FR2938371A1 - ELECTRICAL SWITCH TYPE "PUSH-PUSH" OR "PUSH-DOWN" WITH WAYS OF DRIVING NUTS - Google Patents

Abstract

The invention relates to an electrical switch (100) comprising in a housing (110) a driver (150) adapted to switch between two stable positions, a push button (190) accessible to the user adapted to be moved between a position of rest and a depressed position, a nut (160), pivotally mounted relative to the push button, adapted to act in tilting on said driver, drive means (180) for moving the nut together with the push button, elastic return means which constantly tend to return the push button in the rest position and elastic means of tilting of the trainer. According to the invention, said elastic return means and said resilient tilting means are formed by a single spring (170) compressed between said nut and said driver.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The present invention generally relates to electrical switches such as switches and back-and-forth. It relates more particularly to a switch comprising in a housing: a trainer adapted to switch between two stable positions to put in contact or out of contact a movable contact element with a fixed contact element; - A push button accessible to the user adapted to be moved between a rest position and a depressed position; - A nut, pivotally mounted relative to the push button, adapted to act in tilting on said trainer; - Drive means for moving the nut together with the push button; - Elastic return means which constantly tend to return the push button in the rest position; and - resilient tilting means, to which the trainer is subjected, and which, in response to an action of the nut on it, are able, after crossing a hard point, to urge the coach towards one or the other of its stable positions and to maintain it then elastically in this one. BACKGROUND ART These switches are commonly called "push-push" or "pushdown" because, if, internally, they make it possible to perform a bistable function of change of state, by opening or closing a circuit, each time that it is acted on their push button, they behave externally, like a monostable, their push button returning each time to the initial rest position as soon as the driving action exerted on it is released, and that therefore, in order to make them pass from one state to another, it is necessary each time to act in depression, and thus in push, on the push-button. This push-button movement has the advantage that the entire surface of the push button available to the user is useful for causing the change of state of the switch while in a rocker switch alone fifty percent of the surface of the actuating finger serves for the change of state. One of the difficulties to overcome in the realization of such electrical switches lies in the guiding in translation of the nut so that the nut is positioned correctly relative to the coach, otherwise switch malfunctions are to be feared. Currently, push-push type switches already known, the push button is guided in translation in the housing by means of slides and it directly drives the nut in its translational movement. The guidance of the nut therefore passes through the guidance of the push button. It is generally accepted that, to best guide the push button, it is necessary that the guide length of the latter corresponds to twice or at least one and a half times the planned distance between the slides. This imposes specific arrangements in the switch housing whose interior volume is restricted. Such arrangements make the manufacture of the switch complex and expensive. Furthermore, document EP 0 759 205 already discloses an electrical switch as defined in the introduction in which, on the one hand, said elastic return means which tend to return said pushbutton to its rest position comprise a spring which is compressed between said drive means and the bottom of the switch housing, this spring continuously pushing said drive means towards said push button, and, on the other hand, said resilient tilting means comprise another spring which intervenes directly between the coach and the push button. In addition, in this electrical switch, it is provided that said drive means comprise a spring blade which acts directly on the nut to return said nut from the depressed position in the rest position. Such a switch is complex because it comprises a multitude of parts which each provide a function of return or tilt and pressure well determined. The multiplicity of parts leads to additional manufacturing cost of the switch. In addition, the multiplicity of parts requires placing the nut in the housing offset from the fixed contact element. The trainer then has a complex shape to be able, on the one hand, to be hooked by the nut, and on the other hand, to place the movable contact element in contact with the fixed contact element. Here, the groove or the yoke on which the trainer tilts is located in an intermediate plane located between the nut and the fixed contact element. Such an arrangement increases the total size of said switch.

