JP5408076B2 - Instrument - Google Patents

Description

  The present invention relates to an instrument having a pointer for indicating an index provided on a dial, and more particularly to an instrument having a pointer that is lit and displayed.

  2. Description of the Related Art Conventionally, in order to improve the visibility of a meter, a pointer that emits an indicator that indicates an indicator provided on a dial of the meter is known. For example, Patent Document 1 discloses an instrument that can suppress unevenness in light emission luminance of an instruction unit due to rotation of a pointer. The pointer of this instrument rotates around the rotation center line, and is provided to project the rotating shaft portion that guides the incident light, and to project from the rotating shaft portion in the radial direction, and guides the light guided by the rotating shaft portion. It has an instruction unit that emits light by receiving light and instructs an index provided on the dial. The rotating shaft portion is provided with a plurality of light receiving surfaces that receive light from the light source. Among the plurality of light receiving surfaces, one is provided in the rotational radial direction where the indicating portion is provided, and the other two are provided side by side in the rotational circumferential direction with respect to the light receiving surface provided in the rotational radial direction.

  A plurality of light sources are installed at predetermined intervals in the rotation circumferential direction with the rotation shaft portion deviating from the rotation center line. The light source has two light sources, the first case where the central light receiving surface provided in the rotational radial direction is positioned directly above one of the light sources by the rotation of the rotating shaft about the rotation center line. The second case where the other two light receiving surfaces provided side by side with the central light receiving surface are positioned directly above each of the two is installed.

  In the technique of Patent Document 1, the shape of the light receiving surface is determined so that the total illuminance of the three light receiving surfaces approximates even if the position of the light receiving surface of the rotating shaft portion with respect to the light source is different. This prevents the brightness from changing.

JP 2007-285850 A

  In the pointer of Patent Document 1, the rotating shaft portion has a reflecting surface corresponding to each of the plurality of light receiving surfaces. These reflecting surfaces are provided immediately above the respective light receiving surfaces. These reflecting surfaces reflect the light received by the respective light receiving surfaces toward the pointing unit. In the technique of Patent Document 1, in the first case where the central light receiving surface is located immediately above the light source, the illuminance of the central light receiving surface is much higher than the illuminance of the light receiving surfaces on both sides. In this case, most of the light from the light source is incident from the central light receiving surface. The light incident from the central light receiving surface is reflected by the reflecting surface corresponding to the central light receiving surface and guided to the instruction unit. The reflected light reflected by the central reflecting surface will be along the rotational radial direction where the indicator is provided.

  Further, in the second case where the other two light receiving surfaces are positioned directly above the two light sources, the illuminance of the two light receiving surfaces is higher than the illuminance of the central light receiving surface. In this case, most of the light from the two light sources is incident from the two light receiving surfaces. Light incident from the two light receiving surfaces is reflected by the reflecting surface corresponding to each light receiving surface, and is guided to the instruction unit. Since each reflecting surface is located on both sides of the central reflecting surface, the two reflected lights are guided to the indicating unit at a predetermined angle with respect to the rotational radial direction where the indicating unit is provided. The reflected light guided to the instruction unit in this way travels toward the tip of the instruction unit while being reflected by the side surface of the instruction unit.

  As described above, in the first case and the second case that occur when the pointer rotates, the optical path that is reflected by the reflecting surface and guided to the instruction unit is different. In particular, in the second case, the light guided by the rotating shaft portion is incident on the indicating portion at an angle with respect to the rotational radial direction in which the indicating portion is provided. There should be a lot of reflections and a lot of loss. Therefore, the light emission luminance of the instruction unit in the second case should be lower than that in the first case.

  In the technique of Patent Document 1, the light emission luminance of the indication unit is prevented from changing depending on the rotation position of the pointer by approximating the total illuminance of the three light receiving surfaces in the first and second cases. If the optical paths of the reflected light incident on the indicator are different in the two cases, it should not be possible to suppress the change in the light emission luminance of the indicator depending on the rotation position of the pointer.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an instrument capable of suppressing a change in light emission luminance of an instruction unit depending on a rotation position of a pointer.

According to the first aspect of the present invention, the rotating shaft portion that rotates around the rotation center line and guides the incident light, and projects from the rotating shaft portion in the rotation radial direction, and is guided by the rotating shaft portion. The light is emitted by receiving the received light, and is arranged at a position deviated from the rotation center line with a pointer having an instruction portion for indicating an index provided on the dial, and is directed toward the rotation shaft portion. And a light source that emits
The rotating shaft portion is
A first reflecting portion that reflects the light from the light source incident on the rotating shaft portion in the rotation radial direction so as to be directed to the pointing portion;
A second reflecting portion that is provided side by side in the rotational circumferential direction with respect to the first reflecting portion and reflects light from the light source incident on the rotating shaft portion;
And a third reflecting portion that reflects the light reflected by the second reflecting portion in the rotational radial direction so as to be directed to the indicating portion.

  Here, when the light source that emits light toward the rotation shaft portion of the pointer is arranged at a position deviated from the rotation center line of the rotation shaft portion, the illuminance of the portion facing the light source of the rotation shaft portion is partially It will be different. When the rotation shaft portion rotates around the rotation center line, a portion where the illuminance increases and a portion where the illuminance decreases move in the rotation shaft portion. Even if the first reflecting portion is provided on the rotating shaft portion so that the light from the light source is directed to the instruction portion, the rotating shaft portion rotates, so that the portion where the illuminance at the rotating shaft portion becomes high moves. The amount of light incident on the first reflecting portion changes, and the amount of light incident on the indicating portion changes. For this reason, there exists a possibility that the light emission luminance of an instruction | indication part may change with the rotation position of an instruction | indication part.

