JP4241346B2 - Switch device - Google Patents

Description

The present invention, due to the pressure applied relates switch device using a shape change member shape is changed.

For example, an automobile is provided with a switch device having an operation knob (operation member) for instructing operation of an in-vehicle device such as an audio, an air conditioner, and a headlight. The operation knob is provided with a light-emitting lamp, and by checking the lighting state of the light-emitting lamp, it is possible to confirm what aspect the in-vehicle device is in. Moreover, as shown in Patent Document 1, as a means for notifying the state of the on-vehicle equipment, in addition to using a light-emitting lamp, the operator has performed a desired operation by vibrating the operation knob with a vibration device. Some have been proposed (see Patent Document 1).
JP 2001-283683 A

  However, in the switch device shown in the background art, when confirming the state of the in-vehicle device by the lighting state of the light-emitting lamp, it can be confirmed by visual observation of the operation knob, but it is not understood only by touching the operation knob. . On the other hand, when confirming the mode of the in-vehicle device by vibration, it can be confirmed by touching the operation knob, but it is not understood only by looking at the operation knob. Therefore, it is desired that the in-vehicle device can be confirmed by any method such as viewing or touching the operation knob.

  The present invention has been made paying attention to such problems existing in the prior art. The purpose is to make it easier to grasp the state of the target device that is instructed to operate by the operation member.

In the invention according to claim 1, in the switch device including an operation member for performing a predetermined operation on the target device, the input unit to which pressure is applied from the outside, and the pressure to be applied to the input unit. An output portion that deforms based on the pressure, and a pressure transmission medium for transmitting the pressure input to the input portion to the output portion is accommodated in the input portion and the output portion, respectively, and the design surface of the operation member A shape-changing member that changes to have a step, and an actuator that applies pressure to the input portion of the shape-changing member under a predetermined condition, and the operation member includes a plurality of shape-changing members that are independent of each other. An operator having a storage chamber in which the output unit is stored, and a plurality of movable bodies that are stored so as to correspond to the respective output units in the storage chamber of the operator, and are displaced in accordance with the elastic deformation of the output units; That A flexible sheet material that covers the surface of the movable body, and each movable body includes a movable body that is displaced when the predetermined movable body is displaced along with the elastic deformation of the output unit, and other movable bodies. The gist is that the engaging portions that engage with the movable body are formed respectively .

According to this configuration, when pressure is applied to the input portion of the shape change member by the actuator, the output portion is elastically deformed to have a step with respect to the design surface of the operation member via the pressure transmission medium. Therefore, the aspect of the target device operated by the operation member can be easily grasped not only by visually checking the design surface of the operation member but also by touching it.
Further, when a predetermined output portion of a plurality of output portions is deformed, the corresponding movable body is displaced, and a step is formed on the surface of the sheet material. Further, when the other output portion is deformed, the corresponding movable body is displaced, and a step having a shape different from that when the predetermined output portion is deformed is formed on the surface of the sheet material. Due to the difference in the step shape, different display patterns can appear on the design surface of one operation member.
Further, when the predetermined movable body is displaced, the engaging portions provided on the movable bodies are engaged with each other, and the other movable bodies are also displaced in the same direction as the movable body to be displaced. Therefore, since the other movable body can be displaced without operating the actuator for elastically deforming the output unit corresponding to the other movable body, energy saving can be achieved.
When pressure is applied to the input unit, the pressure is transmitted to the output unit via the pressure transmission medium, and the output unit is elastically deformed by the transmitted pressure. Therefore, it is possible to deform the output unit at a position away from the input unit with a simple configuration.
In the invention according to claim 2, in the switch device including an operation member for performing a predetermined operation on the target device, the input unit to which pressure is applied from the outside, and the pressure to be applied to the input unit. An output portion that deforms based on the pressure, and a pressure transmission medium for transmitting the pressure input to the input portion to the output portion is accommodated in the input portion and the output portion, respectively, and the design surface of the operation member A shape-changing member that changes to have a step, and an actuator that applies pressure to the input portion of the shape-changing member under a predetermined condition, and the operation member includes a plurality of shape-changing members that are independent of each other. An operation element having a storage chamber in which the output unit is stored, and a plurality of movable bodies that are stored in the storage chamber of the operation element so as to correspond to the output units, and are displaced in accordance with elastic deformation of the output units; That And a flexible sheet material that covers the surface of the movable body, and further covers the periphery of the output portion of each of the shape change members and can be deformed in accordance with the elastic deformation of the output portion. The gist of the invention is that a holding body made of a synthetic resin having a thickness is provided.
According to this configuration, when pressure is applied to the input portion of the shape change member by the actuator, the output portion is elastically deformed to have a step with respect to the design surface of the operation member via the pressure transmission medium. Therefore, the aspect of the target device operated by the operation member can be easily grasped not only by visually checking the design surface of the operation member but also by touching it.
Further, when a predetermined output portion of a plurality of output portions is deformed, the corresponding movable body is displaced, and a step is formed on the surface of the sheet material. Further, when the other output portion is deformed, the corresponding movable body is displaced, and a step having a shape different from that when the predetermined output portion is deformed is formed on the surface of the sheet material. Due to the difference in the step shape, different display patterns can appear on the design surface of one operation member.
Furthermore, it is possible to prevent the position of each output unit from being shifted with respect to each movable body by the holding body.
When pressure is applied to the input unit, the pressure is transmitted to the output unit via the pressure transmission medium, and the output unit is elastically deformed by the transmitted pressure. Therefore, it is possible to deform the output unit at a position away from the input unit with a simple configuration.

