JP6349545B2 - Table device - Google Patents

Description

  The present invention relates to a table device used in a meeting or a meeting.

In various facilities such as offices, public facilities, educational facilities, commercial facilities, and hospitals, table devices such as so-called conference tables are widely used for various purposes including meetings and meetings.
Such a table device is provided with casters so that the arrangement can be easily changed according to the user's request.

  As such a table device, there is a movement restraining mechanism that restrains the movement of the table device when used as a fixture, and releases the restraint of the table device and allows the movement by a caster when changing the arrangement. It is desirable to be provided.

In Patent Document 1, as such a movement restraining mechanism, there is a configuration in which the movement of the table device is restrained by projecting the ground leg from the lower part of the leg of the table device to the lower side of the caster and grounding it to the floor. Proposed.
This movement restraint mechanism is a locking spring that urges the caster downward, and engages with the caster when the caster is pushed upward and the grounding leg protrudes downward from the caster to lock the caster. A lock claw for holding the lock claw, a lock portion urging spring for urging the lock claw in a direction to engage the caster, and a release means for releasing the engagement of the caster by the lock claw.

Japanese Patent No. 2726649

In the configuration disclosed in Patent Document 1, the lock claw is urged by the lock portion urging spring in the direction in which the lock claw is engaged with the caster. Therefore, when the caster is pushed upward and the caster reaches the vicinity of the lock position, when the lock claw is automatically engaged with the caster, the lock claw urged by the lock portion urging spring collides with the caster and makes a sound. And vibration occurs.
With these sounds and vibrations, the table device provided with such a movement restraining mechanism is subjected to high quality. In addition, if the movement restraint mechanism is operated while an article or the like is placed on the top plate of the table apparatus, the article or the like on the top plate may fall due to vibration.
SUMMARY OF THE INVENTION An object of the present invention is to provide a table device capable of smoothly restraining a table device by a movement restraining mechanism and improving the quality of the table device.

The present invention employs the following means in order to solve the above problems.
That is, the table device according to the present invention has a support leg extending in the vertical direction, an upper surface on which an article can be placed, a top plate supported on the support leg, and a lower surface of the support leg. A caster capable of traveling on the floor, a restraint of movement of the caster and a restraint mechanism capable of releasing the restraint, and an operation member for operating the restraint mechanism. The mechanism is capable of protruding and retracting downward from the support leg, protrudes downward from the caster and can be grounded to the floor surface, and is supported by the one end side so as to be rotatable about a horizontal rotation axis, and the operation member The other end is formed on the grounding member and the other end is pivotable in the vertical direction around the rotation axis, and the grounding member is displaced in the vertical direction in conjunction with the arm member. And a locking member having a first locking portion formed on the arm member and a second locking portion formed on the grounding member and engageable with the first locking portion. The engagement operation of the first lock portion and the second lock portion is started in a state where the grounding member is positioned above the descending end position, and the grounding member moves toward the descending end position while the grounding member moves toward the descending end position. When the other end side of the arm member swings and the grounding member reaches the lowered end position, the engaging operation between the first lock portion and the second lock portion is completed.

In such a configuration, when the arm member is swung in the vertical direction by the operation member, the linkage member is displaced in the vertical direction in conjunction with the rocking of the arm member. Then, the grounding member is displaced in the vertical direction, and appears and disappears downward from the support leg. Then, the other end side of the arm member is swung downward, and when the grounding member reaches its descending end position, the grounding member protrudes below the caster and contacts the floor surface. Thereby, the movement of a table apparatus can be restrained with the frictional resistance which arises between the lower surface of a grounding member, and a floor surface. In this state, the first lock portion and the second lock portion of the lock means are engaged, whereby the arm member and the ground member are engaged, and the ground member is restrained in a protruding state.
Further, when the other end side of the arm member is swung upward, the engagement of the first lock portion and the second lock portion of the lock means is released, so that the restraint of the ground member is released, and the ground member Can move upward and away from the floor surface to release the restraint of the table device by the casters.
When the grounding member is positioned above the lower end position, the locking means starts the engagement operation between the arm member and the grounding member. When the grounding member further moves toward the lowered end position, the other end side of the arm member swings, and when the grounding member reaches the lowered end position, the engagement operation between the arm member and the grounding member is completed. In this way, the ground member gradually engages with the arm member while moving toward the lower end position, so that the arm member and the ground member smoothly engage.

Further, in the table device according to the present invention, the lock means includes the first lock portion being a protrusion, the second lock portion being an engagement recess that engages with the protrusion, and the engagement recess being Further, it may be formed along the movement locus of the protrusion accompanying the swing of the arm member.
In such a locking means, since the engaging recess is formed along the movement trajectory of the protrusion accompanying the swing of the arm member, the arm member is directed downward as the grounding member reaches the lower end position. When the oscillating, the protrusion enters the engaging recess and smoothly engages.

The table device according to the present invention may be in a non-linked state in which the linkage member and the arm member are not linked in a state where the arm member and the grounding member are engaged by the locking unit. .
According to such a configuration, when the linkage member and the arm member are brought into a non-linked state in a state where the arm member and the grounding member are engaged, a load acting on the grounding member is applied to the arm member via the linkage member. Does not work. Thereby, it is possible to prevent the linkage member from being bent or deformed by the reaction force of the load.
Further, when the engagement between the arm member and the grounding member is released, the arm member and the linking member are not linked, so that the force acting on the arm member via the operation member is not transmitted to the linking member. In addition, it is used for releasing the engagement with the grounding member. Therefore, the engagement between the arm member and the grounding member can be released with a light force.

The table device according to the present invention may further include a biasing member that biases the grounding member downward.
According to such a configuration, by urging the grounding member downward by the urging member, the engagement between the arm member and the grounding member by the locking unit is ensured.