  Therefore, if the second reflecting portion is provided in the rotating shaft portion along the circumferential direction with respect to the first reflecting portion in accordance with the change in the position where the illuminance increases due to the rotation of the rotating shaft portion, Even if the position where the illuminance increases due to the change in the amount of incident light of the light incident on the reflecting portion can be suppressed. However, since the second reflection unit is installed side by side in the rotational circumferential direction with respect to the first reflection unit, the incident direction of light incident on the indication unit from the first reflection unit and the second reflection unit The incident direction of the light incident on the indicator is different. For example, the traveling direction of the reflected light of the first reflecting portion is oriented along the rotational diameter direction where the indicating portion is provided, whereas the traveling direction of the reflected light of the second reflecting portion is provided by the indicating portion. In the case of the direction intersecting the rotation diameter direction, the way in which the light incident on the pointing unit travels in the pointing unit is different. The light incident on the indicator from the first reflector travels toward the tip in the indicator along the direction of the radial direction where the indicator is provided, whereas the light incident on the indicator from the second reflector is Proceeds toward the tip while reflecting in the side of the part. For this reason, assuming that the amount of incident light on the first and second reflecting portions is the same, light is incident on the indicating portion from the first reflecting portion when light is incident on the indicating portion from the second reflecting portion. There is a risk that the light emission luminance may be reduced as compared with the case of doing so. The light is lost every time it is reflected by the object. In this example, the light incident on the indicator from the second reflector is more incident on the indicator than the light incident on the indicator from the first reflector. This is because the number of reflections is considered to increase. As described above, in such a configuration of the pointer, there is a concern that the light emission luminance of the pointing unit changes depending on the rotation position of the pointer.

  Therefore, in the first aspect of the present invention, the first reflecting portion is configured to reflect the light incident on the rotating shaft portion in the rotation radial direction where the indicating portion is provided so as to be directed to the indicating portion. ing. When the first reflecting portion is configured in this way, when light emitted from the light source and incident on the rotating shaft portion of the pointer enters the first reflecting portion, the light is reflected by the first reflecting portion, and the pointing portion Proceed along the rotational radial direction provided. The light that has traveled along the direction of the rotational diameter is incident on the indicator and causes the indicator to emit light.

  According to the first aspect of the present invention, the second reflecting portion is arranged side by side in the rotational circumferential direction with respect to the first reflecting portion, and the light incident on the rotating shaft portion is reflected by the third reflecting portion. And the third reflecting portion is configured to reflect the light reflected by the second reflecting portion in the direction of the radius of rotation where the indicating portion is provided so as to be directed to the indicating portion. When the second and third reflecting portions are configured in this way, when light emitted from the light source and incident on the rotating shaft portion of the pointer enters the second reflecting portion, the light is reflected by the second reflecting portion, It proceeds toward the third reflecting portion and enters the third reflecting portion. And when the light reflected by the 2nd reflection part injects into the 3rd reflection part, the light will be reflected by the 3rd reflection part, and will advance along the rotation radial direction in which an instruction | indication part is provided. The light that has traveled in the direction of the rotation diameter enters the indicator and causes the indicator to emit light.

  In this way, the light incident on the first and second reflecting portions eventually travels in the radial direction in which the indicator is provided and enters the indicator. According to the first aspect of the present invention, it is possible to make the incident direction of the light incident on the indicating portion substantially the same regardless of whether the light is incident from the first reflecting portion or the second reflecting portion. According to this, since the light travels in the instruction unit is almost the same, it is possible to suppress the change in the light emission luminance of the instruction unit depending on the rotation position of the pointer.

In the invention according to claim 2, the amount of incident light on the first reflecting portion of the light from the light source is greater than the amount of incident light on the second reflecting portion due to the rotation of the rotating shaft portion of the first reflecting portion. In this case, the light having a large amount of incident light incident on the first reflecting portion is reflected in the rotation radial direction so as to be directed to the pointing portion,
In the case where the amount of incident light on the second reflecting portion of the light from the light source is larger than the amount of incident light on the first reflecting portion due to the rotation of the rotating shaft portion, the second reflecting portion becomes the second reflecting portion. It is characterized in that the incident light with a large amount of incident light is reflected by the third reflecting portion.

  According to the second aspect of the present invention, in the case where the amount of incident light to the first reflecting portion of the light from the light source is larger than the amount of incident light to the second reflecting portion due to the rotation of the rotating shaft portion, Since the one reflecting portion is configured to reflect the light having a large incident light amount incident on the first reflecting portion in the rotation radial direction so as to be directed to the indicating portion, most of the light from the light source is the first. It will enter into an instruction | indication part through a reflection part. Therefore, in this case, the light incident on the first reflecting part dominates the light emission luminance of the indicating part.

  In addition, when the rotating shaft rotates, the amount of light incident on the second reflecting portion of the light from the light source becomes larger than the amount of incident light on the first reflecting portion, the second reflecting portion Since the light with a large amount of incident light incident on the part is directed to the third reflecting part, most of the light from the light source enters the indicating part via the second and third reflecting parts. It becomes. Therefore, in this case, the light incident on the second reflecting part dominates the light emission luminance of the indicating part.

  As described above, since each reflection unit is configured such that light reflected by the reflection unit having a large amount of incident light enters the instruction unit, in any case, most of the light from the light source is indicated. Can be incident on the part. According to this, even if the rotating shaft portion rotates, the light amount difference of the light to the instruction portion becomes small. Therefore, it is possible to prevent the light emission luminance of the instruction unit from changing depending on the rotation position of the pointer.

  According to a third aspect of the present invention, the third reflecting portion is provided in a recessed portion provided at an end of the rotating shaft portion, and the recessed portion is provided in the optical path of light from the first reflecting portion toward the indicating portion. It is characterized by having.

  According to the third aspect of the present invention, since the concave portion provided with the third reflecting portion is provided in the optical path of the light from the first reflecting portion toward the indicating portion, the light reflected by the first reflecting portion is It will pass through the recess. As described above, when there is a concave portion in the optical path, that is, a substance different from the material constituting the rotary shaft portion, the light diffuses or attenuates when passing through the concave portion. Therefore, the incident light quantity of the light incident on the instruction unit is reduced due to the presence of the recess. Further, when the depth of the recess and the size of the opening are changed, the influence of the light on the recess changes, so that the amount of incident light of the light incident on the indicator also changes. If this is utilized, the incident light quantity of the light which injects into an instruction | indication part from a 1st reflection part can be adjusted by changing the shape of a recessed part.

