CN100449861C - Secondary battery module - Google Patents

Secondary battery module Download PDF

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Publication number
CN100449861C
CN100449861C CNB2005101268206A CN200510126820A CN100449861C CN 100449861 C CN100449861 C CN 100449861C CN B2005101268206 A CNB2005101268206 A CN B2005101268206A CN 200510126820 A CN200510126820 A CN 200510126820A CN 100449861 C CN100449861 C CN 100449861C
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CN
China
Prior art keywords
heat
conduction medium
battery module
distribution plate
secondary battery
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Expired - Fee Related
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CNB2005101268206A
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Chinese (zh)
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CN1783576A (en
Inventor
李建求
全伦哲
金泰容
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Samsung SDI Co Ltd
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Samsung SDI Co Ltd
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Publication of CN1783576A publication Critical patent/CN1783576A/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/65Means for temperature control structurally associated with the cells
    • H01M10/655Solid structures for heat exchange or heat conduction
    • H01M10/6556Solid parts with flow channel passages or pipes for heat exchange
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/62Heating or cooling; Temperature control specially adapted for specific applications
    • H01M10/625Vehicles
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/60Heating or cooling; Temperature control
    • H01M10/65Means for temperature control structurally associated with the cells
    • H01M10/656Means for temperature control structurally associated with the cells characterised by the type of heat-exchange fluid
    • H01M10/6561Gases
    • H01M10/6562Gases with free flow by convection only
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/20Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
    • H01M50/233Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders characterised by physical properties of casings or racks, e.g. dimensions
    • H01M50/24Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders characterised by physical properties of casings or racks, e.g. dimensions adapted for protecting batteries from their environment, e.g. from corrosion
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M2220/00Batteries for particular applications
    • H01M2220/20Batteries in motive systems, e.g. vehicle, ship, plane
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • General Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Secondary Cells (AREA)
  • Battery Mounting, Suspending (AREA)

Abstract

A secondary battery module includes a unit battery pack having a plurality of unit batteries arranged at predetermined intervals, and a housing having the unit battery pack disposed in the housing. A heat transfer medium for controlling temperature of the plurality of unit batteries circulates in the housing. A first dispersion plate is fixedly disposed in the housing so as to be adjacent to the unit battery pack, and distributes the heat transfer medium between the plurality of unit batteries. A second dispersion plate is slidably disposed on the first dispersion plate, and distributes the heat transfer medium between the plurality of unit batteries.

Description

Secondary battery module
Technical field
The present invention relates to a kind of secondary battery module, especially relate to a kind of cooling structure of the secondary battery module that constitutes to connect a plurality of element cells.
Background technology
Usually, different with non-rechargeabel primary cell, secondary cell can charge and discharge.The low capacity secondary cell of being made up of single battery is generally as various portable small-sized electronic installations, as the power supply of portable phone, notebook computer and field camera.Be interconnected on big capacity secondary battery in the encapsulating structure by the polylith battery, generally as the motor driven power supply of hybrid electric vehicle (HEV).
Secondary cell can be made into different shape.Usually,, secondary cell can be divided into cylindrical battery or prismatic battery according to the external shape of battery.
Constitute jumbo secondary cell by this secondary cell of connecting, general as driving the engine power supply that needs powerful equipment such as motor vehicle.
Like this, a jumbo secondary cell (following be called for short in this article " battery module ") is made of a plurality of normally secondary cells of series connection (following be called for short in this article " element cell ")
Each element cell comprises an electrode assemblie that has positive electrode, negative electrode and be inserted in the isolator between them, one has the casing that holds described electrode assemblie space, one combine with casing and with the cap assembly of its sealing and from cap assembly protrude upward and with electrode assemblie positive collector electrode (collector) and negative the collector electrode positive pole and the negative terminal that are electrically connected.
When with prismatic battery during as element cell, for constituting battery module, this element cell all is arranged alternate usually, and anodal and negative terminal links together by the mode of connecting, thereby the positive pole, the negative terminal that protrude upward from cap assembly are replaced with respect to the positive pole and the negative terminal of another element cell that is adjacent.
A battery module comprises a plurality of element cells.Therefore, making heat that each element cell produces be easy to distribute is an important problems.Especially, when described secondary cell is when being used for hybrid electric vehicle, important problem will at first satisfy these conditions exactly.
