JP2022075229A - desk - Google Patents

Abstract

To provide a movable desk which can stably perform a function to control lock of casters.SOLUTION: A desk is provided with leg parts and a top plate. The leg parts can shift to an unlocked state where they can move by casters and to a locked state that disables movements. The desk is provided with a first displacement part 50, a second displacement part 51, a connection rod, and a switch part. The first displacement part displaces interlockingly with rotation of the top plate rotates. The second displacement part displaces when an operation part 32 is operated. The connection rod operates interlockingly with a displacement when at least either the first displacement part or the second displacement part displaces. The switch part switches the unlocked state and the locked state of the leg parts interlockingly with operation of the connection rod.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to a desk with a rotating top plate.

There is a desk equipped with a rotating top plate and casters, and a desk that switches between locking and unlocking the casters according to the rotation of the top plate. Patent Document 1 discloses a desk that can temporarily unlock the caster by operating an operation button arranged on the back surface of the top plate, in addition to the method of rotating the top plate.

Japanese Unexamined Patent Publication No. 2019-62311

The desk described in Patent Document 1 controls the locked state of the caster by one interlocking cam. In other words, the interlocking cam interlocks both the rotation of the top plate and the operation of the operation buttons with the device that executes the lock control of the caster. Therefore, the interlocking cam is used more frequently and is easily damaged. Further, since the interlocking cam needs to be interlocked with both the top plate and the operation button, the structure is complicated and delicate, and there is a high possibility that the function cannot be exhibited due to small damage or deformation.

An object of the present disclosure is to propose a technique capable of stably exerting a caster lock control function.

One aspect of the present disclosure is a desk comprising a leg and a top plate that is supported by the leg and rotatably supported from a use position to a flip-up position. The legs can transition to an unlocked state in which the casters can move and a locked state in which the legs cannot move. This desk includes a first displacement portion, a second displacement portion, a connecting rod, and a switching portion. The first displacement portion is displaced in conjunction with the rotation of the top plate. The second displacement portion is displaced when the operable operation portion is operated by the user of the desk. The connecting rod is arranged inside a cylindrical vertical column having a leg portion having a vertical length, and is linked to the displacement when at least one of the first displacement portion and the second displacement portion is displaced. Works. The switching portion switches between the unlocked state and the locked state of the leg portion in conjunction with the operation of the connecting rod.

With such a configuration, when the top plate is rotated, the first displacement portion is interlocked to operate the switching portion, while when the operation portion is operated, the second displacement portion is interlocked to operate the switching portion. .. Therefore, since one of the parts of the first displacement part and the second displacement part is used to switch between the unlocked state and the locked state, each displacement part is compared with the case where one part is used. The number of uses is reduced and they are less likely to break. Further, even if the switching function of the switching unit 24 using either the first displacement portion or the second displacement portion cannot be used due to damage or the like, the state in which the other function can be used can be maintained. It is possible to reduce the risk that the lock control will be completely disabled. For the above reasons, the caster lock control function can be stably exerted.

In one aspect of the present disclosure, the first displacement portion may be fixed to the top plate so that it cannot be displaced with respect to the top plate. With such a configuration, the movement of the top plate can be satisfactorily transmitted to the first displacement portion.

In one aspect of the present disclosure, the first displacement portion and the second displacement portion may be arranged side by side in the length direction of the rotation axis of the top plate. With such a configuration, the first displacement portion and the second displacement portion can be arranged in a small and cohesive state.

In one aspect of the present disclosure, a horizontal pillar supported by the legs and serving as a center of rotation of the top plate may be provided. The first displacement portion and the second displacement portion may be configured to be rotationally displaced. The rotation axes of the first displacement portion and the second displacement portion may be located coaxially with the rotation axis of the top plate. With such a configuration, the desk mechanism can be simplified.

In one aspect of the present disclosure, the first component, which is either the first displacement portion or the second displacement portion, may be in the shape of a vessel. The second component, which is different from the first component among the first displacement portion and the second displacement portion, may be arranged inside the first component. With such a configuration, the first displacement portion and the second displacement portion can be arranged in a small and cohesive state.