According to a third aspect of the present invention, in the switch device according to the first or second aspect, the input portion and the output portion of the shape changing member communicate with each other via a flexible pipe in which a pressure transmission medium is accommodated. The gist is that they are spaced apart.
With this configuration, the positional relationship between the input unit and the output unit can be arbitrarily set, so that the degree of freedom in arrangement of the input unit and the output unit can be increased.

According to a fourth aspect of the present invention, in the switch device according to any one of the first to third aspects, the output portion of the shape changing member has a thin portion that is thinner than other portions. To do.
According to this configuration, when pressure is applied to the input unit, the output unit is more easily deformed. Therefore, the output unit can be easily deformed with a small pressure.

According to a fifth aspect of the present invention, in the switch device according to any one of the first to fourth aspects, the pressure transmission medium of the shape changing member is a silicon-based liquid.
With this configuration, the pressure transmission medium can have heat resistance. Therefore, even when the shape changing member is placed in a high temperature environment, the reliability can be improved.

In invention of Claim 6 , in the switch apparatus as described in any one of Claims 1-5, the said input part of the said shape change member , an output part, and a flexible pipe are irradiated with respect to an input part. The gist is that it is formed of a synthetic resin material having a light guide property capable of guiding light to the output portion.

  With this configuration, the light emitted to the input unit can be guided to the output unit via the flexible pipe, and the light can be emitted from the output unit, so that a visual effect can be obtained. .

According to the invention described in 請 Motomeko 1-6, easily understand the aspects of the equipment operated by the operating member. Note that the shape of the output section can be changed with a simple configuration.

[First Embodiment]
Hereinafter, a first embodiment in which the present invention is embodied in a power window switch device for opening and closing a window glass of an automobile will be described with reference to the drawings.

  As shown in FIG. 1, a switch device 11 provided in a power window as a target device includes a main body case 12 attached to the inner side surface of a door in an automobile. The main body case 12 is provided with a plurality of operation knobs 13 as operation members, and the operation knobs 13 are supported so as to be tiltable in the vertical direction around the inner end portion thereof. When the occupant tilts the operation knob 13 in the vertical direction, a contact (not shown) provided in the main body case 12 is switched according to the operation direction of the operation knob, and the window glass of the automobile moves up and down. ing.

  As shown in FIGS. 2A and 2B, a tube 17 as a shape changing member is accommodated in the main body case 12. The tube 17 is formed of a silicon rubber material which is a synthetic resin material in order to give flexibility, and the entire tube 17 is bent in a horizontal L shape. The reason why the tube 17 is formed of a silicon rubber material is that it can be prevented from extending in a high temperature environment. In addition to the silicon rubber, the tube 17 can be changed to an arbitrary material such as an elastomer rubber or a transparent material.

  The tube 17 includes a flexible pipe 17c that occupies most of the tube. One end of the flexible pipe 17c is integrally formed with a bag-like input portion 17a to which an external pressure is applied, and the other end is elastically deformed according to the magnitude of the pressure applied to the input portion 17a. A possible bag-shaped output portion 17b is integrally formed. The input part 17 a is fixed to the bottom surface of the main body case 12, and the output part 17 b is inserted and fixed to the back side of the operation knob 13 so that the end surface thereof is located on the same surface as the design surface of the operation knob 13. Both the input part 17a and the output part 17b of the tube 17 have flexibility and are formed in a bag shape so as to seal both ends of the tube 17.

  The inside of the input part 17a, the output part 17b, and the flexible pipe 17c which comprise the tube 17 is mutually connected, and the silicone oil 20 is enclosed with those inside. A thin portion 18 that is thinner than other portions is formed on the end surface of the output portion 17 b of the tube 17, and the thin portion 18 is in contact with the silicon oil 20. When the pressure applied to the input portion 17a is transmitted to the thin portion 18 of the output portion 17b using the silicon oil 20 as a pressure transmission medium, the thin portion 18 projects so as to have a step with respect to the design surface of the operation knob 13. It is designed to deform. The pressure transmission medium enclosed in the tube 17 can be changed to any liquid other than the silicone oil 20, for example, a transparent liquid.

  Support members 25 are provided at positions located on both sides of the input portion 17a of the tube 17 in the main body case 12, and a bimetal 26 as an actuator is provided at the upper end portion of the support member 25 so as to cover the upper side of the input portion 17a. Is provided. One end of the bimetal 26 is fastened and fixed by a screw 27 screwed into the support member 25. The other end of the bimetal 26 is formed with a notch 26a extending along the longitudinal direction, and a screw 27 screwed into the support member 25 is engaged with the notch 26a. The position can be shifted in the direction.

  The bimetal 26 is bonded so that a metal piece having a large thermal expansion coefficient is positioned on the lower side (input part 17a side) and a metal piece having a smaller expansion coefficient is positioned on the upper side (opposite side of the input part 17a). It is a thing. The bimetal 26 is energized when the operation knob 13 is tilted downward, and self-heats due to the specific resistance of the bimetal 26 itself. 2 (c) and 2 (d), the bimetal 26 is curved so as to crush the input portion 17a of the tube 17 when heat is generated.

  A light source 29 made of an LED (light emitting diode) is provided on the extension line of the output portion 17 b of the tube 17 in the main body case 12. The light source 29 emits light when the operation knob 13 is tilted downward. The tube 17 has a light guide property and can guide light incident on the silicon oil 20 from a light source 29 such as a light emitting diode to the operation knob 13. That is, the input portion 17a of the tube 17 is a light introducing portion disposed in the vicinity of the light source 29, while the output portion 17b is an irradiating portion for irradiating light guided from the light source 29 to the outside. Since the output unit 17b having a function as an irradiating unit is disposed with respect to the design surface of the operation knob 13, the light irradiated from the output unit 17b is irradiated from the design surface of the operation knob 13, and the power window. The opening and closing mode of the window glass can be visually confirmed even by light.

