BE439977A - - Google Patents

Description

       

   <Desc / Clms Page number 1>
 



  Henri Maurice Barré Patent of Invention Single or multiple voltage electric current accumulator battery
The invention relates to electric current accumulator batteries and is distinguished by the following characteristics: 1 A combining device described below, makes it possible to couple the elements in "series", in "parallel" or in parallel. "parallel series" if more than two elements are used. 2 The electrodes are formed by lead cups or cups containing the active material and perforated so as to allow electrolytic action while preventing the fall of the active material, in order to avoid internal short circuits.

   3 The leaktightness of the accumulator elements is ensured by one or more tubes intended to allow filling with the electrolyte as well as ventilation of the gases given off by electrolysis during charging.



   By way of example and in order to fix ideas, we give below the description of a two-cell electric current accumulator battery packaged for use in the flashlight cases of the model. dish generally comprising three cylindrical zinc battery elements.

 <Desc / Clms Page number 2>

 
 EMI2.1
 



  / The vase can be indifferently executed in cel- 7 .. '6h .. vase peu'L' etre indîL-L, re, -nmert rx.tr?f'c.c,ir ce] - 9m '"luloid , ralo, lith, ebonite, glass or any other, capable of ensuring the perfect seal and resistant to
 EMI2.2
 the attack of the electrolytic; it can also be made of metal, it suffices in this case to use a metal or a metal alloy resistant to corrosion by electrolysis.
 EMI2.3
 



  This vase will be partitioned into ile - ,,, (see fi.l and 4) or three compartments (see fig. 2) depending on whether it is desired to obtain a battery of two or three elements, or it will be constituted by two or more vases side by side (see fig. 3 - 5 - 6). On the subject of each compartment and in the side wall of the vessel, or in the lid, a
 EMI2.4
 or several tubes (I, fi.g.I - 2 - 3 - 4 - 5) will be arranged so that at no time the level of the liquid to be controlled does not exceed the so "ce of the tube (s).

   The closure of the vessel and of each element will be obtained (2 fig. 6) using one of the above products in Jr0s ric so as to: 7¯ effectively maintain the electrodes (Z - 4 - 5 - 6), to electrically isolate the de :: bnrnes (3 - r - 5 - 6) of each element (in the event that the cover is made of metal or metal alloy and generally in an electrically conductive body it is essential to insulate one or both of the electrodes) 5 ensure
 EMI2.5
 end 7.'cts.nciéi.té of each element. At the point where each electrode exits in the cover (2) it is possible to
 EMI2.6
 b: -e, but not essential, to establish a flexible .'oint to facilitate the sealing of the vase.

   A second plate of insulating material (see 7 fig. 7) can be fitted below the level of the filling tube (I) to give the assembly greater rigidity and to immobilize the electrodes and their electrodes more perfectly. insulating. An insulating cement (9 fig.7) can also be poured over the cover (8 Fig. 7) whose role is to determine the mechanical rigidity 1 of the terminal contacts.

 <Desc / Clms Page number 3>

 



  The electrodes are either a lead laminated in sheets or can be rolled or folded together or separately or else juxtaposed with the interposition of an insulator preferably permeable to the electrolyte. The electrodes can also be formed by lead tubes of cylindrical or polygonal section with closed bases, filled with active material.



   To allow the chemical aotion of the electrolyte on the active material reported, the tubes will be perforated over their entire surface with an infinity of holes sufficient to allow chemical exchange and nevertheless capable of retaining the active material contained in each cylinder. With electrodes thus formed, it is possible to use the arrangement shown in FIG. 9 which allows the positive electrode to be framed between the other two negative ones. The electrodes can also be made using stamped or cast lead cuvettes (IO fig. 10) nested or crimped carefully in a second cuvette (II fig.10) of suitable size. They will also be perforated so as to allow the electrolytic action on the added material.



  In the two cases considered above, it is possible to increase the section of the holes in order to intensify the chemical exchange and by the efficiency by taking care to coat each electrode in glass wadding or all. another insulator sufficiently resistant to acids and permeable to electrolytic liquid, this in .vue to retain the material and to allow the ohimic exchange by capillarity. Figure II shows this model with the cover removed. The insulating agent can be either glass wool, felt, perforated or corrugated cellullold or ebonite or any other dielectric material sufficiently resistant to acids.



    At the terminals furthest from the battery (3 - 6 6 fig. 6) it will be adapted to the electrodes of the flexible metal legs, the positive terminal will be appreciably shorter than the negative, in order to be able to use this battery in the lamp housings pocket generally in use.

 <Desc / Clms Page number 4>

 



   The formation of the polarization of the elentrodes will be obtained electrically by successive charges and discharges.
 EMI4.1
 46ft .... sives after complete drying of the coating (1'0- de. This coating t # J will consist of 19 lit; her and sulfuric acid extended to 20 defrés baumé in pro90tjon convcDJble to obtain The electrolytic liquid proper will be obtained by a solution of sulfuric acid having between 20 and 30 degrees Paume. The litharge at the positive electrode can also be replaced by minium lead to hasten the formation.



   The combining device making it possible to couple the elements (see Fig. 12 - 13) will be obtained as follows: one of the two poles of each element will be detected on the longitudinal axis of the accumulator (see 4 - 5 fig. 6 - 7 - II) a plate of dielectric material (see 12 fig. 12 - 13 and 14) comprising 6, 10, contacts or more, depending on whether you want to connect a battery of two or three cells or more (see fig. 12 - 13 and 14).

   The contacts used for the parallel connection (see 13 and 14) figure 13 will be isolated from each other, either they are each arranged on one of the faces of 18 piquette, or that one interposes
 EMI4.2
 '.'E :. , '\ .. \,.' , '. ,: '-' \ 1; ,,. ,, - F, 1 1. , '' e 1 ,: '.. one of the two or both is coated with an insulating coating.



   These plates allow, depending on whether they are placed upside down or upside down, to connect the battery cells in series (Fig. 12) in parallel (Fig.13).



   If one wishes to avoid having to hover the two close electrodes (4 - 5 fig. 6) out of the axis of the external electrodes (3 - 6 fig. 6) it is then possible to adopt the arrangement indicated in figure 15, in this case the contacts of the combiner will be fitted on a plate of dielectric material so that one side is used for series coupling (see fig. 16) and the other for parallel coupling (/ see @

 <Desc / Clms Page number 5>

 fig.

   17.)
It is obvious that the devices presented above in no way limit the adaptations and combinations permitted by this system, in particular this combining device can be adapted to dry cell batteries or to accumulator batteries intended for use or change. frequent tension is necessary. In addition, accumulators can also be constructed, the cylindrical vessel of which enables the latter to be used for flashlight boxes of the model called "Torch". Finally, it should be noted that this system can be applied to all types of accumulators and more especially to those which have to be transported.



   In summary, I claim as being my invention, a single or multiple voltage electric accumulator battery, which makes it possible, by simply moving a combiner plate described above, to instantly modify the flow rate of the accumulator, either by increasing voltage, or by increasing the intensity. In this accumulator system, the electrodes are formed by perforated lead bowls or cups to allow the active material to come into contact with the electrolytic liquid while preventing it from falling. This accumulator can be used in all positions, the level of the electrolyte being at all times lower than the filling mouth.