JP6637663B2 - Mobile table - Google Patents

Description

  The present invention relates to a movable table, and more particularly, to a movable table having casters for movement in a bedside table, an overbed table, and the like.

  Conventionally, a bedside table which is used by moving from the bedside in the width direction of the bed and arranged at a predetermined position, or an overbed table which is moved from the foot side of the bed in the longitudinal direction of the bed and is used by being arranged at a predetermined position And the like, there is known a movable table provided with a lock operation mechanism for preventing a caster from moving when a user uses the table.

  As a prior art, for example, Patent Literature 1 discloses a lifting table in which a column part expands and contracts and a table part moves up and down. And a brake mechanism for locking the four twin-wheel casters, and a caster lock device for an elevating table in which all the casters are locked and unlocked simultaneously by operating one operation lever. ing.

In this caster lock device for a lifting table, a hollow portion is formed in the table portion, and an operation wire, a wire distributor, a branch wire, and the like are stored in the hollow portion. One operating wire from the operating lever is connected to a wire distributor, from which four branch wires extend to each of the two-wheel casters. Two sets of two branch wires pass through the strut (through a pipe in the strut) and connect to the caster lock mechanism of each twin wheel caster. Each branch wire repeats a relaxation and a state without relaxation as the table part moves up and down, but when the table part descends, the relaxed part is stored in the hollow part, and when the table part rises, it is almost It has a structure in which a branch wire that is not relaxed is stored.
In this caster lock device, one left and right wire guide hole is formed facing the hollow portion inside the table portion, and two left and right branch wires pass through each left and right one wire guide hole. And the branch wires are connected to each of the two-wheel casters.

JP 2012-183202 A

However, in the technique of Patent Document 1, since a branch wire for branching inside the table portion is used for a mechanism for locking the two-wheel cast, when a part of the wire is broken, the branch wire connected to the wire branching board is replaced. There is a problem that the lock mechanism of all the casters cannot be used because it is necessary and cannot be operated from the wire distributor.
In addition, in Patent Document 1, it is necessary to install the wire branching machine in the hollow of the table. However, the wire branching machine requires an installation space, and the space in which the wires are slackened is reduced. easy.

  The present invention has been made in view of the above-mentioned conventional problems, and in the movable table, the wire due to the expansion and contraction of the support portion is hardly entangled, and smooth wire feeding is secured, so that the wire is hardly damaged, An object of the present invention is to provide a movable table having high maintainability since only broken wires need to be replaced in the case of breakage.

The movable table according to the present invention for solving the above-mentioned problems is as follows.
The present invention provides a table plate, a support portion that supports the table plate on the upper side and expands and contracts as required to adjust the position of the table plate relative to the leg portion, and a leg portion that supports a lower side of the support portion. A movable table provided on the leg portion, the movable caster being in contact with the floor, and a brake mechanism for restricting the movement,
The brake mechanism has a plurality of members that regulate the movement by a plurality of casters,
A brake operating mechanism for a user to release the brake of the brake mechanism,
The brake operation mechanism includes:
An operation lever for performing a brake release operation of the brake mechanism;
A plurality of first transmission wire members for transmitting the operation of the operation lever to a plurality of brake mechanisms, respectively;
A second transmission wire member for branching at least one of the plurality of first transmission wire members at a column lower portion or a leg portion and transmitting the branched to the brake mechanism;
At the lower portion of the table plate, provided is a housing body for accommodating the plurality of first transmission wire members in a space portion by being slackened,
A movable table, wherein a guide structure for guiding the first transmission wire member is provided in the support section when the support section expands and contracts.
In the present invention, the brake mechanism locks each of a plurality of casters to restrict the movement, and regulates the movement by generating a frictional force between the legs and the floor. It is preferable to have a friction brake mechanism that performs the operation.

  In the present invention, the portion of the guide structure facing the space of the container is formed in a curved shape, and the bending of the first transmission wire member guided from the space to the guide structure is formed in the curved shape. It is preferable to adopt a structure that can be adjusted and guided by the formation portion of the hologram.

  In the present invention, it is preferable that the curved forming portion is formed to have a radius larger than a bending radius allowed for the first transmission wire member.

