JP2022036788A - Switch device - Google Patents

Abstract

To make a lighting window of an operation handle more uniformly emit light.SOLUTION: A switch device comprises: a device main body; an operation handle 3; a light source; a first light path 10; and a second light path 11. The operation handle 3 includes a lighting window 35 in a first operation part 3R. The light source is fixed to the device main body. The first light path 10 is fixed to the device main body, makes the light from the light source inject thereon to guide the light. The second light path 11 is fixed to the operation handle 3. The second light path 11 includes an incidence surface 11d and an emission surface 11e. An axis passing through a center of the lighting window 35 is a first center axis L6, an axis passing through the center of the emission surface 11e and parallel to the first center axis L6 is a second center axis L7, and a direction where an intensity distribution P2 of emission light in the emission surface 11e is deviated from the center of the emission surface 11e is a first direction. The first center axis L6 is arranged on the side closer to a first direction than the second center axis L7.SELECTED DRAWING: Figure 10

Description

The present disclosure relates to a switch device, and more particularly to a switch device with an operating handle.

The switch (switch device) described in Patent Document 1 includes an operation handle, a display unit (lighting window), a light emitting source (light source), an instrument (device main body), and a condensing unit (second translucent path). And have. The operation handle is swingably supported by the body. The light emitting source is fixed to the back side of the operation handle. The display unit is provided on the front surface of the operation handle. The condensing unit guides the light from the light emitting source to the display unit.

Japanese Patent Application Laid-Open No. 2003-151402

In the switch described in Patent Document 1, the light collecting portion is bent in the middle of the light guide direction. Therefore, the light that guides the condensing unit is condensed in a range deviated from the center on the emission surface of the condensing unit. As a result, the display portion of the operation handle is not uniformly emitted by the light of the light emitting source.

In view of the above problems, it is an object of the present disclosure to provide a switch device capable of more uniformly emitting light from a lighting window of an operation handle.

The switch device according to one aspect of the present disclosure includes a device main body, an operation handle, a contact circuit, a light source, a first translucent path, and a second transmissive path. The operation handle has a first operation unit and a second operation unit, and is arranged so as to be displaceable with respect to the main body of the apparatus. When the first operation unit and the second operation unit are operated, the first operation unit and the second operation unit are displaced in different directions from each other. The operation handle has a lighting window in the first operation unit. The contact circuit switches between an open state and a closed state according to the displacement of the operation handle. The light source is fixed to the device body. The first translucent path is fixed to the main body of the device, and light from the light source is incident and guided. The second light transmission path is fixed to the operation handle. The second light-transmitting path has an incident surface and an emitted surface. The incident surface is incident with the emitted light of the first translucent path. The exit surface emits light incident on the incident surface to the lighting window. The axis passing through the center of the lighting window is set as the first central axis, the axis passing through the center of the emitting surface and parallel to the first central axis is set as the second central axis, and the first intensity distribution of the emitted light is set on the emitting surface. The direction deviated from the center of the emission surface is defined as the first direction. The first central axis is arranged on the side in the first direction with respect to the second central axis.

The switch device according to the present disclosure has an effect that the lighting window of the operation handle can emit light more uniformly.

FIG. 1 is a perspective view of the switch device according to the embodiment as viewed from the front side. FIG. 2 is a perspective view of the same switch device as viewed from the rear side. FIG. 3 is a cross-sectional view taken along the line A1-A1 of FIG. 1 when the operation unit on the right side is lifted. FIG. 4 is a cross-sectional view taken along the line A1-A1 of FIG. 1 when the operation unit on the right side is pressed. FIG. 5 is an exploded perspective view showing the same switch device. FIG. 6 is a perspective view showing the cover of the switch device of the same as above. FIG. 7 is an exploded perspective view showing a part of the switch device of the same as above. FIG. 8 is a perspective view of the operation handle of the switch device of the same as above, as viewed from the rear side. FIG. 9 is a side view showing the first translucent path of the switch device of the same as above. FIG. 10 is a perspective view showing a second translucent path of the switch device of the same as above. FIG. 11 is a side view showing a state in which the second translucent path of the switch device of the above is fixed to the operation handle. 12A and 12B are side views showing how the translucent path guides the light of the first light source. 13A and 13B are side views showing how the translucent path guides the light of the second light source. FIG. 14 is an explanatory diagram illustrating the relationship between the distance between the central axis of the lighting window and the central axis of the exit surface of the second translucent path and the intensity distribution of the emitted light of the light window.

(Embodiment)
(Overview)
The switch device 1 of the present embodiment will be described with reference to FIGS. 1 to 14. In the following description, unless otherwise specified, the vertical, horizontal, and front-back directions of the switch device 1 are defined as the directions indicated by the up-down, left-right, and front-back arrows shown in FIG. These arrows are provided solely for the purpose of assisting explanation and are not accompanied by substance. Further, the above-mentioned provision of the direction is not intended to limit the usage mode of the switch device 1 of the present embodiment.

The switch device 1 of the present embodiment is a seesaw type (also referred to as a tumbler type or rocker type) switch device for switching the operating state of the electric device to be operated. The switch device 1 can be applied as, for example, a switch device attached to an indoor wall surface and for switching between lighting and extinguishing of a lighting fixture (electrical device) installed indoors.

As shown in FIGS. 1 and 2, the switch device 1 includes a device main body 2 and an operation handle 3. The device main body 2 is a portion that houses circuit components including open / close contacts. The operation handle 3 is a portion operated by the user, for example, a seesaw-type operation handle, which is arranged on the front surface 22j (opposing surface) of the apparatus main body 2. That is, the operation handle 3 is arranged in front of the device main body 2. The operation handle 3 has an operation unit 3L (second operation unit) and an operation unit 3R (first operation unit) on both left and right sides. One of the operation units 3L and 3R on the left and right sides of the operation handle 3 (for example, the operation unit 3R on the right side) is provided with a lighting window 35 for emitting light outside the operation unit 3R. ..

More specifically, the lighting window 35 is provided on, for example, the front surface 3g of the operation unit 3R, and the lighting window 35 is provided with a lens 91a that transmits light. Thereby, the emitted light of the lighting window 35 can illuminate a wide range on the front surface of the operation handle.

Further, the rear surface 21b of the apparatus main body 2 is provided with a plurality of (for example, four) wiring holes 22k into which wirings from the electric device to be operated are inserted. By inserting the wiring from the electric device to be operated into the wiring hole 22k, the electric device to be operated and the switch device 1 are electrically connected.

In this switch device 1, when one of the operation units 3L and 3R on both sides of the operation handle 3 is pressed, the other is lifted (that is, when the operation units 3L and 3R are operated, the operation units 3L and 3R are mutually lifted. Displace in different directions), perform seesaw operation. By alternately pressing the operation units 3L and 3R on both sides of the operation handle 3, the opening / closing contacts in the apparatus main body 2 are alternately opened / closed. At that time, the lighting window 35 is always lit, or the lighting window 35 is switched on or off according to the pressing and lifting of the operation unit 3R.

In this switch device 1, a light source is provided in the device main body 2. Then, the light of the light source is guided to the lighting window 35 by the first translucent path 10 fixed to the apparatus main body 2 and the second translucent path 11 fixed to the operation handle 3, and is guided from the lighting window 35. It is emitted. As a result, the lighting window 35 emits light.

As shown in FIG. 3, the switch device 1 is characterized by including light-shielding portions 22i and 36. As a result, the emission light of the first light transmission path 10 is suppressed from leaking to the outside of the switch device 1. Further, the switch device 1 is characterized in that the central axis of the lighting window 35 and the central axis of the exit surface of the second translucent path 11 are deviated from each other. As a result, the lighting window 35 emits light more uniformly. These features will be described in detail below.

(Detailed explanation)
As shown in FIG. 5, the switch device 1 includes a device main body 2, an operation handle 3, a contact device 4 (contact circuit), a light source unit 5, a reversing handle 6, a reversing spring 7, a conversion spring 8, and a translucent path 9. ..

(Device body 2)
As shown in FIG. 5, the device main body 2 accommodates the components of the switch device 1 (operation handle 3, contact device 4, light source unit 5, reversing handle 6, reversing spring 7, conversion spring 8, translucent path 9). It is an outer shell.

The apparatus main body 2 has a body 21 and a cover 22.

