JP6886375B2 - Cup holder - Google Patents

Description

The present invention relates to a cup holder, and more particularly to a cup holder in which a tray for holding a container such as a beverage can be moved up and down.

A cup holder (container holder device) for holding a container such as a beverage is mounted in the passenger compartment of the vehicle. The cup holder is disclosed in Patent Document 1, for example.

The conventional cup holder has a holder body that has a substantially box shape and opens upward and constitutes a storage space, and a tray (lid) that has a plate shape with a design surface on one surface and opens and closes the opening of the holder body. The tray is rotatably held by the holder body, and the closed position that covers the opening with the design surface facing upward by rotation and the mounting surface (holding surface) on the opposite side of the design surface facing upward. It is configured to be displaced between the open position and the inside of the storage space, and to receive and hold the bottom surface of the container inserted from the opening at the open position by the holding surface.

Japanese Unexamined Patent Publication No. 2005-324594

In the conventional cup holder, the tray is rotated to switch between the case where the design surface of the tray is directed upward and the case where the holding surface on the opposite side of the design surface is directed upward. In the conventional cup holder, the bottom surface of the container for beverages and the like is prevented from coming into contact with the holding surface and coming into contact with the design surface. For this reason, scratches on the design surface, that is, deterioration of appearance is suppressed. However, the conventional cup holder has a structure in which the tray rotates, which causes a problem that the structure, structure, or operation of the device is complicated.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a cup holder in which damage to the design surface is suppressed.

The cup holder of the present invention that solves the above problems has a holder body having a storage space surrounded by a peripheral wall, and an object to be placed that is housed in the storage space and supported by the holder body so as to be movable up and down. A cup holder including a tray having a mounting surface on the upper surface thereof, and the tray has a plate-shaped tray main body portion whose upper surface is the previously described mounting surface and a tip portion thereof in contact with the mounted object. As described above, the tray has a plurality of protrusions protruding upward from the tray main body, and the protrusions are formed in a linear shape passing through two points having different radial positions with respect to the peripheral wall. It is characterized by that.

In the cup holder of the present invention, a protrusion protruding upward is formed on the upper surface of a tray that moves up and down in the accommodation space of the holder body. In the cup holder of the present invention, the upper surface of the tray is a design surface and a mounting surface. By having the protruding portion on the upper surface thereof, it is possible to prevent the tray main body portion from coming into contact with the object to be placed (container for beverages or the like). As a result, scratches on the design surface are suppressed, and deterioration of the design is suppressed.
Further, the cup holder of the present invention has a structure in which the tray moves up and down in the accommodating space of the holder body. Unlike the conventional structure in which the tray rotates, it can be formed with a simple structure.

It is a perspective view of the cup holder of an embodiment. It is an exploded perspective view of the cup holder of an embodiment. FIG. 3 is a cross-sectional view taken along the line III-III in FIG. FIG. 5 is a cross-sectional view taken along the line IV-IV in FIG. It is a top view of the cup holder of an embodiment. It is a cross-sectional view taken along the line VI-VI in FIG. FIG. 5 is a cross-sectional view taken along the line VII-VII in FIG. It is an enlarged view of the main part of the tray which shows the guide protrusion part and the holding part of the cup holder of embodiment. It is an exploded perspective view of the operation part of the cup holder of an embodiment. It is an enlarged view of the main part which shows the regulation part and the groove part of the cup holder of embodiment. FIG. 5 is a cross-sectional view taken along the line XI-XI in FIG.

Hereinafter, the cup holder of the present invention will be specifically described with reference to embodiments.
[Embodiment]
The cup holder of this embodiment is mounted on the center console in the vehicle interior. In the drawing showing the cup holder of this embodiment, the front, rear, right, left, top, and bottom are the directions seen from the driver (passenger in the right seat of the center console) seated in the vehicle seat.
The cup holder 1 of this embodiment includes a holder body 2, a tray 3, and a height adjusting means 5 for adjusting the height of the tray 3, as shown in a perspective view in FIG. 1 and an exploded perspective view in FIG. Has.
The holder body 2 has a cylindrical peripheral wall 21 and an upper wall 28 extending to the upper peripheral edge of the peripheral wall 21.

The peripheral wall 21 has a plurality of (four in this embodiment) groove portions 22, 22, 22, 22 arranged at equal intervals in the circumferential direction. The groove portions 22 are located at equal intervals in the circumferential direction, that is, at the ends of the peripheral wall 21 of the cup holder 1 in the front-rear direction and the left-right direction. In the present embodiment, the pair of groove portions 22 and 22 located opposite to each other in the front-rear direction of the cup holder 1 among the groove portions 22 are referred to as the first groove portion 22a, and the pair of groove portions 22 and 22 located facing each other in the left-right direction. Is referred to as a second groove portion 22b.

A rack member 25 corresponding to the shape of the groove 22 is fitted in the first groove 22a. The rack member 25 is a long member having a U-shaped cross section, and is a pair of side walls 26, 26 facing each other and a back wall 27 provided on the back side of the rack member 25 and connecting the pair of side walls 26, 26. And have.