In addition, heat can not effectively distribute as described, and the heat that each element cell produced can cause the increase in temperature of whole secondary battery module, and this device that will cause the use secondary battery module breaks down.
Especially, when using HEV (hybrid electric vehicle) battery module on vehicle, battery module is with large current charge or discharge.For this reason, depend on how secondary cell uses, heat can produce by the internal-response of secondary cell, and this can damage the performance of battery.
Therefore, when a battery module comprises a plurality of secondary cell, especially when battery module comprises prismatic secondary cell, often placing a battery barrier ribs between the element cell usually with the space between the holding unit battery.The purpose that this space is set is that heat-conduction medium can be flowed between element cell.In addition, these element cells are in a housing inboard, and the heat-conduction medium of control unit battery temperature is set in this housing thus.Thereby the heat that each element cell produced can be cooled off by heat-conduction medium is flowed through the battery barrier ribs.
Yet in this traditional cooling means, the amount of flow of its heat-conduction medium can not keep stable owing to the going into flow structure of heat-conduction medium in the housing.This is that the flox condition of drive condition, heat-conduction medium owing to battery module and the weather conditions that produce variations in temperature between each element cell cause.Because the heat that each element cell produced can not distribute equably, cause the reduction of charging and discharging efficiency then.
In addition, in this traditional cooling means, because the heat-conduction medium flow of the circulation of the barrier ribs between each element cell can not keep constant, so between each element cell, can produce variation of temperature.Because the heat that is produced between each element cell can not distribute equably, thereby cause the reduction of charging and discharging efficiency.
Summary of the invention
Therefore, various embodiment of the present invention are devoted to address the above problem always, and a kind of heat-conduction medium secondary battery module of structure of circulation reposefully between battery that can make constant basis that has is provided.
Press one aspect of the present invention, secondary battery module comprises a cell group and the housing that described cell group wherein is set with a plurality of element cells, and described a plurality of element cells are provided with predetermined interval each other.The heat-conduction medium that is used for controlling the temperature of a plurality of element cells flows at housing.Flow controlling unit is controlled at the flow of the heat-conduction medium that circulates between the respective battery and is arranged in the housing.
In the battery module aspect this according to the present invention, cell group comprises units corresponding battery battery barrier ribs separated from one another and the circulating path for forming in described barrier ribs by heat-conduction medium.
The battery module of this aspect comprises a flow controlling unit according to the present invention, and this flow controlling unit is made by plate, and has spray orifice, and wherein the size of spray orifice increases gradually along the direction of mind-set housing periphery from housing.
In addition, in the battery module aspect this according to the present invention, can be by the size of adjusting spray orifice, the heat-conduction medium of constant basis is infeeded in the circulating path between each element cell.
In addition, according to a further aspect in the invention, secondary battery module comprises a cell group and the housing that cell group is set with a plurality of element cells of arranging with predetermined space within it.The heat-conduction medium that is used to control the temperature of corresponding units battery circulates in housing.First distribution plate is placed in the described housing regularly with adjacent with cell group, and this first distribution plate distributes heat-conduction medium between the units corresponding battery.Second distribution plate that is slidably mounted on first distribution plate distributes heat-conduction medium between the units corresponding battery.
Described housing further comprises: the part that becomes a mandarin, and it makes heat-conduction medium longshore current Inbound flow to cell group; With one go out to flow part, being used for will be by the heat-conduction medium discharge of corresponding units battery along discharging direction.The inflow direction of described heat-conduction medium is consistent with the discharge direction of heat-conduction medium.
In another aspect of this invention, the described part that becomes a mandarin forms and makes the sectional area of heat-conduction medium stream increase gradually towards described cell group.The flowing velocity that flows through the described heat-conduction medium of the part that becomes a mandarin reduces on the direction of cell group periphery gradually at the core from cell group.
In addition, in the battery module according to one aspect of the invention, each described element cell forms prismatic, and described first and second distribution plates form rectangle.In this embodiment, described second distribution plate is stacked and placed on described first distribution plate, makes it to slidably reciprocate at the width or the length direction of the first distribution plate upper edge, first distribution plate.
Described housing has guide, is used to guide the motion of described second distribution plate.
Described first and second distribution plates can be provided with a plurality of spray orifices, are used to make the described heat-conduction medium that flows through from the described part that becomes a mandarin to pass through.The periphery of the size of spray orifice described heat-conduction medium stream of mind-set from described heat-conduction medium stream increases gradually.The direction of the size of each spray orifice from the core of cell group towards the periphery of described cell group increases gradually.