  In the present invention, the first transmission wire member passing through the support portion has a structure in which an inner wire advances and retreats in an outer wire, and the outer wire of the first transmission wire member is connected to a lower side of the support portion. It is preferred to fix to.

According to the movable table of the present invention, a plurality of first transmission wire members for transmitting the operation of the operation lever to the plurality of caster brake mechanisms, and at least one of the plurality of first transmission wire members, A second transmission wire member that branches off at a lower portion of a support portion or a leg portion and transmits the divided transmission wires to the friction brake mechanism. The plurality of first transmission wire members are slackened into a space below the table plate. And a guide structure for guiding the first transmission wire member when the support portion expands and contracts is provided and guided inside the support portion, so that a smooth transmission wire member can be provided. Since it is possible to enter and exit and not to be entangled, the brake operation by the transmission wire member can be reliably transmitted, and smooth extension and contraction of the support portion can be secured. At the same time, a second transmission wire member is provided, which branches at least one of the plurality of first transmission wire members at the lower portion of the support column or at the leg portion and transmits the branched to the friction brake mechanism. Since the wire member does not move up and down in the column, it does not hinder expansion and contraction of the column.
Even if the transmission wire is broken, the wire needs to be replaced only with the broken wire (if it is a branch wire, only the broken wire is sufficient), so replacement is easy and maintenance is high.

  Note that a portion of the guide structure facing the space of the container is formed in a curved shape, and the bending of the first transmission wire member guided from the space to the guide structure is adjusted by the curved formed portion. With the guideable structure, the transmission wire member is not excessively bent at the curved portion, so that the transmission member can be smoothly moved in and out, and the durability of the transmission wire member is also improved. Therefore, the frequency of maintenance is reduced and the maintainability is further improved.

  In this case, if the curved portion is formed to have a radius larger than the bend radius allowed for the first transmission wire member, the bend of the transmission wire member can be larger than the bend allowed for the transmission wire member. The durability is further improved and the maintainability is improved.

  Further, the first transmission wire member passing through the support portion has a structure in which an inner wire advances and retreats in an outer wire, and at least one of the transmission wire members is fixed to a lower side of the support portion. By doing so, the expansion and contraction of the support portion prevents the transmission wire member from freely entering and leaving the leg portion, preventing the transmission wire member from getting entangled, smooth operation of the transmission wire member, smooth expansion and contraction of the support portion, In addition, the durability of the transmission wire member can be improved.

FIG. 1 is an explanatory perspective view illustrating an entire configuration of a movable table according to an embodiment of the present invention. It is explanatory drawing by the front view which shows the whole structure of the said movable table. FIGS. 3A and 3B are explanatory views of a side view showing an entire configuration of the movable table, in which FIG. 3A shows a state in which a support is contracted, and FIG. 3B shows a state in which a support is extended. It is explanatory drawing which shows the vicinity of the operation lever of the brake mechanism of the said movable table. It is explanatory drawing which shows the wiring structure of the operation wire in the table part in the said movable table. 4A and 4B schematically show the arrangement of operation wires in the brake mechanism, wherein FIG. 4A is an explanatory view of a movable table according to an embodiment, FIG. 4B is an explanatory diagram of a first modification, and FIG. . It is explanatory drawing of the said operation wire wiring state, Comprising: It is the enlarged explanatory drawing which looked at the part which passes an operation wire from a storage part to a support | pillar part from the upper side. It is explanatory drawing of the wiring state of the said operation wire, Comprising: It is a partially expanded explanatory view which shows each support part upper part and lower part of the said movable table by notching partially. 8A and 8B are explanatory views of the arrangement state of the operation wires, wherein FIG. 8A is a cross-sectional view taken along the line CC of FIG. 7, and FIG. 8B is a cross-sectional view taken along the line EE of FIG. 8. It is explanatory drawing which looked at the said leg part from below. 10A and 10B are cross-sectional views of the periphery of the brake mechanism along the line DD in FIG. 10, wherein FIG. 11A is an explanatory diagram illustrating a released state of a brake of the brake mechanism, and FIG. 10A and 10B are explanatory views of a wiring state of the operation wires, wherein FIG. 10A is an explanatory view in which a part around a leg below a support is partially cut away, and FIG. 10B is an enlarged view of a part B in FIG. It is explanatory drawing seen from the lower part which shows wiring of the operation wire around a caster.

