JP4571453B2 - Shift lever device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shift lever device capable of clearly checking the shift pattern, the shift position or the like provided at a knob without the knob being made large. <P>SOLUTION: In the shift lever device, a lamp 144 which is a light source is not arranged inside the knob 90, and the light is guided to an indicator lens 112 by light guides 98 and 146. The structure of the knob 90 can be simplified thereby, and the knob 90 can be miniaturized. In addition, because the light guide 98 is a part of the structure of the knob 90, the structure of the knob 90 can be simplified. <P>COPYRIGHT: (C)2005,JPO&amp;NCIPI

Description

  The present invention relates to a shift lever device for operating a transmission of a vehicle.

  An operating device for operating the automatic transmission of the vehicle from the vehicle interior side to change the shift range set in the automatic transmission is provided with a rod-shaped shift lever, which is automatically operated by turning the shift lever. A shift lever device for operating a transmission is generally used.

  In this type of shift lever device, for example, in addition to a so-called straight-type shift lever device that performs a turning operation (linearly in a plan view) only around the axis with the vehicle lateral direction as an axial direction, There is a so-called gate-type shift lever device in which the shift lever is turned in a zigzag manner around the respective axes in the vehicle left-right direction and the vehicle front-rear direction.

  In these shift lever devices, a shift pattern that is a pattern of a rotation operation of the shift lever is set in advance. In addition, when a plurality of shift positions are set within the range of this shift pattern and the shift lever is operated to shift to the shift position corresponding to the desired shift range, the shift range of the automatic transmission changes to the shift range corresponding to the shift position. The configuration is changed to

On the other hand, a structure has been devised in which the above shift pattern and shift position are displayed on, for example, a knob of a shift lever, thereby making it easy to check the shift pattern and shift position. Furthermore, the following Patent Documents 1 and 2 disclose a structure in which a knob and an illumination means such as an LED are provided on the knob, and a shift pattern or shift displayed on the knob by causing the illumination means to emit light. This makes it easier to check the position.
Japanese Patent Laid-Open No. 61-50835 JP 62-84809 A

  However, as in the structures disclosed in Patent Documents 1 and 2 above, providing the lighting means such as a lamp or LED on the knob of the shift lever complicates the internal structure of the knob, resulting in a large knob. It will become.

  An object of the present invention is to obtain a shift lever device that can clearly see a shift pattern, a shift position, and the like provided on the knob without enlarging the knob in consideration of the above fact.

According to a first aspect of the present invention, there is provided a shift lever device comprising: a lever main body whose base end side is directly or indirectly connected to a transmission having a plurality of shift ranges and whose front end side protrudes toward the vehicle interior side; A shift lever device that shifts the transmission to a shift range corresponding to the shift position by shifting the predetermined direction to reach a predetermined shift position, wherein the lever is operable to perform the shift operation. A light source provided directly or indirectly on either the housing that directly or indirectly supports the main body or the lever main body, and the lever main body that can be gripped by the vehicle occupant, allowing light to pass through. a knob to transmit light of light guided to the inside to the outside from the Do transmitting unit, before Symbol knob setting vignetting, the interior of the knob emitted light is transmitted through the interior by the light source Has a light guiding means for guiding the further comprises a fixing portion fixed to the distal end of the lever body, and a light shielding portion having a light shielding property formed in a cylindrical shape covering the outer side of the fixed portion, the fixed inward The light shielding part is mounted so that the distal end side of the lever main body enters inside and the base end side is exposed to the outside from the intermediate part along the longitudinal direction of the lever main body to cover the light shielding part. In addition, the knob main body constituting the light guiding means capable of transmitting the light emitted from the light source on the inner side, and the outer peripheral portion of the fixed portion and the inner peripheral portion of the light shielding portion are integrally connected. In addition, the knob is configured to include a connecting piece that passes through the knob body and restricts relative rotation of the knob body with respect to the light-shielding portion whose axial direction is the longitudinal direction of the lever body .

  According to the shift lever device of the present invention as set forth in claim 1, the vehicle occupant grips the knob attached to the tip of the lever main body and moves the lever main body in a predetermined shift operation direction. When the lever main body reaches the shift position, the transmission is changed to a shift range corresponding to the shift position.

Further, the shift lever device according to the present invention is provided with a light source, and light emitted from the light source is transmitted through the inside of the knob body , which is grasped as one mode of the light guiding means covered by the light shielding portion in the knob. To do. The light that has passed through the inside of the knob body is guided to the inside of the knob, is further transmitted through a transmission portion provided in the knob, and is emitted to the outside of the knob. Thereby, the front-end | tip of the shift lever comprised including a lever main body and a knob light-emits.

  Therefore, for example, if a transmission part is provided at the tip of the shift lever and further an operation pattern for shift operation is formed in the transmission part, light is transmitted through the transmission part and the tip of the shift lever emits light. Even if the vehicle interior is dark, the operation pattern formed in the transmission part can be clearly recognized.

Here, in the shift lever device according to the present invention, the light source is provided in the lever main body or the housing that directly or indirectly supports the lever main body. That is, in the shift lever device according to the present invention, the light source is provided in a part different from the knob, and light emitted from a part different from the knob is guided through the inside of the light guiding means, so that the knob The light is transmitted through the transmission part. Thus, by not providing the knob with a light source, the knob can be downsized and the knob structure can be simplified.
In addition, the knob main body is configured as a light guiding means, and light is guided to the knob main body so as to pass through the knob main body and reach the transmitting portion. There is no need to provide a separate light guiding means, the cost can be reduced, and the knob can be downsized. Light passes through the knob body itself, but the surface of the knob body is provided with a light-shielding part that has light-shielding properties, so that when viewed from the outside of the knob, the knob is basically located at a part other than the transmission part. There is no light emission.
Furthermore, the connecting piece that integrally connects the outer peripheral part of the fixed part and the inner peripheral part of the light shielding part passes through the knob main body, whereby the knob main body with respect to the light shielding part with the longitudinal direction of the lever main body as the axial direction. Relative rotation is restricted.
In the present invention, the light shielding part may be configured to shield light leaking from the outer surface of the knob body. Therefore, for example, the knob body formed of a light-transmitting synthetic resin material may be covered with a light shielding portion formed of a synthetic resin material of a color that does not transmit light. A configuration in which the outer surface of the knob body formed of a resin material is painted, printed, or the like, thereby forming a light shielding portion.

In addition, the shift lever device has various structures such as a structure in which the shift lever stays at the shift position after the shift operation and a structure in which the shift lever that has been shifted to the desired shift position returns to the preset operation start position. However, the present invention is not limited to a specific mode of such a shift operation. That is, in order to select the shift range, the behavior of the shift lever is not limited at all as long as the shift range can be changed by shifting the shift lever to reach the desired shift position.

  A shift lever device according to a second aspect of the present invention is the shift lever device according to the first aspect of the present invention, wherein the lever main body reaches the inside of the knob when the lever main body reaches at least one specific shift position set in advance. It is characterized by comprising light guiding control means for guiding the light and stopping the guiding of the light to the knob when the lever body is located at a position other than the specific shift position within the range of the shift operation. .

  In the shift lever device according to the second aspect of the present invention, the shift position is set corresponding to each of the plurality of shift ranges set in the transmission. When the lever main body (shift lever) reaches at least one specific shift position among these shift positions, the light emitted from the light source passes through the light guiding means and is guided into the knob. Therefore, in this state, the tip of the knob (that is, the tip of the shift lever) emits light. For this reason, if the operation pattern of shift operation is formed in the permeation | transmission part, an operation pattern can be confirmed (visually) easily.

  On the other hand, when the lever main body (shift lever) is shifted and the lever main body is detached from such a specific shift position, the light guiding control means stops guiding the light into the knob. Therefore, in this state, the tip of the knob does not emit light. Thus, even if the operation pattern of the shift operation is formed on the transmission part or the like because the tip of the knob does not emit light when the lever body is detached from the specific shift position, such an operation pattern It is possible to confirm that the lever main body has been detached from the specific shift position without gazing at.

  In the present invention, the specific shift position may be all of the plurality of predetermined shift positions corresponding to each of the plurality of shift ranges set in the transmission, or any one of the plurality of predetermined shift positions. It may be.

  Further, in the present invention, the light guiding control means can guide light to the inside of the knob when the lever main body reaches a specific shift position as a result, and when the lever main body is detached from the specific shift position, What is necessary is just to be able to stop the guidance of light to. Therefore, a light blocking member for blocking light on the light source side from the inside of the knob and releasing the blocking may be used as the light guide control means, or an electric control circuit for controlling light emission of the light source may be used as the light guide control means. It is good.

  A shift lever device according to a third aspect of the present invention is the shift lever device according to the second aspect of the present invention, wherein the light emitted from the light source reaches a predetermined path on the optical path until the light reaches the transmission part. A reciprocating movement is provided between a light shielding position and a position away from the light shielding position. The light is shielded when the light is moved to the light shielding position, and the light shielding is performed in conjunction with the shift operation to the specific shift position. The light guide control means is a shutter member that is disengaged from the position.