In the second groove portion 22b, a locking portion 71a of a locking member 71 described later and a regulating portion 81 described later for locking the tray 3 to the lower portion are arranged. As shown in the cross-sectional view of FIG. 6, the second groove portion 22b is a back wall provided behind the pair of side walls 23, 23 facing each other and the pair of side walls 23, 23 provided behind the second groove portion 22b and connecting the pair of side walls 23, 23. Surrounded by 24.

The lower end of the peripheral wall 21 is closed by a substantially disk-shaped bottom plate 9 as shown in a cross-sectional view in FIG. The peripheral edge of the bottom plate 9 is fixed to the lower portion of the peripheral wall 21 of the holder body 2 with screws. The space surrounded by the peripheral wall 21 and the bottom plate 9 is a storage space 20 for accommodating containers such as beverages.

The tray 3 has a substantially disk shape as a whole, and is arranged so as to be vertically movable inside the cylindrical peripheral wall 21 (accommodated in the accommodation space 20 so as to be vertically movable). The tray 3 is supported by the holder body 2. The upper surface of the tray 3 is a mounting surface on which the object to be mounted is placed.
The tray 3 has a tray surface member 30, an elastic member 33, a decorative member 36, and a tray base material 38.

As shown in the top view of FIG. 5, the tray surface member 30 has a substantially disk shape as a whole, and has three notches 31 extending linearly in the radial direction from the axis. Each notch 31 is not formed in the vicinity of the disc-shaped shaft core, but is formed in the vicinity of the edge portion. The surface 30a of the upper surface of the tray surface member 30 serves as a mounting surface and a design surface, and the upper surface 30a may be surface-treated to enhance the design.

The tray surface member 30 has an engaging claw 32 that projects downward and the tip of the tray surface member 30 projects downward and one side in the circumferential direction on the peripheral edge of the substantially disk-shaped lower surface 30b (see FIG. 2). The engaging claw 32 has a substantially L shape when viewed from the outer peripheral surface side. A plurality of engaging claws 32 are arranged at equal intervals in the circumferential direction of the tray surface member 30. In this embodiment, the two engaging claws 32, 32 are formed at the ends in the directions forming an angle of 45 ° with respect to the left-right direction and the front-rear direction, respectively.

As shown in FIG. 2, the elastic member 33 has a plate-shaped (substantially triangular-shaped) outer shape, and has an elastic protruding portion 34 protruding upward. The elastic protrusion 34 is formed so as to extend linearly from the center (center of gravity) of a substantially triangular shape toward each corner. The elastic protrusion 34 is provided with a notch 35 along the extending direction thereof. The elastic protrusion 34 is formed in a substantially U shape so as to surround the notch 35 when the elastic member 33 is viewed from above.
The elastic protrusion 34 is formed so as to penetrate the notch 31 of the tray surface member 30 and its tip protrudes from the surface 30a of the tray surface member 30. The elastic protruding portion 34 is formed so that its protruding tip surface forms a surface substantially parallel to the upper surface 30a of the tray surface member 30.
The elastic protrusion 34 is made of a material that can be elastically deformed. The elastically deformable material is made of a material that is harder than the decorative member 36 (the rigid protrusion 37 described later) (for example, a material having high hardness and rigidity), and specifically, rubber, elastomer, and the like can be selected.
As shown in FIG. 2, the decorative member 36 has a plate-shaped (substantially triangular-shaped) outer shape, and has a rigid protruding portion 37 protruding upward. The rigid protrusion 37 is formed so as to extend linearly from the center (center of gravity) of a substantially triangular shape toward each corner.

The rigid protrusion 37 is formed so as to penetrate the notch 31 of the tray surface member 30 and project its tip from the surface 30a of the tray surface member 30. Further, the rigid protrusion 37 is formed so that the tip surface thereof forms a surface substantially parallel to the upper surface 30a of the tray surface member 30. The rigid protrusion 37 has a shape that substantially coincides with the inner peripheral surface of the notch of the tray surface member 30.
The decorative member 36 is made of resin. A plating layer (plating film) is formed on the surface of the rigid protrusion 37.

The tray base material 38 is a substantially disk-shaped member that moves up and down by the height adjusting means 5. The tray base material 38 holds (fixes) the tray surface member 30 detachably. The substantially disk-shaped tray base material 38 is formed at positions corresponding to the engaging recesses 39 in which the two engaging claws 32 and 32 are engaged.

As shown in FIG. 2, the engaging recess 39 is composed of a defect portion of a substantially disk-shaped end edge portion. The radial width of the engaging recess 39 coincides with the radial width of the engaging claw 32. The engaging recess 39 has a protrusion 390 that regulates the engagement claw 32 from shifting to the other side in the circumferential direction when the engaging claw 32 is engaged with one end side. A groove 391 extending along the circumferential direction is formed inside the protrusion 390 in the radial direction. The groove 391 has the other end in the circumferential direction opened at the engaging recess 39. The arm portion 392 sandwiched in the radial direction by the engaging recess 39 and the groove 391 can be elastically deformed in the radial direction due to its own elasticity. When the arm portion 392 is deformed (transferred) inward in the radial direction, the groove 391 allows the arm portion 392 to be displaced.
The tray 3 holds (fixes) the tray surface member 30 on the tray base material 38 with the decorative member 36 and the elastic member 33 arranged between them.

