JP2008186657A - Lever combination switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lever combination switch in which reliability is improvable. <P>SOLUTION: A photodiode array 30 is arranged and fixed, and in order that mutually different photodiodes (either one of 31 to 34) receives light guided by a light guide 21, at every position of an operation target of an operated means, an LED 11 and the light guide 21 are integrally slid accompanied with the operation of the operated means. Respective photodiodes 31 to 34 outputs mutually different electric signals to a control circuit 40 when they receive the light guided by the light guide or when they do not. By analyzing the electric signals input by each of the photodiodes 31 to 34, the control circuit 40 specifies the position of the operation target of the operated means based on the difference of the photodiodes (either one of 31 to 34) that received the light emitted from the LED 11. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a so-called lever combination switch in which light, turn, and wiper switches that are frequently used during vehicle operation are integrated around a steering wheel.

In this type of lever combination switch, the current path is switched through a sliding contact switch when the knob is rotated or the lever is tilted, and depending on the operation mode. The operation of the light, turn, and wiper is realized (for example, see Patent Documents 1 to 6).
JP 2000-11815 A JP 11-329162 A JP 2000-231841 A JP 2000-208003 A JP 2000-182457 A JP 2003-276573 A

  However, in a conventional lever combination switch in which a contact switch is used, when a volatilized silicone molecule mixed in a spray adheres to the contact portion, an insulating film is formed on the contact portion. There is a risk that it will not flow and will not function as a switch.

  The present invention has been made paying attention to such problems, and an object thereof is to provide a lever combination switch capable of improving the reliability.

  In order to achieve the above object, according to the first aspect of the present invention, when the operated means operated to operate the in-vehicle device is operated, the position of the operation destination of the operated means is detected, In the lever combination switch that realizes the operation of the vehicle-mounted device according to the position of the operation destination, the lever combination switch includes a light emitting unit that emits light, and a light receiving unit that receives the light emitted from the light emitting unit, and the operated unit is operated Accordingly, the mode when the light receiving unit receives the light emitted from the light emitting unit is configured differently, and the difference in the mode when the light receiving unit receives the light emitted from the light emitting unit. Based on the above, the gist of the invention is that it includes an operation position specifying means for specifying the position of the operation destination of the operated means.

  According to this configuration, as the operated means is operated, a difference appears in the light receiving mode by the light receiving means, and the position of the operation destination of the operated means is specified based on this. Here, since an optical contactless switch is used instead of a contact switch, the occurrence of a contact failure due to the formation of an insulating film can be avoided, and thus the reliability can be improved.

  According to a second aspect of the present invention, in the lever combination switch according to the first aspect of the present invention, a plurality of light receiving means that receive light emitted from the light emitting means are received by different light receiving means for each position of the operation destination of the operated means. The gist of the invention is that the light receiving means is provided, and the operation position specifying means specifies the position of the operation destination of the operated means on the basis of the difference in the light receiving means that has received the light emitted from the light emitting means. .

  According to this configuration, depending on the position of the operation destination of the operated means, a difference appears in the light receiving means that receives the light emitted from the light emitting means, and based on this, the position of the operation destination of the operated means can be specified. it can.

  According to a third aspect of the present invention, in the lever combination switch according to the second aspect, a light guide for guiding the light emitted from the light emitting means to the light receiving means is interposed between the light emitting means and the light receiving means. The light guide is operated in response to the operation of the operated means such that different light receiving means receive light guided by the light guide for each position of the operation destination of the operated means. Its gist is that it is displaced relative to the light receiving means.

  According to the same configuration, by adopting a configuration in which at least one of the light guide and the light receiving unit is displaced as the operated unit is operated, according to the position of the operation destination of the operated unit, A difference appears in the light receiving means for receiving the light guided by the light guide, and the position of the operation destination of the operated means can be specified based on this difference.

  According to a fourth aspect of the present invention, in the lever combination switch according to the first aspect of the present invention, light having different modes is emitted from the light emitting means for each position of the operation destination of the operated means, and the light receiving means receives the light. A plurality of light emitting means are provided so as to receive, and the operation position specifying means specifies the position of the operation destination of the operated means on the basis of the difference in the light received by the light receiving means. Yes.