OBJECT OF THE INVENTION In order to overcome the drawbacks of the state of the art, the present invention proposes an electrical switch as defined in the introduction, in which said elastic return means and said resilient tilting means are formed by a single spring. compressed between said nut and said driver. Other advantageous and non-limiting characteristics of the electrical switch according to the invention are the following: said spring permanently urges said nut towards the push-button; said drive means intervene between the push-button and the nut; - Said drive means comprise means for pivoting the nut relative to the push button, able to define at rest a centered position of the nut relative to the push button; said pivoting means are interlocking means; said drive means and said pivoting means form a single piece in one piece; - The fixed contact element, the place of attachment of the nut to the coach and the pivoting groove of the trainer are located in the same plane; said drive means comprise a pantographic displacement system adapted to produce a translation movement of the nut between said rest position and said depressed position; said drive means comprise a connecting arm whose one end is articulated on a fixed part of the switch and the other end of which is articulated on a slide which is mounted in translation in a slideway of the casing so as to produce a movement of translating said nut between said rest position and said depressed position; said drive means comprise two link arms connected to each other by a pivot axis while crossing each other and cooperating with the casing and the push button to move together in the manner of scissors; - The push button is pivotally mounted relative to the housing; the pivoting yoke which defines the axis of pivoting of said pushbutton belongs to the single piece which forms said drive means; and - the push button is mounted in translation relative to the housing. DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The description which follows with reference to the accompanying drawings, given by way of non-limiting example, will make it clear what the invention consists of and how it can be achieved. In the accompanying drawings: - Figure 1 is a perspective view of an embodiment of the electrical switch according to the invention; FIG. 2 is an exploded view of FIG. 1; FIG. 3 is a partial view of FIG. 1; FIG. 4 is a partial exploded view of an alternative embodiment of the electrical switch of FIG. 1; - Figure 5 is a sectional view along the plane A-A of Figure 1; - Figure 6 is a sectional view along the plane B-B of Figure 5; - Figure 7 is a sectional view along the plane C-C of Figure 6; FIG. 8 is a perspective view of another embodiment of the electrical switch according to the invention; Figure 9 is an exploded partial view of Figure 8; - Figure 10 is a partial view of Figure 8; - Figure 11 is an exploded partial view of another embodiment of the electrical switch according to the invention; - Figure 12 is a vertical sectional view of the switch of Figure 11; - Figures 13A to 13D show, in section, the electrical switch of Figure 1 at different stages of operation; and FIGS. 14A to 14D show, in sectional view, the electrical switch of FIG. 1 during different operating steps.

As a preliminary, it will be noted that from one figure to another, the identical or similar elements of the various embodiments of the electrical switch according to the invention will be referenced as far as possible by the same reference signs and will not be described. Everytime.

FIGS. 1 to 7 show an electrical switch 100, here a push-push switch. As will be described in detail later, if such an electrical switch makes it possible to perform a bistable function of change of state, by opening or closing a circuit, each time it is acted on its pushbutton, it behaves externally, like a monostable, its push button returning every time to the initial rest position as soon as the driving action exerted on it is released, and, consequently, to make it pass from a state to another, it is necessary each time to act in depression, and, therefore in push, on the push-button.

More particularly, here, the electrical switch 100 comprises a housing 110 made of insulating material, open at the front, which houses internally in its bottom, three electrical connection terminals 120, 130, 140 aligned along an axis X parallel to the wall housing bottom, including an input terminal 120 placed in the center and two output terminals 130,140 placed on either side of the input terminal 120 (see Figures 3 and 6). Of course, alternatively, it could be provided that the electrical switch housing houses only two connection terminals, an input terminal and an output terminal. According to the example shown, these terminals 120, 130, 140 are self-connecting terminals and each of them is associated with a disconnection lever 11 which passes through an opening 111 of the wall of the housing 110 to act on each blade connecting spring of the corresponding terminal. Each disconnect lever 11 comprises a control lever 11A accessible to the user outside said housing 110 (see Figure 1).

Each terminal 120, 130, 140 comprises a metal cage, the cage of the input terminal 120 forming in the upper part a groove 121 in V and the cage of each output terminal 130, 140 carrying in the upper part a grain of contact forming a fixed contact element 131, 141.