In the table device according to the present invention, the arm member and the grounding member are engaged by the locking means on the opposite side of the arm member across the rotation shaft on the one end side from the other end side. An arm biasing member that biases the arm member in the direction may be provided.
According to such a configuration, the arm member is urged by the arm urging member in a direction in which the arm member and the grounding member are engaged by the locking unit, so that the grounding member is reliably engaged by the locking unit. Can do.

  According to the present invention, since the arm member and the grounding member can be smoothly engaged when the grounding member reaches the descending end position, the table device is smoothly restrained by the movement restraining mechanism. It is possible to improve the quality.

It is a side view which shows the structure of the table apparatus concerning this embodiment. It is a perspective view when the principal part of the table apparatus of FIG. 1 is seen from back. FIG. 3 is a perspective view in a state where some parts of the configuration shown in FIG. 2 are excluded. It is a side view which shows the 3rd state which pulled up the top plate of the table apparatus. FIG. 4 is a perspective view in a state where some parts of the configuration shown in FIG. 3 are excluded. FIG. 6 is a perspective view in a state where some parts of the configuration shown in FIG. 5 are excluded. It is sectional drawing which shows the structure of the stopper mechanism in a table apparatus. It is a perspective developed view which shows the component structure of a stopper mechanism. In a stopper mechanism, it is sectional drawing which shows the state in the middle of lowering a grounding member. In a stopper mechanism, it is sectional drawing which shows the state which lowered | falled the earthing | grounding member to the descent | fall end and was made to earth | ground to the floor surface. (A) is a 1st state, (b) is a side view which shows a 2nd state. It is sectional drawing which shows the modification of the stopper mechanism in the table apparatus concerning this embodiment.

  Embodiments of a table device according to the present invention will be described below with reference to the accompanying drawings. However, the present invention is not limited only to this embodiment.

FIG. 1 is a side view showing the configuration of the table device 10. FIG. 2 is a perspective view of the main part of the table device of FIG. 1 when viewed from the rear. FIG. 3 is a perspective view of the configuration shown in FIG. 2 excluding some parts. FIG. 4 is a side view showing a third state in which the top plate of the table device is pulled up. FIG. 5 is a perspective view in a state in which some parts of the configuration shown in FIG. 3 are excluded. FIG. 6 is a perspective view in a state in which some parts of the configuration shown in FIG. 5 are excluded.
In the following description, the floor F side on which the table device 10 is installed is “downward”, the opposite direction is “upward”, the side facing the table device 10 is “front”, and the opposite side is “ It will be referred to as “rear” or “rear side” as appropriate.

As shown in FIG. 1, the table device 10 has a pair of support legs 20 that stand on the floor surface F and extend in the vertical direction, and an upper surface 30 a on which articles can be placed. For example, a rectangular top plate 30 that is supported, and a curtain plate 15 that is positioned below the top plate 30 on the back side of the table apparatus 10 and closes the space between the support legs 20 are provided.
Here, since FIG. 1 is a side view of the table apparatus 10, only one support leg 20 is illustrated, but the top plate 30 is a rectangular having a longitudinal direction in a direction perpendicular to the paper surface of FIG. 1. The support legs 20 are provided at both ends in the longitudinal direction.
In the present invention, the support legs 20 are not limited to two pairs. Depending on the size and shape of the top plate 30, only one or three or more support legs 20 may be provided. it can.

  The support leg 20 includes a base portion 21 installed on the floor surface F, and a hollow columnar column portion 23 that extends upward from the base portion 21 and can stably support the top plate 30 from below. In this embodiment, the support | pillar part 23 is standingly arranged so that it may curve toward diagonally forward from the rear-end part 21r of the base part 21. FIG.

  Casters 24 and 25 that are rotatable on the floor surface F are provided on the front end portion 21f and the rear end portion 21r of the base portion 21, which are the lower surfaces of the support legs 20. By these casters 24 and 25, the table apparatus 10 can be easily traveled on the floor surface F.

  Further, a stopper mechanism (movement restraining mechanism) 50 capable of restraining the movement of the table device 10 by the casters 24 and 25 and releasing the restraint is provided at one end portion of the base portion 21, for example, an end portion on the rear side. ing.

  As shown in FIGS. 1 and 2, the pair of support legs 20 and 20 are integrally connected by a connecting shaft 26 extending in the width direction of the top plate 30. As shown in FIG. 3, the connecting shaft 26 has mounting plate portions 27 at both ends thereof. The mounting plate portion 27 is fixed to the column portion 23 with bolts or the like.

In such a table device 10, the top plate 30 and the curtain plate 15 are used in a usage state where the top plate 30 is horizontal and the curtain plate 15 is vertical on the back side of the top plate 30, and the top plate 30 is moved upward from the usage state. It is possible to switch between an inclined storage state that can be repelled and stored.
Hereinafter, a configuration for that purpose will be described.

(Top plate rotation mechanism)
As shown in FIGS. 1 and 3, the top plate 30 is integrally provided with support frames 31 at both ends thereof. Each support frame 31 is located in a plane orthogonal to the lower surface 30 b of the top plate 30 and is fixed to the lower surface 30 b by a plurality of bolts 32.

The support frame 31 is provided with a shaft 33 having an axis in the direction connecting the support legs 20 on both sides. The shaft 33 is supported by the cam plate 29 so as to be rotatable about its axis.
Thereby, the top plate 30 is rotatable about the shafts 33 provided on the support frames 31 at both ends. As shown in FIG. 1, the top plate 30 is in a use state in which the upper surface 30a is horizontal, and as shown in FIG. 4, the top plate 30 is tilted up by repelling the front end 30f side upward. It is possible to rotate between the states.

Here, as shown in FIG. 1, when the top plate 30 is used in a horizontal state, the lower surface 30 b of the top plate 30 abuts against the upper surface 29 u of the cam plate 29. Thereby, while maintaining the upper surface 30a of the top plate 30 in a use condition, it is controlled that the front end part 30f side of the top plate 30 rotates below from a horizontal use condition.
As shown in FIG. 4, the bottom surface 30 b of the top plate 30 abuts the slope 29 s of the cam plate 29 when the top plate 30 is lifted up. As a result, the connecting shaft 26 is fitted into the recess 31b formed in the support frame 31, and the rotation in the direction in which the front end 30f side of the top plate 30 is repelled upward is restricted.