  In the shift lever device according to the third aspect of the present invention, the shutter member is provided at a predetermined light shielding position on the optical path until the light emitted from the light source reaches the transmission part. In a state where the lever main body has reached a specific shift position, even if light is emitted from the light source, the shutter member blocks light at the light shielding position. For this reason, basically, light does not reach the inside of the knob, and the tip of the knob does not emit light.

  On the other hand, when the lever body is shifted and separated from the specific shift position, the shutter member is detached from the light shielding position in conjunction with the shift operation. Thereby, the light shielding (light blocking) by the shutter member is released, and the light emitted from the light source reaches the inside of the knob via the light guiding means. Therefore, in this state, the tip of the knob emits light due to the light reaching the inside of the knob.

  Further, from this state, when the lever main body is shifted and the lever main body reaches a specific shift position, the shutter member moves to the light shielding position in conjunction with the shift operation. Thereby, the light is blocked again.

  As described above, in the shift lever device according to the present invention, the shutter member is mechanically interlocked with the shift operation of the lever main body, whereby the light shielding and the light shielding cancellation are performed. For this reason, light emission at the tip of the knob can be controlled without performing light emission control of the light source in conjunction with the shift operation.

A shift lever device according to a fourth aspect of the present invention is the shift lever device according to any one of the first to third aspects, wherein at least a part of the outer surface of the knob body is exposed to the outside. The light source is disposed in the vicinity of the outer surface exposed to the outside and outside the lever body, and the light from the light source is incident from the outer surface exposed to the outside.

In the shift lever device according to the fourth aspect of the present invention, at least a part of the outer surface of the knob body is exposed to the outside. A light source is disposed near the exposed portion and outside the lever body, and light from the light source passes outside the lever body and is incident on the exposed outer surface. Thereby, light permeate | transmits a knob main body and reaches | attains a permeation | transmission part.

The shift lever device according to the present invention according to claim 5, in the present invention according to claim 4, before Symbol shielding portion, the connecting piece, and to integrally form the fixing portion of the same synthetic resin material, that It is a feature.

In the shift lever device according to the fifth aspect of the present invention, the light shielding portion, the connecting piece, and the fixing portion are integrally formed of the same synthetic resin material. For this reason, the number of parts can be reduced and the cost can be reduced.

A shift lever device according to a sixth aspect of the present invention is the shift lever device according to the fifth aspect of the present invention, wherein any one of the light shielding portion and the knob main body is preliminarily molded, and any one of the light shielding portion and the knob main body is formed. One of the other is molded in a state where either one is inserted into a mold for molding the other.

In the shift lever device according to the sixth aspect of the present invention, one of the light shielding portion and the knob body is formed in advance. Next, when either one of the light-shielding portion and the knob body is molded, one of the above-described preforms is inserted into a mold for molding the other. In this state, when the mold is closed and either one is molded, the other is integrated with either the light shielding portion or the knob body.

  For this reason, an assembly process can be omitted compared with the case where the knob main body is constructed by an independent part different from the light shielding portion and assembled, and thus the cost can be reduced.

  In addition, since the shift lever device according to the present invention is configured to be insert-molded as described above, if the knob main body and the light-shielding portion are configured separately and assembled, either the light-shielding portion or the knob main body is assembled. It is possible to adopt a structure or shape in which part of either one interferes with either one and cannot be assembled.

  For this reason, the knob main body can be formed into a structure and shape that are optimal for taking in and guiding light, as well as irradiation with the guided light.

A shift lever device according to a seventh aspect of the present invention is the shift lever device according to the sixth aspect of the present invention, wherein the shift lever device has a cylindrical shape that opens toward the base end side of the knob when the knob is attached to the lever body. The fixing portion is formed, and the tip of the lever main body enters from the opening end of the fixing portion, whereby the fixing portion is fixed to the lever main body, and the end surface of the fixing portion on the side facing the transmitting portion is fixed. The knob main body covers at least a part.

In the shift lever device according to the seventh aspect of the present invention, the fixing portion is formed in a cylindrical shape, and the tip of the lever main body enters the inside of the fixing portion from the opening end of the fixing portion, thereby the tip of the lever main body. The fixing portion is fixed, whereby the knob is attached to the lever body.

  On the other hand, the end of the fixed part on the side facing the transmission part is covered with the knob body. Here, in the case of a structure in which the knob main body is configured by being assembled with an independent part different from the light shielding portion, the light shielding portion is cylindrical, so that the mounting direction of the knob body with respect to the light shielding portion is along the axial direction of the fixed portion. The possibility of becoming a structure is very high.

  In such assembling, when the knob body faces the axial end of the fixed portion, the knob body interferes with the tip of the lever body and cannot be assembled. Therefore, in the case of such assembling, the knob main body cannot be covered with the axial end portion of the fixed portion so as to be covered.

  On the other hand, in the shift lever device according to the present invention, the pre-molded one of the light shielding part and the knob body is placed in the mold so that it is integrated with the light shielding part by filling the synthetic resin material. Since it is the structure which shape | molds a knob main body, at least one part of the axial direction edge part of a fixing | fixed part can be coat | covered with a knob main body. Thereby, the area of the part which takes in light and the area which irradiates the induced | guided | derived light can be enlarged, light can be guided efficiently, and when it sees from the front-end | tip of a knob, light can be irradiated comparatively uniformly.

The shift lever device according to the present invention described in claim 8 is the shift lever device according to any one of claims 5 to 7 , wherein an internal thread is formed on an inner peripheral portion of the fixed portion, and the lever A male screw is formed on the outer peripheral portion on the distal end side of the main body, and the male screw is screwed to the female screw to fix the fixing portion to the lever main body.

In the shift lever device according to the eighth aspect of the present invention, the fixing portion is fixed to the lever main body by the male screw formed on the distal end side of the lever main body being screwed to the female screw formed on the fixing portion. As a result, the knob is attached to the lever body.

  Here, the shift lever device according to the present invention has a configuration in which a female screw is formed on a fixed portion made of the same material as the light shielding portion having light shielding properties. For this reason, it is sufficient that the mechanical strength necessary for screwing the female screw with the male screw has only the material constituting the fixing portion, that is, the material constituting the light shielding portion, and the knob body has such strength. Is not required. For this reason, the knob main body can be formed of a material having good light transmittance.

A shift lever device according to a ninth aspect of the present invention is the shift lever device according to the first or second aspect , wherein the lever main body is formed in a cylindrical shape penetrating from the proximal end portion toward the distal end portion. The light guiding means is allowed to pass through the inside of the lever main body, and the light output from the light source provided on the side of the base end portion of the lever main body is transmitted to the distal end side of the lever main body by the light guiding means. It is characterized by that.

In the shift lever device according to the ninth aspect of the present invention, the lever main body is formed in a cylindrical shape, and the light guiding means passes through the inside of the lever main body. The light source is provided on the side of the base end side of the lever main body, and the light emitted from the light source is condensed on the end of the light guiding means on the base end side of the lever main body.

  The light collected at the end of the light guiding means on the base end side of the lever body passes through the inside of the light guiding means and is guided into the knob from the end of the light guiding means on the tip side of the lever body.

  Thus, in the shift lever device according to the present invention, since the light guiding means passes through the inside of the lever main body, the light source is provided by the housing or the like on the base end side of the lever main body where the light collecting portion of the light guiding means is located. Covered. Thereby, the light leakage from the clearance etc. of a housing can be prevented effectively.

The shift lever device according to the present invention according to claim 1 0, characterized in the present invention as set forth in claim 9, said light source to said lever body at the base end side of the lever body mounted integrally, that It is said.

In the shift lever device according to the present invention according to claim 1 0, the light source is integrally attached to the lever body at the base end side of the lever body. For this reason, when the lever main body is shifted, the light source moves together with the lever main body and the light guiding means.

  That is, in the shift lever device according to the present invention, even when the lever main body is shifted, relative movement occurs between the light guide means end (that is, the condensing portion) and the light source on the base end side of the lever main body. Absent. Thus, even when a shift operation is performed, the end of the light guiding means on the base end side of the lever main body and the light source can be kept opposite to each other, and it is possible to prevent or effectively prevent the light emission state of the knob from being changed by the shift operation. Can be suppressed.

Shift lever device according to the present invention as set forth in claim 1 1, in the present invention as set forth in claim 9, the ends of the light guiding means in the condenser surface and the base end side of the lever body which faces the light source The light from the light source condensed on the light emitting surface is interposed between the light source and the light guide surface on the base end side of the lever body. The light emitting surface emits light from the light emitting surface, and the surface shape of either the light collecting surface or the light emitting surface is the base of the lever main body in any of the plurality of shift positions. It is characterized by comprising condensing means set so as to be able to face one of the end portion of the light guiding means on the end side and the light source corresponding to one of the surfaces.

In the shift lever device according to the present invention as set forth in claim 1 1, between the end and the light source of the light guiding means at the proximal end side of the lever body is interposed condensing means. The light from the light source is condensed on the condensing surface of the condensing means facing the light source. The light condensed on the light collecting surface passes through the inside of the light collecting means.

  When the light passes through the light collecting means and reaches the light emitting surface of the light collecting means, the light emitting surface emits light. Since the light emitting surface faces the end of the light guiding means on the base end side of the lever body, when the light emitting surface emits light, the light is collected at the end of the light guiding means on the base end side of the lever body. Thus, the light is transmitted through the light guiding means and guided to the knob.

