JP4731465B2 - Switch device - Google Patents

Description

  The present invention relates to a contact structure of a switch device in which ON / OFF is switched by operating along an orthogonal coordinate axis.

  A switch module for operating the power mirror device is disposed on an armrest, a front panel, or the like of a driver's seat of an automobile. This switch module is provided with a switch device for adjusting the viewing angle of the left and right side mirrors. Generally, this switch device is composed of a four-way switch capable of switching (switching between ON and OFF states) corresponding to the four directions of upper, lower, left, and right (see, for example, Patent Documents 1 to 4 below). .

  Patent Documents 1 and 2 disclose a structure that realizes switching in four directions by selectively switching and driving three switch elements by using four operation parts of an operation member and four spring parts of a rubber spring. ing. The switch element includes a substrate, a fixed contact provided on the substrate, a slider that slides on the substrate, and a movable contact provided on the slider. In such a structure, one or two sliders and movable contacts slide on the fixed contact depending on the position at which the operation member is pushed, so that a difference occurs in the click characteristics, and the operation feels uncomfortable. Therefore, in order to make the click feeling uniform, in Patent Document 1, the inclination angle of the operation part facing the spring part without the switch element is made larger than the inclination angle of the operation part facing the spring part with the switch element. . In patent document 2, one click rate is made higher than the other click rate among two spring parts which move two movable contacts simultaneously. However, even in this case, due to the size of each part and assembly errors, there is a possibility that the force required for the operation and the click characteristics differ depending on the position where the operation member is pressed, and the operation may feel uncomfortable. Moreover, in the switch apparatus of patent document 1 and 2, it is necessary to selectively switch three switch elements, and a structure becomes complicated.

  In Patent Document 3, a pair of movable contacts is configured to be operated along an orthogonal coordinate inclined by 45 ° with respect to the alignment direction, and four single-pole single-throw switches are configured with a pair of movable contacts and six fixed contacts. A contact structure of a switch that exhibits an equivalent switching function is disclosed. Patent Document 4 discloses a structure that realizes switching in four directions by providing two pairs of movable contacts and providing four sets of fixed contact patterns consisting of four fixed contacts facing each other through an origin on an orthogonal coordinate axis. Has been.

  In the case of the structure of Patent Document 4, when each movable contact is slid in one direction along the orthogonal coordinate axis on the fixed contact, the four movable contacts and the four fixed contacts are simultaneously in contact with each other. On the electric circuit, for example, as shown in FIG. 8, eight switches Sa to Sh are provided. FIG. 8 is an electric circuit diagram of a conventional power mirror device. In FIG. 8, the portion surrounded by the alternate long and short dash line is a switch module for the power mirror device. Four parts surrounded by a two-dot chain line are switch devices for adjusting the viewing angle of the side mirror. The switches Sa to Sh include the movable contact and the fixed contact described in Patent Document 3 or Patent Document 4 described above. The switches Sa and Sb are used to tilt the side mirror upward and open and close simultaneously. The switches Sc and Sd operate to tilt the side mirror downward and open and close at the same time. The switches Se and Sf are used to tilt the side mirror to the left and open and close at the same time. The switches Sg and Sh are used to tilt the side mirror to the right and open and close at the same time. C is a connector terminal. Sx and Sy are switches for switching the object of viewing angle adjustment to either the left side mirror or the right side mirror. The switches Sx and Sy open and close simultaneously. M1 is a motor that tilts the left side mirror up and down. M2 is a motor that tilts the left side mirror to the left and right. M3 is a motor that tilts the right side mirror up and down. M4 is a motor that tilts the right side mirror to the left and right. Switches Sb, Sd, Sf, and Sh open and close a circuit that allows current to flow from power supply ACC to motors M1 to M4. The switches Sa, Sc, Se, and Sg open and close a circuit that allows current to flow from the motors M1 to M4 to the ground GND. The switches Sx and Sy open and close both the circuits.