According to this configuration, a difference appears in the mode of light received by the light receiving means according to the position of the operation destination of the operated means, and the position of the operation destination of the operated means can be specified based on this.
According to a fifth aspect of the present invention, in the lever combination switch according to the fourth aspect of the present invention, a light-blocking portion that blocks light emitted from the light-emitting means and a light-transmitting portion that transmits light emitted from the light-emitting means are provided. The optical action means having the optical action means is interposed between the light emitting means and the light receiving means, and light having different modes is transmitted through the light transmitting portion of the optical action means for each position of the operation destination of the operated means. The gist is that the optical action means is displaced relative to the light emitting means as the operated means is operated so that the light receiving means receives the light.

  According to the same configuration, by adopting a configuration in which at least one of the optical action means and the light emitting means is displaced in accordance with the operation of the operated means, the operation means is operated according to the position of the operation destination. A difference appears in the mode of light (= light received by the light receiving means) transmitted through the light transmitting portion of the optical action means, and based on this, the position of the operation destination of the operated means can be specified.

  According to a sixth aspect of the present invention, in the lever combination switch according to the first aspect of the present invention, a light-blocking body that blocks light emitted from the light-emitting means is interposed between the light-emitting means and the light-receiving means. When the operated means is operated so that the light receiving means receives light without being shielded by the light shielding body with different areas for each operation destination position of the operation means, the light shielding body is moved to the light receiving means. The gist of this is that it is relatively displaced.

  According to the same configuration, by adopting a configuration in which at least one of the light shielding body and the light receiving means is displaced in accordance with the operation of the operated means, light reception is performed according to the position of the operation destination of the operated means. A difference appears in the light receiving area (and thus electrical characteristics such as an electric resistance value) by the means, and based on this, the position of the operation destination of the operated means can be specified.

Since this invention is comprised as mentioned above, there exist the following effects.
According to the present invention, reliability can be improved.

(First embodiment)
A first embodiment in which the present invention is embodied in a lever combination switch of an automobile will be described below.

  As shown in FIG. 1, a lever combination switch 4 including a wiper switch unit 2 and a turn signal switch unit 3 is provided on the back side of the steering wheel 1 in front of the driver's seat. Then, when the lever (operated means) of the wiper switch unit 2 is tilted, the position of the operation destination of the lever is detected, and the operation of the wiper (vehicle equipment) according to the position of the operation destination is realized. It is like that. Further, when the lever (operated means) of the turn signal switch unit 3 is tilted, the position of the operation destination of the lever is detected, and the operation of the direction indicator (in-vehicle device) corresponding to the position of the operation destination is detected. It has come to be realized. Further, when the knob (operated means) of the turn signal switch unit 3 is rotated, the position of the operation destination of the knob is detected, and the operation of the headlamp (on-vehicle equipment) according to the position of the operation destination Has been realized.

  Here, the position of the operation destination of the lever of the wiper switch unit 2, the position of the operation destination of the lever of the turn signal switch unit 3, and the position of the operation destination of the knob of the turn signal switch unit 3 are used using an optical contactless switch. The operation in the case of detection will be described. Here, the lever and the knob are collectively referred to as an operated device, and the operated device is a first operation position, a second operation position, and a second operation position as the operation destination position of the operated device. The operation in the case of operation up to the third operation position, similarly to the fourth operation position, will be described.

  As shown in FIG. 2, in this embodiment, an optical contactless switch is configured by the photodiode array 30 having one LED 11, one light guide 21, and four photodiodes 31 to 34. Yes. The photodiode array 30 is fixedly arranged so that different photodiodes (any one of 31 to 34) receive light guided by the light guide 21 for each position of the operation destination of the operated means. The LED 11 and the light guide 21 are slid together as the operated means is operated.

  Specifically, when the operated means is operated to the first operation position, the light output surface of the light guide 21 and the photodiode 31 are disposed to face each other, and at this time, the light emitted from the LED 11 is emitted from the light guide 21. Is received by the photodiode 31.

  On the other hand, when the operated means is operated to the second operation position, the light output surface of the light guide 21 and the photodiode 32 are disposed to face each other, and at this time, the light emitted from the LED 11 is transmitted by the light guide 21. It is guided and received by the photodiode 32.

  On the other hand, when the operated means is operated to the third operation position, the light output surface of the light guide 21 and the photodiode 33 are arranged to face each other, and at this time, the light emitted from the LED 11 is caused by the light guide 21. It is guided and received by the photodiode 33.

  Finally, when the operated means is operated to the fourth operation position, the light output surface of the light guide 21 and the photodiode 34 are disposed to face each other, and at this time, the light emitted from the LED 11 is emitted from the light guide 21. Is received by the photodiode 34.