In one aspect of the present disclosure, the first displacement portion may have an adjacent portion that is plate-shaped and is arranged adjacent to the second displacement portion. An elongated hole may be formed in the adjacent portion, and the connecting rod may pass through the elongated hole and be connected to the second displacement portion. When the connecting rod is displaced by the displacement of the second displacement portion, the elongated hole does not press the end portion of the elongated hole, and when the first displacement portion is displaced, the end of the elongated hole is formed. The connecting rod may be displaced by the contact of the connecting rod with the portion.

With such a configuration, even though the first displacement portion and the second displacement portion are adjacent to each other, the top plate is displaced when the second displacement portion is displaced by the operation of the operation portion. The connecting rod can be displaced while suppressing it.

It is a perspective view which shows the desk 1 of an embodiment. It is a side view which shows the desk 1 of an embodiment. It is a perspective view which shows the mechanism of the back side of the top plate in the desk 1 of an embodiment. It is a perspective view which shows the mechanism of the back side of the top plate in the desk 1 of an embodiment, and is the perspective view of the state which a part of the structure was disassembled. FIG. 5A is a perspective view of the combination of the first displacement portion and the second displacement portion, and FIG. 5B is a perspective view of the combination of the first displacement portion and the second displacement portion and a viewpoint different from that of FIG. 5A. .. 6A is a perspective view of the second displacement portion, FIG. 6B is a perspective view of the second displacement portion from a different viewpoint from FIG. 6A, and FIG. 6C is a cross-sectional view of the second displacement portion. It is a perspective view which shows only a part component for demonstrating the 1st rod and the 1st displacement part. It is a perspective view which shows only a part component for demonstrating the 1st rod and the 2nd displacement part. It is a figure explaining the operation of the 1st rod by rotating a top plate, FIG. 9A is a side view which shows the state which the top plate is in a use position, and FIG. FIG. 9C is a side view showing a state in which the top plate is in the flip-up position, and FIG. 9C is a side view showing a state in which the top plate is in the flip-up position. 10A is a side view showing a state in which the operation unit is not operated, and FIG. 10B is a state in which the operation unit is operated by a certain amount. 10C is a side view showing a state in which the operation unit has been operated to the end. It is the figure which looked at the top plate from the bottom.

The embodiments of the present disclosure will be described below together with the drawings.
[1. Embodiment]
[1-1. overall structure]
The desk 1 shown in FIG. 1 includes a pair of legs 11 and a top plate 12. In the following description, the configuration of each part may be described using directions such as front-back, left-right, and up-down, but these directions are used only for convenience of explanation, and the embodiments of the present disclosure are limited in any way. It's not something to do. The above-mentioned direction is a direction with respect to the user when the user faces the desk 1. Further, the top plate 12 rotates as described later, but the direction used for the explanation is the direction at the position of use as shown in FIG.

The pair of legs 11 are arranged at intervals in the left-right direction to support the top plate 12. The pair of legs 11 are configured to be able to transition to an unlocked state in which the casters 23 can move and a locked state in which the casters 23 cannot move, respectively.

The pair of legs 11 are a cylindrical vertical pillar 21 having lengths in the vertical direction and a box-shaped floor side member 22 having lengths in the front-rear direction and opening downward, respectively, arranged at the lower end of the vertical pillar 21. And have. Casters 23 are provided below both ends of the floor-side member 22 in the front-rear direction. That is, two casters 23 are provided on each of the pair of legs 11.

As shown in FIG. 2, a switching portion 24 is provided inside the floor side member 22. The switching unit 24 switches between the unlocked state and the locked state described above. The switching unit 24 may be locked by physically limiting the rotation of the caster 23. Further, the switching portion 24 may be locked by driving the caster 23 or a member in contact with the floor surface so that the caster 23 is located away from the floor surface. The switching unit 24 can adopt a well-known configuration capable of switching between the unlocked state and the locked state described above.

The top plate 12 is rotatably supported by the legs 11. The top plate 12 can rotate from the use position shown in FIG. 1 to the flip-up position, which is the position of the top plate 12 shown in FIG. 9C, which will be described later. The locked state and the unlocked state of the leg portion 11 transition in conjunction with the position of the top plate 12. When the top plate 12 is in the used position, the leg portion 11 is in the locked state. When the top plate 12 is in the flip-up position, the leg portion 11 is in the unlocked state.