To fix the tray surface member 30 with the tray base material 38, first, the engaging claw 32 is inserted into the other end side of the engaging recess 39 in the circumferential direction. Then, the tray surface member 30 is rotated to one side in the circumferential direction. The engaging claw 32 shifts in the circumferential direction in the engaging recess 39. The engaging claw 32 that has been displaced in the circumferential direction at the engaging recess 39 comes into contact with the protrusion 390. The engaging claw 32 that further shifts in the circumferential direction pushes the protrusion 390 (and the arm portion 392) inward in the radial direction, and further moves along the circumferential direction. When the engaging claw 32 further shifts in the circumferential direction, the tip portion 320 of the engaging claw 32 shown in FIG. 2 engages with the lower surface of the tray base material 38. At this time, the pushed-in protrusion 390 returns to the original state, and restricts the engagement claw 32 from shifting to the other side in the circumferential direction.

The tray 3 detachably holds (fixes) the tray surface member 30 to the tray base material 38, and forcibly rotates the tray surface member 30 to the other side in the circumferential direction to engage the engaging claws 32. It can be removed by shifting it to the other end side of the engaging recess 39 in the circumferential direction. The operation at the time of removal is the reverse of the above-mentioned operation at the time of fixing.

As shown in the cross-sectional view of the main part in FIG. 3, the tray 3 has a plate-shaped tray main body 40 having an upper surface as a mounting surface and an upward portion from the tray main body 40 so that the tip portion abuts on the object to be placed. It is configured to have a plurality of projecting portions 41 that project. The tray main body 40 of the tray 3 indicates a portion located below the upper surface 30a of the tray surface member 30 of the tray 3, and the protrusion 41 indicates a portion protruding from the upper surface 30a.

The tray body 40 has a tray surface member 30. The protrusion 41 projects upward from the tray body 40 and is formed of a rigid protrusion 37 of the decorative member 36 and an elastic protrusion 34 of the elastic member 33. The rigid protrusion 37 protrudes from the upper surface 30a, and the elastic protrusion 34 is in contact with both sides of the rigid protrusion 37 shown in FIG. 3, and protrudes with a protrusion amount higher than the protrusion height of the rigid protrusion 37. .. Both sides of the elastic protrusion 34 shown in FIG. 3 are in contact with the inner surface of the notch 31.

The height adjusting means 5 is a means for moving the tray 3 up and down. In the height adjusting means 5, the tray base material 38 of the tray 3 is connected, and the tray 3 is moved up and down via the tray base material 38. The structure of the height adjusting means 5 is not limited, and the height adjusting means 5 can be a means for moving the tray 3 up and down in a conventional cup holder. This form is as follows.
The height adjusting means 5 is a means for moving the tray 3 up and down. The height adjusting means 5 includes a pair of rack members 25, a pair of gear members 55, an urging member 53, and a lock mechanism 7.

The pair of rack members 25, 25 are provided in the first groove portion 22a. In the first groove portion 22a, a rack gear 51 is provided on the left side wall 26 of the cup holder 1 among the pair of side walls 26, 26 of each rack member 25. The rack gear 51 extends in the extending direction of the first groove portion 22a, that is, in the vertical direction.

The pair of gear members 55 are provided in the lower part of the tray 3 (tray base material 38). Further, a transmission shaft 54 is rotatably provided in the lower part of the tray 3 (tray base material 38). The transmission shaft 54 has a rod shape and is arranged in the front-rear direction of the cup holder 1, that is, in the radial direction of the tray 3. Gear members 55 are provided at both ends of the transmission shaft 54 in the extending direction.

The gear member 55 is a columnar body and has a pinion gear 55a provided at the outer tip in the circumferential direction and a fitting hole 55b penetrating in the axial direction of the gear member 55. The tip of the transmission shaft 54 is fitted into the fitting hole 55b. In this way, the gear member 55 is integrally fixed to both ends of the transmission shaft 54. Since the pinion gears 55a provided on the pair of gear members 55 have the same number of teeth, they rotate in synchronization with each other.

A pair of holding portions 42, 42 are projected from a portion of the tray 3 facing the first groove portion 22a. Each holding portion 42 has a bearing hole 42a. A gear member 55 is rotatably inserted into the bearing hole 42a. As shown in the cross-sectional view of FIG. 7, the pinion gear 55a at the tip of the gear member 55 meshes with the rack gear 51 of the first groove 22a. As the tray 3 (tray base material 38) moves up and down, the pinion gear 55a moves up and down along the rack gear 51.

Guide protrusions 43 are provided at the lower portions of the pair of holding portions 42, 42, respectively. The guide protrusion 43 projects radially outward from the holding portion 42 and has a pair of tray-side facing surfaces 43a. The pair of tray-side facing surfaces 43a are provided on both the left and right sides of the guide protrusion 43 in the circumferential direction, and each extends in the vertical direction.