The size of corresponding spray orifice is to change according to the motion of described second distribution plate.
Each element cell can form cylindrical.In one embodiment, described cell group comprises the circular packaging part that is used for the encapsulation unit battery.Described first and second distribution plates form and the corresponding circle of the shape of described packaging part, and described second distribution plate is stacked and placed on described first distribution plate, and it can be slided at the circumferencial direction of the first distribution plate upper edge, first distribution plate.
Description of drawings
These of the embodiment of the invention and/or others and feature will become more obvious from the detailed description below in conjunction with accompanying drawing.
Fig. 1 be according to one embodiment of present invention in the outward appearance perspective view of battery module;
Fig. 2 schematically shows the sectional side view of the structure of battery module in accordance with another embodiment of the present invention;
Fig. 3 A is the floor map of the flow controlling unit according to present embodiment shown in Figure 2;
Fig. 3 B is the floor map of flow controlling unit according to another embodiment of the present invention;
Fig. 3 C is the flow controlling unit shown in Fig. 3 B and the perspective illustration of guide according to an embodiment of the invention;
Fig. 4 schematically shows the sectional side view of the cell group structure of battery module according to another embodiment of the present invention;
Fig. 5 is the floor map of battery module according to another embodiment of the present invention;
Fig. 6 is the flow controlling unit plane graph according to another embodiment of the present invention battery module;
Fig. 7 is a battery module schematic cross sectional view according to an embodiment of the invention;
Fig. 8 is the plane graph of the flow controlling unit of battery module according to another embodiment of the present invention;
Fig. 9 is the plane graph according to further embodiment of this invention battery module flow controlling unit; With
Figure 10 is the calcspar that schematically shows as the secondary cell of the power supply that is used for CD-ROM drive motor.
Embodiment
Below, with reference to the accompanying drawings embodiments of the invention are elaborated, so that those of ordinary skill in the art all can implement.But the present invention is not subjected to the restriction of these embodiment, can carry out multiple modification.
Referring to Fig. 1 and Fig. 2, battery module 100 is a kind of high capacity cell modules, and it comprises a plurality of element cells of arranging with predetermined space 11.
Each element cell 11 has an electrode assemblie, and this electrode assemblie has a positive electrode, a negative electrode and an isolator that is inserted between positive electrode and the negative electrode.In the present embodiment, element cell 11 has essentially rectangular shape (having a pair of long limit and pair of short edges in the present embodiment).
Between each element cell 11, be provided with battery barrier ribs 15, supporting the side of each element cell 11, thus the spacing between the holding unit battery.
Be formed with circulating path 17 in each battery barrier ribs 15, heat-conduction medium can be flowed between these corresponding units batteries 11.
Therefore, in the battery module 100 according to present embodiment, a plurality of element cells 11 are separated from each other them by the battery barrier ribs 15 that is arranged between them, form cell group 13.
Battery module 100 comprises that an inside is equipped with the housing 30 of element cell 11 and battery barrier ribs 15.In addition, housing 30 also plays the effect of cooling system, the heat that it produces by means of the heat-conduction medium cooling unit battery 11 of circulation in the circulating path between element cell 11 17.
The installed part 32 of support unit battery 11 is formed in the housing 30, in order to the position of fixed cell battery 11.
Housing 30 is also as the passage of heat-conduction medium through its circulation, it comprises that a heat-conduction medium flows into become a mandarin that part 34 and heat-conduction medium discharge go out to flow part 35.
The part that becomes a mandarin 34 comprises the inlet 34a that a heat-conduction medium flows into, and the flow area that is configured to enter the mouth increases gradually along the direction of inlet 34a to housing 30 inside.
Go out to flow part 35 and comprise an outlet 35a, make and discharge along the direction identical with the heat-conduction medium inflow direction by the heat-conduction medium of the circulating path 17 between each element cell 11.
As shown in Figure 4, battery module 100 ' the part 34 that becomes a mandarin ' can on the direction identical, form and go out to flow part 35 as shown in Figure 2 to a direction bending with circulating path.
Therefore, owing to heat-conduction medium spreads along with flow area increases, by inlet 34a become a mandarin part 34 ' heat-conduction medium flow slow.In addition, when heat-conduction medium spread, the density of heat-conduction medium flowed along with heat-conduction medium its edge of mind-set from housing and reduces.Like this, heat-conduction medium moves to the edge more, and the flow velocity of heat-conduction medium is slow more.