  Further, in the reflected light of the first reflecting portion, by changing the shape of the concave portion in order to adjust the amount of incident light incident on the indicating portion, the size of the third reflecting portion is also changed at the same time. . If the size of the third reflecting portion is changed, the amount of light directed from the third reflecting portion to the indicating portion also changes. That is, by changing the shape of the concave portion, not only the incident light amount of light incident on the indicating portion from the first reflecting portion but also the incident light amount of light incident on the indicating portion from the third reflecting portion can be adjusted simultaneously.

  According to a fourth aspect of the present invention, the third reflecting portion is provided in a through-hole penetrating both ends of the rotating shaft portion so as to be along the rotation center line direction of the rotating shaft portion, and the through-hole is the first reflecting portion. It is characterized in that it is provided in the middle of the optical path of light from the unit to the instruction unit.

  According to the fourth aspect of the present invention, since the through hole in which the third reflecting portion is provided is provided in the optical path of the light from the first reflecting portion toward the indicating portion, the light reflected by the first reflecting portion Will pass through the through hole. Thus, if there is a through hole, that is, a substance different from the material constituting the rotating shaft portion, in the middle of the optical path, light diffuses or attenuates when passing through the through hole. Therefore, the amount of light incident on the indicator is reduced due to the presence of the through hole. Further, when the axial length of the through hole or the size of the opening is changed, the influence of the light on the through hole is changed, so that the amount of incident light of the light incident on the pointing unit is also changed. If this is utilized, the incident light quantity of the light which injects into an instruction | indication part from a 1st reflection part can be adjusted by changing the shape of a through-hole.

  Further, in the reflected light of the first reflecting portion, by changing the shape of the through hole in order to adjust the amount of incident light incident on the indicating portion, the size of the third reflecting portion is also changed at the same time. Become. If the size of the third reflecting portion is changed, the amount of light directed from the third reflecting portion to the indicating portion also changes. That is, by changing the shape of the through-hole, not only the incident light amount of light incident on the indicating portion from the first reflecting portion but also the incident light amount of light incident on the indicating portion from the third reflecting portion can be adjusted simultaneously. .

  According to a fifth aspect of the present invention, the third reflecting portion is provided in a concave portion provided at an end portion opposite to the end portion where the light from the light source is incident, among the end portions of the rotating shaft portion. A first reflecting portion is provided at the bottom of the base plate.

  According to invention of Claim 5, the 1st reflection part is provided in the bottom part of the recessed part in which the 3rd reflection part is provided. For this reason, if the light from a light source injects into a 1st reflection part and the light which injected into the 1st reflection part reflects, the reflected light will advance along the rotation radial direction in which an instruction | indication part is provided. The light that has traveled in the direction of the rotation diameter enters the indicator and causes the indicator to emit light.

  Further, when the light from the light source is incident on the second reflecting portion and the light incident on the second reflecting portion is reflected, the reflected light travels toward the third reflecting portion provided in the concave portion, and the third reflecting portion. Incident on the reflection part. When the light reflected by the second reflecting portion enters the third reflecting portion, the light is reflected by the third reflecting portion and travels along the rotational radial direction in which the pointing portion is provided. The light that has traveled in the direction of the rotation diameter enters the indicator and causes the indicator to emit light.

  In this way, even if the first reflecting portion is provided not only at the third reflecting portion but also at the bottom of the recess, it is possible to suppress the change in the light emission luminance of the indicating portion depending on the rotation position of the pointer.

  According to the fifth aspect of the present invention, by changing the depth of the recess, the size of the opening, and the area of the bottom, the amount of incident light incident on the indicating unit from the first reflecting unit, and the third It is possible to simultaneously adjust the amount of incident light that enters the indicating unit from the reflecting unit.

It is a fragmentary sectional view of a meter concerning a first embodiment to which the present invention is applied. FIG. 2 is a perspective view of a pointer illustrated in FIG. 1. FIG. 3 is a plan view of the pointer illustrated in FIG. 2. FIG. 4 is a sectional view taken along line IV-IV illustrated in FIG. 3. FIG. 5 is a cross-sectional view taken along line VV illustrated in FIG. 3. FIG. 5 is a cross-sectional view taken along line VI-VI illustrated in FIG. 4. It is sectional drawing of the pointer | guide which concerns on 2nd embodiment to which this invention is applied. It is a top view of a pointer concerning a third embodiment to which the present invention is applied. It is sectional drawing of the IX-IX line shown in FIG. It is sectional drawing of the XX line shown in FIG.

  Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. In addition, the overlapping description is abbreviate | omitted by attaching | subjecting the same code | symbol to the component corresponding in each embodiment.

(First embodiment)
FIG. 1 is a partial cross-sectional view of a meter according to a first embodiment to which the present invention is applied. A meter 1 shown in FIG. 1 is a part of a combination meter mounted on a vehicle. The combination meter is installed on an instrument panel provided in front of the driver's seat and the passenger's seat. The meter provided in the combination meter includes a speedometer that indicates the running speed of the vehicle, a tachometer that indicates the rotational speed of the engine mounted on the vehicle, and the remaining amount of fuel in the fuel tank mounted on the vehicle. There are fuel gauges to show. In this embodiment, a case where the meter 1 is used as a speedometer will be described.

(Basic structure of the instrument)
The meter 1 shown in FIG. 1 has a vehicle state, for example, traveling speed, engine rotation, and the like, by indicating an indicator (not shown) composed of characters, scales, and the like provided on a dial 10 by an instruction unit 16 of a pointer 14. Displays speed and fuel level. For example, when the meter 1 is used as a speedometer, the pointer 14 moves along the dial 10 and indicates the traveling speed of the vehicle by pointing to characters and scales corresponding to the traveling speed of the vehicle. The meter 1 includes a dial 10, a pointer 14, a drive device 34, a light source 38, a partition member 40, and the like.