  For example, when each of the movable contacts is slid in one direction along the orthogonal coordinate axis corresponding to the upward direction of the side mirror in a state where the switches Sx and Sy are in contact with the contact on the left side and turned on as indicated by a broken line, the switch As shown by broken lines, Sa and Sb come into contact with the contact point to be turned on, and a current flows from the power supply ACC to the upper and lower motors M1 for the left side mirror, and a current flows from the upper and lower motors M1 to the ground GND. The circuit is closed. As a result, a current flows from the top to the bottom of the vertical motor M1, and the left side mirror tilts upward. In addition, when the movable contacts are slid in one direction along the orthogonal coordinate axis corresponding to the right direction of the side mirror while the switches Sx and Sy are in contact with the right contact as shown by the broken line and turned on, the switch As shown by the broken lines, Sg and Sh are in contact with the contact point and are turned on, and a circuit for supplying current from the power supply ACC to the right and left motor M4 for the right side mirror, and a circuit for supplying current from the left and right motor M4 to the ground GND And are closed. As a result, current flows from the bottom to the top of the left and right motor M4, and the right side mirror tilts to the right.

Japanese Patent No. 3766251 Japanese Patent No. 3766252 Japanese Patent No. 2500445 JP 2002-245901 A

  An object of the present invention is to provide a switch device in which the force required for operation in each direction is made uniform and the structure is simplified.

  The present invention includes a movable piece provided with a movable contact group, a plurality of sets of fixed contacts and a substrate provided with a plurality of sets of common contacts corresponding thereto, and the fixed contacts are normally closed fixed contacts and normally open fixed contacts. The movable contact group and the plurality of sets of fixed contacts are brought into contact or non-contact state by operating the movable piece and sliding the movable contact group on the plurality of sets of fixed contacts. In a switch device that realizes ON or OFF of a switch by always bringing a group and a plurality of sets of common contacts in contact, the fixed contact is on both axes of the orthogonal coordinates with the normally closed fixed contact and the normally open fixed contact It is arranged so as to face each other across the origin, and a set of normally closed fixed contacts also provided on the origin is arranged in three sets, and the movable contact group consists of two provided on one conductor Three sets of movable contacts are arranged. And one of the two movable contacts of each conductor is provided so as to be in contact with each fixed contact, and is in contact with the normally closed fixed contact or the normally open fixed contact as the movable contact group slides. The other movable contact is always provided so as to contact the common contact, and the arrangement of the normally closed fixed contact and the normally open fixed contact is different for each fixed contact.

  According to the above, by operating the movable piece, the movable contact group, that is, all the movable contacts are slid on the fixed contact and the common contact, and the contacts are brought into contact or non-contact state, and the switch is turned on or off. Therefore, the structure is simplified and is not affected by the size of each part or assembly error, and the force required when operating the movable piece in each of the four directions along the orthogonal coordinate axes can be made uniform. I don't feel uncomfortable.

  Moreover, in one Embodiment of this invention, a movable contact group is provided in one movable piece in the said switch apparatus. As a result, the movable contact group is integrated into one movable piece, and the assembly accuracy of the movable contact, the movable piece, and these and other parts is increased, the number of assembly steps is reduced, and the assemblability can be improved.

  Furthermore, in one embodiment of the present invention, in the above switch device, a guide for moving the movable piece along both axes of orthogonal coordinates is provided. Thereby, it is possible to reliably prevent the movable piece and the movable contact group from moving in a direction deviating from the orthogonal coordinate axis, and it is possible to reliably switch the switch on or off.

  According to the present invention, by operating the movable piece, all the movable contacts are slid on the fixed contact and the common contact, and the switch is turned on or off. Therefore, the force required when operating the movable piece in each direction Can be made uniform and the structure can be simplified.