Here, advantageously, the bottom of the groove 121 V and the two fixed contact elements 131, 141 are located in the same plane and aligned along the X axis (see Figure 3). In addition, the electrical switch 100 comprises inside the housing 110 a driver 150 adapted to tilt or pivot between two stable positions to put in contact or out of contact a movable contact element 154, 155 with a fixed contact element 131 141. As shown more particularly in Figure 2, the driver 150 is here a metal plate, commonly called conductive brush, which is cut and folded to form a vertical central knife 151 from which extend, in contrast from each other, two flaps each carrying a platform 152, 153 horizontal. Each platform 152, 153 comprises a contact grain 154, 155, forming a movable contact element. Each contact grain 154, 155 protrudes from the face of said platform 152, 153 facing one of the two fixed contact elements 131, 141. Each platform 152, 153 has a curved portion towards the front opening of the housing 110 (opposite to its bottom wall). This bent portion of each platform 152, 153 forms a hook 152B, 153B (see Figures 2 and 6).

According to the examples shown in Figures 2 and 4, at one of its two opposite ends, the central knife 151 of the driver 150 is supported in the bottom of the groove 121 V of the input terminal 120 for, on the one hand, establish an electrical connection between the driver 150 and said terminal 120, and, on the other hand, allow the tilting or pivoting of the driver 150 about a Y axis (the longitudinal axis of said 121) coplanar and perpendicular to said axis X (see Figure 5). Advantageously, the central knife 151 comprises two feet 151A which are placed on either side of the groove 121 in V to immobilize said knife in the direction of the Y axis. At the other of its two opposite ends, the knife central 151 has a tooth 151B; 151D which protrudes from the end edge 151C of said central knife 151. According to the embodiment of the electrical switch shown in FIG. 2, this tooth 151B comes from forming with the driver 150, it is delimited by a rounded edge of the central knife 150. According to another embodiment of the electrical switch shown in Figure 4, the tooth 151D is attached astride the end edge 151C right of said central knife 151. For this, the tooth 151D has a foot 151E provided with a notch which engages on said end edge 151C.

Furthermore, the electrical switch 100 comprises a push button 190 which closes the front opening of the housing 110. This push button 190 is accessible to the user and is adapted to be moved between a rest position (see FIG. 13A). and a depressed position (see Figure 13C). According to the example shown in Figure 2, the push button 190 is adapted to be displaced in translation inside the housing 110 along an axis Z perpendicular to the X and Y axes (see Figures 5 and 6). This push button 190 comprises a wall 191, called the closing wall, which closes the front opening of the housing 110. The front face 191A of this closing wall 191 is the bearing surface of the user's finger. Here the closure wall 191 has an oblong outline, but according to other variants not shown, it can be provided that this closure wall has a rectangular shape, round or square or any other suitable form. The push-button 190 shown in FIG. 2 has at its two ends two pairs of legs 192 which extend generally perpendicularly to the rear face 191B of the closing wall 191 of the push-button 190, towards the bottom of the housing 110. Each leg 192 has at its free end a hook 192A. When the pushbutton 190 is moved in the housing 110 of the electrical switch 100, the legs 192 provided with their hook 192A engaged in the housing 110, allow to limit the output of the pushbutton 110 relative to the housing 110 by clinging by their hook 192A under the rim 115 of the housing which borders the front opening of the latter. In addition, the push button 190 has on each of the longitudinal edges of its closure wall 191 a pair of guide walls 193 facing. These guide walls 193 extend from the rear face 191B of the closure wall 191 perpendicularly thereto (see FIG. 7). The electrical switch 100 comprises a nut 160, pivotally mounted relative to the push button 190, able to act in a tilting manner on said driver 150.

The nut 160 is able to act on the driver 150 in response to a depression action exerted on the pushbutton 190 along the Z axis, thereby alternately causing the tilting of the driver 150 in one direction or in the second direction. Another way of doing this, as shown for example in Figures 2 and 6, it comprises, on its lateral sides, two legs 163, 162 which each cooperate respectively with a hook 152B, 153B of the coach 150. In practice, the jambs 162, 163 of the nut 160 extend slightly obliquely relative to each other, away from each other as and when as they get closer to the coach 150 (see Figure 6). These legs 162, 163 comprise, at their free end, nozzles 162A, 163A adapted to cooperate alternately, as will be explained in more detail later, with the hooks 152B and 153B of the coach 150. The action of the nut 160 on the trainer 150 is achieved by the alternative hooking of the nozzles 162A, 163A to the hooks 152B, 153B of the driver 150. For this cooperation to take place, there is provided in the housing 110 of the electrical switch 100, a relay between the push-button 190 and the nut 160. This relay includes drive means 180 for moving the nut 160 together with the push-button 190.

