CN206921972U - A kind of radiator structure, thermal management device of battery and automobile - Google Patents

Abstract

The utility model provides a kind of radiator structure, cell managing device and automobile.The radiator structure includes collecting plate and multiple heat pipes, the collecting plate includes integrally formed vertical plate and level board, the vertical plate includes first surface and the second surface relative with the first surface, the first surface of the vertical plate is towards the side of the battery, the level board is towards the lower surface of the battery, the collecting plate is provided with multiple grooves, and the groove has been embedded in the heat pipe.Multiple heat pipes are reasonably distributed with the collecting plate small volume and its surface, and the heat pipe can rapidly take away the heat of battery, so both reduced the space-consuming of radiator structure, and in turn ensure that the heat exchange efficiency of radiator structure.

Description

A kind of radiator structure, thermal management device of battery and automobile

Technical field

The utility model is related to field of automobile, and in particular to a kind of radiator structure, thermal management device of battery and Automobile.

Background technology

Lithium ion battery is often used as the electrokinetic cell of electric automobile, lithium ion battery optimum working temperature scope 20 ~ 40 DEG C, temperature is too low or too high unfavorable to electrokinetic cell.Therefore, be ensure electrokinetic cell performance play, extend cycle life, Security is improved, it is necessary to which thermal management device of battery reasonable in design, the device can radiate in high temperature to battery, in low temperature When battery is preheated and is incubated, and can be between balanced each battery cell the temperature difference, so as to lift the vehicle performance of electric automobile.

Prior art is controlled using air-cooled or water-cooling project to the operating temperature of battery mostly.Air-cooled scheme be with Air is medium, by way of free convection or forced convertion, realizes radiating or heating to battery.Air-cooled scheme advantage exists In it is simple in construction, cost is low, for ease of maintenaince, shortcoming is that taking up space for thermal management device of battery is big, noise is big, heat exchange efficiency Low, response time is slow, thermal field lack of homogeneity, and with the continuous increase of battery charging and discharging multiplying power, air-cooled scheme has been difficult to meet need Ask.The cold scheme of liquid is using liquid as medium, and by the arrangement pipeline between battery or setting water jacket or battery directly is immersed into liquid, Realize the radiating or heating to battery.The advantages of liquid cold scheme, is the compact-sized of thermal management device of battery, small volume, heat exchange Efficiency high, shortcoming are that cost is higher, not easy-maintaining, weight is larger, leakage risk be present.

Utility model content

The utility model is intended to one of technical problem at least solving in above-mentioned technology to a certain extent.Therefore, this reality It is to propose a kind of radiator structure with first new purpose, the radiator structure has heat exchange efficiency high, compact-sized and account for With space it is small the advantages of.Second purpose of the present utility model be to propose a kind of thermal management device of battery, and the device can controlled The operating temperature of battery pack processed is in the range of optimum working temperature, and has the advantages that heat exchange efficiency is high, compact-sized.This 3rd purpose of utility model is to provide a kind of automobile.

To achieve the above objectives, on the one hand the utility model provides a kind of radiator structure, and the radiator structure includes thermal-arrest Plate and multiple heat pipes, the collecting plate include integrally formed vertical plate and level board, the vertical plate include first surface and The second surface relative with the first surface, the first surface of the vertical plate are flat towards the side of the battery, the water 1 Plate face is provided with multiple grooves to the lower surface of the battery, the collecting plate, and the groove has been embedded in the heat pipe.

Preferably, the groove includes the first groove, the second groove and the 3rd groove, and the heat pipe is shaped as L-type and bag Include the first heat pipe and the second heat pipe；

First heat pipe includes the first vertical portion and first level portion, and second heat pipe includes the second vertical portion and the Two horizontal parts；

First groove is arranged on the first surface, and first vertical portion is embedded in first groove；

Second groove is arranged on the second surface, and second vertical portion is embedded in second groove；

3rd groove is arranged on the lower surface of the level board, and the first level portion and the second horizontal part are embedded In the 3rd groove.

Preferably, the 3rd groove is intervally arranged in the lower surface of the level board, accordingly, first groove It is intervally arranged with cross-sectional direction of second groove along the vertical plate.

Preferably, the collecting plate is additionally provided with multiple notch parts, and the notch part is arranged on the vertical plate and level board Junction, the notch part is correspondingly arranged with first chute, and first vertical portion passes through the notch part and insertion In first groove.

Preferably, the thickness of the collecting plate is 1-3mm.

Preferably, the heat pipe is welded in the groove.

Preferably, the heat pipe is bonded in the groove by heat conductive silica gel or heat-conducting resin.