  The dial 10 is formed by laminating a light-shielding printing layer having a light-shielding property on a light-transmissive substrate made of light-transmitting polycarbonate or acrylic. The indicators provided on the dial 10 are provided side by side on an arc centered on the rotation center line 42 of the pointer 14. The indicator provided on the dial 10 emits light by transmitting light from a light source (not shown) provided behind the dial 10. Here, the back means the side opposite to the viewer side viewing the instrument 1. The back of the dial 10 is the lower side of the dial 10 in FIG. On the contrary, the front side of the dial 10 means the viewer side, and the upper side of the dial 10 is the front side of the dial 10 in FIG. The indicator is formed of, for example, a portion exposed from the through hole of the light-shielding print layer in the light-transmitting substrate, and transmits light from a light source provided behind the dial 10 to the front side of the dial 10. Thereby, the indicator is displayed by light emission.

  A pointer 14 is installed on the front side of the dial 10 so as to be rotatable along the front surface of the dial 10. The pointer 14 includes a rotating shaft part 20, an instruction part 16, a cover 30, and the like. The rotating shaft portion 20 and the instruction portion 16 are made of light-transmitting polycarbonate or acrylic. The cover 30 is made of light-opaque black polypropylene, acrylonitrile, butadiene, styrene, or the like.

  The rotating shaft portion 20 is installed so as to cover the opening portion 12 of the dial 10. The rotary shaft portion 20 has a rotary shaft 22 that is mechanically connected to the output shaft 36 of the driving device 34 at the end portion 26 on the dial 10 side. The rotating shaft 22 protrudes from the end portion 26 of the rotating shaft portion 20 toward the driving device 34 and penetrates the opening 12. Thereby, the rotation driving force of the output shaft 36 is transmitted to the rotating shaft 22 by rotating the output shaft 36 of the driving device 34. Thereby, the rotating shaft part 20 rotates around the rotation center line 42.

  The rotating shaft portion 20 has a light receiving portion 28 around the rotating shaft 22 at the end portion 26. The light receiving unit 28 receives light from the light source 38 provided behind the dial 10 and makes the light incident on the rotary shaft unit 20. The rotating shaft unit 20 guides the light incident from the light receiving unit 28 to the instruction unit 16. The structure for guiding light will be described later.

  The instruction unit 16 is formed in a bar shape so that the index of the dial 10 can be pointed. The instruction part 16 protrudes from the side part of the rotary shaft part 20 in the rotational radial direction of the rotary shaft part 20. The instruction unit 16 further extends along the dial 10. The instruction unit 16 has a reflective layer 18 that reflects light to the front side, that is, the viewer side, on the surface on the dial 10 side. The reflective layer 18 is formed by applying a red hot stamp or the like. Thus, according to the instruction | indication part 16 which has the reflection layer 18, when light injects from the rotating shaft part 20, light is reflected in a reflection layer 18 toward a viewer. Thereby, the viewer visually recognizes the indicator 16 that has emitted light.

  The cover 30 is a member that covers the end 24 on the opposite side of the end 26 of the rotary shaft 20. The cover 30 covers the end portion 24 of the rotating shaft portion 20, thereby suppressing light incident from the light receiving portion 28 from being emitted from the end portion 24 toward the viewer.

  The driving device 34 is, for example, a stepping motor or a cross coil type rotating machine, and is installed behind the dial 10. The output shaft 36 of the drive device 34 is connected to the rotary shaft 22 of the pointer 14. The driving device 34 is mounted on a circuit board 44 installed behind the dial 10. The drive device 34 is controlled by a control device (not shown) mounted on the circuit board 44. The control device controls the rotation of the output shaft 36 by controlling the energization to the drive device 34.

  A light source 38 is mounted on the circuit board 44. The light source 38 is mainly composed of a light emitting diode, for example. The light source 38 is mounted around an opening 46 formed to project the output shaft 36 toward the pointer 14. The light source 38 is mounted at a position shifted from the rotation center line 42. The light source 38 is located in a region formed on the circuit board 44 when the rotary shaft portion 20 is projected in the direction behind the dial 10.

  The partition member 40 is made of light-opaque white polypropylene, acrylonitrile, butadiene, styrene, or the like. The partition member 40 is a member installed between the dial 10 and the circuit board 44 that surrounds the output shaft 36, the rotation shaft 22, and the light source 38. According to the partition member 40, it is possible to suppress the light emitted from the light source 38 from being directed to other parts without being directed to the light receiving unit 28.

  The operation of the instrument 1 configured as described above will be described. The control device is electrically connected to the ABS control device via a signal line. The ABS control device is a device that controls the braking device so that the wheel is not locked during braking, calculates the traveling speed of the vehicle from the detected rotational speed of the wheel, and outputs a vehicle speed signal corresponding to the calculated traveling speed. Output.

  When the control device receives the vehicle speed signal from the ABS control device, the control device controls the drive device 34 based on the received vehicle speed signal. Specifically, the control device drives the drive device 34 so that the traveling speed displayed by the instruction unit 16 of the pointer 14 and the index instructed by the instruction unit 16 matches the traveling speed corresponding to the received vehicle speed signal. The rotation angle of the output shaft 36 is controlled.

(Guideline structure)
Next, the structure of the pointer 14 will be described in detail with reference to FIGS.

  FIG. 2 is a perspective view of the pointer 14 shown in FIG. 3 is a plan view of the rotary shaft 20 of the pointer 14 shown in FIG. 1 when viewed from the viewer side. 4 is a cross-sectional view taken along line IV-IV shown in FIG. FIG. 5 is a cross-sectional view taken along line VV shown in FIG. FIG. 6 is a sectional view taken along line VI-VI.