The body 21 is a rectangular parallelepiped box with an open front surface. The contact device 4 and the light source unit 5 are housed in the body 21. The cover 22 is a component in which the operation handle 3 is operably supported (displaceable), and is attached to the front surface side of the body 21. The cover 22 has a rectangular frame shape having an opening 22c. The body 21 and the cover 22 are made of synthetic resin.

The body 21 has a plurality of (for example, four) protrusions 21a (see FIGS. 1 and 2). The plurality of protrusions 21a are provided on both side surfaces of the body 21 in the lateral direction (vertical direction) so as to be separated from each other in the longitudinal direction of the body 21. The cover 22 has a plurality of (eg, four) tongue pieces 22a. The plurality of tongue pieces 22a extend posteriorly from the posterior edge of the cover 22. The tongue piece 22a has a hole 22b. The body 21 and the cover 22 are assembled to each other by fitting the hole 22b of the tongue piece 22a and the protrusion 21a to each other (see FIG. 1).

More specifically, as shown in FIG. 6, the cover 22 includes the above-mentioned opening 22c, a fixing portion 22d, a pair of bearing protrusions 22f, a pair of bearing recesses 22h, and a first light-shielding portion 22i. It has a storage recess 22q.

The opening 22c is a place where the reversing handle 6 is arranged. The opening 22c penetrates the cover 22 in the front-back direction (front-back direction). The opening 22c is, for example, rectangular. The opening 22c is provided, for example, in the center of the cover 22 in the longitudinal direction.

The fixing portion 22e is a portion for fixing the first light transmission path 10. The fixed portion 22e projects from the inner side surface 22m of the opening 22c to the inside of the opening 22c. The inner side surface 22m is an inner side surface on one side (for example, the right side) in the longitudinal direction (left-right direction) of the cover front surface 22j on the inner peripheral surface of the opening 22c. The fixing portion 22e projects from the center of the opening 22c to the inside of the opening 22c in the longitudinal direction of the cover front surface 22j.

The fixed portion 22e has, for example, a rectangular box shape, and the back surface (rear surface) and the end surface on the protruding side are open. The fixing portion 22e has a pair of fixing holes 22n. The pair of fixing holes 22n is a portion where the pair of fixing protrusions 10g of the first light transmission path 10 are hooked. The pair of fixing holes 22n are provided on the side walls on both sides of the cover front surface 22j in the fixing portion 22e in the lateral direction (vertical direction). The pair of fixing holes 22n penetrate in the thickness direction (vertical direction) of the side wall.

In the fixed portion 22e, the first light transmission path 10 is accommodated from the back surface opening of the fixed portion 22e. Further, the exit surface of the first light transmission path 10 is exposed from the end face opening of the fixed portion 22e.

The pair of bearing protrusions 22f project forward from the center in the longitudinal direction (horizontal direction) at both side edges in the lateral direction (vertical direction), for example, on the front surface 22j of the cover. A bearing hole 22g into which a pair of shaft protrusions 32 of the operation handle 3 are inserted is formed on each facing surface of the pair of bearing protrusions 22f. Each of the pair of bearing holes 22g penetrates in the thickness direction (vertical direction) of the bearing protrusion 22f. Each of the pair of bearing holes 22g is a substantially pentagonal hole having a triangular shape at the front and a rectangular shape at the rear.

The pair of bearing recesses 22h is a portion into which the pair of shaft protrusions 32 of the reversing handle 6 are inserted. The pair of bearing recesses 22h are provided in a concave shape in the center of the longitudinal direction on the inner surfaces of both sides of the opening 22c in the lateral direction. The pair of bearing recesses 22h are opened on the back surface (rear surface) of the cover 22. Each of the pair of bearing recesses 22h has a substantially triangular shape, for example, when viewed from the lateral direction (vertical direction) of the opening 22c.

The first light-shielding unit 22i is a member that shields at least a part of the light emitted from the light-emitting surface of the first light-transmitting path 10. Further, the first light-shielding portion 22i is a member that shields at least a part of the emitted light (leakage light) from the side surface of the second light-transmitting path 11. The first light-shielding portion 22i has, for example, a plate shape. The first light-shielding portion 22i projects from, for example, the edge portion 22p of the opening 22c in the front surface 22j (opposing surface) of the cover in a direction approaching the operation handle 3 (that is, in the front direction). The front surface 22j of the cover is a facing surface facing the operation handle 3. The edge portion 22p is an edge portion of the peripheral edge of the opening 22c facing the fixing portion 22e in the longitudinal direction (left-right direction) of the cover front surface 22j. The first light-shielding portion 22i is formed, for example, over the entire longitudinal direction (vertical direction) of the edge portion 22p of the opening 22c.

The accommodating recess 22q is a portion in which the second light-shielding portion 36 of the operation handle 3 is accommodated when the operation portion 3R on the lighting window 35 side of the operation handle 3 is pressed. The accommodating recess 22q is provided in a concave shape on the outer surface of the first light-shielding portion 22i in the left-right direction on the front surface 22j of the cover. The accommodating recess 22q is provided, for example, along the first light-shielding portion 22i over the entire longitudinal direction (vertical direction) of the first light-shielding portion 22i.

(Contact device 4)
The contact device 4 includes an open / close contact for switching the operating state (operation and stop) of the electric device to be operated, and an external connection terminal for connecting to wiring from the electric device to be operated. More specifically, as shown in FIG. 7, the contact device 4 includes terminal plates 41 to 43, a support plate 44, an opening / closing element 45, and a lock spring 46.

Each of the terminal boards 41 to 43 is a portion that is electrically connected to the wiring from the electric device to be operated. The terminal plates 41 and 42 are housed in one end (for example, the left end) of the body 21 in the longitudinal direction (left-right direction). The terminal board 43 is housed in the other end portion (for example, the right end portion) of the body 21 in the longitudinal direction. The terminal plates 41 and 42 are provided with fixed contacts 41a and 42b. The switch 45 is arranged between the fixed contacts 41a and 42b. One lock spring 46 is housed in each of the terminal plates 41 and 42, and two lock springs 46 are housed in the terminal board 43.

The support plate 44 is arranged in the center of the bottom surface of the body 21 and is electrically connected to the terminal plate 43. The switch 45 is housed in the center of the body 21 in the longitudinal direction. The lower end of the switch 45 is in contact with the support plate 44. The switch 45 can swing on the support plate 44 with its lower end as a fulcrum.

The switch 45 has, for example, a plate shape. The front end portion of the switch 45 is provided with a groove 45c into which the peripheral edge of the tubular portion 62 described later of the reversing handle 6 is fitted. The switch 45 has movable contacts 45a and 45b on the main surfaces on both sides, respectively. The movable contact 45a and the fixed contact 41a form one open / close contact, and the movable contact 45b and the fixed contact 41b form one open / close contact. When the switch 45 swings, the closed state and the open state of the two open / close contacts are switched alternately. These two open / close contacts constitute the above open / close contact.

In the present embodiment, as described later, when the operation handle 3 operates with a seesaw, the reversing handle 6 operates with a seesaw, and when the reversing handle 6 operates with a seesaw, the switch 45 swings and the above two opening / closing contacts are closed. And switch to the open state. Therefore, the contact device 4 switches between the open state and the closed state according to the operation of the operation handle.

Such a switch device in which two switching contacts are alternately switched by a common switch 45 is called a three-way switch. This three-way switch is provided, for example, on the upper floor and the lower floor of the stairs, and can be used as a switch device for switching on and off of a common lighting fixture that illuminates the stairs. In the present embodiment, the switch device 1 is a three-way switch, but the switch device 1 is not limited to the three-way switch.

A wiring hole 22k (see FIG. 2) is provided in a portion of the rear wall of the body 21 corresponding to each of the four lock springs 46. By inserting the electric wire into the body 21 through the wiring hole 22k, the tip of the electric wire is sandwiched between the lock spring 46 and the terminal plates 41, 42, 43. As a result, the tip of the electric wire is electrically connected to the terminal plates 41 to 43. These terminal boards 41 to 43 form the above-mentioned external connection terminal.

(Light source unit 5)
As shown in FIG. 7, the light source unit 5 includes a circuit board 52 and two light sources (first light source 51a and second light source 51b).

