FR2911000A1 - Metallic contact dome for switch in motor vehicle, has contact zone whose projecting distance is such that contact zone reaches tangential plane before central projection during handling of dome by applying force towards tangential plane - Google Patents

Abstract

The dome has a bulged body obtained by cutting a metal sheet, and delimiting a contact zone (36) arranged in a plane tangential to the body. The body has a central projection (50) arranged at center of the body and remote from periphery of the body. Another contact zone (46) between the former zone and the projection is arranged in projection from a hollow side of the dome. Projecting distance of the contact zone (46) is such that the contact zone (46) reaches the tangential plane before the central projection during handling of the dome by applying a force towards the tangential plane.

Description

The present invention relates to contact domes, for example of the type

  used in keyboards, and switches with them. Contact domes are already known, used in particular in keyboards, which belong to simple switches, that is to say which open or close a single circuit under the control of an operating member. It is sometimes desirable to perform several commands with a single actuator. Thus, US-6,794,589 discloses an assembly with a plurality of electrical switches controlled by a single actuator that is pivotable; at any one of four contact elastic dome switches, only one is selected to close an associated circuit.

  It is also known from JP-2001006498, a multidirectional switch controlled by an actuator and which comprises a plurality of contact domes which are selectively manipulated. In other fields, for example in the automotive field, it is desirable to have switches with a single actuator allows the selection of several functions. For example, it is desirable that an automobile window regulator control comprises a single operating member which, in a first activation position, makes it possible to stop the window operated at any height, and, in a second position, controls the movement of the window until the end of its travel. With reference to FIGS. 1 and 2, reference is now made to such a contact dome, used especially in keyboards to open or close a circuit. FIG. 1 shows a known contact dome which has the general reference 10 and comprises a convex body 12 having at its edge a lip 14 which delimits, on the opposite side 35 to the domed top of the body, an edge 16 forming a zone of contact with a conductive track of a printed circuit for example. This ridge is almost in a plane. The center of the body comprises a projection 18 intended to come or not in contact with another conductive track of the printed circuit. This arrangement of the dome appears in Figure 2 which is a section of the dome along the line AûA of Figure 1.

  When a force is applied to the center of the body towards the plane of the edge 16, the contact 18 is applied against the conductive track of the circuit of the substrate on which is placed the dome; it departs from it as soon as the maneuvering force is eliminated, thanks to the elasticity given by the curved shape of the body 12. This curved shape has the advantage of being deformed in the opposite direction to the bulge when the force applied reaches a certain value, coming to firmly apply the central contact 18 against the antagonistic conductive track.

  This behavior is illustrated in FIG. 3 which indicates that, when the force F is applied, it causes a progressive displacement D of the central part relative to the substrate which carries the dome, and that, as soon as a certain maximum value is reached , the dome is more easily deformed by coming into contact with the antagonistic conductive part. According to the known technique, illustrated by the aforementioned documents, it is necessary to use several domes to obtain several successive contacts. Several electrical circuits are not successively closed with a single dome. The object of the invention is to perform a commutation by successive realization of two electric circuit closures having a common part with a single dome cooperating with a circuit having a plurality of conductive tracks. According to the invention, the dome comprises a convex body of which not only the peripheral part behaves like a first contact member always in contact with a track of the circuit and the central part behaves like a second contact member, but also which has a third contact member placed between the first and second contact members, the second and third contact members being controlled by different actuating forces applied by the same operating member, so that they are only temporarily in contact with a conductive track. Other contact members may also be added. More specifically, the invention relates to a contact dome, of the type which comprises a curved body cut in a metal sheet and delimiting, at its periphery or in proximity, a first contact member disposed substantially in a plane tangent to the body of the opposite side at a vertex disposed at or near the center of the body, the body having at least one second contact member disposed at or near the center of the body; according to the invention, the dome comprises, between the first contact member disposed towards the periphery and the second contact member arranged towards the center, a third contact member disposed projecting from the hollow side of the dome, the projection distance the third contact member being such that, during the operation of the dome by applying to the central portion a force directed towards the plane tangential to the periphery of the body, the third contact member reaches the tangent plane before the second member of the body; contact placed towards the center. Preferably, the periphery is substantially circular, the first contact member substantially follows an outer circle, and the third contact member substantially follows a smaller circle than the outer circle. In this case, all the contact members, with the possible exception of the second, are preferably arranged on circular arcs surrounding the curved body center. In one embodiment, the first contact member is continuous and covers more than half of the periphery of the body, and the third contact member is also continuous. In another embodiment, the first contact member is discontinuous and comprises at least three contact zones formed at the free end of at least three arms obtained by cutting the metal sheet at its periphery.