Preferably, as shown in Figures 1 to 7, said drive means are formed by a single piece, made of insulating material, a part of which is interposed between the push-button 190 and the nut 160 to intervene between these two pieces. The upper face 180A of said single piece forming said drive means 180 is permanently pressed against the rear face 191B of the closure wall 191 of the push button 190 (see FIG. 7). Said drive means 180 comprise pivoting means 187 of the nut 160 relative to the push button 190, able to define at rest a centered position of the nut 160 relative to the push button 190. Advantageously, these means of pivoting 187 are interlocking means. They comprise two parallel ribs 187A, whose outer face is rounded. These ribs 187A fit into grooves 164A of complementary rounded profile, provided at the bottom of a housing 164, open towards the front, provided at the top of the nut 160.

As will be described in more detail later, the nut 160, when it engages alternately on the hooks 152B, 153B of the driver 150 pivots on one or other of the ribs 187A of said drive means 180.

According to the embodiment of the invention shown in Figures 1 to 7, said drive means 180 comprise a pantographic displacement system adapted to produce a translational movement of the nut 160 between said rest position and said depressed position of the push-button 190. In all rigor, the movement of the nut 160 produced by the pantographic displacement system is a rotational movement that is similar to a translational movement because the arc described by the nut has a very narrow angle. weak and a large radius of curvature. As best shown in FIGS. 2, 5 and 6, the pantographic displacement system comprises two pairs of parallel vertical uprights 181, 182 which extend parallel to the translation axis Z of the nut 160 and link arms 185. 186 parallels which extend transversely of a pair of vertical uprights 181 to the other 182. Each connecting arm 185, 186 has ends hinged 185A, 186A to vertical uprights 181, 182. The pairs of uprights 181, 182 and the connecting arms 185, 186 form a deformable parallelogram in a vertical plane which contains the Z axis and which is perpendicular to the horizontal plane formed by the two axes X, Y perpendicular to each other. Each vertical upright 181 of one of the pairs of vertical uprights, comprises on an external face facing a side wall of the housing 110, on the one hand, recessed, a groove 181A engaged on a rib 116 (see FIGS. ) provided on the inner side of the side wall of the housing 110, and, on the other hand, projecting, a tooth 181B, snapped into an opening 113 of the corresponding side wall of the housing 110 (see Figures 2 and 5). Thus, each vertical upright 181 is fixedly mounted inside the housing 110.

Each vertical upright 182 of the other pair of vertical uprights, is mounted to move in translation along the Z axis inside the housing 110. Each vertical upright 182 has a projection on an outer face facing a side wall of the housing 110. , a tooth 182A engaged in an elongated opening 112 of the corresponding side wall of the housing 110 (see FIGS. 2, 5 and 7). During the translational movement of the uprights 182, the teeth 182A slide in said elongated openings 112 so as to guide the movement of said uprights. In addition, they make it possible to limit the stroke of said vertical uprights 182 in the direction of the exit of the housing, and therefore of the pantographic displacement system, while abutting against the edge of the upper end of said elongated openings 112. The free ends uprights 182 abut against interior arrangements of the housing 110 to limit the depression of the push button. Furthermore, the single piece forming said drive means 180 10 comprises two pairs of parallel walls 183 leaning against said vertical uprights 182 movable. The walls 183 of each pair define between them a housing which accommodates one of the guide walls 193 of the push-button 190. In addition, for each of the pairs, the wall 183 situated outside the pair, opposite a side wall of the housing 110, has on its outer face a recess 183A which accommodates another guide wall 193 of the push button 190 (see Figures 2 and 5). In this way, the push-button 190, in permanent support on said single piece which forms said drive means 180, is made integral with the displacement of said drive means 180. As will be described in more detail later, the depressing movement of said push button 190 then causes the translational movement of said drive means 180 with the elastic deformation of the pantographic system. These drive means 180, which cooperate via said pivoting means 187 with the nut 160, drive it and thus guide it in translation in the direction of the driver 150. Furthermore, the raising of said driving means 180 pushed by the nut 160, causes the push button 190 to rise from its depressed position to its initial rest position. Advantageously, the nut 160 is held laterally in the housing 110 by the two inner walls 183 of the two pairs of walls 183 of said drive means 180, which are placed on either side of the nut 160 (see FIG. 5). .

