DE102013108712A1 - Method for initial filling of a rechargeable battery and accumulator and accumulator filling device - Google Patents

Abstract

The invention relates to a method for first filling a rechargeable battery with liquid electrolyte, the rechargeable battery having a housing with a top side lying in normal operation of the accumulator top and a bottom opposite the top, wherein in the housing battery electrodes and a disposed between battery electrodes liquid absorbing material in that the liquid electrolyte receives, is arranged and the housing has at least one liquid electrolyte filling opening, wherein liquid electrolyte flows through the at least one filling opening via a liquid-tight electrolyte guide channel in the housing from the filling opening to the bottom of the housing or at least as far as Bottom of the battery electrodes is guided. The invention also relates to an accumulator to be filled or filled with liquid electrolyte and an accumulator-filling device.

Description

The invention relates to a method for initial filling of a liquid electrolyte to be filled with accumulator according to the preamble of claim 1. The invention also relates to an accumulator to be filled or filled with liquid electrolyte, according to the preamble of claim 4 and an accumulator filling device according to claim 9.

The invention relates to the field of accumulators to be filled with a liquid electrolyte, such as. B. lead-acid batteries, as they are for. B. be used as starter batteries for motor vehicles. Such an accumulator is eg from the US 5,356,733 known. In the manufacture of such a rechargeable battery, the filling process is carried out with the liquid electrolyte according to the 1 illustrated approach. The filling takes place through a filling opening 5 standing at a top 3 of the housing 1 or at least above the center of the housing 1 is arranged. The accumulator 10 stands with his bottom 4 on a horizontal surface. The interior of the housing 1 is evacuated by a vacuum. The vacuum causes a predetermined amount of liquid electrolyte 2 in the case 1 through the filling opening 5 sucked. As a result of the rapid filling with the liquid electrolyte forms above the in the housing 1 provided battery electrodes 6 a kind of "lake", ie a collection 7 of liquid electrolyte 2 , which then continues between the battery electrodes 6 distributed and in consequence of the gravity to the bottom 4 flows down. It happens that by the inflowing liquid electrolyte 2 Gases between the battery electrodes 6 or in a separator material containing the battery electrodes 6 surrounds, being trapped and unable or able to escape.

Especially with very fine-grained separator material, the escape of gases is additionally complicated by capillary effects. But even with differently constructed battery electrodes or other sheaths of the battery electrodes, the described effect occurs.

On the one hand, the trapped gases may be air remaining from the environment despite the evacuation. In addition, when filling a lead-acid battery with the liquid electrolyte, carbon dioxide can form in some cases relatively quickly, which also can not or only with difficulty escape in the previously described type of filling.

The accumulations of gas remaining in the region of the battery electrodes are undesirable, because in itself a complete filling of the area of the battery electrodes with the liquid electrolyte is intended. In addition, in certain accumulator types due to the trapped gas bubbles, staining of the separator material occurs, which is also undesirable. This allows soluble substances to separate out and deposit them visibly on the separator material.

It is therefore intended to specify a method for filling an accumulator to be filled with liquid electrolyte, which avoids, or at least significantly reduces, the gas inclusion in the housing and any possible staining on the separator material when initially charged with liquid electrolyte. From the DE 10 2011 110 479 A1 There are already proposals for a solution to this problem.

The present invention has for its object to provide further solutions to the above problem.

The object is achieved according to claim 1 by a method for initial filling of a rechargeable battery with liquid electrolyte, wherein the rechargeable battery has a housing with a top side lying in normal operation of the accumulator top and one of the top opposite bottom, wherein in the housing battery electrodes and an intermediate Liquid electrolyte disposed on the battery electrodes disposed liquid absorbing material, and the housing has at least one filling opening for the liquid electrolyte, said liquid electrolyte through the at least one filling opening via a liquid-tight electrolyte guide channel in the housing from the filling opening to the bottom of the Housing or at least to the bottom of the battery electrodes is performed.

The terms "fill" and "fill in" are synonyms. This also applies to derived concepts.

