DE102005005530A1 - Battery e.g. lead acid battery, for use in vehicle, has base channel unit fixed in battery cell container, and one of two bar units provided between support bases and including one channel at its free end for electrode plates - Google Patents

Abstract

The battery has a base channel unit (1) inserted on a base of a battery cell container and fixed in the container. Two spaced apart support bases (2a, 2b) are arranged along a longitudinal axis of electrode plates. One of the bar units (3a, 3b) is provided between the bases and has a channel at its free end for the plates. One bar unit extends in the direction of axis, where ends of the units are respectively connected with the bases.

Description

The The invention relates to an accumulator with a battery case, the at least one battery cell vessel and a Variety of parallel stacked electrode plates, which extend transversely to the stacking direction over a longitudinal axis in the battery cell vessel. In particular, the invention relates to a lead-acid battery.

Generic accumulators are known in particular in the form of lead-acid batteries which For example, be used as starter batteries in vehicles. The stacked electrode plates are directly on the Bottom of the battery case posed. To a collection room for to create settling mud is the use of mud ribs known, which are placed on the bottom of the battery case and one opposite the Bottom of the battery case increased bearing surface for the Provide electrode plates.

One Problem with the conventional ones Accumulators, in particular lead-acid batteries with liquid electrolyte is that a layer of electrolyte concentration which can lead to reduced performance of the accumulator leads.

task The invention therefore is to provide an improved accumulator, with the cheap way the construction of electrolyte stratification can be counteracted.

The Task is with the generic accumulator according to the invention thereby solved, that for each battery cell vessel on the bottom of the battery cell vessel inserted Floor channel element is provided, wherein the bottom channel element in fixed to the battery cell vessel is and two along the longitudinal axis the electrode plates away from each other arranged support bottoms and has a channel releasing web elements between the support floors. The web elements extend in the direction of the longitudinal axis and the ends of the web members each connected to the support bottoms.

The Floor duct element can be used as a cheap plastic insert in the Mounting simply in the battery cell containers of the battery case are inserted. Through the channel between the support plates for the electrode plates is allows circulation of the electrolyte within the battery cell, that of acid stratification counteracts. The channel is located in the middle area the electrode plates, allowing a stable storage of the electrode plates through the support bottoms is ensured at the ends of the electrode plates. The floor duct element thus does not adversely affect the stability of the accumulator out.

The Web elements are preferably made integral with the support floors. It is advantageous if the height of the web elements lower as the height the support floors is, making a channel by the height difference of the web elements to the support bottoms is formed. Alternatively, the But web elements have holes to create a channel.

By the web elements, which are spaced apart in the stacking direction are, an electrolyte passage from the gap of the electrode plates guaranteed in the channel below the web elements.

Preferably locking connections between the floor duct element and the battery cell vessel are provided, so that the bottom channel element against slipping relative to the Bottom of the battery case is secured.

The Locking connections can for example, at the bottom of the battery cell vessel into the operating cell vessel extending locking holes for engagement in corresponding grid elevations having the bottom channel element. During assembly, the bottom channel element both attached to the grid surveys and then snaps captive one. The locking connections can also at the bottom of the battery cell vessel into the battery cell vessel extending grid elevations for engagement in corresponding locking bores have the bottom channel element. Then the grid elevations become the bottom channel element in the locking holes of the battery cell vessel inside plugged.

Farther it is advantageous if latching connections by itself from the top the battery cell vessels to the Bottom extending grooves on the inner wall of the battery cell vessels and corresponding Teeth on the outer edge the bottom channel elements are formed for engagement in the grooves. During assembly, the bottom channel element so that with the teeth in inserted the grooves of the battery cell vessel and then guided by the grooves down to the bottom of the battery cell vessel. This facilitates not only the assembly, but leads also to an improved fit of the floor duct element.