Next, the operation of the power window switch device configured as described above will be described.
When the operation knob 13 is tilted downward, when the window glass is moved downward and opened, the bimetal 26 is energized, and the bimetal 26 is bent so that the input portion 17a of the tube 17 is crushed. Then, the pressure applied to the input part 17 a by the bimetal 26 is transmitted to the thin part 18 which is a part of the output part 17 b using the silicon oil 20 as a pressure transmission medium, and the thin part 18 is applied to the design surface of the operation knob 13. Projected to have a step. Thereby, the opening / closing mode of the window glass in the power window can be confirmed by visual observation, and the opening / closing mode of the window glass can also be confirmed by the fingertip touching the thin portion 18 protruding from the design surface of the operation knob 13.

  Further, when the operation knob 13 is tilted downward, the light source 29 emits light. Thereby, the light from the light source 29 is irradiated to the outside from the thin portion 18 of the output portion 17b located on the opposite side of the light input from the input portion 17a of the tube 17. In other words, the thin-walled portion 18 protruding so as to have a step with respect to the design surface of the operation knob 13 is irradiated to the outside, and the opening / closing mode of the window glass is also confirmed by this irradiation.

Therefore, according to the present embodiment, the following effects can be obtained.
(1) When the window glass is opened, the thin portion 18 in the output portion 17b of the tube 17 projects from the design surface of the operation knob 13, so that the design surface of the operation knob 13 is not only visually observed but also touched. The window glass can be opened and closed. Therefore, it becomes easy to grasp the opening / closing mode of the window glass.

  (2) Since the flexible pipe 17c of the tube 17 has flexibility throughout, the degree of freedom in arrangement of the input unit 17a and the output unit 17b can be increased, and the switch device 11 can be designed. Ease can be improved.

  (3) Since the silicone oil 20 which is a liquid is sealed inside the tube 17 and the pressure applied to the input portion 17a is transmitted to the thin portion 18 of the output portion 17b as a pressure transmission medium, for example, gas or the like In comparison, there is almost no loss in pressure transmission efficiency, and the pressure applied to the input unit 17a can be transmitted to the output unit 17b. Further, since the silicon oil 20 has a high affinity with the silicon rubber that is the material for forming the tube 17, the deterioration of the tube 17 can be prevented and the life of the tube 17 can be increased.

  (4) Since the tube 17 is formed of a silicon-based material, that is, silicon rubber, the heat resistance can be improved. Therefore, when the window glass is closed in summer or the like, the tube 17 can be prevented from extending even when the switch device 11 is placed in a high temperature environment, and the reliability of the switch device 11 is improved. be able to.

  (5) Since the tube 17 has light guide properties, the thin portion 18 can emit light. Therefore, the thin part 18 can be made conspicuous and it becomes easier to grasp the opening and closing mode of the window glass.

[Second Embodiment]
The second embodiment will be described focusing on the differences from the previous embodiment.
As shown in FIGS. 3A and 3B, an electromagnetic solenoid 31 as an actuator is provided at a position in the main body case 12 above the input portion 17 a of the tube 17. The electromagnetic solenoid 31 includes an electromagnetic coil (not shown) around which a magnet wire is wound, and a plunger 32 inserted through an insertion hole located at the center of the electromagnetic coil. The electromagnetic solenoid 31 is excited (energized) when the operation knob 13 is tilted downward. When the electromagnetic coil is excited, the plunger 32 is immersed, and when the electromagnetic coil is demagnetized, the plunger 32 protrudes by a spring (not shown) provided inside the electromagnetic solenoid 31.

  The distal end portion of the plunger 32 in the electromagnetic solenoid 31 is fitted into a connecting portion 33 having a concave cross section formed in the input portion 17 a of the tube 17. When the plunger 32 is immersed, the input portion 17 a of the tube 17 is pulled up toward the electromagnetic solenoid 31, and the thin portion 18 is recessed with respect to the design surface of the operation knob 13.

  Therefore, according to this embodiment, when the operation knob 13 is tilted downward and the window glass is moved downward and opened, the electromagnetic solenoid 31 raises the input portion 17a of the tube 17 upward, and silicon The thin part 18 which is a part of the output part 17b is recessed using the oil 20 as a pressure transmission medium. Thereby, the open / close mode of the window in the power window can be confirmed by visual observation, and the open / close mode of the power window can also be confirmed by touching the thin-walled portion 18 recessed from the design surface of the operation knob 13. Of course, as described in the first embodiment, the light from the light source 29 is guided to the thin portion 18 of the output portion 17b of the tube 17, and the thin portion 18 emits light, so that the window glass can be opened and closed visually. Can also be confirmed.

[Third Embodiment]
As shown in FIG. 4, the steering 41 of the automobile is provided with a push switch device 42 that can operate the target device. A plurality of push-type switch devices 42 (four in this embodiment) are provided, and these push-type switch devices 42 are intensively arranged so as to be adjacent to each other.

  As shown in FIGS. 5 and 6, the push-type switch device 42 includes a tube 44 that is made of the same material as the tube described in the first embodiment and is formed in a substantially horizontal U shape. An elastically deformable input portion 44 a to which pressure is applied from the outside is formed in a bag shape at one end portion of the tube 44, and an electromagnetic solenoid that is an actuator fixed to the pad portion of the steering 41 is provided in the input portion 44 a. 46 plungers 46a are connected. Since this connection structure is the same as that already described in the second embodiment, description thereof is omitted in this embodiment.

