FR2680270A1 - Electronic equipment box comprising a device for storing electrical energy - Google Patents

Abstract

Electronic apparatus box, at least a part (13, 14, 15) of the wall of which comprises a laminated material possessing sheets including electrodes and an electrolyte separating the electrodes. This material constitutes a device for storing electrical energy, used for supplying electrical power to the apparatus, at least one of the electrodes furthermore acting as electromagnetic screening.

Description

ELECTRONIC EQUIPMENT BOX COMPRISING
A DEVICE FOR STORING ELECTRICAL ENERGY
The invention relates to an electronic device housing comprising a device for storing electrical energy. This housing also provides electromagnetic shielding of the device.

 In many electronic devices and especially in portable electronic devices such as radiotelephones arises the double problem of power supply and electromagnetic shielding.

It is also desirable that these devices are neither heavy nor bulky and that the distribution of the masses in the device is substantially uniform, the cost being finally as low as possible. Now a portable device, in particular, must be autonomous and therefore its power supply is generally provided by at least one electrochemical generator of the battery or accumulator type. Conventional generators are heavy, bulky and compact.

The electromagnetic shielding which must protect the circuits and components of the device against external electromagnetic influences is generally obtained by associating a shield with the box of the device, in the form of a metallic or metallized sheet, which involves a cost and possibly an additional weight.

 The object of the invention is to solve the problems of power supply and electromagnetic shielding, in electronic devices, especially portable, by satisfying better than in the past the requirements relating to weight, volume and distribution of masses, and this at a moderate cost.

 The object of the invention is an electronic device housing of which at least part of the wall comprises a laminated material comprising sheets including electrodes and an electrolyte separating the electrodes, this material constituting a device for storing energy. electrical power used for the power supply of the device, at least one of the electrodes further acting as electromagnetic shielding.

 Thus, the laminate material integrated in the box serves both as a device for storing electrical energy and electromagnetic shielding, which achieves the objectives of distribution of uniform masses and electromagnetic shielding indicated above. All that is required is for the laminated material to extend over most of the housing, for example at least over the entire bottom of the housing. In addition, the integration of the electricity generator and limp into a single component already leads to a saving of weight.

 According to another characteristic of the invention, said electrode acting as electromagnetic shielding extends substantially over the entire surface of the housing.

 According to another characteristic of the invention, said electrode acting as electromagnetic shielding is the outermost of the electrodes of the housing material.

 According to another characteristic of the invention, said laminated material is formable and extends substantially over the entire surface of the housing.

 According to another characteristic of the invention, the lithium is used in at least one of the electrodes of the housing material.

According to another characteristic of the invention, the electrolyte is a solid material consisting of a polymer mixed with a salt in solution in a polymer. It is possible in particular to use polyoxyethylenes in which salts have been dissolved such as LiAsF6, LicolO4, LiCF3SO3,
LiTFSI.

 According to another characteristic of the invention, one of the electrode sheets consists of a polymer-based composite and a compound selected from the group NiS2, NiPS3, FePS3, V6O12, V20s, MnO2, (bu2O3, PbO). , NiO (OH), PbO2, Co304, LiCoO2.

 According to another characteristic of the invention, the wall consists of a hard plastic sandwich surrounding a laminated material as defined above.

The characteristics and advantages of the invention will emerge more clearly from the description which follows, made with reference to the appended figures which represent
- Figure 1, a representation of the housing of the invention,
- Figure 2, a representation of the elementary structure of the laminate material included in the housing of the invention.

 FIG. 3, curves illustrating measurement results relating to the electromagnetic shielding properties of the material of the housing of the invention.

 Figure 1 shows a portable electronic device housing 1, such as a radiotelephone. This housing comprises a lid 2 consisting essentially of a front plate 3 provided with a flange 4. The lid 2 is connected to the housing body 5, essentially consisting of a bottom 6 and side walls 7. This connection comprises a flexible hinge 8 which contains electrical conductors 9 covered with insulating material. The cover is applied by its rim 4 to the side walls 7, to which it is fixed by means not shown, such as latches of the current technique, enclosing a volume containing, in addition to the hinge 8, electronic equipment of the 'apparatus. For the purposes of using the apparatus, the lid 2 comprises various openings, such as an opening 10 provided for a display, or openings such as 11 each corresponding to a key of a keyboard diagrammed at 12. In addition, an opening 12 'corresponds to the passage of the antenna. In application of the conventional technique, such a housing would be essentially made of a plastic material or a composite based on plastic material and obtained by molding.