A rotary lever 31 and an operation unit 32 are arranged in the vicinity of the left and right end portions on the back side of the top plate 12, respectively. All of these can be operated by the user of the desk 1. The top plate 12 in the used position is restricted so as not to rotate. When the rotary lever 31 is operated, the restriction is released and the rotation to the flip-up position becomes possible. The operation unit 32 is a lever for unlocking the leg portion 11 without rotating the top plate 12. When the top plate 12 is in the used position and the operation unit 32 is being operated, the leg portion 11 is in the unlocked state. As a result, the desk 1 can be moved without rotating the top plate 12.

The configuration of the back side of the top plate 12 will be described with reference to FIGS. 3 and 4. Although the left side of the top plate 12 is shown in FIGS. 3 to 4, the right side of the top plate 12 is also provided with the same configuration in which the top plate 12 is inverted left and right.
As a configuration for realizing the rotation of the top plate 12, the desk 1 includes a horizontal pillar 41, a horizontal pillar fixing portion 42, a top plate fixing portion 43, an annular support portion 44, a fixing piece 45, a release shaft 46, and a connecting rod 47. And has a rotation control plate 48.

The horizontal pillar 41 has a cylindrical shape having a length in the left-right direction. The horizontal pillar 41 connects a pair of legs 11 to each other. The horizontal pillar fixing portion 42 is fixed to the horizontal pillar 41 and is fixed to the vertical pillar 21. In other words, the horizontal pillar 41 is fixed to the pair of leg portions 11 via the horizontal pillar fixing portion 42, and the horizontal pillar 41 is supported by the pair of leg portions 11.

The top plate fixing portion 43 is a component that is fixed to the top plate 12 by screwing or the like. The annular support portion 44 is divided into a portion that covers the lower side and the front and back of the horizontal pillar 41 and a portion that covers the upper side of the horizontal pillar 41. Then, by combining them, an annular body that surrounds the entire circumferential direction of the horizontal pillar 41 at a predetermined position of the horizontal pillar 41 is formed (see FIG. 7). The annular support portion 44 is fixed to the top plate fixing portion 43. On the other hand, the horizontal column 41 is not fixed to the annular support portion 44. With such a configuration, the top plate 12 can rotate with the horizontal pillar 41 as a rotating shaft member. In other words, the horizontal pillar 41 is the center of rotation of the top plate 12.

Next, a mechanism for limiting the rotation of the top plate 12 will be described. The rotary lever 31, the fixing piece 45, and the release shaft 46 are parts fixed to the top plate 12 side. In other words, it is a component whose relative position with respect to the top plate 12 does not change even if the top plate 12 rotates. On the other hand, the rotation control plate 48 is a component fixed to the horizontal pillar 41. The rotary lever 31 is connected to the release shaft 46. When the rotary lever 31 is operated, the release shaft 46 rotates, and the fixed piece 45 fixed to the release shaft 46 is displaced. The rotation control plate 48 is formed with a plurality of grooves to which the fixing piece 45 can be engaged.

When the top plate 12 is in the used position, the upper end portion of the rotation control plate 48 is in contact with the lower side surface of the top plate fixing portion 43, whereby the top plate 12 is lowered so that the rear end portion of the top plate 12 is lowered. Rotation is suppressed. When the rotary lever 31 is not operated, the fixing piece 45 is fitted in a predetermined groove of the rotation control plate 48, whereby the rotation of the top plate 12 is restricted so that the rear end portion of the top plate 12 is raised. .. When the rotary lever 31 is operated and the fixed piece 45 comes out of the predetermined groove of the rotation control plate 48, the restriction on the rotation of the top plate 12 is released, and the top plate 12 can rotate toward the flip-up position. Similarly, when the top plate 12 is in the flip-up position, when the rotary lever 31 is not operated, the fixing piece 45 is fitted in another groove of the rotation control plate 48, and the rotation of the top plate 12 is restricted. Then, by operating the rotary lever 31, the restriction on the rotation of the top plate 12 is released. The connecting rod 47 connects a pair of release shafts 46 provided on the left and right sides of the desk 1. Therefore, if one of the release shafts 46 rotates, the other release shaft 46 also rotates, and the pair of left and right fixed pieces 45 are also displaced. With such a configuration, by operating either the left or right rotary lever 31, the restriction on the rotation of the top plate 12 by the fixed piece 45 and the rotation control plate 48 on both the left and right sides of the desk 1 is released. ..