  1 and 2 are perspective views of an in-vehicle switch module 100. FIG. The switch module 100 operates the power mirror device, and is disposed on the armrest of the driver's seat of the automobile. At the front of the switch module 100, switch devices 10, 20, and 30 are provided. 3A and 3B are cross-sectional views of the switch module 100 and the switch device 10. Specifically, FIGS. 3A and 3B show a state in which longitudinal sections of the switch module 100 and the switch device 10 are viewed from the switch devices 20 and 30 side. The switch device 10 comprises a four-way switch, and adjusts the viewing angle of the left and right side mirrors of the automobile. The switch device 10 constitutes an embodiment of the switch device in the present invention. The switch device 20 is composed of a slide switch, and switches the side mirror that is the object of viewing angle adjustment. The switch device 30 is formed of a push switch, and raises or falls the left and right side mirrors.

  As shown in FIG. 3A, the lower side of the case 41 of the switch module 100 is opened, and is closed by fitting the cover 42. A substrate 8 is provided in the case 41. The substrate 8 is supported from above and below by a case 41 and a cover 42. As shown in FIG. 2, a slide type switch 24 of the switch device 20, a push-in type switch 34 of the switch device 30, and other electronic components and electric circuits (not shown) are mounted on the substrate 8. The lower end of the operation shaft 22 is engaged with the actuator 23 of the switch 24. The operation shaft 22 passes through a cylinder 44 (FIG. 1) provided in the case 41 and projects on the case 41. An operation knob 21 is attached to the upper end of the operation shaft 22 so as to cover the upper opening of the tube 44. By operating the operation knob 21 to the left and right L, R (the direction R that is away from the switch device 30), the actuator 23 is pulled by the operation shaft 22 and moves to the left and right L, R. The ON / OFF state is switched, and the viewing angle adjustment target becomes the left side mirror or the right side mirror. The actuator 33 of the switch 34 passes through a cylinder 45 (FIG. 1) provided in the case 41 and projects on the case 41. An operation knob 31 is attached to the upper end of the actuator 33 so as to cover the upper opening of the cylinder 45. By pushing the operation knob 31 downward, the actuator 33 is pushed into the switch 34, the ON / OFF state of the switch 34 is switched, and the left and right side mirrors stand or fall.

  As shown in FIG. 3A, cylinders 43 and 46 are provided so as to communicate with the upper portion and the inside of the case 41. On the inner surface of the tube 43, a sash 43 a is provided. The operation shaft 2 passes through the cylinders 43 and 46 and protrudes to the upper part and the inside of the case 41. An operation knob 1 is attached to the upper end of the operation shaft 2 so as to cover the upper opening of the cylinder 43. On the upper surface of the operation knob 1, four triangular marks 1U, 1D, 1L, and 1R are provided as shown in FIGS. The mark 1U on the front U side points in a direction corresponding to the upward direction of each side mirror. A mark 1D on the rear D side indicates a direction corresponding to the downward direction of each side mirror. A mark 1L on the left L side indicates a direction corresponding to the left direction of each side mirror. A mark 1R on the right R side indicates a direction corresponding to the right direction of each side mirror.

  A collar 3 is attached to the center of the operation shaft 2. As shown in FIG. 3A, a coil spring 4 is provided around the operation shaft 2 between the collar 3 and the hook 43a. The coil spring 4 pushes the collar 3 and the hook 43a away from each other. When the coil spring 4 presses the flange 3 and the hook 43a, the stepped portion 2a provided on the operation shaft 2 is engaged with the hook 43a, and the operation shaft 2 is held in a posture perpendicular to the substrate 8. A lower end portion of the operation shaft 2 passes through a hole 5 a provided in the guide 5 and is fitted into a hole 6 a provided in the movable piece 6. As shown in FIG. 2, the hole 5a of the guide 5 is formed on an orthogonal coordinate axis extending to the front U, the rear D, the left L, and the right R. As shown in FIG. 3A, the guide 5 is supported from above and below by a step surface 46 a provided on the cylinder 46 and a protrusion 6 b provided on the movable piece 6. Further, the movement of the guide 5 is restricted by the side wall of the tube 46 so that it cannot move in parallel with the substrate 8.