Furthermore, it is advantageous if in the support floors extending from the top to the bottom of the adjacent battery cell vessel Holes are provided. The bottom channel elements are then connected to the battery cell vessel by inserted into the holes adhesive connector such. As a plastic hot melt adhesive, mechanically bonded and secured against slipping on vibration.

The Web elements are preferably on the inner bottom of the associated Battery cell receptacle, so that in the area of the channel, the spaces between the electrode plates go straight to the channel and thus ensures optimum electrolyte circulation is.

Farther it is advantageous if at least one of the bottom of the battery cell vessel upwards running gas pipeline is provided communicating with at least one through the bottom channel element formed channel and to reduce electrolyte stratification is provided. Through the gas guidance line it is achieved that the gas from the bottom of the battery after led upstairs becomes. The gas circulation causes that also the electrolyte circulates.

to Improvement of the electrolyte circulation can also be achieved with the gas supply line be provided communicating pump.

The Gas transfer lines are preferably at least partially integrated into the battery housing, for example, by a corresponding the gas guide conduit forming cavity realized in a plastic injection-molded battery housing.

The Invention will be exemplified with reference to the accompanying drawings explained in more detail. It demonstrate:

1 - Top view of an embodiment of a bottom channel element;

2 - Cross-sectional view of the floor channel element 1 ;

3 - Top view of a battery cell vessel with built-in bottom channel element;

4 - Side view of the battery cell vessel 3 ,

The 1 lets a plan view of an embodiment of a floor channel element 1 for use in a battery cell vessel of a battery case, for example, a lead-acid battery detect. The bottom channel element is rectangular according to the cross section of the battery cell vessel and has two support bottoms 2a . 2 B along the longitudinal axis of the bottom channel element 1 are arranged away from each other. The support floors 2a . 2 B are with web elements 3a . 3b interconnected, extending between the support floors 2a . 2 B extend in the direction of the longitudinal axis. The bridge elements 3a . 3b are integral with the support bottoms 2a . 2 B for example, manufactured as an injection molded plastic. The space between the support bottoms 2a . 2 B and the area above the web elements 3a . 3b forms a channel for a circulation of electrolyte flowing from the gap of electrode plates into the channel. The electrode plates, not shown, are stacked in the stacking direction along the shorter side of the rectangular bottom channel element at a distance from each other, wherein the electrode plates at their outer ends on the support bottoms 2a . 2 B rest.

At the outer edges of the floor channel element 1 can optional teeth 4a . 4b . 4c . 4d be provided for engagement in corresponding grooves of the battery cell vessel. Similarly, it is conceivable in the bottom channel element 1 Provide grooves on the outer edges for engagement in teeth of the battery cell vessel.

Furthermore, it can be seen that in the support floors 2a . 2 B drilling 5a . 5b are provided, which for gripping and inserting the floor channel element 1 serve in the battery cell vessel. After the bottom channel element 1 placed on the bottom of the battery cell vessel, provide the holes 5a . 5b a space for adhesive, preferably a hot melt, around the bottom channel element 1 firmly connected to the bottom of the battery cell vessel and to secure against slipping on vibration.

The 2 leaves a cross-sectional view of the bottom channel element 1 detect. It becomes clear that the height of the web elements 3 much smaller than the height of the support floors 2a . 2 B is. The height of the support bottoms should be about 3 to 6 mm and preferably 5 mm, while the height of the web elements about 0.5 to 2 mm, preferably 1 mm.

It can also be seen that at the bottom of the floor channel element 1 Rest surveys 6a . 6b protrude, which are provided for insertion into corresponding locking holes in the bottom of the battery cell vessel. This creates a detent connection that continues to provide protection against vibration displacement.

The 3 leaves a plan view of a battery cell vessel 7 with bottom channel element inserted therein 1 detect. It becomes clear that the bottom channel element 1 to the walls of the battery cell vessel 7 abuts and thus before moving and Slipping is secured. Furthermore, grooves 8a . 8b . 8c . 8d recognizable, extending from the top of the battery cell vessel 7 extend to the floor and into the teeth 4a . 4b . 4c . 4d of the floor duct element 1 are inserted. As a result, the insertion of the floor channel element 1 in the battery cell vessel 7 considerably simpler and at the same time the bottom channel element 1 fixed.

