JP2019124627A - Pointer and display device - Google Patents

Abstract

To provide a pointer capable of simplifying work for holding a pointer cap in a pointer body.SOLUTION: A pointer used for a display device includes a pointer body, and a pointer cap 150 held by the pointer body. The pointer body includes a protrusion 147 and a section in addition to a columnar pin part 144. The protrusion 147 projects from an outer surface of the pin part 144. The section partitions a slit along an axial direction of the pin part 144 in the pin part 144. The pointer cap 150 includes a regulation part 157 in addition to a hole 156 into which the pin part 144 is inserted. The regulation part 157 is positioned in a root direction of the pin part 144 as compared with the projection 147 and regulates movement of the projection 147 in a root direction.SELECTED DRAWING: Figure 8

Description

  The present disclosure relates to a guide and a display device using the guide.

  Patent Document 1 discloses guidelines for a display device. The pointer comprises a pointer body and a pointer cap. A through hole is formed in the pointer body. A cylindrical boss is formed on the pointer cap. The boss is inserted through the through hole. An enlarged diameter portion with an increased outer diameter is formed by caulking on the tip end portion of the boss. A pointer cap is fixed to the pointer body by the contact between the enlarged diameter portion and the inner peripheral edge of the through hole.

JP 2007-121229 A

  As described above, in the pointer of Patent Document 1, in order to hold the pointer cap on the pointer main body, caulking is performed after the insertion step of inserting the columnar pin portion formed on one into the hole formed on the other. Further post processing was needed. Such a post process prevents the simplification of the operation of holding the pointer cap on the pointer body.

  An object of the present disclosure is to provide a guide capable of simplifying an operation of holding a guide cap on a guide body, and a display device using the guide.

  The above object is achieved by the combination of the features described in the independent claims, and the subclaims define further advantageous embodiments of the present disclosure. The reference numerals in parentheses described in the claims indicate the correspondence with the specific means described in the embodiment described later as one aspect, and do not limit the technical scope of the present disclosure. .

  The present disclosure to achieve the above object is a pointer (100) used in a display device (1), including a pointer body (110) and a pointer cap (150) held on the pointer body. The first member (110), which is either the pointer body or the pointer cap, has a columnar pin portion (144), a protrusion (147) protruding from the outer surface of the pin portion, and an axial direction of the pin portion And a second member (150), which is the other of the pointer body and the pointer cap, has a hole (156) through which the pin portion is inserted. And a restricting portion (157) positioned in the direction of the base of the pin portion relative to the projecting portion to restrict movement of the projecting portion in the direction of the base.

  According to the above configuration, in the columnar pin portion, the slit along the axial direction is divided by the dividing portion. The slits allow the projections projecting from the outer surface of the pin to be displaced inwardly. Therefore, in the insertion step of inserting the pin portion into the hole portion, the protrusion can move in the distal direction more than the restriction portion by passing the restriction portion due to the inward displacement. The protrusion which has moved in the distal direction than the restricting portion returns outward due to the restoring force of the pin. The protruding portion returned outward is in a state in which the movement in the root direction is restricted by the restriction portion located in the root direction. According to the above, after the insertion step, the movement of the pin portion in the root direction can be restricted. As a result, in the holding operation, it is possible to hold the pointer cap on the pointer body without performing a post process. Therefore, the operation of holding the pointer cap on the pointer body can be simplified.

It is a front view of a display apparatus. It is the II-II sectional view taken on the line of FIG. It is a perspective view of a light guide. It is a perspective view of a light-shielding plate. It is a rear view of a pointer. It is a perspective view of a pointer cap. It is a rear view of a pointer cap. It is the VIII-VIII sectional view taken on the line of FIG. It is a perspective view of a pin part. It is a figure which shows the pointer cap shape | molded in the metal mold | die. It is a figure which shows mold release from the cavity of pointer cap. It is a figure which shows release from the core of a pointer cap. It is a figure which shows the movement to the inward direction of a protrusion part. It is a figure which shows the movement to the outward direction of a protrusion part. It is a figure which shows the state after the penetration process. It is a figure showing the pointer of modification 1. It is a figure which shows the light guide of the modification 1. FIG.