(Movement restraint mechanism)
As shown in FIGS. 5 and 6, the connecting shaft 26 has a predetermined clearance with the support frame 31 and is positioned in a plane perpendicular to the axis of the connecting shaft 26 and faces the support frame 31. A plate 29 is provided.
The base portion 29 a of the cam plate 29 is integrally fixed to the outer peripheral surface of the connecting shaft 26. The cam plate 29 extends upward from the base portion 29a, and the shaft 33 is fixed through. The cam plate 29 is formed with a cam guide hole 29c, which will be described later, on the inside thereof, and a lock claw engagement groove 29b is formed on the lower outer peripheral surface.

  As shown in FIG. 6, a floating lever member 36 is disposed on one surface side of the cam plate 29. The floating lever member 36 includes a substantially U-shaped lever portion 36a, a rotary shaft 36b formed to protrude from the lever portion 36a on the opposite side of the cam plate 29, and a rotary shaft 36b on one end side of the lever portion 36a. A first guide protrusion 36c that protrudes on the same side and a second guide protrusion 36d that protrudes on the opposite side of the rotary shaft 36b on one end side of the lever portion 36a are provided.

As shown in FIG. 5, a swing plate 37 is disposed on the opposite side of the floating lever member 36 from the cam plate 29 side. One end portion 37 a of the swing plate 37 is rotatably connected to a shaft 33 that serves as a rotation center of the top plate 30. Thereby, the swing plate 37 is rotatable about the shaft 33, and the other end 37b side can be swung.
The rotating shaft 36b of the floating lever member 36 is inserted into the other end 37b which is the free end side of the swing plate 37. As a result, the floating lever member 36 can be rotated around the rotation shaft 36 b at the other end portion 37 b which is the free end side of the swing plate 37.
The swing plate 37 is formed with an arcuate guide groove 37c centered on the rotary shaft 36b. A first guide protrusion 36c is inserted into the guide groove 37c. Accordingly, the rotation range of the floating lever member 36 around the rotation shaft 36b is restricted by the first guide protrusion 36c moving within the range of the guide groove 37c.

  Further, as shown in FIG. 6, the second guide protrusion 36d of the floating lever member 36 is disposed so as to be positioned in the cam guide hole 29c of the cam plate 29, and is movable within the range of the cam guide hole 29c. ing. The cam guide hole 29c is formed so as not to hinder the movement of the second guide protrusion 36d.

  The support frame 31 has a shaft receiving groove 38 formed in the upper part thereof. A rotating shaft 39 provided in parallel with the shaft 33 is supported in the shaft receiving grooves 38 so as to be rotatable around the axis thereof. At least one end 39 a of the rotation shaft 39 protrudes to the side of the support frame 31.

(Top plate restraint mechanism)
The rotating shaft 39 is integrally provided with a locking claw member 41 and an arm member 42 that are V-shaped in a side view.
Here, the locking claw member 41 is provided so as to be positioned in the same plane as the cam plate 29. The locking claw member 41 is formed to extend from the rotary shaft 39 along the lower outer peripheral surface of the cam plate 29. The latching claw member 41 is configured such that a latching claw 41 </ b> S formed at the tip of the latching claw member 41 can be latched in the locking claw engagement groove 29 b of the cam plate 29. In the state in which the locking claw 41S is locked in the lock claw engaging groove 29b, the rotation of the top plate 30 is restricted, and the upper surface 30a is horizontal.

The arm member 42 is formed so as to be offset in the thickness direction of the cam plate 29 with respect to the locking claw member 41 and is provided so as to be positioned in the same plane as the floating lever member 36.
A recess 43 is formed at the tip 42 a of the arm member 42. The recess 43 of the arm member 42 abuts against one end of the lever portion 36a of the floating lever member 36 when the top plate 30 is in use.

(Control lever)
As shown in FIG. 5, an operation lever (operation member) 40 is integrally fixed to the end 39 a of the rotary shaft 39 protruding from the support frame 31. Here, the operation lever 40 is provided so as to extend to the opposite side of the locking claw member 41 and the arm member 42 with respect to the rotary shaft 39. Thereby, the operation lever 40 is provided integrally with the locking claw member 41 and the arm member 42 via the rotary shaft 39.
By operating the operation lever 40 in the direction around the axis of the rotary shaft 39, the locking claw member 41 and the arm member 42 rotate around the axis along with the rotary shaft 39.

(Curtain plate moving mechanism)
Further, the upper end 15a of the curtain plate 15 is connected to the lower end of the cam plate 29 via a link plate 45A. Both end portions of the link plate 45A are rotatably connected to the cam plate 29 and the curtain plate 15 via pins 46A and 46B.
Further, a connecting plate 47 whose one end is connected to the rear ends of the support frames 31 and 31 is connected to the intermediate portion of the link plate 45A. The connecting plate 47 is also rotatably connected to the link plate 45A and the support frame 31 via pins 48A and 48B.
A support groove 23 of the support leg 20 is formed with a slide groove 23a continuous in the vertical direction. The lower end 15b of the curtain plate 15 is slidably coupled along the slide groove 23a via the link plate 45B and the coupling pin 49.

(Stopper mechanism)
FIG. 7 is a cross-sectional view showing a configuration of a stopper mechanism in the table device. FIG. 8 is an exploded perspective view showing the component structure of the stopper mechanism. FIG. 9 is a cross-sectional view showing a state in the middle of lowering the grounding member in the stopper mechanism. FIG. 10 is a cross-sectional view showing a state where the grounding member is lowered to the descending end and is grounded to the floor surface in the stopper mechanism.
As shown in FIG. 7, the stopper mechanism 50 provided in the base portion 21 includes a grounding member 51, a linkage pin (linkage member) 54, a biasing member 57, an arm member 55, and an arm biasing member 59. , And locking means 60.