The beneficial effect of radiator structure provided by the utility model is, although the collecting plate small volume, described But multiple heat pipes are reasonably distributed with collecting plate, the heat of battery can rapidly be taken away, so both reduced by the heat pipe The space-consuming of radiator structure, it in turn ensure that the heat exchange efficiency of radiator structure.

The utility model on the other hand a kind of thermal management device of battery is provided, it include it is multiple it is above-described any one Radiator structure, in addition to cooling and heating source with by multiple single battery groups into battery pack, each monocell is arranged in correspondence with There is the radiator structure, the cooling and heating source are arranged on the lower section of the battery pack.

Preferably, the tabular that is shaped as cooling down simultaneous heating source, it is described to cool down inside simultaneous heating source optionally Flowing has high-temp liquid or cryogenic liquid.

Preferably, heat-conduction insulation spacer, the heat-conduction insulation spacer are additionally provided between the integrated board and the monocell It is shaped as L-type.

Preferably, heat-conduction insulation spacer, the heat-conduction insulation spacer are additionally provided between the integrated board and the monocell Including vertical pad and leveling plates, the vertical pad is arranged between the side of the first surface and the monocell, The leveling plates are arranged between the upper surface of the level board and the lower surface of the monocell.

Thermal management device of battery provided by the utility model is by cooling down and heating source is heated or cold to battery pack But, to ensure that the operating temperature of battery pack is in the range of optimum working temperature, radiator structure can promote to cool down and heating source with Heat transfer process between battery, and radiator structure is compact-sized, occupies little space, and will not too greatly increase battery thermal management dress The overall volume and weight put.

The utility model also provides a kind of automobile, and it includes any one above-described thermal management device of battery.

Brief description of the drawings

Accompanying drawing is to be further understood for providing to of the present utility model, and a part for constitution instruction, and following Embodiment be used to explain the utility model together, but do not form to limitation of the present utility model.In the accompanying drawings：

Fig. 1 is the assembling explosive view of the thermal management device of battery described in the embodiment of the utility model one, and two are only provided in figure Individual monocell and two collecting plates are assembled as demonstrating；

Fig. 2 is the rear isometric view of the radiator structure described in the embodiment of the utility model one；

Fig. 3 is the isometric front view of the radiator structure described in the embodiment of the utility model one；

Fig. 4 is the sectional view of vertical plate in radiator structure described in the embodiment of the utility model one；

Fig. 5 is the sectional view of level board in radiator structure described in the embodiment of the utility model one；

Fig. 6 is the rear isometric view of collecting plate in the embodiment of the utility model one；

Fig. 7 is the isometric front view of collecting plate in the embodiment of the utility model one；

Fig. 8 is the structural representation of heat pipe described in the embodiment of the utility model one；

Fig. 9 is the top view of the thermal management device of battery described in the embodiment of the utility model one；

Figure 10 is the partial enlarged drawing in A portions in Fig. 9.

Drawing reference numeral explanation：

1- monocells；

2- coolings and heating source, 21- inlets, 22- liquid outlets；

3- collecting plates, 31- vertical plates, 311- first surfaces, 312- second surfaces, 32- level boards, 33- notch parts；

4- heat pipes, the heat pipes of 41- first, the vertical portions of 411- first, 412- first levels portion, the heat pipes of 42- second, 421- second Vertical portion, the horizontal parts of 422- second；

5- grooves, the grooves of 51- first, the grooves of 52- second, the grooves of 53- the 3rd；

6- heat-conduction insulation spacers, the vertical pads of 61-, 62- leveling plates；

100- thermal management device of batteries, 200- radiator structures.

Embodiment

Embodiment of the present utility model is described below in detail, the example of the embodiment is shown in the drawings.Below by The embodiment being described with reference to the drawings is exemplary, it is intended to for explaining the utility model, and it is not intended that new to this practicality The limitation of type.

In description of the present utility model, it is to be understood that term " longitudinal direction ", " transverse direction ", " thickness ", " on ", " under ", The orientation or position relationship of the instruction such as "front", "rear", "left", "right", " vertical ", " level " be based on orientation shown in the drawings or Position relationship, it is for only for ease of description the utility model and simplifies description, rather than indicates or imply signified device or member Part must have specific orientation, with specific azimuth configuration and operation, therefore it is not intended that to limitation of the present utility model.

In addition, term " first ", " second ", " the 3rd ", and it is not intended that instruction or imply relative importance or The implicit quantity for indicating indicated technical characteristic.Thus, " first " is defined, " second ", the feature of " the 3rd " can be expressed Or implicitly include at least one this feature.In description of the present utility model, " multiple " are meant that at least two, such as Two, three etc., unless otherwise specifically defined.

