JP6442335B2 - Locking device - Google Patents

Description

  The present invention relates to a locking device that can be used in a vehicle mounting device such as a glove box.

  Many automobiles have a glove box on the passenger seat side of the instrument panel for storing vehicle inspections and personal accessories. The glove box is put in and out of an article in an open posture inclined toward the passenger compartment, and is held so as not to be opened by the lock device in a closed posture accommodated in the instrument panel. For example, the lock device has a configuration in which two rods on the left and right sides that are engaged with and disengaged from the instrument panel are connected by a rack and pinion mechanism, and one rod moved by the operation knob is linked to the other rod (see Patent Document 1). ). Another locking device includes a link member having two arms extending in opposite directions in the radial direction from the rotating shaft, and two left and right rods connected to the extending ends of the arms, and the link member. There is a configuration in which the two rods are interlocked with each other as they are rotated by the operation knob (see Patent Document 2). The locking devices disclosed in Patent Documents 1 and 2 move so that one rod retracts from the instrument panel, and the other rod also moves so as to retract from the instrument panel. Thus, since the left and right rods operate in synchronism, it is possible to avoid problems such as the other rod not catching on the instrument panel regardless of whether one rod is caught on the instrument panel.

Japanese Patent No. 4197941 Japanese Patent No. 4444724

  The locking device of Patent Document 1 has a problem that rattling, gear noise, and the like are generated due to backlash (gap) required between the rack and the pinion. In addition, since the locking device of Patent Document 2 connects a rod that is displaced linearly to an arm that is displaced in a circular arc shape, a play (gap) is required at a connecting portion between the arm and the rod. May cause rattling or synchronization shift. In particular, when used in an automobile, abnormal noise may be generated due to vibration during traveling, and therefore it is required to reduce the gap between the constituent members in the lock device. However, if the clearance between the structural members is reduced in the locking device, another problem such as an increase in the operation load due to interference between the structural members is caused.

  That is, the present invention has been proposed to solve these problems in view of the above-described problems related to the prior art, and has a simple configuration and allows two hooks to be interlocked with each other. It aims at providing the locking device which can control generating.

In order to overcome the above-mentioned problems and achieve the intended purpose, the locking device of the invention according to claim 1 of the present application provides:
In a locking device that reciprocally displaces two hooks in opposite directions to lock or unlock,
An interlocking structure that transmits force between the two collars by means of two flexible couplings that are laid between the two collars and have a displacement. Guide means for guiding the linkage structure to be deformed,
The linkage portion is provided between two curved portions that bend in a direction crossing the displacement direction of the heel portion as it goes from each heel portion to the middle of the two heel portions, and between the two curved portions, A folded portion that bends so that the convex faces in the direction intersecting the displacement direction of the portion,
In the linkage structure, the folded portions of the two linkage portions are provided in directions opposite to each other,
The guide means is provided on the inner side of the linkage structure surrounded by the two linkage portions, and an inner guide portion that guides the curved portion bent in a convex shape toward the inner side of the linkage structure, and the linkage structure An outer guide portion provided outside the body and guiding the curved portion;
The gist of the present invention is that the linkage structure is configured so that the two flange portions are displaced in opposite directions by the linkage structure in which the curved shape of the curved portion is defined by the inner guide portion and the outer guide portion. To do.
According to the first aspect of the present invention, the two flanges can be displaced in opposite directions with a simple configuration by deformation of the linkage structure itself. Since the two flanges are displaced in opposite directions by deformation of the linkage structure itself, it is possible to prevent occurrence of problems such as generation of abnormal noise and synchronization deviation due to gaps between the structural members of the locking device. be able to. In addition, since the linkage structure is configured to transmit force between the two flanges divided into two linkage portions, it is possible to suppress the bias of the force accompanying the change in the direction of the force by the linkage portion, Force can be stably transmitted to the two buttocks.

The gist of the invention according to claim 2 is that the linking portion is configured such that the folded portion bent in an arc shape is elastically deformed.
According to the invention which concerns on Claim 2, when a collar part is displaced so that the folding | returning part of a connection part may be elastically deformed, it assists to displace in the direction which returns a collar part with the restoring force of this folding | turning part. Can do.

The gist of the invention according to claim 3 is that the two linkage parts are formed in a symmetrical shape.
According to the third aspect of the present invention, since the bias of the force applied to the two linkage parts can be suppressed, the force can be stably transmitted to the two collar parts.