The two light sources 51a and 51b are light sources that emit light emitted from the lighting window 35. The two light sources 51a and 51b emit light having different light colors (for example, red light and white light). The first light source 51a is a light source for a position display function, and emits, for example, white light. The second light source 51b is a light source for a pilot function, and emits, for example, red light. The two light sources 51a and 51b are, for example, LEDs (Light Emitting Diodes). The two light sources 51a and 51b are provided on the front surface of the circuit board 52 in a state of being arranged side by side in the longitudinal direction (left-right direction) of the body 21. The two light sources 51a and 51b are arranged behind the operation handle 3 in the device main body 2. More specifically, the two light sources 51a and 51b are arranged behind the operation unit 3L of the operation handle 3 (that is, the operation unit not provided with the lighting window 35) in the apparatus main body 2. In other words, the two light sources 51a and 51b are arranged in a portion of the apparatus main body 2 facing the operation unit 3L.

In this way, the light sources 51a and 51b and the lighting window 35 are arranged on opposite sides of each other in the left-right direction (that is, the direction in which the two operating units 3L and 3R are arranged). As a result, the distance between the light sources 51a and 51b and the lighting window 35 can be secured. As a result, it is possible to suppress a change in the brightness of the lighting window 35 with respect to the operation of the operation handle 3.

The first light source 51a is always lit regardless of whether the open / close contact of the contact device 4 is energized or de-energized (that is, regardless of whether the electric device to be operated is operated or stopped). The second light source 51b is switched on and off according to the energization and de-energization of the open / close contact in the closed state of the contact device 4 (that is, according to the operation and stop of the electric device to be operated). Specifically, the second light source 51b is turned off when the closed open / close contact is energized (that is, when the electric device to be operated is operating), and the closed open / close contact is not energized. When (that is, when the electrical device to be operated is stopped), it is lit.

The light source unit 5 is housed above the terminal plates 41 and 42 at one end (for example, the left end) in the longitudinal direction (left-right direction) of the body 21. That is, the two light sources 51a and 51b are housed in one end (left end) side in the longitudinal direction in the body 21 and are arranged in the longitudinal direction of the body 21.

(Reversing handle 6)
The reversing handle 6 is a handle that opens and closes the opening / closing contact of the contact device 4 according to the operating state of the operating handle 3. As shown in FIG. 5, the reversing handle 6 has a reversing handle main body 61 and a tubular portion 62.

The reversing handle main body 61 has a bottom portion 61a, two side wall portions 61b, a plurality of (for example, two) fitting protrusions 61c, a pair of shaft protrusions 61d, and a pair of hook protrusions 61e.

The bottom portion 61a has a rectangular plate shape. Each of the two side wall portions 61b has a rectangular plate shape. The two side wall portions 61b project forward from both the upper and lower edges of the bottom portion 61a. The two fitting protrusions 61c are protrusions for fixing the conversion spring 8. Two fitting protrusions 61c are provided one at the center of each of the two side wall portions 61b. The pair of shaft protrusions 61d is a portion swingably supported by the pair of bearing recesses 22h of the cover 22. Each of the pair of shaft protrusions 61d is, for example, a triangular column with a front end as an apex angle. The pair of shaft protrusions 61d are provided so as to project from the outer surface of each of the pair of side wall portions 61b. The pair of hooking protrusions 61e is a portion on which the hooking piece 83 of the conversion spring 8 is hooked. One pair of hooking protrusions 61e is provided on the outer surface of each of the two side wall portions 61b.

The tubular portion 62 is a portion that accommodates the reversing spring 7. The tubular portion 62 is provided so as to project rearward from the rear surface of the reversing handle main body 61. The rear peripheral edge of the tubular portion 62 is hooked on the groove 45c (see FIG. 7) at the front end portion of the switch 45. In this state, a reversing spring 7 made of a coil spring is held between the cylinder portion 62 and the switch 45.

The reversing handle 6 is arranged in the opening 22c of the cover 22 (see FIG. 3). In this state, the pair of shaft protrusions 61d of the reversing handle 6 are inserted into the pair of bearing recesses 22h of the cover 22. As a result, the reversing handle 6 can swing (that is, seesaw operation) with respect to the cover 22 with the front end of the pair of shaft protrusions 61d as a fulcrum. Due to the swing of the reversing handle 6, the direction of the spring force acting on the switch 45 from the reversing spring 7 is reversed, and one of the movable contacts 45a and 45b is the fixed contact 41a, corresponding to the movable contact 45a and 45b. Contact 42b. That is, the terminal board 43 electrically connected to the switch 45 is selectively connected to any one of the two terminal boards 41 and 42.

(Operation handle 3)
The operation handle 3 operates (operates) the seesaw according to the operation of the operator. The operation handle 3 has a shallow box shape with an open rear surface. As shown in FIG. 8, the operation handle 3 is lit with an operation handle main body 31, a pair of shaft protrusions 32, a plurality of (for example, four) contact portions 33, and a plurality of (for example, two) fixed protrusions 34. It has a window 35 and a second light-shielding portion 36.

The operation handle main body 31 has a main wall portion 31a and a peripheral wall portion 31b. The main wall portion 31a has, for example, a rectangular plate shape. The main wall portion 31a is bent in a substantially V shape along the center line L3 (see FIG. 5). As a result, the portions on both sides of the center line L3 on the main wall portion 31a are inclined so as to project forward. The center line L3 extends in the lateral direction (vertical direction) of the main wall portion 31a at the center of the main wall portion 31a in the longitudinal direction (horizontal direction). The peripheral wall portion 31b rises behind the main wall portion 31a from the entire outer peripheral edge of the main wall portion 31a. The peripheral wall portion 31b is configured such that the upper wall portion 31c, the lower wall portion 31d, the left wall portion 31e, and the right wall portion 31f are integrally connected in an annular shape. The upper wall portion 31c and the lower wall portion 31d are bent in a substantially V shape according to the substantially V-shaped bend of the main wall portion 31a. The outer surface of the main wall portion 31a constitutes the front surface 3g of the operation handle 3.

In the present embodiment, the front surface of the main wall portion 31a constitutes the front surface 3g of the operation handle 3. Further, the left and right portions of the center line L3 in the operation handle main body 31 constitute the operation portions 3L and 3R on both sides of the operation handle 3. The two operation units 3L and 3R are arranged in the left-right direction. That is, the direction (arrangement direction) in which the two operation units 3L and 3R are lined up is the left-right direction.

The pair of shaft protrusions 32 are portions supported by the pair of bearing holes 22g of the cover 22. The pair of shaft protrusions 32 are provided so as to project from the inner side surfaces on both the upper and lower sides of the operation handle main body 31. Each of the pair of shaft protrusions 32 has a substantially triangular shape with the front end as the apex.

When the pair of shaft protrusions 32 are inserted into the pair of bearing holes 22g of the cover 22, the operation handle 3 can swing with respect to the cover 22 (that is, seesaw operation is possible) with the front end of the shaft protrusions 32 as a fulcrum. .. In this state, the operation handle 3 is arranged on the front surface 22j of the main body of the apparatus (see FIG. 1). More specifically, the operating handle 3 is arranged on the front side of the reversing handle 6 so as to cover the entire opening 22c of the cover 22.

The four contact portions 33 are portions with which the conversion spring 8 comes into contact. The four contact portions 33 project rearward from the back surface of the operation handle main body 31 (that is, the back surface of the main wall portion 31a). The four contact portions 33 are provided, for example, in the vicinity of the four corner portions on the back surface of the operation handle main body 31. In the four contact portions 33, the upper left and right two contact portions 33a and 33b form a pair of contact portions, and the lower left and right two contact portions 33a and 33b form a pair of contact portions.

The two fixing protrusions 34 are portions for fixing the second translucent passage 11. The two fixing protrusions 34 are inserted into the fixing holes 11f of the second light transmission path 11. The two fixing protrusions 34 project rearward from the back surface of the operation handle main body 31. The two fixing protrusions 24 are arranged on both the upper and lower sides of the lighting window 35, for example.

The lighting window 35 is a portion that emits light from the light sources 51a and 51b, and is, for example, a circular window. The lighting window 35 emits light by emitting light from the light sources 51a and 51b. The lighting window 35 is provided in one of the left and right regions (for example, the right region) on the front surface of the main wall portion 31a (that is, the front surface 3g of the operation handle 3). In other words, the lighting window 35 is provided on the front surface of one of the operation units 3L and 3R on both sides of the operation handle 3 (for example, the operation unit 3R on the right side).