Next, the parts that control the lock of the caster 23 will be described. As a configuration for realizing lock control of the caster, the desk 1 has a first rod 49, a first displacement portion 50, a second displacement portion 51, a connecting portion 52, a second rod 53, a coil spring 54, and a case 55. ..

The first rod 49 is arranged inside the vertical column 21. Further, when at least one of the first displacement portion 50 and the second displacement portion 51 is displaced, the first rod 49 operates in conjunction with the displacement. The switching unit 24 switches between the unlocked state and the locked state of the leg portion 11 in conjunction with the operation of the first rod 49.

The first displacement portion 50 is fixed to the top plate 12 and is rotationally displaced in conjunction with the rotation of the top plate 12. When the operation unit 32 is operated, the second displacement unit 51 is pressed via the second rod 53 interlocked with the operation unit 32 and is rotationally displaced. The first displacement portion 50 and the second displacement portion 51 are arranged side by side in the length direction of the horizontal pillar 41, which is the axis member for the rotation of the top plate 12, that is, in the left-right direction. The first displacement portion 50 has a vessel shape. The second displacement portion 51 is arranged inside the first displacement portion 50.

As shown in FIGS. 5A-5B, the first displacement portion 50 has a flat plate-shaped adjacent portion 71, a peripheral wall portion 72 extending from the adjacent portion 71 in a direction intersecting the adjacent portion 71, and an elongated hole 73. .. The adjacent portion 71 extends in a direction orthogonal to the rotation axis of the top plate 12 and is arranged adjacent to the second displacement portion 51. The peripheral wall portion 72 is arranged so as to surround the side surface of the second displacement portion 51. The elongated hole 73 is formed in the adjacent portion 71. The elongated hole 73 is a hole extending in the circumferential direction about the rotation axis of the top plate 12, that is, the virtual central axis of the horizontal pillar 41.

As shown in FIGS. 6A-6C, the second displacement portion 51 is a substantially disk-shaped member. The second displacement portion 51 includes a groove 81 formed on the side surface of the disk and extending in the circumferential direction, and a cylindrical portion 82 having a cylindrical shape in which the axis and the central axis of the disk coincide with each other and projecting unilaterally from the disk. , Have. The first elongated hole portion 83 is formed on the wall surface of the wall surface constituting the groove 81 and extending in the direction orthogonal to the axis of the disk, on the side surface opposite to the protruding side of the tubular portion 82. Will be done. Further, of the two wall surfaces described above, the second elongated hole portion 84 is formed on the wall surface on the cylinder portion 82 side. The first elongated hole portion 83 and the second elongated hole portion 84 extend in the circumferential direction about the virtual central axis of the horizontal column 41. Further, the first elongated hole portion 83 and the second elongated hole portion 84 are provided at positions facing each other.

The depth of the groove 81 is not constant and varies depending on the position in the circumferential direction. A step is formed inside the groove 81 due to a large change in depth. The position on the side where the depth of the groove is small in the portion where the step is formed is defined as the contact portion 85. Further, a hole 86 for inserting a screw is formed on the side surface of the disk where the groove 81 is not formed. A connecting portion 52 is inserted into the tubular portion 82 described above. Then, the second displacement portion 51 and the connecting portion 52 are fixed by screwing with a screw inserted from the hole 86. The second displacement portion 51 is configured to be rotatable and displaceable about the connecting portion 52.

The rotation axes of the first displacement portion 50 and the second displacement portion 51 are located coaxially with the rotation axis of the top plate 12. Therefore, the first displacement portion 50 and the second displacement portion 51 are displaced along a virtual plane orthogonal to the rotation axis of the top plate 12. The rotation axis of the top plate 12 referred to here refers to a virtual axis of a portion of the horizontal pillar 41 that supports the top plate 12. Further, the rotation axes of the first displacement portion 50 and the second displacement portion 51 refer to virtual axes that are the centers of these rotations.

As shown in FIG. 7, the tip of the first rod 49 is inserted into the elongated hole 73. As a result, when the top plate 12 rotates and the first displacement portion 50 is rotationally displaced, the first rod 49 abutting on the lower end portion of the elongated hole 73 is pulled up. Note that FIG. 7 illustrates only some of the components in order to facilitate understanding of the first rod 49 and the first displacement portion 50.