  Each of the photodiodes 31 to 34 generates different electrical signals when receiving light guided by the light guide 21 and when it does not, and outputs it to the control circuit 40. It has become. Then, the control circuit 40 analyzes the electrical signal input from each of the photodiodes 31 to 34, thereby determining the difference between the photodiodes (any one of 31 to 34) that has received the light emitted from the LED 11. As a basis, the position of the operation destination of the operated means is specified.

  Specifically, when an electrical signal indicating that the light guided by the light guide 21 has been received is output from the photodiode 31 to the control circuit 40, the control circuit 40 transmits the light emitted from the LED 11 to the photodiode 31. The fact that the operated means has been operated to the first operation position is specified based on the fact that the operation has been received.

  On the other hand, when an electrical signal indicating that the light guided by the light guide 21 has been received is output from the photodiode 32 to the control circuit 40, the control circuit 40 causes the photodiode 32 to transmit the light emitted from the LED 11. Based on the reception, it is specified that the operated means has been operated to the second operation position.

  On the other hand, when an electrical signal indicating that the light guided by the light guide 21 has been received is output from the photodiode 33 to the control circuit 40, the control circuit 40 causes the photodiode 33 to transmit the light emitted from the LED 11. Based on the receipt, it is specified that the operated means has been operated to the third operation position.

  Finally, when an electrical signal indicating that the light guided by the light guide 21 has been received is output from the photodiode 34 to the control circuit 40, the control circuit 40 transmits the light emitted from the LED 11 to the photodiode 34. The fact that the operated means has been operated to the fourth operation position is specified based on the fact that the operation has been received.

  Note that when such an optical contactless switch is applied to the position detection of the lever of the wiper switch unit 2, the first operation position corresponds to, for example, the wiper OFF position, and the second operation position corresponds to the wiper. It corresponds to the INT position, the third operation position corresponds to the wiper LO position, and the fourth operation position corresponds to the wiper HI position. Therefore, for example, when the lever of the wiper switch unit 2 is tilted to the third operation position (wiper LO position), this is specified by the control circuit 40, and at this time, the low-speed drive (LO) of the wiper is performed. Will be realized.

  Similarly, when such an optical contactless switch is applied to detect the position of the lever of the turn signal switch unit 3 and to detect the position of the knob of the turn signal switch unit 3, the lever and knob The position of the operation destination is specified by the control circuit 40, and the operation of the direction indicator and the headlamp according to the position of the operation destination is realized.

  In the present embodiment, the LED 11 corresponds to a light emitting unit, the photodiodes 31 to 34 correspond to a light receiving unit, and the light guide 21 corresponds to a light guide. The control circuit 40 corresponds to operation position specifying means.

As described above, according to the present embodiment, the following operations and effects can be obtained.
(1) As the lever or the like of the wiper switch unit 2 is operated, a difference in the light receiving mode by the photodiodes 31 to 34 appears. Based on this, the position of the operation destination of the lever or the like is specified. Here, since an optical contactless switch is used instead of a contact switch, the occurrence of a contact failure due to the formation of an insulating film can be avoided, and thus the reliability can be improved.

  (2) Depending on the position of the operation destination such as the lever of the wiper switch unit 2, a difference appears in the photodiode (any one of 31 to 34) that receives the light emitted from the LED 11, and the lever is based on this. The position of the operation destination such as can be specified.

  (3) By adopting a configuration in which the photodiodes 31 to 34 are fixedly arranged and the light guide 21 is displaced as the lever of the wiper switch unit 2 is operated, the lever Depending on the position of the operation destination, a difference appears in the photodiode (any one of 31 to 34) that receives the light guided by the light guide 21, and based on this, the position of the operation destination such as the lever is specified. be able to.

(4) Since the non-contact position detection is performed by the optical contactless switch, there is no mechanical sliding portion in such a detection system, so that abnormal noise can be prevented.
(5) In relation to the above (4), since there is no mechanical sliding portion in the detection system, the generation of foreign matter such as wear powder can be prevented.

(6) Although it depends largely on the lifetime of the LED 11 and the photodiodes 31 to 34, generally the lifetime can be extended.
(7) If a contact switch is used in a situation where a large current flows, even if an insulating film is formed at the contact portion, dielectric breakdown occurs due to the current, so that the switch functions sufficiently. Become. On the other hand, when a contact switch is used in a situation where only a small current flows like a lever combination switch, dielectric breakdown due to the current cannot be expected. Therefore, it is useful to employ a non-contact switch for the lever combination switch 4 that allows only a small current to flow as in this embodiment, thereby avoiding the occurrence of contact failure due to the formation of an insulating film.