  The tube 44 is connected to an input portion 44a with a cylindrical output portion 44b that can be elastically deformed. Since the flexible pipe 17c demonstrated in the said embodiment is abbreviate | omitted here for the tube 44, the input part 44a and the output part 44b are directly connected. The entire output portion 44b of the tube 44 is covered with an operation button 48 as a thin plate-like operation member, and the opening at the end of the output portion 44b of the tube 44 is sealed by the operation button 48. . The operation button 48 includes a soft portion 49 formed of a soft synthetic resin material such as silicon rubber that can be easily deformed by slight pressure fluctuations, and a hard portion 50 formed of a hard resin material that cannot be deformed. They are integrated by two-color molding. The hard part 50 occupies the input part 44a, while the soft part 49 occupies the output part 44b.

  The design surface of the soft portion 49 in the operation button 48 is exposed to the outside so as to be flush with the design surface of the pad portion of the steering 41, and the soft portion 49 is pressed to face the soft portion 49. The rubber contact 54 arranged so as to be closed is closed, and the target device operated by the push switch device 42 is activated. Examples of the target device include audio, an air conditioner, navigation, and the like. Of course, it is possible to freely change to other target devices.

  Then, when the plunger 46a of the electromagnetic solenoid 46 protrudes based on the opening / closing of the rubber contact 54, pressure is applied to the input portion 44a of the tube 44 and the silicon oil 51 enclosed therein is used as a pressure transmission medium. The design surface of the soft part 49 in the operation button 48 is deformed so as to have a step. That is, as shown in FIG. 7, the design surface of the soft portion 49 in the operation button 48 is raised, thereby forming a display pattern 52 representing the target device operated by the push switch device 42. The display pattern 52 can also be formed by recessing the design surface of the operation button 48 by immersing the plunger 46a of the electromagnetic solenoid 46. Incidentally, in the present embodiment, the display pattern 52 is formed when the target device is turned on, and the design surface of the operation button 48 is kept smooth when the target device is turned off, and the display pattern 52 is not formed. .

  As shown in FIG. 5, a plurality of dummy tubes 53 that are hollow and elastically deformable cushion members are embedded in the soft portion 49 of the operation button 48. The elastic force of the dummy tube 53 is substantially the same as that of the output portion 44 b of the tube 44. Both end portions of the dummy tube 53 are sealed by the soft portion 49 so that the air sealed inside does not escape to the outside. Each dummy tube 53 is disposed along the axial direction of the output portion 44 b in the tube 44. The dummy tube 53 is provided so that the entire soft portion 49 of the operation button 48 is as soft as a portion where the tube 44 is circulated. Note that a fluid other than air can be sealed in the dummy tube 53, and for example, silicon oil or the like can be sealed.

  Therefore, according to the present embodiment, the ON / OFF state of the target device of the push-type switch device 42 is displayed with or without viewing the display pattern 52 that appears when the design surface of the operation button 48 is raised. It can be recognized by touching the pattern 52 with a finger.

  Since the dummy tube 53 is provided in addition to the tube 44 in the soft part 49 of the operation button 48, only the portion where the tube 44 is disposed is not softened, and the entire soft part 49 can be softened. Therefore, it is possible to prevent a sense of incongruity when touching the soft portion 49 of the operation button 48, and to operate the operation button 48 with a light pressing force.

  Since the vicinity of the input portion 44a in the tube 44 is covered with the hard portion 50 of the operation button 48, when pressure is applied to the input portion 44a, the pressure can be efficiently transmitted to the output portion 44b. Thereby, the display pattern 52 can be clearly raised on the design surface of the soft part 49 in the operation button 48 without increasing the pressure applied to the input part 44a.

[Fourth Embodiment]
As shown in FIG. 8, a paddle type switch device 58 is provided on the steering wheel 57 of the automobile. The paddle type switch device 58 includes a paddle lever 59 as an operation restricting means extending obliquely downward. The paddle lever 59 is not operated by an elastic force of an elastic member (not shown) when no operating force is applied. It comes to return to the position.

  As shown in FIGS. 9 and 10, a plurality of seesaw switches 60 electrically connected to the target device are juxtaposed at the tip of the paddle lever 59. Then, the electric path between each seesaw switch 60 and the target device can be opened and closed by snapping the paddle lever 59 to the front side. Here, each time the paddle lever 59 is snap-operated to the front side of the steering wheel 57, any one of the seesaw switches 60 can be sequentially activated. When the seesaw switch 60 is enabled, each target device can be operated based on the operation of the operation lever 61 as an operation member. When the seesaw switch 60 is disabled, the seesaw switch 60 can be operated. Each target device cannot be operated. Examples of the target device here include an audio, an air conditioner, and navigation.

  Each seesaw switch 60 includes an operation lever 61 protruding from the end of a paddle lever 59, and each operation lever 61 is swingable with respect to a common shaft 62 fixed to the paddle lever 59. It is supported. By snapping the operation lever 61 in the same direction as the paddle lever 59, the rubber contact 64 provided on the printed circuit board 63 is closed so as to face each operation lever 61, and the target device is activated. ing. When no operating force is applied to the operation lever 61, the operation lever 61 returns to the position before the operation by the elastic force of the rubber contact 64. An identification seal 65 is attached on the front surface of the outer end of each operation lever 61 to indicate what the target device of these operation levers 61 is.

  As shown in FIG. 11, the paddle type switch device 58 includes a tube 67 as a shape changing member embedded therein, and a bag-like input portion 67a is provided at one end of a flexible pipe 67c that occupies most of the tube 67. Is formed. A plunger 68a of an electromagnetic solenoid 68 that is an actuator fixed to the paddle lever 59 is connected to the input portion 67a. Since this connection structure is the same as that already described in the second embodiment, description thereof is omitted in this embodiment.