  As shown in FIGS. 2 and 3, the pointer 14 includes a rotating shaft portion 20 and an instruction portion 16. The rotating shaft portion 20 has a rotating shaft 22. The rotation shaft 22 protrudes from the end portion 26 of the rotation shaft portion 20 along the rotation center line 42 shown in FIG. When the output shaft 36 is connected to the rotating shaft 22 and the output shaft 36 rotates by driving the drive device 34, the rotating shaft 22 is provided on the rotation center line 42 and rotates around the rotation center line 42. As a result, the rotating shaft portion 20 rotates around the rotation center line 42 (see the arrow in FIG. 2).

  As already described, from the side of the rotating shaft portion 20, the bar-shaped indicating portion 16 is directed in the radial direction of the rotating shaft portion 20 and protrudes along the dial 10. As shown in FIG. 2 and FIG. 3, the longitudinal line 32 of the indicator 16 is a line that passes through the center of the indicator 16 and intersects the rotation center line 42 of the rotary shaft 20. In the present embodiment, the longitudinal direction line 32 and the rotation center line 42 are orthogonal to each other.

  The rotating shaft part 20 has the 1st reflection part 50, 2nd reflection part 52a, b, and 3rd reflection part 54a, b. The first reflecting portion 50 is provided on the longitudinal direction line 32. The first reflecting portion 50 is provided on the opposite side of the rotation center line 42 from the indicating portion 16. The first reflecting portion 50 is a flat surface that is separated from the rotation center line 42 as it goes from the end 24 to the end 26 of the rotating shaft portion 20. The second reflecting portions 52a and 52b are provided side by side on both sides in the rotational circumferential direction with respect to the first reflecting portion 50. The second reflecting portions 52 a and 52 b are flat surfaces that are separated from the instruction portion 16 as they go from the end 24 to the end 26 of the rotating shaft portion 20.

  Here, the positional relationship between the first reflection unit 50, the second reflection units 52a and 52b, and the light source 38 will be described. As described above, the rotating shaft portion 20 rotates around the rotation center line 42. On the other hand, the light source 38 is mounted on the circuit board 44. Therefore, the rotation shaft 20 rotates around the rotation center line 42, so that the relative position with the light source 38 changes. In addition, the light source 38 has the highest luminous intensity in the central portion, and the luminous intensity in the portion outside the central portion is low. When an LED is used as the light source 38, it has a certain degree of directivity and therefore has the highest luminous intensity at the center. When the light receiving unit 28 is disposed to face the light source 38, the portion of the light receiving unit 28 closest to the light source 38 has the highest illuminance.

  FIG. 3 shows the positional relationship between the rotating shaft portion 20 and the light source 38. A light source 38 indicated by a broken line illustrated in FIG. 3 indicates a position when the rotary shaft portion 20 is illustrated by a solid line. When the rotary shaft portion 20 rotates around the rotation center line 42, the relative positions of the first and second reflecting portions 50, 52a, b and the light source 38 change. When the relative positions of the reflecting portions 50, 52a, b and the light source 38 change, the light from the light source 38 that is incident on the first reflecting portion 50 or the second reflecting portions 52a, 52b depends on the rotational position of the rotating shaft portion 20. The amount of light changes.

  In the state shown in FIG. 3, the light source 38 is disposed at a position closest to the first reflecting unit 50. Hereinafter, this state is referred to as a “first state”. In the first state, the amount of light incident on the first reflecting portion 50 is greater than the amount of light incident on each of the second reflecting portions 52a and 52b.

  In FIG. 3, when the rotary shaft 20 rotates a predetermined angle clockwise with respect to the rotation center line 42, the light source 38 comes closest to the position A in FIG. 3, that is, the second reflecting portion 52a. Will be placed at the position. Hereinafter, this state is referred to as a “second state”. In the second state, the amount of incident light incident on the second reflecting portion 52a is greater than the amount of incident light incident on each of the first reflecting portion 50 and the second reflecting portion 52b.

  Further, in FIG. 3, when the rotary shaft 20 rotates a predetermined angle counterclockwise with respect to the rotation center line 42, the light source 38 comes closest to the position B in FIG. 3, that is, the second reflecting portion 52b. It will be arranged at the position. Hereinafter, this state is referred to as a “third state”. In the third state, the amount of incident light incident on the second reflecting portion 52b is larger than the amount of incident light incident on each of the first reflecting portion 50 and the second reflecting portion 52a.

  The talk is returned to the first reflecting part 50 and the second reflecting parts 52a, 52b again. As shown in FIGS. 4 and 6, in the first state, the first reflecting unit 50 is configured so that the instruction unit 16 directs the light from the light source 38 incident on the rotation shaft unit 20 to the instruction unit 16. Reflected in the direction of the diameter of the rotary shaft 20 provided. Hereinafter, the reflected light from the first reflecting portion 50 is referred to as “reflected light from the first reflecting portion 50”.

  Since the first reflecting part 50 is installed on the longitudinal direction line 32 of the indicating part 16 as already described, the reflected light of the first reflecting part 50 toward the indicating part 16 is as shown in FIGS. And along the longitudinal line 32. It can be said that the reflected light of the first reflection unit 50 is along the rotation diameter direction.

  As shown in FIGS. 4 and 6, the second reflecting portion 52a is in the second state, and the light from the light source 38 incident on the rotating shaft portion 20 is directed toward the longitudinal line 32, that is, to the third reflecting portion 54a. Reflected toward. Similarly, in the third state, the second reflecting portion 52b reflects light from the light source 38 incident on the rotating shaft portion 20 toward the longitudinal direction line 32, that is, toward the third reflecting portion 54b. ing. Hereinafter, the reflected light from the second reflecting portions 52a and 52b is referred to as “reflected light from the second reflecting portion 52a” and “reflected light from the second reflecting portion 52b”, respectively.