In the battery module 100 according to Fig. 2, the cross-sectional area of circulating path 17 is constant, and becomes a mandarin the flow velocity of heat-conduction medium of part 34 along with heat-conduction medium is mobile laterally and reduce gradually from the center of cell group by inlet 34a.Therefore, along with heat-conduction medium flows laterally from the center of cell group 13, the flow of the heat-conduction medium by the circulating path between the corresponding units battery 11 17 diminishes gradually.
Therefore, with respect to cell group 13, the flow of the heat-conduction medium by the circulating path between the corresponding units battery 11 17 can not keep constant, has so just stoped temperature uniformity on the whole zone of cell group 13 of cell group 13.
Battery module 100 of the present invention provides one to be arranged at housing 30 inside in order to be controlled at the flow controlling unit 40 of the heat-conduction medium flow of circulation in the circulating path 17 between the corresponding units battery 11.
Flow controlling unit 40 comprises a plurality of holes (back is also referred to as spray orifice), heat-conduction medium these holes of flowing through.The size in these holes changes in flow controlling unit 40, makes the heat-conduction medium of constant basis of can circulating in the circulating path 17 between corresponding units battery 11.Flow controlling unit 40 in the present embodiment comprises first and second distribution plates 41 and 42 that are arranged at the part 34 that becomes a mandarin.
Referring to Fig. 2 and Fig. 3 A to 3C, distribution plate 41 forms the rectangular slab of capping unit battery pack 13.Distribution plate 41 is wholy set in and is connected in the part 34 that becomes a mandarin of housing 30 or with the part 34 that becomes a mandarin and is fixed in wherein, make it with housing 30 in cell group 13 adjacent.
First distribution plate 41 act as so-called diffuser, and it is distributed in the circulating path 17 between the corresponding units battery 11 heat-conduction medium and goes, and the flow of heat-conduction medium depends on the position of corresponding units battery 11 and changes to some extent.
In other words, first distribution plate 41 act as the first heat-conduction medium guiding device that disperses and distribute heat-conduction medium.This distribution can be controlled the become a mandarin flow of part 34 by inlet 34a, infeeds in the circulating path 17 between the corresponding units battery 11 with the heat-conduction medium of constant basis the most at last.
First distribution plate 41 has a plurality of first spray orifices 43, is used to make via the become a mandarin heat-conduction medium of part 34 of inlet 34a pass through first spray orifice 43.
In the present embodiment, the size of spray orifice 43 increases gradually along its lateral direction of mind-set from the becoming a mandarin of heat-conduction medium.Spray orifice 43 can form circle, ellipse or polygon.In the embodiment shown in Fig. 3 A-3C, spray orifice 43 forms circle.
In addition, first distribution plate 41 is set to stop heat-conduction medium by the inlet 34a part 34 that becomes a mandarin, and the size of spray orifice 43 increases gradually along the core direction laterally from cell group 13.
Here, first spray orifice, 43 major parts are to be arranged at the position corresponding with respective cycle path 17, and can be provided with continuously or also can be provided with brokenly with predetermined interval.In addition, replace first spray orifice, can single hole be set in the position corresponding with respective cycle path 17.
Second distribution plate 42 according to present embodiment forms and first distribution plate, 41 corresponding rectangles, and is stacked and placed on first distribution plate 41, so that slide on first distribution plate 41.As shown in Figure 3A, second distribution plate 42 can slide along the length direction A of first distribution plate 41.For this reason, the width of second distribution plate 42 is identical with first distribution plate 41, and its length is less than the length of first distribution plate 41.
Shown in the chain-dotted line among Fig. 2, the guide 36 of guiding 42 slips of second distribution plate basically is arranged in the part 34 that becomes a mandarin of housing 30.Guide 36 comprises from the part 34 that becomes a mandarin outstanding with on glide direction, slides as the length direction (A among Fig. 3 A) along first distribution plate 41 and guides the projection of second distribution plate 41.Therefore, as shown in Figure 3A since its with the end face state of contact of first distribution plate 41 under and the outer peripheral portion of second distribution plate 42 is directed to part 36 guidings, second distribution plate 42 is slip before and after the A along its length on first distribution plate 41.
Shown in Fig. 3 B, flow controlling unit 40 ' second distribution plate 42 ' can be in another way first distribution plate 41 ' on broad ways B slide.For this reason, second distribution plate 42 ' length and first distribution plate 41 ' length identical, and width less than first distribution plate 41 ' width.