  One electromagnetic solenoid 68 is provided for each seesaw switch 60 and is connected to a microcomputer 69 as a control means. A position detection sensor 70 for detecting the operation position of the paddle lever 59 is electrically connected to the input side of the microcomputer 69, and the microcomputer 69 drives the electromagnetic solenoid 68 based on a detection signal from the position detection sensor 70. To control. That is, when the position detection sensor 70 detects that the paddle lever 59 is in the snap operation position, the microcomputer 69 energizes the electromagnetic solenoid 68 to cause the plunger 68a to protrude. Further, when the microcomputer 69 detects that the paddle lever 59 is in the snap operation position, the microcomputer 69 sequentially controls the seesaw switch 60 to be activated one by one, and corresponds to the activated seesaw switch 60. The electromagnetic solenoid 68 is energized.

  At the other end of the flexible pipe 67c in the tube 67, an output portion 67b that can be elastically deformed according to the magnitude of pressure applied to the input portion 67a is formed in a bag shape, and a part of the output portion 67b is an operation lever. 61 is exposed to the outside on the rear surface of the outer end portion. The inside of the input part 67a, the output part 67b, and the flexible pipe 67c which comprise the tube 67 is mutually connected, and the silicone oil 71 is enclosed with those inside. When the pressure applied to the input unit 67a by the electromagnetic solenoid 68 is transmitted to the output unit 67b using the silicon oil 71 as a medium, the output unit 67b is touched by a finger or the like as compared with a case where the pressure is not transmitted. Furthermore, it swells to such an extent that the operation mode of the target device can be identified.

  The paddle lever 59, the tube 67, the operation lever 61, and the silicon oil 71 are all made of a light transmissive (transparent) material. The reason for this is to make it possible to see the finger placed on the back side of the paddle type switch device 58 in order to operate the operation lever 61 from the front side.

  In the paddle type switch device 58 configured as described above, when the paddle lever 59 is snapped, the electromagnetic solenoid 68 corresponding to the seesaw switch 60 to be activated is energized and the plunger 68a protrudes. Then, pressure is applied to the input portion 67a of the tube 67, and the output portion 67b of the tube 67 at the distal end portion of the operation lever 61 is subjected to other operations using the silicon oil 71 sealed in the tube 67 as a pressure transmission medium. It swells more than the output part 67b of the lever 61.

  Therefore, according to this embodiment, it is possible to easily grasp which of the plurality of operation levers 61 is activated by touching the swollen output portion 67b of the plurality of operation levers 61 with a finger or the like. be able to. Therefore, for example, during operation, the target device can be operated by a blind operation without looking at the operation lever 61.

  Among the plurality of operation levers 61 that are activated, the output portion 67b of the tube 67 at the tip thereof is swollen more than the output portion 67b of the operation lever 61 that is invalidated. Whether or not the operation lever 61 is activated can be easily grasped simply by touching the output unit 67b.

  Since the plurality of operation levers 61 are selectively enabled by snapping the paddle lever 59, even if the disabled operation lever 61 is operated against the user's will, It is possible to prevent the target device from operating.

  Since the paddle lever 59, the tube 67, the operation lever 61, and the silicon oil 71 are all light transmissive, the front side of the paddle type switch device 58 indicates which of the plurality of operation levers 61 should be operated. Can be visually recognized. Therefore, it is possible to reduce an operation error such as operating the disabled operation lever 61.

[Fifth Embodiment]
As shown in FIGS. 12, 13, and 14, the instrument panel 74 of the automobile is provided with a push-type switch device 75 that can operate the target device by pressing. The push type switch device 75 is provided with a casing 76 formed of a synthetic resin material. The casing 76 is divided into a plurality of (four in this embodiment) storage chambers 77 defined by a cross-shaped partition wall 76a. have. A printed circuit board 79 having a rubber contact 78 is provided at the bottom of each housing chamber 77 in the casing 76, and an operation button 81 as an operation member faces the rubber contact 78 via a pusher 80 above the printed circuit board 79. It is provided as follows. When the operation button 81 is pressed, the rubber contact 78 is closed and the target device is activated. Examples of the target device include audio, an air conditioner, and navigation.

  The configuration of the operation button 81 will be described. The operation button 81 includes an operation element 82 that can be displaced in the vertical direction. The operation element 82 has a guide in which a locking claw 92 that protrudes from the outer surface of the operation button 82 is recessed in the inner surface of the casing 76. By being engaged in the groove 93, it is prevented from coming out of the storage chamber 77. In the operation element 82, output portions 83b and 84b of the first and second tubes 83 and 84 are accommodated as independent shape changing members. The output part 83b of the 1st tube 83 is arrange | positioned inside the output part 84b of the 2nd tube 84, and these output parts 83b and 84b have a mutually different shape. Here, the output portion 83b of the first tube 83 is formed in a substantially circular shape, while the output portion 84b of the second tube 84 is formed in a substantially square shape.

  The configuration of the first and second tubes 83 and 84 other than the output portions 83b and 84b is the same as that of the second embodiment. That is, elastically deformable input portions 83a and 84a to which pressure is applied from the outside via flexible pipes 83c and 84c are formed in a bag shape at the opposite ends of the output portions 83b and 84b in the tubes 83 and 84, respectively. Is formed. Plungers 85a and 86a of electromagnetic solenoids 85 and 86, which are actuators fixed to the instrument panel 74, are connected to the input portions 83a and 84a. When pressure is applied to the input parts by the electromagnetic solenoids 85 and 86, the silicon oil 87 enclosed in the tubes 83 and 84 is used as a pressure transmission medium so that the output parts 83b and 84b expand. Deform.

  A holding body 88 in which the output portions 83 b and 84 b of the tubes 83 and 84 are embedded is provided in the operation element 82, and the holding body 88 is prevented from coming out by a protruding piece 82 a formed on the inner wall of the operation element 82. It has become. The holding body 88 has a role of preventing the output portions 83b and 84b of the tubes 83 and 84 from being displaced from predetermined positions and holding their shapes. The holding body 88 is formed of a soft synthetic resin material such as silicon rubber, and can be elastically deformed together with the expansion and deformation of the output portions 83b and 84b of the tubes 83 and 84.