Furthermore, the electrical switch 100 comprises elastic return means which constantly tend to return the push button 190 in the rest position. It further comprises resilient tilting means, to which the driver 150 is subjected, and which, in response to an action of the nut 160 on the latter, are able, after crossing a hard point, to request the 150 in the direction of one or the other of its stable positions and then maintain it elastically in it. Advantageously, according to an essential characteristic of the electrical switch 100, said resilient biasing means and said resilient tilting means are formed by a single spring 170 compressed between said nut 160 and said rocking driver 150. As best shown in Figures 6 and 7, the spring 170 is a compression spring interposed between the nut 160 and the driver 150. It is supported, on the one hand, on the trainer 150 being engaged on the tooth 151B ; 151D of the central knife 151 of the driver 150, and, secondly, on the blind bottom of a recess 161 that the nut 160 forms internally between its legs 162, 163, being engaged on a centering pin 165 provided for this purpose at the bottom of this recess 161. This spring 170 has, preferably, for example, a stiffness equal to about 2.6 Newtons per millimeter. Thus, assuming that the contact force between each fixed contact element 131, 141 and each movable contact element 154, 155 is of the order of 0.1 Newton, the spring 170 is capable of producing on the The driver 150 has an evolutionary compressive force that can reach a maximum of 16 Newton when the trainer reaches his equilibrium point between his two stable positions, for a compression force exerted on the push-button 190 of the order of 19 Newton. Advantageously, said spring 170 permanently urges said nut 160 towards the push button 190. This spring 170 alone provides three different functions.

It ensures the raising of the driving means 180 from the depressed position to the rest position. Indeed, it constantly pushes the nut 160 in the direction of the push button 190, which acts directly, via said pivoting means 187 on said drive means 180. Thus, when the driving force on the nut 160 is removed, it rises under the action of return of the spring 170 and pushes said drive means 180 which then up said push button 190. It ensures the tilting of the driver 150 under the action of the nut 160. Indeed, in response to an action of the nut 160 on the driver 150, the spring 170, after crossing a hard point, biases the driver 150 towards one or the other of its stable positions and then holds it elastically in this position. In this regard, it should be emphasized that during the depression of the push button 190, the effort exerted by the spring 170 on the trainer 150 increases until it reaches its maximum at the equilibrium point of the coach 170 halfway between his two stable positions. This advantageously allows to give a maximum speed to the driver 170 when it closes the electrical circuit between the movable contact element and the fixed contact element. The movable contact element is then quickly plated on the fixed contact element and thus avoid rebound phenomena detrimental to the proper operation of the electrical switch. Finally, it ensures, in combination with said pivoting means 187, the positioning and centering of the nut 160 relative to the push button 190, by permanently exerting on said nut a pressure in the direction of the push-button 190. Advantageously, in the electrical switch 100, no resilient return or tilting means other than the spring 170 is provided. This then reduces the number of parts of the electrical switch, thus its bulk and its cost of manufacture.

In addition, the advantageous arrangement of the spring 170 makes it possible to dispose, the spring 170, each fixed contact element 131, 141, the attachment point 152B, 153B of the nut 160 to the driver as well as the throat 121 for pivoting the the coach 150 in the same plane (see Figure 5). This symmetrical arrangement is particularly advantageous because it reduces the size of the switch mechanism. FIGS. 8 to 10 show an alternative embodiment of the electrical switch 100 described above with reference to FIGS. 1 to 7. For the most part, this electrical switch 100 is identical to the previous one, which is why It will not be described here in detail, but only the characteristics which distinguish it from the latter will be described in detail. This is an electrical switch commonly called pushdown because its push button 190 'is pivotally mounted relative to the housing 110. For this, the closing wall 191' of the push button 190 'carries, at one of its ends, two parallel uprights 194 'extending from the rear face of the closure wall 191' perpendicular thereto. Each upright 194 'bears on an outer side a pin 194'A which is pivotally engaged in a bearing 188A defined in a pivoting yoke 188 fixedly mounted in the housing 110. Here, as best shown in FIGS. 9 and 10, the pivoting yoke 188 which defines the pivot axis of said push button 190 'belongs to the single piece piece which forms said drive means 180. In particular, it constitutes an extension in the direction of the push button 190' of each amount vertical 181 fixes the pantographic displacement system. At the other end, the closing wall 191 'of the push button 190' comprises, as in the embodiment described above, two parallel legs 192 'provided with the hooks 192'A limiters.