  The grounding member 51 includes a shaft 51s extending in the vertical direction and a grounding pad 51p having a disk shape provided at the lower end of the shaft 51s and having a lower surface 51b parallel to the floor surface F. The grounding member 51 can protrude and descend from the support leg 20 downward, protrudes downward from the caster 25, and the grounding pad 51p can be grounded to the floor surface F.

  A hollow cylindrical holder 53 is provided in the hollow support 23. The holder 53 includes holder members 53a and 53a that are divided into two along the central axis in the vertical direction.

  Each holder member 53a includes a shaft insertion hole 53c through which the shaft 51s is inserted in the vertical direction, a spring housing portion 53s for housing the biasing member 57, and an arm member 55 on the mating surface side between the holder members 53a and 53a. An arm accommodating portion 53d for accommodating, an arm urging member accommodating portion 53e for accommodating the arm urging member 59, and an operation rod insertion portion 53f for inserting the operation rod 58 are formed.

  The shaft insertion hole 53c is formed so as to penetrate the holder member 53a in the vertical direction. The spring accommodating portion 53s is formed in the upper part of the shaft insertion hole 53c by expanding the diameter of the shaft insertion hole 53c over a certain length in the vertical direction.

The arm accommodating portion 53d is formed below the shaft insertion hole 53c, and a space in which the arm member 55 can swing is formed around the shaft insertion hole 53c.
The arm urging member accommodating portion 53e is formed to extend upward from one side end portion of the arm accommodating portion 53d.

  The operation rod insertion portion 53f extends upward from the other side end portion of the arm accommodating portion 53d and penetrates to the upper surface of the holder member 53a. The operation rod insertion portion 53f has a constant inner diameter within a certain length range downward from the upper surface of the holder member 53a, and has a reduced diameter portion 53g at a portion communicating with the lower arm accommodating portion 53d. Yes.

  The shaft 51s is inserted into the shaft insertion hole 53c of the holder 53 and is slidable in the vertical direction. Further, the lower portion of the shaft 51 s penetrates the caster bracket 25 b that fixes the caster 25 to the lower surface of the holder 53. A grounding pad 51p is provided at the lower end of the shaft 51s penetrating the caster bracket 25b.

  The linking pin 54 is formed so as to protrude from the outer peripheral surface of the shaft 51 s of the grounding member 51 in a direction perpendicular to the central axis of the shaft 51 s. The linkage pins 54 are provided on both sides of the central axis of the shaft 51s. And the front-end | tip part of the link pin 54 is inserted in the guide groove 53m formed in the internal peripheral surface of the arm accommodating part 53d of the holder member 53a, and continuing in an up-down direction. When the grounding member 51 is displaced in the vertical direction, the linkage pin 54 slides in the guide groove 53m. And when the linkage pins 54 abut against the upper and lower ends of the guide groove 53m, the vertical movement stroke of the grounding member 51 is restricted.

  The urging member 57 is formed of a substantially cylindrical coil spring. The grounding member 51 is inserted inside the urging member 57. The biasing member 57 is compressed between a ring portion 51r formed integrally with the grounding member 51 and projecting to the outer peripheral side, and an upper end of a spring accommodating portion 53s formed on the holder 53 above the ring portion 51r. Is provided. Thereby, the urging member 57 urges the grounding member 51 downward.

As shown in FIG. 8, the arm member 55 is provided in pairs of two arranged on both sides of the central axis of the shaft 51s.
The two pairs of arm members 55 are integrally connected to each other at one end side 55a and the other end side 55b. In this way, the pair of two arm members 55 are integrally connected in a state of facing each other with a space therebetween by the connecting portions 55j provided at a plurality of locations. Thus, a hollow portion 55h is formed between the two pairs of arm members 55 and 55 when seen in a plan view, and the grounding member 51 is inserted into the hollow portion 55h. Such a pair of arm members 55, 55 and a connecting portion 55j for connecting them can be integrally formed of a cast product made of a metal material, a molded product made of a resin material, or the like.

  One end side 55a of each arm member 55 is provided with a rotation shaft 56 having a central axis in the horizontal direction and protruding toward the inner peripheral surface of the arm accommodating portion 53d of the holder member 53a. The rotation shaft 56 is rotatably held in a shaft support hole 53h formed on the inner peripheral surface of the arm housing portion 53d. As a result, the arm member 55 is supported such that one end side 55 a is rotatable around the rotation shaft 56.

As shown in FIG. 7, the other end side 55b of each arm member 55 is formed with a hook portion 55f extending downward. The hook portion 55f is formed with a locking recess 55g that opens downward. Both ends of the connecting pin 52 are locked to the locking recesses 55g of the two pairs of arm members 55. The tip of an operation rod (operation transmission member) 58 operated by the operation lever 40 is connected to the central portion of the connection pin 52. The operation rod 58 is inserted into a cylindrical tube body 58K provided in the column portion 23. The upper end of the operating rod 58 is connected to the first guide protrusion 36c of the floating lever member 36 shown in FIG.
As a result, as shown in FIGS. 7, 9, and 10, the arm member 55 has the other end side with respect to the rotation shaft 56 as a result of the operation rod 58 being displaced in the central axis direction by the operation of the operation lever 40. 55b can swing in the vertical direction.

On the upper surface of the arm member 55, a curved concave portion 55w that is concave downward is formed at an intermediate portion between the one end side 55a and the other end side 55b. The connecting pin 54 of the shaft 51s comes into contact with the curved recess 55w.
In this arm member 55, when the arm member 55 is swung up and down by the operation lever 40 in a state where the link pin 54 hits the curved recess 55 w on the upper surface (upper part) of the intermediate part of the arm member 55, the link pin 54 is moved up and down. Is displaced up and down in conjunction with the swing of the arm member 55. Then, the grounding member 51 is displaced up and down, and appears and disappears from the support leg 20 downward. In addition, the operation | movement which appears and disappears below is an operation | movement which protrudes below and returns to the original position.
As described above, the curved recess 55w is such that the portion with which the linkage pin 54 abuts when the arm member 55 is swung to move the grounding member 51 in the vertical direction always moves in the direction in which the grounding member 51 moves (the direction of the central axis of the shaft 51s). ) To form a curved surface that is continuous.