  In the operation element 82, a circular first movable body 89 is disposed at a position facing the output portion 83b of the first tube 83. In the operation element 82, a second movable body 90 having a quadrangular annular shape is disposed so as to surround the periphery of the first movable body 89 at a position facing the output portion 84 b of the second tube 84. The outer peripheral edge of the first movable body 89 and the inner edge portion of the second movable body 90 are overlapped in the thickness direction, and the overlapped portion is used as an engaging portion having a thinner thickness than the other portions. Engagement step portions 89a and 90a are formed. The thicknesses of the engagement step portions 89a and 90a are such that the upper surfaces of the first movable body 89 and the second movable body 90 are flush with each other when the output portions 83b and 84b of the tubes 83 and 84 are not expanded. It is set to be. When the output portion 83 b of the first tube 83 expands, only the first movable body 89 is displaced upward from the second movable body 90. When the output portion 84b of the second tube 84 is expanded, both the first and second movable bodies 89 and 90 are displaced upward.

  The operation element 82 is provided with a sheet material 91 made of synthetic resin having elasticity so as to cover the first and second movable bodies 89 and 90, respectively. The back surface of the sheet material 91 is fixed with an adhesive to the upper surface of the second movable body 90, the protruding piece 82a, and the inner wall surface of the operation element 82 positioned above the protruding piece 82a. That is, the sheet material 91 is bonded except for the first movable body 89.

  Then, as shown in FIG. 15, when the first movable body 89 is displaced upward, a first display pattern having a circular shape is formed on the surface of the sheet material 91 which is the design surface of the operation button 81 (FIG. 12). Reference) 94a is lifted. As shown in FIG. 16, when the first and second movable bodies 89 and 90 are both displaced upward, a second display pattern 94 b (see FIG. 12) having a rectangular shape is formed on the surface of the sheet material 91. It comes to float. For example, if the target device by the operation of the push-type switch device 75 is audio, the first display pattern 94a floats on the surface of the sheet material 91 when the audio is on and the CD is selected, and the audio is on. If the radio is selected, the second display pattern 94b is raised. If the audio is OFF, the surface of the sheet material 91 remains smooth.

  Therefore, according to the present embodiment, the first display pattern 94a formed only by the first movable body 89 and the first and second movable bodies 89 and 90 are formed on the design surface of the operation button 81. The second display pattern 94b can be selectively raised. That is, since two kinds of display patterns 94a and 94b that can confirm the mode of the operation target can be switched and displayed by touching the design surface of one operation button 81, one operation button 81 is provided for each display pattern. You don't have to set them up Thereby, the number of operation buttons 81 can be reduced.

  Engagement step portions 89a and 90a are formed at the boundary portions of the first and second movable bodies 89 and 90, respectively. When the first movable body 89 is displaced, the engagement step portions 89a and 90a are engaged. Therefore, not only the first movable body 89 but also the second movable body 90 can be displaced. Therefore, in order to displace both the movable bodies 89 and 90, it is not necessary to excite the two electromagnetic solenoids 85 and 86 to expand and deform the two output portions 83b and 84b. Therefore, it is possible to reduce the complexity of the control and to save energy.

  Furthermore, since the output portions 83b and 84b of the first and second tubes 83 and 84 are both embedded by the holding body 88, the positions of the output portions 83b and 84b with respect to the first and second movable bodies 89 and 90 are determined. It is possible to prevent deviation. Accordingly, since the first and second movable bodies 89 and 90 can be displaced without being partially biased, the first display pattern 94a and the second display pattern 94b are clearly displayed on the design surface of the operation button 81. It can be raised.

[Another embodiment]
The embodiment of the present invention may be modified as follows.
In the first and second embodiments, the power window switch device 11 that opens and closes the window glass of the automobile is embodied. However, as shown in FIGS. 17A and 17B, the air volume of the air conditioner is used. It may be embodied in a switch device 95 for adjusting the angle. The switch device 95 has a push button 97 disposed on an instrument panel 96 in the vehicle, and a cylindrical body 99 filled with silicon oil 98 is provided around the push button 97. . When pressure is applied by an actuator to an input portion (not shown) provided at the inner end of the cylindrical body 99, the output portion 100 having the thin portion 100a provided at the outer end of the cylindrical body 99 is formed on the design surface. On the other hand, it overhangs and deforms to have a step. The application of the switch device 95 shown in FIGS. 17 (a) and 17 (b) is embodied in a switch device or the like that starts and stops the engine by pushing a button in addition to adjusting the air volume of the air conditioner. It is possible.

  -As another example of the first embodiment, the value of the current flowing through the bimetal 26 may be proportional to the degree of opening of the window glass. With this configuration, since the curvature of the bimetal 26 changes according to the degree of opening of the window glass, the amount of protrusion of the thin portion 18 with respect to the design surface of the operation knob 13 can be varied. Therefore, the degree of opening of the window glass can be grasped by touching the thin portion 18.

  In the first embodiment, the bimetal 26 is used as the actuator that applies pressure to the input portion 17a of the tube 17, and the electromagnetic solenoid 31 is used in the second embodiment. However, the actuator may be changed to any member.

  In the first and second embodiments, the pressure applied to the input part 17a of the tube 17 is transmitted to the output part 17b via the silicon oil 20, but liquids other than silicon-based, air, etc. You may change to gas.

  In the first and second embodiments, the operation knob 13 may be formed of a transparent synthetic resin material, and the silicon oil 20 may be colored so as to be distinguished from the operation knob 13 by color. In this way, when the thin portion 18 is deformed into a convex spherical shape, the thin portion 18 serves as a lens, so that the color of the silicon oil 20 can be made more conspicuous.

