FR2633778A1 - Equipressure battery resistant to high pressures and usable in liquid or gaseous medium - Google Patents

Abstract

The invention relates to a sealed battery in which the pressure existing inside the battery is substantially equal to the pressure of the ambient medium by virtue of the adjoining of a reservoir 12 having a deformable envelope 24. The reservoir 12 is filled with a fluid or with an electrolyte which transmits the ambient pressure P to the fluid contained in the battery via a duct 13. The reservoir is housed in a protection chamber 25 communicating with the ambient medium via orifices 26. The battery can operate irrespective of the pressure and position of the battery. Applications: electrical propulsion under water. Work carried out by underwater divers or naval frogmen.

Description

High pressure resistant equipression battery and usable in liquid or gaseous medium.

 The present invention relates to an electric storage battery resistant to high pressures. More specifically, it relates to an equipression battery comprising a housing having outer walls delimiting an interior chamber, an electrochemical group housed in said chamber, two battery terminals disposed outside said housing and connected to said electrochemical group, and means allowing to balance the pressures existing inside said chamber and outside said housing.

 In the current state of the art, batteries used in environments subjected to high pressures, in the marine environment for example, are either placed in watertight boxes resistant to high pressures, or put into equipression by means of a layer of a neutral liquid isolating the electrolyte from seawater in open batteries.

 In the case of these open batteries, the external pressure is exerted on the tank and on the neutral liquid which is generally oil, and the oil transmits this pressure to the electrolyte, which thus balances the pressure exerted on Baccalaureat.

This solution has the major drawback that the battery must be kept vertical so as not to spill the electrolyte.

Finally, this open battery at equilibrium cannot be charged in a marine environment because the bubbling produced during charging causes emulsions of oil and water. These batteries can only be used vertically and need to be brought to the surface to be recharged, can not be used by divers or combat swimmers, and are difficult to use in operating sites permanent due to charging difficulties.

 The solution of using watertight boxes also has drawbacks #. The first of these drawbacks is the weight, which excludes their use by divers or combat swimmers. The second drawback is due to sealing problems at high pressures, since the external wires connected to the terminals of the battery obviously have to pass through the walls of the sealed trunk through orifices, and a leaking fault results in degradation of the battery. , due to the fact that the insulating envelope of the battery in which an electrochemical group is housed can only withstand undue deformation a slight overpressure. In the event of excessive deformation of the envelope, the electrochemical group undergoes stresses and deteriorates rapidly.

 The object of the present invention is to provide an equilibrium battery of the type mentioned which operates whatever the external pressure exerted on it, whatever the position of use of the battery without excessive increase in the weight of the battery and at a reasonable cost price.

 The object is achieved according to the invention by the fact that the means for balancing the pressures existing inside the chamber and outside the housing consist of a reservoir located outside of said housing and communicating with said chamber by a conduit, said reservoir containing a fluid and being deformable under the action of external pressure such that said fluid undergoes the external pressure exerted on said reservoir and transmits the variations in pressure exerted on said reservoir inside from said chamber through said conduit.

 Thanks to this structure, the pressure inside the chamber is substantially equal to the pressure outside d; housing. The housing does not undergo any additional deformation, and the battery can be used as usual on the surface. If the battery is also waterproof, it can be used in all positions.

 Preferably, the reservoir consists of a deformable envelope under the action of external pressure and fixed to one of the walls of the housing, a part of said wall of the housing being common to said housing and to said reservoir.

 The entire battery is thus compact and the battery is easy to handle.

 According to an advantageous characteristic of the invention, the electrochemical group is immersed in an electrolyte and the fluid contained in the reservoir is electrolyte.

 The advantage of this solution is that the weight of the reservoir and of the additional electrolyte is not excessive and this weight is compensated in the marine environment by the buoyancy of Archimede.