In the present embodiment, flow controlling unit 40 may further include the actuated piece 47 that makes second distribution plate 42 ' action.The actuated piece 47 of present embodiment is an electric actuator, but the invention is not restricted to this, can be with various actuating units as described actuated piece.
As above address among Fig. 3 C pointedly, guide the guide 36 of second distribution plate 42 ' slip ' be arranged at part 34 places that become a mandarin of housing 30 basically.Guide 36 ' constitute by projection 36a ', projection 36a ' from the part 34 of becoming a mandarin outstanding with guide along glide direction second distribution plate 42 ', promptly along first distribution plate 41 ' Width guide second distribution plate 42 '.Therefore, second distribution plate 42 ' with first distribution plate 41 ' the end face state of contact under, along guide 36 ' first distribution plate 41 ' on broad ways B slide.
Shown in Fig. 2 and Fig. 3 A to 3C, with first distribution plate 41,41 ' the same, have one of second distribution plate 42,42 of said structure ' play heat-conduction medium is distributed to the effect of the air diffuser that goes in the circulating path 17 between the corresponding units battery 11, and the amount of heat-conduction medium depends on the position of corresponding units battery 11 and changes to some extent.
In other words, second distribution plate 42,42 ' the play effect of the second heat-conduction medium guiding device, it will scatter by the become a mandarin heat-conduction medium that is used to control temperature of part 34 of inlet 34a, and the heat-conduction medium of constant basis infeeds in the circulating path 17 between the corresponding units battery 11 the most at last.
Second distribution plate 42,42 ' have second spray orifice 44 is used to make by the become a mandarin heat-conduction medium of part 34 of inlet 34a and flows through.In the above-described embodiment, the size of second spray orifice 44 increases gradually towards the periphery that becomes a mandarin.
Second spray orifice 44 can be circular, oval or polygonal.
In addition, second distribution plate 42,42 ' in, the size of second spray orifice 44 increases gradually along the core direction laterally from cell group 13.In other words, the size of second spray orifice 44 is along from diminishing to the direction with the circulating path 17 corresponding parts of the battery barrier ribs 15 that is positioned at cell group 13 cores with the circulating path 17 corresponding parts of the battery barrier ribs 15 of the outermost portion that is positioned at cell group 13.As shown in the figure, second spray orifice, 44 major parts are arranged at and 17 corresponding positions, respective cycle path, and the quantity of second spray orifice 44 is corresponding with the quantity and the size of first spray orifice 43 with size.
Second spray orifice 44 can perhaps also can be provided with in irregular mode with the predetermined spacing setting.In addition, also can single hole be set in the position corresponding with respective cycle path 17.Can change from the difference between the spray orifice 44 at its center, lateral of second distribution plate 42.In one embodiment, the cross-sectional area and the flow velocity of spray orifice 44 are inversely proportional to, this flow velocity along from the core of cell group 13 laterally the direction of part reduce gradually, like this, consider fluid dynamic continuous equation, can make heat-conduction medium constant flow by second spray orifice 44.
Therefore, be bigger in general owing to flow into the flowing velocity of the heat-conduction medium of cell group 13 cores, so can adjust the sectional area with corresponding first and second spray orifices 43 of the core of cell group 13 and 44.To the flows outside of cell group 13, it is slow more that the flow velocity of heat-conduction medium just becomes more for heat-conduction medium.Therefore, can adjust sectional area with corresponding first and second spray orifices 43 of the Outboard Sections of cell group 13 and 44, it is increased gradually, thereby the flow velocity of the sectional area that makes first and second spray orifices 43 and 44 and heat-conduction medium by first and second spray orifices 43 and 44 is inversely proportional to.
Except the structure of the above-mentioned part 34 that becomes a mandarin, flox condition and weather conditions that first and second spray orifices 43 and 44 size can also be according to the conditions of work of battery module 100, be used to control the heat-conduction medium of temperature are adjusted.
In the above embodiment of the present invention, one of second distribution plate 42,42 ' be can first distribution plate 41,41 ' on the veneer that slides, but its structure is not limited only to this.Second distribution plate 42,42 ' can be two or polylith plate.