The second light-shielding portion 36 is a portion that shields at least a part of the light emitted from the emission surface of the first light-transmitting path 10 on the device main body 2 side. Further, the second light-shielding portion 36 is a member that shields at least a part of the emitted light (leakage light) from the side surface of the second light-transmitting path 11. The second light-shielding portion 36 projects from one end (right wall portion 31f) in the left-right direction of the operation handle 3 in a direction approaching the device main body 2. More specifically, the second light-shielding portion 36 projects rearward (that is, the device main body 2 side) from the rear end of the right wall portion 31f of the operation handle 3. The second light-shielding portion 36 is provided at the center of the right wall portion 31f in the longitudinal direction (vertical direction). The second light-shielding portion 36 has a rectangular plate shape.

(Conversion spring 8)
As shown in FIG. 5, the conversion spring 8 is a component that transmits the operation of the operation handle 3 to the reversing handle 6. The conversion spring 8 is arranged between the operation handle 3 and the reversing handle 6, and is fixed to, for example, the reversing handle 6 and elastically contacts the operating handle 3.

The conversion spring 8 has a pair of spring bodies 81, a pair of connecting pieces 82, and a pair of hooking pieces 83.

Each of the pair of spring bodies 81 extends in the left-right direction, and is arranged side by side in the vertical direction. The pair of spring bodies 81 have a one-to-one correspondence with the two side wall portions 61b of the reversing handle 6, and have a one-to-one correspondence with the upper and lower two pairs of contact portions 33 of the operation handle 3. The pair of spring bodies 81 each have a through hole 81f and a pair of elastic pieces 81d and 81e. The through hole 81f penetrates the center of the spring body 81 in the longitudinal direction. The fitting projection 61c of the corresponding side wall portion 61b of the reversing handle 6 fits into the through hole 81f. The pair of elastic pieces 81d and 81e are portions of the operation handle 3 that come into contact with the corresponding pair of contact portions 33a and 33b. The pair of elastic pieces 81d and 81e are bent in a V shape so as to project forward at both ends of the spring body 81 in the longitudinal direction (left-right direction).

One connecting piece 82 connects the left ends of the pair of spring bodies 81 to each other, and the other connecting piece 82 connects the right ends of the pair of spring bodies 81 to each other. The pair of hook pieces 83 are portions of the reversing handle 6 that are hooked on the hook protrusion 61e of the corresponding side wall portion 61b. The hook piece 83 projects rearward from one end of the spring body 81 in the width direction (for example, one end facing the other spring body 81).

In the state where the conversion spring 8 is fixed to the reversing handle 6, the pair of spring bodies 81 are arranged on the front end faces of the two side wall portions 61b of the reversing handle 6. In this state, the through holes 81f of the pair of spring bodies 81 fit into the fitting protrusions 61c of the two side wall portions 61b. Further, the pair of hooking pieces 83 are hooked and fixed to the hooking protrusions 61e of the two side wall portions 61b of the reversing handle 6.

Further, in a state where the conversion spring 8 is fixed to the reversing handle 6, the four elastic pieces 81d and 81e elastically contact the four contact portions 33a and 33b of the operation handle 3. More specifically, the pair of left and right elastic pieces 81d and 81e of the upper spring body 81 elastically contact the pair of left and right contact portions 33a and 33b on the upper side of the operation handle 3. Then, the pair of left and right elastic pieces 81d and 81e of the lower spring body 81 elastically contact the pair of left and right contact portions 33a and 33b on the lower side of the operation handle 3.

(Translucent path 9)
The light transmission path 9 guides the light from the light sources 51a and 51b to the lighting window 35 of the operation handle 3. The light transmission path 9 has a first light transmission path 10 and a second light transmission path 11. The first light transmission path 10 is fixed to the device main body 2. The second translucent path 11 is fixed to the operation handle 3.

(1st translucent path 10)
The first light transmission path 10 is a member that incidents the emitted light of the two light sources 51a and 51b and guides the light to the incident surface of the second light transmission path 11. The first light transmission path 10 is an optical member (for example, a prism) formed of a transparent member.

As shown in FIG. 9, the first light transmission path 10 has a shape extending in one direction (for example, right front). The first light-transmitting path 10 has two incident surfaces (first incident surface 10a and second incident surface 10b), one exit surface 10c, and three reflection surfaces (first reflection surface 10d and second reflection surface 10e). And a third reflecting surface 10f).

The first incident surface 10a is arranged in front of the first light source 51a and incidents light from the first light source 51a. The second incident surface 10b is arranged in front of the second light source 51b and incidents light from the second light source 51b. The first incident surface 10a is, for example, a convex surface, and the second incident surface 10b is, for example, a flat surface. The first optical axis L4 of the first incident surface 10a and the second optical axis L5 of the second incident surface 10b are parallel to each other in the front-rear direction.

The two incident surfaces 10a and 10b are arranged at one end (for example, the left end) in the longitudinal direction on one side surface (rear surface) on both front and rear sides of the first light transmission path 10. One side surface on both the front and rear sides is one side surface (rear surface) of a pair of side surfaces along the longitudinal direction in the first light transmission path 10. The second incident surface 10b is arranged on the right side (exiting surface 10c side) of the first incident surface 10a. The second incident surface 10b is arranged on the front side of the first incident surface 10a.

The emission surface 10c emits light guided by the first light transmission path 10 toward the incident surface 11d of the second light transmission path 11. The emission surface 10c is arranged on the other end surface (right side) in the longitudinal direction in the first light transmission path 10. The emission surface 10c is arranged so as to face the entrance surface 11d of the second light transmission path 1110.

The first reflecting surface 10d is arranged on the other side surface (front surface) on both the front and rear sides so as to face the incident surfaces 10a and 10b in the directions of the optical axes L4 and L5 of the incident surfaces 10a and 10b. The first reflecting surface 10d is inclined so as to move away from the incident surfaces 10a and 10b from one side (left side) to the other side (right side) in the longitudinal direction of the first light transmission path 10 with respect to the optical axes L4 and L5. is doing. The second reflecting surface 10e is arranged on one side surface (rear surface) on both front and rear sides of the first translucent path 10 at a portion between the second incident surface 10b and the exit surface 10c. The third reflecting surface 10f is arranged at a portion between the first reflecting surface 10d and the emitting surface 10c on the other side surface (front surface) on both front and rear sides of the first light transmitting path 10. The third reflecting surface 10f faces the second reflecting surface 10e in the directions of the optical axes L4 and L5 of the incident surfaces 10a and 10b. The distance between the third reflecting surface 10f and the second reflecting surface 10e may be as small as the exit surface 10c side.

The first light transmission path 10 has a pair of fixed protrusions 10g and a pair of positioning ribs 10h. The pair of fixing protrusions 10g is a portion that is hooked on the fixing hole 22n of the fixing portion 22e of the cover 22. The pair of fixing protrusions 10g are provided on the upper and lower side surfaces of the first light transmission path 10, for example, in the center in the longitudinal direction. The pair of positioning ribs 10h is a portion that fits into a predetermined groove portion of the fixing portion 22e of the cover 22. The pair of positioning ribs 10h are provided on the upper and lower side surfaces of the first light transmission path 10, for example, on one end side (left side) in the longitudinal direction.

The first light transmission path 10 is housed inside the fixed portion 22e from the back opening of the fixed portion 22e (see FIG. 3). In this accommodation state, the pair of fixing protrusions 10g of the first light-transmitting path 10 are caught in the pair of fixing holes 22n of the fixing portion 22e, and the pair of positioning ribs of the first light-transmitting path 10 are predetermined for the fixing portion 22e. Fits into a pair of grooves. As a result, the first light transmission path 10 is positioned and fixed inside the fixing portion 22e.

Further, in this accommodation state, the first incident surface 10a and the second incident surface 10b of the first light transmission path 10 are arranged in front of the first light source 51a and the second light source 51b of the light source unit 5, respectively. The emission surface 10c of the first light transmission path 10 is exposed from the end face opening of the fixed portion 22e and faces the entrance surface 11d of the second light transmission path 11. As a result, the light of the light sources 51a and 51b incident on the two incident surfaces 10a and 10b guides the inside of the first translucent path 10 while being reflected by the first to second reflecting surfaces 10d to 10f, and the exit surface. It is emitted from 10c toward the incident surface 11d of the second light transmission path 11.