Further, the guide protrusion 43 is fitted to the rack member 25 arranged in the first groove 22a so as to be vertically movable. The pair of side walls 26, 26 of the rack member 25 are located on the back side of the rack gear 51 and have groove-side facing surfaces 26a, 26a facing each other in the circumferential direction of the accommodation space 20. The guide protrusion 43 of the tray 3 is inserted into the rack member 25 in the first groove 22a, and the tray-side facing surfaces 43a and 43a face the groove-side facing surfaces 26a and 26a. The tray-side facing surfaces 43a and 43a face each of the groove-side facing surfaces 26a and 26a, respectively, and have a shape corresponding to the shape of the groove-side facing surfaces 26a and 26a. In this embodiment, the groove-side facing surfaces 26a and 26a and the tray-side facing surfaces 43a and 43a are all flat surfaces extending in the vertical direction.

As shown in the enlarged view of the main part in FIG. 8, the guide protrusion 43 is formed by the pair of groove-side facing surfaces 26a and 26a in a state where the guide protrusion 43 is in surface contact with the groove-side facing surfaces 26a and 26a on the pair of tray-side facing surfaces 43a. It is sandwiched. The pair of groove-side facing surfaces 26a and 26a receive a load applied to the tray 3 and maintain the tray 3 in the horizontal direction. When the tray 3 is moved in the vertical direction, the pinion gear 55a moves along the rack gear 51, and the tray-side facing surface 43a of the tray 3 slides on the groove-side facing surfaces 26a and 26a of the first groove portion 22a. Since the guide protrusions 43 are arranged in the first groove 22a with the pair of tray-side facing surfaces 43a in surface contact with the pair of groove-side facing surfaces 26a, the tray 3 wobbles with respect to the holder body 2. There is no. The tray 3 can move up and down in the accommodation space 20 stably and smoothly.

Further, a plate-shaped protrusion 44 is provided on the peripheral edge of the tray 3 and directly above the guide protrusion 43. The protrusion 44 is inserted into the first groove portion 22a together with the guide protrusion portion 43, and is sandwiched between the groove-side facing surfaces 26a and 26a of the first groove portion 22a. The protrusion 44 secures a certain gap between the peripheral edge of the tray 3 and the peripheral wall 21 of the holder body 2 to prevent the tray 3 from interfering with the peripheral wall 21. Therefore, the tray 3 can be smoothly moved up and down.

The urging member 53 is a coil spring and is mounted on the outside of the cylindrical collar 56 through which the transmission shaft 54 is inserted. One end of the urging member 53 is fitted to a pin 54b projecting from the transmission shaft 54, and the other end of the urging member 53 is connected to the lower surface of the tray base material 38 of the tray 3.

The urging member 53 urges the transmission shaft 54 in the direction in which the tray 3 moves upward. In this embodiment, the urging member 53 when the transmission shaft 54 is viewed from the rear side in the front-rear direction urges the transmission shaft 54 in the clockwise rotation direction (clockwise direction). The rotation of the transmission shaft 54 in the clockwise direction causes the pinion gear 55a to move upward while rotating along the rack gear 51. As a result, the tray 3 is moved upward.

A speed shock absorber 57 is provided at the lower part of the tray 3. The speed shock absorber 57 has a fixing portion 57a, a rotating portion 57b rotatable with respect to the fixing portion 57a, and a viscous liquid interposed between the fixing portion 57a and the rotating portion 57b. The fixing portion 57a of the speed shock absorber 57 is fixed to the mounting portion 45 protruding downward from the lower surface of the tray 3 with screws (see FIG. 4). A gear 57c is provided at the tip of the rotating portion 57b. Further, a transmission gear 58 is inserted through the transmission shaft 54 and is integrally fixed to the transmission shaft 54.

The transmission gear 58 meshes with the gear 57c of the speed shock absorber 57. When the transmission shaft 54 rotates, the transmission gear 58 rotates in synchronization with the rotation. When the transmission gear 58 rotates, the gear 57c of the speed shock absorber 57 is rotated. The viscous liquid in the speed shock absorber 57 causes the gear 57c to resist and mitigate abrupt changes in rotational speed. The rotation speed of the gear 57c is relaxed, and a sudden speed change of the transmission shaft 54 is suppressed. When the transmission shaft 54 is about to suddenly increase in rotational speed by the urging member 53, the speed shock absorber 57 alleviates the rapid increase in rotational speed.
As shown in exploded views in FIGS. 2 and 9, the lock mechanism 7 locks the tray 3 to the lowest position. The lock mechanism 7 includes a lock member 71, a regulation unit 81, a lock urging member 76, and an operation unit 8.

As shown in the enlarged view of the main part in FIG. 10, the lock member 71 has a flat plate shape, and has a rotation center portion 71c protruding upward and downward and a pair of arms extending in opposite directions from the rotation center portion 71c. It has a portion 71b and a locking portion 71a provided at the tip of each arm portion 71b. As shown in FIG. 10, the lower surface of the locking portion 71a has an inclined surface 71f that inclines upward toward the regulating portion 81 side.

An upper cover 72 and a lower cover 73 are arranged on the upper side and the lower side of the lock member 71. A lock member 71 is arranged between the upper cover 72 and the lower cover 73, and the convex rotation center portion 71c of the lock member 71 is inserted into the center hole 72a of the upper cover 72 and the center hole 73a of the lower cover 73. In this state, the screw 78 is screwed into the lock member 71 through the center hole 73a of the lower cover 73, through the rotation center of the lock urging member 76. The screw 79 is screwed into the screw hole 47 of the tray 3 through the boss portion 73b of the lower cover 73 and the screw hole 72b of the upper cover 72. As a result, the lock member 71 is rotatably held by the tray 3. The locking portion 71a of the lock member 71 is arranged in the second groove portion 22b.