  Here, one of the light emitting surface and the light collecting surface faces the corresponding one of the end of the light guiding means and the light source on the base end side of the lever body, regardless of the shift position of the lever body. The surface shape is set as follows. For this reason, even if a lever main body is shifted, the confronting state of the condensing surface, the light source, the end of the light guiding means, and the light emitting surface is maintained.

  Thereby, it can prevent or suppress effectively that the state of the light emission in a knob changes by shift operation.

  As described above, in the shift lever device according to the present invention, light is guided from the light source provided outside the knob to the inside of the knob, so that it is not necessary to provide illumination means such as a light bulb or LED inside the knob. Light can be emitted from the inside of the knob. Thereby, the shift pattern and the shift position can be easily confirmed without complicating the structure of the knob or increasing the size of the knob.

<Configuration of First Embodiment>
FIG. 3 shows an exploded perspective view of the structure of the shift lever device 10 according to the first embodiment of the present invention, and FIG. 1 shows an exploded perspective view of the structure of the main part of the shift lever device 10. It is shown by the figure. As shown in FIG. 3, the shift lever device 10 includes a lower housing 14 constituting a housing 12. The lower housing 14 is provided, for example, at a predetermined position on the front side between the driver's seat and the front passenger seat of the vehicle, for example, below the front side of the console box or on the back side of the instrument panel. Yes.

  The lower housing 14 is formed in a cylindrical shape having a substantially rectangular cross section including a pair of side walls 16 facing each other substantially along the vehicle left-right direction and a pair of side walls 18 facing each other substantially along the vehicle front-rear direction. . The upper open end of the lower housing 14 in FIG. 3 is closed by the upper housing 20. The upper surface of the upper housing 20 is exposed to the vehicle interior side, and the upper housing 20 closes the opening end of the lower housing 14 to conceal various members inside the lower housing 14 and Intrusion is prevented or suppressed.

  A lever main body 24 that constitutes the shift lever 22 is provided inside the lower housing 14. The lever body 24 includes a retainer 26. The retainer 26 is formed in an inverted triangular shape with the lower end being the top in a front view. The upper end portion is formed with a substantially cylindrical tube portion 28 penetrating along the opposing direction of the side wall 16.

  The cylindrical portion 28 is connected substantially integrally with a shaft 30 extending in the axial direction along the opposing direction of the side wall 16. The shaft 30 penetrates the side walls 16 at both axial ends, and is supported by the side walls 16. Thereby, the retainer 26 and the shaft 30 are pivotally supported around the axis of the shaft 30 so as to be rotatable.

  A sensor arm 32 is integrally fixed to one axial end of the shaft 30 with a screw or the like. The sensor arm 32 is formed with a pair of pressing pieces 34 having a thickness direction along the rotational circumferential direction of the shaft 30. These pressing pieces 34 enter the inside of a sensor case 35 that is integrally attached to the side wall 16 that supports the end of the shaft 30 on the side where the sensor arm 32 is provided.

  Inside the sensor case 35, there are one or more Hall IC elements as magnetic sensors constituting position detection means (shift direction position detection means), and one or more magnets (position detection means together with the Hall IC elements). All of the unsigned ones are not shown). The magnet accommodated in the sensor case 35 is directly or indirectly engaged with the pressing piece 34, and when the pressing piece 34 presses the magnet as the shaft 30 rotates about its axis, The magnet is moved by the pressing force from the pressing piece 34.

  When the Hall IC element accommodated in the sensor case 35 detects the magnetic fluctuation caused by the movement of the magnet, a signal from the Hall IC element is input to the ECU on the PC board 62 described later, and the ECU As a result, it is detected that the retainer 26 has rotated around the axis of the shaft 30.

  The lever body 24 includes a body 36. The body 36 includes a block-like base 38. A pair of leg plates 40 extend from the lower end of the base 38. Both leg plates 40 are formed so as to be in the thickness direction along the facing direction of the side wall 18 and to face each other along the facing direction of the side wall 18.

  The distance between the leg plates 40 is slightly larger than the thickness dimension of the retainer 26 described above, and the retainer 26 is disposed between the leg plates 40. At the lower end portions of these leg plates 40, through holes 42 penetrating along the thickness direction of the respective leg plates 40 are formed. Corresponding to these through holes 42, through holes 44 are formed in the lower end portion of the retainer 26. A shaft 46 is formed in the through hole 42, 44 in the axial direction along the opposing direction of the side wall 18, and the body 36 can rotate relative to the retainer 26 around the axis of the shaft 46. Is pivotally supported.

  Further, a sensor case 48 is disposed inside the lower housing 14 and on the side opposite to the other of the one leg plate 40. A shaft 50 is formed at the upper end of the sensor case 48 so as to protrude toward the body 36, and a sensor link 52 is pivotally supported so as to be rotatable about an axis whose axial direction is the opposite direction of the side wall 18.

  An engagement protrusion 54 is formed on one leg plate 40 so as to protrude toward the sensor case 48 in correspondence with the sensor link 52. The engaging protrusion 54 is mechanically connected to the sensor link 52, and when the body 36 rotates around the shaft 46, the engaging protrusion 54 presses the sensor link 52 and rotates around the shaft 50.

  A slider 56 is disposed on the side opposite to the sensor case 48 via the sensor link 52. The slider 56 is held in the sensor case 48 so as to be slidable along the opposing direction of the side wall 16, and an engagement pin (not shown) protruding from the slider 56 passes through the sensor case 48 and rotates the sensor link 52. It engages in the state which entered the long hole 58 formed in the radial direction front end side.

  The slider 56 slides in the opposite direction of the side wall 16 when the engagement pin is pressed against the inner wall of the long hole 58 when the sensor link 52 rotates around the axis of the shaft 50. Further, a magnet (permanent magnet) 60 constituting a position detecting means (select direction position detecting means) is fixed to the slider 56. The magnet 60 is, for example, an Sr ferrite magnet, and forms a predetermined magnetic field around it. Further, since the magnet 60 is fixed to the slider 56, the magnet 60 slides integrally with the slider 56. Therefore, when the magnet 60 slides in this way, the magnetic field formed around the magnet 60 also slides.

  Further, a PC board 62 is attached to the sensor case 48 on the opposite side of the sensor case 48 via the slider 56. On the PC board 62, a pair of Hall IC elements 64 and 66 (not shown in FIG. 3, refer to FIG. 4) connected to an ECU (not shown) are arranged side by side in the opposite direction of the side wall 16. These Hall IC elements 64 and 66 detect fluctuations in the magnetic field formed by the magnet 60 (more specifically, changes in the strength of magnetism passing through the Hall elements constituting the Hall IC elements 64 and 66), An electric signal corresponding to the fluctuation of the magnetic field is output.

  On the other hand, as shown in FIG. 3, a bottomed circular hole 78 is formed on the upper surface of the base portion 38 of the body 36, and the base end portion of the rod-shaped lever member 80 constituting the shift lever 22 is inserted. It is fixed integrally. The lever member 80 passes through a shift hole 82 formed in the upper housing 20 at an intermediate portion in the longitudinal direction. The shift hole 82 has a longitudinal hole 82A that is elongated in a predetermined direction and a horizontal hole 82B that is elongated in a direction intersecting (for example, orthogonal to) the longitudinal direction of the longitudinal hole 82A. It is formed in a substantially “h” shape. The lever member 80 passes through the shift hole 82, and the tip side thereof extends to the outside of the upper housing 20. Further, a knob 90 is attached to the lever member 80 extending to the outside of the upper housing 20.

  As shown in FIGS. 2 to 5, the knob 90 includes a knob body 92 as light guiding means. The knob main body 92 includes a base portion 94 formed of a synthetic resin material that is substantially transparent or colored to the extent that light can be transmitted, such as acrylic resin (PMMA: polymethyl methacrylate or methacrylic resin). A through hole 96 is formed in the base portion 94, and the distal end side of the lever member 80 is inserted. A light guide 98 made of a synthetic resin material that is substantially transparent or colored to the extent that light can be transmitted is formed on the upper surface of the base 94.

  As shown in FIG. 2, the light guide 98 is basically formed in a cylindrical shape substantially coaxial with the through hole 96. The light guide 98 has three slits 100 formed around the axial center of the through hole 96 at predetermined angles. These slits 100 are opened at the inner peripheral portion, the outer peripheral portion, and the upper end portion of the light guide 98. By forming these slits 100, the light guide 98 substantially becomes the axis of the through hole 96. It is divided into three around.

  As shown in FIG. 5, the end surface of the base 94 opposite to the light guide 98 is a daylighting surface 101, and when the daylighting surface 101 is irradiated with light, the knob main body 92 extends from the daylighting surface 101. Light is taken in.

  As shown in FIGS. 2 and 5, the knob 90 includes a knob body 102 as a covering portion. The knob body 102 includes an outer cylinder portion 103 formed in a substantially cylindrical shape by a synthetic resin material such as nylon resin (PA) colored to the extent that light is not transmitted. The inner peripheral shape of the outer cylindrical portion 103 corresponds to the outer peripheral shape of the light guide 98, and the light guide 98 is inserted into the outer cylindrical portion 103 from above the knob body 92 so that the outer cylindrical portion 103 is inserted into the light guide. As a result, the outer peripheral portion of the light guide 98 is covered with the outer tube portion 103.