One embodiment of the present utility model provides a kind of radiator structure 200, with reference to Fig. 1-8, to radiator structure 200 are described in detail.

Radiator structure 200 includes collecting plate 3 and multiple heat pipes 4, in the present embodiment, as shown in Figure 6, Figure 7, collecting plate 3 L-type is shaped to, in order to ensure that its is compact-sized and reduce space-consuming, the thickness of collecting plate 3 is preferably 1-3mm.Collecting plate 3 includes Integrally formed vertical plate 31 and level board 32.Vertical plate 31 includes first surface 311 and relative with the first surface 311 Second surface 312.Battery corresponding to first surface 311 towards radiator structure 200, level board 32 are arranged on the lower end of the battery Face.

Collecting plate 3 is provided with multiple grooves 5 coordinated with heat pipe 4, and groove 5 includes the first groove 51, the and of the second groove 52 3rd groove 53.First groove 51 is arranged on first surface 311, and the second groove 52 is arranged on second surface 312, the 3rd groove 53 It is arranged on the lower surface of level board 32.

As shown in figure 8, heat pipe 4 is shaped as L-type, including the first heat pipe 41 and the second heat pipe 42, the first heat pipe 41 includes the One vertical portion 411 and first level portion 412, the second heat pipe 42 include the second vertical portion 421 and the second horizontal part 422.

As shown in Figure 2-5, the first vertical portion 411 is embedded in the first groove 51, and it is recessed that the second vertical portion 421 is embedded in second In groove 52, the horizontal part 422 of first level portion 412 and second is embedded in the 3rd groove 53.

It should be noted that the shape of the first heat pipe 41 and the second heat pipe 42 is roughly the same.In the present embodiment, the first water The end in flat portion 412 and the end of the second horizontal part 422 are concordant, and observe knowable to Fig. 2, Fig. 4, due to assembly relation, the first water The length in flat portion 412 can be shorter than the length of the second horizontal part 422.And in some other embodiment of the present utility model, first The heat pipe 42 of heat pipe 41 and second can be the identical heat pipe of shape and size.So the utility model not opposite heat tube 4 Size limits.

As shown in Figure 4, Figure 5, the 3rd groove 53 is evenly spaced the lower surface for being arranged in level board 32, accordingly, the The cross-sectional direction of one groove 51 and the second groove 52 along vertical plate 31 is evenly spaced arrangement.

As shown in Figure 6, Figure 7, collecting plate 3 is provided with multiple notch parts 33, and notch part 33 is arranged on vertical plate 31 and level The corner of the junction of plate 32, i.e. collecting plate 3, the set location of notch part 33 is corresponding with the first groove 51, in assembling the When one heat pipe 41 and collecting plate 3, the first vertical portion 411 may pass through notch part 33, then coordinate with the first groove 51.

Heat pipe 4 can be fixed on collecting plate 3 after being embedded in groove 5 by way of welding, and in addition, heat pipe 4 is embedded in recessed During groove 5, it can also be bonded in by heat conductive silica gel or heat-conducting resin on collecting plate 3.The material of collecting plate 3 can be heat conductivility Metal material or nylon, polyethylene, the polypropylene Polymer materials such as preferable copper, aluminium, steel.Metal material it is excellent Point is that heat conduction is good, is in light weight the advantages of high polymer material.If battery pack heat production is more, the optional metal material of material of collecting plate 3 Material；If battery pack heat production is less, the optional high polymer material of material of collecting plate 3.When collecting plate 3 is metal material, Ke Yitong Cross welding and heat pipe 4 is embedded in groove 5, heat pipe 4 can also be embedded in by groove 5 by heat conductive silica gel or heat-conducting resin；When collecting plate 3 For high polymer material when, heat pipe 4 can be embedded in by groove 5 by heat conductive silica gel or heat-conducting resin.

In the present embodiment, the turning of collecting plate 3 is a rounded corner, and similarly, the turning of heat pipe 4 is also that a circle falls Angle.As skilled person will appreciate that, the internal structure of heat pipe 4 is complicated, if when heat pipe 4 directly processes l-shaped, directly heat The turning of pipe 4 is squared up, so not only processing difficulties, but also can destroy the inside structure of heat pipe 4, influences the work of heat pipe 4 Make performance, therefore, in the present embodiment, for easy to process and guarantee heat pipe 4 performance, the turning of heat pipe 4 is shaped to one Rounded corner.In order to ensure the overall appearance effect of radiator structure 200, turning is set to rounded corner by collecting plate 3 as heat pipe 4, So setting can also avoid hurting user because the turning of collecting plate 3 is sharp in assembling.The size of rounded corner with The overall dimensions of radiator structure 200 are relevant, i.e., related to the size of the battery of the practical function of radiator structure 200, therefore, this implementation Example is not limited the size of rounded corner.