The invention is based on an accumulator having a housing with at least one filling opening for the liquid electrolyte. It can also be provided a plurality of openings, wherein the remaining openings are optionally closed during the filling process. The at least one filling opening for the liquid electrolyte may be arranged at the top of the housing, for. B. in a cover part. But at least the filling opening can be arranged above the center of the housing, ie above an imaginary plane which runs centrally between the top and the bottom of the housing. The invention has the advantage that, when the liquid electrolyte is supplied, the upper area of the battery electrodes, with respect to the effective direction of gravity, is maintained throughout Filling process is left free of liquid electrolyte. At this uppermost point gas accumulations can then escape undisturbed. The escaping gas can be z. B. initially collect in a housing located above the uppermost point of the battery electrodes housing area or escape through an opening of the housing, z. B. through the filling opening or another opening. The inventive method, the formation of the aforementioned "lake" on the surface of the battery electrodes is avoided, so that always leaves a free path for the exiting gas. Thus, an accumulator without the unwanted gas inclusions or with significantly reduced amount of gas inclusions can be produced. Another advantage of the method is that a continuous filling of the accumulator with the liquid electrolyte can take place, ie there is no need to interrupt the filling process in order to allow trapped gas to escape. This in turn has the advantage that the filling with the liquid electrolyte can take place relatively quickly, as in the known method, which is advantageous for an industrial production process. In the method, an evacuation of the housing may additionally be provided to assist the filling process.

Another advantage of the invention is that the filling of the housing and thus the wetting of the battery electrodes takes place exclusively from the underside thereof, although the filling opening can be located further up. This is also a major difference from the proposals DE 10 2011 110 479 A1 where it should only be ensured that the uppermost point of the battery electrodes is not completely covered with the liquid electrolyte during the filling process. By the method proposed here, the first-time filling of the accumulator with the liquid electrolyte can take place even more gently. It can be ensured by the electrolyte guide channel that when the accumulator is first charged with the liquid electrolyte, it does not wet the battery electrodes from the side or from above, but the electrolyte level rises from bottom to top.

In particular, the battery electrodes are not wetted directly by the electrolyte flowing through the electrolyte guide channel, but the electrolyte can wet the battery electrodes only after its exit from the electrolyte guide channel and correspondingly rising electrolyte level. The gas displaced by the liquid front is not trapped, and a dry degassing path is kept clear. This leads advantageously to a relatively homogeneous filling of the accumulator and a homogeneous wetting of the battery electrodes. An emergence of less well-filled points of the accumulator is thus avoided. In this way, a homogeneous behavior of the accumulator and thus a better performance of the accumulator can be achieved.

The uppermost point of the battery electrodes comes in a horizontally standing accumulator facing the top of the housing towards the upper edge of the battery electrodes into consideration, in the basis of the 1 illustrated, known method is covered with the liquid electrolyte.

The invention is suitable for all types of accumulators to be filled with a liquid electrolyte, regardless of the nature and design of the battery electrodes. The invention is suitable both for battery electrodes which are completely surrounded by a separator material, d. H. are located in a casing formed by the separator material in the manner of a pocket, as well as for battery electrodes, in which different types of separators are used. The invention is suitable for battery electrodes, in which the separator material is beyond the edges of the battery grating out what z. B. in the pocket-like design of separators is the case regularly, as well as for battery electrodes with not beyond the battery grid beyond separators. In this respect, for the purposes of the present application, the separator is understood as part of the battery electrode. If a plurality of battery electrodes is provided to a so-called battery electrode stack in a cell of the accumulator, d. H. a plurality of immediately adjacent juxtaposed battery electrodes, it is advantageous to keep the respective uppermost point of the battery electrode stack during the filling process of the liquid electrolyte from the liquid electrolyte.

The invention can be used in prismatic housing designs as well as in other housing designs, eg. B. in round or oval housings, are used.

The accumulator can be designed as a single-cell or multi-cell accumulator. If the accumulator is designed to be multicellular, then the statements regarding the housing also apply with respect to a respective housing part of the accumulator housing, which encloses in each case one cell of the accumulator. In the case of a single-cell accumulator, the corresponding housing part of a cell can accordingly also form the entire housing of the accumulator. In the case of a multicellular accumulator, it is advantageously provided that each cell or each housing part of a cell has at least one own filling opening for the liquid electrolyte.