  The display device 1 according to the embodiment of the present disclosure is a combination meter which is installed in an instrument panel of a vehicle as shown in FIG. 1 and performs various displays on a driver. In the display device 1, a pointer display unit 10 is formed. The pointer display unit 10 is used, for example, to display vehicle information such as the speed of the vehicle, the engine speed, and the remaining amount of fuel. The pointer display unit 10 is formed by the display plate 40 and the pointer 100 shown in FIGS. 1 and 2. In the following description, the direction perpendicular to the display plate 40 and where the driver is to be positioned is referred to as the front direction, and the direction opposite to the front direction is referred to as the back direction. The display device 1 is provided with a case 20 and a substrate 30 in addition to the display plate 40 and the pointer 100 described above.

  The case 20 is formed of a light shielding resin material such as an ABS resin. The case 20 supports the display plate 40 from the rear direction. The case 20 accommodates the substrate 30 inside. In the case 20, a case opening 21 for disposing the pointer 100 is formed.

  The substrate 30 is a plate-like member formed by providing a circuit pattern of copper or the like on an insulating base material such as a resin. Both surfaces of the substrate 30 are directed in the front direction and the back direction, respectively. The substrate 30 is provided with a drive device 31, a light source 32, and a control unit 33.

  The driving device 31 is, for example, a stepper motor. The driving device 31 is electrically connected to the control unit 33 via the circuit pattern of the substrate 30. The drive device 31 is mechanically connected to the pointer 100 and rotationally drives the pointer 100.

  The light source 32 is, for example, a light emitting diode. The light source 32 is provided on the surface of the substrate 30 facing the front direction. The light source 32 is disposed in the back direction of the case opening 21. The light source 32 is electrically connected to the control unit 33 via the circuit pattern of the substrate 30. The light source 32 emits light toward the front. The light emitted from the light source 32 causes the pointer 100 to emit light.

  The control unit 33 is configured of, for example, a microcontroller. The control unit 33 acquires vehicle information to be displayed on the pointer display unit 10 from an engine ECU or a body ECU used in the vehicle. The control unit 33 performs rotation control of the drive device 31, brightness control of the light source 32, and the like according to the vehicle information.

  The display board 40 is formed in plate shape with translucent resin materials, such as polycarbonate resin and an acrylic resin. On the display plate 40, indicators such as numbers and graduations indicated by the pointer 100 are printed. At a position corresponding to the case opening 21 in the display plate 40, a display plate opening 41 for arranging the pointer 100 is formed.

  The pointer 100 is a member that points to the display plate 40 by rotating around a rotation axis Ar along the front direction. The pointer 100 includes a pointer body 110 and a pointer cap 150.

  The pointer body 110 is connected to the drive device 31 and rotationally driven to change the position pointed by the pointer 100 on the display plate 40. The pointer body 110 guides the light emitted from the light source 32 and emits it toward the front. The pointer body 110 includes a light guide 120, a diffuser 130, and a light shield plate 140.

  The light guide 120 is formed of a translucent resin material. As shown in FIGS. 2 and 3, the light guide 120 has a shaft 121, an incident part 122, a rotation center part 123, an indication part 125, and a light shielding plate holding part 126.

  The shaft portion 121 is formed in a cylindrical shape. The central axis of the shaft portion 121 substantially coincides with the rotation axis Ar. The shaft portion 121 is connected to the drive device 31. The connection of the shaft portion 121 enables the drive device 31 to rotationally drive the pointer 100.

  The incident part 122 is formed in the disk shape which turned both surfaces to the front direction and the back direction. The incident part 122 is connected to one end of the shaft part 121 in the front direction. The outer peripheral surface of the incident portion 122 protrudes in the outer peripheral direction more than the outer peripheral surface of the shaft portion 121. The light emitted from the light source 32 is incident on the surface of the incident portion 122 facing the back direction.