The arm member 55 has extension portions 55c and 55d extending upward from the curved recess 55w on one end side 55a and the other end side 55b, respectively, and has a substantially U shape as a whole.
Here, on the other end side 55 b of the arm member 55 extending upward, the connecting pin 52 to which the tip of the operating rod 58 is connected is vertically below the lower end portion 58 b of the tubular body 58 K held by the holder 53. It is provided so that it may be located in.
More specifically, the connecting pin 52 is a tube held by the holder 53 in a state in which a projection 61 of the locking means 60 described later and an engaging recess 62 are engaged and the grounding member 51 is grounded to the floor surface F. It is provided so as to be positioned vertically below the lower end 58b of the body 58K. Accordingly, when the operation lever 40 is operated to swing the other end side 55b of the arm member 55 upward, and the engagement between the projection 61 and the engagement recess 62 is released, the operation pin 58 is connected to the connecting pin. The operating force applied to the arm member 55 is transmitted most efficiently through 52.
Further, the connecting pin 52 is preferably arranged on the outermost side of the arm member 55 with respect to the rotation shaft 56 that is the center of rotation. Thereby, the curvature radius of the movement locus | trajectory of the connection pin 52 when the arm member 55 rock | fluctuates becomes large by arrange | positioning the connection pin 52 to the outermost periphery side. In addition, the connection pin 52 is preferably provided so that the movement range of the connection pin 52 when the arm member 55 swings is in a region having substantially the same height as the rotation shaft 56. In this way, when the arm member 55 is swung by operating the operation lever 40, the tip of the operation rod 58 is connected in the horizontal direction perpendicular to the vertical direction (the left-right direction in the drawing of FIG. 7). The movement width of the connecting pin 52 can be kept small. Therefore, the swing width in the horizontal direction (left and right direction in FIG. 7) orthogonal to the vertical direction of the operation rod 58 is reduced. Thereby, it is possible to suppress the operation rod 58 from being buffered by other members and the like, and it is possible to suppress a resistance force due to friction with the inner peripheral surface of the tube body 58K.

In the extending portion 55c of the arm member 55, an arm biasing member 59 that biases the arm member 55 upward is provided on the opposite side to the other end side 55b across the rotation shaft 56 on the one end side 55a. The two pairs of arm members 55, 55 support both ends of a support shaft portion 55s extending in a direction of connecting them. The lower end 59a of the arm biasing member 59 is locked to the center portion of the support shaft portion 55s. The upper end 59b of the arm urging member 59 is locked to a support shaft portion 53z provided in the arm urging member accommodating portion 53e of the holder member 53a. The support shaft portion 53z extends in a direction connecting the holder members 53a and 53a, and both end portions thereof are supported by the holder members 53a and 53a.
The arm urging member 59 is formed by a tension spring that applies a tensile force in a direction in which the lower end 59a and the upper end 59b approach each other.

The lock means 60 includes a projection (first lock portion) 61 formed on the arm member 55, an engagement recess (second lock portion) 62 formed on the shaft 51s of the grounding member 51, with which the projection 61 engages, It has. The protrusion 61 is a shaft-like member 61 s extending in a direction connecting the two pairs of arm members 55, 55, and both ends of the shaft-like member 61 s are formed by being supported by the arm members 55, 55. . The engaging recess 62 is formed so as to be gradually inclined downward from the outer peripheral surface of the shaft 51s toward the center side of the shaft 51s.
As shown in FIG. 10, the locking means 60 restrains the grounding member 51 from being displaced upward by the protrusion 61 of the arm member 55 engaging with the engaging recess 62 of the grounding member 51.
Here, as shown in FIGS. 9 and 10, the arm member 55 swings with the other end side 55 b downward as the grounding member 51 descends. Then, as shown in FIG. 10, when the grounding member 51 is positioned above the lower end position just before the grounding member 51 reaches the lower end position, the protrusion 61 enters the engaging recess 62, and the arm member The engaging operation of 55 and the grounding member 51 is started. When the grounding member 51 further moves toward the lowered end position, the other end side 55b of the arm member 55 swings downward in conjunction with it. When the grounding member 51 reaches the lowered end position, the engaging operation between the protrusion 61 and the engaging recess 62 is completed. For this reason, the engaging recess 62 is formed to be curved in an arc along the swing locus of the protrusion 61 formed on the arm member 55.

  In addition, as shown in FIG. 10, in the state where the arm member 55 and the grounding member 51 are engaged by the engagement of the protrusion 61 of the lock means 60 and the engagement recess 62, the linkage pin 54 and the arm member 55 Are separated from each other in the up-and-down state. For this reason, after the linkage pin 54 of the grounding member 51 hits the lower end of the guide groove 53m, the downward movement stroke of the grounding member 51 is restricted, and then the arm member 55 is further swung by a certain angle. 61 engages with the engaging recess 62.

  In the stopper mechanism 50 having such a configuration, as shown in FIGS. 7 and 9, when the grounding member 51 is pulled up, the linkage provided on the grounding member 51 urged downward by the urging member 57. The pin 54 hits the curved recess 55w of the arm member 55 and is linked. When the arm member 55 is swung in the vertical direction by the operation lever 40, the arm member 55 is displaced in the vertical direction in conjunction with the rocking of the arm member 55. Then, the grounding member 51 is displaced in the vertical direction, and appears and disappears downward from the support leg 20.