The filling of the accumulator with the liquid electrolyte can be controlled or unregulated. In unregulated filling, the supply of the liquid electrolyte z. B. to adjust by experiments such that during the filling process, the electrolyte level does not rise too fast, so that the electrolyte level between the battery electrodes does not lag too much the electrolyte level in the free area of the housing. This can be z. B. by adjusting a dosing. According to an advantageous embodiment of the invention, the liquid electrolyte is metered into the housing by a control. This has the advantage that it can be ensured by the regulation that the electrolyte level between the battery electrodes does not lag too much the electrolyte level in the free area of the housing and it can not happen that during the current filling process of the liquid electrolyte in relation to the Direction of action of gravity uppermost point of the battery electrodes is completely covered with the electrolyte.

The control can be designed as active or passive control. In an active control a controller is provided, for. B. in the form of a mechanical or electronic controller, an input size, such. B. the current level of the liquid electrolyte in the housing is supplied. The controller then regulates the level to a predetermined setpoint. The setpoint value is advantageously set such that the topmost point of the battery electrodes during the filling process of the liquid electrolyte is not completely covered with the electrolyte at any time with respect to the effective direction of gravity. The scheme can also be performed passively, z. B. in the case of filling by means of the below-explained filling vessel via at least one elongated hollow body.

According to the invention, a fluid-absorbing material enveloping the battery electrodes receives the liquid electrolyte during the filling operation of the liquid electrolyte. The liquid-absorbing material advantageously takes up the liquid electrolyte permanently and keeps it even after the filling process. The material absorbing the liquid electrolyte may in particular be the separator material, e.g. in the case of AGM batteries is designed as an absorbent glass fiber mat. The separator material then absorbs the liquid electrolyte. The method is particularly suitable for accumulators in the form of AGM batteries. The liquid-absorbent material may also be a porous mat of micro-glass fibers, whereby a certain proportion of polymer fibers may also be contained. The invention is therefore particularly suitable for accumulators with fine-grained separator material, which surrounds the battery electrodes. The invention is particularly suitable for accumulators with densely packed battery electrodes, which are pressed relatively close together in the housing. In such embodiments of accumulators, uniform wetting of the battery electrodes is usually relatively difficult. This is simplified by the present invention.

The liquid absorbent material may e.g. pocket-shaped respectively for the positive battery electrodes on both sides, so that there is a separation of adjacent negative battery electrodes.

According to an advantageous development of the invention, the liquid electrolyte is metered in by a metering device, so that the electrolyte level between the battery electrodes at any time during the filling process of the liquid electrolyte with respect to the effective direction of gravity is more than 50% of the battery electrode height lower than during the filling process highest electrolyte levels in the housing. Particularly in the case of accumulators with densely packed battery electrodes, the highest electrolyte level during the filling process occurs at the edges of the electrodes in the vicinity of the housing walls of the accumulator housing. By virtue of the above-mentioned metered addition of the electrolyte, the lag of the electrolyte level between the battery electrodes can be limited to an acceptable level, so that the aforementioned staining on the separator material is completely or largely avoided. To further optimize the filling process, said 50% threshold can be further reduced, e.g. to 25% or 10%.

The electrolyte guide channel may be formed as a permanent part of the housing of the accumulator, which remains in the later operation of the accumulator therein. The electrolyte guide channel can also be designed as a temporary auxiliary device, which is introduced into the housing for the first filling operation and is removed again after the filling process. For this, e.g. a hose is used, which is guided in the housing of the accumulator through the filling opening to the bottom of the housing or at least to the bottom of the battery electrode.

According to an advantageous development of the invention, a vacuum is generated in the housing before and / or during the filling process of the liquid electrolyte. If the vacuum is generated during the filling process, during this period, a vacuum pump continues to operate, thereby maintaining or increasing a corresponding negative pressure in the housing.

The above-mentioned object is further achieved according to claim 4 by an accumulator to be filled or filled with liquid electrolyte, wherein the accumulator a housing with a normal operation of the accumulator overhead top and one of the top opposite bottom, battery electrodes in the housing and a liquid disposed between battery electrodes absorbing material that receives the liquid electrolyte, wherein the housing has at least one filling opening for the liquid electrolyte, wherein the housing has an electrolyte guide channel at or in the vicinity of the at least one filling opening for the liquid electrolyte begins and extends from the filling opening to the bottom of the housing or at least to the bottom of the battery electrodes. The accumulator supports by the provided in its housing liquid-tight electrolyte guide channel gentle initial filling with liquid electrolyte. In particular, the method mentioned in the introduction can be applied in an advantageous manner. The corresponding advantages of the gentle filling, as explained above, can be realized.