Other advantages and characteristics of the invention will appear on reading an embodiment described below by way of illustrative and non-limiting example, with reference to the accompanying drawings in which
FIG. 1 is a diagrammatic representation of an equipression battery according to the known state of the art,
FIG. 2 is a block diagram of a sealed battery with equipression according to the invention,
FIG. 3 shows a first embodiment of a sealed battery with equipression according to the invention,
FIG. 4 shows a second embodiment of a sealed battery at equipression, and
- Figure 5 is a third embodiment of a sealed battery at equipression.

 As can be seen in FIG. 1, the state-of-the-art battery 1 at equilibrium comprises a housing 2 having side walls 3, a bottom plate 4 and a cover 5. The housing delimits an interior chamber 6 containing a liquid electrolyte 7. For the sake of clarity of the drawing, the electrolytic group is not shown, and the terminals of the battery are not shown in all the figures. The cover 5 is provided with an opening 8 directed upwards and passing right through the cover 5. The electrolyte 7 almost completely fills the chamber 6. An oil 9 having a density less than the density of the electrolyte 7 and immiscible with the electrolyte 7 completes the filling of the chamber 6. The battery 1 is subjected to an external pressure represented by the arrow P. In the absence of the opening 8 of the cover 5, the pressure P would deform the housing 2, and the electrolytic group not shown would be subjected to stresses causing deterioration of the battery 1. The pressure P is transmitted by the opening 8 of the cover 5 to the electrolyte 7 via the oil 9. Thus the pressures are balanced on each face of the walls 3, 4, 5 of the housing 2. The housing 2 is not deformed and the electrolytic group is not subjected to stresses leading to the deterioration of the battery 1. This battery 1 can be used in a marine or gaseous environment. It is easily understood that the opening 8 of the cover 7 must always be directed upwards, otherwise the electrolyte 7 or the oil 9 will come out through the opening 8 and be replaced by the fluid from the ambient medium.

In the case where the battery 1 is used in a marine environment, the oil must be chosen in such a way that its density is both greater than the density of seawater and less than the density of the electrolyte. The oil 9 and the opening 8 of the cover 5 constitute the means making it possible to balance the pressures existing inside the chamber 6 and outside the housing 2.

 FIG. 2 represents a block diagram of the watertight battery with equipression according to the invention. For the sake of convenience of reading, the elements identical to the elements known from the state of the art represented by FIG. 1 bear the same references.

 The battery 1 comprises a housing 2 having side walls 3, a bottom plate 4 and a cover 5. The housing defines an interior chamber 6 containing a liquid electrolyte 7. The electrochemical group and the terminals of the battery are not shown in this schematic diagram. The gases 10 produced by the charge and the self-discharge of the battery occupy the upper space 11 of the chamber 6. A reservoir 12 situated outside the housing 2 communicates with the chamber 6 by a conduit 13 which passes through one of the walls of the housing 2, the cover 5 in the diagram shown in FIG. 2.

 The reservoir 12 is filled with a fluid 14 and it is subjected to the pressure P of the ambient medium. According to the invention, the reservoir 12 is made of a flexible material which is deformable under the action of the pressure P, in such a way that the fluid 14 located inside the reservoir 12 is subjected to the same pressure P or at least at substantially equal pressure. The conduit 13 transmits the variations of the pressure P undergone by the reservoir 12 to the electrolyte 7 and to the gases 10. It thus exists. in the chamber 6 a pressure substantially equal to the pressure P exerted on the housing 2 by the ambient medium.

 As can be seen in FIG. 2, the interior of the reservoir 12 communicates directly with the chamber 6 via the conduit 13. The fluid 14 contained in the reservoir 12 is also electrolyte 7 or gas 10.

 The reservoir 12 is calculated in such a way that its volume V2 is greater than or equal to the volume of gas Vg existing in the battery 1, and less than the volume VI, sum of the volumes of the active materials of the electrochemical group, of the electrolyte and of the gas existing in room 6.

