FR2634585A1 - Energy source switchable under the action of an inertia force - Google Patents

Abstract

The present invention relates to electrical energy sources switchable under the action of an inertia force or the like. The switchable electrical energy source according to the invention is able to be installed on a moving object subjected, over at least a portion of its path, in succession to an acceleration and a deceleration, and is essentially characterised in that it includes at least one mass 17, means 16 for raising the mass freely in translation along a direction 44 forming an angle of less than ninety degrees with the path, means 18 for converting into electrical energy the pressure energy provided by the mass when the moving object is subjected to acceleration, means 18 for storing this electrical energy, means 18, 40, 21, 22 for producing an electrical circuit including the means 18 for storing the electrical energy and a switch 21, 22 at least monostable with two states "open" and "closed", and means for switching the monostable switch, from the "open" state to the "closed" state, under the action of the inertia force exerted by the mass when the moving object is subjected to deceleration. Application, especially, to the triggering of an apparatus simultaneously with the crashing of a moving object against a body.

Description

SWITCHABLE ENERGY SOURCE UNDER ACTION
FORCE OF INERTIA
The present invention relates to switchable energy sources under the action of an inertial force or the like which may be the consequence of different phenomena.

 There are switchable sources of energy under the action of a given force1 for example, a shock. This type of energy source is for example on board mobiles and can be switched when they are subjected to a shock. Following this switching, the source can supply equipment, systems, etc. which then draw up orders of all kinds.

 These sources generally include a generator able to store a certain amount of energy and to restore it, and a detector able to be triggered under the action of a given force, this detector also playing the role of a switch connected to generator terminals and allowing it to discharge its stored energy, to trigger the desired function.

 Such switchable sources give satisfactory results, but nevertheless have drawbacks constituted by their weight and their bulk. In an attempt to overcome the drawbacks mentioned above, sources were then made comprising means making it possible to transform the energy supplied by the shock into electrical energy, and a capacity capable of being charged by this energy and connected in series. with a switch controllable by means of an energy derived from that supplied by the shock.

 This solution overcomes the drawbacks mentioned above, but still has at least one. Indeed, in the latter solution, there is a loss G; time which corresponds to the time it takes for the capacity to charge before being able to command the switch. It is true that, in absolute terms, this time constant is very small. Nevertheless, for certain applications, it may be advantageous to be able to give it the lowest possible value, and even a zero value for the case, for example, of the command of an operation following the impact of a moving mobile. against a given body.

 The object of the present invention is to produce an energy source of the electrical type switchable under the action of a given force, which can be carried on board a mobile capable of being driven by a movement of movement having, on at least a portion of the trajectory, successively an acceleration and a deceleration, which is of a simple structure, not very bulky and which has a shorter response time than sources of the same type, for the same applications as that known from l prior art.

More specifically, the subject of the present invention is a source of energy of the electrical type capable of being carried on a mobile subject, over at least a portion of its trajectory, successively to an acceleration and a deceleration, and switchable when said mobile is subject to deceleration, characterized in that it comprises
- at least one mass,
means for mounting said free mass in translation, in a direction forming with said trajectory an angle less than eighty degrees,
means for transforming the pressure energy supplied by said mass into electrical energy when said mobile is subjected to said acceleration,
- means for storing said electrical energy,
means for producing an electrical circuit comprising said means for storing said electrical energy and an at least monostable switch with two "open" and "closed" states, and
- Means for switching said monostable switch, from the "open" state to the "closed" state, under the action of the inertial force exerted by said mass when said mobile is subjected to said deceleration.

Other characteristics and advantages of the present invention will emerge during the following description given with reference to the accompanying drawings by way of illustration, but in no way limitative, in which
FIG. 1 represents a block diagram of a source according to the invention, in the form of a block diagram,
FIG. 2 represents, seen in section, an embodiment of a source according to the invention in accordance with the block diagram of FIG. 1,
FIG. 3 represents an element of the embodiment according to FIG. 2, and
FIGS. 4 and 5 respectively represent two views making it possible to explain the operation of the embodiment according to FIGS. 2 and 3.