FIGS. 11 and 12 show an alternative embodiment of the electrical switch 100 described above with reference to FIGS. 8 to 10. For the most part, this electrical switch 100 is identical to the preceding one, which is why It will not be described here in detail, but only the characteristics which distinguish it from the latter will be described in detail. It is therefore also here an electrical switch commonly called push-down because its push button 190 'is pivotally mounted relative to the housing 110. The variant embodiment is located at said drive means 180' of the nuts 160, which comprise a single connecting arm 185 'whose end 185'A is articulated on a fixed part of the switch and whose other end 185'A is articulated on a slide 182'B which is mounted in translation in a slider 117 of the housing 110 so as to produce a translational movement of said nut 160 between said rest position and said depressed position. Here also said drive means 180 'are formed of a single piece.

The fixed part of the electrical switch consists of two vertical uprights 181 parallel fixedly mounted in the housing 110, as described above with reference to the first embodiment shown in Figures 1 to 7. Furthermore, the link arm 185 is articulated to the other two vertical uprights 182 parallel, movably mounted in the housing 110. Each of these uprights 182 'externally carries a slide 182'B in the form of a rib. Each slide 182'B slides in a slideway 117 provided on the inner face of a side wall of the housing 110. Each vertical upright 182 further includes a tooth 182'A which is engaged in an elongate opening 112 of the corresponding wall. 110. Each tooth 182'A limits the travel of said drive means 180 'abutting the top and bottom edges of said elongate opening 112. Referring to Figs. 13A-13D and Figs. 14A at 14D, we will describe simultaneously the operation of the push-push switch shown in FIGS. 1 to 7 and the push-down switch shown in FIGS. 8 to 10. In the initial rest position shown in FIGS. 13A, 14A, 150 is tilted in one of its stable positions in which it closes the electrical contact between the movable contact element 155 and the fixed contact element 141 integral with the output terminal 140, resting against each other. The driver 150 is held in this position by the action of pressure exerted on it by the spring 170. From this rest position of the push button 190; 190 ', the pressure of a user's finger on the front face 191A; 191'A of the closing wall 191; 191 'of the pushbutton 190; 190' causes the depression inside the housing 110 of the push-button 190; 190 'by translation (Figure 13B) or by pivoting (Figure 14B).

The driving movement of said push button 190; 190 'then causes the translation movement of said drive means 180 with the elastic deformation of the pantographic displacement system. These drive means 180, which cooperate via said pivoting means 187 with the nut 160, thus drive it in translation in the direction of the driver 150 until the nose 163A of the nut 160 catches on the hook 153B of the platform 150 of the trainer 150 (see FIGS. 13B, 14B). The finger of the user continuing to push the pushbutton 190; 190 ', the nut 160, locked in translation by the driver 150, pivots with respect to the pushbutton 190; 190 ', around one of the ribs 187A of said pivoting means 187, and causes the tilting of the driver 150 to open the contact between the fixed contact element 141 and the movable contact element 155. a hard point located vertically of the throat 121 pivoting, the spring 170 urges the central knife 151 of the trainer 150 towards the other fixed contact element 131 to close the contact between this element and the other movable contact element 154 by placing them in abutment against each other. Once the trainer 150 is tilted, the spring 170 keeps it in this position (see FIGS. 13C and 14C). When the user releases the pressure on the push-button 190; 190 ', the spring 170 which continuously pushes the nut 160 in the direction of the pushbutton 190; 190' causes the raising of said drive means 180 pushed by the nut 160 which cooperates with said pivoting means 187. The rise of said drive means 180 is effected by elastic deformation of the pantographic displacement system. Said drive means 180 in permanent contact with the push-button 190; 190 'cause in their upward movement push-button 190; 190' which is translated or which pivots from its depressed position to its initial rest position (see Figures 13D and 14D). During the ascent, said pivoting means 187 which engage said nut 160 allow under the action of pressure exerted by the spring 170 to correctly position (in particular to center) the nut 160 relative to said drive means 180 and therefore to said push button 190; 190 '. The pantographic displacement system of said drive means 180 has the advantage over other guide and displacement systems, such as the slide system shown in FIGS. 11 and 12, of guiding the nut in a very satisfactory manner over a distance. very short guide for the electrical switch to work properly.