In particular, the electrolyte guide channel may be permanent, i. firmly, be arranged in the housing. The electrolyte guide channel may e.g. by a double-walled construction of a region of the housing, a hose or tube provided in the housing or a combination thereof.

According to an advantageous development of the invention, the electrolyte guide channel has at least one horizontally or diagonally extending first section, which leads on the one hand to the filling opening and on the other hand is coupled to a second section of the electrolyte guide channel, in the housing to the bottom of the housing or at least until is guided to the bottom of the battery electrodes. The second section may e.g. run vertically or diagonally, wherein between the first and the second portion angling is provided. In particular, the horizontally or diagonally extending first section of the electrolyte guide channel can be arranged in a cover part of the housing in which degassing channels of the accumulator are located. This allows e.g. in accumulators with a degassing in the lid part a cheap and space-saving guidance of the first portion of the electrolyte guide channel.

The electrolyte guide channel may be formed completely or partially closed. The electrolyte guide channel is advantageously formed from a liquid-tight material. The electrolyte guide channel itself does not have to be completely liquid-tight, but may be made liquid-tight. It is crucial that over the electrolyte guide channel, the introduced liquid electrolyte does not wet the battery electrodes or the separators with the electrolyte already in the upper area. To carry out the first-time filling, a filling head can be inserted into the at least one filling opening of the accumulator and the liquid electrolyte can be introduced through the filling head from the outside. The filling head can be inserted in particular liquid-tight and / or gas-tight in the filling opening. The filling head may e.g. be formed as a plug of an accumulator.

According to an advantageous development of the invention, the transition from the filling opening or the material surrounding the filling opening of the housing of the accumulator into the electrolyte guide channel has at least one gas passage opening formed within the housing. This has the advantage that when using e.g. of the two-channel filling head explained below, a continuous evacuation of the housing via the gas passage opening can be carried out simultaneously during the filling process.

The above-mentioned object is further achieved according to claim 9 by an accumulator filling device with a filling head, which is designed for insertion into a filling opening of the accumulator, wherein the filling head has an evacuation channel for producing a vacuum in the housing of the accumulator and a separate from the evacuation channel Elektrolyteinfüllkanal which opens when inserted into the filling opening Einfüllkopf with an outlet opening to an electrolyte guide channel of the housing of the accumulator. This has the advantage that only a single filling head per filling opening to be arranged on the housing of the accumulator to perform both the generation of the vacuum in the housing and the filling of the liquid electrolyte. Due to the separate channels, a continuous evacuation of the housing can also be carried out simultaneously during the filling process.

The filling head can also be used in addition to evacuate the housing. He can e.g. first an evacuation of the housing take place, then liquid electrolyte is introduced. The process can also be performed several times alternating, in which the electrolyte filling is interrupted and in turn evacuated through the filling head. Thereafter, the filling with the electrolyte is continued through the filling head.

The invention will be explained in more detail by means of embodiments using drawings.

Show it:

1 An accumulator in which a filling operation according to the prior art is carried out, and

2 - 6 - Each one accumulator, in which a filling process according to the invention.

In the figures, like reference numerals are used for corresponding elements.

The 4 to 6 show an accumulator before the start of the filling process, the 1 to 3 show an accumulator that is already completely or partially filled with the electrolyte.

The 1 shows an accumulator 10 in which liquid electrolyte 2 supplied according to the input explained prior art. The liquid electrolyte 2 is under vacuum influence through the filling opening 5 in the case 1 filled so that the input already mentioned fluid accumulation 7 above the battery electrodes 6 results. The one in the case 1 already existing liquid electrolyte 11 indicates a water level 12 on. The battery electrodes 6 , in the figures in addition with connecting lugs 9 are shown for electrical contacting, are wrapped with a fibrous separator material. In the filling process according to 1 remain gas bubbles 17 in the field of battery electrodes, z. B. in the separator material. Corresponding reactions form surface stains in the separator material 8th off, and at about those places where the gas bubbles 17 have formed.