Hereinafter, embodiments of a movable table according to the present invention will be described in detail with reference to the drawings.
1 to 3 are explanatory views showing the entire configuration of a movable table according to an embodiment of the present invention, FIG. 4 is an explanatory view of a brake operation section of the movable table, and FIG. 5 is an operation wire arrangement of the movable table. It is explanatory drawing of a cable | wire state.

  As shown in FIG. 1 and FIG. 2, the movable table 1 according to the present embodiment includes a table plate 10, an extendable column portion 20 that supports the table plate 10 from one end in the length direction, and a table. It has a structure extending in a direction parallel to the length direction of the plate 10 and includes a leg 30 for supporting the column 20 from a lower base. The leg 30 includes a caster 41 with a lock mechanism and a brake mechanism (friction brake). This is a movable table having a mechanism (corresponding to a mechanism) 42 and casters 43 for movement.

  The movable table 1 includes a caster 41 with a lock mechanism and a brake release mechanism 50 that releases a brake by a brake mechanism 42 by wire operation.

  In other words, the movable table 1 includes, as a brake mechanism of the present invention, a plurality of caster brake mechanisms that lock each of a plurality of casters 41 with a lock mechanism to restrict the movement, A friction brake mechanism (brake mechanism 42) for generating a frictional force therebetween to regulate the movement, and a brake operation mechanism 50 for the user to release the brakes of these brake mechanisms. is there.

  The brake operation mechanism is a brake release mechanism 50, an operation lever 53 for performing a brake release operation of the brake mechanism, an operation wire 511 for transmitting the operation of the operation lever 53 to each of a plurality of caster brake mechanisms, 512 (corresponding to a plurality of first transmission wire members) and the operation wire 512 of the plurality of operation wires 511 and 512 are branched at the lower portion of the support 20 or the leg 30 to form a brake mechanism 42 (corresponding to a friction brake mechanism). ), And a table base 11 (container) for accommodating the operation wires 511 and 512 in the space below the table plate 10 under the table plate 10. The operation wires 511, 512, and 52 are provided in the support portion 20 when the support portion 20 expands and contracts. A plurality of guide structure 21 (21A, 21B) for guiding each in which the provided.

  First, the configuration of the mobile table 1 of the present embodiment will be described with reference to the drawings. The movable table 1 is configured such that the table board 10 faces the upper side of the bed device by inserting the legs 30 into the foot space from the front side of the bed device (not shown), so that the user of the bed device can enjoy meals or the like. This is called a bedside table, which allows a product to be put on the table board 10 and used.

  As shown in FIGS. 1 and 2, the table plate 10 is formed in an elongated rectangular shape so that the table plate 10 can be disposed above the bed device over the width direction of the bed device (not shown). The table plate 10 is a flat plate material and has a substantially rectangular shape or a rectangular shape in plan view, and both ends in the length direction are rounded so as to draw a slightly arc.

  As shown in FIG. 2, a table base 11 that supports the table plate 10 from a lower surface side is substantially below the table plate 10 from one end in the longitudinal direction of the table plate 10 (the end on the support 20 side). It is formed over the central part.

  A column 20 is arranged at one longitudinal end of the table base 11, and the column 20 supports the table base 11 and the table plate 10 on only one side. The table plate 10 is provided above the column 20, and the legs 30 are provided below the base near the floor.

The table base 11 has a box shape with an open inner space on the upper side, and is made of, for example, metal or resin having rigidity and having a flange portion developed in the width direction of the table plate 10 at an upper edge thereof. The table base 11 has its flange portion fixed to the lower surface of the table plate 10 by screws.
The table board 10 is fixed to the upper side of the table base 11 and the upper side of the internal space is closed, so that a space is formed between the table board 10 and the table base 11.