 Figure 1 shows, in schematic form, the block diagram of an electrical source 1 according to the invention, capable of being carried on a mobile 2 subjected, on at least part of its trajectory, successively to an acceleration and a deceleration , and switchable when the mobile is subjected to deceleration.

 The source 1 comprises a mass 3 and means 4 for mounting this free mass in translation in a direction 5 forming with that of the trajectory 6 of the mobile 2 an angle less than ninety degrees.

 It further comprises means 7 for transforming the pressure energy supplied by the mass 3 when the mobile is subjected to acceleration, into electrical energy available between two terminals 8, 9, and means 10 for storing this electrical energy .

 These means 7 and 10 are associated with means 11 for producing an electrical circuit 14 further comprising a switch 12 at least monostable with two states "open" and "closed", and means 13 for switching said monostable switch, from the 'state "open" in the state "closed", under the action of the inertial force released by the mass 3 when the mobile 2 is subjected to deceleration.

 The block diagram described above clearly highlights the different means constituting the source according to the invention defined by their functions.

Figures 2 and 3 show an advantageous embodiment of such a source.

 In the source according to this embodiment, the mass 3 is constituted by a sphere 17 made of a relatively dense material, and the means 4 for mounting the free sphere in translation in a direction forming with that of the trajectory of the mobile an angle less than ninety degrees consist of a body 15 in which a breakthrough 16 is made, in which the sphere 17 is placed. The body 15, for its part, is advantageously made of an insulating material, for example a plastic material.

 In this case, the means 7 for transforming the energy of pressure supplied by the sphere into electrical energy when the moving body is subjected to acceleration comprise a pellet 18 of piezoelectric material located in a housing 20 arranged for a first end 19 of the opening 16, and advantageously secured to this housing.

 In this embodiment of the means 7 for converting the pressure energy into electrical energy, the means 10 for storing this electrical energy produced by the chip 18 when it is subjected to a pressure, illustrated diagrammatically by a capacitor in FIG. 1 , are formed by the patch itself as long as it is not connected to a closed electrical circuit.

 The switch 12 at least monostable in two states is then constituted by two poles 21, 22 of conductive material and insulated from each other by an insulator 23 which can be a part of the wall of the body 15, in which are then respectively embedded the ends 24, 25 of the two poles.

Furthermore, at least one of the two poles, in this case the pole 21 in the illustrated embodiment, is elastically deformable so as to be able to come into contact with the second 22, this first pole 21 being mounted on the path of displacement of the sphere 17 so as to be able to be deformed and come into contact with the second 22 when the sphere is subjected to a displacement towards the second end 26 of the breakthrough 16 opposite the end 19 on which the piezoelectric pad is disposed 18.

 Figure 3 shows an embodiment of the first pole 21 which is adapted to be positioned in a cylindrical breakthrough of revolution. This pole 21 is constituted by a disc 27 made of relatively elastic conductive material and of small thickness, in which cuts 28, 29, etc. are made which compete at the center 30 of the disc, but which stops at a certain distance 31 from the edge 32 of the disc to obtain a solid continuity thereof by keeping the portions 33, 34 ... separated by the cutouts 28, 29 ... These disc portions 33, 34 ... can therefore deform when the sphere 17 comes press on their central ends 35, 36 ... and thus come into contact with the wall 37 of the fixed pole 22 facing the inside of the opening 16.

 In this embodiment, the source comprises a connecting piece 40 which is mounted to slide freely in the opening 16 between the patch 18 and the sphere 17. This connecting piece 40 has a first face 41 which can come into contact with the face 42 of the patch 18 facing inward of the breakthrough 16, and a second face 43 against which the sphere 17 can come into contact. Advantageously, this second face makes an angle different from a right angle with the direction of movement in translation of the sphere 17, this direction being in fact the axis 44 of the breakthrough 16 when the latter is a cylindrical breakthrough, which is generally the case. However, as will be explained below, this second face 43 is advantageously of concave conical shape, that is to say hollow.

