CN206349471U - Distributed heat management system and battery - Google Patents

Abstract

The utility model provides a kind of distributed heat management system and battery, and the battery includes multiple battery modules, and the distributed heat management system includes multiple heat management devices, and the heat management device includes：It is arranged at the heat transfer component between two neighboring battery modules；The thermal control component being connected with the heat transfer component, the thermal control component controls the heat transfer component heating or cooled.By setting multiple heat management devices, each heat management device includes the heat transfer component being arranged between two neighboring battery modules, and the thermal control component being connected with the heat transfer component.The heat transfer component heating is controlled by the thermal control component or is cooled, to carry out temperature control to two neighboring battery modules.In this way, using the concentration temperature control that prior art is replaced by distributed heat management system, battery modules that can be more targetedly to different temperatures carry out more accurate temperature control.

Description

Distributed heat management system and battery

Technical field

The utility model is related to battery thermal management technical field, in particular to a kind of distributed heat management system and Battery.

Background technology

Battery modules are the critical components of electric automobile, directly affect electricity as the main energy-storage travelling wave tube on electric automobile The performance of electrical automobile.When vehicle is run under the different travel conditions of the checkers such as high speed, low speed, acceleration, deceleration, battery Module can be discharged with different multiplying, produced amount of heat with different heat speed, caused heat skewness.At this moment it is accomplished by Temperature control is carried out to battery modules by heat management system, so that the temperature of each battery modules is basically identical, each electricity is prevented Discharge condition of the pond module caused by temperature inequality differs, and causes battery modules reduced lifetime.

In the heat management system of prior art, the heat transfer component battery modules is entered by unified thermal source or low-temperature receiver Trip temperature is controlled.When the amount of battery modules is larger, each battery modules temperature of accurate management and control, temperature control can not be accomplished by being uniformly controlled Effect processed is not good.

Utility model content

In order to overcome above-mentioned deficiency of the prior art, the purpose of this utility model is to provide a kind of distributed heat management System, applied to battery modules, the distributed heat management system includes multiple heat management devices, the heat management device bag Include：

It is arranged at the heat transfer component between two neighboring battery modules；

The thermal control component being connected with the heat transfer component, the thermal control component controls the heat transfer component heating Or cooling.

Further, in above-mentioned distributed heat management system, the heat transfer component includes hollow heat-conducting plate and roundabout Be arranged at the liquid conduits in the hollow heat-conducting plate, the inlets of the liquid conduits and liquid outlet respectively with the thermal control Component is connected.

Further, in above-mentioned distributed heat management system, the heat transfer component include hollow heat-conducting plate, it is described in Multiple liquid dividing plates are provided with empty heat-conducting plate, the inner chamber of the hollow heat-conducting plate is divided into multiple liquid by the liquid dividing plate Passage, the multiple fluid passage makes liquid circuitous flow in the inner chamber of the hollow heat-conducting plate；The hollow heat-conducting plate Inlet is connected with the thermal control component respectively with liquid outlet.

Further, in above-mentioned distributed heat management system, the heat management device also includes：

The temperature acquisition component of the battery modules is arranged at, the temperature of the temperature acquisition component collection battery modules is simultaneously The thermal control component is sent to, so that thermal control component heat transfer group according to the temperature control of the battery modules Part heats up or cooled.

Further, in above-mentioned distributed heat management system, the heat pipe between two neighboring battery modules Managing device includes temperature acquisition component described at least two, and two temperature acquisition components gather the two neighboring electricity respectively The temperature of pond module is simultaneously sent to the thermal control component, makes the thermal control component according to the temperature of two battery modules obtained Average value is spent to control the heat transfer component heating or cool.

Further, in above-mentioned distributed heat management system, the thermal control component includes：

For the electric heating unit heated to the liquid in the liquid conduits；

For the heat-sink unit cooled down to the liquid in the liquid conduits；And

For the control list for according to the battery modules temperature of acquisition selecting that the heat transfer component is heated or cooled Member, described control unit is connected with the electric heating unit and heat-sink unit respectively.