  In a variant, the third contact member comprises at least two contact zones formed at the free end of at least two arms obtained by cutting the metal sheet between the center and the periphery.

  In examples, the dome comprises stiffness-modifying members, for example slits cut into the metal sheet of the dome, or deformations of this sheet. According to an improvement, the dome comprises a plurality of third contact members offset between the first and second contact members. The invention also relates to a metal dome switch, which comprises a dome according to one of the preceding paragraphs, so that it successively closes two electrical circuits by contacting a third and a second contact member. with a substrate with which a first contact member is always in contact. Other features and advantages of the invention will be better understood on reading the following description of embodiments, with reference to the accompanying drawings, in which, FIGS. 1, 2 and 3 have already been described: Figure 4 is a plan view of a contact dome in an embodiment of the invention; Figure 5 is a section along line B-B of Figure 3; Fig. 6 is a movement-driving force graph illustrating the operation of the dome shown in Figs. 4 and 5, showing only, as in Fig. 3, the force application portion, and not its reduction; Figure 7 is a perspective view of a switch made according to the invention, successively closing two electrical circuits, the dome being of the type with elastic arms; Figure 8 is similar to Figure 7, but has torn portions clearly indicating the arrangement of the conductive tracks of the switch substrate; and Figs. 9, 10 and 11 are sections showing the dome arrangement of Figs. 7 and 8 successively when no closing, first closing and first and second circuit closures are respectively performed. Figure 4 shows in plan a dome according to the invention, having the same arrangement as that of Figure 1 to be compared. This dome 20 has a curved body 22, 23 having a peripheral lip 24 defining a first contact member 26 disposed on a circular arc which covers about 220 '. The member 26 is intended to be held in contact with a conductive track of a substrate on which the dome is placed. A central projection 28 constitutes a second contact member intended to come into contact with another conductive track of the substrate on which the dome is placed, when a sufficient maneuvering force is applied thereto. According to the invention, the domed body comprises two parts 22, 23 which have different curvatures and are separated by an edge 29 which constitutes a third contact member. The curvature of the portion 23 is greater than that of the portion 22. Accordingly, when a force is applied to the center of the dome, it is deformed until the edge 29 comes into contact with a conducting track of the substrate. At this time, the central projection 28, forming the second contact member is always distant from the substrate. An additional force is therefore necessary for this second contact member 28 of the central part to come against a conductive track of the substrate. Figure 6 illustrates this behavior. When a force is applied progressively, the dome has a certain displacement up to a certain force at which the portion 22 of the domed body has a turnaround so that the displacement increases rapidly until contact of the rib 29 with the associated conductive range of the substrate. Then, the continuation of the application of a force brings about the approaching of the second central contact member 28, so that the central part 23 of the curved body presents turns when a certain force is reached, and ensures a second closing of electrical circuit. A dome has been described in which the curved body has only two concentric portions 22, 23. It is obviously conceivable to make a larger number of concentric parts intended to be successively ordered. The limit of this number is determined by the size of the dome. The gradation of the operating forces of the different concentric parts can be controlled either by weakening of too rigid parts, for example by forming cuts or by reducing thickness, or by increasing the rigidity of too flexible parts, for example by creating deformations , such as ridges, substantially radially. Figures 7 to 11 show another example of a dome according to the invention for closing successively two electrical circuits. The dome is of the type in which contact zones are formed at the ends of flexible arms. In FIGS. 7 to 11, reference numeral 30 denotes the entire dome which comprises a convex body having four outer arms 32 which each delimit, by a lip 34, a contact zone 36 with a conductive track 38 of a substrate 40 bearing several conductive tracks. In the embodiment shown, the dome comprises four arms 32. The contact zones 36 of the four arms constitute the first contact member placed at the periphery in permanent contact with a conductive track of the substrate.

  The arms are arranged outside a circle 42 inside which is formed, in the same sheet, a structure constituting a second dome having itself arms 44 whose outer ends form contact zones 46 intended to to come into contact with another conductive track 48 of the substrate 40. These contact areas 46 constitute the third contact member according to the invention.

  A central deformation 50 is intended to come into contact with a conductive track 52, and constitutes the second contact member according to the invention. Figures 9 to 11 indicate the positions of this dome 30 when it is subjected to the application of a maneuvering force that tends to crush. In the position of FIG. 9, only the first peripheral contact member, formed by the end contact zones 36 of the arms 34, is in contact with the conductive track 38 of the substrate 40. The contact zones 46 of the arm 44, which constitutes the third contact member, and the central projection 50, which constitutes the second contact member, are spaced apart from their respective conductive track 48, 52.

