DE102006021576B3 - Liquid electrolyte battery for use in e.g. airplane, has plate shaped electrodes arranged in housing with side walls, liquid electrolyte covering electrodes, and flow channel plates arranged parallel to perpendicular edges of electrodes - Google Patents

Abstract

The battery has plate shaped electrodes (2), which are arranged in housing (1) with side walls, and a liquid electrolyte (3) covering the electrodes. A liquid electrolyte rolling over device has flow channel plates arranged parallel to perpendicular edges of the electrodes, and forming left and right sided flow channels (5a, 5b). Electrolyte capture openings (6a, 6b) of the channels lie at a height greater than a gauge height of the electrolyte. Two sections are aligned parallel to a horizontal lower edge of the electrodes, where ends of the sections form a flow opening (8).

Description

The The invention relates to a battery with liquid electrolyte, below Called liquid electrolyte battery, preferably in moving vehicles, such. B. in cars, boats or aircraft is used and a device for electrolyte mixing having.

The The endeavor of the vehicle industry for lightweight construction also applies the saving of battery weight. At the same time, however, the Request for higher Battery power, in addition to the conventional energy to start z. B. a car and energy for additional Units such as electric windows, servo motors for adjustment the seats or also for electrically heating the seats is needed. Furthermore, it is desirable the battery power over the life of the battery as possible to maintain a constant high level, as increasingly safety-relevant Function units such as steering and brakes controlled electrically and pressed become. Below battery power is the capacity of the battery below as well as the ability the battery for current output or power consumption understood. The battery performance is determined by various factors known to those skilled in the art affected.

Out In the prior art, various measures are known to improve performance a battery with a liquid Electrolytes, such as. As a lead-acid battery to increase. A special problem with lead-acid batteries is the so-called stratification of the acid, d. H. the acid concentration is in terms of the electrode surface not even. The causes the Electrodes in places where the acid concentration is too high, corrode, so that reduces the life of the battery, and at the electrode sites, where the acid concentration is too low, the battery does not reach its full capacity.

Therefore, various devices and methods have been developed for circulating the electrolyte so that the acid concentration is equal in all volume portions of the battery. For stationary batteries z. B. blown air into the electrolyte. For vehicle batteries, electrolyte mixing devices known as hydrostatic pumps are known. These devices are effective only on moving vehicles because they use braking and acceleration operations in conjunction with the inertial force of the liquid electrolyte. This technique is known to those skilled in the art, so that only by way of example to the documents US 4,963,444 ; US 5,096,787 and US 5,032,476 and DE 297 18 004.5 and specifically G 91 15 163.5 and G 91 15 597.5 is referenced.

The However, inventors of the present invention have determined that with these From the prior art devices are still not optimal Electrolyte Durchmischung is achievable.

The The object of the invention is to provide a liquid electrolyte battery with electrolyte mixing by accelerated movements of the battery, wherein the electrolyte mixing improves over the prior art shall be.

The object is achieved by means of a battery according to claim 1 and 4, wherein the battery according to claim 1 comprises:
A housing with side walls, a caseback and a cover. This housing forms a battery cell. Usually several such battery cells are combined to form a battery with a multiple housing. In the preferably rectangular housing, the plate-shaped electrodes are covered, which are covered by the liquid electrolyte.

For circulating the electrolyte in a positive or negative acceleration of the battery in a preferred direction, a liquid electrolyte circulating device is provided which has the following features:
Parallel to the vertical edges of the electrodes, one flow channel plate is arranged at a distance, so that a respective flow channel is formed between the respective battery housing wall and the flow channel plate. In the battery housing is a liquid electrolyte whose level reaches beyond the top of the electrodes. At the upper end of the flow channel plate an electrolyte inlet opening is provided, the edge of which is slightly higher than the electrolyte level, so that sloshes in a braking or acceleration process, the electrolyte over the edge of the electrolyte inlet opening. Since the liquid level in the flow channel is now somewhat higher than the level outside the flow channel, the electrolyte flows downwards in the flow channel, causing both levels to equalize again.