  The third reflecting portions 54a and 54b are portions that reflect the reflected light of the second reflecting portions 52a and 52b, and are disposed on the longitudinal line 32 side of the second reflecting portions 52a and 52b. The third reflecting portion 54 a is provided on the second reflecting portion 52 a side with respect to the longitudinal direction line 32, and is provided on the second reflecting portion 52 b side with respect to the longitudinal direction line 32. As shown in FIG. 4, the third reflecting portions 54 a and 54 b are flat surfaces that approach the longitudinal direction line 32 from the rotation center line 42 toward the pointing portion 16, and rotate as shown in FIG. 5. The flat surface approaches the rotation center line 42 from the end portion 24 of the shaft portion 20 toward the end portion 26.

  As shown in FIG. 6, the third reflecting portion 54 a is a rotating shaft portion provided with the instruction portion 16 so that the reflected light of the second reflection portion 52 a is directed to the instruction portion 16 in the second state. Reflected in the direction of the 20 rotation diameter. As shown in FIG. 6, the third reflecting portion 54 b is a rotating shaft portion provided with the instruction portion 16 so that the reflected light of the second reflection portion 52 b is directed to the instruction portion 16 in the third state. Reflected in the direction of the 20 rotation diameter. As described above, since the third reflecting portions 54a and 54b reflect the reflected light of the second reflecting portions 52a and 52b toward the instruction unit 16, the reflected light reflected by the third reflecting portions 54a and 54b is As shown in FIG. 6, it is along the longitudinal line 32. It can be said that the reflected light of the third reflecting portions 54a and 54b is along the rotational radial direction. Hereinafter, the reflected light from the third reflecting portions 54a and 54b is referred to as “reflected light from the third reflecting portion 54a” and “reflected light from the third reflecting portion 54b”, respectively.

  The third reflecting portions 54a and 54b are provided on the side surface of the recess 56 as shown in FIGS. The recessed portion 56 is a portion formed so as to be recessed from the end portion 24 located in the direction of the rotation center line 42 of the rotating shaft portion 20 toward the end portion 26. As shown in FIG. 3, the concave portion 56 is provided in the middle of the optical path of the reflected light of the first reflecting portion 50. The third reflecting portions 54a and 54b are provided in the concave portion 56 on the respective second reflecting portions 52a and 52b on the side surface sandwiching the longitudinal direction line 32 therebetween. As shown in FIG. 3, the side surfaces on which the third reflecting portions 54 a and 54 b are provided approach each other as they face the pointing portion 16. Further, as shown in FIG. 5, the side surfaces approach each other as they approach the end portion 26 of the rotating shaft portion 20.

  The structure of the pointer 14 has been described in detail above. Next, the operation for causing the pointer 14 to emit light will be described for each of the first, second, and third states described above.

(First state)
In the first state, the light from the light source 38 incident on the first reflecting portion 50 is reflected by the first reflecting portion 50 and travels along the longitudinal line 32 and toward the pointing portion 16 (FIGS. 4 and 4). 6). Then, the reflected light of the first reflection unit 50 enters the instruction unit 16. The light incident on the instruction unit 16 travels toward the tip of the instruction unit 16 and is reflected toward the viewer side by the reflective layer 18. As a result, the instruction unit 16 is lit and displayed.

  In the first state, the amount of incident light incident on the first reflecting portion 50 is greater than the amount of incident light incident on the second reflecting portions 52a and 52b. Then, in the first state, the first reflecting unit 50 reflects the light having a large incident light amount incident on the first reflecting unit 50 along the longitudinal direction line 32 so as to be directed to the indicating unit 16. It is configured as follows. For this reason, most of the light from the light source 38 enters the indicator 16 via the first reflector 50. Therefore, in this first state, the light having a large incident light amount incident on the first reflecting unit 50 dominates the light emission luminance of the instruction unit 16.

(Second state)
In the second state, the light from the light source 38 incident on the second reflecting portion 52a is reflected by the second reflecting portion 52a and travels toward the third reflecting portion 54a (see FIG. 6). Thereafter, the reflected light of the second reflecting portion 52a enters the third reflecting portion 54a. When the reflected light of the second reflecting portion 52a enters the third reflecting portion 54a, the reflected light is reflected by the third reflecting portion 54a and travels along the longitudinal direction line 32 and toward the pointing portion 16 (FIG. 6). Then, the reflected light of the third reflecting portion 54 a enters the indicating portion 16. The light incident on the instruction unit 16 travels toward the tip of the instruction unit 16 and is reflected toward the viewer side by the reflective layer 18. As a result, the instruction unit 16 is lit and displayed.

  In the second state, the amount of incident light incident on the second reflecting portion 52a is larger than the amount of incident light incident on the first reflecting portion 50 and the second reflecting portion 52b. In the second state, the second reflecting portion 52a is configured to reflect a large amount of incident light incident on the second reflecting portion 52a so as to be directed toward the third reflecting portion 54a. Yes. For this reason, most of the light from the light source 38 enters the indicator 16 through the second reflecting portion 52a and the third reflecting portion 54a. Therefore, in this second state, light with a large amount of incident light that has entered the second reflecting portion 52a dominates the light emission luminance of the indicating portion 16.

(Third state)
In the third state, the light from the light source 38 incident on the second reflecting portion 52b is reflected by the second reflecting portion 52b and travels toward the third reflecting portion 54b (see FIG. 6). Thereafter, the reflected light of the second reflecting portion 52b enters the third reflecting portion 54b. When the reflected light of the second reflecting portion 52b enters the third reflecting portion 54b, the reflected light is reflected by the third reflecting portion 54b and travels along the longitudinal direction line 32 and toward the pointing portion 16 (FIG. 6). Then, the reflected light of the third reflecting portion 54 b enters the indicating portion 16. The light incident on the instruction unit 16 travels toward the tip of the instruction unit 16 and is reflected toward the viewer side by the reflective layer 18. As a result, the instruction unit 16 is lit and displayed.