  In the position of Figure 10, in which a moderate force is applied to the dome, the contact areas 46 formed at the ends of the inner arms 44 have come against the conductive track 48, so that an electrical circuit is closed between the tracks. 38 and 48. On the other hand, the second contact member formed by the central projection 50 is always remote from the conductive track 52 of the substrate 40. The electrical circuit is therefore open between this track 52 and each of the other tracks 38 and 48. the position of Figure 11, in which a higher force is applied to the dome, the second contact member consisting of the projection 50 has come against the central conductive track 52 of the substrate 40, so that the three conductive tracks 38, 48 , 52 are at the same potential, and two circuits are closed.

  Although an embodiment has been described in which there is a first contact member formed by the contact zones 36 of the outer arms 32, a second contact member formed by the central projection 50 and a third contact member formed by the contact areas 46 of the ends of the intermediate arms 44, it is possible to incorporate a plurality of third staged contact members between the first contact member placed at the periphery and the second contact member placed in the center. These third contact members may comprise arms, as indicated in FIGS. 7 and 8, or have a circular shape as shown in FIG. 3. The examination of FIGS. 7 and 8 shows that there are a large number of of parameters that can be used for gradation of the forces with which successive circuit closings are obtained. Such parameters are, for example, the length of the arms 32, 44, the width of these arms, their distance from the center, etc., without it being necessary to resort to localized cuts or localized deformations of the sheet forming the metal dome for this purpose. However, such cuts and deformations can be used as appropriate. Although domes whose shape is in a circle have been described, other non-circular shapes are possible. The realization of a dome as shown in FIGS. 7 to 11 requires only the addition of simple tooling in the dome production line, without modifying the sheet used or reducing the production rate. The cost of these domes integrated in switches is therefore of the same order of magnitude as that of the domes integrated in simple switches. Since the production of three or more conductive tracks instead of only two on a printed circuit corresponds only to a negligible cost increase, a switch providing consecutive closures of at least two circuits has substantially the same cost. than a simple switch that closes only one circuit. The invention therefore makes it possible to produce switching elements of particularly low cost, particularly of interest for large-scale production, for example for the control of motor vehicle circuits.

Claims (10)

  A contact dome of the type comprising a domed body cut from a metal foil and defining, at its periphery or near, a first contact member (26, 36) disposed substantially in a plane tangential to the body of the opposite side to a vertex disposed at or near the center of the body, the body having at least one second contact member (28, 50) disposed at or near the center of the body at a distance from its periphery, characterized in that it comprises, the first contact member (26, 36) disposed towards the periphery and the second contact member (28, 50) arranged towards the center, a third contact member (29, 46) projecting from the hollow side of the dome the projection distance of the third contact member (29, 46) being such that, during the operation of the dome by applying to the central part a force directed towards the plane tangential to the periphery of the body, the third member contact (29, 46) reaches this p lan tangent before the second contact member (28, 50) placed towards the center.   Contact dome according to claim 1, characterized in that its periphery is substantially circular, the first contact member (26, 36) substantially follows an outer circle, and the third contact member (29, 46) substantially follows a circle smaller than the outer circle.   3. Contact dome according to one of claims 1 and 2, characterized in that all the contact members, with the possible exception of the second (28, 50), are arranged on circular arcs surrounding the center of the body bomb.   4. Contact dome according to any one of claims 1 to 3, characterized in that the first contact member (26) is continuous and covers more than half of the periphery of the body, and the third contact member (29 ) is also continuous.   5. Contact dome according to any one of claims 1 to 3, characterized in that the first contact member (36) is discontinuous and comprises at least three contact zones formed at the free end of at least three arms (32) obtained by cutting the metal foil at its periphery.   6. Contact dome according to claim 5, characterized in that the third contact member (46) comprises at least two contact zones formed at the free end of at least two arms (44) obtained by cutting of the metal sheet between the center and the periphery.   7. Contact dome according to any one of the preceding claims, characterized in that it comprises stiffness modifying members.   8. Contact dome according to claim 7, characterized in that the stiffness modifying members are selected from slits cut in the dome sheet, and deformations of the dome sheet. 15   9. Contact dome according to any one of the preceding claims, characterized in that it comprises a plurality of third contact members offset between the first and the second contact member.   10. Metal dome switch, characterized in that it comprises a dome according to any one of the preceding claims, so that it successively closes two electric circuits by contacting a third (29, 46), then a second (28, 50) contact member with a substrate with which a first contact member (26, 36) is always in contact.