Further, in above-mentioned distributed heat management system, the thermal control component includes：

Semiconductor for the liquid in the liquid conduits to be heated or cooled according to current direction, which is heated, to freeze Unit；And

It is connected with semiconductor heating refrigeration unit, for semiconductor described in the battery modules temperature control according to acquisition Heat the control unit of the current direction of refrigeration unit.

Another object of the present utility model is to provide a kind of distributed heat management system, described applied to battery modules Battery modules include multiple battery cells, and the distributed heat management system includes multiple heat management devices, the heat management Device includes：

It is arranged at the heat transfer component contacted in battery modules with the multiple battery cell；

The thermal control component being connected with the heat transfer component, the thermal control component controls the heat transfer component heating Or cooling.

Further, in above-mentioned distributed heat management system, the heat transfer component is arranged at the electricity including roundabout The liquid flat tube contacted in the module of pond with the multiple battery cell, the inlet of the liquid flat tube and liquid outlet respectively with institute State the connection of thermal control component.

Another object of the present utility model is to provide a kind of battery, and the battery includes multiple battery modules and this practicality The distributed heat management system of new offer.In terms of existing technologies, the utility model has the advantages that：

Distributed heat management system and battery that the utility model is provided, by setting multiple heat management devices, Mei Gesuo The heat transfer component that heat management device includes being arranged between two neighboring battery modules is stated, and is connected with the heat transfer component Thermal control component.The heat transfer component heating is controlled by the thermal control component or is cooled, with to two neighboring battery mould Group carries out temperature control.In this way, using the concentration temperature control that prior art is replaced by distributed heat management system, Ke Yigeng Targetedly the battery modules to different temperatures carry out more accurate temperature control.

Brief description of the drawings

In order to illustrate more clearly of the technical scheme of the utility model embodiment, it will use below required in embodiment Accompanying drawing be briefly described, it will be appreciated that the following drawings illustrate only some embodiments of the present utility model, therefore should not be by Regard the restriction to scope as, for those of ordinary skill in the art, on the premise of not paying creative work, may be used also To obtain other related accompanying drawings according to these accompanying drawings.

The distributed heat management system schematic diagram that Fig. 1 provides for the utility model first embodiment；

A kind of embodiment schematic diagram for the heat transfer component that Fig. 2 provides for the utility model first embodiment；

The another embodiment schematic diagram for the heat transfer component that Fig. 3 provides for the utility model first embodiment；

The temperature acquisition component diagram that Fig. 4 provides for the utility model first embodiment；

A kind of embodiment schematic diagram for the thermal control component that Fig. 5 provides for the utility model first embodiment；

The another embodiment schematic diagram for the thermal control component that Fig. 6 provides for the utility model first embodiment；

The centralized control apparatus schematic diagram that Fig. 7 provides for the utility model first embodiment；

The distributed heat management system schematic diagram that Fig. 8 provides for the utility model second embodiment；

The schematic diagram for the heat transfer component that Fig. 9 provides for the utility model second embodiment.

Icon：10- distributed heat management systems；100- heat management devices；110- heat transfer components；The hollow heat conduction of 111- Plate；112- liquid conduits；1121 (1141,1151)-inlets；1122 (1142,1152)-liquid outlets；113- liquid dividing plates； 114- fluid passages；115- liquid flat tubes；120- thermal control components；121- control units；122- electric heating units；123- radiatings are single Member；124- semiconductors heat refrigeration unit；130- temperature acquisition components；200- centralized control apparatuses；20- battery modules；201- Battery cell.

Embodiment

It is new below in conjunction with this practicality to make the purpose, technical scheme and advantage of the utility model embodiment clearer Accompanying drawing in type embodiment, the technical scheme in the utility model embodiment is clearly and completely described, it is clear that retouched The embodiment stated is a part of embodiment of the utility model, rather than whole embodiments.Generally here described in accompanying drawing and The component of the utility model embodiment shown can be arranged and designed with a variety of configurations.

Therefore, the detailed description of embodiment of the present utility model below to providing in the accompanying drawings is not intended to limit requirement The scope of the present utility model of protection, but it is merely representative of selected embodiment of the present utility model.Based in the utility model Embodiment, the every other embodiment that those of ordinary skill in the art are obtained under the premise of creative work is not made, all Belong to the scope of the utility model protection.