  Further, inside the outer cylinder portion 103, there is provided a female screw portion 104 formed of a metal in a substantially cylindrical shape and having an inner screw 104A formed on the inner peripheral portion. A plurality of connecting pieces 106 are provided around the axis of the female screw portion 104 at predetermined angles between the outer peripheral portion of the female screw portion 104 and the inner peripheral portion of the knob body 102, and the knob body 102 and the female screw are connected by the connecting piece 106. The part 104 is integrally connected. The connecting piece 106 has a thickness direction along the direction around the axis of the female screw portion 104, and the thickness dimension is slightly smaller than the inner width dimension of the slit 100.

  Further, these connecting pieces 106 are formed so as to correspond to the slits 100, and when the light guide 98 is inserted inside the outer tube portion 103, the female screw portion 104 is coaxially inserted inside the light guide 98. At the same time, the connecting piece 106 corresponding to each slit 100 enters. Thereby, the relative displacement of the knob body 102 with respect to the knob main body 92 along the direction around the axis of the light guide 98 and the female thread portion 104 is restricted.

  With the knob body 102 mounted on the knob body 92 as described above, the lever member 80 is inserted from below the base portion 94 of the knob body 92, and the male screw 80 </ b> A formed at the tip of the lever member 80 is the female screw of the female screw portion 104. The knob 90 is coupled to the lever member 80 by being screwed to 104A.

  On the other hand, a cap 107 is provided above the female screw portion 104. The cap 107 includes a guide lens 108 as a transmission part. The guide lens 108 is formed of a synthetic resin material that is substantially transparent or colored to the extent that light can be transmitted in the same manner as the light guide 98 described above, and is disposed inside the outer cylinder portion 103. The outer peripheral shape of the guide lens 108 corresponds to the outer peripheral shape of the outer cylindrical portion 103 (knob body 102), and the guide lens 108 is formed in the outer cylindrical portion 103 by the adhesive applied to the outer peripheral portion of the guide lens 108. It is integrally fixed to the periphery.

  Further, an indicator plate 110 as a transmission part is provided on the guide lens 108. The indicator plate 110 is basically formed of a substantially transparent plate material, and a shift range corresponding to the shape of the shift hole 82 formed in the upper housing 20 and a shift range on the side of the shift pattern portion. Except for the mark part which means, it is colored with a color that does not transmit light. Accordingly, even when light is uniformly irradiated from the lower side of the indicator plate 110, only the portions of the shift pattern portion and the mark portion transmit light.

  Further, an indicator lens 112 as a transmission part is provided on the indicator plate 110. Like the guide lens 108, the indicator lens 112 is formed of a synthetic resin material that is substantially transparent or colored to the extent that light can be transmitted. Although the outer peripheral shape of the indicator lens 112 is substantially similar to the indicator plate 110, it is slightly larger than the indicator plate 110, and the outer peripheral shape of the indicator lens 112 is substantially the same as the outer peripheral shape at the upper end of the knob body 102. It has become.

  The indicator lens 112, the indicator plate 110, and the guide lens 108 are integrally formed by in-mold molding, and the lower surface (the surface on the indicator plate 110 side) of the indicator lens 112 positioned outside the outer peripheral portion of the indicator plate 110. The knob body 102 is integrally fixed to the upper end portion by an adhesive applied to the knob body 102.

  On the other hand, as shown in FIG. 3, on the side of the lever member 80, a cylindrical pin accommodating portion 120 is formed on the base portion 38 of the body 36. The pin accommodating portion 120 is open at the upper end of FIG. 3, and the compression coil spring 122 and the pin 124 are accommodated therein. As shown in FIGS. 1 and 3, a gate member 126 is disposed inside the lower housing 14 and on the back side of the upper housing 20. A return groove (not shown) is formed on the back surface of the gate member 126.

  The return groove is a bottomed groove having an upper bottom, and has substantially the same “reverse h” shape as the shift hole 82 in plan view (back view). The upper end of the pin 124 enters the return groove with the compression coil spring 122 compressed from above, and is pressed against the upper bottom of the return groove by the urging force of the compression coil spring 122. Further, the upper bottom of the return groove is appropriately inclined, and the same position as the return position in the return groove returns most when the lever body 24 is positioned at the return position S in the shift hole 82 shown in FIG. The groove is deep.

  As shown in FIG. 1, the gate member 126 has a shift hole 128 having substantially the same shape as the shift hole 82, and the lever member 80 passes therethrough. Further, the gate member 126 is provided with a pair of gate plates 130. The gate plates 130 are respectively provided on both ends of the gate member 126 along the opposing direction of the side wall 18, and are formed on the upper surface of the gate member 126 so that a predetermined gap is formed between the gate plate 130 and the upper surface of the gate member 126. The gate member 126 is integrally formed in a state of being separated from the gate member 126.

  A cover plate 132 is disposed on the upper surface of the gate member 126. The cover plate 132 is formed in a substantially rectangular shape in plan view, and both end sides of the cover plate 132 along the facing direction of the side wall 18 enter between the upper surface of the gate member 126 and the gate plate 130. As a result, the cover plate 132 is basically restricted in displacement other than sliding in the direction along the opposing direction of the side wall 16.

  Further, a long hole 134 is formed in the cover plate 132 corresponding to the shift hole 128 of the gate member 126 described above, and the lever member 80 passes therethrough. When the retainer 26 and the body 36 rotate around the axis of the shaft 30, the lever member 80 moves inside the long hole 134 along the longitudinal direction of the long hole 134.

  On the other hand, when the body 36 rotates around the axis of the shaft 46, the lever member 80 presses the inner peripheral portion of the elongated hole 134 to press the cover plate 132, and the cover plate 132 is moved along the direction in which the side wall 16 faces. And slide.

  Further, a substantially triangular or substantially fan-shaped cover plate 136 is disposed on the back surface of the cover plate 132 (between the cover plate 132 and the upper surface of the gate member 126). In the cover plate 136, a pin (not shown) protruding from the back surface of the cover plate 132 is fitted into a through hole 138 formed in the corner portion thereof. A cover plate 136 is rotatably supported around an axis whose thickness direction is an axial direction.

  A circular hole 140 is formed in the cover plate 136. The circular hole 140 is formed to correspond to the long hole 134 and the shift hole 128 described above, and the lever member 80 passes therethrough.

  Further, a lamp house 142 is formed in the upper housing 20 described above, and a lamp (bulb) 144 that is turned on when energized is housed inside the lamp house 142. In addition, inside the lamp house 142, a light guide 146 having a square bar shape appropriately bent is housed. A part of the light guide 146 is opposed to the lamp 144, and one end face of the light guide 146 extends in the longitudinal direction along the direction inclined with respect to the longitudinal direction of the lever member 80. Turn to the bottom.

  A shutter 148 as a light control means and a shutter member is formed on the upper surface of the cover plate 132 corresponding to the lamp 144 and the light guide 146. The shutter 148 includes side walls 150 facing each other along the facing direction of the side walls 16. These side walls 150 are spaced so that the cover plate 132 does not interfere with the lamp house 142 even if the cover plate 132 slides in the direction opposite to the side wall 16, and a part of the lamp house 142 is located inside the side wall 150. Be contained.

  Furthermore, the end portions of the side walls 150 on the long hole 134 side are connected by the shutter wall 152. A rectangular notch 154 is formed in the shutter wall 152. When one end surface of the light guide 146 and the notch 154 face each other along the opposing direction of the side wall 18, light emitted from one end of the light guide 146 is emitted. The lower end of the base 94 can be reached. However, in a state where a portion other than the notch 154 of the shutter wall 152 is interposed between one end of the light guide 146 and the lower end of the base portion 94, the light emitted from one end of the light guide 146 is blocked by the shutter wall 152 and the base portion 94. It has a structure that cannot reach the lower end of.

<Operation and Effect of First Embodiment>
Next, the operation and effect of the present embodiment will be described.

In the present shift lever device 10, from the state where the lever main body 24 penetrates the shift hole 82 at the position S in FIG. 4, the knob 90 is gripped and the shift lever 22 is moved to the right in FIG. The body 36 rotates relative to the retainer 26 around the shaft 46. As a result, the lever member 80 passes through the shift hole 82 at the position N in FIG. With such a body 36 with respect to the retainer 26 about the shaft 46 is rotated, the engaging projection 54 rotates the sensor link 52 about the shaft 50 to press the sensor link 52.

  When the sensor link 52 is rotated, the slider 56 and thus the magnet 60 slide. As the magnet 60 slides, the position of the magnet 60 with respect to the PC board 62 changes, and thereby, the opposing state between the Hall IC element 64 and the magnet that has been opposed to the magnet 60 is released, and until then. The Hall IC element 66 that has not faced the magnet 60 faces the magnet 60. As a result, the signal output from the Hall IC element 64 is at the Low level, and the signal output from the Hall IC element 66 is at the High level.