Further, in this accommodation state, the fixed portion 22e covers the front side and the upper and lower sides of the first light transmission path 10. As a result, the fixed portion 22e suppresses the light incident on the two incident surfaces 10a and 10b from being emitted (that is, leaking) from the front surface and both the upper and lower surfaces of the first translucent path 10. As a result, it is possible to prevent light incident on the two incident surfaces 10a and 10b from leaking to the outside of the switch device 1 from between the cover 22 and the operation handle 3 (particularly between the cover 22 and the operation unit 3L on the left side). ..

(Second translucent path 11)
The second light-transmitting path 11 is a member that guides the light emitted from the light-emitting surface 10c of the first light-transmitting path 10 to the lighting window 35 of the operation handle 3. The second light transmission path 11 is an optical member (for example, a prism) formed of a transparent member.

As shown in FIGS. 10 and 11, the second translucent path 11 has a translucent path main body 11a, a fixed portion 11b, and a lens portion 11c (lens). The second light transmission path 11 is integrally formed of a transparent member. The lens portion 11c may be formed separately from the translucent path main body 11a and the fixed portion 11b.

The translucent path main body 11a is a portion that guides the emitted light from the emitting surface 10c of the first translucent path 10 to the lighting window 35 of the operation handle 3. The translucent path main body 11a has an incident surface 11d and an exit surface 11e. The incident surface 11d is a surface on which the light emitted from the exit surface 10c of the first translucent path 10 is incident. The incident surface 11d faces the exit surface 10c of the first light transmission path 10. The emission surface 11e is a surface that emits light that has guided the light passing path main body 11a. The emission surface 11e faces the back surface (rear surface) of the lighting window 35 via the fixing portion 11b.

The light transmission path main body 11a is curved forward from the entrance surface 11d toward the emission surface 11e. That is, the incident surface 11d is arranged on the left side (that is, on the first translucent path 10 side) of the exit surface 11e. In the present embodiment, as will be described later, the intensity distribution of the emitted light on the emitting surface 11e is shifted to the right side (first direction) from the center of the emitting surface 11e. Therefore, the left side (that is, the first translucent path side) is, in other words, the side opposite to the direction in which the intensity distribution deviates (first direction).

As described above, in the present embodiment, the incident surface 11d is arranged on the left side of the exit surface 11e in the second transparent path 11 due to the bending of the transparent path main body 11a, but the transparent path main body 11a is bent. By doing so, the incident surface 11d may be arranged on the left side of the exit surface 11e.

The fixing portion 11b is a portion in which the second translucent passage 11 is fixed to the back surface of the operation handle 3 (more specifically, the back surface of the operation portion 3R on the lighting window 35 side). The fixing portion 11b has, for example, a rectangular plate shape. The exit surface 11e of the translucent path main body 11a is connected to the back surface of the fixed portion 11b. The fixing portion 11b has two fixing holes 11f through which the two fixing protrusions 34 of the operation handle 3 penetrate. The two fixing holes 11f are arranged on both the upper and lower sides of the lens portion 11c on the front surface of the fixing portion 11b. The thickness of the fixed portion 11b (distance between the front surface and the rear surface) becomes wider from the left side to the right side, for example.

The lens portion 11c is an optical portion that is arranged inside the lighting window 35 of the operation handle 3 and diffuses the light emitted from the lighting window 35. The lens portion 11c is connected to the front surface of the fixed portion 11b. The front surface (front surface) 11g of the lens portion 11c is a concave surface. As a result, the light emitted from the lighting window 35 can be diffused over a wide range.

In a state where the second light-transmitting path 11 is fixed to the back surface of the operation handle 3, the two fixing protrusions 34 of the operation handle 3 are inserted into the two fixing holes 11f of the fixing portion 11b. In this state, the tips of the two fixing protrusions 34 are melted, crushed, and spread out in a disk shape. As a result, the fixing protrusion 34 does not come off from the fixing hole 11f, and the fixing portion 11b is fixed to the back surface of the operation handle 3. That is, the second translucent path 11 is fixed to the back surface of the operation handle 3.

Further, in this fixed state, the lens portion 11c is arranged inside the lighting window 35 of the operation handle 3. Further, since the translucent path main body 11a is curved along the length direction, the incident surface 11d side of the translucent path main body 11a is arranged on the left side of the exit surface 11e. The incident surface 11d faces the exit surface 10c of the first light transmission path 10. As a result, the second light-transmitting path 11 incidents the light emitted from the light-emitting surface 10c of the first light-transmitting path 10 from the incident surface 11d, guides the light, and guides the light from the light-emitting surface 11e via the fixed portion 11b to the lighting window 35. It emits light to.

More specifically, the second light-transmitting path 11 is displaced with respect to the first light-transmitting path 10 in response to pressing and lifting of the operation unit 3R on the right side (lighting window 35 side) of the operation handle 3. However, regardless of whether the right operating unit 3R is pressed or the right operating unit 3R is lifted, the incident surface 11d of the second translucent path 11 is the exit surface of the first transmissive path 10. Facing 10c. Therefore, as long as the light sources 51a and 51b emit light, the light of the light sources 51a and 51b is emitted from the lighting window 35 in any of the above cases.

Further, in the fixed state in which the second translucent path 11 is fixed to the back surface of the operation handle 3, the first central axis L6 of the lighting window 35 is to the right (first direction) of the second central axis L7 of the exit surface 11e. ) (See FIG. 11). In the present embodiment, in the second translucent path 11, the incident surface 11d is displaced to the left from the exit surface 11e, and the above-mentioned right direction (first direction) is, in other words, the incident surface 11d. The direction is opposite to the direction of deviation (left direction). Here, the first central axis L6 is an axis passing through the center of the lighting window 35. The first central axis L6 is the same axis as the central axis of the lens unit 11c. The second central axis L7 is an axis that passes through the center of the exit surface 11e of the second translucent path 11 and is parallel to the first central axis L6.

By arranging the first central axis L6 on the right side of the second central axis L7 in this way, the lighting window 35 can emit light more uniformly for the reason described later.

(Light guidance by the translucent path 9)
A state in which the light transmission path 9 guides light will be described with reference to FIGS. 12A to 13B.

With reference to FIGS. 12A and 12B, first, a state in which the light transmission path 9 guides the emitted light of the first light source 51a will be described.

When the operation unit 3L on the right side of the operation handle 3 is pressed (see FIG. 12A), a part of the light emitted from the first light source 51a (for example, the lights C1 to C3) is introduced in the first light transmission path 10. It is incident from the first incident surface 10a, is guided while being reflected inside the first light transmission path 10, and is emitted from the exit surface 10c. Then, each of the light C1 to C3 is incident on the incident surface 11d in the second translucent path 11 and is guided along the curved surface 11h on the convex side of the second transmissive path 11 while being guided to the lens portion 11c. It is emitted from the front surface (that is, the front surface of the lighting window 35) 11 g.

When the operation unit 3L on the right side of the operation handle 3 is lifted (see FIG. 12B), a part of the light emitted from the first light source 51a (for example, light C2 and C3) is introduced in the first light transmission path 10. It is incident from the incident surface 10a, is guided while being reflected inside the first light transmission path 10, and is emitted from the exit surface 10c. Then, each of the light C2 and C3 is incident on the incident surface 11d in the second translucent path 11 and is guided along the curved surface 11h on the convex side of the second transmissive path 11 while being guided to the lens portion 11c. It is emitted from the front surface 11g of. Further, a part of the light emitted from the first light source 51a (for example, light C1) is incident on the incident surface 10a in the first translucent path 10 and is reflected inside the first transmissive path 10 to guide the light. Then, it is emitted from the emission surface 10c. Then, the light C1 propagates toward the outside of the switch device 1 without being incident on the incident surface of the second light transmission path 11.

Also in the case of FIG. 12A, as in the case of FIG. 12B, a part of the light of the first light source 51a is emitted from the exit surface 10c of the first light transmission path 10 and then incident on the second light transmission path 11. It may contain light that propagates outside the switch device 1 without being incident on the surface 11d.