The 2 shows an accumulator 10 in which liquid electrolyte is metered through a passive metering device. The accumulator 10 has a housing 1 with a normal operation of the accumulator 10 overhead top 3 and one of the top 3 opposite bottom 4 on. Normal operation is the specification according to the position of an accumulator, which corresponds essentially to a horizontal position, wherein slight deviations from the horizontal position are allowed. The accumulator 10 points inside the case 1 battery electrodes 6 on which are wrapped by a liquid-absorbing separator material. The battery electrodes 6 have the connection lugs 9 on. The accumulator 10 is in the embodiment according to 2 in a horizontal position. Shown is also a filling vessel 13 , z. In the form of a bottle or a bag. The filling vessel 13 is with an elongated hollow body 14 connected, which is formed in the illustrated embodiment as a hose. The hose 14 is through the filling hole 5 up to a desired water level 12 of the liquid electrolyte 11 in the case 1 guided. The hose 14 ends with an outlet opening 20 from which the liquid electrolyte from the hose 14 exit. The filling vessel 13 is filled with the liquid electrolyte. The filling vessel 13 is held on a holding device, which is not shown. The filling vessel 13 has a ventilation opening 15 on and is otherwise closed. By choosing the size of the position of the ventilation opening 15 and the passage cross section of the hose 14 a desired slow, ie metered, feeding the liquid electrolyte can be ensured. This will ensure that the level of electrolyte between the battery electrodes 6 not too much the electrolyte level 12 in the free area of the housing 1 lags. Thus, the top edge remains 18 the battery electrodes 6 free of the liquid electrolyte so that gas can escape upwards.

The 3 shows an accumulator 10 during the filling process of the liquid electrolyte. For the metered supply of the liquid electrolyte, an active control is provided by a control device 30 . 31 . 32 is carried out. The control device 30 . 31 . 32 has a regulator 30 , a sensor 31 as well as an actor 32 on. The regulator 30 can z. B. in the form of an electronic controller, z. B. as an electronic circuit with a microprocessor having a corresponding programming for performing the control function. The sensor 31 is for recording the water level 12 set up. The sensor 31 can be realized in different ways, eg. B. in the form of an in 3 represented electronic camera, the images of the accumulator 10 from a housing side receives, or than at the top 3 of the housing 1 mounted ultrasonic sensor, the level 12 detected without contact, or as a mechanical sensor, eg. B. with a float. In the in 3 illustrated embodiment detects as a camera 31 trained sensor by optical means the level 12 , This is the case 1 at least from the camera 31 formed side transparent, so that by processing the camera 31 captured images of the level 12 can be determined. To improve the contrast in the image capture can, for. B. additionally a light source 34 be provided, which is the accumulator 10 illuminates with light. The light source 34 can z. B. give off colored light. This will cause the contrast between that with the electrolyte 11 filled area of the accumulator 10 and not with the electrolyte 11 reinforced area, so that improved image capture by the camera 31 results. The camera 31 can also be designed as a thermal imaging camera, or it can be provided a temperature sensor. In this case, the level can 12 be determined by a temperature measurement, taking care that the temperature of the filled electrolyte 11 from the temperature of the case 1 different. This allows a determination of the water level 12 even with completely non-transparent housings.

The actor 32 can be designed as an electrically actuated metering valve, which via a feed channel 33 supplied liquid electrolyte dosed through the filling opening 5 in the case 1 emits. The regulator 30 evaluates the from the sensor 31 delivered data, it determines an actual value of the water level 12 compares this with a setpoint and controls the actuator 32 such that the inflowing amount of electrolyte 2 not too big, so that the actual value of the water level 12 does not exceed the setpoint.

The regulation can also be carried out by metrological detection of other sizes of the battery electrode set, e.g. by measuring the ohmic resistance, the capacity. Also, a temperature measurement on the connector element between the individual battery electrodes can be performed. A determination of the electrolyte wetting or the electrolyte level is possible, because when filling the liquid electrolyte heats up due to chemical reactions with the battery electrodes. It can reach temperatures of about 100 ° C.

In the 2 and 3 it can be seen that the hose forming the electrolyte guide channel 14 at least to the bottom 19 the battery electrodes 6 ranges, ie the exit point 20 of the hose 14 is at the level of the bottom 19 the battery electrodes or below. The filled electrolyte 11 can therefore rise slowly from below and the battery electrodes 6 wet.