(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described.
As shown in FIG. 3, in this embodiment, an optical type is provided by a photodiode array 30 having one LED 11, one optical fiber 15, one light guide 21, and four photodiodes 31 to 34. A contactless switch is configured. The LED 11, the optical fiber 15, and the photodiode array 30 are fixedly arranged, and different photodiodes (any one of 31 to 34) are guided by the light guide 21 at each operation target position of the operated means. The light guide 21 is slid in accordance with the operation of the operated means so as to receive light.

  In the present embodiment, the light emitted from the LED 11 reaches the light input surface of the light guide 21 via the optical fiber 15 and then is refracted by 90 degrees in the light guide 21. A photodiode (any one of 31 to 34) guided to the light output surface and arranged to face the light output surface receives the light.

  In the present embodiment, as in the first embodiment shown in FIG. 2, when the operated means is operated to the first operation position, the light output surface of the light guide 21 and the photodiode 31 are At the same time, the photodiode 31 finally receives the light emitted from the LED 11. At this time, as in the first embodiment, the control circuit 40 operates the operated means up to the first operation position on the basis that the photodiode 31 receives the light emitted from the LED 11. It has come to identify what has been done.

  Incidentally, when the operated means is operated to the second operation position (the third operation position, the fourth operation position), the light output surface of the light guide 21 and the photodiode 32 as in the first embodiment. (33, 34) are arranged opposite to each other, and at this time, the light emitted from the LED 11 is finally received by the photodiode 32 (33, 34). At this time, the control circuit 40 determines that the operated means is in the second operation position (the third operation position, the third operation position, based on the fact that the photodiode 32 (33, 34) receives the light emitted from the LED 11. (Operation position 4) is specified.

  In the present embodiment, the LED 11 corresponds to a light emitting unit, the photodiodes 31 to 34 correspond to a light receiving unit, and the light guide 21 corresponds to a light guide. The control circuit 40 corresponds to operation position specifying means.

As described above in detail, according to this embodiment, in addition to the operations and effects (1) to (7) according to the first embodiment, the following operations and effects can be obtained.
(8) Since the light guide 21 that does not require harness connection is displaced, the position of the operation destination such as the lever of the wiper switch unit 2 can be detected while suitably maintaining the electrical connection state.

(Third embodiment)
The third embodiment of the present invention will be described below.
As shown in FIG. 4, in this embodiment, an optical type is provided by a photodiode array 30 having one LED 11, one optical fiber 15, one light guide 21, and four photodiodes 31 to 34. A contactless switch is configured. The LED 11, the optical fiber 15, and the photodiode array 30 are fixedly arranged, and different photodiodes (any one of 31 to 34) are guided by the light guide 21 at each operation target position of the operated means. The light guide 21 is rotated as the operated means is operated so as to receive light.

  In the present embodiment, the light emitted from the LED 11 reaches the light input surface of the light guide 21 through the optical fiber 15 and then is refracted by 90 degrees twice in the light guide 21. The light guide 21 is guided to the light output surface, and a photodiode (any one of 31 to 34) arranged to face the light output surface receives the light.

  In this embodiment, as in the first embodiment shown in FIG. 2 and the second embodiment shown in FIG. 3, when the operated means is operated to the first operation position, the light is The light output surface of the guide 21 and the photodiode 31 are arranged to face each other, and at this time, the photodiode 31 finally receives the light emitted from the LED 11. At this time, similarly to the first embodiment and the second embodiment, the control circuit 40 determines that the operated means is the first based on the fact that the photodiode 31 has received the light emitted from the LED 11. It is specified that the operation has been performed up to the operation position 1.

  Incidentally, when the operated means is operated to the second operation position (the third operation position, the fourth operation position), the light of the light guide 21 is the same as in the first embodiment and the second embodiment. The output surface and the photodiode 32 (33, 34) are arranged to face each other, and at this time, the light emitted from the LED 11 is finally received by the photodiode 32 (33, 34). At this time, the control circuit 40 determines that the operated means is in the second operation position (the third operation position, the third operation position, based on the fact that the photodiode 32 (33, 34) receives the light emitted from the LED 11. (Operation position 4) is specified.

  In the present embodiment, the LED 11 corresponds to a light emitting unit, the photodiodes 31 to 34 correspond to a light receiving unit, and the light guide 21 corresponds to a light guide. The control circuit 40 corresponds to operation position specifying means.

