DE202010013664U1 - Power supply device in the form of a single cell or a battery consisting of several electrically interconnected single cells - Google Patents

Abstract

Power supply device in the form of - a cell or - a battery, consisting of a plurality of individual cells which are inserted into a battery housing and are electrically connected to one another and which is or are washed around for the temperature control by a temperature control medium, characterized in that each cell is inserted in a cooler housing, the Housing casing (5) for forming an annular gap (4) surrounding a cell (1) lies at a distance from the outer casing of the cell (1), and that air inlet channels and air outlet channels (11) open into the annular gap (4).

Description

The invention relates to a power supply device according to the preamble of claim 1.

In the case of power supply cells, for example based on nickel-metal hydride or lithium, in particular if they are composed to form a battery, in particular a motor vehicle battery, into a composite of a multiplicity of individual cells, there is the need for active cell or battery cooling.

In the DE 601 24 634 T2 (ex EP 1 178 558 ) is described as belonging to the prior art, a cooling system for a power supply device for a motor vehicle. This cooling system comprises a housing accommodating a large number of individual cells with air inlets arranged in the region of the housing bottom and air outlets located at the top of the housing. In order to ensure the most uniform possible cooling of the individual cells, Kühlseinstellrippen are arranged such that the speed of the cooling air from the housing bottom to the housing top side is larger inside the housing.

Another in this document treated power supply device includes a plurality of arranged in upper and lower rows of individual cells which are inserted into a block containing a plurality of air gaps such that around the individual cells air channels for the individual cells flowing around cooling air are formed. The cooling air flows into a located in the top of the block air inlet duct, to which the air gaps and thus the individual cells surrounding cooling channels are connected. The cooling air flows through the block receiving the individual cells substantially in "parallel connection" and leaves this block through an air outlet channel, which runs essentially parallel to the air inlet channel. Apart from the fact that the block with the cooling channels surrounding the individual cells is structurally very complicated, no uniform cooling of all individual cells is guaranteed here if a plurality of rows of single cells are arranged in the block between the air inlet duct and the air outlet duct.

In the DE 102 02 807 B4 For temperature control of high-performance secondary batteries for vehicle applications, a device is described in which a temperature control medium flows for cooling or heating through the interior of each cell.

The invention has for its object to provide a device to provide with improved efficiency, a power supply device, in particular in the form of a single cell or a plurality of electrically interconnected single cells existing battery to achieve improved efficiency, a uniform and sufficient temperature, especially cooling can ,

To solve this problem, the device according to the invention is characterized by the features of the characterizing part of claim 1, d. H. the essential feature of the invention is that each individual cell is housed by itself in a substantially closed radiator housing, which is provided with air inlet and outlet ducts.

Preferred embodiments are treated in the subclaims.

The invention will be described in more detail below with reference to the drawing:

The 1 and 1a show in isometric view an exploded view of a single cell with various cooler housing elements;

2 shows an axial section of the cooler housing with inserted cell;

The 2A and 2 B show in enlarged detail views according to the sections A and B in 2 ,

3 shows two juxtaposed cells of a battery.

The 3A and 3B show in enlarged detail views according to the sections A and B in 3 ,

4 shows a simplified representation of a housing shell arranged on the inside ribs.

5 shows a radial section of a ribbed housing shell with cell inserted therein approximately in the region of the section line VV in 2A ,

6 shows spirally running ribs without the housing shell.

7 is an isometric view of a composite of several individual cells battery with individual supply of the radiator housing via a hose system;

8th is an isometric view of a composite of several single cells Battery with cooling air supply to the radiator housing via a compressed air chamber.

9 shows an isometric view of a composite of several individual cells battery with cooling air supply to the radiator housing via a distributor plate.

The term "cooling" is representative of the term "tempering", since it may be appropriate for cold start in cold environment to supply the individual cells warmth or hot air to preserve and extend the life.

The invention is based on a two cell poles 2 and 3 having single cell 1 described in the in 2 shown manner is inserted into a radiator housing. The radiator housing consists essentially of a cell 1 leaving an annular gap 4 surrounding housing jacket 5 and upper and lower closure means in the form of an upper locking ring 6 and a lower locking ring 7 ,

The cells 1 may in particular have circular, but also rectangular, square or polygonal, oval or other cross-sections.

The upper locking ring 6 is for the inflow of cooling air in the direction of arrow "Y" with a preferably axially extending supply air opening 6.1 provided in accordance with 2A in a ring channel 6.2 which preferably leads inwards by means of one on top of the cell 1 resting O-rings 8th and out through one on the outer edge of the housing shell 5 lying O-ring 9 is sealed.