The present invention is not limited to the embodiments described and shown, but the skilled person will be able to make any variant within his mind. According to a variant not shown, it can be provided that said drive means of the nut comprises two connecting arms connected to each other by a pivot axis by crossing and cooperating with the housing and the push-button for move together like scissors. It can also be provided that the electrical switch according to the invention comprises a single fixed contact element and a single associated movable contact element. In this case, it is expected that a single output terminal provided with said fixed contact element, the coach carrying a single mobile contact bump.

Claims (4)

REVENDICATIONS1. An electrical switch (100) having in a housing (110) - a driver (150) adapted to switch between two stable positions for contacting or disengaging a movable contact member (154,155) with a fixed contact member (131,141); - A push button (190) accessible to the user adapted to be moved between a rest position and a depressed position; a nut (160), pivotally mounted relative to the push button, adapted to act in a tilting manner on said driver; drive means (180) for moving the nut together with the push button; - Elastic return means which constantly tend to return the push button in the rest position; and resilient tilting means, to which the driver is subjected, and which, in response to an action of the nut on it, are able, after crossing a hard point, to urge the coach towards the one or the other of its stable positions and then maintain elastically therein, characterized in that said elastic return means and said resilient tilting means are formed by a single spring (170) compressed between said nut (160) and said driver (170). 2. Electrical switch (100) according to claim 1, characterized in that said spring (170) permanently urges said nut (160) in the direction of the push button (190). 3. Electrical switch (100) according to one of the preceding claims, characterized in that said drive means (180) intervene between the push button (190) and the nut (160). 4. Electrical switch (100) according to one of the preceding claims, characterized in that said drive means (180) comprise pivoting means (187) of the nut (160) relative to the push button (190). , able to define at rest a centered position of the nut with respect to the push button. . Electrical switch (100) according to the preceding claim, characterized in that said pivoting means (187) are interlocking means. 6. Electrical switch (100) according to one of the two preceding claims, characterized in that said drive means (180) and said pivot means (187) form a single piece. 7. Electrical switch (100) according to one of the preceding claims, characterized in that the fixed contact element (131,141), the place of attachment (1526, 1536) of the nut to the coach and the groove ( 121) of the driver (150) are located in the same plane. 8. Electrical switch (100) according to one of the preceding claims, characterized in that said drive means (180) comprise a pantographic displacement system adapted to produce a translational movement of the nut (160) between said position of rest and said depressed position. 9. Electrical switch (100) according to one of claims 1 to 7, characterized in that said drive means comprise a link arm (185 ') whose end is articulated on a fixed portion (181) of the switch and whose other end is articulated on a slide (182'B) which is mounted in translation in a slide (117) of the casing (110) so as to produce a translation movement of said nut (160) between said rest position and said depressed position. 10. Electrical switch according to one of claims 1 to 7, characterized in that said drive means comprise two connecting arms connected to each other by a pivot axis by crossing and cooperating with the housing and the push button to move together in the manner of scissors. 11. Electrical switch (100) according to one of claims 1 to 9, characterized in that the push button (190 ') is pivotally mounted relative to the housing (110). 12. Electrical switch (100) according to the preceding claim, characterized in that the pivoting clevis (188) which defines the pivot axis of said pushbutton (190 ') belongs to the single piece piece which forms said means of driving (180) .13. Electrical switch (100) according to one of claims 1 to 10, characterized in that the push button (190) is mounted in translation relative to the housing (110).