  Next, when the knob 90 is pressed upward in FIG. 4 (in the direction of arrow U in FIG. 4) from this state, the body 36 and the retainer 26 rotate around the shaft 30. Accordingly, when the lever member 80 passes through the shift hole 82 at the D position in FIG. 4 (that is, when the lever member 80 reaches a predetermined D position among a plurality of shift positions), the lever member 80 is accommodated in the sensor case 35. The magnet is moved by being pressed by the pressing piece 34, the Hall IC element housed inside the sensor case 35 detects the change in the magnetic field that changes in accordance with the movement of the magnet, and a signal corresponding to the change in the magnetic field is generated. Input to the ECU 68 of the PC board 62.

  On the other hand, as described above, after the shift lever 22 is rotated from the S position to the N position, when the knob 90 is pressed downward in the direction of FIG. 4 (in the direction of arrow D in FIG. 4), the body 36 and the retainer 26 are moved to the shaft 30. Rotate around. Accordingly, when the lever member 80 passes through the shift hole 82 at the R position in FIG. 4 (that is, when the lever member 80 reaches a predetermined R position among the plurality of shift positions), the lever member 80 is accommodated in the sensor case 35. The magnet is moved by being pressed by the pressing piece 34, the Hall IC element housed inside the sensor case 35 detects the change in the magnetic field that changes in accordance with the movement of the magnet, and a signal corresponding to the change in the magnetic field is generated. Input to the ECU 68 of the PC board 62.

  On the other hand, when the lever 90 is pushed upward in FIG. 4 (in the direction of arrow U in FIG. 4) from the state in which the lever main body 24 penetrates the shift hole 82 at the position S in FIG. 4, the body 36 and the retainer 26 are moved. It rotates around the shaft 30. Accordingly, when the lever member 80 passes through the shift hole 82 at the position B in FIG. 4 (that is, when the lever member 80 reaches a predetermined position B among the plurality of shift positions), the lever member 80 is accommodated in the sensor case 35. The magnet is moved by being pressed by the pressing piece 34, the Hall IC element housed inside the sensor case 35 detects the change in the magnetic field that changes in accordance with the movement of the magnet, and a signal corresponding to the change in the magnetic field is generated. Input to the ECU 68 of the PC board 62.

  As described above, depending on whether the lever main body 24 passes through the shift hole 82 at the S position, the D position, the R position, or the B position, the Hall IC elements 64 and 66 and the Hall IC elements in the sensor case 35 are determined. The level of at least one of the signals from is different. Based on the change in the level of these signals, the ECU 68 of the PC board 62 determines whether the lever member 80 (that is, the shift lever 22) is located at the S position, the D position, the R position, or the B position. The

  Further, the ECU 68 outputs a signal based on the determination result of the position of the lever member 80. The signal output by the ECU 68, that is, the determination result of the position of the lever member 80 is input to the ECU 70 as a signal.

  In the ECU 70, if the lever member 80 is in the D position based on a signal from the ECU 68, the shift range is changed to the drive range (D range) so that the vehicle can move forward. If the lever member 80 is in the R position, the shift range is changed to the reverse range (R range) so that the vehicle can move backward. Furthermore, if the position of the lever member 80 is the B position, the shift range is changed to the engine brake (B range), and the shift range is changed to a shift range that frequently uses gears having a relatively low gear ratio. If the gear range having a relatively high gear ratio is used for traveling and the gear range having such a low gear ratio is changed to a shift range in which the gear ratio is frequently used, a so-called engine brake can be achieved.

  Further, as described above, after the lever member 80 (shift lever 22) is moved from the S position to the D position, the R position, or the B position, when the pressing force applied to the knob 90 is released, the back surface of the gate member 126 The pin 124 press-contacted by the urging force of the compression coil spring 122 to the upper bottom of the gate groove formed on the gate groove is the most reactive force received from the upper bottom of the gate groove by the urging force of the compression coil spring 122. It is moved to the S position which is a deep part. As a result, the lever member 80 (shift lever 22) returns to the S position.

  As described above, the shift lever device 10 is basically maintained with the lever member 80 (shift lever 22) penetrating the shift hole 82 at the S position so that the shift range is changed to a desired shift range. The lever member 80 (shift lever 22) is rotated to the corresponding shift position (D position, R position, or B position). After the shift range is changed, the lever member 80 (shift lever 22) returns to the S position, and the previous shift range is maintained until the lever member 80 (shift lever 22) is rotated to another shift position. .

  On the other hand, when a switch operation is performed in the vehicle interior to turn on the vehicle headlights or vehicle width lights at night or the like, the lamp 144 is turned on in conjunction with this. In a state where the lever main body 24 passes through the shift hole 82 at the S position, the lower surface of the base portion 94 and one end in the longitudinal direction of the light guide 146 are opposed to each other through the notch 154. Therefore, in this state, the light from the lamp 144 is guided by the light guide 146 and emitted from one end in the longitudinal direction of the light guide 146.

  Light emitted from one end in the longitudinal direction of the light guide 146 passes through the notch 154 and enters the lower end of the base 94. Light incident on the lower end of the base 94 passes through the light guide 98 from the base 94 and is emitted from the upper surface of the light guide 98. Light emitted from the upper surface of the light guide 98 enters the guide lens 108, passes through the indicator plate 110 and the indicator lens 112, and exits the knob 90.

  As described above, the indicator plate 110 has a structure that allows light to pass through only the shift pattern portion corresponding to the shape of the shift hole 82 and the mark portion indicating the shift range on the side of the shift pattern portion. For this reason, the upper end (tip) of the knob 90 emits light corresponding to the shapes of the shift pattern portion and the mark portion. Therefore, by visually recognizing the upper surface of the knob 90, the shift pattern can be confirmed even when the vehicle interior is dark, such as at night.

  On the other hand, as described above, when the lever member 80 (shift lever 22) is rotated from the S position to the N position, the cover plate 132 pressed by the lever member 80 slides. The sliding of the cover plate 132 causes the shutter wall 152 to slide, the opposed state of the notch 154 and the light guide 146 is released, and the portion other than the notch 154 of the shutter wall 152 is between the light guide 146 and the lower end of the base 94. Intervene on the optical path.

  As a result, light traveling from the light guide 146 toward the base 94 is blocked and cannot enter the lower end of the base 94. For this reason, light emission does not occur at the upper end (tip) of the knob 90 as described above. Thus, in the present shift lever device 10, when the shift lever 22 is moved from the S position to the N position in order to move the shift lever 22 to the D position or the R position, the light emission at the upper end of the knob 90 is stopped and the light is turned off. Is done.

  Thus, by intentionally stopping the light emission on the upper surface of the knob 90, it becomes difficult for the occupant to see the shift pattern and the like on the upper surface of the knob 90. For this reason, it is possible to prevent the passenger from gazing at the knob 90 when changing the shift range to the drive range or the reverse range.

  In this way, in this shift lever device 10, the lamp 144 as a light source is not disposed inside the knob 90, and the light guides 98 and 146 guide light to the indicator lens 112. In addition to simplification, the knob 90 can be downsized. Moreover, since the light guide 98 is a part of the structure of the knob 90, the structure of the knob 90 can be simplified in this sense.

<Configuration of Second Embodiment>
Next, a second embodiment of the present invention will be described. In the description of the present embodiment, the same reference numerals are given to the portions that are basically the same as those in the first embodiment, and the detailed description thereof is omitted.

  FIG. 6 is an enlarged perspective view of a main part of the shift lever device 160 according to the present embodiment. FIG. 7 is an enlarged cross-sectional view of a main part of the shift lever device 160.

  As shown in these drawings, the knob body 102 constituting the knob 162 of the present shift lever device 160 does not include the female screw portion 104 but instead includes a female screw portion 164 as a fixing portion. The female screw part 164 is formed in a cylindrical shape having both ends opened along the opening direction of the outer cylinder part 103, and the female screw part 164A is formed on the inner peripheral part thereof, but is the same as the female screw part 104. This configuration differs from the female screw portion 104 in the first embodiment in that the female screw portion 164 is formed of the same synthetic resin material as the outer cylinder portion 103 and the connecting piece 106.

  On the other hand, in the present embodiment, the knob body 92 includes a light guide 166 instead of the light guide 98. The knob main body 92 including the light guide 166 is the same as the first embodiment in that it is formed entirely of a transparent acrylic resin (PMMA: polymethyl methacrylate or methacrylic resin). In the present embodiment, the synthetic resin material constituting the knob body 92 and the synthetic resin material constituting the knob body 102 are different in material.

  Although the light guide 166 is formed in a cylindrical shape, the slit 100 is not formed unlike the light guide 98, and the connecting piece 106 penetrates the light guide 166 along the radial direction of the light guide 166. ing.

  The upper end of the light guide 166 facing the upper end side of the outer cylinder portion 103 (that is, the other axial end side of the outer cylinder portion 103) is located above the upper end of the female screw portion 164. Further, in the present embodiment, the upper bottom portion 168 is formed at the upper end of the outer cylinder portion 103, and the upper bottom portion 168 covers the upper end of the female screw portion 164 (that is, the light guide 166 is basically the upper end portion). Is formed in a bottomed cylindrical shape closed by an upper bottom portion 168).