  As described above, according to the present embodiment, the operations and effects as in (1) to (7) according to the first embodiment and the operations and effects as in (8) according to the second embodiment are achieved. Obtainable.

The first to third embodiments can be modified and embodied as follows.
A configuration may be adopted in which a plurality of photodiodes having different combinations for each operation destination position of the operated means receive the light guided by the light guide 21. In this case, the position of the operation destination of the operated means is specified by the control circuit 40 on the basis of the difference in the combination mode of the plurality of photodiodes that have received the light emitted from the LED 11.

  The light guide 21 is fixedly arranged, and different photodiodes (any one or a plurality of 31 to 34) for each operation destination position of the operated means receive the light guided by the light guide 21. A configuration in which the photodiode array 30 is displaced as the operated means is operated may be employed.

  The configuration in which the light guide 21 is displaced relative to the photodiode array 30 is not limited to the configuration in which one of the light guide 21 and the photodiode array 30 is fixedly arranged and the other is displaced. That is, a configuration in which both the light guide 21 and the photodiode array 30 are displaced may be employed. In this case, the light guide 21 is displaced, and the photodiode array 30 is displaced independently of the light guide 21. As a result, the light guide 21 is displaced relative to the photodiode array 30. . Then, different photodiodes (any one or more of 31 to 34) for each operation target position of the operated means may receive light guided by the light guide 21.

(Fourth embodiment)
The fourth embodiment of the present invention will be described below.
As shown in FIG. 5, in the present embodiment, an optical array 10 having four LEDs 11 to 14, a single light transmission window 51, and a single optical element having a light shielding portion 52 around it. The action plate 50 and one photodiode 31 constitute an optical contactless switch. In addition, each of LED11-14 blinks with a mutually different period. The LED array 10 and the photodiode 31 are fixedly arranged, and light having different blinking periods is transmitted through the light transmitting window 51 for each position of the operation destination of the operated means so that the photodiode 31 receives the light. In addition, the optical action plate 50 is slid as the operated means is operated.

  Specifically, when the operated means is operated to the first operation position, the LED 11 and the light transmission window 51 are disposed to face each other, and at this time, the light emitted from the LED 11 passes through the light transmission window 51. This is received by the photodiode 31.

  On the other hand, when the operated means is operated to the second operation position, the LED 12 and the light transmission window 51 are disposed to face each other, and at this time, the light emitted from the LED 12 passes through the light transmission window 51, This is received by the photodiode 31.

  On the other hand, when the operated means is operated to the third operation position, the LED 13 and the light transmission window 51 are disposed to face each other, and at this time, the light emitted from the LED 13 passes through the light transmission window 51, This is received by the photodiode 31.

  Finally, when the operated means is operated to the fourth operation position, the LED 14 and the light transmission window 51 are disposed to face each other, and at this time, the light emitted from the LED 14 is transmitted through the light transmission window 51. This is received by the photodiode 31.

  The photodiode 31 generates an electrical signal corresponding to the blinking cycle of the light received by the photodiode 31 and outputs it to the control circuit 40. Then, the control circuit 40 analyzes the electrical signal input from the photodiode 31 so as to specify the position of the operation destination of the operated means based on the difference in the blinking cycle of the light received by the photodiode 31. It has become.

  Specifically, when an electrical signal indicating that the light emitted from the LED 11 has been received is output from the photodiode 31 to the control circuit 40, the control circuit 40 receives the light emitted from the LED 11 by the photodiode 31. Based on this fact, it is specified that the operated means has been operated to the first operation position.

  On the other hand, when an electrical signal indicating that the light emitted from the LED 12 has been received is output from the photodiode 31 to the control circuit 40, the control circuit 40 receives the light emitted from the LED 12. Based on this fact, it is specified that the operated means has been operated to the second operation position.

  On the other hand, when an electrical signal indicating that the light emitted from the LED 13 is received is output from the photodiode 31 to the control circuit 40, the control circuit 40 receives the light emitted from the LED 13. Based on this fact, it is specified that the operated means has been operated to the third operation position.

  Finally, when an electrical signal indicating that the light emitted from the LED 14 has been received is output from the photodiode 31 to the control circuit 40, the control circuit 40 receives the light emitted from the LED 14. Based on this fact, it is specified that the operated means has been operated to the fourth operation position.

  In the present embodiment, the LEDs 11 to 14 correspond to light emitting means, the photodiode 31 corresponds to light receiving means, and the optical action plate 50 corresponds to optical action means. The light transmission window 51 corresponds to a light transmission part, and the light shielding part 52 corresponds to a light shielding part. The control circuit 40 corresponds to operation position specifying means.