  When the grounding member 51 is projected downward from the state shown in FIG. 7 as shown in FIGS. 9 and 10, the operation lever 40 is operated to swing the other end side 55b of the arm member 55 downward. . Then, the grounding member 51 is displaced downward in conjunction with the swing of the arm member 55. The ground member 51 is urged downward by the urging member 57. The arm member 55 is urged downward by the arm urging member 59 at the other end 55b. Accordingly, the grounding member 51 can be protruded downward by operating the operation lever 40 with a light force.

As shown in FIG. 10, when the grounding member 51 protrudes below the casters 24 and 25 and contacts the floor surface F, the casters 24 and 25 cause frictional resistance generated between the lower surface of the grounding member 51 and the floor surface F. The movement of the table device 10 can be restricted. At this time, since the grounding member 51 is biased downward by the biasing member 57, the frictional force generated between the lower surface of the grounding member 51 and the floor surface F is increased, and the movement restraining force of the table apparatus 10 is increased. be able to.
Further, in this state, the arm member 55 and the grounding member 51 are engaged by the lock means 60 and are restrained in a state where the grounding member 51 protrudes. The arm member 55 on which the protrusion 61 constituting the lock means 60 is formed is urged by the arm urging member 59 in the direction in which the protrusion 61 bites into the engaging recess 62. Thereby, the engagement state of the arm member 55 and the grounding member 51 by the lock means 60 is reliably maintained.
Further, immediately before the grounding member 51 is grounded to the floor F, if the downward movement of the grounding member 51 is restricted by the linkage pins 54 abutting against the upper and lower ends of the guide groove 53m, the linkage pin 54 and the arm The member 55 is separated in the vertical direction and is in a non-linked state. Then, the urging force of the urging member 57 that urges the shaft 51s downward is transmitted only to the shaft 51s, and the urging force of the urging member 57 is effectively exhibited. Further, the load acting on the grounding member 51 does not act on the arm member 55 via the linkage pin 54.

  When the operation lever 40 is operated from the state shown in FIG. 10 and the other end side 55b of the arm member 55 is swung upward, as shown in FIG. The engagement with 51 is released, and the grounding member 51 moves upward and leaves the floor surface F. Thereby, the restraint of the table apparatus 10 by the casters 24 and 25 can be released.

(Switching with operation lever)
In the table device 10 having the above-described configuration, the top plate 30 is in a non-rotatable state in a use state where the upper surface 30a is horizontal, and the top state is such that the movement of the table device 10 by the casters 24 and 25 is restricted. The second state in which the lock of the movement of the table device 10 is unlocked while the plate 30 is not rotatable in the use state where the upper surface 30a is horizontal, and the movement of the table device 10 is performed while the top plate 30 is rotatable. It is possible to switch to the third state in which the lock of the constraint is released by rotating the operation lever 40. And in a 3rd state, it will be in the state which a user can rotate the top plate 30 and can transfer to a storage state from a use state.
Details are shown below.

(First state)
As shown in FIG. 11A, when the top surface 30 a of the top plate 30 is horizontal and the curtain plate 15 is in a first state that is substantially vertical on the back side of the top plate 30, the user The space above can be used. In this state, in the curtain plate 15, the link plate 45A is positioned on the upper side of the pin 46B with respect to the pin 46A according to the interval between the pins 48A and 48B of the connecting plate 47, and the curtain plate 15 is on the back side of the top plate 30. It is located almost vertically below.
In this state, the locking claw 41S is locked in the lock claw engaging groove 29b, and the top plate 30 is restrained from rotating so that the upper surface 30a is in a horizontal use state.
7 and 8, in this state, the first guide protrusion 36c of the floating lever member 36 is located at the lower end of the guide groove 37c of the swing plate 37, and the grounding member 51 is correspondingly corresponding to this. The ground pad 51p is grounded to the floor surface F and is pressed against the floor surface F by the urging force of the urging member 57. In this state, the casters 24 and 25 remain grounded without rising from the floor surface F, and the movement of the table device 10 is restrained by the frictional force between the ground pad 51p and the floor surface F. Yes.

(Second state)
As shown in FIG. 11B, when the user pulls the operation lever 40 upward by a certain amount from the first state, the locking claw member 41 and the arm member 42 rotate around the axis of the rotation shaft 39. . Then, the floating lever member 36 is pressed by the arm member 42. As a result, the floating lever member 36 rotates about the rotation shaft 36 b, and the first guide protrusion 36 c moves upward along the guide groove 37 c of the swing plate 37.
As a result, the operation rod 58 moves upward. Then, the arm member 55 rotates about the rotation shaft 56, and the other end side 55b rises. As a result, as shown in FIG. 9, the ground pad 51 p of the ground member 51 rises and separates from the floor surface F to be in the second state. Thereby, the table apparatus 10 can be moved on the floor surface F by the casters 24 and 25.
Further, as shown in FIG. 11B, in this state, the locking claw 41S formed at the tip of the locking claw member 41 is completely removed from the lock claw engaging groove 29b of the cam plate 29. The top plate 30 is kept locked, and is kept locked.

(Third state)
As shown in FIG. 1, when the operation lever 40 is further pulled upward, the locking claw 41 </ b> S formed at the tip of the locking claw member 41 comes out of the lock claw engagement groove 29 b of the cam plate 29. Unlocked state. As a result, the top plate 30 is unlocked while being able to move on the floor surface F by the casters 24, 25, and a third state is reached in which the top plate 30 can be lifted up.
In this state, the shaft 51s and the ground pad 51p of the grounding member 51 are maintained in the same state as in the second state, that is, the state separated from the floor surface F, and the table device 10 is supported by the casters 24 and 25. It can move on F.