  In addition, a through hole 170 that penetrates in the axial direction of the light guide 166 is formed in the upper bottom portion 168. The through hole 170 communicates with the inner side of the female screw portion 164 on the inner side of the light guide 166, and the male screw 80 </ b> A at the tip of the lever member 80 (lever body 24, shift lever 22) is connected to the female screw 164 </ b> A of the female screw portion 164. When the lever member 80 is screwed and the tip of the lever member 80 approaches the upper bottom portion 168, the air in the female screw portion 164 is drawn out of the female screw portion 164 and the light guide 166, and the air is trapped in the female screw portion 164. It is preventing.

<Outline of manufacturing process of knob 162 and operation and effect of this embodiment>
Next, the manufacturing process of the knob 162 in this Embodiment is demonstrated.

  In the manufacturing process of the knob 162, first, the knob body 102 is manufactured in the knob body forming process. In the knob body forming step, as shown in FIG. 8, a mold 172 including an upper mold 174 and a lower mold 176 is used.

  The cavity 178 of the lower mold 176 is basically formed in a shape corresponding to the outer peripheral shape of the outer cylinder portion 103. The shape of the core 180 of the upper die 174 corresponding to the cavity 178 of the lower die 176 corresponds to the inner peripheral shape of the outer cylinder portion 103 except for the portions corresponding to the outer peripheral shapes of the connecting piece 106 and the female screw portion 164. Molded. The lower mold 176 has a thread-forming core 182 protruding therefrom.

  In the knob body molding process, after the mold 172 including the upper mold 174 and the lower mold 176 is clamped, a synthetic resin material such as nylon resin (PA) is filled in the mold 172, and the filling is performed. The knob body 102 is molded by cooling and curing the synthetic resin material.

  Next, as shown in FIG. 9, the knob body 102 manufactured in the knob body molding process is placed in a mold 184 used in the guide molding process. The mold 184 includes an upper mold 186 and a lower mold 188. The inner peripheral shape of the lower mold 188 on the upper side (opening end side) of the cavity 190 in the depth direction corresponds to the outer peripheral shape of the knob body 102 (that is, the outer peripheral shape of the outer cylinder portion 103). When 102 is disposed in the cavity 190 of the lower mold 188, the outer peripheral portion of the knob body 102 uniformly contacts the inner peripheral portion of the cavity 190 above the intermediate portion in the depth direction of the cavity 190. A core 192 is formed in the cavity 190 of the lower mold 188 so as to correspond to the through hole 44 and the inner peripheral portion of the female screw portion 164.

  On the other hand, a core 194 is formed on the upper die 186 except for a portion where the light guide 166 is formed. The outer peripheral shape of the core 194 basically corresponds to the inner peripheral shape of the outer cylindrical portion 103, and when the mold 184 is clamped with the knob body 102 disposed in the cavity 190, the outer peripheral portion of the core 194 becomes the knob body 102. Abuts against the inner periphery.

  In the guide molding process, the mold 184 is clamped in a state where the knob body 102 is disposed in the lower mold 188, and a synthetic resin material such as acrylic resin (PMMA) is filled in the mold 184. The knob body 92 is molded by cooling and curing the synthetic resin material filled in the mold 184.

  In this manner, the knob 162 is formed by assembling and fixing the cap 107 to the knob body 102 in which the knob main body 92 is integrally formed in the cap mounting process.

  Here, the knob 162 of the shift lever device 160 is formed with the knob body 92 in a state where the knob body 102 is disposed in the mold 184. For this reason, the knob body 92 is already connected to the knob body 102 by being molded. Thereby, the process for assembling the knob body 102 and the knob main body 92 can be substantially eliminated as compared with the case where the knob body 102 and the knob main body 92 are completely separate parts. For this reason, the manufacturing cost of the knob 162 can be reduced.

  In addition, the knob 162 formed in this way is formed when the knob body 102 is molded with the female screw portion 164 as a part of the knob body 102. For this reason, it is not necessary to use the screw member corresponding to the internal thread part 164 separately. Thereby, the number of parts can be reduced, and in this sense, the cost can be reduced.

  Further, if the internal thread portion 164 is formed on the knob body 92 instead of the knob body 102, the structure is simplified, but the nylon resin or the like used for the knob body 102 is more resistant to the acrylic resin or the like used for the knob body 92. Since it is excellent in wear resistance and impact resistance, it is effective that the female screw portion 164 is damaged when the female screw portion 164 of the knob 162 is screwed and assembled to the male screw 80A formed at the tip of the lever member 80. The knob 162 can be assembled to the lever member 80 without paying special attention. Thereby, workability | operativity can be improved and cost reduction can be aimed at also in this meaning.

  As shown in FIG. 9, the knob 162 of the shift lever device 160 has a light guide 166 with an upper bottom portion 168 formed therein. Thereby, the area of the end surface of the light guide 166 when the knob body 102 is viewed from above is increased as compared with the configuration in which the upper bottom portion 168 is not formed.

  Considering that the light taken in by the lighting surface 101 of the base 94 is guided to the light guide 166 to emit light at the end surface of the light guide 166 and this light is transmitted through the cap 107, as described above. By forming the upper bottom portion 168 and increasing the end face of the light guide 166, the light emitting area is increased and the variation in the brightness of the light transmitted through the cap 107 can be reduced.

  Here, when the knob body 102 and the knob body 92 are assembled as separate parts, the light guide 166 is inserted from the lower opening end of the knob body 102 and the knob body 92 is assembled to the knob body 102. become. In such an assembly, a hole having a size that allows the female screw portion 164 to pass therethrough and a notch having a size that allows the coupling piece 106 to pass through must be formed at the upper end of the light guide 166. In addition, the area of the end face of the light guide 166 cannot be increased by forming a notch or the like.

  On the other hand, the knob 162 of the shift lever device 160 is formed by the so-called insert molding in which the knob body 102 is arranged in the mold 184 as described above, so that the upper bottom portion 168 can be formed. Thus, as described above, the light emitting area can be increased, and as a result, the variation in the brightness of the light transmitted through the cap 107 can be reduced.

<Configuration of Third Embodiment>
FIG. 10 is an enlarged perspective view of the main part of the shift lever device 210 according to the third embodiment of the present invention.

  As shown in this figure, the shift lever device 210 includes a shift lever 212. The shift lever 212 includes a first lever 214 as a substantially cylindrical lever main body that is formed in a longitudinal direction along a predetermined direction (for example, a substantially vehicle vertical direction).

  The base end portion of the first lever 214 in the longitudinal direction is a base member that can pivot about both the front-rear direction perpendicular to the longitudinal direction and the left-right direction perpendicular to both the front-rear direction and the longitudinal direction as axial directions. (Not shown).

  Note that the front-rear direction and the left-right direction referred to here are directions that are not related directly to the front-rear direction and the left-right direction of the vehicle, but merely for convenience. That is, if the shift lever device 210 is installed so as to be approximately in the longitudinal direction of the shift lever 212 along the vertical direction of the vehicle, the front-rear direction and the left-right direction described above substantially coincide with the front-rear direction and the left-right direction of the vehicle However, for example, when the shift lever device 210 is installed on an instrument panel or the like of the vehicle, the longitudinal direction of the shift lever 212 is the longitudinal direction of the vehicle.

  A bracket 216 is provided on the base end side in the longitudinal direction of the first lever 214. As shown in FIG. 12, the bracket 216 has a hollow interior. The base end side of the first lever 214 penetrates the upper wall 218 of the bracket 216 and enters the inside of the bracket 216 so as to be integrated with the bracket 216 by fixing means represented by fastening means such as screws and bolts (not shown). It is fixed.

  On the other hand, a pair of vertical walls 222 extend from the bottom wall 220 of the bracket 216. These vertical walls 222 are opposed to each other along the front-rear direction. As shown in FIG. 10, the longitudinal tip end side of the second lever 224 as a substantially rod-shaped lever main body enters between the vertical walls 222. A shaft 226 passes through the vertical wall 222 into which the tip of the second lever 224 has entered along the facing direction (that is, the front-rear direction). 214 can pivot about shaft 226.

  The intermediate portion in the longitudinal direction of the second lever 224 is supported on the side wall 230 of the base 228 so as to be pivotable about the left-right direction as an axial direction. The base 228 is fixed to the vehicle body at an appropriate position of the vehicle, for example, if the shift lever device 210 is disposed between the driver seat and the passenger seat of the vehicle.

  Further, the other end side of the second lever 224 in the longitudinal direction is connected to an automatic transmission (transmission) of the vehicle via a mechanical connection means such as a wire cable (not shown), and the second lever 224 is connected. When the automatic transmission control device detects that has reached the predetermined turning position, the shift range is changed to a shift range corresponding to the turning position of the second lever 224 out of a plurality of shift ranges preset in the automatic transmission. .

  On the other hand, a housing 232 is disposed above the base 228, and each member constituting the shift lever device 210 disposed below the housing 232 is covered.

  The housing 232 is formed with a zigzag-shaped shift hole 234 that is appropriately bent in the front-rear and left-right directions. The first lever 214 passes through the shift hole 234, and the shift lever 212 is operated zigzag along the shift hole 234.

  Of the swiveling positions of the shift lever 212 that are shifted in the front-rear and left-right directions as described above, the second lever 224 is a machine such as a wire cable as described above. The automatic transmission can detect the turning position of the shift lever 212 by being connected to the automatic transmission through the automatic connection means.