  When one of the marks 1U, 1D, 1L, and 1R on the upper surface of the operation knob 1 is pressed with a finger, the operation knob 1 and the operation shaft 2 are moved to the marks 1U, 1D, 1L, and 1R as shown in FIG. 3B. A certain front U, rear D, left L, or right R is tilted, and the movable piece 6 moves in parallel to the substrate 8 in the opposite direction. That is, the movable piece 6 is operated in any of the four directions U, D, L, and R along the orthogonal coordinate axes. FIG. 3B shows a state where the position of the mark 1R of the operation knob 1 is pressed, the operation knob 1 and the operation shaft 2 are tilted in the R direction, and the movable piece 6 is moved and operated in the L direction. At the time of the above operation, the guide 5 guides the movable piece 6 to move by tilting the operation knob 1 and the operation shaft 2 in either the front, rear, left, or right direction. The amount of tilt of the operation knob 1 and the operation shaft 2 and the amount of movement of the movable piece 6 are limited by the lower end surface 1 a of the operation knob 1 contacting the step surface 43 b of the cylinder 43 of the case 41. When the push operation of the operation knob 1 is released, the operation knob 1, the operation shaft 2, and the movable piece 6 are restored to the original neutral state by the force of the coil spring 4 as shown in FIGS. 1, 2, and 3A. .

  FIG. 4 is a view of the vicinity of the movable piece 6 in the neutral state (the state shown in FIG. 3A) as viewed from above (the operation knob 1 side). 5A to 5E are diagrams showing contact states of the contact provided on the movable piece 6 and the substrate 8. The movable piece 6 is made of synthetic resin. As shown in FIG. 4, the movable piece 6 is provided with three conductors 71 to 73 having spring properties. The substrate 8 is made of glass epoxy resin or the like. On the substrate 8, a plurality of sets of fixed contacts 81 to 83 and a plurality of sets of common contacts 84 to 86 corresponding thereto are provided. The movable contacts 81 to 83 and the common contacts 84 to 86 are formed of conductors. The fixed contacts 81 to 83 include a normally closed fixed contact NC and a normally open fixed contact NO as shown in FIG. 5A. Specifically, the fixed contacts 81 to 83 have their origins on the axes of the orthogonal coordinates of the normally closed fixed contact NC and the normally open fixed contact NO (shown by a dashed line only at the position of the fixed contact 81 in FIG. 5A). Three sets are arranged in the left and right directions L and R, with one set having a normally closed fixed contact NC disposed on the origin as opposed to the other. That is, each of the fixed contacts 81 to 83 has three normally closed fixed contacts NC and two normally open fixed contacts NO. In each of the fixed contacts 81 to 83, the three normally closed fixed contacts NC are continuous, and the two normally open fixed contacts NO are continuous. Further, the arrangement of the normally closed fixed contact NC and the normally open fixed contact NO is different for each of the fixed contacts 81 to 83. Each of the common contacts 84 to 86 is provided so as to extend along both axes of orthogonal coordinates. The common contacts 84 to 86 are arranged in the left and right directions L and R on the rear D side of the fixed contacts 81 to 83.

  Each conductor 71-73 of the movable piece 6 is formed in the shape as shown in FIG. FIG. 6 is a cross-sectional view of the conductors 71 to 73 in the U and D directions. Each of the conductors 71 to 73 is provided with two movable contacts 7a to 7f protruding downward. That is, the movable contact groups 7a to 7f are configured by arranging three sets of two movable contacts provided on one conductor as one set. The movable contact groups 7a to 7f protrude downward from the movable piece 6 and are in contact with the substrate 8 at a predetermined pressure. When the movable piece 6 is operated in any of the front U, rear D, left L, and right R directions, the movable contact groups 7a to 7f are moved on the fixed contacts 81 to 83 and the common contacts 84 to 86, respectively. Slide in the same direction. Of the two movable contacts 7a to 7f of the conductors 71 to 73, the movable contacts 7a, 7c and 7e on the front U side are provided so as to be in contact with the fixed contacts 81 to 83, and the movable contact groups 7a to 7f. With the sliding of 7f, the contact state with the normally closed fixed contact NC or the normally open fixed contact NO is switched. The rear D-side movable contacts 7b, 7d, and 7f are provided so as to always contact the respective common contacts 84 to 86. With such a structure, on the electric circuit, the switch 71 is constituted by the conductor 71, the movable contacts 7a and 7b, the fixed contact 81, and the common contact 84. The conductor S, the movable contacts 7c and 7d, the fixed contact 82, and the common contact 85 constitute a switch S2. Further, the switch 73 is constituted by the conductor 73, the movable contacts 7e and 7f, the fixed contact 83, and the common contact 86.