The lock urging member 76 is a torsion coil spring. One end of the lock urging member 76 is locked to the spring holding portion 71d provided on the arm portion 71b of the lock member 71, and the other end of the lock urging member 76 is locked to the protruding portion 73c of the lower cover 73. ing. The lock member 76 urges the lock member 71 in a direction in which the lock member 71 is locked to the regulation portion 81. In this embodiment, the lock urging member 76 urges the lock member 71 in the clockwise rotation direction (clockwise direction) when the lock member 71 is viewed from above.

The operation unit 8 has a knob 82, a case 83, a support shaft 84, and an operation rod 85. The operation unit 8 is arranged on the outside of the peripheral wall 21 of the holder body 2 and in the vicinity of the second groove portion 22b. The knob 82 includes a pressing portion 82a, a slide portion 82b protruding from the pressing portion 82a, a through hole 82c formed in the slide portion 82b and penetrating in the vertical direction, and play holes 82d formed on both side surfaces of the slide portion 82b. And have. The knob 82 is arranged so as to be able to advance and retreat in the operation hole 21c formed in the peripheral wall 21 of the holder main body 2. The pressing portion 82a of the knob 82 is exposed from the operation hole 21c to the accommodation space 20 side, and the sliding portion 82b is directed to the outside of the peripheral wall 21.

The play hole 82d is a guide hole that inclines upward in the direction away from the accommodation space 20 (outward in the radial direction of the holder body 2). The case 83 has a tubular accommodating portion 83a into which the sliding portion 82b of the knob 82 can be moved forward and backward, a through hole 83b that penetrates the accommodating portion 83a in the vertical direction, and a flange portion 83c that extends to the outside of the accommodating portion 83a. Have. An elongated hole 83d extending in the vertical direction is formed on both side surfaces of the accommodating portion 83a. The inner surface of the slide portion 82b of the knob 82 (the surface on which the spring holding portion 82e protrudes in FIG. 9) and the inner surface of the accommodating portion 83a of the case 83 (the surface facing the spring holding portion 82e in FIG. 9). A spring 86 is interposed between them. The spring 86 is extrapolated to the spring holding portion 82e projecting from the back surface of the slide portion 82b of the knob 82. The knob 82 is urged by the spring 86 in the direction of advancing toward the accommodation space 20 side from the operation hole 21c of the holder main body 2.

The operation rod 85 has a long portion 85b, a connecting portion 85c having a narrowed width on the upper side of the long portion 85b, and a support hole 85d provided in the connecting portion 85c. A thin columnar spring holding portion 85e is provided from the lower part of the operating rod 85. A return spring (compression spring) 87 is extrapolated to the spring holding portion 85e. The return spring 87 is a compression coil spring, which is arranged between the outer peripheral edge of the bottom plate 9 of the holder body 2 and the lower portion of the operation rod 85, and urges the operation rod 85 upward.

The balance between the urging force of the return spring 87 and the lock urging member 76 is such that the swinging force of the lock member 71 generated by the lock urging member 76 is smaller than the upward return force of the regulating portion 81 generated by the return spring 87. Is set to.

In order to assemble the operation unit 8, the slide portion 82b of the knob 82 is accommodated in the accommodating portion 83a of the case 83. The connecting portion 85c of the operating rod 85 is inserted into the through hole 83b of the case 83. The support shaft 84 is inserted into the play hole 82d of the slide portion 82b, the elongated hole 83d of the accommodating portion 83a, and the support hole 85d of the operation rod 85. Retaining rings (not shown) are fitted to both ends of the support shaft 84 to prevent them from coming off. As a result, the knob 82, the case 83, the operation rod 85, and the support shaft 84 are integrated to obtain the operation unit 8.

A regulation portion 81 is provided below the operation rod 85. The regulation unit 81 projects from the lower part of the operation rod 85 toward the rear side of the vehicle. The lower side surface of the regulating portion 81 has an inclined surface 81a that inclines upward toward the tip end. The operation rod 85 is arranged in the vicinity of the groove on the left side of the second groove 22b on the outside of the peripheral wall 21 of the holder body 2.

One of the left and right groove portions (the groove portion on the left side in this embodiment) of the second groove portion 22b is provided with an insertion hole 22c at the lower portion thereof. The insertion hole 22c is formed continuously on one of the side walls 23 and the back wall 24 of the side walls facing each other in the second groove 22b.
The regulating unit 81 is configured to be displaced in the vertical direction by the operation of the operating unit 8. The locking portion 71a of the locking member 71 is in contact with the inclined surface 81a of the regulating portion 81 so as to be separable.

(Operation of cup holder)
The operation of the cup holder 1 of this embodiment will be described. First, a case where the tray 3 is held at the lowest position will be described. The dotted line in FIG. 4 indicates a state in which the tray 3 is held at the lowest position. In this case, as shown in FIG. 10, since the regulating portion 81 is arranged on the upper side of the locking portion 71a of the locking member 71 and the locking portion 71a is locked to the regulating portion 81, the locking member 71 is on the upper side. The tray 3 is locked at the lowest position in the accommodation space 20 without being able to move to.