Referring again to Fig. 2, the heat-conduction medium that heat-conduction medium is infeeded housing is supplied with the inlet 34a place that part 38 is arranged at housing 30, thereby can be by predetermined revolving force inspiration heat-conduction medium.In addition, heat-conduction medium is supplied with part 38 and is comprised a fan (not shown) with typical structure, and this fan sprays into housing 30 with heat-conduction medium by inlet 34a.
But above-mentioned heat-conduction medium is supplied with part 38 and is not limited to have this fan.Heat-conduction medium is supplied with part 38 can also comprise pump or air blast, blows heat-conduction medium by them.
In battery module shown in Figure 2 100, the heat-conduction medium that is used to control temperature is supplied with part 38 by heat-conduction medium and is flowed into housing 30 by inlet 34a along the short transverse of corresponding units battery 11.
Because heat-conduction medium has pipe shape, the sectional area of the part that wherein becomes a mandarin 34 is to increase gradually from inlet 34a to the direction of cell group 13, so the flow velocity of heat-conduction medium is along diminishing gradually on the direction of part laterally from the core of cell group 13.
When heat-conduction medium flowed, heat-conduction medium was recycled into circulating path 17 by first and second spray orifices 43 and 44.Along with second distribution plate 42 slides on first distribution plate 41, first and second distribution plates 41 and 42 are arranged to make first and second spray orifices 43 and 44 to correspond to each other.
Because the size of first and second spray orifices 43 on first and second distribution plates 41 and 42 and 44 along from the core of cell group 13 laterally the direction of part increase gradually, so the sectional area of first and second spray orifices 43 and 44 and the flowing velocity of heat-conduction medium are varied to inverse ratio.Thus, the heat-conduction medium of constant basis flows through first and second spray orifices 43 and 44.
Therefore, this battery module 100 heat-conduction medium that can make constant basis by and first and second spray orifices 43 and 44 corresponding element cells 11 between circulating path 17.When heat-conduction medium flowed, the heat and the heat-conduction medium that produce in the corresponding units battery 11 carried out heat exchange, and the heat-conduction medium that carries out heat exchange leaves circulating path 17 and also discharges by outlet 35a.
Because the flox condition and the weather conditions of the heat-conduction medium of the condition of work of battery module 100, control temperature, and the flow that makes the heat-conduction medium by first and second spray orifices 43 and 44 be can not keep constant the time, and second distribution plate 42 slides on first distribution plate 41 along length or Width.Like this, under second distribution plate 42 and situation that the end face of first distribution plate 41 contacts, second distribution plate 42 is by guide 36 guidings, slides on first distribution plate 41 along the width or the length direction of first distribution plate 41.
Therefore, first and second spray orifices 43 on first and second distribution plates 41 and 42 and 44 sectional area change with moving of second distribution plate 42, and the heat-conduction medium that can make constant basis thus is by first and second spray orifices 43 and 44.
In the present embodiment, the heat-conduction medium that can make constant basis by and first and second spray orifices 43 and 44 corresponding element cells 11 between circulating path 17.So the heat that is produced in each element cell 11 can distribute equably and be cooled, thereby can keep steady temperature on the whole zone of cell group 13.
Referring to Fig. 5, battery module 200 has such structure, and wherein each element cell 21 forms cylindrically, and the heat-conduction medium of constant basis is recycled into the circulating path 27 between each element cell 21.
Therefore, element cell 21 is by packaging part 24 continuous or separate brokenly settings, thereby makes cell group 23 be formed with a circular external shape, will further be described below.
Packaging part 24 is the circular housings with element cell 21 overall package, and constitutes by having the material of insulation characterisitic with relative higher thermal conductivity.
Patchhole 24a is formed in the packaging part 24, and each element cell 21 can insert in these holes and by basic fixed.Around each element cell 21, be formed for the circulating path 27 of the heat-conduction medium of loop control temperature.
Comprise that according to the battery module 200 of present embodiment an inside is equipped with the cylindrical housings 50 of cell group 23.Because the structure of housing 50 and the housing in the foregoing description are basic identical, so no longer describe in detail.
Fig. 6 is the floor map of the flow controlling unit of the described battery module of Fig. 5.
Referring to Fig. 5 and Fig. 6, the battery module 200 with said structure comprises a flow controlling unit 60, is used for heat-conduction medium with constant basis and infeeds circulating path 27 between each element cell 21.
According to present embodiment, flow controlling unit 60 comprises that first and second distribution plates 61 and 62, the first and second distribution plates form plectane, and its size is corresponding with the size of cell group 23.