  The rotation center portion 123 is formed in a rectangular plate shape. The rotation center portion 123 is located in the front direction of the case opening 21. The rotation center portion 123 is a posture in which the short direction is along the rotation axis Ar, and the longitudinal direction and the thickness direction are along the direction orthogonal to the rotation axis Ar. Both ends in the longitudinal direction of the rotation center portion 123 protrude in the outer peripheral direction more than the incident portion 122. A fitting hole 124 is formed at a position of the rotation center portion 123 in the front direction of the incident portion 122. The fitting hole 124 is a through hole which penetrates the rotation center portion 123 in the thickness direction.

  The instruction unit 125 is formed in a columnar shape having a rectangular cross section. The pointing portion 125 extends from one end of the longitudinal center of the rotation center portion 123 along a direction orthogonal to the rotation axis Ar. The dimension of the indicator 125 along the front direction and the dimension of the indicator 125 along the width direction of the pointer 100 decrease with distance from the rotation axis Ar.

  The light shielding plate holding portion 126 is formed in a rectangular plate shape. The light shielding plate holding portion 126 is in a posture orthogonal to the rotation axis Ar. The light shielding plate holding portions 126 are provided at four positions of the rotation center portion 123. Specifically, the light shielding plate holding portions 126 are respectively provided on both sides of the rotation center portion 123 in the longitudinal direction. Each light shielding plate holding portion 126 protrudes from the rotation center portion 123 along the width direction of the pointer 100. In each light shielding plate holding portion 126, arrangement holes 127 penetrating in the thickness direction are respectively formed. Each arrangement hole 127 is formed in an arrangement in which circumferential intervals are substantially equal around the rotation axis Ar.

  The diffuser 130 is formed of a resin material that diffuses and transmits light, such as a white polypropylene resin. The diffuser 130 is attached to the light guide 120 by being fitted in the fitting hole 124. The diffuser 130 diffuses the light incident on the light guide 120 from the incident part 122 toward the indication part 125.

  The light shielding plate 140 is formed in a plate shape from a light shielding resin material as shown in FIGS. 2, 4 and 5. The light shielding plate 140 is disposed in the back direction of the rotation center portion 123 and the instruction portion 125. The light shielding plate 140 shields light which is emitted from the rotation center portion 123 and the instructing portion 125 in the back direction and travels to the display plate 40. The light blocking plate 140 has a central light blocking portion 141, a pointer light blocking portion 143, and a pin portion 144.

  The central light shielding portion 141 is formed in a disk shape. The central axis of the central light shield 141 substantially coincides with the rotation axis Ar. The central light shielding portion 141 covers the back surface of the rotation center portion 123 and the light shielding plate holding portion 126 (see FIG. 3). A light shielding plate opening 142 is formed in the central light shielding portion 141. The shaft portion 121 is inserted through the light shielding plate opening 142. The light shielding plate opening 142 exposes the incident portion 122 in the back direction.

  The pointer light shielding portion 143 is formed in a band plate shape. The pointer light shielding portion 143 protrudes from the outer peripheral surface of the central light shielding portion 141 in a direction away from the rotation axis Ar. The pointer light shielding unit 143 covers the back direction of the instruction unit 125.

  The pin portion 144 is formed in a substantially cylindrical shape extending in the front direction from the central light shielding portion 141. The pin portions 144 are formed at four positions substantially equal in circumferential spacing around the rotation axis Ar. After this, the direction along the axial direction of each pin portion 144, which is the direction from the tip 144a to the root end 144b of each pin 144 as the root direction, and the direction from the root end 144b to the tip 144a as the tip direction explain. Each pin portion 144 is inserted into each arrangement hole 127. The light shielding plate 140 is attached to the light guide 120 by inserting each pin portion 144 into each arrangement hole 127 (see FIG. 3).

  As shown in FIGS. 2, 6, and 7, the pointer cap 150 is formed in a bottomed cylindrical shape with one end opened by a light shielding resin material. The pointer cap 150 is held by the pointer body 110 in a posture in which the opening is directed rearward. The pointer cap 150 covers the front direction and the outer peripheral direction of the pointer body 110. The pointer cap 150 decorates the pointer body 110. The pointer cap 150 has a bottom plate portion 151, an outer peripheral wall portion 153, an outer peripheral convex portion 154, and a pin receiving portion 155.