In the invention according to claim 4, the linkage portion is formed in a plate shape, and the curved portion is bent in the thickness direction and is formed in an arc shape that is convex toward the inside of the linkage structure,
The inner guide portion has an inner guide surface formed in a concave shape in accordance with the convex shape of the curved portion,
The outer guide portion is formed with a convex outer guide surface in accordance with the concave shape of the curved portion,
The gist is that the inner guide surface and the outer guide surface are spaced apart according to the thickness of the linkage portion.
According to the fourth aspect of the present invention, since the curved portion of the linkage portion can be appropriately guided by the guide means, it is possible to suppress the loss of force due to the change in the direction of the force caused by the linkage portion. Force can be stably transmitted to the buttocks.

In the invention according to claim 5, the linkage structure is set so that at least one edge in the plate width direction protrudes from the inner guide portion and the outer guide portion,
The gist of the linking structure is that the edge protruding from the inner guide portion and the outer guide portion is in contact with a cushioning portion having cushioning properties.
According to the invention of claim 5, since the edge protruding from the inner guide portion and the outer guide portion is in contact with the buffer portion in the linkage structure, play in the plate width direction in the linkage structure is suppressed, and this play is prevented. The occurrence of abnormal noise can be suppressed.

  According to the locking device of the present invention, it is possible to interlock the two buttocks with a simple configuration and to suppress the generation of abnormal noise.

It is a schematic perspective view which shows the instrument panel provided with the glove box by which the locking device based on the suitable Example of this invention was arrange | positioned. It is a schematic perspective view which shows the glove box by which the locking device of the Example was arrange | positioned. It is a rear view which shows the lid of the glove box of an Example. In the lid of an Example, it is a rear view of the locking device shown in the state which removed the backplate part. FIG. 4 is a sectional view taken along line AA in FIG. 3. In the locking device of the embodiment, (a) is a schematic perspective view showing the linkage structure and the guide means in an exploded state, and (b) is a schematic perspective view showing the linkage structure and the guide means assembled. It is. In the lock device of the embodiment, it is a rear view showing the linkage structure and the guide means, (a) is a state corresponding to when the collar portion is in the locked position, (b) is a state in which the collar portion is unlocked position It is a state corresponding to when there is. It is a rear view which shows the linkage structure of an Example, (a) is a state corresponding when a collar part exists in a lock position, (b) is a state corresponding when a collar part is in a lock release position. It is.

  Next, a preferred embodiment of the locking device according to the present invention will be described below with reference to the accompanying drawings. In the embodiment, a case where the locking device according to the present invention is applied to a glove box as a vehicle mounting device will be described.

  As shown in FIG. 1 and FIG. 2, a glove box 20 according to an embodiment includes a box-shaped box body 22 that is disposed inside the instrument panel 10 and opens to the passenger compartment side, and a lower portion of the box body 22. And a lid 24 that opens and closes the opening of the box body 22. The glove box 20 is configured such that the lid 24 forms a part of the design surface of the instrument panel 10 in a closed position in which the opening of the box body 22 is closed, and the lid 24 is closed in a closed position by a lock device 30 (see FIG. 4). Is retained. In addition, the glove box 20 can be opened by opening the box body 22 by tilting toward the passenger compartment with the hinge at the lower portion of the lid 22 as a fulcrum by releasing the lock by the lock device 30 by operating the operation button 32. It has become.

  As shown in FIGS. 2 to 4, the lid 24 constitutes a front plate portion 26 that forms a surface facing the passenger compartment, and a back surface that is attached to the back side of the front plate portion 26 and faces the inside of the box body 22. The back plate portion 28 is configured. In the lid 24 of the embodiment, the front plate portion 26 and the back plate portion 28 are assembled by joining the welding ribs 26a formed on the back surface of the front plate portion 26 to the back plate portion 28 by vibration welding. ing. Further, the lid 24 is provided with a device accommodating space 24a between the front plate portion 26 and the back plate portion 28, and a lock device 30 is disposed in the device accommodating space 24a.

  As shown in FIG. 4, the locking device 30 is provided between the two flange portions 34, 34 disposed so as to be displaceable in the left-right direction with respect to the lid 24, and the two flange portions 34, 34. The linkage structure 36 is provided. In the embodiment, the two flange portions 34 and 34 and the linkage structure 36 are configured as separate members, thereby improving the degree of freedom in designing the flange portion 34 and the linkage structure 36. The locking device 30 is interlocked so that the two flange portions 34 and 34 are displaced toward and away from each other in the left-right direction by a linkage structure 36 that is deformed while being guided by the guide means 38 provided on the lid 24. . The locking device 30 is configured such that one end portion of the flange portion 34 protrudes outward from each of the flange openings 24b (see FIG. 3) opened on the left and right side surfaces of the lid 24. The locking device 30 inserts one end portion of the collar portion 34 into an engagement opening (engagement portion) 22 a (see FIG. 3) provided in the box body 22, thereby restricting the opening of the lid 24 and closing it. It is designed to hold in a posture. In addition, the locking device 30 is operated by the other collar 34 in conjunction with the fact that one collar 34 is pushed toward the device accommodating space 24a and comes out of the engagement opening 22a by the operation of the operation button 32 of the user. It is comprised so that it may be drawn in to the accommodation space 24a side and may come out from the engagement opening 22a. Thus, the locking device 30 is configured to lock or unlock by reciprocally displacing the two flange portions 34, 34 in opposite directions.