As described above, according to the present embodiment, the following operations and effects can be obtained.
(9) As the lever of the wiper switch unit 2 is operated, a difference in the light receiving mode by the photodiode 31 appears, and based on this, the position of the operation destination of the lever or the like is specified. Here, since an optical contactless switch is used instead of a contact switch, the occurrence of a contact failure due to the formation of an insulating film can be avoided, and thus the reliability can be improved.

  (10) Depending on the position of the operation destination such as the lever of the wiper switch unit 2, a difference appears in the mode of light received by the photodiode 31, and based on this, the position of the operation destination such as the lever can be specified. .

  (11) By adopting a configuration in which the LEDs 11 to 14 are fixedly arranged and the optical action plate 50 is displaced as the lever of the wiper switch unit 2 is operated, the lever and the like Depending on the position of the operation destination, a difference appears in the mode of light that passes through the light transmission window 51 of the optical action plate 50 (= light received by the photodiode 31), and the position of the operation destination of the lever or the like is based on this. Can be specified.

  (12) Since the non-contact position detection is performed by the optical contactless switch in the same manner as the operation and effect as in (4) according to the first embodiment, the mechanical sliding is performed in such a detection system. There is no moving part, so that abnormal noise can be prevented.

(13) In relation to the above (12), since there is no mechanical sliding portion in the detection system, generation of foreign matters such as wear powder can be prevented.
(14) The lifespan of the LEDs 11 to 14 and the photodiode 31 is large, but generally the lifespan can be extended.

  (15) Since the configuration that displaces the optical action plate 50 that does not require harness connection is adopted, it is possible to detect the position of the operation destination such as the lever of the wiper switch unit 2 while suitably maintaining the electrical connection state. .

(16) The operation and effect as in (7) according to the first embodiment can be obtained.
Note that the fourth embodiment can be modified and embodied as follows.
The light emitted from each of the plurality of LEDs having different combinations depending on the operation destination position of the operated means passes through the light transmitting window 51 of the optical action plate 50 and is received by the photodiode 31. A configuration may be adopted. In this case, the position of the operation destination of the operated means is specified by the control circuit 40 based on the difference in the combination mode of the blinking cycle of the light emitted from each of the plurality of LEDs.

  The optical action plate 50 is fixedly arranged, and light having a different blinking period is transmitted through the light transmitting window 51 and received by the photodiode 31 for each position of the operation destination of the operated means. A configuration in which the LED array 10 is displaced as the means is operated may be employed.

  The configuration in which the optical action plate 50 is displaced relative to the LED array 10 is not limited to a configuration in which one of the optical action plate 50 and the LED array 10 is fixedly arranged and the other is displaced. That is, a configuration in which both the optical action plate 50 and the LED array 10 are displaced may be employed. In this case, the optical working plate 50 is displaced, and the LED array 10 is displaced independently of the optical working plate 50. As a result, the optical working plate 50 is displaced relative to the LED array 10. That's fine. Then, light having different blinking periods may be transmitted through the light transmission window 51 and received by the photodiode 31 for each position of the operation destination of the operated means.

  Instead of the configuration in which the optical action plate 50 is slid relative to the LED array 10, a configuration in which the optical action plate 50 is rotated relative to the LED array 10 may be employed.

(Fifth embodiment)
Hereinafter, a fifth embodiment of the present invention will be described.
As shown in FIG. 6, in the present embodiment, one LED 11, one light guide 21, one light shielding plate 61, and one detector 35 constitute an optical contactless switch. The LED 11, the light guide 21, and the detector 35 are fixedly arranged, and the operated means is arranged so that the detector 35 receives light without being shielded by the light shielding plate 61 with different areas for each position of the operated means of the operated means. The light shielding plate 61 is rotated in accordance with the operation.

  In the present embodiment, the light emitted from the LED 11 is guided to the light output surface of the light guide 21 so as to be reflected and refracted toward the light receiving surface of the detector 35 in the light guide 21, and the light output thereof. A portion of the light receiving surface of the detector 35 disposed opposite to the surface that is not interfered with the light shielding plate 61 receives the light.

  Specifically, when the operated means is operated to the first operation position, the light receiving surface of the detector 35 is not interfered with the light shielding plate 61 at all. That is, at this time, the ratio of the area of the light receiving surface that can receive the light guided by the light guide 21 in the detector 35 (effective light receiving area of the detector 35) is 100% of the total area of the light receiving surface of the detector 35. It has become.