  The bottom plate portion 151 is formed in a plate shape whose both surfaces are directed in the front direction and the back direction, respectively. The shape of the bottom plate portion 151 projected in the back direction substantially matches the shape of the light blocking plate 140 projected in the back direction. The bottom plate portion 151 is disposed in the front direction of the light guide 120. The bottom plate portion 151 partially blocks light emitted from the light guide 120 in the front direction. A cap opening 152 is formed in the bottom plate portion 151.

  The cap opening 152 is an opening formed in a strip shape extending from a portion covering the rotation center portion 123 of the bottom plate portion 151 to a portion covering the indication portion 125. The cap opening 152 exposes the surface of the rotation center portion 123 and the pointing portion 125 facing the front direction. The light emitted from the rotation center portion 123 and the pointing portion 125 in the front direction through the cap opening 152 causes the pointer 100 to be visually recognized by the driver as a state of partial light emission.

  The outer peripheral wall portion 153 is a wall portion that extends in the back direction from the outer edge of the bottom plate portion 151 and covers the outer periphery of the pointer main body 110. The outer peripheral wall portion 153 extends further in the back direction than the light shielding plate 140. The outer peripheral wall portion 153 is inclined in the outer peripheral direction as it goes back. The outer peripheral wall portion 153 is inclined, for example, 5 to 8 degrees with respect to the rotation axis Ar. The outer peripheral wall portion 153 shields the light emitted from the light guide 120 in the outer peripheral direction. The outer peripheral wall portion 153 includes a cylindrical wall portion 153 a.

  The cylindrical wall portion 153 a is a portion of the outer peripheral wall portion 153 which is formed in a partial cylindrical shape and covers the outer peripheral surface of the central light shielding portion 141. The cylindrical wall portion 153 a covers the entire outer peripheral surface of the central light shielding portion 141 except the protruding portion of the pointer light shielding portion 143.

  The outer peripheral convex portion 154 is a protruding portion that protrudes in the inner circumferential direction from the position in the back direction with respect to the light shielding plate 140 in the inner peripheral surface of the cylindrical wall portion 153 a. The outer peripheral convex portion 154 contacts the surface of the central light shielding portion 141 facing in the back surface direction, and restricts the movement of the central light shielding portion 141 in the back surface direction. The outer circumferential convex portion 154 extends along the circumferential direction, and is formed substantially over the entire circumferential direction of the cylindrical wall portion 153 a. The outer peripheral convex portion 154 is in contact with substantially the entire periphery of the outer peripheral edge of the surface of the central light shielding portion 141 facing the back direction.

  The pin receiving portion 155 is a cylindrical protruding portion having a hole 156 formed therein. The pin receiving portion 155 extends in the back direction from the bottom plate portion 151. The pin receiving portions 155 are provided at four positions of the bottom plate portion 151. Specifically, the pin receiving portions 155 are provided so as to arrange the hole portions 156 at four positions where the circumferential intervals are substantially equal around the rotation axis Ar. The outer circumferential surface of each pin receiving portion 155 is inclined in the inner circumferential direction of each pin receiving portion 155 as it goes back. The inner peripheral surface of each pin receiving portion 155 is inclined in the outer peripheral direction of each pin receiving portion 155 as it goes back. The pin portion 144 is inserted into the hole portion 156.

  In the pointer 100 of the present embodiment, in order to hold the pointer cap 150 on the pointer body 110, the light shielding plate 140 is formed with a recess 146, a projection 147, and a partition 148 as shown in FIG. Further, on the pointer cap 150, a restricting portion 157 and a stopper 158 are formed.

  Recesses 146 are formed on the outer surface of each pin portion 144 as shown in FIGS. 8 and 9. The concave portion 146 is formed in a groove shape extending in the circumferential direction on the outer side surface of each pin portion 144.

  The protruding portion 147 is a portion of the outer side surface of each pin portion 144 in the distal direction than the recessed portion 146. Each protrusion 147 protrudes from the outer surface of each pin 144 relative to the recess 146.