The first-time filling of the accumulator with the liquid electrolyte was previously based on the 2 and 3 using a hose 14 described. The hose 14 can eg only temporarily in the housing 1 introduced and will be removed again after the filling process, but it can also be in the housing 1 remain in the filling process. It is also possible to Die 4 shows an embodiment of the invention, in which a permanent aid for the filling of the battery is present, in the form of an inner housing wall 40 , which together with an outer housing wall of the housing 1 an electrolyte guide channel 42 forms. The exit point 41 of the electrolyte guide channel 42 is again at the bottom 19 the battery electrodes 6 , In the example according to 4 gets from one more to the edge of the case 1 arranged filling opening 5 went out.

The 5 shows an alternative embodiment, with the exception of the below explained differences of the embodiment of 4 equivalent. It is from a housing 1 gone out, that is an upper cover part 50 having.

The lid part 50 will after the assembly of the housing 1 with the battery electrodes 6 placed on a housing base and thus sealed. The electrolyte guide channel is again in this embodiment by a permanently present, inner wall element in the housing 1 the accumulator formed, similar to 4 , with the difference that the wall element has a fixed portion in the housing lower part 52 and one in the lid part 50 fixed section 51 having. The sections 51 . 52 are designed so that they are after placing the lid part 50 overlap and thereby the liquid electrolyte at the battery electrodes 6 over to the exit point 53 is performed without at any higher place in each case a wetting of the battery electrodes 6 with the electrolyte. Through the wall element sections 51 . 52 in turn, together with an outer housing wall of the housing 1 an electrolyte guide channel is formed, such that the wall element section 51 with an outer housing wall, a first (upper) section 55 of the electrolyte guide channel, and the wall element section 52 with an outer housing wall a second (lower) section 54 of the electrolyte guide channel forms. An electrolyte outlet 53 is back in the area of the bottom 19 the battery electrodes 6 ,

The 6 shows an alternative embodiment of a rechargeable battery 10 which, except for the differences explained below of the embodiment of the 5 equivalent. In the housing lower part of the housing 1 is in turn the permanently existing wall element section 52 provided that together with a wall of the housing 1 the second section 54 the electrolyte guide channel forms, up to an exit point 53 for the electrolyte. The lid part 50 , in the eg degassing channels of the accumulator 10 can be integrated, has a wall element 60 on, that together with an outer housing wall of the housing 10 the first section 55 of the electrolyte guide channel forms. The wall element 60 runs diagonally in an area and goes into a horizontal section 61 above. The horizontal section 61 is below the filling opening 5 arranged. This construction is particularly suitable for the use of an accumulator filling device with an at least two-channel filling head 62 , Such a filling head 62 is in the 6 once right above the accumulator 10 shown separately, and additionally in one in the filling opening 5 inserted state. The filling head 62 has an evacuation channel 63 on, over the im casing 1 Existing air or other gases are removed via a vacuum pump, as in 6 through the arrow 65 shown. In addition, the filling head 62 an electrolyte filling channel 64 on, over which the liquid electrolyte 2 in the case 1 to be led. The horizontal section 61 the Wall 60 serves as a stop for a correct positioning of the filling head 62 when inserting into the filling opening 5 , By means of the two-channel filling head 62 can simultaneously the interior of the housing 1 be evacuated and filled with liquid electrolyte. This allows the filling process to be carried out with maximum efficiency.

The vacuum vacuum and the electrolyte feed rate should be adjusted so that it does not overlap dry areas of the battery electrodes 6 comes.

The basis of the 6 described filling with the at least two-channel filler head, for example, in the embodiments according to the 4 and 5 will be realized.

After completion of the filling process, the filling opening 5 closed with a lid or stopper.

The wall elements 40 . 51 . 52 . 60 . 61 can in the manufacture of the housing 1 either directly produced, for example in the form of a double housing wall, or as a separate component, eg. B. from the housing material such as polypropylene in the housing 1 be inserted, for example, in the housing 1 provided guide rails.

The filling opening 5 does not necessarily have to be arranged on the top of the housing, but can also be laterally on the housing 1 be provided, for example in the region of the cover part 50 , In this case, even with the described two-channel filling head 62 to be worked. It is advantageous, the filling head 62 such in the side-mounted filling opening 5 introduce that evacuation channel 63 above the electrolyte fill channel 64 is located to avoid unwanted suction of the filled liquid electrolyte through the evacuation channel.