 The source further comprises, in the case of this embodiment, elastic means for tending to hold the sphere on the concave conical face 43 of this connecting piece, against the piezoelectric pellet.

In an advantageous embodiment, these elastic means are constituted by the first pole 21 itself, when it is, as described above, constituted by an elastic disc which, in its rest position corresponding to the state " open "of the switch 21, 22, presses on the sphere 17 to hold it against the concave conical face 43 of the connecting piece.

 Furthermore, the connecting piece 40 is inserted between the piezoelectric pad 18 and the edge 31 of the elastic disc 27, all of these three elements being crimped into the insulator 23 also used to insulate one of the other the two poles 21, 22 as described above. In addition, to allow it to establish an electrical connection between the pad 18 and the switch 21, 22, the connecting piece is made of an electrically conductive material and the crimping of the three elements mentioned above allows the pressure forces applied to the face 43 of the connecting piece to be transmitted to the patch 18.

 With such a characteristic, it is therefore established a portion of electrical circuit in series consisting of, successively, the pad 18, the connecting piece 40, the first pole 21 and the second pole 22, these last two elements constituting the switch described above. In this way the face 50 of the patch 18 opposite to that, 42, which is in contact with the connecting piece 40 and the second pole 22 constitute the two terminals 51, 52 of the source according to the invention which can supply, according to the desired application, devices of all kinds shown diagrammatically at 100 in FIG. 1, for example a transmitter, the ignition system of a given operation, etc.

 The source described above works in the following way: it is first of all specified that the source 1 is mounted on board the mobile 2, being integral with it in a position such that the axis 44 of the breakthrough is oriented along the most likely path of the mobile, and so that the switching means 12 are placed, relative to the direction of movement of the mobile, in front of the means 7 for converting pressure energy into electrical energy. In the case of the embodiment according to FIGS. 2 to 5, the switch 21, 22 is therefore located in front of the piezoelectric pad 18.

 This being specified, when the mobile 2 is subjected to an acceleration, the sphere 17 is pressed against the concave conical face 43 of the connecting piece 40 which then compresses the piezoelectric pellet 18. In this state, the switch 21 , 22 being open, the piezoelectric pad 18 is in an open circuit and can therefore be charged with electrical energy by the piezoelectric phenomenon well known in itself, and remains charged as long as this circuit remains open.

 On the other hand, as soon as the mobile 2 is subjected to a deceleration, the sphere 17, owing to the fact that it is mounted free in translation in the breakthrough 16, by the inertia which it has acquired, slides on the face 43 in the direction of movement of the mobile and deforms the elastic wall portions 33, 34 ... of the first pole 21 of the switch, to bring them into contact with the second pole 22, and thus close the circuit between the two terminals 51, 52 comprising the piezoelectric pad 18, the connecting piece 40 of conductive material1 the first pole 21 and the second pole 22 against which is pressed against at least a portion of the first. The amount of electrical energy stored in the piezoelectric pad 18 can then discharge and supply any apparatus such as that shown diagrammatically at 100 in FIG. 1.

 Figures 4 and 5 explain the operation of the source, respectively when the path of the mobile is parallel to the axis 44 of the bore 16 and when it forms with it a non-zero angle of up to one hundred and thirty degrees .

 In fact, in the case of FIG. 4, when the sphere 17 is detached from the concave conical face 43 of the connecting piece 40, it comes to apply freely at the center 30 of the set of elastically deformable wall portions 33 , 34 ... constituting the first pole 21, which therefore all come into contact with the second pole 22.

 On the other hand, when the mobile has a trajectory not parallel to this axis 44, during deceleration, the sphere 17 slides on the wall 43 of the connecting piece 40 in a direction parallel to that of the trajectory of the mobile - and the surface conical 43 comes to apply a feedback force on the sphere 17 which is therefore subjected to a translational force parallel to the axis 44. The sphere 17 is in this case applied against at least one of the elastically deformable wall portions 33, 34 ... who comes to contact the second pole to close the circuit.