  Partitions 148 are two wall surfaces facing each other at a distance so as to partition slits 149 therebetween. The dividing portion 148 divides the slit 149 along the axial direction of each pin portion 144 into each pin portion 144. Each dividing portion 148 divides each slit 149 from the tip of each pin portion 144 to the root direction more than each protruding portion 147. Specifically, each partition portion 148 partitions each slit 149 further to the back direction than the root end 144 b of each pin portion 144.

  Each slit 149 penetrates the pin portion 144 in the cross section of the pin portion 144. Each pin portion 144 is divided into two pillars each having a semicircular cross section at the positions where the slits 149 are divided by the slits 149. Each slit 149 divides each pin portion 144 into two columns throughout the axial direction. The portion of each pin portion 144 divided by the slit 149 is elastically deformable along the displacement direction. The displacement direction is a direction along the cross section of the pin portion 144, and is a direction orthogonal to the penetrating direction in which the slit 149 penetrates.

  The restricting portion 157 is a convex portion protruding from the inner peripheral surface of each pin receiving portion 155 as shown in FIG. The restricting portion 157 protrudes from a position facing the concave portion 146 in the inner circumferential surface. Each restricting portion 157 is annularly provided along the circumferential direction of each pin receiving portion 155. Each restricting portion 157 is located in the back direction of the projecting portion 147 and restricts the movement of the projecting portion 147 in the root direction. Specifically, each restricting portion 157 is engaged with the recess 146.

  The stopper 158 is a convex portion that protrudes toward the inside of the pin receiving portion 155 and is fitted to the slit 149. The stopper 158 protrudes from the bottom plate portion 151 in the back direction. The stopper 158 has a substantially conical shape with an outer diameter decreasing toward the rear surface direction. The stopper 158 is in contact with the dividing portion 148 in the distal direction than the restricting portion 157. The end portion 158 a in the root direction of the stopper 158 is positioned more distal than the restriction portion 157.

  Next, an example of a method of manufacturing the pointer cap 150 will be described with reference to FIGS. The pointer cap 150 is manufactured by a molding operation and a mold release operation. In the molding operation, as shown in FIG. 10, the pointer cap 150 is molded in the mold by filling the mold constituted by the core 50 on the movable side and the cavity 60 on the fixed side with a resin. In the mold, the inner circumferential surface of the cylindrical wall portion 153 a is in contact with the core 50. In the mold, the outer peripheral surface of the cylindrical wall portion 153 a is in contact with the cavity 60.

  In the mold release operation, the pointer cap 150 molded in the mold is released from the core 50 and the cavity 60. As shown in FIG. 11, by opening the mold and moving the core 50 in the direction away from the cavity 60 along the axial direction of the pointer cap 150, the pointer cap 150 moves along with the core 50 to move out of the cavity 60. Release the mold. As a result, as shown in FIG. 12, the pointer cap 150 can be released from the core 50 by displacing the cylindrical wall portion 153 a and the outer peripheral convex portion 154 in the outer peripheral direction.

  Next, a method of assembling the pointer 100 will be described with reference to FIGS. The pointer 100 is assembled by the main body preparation operation and the holding operation. In the main body preparation work, the diffuser 130 and the light shielding plate 140 are attached to the light guide 120. The pointer body 110 having the pin portion 144 is prepared by the main body preparation operation.

  In the holding operation, the pointer cap 150 is held by the pointer main body 110 prepared in the main body preparation operation. In the holding operation of the present embodiment, the pointer cap 150 is held by the pointer main body 110 in the insertion step. In the insertion step, the pin portion 144 is inserted into the hole portion 156 formed in the pin receiving portion 155. Specifically, the pin portion 144 is inserted so as to move the protrusion 147 in the distal direction of the restricting portion 157. When the projecting portion 147 contacts the restricting portion 157 as shown in FIG. 13, the projecting portion 147 can be displaced inward by elastic deformation of the pin portion 144. The inward direction is a direction along the displacement direction and a direction in which the slit 149 is narrowed. By the inward displacement, as shown in FIG. 14, the projecting portion 147 can move in the distal direction more than the restricting portion 157 by passing the restricting portion 157.