  On the other hand, the turning position of the shift lever 212 around the axis with the front-rear direction as the axial direction, that is, the turning position of the first lever 214 around the shaft 226 is a micro switch provided on the side wall 230 of the base 228 or the like. The control unit of the automatic transmission detects the turning position based on the conduction state of the detection means and the signal output from the detection means.

  On the other hand, as shown in FIG. 10, a gripping knob 236 is provided at the tip of the first lever 214. As shown in FIG. 10, the knob 236 is formed of a synthetic resin material, and a through hole 238 for inserting the first lever 214 is formed at the lower end of the knob 236, and the distal end side of the first lever 214 is the through hole. 238 enters from the lower open end.

  The first lever 214 entering the through hole 238 is integrally fixed to the knob 236. Note that the first lever 214 and the knob 236 are not particularly limited. Therefore, any of fastening fixing by a fastening means such as a screw, adhesive fixing by an adhesive means such as an adhesive, and press fitting of the first lever 214 into the through hole 238 may be used, and the tip of the first lever 214 may be used. On the side, a male screw may be formed on the outer peripheral portion, a female screw may be formed on the inner peripheral portion of the through hole 238, and the first lever 214 and the knob 236 may be screwed together to be fixed.

  A lamp house 240 is formed on the knob 236. The lamp house 240 is a space formed in a substantially concave shape opened at the upper end of the knob 236, and the upper end of the through hole 238 is opened at the bottom thereof.

  Further, an indicator 242 as a transmission part is attached to the upper opening end of the lamp house 240. The indicator 242 is a plate-like member that is transparent, translucent, or colored in a desired color so that light can be transmitted. The upper end of the lamp house 240 is opened by so-called snap fit, heat welding, or adhesive bonding. Is integrally fixed to the knob 236 in a closed state.

  As shown in FIG. 11, the surface of the indicator 242 has a shift as an operation pattern constituted by a line substantially the same shape as the shift hole 234 described above, and letters and numbers located on the side of the line. A pattern 244 is formed. In the shift pattern 244, a line having substantially the same shape as the shift hole 234 indicates the operation direction of the shift lever 212, and letters and numbers located on the side of the line indicate a shift range.

  As shown in FIG. 10, an optical fiber 246 serving as a light guiding unit is provided inside the lamp house 240. As conventionally known, the optical fiber 246 is a string-like member formed of glass or the like, and can transmit light from the proximal end side in the longitudinal direction to the distal end side.

  A light guide 248 as light guiding means is integrally fixed to the longitudinal end portion of the optical fiber 246. The light guide 248 is fixed to the back surface of the indicator 242 inside the lamp house 240, and the light transmitted from the longitudinal base end side of the optical fiber 246 constituting the illumination means to the front end passes through the light guide 248. In addition, the indicator 242 is transmitted.

  The base end side of the optical fiber 246 passes through the inside of a ring-shaped vibration-proof rubber 250 fitted into the upper opening end of the through hole 238. Further, the base end side of the optical fiber 246 passes through the through hole 238 and the inside of the first lever 214, and enters the inside of the bracket 216 from the base end portion of the first lever 214 as shown in FIG.

  A guide member 252 is disposed on the bottom of the bracket 216 corresponding to the optical fiber 246 that has entered the bracket 216. The guide member 252 is formed with a guide surface 254 that is substantially perpendicular to a part of the guide member 252 and whose corners are curved in an arc shape. The optical fiber 246 that enters the bracket 216 from the first lever 214 is the guide surface of the guide member 252. It is guided to the side wall 256 side of the bracket 216 by being guided by H.254.

  Further, a substrate 258 is disposed on the side of the base end portion of the optical fiber 246. The substrate 258 is erected on the bottom of the bracket 216 with one surface in the thickness direction facing the base end of the optical fiber 246, and the distal end side penetrates the side wall 256 from the outside of the side wall 256 of the bracket 216. The screw 260 is fixed.

  On one surface in the thickness direction of the substrate 258 (the surface on the base end side of the optical fiber 246), an LED 262 constituting an illuminating device is provided as a light emitting device, and of the both surfaces in the thickness direction of the substrate 258 On one side, electronic components (not shown) such as a resistance element and a transistor are provided to constitute a circuit.

  Further, the tips of the two cords 264 are fixed to the other surface in the thickness direction of the substrate 258. Both cords 264 are electrically connected to the circuit on the substrate 258. On the other hand, the base end side of the cord 264 extends through the side wall 256 to the outside of the bracket 216, and further, a battery mounted on the vehicle via a control means (not shown) such as an ECU (all the reference numerals are not shown). Is omitted). For example, the ECU is connected to a headlamp switch for external illumination of the vehicle, and when the headlamp switch is operated to light the vehicle width lamp or the headlamp, the ECU supplies a current to the circuit of the board 258 via the code 264. It is structured to flow.

<Operation and Effect of Third Embodiment>
In this shift lever device 210, the knob 236 is gripped by the vehicle occupant, and in this state, the shift lever 212 is turned along the shift hole 234 about the axis whose axial direction is the left-right direction or the front-rear direction. When the first lever 214 arrives at a predetermined position in the shift hole 234, the control means of the automatic transmission changes from the previous shift range to a shift range corresponding to the turning position of the shift lever 212.

  On the other hand, when a vehicle occupant operates a headlamp switch and lights a vehicle headlamp or a vehicle width lamp at night or the like, usually, meters provided in the instrument panel are illuminated accordingly. Thereby, even if the vehicle interior is dark, the meters can be easily visually recognized.

  Further, when the headlamp switch is operated to turn on the headlamp and the vehicle width lamp in this way, the ECU connected to the headlamp switch causes a current to flow to the electric circuit of the board 258 via the cord 264. When a current is passed through the circuit of the substrate 258, the LED 262 emits light. Since the LED 262 faces the proximal end portion of the optical fiber 246, the light emitted from the LED 262 passes from the proximal end portion of the optical fiber 246 through the optical fiber 246 toward the distal end side. Further, the light that has passed through the optical fiber 246 and traveled toward the distal end side thereof passes through the light guide 248 provided at the distal end portion of the optical fiber 246, and the light is transmitted from the back side to the front side of the indicator 242.

  In this way, light is transmitted from the back surface side to the front surface side of the indicator 242 so that the upper surface of the knob 236 emits light, and thus the shift pattern 244 formed on the indicator 242 can be easily formed even when the vehicle interior is dark. It becomes possible to visually recognize.

  In this embodiment, the light emitted from the LED 262 passes through the optical fiber 246 and passes through the indicator 242, but the substrate 258 provided with the LED 262 is attached in the bracket 216. Thus, even when the shift lever 212 is operated, the relative displacement between the LED 262 and the optical fiber 246 basically does not occur.

  For this reason, even if the shift lever 212 is operated, the LED 262 and the proximal end portion of the optical fiber 246 always face each other. Therefore, regardless of the turning position of the shift lever 212, the amount of light emitted from the LED 262 and reaching the proximal end portion of the optical fiber 246 does not change. Thereby, the brightness | luminance in the indicator 242 can be made constant irrespective of the turning position of the shift lever 212. FIG.

<Configuration of Fourth Embodiment>
Next, a fourth embodiment of the present invention will be described. Note that in explaining the fourth respective embodiments described below, including the exemplary embodiment, with respect to the third embodiment is basically the same sites of its description by the same reference numerals Is omitted.

  FIG. 14 is a cross-sectional view corresponding to FIG. 12 showing the configuration of the main part of a shift lever device 280 according to the fourth embodiment of the present invention.

  As shown in this figure, the shift lever device 280 is different from the shift lever device 210 according to the third embodiment in that the substrate 258 is not provided in the bracket 216 and the side wall 256 of the bracket 216 is not provided. Is integrally fixed to the side wall 230 of the base 228.

  In the shift lever device 280, a light guide 282 as a light collecting means is provided inside the bracket 216. The light guide 282 is formed in a substantially quadrangular pyramid shape that gradually tapers from the bottom side to the top side with glass or the like. The bottom surface of the light guide 282 is a condensing surface 284, and the light irradiated to the condensing surface 284 is refracted in the light guide 282 and is directed toward the top side, and is emitted from the top portion.

  The top of the light guide 282 faces the proximal end of the optical fiber 246, and light emitted from the top passing through the light guide 282 travels toward the proximal end of the optical fiber 246. The light guide 282 passes through an opening 86 formed on the side wall 256 on the light collecting surface 284 side, protrudes to the outside of the bracket 216, and faces the LED 262 attached to the substrate 258. Here, the light condensing surface 284 of the light guide 282 has at least a width facing the LED 262 even when the shift lever 212 is pivoted in the front-rear direction and the left-right direction.

<Operation and Effect of Fourth Embodiment>
As described above, the shift lever device 280 is different from the shift lever device 210 according to the third embodiment in that the substrate 258 is attached to the base 228. For this reason, when the shift lever 212 is turned, the base end portion of the optical fiber 246 moves toward and away from the LED 262 in the front, rear, left, and right directions. However, even if the shift lever 212 is turned, the light converging surface 284 of the light guide 282 attached to the bracket 216 faces the LED 262 regardless of the turning position of the shift lever 212.