 According to the invention, at least part of the wall of this housing comprises a laminated material comprising sheets including electrodes and an electrolyte separating the electrodes, this material constituting a device for storing the electrical energy used by the power supply. of the apparatus, at least one of the electrodes further acting as electromagnetic shielding.

 For example, the portion of the wall of the housing in question is that which is delimited at 13 and corresponds substantially to the entire surface of the bottom of the housing.

But, preferably, said material extends at least not only at the bottom of the housing, but also at its side walls, up to the limit 14. Advantageously, this material can also extend to all or part of the lid, as illustrated in 15, the connections such as 9 provided in the hinge 8 ensuring the necessary electrical interconnections.

 Figure 2 is a representation of the elementary structure 20 of the laminate material included in the housing of the invention. This elementary structure 20, which will be called a layer, with a total thickness of 300 μm, comprises 4 superposed sheets, the respective thicknesses of which are similar: a sheet constituting a positive electrode 21, a solid electrolyte sheet 22, a negative electrode sheet 23 and a conductive sheet 24. This last sheet is metal good conductor of electricity, such as silver or copper. Its role is to distribute or redistribute the current on the negative electrode, by overcoming a certain lack of electrical conductivity of the material of which this electrode is made. The compositions of the other three sheets that constitute an electrochemical generator will be discussed later.

 In general, the sheets 21, 22, 23 constitute a generator producing a voltage of approximately 1.2 V. A voltage of approximately 5 V would thus be obtained by stacking four four-leaf layers, such as that of the Figure 2, to form a set with a thickness of 1.2 mm. At this thickness, the amount of electricity available will depend essentially on the surface. It can be increased by superimposing several sets that will be connected in parallel. Higher voltages will be obtained by varying the number of layers of the sets and the series or parallel connection of the sets. Of course, the connections between assemblies and the output connections of the generator will have to be arranged. This will be done according to the usual techniques in this area.

 A material comprising a set of several layers, each corresponding to that represented in FIG. 2, is therefore a flat body which can be cut to have any shape, for example that defined at 13 or 15 in FIG. moreover, by means of the choice of deformable materials to form the sheets thereof, this material may be shaped so as to conform to the shape delimited at 14.

 The casing of FIG. 1 will be obtained from the material that has just been defined by coating this material, for example by overmoulding, with an appropriate plastic material chosen from those which are customarily adopted for this use, such as PVC or ABS, thus producing a hard plastic sandwich surrounding a laminate material as defined above.

 The electrochemical generator electrodes of Figure 2 play a role of electromagnetic shielding. This effect, as will be seen later, is more or less effective depending on the composition of the layer and its location in the material. It is preferable that the electrode acting as electromagnetic shielding is of all those of the material closest to the outer surface of the housing.

It is also preferable that this electrode extends substantially over the entire surface of the housing. In a case where the electrochemical generator would stop at the limits indicated at 13 in FIG. 1, the electrode acting as shielding would advantageously be used for what is delimited at 14 and 15, with interconnection at 9.

 The cutting of the different leaves, according to the forms that have just been envisaged, will of course be accompanied, in accordance with the state of the art, by any measure aimed at avoiding any short-circuit between electrodes at the margins of the leaves, especially around the openings such as 10 and 11 and along the edges of the material, such as additional insulation localized to the places to be protected.

 The composition of the sheets constituting the electrodes and the electrolyte of the electrochemical generator of FIG. 2 will now be considered.

 According to a preferred mode of implementation of the invention, the lithium is used in at least one of the electrodes of the material of the case.

 Preferably, the negative electrode is based on lithium, but it can also be an alloy such as for example LiAl or an insertion compound such as CLi.