(Fourth state)
When the user pulls the front end 30 f of the top plate 30 upward from the third state, the top plate 30 rotates about the shafts 33 and 33. Then, the connecting plate 47 whose one end is connected to the back side of the top plate 30 moves downward as the top plate 30 rotates, whereby the intermediate portion of the link plate 45A is pressed downward. The link plate 45A rotates around the pin 46A, and the pin 46B side moves downward. As a result, the curtain plate 15 is pushed downward. At this time, the lower end portion 15 b of the curtain plate 15 slides downward along the slide groove 23 a of the column portion 23.
Then, when the connecting shaft 26 abuts against the recess 31b formed in the support frame 31, the rotation of the top plate 30 is restricted. In this state, as shown in FIG. 4, the locking claw 41 </ b> S of the locking claw member 41 is fitted into the stepped portion 29 d formed on the cam plate 29, and thereby the top plate 30 is flipped up. Restrains in a non-rotatable state when stored. In this way, finally, the top plate 30 and the curtain plate 15 are raised to a state where they are located along the back side of the support column 23.
As a result, the table device 10 can accommodate a plurality of units that are overlapped in the front-rear direction.

  In this state, the first guide protrusion 36 c of the floating lever member 36 is positioned at the lower end of the guide groove 37 c of the swing plate 37, but the swing plate 37 moves the shaft 33 along with the rotation of the top plate 30. It rotates about the center, and the position of the first guide protrusion 36c is maintained in the same state as the second and third states. As a result, the ground pad 51p remains away from the floor surface F, and the table device 10 maintains a state where it can be moved on the floor surface F by the casters 24 and 25.

When the front end 30f of the top plate 30 is pushed down from the fourth state, the top plate 30 rotates about the shafts 33 and 33, and the curtain plate 15 is pulled upward by the link plate 45A and the connecting plate 47.
When the lower surface 31a of the support frame 31 of the top plate 30 abuts on the connecting shaft 26, the top plate 30 is in a second horizontal state as shown in FIG. When the operation lever 40 is lowered in this state, the arm member 55 is rotated by the urging force of the urging member 57, and the other end side 55b is lowered. As a result, the grounding pad 51p of the grounding member 51 descends and contacts the floor surface F, resulting in the first state as shown in FIG.

According to the configuration as described above, by directly biasing the grounding member 51 downward by the biasing member 57, the frictional force generated between the lower surface of the grounding member 51 and the floor surface F is increased, and the table device 10 The movement restraining force can be increased. When operating the grounding member 51, the arm member 55 is a fulcrum whose one end side 55 a is the center of rotation, the other end side 55 b is a force point for transmitting the operation force by the operation lever 40, and the intermediate portion is the link pin 54. This acts as an action point for displacing the grounding member 51 in the vertical direction. When the biasing member 57 is provided, the grounding member 51 is operated against the downward biasing force of the biasing member 57 in order to move the grounding member 51 upward in order to release the restraint of the table device 10. There is a need. However, in such a configuration, since the action point of the arm member 55 is closer to the fulcrum than the force point, the arm member 55 can be operated with a lighter force.
Therefore, it is possible to operate the stopper mechanism 50 with a light operating force while increasing the restraining force of the table device 10.

Further, according to the configuration as described above, the curved concave portion 55 w that is concave downward is formed on the upper surface of the arm member 55. The curved concave portion 55w is formed such that the portion where the linkage pin 54 abuts when the arm member 55 is swung to move the grounding member 51 in the vertical direction is always orthogonal to the moving direction of the grounding member 51.
When the upper surface of the arm member 55 is linear from the one end side 55 a to the other end side 55 b, the upper surface of the arm member 55 is inclined by the swinging of the arm member 55. Then, when the arm member 55 is swung to move the grounding member 51 in the vertical direction, the force transmitted from the arm member 55 to the linkage pin 54 is dispersed in the vertical direction and the horizontal direction.
On the other hand, when the curved concave portion 55w is formed on the upper surface of the intermediate portion of the arm member 55 as described above, the arm member 55 is swung to move the grounding member 51 in the vertical direction on the upper surface of the arm member 55. The portion where the linkage pin 54 abuts can be a horizontal plane orthogonal to the direction of movement of the linkage pin 54. Therefore, it is possible to prevent the force transmitted from the arm member 55 to the linkage pin 54 from being dispersed in the horizontal direction. Accordingly, the operating force of the arm member 55 can also be reduced in this respect.

Further, the arm member 55 is provided in two pairs arranged on both sides of the center axis of the grounding member 51, and the linkage pins 54 are provided so as to protrude on both sides of the center axis of the grounding member 51, respectively. It has been.
As a result, the grounding member 51 moves in the vertical direction while the linkage pin 54 abuts against the arm member 55 on both sides of the center axis. As a result, the grounding member 51 stably moves in the vertical direction.

  Furthermore, the pair of two arm members 55 are integrally connected to each other at one end side 55a and the other end side 55b, and the grounding member 51 is inserted through the hollow portion 55h. Thereby, it is possible to prevent the ground contact member 51 from being displaced in a direction (horizontal direction) orthogonal to the central axis. Further, at the time of assembly, the grounding member 51 may be inserted through the hollow portion 55h, and the assembly can be easily performed.

  In the arm member 55, an arm urging member 59 for urging the arm member 55 upward is provided on the opposite side to the other end side 55b across the rotation shaft 56 on the one end side 55a. Thereby, the swinging of the arm member 55 in the direction in which the grounding member 51 is displaced downward can be urged, and the operating force when the grounding member 51 protrudes downward can be reduced. Further, the arm biasing member 59 biases the arm member 55 in a direction in which the projection 61 does not come out of the engagement recess 62 in a state where the projection 61 of the lock means 60 and the engagement recess 62 are engaged. The engaged state between the arm member 55 and the ground member 51 can be reliably maintained.

  Further, the locking means 60 starts the engagement between the protrusion 61 and the engaging recess 62 immediately before the grounding member 51 reaches the lowered end position, and the protrusion 61 and the engaging recessed portion when the grounding member 51 reaches the lowered end position. The engagement with 62 is completed. Further, in the lock means 60, the engagement recess 62 is formed along the swing locus of the arm member 55. Accordingly, when the arm member 55 swings downward as the grounding member 51 reaches the lower end position, the protrusion 61 enters the engagement recess 62 and engages. Therefore, the arm member 55 and the grounding member 51 are smoothly engaged. As a result, when the arm member 55 and the grounding member 51 are engaged with each other by the lock means 60, it is possible to suppress the occurrence of impact and sound, and to make the table device 10 have a high-quality operational feeling.