  On the other hand, when the operated means is operated to the second operation position, 25% of the light receiving surface of the detector 35 is interfered with the light shielding plate 61. That is, at this time, the ratio of the effective light receiving area of the detector 35 is 75% of the total area of the light receiving surface of the detector 35.

  On the other hand, when the operated means is operated up to the third operation position, 50% of the light receiving surface of the detector 35 is interfered with the light shielding plate 61. That is, at this time, the ratio of the effective light receiving area of the detector 35 is 50% of the total area of the light receiving surface of the detector 35.

  Finally, when the operated means is operated to the fourth operation position, all of the light receiving surface of the detector 35 is interfered with the light shielding plate 61. That is, at this time, the ratio of the effective light receiving area of the detector 35 is 0% of the total area of the light receiving surface of the detector 35.

  The detector 35 has an electric resistance value that changes in accordance with the area of the light guided by the light guide 21. And the control circuit 40 monitors the voltage according to the electric resistance value of the detector 35, and based on the difference in the area (the difference in the monitoring voltage) that the detector 35 receives the light guided by the light guide 21, The position of the operation destination of the operated means is specified.

  Specifically, when acquiring a voltage indicating that the ratio of the effective light receiving area is 100%, the control circuit 40 determines that the operated means is at the first operation position on the basis of the effective light receiving area being 100%. It has come to specify that it was operated until.

  On the other hand, when the voltage indicating that the ratio of the effective light receiving area is 75% is acquired, the control circuit 40 determines that the operated means reaches the second operation position on the basis of the effective light receiving area being 75%. It is designed to identify the operation.

  On the other hand, when acquiring a voltage indicating that the proportion of the effective light receiving area is 50%, the control circuit 40 determines that the operated means reaches the third operation position on the basis of the effective light receiving area being 50%. It is designed to identify the operation.

  Finally, when a voltage indicating that the ratio of the effective light receiving area is 0% is acquired, the control circuit 40 determines that the operated means is the fourth operation position on the basis that the effective light receiving area is 0%. It has come to specify that it was operated until.

  In this embodiment, the LED 11 corresponds to a light emitting means, the detector 35 corresponds to a light receiving means, and the light shielding plate 61 corresponds to a light shielding body. The control circuit 40 corresponds to operation position specifying means.

As described above, according to the present embodiment, the following operations and effects can be obtained.
(17) As the lever or the like of the wiper switch unit 2 is operated, a difference in the light receiving mode by the detector 35 appears. Based on this, the position of the operation destination of the lever or the like is specified. Here, since an optical contactless switch is used instead of a contact switch, the occurrence of a contact failure due to the formation of an insulating film can be avoided, and thus the reliability can be improved.

  (18) By adopting a configuration in which the detector 35 is fixedly disposed and the light shielding plate 61 is displaced in accordance with the operation of the lever or the like of the wiper switch unit 2, the operation destination of the lever or the like can be changed. Depending on the position, a difference appears in the light receiving area by the detector 35 (and eventually the electrical characteristics such as the electrical resistance value), and based on this, the position of the operation destination of the lever or the like can be specified.

  (19) Since the non-contact position detection is performed by the optical contactless switch in the same manner as the function and effect as in (4) according to the first embodiment, the mechanical sliding is performed in such a detection system. There is no moving part, so that abnormal noise can be prevented.

(20) In relation to the above (19), since there is no mechanical sliding portion in the detection system, generation of foreign matter such as wear powder can be prevented.
(21) The life of the LED 11 and the detector 35 is large, but generally the life can be extended.

  (22) Since the configuration in which the light shielding plate 61 that does not require harness connection is displaced is adopted, the position of the operation destination such as the lever of the wiper switch unit 2 can be detected while suitably maintaining the electrical connection state.

(23) The operation and effect as in (7) according to the first embodiment can be obtained.
The fifth embodiment can be modified and embodied as follows.
The light-shielding plate 61 is fixedly arranged, and the operated means is operated so that the detector 35 receives light without being shielded by the light-shielding plate 61 with different areas for each operation target position of the operated means. A configuration may be adopted in which the detector 35 is displaced accordingly.