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

• US 5356733 [0002]
• DE 102011110479 A1 [0006, 0011]

Claims (9)

Method for initial filling of a rechargeable battery ( 10 ) with liquid electrolyte ( 2 . 11 ), the accumulator ( 10 ) a housing ( 1 ) with a top side in normal operation of the accumulator ( 3 ) and one of the top ( 3 ) opposite underside ( 4 ), wherein in the housing ( 1 ) Battery electrodes ( 6 ) and between battery electrodes ( 6 ) arranged liquid absorbing material, the liquid electrolyte ( 2 . 11 ) are arranged, and the housing ( 1 ) at least one filling opening ( 5 ) for the liquid electrolyte ( 2 . 11 ), characterized in that liquid electrolyte through the at least one filling opening ( 5 ) via an electrolyte guide channel ( 42 ) in the housing ( 1 ) from the filling opening ( 5 ) to the bottom ( 4 ) of the housing ( 1 ) or at least to the bottom ( 19 ) of the battery electrodes ( 6 ) to be led. Process according to claim 1, characterized in that the liquid electrolyte ( 2 . 11 ) by a metering device ( 32 ) is metered, so that the electrolyte level between the battery electrodes ( 6 ) at any time during the filling process of the liquid electrolyte ( 2 . 11 ) is more than 50% of the battery electrode height (H) lower than the highest electrolyte level during the filling process with respect to the effective direction of gravity ( 12 ) in the housing ( 1 ). Method according to one of the preceding claims, characterized in that before and / or during the filling process, a vacuum in the housing ( 1 ) is produced. Accumulator ( 10 ), with liquid electrolyte ( 2 . 11 ) is filled or filled, the accumulator ( 10 ) a housing ( 1 ) with a normal operation of the accumulator ( 1 ) top side ( 3 ) and one of the top ( 3 ) opposite underside ( 4 ), Battery electrodes ( 6 ) in the housing ( 1 ) and between battery electrodes ( 6 ) arranged liquid-absorbing material that the liquid electrolyte ( 2 . 11 ), wherein the housing ( 1 ) at least one filling opening ( 5 ) for the liquid electrolyte ( 2 . 11 ), characterized in that the housing has an electrolyte guide channel ( 42 ) at or in the vicinity of the at least one filling opening ( 5 ) for the liquid electrolyte ( 2 . 11 ) and starts from the filling opening ( 5 ) to the bottom ( 4 ) of the housing ( 1 ) or at least to the bottom ( 19 ) of the battery electrodes ( 6 ). Accumulator according to Claim 4, characterized in that the electrolyte guide channel ( 42 ) by a double-walled construction of a region of the housing ( 1 ), one in the housing ( 1 ) provided hose ( 14 ) or pipe or a combination thereof. Accumulator according to claim 4 or 5, characterized in that the electrolyte guide channel ( 42 ) at least one horizontally or diagonally extending first section ( 55 ), on the one hand to the filling opening ( 5 ) and on the other hand with a second section ( 54 ) is coupled, at least to the bottom ( 19 ) of the battery electrodes ( 6 ) enough. Accumulator according to claim 6, characterized in that at least the horizontally or diagonally extending first section ( 55 ) of the electrolyte guide channel in a cover part ( 50 ) of the housing ( 1 ) is arranged, in which also degassing channels of the accumulator ( 10 ) are located. Accumulator according to one of claims 4 to 7, characterized in that the transition from the filling opening ( 5 ) or of the filling opening ( 5 ) surrounding material of the housing ( 1 ) of the accumulator ( 10 ) into the electrolyte guide channel ( 42 ) at least one gas passage opening formed inside the housing ( 43 ) having. Accumulator filling device with a filling head ( 62 ), for insertion into a filling opening ( 5 ) of the accumulator ( 10 ) is formed, wherein the filling head ( 62 ) an evacuation channel ( 63 ) for producing a vacuum in the housing ( 1 ) of the accumulator ( 10 ) and one from the evacuation channel ( 63 ) separate electrolyte filling channel ( 64 ) which, when in the filling opening ( 5 ) inserted filling head ( 62 ) with an outlet opening to an electrolyte guide channel ( 42 ) of the housing ( 1 ) of the accumulator ( 10 ) opens.

Images