  Further, when the grounding member 51 is grounded to the floor surface F and the arm member 55 and the grounding member 51 are engaged with each other by the lock means 60, the linkage pin 54 and the arm member 55 are brought into a non-linked state. Yes. Then, the load acting on the grounding member 51 does not act on the arm member 55 via the linkage pin 54. Thereby, it is possible to prevent the linkage pin 54 from being bent or deformed by the reaction force of the load.

In addition, by operating the operation lever 40, the locking claw member 41 restrains / releases the rotation of the top plate 30, and the arm member 42 operates the operation rod 58 that moves the ground pad 51p up and down. Thus, in the table apparatus 10, whether or not the top plate 30 is lifted up and whether or not the casters 24 and 25 are locked can be easily selected according to the operation of the operation lever 40 by the user.
Then, in a state where the rotation lock of the top plate 30 is released by the operation of the operation lever 40, the top plate 30 can be easily rotated with a light operation force. Moreover, since the rotation of the operation lever 40 is independent of the rotation operation of the top plate 30, the operation lever 40 can be operated with a light operation force.

  Further, the movement restriction of the table device 10 can be released by operating the ground pad 51p only by operating the operation lever 40, without lifting the top plate 30. As a result, the table apparatus 10 can be easily moved even when an article or the like is placed on the top board 30, and convenience can be improved. Further, the table apparatus 10 can always be easily moved in a state where the top plate 30 is lifted up.

(Other embodiments)
The table device of the present invention is not limited to the above-described embodiment described with reference to the drawings, and various modifications can be considered within the technical scope.
For example, in the above-described embodiment, the protrusion 61 is provided on the arm member 55 and the engaging recess 62 is formed on the shaft 51s of the ground member 51 as the lock unit 60. However, the protrusion 61 is provided on the shaft 51s of the ground member 51. The engaging recess 62 may be formed in the arm member 55.

  Moreover, in the said embodiment, although it was set as the structure provided with the curved recessed part 55w on the upper surface of the arm member 55, it is not restricted to this. As shown in FIG. 12, the upper surface of the arm member 55 may be linearly formed from the one end side 55a to the other end side 55b.

In addition, the configuration of each part of the table device 10 may be any other configuration as long as it has a shape and structure that can realize the configuration in accordance with the gist of the present invention. For example, the top plate 30 may be configured to repel the rear end portion 30r side instead of the front end portion 30f side. The curtain plate 15 may not be moved in conjunction with the top plate 30 but may be fixed integrally to the column portion 23. In addition, in the use state, the top plate 30 is in a horizontal state, but is not limited thereto, and may be in an inclined state.
Furthermore, the configuration of the present invention can be applied to a table device having a configuration in which the top plate 30 does not lift up.

Further, by rotating the operation lever 40 upward, the movement restriction of the top board 30 and the table device 10 is released, but the operation direction is not limited. Furthermore, the operation lever 40 can be configured to be operated by a slide operation or the like instead of a rotation operation.
Furthermore, the operation of the stopper mechanism 50 is not limited to the operation of the operation lever 40, and may be interlocked with, for example, the rotation operation of the top plate 30.
In addition to this, as long as it does not depart from the gist of the present invention, the configuration described in the above embodiment can be selected or changed to another configuration as appropriate.

DESCRIPTION OF SYMBOLS 10 Table apparatus 20 Support leg 24,25 Caster 30 Top plate 30a Upper surface 40 Operation lever (operation member)
50 Stopper mechanism (movement restraint mechanism)
51 Grounding member 54 Linkage pin (linkage member)
55 Arm member 55a One end side 55b The other end side 56 Rotating shaft 57 Energizing member 59 Arm energizing member 60 Locking means 61 Projection (first lock portion)
62 Engaging recess (second locking part)
F Floor

Claims (5)

A support leg extending in the vertical direction;
A top plate having an upper surface on which an article can be placed and supported on the support leg;
A caster that is provided on the lower surface of the support leg and is capable of traveling on the floor surface;
A movement restraint mechanism capable of restraining the caster and releasing the restraint;
An operation member for operating the movement restraining mechanism,
The movement restraining mechanism is
A grounding member that can be projected and lowered downward from the support leg, protrudes downward from the caster, and can be grounded to a floor surface;
An arm member supported at one end side so as to be rotatable around a rotation axis in the horizontal direction and operated by the operation member so that the other end side can swing up and down around the rotation axis;
A link member formed on the ground member, and linked to the arm member to displace the ground member in the vertical direction to move in and out;
A first locking portion formed on the arm member, and a locking means having a second locking portion formed on the grounding member and engageable with the first locking portion,
The engagement operation of the first lock portion and the second lock portion is started in a state where the grounding member is positioned above the descending end position, and the grounding member moves toward the descending end position while the grounding member moves toward the descending end position. The table device characterized in that when the other end side of the arm member swings and the grounding member reaches the lowered end position, the engaging operation of the first lock portion and the second lock portion is completed. The locking means is
The first lock part is a protrusion,
The second lock portion is an engagement recess that engages with the protrusion,
The table device according to claim 1, wherein the engaging recess is formed along a movement locus of the protrusion accompanying the swing of the arm member.   3. The table device according to claim 1, wherein in a state in which the arm member and the grounding member are engaged by the locking unit, the linkage member and the arm member are not linked to each other. .   The table apparatus according to any one of claims 1 to 3, further comprising a biasing member that biases the grounding member downward.   In the arm member, on the opposite side to the other end side across the rotation shaft on the one end side, an arm is attached to bias the arm member in a direction in which the arm member and the grounding member are engaged by a locking means. The table device according to any one of claims 1 to 4, wherein a biasing member is provided.

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