As shown in FIG. 9, when the pressing portion 82a of the knob 82 is pushed into the operation hole 21c, the knob 82 slides outward in the radial direction. The support shaft 84 is moved downward relative to the play hole 82d provided in the knob 82. With the downward movement of the support shaft 84, the operating rod 85 is moved downward, and the regulating portion 81 is moved downward. As shown in FIG. 10, the inclined surface 81a of the regulating portion 81 pushes the locking portion 71a of the locking member 71 toward the tip end side of the regulating portion 81. The lock member 71 rotates toward the tip end side (rear direction in FIG. 10) of the regulating portion 81 against the urging force of the lock urging member 76. The locking portion 71a of the lock member 71 is separated from the inclined surface 81a of the regulating portion 81 and is movable upward in the groove portion 22b. The locking portion 71a moves upward in the second groove portion 22b. That is, the pinion gear 55a is rotated by the urging member 53 and moves upward along the rack gear 51. As shown in FIG. 4, the tray 3 is moved upward in the accommodation space 20.

Here, as shown in FIG. 4, the pinion gear 55a is connected to a transmission shaft 54 provided with a speed shock absorber 57. The sudden change in the rotation of the pinion gear 55a is suppressed by the speed shock absorber 57. Therefore, the pinion gear 55a rises while rotating at a low speed along the rack gear 51. The tray 3 ascends the accommodation space 20 at a low speed.

As shown in FIG. 11, when the tray 3 is stopped at the uppermost position, the locking portion 71a of the locking member 71 is formed in the side wall 23 of the second groove 22b by the urging force of the locking member 76. Inserted into 22h, the vertical movement of the lock member 71 is stopped. As a result, the ascending of the tray 3 is stopped, and the tray 3 stays at the uppermost position. At this time, as shown by the solid lines in FIGS. 1 and 4, the tray 3 is located at the same height as the upper wall 28 of the holder body 2. Therefore, the tray 3 is visually recognized integrally with the upper wall 28 of the holder main body 2, and the appearance is good.

In this embodiment, when the tray 3 is located at the uppermost position, the upper surface of the tray 3 is located at the same height as the upper wall 28 of the holder body 2, but the engaging hole provided in the second groove 22b. By changing the height of 22h up and down, the uppermost position of the tray 3 can be freely adjusted.

The second groove 22b regulates the uppermost position of the tray 3 by locking the locking portion 71a of the lock member 71 to the engaging hole 22h, but the tray is located at the upper end 22f of the second groove 22b. The rise of the tray 3 can also be restricted by bringing the protrusion 44 protruding from the peripheral edge of the tray 3 into contact with the protrusion 44.

As shown in FIGS. 4 and 7, the tray 3 located at the uppermost position is pushed downward. Then, the pinion gear 55a moves downward along the rack gear 51 against the urging force of the urging member 53, and the tray 3 is moved below the accommodation space 20.

As shown in FIG. 11, the locking portion 71a of the locking member 71 hits the upper end portion 81b of the regulating portion 81 protruding from the insertion hole 22c into the second groove portion 22b. The inclined surface 71f on the lower surface of the locking portion 71a of the lock member 71 forms a gentle slope. The urging force of the lock urging member 76 is smaller than the urging force of the return spring 87. Therefore, the locking portion 71a of the lock member 71 gradually slides on the upper end portion 81b of the regulating portion 81 as it descends, and swings toward the tip end side of the regulating portion 81. When the tray 3 is further moved downward, the locking portion 71a of the locking member 71 deviates from the upper end portion 81b of the regulating portion 81 and moves downward along the end surface of the tip of the regulating portion 81, and is further moved below the regulating portion 81. It is placed on the lower side. At this time, the lock member 71 abuts on the inclined surface 81a of the regulation portion 81 while swinging toward the regulation portion 81 by the urging force of the lock urging member 76. As a result, as shown by the dotted line in FIG. 11, the lock member 71 is locked to the regulation portion 81, and the tray 3 is held in the lower part of the accommodation space 20.

Although the regulating portion 81 is provided on the operation rod 85, the insertion hole 22c formed in the second groove portion 22b may be the regulating portion. When the insertion hole 22c is a restricting portion, the locking portion 71a of the lock member 71 is locked in the insertion hole 22c. When the operating portion 8 is operated, the locking portion 71a is pushed out from the insertion hole 22c by the operating rod 85 to release the locking portion 71a from the insertion hole 22c.

As shown in FIG. 4, a pinion gear 55a is rotatably supported on the tray 3. The pinion gear 55a meshes with a rack gear 51 provided on the peripheral wall 21 of the holder body 2. The pinion gear 55a moves upward while rotating on the rack gear 51 due to the urging force of the urging member 53. The tray 3 supporting the pinion gear 55a is also moved upward.
When the tray 3 is pushed downward, the pinion gear 55a is moved downward together with the tray 3 while rotating on the rack gear 31 against the urging force of the urging member 53.