The in the hole 5a . 5b filled hot glue not only serves to fix the bottom channel element 1 at the bottom of the battery cell vessel 7 , but also for fixing the electrode plate block on the support floors 2a . 2 B ,

From the 4 , which is a transparent side view of the battery cell vessel 7 of the 3 shows, it becomes clear that the grooves 8a . 8b . 8c . 8d from the top of the battery cell vessel 7 extend to the ground. Furthermore, locking holes 9a . 9b visible in which the latch bumps 6a . 6b at the bottom of the bottom channel element 1 intervention.

Claims (12)

Accumulator with a battery housing, the at least one battery cell vessel ( 7 ) and a multiplicity of electrode plates stacked parallel to one another and extending transversely to the stacking direction over a longitudinal axis in the battery cell receptacle ( 7 ), characterized in that for each battery cell vessel ( 7 ) on the bottom of the battery cell vessel ( 7 ) inserted bottom channel element ( 1 ), wherein the bottom channel element ( 1 ) in the battery cell vessel ( 7 ) is fixed and two along the longitudinal axis of the electrode plates away from each other arranged support bottoms ( 2a . 2 B ) and at least one channel element which releases a channel ( 3a . 3b ) between the support floors ( 2a . 2 B ), and wherein the at least one web element ( 3a . 3b ) extends in the direction of the longitudinal axis and the ends of the at least one web element each with the support bottoms ( 2a . 2 B ) are connected. Accumulator according to claim 1, characterized in that the height of the web elements ( 3a . 3b ) lower than the height of the support floors ( 2a . 2 B ). Accumulator according to claim 1 or 2, characterized in that latching connections ( 6 . 9 ) between floor duct element ( 1 ) and battery cell vessel ( 7 ) are provided. Accumulator according to claim 3, characterized in that at the bottom of the battery cell vessel ( 7 ) into the battery cell vessel ( 7 ) extending into locking bores ( 9a . 9b ) for engaging in corresponding grid elevations ( 6a . 6b ) of the floor channel element ( 1 ) are provided. Accumulator according to claim 3 or 4, characterized in that at the bottom of the battery cell vessel ( 7 ) into the battery cell vessel ( 7 ) extending into grid elevations are provided for engagement in corresponding locking bores of the bottom channel element. Accumulator according to one of the preceding claims, characterized in that latching connections by itself from the top of the battery cell vessels ( 7 ) to the bottom extending grooves ( 8th ) on the inner wall of the battery cell vessels ( 7 ) and corresponding teeth ( 4 ) on the outer edge of the floor channel elements ( 7 ) for engagement in the grooves ( 8th ) are formed. Accumulator according to one of the preceding claims, characterized in that in the support bottoms ( 2a . 2 B ) from the top to the bottom of the adjacent battery cell vessel ( 7 ) extending bores ( 5a . 5b ) and adhesive connectors in the holes ( 5a . 5b ) for the mechanical connection of the floor channel elements ( 1 ) with the battery cell vessel ( 7 ) are. Accumulator according to Claim 7, characterized that the adhesive connector is a plastic hot melt adhesive. Accumulator according to one of the preceding claims, characterized in that web elements ( 3a . 3b ) on the inner bottom of the associated battery cell vessel ( 7 ) rest. Accumulator according to one of the preceding claims, characterized by at least one from the bottom of the battery cell vessel ( 7 ) upwardly running gas guide line communicating with at least one through the bottom channel element ( 1 ) formed channel and provided for reducing an electrolyte stratification. Accumulator according to claim 10, characterized by a communicating with the at least one gas guide line Pump for generating an electrolyte circulation. Accumulator according to claim 10 or 11, characterized that gas guide lines at least partly in the battery case are integrated.