It should be noted that：Similar label and letter represents similar terms in following accompanying drawing, therefore, once a certain Xiang Yi It is defined in individual accompanying drawing, then it further need not be defined and explained in subsequent accompanying drawing.

, it is necessary to explanation in description of the present utility model, term " " center ", " on ", " under ", it is "left", "right", " perpendicular Directly ", the orientation or position relationship of the instruction such as " level ", " interior ", " outer " be based on orientation shown in the drawings or position relationship, or It is the orientation or position relationship usually put when the utility model product is used, is for only for ease of description the utility model and letter Change description, rather than indicate or imply signified device or element must have specific orientation, with specific azimuth configuration and Operation, therefore it is not intended that to limitation of the present utility model.

In description of the present utility model, in addition it is also necessary to which explanation, unless otherwise clearly defined and limited, term " are set Put ", " installation ", " connected ", " connection " should be interpreted broadly, for example, it may be fixedly connected or be detachably connected, Or be integrally connected；Can be mechanical connection or electrical connection；Can be joined directly together, intermediary can also be passed through It is indirectly connected to, can is the connection of two element internals.For the ordinary skill in the art, it can be managed with concrete condition Solve concrete meaning of the above-mentioned term in the utility model.

First embodiment

It refer to Fig. 1, a kind of distributed heat management system 10 that Fig. 1 provides for the present embodiment, applied to battery modules 20, The distributed heat management system 10 includes multiple heat management devices 100, and each heat management device 100 works independently, right Two neighboring battery modules 20 carry out temperature control.The heat management device 100 includes heat transfer component 110 and thermal control component 120。

The heat transfer component 110 is arranged between two neighboring battery modules 20.

The thermal control component 120 is connected with the heat transfer component 110, and the thermal control component 120 controls described Heat transfer component 110 heats up or cooled.

Specifically, in the present embodiment, the heat transfer component 110 carries out temperature by the heat-conducting liquid flowed wherein Degree transmission.In the present embodiment, the heat-conducting liquid can be water.

Fig. 2 is refer to, in an embodiment of the present embodiment, the heat transfer component 110 includes hollow heat-conducting plate 111 and the roundabout liquid conduits 112 being arranged in the hollow heat-conducting plate 111.The hollow heat-conducting plate 111 and two neighboring electricity Pond module 20 is fitted, to absorb the heat of the battery modules 20 or transfer heat to the battery modules 20.

The liquid conduits 112 include an inlet 1121 and a liquid outlet 1122, the inlet 1121 and liquid outlet 1122 are connected with the thermal control component 120 respectively.Heat-conducting liquid be heated or cooled by the thermal control component 120 after by entering The injection of liquid mouthfuls 1121 liquid conduits 112, heat-conducting liquid flows in the liquid conduits 112, by temperature pass to it is described in Empty heat-conducting plate 111.The heat-conducting liquid from the liquid outlet 1122 be back to the thermal control component 120 heated again or Cooling.

What deserves to be explained is, in this embodiment, Fig. 2 is only a kind of setting for liquid conduits 112 that present embodiment is provided Schematic diagram, the quantity and round about manner of the liquid conduits 112 are not limited in quantity and round about manner shown in Fig. 2, can be with The many liquid conduits 112 and different round about manners are set., can be by when being provided with many liquid conduits 112 The inlet 1121 of many liquid conduits 112 is arranged at diverse location with liquid outlet 1122, so that the different liquid are led Heat-conducting liquid flow direction in pipe 112 is different, reaches the effect of further equalization temperature.

Fig. 3 is refer to, in the another embodiment of the present embodiment, the heat transfer component 110 includes hollow heat conduction It is provided with multiple liquid dividing plates 113 in plate 111, the hollow heat-conducting plate 111, the liquid dividing plate 113 is by the hollow heat conduction The inner chamber of plate 111 is divided into multiple fluid passages 114, and the multiple fluid passage 114 makes liquid in the hollow heat-conducting plate 111 Inner chamber in circuitous flow.The hollow heat-conducting plate 111 is fitted with two neighboring battery modules 20, to absorb the battery modules 20 heat transfers heat to the battery modules 20.