Here, the urging member 53 is provided on the tray 3. That is, the urging member 53 does not connect the holder main body 2 and the tray 3 to suspend the tray 3 with respect to the holder main body 2. Therefore, in this embodiment, the urging member 53 does not limit the ascending position of the tray 3. The tray 3 of this embodiment has a high degree of freedom in the elevating position and a high degree of freedom in setting the uppermost position of the tray 3.

The balance between the urging force of the return spring 87 and the lock urging member 76 is such that the swinging force of the lock member 71 generated by the lock urging member 76 is smaller than the upward return force of the regulating portion 81 generated by the return spring 87. It is better to set to. As a result, even if the lock member 71 hits the regulating portion 81 when the tray 3 is pushed down, the regulating portion 81 is prevented from moving. Since the movement of the regulating unit 81 is restricted, the operating unit 8 is not displaced either. When the tray 3 moves to the lowest position, the lock member 71 can be securely locked to the regulation portion 81. The tray 3 can be securely locked to the lowest position.

In the cup holder 1 of the present embodiment, by pushing (pushing down) the tray 3 downward, the tray 3 moves downward and is held at the lowest position. The tray 3 is pushed down by pressing the container for beverages (the object to be placed on the tray 3) held in the cup holder 1 against the tray 3 (upper surface of the tray 3).

In the cup holder 1 of the present embodiment, the mounting surface of the tray 3 is a plurality of protrusions 41 (from the upper surface 30a) whose mounting surface is projected upward from the upper surface of the tray main body 40 (upper surface 30a of the tray surface member 30) and the tray main body 40. It is composed of a protruding elastic protrusion 34) and a rigid protrusion 37).

When the object to be placed is pressed against the upper surface of the tray 3 in an attempt to push down the tray 3, the object to be placed first comes into contact with the protrusion 41 (of which the elastic protrusion 34). Then, when the object to be placed is further pressed against the upper surface of the tray 3, the elastic protrusion 34 is elastically deformed so as to fall toward the rigid protrusion 37 or the upper surface 30a of the tray surface member 30.

When the object to be placed is further pressed against the upper surface of the tray 3, the object to be placed presses the upper surface 30a and the rigid protrusion 37 via the rigid protrusion 37 and the elastic protrusion 34 deformed so as to fall. At this time, since the object to be placed presses the upper surface 30a of the tray surface member 30 through the rigid protrusion 37 or the deformed elastic protrusion 34, the object to be placed comes into direct contact with the upper surface 30a of the tray surface member 30. Is regulated.

The cup holder 1 of the present embodiment is formed so that the plurality of protrusions 41 pass through two points having different radial positions with respect to the peripheral wall 21. According to this configuration, the protrusions are suppressed from being formed along the circumferential direction. That is, even if the object to be placed has a circular outer bottom surface such as a beverage container, the shape is such that the object does not fit into the portion where the plurality of protrusions 41 are not formed at the axial center portion. .. That is, it is suppressed that the object to be placed comes into contact with the tray main body 40.
As described above, the cup holder 1 of the present embodiment is configured such that the object to be placed presses the protrusion 41 and the object to be placed does not come into direct contact with the tray main body 40.

(Effect of this form)
The cup holder 1 of this embodiment includes a holder body 2 and a tray 3. The holder body 2 has a storage space 20 surrounded by a peripheral wall 21. The tray 3 is housed in the storage space 20 and is supported by the holder body 2 so as to be vertically movable, and has a mounting surface on the upper surface on which the mounted object is placed. The tray 3 includes a plate-shaped tray main body 40 having an upper surface 30a as a mounting surface, and a plurality of protrusions 41 protruding upward from the tray main body 40 so that the tip end abuts on the object to be placed. Has. The protrusion 41 is formed so as to form a linear shape passing through two points having different radial positions with respect to the peripheral wall 21.

In the cup holder 1 of the present embodiment, a protrusion 41 projecting upward is formed on the upper surface 30a of the tray 3 that moves up and down in the accommodation space 20 of the holder body 2. In the cup holder 1 of this embodiment, the upper surface 30a of the tray 3 is a design surface and a mounting surface. By having the protrusion 41 on the upper surface, contact between the tray main body 40 (tray surface member 30) and the object to be placed (container for beverages or the like) can be suppressed. As a result, scratches on the design surface formed by the tray body 40 (upper surface 30a of the tray surface member 30) are suppressed, and deterioration of the design is suppressed.
Further, the cup holder 1 of the present embodiment has a configuration in which the tray 3 moves up and down in the accommodating space 20 of the holder main body 2. This configuration is different from the conventional configuration in which the tray rotates, and can be formed with a simple configuration.

In the cup holder 1 of the present embodiment, the protrusion 41 is formed so that at least the tip thereof can be elastically deformed. According to this configuration, the tip portion that comes into contact with the object to be placed first is elastically deformed, so that the elastically deformed protrusion 41 (specifically, the elastically deformed elastic protrusion 34) is placed on the tray body 40. Contact with figurines can be reliably regulated.