  The protruding portion 147 moved in the distal direction beyond the restricting portion 157 returns outward due to the restoring force of the pin portion 144 and the fitting of the stopper 158 into the slit 149. The outward direction is a direction along the displacement direction and a direction in which the slit 149 is expanded. As shown in FIG. 15, the protruding portion 147 returned outward is in a state in which the movement in the root direction is restricted by the restriction portion 157 located in the root direction.

[Summary of the embodiment]
As described above, according to the embodiment described above, in the columnar pin portion 144, the slit 149 along the axial direction is divided by the dividing portion 148. The slit 149 allows the projection 147 projecting from the outer surface of the pin 144 to be displaced inwardly. Therefore, in the insertion step of inserting the pin portion 144 into the hole portion 156, the projecting portion 147 can move in the distal direction more than the restricting portion 157 through the restricting portion 157 by the inward displacement. The protruding portion 147 moved in the distal direction than the restricting portion 157 returns outward due to the restoring force of the pin portion 144. The protruding portion 147 returned outward is in a state in which the movement in the root direction is restricted by the restriction portion 157 positioned in the root direction. According to the above, after the insertion step, the movement of the pin portion 144 in the root direction can be restricted. As a result, in the holding operation, it is possible to hold the pointer cap 150 on the pointer body 110 without performing a post process. Therefore, the holding operation for holding the pointer cap 150 on the pointer body 110 can be simplified.

  Further, in the present embodiment, the projection portion 147 returned outward is restricted from moving inward by the stopper 158 fitted in the slit 149. As a result, the protrusion 147 is restricted from moving in the root direction passing through the restricting portion 157. Therefore, the pointer cap 150 is more difficult to remove from the pointer body 110.

  Furthermore, in the present embodiment, the end portion 158 a in the root direction of the stopper 158 is positioned more distal than the restricting portion 157. Therefore, the stopper 158 is less likely to prevent the inward movement of the protrusion 147 before the protrusion 147 is moved in the distal direction beyond the restricting portion 157. Therefore, the projecting portion 147 can more easily pass through the restricting portion 157 in the insertion step.

  Also, the slit 149 is partitioned from the tip end 144 a of the pin portion 144. Therefore, the portion divided by the slit 149 of the pin portion 144 has a cantilever shape with the tip end 144a as a free end. As a result, the protrusion 147 is more likely to be displaced inward. Therefore, the protruding portion 147 can more easily pass through the restricting portion 157 in the insertion step.

  In addition, the slit 149 is partitioned to the root direction rather than the protrusion 147. As a result, the projection 147 is more likely to be displaced inward by being supported in a cantilevered state as a whole. Therefore, the projecting portion 147 can more easily pass through the restricting portion 157 in the insertion step.

  Further, in the present embodiment, the pointer cap 150 restricts the movement of the central light shielding part 141 by the outer peripheral convex part 154 in addition to the restriction of the movement of the projecting part 147 by the restricting part 157. Therefore, the pointer cap 150 is more difficult to remove from the pointer body 110.

  Further, the outer peripheral convex portion 154 protrudes from the inner peripheral surface of the cylindrical wall portion 153 a. Therefore, in the cap preparation operation, after the outer peripheral surface of the cylindrical wall portion 153a is released from the cavity 60, the outer peripheral convex portion 154 can be displaced in the outer peripheral direction together with the cylindrical wall portion 153a. As a result, the pointer cap 150 can be easily released from the core 50 by so-called forced removal even if the outer peripheral convex portion 154 is provided. That is, the pointer cap 150 can be easily released from the core 50 even if it is molded using the core 50 which is not provided with the slide core which can be retracted in the inner circumferential direction. Therefore, the outer peripheral convex portion 154 is unlikely to disturb the manufacture of the pointer cap 150.

  In the present embodiment, the pointer body 110 corresponds to the "first member", and the pointer cap 150 corresponds to the "second member".