At the lower of the end flow channel plates these are bent at right angles, so that the bent sections parallel to the bottom edge of the electrodes. Both sections are the same length, with a between the ends of these sections Free space remains, which serves as a flow-through, through which the electrolyte flows between the electrodes. The flow-through is is dimensioned so that over the Elektrolyteinfangöffnung incoming Electrolyte volume fast pass through the flow opening can, d. H. a backwater is avoided.

To Claim 2, the cross section of the flow opening is at least as large as the cross section a flow channel. This ensures that that the Electrolyte can drain sufficiently fast.

To Claim 3 holes are provided in the horizontal sections, whose distribution and size are so formed are that that downflowing electrolyte volume largely evenly over the entire bottom of the electrode plates is distributed. This almost even distribution of Electrolytes largely prevent intermixed zones between the electrode plates.

The Battery according to claim 4 also has a housing with side walls, a caseback and a cover. In the preferably rectangular housing the plate-shaped Arranged electrodes covered by the liquid electrolyte.

For circulating the electrolyte in a positive or negative acceleration of the battery in a preferred direction, a liquid electrolyte circulating device is provided which has the following features:
Parallel to the vertical edges of the electrodes, one flow channel plate is arranged at a distance, so that a respective flow channel is formed between the respective battery housing wall and the flow channel plate. In the battery housing is a liquid electrolyte whose level reaches beyond the top of the electrodes. At the upper end of the flow channel plate an electrolyte inlet opening is provided, the edge of which is slightly higher than the electrolyte level, so that sloshes in a braking or acceleration process, the electrolyte over the edge of the electrolyte inlet opening. Since now the liquid level in the flow channel is slightly higher than the level outside the flow channel, the electrolyte flows in the flow channel downwards, so that thereby equalize both water levels again.

The lower ends of the flow channel plates are connected to a plate that is parallel to the lower edge the electrodes runs. There are holes in this plate provided, whose distribution and size are designed so that the downwardly flowing electrolyte volume without delay evenly over the Bottom of the battery is distributed.

It It is clear to the person skilled in the art that a Battery, which is the technical teaching of claims 1 or 4 uses, preferably will be rectangular. The technical However, teaching can also be adapted to other forms of battery, without the need for an inventive step. It is still clear that the holes do not have to be round or also slots and other breakthroughs could be.

Further activities and advantages of the invention will become apparent from the following description the embodiments in conjunction with the attached schematic drawings.

1 shows a side sectional view of the first liquid electrolyte battery according to the invention in a first embodiment with a schematic representation of the flow of electrolyte.

2 shows a sectional side view of the first liquid electrolyte battery according to the invention in a second embodiment with a schematic representation of the flow of electrolyte.

3 shows a sectional side view of the second liquid electrolyte battery according to the invention with a schematic representation of the flow of electrolyte.

4 shows an empty battery box according to the prior art.

The following explanation of the invention begins with the prior art 4 because it makes the invention easier to understand.

The 4 shows a battery box with 6 cells. All the following explanations relate to a single cell, this cell in 1 to 3 is shown from the direction in 4 with the reference number 1c is designated.

The 1 shows a side sectional view of the first liquid electrolyte battery according to the invention in a first embodiment.

A housing with side walls 1a . 1b , a caseback 1e and a cover contains vertical plate electrodes 2 and a liquid electrolyte 3 , This housing forms a battery cell. Usually several such battery cells are combined to form a battery with a multiple housing, as in 4 shown. The level of the electrolyte is with 3a characterized.

Parallel to the vertical edges of the electrodes is a respective flow channel plate 4a and 4b arranged so that between the respective battery housing wall 1a . 1b and the flow channel plate 4a . 4b one flow channel each 5a . 5b is formed. At the upper end of each flow channel plate 4 is an electrolyte trap 6a . 6b provided whose edge is slightly higher than the electrolyte level 3a so that during a braking or acceleration process the electrolyte spills over the edge of the electrolyte inlet opening. Since now the liquid level in the flow channel 5 slightly higher than the liquid level 3 outside the flow channel 5 , the electrolyte flows 3 down the flow channel.

