention has compact structure, light weight and easy assembly. The heat-conducting bracket, the heat-conducting sheet and the heat-conducting tube can be assembled in advance. After the battery unit is added and positioned by the heat-conducting sheet and the heat-conducting bracket, the series-parallel connection between the battery electrodes can be performed, and the installation is very convenient.

As described above, the technical means of the present invention are simple and easy, and the heat exchange effect of the power battery pack is ensured. The direct contact between the liquid and the battery module is avoided, the probability of internal short circuit of the battery module due to liquid leakage is reduced, and the safety of the power battery is improved.

DRAWINGS

1 is a top plan view of an indirect contact liquid cooling/heating device for a power battery pack of the present invention.

Figure 2 is a side elevational view of Figure 1 (away from the middle of the battery).

detailed description

The present invention will be further described in detail below in conjunction with specific embodiments.

Example

As shown in Figure 1, 2. The invention discloses a power battery pack indirect contact liquid cooling/heating device, which comprises a plurality of battery modules 4 distributed by a battery cell array, and a heat conducting sheet 2 is adhered between each battery module 4, The two ends of the heat conducting sheet 2 are respectively connected with the heat conducting bracket 3, and the two ends of the heat conducting bracket 3 are respectively connected to the heat conducting pipe 1, and the heat conducting pipe 1 has a circulating liquid medium therein. The heat conducting pipe 1 can be made of a metal, aluminum, copper, iron or the like which is easy to process and has a high thermal conductivity material.

The heat conducting pipe 1 communicates with an external heat exchanger or an evaporator pipe. The heat conducting sheet 2 absorbs heat generated during the operation of the battery module 4 and is transmitted to the heat conducting pipe 1 through the heat conducting bracket 3; The circulating liquid medium takes away the heat transferred from the heat conducting bracket 3; thereby avoiding direct contact between the liquid medium and the battery cell, and reducing the probability of liquid leakage causing internal short circuit of the battery.

The temperature control of the battery module 4 is achieved by changing the flow rate and temperature of the liquid medium in the heat transfer conduit 1.

The longitudinal direction of the heat conducting bracket 3 is perpendicular to the axis of the heat conducting duct 1; the longitudinal direction of the heat conducting bracket 3 is perpendicular to the longitudinal direction of the heat conducting sheet 2. Of course, the specific layout can be determined according to the actual situation.

The thermal conductive adhesive is coated between the battery module 4 and the thermal conductive sheet 2. The thermal conductive adhesive can be made of polyurethane, silicone, epoxy resin and other bonding materials, and its thermal conductivity should be no less than 0.5W/mK to ensure its good thermal conductivity.

The inner side of the heat conducting pipe 1 is a boss structure 11 , and the two ends of the heat conducting bracket 3 are respectively connected to the heat conducting pipe 1 through the boss structure 11 .

The liquid medium is water, heat transfer oil or water-ethylene glycol.

The heat conductive sheet 2 has a thickness of 0.3 mm to 1.5 mm, a thermal conductivity of not less than 10 W/mK, and the material may be metal aluminum or aluminum oxide; the heat conductive sheet 2 completely conforms to the outer surface of the battery cell, and has a corresponding shape and area. It is equal to or larger than the area of the central heating area of the battery cell or battery module, and its surface can be subjected to appropriate surface treatment, such as passivation treatment, to have a certain electrical insulation strength. The joints of the two ends of the heat conducting sheet 2 and the heat conducting bracket 3 are bonded by welding or thermal conductive adhesive.

The heat-conducting bracket 3 can be the same material as the heat-conducting sheet 2, and has a flat shape with a thickness of 0.8 to 1.5 mm, and the height thereof can be specifically determined according to the overall height or thickness of the battery module 4.

The joint between the two ends of the heat-conducting bracket 3 and the heat-conducting pipe 1 is bonded by welding or thermal conductive adhesive.

The cross-sectional shape of the heat conducting pipe 1 is rectangular or circular. Of course, the shape and size thereof can be designed according to the power level of the battery module and the heat dissipation requirement.

The indirect contact liquid cooling/heating method of the power battery of the present invention can be realized by the following steps:

The battery module cooling step: connecting the two ports of the heat conduction pipe 1 to the external evaporator pipe, and when the battery module temperature is too high, starting the evaporator;

The heat conducting sheet 2 absorbs heat generated during the operation of the battery module 4, and is transmitted to the wall of the heat conducting pipe 5 through the heat conducting bracket 3; and then transferred to the cooled liquid medium circulating in the heat conducting pipe 5 by the pipe wall, and then The heat generated during the operation of the battery module 4 is taken away;

The heating step of the battery module: the two ports of the heat conducting pipe 1 are respectively connected in series with the pipes of the external heat exchanger, and when the temperature of the battery module is too low, the heat exchanger is started;

The heated liquid medium circulating in the heat conducting pipe 1 transfers heat to the heat conducting bracket 3 and the heat conducting sheet 2 through the pipe wall of the heat conducting pipe 1; the heat transfer piece 2 transfers heat to the battery cells in the battery module 4;

By changing the flow rate and temperature of the liquid medium in the heat conduction pipe 1, the battery module 4 is realized. temperature control.