  As shown in FIG. 4, the flange portion 34 is formed in a rod shape extending in the left-right direction which is the insertion / removal direction with respect to the engagement opening 22 a. The two eaves 34 and 34 arranged in the apparatus housing space 24a side by side are arranged such that one end portions facing opposite sides protrude from the eaves opening 24b to the outside of the lid 24 and the other end portions facing each other. Each is linked to the linkage structure 36. The flange 34 is held at one end by a support opening (not shown) formed in the support 27 formed on the back surface of the front plate 26, and the front and rear and the vertical direction (crossing the displacement direction of the flange 34). Movement in the direction of movement) is restricted. The flange 34 has a lock position in which one end protrudes from the flange opening 24b and can be engaged with the engagement opening 22a, and the protrusion from the flange opening 24b becomes smaller than the lock position so that the protrusion 34 can be engaged with the engagement opening 22a. It can slide between the retractable lock release position. Note that the flange portion 34 has a rigidity that does not deform even if it interferes with the box main body 22 during engagement with the engagement opening 22a. A tapered surface 34a is formed at one end portion of the flange portion 34 so as to be inclined inwardly from the front side toward the rear side. When the lid 24 is closed, the flange portion 34 is locked by the tapered surface 34a that is in contact with the box body 22. It is guided to be displaced from the position toward the unlocking position.

  As shown in FIGS. 6 to 8, the link structure 36 includes two link portions 40 and 40 having flexibility, and connection portions provided at the ends of the two link portions 40 and 40, respectively. 42 and 42, and two link parts 40 and 40 are constructed between a pair of connection parts 42 and 42 spaced apart on either side. Further, the linkage structure 36 is connected to the flange 34 to each of the two connection portions 42, 42. The connecting portion 42 and the flange portion 34 are connected by being hooked in the left-right direction by a fitting structure formed by mutual unevenness, and can be attached and detached by relative displacement in the front-rear direction. In the linkage structure 36, one end of the two linkage portions 40, 40 is connected to one flange portion 34 so that force can be transmitted via the connection portion 42, and two linkage portions 36 are connected to the other flange portion 34. The other ends of the linking portions 40, 40 are connected so as to be able to transmit force via the connection portion 42. The linkage structure 36 transmits a force between the two flange portions 34 and 34 by the two linkage portions 40 and 40 that are installed between the two flange portions 34 and 34. Thus, the two flange portions 34, 34 are displaced in an interlocking direction. Here, in the linkage structure 36, the two linkage portions 40, 40 and the two connection portions 42, 42 are integrally formed by molding a synthetic resin having excellent slipperiness such as polyacetal (POM). Has been.

  As shown in FIGS. 6A and 8, the linkage portion 40 is a plate shape formed thinner than the rod-like connection portion 42, and the whole is elastically deformable in the thickness direction. Each linking part 40 has two places that bend in the vertical direction (direction intersecting the displacement direction of the heel part 34) from the left and right ends connected to the heel part 34 toward the inside (in the middle of the two heel parts 34, 34). One folded portion 40b provided between the curved portions 40a, 40a and the two curved portions 40a, 40a and bent so that the convex faces upward or downward (direction intersecting the displacement direction of the flange 34). And. The linkage structure 36 is provided with folded portions 40b, 40b of the two linkage portions 40, 40 in directions opposite to each other. In other words, the linkage structure 36 is formed in the middle of the two flange portions 34, 34 in the two linkage portions 40, 40, respectively, and is folded back portions 40b, 40b that bend so that the protrusions face in opposite directions. And curved portions 40a and 40a that bend so as to approach each other from the upper and lower folded portions 40b toward the flange portions 34.

  As shown in FIG. 8, each linking part 40 is connected between the curved part 40a and the connecting part 42 via a first extending part 40c extending in the left-right direction, and between the curved part 40a and the folded part 40b. Are connected via a second extending portion 40d extending in the vertical direction. In the linkage structure 36, the first extending portions 40 c and 40 c that are connected to the same connection portion 42 in the two linkage portions 40 and 40 are formed in parallel, and the two second extensions that are connected to the folded portion 40 b in each linkage portion 40. The existing portions 40d and 40d are formed in parallel. Further, the first extending portions 40c, 40c connected to the same connecting portion 42 in the two connecting portions 40, 40 are connected to the upper and lower ends of the connecting portion 42, and the vertical width of the connecting portion 42 (with the displacement direction of the flange portion 34). The vertical width of the two first extending portions 40c, 40c is set to be the same. In addition, two second extending portions 40d and 40d connected to the folded portion 40b in each linking portion 40 have two first extending portions whose left and right widths (dimensions in the displacement direction of the flange portion 34) are arranged vertically. It is set to be the same as the vertical width of 40c, 40c. And the 1st extension part 40c of the connection part 40 is from the displacement direction (displacement direction of the connection part 40) of the collar part 34 to the inner end part on the opposite side to the outer end part to which the collar part 34 is connected in the connection part 42. The power is efficiently transmitted between the link part 40 and the connection part 42.