At the bottom of the end flow channel plates, these are bent at right angles, so that the bent portions 7a . 7b parallel to the bottom edge of the electrodes. Both sections 7a . 7b are the same length, being between the ends of these sections 7a . 7b a free space remains, as a flow-through 8th serves, through which the from the flow channels 5 downflowing electrolyte 3 flows between the electrodes. The flow opening 8th is dimensioned so that the inflowing over the electrolyte inlet opening electrolyte volume can quickly pass through the flow opening, that is, a backwater is avoided. Thus, the upper lighter acid mixed with the lower heavier acid, so that a so-called stratification is avoided.

The 2 shows a side sectional view of the first liquid electrolyte battery according to the invention in a second embodiment.

In 2 show the sections 7a . 7b additional holes 9 on, so that an even better distribution of the acid 3 he follows. The holes 9 are arranged in the present example so that the hole diameter towards the center, ie the flow-through 8th grow. This takes into account that the flow velocity of the downflowing acid in the direction of the flow-through 8th decreases. As a result, this hole arrangement ensures that almost the same amount of electrolyte flows out of the holes between the electrodes.

The 3 shows a side sectional view of an embodiment of the second liquid electrolyte battery according to the invention, in which the lower end portions of the flow channel plates 4a . 4b with a horizontal plate 10 are connected. In this plate 10 are holes 9 provided, the arrangement and size are dimensioned so that the flowing through electrolyte is optimally distributed. This is the technical teaching after 2 applied.

At Hand of the described embodiments the person skilled in the technical teaching of the present invention Completely remove. It is clear that these embodiments further developed by a person skilled in the art with the aid of the teaching according to the invention and can be modified or combined. Therefore, these also fall not explicitly mentioned or shown further embodiments in the scope of the following claims.

Claims (4)

Liquid electrolyte battery comprising: - a housing ( 1 ) with side walls ( 1a . 1b . 1c . 1d ), a housing bottom ( 1e ) and a cover, - electrodes ( 2 ) in the housing ( 1 ), - a liquid electrolyte ( 3 ) whose level ( 3a ) in the housing ( 1 ) to over the top edge ( 2a ) of the electrodes ( 2 ) and - a liquid electrolyte circulating device which has the following features: parallel to the vertical edges of the electrodes ( 2 ) is ever a flow channel plate ( 4a . 4b ) arranged between itself and the battery walls ( 1a . 1b ) a left and right flow channel ( 5a . 5b ), which has at its upper end one respective electrolyte inlet opening ( 6a . 6b ), which is higher than the electrolyte level ( 3a ), characterized in that - each of the flow channel plates ( 4a . 4b ) is bent at right angles at its lower end, wherein - the two right-angled portions ( 7a . 7b ) are aligned parallel to the horizontal lower edge of the electrodes, wherein the ends of the sections ( 7a . 7b ) spaced opposite and a flow opening ( 8th ) form. Battery according to Claim 1, characterized in that the cross-section of the flow-through opening ( 8th ) is at least as large as the cross section of a flow channel ( 5 ). Battery according to claim 1, characterized in that in the sections ( 7a . 7b ) Holes ( 9 ) are provided whose distribution and size are formed so that the downward-flowing electrolyte volume over the bottom of the electrode plates ( 2 ) equally distributed. Liquid electrolyte battery comprising: - a housing ( 1 ) with side walls ( 1a . 1b . 1c . 1d ), a housing bottom ( 1e ) and a cover, - electrodes ( 2 ) in the housing ( 1 ), - a liquid electrolyte ( 3 ) whose level ( 3a ) in the housing ( 1 ) to over the top edge ( 2a ) of the electrodes ( 2 ) and - a liquid electrolyte circulating device which has the following features: parallel to the vertical edges of the electrodes ( 2 ) is ever a flow channel plate ( 4a , 4b ) arranged between itself and the battery walls ( 1a . 1b ) a left and right flow channel ( 5a . 5b ), which has at its upper end one respective electrolyte inlet opening ( 6a . 6b ), which is higher than the electrolyte level ( 3a ), characterized in that - the flow channel plates ( 4a . 4b ) at its lower end with a horizontal plate ( 10 ) verbun that are parallel to the bottom edge of the electrodes ( 2 ) and that - in the horizontal plate ( 10 ) Holes ( 9 ) are provided whose distribution and size are formed so that the downwardly flowing electrolyte volume is uniform over the underside of the electrode plates ( 2 ).