  As shown in FIGS. 18A and 18B, as another example of the first and second embodiments, the bimetal 26 is supported in a cantilever shape, and a magnetic pusher 103 is attached to the tip of the bimetal 26. Good. When the bimetal 26 is energized, the bimetal 26 is bent so that the input portion 17 a of the tube 17 is crushed by the pusher 103. Further, the input portion 17a of the tube 17 is supported on a pedestal 104 having a covered cylindrical shape that can move up and down, and this pedestal 104 has a magnetism opposite to that of the pusher 103. According to this configuration, when the input portion 17a of the tube 17 is crushed by the pusher 103, the pusher 103 and the pedestal 104 attract each other with their magnetic force. Can be pinched strongly. Therefore, the input portion 17 a of the tube 17 can be effectively crushed by the pressing force by the pusher 103 and the magnetic force by the pusher 103 and the pedestal 104.

  In the third embodiment, the plurality of dummy tubes 53 are arranged along the axial direction of the output portion 44b of the tube 44. For example, a large number of bead-shaped cushion members are scattered at arbitrary positions, or dummy The tubes 53 may be shortened and scattered.

  In the fourth embodiment, the paddle lever 59 can be snapped. However, the snap operation may be disabled, that is, the paddle lever 59 may be fixed. In this case, it is assumed that a plurality of seesaw switches 60 are always enabled.

In the fourth embodiment, the paddle lever 59, the tube 67, the operation lever 61, and the silicon oil 71 are all light-transmitting, but may be colored.
In the fourth embodiment, only one seesaw switch 60 is activated each time the paddle lever 59 is snapped, but two seesaw switches 60 may be activated simultaneously. With this configuration, two target devices can be operated.

  -In 5th Embodiment, although the output parts 83b and 84b of both the tubes 83 and 84 were each embed | buried in the holding body 88, this holding body 88 may be abbreviate | omitted. In this case, the output portions 83b and 84b are fixed to the bottom of the operation element 82 with an adhesive so that the positions of the output portions 83b and 84b of the tubes 83 and 84 do not shift.

  -Engagement step part 89a, 90a provided in the overlapping part of the 1st movable body 89 and the 2nd movable body 90 demonstrated in 5th Embodiment may be abbreviate | omitted. With this configuration, the first movable body 89 moves upward, whereby the first display pattern in which the surface of the sheet material 91 has a circular shape can be raised. Further, when the second movable body 90 moves upward, the second display pattern in which the surface of the sheet material 91 forms a square ring can be lifted.

In the fifth embodiment, two tubes 83 and 84 that are independent from each other are provided, but three or more independent tubes may be provided, and a movable body corresponding to these tubes may be provided.
In the fifth embodiment, the engagement step portion 89a of the first movable body 89 is disposed on the upper side, and the engagement step portion 90a of the second movable body 90 is disposed on the lower side. , 90a may be reversed. That is, the engagement step portion 89a of the first movable body 89 may be disposed on the lower side, and the engagement step portion 90a of the second movable body 90 may be disposed on the upper side. In the case of changing to this configuration, when the first movable body 89 is displaced, the second movable body 90 can also be displaced, and a display pattern raised in a square shape on the design surface of the operation button 81 can be obtained. Further, when the second movable body 90 is displaced, the first movable body 89 is not displaced, so that another display pattern protruding in a square ring shape on the design surface of the operation button 81 can be obtained.

  In the fifth embodiment, the first display pattern 94a or the first display pattern 94a on the design surface of the operation button 81 is provided by providing the first tube 83 and the second tube 84 that are independent from each other and expanding and deforming the output portions 83b and 84b. The second display pattern 94b is raised. Instead of this configuration, as shown in FIGS. 19 and 20, the inner surface of the operation element 82 of the push-type switch device 75 is made of a flexible synthetic resin that can be expanded and contracted as an output portion at a predetermined interval from the bottom. The thin film 105 is integrally formed by two-color molding. Then, silicon oil 106 is sealed in a space surrounded by the thin film 105 in the operation element 82. When pressure is applied to an input portion (not shown) that communicates with the space, silicon oil 106 flows into the space of the operation element 82 from the input section, and the entire design surface of the operation element 82 is raised. With this configuration, whether or not each operation button 81 is activated can be grasped by touching as well as visually depending on whether or not the design surface of the operation element 82 is raised. Note that the operation button 81 is enabled means a state in which the target device can be activated based on the pressing operation of the operation button 81 as described in the fourth embodiment, and is disabled. This means a state in which the target device can be operated even when the operation button 81 is pressed.

Next, in addition to the technical idea described in the claims, the technical idea grasped in the above-described embodiment will be described below.
[1] before Symbol shape-changing member that is formed of a synthetic resin material of the silicon system. According to this configuration, the heat resistance performance of the shape change member can be increased, and the shape change member can be prevented from extending even when the shape change member is used in a high temperature environment.

[2] before Symbol shape-changing member, that it has been formed of a synthetic resin material of the silicon-based or elastomer-based.
[3] the output of said shape-changing member, together are formed in a linear shape, and this covered with a coating member made of a synthetic resin material having a deformable hardness with the output unit. With this configuration, the shape of the output unit can be held in a desired shape.

[4] In the switching device, the actuator, and this has been an electromagnetic solenoid having a plunger that can advance and retreat by the magnetic force together with the tip is fixed to the input unit.

[5] In the switching device, the output of said shape changing member is that you have been exposed to the design surface of the operating member. With this configuration, the design surface of the operation member can have a sharp step.