With reference to FIGS. 13A and 13B, a state in which the light transmission path 9 guides the emitted light of the second light source 51b will be described next.

When the operation unit 3L on the right side of the operation handle 3 is pressed (see FIG. 13A), a part of the light emitted from the second light source 51b (for example, light C4 to C6) is emitted in the first light transmission path 10. It is incident from the second incident surface 10b, is guided while being reflected inside the first light transmission path 10, and is emitted from the exit surface 10c. Then, each of the light C4 to C6 is incident on the incident surface 11d in the second translucent path 11 and is guided along the curved surface 11h on the convex side of the second transmissive path 11 while being guided to the lens portion 11c. It is emitted from the front of.

When the operation unit 3L on the right side of the operation handle 3 is lifted (see FIG. 13B), a part of the light emitted from the second light source 51b (for example, light C4 and C6) is emitted in the first light transmission path 10. It is incident from the second incident surface 10b, is guided while being reflected inside the first light transmission path 10, and is emitted from the exit surface 10c. Then, each of the light C4 and C6 is incident from the incident surface 11d in the second translucent path 11 and is guided along the curved surface 11h on the convex side of the second transmissive path 11 while being guided to the lens portion 11c. It is emitted from the front surface 11g of. Further, a part of the light emitted from the second light source 51b (for example, light C5) is incident on the second incident surface 10b in the first translucent path 10 and is reflected inside the first transmissive path 10. The light is guided and emitted from the emission surface 10c. Then, the light C5 propagates toward the outside of the switch device 1 without being incident on the incident surface 11d of the second light transmission path 11.

Also in the case of FIG. 13A, as in the case of FIG. 13B, a part of the light of the second light source 51b is emitted from the exit surface 10c of the first light transmission path 10 and then incident on the second light transmission path 11. It may contain light that propagates outside the switch device 1 without being incident on the surface 11d.

As described above, a part of the emitted light of the light sources 51a and 51b (for example, the light C1 of FIG. 12B and the light C5 of FIG. 13B) is the incident surface from the exit surface 10c of the first transmission path 10 to the incident surface of the second transmission path 11. It propagates to the outside of the switch device 1 without being incident on 11d. As will be described later, the lights C1 and C5 are shielded from light by the first light-shielding unit 22i and the second light-shielding unit 36, and leakage to the outside of the switch device 1 is suppressed.

Further, a part of the emitted light of the light sources 51a and 51b (for example, the light C1 to C3 in FIG. 12A and the light C4 to C6 in FIG. 13A) guides the second light transmitting path 11 when the second light transmitting path 11 is guided. The inside of the light source is guided while being reflected by the curved surface 11h on the convex side. Therefore, when the light C1 to C6 pass through the exit surface 11e of the second translucent path 11, they are concentrated on the right side of the center on the exit surface 11e (that is, on the curved surface 11h side (first direction)). That is, on the emission surface 11e, the intensity distribution of the emitted light is distributed to the right from the center of the emission surface 11e.

In the above intensity distribution (first intensity distribution), the central region of the intensity distribution is bright and the outer peripheral region of the intensity distribution is darker than the central region. That is, the above intensity distribution has a central region brighter than the outer peripheral region inside the outer peripheral region. Here, the above-mentioned "intensity distribution of the emitted light on the emitting surface 11e is shifted to the right from the center of the emitting surface 11e" means that the center of the central region (bright region) of the intensity distribution is the center of the emitting surface 11e. It is to shift to the right from the center.

Therefore, in this switch device 1, the first central axis L6 of the lighting window 35 is arranged so as to be offset to the right side (first direction) of the second central axis L7 of the exit surface 11e of the second translucent path 11. (See FIG. 10). Here, the first direction is a direction in which the intensity distribution of the emitted light of the emitting surface 11e of the second translucent path 11 deviates from the center of the emitting surface 11e (more specifically, it is brighter than the outer peripheral region in the above intensity distribution). The direction in which the center of the central region deviates from the center of the exit surface 11e). As a result, when viewed from the first central axis L6 direction (or forward direction), the central region (that is, the bright region) of the above intensity distribution is substantially in the center of the front surface of the lighting window 35 (that is, the front surface 11 g of the lens portion 11c). Be placed. As a result, the lighting window 35 can emit light more uniformly.

(Range of distance R1 between two central axes L6 and L7)
As shown in FIG. 10, the distance between the two central axes L6 and L7 is defined as the distance R1. Further, the diameter of the exit surface 11e of the second light transmission path 11 is defined as the diameter R2. Further, the ratio of the interval R1 to the diameter R2 is defined as the ratio W1 (= R1 / R2). The diameter R2 is 2.0 mm as an example.

In the following description, the intensity distribution of the emitted light on the emitting surface 11e of the second translucent path 11 is referred to as the first intensity distribution P1 (see FIG. 10). The intensity distribution of the emitted light on the front surface (exiting surface) of the lighting window 35 of the operation handle 3 is referred to as a second intensity distribution P2 (see FIG. 10). Since the front surface of the lighting window 35 is the same as the front surface 11g of the lens unit 11c, the second intensity distribution P2 is also the intensity distribution of the emitted light on the front surface 11g of the lens unit 11c. The second intensity distribution P2 is the first intensity distribution P1 reflected on the front surface of the lighting window 35 when the front surface of the lighting window 35 is viewed from the direction of the first central axis L6.

Therefore, the second intensity distribution P2 has a light region E1 and a dark region E2 (see FIG. 14), and the bright region E1 and the dark region E2 correspond to the bright region and the dark region of the first intensity distribution P1, respectively. do. The bright region E1 of the second intensity distribution P2 is a relatively bright region in the second intensity distribution P2, and the dark region E2 of the second intensity distribution P2 is from the bright region E1 in the second intensity distribution P2. Is also a relatively bright area. Further, the bright region of the first intensity distribution P1 is a region where the emitted light is concentrated and relatively bright on the exit surface 11e of the second light transmission path 11. The dark region of the first intensity distribution P1 is a region darker than the bright region of the first intensity distribution P1.

FIG. 14 shows the second intensity distribution P2 when the interval R1 is changed from 0.2 mm to 1.0 mm by 0.2 mm. That is, as described above, the first intensity distribution P1 is distributed on the exit surface 11e of the second translucent path 11 so as to be offset to the right side (first direction) from the center. When the first central axis L6 is changed by 0.2 mm from the position shifted 0.2 mm to the right (first direction) from the second central axis L7 to the position shifted 1.0 mm so as to match this deviation. The second intensity distribution P2 in FIG. 14 is the second intensity distribution P2 in FIG.

As shown in FIG. 14, when the interval R1 is 0.2 mm or 1.0 mm, the bright region E1 of the second intensity distribution P2 is largely deviated from the center of the front surface of the lighting window 35 (that is, the front surface 11 g of the lens portion 11c). You can see that. In this case, it can be seen that the front surface of the lighting window 35 does not emit light uniformly. On the other hand, when the interval R1 is 0.4 mm, 0.6 mm or 0.8 mm, the bright region E1 of the second intensity distribution P2 is approximately in the center of the front surface of the lighting window 35 (that is, the front surface 11 g of the lens portion 11c). You can see that it is placed. In this case, it can be seen that the front surface of the lighting window 35 emits light almost uniformly.

In the state where the operation unit 3R on the right side (lighting window 35 side) is lifted, the front surface of the lighting window 35 is inclined with respect to the front-rear direction. Therefore, it is desirable that the bright region E1 on the front surface of the lighting window 35 is slightly shifted to the left from the center of the lighting window 35. As a result, when the lighting window 35 is viewed from the front, the bright region E1 appears to be arranged in the center of the front surface of the lighting window 35.

From the above, in order to make the front surface of the lighting window 35 (that is, the front surface 11 g of the lens portion 11c) emit light more uniformly, the interval R1 is in the range of 0.2 mm <R1 <1.0 mm (that is, the ratio W1 is 0.1). It is desirable to set <W1 <0.5). Desirably, it is desirable to set the interval R1 in the range of 0.4 mm ≦ R1 ≦ 0.8 mm (that is, the ratio W1 is 0.2 ≦ W1 ≦ 0.4). More preferably, it is desirable to set the interval R1 in the range of 0.5 mm ≦ R1 ≦ 0.7 mm (that is, the ratio W1 is 0.25 ≦ W1 ≦ 0.35).