As described above, the present invention can be preferably implemented.

The embodiments of the present invention are not limited to the above-described embodiments, and any other changes, modifications, substitutions, combinations, and simplifications that are made without departing from the spirit and scope of the present invention should be equivalent. Within the scope of protection of the present invention.

Claims (10)

1. An indirect contact liquid cooling/heating device for a power battery pack, comprising: a plurality of battery modules (4) distributed from a battery cell array, each battery module (4) being laminated The heat conducting sheet (2), the two ends of the heat conducting sheet (2) are respectively connected with the heat conducting bracket (3), and the two ends of the heat conducting bracket (3) are respectively connected with the heat conducting pipe (1), and the heat conducting pipe (1) has a circulating flowing liquid medium. .
2. The indirect contact liquid cooling/heating device for a power battery according to claim 1, wherein the heat conducting pipe (1) communicates with an external heat exchanger or an evaporator pipe, and the heat conducting sheet (2) absorbs The heat generated during the operation of the battery module (4) is transmitted to the heat conducting pipe (1) through the heat conducting bracket (3); the liquid medium circulating in the heat conducting pipe (1) carries away the heat transferred from the heat conducting bracket (3) ;

   The temperature control of the battery module (4) is achieved by changing the flow rate and temperature of the liquid medium in the heat transfer pipe (1).
3. The indirect contact liquid cooling/heating device for a power battery pack according to claim 1, wherein a length direction of said heat conducting bracket (3) is perpendicular to an axis of said heat conducting conduit (1); and a length direction of said heat conducting bracket (3) It is perpendicular to the longitudinal direction of the thermal pad (2).
4. The indirect contact liquid cooling/heating device for a power battery pack according to any one of claims 1 to 3, characterized in that the battery module (4) and the heat conducting sheet (2) are coated with a heat conductive insulating rubber. The inner side of the heat conducting pipe (1) is a boss structure (11), and two ends of the heat conducting bracket (3) are respectively connected to the heat conducting pipe (1) through the boss structure (11).
5. The indirect contact liquid cooling/heating device for a power battery pack according to claim 4, wherein the liquid medium is water, heat transfer oil or water-glycol.
6. The indirect contact liquid cooling/heating device for a power battery pack according to claim 4, wherein the heat conductive sheet (2) has a thickness of 0.3 mm to 1.5 mm and is made of metal aluminum or aluminum oxide; The area of the battery is equal to or larger than the area of the central heating area of the battery cell or battery module (4).
7. The indirect contact liquid cooling/heating device for a power battery pack according to claim 4, characterized in that the joint between the two ends of the heat conducting sheet (2) and the heat conducting bracket (3) is bonded by welding or thermal conductive adhesive. .
8. The indirect contact liquid cooling/heating device for a power battery pack according to claim 4, characterized in that the joint between the two ends of the heat conducting bracket (3) and the heat conducting pipe (1) is bonded by welding or thermal conductive adhesive. .
9. The indirect contact liquid cooling/heating device for a power battery pack according to claim 4, characterized in that the heat transfer duct (1) has a rectangular or circular cross section.
10. A power battery indirect contact liquid cooling/heating method, characterized by using the power battery indirect contact liquid cooling/heating device according to any one of claims 1 to 9, comprising the steps of:

    Battery module cooling step

    The two ports of the heat conducting pipe (1) are respectively connected in series with the pipes of the external evaporator, and when the temperature of the battery module (4) is higher than the set value, the evaporator is started;

    The heat conducting sheet (2) absorbs heat generated during the operation of the battery module (4), and is transmitted to the pipe wall of the heat conducting pipe 5 through the heat conducting bracket (3); and then is cooled by the pipe wall to the circulating flow in the heat conducting pipe 5. Liquid medium, which in turn removes heat generated during operation of the battery module (4);

    Battery module heating step

    The two ports of the heat conducting pipe (1) are respectively connected in series with the pipes of the external heat exchanger, and when the temperature of the battery module (4) is lower than the set value, the heat exchanger is started;

    The heated liquid medium circulating in the heat conducting pipe (1) transfers heat to the heat conducting bracket (3) and the heat conducting sheet (2) through the pipe wall of the heat conducting pipe (1); the heat is transmitted by the heat conducting piece (2) a battery cell in the battery module (4);

    The temperature control of the battery module (4) is achieved by changing the flow rate and temperature of the liquid medium in the heat transfer pipe (1).

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