  A brake release mechanism 50 is provided at an end of the table base 11 on the side of the column 20. In the space of the table base 11, bendable and extendable operation wires 511 and 512 constituting a part of the brake release mechanism 50 are laid. The operation wire 52 for the brake mechanism is branched from one of the operation wires 512 and 512 among the operation wires 512. In this branch portion, even if the operation wire 52 is branched using a branch board as a connection member, Further, a forked wire obtained by branching the inner wire may be used.

  The operation wires 511 and 512 are connected to each lock mechanism of the caster 41 with a lock mechanism. The operation wire 52 is connected to the brake mechanism 42. Each of the operation wires 511, 512, and 52 is such that an inner wire is disposed in an outer wire (outer) fixed at the time of wiring so as to be able to move forward and backward.

As shown in FIG. 3, the support portion 20 is configured to be entirely expandable and contractible.
The support portion 20 includes a first support member 201 and a second support member 202, each of which is a cylindrical pillar, and the lower first support member 201 is covered by the upper second support portion 202. The second support member 202 is configured to expand and contract by moving in the vertical direction in the figure together with the table plate 10 along the first support member 201. 3A illustrates a state in which the support 20 is contracted, and FIG. 3B illustrates a state in which the support 20 is extended.

  The first support member 201 is provided on the leg portion 301 side, and the second support member 202 is provided on the table base portion 11 side. The user pushes up or down the table board 10 by a driving mechanism such as a gas spring (not shown). The height of the table plate 10 can be adjusted by the user's operation. The table base 11 is provided with an operation lever 60 for vertically operating the drive mechanism.

  Two telescopic guide structures 21 (21A, 21B) for guiding the operation wires 511, 512 disposed inside the column 20 in accordance with the operation of the column 20 to expand and contract are provided inside the column 20. ing. An operation wire 511 is guided by one telescopic guide structure 21A, and an operation wire 512 is guided by another telescopic guide structure 21B.

Each telescopic guide structure 21 (21A, 21B) includes a first guide member 211 and a second guide member 212, respectively.
The second guide member 212 is configured to expand and contract by moving in the vertical direction in the drawing along the first guide member 211 within a range where the support portion 20 expands and contracts.

  The first guide member 211 is provided on the lower side (table base 11 side) of the first support member 201 side. The second guide member 212 is provided on the upper side (the leg 30 side) of the second support member 202. The first guide member 211 and the second guide member 212 do not bend even if the lengths of the operation wires 511 and 512 disposed inside the support portion 20 change due to the expansion and contraction of the support portion 20. It is configured to guide.

FIG. 4 shows the table base 11 viewed from its end.
As shown in FIG. 4, the table base 11 is provided with an operation lever 60 for raising and lowering the same, and together with the operation lever 53 for operating the operation wires 511, 512 and 52 of the brake release mechanism 50, A lock lever 56 for bringing the lever 53 into the brake release state is provided. The operation lever 53 is provided in a pair in the width direction of the table 10, and an end extending rearward is an operation portion 53a, and a portion near the operation shaft 54 is a lock portion 53b. Details of the entire brake release mechanism 50 will be described later.

  FIG. 5 shows the internal structure of the table base 11, and shows a schematic situation in which the operation wires 511 and 512 are bent in the internal space. FIGS. 6A and 6B are schematic explanatory diagrams of the arrangement of the operation wires. FIG. 6A illustrates the embodiment, FIG. 6B illustrates the first modification, and FIG. 6C illustrates the second modification. FIG. 7 is a detailed view of the vicinity of the upper side of the telescopic guide structure of the base 11. FIG. 8 and FIG. 9 are explanatory views of the internal state of the upper and lower portions of the support portion 20.

  In the table base 11, as shown in FIG. 5, FIG. 7, and FIG. 9A, the introduction ports of the second guide members 212 of the telescopic guide structure 21 (21A, 21B) are in the space in the table base 11. Is facing. Also, as shown in FIG. 9B, which is a cross-sectional view taken along the line EE in FIG. 8, the first guide members in the telescopic guide structures 21 (21A, 21B) are provided in the column 20 near the leg 30. The outlet 211 is facing.