On the other hand, as shown in FIG. 8, the tip of the first rod 49 that has passed through the elongated hole 73 is inserted into the first elongated hole portion 83 of the second displacement portion 51. That is, the first rod 49 passes through the elongated hole 73 and is connected to the second displacement portion 51. When the operation portion 32 is operated and the second displacement portion 51 is rotationally displaced, the first rod 49 abutting on the lower end portion of the first elongated hole portion 83 is pulled up. The second displacement portion 51 is arranged side by side with respect to the horizontal pillar 41 in the length direction of the horizontal pillar 41. Note that FIG. 8 illustrates only some of the components in order to facilitate understanding of the first rod 49 and the second displacement portion 51. The second elongated hole portion 84 defines a rotatable range of the second displacement portion 51 by inserting a protrusion (not shown) provided in the horizontal column fixing portion 42.

The explanation returns to FIG. 3-FIG. 4. The connecting portion 52 is arranged so as to pass through the inside of the horizontal pillar 41. The connecting portion 52 is a rod-shaped member having lengths on the left and right. As described above, both ends of the connecting portion 52 are inserted into the tubular portions 82 of each of the pair of second displacement portions 51. Then, the connecting portion 52 connects and interlocks a pair of second displacement portions 51 arranged on the left and right sides of the desk 1 at intervals. The connecting portion 52 interlocks the pair of second displacement portions 51 so that the pair of second displacement portions 51 are displaced in synchronization. Therefore, if one of the second displacement portions 51 is displaced by operating either the left or right operation portion 32, the other second displacement portion 51 is also displaced in conjunction with the displacement. The rotation of the second displacement portion 51 when the rotation axis of the pair of second displacement portions 51 (that is, the central axis of the connecting portion 52) and the horizontal column 41 are projected onto a plane orthogonal to the rotation axis of the second displacement portion 51. The shaft is located within the cross section of the horizontal column 41.

The second rod 53 slides on the operation unit 32 along the back surface of the top plate 12 in accordance with the operation, and presses the second displacement portion 51 to rotationally displace the second displacement portion 51. The second rod 53 is urged by the coil spring 54 in a direction in which the second rod 53 is separated from the second displacement portion 51. The case 55 supports the operation unit 32 in a displaceable manner, supports the second rod 53, and protects the coil spring 54.

Further, the desk 1 has a top plate back cover 56, a vertical pillar cover 57, a side cover 58, and the like as a cover that protects each of the above-mentioned components and prevents the user's fingers, clothes, and the like from being pinched. ..

[1-2. Rod operating mechanism]
The operation of the first rod 49 by rotating the top plate 12 will be described with reference to FIGS. 9A-9C. 9A-9C are schematic drawings showing only some of the components. The first rod 49 is urged to the lower side (floor side member 22 side) by an urging member (not shown). Therefore, 49 is located at the lowest position in the predetermined movable range when no load for displacement is applied. At this time, the leg portion 11 is in the locked state.

FIG. 9A shows a state in which the top plate 12 is in the used position. The tip of the first rod 49 is located close to the lower end of the elongated hole 73 of the first displacement portion 50. When the top plate 12 is rotated, as shown in FIG. 9B, the first displacement portion 50 fixed to the top plate 12 rotates together with the top plate 12. Since the elongated hole 73 is located at a position away from the rotation center of the first displacement portion 50, it moves with the rotation of the first displacement portion 50. As a result, the tip of the first rod 49 comes into contact with the end of the elongated hole 73 and is pulled up. FIG. 9C shows a state in which the top plate 12 is in the flip-up position. At this time, the first rod 49 is pulled up to the highest position. When the switching portion 24 is driven by such a displacement of the first rod 49, the leg portion 11 transitions to the unlocked state.

Since the second displacement portion 51 is not fixed to the top plate 12, it does not displace as the top plate 12 rotates. The tip of the first rod 49 is inserted into the first elongated hole portion 83 of the second displacement portion 51, and the tip thereof moves inside the first elongated hole portion 83 with the rotation of the top plate 12. Therefore, the first rod 49 does not displace the second displacement portion 51. Since the second rod 53 connected to the operation unit 32 is attached to the top plate 12, it is displaced as the top plate 12 rotates. However, since the tip portion 53a of the second rod 53 does not abut on the contact portion 85 of the groove 81 but only moves inside the groove 81, the second displacement portion 51 is not displaced.