  FIG. 7 is an electric circuit diagram of the power mirror device operated by the switch module 100. In the drawing, the illustration of the configuration of a switch device, a motor, and the like for raising or lowering the side mirror is omitted. The part surrounded by the alternate long and short dash line is the switch module 100. Three portions surrounded by a two-dot chain line are the above-described three switches S <b> 1 to S <b> 3 provided in the switch device 10. C is a connector terminal. Sx and Sy are switches for switching the object of viewing angle adjustment to either the left side mirror or the right side mirror. The switches Sx and Sy are provided in the switch device 20 and open and close at the same time. M1 is a motor that tilts the left side mirror up and down. M2 is a motor that tilts the left side mirror to the left and right. M3 is a motor that tilts the right side mirror up and down. M4 is a motor that tilts the right side mirror to the left and right.

  As shown in FIGS. 1, 2, 3A, and 5A, when the switch devices 10 and 20 are in a neutral state, the switches S1 to S3, Sx, and Sy of the switch module 100 are indicated by solid lines in FIG. Is in the OFF state. The left and right side mirrors are erected by operating the switch device 30. From this state, when the operation knob 21 of the switch device 20 is slid in either the left L or right R direction, the switches Sx and Sy come into contact with either the left or right contact as shown by the broken line. Become. Further, when any one of the marks 1U, 1D, 1L, and 1R on the upper surface of the operation knob 1 of the switch device 10 is pushed with a finger, the operation knob 1 and the operation shaft 2 are moved forward U and rear as shown in FIG. 3B. D, left L or right R is tilted in any direction, the movable piece 6 moves in the opposite direction, and the movable contact groups 7a-7f slide on the fixed contacts 81-83 and the common contacts 84-86. Move. Then, the contact state between the movable contact groups 7a to 7f and the fixed contacts 81 to 83 changes, and the ON / OFF states of the switches S1 to S3 are switched.

  Specifically, when the position of the mark 1U of the operation knob 1 is pressed with a finger, the operation knob 1 and the operation shaft 2 are tilted forward U, the movable piece 6 is moved rearward D, and the movable contact groups 7a to 7 7f slides on the fixed contacts 81-83 and the common contacts 84-86. 5B, the movable contact 7a contacts the normally open fixed contact NO of the fixed contact 81, the movable contacts 7c, 7e contact the normally closed fixed contact NC of the fixed contacts 82, 83, the movable contact 7b, 7d and 7f are in contact with the common contacts 84 to 86. Then, in FIG. 7, the switch S1 comes into contact with the normally open fixed contact NO as indicated by a broken line and is turned on, and the switches S2 and S3 are brought into the OFF state while being in contact with the normally closed fixed contact NC as shown by a solid line. . As a result, the current flows from the power source ACC through the normally open fixed contact NO of the switch S1 and the common contact 84 to the upper and lower motors M1 and M3 from the top to the bottom, and either the left or right contact of the switch Sx and the switch It flows to the ground GND through the common contact 86 of S3 and the normally closed fixed contact NC. For this reason, one of the left and right side mirrors tilts upward.