  As schematically shown in FIG. 6A, an operation wire 511 is connected to the lock mechanism of the caster 41 with a lock mechanism at one end (specifically shown in FIGS. 10 and 12B), The operation wire 512 is connected to the lock mechanism of the caster 41 with a lock mechanism. The operation wires 511 and 512 are connected to the operation unit 53 side. An operation wire 52 branched from one of the operation wires 512 in the lower portion of the support 20 or in the leg 30 is connected to the brake mechanism 42.

FIG. 10 is a view of the leg 30 as viewed from below.
As shown in FIGS. 1 and 10, the leg 30 includes a first leg frame 301 provided with a caster 41 with a lock mechanism on the column 20 side, and a brake mechanism 42 and a caster 43 for movement on the side opposite the column 20. And a connecting frame 303 for connecting the first leg frame 301 and the second leg frame 302 to each other, and is formed in an H-shape.

  As shown in FIG. 1, the first leg frame 301 is formed to be long along the width direction of the table plate 10, and casters 41 with a lock mechanism are attached to both ends thereof.

  FIG. 11 is a view for explaining the brake mechanism 42 inside the casters 43. FIG. 12B is an enlarged view of a portion B in FIG. 10 and shows a wire routing situation around the casters 41 with the lock mechanism.

  The lock mechanism of the caster 41 with a lock mechanism is normally configured to be in a locked state so that the caster does not rotate.

  As shown in FIGS. 1 and 10, the second leg frame 302 is formed to be long along the width direction of the table plate 10, and the casters 43 for movement are attached to both ends thereof via attachment brackets 431. I have.

  As shown in FIG. 10, two brake mechanisms 42 are provided adjacent to each caster 43. The brake mechanism 42 is arranged on the second leg frame 302 inside the casters 43.

  As shown in FIGS. 6A and 10, the brake mechanism operation wires 521 and 522 are connected to the brake mechanism 42 of the embodiment, respectively. The brake mechanism operation wires 521 and 522 are connected to the operation wire 52 via a connection portion 523. When the inner wire of the operation wire 52 is pulled, the brake operation wires 521 and 522 are pulled, and each brake mechanism 42 operates.

The brake mechanism 42 can be variously modified.
For example, as shown in Modification Example 1 of FIG. 6B, when the brake mechanisms 42, 42 are a pair, the connecting portions 523 and the brake mechanism operation wires 521, 522 are eliminated, and the respective brake mechanisms 42, 42 are removed. And two (plural) operation wires 52, 52 may be connected to the operation wires 511, 512 for the lock mechanism, respectively. This configuration has a merit that, although the number of branch portions is plural, the connecting portion 523 and the operation wires 521 and 522 are omitted, and only the two operation wires 52 and 52 branched from the operation wires 511 and 512 are required.
Further, as shown in a modified example 2 of FIG. 6C, in the brake mechanism 42, a single operation wire 52 is connected to the single brake mechanism 42 as a structure for driving a single stopper member (brake shoe). Therefore, there is an advantage that the configuration can be further simplified as compared with the first modification.

  As shown in FIG. 11, the brake mechanism 42 includes a stopper 421 and a holder 422 for holding the stopper 421, and is mounted to be rotatable about a mounting shaft 423 as a fulcrum.

  In a normal state, as shown in FIG. 11B, the brake mechanism 42 is urged by a spring member (not shown) so that the stopper 421 protrudes toward the floor, and the stopper 421 is moved relative to the floor. It is configured to exert a frictional force to be in a braking state. Then, at the time of the brake release operation, as shown in FIG. 11A, the stopper 421 is configured to be pulled into the second leg frame 302 by operating the operation wire 52.

  Next, the characteristic configuration of the brake release mechanism 50 of the present embodiment will be described in more detail.

  As shown in FIGS. 1, 2, and 5, the brake release mechanism 50 includes operation wires 511 and 512, an operation wire 52 connected to the operation wire 512, an operation lever 53, and a lock lever 56. .

  The operation wires 511, 512, and 52 are provided with an outer wire and an inner wire that operates, and are connected to the operation lever 53 on the table base 11 side and the lock mechanism and the brake mechanism 42 of the caster 41 with a lock mechanism on the leg 30 side to brake. Perform the release operation.