  In the third state, the amount of incident light incident on the second reflecting portion 52b is larger than the amount of incident light incident on the first reflecting portion 50 and the second reflecting portion 52a. In the third state, the second reflecting portion 52b is configured to reflect a large amount of incident light incident on the second reflecting portion 52b so as to be directed toward the third reflecting portion 54b. Yes. For this reason, most of the light from the light source 38 enters the indicator 16 through the second reflecting portion 52b and the third reflecting portion 54b. Therefore, in this third state, light with a large amount of incident light incident on the second reflecting portion 52b dominates the light emission luminance of the indicating portion 16.

  The light emission of each instruction unit 16 in the first to third states has been described above. In this embodiment, as described above, in any state, the light incident on the first and second reflecting portions 50, 52a, and b is rotated by the rotating shaft portion 20 where the indicating portion 16 is finally provided. The light travels along the radial direction (longitudinal line 32) and enters the indicator 16. According to the present embodiment, the incident direction of the light incident on the instruction unit 16 is substantially the same regardless of whether it is from the first reflection unit 50 or from the second reflection units 52a and 52b. it can. According to this, since the light travels in the instruction unit 16 is almost the same, it is possible to suppress the light emission luminance of the instruction unit 16 from changing depending on the rotation position of the pointer 14.

  Further, in the present embodiment, each reflection is configured so that light reflected by the reflection units 50, 52a, and b having a large amount of incident light is incident on the instruction unit. Therefore, in any case (first case, Even in the second case and the third case), most of the light from the light source 38 can be incident on the indicator 16. According to this, even if the rotating shaft part 20 rotates, the difference in the amount of incident light to the instruction part 16 becomes small. Therefore, it is possible to suppress the light emission luminance of the instruction unit 16 from changing depending on the rotation position of the pointer 14.

(Regarding the adjustment of the light emission luminance of the instruction unit 16)
Next, adjustment of the light emission luminance of the instruction unit 16 will be described. As described above, in the first state, the reflected light of the first reflecting portion 50 travels along the longitudinal direction line 32 toward the indicating portion 16. A concave portion 56 is provided in the middle of the reflected light traveling toward the instruction portion 16. For this reason, a part of the reflected light passes through the recess 56. The reflected light passing through the recess 56 is diffused or attenuated. Unlike the resin constituting the rotary shaft portion 20, the inside of the concave portion 56 is an air layer. The light diffuses or attenuates when traveling from the inside of the rotating shaft portion 20 to the air layer inside the recessed portion 56 and entering the rotating shaft portion 20 again from the air layer inside the recessed portion 56. The reflected light that has not passed through the recess 56 travels as it is toward the indicator 16 in the rotary shaft 20. As described above, when the concave portion 56 is provided in the optical path of the reflected light of the first reflecting portion 50, the amount of incident light of the light incident on the indicating portion 16 is reduced by the diffusion and attenuation action of the light in the concave portion 56.

  This diffusion or attenuation of light is largely related to the shape of the recess 56. For example, as the depth of the recess 56 increases, the volume of the air layer formed increases, so that the degree of light diffusion or attenuation increases. That is, by adjusting the shape of the concave portion 56, the amount of incident light of the light incident on the instruction unit 16 can be adjusted.

  On the other hand, as the depth of the recess 56 increases, the area of the side surface of the recess 56 increases. That is, the size of the third reflecting portions 54a and 54b is increased. For this reason, the deeper the recess 56, the greater the amount of reflected light from the third reflecting portions 54a, 54b.

  According to these things, by changing the depth of the recessed part 56, the incident light quantity of the light which injects into the instruction | indication part 16 from the 1st reflection part 50, and injects into the instruction | indication part 16 from the 3rd reflection part 54a, b. The incident light quantity of light can be adjusted simultaneously. By optimizing the depth of the concave portion 56, it is possible to further suppress the change in the light emission luminance of the instruction portion 16 depending on the rotational position of the pointer 14.

  This adjustment of light is possible not only by changing the depth of the recess 56 but also by changing the size of the opening of the recess 56. For example, by increasing the length of the recess 56 in the direction along the longitudinal direction line 32, the degree of diffusion or attenuation of the reflected light of the first reflecting unit 50 increases, and the amount of incident light of the light incident on the indicating unit 16 is increased. decrease. This is because the air layer formed by the recess 56 becomes larger. On the other hand, since the size of the third reflecting portions 54a and 54b provided in the concave portion 56 is also increased, the amount of incident light of the light incident on the indicating portion 16 is increased. Thus, the same effect as adjusting the depth of the recess 56 can be obtained by changing the size of the opening of the recess 56.

(Second embodiment)
A pointer 114 according to the second embodiment shown in FIG. 7 is a modification of the pointer 14 according to the first embodiment. FIG. 7 is a cross-sectional view of the pointer 114 according to the second embodiment to which the present invention is applied. This figure corresponds to FIG. 4 of the preceding embodiment. Therefore, except for the shape peculiar to this embodiment, it is the same as that shown in FIG.

  As shown in FIG. 7, the rotating shaft portion 120 has a through hole 156 that penetrates both end portions 24 and 26 in place of the recessed portion 56. The through hole 156 is along the rotation center line 42 of the rotation shaft portion 120. Third reflecting portions 54a and 54b are provided on the side surface of the through hole 156 sandwiching the longitudinal direction line 32 therebetween. As described above, even when the third reflecting portions 54 a and 54 b are provided on the side surface of the through-hole 156, the same as in the previous embodiment that suppresses the change in the light emission luminance of the indication portion 16 depending on the rotation position of the pointer 114. The effect is obtained.

  Further, by changing the axial length and the opening area of the through-hole 156, the amount of incident light incident on the indicating unit 16 from the first reflecting unit 50 and the amount of light incident on the indicating unit 16 from the third reflecting unit 54 are changed. The same effect as the previous embodiment that the incident light quantity can be adjusted simultaneously can be obtained.

(Third embodiment)
A pointer 214 according to the third embodiment shown in FIGS. 8 to 10 is a modification of the pointer 14 according to the first embodiment. FIG. 8 is a plan view of the pointer 214 according to the third embodiment to which the present invention is applied. 9 is a cross-sectional view taken along line IX-IX shown in FIG. 10 is a cross-sectional view taken along line XX illustrated in FIG.