(Operation of switch device 1)
The operation of the light-transmitting path 9 and the light-shielding portions 22i and 36 of the switch device 1 will be described with reference to FIGS. 3 and 4.

When the operation unit 3R on the right side (lighting window 35 side) of the operation handle 3 is pressed (see FIG. 4), the operation unit 3L on the left side is lifted. In this state, the second light-transmitting path 11 and the second light-shielding portion 36 are arranged at a lowered position in conjunction with the operation unit 3R on the right side. As a result, the incident surface 11d of the second light-transmitting path 11 faces the exit surface 10c of the first light-transmitting path 10. When the light sources 51a and 51b emit light in this state, the light from the light sources 51a and 51b guides the first transparent path 10 and the second transparent path 11 and is emitted from the lighting window 35 of the operation handle 3. ..

Further, as described above, when the second light-shielding portion 36 is arranged at a lowered position in conjunction with the operation unit 3R on the right side, the second light-shielding portion 36 is arranged in the accommodating recess 22q of the apparatus main body 2. In this state, the front half of the first light-shielding portion 22i overlaps with almost the entire second light-shielding portion 36 in the left-right direction (direction in which the two operating units 3L and 3R are lined up). As a result, the gap between the right end portion (right wall portion 31f) of the right operation portion 3R and the front surface 22j of the apparatus main body 2 is almost completely closed by the first light-shielding portion 22i and the second light-shielding portion 36.

As a result, for example, the light C8 leaking from the curved surface 11h on the convex side of the second light-transmitting path 11 is shielded by the first light-shielding portion 22i and the second light-shielding portion 36. As a result, the light C8 is prevented from leaking to the outside of the switch device 1. In this case, since the light C8 is shielded by the double walls of the first light-shielding portion 22i and the second light-shielding portion 36, the light C8 is almost completely shielded from light.

Further, the light C9 leaking from the surface (excluding the rear surface) other than the exit surface 10c of the first translucent path 10 is shielded by the fixed portion 22e covering the first transmissive path 10. By this. It is suppressed that the light C9 leaks to the outside of the switch device 1 from the gap between the left end (left wall portion 31e) of the left operation unit 3L and the front surface 22j of the device main body 2.

When the operation unit 3L on the left side of the operation handle 3 is pressed (see FIG. 3), the operation unit 3R on the right side is lifted. In this state, the second light-transmitting path 11 and the second light-shielding portion 36 are arranged at an elevated position in conjunction with the operation unit 3R on the right side. Even in this arrangement, the incident surface 11d of the second light-transmitting path 11 faces the exit surface 10c of the first light-transmitting path 10. When the light sources 51a and 51b emit light in this state, the light from the light sources 51a and 51b guides the first transparent path 10 and the second transparent path 11 and is emitted from the lighting window 35 of the operation handle 3. ..

Further, as described above, even when the second light-shielding unit 36 is arranged at an elevated position in conjunction with the right-side operation unit 3R, the first light-shielding unit 22i and the second light-shielding unit 36 provide the right operation unit to the right operation unit. A gap is closed between the right end (right wall portion 31f) and the front surface 22j of the apparatus main body 2.

As a result, of the light emitted from the first light-transmitting path 10, the light C11 leaked without being incident on the incident surface 11d of the second light-transmitting path 11 and from the curved surface 11h on the convex side of the second light-transmitting path 11. The leaked light C10 is shielded by the first light-shielding unit 22i and the second light-shielding unit 36. As a result, the leakage of the respective lights C10 and C11 to the outside of the switch device 1 is suppressed.

Also in this case, the light C9 leaking from the surface other than the exit surface 10c (excluding the rear surface) of the first translucent path 10 is shielded by the fixed portion 22e covering the first transmissive path 10. By this. It is suppressed that the light C9 leaks to the outside of the switch device 1 from the gap between the left end (left wall portion 31e) of the left operation unit 3L and the front surface 22j of the device main body 2.

Next, the lighting operation (position display function and pilot function) of the switch device 1 will be described with reference to FIGS. 3 and 4.

In this switch device 1, the first light source 51a (for example, a white light source) is always lit. As a result, the light from the first light source 51a (for example, white light) is constantly guided through the first translucent path 10 and the second transmissive path 11 and emitted from the lighting window 35 of the operation handle 3. As a result, the lighting window 35 always emits light, for example, white light regardless of the operation of the operation handle 3. Thereby, the position of the operation handle 3 can be easily visually recognized even in the dark by the light emission (position display function).

On the other hand, in the switch device 1, the second light source 51b (for example, a red light source) is switched on and off according to the operation and stop of the electric device to be operated. For example, the second light source 51b is turned off when the electric device to be operated is operating, and turned on when the electric device to be operated is stopped.

As a result, when the electric device to be operated is in operation, the second light source 51b is turned off. Therefore, even if the operation handle 3 is operated, the light from the second light source 51b is emitted from the lighting window 35 of the operation handle. Is not emitted. That is, the lighting window 35 does not emit light. On the other hand, when the electric device to be operated is stopped, the second light source 51b is turned on. Therefore, when the operation handle 3 is operated and the operation unit 3R on the right side of the operation handle 3 is lifted, the operation handle 3 is turned on. Light from the second light source 51b (for example, red light) is emitted from the window 35. That is, the lighting window 35 emits red light. As a result, the light emission makes it possible to easily visually recognize the portion of the operation handle 3 for operating the electric device to be operated even in the dark (pilot function).

In this embodiment, since the pilot function and the position display function are implemented together, in this case, the red light by the pilot function and the white light by the position display function are emitted from the lighting window 35.

(Main effect)
As described above, the switch device 1 according to the present embodiment includes a device main body 2, an operation handle 3, a contact circuit 4, light sources 51a and 51b, a first translucent path 10, and a second transmissive path 11. .. The operation handle 3 has a first operation unit 3R and a second operation unit 3L, and is displaceably arranged with respect to the device main body 2. When the first operation unit 3R and the second operation unit 3L are operated, the first operation unit 3R and the second operation unit 3L are displaced in different directions from each other. The operation handle 3 has a lighting window 35 on the first operation unit 3R. The contact circuit 4 switches between an open state and a closed state according to the displacement of the operation handle 3. The light sources 51a and 51b are fixed to the apparatus main body 2. The first light transmission path 10 is fixed to the main body 2 of the apparatus, and light from the light sources 51a and 51b is incident and guided. The second translucent path 11 is fixed to the operation handle 3 and guides the emitted light of the first transmissive path 10 to the lighting window 35.

According to this configuration, since the first translucent path 10 and the second transmissive path 11 are provided, the light of the light sources 51a and 51b is operated from the apparatus main body 2 in a manner of fixing the light sources 51a and 51b to the apparatus main body 2. It is possible to guide light to the lighting window 35 of the handle 3.

Further, the second light transmission path 11 has an incident surface 11d and an exit surface 11e. The incident surface 11d is incident with the emitted light of the first light transmission path 10. The exit surface 11e emits light incident on the incident surface 11d to the lighting window 35. The axis passing through the center of the lighting window 35 is referred to as the first central axis L6, and the axis passing through the center of the emission surface 11e and parallel to the first central axis L6 is referred to as the second central axis L2. The direction in which the first intensity distribution P1 of the emitted light on the emitting surface 11e deviates from the center of the emitting surface 11e is defined as the first direction. The first central axis L6 is arranged on the side in the first direction with respect to the second central axis L7.

According to this configuration, the first central axis L6 is on the side in the first direction with respect to the second central axis L7 (that is, the side in the direction in which the intensity distribution P2 of the emitted light deviates from the center of the emitted surface 11e on the emitted surface 11e). Have been placed. Therefore, the lighting window 35 of the operation handle 3 can be made to emit light more uniformly by the light of the light sources 51a and 51b.

(Modification example)
In the above embodiment, the case where two light sources 51a and 51b are provided is illustrated, but only one of the two light sources 51a and 51b may be provided.

(summary)
As is clear from the embodiments and modifications described above, the following aspects can be taken.