  As shown in FIG. 8, the linkage structure 36 has two connection portions 42 and 42 (ends connected to the flange portion 34 of the linkage portion 40) spaced apart in the left-right direction. The folded portions 40b, 40b of the linkage portions 40, 40 are arranged side by side in the vertical direction. The linkage structure 36 is formed in an annular shape that surrounds the two connection portions 42, 42 with the two linkage portions 40, 40, and each side has the folded portions 40 b, 40 b and the connection portions 42, 42 as vertices. It is formed in a shape that curves inward. In the linkage structure 36, two linkage portions 40, 40 are formed symmetrically with respect to a line connecting the upper and lower folded portions 40b, 40b, and left and right connection portions 42, 42 (of the linkage portion 40). It is formed vertically symmetrically across a line connecting the ends) connected to the flange 34. That is, the two linking portions 40, 40 are formed in the same symmetrical shape across a line along the displacement direction of the flange portion 34, and each linkage portion 40 defines the folded portion 40b in the displacement direction of the flange portion 34. Are formed in the same symmetrical shape across a line passing in a direction perpendicular to the line.

  As shown in FIG. 8, each curved portion 40 a is formed in an arcuate shape that curves in the thickness direction and protrudes toward the inside of the linkage structure 36 that is surrounded by the two linkage portions 40 and 40. Further, the curved portion 40a is formed in an arc shape extending over a quarter of the circumference in contact with the line along the displacement direction of the flange portion 34 and the line along the direction orthogonal to the displacement direction. Each folded portion 40b is formed to be bent in an arc shape in the thickness direction, and can be elastically deformed so that the two second extending portions 40d and 40d connected to the folded portion 40b are close to and separated from each other. Here, the folded portion 40b is formed to extend in a semicircular arc shape. The linkage structure 36 is formed in a state where the curved portion 40a and the folded portion 40b of the linkage portion 40 are bent, and has a shape capable of holding the two flange portions 34 and 34 in the locked position in a natural state where no external force is applied. (See FIG. 7 (a) and FIG. 8 (a)). Then, in the linkage structure 36, the linkage portions 40, 40 are respectively deformed so that the two folded portions 40b, 40b are separated from each other as the two connection portions 42 are displaced from each other from the natural state. It becomes a shape which can make the two collar parts 34 and 34 into a lock release position (refer FIG.7 (b) and FIG.8 (b)).

  As shown in FIG. 4, the guide means 38 is provided on the back side of the front plate portion 26 in the lid 24 and is accommodated in the device accommodating space 24a. The guide means 38 of the embodiment is formed separately from the front plate portion 24 (see FIG. 6), and is attached by an engagement structure or adhesion by a boss and a locking claw that are raised from the back surface of the front plate portion 26. It has been. The guide means 38 includes an inner guide portion 46 and an outer guide portion 48 that protrude from a plate-like attachment portion 44 that runs along the back surface of the front plate portion 26.

  As shown in FIGS. 6 and 7, the inner guide portion 46 is provided inside the linkage structure 36 surrounded by the two linkage portions 40, 40 and bends in a convex shape toward the inside of the linkage structure 36. It is comprised so that the convex side of the curved part 40a may be guided. The inner guide portion 46 is formed in a wall shape rising from the attachment portion 44 toward the back plate portion 28 side, and the inner guide surface 46a formed in a concave shape in accordance with the convex shape of the curved portion 40a of the linkage portion 40 is curved. It comes into contact with the convex side (inner side) of the portion 40a. The inner guide surface 46a is formed so as to bend in a direction intersecting the displacement direction of the flange 34 as it goes in the direction of displacement of the two flanges 34, 34 close to each other. Moreover, the inner guide surface 46a is formed in the circular arc shape over 1/4 of the circumference which touches the line along the displacement direction of the collar part 34, and the line along the direction orthogonal to the said displacement direction. In the guide means 38, four end portions of the inner guide portions 46 provided corresponding to the two curved portions 40a, 40a of the two linkage portions 40, 40 are connected to each other, and each inner guide is provided. The portion 46 is formed in a substantially rhombic annular shape that curves inward. The four inner guide portions 46 are formed in the same symmetrical shape across the line along the displacement direction of the flange portion 34, and the same symmetrical across the line along the direction orthogonal to the displacement direction of the flange portion 34. It is formed in a shape.