The fluid passage 114 includes an inlet 1141 and a liquid outlet 1142, the inlet 1141 and liquid outlet 1142 are connected with the thermal control component 120 respectively.Heat-conducting liquid be heated or cooled by the thermal control component 120 after by entering The injection of liquid mouthfuls 1141 fluid passage 114, heat-conducting liquid flows in the fluid passage 114, by temperature pass to it is described in Empty heat-conducting plate 111.The heat-conducting liquid from the liquid outlet 1142 be back to the thermal control component 120 heated again or Cooling.

What deserves to be explained is, in this embodiment, Fig. 3 is only a kind of setting for fluid passage 114 that present embodiment is provided Schematic diagram, the quantity and round about manner of the fluid passage 114 are not limited in quantity and round about manner shown in Fig. 3, can be with Multiple fluid passages 114 and different round about manners are set., can be by when being provided with multiple fluid passages 114 The inlet 1141 of multiple fluid passages 114 is arranged at diverse location with liquid outlet 1142, so that the different liquid are logical Heat-conducting liquid flow direction in road 114 is different, reaches the effect of further equalization temperature.

In this way, when the temperature of battery modules 20 is too high, the heat transfer component 110 absorbs the heat of battery modules 20, And taken away heat by the heat-conducting liquid, make the cooling-down effect of battery modules 20 to reach.When the temperature of battery modules 20 When spending low, the heat transfer that the heat transfer component 110 brings the heat-conducting liquid gives the battery modules 20, to reach The effect for making the battery modules 20 heat up.

Further, the heat management device 100 also includes temperature acquisition component 130.

The temperature acquisition component 130 is arranged at the battery modules 20, and the temperature acquisition component 130 gathers battery mould The temperature of group 20 is simultaneously sent to the thermal control component 120, so that the thermal control component 120 is according to the battery modules 20 Heat transfer component 110 heats up or cooled described in temperature control.In the present embodiment, the temperature acquisition component 130 can include But it is not limited only to, thermoelectricity occasionally thermal resistance etc..

Further, Fig. 4 is refer to, due to a meeting of heat management device 100 two batteries adjacent to its Module 20 works, therefore in this implementation row, the heat management device 100 between two neighboring battery modules 20 includes Temperature acquisition component 130 described at least two.

Two temperature acquisition components 130 are respectively arranged at the two neighboring battery modules 20, for gathering respectively The temperature of the two neighboring battery modules 20 is simultaneously sent to the thermal control component 120, makes the basis of thermal control component 120 The temperature averages of two battery modules 20 obtained control the heat transfer component 110 to heat up or cool.

Referring once again to Fig. 4, in this implementation row, the heat management device 100 positioned at the side of single battery module 20 Including temperature acquisition component 130 at least one described, the temperature for only gathering a battery modules 20 is used as temperature controlled foundation.

In this way, the temperature for gathering each battery modules 20 by multiple heat management devices 100 is used as temperature controlled basis, Battery modules 20 that can be more accurately to different temperatures carry out temperature control.

In the present embodiment, the temperature information pair that the thermal control component 120 is gathered according to the temperature acquisition component 130 Heat-conducting liquid in the heat transfer component 110 is heated or cooled.

Specifically, when the battery temperature that the thermal control component 120 receives the acquisition of temperature acquisition component 130 is higher than During one first temperature threshold, cooling is taken to handle the battery modules 20；When the thermal control component 120 receives the temperature When the battery temperature for spending the acquisition of acquisition component 130 is less than a second temperature threshold value, heating treatment is taken to the battery modules 20. Wherein, first temperature threshold is higher than the second temperature threshold value.

Fig. 5 is refer to, in an embodiment of the present embodiment, the thermal control component 120 includes electric heating unit 122nd, heat-sink unit 123 and control unit 121.

Described control unit 121 is connected with the temperature acquisition component 130, and the temperature control unit 121 is used for basis The heat transfer component 110 is heated or cooled for the temperature of battery modules 20 selection of acquisition, and described control unit 121 is distinguished It is connected with the electric heating unit 122 and heat-sink unit 123.