The switch device (1) of the first aspect includes a device main body (2), an operation handle (3), a contact circuit (4), a light source (51a, 51b), and a first translucent path (10). , A second translucent path (11). The operation handle (3) has a first operation unit (3R) and a second operation unit (3L) and is displaceably arranged with respect to the device main body (2). When the first operation unit (3R) and the second operation unit (3L) are operated, the first operation unit (3R) and the second operation unit (3L) are displaced in different directions from each other. The operation handle (3) has a lighting window (35) on the first operation unit (3R). The contact circuit (4) switches between an open state and a closed state according to the displacement of the operation handle (3). The light source (51a, 51b) is fixed to the apparatus main body (2). The first translucent path (10) is fixed to the apparatus main body (2), and light from the light sources (51a, 51b) is incident and guided. The second translucent path (11) is fixed to the operation handle (3). The second translucent path (11) has an incident surface (11d) and an exit surface (11e). The incident surface (11d) is incident with the emitted light of the first translucent path (10). The exit surface (11e) emits light incident on the incident surface (11d) to the lighting window (35). The axis passing through the center of the lighting window (35) is defined as the first central axis (L6), and the axis passing through the center of the exit surface (11e) and parallel to the first central axis (L6) is defined as the second central axis (L7). .. The direction in which the first intensity distribution (P1) of the emitted light deviates from the center of the emitting surface (11e) on the emitting surface (11e) is defined as the first direction (for example, the right direction). The first central axis (L6) is arranged on the side in the first direction with respect to the second central axis (L7).

According to this configuration, the first central axis (L6) has the first intensity distribution (P1) of the emitted light on the side in the first direction (that is, the emitting surface (11e)) with respect to the second central axis (L7). (11e) is arranged on the side deviating from the center). Therefore, the lighting window (35) of the operation handle (3) can be made to emit light more uniformly by the light of the light source (51a, 51b).

In the first aspect of the switch device (1) of the second aspect, the direction in which the first intensity component (P1) deviates from the center of the exit surface (11e) is from the outer peripheral region in the first intensity distribution (P1). The center of the bright central region is deviated from the center of the exit surface (11e).

According to this configuration, the first central axis (L6) is the outer peripheral region in the first intensity distribution (P1) of the emitted light on the side in the first direction (that is, the emitting surface (11e)) with respect to the second central axis (L7). The center of the brighter central region is arranged on the side of the exit surface (11e) in a direction deviating from the center). Therefore, the lighting window (35) of the operation handle (3) can be made to emit light more uniformly by the light of the light source (51a, 51b).

In the switch device (1) of the third aspect, in the first or second aspect, the exit surface (front surface) of the lighting window (35) has a second intensity distribution (P2) of the emitted light. The second intensity distribution (P2) has a bright bright region (E1) and a dark region (E2) darker than the bright region (E1). The bright region (E1) is arranged at the center of the exit surface of the lighting window (35). The dark region (E2) is arranged on the outer periphery of the bright region (E1) on the exit surface of the lighting window (35).

According to this configuration, the lighting window (35) can be made to emit light more uniformly.

In any one of the first to third aspects, the switch device (1) of the fourth aspect has the incident surface (11d) as the exit surface (11e) when viewed from the direction of the first central axis (L6). ) Is located on the side opposite to the first direction (for example, the left side).

According to this configuration, when the incident surface (11d) is arranged on the side opposite to the first direction from the exit surface (11e), the above intensity distribution (P2) is on the exit surface (11e). It may shift from the center to the side in the first direction (for example, the right side). Therefore, in the above state, the first central axis (L6) is arranged on the side in the first direction (that is, the side opposite to the incident surface (11d)) with respect to the second central axis (L7). As a result, the lighting window (35) of the operation handle (3) can be made to emit light more uniformly by the light of the light sources (51a and 51b).

The switch device (1) of the fifth aspect includes a lens (11c) arranged in the lighting window (35) in any one of the first to fourth aspects. The front surface (11 g) of the lens (11c) is concave.

According to this configuration, the light emitted from the lighting window (35) can be diffused over a wide range.

In the switch device (1) of the sixth aspect, in any one of the first to fifth aspects, the distance between the first central axis (L6) and the second central axis (L7) is set to R1, and the emission surface is set to R1. The diameter of (11e) is R2, and the ratio of the diameter R2 to the interval R1 is W1. R1 satisfies the relationship of 0.1 <W1 <0.5.

According to this configuration, the lighting window (35) of the operation handle (3) can be made to emit light more uniformly by the light of the light source (51a, 51b).

In the switch device (1) of the seventh aspect, in any one of the first to sixth aspects, the second translucent path (11) is directed from the entrance surface (11d) to the exit surface (11e). It is curved.

According to this configuration, when the second translucent path (11) has a curved shape, the lighting window (35) of the operation handle (3) is made to emit light more uniformly by the light of the light source (51a, 51b). Can be done.

In the switch device (1) of the eighth aspect, in any one of the first to seventh aspects, the light source (51a, 51b) is the operation unit (3L, 3R) on both sides in the device main body (2). Of these, the lighting window (35) is arranged on the rear side of the operation unit (for example, 3L) which is not provided.

According to this configuration, the distance between the light source (51a, 51b) and the lighting window (35) can be secured. As a result, it is possible to suppress a change in the brightness of the lighting window (35) due to the operation of the operation handle (3). That is, the brightness of the lighting window (35) can be kept more uniform with respect to the operation of the operation handle (3).

1 Switch device 2 Device body 3 Operation handle 3R Operation unit (1st operation unit)
3L operation unit (second operation unit)
4 Contact device (contact circuit)
11c Lens 11d Incident surface 11e Exit surface 11g Front surface (front surface)
22i 1st shading part 22j front surface (opposing surface)
31f Right wall (end)
35 Lighting window 36 Second shading part 51a First light source (light source)
51b Second light source (light source)
E1 Light region E2 Dark region L6 1st central axis L7 2nd central axis P1 1st intensity distribution P2 2nd intensity distribution R1 interval R2 diameter

Claims (8)

With the main body of the device
The first operation unit and the second operation unit are provided so as to be displaceable with respect to the main body of the apparatus, and when the first operation unit and the second operation unit are operated, the first operation unit and the first operation unit are operated. The two operation units are displaced in different directions, and the operation handle having a lighting window in the first operation unit and the operation handle
A contact circuit that switches between an open state and a closed state according to the displacement of the operation handle,
The light source fixed to the main body of the device and
A first translucent path fixed to the main body of the apparatus and incident and guiding light from the light source,
A second translucent path fixed to the operation handle is provided.
The second translucent path is
An incident surface on which the emitted light of the first translucent path is incident, and
It has an exit surface that emits incident light to the incident surface to the lighting window.
The axis passing through the center of the lighting window is set as the first central axis, the axis passing through the center of the emitting surface and parallel to the first central axis is set as the second central axis, and the first intensity distribution of the emitted light is set on the emitting surface. The direction deviated from the center of the emission surface is defined as the first direction.
The first central axis is arranged on the side in the first direction with respect to the second central axis.
Switch device. The direction in which the first intensity distribution deviates from the center of the exit surface is the direction in which the center of the central region brighter than the outer peripheral region in the first intensity distribution deviates from the center of the exit surface.
The switch device according to claim 1. The exit surface of the lighting window has a second intensity distribution of emitted light.
The second intensity distribution has a bright bright region and a dark region darker than the bright region.
The bright region is arranged in the center of the emitting surface of the lighting window, and the dark region is arranged on the outer periphery of the bright region on the emitting surface of the lighting window.
The switch device according to claim 1 or 2. The incident surface is arranged on the side opposite to the first direction with respect to the exit surface when viewed from the direction of the first central axis.
The switch device according to any one of claims 1 to 3. With a lens placed in the lighting window
The front surface of the lens is concave.
The switch device according to any one of claims 1 to 4. Assuming that the distance between the first central axis and the second central axis is R1, the diameter of the emission surface is R2, and the ratio of the diameter R2 to the distance R1 is W1, R1 is 0.1 <W1 <0. Satisfy the relationship of 5,
The switch device according to any one of claims 1 to 5. The second light-transmitting path is curved from the entrance surface toward the emission surface.
The switch device according to any one of claims 1 to 6. The light source is arranged on the rear side of the operation unit on both sides of the main body of the device, which is not provided with the lighting window.
The switch device according to any one of claims 1 to 7.

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