In the upper end of the annular gap 4 is a ring 10 used, which is provided with a plurality of circumferentially distributed air inlet ducts, according to arrow "Y" a connection between the annular channel 6.2 and the annular gap 4 produce.

The lower locking ring 7 is according to 2 B with to the annular gap 4 subsequent air outlet channels 11 provided through the air in the direction of the arrows Z can flow out of the radiator housing. An O-ring 13 between the locking ring 7 and the cell 1 and an O-ring 14 between the lower edge of the housing shell 5 and the lock ring 7 prevent a lateral outflow of cooling air. The lower locking ring 7 is distributed over its circumference with, for example, three supports 12 as a support for a cell 1 Mistake.

In 2 is by the arrow "X" the inside of the cell 1 indicated upward heat flow.

The total opening cross section of the in the annular gap 4 opening air inlet ducts is equal to or greater than the total opening cross section of the air outlet ducts 11 , such that is within the annular gap 4 if necessary, build up a certain overpressure.

In accordance with the 2 . 2A and 2 B several juxtaposed cells 1 and housing mantles 5 The upper and lower locking devices are in the form of cover plates 26 and floor plates 21 ,

The construction and the concept of the floor slab 21 in association with the lower ends of each housing shell 5 and every cell 1 corresponds in terms of elements 11 . 12 . 13 and 14 essentially the basis of 2 B described system of a lower locking ring 7 ,

The construction and the concept of in the 3 and 3A illustrated cover plates 26 in association with the upper ends of the housing shells 5 and the cells 1 is essentially the same as based on 2A for a locking ring 6 described system.

According to 4 are on the inner surface of the housing shell 5 at non-uniform angular intervals ribs 5.1 arranged, whereby individual chambers are formed with different cross sections. In this way, there is the possibility of being in a housing shell 5 used single cell 1 to allow larger volumes of air to flow along the areas exposed to higher heat loads during operation.

According to 5 can, according to a preferred embodiment of the invention, when the ribs 5.1 are arranged in uniform but also at irregular angular intervals, the air inlet ducts 10.2 and 10.3 have different opening cross-sections to regulate the air supply in the chambers located between the ribs can. 5 also shows that in the case of the use of ribs 5.1 in the upper part of the gap 4 located ring 10 from ring sections 10.1 consists. In the case of a full ring this may also be with the upper ends of the ribs 5.1 be provided receiving incisions.

According to a modified form of the invention according to 6 also spirally formed ribs 5.2 to be appropriate.

In the in the 7 to 9 shown, several cells 1 containing batteries 20 respectively. 30 respectively. 40 are the cells 1 with the radiator housings receiving them on supports of the floor panels 21 respectively. 31 respectively. 41 turned off, as it is z. B. for the baseplate 21 in the 3 and 3A is shown.

The batteries 20 . 30 and 40 are above the cells 1 each with a cover plate 26 respectively. 36 respectively. 46 provided, as it is in the 3 and 3A for the cover plate 26 is shown, for each individual cell in an annular gap 4 between a cell 1 and a housing shell 5 opening supply air opening 26.1 respectively. 36.1 respectively. 46.1 having.

The floor plates 31 and 41 and the cover plates 36 and 46 the batteries 30 and 40 are designed in the same way as the bottom plate 21 and the cover plate 26 ,

In 7 correspond to the supply air openings 26.1 the cover plate 26 the in 3A illustrated Zuluftöffnungen 26.1 to which the cooling air and sealing elements connect.

At the in 7 illustrated battery 20 the coolant supply takes place by means of a hose system 22 that a main line 23 and branching off to the supply air openings 26.1 leading branch lines 24 contains.

At the in 8th illustrated battery 30 are the single cells in an outwardly sealed compressed air chamber 32 accommodated. The through an air inlet 33 supplied cooling air is distributed within the pressure chamber and passes through supply air openings 36.1 into the respective annular gaps surrounding the cells.

At the in 9 illustrated battery 40 the cooling air supply of the annular gaps surrounding the individual cells takes place by means of a cover plate 46 overlying distributor plate 42 that one to the Zuluftöffnungen 46.1 driving channel system 42.1 having outgoing therefrom, not shown bores, in the Zuluftöffnungen 46.1 lead. The at the top of the distributor plate 42 attached canal system 42.1 is by means of a cover plate 43 locked.