First distribution plate 61 is fixedly arranged in the housing 50, makes it adjacent with cell group 23.First distribution plate 61 has a plurality of first spray orifices 63, is used to make the heat-conduction medium that flows into housing 50 to flow to cell group 23.The sectional area of first spray orifice 63 along from the core of cell group 23 laterally direction increase gradually.
Second distribution plate 62 is mounted slidably at the circumferencial direction C with first distribution plate, 61 state of contact lower edges, first distribution plate 61.Because the outer peripheral portion of second distribution plate 62 is subjected to the guiding of guide 56 (among the figure shown in the chain-dotted line), thus second distribution plate 62 along the circumferential direction C rotate, this guide is along the circumferential direction outstanding from housing 50.In second distribution plate 62, form a plurality of second spray orifices 64 that are used for by heat-conduction medium.
The sectional area of second spray orifice 64 increases gradually along the core direction laterally from cell group 23.Like this, first and second spray orifices 63 on first and second distribution plates 61 and 62 and 64 sectional area change with the rotation of second distribution plate 62.
Therefore, battery module 200 according to this embodiment has such structure, though wherein the flowing velocity of heat-conduction medium reduces gradually from the core direction laterally of cell group 23, first and second spray orifices 63 and 64 sectional area increase gradually along the core direction laterally from cell group 23.Therefore, by in first and second spray orifices 63 and 64 circulating paths 27 that the heat-conduction medium of constant basis can be infeeded between the element cell 21.
Make owing to the flox condition of the heat-conduction medium of the condition of work of battery module 200, control temperature and weather conditions by the heat-conduction medium flow of first and second spray orifices 63 and 64 when non-constant, then second distribution plate 62 rotates along the circumferencial direction C of first distribution plate 61.
So when changing according to the rotation of second distribution plate 62 along with the sectional area of first and second spray orifices 63 on first and second distribution plates 61 and 62 and 64, first and second spray orifices 63 and 64 sectional area and the change in flow of heat-conduction medium are inversely proportional to.Therefore, the heat-conduction medium of constant basis can pass through first and second spray orifices 63 and 64.
Because the working condition of present embodiment battery module 200 is identical with last embodiment basically, no longer describe in detail.
Fig. 7 is the side generalized section of cell group that schematically shows the battery module of another embodiment of the present invention.
Referring to Fig. 7 and Fig. 8, battery module 100 " comprises the flow controlling unit 70 that is made of a plate.Flow controlling unit 70 is by constituting with the corresponding rectangular flat of the size of cell group 13.
Flow controlling unit 70 has a distribution member 71, and it is wholy set in the part 34 that becomes a mandarin of housing 30, or combine with the part 34 that becomes a mandarin and fixing wherein, make it near the cell group 13 in the housing 30.
Heat-conduction medium distribution member 71 has a plurality of spray orifices 73, is used to pass the become a mandarin heat-conduction medium of part 34 through inlet 34a.The size of spray orifice 73 is along increasing gradually from the center that the becomes a mandarin corresponding part direction laterally with heat-conduction medium.
Spray orifice 73 can form circle, ellipse or polygonal.But the spray orifice 73 shown in the figure forms circular.
Therefore, though the heat-conduction medium of the part 34 that becomes a mandarin is distributed to the outside unevenly owing to the increase of sectional area, distribution member 71 can force to distribute heat-conduction medium, makes its cooling unit battery equably.
Referring to Fig. 9, flow controlling unit 80 can be applied in the battery module shown in Figure 5 according to another embodiment of the present invention, and is different with the flow controlling unit shown in Fig. 5, and it is made of a plate.
Flow controlling unit 80 according to present embodiment comprises a heat-conduction medium distribution member 81 that forms circular plate type, and its size is corresponding with cell group 23.This heat-conduction medium distribution member 81 has a plurality of spray orifices 83, be used to make the heat-conduction medium that flows into housing 50 to flow to cell group 23, and the sectional area of spray orifice 83 increases gradually along the core direction laterally from cell group 23.
When heat-conduction medium flowed into, the sectional area of the part that becomes a mandarin 34 increased.Therefore, though heat-conduction medium can not be assigned to the outside equably, distribution member 81 can force to distribute heat-conduction medium to make it cooling unit battery equably.
Figure 10 is the schematic block diagram that Fig. 2,5 is connected with motor 110 with the battery module 100 shown in 7.