  As shown in FIGS. 6 and 7, the outer guide portion 48 is provided outside the linkage structure 36 surrounded by the two linkage portions 40, 40 and bends in a convex shape toward the inside of the linkage structure 36. It is comprised so that the concave side of the curved part 40a may be guided. The outer guide portion 48 rises from the mounting portion 44 toward the back plate portion 28 side, and the outer guide surface 48a formed in a convex shape in accordance with the concave shape of the curved portion 40a of the linking portion 40 has a concave shape of the curved portion 40a. It comes in contact with the side (outside). The outer guide surface 48a is formed so as to bend in a direction intersecting the displacement direction of the flange 34 as the two flanges 34, 34 move in the displacement direction close to each other. The outer guide surface 48a is formed in an arc shape extending over a quarter of the circumference in contact with the line along the displacement direction of the flange 34 and the line along the direction orthogonal to the displacement direction. The outer guide portion 48 is formed to be connected to one end of the outer guide surface 48a, is formed to be connected to the first guide surface 48b extending in the left-right direction, and the other end of the outer guide surface 48a, and extends in the up-down direction. And a second guide surface 48c. The guide means 38 has four outer guide portions 48 surrounding the four inner guide portions 46 corresponding to the two curved portions 40a, 40a of the two linkage portions 40, 40, respectively. They are separated from each other.

  As shown in FIG. 7, the outer guide portion 48 is provided such that the outer guide surface 48a faces the outer side of the inner guide surface 46a of the inner guide portion 46, and the inner guide surface 46a and the outer guide surface 48a are linked. They are spaced apart according to the thickness of the portion 40. That is, between the inner guide surface 46a and the outer guide surface 48a, a curved guide groove 50 that opens to the back plate portion 28 side extends in an arc shape with a width equal to or slightly wider than the thickness of the linking portion 40. The curved shape of the curved portion 40a of the linking portion 40 is defined by being guided by the curved guide groove 50. Further, the two outer guide portions 48, 48 arranged in the vertical direction are provided so that the first guide surfaces 48b, 48b face each other. The first draft surfaces 48b and 48b that are vertically opposed to each other are spaced apart according to the vertical width of the first extending portions 40c and 40c (connecting portion 42) of the two linking portions 40 and 40. Further, the two outer guide portions 48, 48 arranged side by side are provided so that the second guide surfaces 48 c, 48 c face each other. The second guide surfaces 48c and 48c facing left and right are spaced apart according to the left and right widths of the second extending portions 40d and 40d of the two linking portions 40 and 40. A first displacement guide groove 52 that opens to the back plate portion 28 side is formed between the two first guide surfaces 48b, 48b opposed to each other in the vertical direction, and extends in the left-right direction. 52, the displacement of the first extending portion 40c of the linkage portion 40 and the connecting portion 42 in the vertical direction is restricted. A second displacement guide groove 54 opened to the back plate portion 28 side is formed between the two second guide surfaces 48c, 48c facing left and right so as to extend in the vertical direction. 54, the displacement of the second extending portion 40d and the folded portion 40b of the linkage portion 40 in the left-right direction is restricted. The four outer guide portions 48 have guide surfaces 48a, 48b, and 48c formed symmetrically across a line along the displacement direction of the flange portion 34, and along a direction orthogonal to the displacement direction of the flange portion 34. Guide surfaces 48a, 48b, and 48c are formed in a symmetrical shape across the line.

  As shown in FIG. 6A, the guide means 38 has four curved guide grooves 50 curved inwardly extending in a substantially rhombus-like shape, and the two curved guide grooves 50, 50 are joined together. Displacement guide grooves 52 and 54 are formed so as to be continuous with the respective parts. The guide means 38 is formed with a curved guide groove 50 and displacement guide grooves 52 and 54 in accordance with the linkage structure 36 in the natural state, and deforms the linkage structure 36 in which the curved portion 40a and the folded portion 40b are previously formed. Without being received in the guide grooves 50, 52, 54. When the linkage structure 36 is set in the guide grooves 50, 52, 54 of the guide means 38, the inner guide portion 46 and the connecting portion 42 are separated from each other, and the inner guide portion 46 and the folded portion 40b are separated from each other. To be arranged. The link structure 36 is guided by the curved guide groove 50, and when the left and right connecting portions 42 and 42 (ends connected to the flange portion 34 of the link portion 40) approach each other, the upper and lower folded portions 40b and 40b are mutually connected. When the left and right connecting portions 42 and 42 are separated from each other, the upper and lower folded portions 40b and 40b are close to each other.