The beneficial effect for the radiator structure 200 that the present embodiment provides is, although the small volume of collecting plate 3, collecting plate 3 On multiple heat pipes 4 are but reasonably distributed with, heat pipe 4 can rapidly take away the heat of battery, so both reduce radiator structure 200 space-consuming, it in turn ensure that the heat exchange efficiency of radiator structure 200.

Second embodiment of the present utility model provides a kind of thermal management device of battery 100, and it is above-mentioned reality that it, which includes above-mentioned, Apply the radiator structure 200 described in example, in addition to cooling and heating source 2, the battery pack being made up of multiple monocells 1, multiple heat conduction Insulation spacer 6.

As shown in Fig. 1, Fig. 9, in the present embodiment, monocell 1 is shaped to approximately parallelepiped body, and neat arrangement In cooling and the top of heating source 2.Each monocell 1 is accordingly provided with collecting plate 3, i.e. each monocell 1 has corresponding thereto The collecting plate 3 answered, each collecting plate 3 have monocell 1 corresponding thereto.

As shown in figure 1, cooling and heating source 2 are arranged on the lower section of battery pack, cool down simultaneous heating source 2 is shaped as flat board Shape, optionally flowing has high-temp liquid or cryogenic liquid inside it.Cooling and heating source 2 are set to tabular and are advantageous to battery The placement of group.Cooling and heating source 2 work as battery pack to ensure that the operating temperature of battery pack is in the range of optimum working temperature During overheat, cooling down simultaneous heating source 2 and optionally flowing has cryogenic liquid, and battery pack is cooled down；It is cold when battery pack is subcooled Simultaneous heating source 2, which optionally flows, high-temp liquid, and battery pack is heated.Cooling and heating source 2 are provided with inlet 21 With liquid outlet 22, the high-temp liquid or cryogenic liquid are flowed into from inlet 21, flowed out from liquid outlet 22.

Heat-conduction insulation spacer 6 includes vertical pad 61 and leveling plates 62, and vertical pad 61 is arranged on the He of first surface 311 Between monocell 1 corresponding to collecting plate 3, leveling plates 62 be arranged on level board 32 upper surface and collecting plate 3 corresponding to single electricity Between the lower end in pond 1.In other words, an end face of vertical pad 61 can contact with first surface 311, vertical pad 61 it is another Individual end face can contact with monocell 1 corresponding to collecting plate 3, and the upper surface of leveling plates 62 can monocell 1 corresponding with collecting plate 3 Lower end in contact, the lower surface of leveling plates 62 and the upper surface of level board 32.

There is foregoing description to understand, heat-conduction insulation spacer 6 is also what is be correspondingly arranged with monocell 1, i.e., each monocell 1 has Its corresponding heat-conduction insulation spacer 6.

Observe Fig. 1 to understand, because collecting plate 3 is provided with rounded corner, therefore collecting plate 3 is directly and meeting if the cooperation of monocell 1 Gap be present, and heat-conduction insulation spacer 6 can also fill up the gap in addition to playing a part of insulation protection, ensure radiating The heat exchange property of structure 200.

And in some other embodiment of the present utility model, heat-conduction insulation spacer 6 can also be directly formed to L-type, in order to Ensure the stability coordinated, the shape of heat-conduction insulation spacer 6 can be adapted with collecting plate 3, monocell 1, i.e. heat-conduction insulation spacer 6 The shape of one side of close collecting plate 3 can be adapted with the shape of collecting plate 3, the close monocell 1 of heat-conduction insulation spacer 6 The shape of one side can be adapted with the shape of monocell 1.It is into two pieces compared to heat-conduction insulation spacer 6, heat conduction is exhausted Edge pad 6, which is directly formed to L-type, can realize the Fast Installation of thermal management device of battery 100, and the shape of heat-conduction insulation spacer 6 It can be adapted with collecting plate 3, monocell 1, can so make installation more firm.

As shown in Figure 9, Figure 10, when assembling whole thermal management device of battery 100, multiple monocells 1 are proper alignments, The second surface 312 of collecting plate 3 can be with adjacent single cells 1（It is not monocell 1 corresponding to collecting plate 3）A contacts side surfaces, In other words, collecting plate 3（Radiator structure 200）Not only heat exchange can be carried out with corresponding monocell, can also be with adjacent monocell Carry out heat exchange.