According to various embodiments of the present invention, provide flow controlling unit, it can optionally be controlled at the heat of cooling transmitting medium that circulates in the circulating path between the element cell.Therefore, though the flox condition and the weather conditions of the drive condition of going into flow structure, battery module of heat-conduction medium, heat-conduction medium change in housing, but, make the temperature on the whole unit battery pack can be very even by the heat-conduction medium of the constant basis that circulates reposefully in the circulating path between element cell.
Therefore, have and optimize the cooling effectiveness on the whole unit battery and improve the charging of battery module and the effect of discharging efficiency.
Here, above-mentioned secondary cell (or battery module) can be used as the driving arrangement motor, as the power source of hybrid electric vehicle (HEV), electric motor car (EV), wireless cleaner, electric bicycle, Segway Human Transporter or similar devices.
Though above various embodiments of the present invention is described in detail, the present invention is not subjected to the restriction of these embodiment.Clearly, to those skilled in the art, under the situation that does not deviate from claims and the desired marrow of the present invention of its equivalent and scope, can make multiple improvement and variation to it.

Claims (17)

1. secondary battery module comprises:
Has cell group with a plurality of element cells of arranged at predetermined intervals;
Be provided with the housing of cell group within it and be used to control the temperature of a plurality of element cells and the heat-conduction medium that in housing, circulates;
Be fixedly set in first adjacent with cell group in the described housing distribution plate, described first distribution plate is suitable for heat-conduction medium is allocated between a plurality of element cells; With
Be slidably disposed on second distribution plate on first distribution plate, this second distribution plate is suitable for heat-conduction medium is allocated between a plurality of element cells.
2. secondary battery module as claimed in claim 1, wherein, described housing also comprises:
The part that becomes a mandarin is used to make heat-conduction medium longshore current Inbound to flow to cell group; With
Go out to flow part, be used for the heat-conduction medium by described a plurality of element cells is discharged along discharging direction,
Wherein, the inflow direction of heat-conduction medium is consistent with the discharge direction of heat-conduction medium.
3. secondary battery module as claimed in claim 2, wherein, the described part that becomes a mandarin forms and makes the sectional area of heat-conduction medium stream increase gradually towards described cell group.
4. secondary battery module as claimed in claim 2, wherein, the flowing velocity that flows through the described heat-conduction medium of the part that becomes a mandarin reduces gradually towards the cell group periphery.
5. secondary battery module as claimed in claim 2, wherein, the part that becomes a mandarin has such structure, and this structure is suitable for making flow velocity mind-set periphery from MEDIA FLOW of heat-conduction medium stream to reduce gradually.
6. secondary battery module as claimed in claim 1, wherein, each in described a plurality of element cells is prismatic.
7. secondary battery module as claimed in claim 6, wherein, described first and second distribution plates are rectangular.
8. secondary battery module as claimed in claim 7, wherein, described second distribution plate is stacked and placed on described first distribution plate, so that slide at first its width of distribution plate upper edge or length direction.
9. secondary battery module as claimed in claim 1, wherein, described housing also comprises guide, is used to guide the motion of described second distribution plate.
10. secondary battery module as claimed in claim 2, wherein, described first and second distribution plates are provided with spray orifice, are used to pass the described heat-conduction medium that flows through from the part that becomes a mandarin.
11. secondary battery module as claimed in claim 10, wherein, the size of corresponding spray orifice increases to the periphery of heat-conduction medium stream gradually from the center of heat-conduction medium stream.
12. secondary battery module as claimed in claim 10, wherein, the size of corresponding spray orifice increases gradually towards the periphery of described cell group.
13. secondary battery module as claimed in claim 10, wherein, the size of corresponding spray orifice changes according to the position of described second distribution plate.
14. secondary battery module as claimed in claim 1, wherein, each in described a plurality of element cells is cylindrical.
15. secondary battery module as claimed in claim 14, wherein, described cell group comprises the circular packaging part that is used for the encapsulation unit battery.
16. secondary battery module as claimed in claim 15, wherein, described first and second distribution plates form and the corresponding circle of described packaging part.
17. secondary battery module as claimed in claim 16, wherein, described second distribution plate is stacked and placed on described first distribution plate, so that slide at the circumferencial direction of the first distribution plate upper edge, first distribution plate.
CNB2005101268206A 2004-11-29 2005-11-22 Secondary battery module Expired - Fee Related CN100449861C (en)

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