The operation of the first rod 49 by operating the operation unit 32 will be described with reference to FIGS. 10A-10C. 10-10C is a schematic drawing showing only a part of the components. FIG. 10A shows a state in which the operation unit 32 is not operated. The tip of the first rod 49 is located close to the lower end of the first elongated hole portion 83 of the second displacement portion 51. When the operation unit 32 is operated by a certain amount, as shown in FIG. 10B, the second rod 53 slides and the tip portion 53a of the second rod 53 abuts on the abutting portion 85 and presses the second rod 53 to cause a second displacement. The portion 51 is rotationally displaced. Since the first elongated hole portion 83 is located at a position away from the rotation center of the second displacement portion 51, it moves with the rotation of the second displacement portion 51. As a result, the tip of the first rod 49 comes into contact with the end of the first elongated hole 83 and is pulled up. FIG. 10C shows a state in which the operation unit 32 is operated to the end within the operable range. At this time, the first rod 49 is pulled up to the highest position. By driving the switching portion 24 by such a displacement of the first rod 49, the leg portion 11 transitions to the unlocked state.

The tip of the first rod 49 passes through the long hole 73 of the first displacement portion 50, but when the tip of the first rod 49 is displaced in conjunction with the operation unit 32, the tip of the long hole 73 Move inside the. Therefore, the first displacement portion 50 does not interfere with the displacement of the first rod 49. That is, when the first rod 49 is displaced due to the displacement of the second displacement portion 51, the first rod 49 does not press the end portion of the elongated hole 73. On the other hand, as described above, when the first displacement portion 50 is displaced, the first rod 49 is displaced by the contact of the first rod 49 with the end portion of the elongated hole 73.

As described above, the first rod 49 is displaced upward by either the rotation of the top plate 12 or the operation of the operation unit 32. As a result, the switching portion 24 is activated, and the leg portion 11 is in the unlocked state. That is, the switching unit 24 switches between the unlocked state and the locked state described above in conjunction with the displacement of the pair of first displacement units 50 or the displacement of the pair of second displacement units 51.

[1-3. Protection by top plate back cover]
FIG. 11 is a view seen from below the top plate 12, and the top plate 12 and a part of the configuration are omitted. The top plate back cover 56 is a part of the horizontal pillar 41, a top plate fixing portion 43, an annular support portion 44, a fixing piece 45, a release shaft 46, and other parts related to the rotation of the top plate 12 and the rotation suppression of the top plate 12. Cover and protect much of. Further, these parts do not displace their relative positions with respect to the top plate 12 when the top plate 12 rotates. Therefore, it is not necessary to form a large opening or the like required to enable the displacement. This can be suitably realized by arranging the connecting portion 52 inside the horizontal pillar 41. The reason will be explained below.

It is assumed that the connecting portion 52 is arranged outside the horizontal pillar 41 in a virtual configuration. The second displacement portion 51 is fixed to the leg portion 11 and is not fixed to the top plate 12, and when the top plate 12 rotates, the position with respect to the top plate 12 changes. The connecting portion 52 connected to the second displacement portion 51 is also not fixed to the top plate 12, and when the top plate 12 rotates, the position changes with respect to the top plate 12. Therefore, when the top plate 12 is rotated, the top plate back cover 56 rotates together with the top plate 12, but the connecting portion 52 is not displaced, so that the relative positions of the top plate back cover 56 and the connecting portion 52 change. In that case, it becomes necessary to form a large opening or an elongated hole in the top plate back cover 56 to accept the relative displacement of the connecting portion 52. On the other hand, in the desk 1 of the present embodiment, since the connecting portion 52 is arranged inside the horizontal pillar 41, the above-mentioned openings and elongated holes are not required.

[1-4. effect]
According to the embodiment described in detail above, the following effects can be obtained.
(1a) In the desk 1 described above, when the top plate 12 rotates to the flip-up position, the first displacement portion 50 is rotationally displaced, and the first rod 49 is pulled upward. Further, in the desk 1, when the operation unit 32 is operated, the second displacement unit 51 is rotationally displaced, and the first rod 49 is pulled upward. That is, when the top plate 12 is rotated and when the operation unit 32 is operated, different parts move the first rod 49 upward. Therefore, the number of times the first displacement portion 50 and the second displacement portion 51 are used is reduced as compared with the case where the first rod 49 is moved by a single component, so that they are less likely to break. Further, as compared with the case where the functions of the first displacement portion 50 and the second displacement portion 51 are integrated into one component, a complicated and precise mechanism becomes unnecessary, and the robustness is improved. Further, even if the control function of the switching unit 24 using either the first displacement unit 50 or the second displacement unit 51 cannot be used due to damage or the like, the other function may remain usable. Yes, the risk of lock control becoming completely unusable can be reduced. For the above reasons, the desk 1 can stably exert the lock control function of the caster 23.