 Figures 3 to 5 show three examples of watertight battery 1 at equilibrium comprising a housing 2 having side walls 3, a bottom plate 4, a cover 5 and defining a chamber 6 containing an electrolyte and an electrochemical group not shown. The battery 1 has two battery terminals 20, 21 intended to supply direct current to an external circuit to the battery 1. In each of these batteries 1, the reservoir 12 is attached to the housing 2 either by the cover 5 (FIG. 3) , either by the bottom plate 6 (Figure 4), or by a side wall 3 (Figure 5). The reservoir 12 is constituted by two rigid walls 22, 23 opposite one of which 22 is one of the walls 3, 4, 5 of the housing 2, the two walls 22 and 23 being connected to each other in leaktight manner by a deformable envelope 24 The reservoir 12 is housed in a protective chamber 25 communicating with the ambient environment external to the battery 1 by orifices 26 formed in at least one of the walls 27 of the chamber 25. The walls 27 are fixed together and to the housing 2 in a manner known per se. The purpose of the chamber 25 is to protect the reservoir 12 against impact and possible damage.

 Tank 1? communicates with the chamber 6 through openings 28 passing through the wall 22 common to the reservoir 12 and to the housing 2. A tube 29 open at its two ends 30 and 31 is positioned in the chamber 6 and one of its ends 30 opens into the reservoir 12 through opening 28. Reservoir 12 is filled with a fluid, liquid or gas. If the chamber 6 contains an electrolyte, the reservoir 12 is preferably filled with the same electrolyte or a gas produced by the battery during charging or during self-discharge. In the case of a dry battery without electrolyte, the reservoir 12 is filled either with a neutral liquid, or with a gas identical to the gas produced by the battery.

 The operation of the battery 1 is easily understood.

The fluid from the ambient medium is introduced into the space 32 of the chamber 25 comprised between the walls 27 of the reservoir 12 and exerts the ambient pressure P on the exterior faces of the reservoir 12 opposite the walls 27 and the chamber 25. The wall 24 of the reservoir 12 being deformable, the volume V2 of the reservoir 12 varies as a function of the pressure P. The fluid contained in the reservoir 12 is subjected to a pressure close to the pressure P and the fluids contained in the chamber 6 are subjected to this same pressure P. Thus, in the case of a battery with electrolyte when the pressure P increases, the electrolyte contained in the reservoir 12 is injected into the chamber 6, which compresses the gases contained in this chamber 6 until internal and external pressures are balanced. Conversely, when the pressure P decreases, the gases expand in chamber 6, driving the electrolyte back into the reservoir 12 which resumes its initial form and space 32 decreases by volume.

 Thus, whatever the pressure P, the battery 1 is in working condition. During a charge, the internal pressure tends to increase and the gases recombine or escape as in an atmospheric sealed battery having a safety valve.

 The deformable envelope 24 can be chosen such that there is a slight overpressure inside the chamber 6 and inside the tank 12 with respect to the ambient pressure P. In this case, the battery can be fitted with a safety valve which allows gases to be evacuated when the overpressure exceeds a minimum safety threshold.

For example, the applicant has carried out tests with three assemblies
Example A
Realization of a 2V 7AH battery having a tank above the cover as shown in Figure 3.

 The tank is made of molded ABS, the walls are 1.5 mm thick. The tank is made of polyethylene, fixed vertically by a flexible polyurethane resin. The connection between the chamber tank is made by a polyethylene tube with a diameter of 4 mm and a length of 30 mm. The dimensions of the case are 84 x 34 x 50 mm.

Example B
Realization of a 2V 120AH battery having a tank above the cover as shown in Figure 3.

 The tank is made of standard polystyrene, made from 5 mm thick glued plates. The tank is made of polyethylene, fixed horizontally with a hard polyurethane resin. The connection between the tank and the chamber is carried out by a polyethylene tube with a diameter of 4 mm and a length of 80 mm. The dimensions of the case are 165 x 120 x 150 (height).