  The guide means 38 is formed to be thinner than the distance between the front plate portion 26 and the back plate portion 28, and when the guide means 38 is attached to the front plate portion 26 by vibration welding, the inner guide portion 46 and the outer guide portion 38 are provided. The edge of the part 48 does not interfere with the back plate part 28. As shown in FIG. 5, the inner guide portion 46 and the outer guide portion 48 are set to have the same rising height from the mounting portion 44. On the other hand, the linkage structure 36 is formed wider than the rising height of the inner guide portion 46 and the outer guide portion 48 from the mounting portion 44. The linkage structure 36 is set so that at least one edge in the plate width direction (corresponding to the front-rear direction in the embodiment) protrudes from the inner guide portion 46 and the outer guide portion 48. In the embodiment, the trailing edge in the plate width direction of the linkage structure 36 slightly protrudes from the protruding ends of the inner guide portion 46 and the outer guide portion 48 toward the back plate portion 28 (about 0.1 to 0.3 mm). It is supposed to be. Further, the back plate portion 28 is provided with a buffer portion 56 at a position facing the guide means 38, and the buffer portion 56 is configured to contact the guide means 38 and the linkage structure 36. The buffer part 56 is provided with a cushioning property and a sliding property that does not hinder the displacement of the linkage structure 36, and for example, a nonwoven fabric such as a spunbond made of polyester or the like can be used. The thickness of the buffer portion 56 is set to be equal to or slightly larger than the distance between the guide means 38 and the back plate portion 28, and the trailing edge in the plate width direction of the linkage structure 36 protruding from the guide means 38 slightly bites into the buffer portion 56. Configured as follows. The linkage structure 36 is fitted in the guide grooves 50, 52, 54 of the guide means 38 to define a displacement path and a deformed state, and is sandwiched between the mounting portion 44 and the buffer portion 56 to restrict displacement in the front-rear direction. The Thus, the linkage structure 36 is held so as to be displaceable with respect to the guide means 38 by abutting against the buffer portion 56. The buffer portion 56 is preferably arranged so as to cover at least the curved portion 40 a of the linkage structure 36. In the embodiment, the two buffer portions 56 are arranged side by side on the left and right. Each buffer portion 56 is formed in a vertically long rectangular shape corresponding to the two curved portions 40a, 40a arranged vertically.

  As shown in FIG. 4, the locking device 30 is configured to always apply a force in the direction in which the collar portion 34 is in the locked position by the biasing means 58 using an elastic body such as a coil spring. In the embodiment, an urging means 58 made of a coil spring is installed between the main body suspension portion 26b formed on the back surface of the front plate portion 26 and the flange suspension portion 34b formed on one flange portion. By urging one of the collar portions 34 toward the lock position, the linkage structure 36 assists the two collar portions 34, 34 interlocked to be held at the lock position.

(Effects of Example)
Next, the operation of the locking device 30 according to the embodiment will be described. By operating the operation button 32, one connecting portion 42 connected to the one collar 34 is pushed inward as the one collar 34 is pushed inward. When the one connecting portion 42 is displaced inward, the first extending portion 40c, the curved portion 40a, and the second extending portion 40d of the two connecting portions 40, 40 connected to the one connecting portion 42 are pushed. . As a result, the linkage structure 36 is guided by the curved guide groove 50 and deformed so that the first extended portion 40c becomes the curved portion 40a, and deformed so that the curved portion 40a becomes the second extended portion 40d. However, the upper and lower folded portions 40b, 40b are displaced in the vertical direction so as to be separated from each other. When the upper and lower folded portions 40b and 40b are displaced in the vertical direction so as to be separated from each other, the first extending portion 40c, the curved portion 40a and the second portion of the two connecting portions 40 and 40 connected to the other connecting portion 42 are provided. The curved portion 40d is displaced inwardly against the urging force of the urging means 58, so that the other flange portion 34 is displaced inward in conjunction with the one flange portion 34. As described above, the locking device 30 displaces one of the flanges 34 inward from the locked position toward the unlocked position, thereby causing the linkage structure 36 to move the other flanged part 34 from the locked position to the unlocked position. And can be displaced in synchronization with the inside.

  By releasing the operation by the operation button 32, the upper and lower folded portions 40b and 40b are brought close to each other by the restoring force of the linkage structure 36 elastically deformed from the natural state and the urging force of the urging means 58. It is displaced to. Accordingly, the left and right connecting portions 42 and 42 are displaced so as to be separated from each other while the linkage portions 40 and 40 are guided by the curved guide groove 50, so that the left and right flange portions 34 and 34 are moved from the unlocked position to the locked position. And can be displaced in synchronization with the outside. When the lid 24 is returned from the open position to the closed position, the left and right flanges 34, 34 are pushed by the box body 22 and retracted toward the device accommodating space 24a, and are directed outward by the linkage structure 36 and the biasing means 58. When the lid 24 is closed, the flanges 34 and 34 thus pushed fit into the corresponding engagement openings 22a.