  For this reason, regardless of the turning position of the shift lever 212, the light emitted from the LED 262 reaches the light condensing surface 284 of the light guide 282. In this way, the light that has reached the condensing surface 284 passes through the light guide 282, is emitted from the top, travels toward the base end of the optical fiber 246, and further reaches the base end of the optical fiber 246. It passes through the optical fiber 246.

  As described above, in the present shift lever device 280, although the substrate 258 is attached to the base 228, the light emitted from the LED 262 can be sent to the optical fiber 246. For this reason, the upper surface of the knob 236 can emit light as in the third embodiment, and as a result, the shift pattern 244 formed on the indicator 242 can be easily visually recognized even when the vehicle interior is dark. become.

  In this embodiment, since the board 258 is attached to the base 228, the board 258 and the cord 264 do not move even when the shift lever 212 is turned. For this reason, it is possible to prevent or reduce the vibration and impact caused by the turning operation of the shift lever 212 from being transmitted to the substrate 258, and it is not necessary to improve the vibration resistance and impact resistance of the substrate 258 more than necessary.

  Further, as described above, the cord 264 does not move even when the shift lever 212 is turned. Therefore, it is not necessary to bend or bend the cord 264 between the base 228 and the bracket 216 in advance by considering the amount of movement of the cord 264 when the shift lever 212 is turned. Thereby, it is not necessary to improve the bendability of the cord 264 more than necessary.

<Fifth embodiment>
Next, a fifth embodiment of the present invention will be described.

  FIG. 15 shows a main part of shift lever device 300 according to the present embodiment in a sectional view corresponding to FIG.

  As shown in this figure, in the present shift lever device 300, instead of the optical fiber 246 used in the third and fourth embodiments, the outer diameter dimension is sufficiently smaller than the optical fiber 246 (that is, it is thin) ) A plurality of optical fibers 302 as light guiding means are provided.

  Like the optical fiber 246 used in the fourth embodiment, these optical fibers 302 have a distal end side located in the lamp house 240 and a proximal end side through the through hole 238 and the first lever 214. It passes through the inside and is bent in the bracket 216, and the base end portion faces the top portion of the light guide 282.

  However, in this embodiment, the light guide 248 is not provided at the tip of the optical fiber 302.

  Moreover, although the tips of these optical fibers 302 are generally directed to the indicator 242, they are individually directed in different directions, and the light that passes through each optical fiber 302 and reaches the tips is in different directions. In general, it is emitted almost radially.

  As described above, in the present embodiment, the tip portions of the respective optical fibers 302 are individually directed in different directions, so that the light is diffused and emitted substantially radially as a whole. Thereby, light is irradiated in a wide range with respect to the back surface of the indicator 242. For this reason, unevenness in luminance in the indicator 242 is reduced.

It is a disassembled perspective view of the principal part of the shift lever apparatus which concerns on the 1st Embodiment of this invention. It is a disassembled perspective view of the knob of the shift lever apparatus which concerns on the 1st Embodiment of this invention. It is a disassembled perspective view which shows the whole structure of the shift lever apparatus which concerns on the 1st Embodiment of this invention. It is a top view which shows the shift pattern and shift position of the shift lever apparatus which concern on the 1st Embodiment of this invention. It is sectional drawing of the knob of the shift lever apparatus which concerns on the 1st Embodiment of this invention. It is a perspective view of the principal part of the shift lever apparatus which concerns on the 2nd Embodiment of this invention. It is sectional drawing of the knob of the shift lever apparatus which concerns on the 2nd Embodiment of this invention. It is a schematic sectional drawing of the metal mold | die used for a knob body shaping | molding process. It is a schematic sectional drawing of the metal mold | die used for a guide formation process. It is sectional drawing of the knob of the shift lever apparatus which concerns on the 3rd Embodiment of this invention. It is a top view of the knob of the shift lever apparatus which concerns on the 3rd Embodiment of this invention. It is sectional drawing of the base end side of the lever main body of the shift lever apparatus which concerns on the 3rd Embodiment of this invention, and its vicinity part. FIG. 9 is a schematic perspective view of a shift lever device according to a fourth embodiment of the present invention. It is sectional drawing corresponding to FIG. 8 of the shift lever apparatus which concerns on the 4th Embodiment of this invention. It is sectional drawing corresponding to FIG. 6 of the shift lever apparatus which concerns on the 5th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Shift lever apparatus 12 Housing 24 Lever main body 90 Knob 92 Knob main body (light guide means)
102 Knob body (shading part)
108 Guide lens (transmission part)
106 Connecting piece 110 Indicator plate (transmission part)
112 Indicator lens (transmission part)
144 Lamp (light source)
146 Light guide (light guiding means)
148 Shutter (light control means, shutter member)
160 Shift lever device 162 Knob 164 Female thread part (fixed part)
166 Light guide (light guiding means)
184 Mold 210 Shift lever device 212 Shift lever 214 First lever (lever body)
224 Second lever (Lever body)
232 Housing 236 Knob 242 Indicator (transmission part)
246 Optical fiber (light guiding means)
248 Light guide (light guiding means)
280 Shift lever device 282 Light guide (condensing means)
300 Shift lever device 302 Optical fiber (light guiding means)

Claims (11)

Shifting a lever body, whose base end side is directly or indirectly connected to a transmission having a plurality of shift ranges and whose front end side protrudes toward the vehicle interior side, in a predetermined direction set in advance, a predetermined shift position A shift lever device that changes the transmission to a shift range corresponding to the shift position by arriving at
A light source provided directly or indirectly on one of the housing and the lever body that directly or indirectly supports the lever body so that the shift operation is possible;
A knob that is attached to the tip of the lever main body so that it can be gripped by a vehicle occupant, and that transmits light guided to the inside from a transmission portion that can transmit light to the outside;
Setting vignetting prior Symbol knob, and light directing means emitted light is transmitted through the inner leads to the interior of the knob at the light source,
In addition,
A fixing portion fixed to the tip of the lever body;
A light-shielding part having a light-shielding property formed in a cylindrical shape covering the outside of the fixed part;
The fixing portion is arranged on the inner side so that the distal end side of the lever main body enters the inner side, and the light shielding portion is mounted in a state where the base end side is exposed to the outside from the intermediate portion along the longitudinal direction of the lever main body. A knob body that is covered with a light-shielding portion and that can transmit light emitted from the light source on the inside thereof and constitutes the light guiding means;
The outer periphery of the fixed part and the inner periphery of the light shielding part are integrally connected, and the knob body relative to the light shielding part passes through the knob body and has the longitudinal direction of the lever body as an axial direction. Connecting piece to regulate,
A shift lever device including the knob . When the lever main body reaches at least one specific shift position set in advance, the light is guided to the inside of the knob, and the lever main body is positioned other than the specific shift position within the range of the shift operation. A light guidance control means for stopping the guidance of the light to the knob in case
The shift lever device according to claim 1. The light emitted from the light source is provided so as to be able to reciprocate between a predetermined light shielding position on the optical path of the light and a position away from the light shielding position until the light reaches the transmitting portion. The light guiding control means is a shutter member that blocks the light in the moved state and leaves the light blocking position in conjunction with the shift operation to the specific shift position.
The shift lever device according to claim 2. At least a part of the outer surface of the knob body is exposed to the outside, the light source is disposed in the vicinity of the outer surface exposed to the outside and outside the lever body, and the light of the light source is exposed to the outside Incident from the outer surface,
The shift lever device according to any one of claims 1 to 3, wherein the shift lever device is provided. Before SL shielding portion, it is integrally formed by the connecting piece, and the same synthetic resin material of the fixing portion,
The shift lever device according to claim 4 . Either one of the light shielding part and the knob main body is molded in advance, and either one of the light shielding part and the knob main body is molded in a state where either one of the light shielding part and the knob main body is inserted. To be
The shift lever device according to claim 5 . When the knob is attached to the lever main body, the fixing portion is formed in a cylindrical shape that opens toward the proximal end of the knob, and the tip of the lever main body enters from the opening end of the fixing portion. The fixing part is fixed to the main body,
The knob body covers at least a part of an end surface of the fixed portion facing the transmitting portion.
The shift lever device according to claim 6 . Forming an internal thread on the inner peripheral part of the fixing part, forming an external thread on the outer peripheral part on the distal end side of the lever body, and screwing the male screw into the internal thread to fix the fixing part to the lever body;
The shift lever measure according to any one of claims 5 to 7 , wherein the shift lever measure is provided. The lever main body is formed in a cylindrical shape penetrating from the proximal end portion toward the distal end portion, and the light guiding means is passed through the lever main body, and is provided on the side of the proximal end portion of the lever main body. The light output from the light source is guided to the tip side of the lever body by the light guiding means.
The shift lever device according to claim 1 or 2 , characterized by the above. The light source is integrally attached to the lever body on the base end side of the lever body.
The shift lever device according to claim 9 . A light converging surface facing the light source and a light emitting surface facing the end of the light guiding means on the base end side of the lever body, and the end of the light guiding means on the base end side of the lever body Light from the light source condensed on the light emitting surface passes between the light source and emits light from the light emitting surface, and the lever body is located at any of the plurality of shift positions. Even in the state, the surface shape of one of the light-collecting surface and the light-emitting surface corresponds to one of the surfaces of the light guide means and the light source on the base end side of the lever body. And condensing means set to be able to face each other,
The shift lever device according to claim 9 .

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