Since in a plurality of individual cells combined to form a battery, these heat differently depending on their local position, according to a further invention the air distribution and air supply system is associated with a control device, not shown, such that each individual cell can be supplied with cooling air quantities adapted to its cooling requirement.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 60124634 T2 [0003]
• EP 1178558 [0003]
• DE 10202807 B4 [0005]

Claims (22)

Power supply device in the form - a cell or - a battery consisting of several used in a battery case, electrically interconnected single cells, which is lapped for controlling a temperature control medium or be, characterized in that each cell is used for itself in a radiator housing whose Housing jacket ( 5 ) to form a cell ( 1 ) surrounding annular gap ( 4 ) at a distance from the outer shell of the cell ( 1 ), and that in the annular gap ( 4 ) Air inlet ducts and air outlet ducts ( 11 ). Device according to claim 1, characterized in that the air inlet ducts ( 10.1 ) through one in the upper end of each annular gap ( 4 ) inserted ring ( 10 ) are passed. Apparatus according to claim 1 or 2, characterized by on the inner circumferential surface of the housing shell ( 5 ) attached ribs ( 5.1 respectively. 5.2 ). Device according to claim 3, characterized in that the ribs ( 5.1 ) axially to the axis of the housing shell ( 5 ). Device according to claim 3, characterized in that the ribs ( 5.2 ) spirally to the axis of the housing shell ( 5 ). Device according to one of claims 3 to 5, characterized in that the ribs ( 5.1 ; 5.2 ) are arranged at regular intervals from each other. Device according to one of claims 3 to 5, characterized in that the ribs ( 5.1 ; 5.2 ) are arranged at irregular intervals from each other. Device according to one of claims 3 to 7, characterized in that in the individual compartments opening air inlet ducts ( 10.2 ; 10.3 ) have different opening cross sections. Apparatus according to claims 1 to 87, characterized in that the air inlet ducts ( 10.2 ; 10.3 ) at the one radiator housing end and the air outlet ducts ( 11 ) are disposed at the opposite radiator housing end. Device according to one of claims 1 to 98, characterized by at the upper and lower ends of each housing shell ( 5 ) ( 6 . 7 respectively. 21 . 26 respectively. 31 . 36 respectively. 41 . 46 ). Device according to one of claims 1 to 10, characterized in that the air inlet ducts ( 10.2 ; 10.5 ) to an annular channel ( 6.2 ) are connected, in which a supply air opening ( 6.1 ) opens. Apparatus according to claim 11, characterized in that the upper closure means take the form of a on the housing shell ( 5 ) attached lock ring ( 6 ), and that the lower closure device also serves as a closure ring ( 7 ) is trained. Device according to one of claims 10 to 12, characterized in that the upper and lower closure means sealing rings ( 8th . 9 respectively. 13 . 14 ) assigned. Apparatus according to claim 1, characterized in that in each annular gap ( 4 ) a plurality of circumferentially distributed air inlet ducts and air outlet ducts ( 11 ). Device according to one of claims 1 to 14, characterized in that the total opening cross section of the in the annular gap ( 4 ) opening air inlet ducts equal to or greater than the total opening cross-section of the annular gap ( 4 ) subsequent air outlet channels ( 11 ). Apparatus according to claim 10, characterized in that each lower closure means radially inwardly directed supports ( 12 ) as a support for each cell ( 1 ) having. Device according to one of Claims 1 to 16, characterized by a housing jacket ( 5 ) as a closure device attached cover plate ( 26 respectively. 36 respectively. 46 ), for each cell ( 1 ) an air inlet opening ( 26.1 respectively. 36.1 respectively. 46.1 ) for introducing temperature control medium in between the cells ( 1 ) and the housing mantles ( 5 ) formed annular gaps ( 4 ) having. Apparatus according to claim 17, characterized in that the supply air openings ( 36.1 ) within a compressed air chamber ( 32 ) into which an air inlet opening ( 33 ) opens. Apparatus according to claim 17, characterized in that a connected to a cooling air supply source channel system with a plurality of in the Zuluftöffnungen ( 26.1 respectively. 46.1 ) individual channels is provided. Apparatus according to claim 19, characterized by a on the cover plate ( 46 ) lying distributor plate ( 42 ), one to the supply air openings ( 46.1 ) leading channel system ( 42.1 ) with it having subsequent bores which into the Zuluftöffnungen ( 46.1 ). Device according to claim 20, characterized in that the channel system ( 42.1 ) at the top of the distributor plate ( 42 ) and by a cover plate ( 43 ) is closed. Device according to one of claims 17 to 21, characterized by an air distribution and supply system with associated control device, such that each individual cell can be fed to its cooling demand coordinated amounts of cooling air.

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