More preferably, the electrolyte is a solid material consisting of a salt in solution in a polymer. A polyoxyethylene in which salts such as LiAsF 6,
LiCF3SO3, LiTFSI. Such solid electrolytes based on polymer, for use in electrochemical generators, in particular lithium, have in particular been described in French Patent No. 8120586 of the number 1981
Also preferably, the positive electrode consists of a polymer-based composite and a compound selected from the group NiS2, NiPS3, FePS3, V6O13, V205, MnO2, (Bi2O3, PbO), NiO (OH), PbO2, Co304, LiCoO2.

In one embodiment of the invention, a rechargeable battery of approximately 10 V and 800 mA / h, with a total surface area of 400 cm 2, is obtained in four superposed sets of 100 cm 2, arranged electrically in parallel, and a total thickness of 4.8 mm. In each layer, we find, for example
a negative electrode which is a composite sheet of LiAl powder mixed with carbon black in a plastic matrix of PEO.LiTFSI type,
a solid electrolyte sheet of PEO type dissolved in a salt of LiTFSI type,
a positive electrode which is a sheet containing 20% of the above electrolyte and 80% of V6013.

Measurements have been made concerning the electromagnetic shielding effect provided by the negative electrode; they are recorded in the table below
Case TSv Type R TSr TSbl TSb2
A 60-120 Low level video 1000 105 100 10
B 120-200 Low Level Audio 600 104 100 10
C 200-250 Radiotelephone
D> 250 Wireless relay 50> 104 100 10
In this table are presented four types of measures identified by the letters A to C, relating to equipment whose characteristics are set out in the "Type" column. The table shows the intrinsic susceptibility rate of the standard circuit in these devices TSv, the load resistance of the circuit-type R, its actual susceptibility TSr, which is the product of the two preceding parameters, and the susceptibility rate obtained when the equipment is protected by a housing according to the invention, noted TSbl when the electrode acting as electromagnetic shielding is not the one that is the outermost in the laminated material of the housing, and noted
TSb2 when the shield is outside.

 We see a reduction of nearly 103 of the susceptibility rate obtained thanks to the case of the invention.

 FIG. 3 illustrates, for its part, measurement results relating to immunity to electromagnetic noise of Schottky diode logic circuits at different frequencies. The minimum power which it was necessary to radiate was measured to cause the inversion of the logic state of circuits of this type, without protection (curve 31), in a case according to the invention when the electrode acting as shielding electromagnetic is not that which is the outermost in the laminated material of the housing (curve 32), and in a housing according to the invention, when the shield is outside (curve 33).

 These curves confirm the protection effect against external electromagnetic influences provided by the housing of the invention.

 As of course, the invention is not applicable only in the case of housings of electronic devices, such as radiotelephones, but can be applied profitably whenever an independent power source is needed at the same time electrical and electromagnetic shielding.

Claims (9)

An electronic device housing characterized in that at least one portion (13, 14, 15) of the wall of said housing comprises a laminated material having sheets including electrodes and an electrolyte separating the electrodes, which material constitutes a storage device for the electrical energy used for the power supply of the apparatus, at least one of the electrodes further acting as electromagnetic shielding. An electronic apparatus housing according to claim 1, characterized in that said electrode acting as an electromagnetic shield (21) extends substantially over the entire surface of the housing. An electronic apparatus housing according to claim 1 or 2, characterized in that said electrode acting as an electromagnetic shield (21) is the outermost of the electrodes of the housing material. An electronic apparatus housing according to claim 1 or 3, characterized in that said laminated material is formable and extends substantially over the entire surface of the housing. 5. Electronic device housing according to any one of claims 1 to 4, characterized in that the lithium is used in at least one of the electrodes of the housing material. 6. Electronic device housing according to claim 5, characterized in that the electrolyte is a solid material consisting of a salt in solution in a polymer. 7. Electronic device housing according to claim 6, characterized in that the electrolyte is a polyoxyethylene in which salts have been dissolved such that LiAsF6, LicolO4, LiCF3So3, LiTFSI. An electronic apparatus housing according to claim 6, characterized in that the electrode sheets consist of a polymer-based composite and a compound selected from the group NiS2, NiPS3, FePS3, V6012, V205, MnO2, (Bi2O3, PbO), NiO (OH), PbO2, Co3O4, LiCoO2. 9. Electronic device housing according to any one of claims 1 to 8, characterized in that the wall consists of a hard plastic sandwich surrounding a laminate material as defined above.