  As shown in FIGS. 8-10, in this embodiment, the installation position with respect to the rotating shaft 220 of the light source 38 differs from the thing of 1st, 2nd embodiment. The difference is that the light source 38 is disposed closer to the pointing unit 16 than the rotation center line 42 of the pointer 214 and the first reflecting unit 50 is disposed closer to the pointing unit 16 than the rotation center line 42. It is a point.

  In this embodiment, the first reflecting portion 50 is provided at the bottom of the recess 256, and the third reflecting portions 54 a and 54 b are provided on the side surface sandwiching the longitudinal line 32 of the recess 256. The recess 256 is provided at the end 24 opposite to the end 26 where the light from the light source 38 of the rotary shaft 220 enters.

  In the first state in which the light source 38 is closest to the first reflecting unit 50, as shown in FIG. 9, the light from the light source 38 incident from the light receiving unit 28 is reflected by the first reflecting unit 50, and the indicating unit Go to 16. The reflected light of the first reflecting portion 50 is along the longitudinal direction line 32 as shown in FIG.

  Further, in FIG. 8, in the second state where the rotating shaft portion 220 rotates counterclockwise and the light source 38 is closest to the second reflecting portion 52 a, as shown in FIGS. 8 and 10, from the light receiving portion 28. The incident light from the light source 38 is reflected by the second reflecting portion 52a and travels toward the third reflecting portion 54a. And the 3rd reflection part 54a reflects the reflected light of the 2nd reflection part 52a toward the instruction | indication part 16, as shown in FIG. The reflected light of the third reflecting portion 54 a is along the longitudinal line 32.

  Further, in FIG. 8, in the third state where the rotating shaft portion 220 rotates clockwise and the light source 38 is closest to the second reflecting portion 52b, the light enters from the light receiving portion 28 as shown in FIGS. The light from the light source 38 is reflected by the second reflecting portion 52b and travels toward the third reflecting portion 54b. And the 3rd reflection part 54b reflects the reflected light of the 2nd reflection part 52b toward the instruction | indication part 16, as shown in FIG. The reflected light of the third reflecting portion 54b is along the longitudinal line 32.

  As described above, in this embodiment as well, the optical path of light incident on the pointing unit 16 is almost the same regardless of the rotational position of the pointer 214 as in the preceding embodiment. Similar effects can be obtained.

  Also in this embodiment, the first reflection can be achieved by changing the shape of the recess 256, for example, by changing the depth of the recess 256, the size of the bottom of the recess 256, or the size of the opening of the recess 256. It is possible to adjust the amount of incident light incident on the instruction unit 16 from the unit 50 and the amount of incident light incident on the instruction unit 16 from the third reflection units 54a and 54b.

(Other embodiments)
In the above, several embodiment of this invention was described. The present invention is not construed as being limited to the above-described embodiments, and can be applied to various embodiments without departing from the scope of the invention.

  For example, the shapes of the first reflecting portion 50, the second reflecting portions 52a and 52b, and the third reflecting portions 54a and 54b are not limited to planar shapes, and may be curved shapes.

  In the first embodiment, the recess 56 is formed at the end 24 of the rotary shaft 20, but may be formed at the end 26 of the rotary shaft 20.

  1 instrument, 10 dial, 14, 114, 214 pointer, 16 indicator, 18 reflective layer, 20, 120, 220 rotating shaft, 22 rotating shaft, 24 end, 26 end, 28 light receiving unit, 30 cover, 32 Longitudinal line, 34 Drive unit, 38 Light source, 42 Rotation center line, 44 Circuit board, 50 First reflector, 52a, 52b Second reflector, 54a, 54b Third reflector, 56, 256 Recess, 156 Through Hole

Claims (5)

By rotating around the rotation center line and guiding the incident light, and by projecting in the rotation radial direction from the rotation shaft, and receiving the light guided by the rotation shaft A pointer that has a pointing unit that indicates an index provided on the dial and emits light, and a light source that is disposed at a position shifted from the rotation center line and emits light toward the rotation shaft unit. In the instrument,
The rotating shaft portion is
A first reflecting portion that reflects the light from the light source incident on the rotating shaft portion in the rotation radial direction so as to be directed to the pointing portion;
A second reflecting portion that is provided side by side in the rotational circumferential direction with respect to the first reflecting portion and reflects light from the light source incident on the rotating shaft portion;
An instrument comprising: a third reflecting portion that reflects the light reflected by the second reflecting portion in the rotational radial direction so as to be directed toward the pointing portion. In the case where the amount of incident light on the first reflecting portion of the light from the light source is larger than the amount of incident light on the second reflecting portion by rotating the rotating shaft portion, the first reflecting portion, A large amount of incident light incident on the first reflecting portion is reflected in the rotational radial direction so as to be directed to the pointing portion,
In the case where the amount of incident light to the second reflecting portion of the light from the light source is larger than the amount of incident light to the first reflecting portion by rotating the rotating shaft portion, The instrument according to claim 1, wherein light having a large incident light amount incident on the second reflecting portion is reflected on the third reflecting portion. The third reflecting portion is provided in a recess provided at an end of the rotating shaft portion,
The instrument according to claim 1 or 2, wherein the concave portion is provided in the middle of an optical path of light from the first reflecting portion toward the indicating portion. The third reflecting portion is provided in a through-hole penetrating both end portions of the rotating shaft portion so as to be along the rotation center line direction of the rotating shaft portion,
The instrument according to claim 1 or 2, wherein the through hole is provided in the middle of an optical path of light from the first reflecting portion toward the indicating portion. The third reflecting portion is provided in a concave portion provided at an end portion opposite to an end portion where light from the light source is incident among the end portions of the rotating shaft portion,
The instrument according to claim 1, wherein the first reflecting portion is provided at a bottom portion of the concave portion.

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