  The configuration in which the light shielding plate 61 is displaced relative to the detector 35 is not limited to a configuration in which one of the light shielding plate 61 and the detector 35 is fixedly arranged and the other is displaced. That is, a configuration in which both the light shielding plate 61 and the detector 35 are displaced may be employed. In this case, the light shielding plate 61 is displaced, and the detector 35 is displaced independently of the light shielding plate 61. As a result, the light shielding plate 61 may be displaced relative to the detector 35. Then, the detector 35 may receive light without being shielded by the light shielding plate 61 with different areas for each position of the operation destination of the operated means.

Instead of the configuration in which the light shielding plate 61 is rotated relative to the detector 35, a configuration in which the light shielding plate 61 is slid relative to the detector 35 may be employed.
Since the electric resistance value of the detector 35 changes according to the light receiving area, the monitoring voltage by the control circuit 40 also depends on the light receiving area. Therefore, the present invention can be applied to detection of not only four operation positions such as the first operation position to the fourth operation position as in the fifth embodiment but also more operation positions. That is, the position of the operation destination of the operated means can be detected linearly. In short, a high resolution can be obtained when detecting the position of the operation destination of the operated means.

The first to fifth embodiments can be modified and embodied as follows.
A moderation mechanism may be provided that gives a feeling of operation to the operator when the operated means is operated.

  A cover should be provided to prevent disturbance light from affecting the optical contactless switch. It should be noted that it is convenient to prevent intrusion of dust with such a cover.

A phototransistor may be used as the light receiving means.
Of course, the light emitting means is not limited to LEDs.
An optical contactless switch may be embodied as a lever combination switch that is applied to a momentary switch.

The perspective view which shows the important point in the vehicle in which a lever combination switch is provided. The principle figure which shows the optical contactless switch of 1st Embodiment. The principle figure which shows the optical contactless switch of 2nd Embodiment. The principle figure which shows the optical non-contact switch of 3rd Embodiment. The principle figure which shows the optical non-contact switch of 4th Embodiment. The principle figure which shows the optical non-contact switch of 5th Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 4 ... Lever combination switch, 11-14 ... LED (light emission means), 21 ... Light guide (light guide), 31-34 ... Photodiode (light reception means), 35 ... Detector (light reception means), 40 ... Control circuit ( (Operation position specifying means), 50... Optical action plate (optical action means), 51... Light transmission window (light transmission part), 52.

Claims (6)

A lever combination that detects the position of the operation destination of the operated means when the operated means operated to operate the in-vehicle equipment is detected, and realizes the operation of the in-vehicle equipment according to the position of the operated destination In the switch
A light emitting means for emitting light, and a light receiving means for receiving the light emitted from the light emitting means,
As the operated means is operated, the light receiving means is configured to have different modes when receiving light emitted from the light emitting means,
Lever combination characterized by comprising an operation position specifying means for specifying the position of the operation destination of the operated means on the basis of a difference in mode when the light receiving means receives light emitted from the light emitting means. switch. The lever combination switch according to claim 1,
A plurality of light receiving means are provided such that different light receiving means for each position of the operated means of the operated means receive light emitted from the light emitting means,
The lever combination switch characterized in that the operation position specifying means specifies the position of the operation destination of the operated means on the basis of a difference in light receiving means that has received light emitted from the light emitting means. The lever combination switch according to claim 2,
A light guide for guiding the light emitted from the light emitting means to the light receiving means is interposed between the light emitting means and the light receiving means;
The light guide is operated as the light receiving means is operated in such a manner that the light receiving means different from each other for each position of the operation destination of the operated means receives the light guided by the light guide. Lever combination switch characterized by being displaced relative to The lever combination switch according to claim 1,
A plurality of light emitting means are provided so that light of different modes is emitted from the light emitting means for each position of the operation destination of the operated means, and the light receiving means receives the light.
The lever combination switch characterized in that the operation position specifying means specifies the position of the operation destination of the operated means on the basis of the difference in the form of light received by the light receiving means. The lever combination switch according to claim 4,
An optical action means having a light shielding portion for blocking light emitted from the light emitting means and a light transmitting portion for transmitting light emitted from the light emitting means is interposed between the light emitting means and the light receiving means;
The operated means is operated so that light of different modes for each position of the operated means of the operated means is transmitted through the light transmitting portion of the optical action means and the light receiving means receives the light. Accordingly, the optical action means is displaced relative to the light emitting means. The lever combination switch according to claim 1,
A light-blocking body that blocks light emitted from the light-emitting means is interposed between the light-emitting means and the light-receiving means,
When the operated means is operated so that the light receiving means receives light without being shielded by the light shielding body with different areas for each position of the operation destination of the operated means, A lever combination switch that is displaced relative to a light receiving means.

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