  The locking device 30 can displace the two flange portions 34 and 34 in opposite directions with a simple configuration by deformation of the linkage structure 36 itself guided by the curved guide groove 50. In addition, the linkage structure 36 is not configured to be deformed by operably connecting a plurality of constituent members to each other, but the two linkage structures 36 and 40 themselves are deformed by deformation of the flexible linkage portions 40 and 40 themselves. It is the structure which displaces the collar parts 34 and 34 to the opposite direction. In other words, the locking device 30 does not cause troubles such as generation of abnormal noise due to a gap (play) between the constituent members operably connected and synchronization shift of the left and right flange portions 34 and 34. Further, since the linkage structure 36 can be configured as a single member by molding with a synthetic resin or the like, it is possible to reduce the number of parts and to save time and labor for connecting the configuration members. A dimensional error does not occur due to the connection of the members. Since the linkage structure 36 is configured to transmit force between the two flange portions 34 and 34 by being divided into the two linkage portions 40 and 40, the force accompanying the change in the direction of the force by the linkage portion 40. Can be suppressed, and the force can be stably transmitted to the two flange portions 34, 34. Therefore, the locking device 30 can synchronize the left and right flanges 34, 34 without deviation and can reduce the operation load. In the linkage structure 36, the two linkage portions 40, 40 are formed in a symmetrical shape, and the curved portions 40a and the extended portions 40c, 40d are symmetrical in shape with each linkage portion 40 sandwiching the folded portion 40b. Is formed. Thereby, the linkage structure 36 can suppress the bias of the force applied to the two linkage portions 40, 40, and can transmit the force more stably between the two flange portions 34, 34. it can.

  When the linkage structure 36 is deformed so that the collar portion 34 is in the unlocked position, the portion that has become the curved portion 40a in a natural state is deformed so as to become the second extending portion 40d. A force is applied to the folded portion 40b of the linkage portion 40 so that the second extending portion 40d approaches each other. Since the folded portion 40b is configured to be elastically deformable, it is possible to assist the displacement of the collar portion 34 that returns from the unlocked position to the locked position by the restoring force of the folded portion 40b. In other words, the locking device 30 can weaken the urging force of the urging means 58 that returns the collar portion 34 from the unlocked position to the locked position and holds it in the locked position, or may omit the urging means 58 in some cases. It becomes.

  The linkage structure 36 is deformed so that the first extending portion 40c becomes the curved portion 40a when the flange portion 34 is displaced inward, and the second extension portion is formed when the flange portion 34 is displaced outward. The portion 40d is deformed so as to be a curved portion 40a. As described above, since the shape of the curved portion 40a is regulated by being guided by the curved guide groove 50 when the linkage portion 40 is deformed, it is possible to avoid a loss of force without determining the deformation shape of the linkage portion 40. In other words, since the locking device 30 guides the linking part 40 through the curved guide groove 50 along an appropriate route, it is possible to suppress the bias of the force accompanying the change in the direction of the force by the linking part 40. The force can be stably transmitted to the portions 34 and 34. Moreover, since the guide means 38 is guiding the 1st extension part 40c of the connection part 40 with the 1st displacement guide groove 52, it stabilizes the connection part 42 and the collar part 34 connected to this connection part 42 in the left-right direction. Can be displaced. Further, since the guide means 38 guides the folded portion 40b and the second extended portion 40d of the linkage portion 40 with the second displacement guide groove 54, the folded portion 40b can be stably displaced in the vertical direction. . As described above, the locking device 30 is configured such that the linkage structure 36 is deformed under the guidance of the guide means 38, so that the stability of the interlocking of the left and right flange portions 34, 34 can be increased and the operation load can be increased. Can be reduced.

  If the linkage structure 36 is set lower than the guide portions 46, 48, the buffer portion 56 does not enter the thin curved guide groove 50, and the linkage structure 36 may rattle between the buffer portion 56 and the mounting portion 44. . Since the linkage structure 36 of the embodiment is configured such that the rear edge in the plate width direction protrudes from the guide grooves 50, 52, 54 when fitted to the guide grooves 50, 52, 54, the inner guide portion The buffer portion 56 can be brought into contact with the linkage structure 36 without being obstructed by 46 and the outer guide portion 48. In this way, the trailing edge in the plate width direction protruding from the inner guide portion 46 and the outer guide portion 48 in the linkage structure 36 is held in contact with the buffer portion 56, so that play in the plate width direction in the linkage structure 36 is prevented. It is possible to suppress the occurrence of abnormal noise caused by this play.