 The preceding description shows the advantage of such an embodiment of a switchable source. In fact, the electrical energy necessary to trigger different devices is produced by the movement of the mobile itself, without the need to use accessory energy sources such as batteries, batteries, etc. which are generally high weight and short life. In addition, this energy is available at the time of deceleration of the mobile, which is important, in particular for producing a given signal when, for example, this deceleration is produced by a shock of the mobile against an obstacle and it is necessary to trigger a given device as quickly as possible after this shock, or even simultaneously. In addition, this source can be switched regardless of the direction of the path of the mobile, at least in a solid angle less than two hundred and sixty degrees.

Claims (12)

 1. Power source of the electrical type capable of being carried on a mobile (2) subjected, over at least a portion of its trajectory (6), successively to an acceleration and a deceleration and switchable when said mobile is subjected to the deceleration, CHARACTERIZED BY THE FACT THAT IT CONTAINS  - at least one mass (3, 17),  means (4) for mounting said free mass in translation in a direction forming with said trajectory an angle less than ninety degrees,  - means (7) for transforming the energy of pressure supplied by said mass into electrical energy when said mobile is subjected to said acceleration,  - means (10) for storing said electrical energy,  means (11) for producing an electrical circuit (14) comprising said means (10) for storing said electrical energy and a switch (12) at least monostable with two "open" and "closed" states, and  - Means for switching said monostable switch, from the "open" state to the "closed" state, under the action of the inertial energy exerted by said mass when said mobile is subjected to said deceleration.  2. Source according to claim 1, CHARACTERIZED BY THE FACT THAT said means (4) for mounting said free mass in translation in a direction forming with said trajectory an angle less than ninety degrees consist of a body (15) in which a breakthrough is made (16), said mass being disposed in said breakthrough.  3. Source according to one of claims 1 and 2, CHARACTERIZED BY THE FACT THAT said means (7) for transforming into electrical energy the pressure energy supplied by said mass (17) when said moving body is subjected to said acceleration comprise a piezoelectric material pellet (18), said pellet being located at a first end (19) of said breakthrough (16).  4. Source according to claims 1 and 3, CHARACTERIZED BY THE FACT THAT said means (10) for storing said electrical energy are constituted by said pellet of piezoelectric material (18).  5. Source according to one of the claims 1 to 4, CHARACTERIZED BY THE FACT THAT said two-state switch (12) consists of two poles (21, 22) of conductive material and an insulator (23) disposed between the two said poles, at least one first (21) of the two said poles being deformable to come in contact with the second (22), this first said pole being mounted on the path of movement (44) of said mass (17) of baleen to be able to be deformed to come into contact with the second pole, by a relative displacement of said mass towards the second end (26) of said breakthrough (16).  6. Source according to claims 3 and 5, CHARACTERIZED BY THE FACT THAT said circuit (14) comprises a connecting piece (40) of a conductive material connecting said pellet of piezoelectric material (18) to said first pole (21).  7. Source according to claim 6, CHARACTERIZED BY THE FACT THAT said connecting piece (40) is mounted in said breakthrough (16) between said piezoelectric pad (18) and said mass (17).  8. Source according to claim 7, CHARACTERIZED BY THE FACT THAT said connecting piece (40) has a first face (42) in contact with said pad, and a second face (43) in contact with said mass, said second face forming with the direction of translation (44) of said mass (17) an angle different from a right angle.  9. Source according to claim 8, CHARACTERIZED BY THE FACT THAT said second face (43) is of concave conical shape, and that said mass is constituted by a sphere (17) of dense material.  10. Source according to claim 9, CHARACTERIZED BY THE FACT THAT it comprises elastic means for tending to hold said sphere (17) on said concave conical surface (43).  11. Source according to claims 5 and 10, CHARACTERIZED BY THE FACT THAT said first pole (21) is constituted by a disc of elastic material (27) and that said elastic means for tending to maintain said sphere on said concave conical surface are constituted by said disc of elastic material.  12. Source according to one of the preceding claims, CHARACTERIZED BY THE FACT THAT said insulating material (23) constitutes said body (15) in which said breakthrough (16) is made.