Other Embodiments
The embodiment of the present disclosure has been described above, but the present disclosure is not limited to the above-described embodiment, and the following modifications are also included in the technical scope of the present disclosure. Various modifications can be made without departing from the scope of the invention. In the following description, elements having the same reference numerals as the codes used so far are the same as the elements having the same reference numerals in the previous embodiments, unless otherwise specified. In addition, when only a part of the configuration is described, the embodiment described above can be applied to other parts of the configuration.

  In the first modification of the above-described embodiment, as shown in FIGS. 16 and 17, the pin portion 144 is formed on the light guide 120 in the pointer main body. Also in the first modification, the holding operation can be simplified. Further, in the pointer cap 150 in the modified example 1, in place of two of the pin receiving portions 155 provided in four places, columnar positioning pins extending in the back direction are provided. The positioning pin is held by the pointer main body 110 by being press-fit into a through hole formed in the light guide 120 and the light shielding plate 140.

  In the second modification related to the above-described embodiment, the pin receiving portion 155 in which the hole portion 156 is formed is provided in the light shielding plate 140 included in the pointer main body 110. Also, the pin portion 144 is provided on the pointer cap 150. Also in the second modification, the holding operation can be simplified. In the second modification, the pointer body 110 corresponds to the "second member", and the pointer cap 150 corresponds to the "first member".

  In the third modification of the above-described embodiment, the pin portion 144 is not formed with the recess 146, and is provided with a protrusion 147 that protrudes from the outer side surface. The pin receiving portion 155 is formed with a concave portion on the inner circumferential surface in which the projecting portion 147 is fitted. The restricting portion 157 in the third modification is a portion of the inner peripheral surface of the pin receiving portion 155 in the root direction rather than the concave portion. Also in the third modification, the movement of the protrusion 147 in the root direction is restricted by the restriction portion 157 located in the root direction.

  In the above-described embodiment, the slit 149 is divided all over the axial direction of the pin portion 144. However, the sectioned range of the slit 149 in the axial direction of the pin portion 144 can be changed as appropriate.

  In the above-described embodiment, the cross-sectional shapes of the pin portion 144, the hole portion 156, and the stopper 158 are each circular. However, the cross-sectional shapes of the pin portion 144, the hole portion 156, and the stopper 158 may be shapes other than circular such as rectangular. Further, in the above embodiment, the stopper 158 protrudes from the bottom plate portion 151. However, the stopper 158 may protrude from the inner circumferential surface of the pin receiving portion 155.

  In the above embodiment, the pin portion 144 is divided into two by the slit 149 in the cross section. However, the pin portion 144 may be divided into three or more.

  In the above-mentioned embodiment, display 1 which uses pointer 100 was a combination meter used by vehicles. However, the display device 1 using the pointer 100 may be an instrument used on a ship or the like, or a pointer display device used on a home appliance or the like.

1: Display device, 40: Display board, 100: pointer, 110: pointer body (first member), 144: pin, 144a: tip, 147: protrusion, 148: partition, 149: slit, 150: pointer Cap (second member), 156: hole portion, 157: restricting portion, 158: stopper, 158a: end portion

Claims (6)

A pointer (100) used in the display device (1),
A pointer body (110),
And a pointer cap (150) held by the pointer body,
The first member (110), which is either one of the pointer body and the pointer cap,
Columnar pin (144),
A protruding portion (147) protruding from the outer side surface of the pin portion;
And a dividing section (148) for dividing the slit (149) along the axial direction of the pin section into the pin section;
The second member (150), which is the other of the pointer body and the pointer cap,
A hole (156) through which the pin is inserted;
A pointer provided with a restricting portion (157) positioned in the root direction of the pin portion relative to the protrusion and restricting the movement of the protrusion in the root direction.   The pointer according to claim 1, wherein the second member has a stopper (158) fitted to the slit.   The pointer according to claim 2, wherein the end (158a) in the root direction of the stopper is located in the tip direction of the pin portion relative to the restriction portion.   The pointer according to any one of claims 1 to 3, wherein the dividing portion divides the slit from a tip end (144a) of the pin portion.   The pointer according to claim 4, wherein the partition divides the slit in the direction of the root more than the protrusion. The guideline according to any one of claims 1 to 5;
And a display board (40) indicated by the pointer.

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