(1b) In the desk 1 described above, since the first displacement portion 50 is directly fixed to the top plate 12, the first displacement portion 50 is reliably displaced with the top plate. If the first displacement portion 50 is fixed to the top plate 12 so that it cannot be displaced with respect to the top plate 12, it may be indirectly fixed to the top plate 12 with another component in between. good. Even in that case, the above-mentioned effect can be achieved.

(1c) In the desk 1 described above, the first displacement portion 50 and the second displacement portion 51 are arranged side by side in the length direction of the rotation axis of the top plate 12. Therefore, the above-mentioned first displacement portion 50 and second displacement portion 51 can be arranged in a small and organized state.

(1d) In the desk 1 described above, the rotation axes of the first displacement portion 50 and the second displacement portion 51 are located coaxially with the rotation axis of the top plate 12. Therefore, the mechanism of the desk 1 can be simplified. For example, the axial positions of the first displacement portion 50 and the second displacement portion 51 do not change regardless of the rotational position of the top plate 12, so that the positions of other parts due to the displacement of those axial positions do not change. It is not necessary to consider the change. Also, it is not necessary to increase the size of the cover to cover the part whose position changes.

(1e) In the desk 1 described above, the first displacement portion 50 has a device shape, and the second displacement portion 51 is arranged inside the first displacement portion 50. Therefore, the first displacement portion 50 and the second displacement portion 51 can be arranged in a small and cohesive state.

(1f) In the desk 1 described above, the second displacement portion 51 is adjacent to the adjacent portion 71 of the first displacement portion 50. Further, an elongated hole 73 is formed in the adjacent portion 71, and the first rod 49 passes through the elongated hole 73 and is connected to the second displacement portion 51. When the first rod 49 is displaced by the displacement of the second displacement portion 51, the first rod 49 does not press the end portion of the elongated hole 73, so that the first displacement portion 50 is not displaced.

Therefore, in the desk 1 described above, even though the first displacement portion 50 and the second displacement portion 51 are adjacent to each other, when the second displacement portion 51 is displaced by the operation of the operation unit 32, the top plate 12 The first rod 49 can be displaced while suppressing the displacement of the rod 49.

[1-5. Correspondence]
In the above embodiment, the pair of legs 11 corresponds to the legs. The first rod 49 corresponds to the connecting rod. The first displacement portion 50 corresponds to the first component, and the second displacement portion 51 corresponds to the second component.

[2. Other embodiments]
Although the embodiments of the present disclosure have been described above, it is needless to say that the present disclosure is not limited to the above embodiments and may take various forms as long as it belongs to the technical scope of the present disclosure.

(2a) The desk 1 shown in the above embodiment may be configured as follows. For example, the first displacement portion 50 may be fixed so that its position relative to the top plate 12 changes. Further, the configuration in which the horizontal pillar 41 has a cylindrical shape as a whole in the left-right direction is exemplified. However, at least a part of the horizontal column 41 may be formed as a columnar portion having a cylindrical shape, and the top plate 12 may be configured to rotate around the columnar portion as a rotation center. Further, the mechanism for rotating the top plate 12 is not particularly limited. For example, the pair of legs 11 may be connected by a stile extending to the left and right, and the top plate 12 may be pivotally supported with respect to each of the pair of legs 11.

(2b) The embodiment of the first displacement portion 50 and the second displacement portion 51 is not limited to the configuration of the above embodiment. For example, contrary to the embodiment, the second displacement portion 51 may be in the shape of a vessel, and the first displacement portion 50 may be arranged inside the second displacement portion 51. Further, the first displacement portion 50 may not be formed in a vessel shape, and the second displacement portion 51 may not be arranged inside the first displacement portion 50. That is, the first displacement portion 50 and the second displacement portion 51 can adopt various forms as long as they function to displace the first rod 49 in conjunction with the top plate 12 and the operation unit 32, respectively. Further, the first displacement portion 50 and the second displacement portion 51 may be arranged at positions separated from each other in a direction intersecting the length direction of the rotation axis of the top plate 12. Further, one or both of the first displacement portion 50 and the second displacement portion 51 may be arranged at a position where the rotation axis thereof deviates from the rotation axis of the top plate 12.