  Further, when the position of the mark 1D of the operation knob 1 is pushed with a finger, the operation knob 1 and the operation shaft 2 are inclined to the rear D side, the movable piece 6 is moved to the front U side, and the movable contact groups 7a to 7f are fixed. Slide on contacts 81-83 and common contacts 84-86. As shown in FIG. 5C, the movable contact 7a contacts the normally closed fixed contact NC of the fixed contact 81, the movable contacts 7c and 7e contact the normally open fixed contact NO of the fixed contacts 82 and 83, and the movable contact 7b, 7d and 7f are in contact with the common contacts 84 to 86. Then, in FIG. 7, the switch S1 is in the OFF state while being in contact with the normally closed fixed contact NC as indicated by a solid line, and the switches S2 and S3 are in contact with the normally open fixed contact NO and are in the ON state as indicated by a broken line. . As a result, the current flows from the power source ACC through the normally-open fixed contact NO of the switch S3, the common contact 86, and the left and right contacts of the switch Sx to the upper and lower motors M1 and M3 from the bottom to the top. It flows to the ground GND through the common contact 84 of S1 and the normally closed fixed contact NC. For this reason, one of the left and right side mirrors tilts downward.

  When the position of the mark 1L of the operation knob 1 is pushed with a finger, the operation knob 1 and the operation shaft 2 are tilted to the left L side, the movable piece 6 is moved to the right R side, and the movable contact groups 7a to 7f are fixed. Slide on contacts 81-83 and common contacts 84-86. As shown in FIG. 5D, the movable contacts 7a and 7e are in contact with the normally open fixed contact NO of the fixed contacts 81 and 83, the movable contact 7c is in contact with the normally closed fixed contact NC of the fixed contact 82, and the movable contacts 7b, 7d and 7f are in contact with the common contacts 84 to 86. Then, in FIG. 7, the switches S1 and S3 are in contact with the normally open fixed contact NO as shown by the broken line and are turned on, and the switch S2 is in the OFF state while being in contact with the normally closed fixed contact NC as shown by the solid line. . As a result, the current flows from the power source ACC through the normally open fixed contact NO of the switch S3, the common contact 86, and the left and right contacts of the switch Sx to the left and right motors M2 and M4 from the bottom to the top, It flows to the ground GND through one of the left and right contacts of the switch Sy, the common contact 85 of the switch S2, and the normally closed fixed contact NC. For this reason, one of the left and right side mirrors tilts to the left.

  Further, when the position of the mark 1R of the operation knob 1 is pushed with a finger, the operation knob 1 and the operation shaft 2 are tilted to the right R side, the movable piece 6 is moved to the left L side, and the movable contact groups 7a to 7f are fixed. Slide on contacts 81-83 and common contacts 84-86. As shown in FIG. 5E, the movable contacts 7a and 7e are in contact with the normally closed fixed contact NC of the fixed contacts 81 and 83, the movable contact 7c is in contact with the normally open fixed contact NO of the fixed contact 82, the movable contact 7b, 7d and 7f are in contact with the common contacts 84 to 86. Then, in FIG. 7, the switch S2 comes into contact with the normally open fixed contact NO as shown by a broken line and is turned on, and the switches S1 and S3 come into the off state while being in contact with the normally closed fixed contact NC as shown by a solid line. . As a result, the current flows from the power source ACC through the normally open fixed contact NO of the switch S2, the common contact 85, and the left and right contacts of the switch Sy to the left and right motors M2 and M4 from the top to the bottom. It flows to the ground GND through one of the left and right contacts of Sx, the common contact 86 of the switch S3, and the normally closed fixed contact NC. For this reason, one of the left and right side mirrors tilts to the right.

  When the push operation of the operation knob 1 is released, the operation knob 1, the operation shaft 2, and the movable piece 6 are restored to the original neutral state by the force of the coil spring 4 as shown in FIGS. 1, 2, and 3A. The movable contact groups 7a to 7f slide on the fixed contacts 81 to 83 and the common contacts 84 to 86, and return to the original contact state as shown in FIGS. 4 and 5A.