In the cup holder 1 of the present embodiment, the protruding portion 41 supports the elastically deformable tip portion (the portion protruding from the rigid protruding portion 37 of the elastic protruding portion 34) and the tip portion on the proximal end side in the protruding direction. It has a rigid support portion (rigid protrusion 37) that is harder than the portion. According to this configuration, the tip end portion of the protrusion 41 can be brought into contact with the object to be placed first to cause elastic deformation.
In the cup holder 1 of the present embodiment, the protrusion 41 has a linear shape extending along the radial direction. According to this configuration, it is possible to reliably prevent the tray main body 40 from coming into contact with the object to be placed (container for beverages or the like).

In the cup holder 1 of the present embodiment, the tray main body 40 (tray surface member 30) is housed in the storage space 20 and can be moved up and down. It is held in a state of being. According to this configuration, the tray main body 40 (tray surface member 30) can be replaced. When the object to be placed is a beverage container, even if the beverage spills and adheres to the tray main body 40, it can be removed and washed.

In the cup holder 1 of the present embodiment, the tray body 40 is formed of a plate-shaped member (tray surface member 30) having a notch 31 at a position corresponding to the protrusion 41, and the protrusion 41 has the notch 31. It has an elastic protrusion 34 made of an elastically deformable material that penetrates and projects upward, and a rigid protrusion 37 that is arranged adjacent to the elastic protrusion 34 and supports the elastic protrusion 34. According to this configuration, the tip end portion of the protrusion 41 can be brought into contact with the object to be placed first to cause elastic deformation.

[Transformed form]
In the embodiment, an example in which the protrusions 41 are three linear shapes is shown, but the shape of the protrusions 41 is not limited to this shape, and can be appropriately determined by the shape of the bottom surface of the beverage container or the like. That is, the shape may be a combination of linear and curved shapes so that the bottom surface of the beverage container or the like does not come into direct contact with the upper surface 30a of the tray surface member 30.

Further, the height adjusting means for moving the tray 3 up and down is not limited to the height adjusting means 5 of the embodiment. This embodiment can be applied as long as the tray 3 can be moved up and down in the accommodation space 20. For example, in the embodiment, the tray 3 is pushed down by pressing the object to be placed against the tray 3, but the present invention is not limited to this mode. That is, it may be a height adjusting means that can achieve the downward displacement of the tray 3 by a mechanism that does not rely on manual operation.

1: Cup holder 2: Holder body, 20: Storage space, 21: Peripheral wall, 22 grooves 3: Tray, 30: Tray surface member, 31: Notch, 32: Engagement claw, 33: Elastic member, 34: Elastic protrusion Part, 35: Notch, 36: Decorative member, 37: Rigid protrusion, 38: Tray base material, 39: Engagement recess, 390: Projection, 391: Groove, 40: Tray body, 41: Projection 5: Height adjusting means, 51: Rack gear, 53: Biasing member, 54: Transmission shaft, 55: Gear member, 57: Speed shock absorber 7: Lock mechanism, 71: Lock member, 76: Lock urging member, 81 : Regulator, 82: Knob, 83: Case, 84: Support shaft, 85: Operation rod,
8: Operation unit

Claims (6)

A holder body having a storage space surrounded by a peripheral wall, and a tray having a mounting surface on the upper surface, which is housed in the storage space and supported by the holder body so as to be vertically movable.
It is a cup holder equipped with
The tray is
A plate-shaped tray body whose upper surface is the above-mentioned mounting surface, and
A plurality of protrusions protruding upward from the tray main body so that the tip portion abuts on the object to be placed,
Have,
The protrusion has an elastically deformable tip and a rigid support that supports the tip on the base end side in the protrusion direction and is harder than the tip, and has a radial direction with respect to the peripheral wall. A cup holder characterized in that it is formed so as to form a linear shape passing through two different points. The cup holder according to claim 1 , wherein the tray body is housed in the storage space and is held in a detachable state on an upper portion of a base supported by the holder body so as to be vertically movable. The tray body is formed of a plate-shaped member having a notch at a position corresponding to the protrusion.
The protrusion is made of an elastically deformable material that penetrates the notch and projects upward, and is arranged adjacent to the elastic protrusion forming the tip and the elastic protrusion. The cup holder according to claim 2 , further comprising a rigid protrusion that supports and forms the rigid support portion. A holder body having a storage space surrounded by a peripheral wall, and a tray having a mounting surface on the upper surface, which is housed in the storage space and supported by the holder body so as to be vertically movable. It is a cup holder equipped with
The tray is
A plate-shaped tray body whose upper surface is the above-mentioned mounting surface, and
A plurality of protrusions protruding upward from the tray main body so that the tip portion abuts on the object to be placed,
Have,
The tray body is formed of a plate-shaped member having a notch at a position corresponding to the protrusion, and is housed in the storage space and can be moved up and down. It is held in a state of
The protrusions include an elastic protrusion made of an elastically deformable material that penetrates the notch and protrudes upward, and a rigid protrusion that is arranged adjacent to the elastic protrusion and supports the elastic protrusion. The cup holder is formed so as to form a linear shape passing through two points having different radial positions with respect to the peripheral wall. The cup holder according to claim 4, wherein the rigid protrusion supports the elastic protrusion on the base end side in the protrusion direction. The cup holder according to any one of claims 1 to 5 , wherein the protrusion has a linear shape extending along the radial direction.

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