Further, in the above embodiment, the configuration in which the first displacement portion 50 and the second displacement portion 51 are both rotationally displaced is exemplified. However, one or both of the first displacement portion 50 and the second displacement portion 51 may be configured to have a displacement other than rotation, for example, linearly moving in a predetermined range.

Further, in the above embodiment, a configuration in which the first displacement portion 50 and the second displacement portion 51 are connected to each other by penetrating the elongated hole 73 is exemplified, but the first displacement portion 50 and the second displacement portion are displaced by other methods. It may be connected to the section 51. For example, the first rod 49 may have two engaging pieces that separately engage the first displacement portion 50 and the second displacement portion 51.

Further, for example, the first displacement portion 50 and the second displacement portion 51 may be configured to displace different connecting rods up and down. In this case, the switching portion 24 may be configured to switch between the unlocked state and the locked state of the leg portion when one of the two connecting rods is displaced.

(2c) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment.

1 ... desk, 11 ... legs, 12 ... top plate, 21 ... vertical pillars, 22 ... floor side members, 23 ... casters, 24 ... switching parts, 31 ... rotary levers, 32 ... operation parts, 41 ... horizontal pillars, 42 ... Horizontal column fixing part, 43 ... Top plate fixing part, 44 ... Ring support part, 45 ... Fixed piece, 46 ... Release shaft, 47 ... Connection rod, 48 ... Rotation control plate, 49 ... First rod, 50 ... First Displacement part, 51 ... Second displacement part, 52 ... Connecting part, 53 ... Second rod, 53a ... Tip part, 54 ... Coil spring, 55 ... Case, 56 ... Top plate back cover, 57 ... Vertical pillar cover, 58 ... Side surface Cover, 71 ... adjacent portion, 72 ... peripheral wall portion, 73 ... elongated hole, 81 ... groove, 82 ... tubular portion, 83 ... first elongated hole portion, 84 ... second elongated hole portion, 85 ... contact portion, 86 ... hole.

Claims (6)

A leg that can be moved to an unlocked state that can be moved by a caster and a locked state that cannot be moved, and a leg that is supported by the leg and rotatably supported from the use position to the flip-up position. It is a desk equipped with a top plate
The first displacement portion that displaces in conjunction with the rotation of the top plate,
A second displacement unit that is displaced when the operation unit that can be operated by the user of the desk is operated, and
It is arranged inside a cylindrical vertical column having lengths above and below the legs, and when at least one of the first displacement portion and the second displacement portion is displaced, it is interlocked with the displacement. With a working connecting rod,
A desk comprising a switching unit for switching between the unlocked state and the locked state of the legs in conjunction with the operation of the connecting rod. The desk according to claim 1.
The first displacement portion is a desk fixed to the top plate so that it cannot be displaced with respect to the top plate. The desk according to claim 1 or 2.
The first displacement portion and the second displacement portion are arranged side by side in the length direction of the rotation axis of the top plate. The desk according to any one of claims 1 to 3.
A horizontal pillar that is supported by the legs and serves as the center of rotation of the top plate is provided.
The first displacement portion and the second displacement portion are configured to be rotationally displaced.
The rotation axis of the first displacement portion and the second displacement portion is a desk located coaxially with the rotation axis of the top plate. The desk according to any one of claims 1 to 4.
The first component, which is either the first displacement portion or the second displacement portion, is in the shape of a vessel.
A desk in which the first displacement portion and the second displacement portion of the second displacement portion, which are different from the first component, are arranged inside the first component. The desk according to any one of claims 1 to 4.
The first displacement portion has a plate-like shape and has an adjacent portion arranged adjacent to the second displacement portion, an elongated hole is formed in the adjacent portion, and the connecting rod passes through the elongated hole. It is connected to the second displacement part.
In the elongated hole, when the connecting rod was displaced by the displacement of the second displacement portion, the connecting rod did not press the end portion of the elongated hole, and the first displaced portion was displaced. Occasionally, a desk that displaces the connecting rod by abutting the connecting rod at the end of the elongated hole.

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