  According to the above, by moving the movable piece 6 in the four directions of the front U, the rear D, the left L, or the right R along the orthogonal coordinate axis by the operation knob 1 and the operation shaft 2, all the movable contacts 7a˜ 7f can be slid on the fixed contacts 81 to 83 and the common contacts 84 to 86 to bring the contacts into contact or non-contact, and the switches S1 to S3 can be switched ON or OFF. That is, when the movable piece 6 is moved in each of the four directions U, D, L, and R, the number of movable contacts 7a to 7f that slide on the fixed contacts 81 to 83 and the common contacts 84 to 86 is always six. And, it does not change like the structure of the conventional patent documents 1 and 2. For this reason, the structure is simplified, and it is not affected by the size of each part or assembly error, and the force and the click feeling required when operating the movable piece 6 in each of the four directions U, D, L, and R are made uniform. It becomes possible, and the operation does not feel strange.

  Moreover, since the movable contact groups 7a to 7f are provided and integrated on one movable piece 6, the assembly accuracy of the conductors 71 to 73 provided with the movable contacts 7a to 7f, the movable piece 6, and these and other parts is increased. As a result, the number of assembling steps is reduced, and the assembling property can be improved.

  Further, since the guide 5 for moving the movable piece 6 along both axes of the orthogonal coordinates is provided, the movable piece 6 and the movable contact groups 7a to 7f are reliably prevented from moving in a direction deviating from the orthogonal coordinate axes. Therefore, it is possible to ensure the ON / OFF switching of the switches S1 to S3.

  In the embodiment described above, the example in which the present invention is applied to the switch device 10 for adjusting the viewing angle of the side mirror combined with the power mirror device of the automobile has been described. However, the present invention is a switch used for other purposes. The present invention can also be applied to an apparatus.

It is a perspective view of the switch module concerning an embodiment. It is a perspective view of the switch module concerning an embodiment. It is sectional drawing of the switch apparatus which concerns on embodiment. It is sectional drawing of the switch apparatus which concerns on embodiment. It is a vicinity view of the movable piece of the switch device according to the embodiment. It is a contact state figure of the contact of the switch device concerning an embodiment. It is a contact state figure of the contact of the switch device concerning an embodiment. It is a contact state figure of the contact of the switch device concerning an embodiment. It is a contact state figure of the contact of the switch device concerning an embodiment. It is a contact state figure of the contact of the switch device concerning an embodiment. It is sectional drawing of the conductor of the switch apparatus which concerns on embodiment. It is an electric circuit diagram of the power mirror device according to the embodiment. It is an electric circuit diagram of the conventional power mirror device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Operation knob 2 Operation shaft 5 Guide 6 Movable piece 7a-7f Movable contact 8 Substrate 10 Switch device 71-73 Conductor 81-83 Fixed contact 84-86 Common contact NC Normally closed stationary contact NO Normally open stationary contact S1-S3 switch

Claims (3)

A movable piece provided with a movable contact group, a plurality of sets of fixed contacts, and a substrate provided with a plurality of sets of common contacts corresponding thereto, the fixed contacts comprising a normally closed fixed contact and a normally open fixed contact. The movable contact group and the plurality of sets of fixed contacts are brought into a contact or non-contact state by operating the movable piece and sliding the movable contact group on the plurality of sets of fixed contacts. In the switch device that achieves ON or OFF of the switch by always bringing the movable contact group and the plurality of sets of common contacts into contact with each other,
The fixed contact is a pair of a normally closed fixed contact and a normally open fixed contact arranged on both sides of an orthogonal coordinate so as to face each other across the origin, and the normally closed fixed contact is also provided on the origin. As a result, three sets are arranged,
The movable contact group is formed by arranging three sets of two movable contacts provided on one conductor as one set,
Of the two movable contacts of each of the conductors, one movable contact is provided so as to contact each of the fixed contacts, and the normally closed fixed contact or the normally open fixed contact as the movable contact group slides. The contact with the other is switched, the other movable contact is always provided to contact the common contact,
An arrangement of the normally closed fixed contact and the normally open fixed contact is different for each of the fixed contacts. The switch device according to claim 1,
The movable contact group is provided on one movable piece. The switch device according to claim 1,
A switch device comprising a guide for moving the movable piece along both axes of the orthogonal coordinates.

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