The electric heating unit 122 is used to heat the liquid in the liquid conduits 112, the electric heating unit 122 Heating wire can be included.The heat-sink unit 123 is used for the heat-sink unit cooled down to the liquid in the liquid conduits 112 123。

Fig. 6 is refer to, in the another embodiment of the present embodiment, the thermal control component 120 includes control unit 121 and semiconductor heating refrigeration unit 124.

The semiconductor heating refrigeration unit 124 is connected with described control unit 121, for being produced according to control unit 121 Liquid in the liquid conduits 112 is heated or cooled raw current direction.

Described control unit 121 is connected with the temperature acquisition component 130, and the temperature control unit 121 is used for basis Semiconductor described in the temperature control of battery modules 20 of acquisition heats the current direction of refrigeration unit 124.In the present embodiment, it is described Semiconductor heating refrigeration unit 124 can include semiconductor chilling plate.

Further, Fig. 7 is refer to, in the present embodiment, the distributed heat management system 10 also includes Centralized Monitoring Device 200.

The centralized control apparatus 200 that the centralized control apparatus 200 is connected with each heat management device 100, it is described Centralized control apparatus 200 obtains the temperature for each battery modules 20 that multiple temperature acquisition components 130 are obtained, and according to each electricity The temperature of pond module 20 issues temperature adjustment signal to the thermal control component 120.

In the present embodiment, the centralized control apparatus 200 can be according to the temperature of each battery modules 20, current Travel conditions, ambient temperature or the electricity consumption situation of vehicle are carried out calculating optimal battery temperature scope, and temperature is issued according to result of calculation Degree adjustment signal changes first temperature threshold and second temperature threshold value of the heat management device 100.

In this way, using distributed heat management system, multiple heat management devices 100 are relatively independent to be operated, Mei Gere The one heat transfer component 110 of correspondence of control assembly 120, is solved in the case where battery modules 20 are excessive, single source or cold Source can not accomplish the defect of balanced temperature control to each battery modules 20.

Further, in the present embodiment, the centralized control apparatus 200 is additionally operable to be connected with a display device, will be each The temperature information of the battery modules 20 is sent to the display device and shown.

In this way, user can intuitively grasp the temperature conditions of each battery modules 20.

Second embodiment

Fig. 8 is refer to, the present embodiment provides a kind of distributed heat management system 10, applied to battery modules 20, the electricity Pond module 20 includes multiple battery cells 201, and the distributed heat management system 10 includes multiple heat management devices 100, institute Stating heat management device 100 includes heat transfer component 110 and thermal control component 120.

From unlike the set-up mode of the heat transfer component 110 described in first embodiment, in the present embodiment, the heat Transmitting assembly 110 is arranged in battery modules 20 to be contacted with the multiple battery cell 201.

Specifically, Fig. 9 is refer to, the heat transfer component 110 includes roundabout be arranged in the battery modules 20 and institute State the liquid flat tube 115 that multiple battery cells 201 are contacted, 1152 points of inlet 1151 and the liquid outlet of the liquid flat tube 115 It is not connected with the thermal control component 120.The liquid flat tube 115 into it is wavy in the battery modules 20 it is roundabout set, To increase the contact area of the liquid flat tube 115 and the battery cell 201, heat transfer effect in heating or cooling is improved Rate.

The thermal control component 120 is connected with the heat transfer component 110, and the thermal control component 120 controls the heat Transmitting assembly 110 heats up or cooled.

Specifically, the embodiment of the thermal control component 120 refer to institute in the utility model first embodiment The embodiment stated, will not be repeated here.

3rd embodiment

The present embodiment provides a kind of battery, the battery include multiple battery modules and the utility model first embodiment and The distributed heat management system that second embodiment is provided.

In summary, the utility model is provided distributed heat management system and battery, by setting multiple heat managements to fill 100 are put, each heat management device 100 includes the heat transfer component 110 being arranged between two neighboring battery modules 20, and The thermal control component 120 being connected with the heat transfer component 110.The heat transfer component is controlled by the thermal control component 120 110 heatings cool, to carry out temperature control to two neighboring battery modules 20.Pass through distributed heat management in this way, using System replaces the concentration temperature control of prior art, more targetedly the battery modules 20 of different temperatures can be carried out more smart True temperature control.