The thermal management device of battery 100 that the present embodiment provides by cool down and heating source 2 being heated to battery pack or Cooling, to ensure that the operating temperature of battery pack is in the range of optimum working temperature, radiator structure 200 can promote to cool down and heating Heat transfer process between source and battery, and radiator structure 200 is compact-sized, occupies little space, and will not too greatly increase battery The overall volume and weight of heat management device 100.

In some embodiments of the utility model, a kind of automobile is also provided, the automobile is included described in above-described embodiment Thermal management device of battery 100.

In the description of this specification, reference term " the present embodiment ", " preferred embodiment ", " some embodiments " etc. It is of the present utility model that description means that specific features, structure, material or the feature with reference to the embodiment or example description are contained in In at least one embodiment or example.In this manual, the schematic representation of above-mentioned term is necessarily directed to identical Embodiment or example.Moreover, specific features, structure, material or the feature of description can be in any one or more embodiments Or combined in an appropriate manner in example.In addition, in the case of not conflicting, those skilled in the art can say this Different embodiments or example and the feature of different embodiments or example described in bright book are combined and combined.

Although embodiment of the present utility model has been shown and described above, it is to be understood that above-described embodiment is Exemplary, it is impossible to it is interpreted as to limitation of the present utility model, one of ordinary skill in the art is in the scope of the utility model It is interior above-described embodiment to be changed, changed, replaced and modification.

Claims (12)

1. a kind of radiator structure, it is used to radiate to battery, it is characterised in that the radiator structure includes collecting plate and more Individual heat pipe, the collecting plate include integrally formed vertical plate and level board, the vertical plate include first surface and with it is described The relative second surface of first surface, the first surface of the vertical plate towards the side of the battery, the level board towards The lower surface of the battery, the collecting plate are provided with multiple grooves, and the groove has been embedded in the heat pipe.

2. radiator structure as claimed in claim 1, it is characterised in that the groove includes the first groove, the second groove and the Three grooves, the heat pipe are shaped as L-type and including the first heat pipes and the second heat pipe；

First heat pipe includes the first vertical portion and first level portion, and second heat pipe includes the second vertical portion and the second water Flat portion；

First groove is arranged on the first surface, and first vertical portion is embedded in first groove；

Second groove is arranged on the second surface, and second vertical portion is embedded in second groove；

3rd groove is arranged on the lower surface of the level board, and the first level portion and the second horizontal part are embedded in institute State in the 3rd groove.

3. radiator structure as claimed in claim 2, it is characterised in that the 3rd groove is intervally arranged in the level board Lower surface, accordingly, the cross-sectional direction of the first groove and the second groove along the vertical plate are intervally arranged.

4. radiator structure as claimed in claim 2, it is characterised in that the collecting plate is additionally provided with multiple notch parts, described to lack Oral area is arranged on the junction of the vertical plate and level board, and the notch part is correspondingly arranged with first groove, and described One vertical portion is through the notch part and is embedded in first groove.

5. radiator structure as claimed in claim 1, it is characterised in that the thickness of the collecting plate is 1-3mm.

6. radiator structure as claimed in claim 1, it is characterised in that the heat pipe is welded in the groove.

7. radiator structure as claimed in claim 1, it is characterised in that the heat pipe is bonded by heat conductive silica gel or heat-conducting resin In the groove.

8. a kind of thermal management device of battery, it is characterised in that it includes multiple radiatings as described in claim 1-7 any one Structure, in addition to cooling and heating source with by multiple single battery groups into battery pack, each monocell is arranged in correspondence with Radiator structure is stated, the cooling and heating source are arranged on the lower section of the battery pack.

9. thermal management device of battery as claimed in claim 8, it is characterised in that the simultaneous heating source of cooling is shaped as flat board Shape, it is described cooling and heating source inside optionally flowing have high-temp liquid or cryogenic liquid.

10. thermal management device of battery as claimed in claim 8, it is characterised in that between the collecting plate and the monocell also Provided with heat-conduction insulation spacer, the heat-conduction insulation spacer is shaped as L-type.

11. thermal management device of battery as claimed in claim 8, it is characterised in that between the collecting plate and the monocell also Provided with heat-conduction insulation spacer, the heat-conduction insulation spacer includes vertical pad and leveling plates, and the vertical pad is arranged on institute Between the side for stating first surface and the monocell, the leveling plates are arranged on the upper surface of the level board and the list Between the lower surface of battery.

12. a kind of automobile, it is characterised in that including the thermal management device of battery any one of claim 8-11.