The perspective view of the switch apparatus in 1st Embodiment. Similarly, (a) is a cross-sectional view when no pressure is applied to the input part of the switch device, (b) is a cross-sectional view of 1-1 of (a), and (c) is a pressure applied to the input part of the switch device. Sectional drawing when being done, (d) is 2-2 sectional drawing of (c). FIG. 4 is a switch device according to a second embodiment, where (a) is a cross-sectional view when no pressure is applied to the input portion of the switch device, and (b) is a cross-sectional view when the input portion of the switch device is pulled up. . The front view of the push type switch apparatus provided in the steering in 3rd Embodiment. Similarly, the perspective view which shows a part of push type switch apparatus. Similarly, sectional drawing of a push-type switch apparatus. Similarly, the principal part perspective view of a push-type switch apparatus. The front view of the paddle type switch apparatus in 4th Embodiment. Similarly, the perspective view of a paddle type switch device. Similarly, the fragmentary sectional view of a paddle type switch device. Similarly, sectional drawing which shows a paddle type switch apparatus schematically. The perspective view of the push type switch apparatus in 5th Embodiment. Similarly, the front view of a push-type switch apparatus. Similarly, sectional drawing of a push-type switch apparatus. Similarly, sectional drawing of a push-type switch apparatus when the 1st display pattern has floated. Similarly, sectional drawing of a push-type switch apparatus when the 2nd display pattern has floated. The switch apparatus in another embodiment is shown, (a) is the front view, (b) is the sectional drawing. The switch apparatus in another embodiment is shown, (a) is sectional drawing when the input part is not pressed, (b) is sectional drawing when the input part is pressed. The perspective view which shows the switch apparatus in another embodiment. Similarly, sectional drawing which shows the inside of the switch apparatus shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Switch apparatus, 13 ... Operation knob (operation member), 17 ... Tube (shape change member), 17a ... Input part, 17b ... Output part, 17c ... Flexible pipe, 18 ... Thin part, 20 ... Silicon oil (pressure transmission) Medium), 26 ... bimetal (actuator), 31 ... electromagnetic solenoid (actuator), 42 ... push switch device, 44 ... tube (shape changing member), 44a ... input unit, 44b ... output unit, 46 ... electromagnetic solenoid (actuator) , 48 ... Operation buttons (operation members), 53 ... Dummy tubes (cushion members), 58 ... Paddle type switch devices, 59 ... Paddle levers (operation restricting means), 61 ... Operation levers (operation members), 67 ... Tubes ( 68a ... input part, 67b ... output part, 67c ... flexible pipe, 68 ... Electromagnetic solenoid (actuator), 69 ... Microcomputer (control means), 71 ... Silicon oil (pressure transmission medium), 75 ... Push-type switch device, 81 ... Operation button (operation member), 77 ... Storage chamber, 82 ... Operator 83 ... first tube (shape changing member), 83a ... input portion, 83b ... output portion, 83c ... flexible pipe, 84 ... second tube (shape changing member), 84a ... input portion, 84b ... output portion, 84c ... Flexible pipe, 85 ... Electromagnetic solenoid (actuator), 86 ... Electromagnetic solenoid (actuator), 87 ... Silicon oil, 88 ... Holding body, 89 ... First movable body, 89a ... Engagement step part (engagement part), 90 ... 2nd movable body, 90a ... engagement step part (engagement part), 91 ... sheet material, 95 ... switch apparatus, 100a ... thin part, 100 ... output part.

Claims (6)

In the switch device including an operation member for performing a predetermined operation on the target device,
A pressure transmission configured to include an input unit to which pressure is applied from the outside and an output unit that is deformed based on the pressure applied to the input unit, and to transmit the pressure input to the input unit to the output unit A shape change member that accommodates a medium in each of the input unit and the output unit and changes the design surface of the operation member to have a step,
An actuator that applies pressure to the input portion of the shape changing member under a predetermined condition;
The operating member is accommodated so as to correspond to each output unit in the accommodating chamber of the operating element, and an operating element having an accommodating chamber in which output parts of a plurality of independent shape changing members are accommodated. A plurality of movable bodies that are displaced in accordance with the elastic deformation, and a flexible sheet material that covers the surfaces of the movable bodies,
Each movable body is formed with an engaging portion that engages the movable body and the other movable body with each other when the predetermined movable body is displaced along with the elastic deformation of the output portion. A switch device characterized by.   In the switch device including an operation member for performing a predetermined operation on the target device,
  A pressure transmission configured to include an input unit to which pressure is applied from the outside and an output unit that is deformed based on the pressure applied to the input unit, and to transmit the pressure input to the input unit to the output unit A shape change member that accommodates a medium in each of the input unit and the output unit and changes the design surface of the operation member to have a step,
  An actuator that applies pressure to the input portion of the shape changing member under a predetermined condition;
  The operating member is accommodated so as to correspond to each output unit in the accommodating chamber of the operating element, and an operating element having an accommodating chamber in which output parts of a plurality of independent shape changing members are accommodated. A plurality of movable bodies that are displaced in accordance with the elastic deformation, and a flexible sheet material that covers the surfaces of the movable bodies,
  Furthermore, a synthetic resin holding body having a hardness that covers the periphery of the output portion of each of the shape changing members and can be deformed along with elastic deformation of the output portion is provided. Switch device.   3. The switch according to claim 1, wherein the input portion and the output portion of the shape changing member are spaced apart so as to communicate with each other via a flexible pipe in which a pressure transmission medium is accommodated. apparatus.   The switch device according to claim 1, wherein the output portion of the shape changing member has a thin portion that is thinner than other portions.   The switch device according to claim 1, wherein the pressure transmission medium of the shape changing member is a silicon-based liquid.   The input portion, the output portion, and the flexible pipe of the shape changing member are formed of a synthetic resin material having a light guide property capable of guiding light irradiated to the input portion to the output portion. The switch device according to any one of claims 1 to 5.

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