Preferred embodiment of the present utility model is the foregoing is only, the utility model is not limited to, for this For the technical staff in field, the utility model can have various modifications and variations.It is all it is of the present utility model spirit and principle Within, any modification, equivalent substitution and improvements made etc. should be included within protection domain of the present utility model.It should be noted that Arrive：Similar label and letter represents similar terms in following accompanying drawing, therefore, once determined in a certain Xiang Yi accompanying drawing Justice, then further need not be defined and be explained to it in subsequent accompanying drawing.

It is described above, embodiment only of the present utility model, but protection domain of the present utility model do not limit to In this, any one skilled in the art can readily occur in change in the technical scope that the utility model is disclosed Or replace, it should all cover within protection domain of the present utility model.Therefore, protection domain of the present utility model should be described with power The protection domain that profit is required is defined.

Claims (10)

1. a kind of distributed heat management system, applied to battery modules, it is characterised in that the distributed heat management system includes Multiple heat management devices, the heat management device includes：

It is arranged at the heat transfer component between two neighboring battery modules；

The thermal control component being connected with the heat transfer component, the thermal control component controls the heat transfer component heating or dropped Temperature.

2. distributed heat management system according to claim 1, it is characterised in that the heat transfer component includes hollow lead Hot plate and the roundabout liquid conduits being arranged in the hollow heat-conducting plate, the inlets of the liquid conduits and liquid outlet respectively with The thermal control component connection.

3. distributed heat management system according to claim 1, it is characterised in that the heat transfer component includes hollow lead Multiple liquid dividing plates are provided with hot plate, the hollow heat-conducting plate, the liquid dividing plate divides the inner chamber of the hollow heat-conducting plate Multiple fluid passages are segmented into, the multiple fluid passage makes liquid circuitous flow in the inner chamber of the hollow heat-conducting plate；It is described The inlet of hollow heat-conducting plate is connected with the thermal control component respectively with liquid outlet.

4. the distributed heat management system according to Claims 2 or 3, it is characterised in that the heat management device also includes：

It is arranged at the temperature acquisition component of the battery modules, the temperature of the temperature acquisition component collection battery modules and transmission To the thermal control component, so that thermal control component heat transfer component liter according to the temperature control of the battery modules Temperature or cooling.

5. distributed heat management system according to claim 4, it is characterised in that

The heat management device between two neighboring battery modules includes temperature acquisition component described at least two, two The temperature acquisition component gathers the temperature of the two neighboring battery modules and is sent to the thermal control component respectively, makes institute State thermal control component controls the heat transfer component to heat up or cool according to the temperature averages of two battery modules obtained.

6. distributed heat management system according to claim 4, it is characterised in that the thermal control component includes：

For the electric heating unit heated to the liquid in the liquid conduits；

For the heat-sink unit cooled down to the liquid in the liquid conduits；And

For the control unit for according to the battery modules temperature of acquisition selecting that the heat transfer component is heated or cooled, institute Control unit is stated to be connected with the electric heating unit and heat-sink unit respectively.

7. distributed heat management system according to claim 4, it is characterised in that the thermal control component includes：

Semiconductor for the liquid in the liquid conduits to be heated or cooled according to current direction heats refrigeration unit； And

It is connected, is heated for semiconductor described in the battery modules temperature control according to acquisition with semiconductor heating refrigeration unit The control unit of the current direction of refrigeration unit.

8. a kind of distributed heat management system, applied to battery modules, the battery modules include multiple battery cells, and it is special Levy and be, the distributed heat management system includes multiple heat management devices, the heat management device includes：

It is arranged at the heat transfer component contacted in battery modules with the multiple battery cell；

The thermal control component being connected with the heat transfer component, the thermal control component controls the heat transfer component heating or dropped Temperature.

9. distributed heat management system according to claim 8, it is characterised in that the heat transfer component includes roundabout set The liquid flat tube contacted in the battery modules with the multiple battery cell is placed in, the inlet of the liquid flat tube is with going out liquid Mouth is connected with the thermal control component respectively.

10. a kind of battery, it is characterised in that the battery includes any one institute in multiple battery modules and claim 1-9 The distributed heat management system stated.