Example C
Realization of a 2V 1OAH battery having a reservoir below the bottom plate as shown in Figure 4.

 The tank is made of molded ABS, the walls are 2.5 mm thick. The tank is made of fixed polyethylene with a hard polyurethane resin. The connection between the tank and the chamber is made by a 2 mm opening located at the bottom of the tank. The dimensions of the case are 84 x 48 x 50 (height).

 These three assemblies were subjected to pressures of 150 and 280 bars with maintenance of the pressure for three hours.

The battery of Example B was further subjected to an additional series of tests while lying on one side. The three assemblies withstood these tests perfectly, without damaging the electrochemical group.

 There is no limit to the operating pressures and the capacity of the battery increases with pressure, by impregnation of the current materials of the electrochemical group and by renewal of the electrolyte. The battery life is thus improved.

As proved by the tests carried out, the battery proposed by the invention highlights the following advantages
- resistance to high pressures in liquid or gaseous medium,
operation in all positions in environments subject to pressure variations or high pressures.

 The proposed system can be used for all battery sizes, for all types of batteries, alkaline or acid and for all types of batteries.

 In the case of a battery without electrolyte, the reservoir can receive a neutral gas or liquid.

 It goes without saying that the principle of the equipression battery described above for a battery 1 having a single electrochemical group is also valid for a battery 1 having several chambers 6, each chamber 6 containing an electrochemical group, and the electrochemical groups being electrically interconnected. In this case, the battery I has as many reservoirs 12 as there are chambers 6, each of the chambers 6 communicating with a single reservoir 12.

Claims (10)

1. Equipped battery comprising a housing (2) having external walls (3, 4, 5) delimiting an internal chamber (6), an electrochemical group housed in said chamber (6), two battery terminals ((20, 21 ) arranged outside said housing (2) and connected to said electrochemical group, and means making it possible to balance the pressures existing inside said chamber (6) and outside said housing (2), characterized battery in that said means consist of a reservoir (12) located outside of said housing (2) and communicating with said chamber (6) by a conduit (13), said reservoir containing a fluid (14) and being deformable under the action of the external pressure so that said fluid (14) undergoes the external pressure P exerted on said tank (12) and transmits the variations in pressure exerted on said tank (12) inside said chamber (6 ) through said conduit (13). 2. Battery according to claim 1, characterized in that said reservoir (12) consists of an envelope (24) deformable under the action of the external pressure P and fixed to one of the walls (3, 4, 5 ) of said housing (2), a part of said wall of the housing (22), being common to said housing (2) and to said reservoir (12). 3. Battery according to claim 2, characterized in that said reservoir (12) communicates with said chamber (6) by at least one opening (28) formed in the common wall part (22) of said reservoir (12) and said housing (2). 4. Battery according to claim 3, characterized in that the communication of said reservoir (12) with said chamber (6) takes place by at least one tube (29) open at its two ends (30, 31), said tube (29 ) being located in said chamber (6) and opening into said reservoir (12) through said opening (28). 5. Battery according to one of claims 1 to 4, characterized in that said electrochemical group is immersed in an electrolyte (7), and in that the fluid (14) contained in said reservoir (12) is electrolyte ( 7). 6. Battery according to one of claims 1 to 5, characterized in that the fluid (14) contained in said reservoir (12) is a gas.  7. Battery according to one of the preceding claims, characterized in that it is waterproof. 8. Battery according to one of claims 1 to 6, characterized in that it comprises a safety valve allowing the evacuation of gases (10). 9. Battery according to one of claims 1 to 8, characterized in that the reservoir (12) is housed in a protective chamber (25) communicating with the ambient environment. 10. Battery according to one of the preceding claims, characterized in that said housing (2) contains several chambers (6), in that each chamber (6) contains an electrochemical group, the electrochemical groups being connected together, and in what it includes as many reservoirs (12) as there are chambers (6), each reservoir (12) communicating with a single chamber (6).