  The linkage structure 36 is formed in advance in a shape that allows the collar 34 to be in the locked position, and the guide groove of the guide means 38 is formed in accordance with the shape of the linkage structure 36 without deforming this natural state. 50, 52, 54. That is, since no force is applied between the linkage structure 36 and the guide portions 46 and 48 when the collar portion 34 is in the locked position, the initial time when the collar portion 34 is operated from the locked position to the unlocked position. The operation load can be reduced. Further, when operating the collar portion 34 from the lock position to the lock release position, the sliding resistance between the linkage portion 40 and the guide portions 46 and 46 can be reduced, so that the lock can be released with a light operation load. .

(Example of change)
The present invention is not limited to the configuration described above, and can be modified as follows, for example.
(1) In the embodiment, the configuration in which the linkage portion of the linkage structure is linked to the flange portion via the connection portion has been described, but the linkage portion may be directly linked to the flange portion.
(2) You may integrally form a collar part and a linkage structure.
(3) The operation of the locking device is not limited to the button type of the embodiment, and various configurations such as a knob type for turning the operation knob and a form for turning the knob can be adopted. Moreover, the structure which displaces a collar part from a locked position to a lock release position by operating a linkage structure, such as displacing a folding | returning part instead of operating a collar part, may be sufficient.
(4) In the embodiment, the linkage structure is formed by resin molding or the like so that the two collars are in the locked position, but the shape in which the two collars are in the unlocked position or the two collars The linkage structure may be formed in a shape that becomes an intermediate position between the lock position and the unlock position. In addition, the linkage structure is not limited to be formed in accordance with the inner guide portion and the outer guide portion. For example, by combining a linkage structure formed with the linkage portion in a linear state with the guide means, the curved portion and the folded portion are formed. The structure which deform | transforms a connection part so that a part may be sufficient may be sufficient.
(5) In the embodiment, the guide means is formed separately from the lid, but the guide means may be formed integrally with the lid. That is, the number of parts can be further reduced by forming the inner guide portion and the outer guide portion on the lid.
(6) The urging means may be omitted, and the user may also operate when returning the buttocks from the unlocked position to the locked position.
(7) In the embodiment, the example in which the lock device is applied to the glove box has been described. However, the lock device according to the present invention is applied to a vehicle-mounted device such as a console box or an accessory case, or a lid other than the vehicle-mounted device. can do. The locking device engages and disengages the two flanges provided on the first member (for example, the lid) with the engaging portions provided on the second member (for example, the box main body), so that the first member and the first member The relative displacement between the two members can be regulated or deregulated.

34 collar part, 36 linkage structure, 38 guide means, 40 linkage part, 40a curved part,
40b Folding part, 46 inner guide part, 46a inner guide surface, 48 outer guide part,
48a outer guide surface, 56 shock absorber

Claims (5)

In a locking device that reciprocally displaces two hooks in opposite directions to lock or unlock,
An interlocking structure that transmits force between the two collars by means of two flexible couplings that are laid between the two collars and have a displacement. Guide means for guiding the linkage structure to be deformed,
The linkage portion is provided between two curved portions that bend in a direction crossing the displacement direction of the heel portion as it goes from each heel portion to the middle of the two heel portions, and between the two curved portions, A folded portion that bends so that the convex faces in the direction intersecting the displacement direction of the portion,
In the linkage structure, the folded portions of the two linkage portions are provided in directions opposite to each other,
The guide means is provided on the inner side of the linkage structure surrounded by the two linkage portions, and an inner guide portion that guides the curved portion bent in a convex shape toward the inner side of the linkage structure, and the linkage structure An outer guide portion provided outside the body and guiding the curved portion;
The interlocking structure in which the curved shape of the curved portion is defined by the inner guide portion and the outer guide portion is configured to interlock the two flange portions so as to be displaced in opposite directions. Locking device to do.   The locking device according to claim 1, wherein the linking portion is configured such that the folded portion bent in an arc shape is elastically deformed.   The locking device according to claim 1, wherein the linkage structure is formed such that the two linkage portions are symmetrical. The link portion is formed in a plate shape, and the curved portion is bent in the thickness direction and formed in an arc shape that is convex toward the inside of the link structure,
The inner guide portion has an inner guide surface formed in a concave shape in accordance with the convex shape of the curved portion,
The outer guide portion is formed with a convex outer guide surface in accordance with the concave shape of the curved portion,
The locking device according to any one of claims 1 to 3, wherein the inner guide surface and the outer guide surface are spaced apart according to the thickness of the linkage portion. The linkage structure is set so that at least one edge in the plate width direction protrudes from the inner guide part and the outer guide part,
The locking device according to claim 4, wherein an edge protruding from the inner guide portion and the outer guide portion in the linkage structure is in contact with a cushioning portion having a cushioning property.

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