  As shown in FIG. 1, the operation wires 511 and 512 have one end attached to the operation lever 53, are laid from the table base 11 side to the leg 30 side through the inside of the column 20, and are shown in FIG. 2. As described above, the other end is attached to the lock mechanism of the caster 41 with the lock mechanism of the first leg frame 301 of the leg 30 and the brake mechanism 42 of the second leg frame 302.

  Then, the operation wires 511 and 512 are moved so that the lock release operation of the lock mechanism of the caster 41 with the lock mechanism and the brake release operation of the brake mechanism 42 (friction brake mechanism) can be performed within the range in which the column 20 extends and contracts. As shown in the figure, the table is bent and laid between the table plate 10 and the table base 11 so as to have a margin.

  Specifically, as shown in FIGS. 5 and 7, one end of the inner wire is attached to the operation lever 53, and one end of the outer wire is attached to the operation wire attachment portion provided on the table base 11, as shown in FIGS. 111.

  The operation wires 511 and 512 extend from the operation wire attachment portion 111 to the other end of the table base 11, and are bent in an arc shape toward the one end near the center to be folded back so as to have a margin. Extends to one end.

  The operation wires 511 and 512 enter the upper end side guide portion (second guide member 212) of the telescopic guide structure 21 (21A, 21B) on one end side of the table base 11, as shown in FIG. Then, it is routed to the leg 30 through the inside of the column 20 through the telescopic guide structure 21 (21A, 21B). One end of the operation wire 52 of the brake mechanism 42 is branched or connected to the operation wire 512 of the caster 41 with a lock mechanism in the lower part of the support 20 or in the leg 30.

  The other ends of the operation wires 511 and 512 are attached to the lock mechanism of the caster 41 with a lock mechanism. The other end of the operation wire 52 is attached to the brake mechanism 42.

  In the present invention, a portion of the guide structure facing the space of the housing is formed in a curved shape, and the first transmission wire members (the operation wires 511 and 512 correspond to the first transmission wire member guided from the space to the guide structure). ) Can be guided by adjusting the bend by the curved forming portion.

  Specifically, as shown in FIGS. 7 and 8, each upper end side guide portion (upper end of the second guide member 212) of the telescopic guide structure 21 (21A, 21B) is a curved cylindrical body made of a corrugated pipe or the like. When the operation wires 511 and 512 are displaced by the expansion and contraction of the column 20, the guides are guided while sliding so that the bending R does not become extremely small. Each upper end side guide portion (upper end of the second guide member 212) is fixed to the table base 11 with a resin binding band 11a or the like.

Each upper end side guide portion (upper end of the second guide member 212) of the telescopic guide structure 21 (21A, 21B) has a curved portion facing the space portion of the table base 11 (container) in the guide structure 21 (21A, 21B). Since the bending of the operation wires 511 and 512 (first transmission wire members) guided from the inside of the space to the guide structure is adjusted by the curved forming portion, the structure can be guided. Since the operation wires 511 and 512 are not excessively bent at the curved portions, the operation wires 511 and 512 can smoothly enter and exit, and the durability of the operation wires can be improved. Eventually, the frequency of maintenance is reduced, and the maintainability is further improved.
Further, the curved portion is formed to have a radius larger than a bending radius allowed for the operation wires 511 and 512, thereby reliably preventing the operation wires 511 and 512 from being excessively bent and damaged. .

The operation wires 511 and 512 passing through the support portion 20 have a structure in which the inner wire advances and retreats in the outer wire. As shown in FIGS. 8 and 12, the outer wires of the operation wires 511 and 512 are used. Is fixed to the leg 30 at the lower side of the column 20. The fixing structure 71 of the outer wires of the operation wires 511 and 512 is to fix the leg 30 from above and below. The fixing structure 71 can be of various types such as caulking a tubular body with an outer wire or tying a binding band to the operation wires 511 and 512. In addition, the washer 73 is interposed between the fixing structure 71 and the leg portion 30 so that the operation wire is prevented from being damaged even if vibration occurs due to a certain amount of play.
Also, the branch of the operation wire 512 to the operation wire 52 is branched in the pipe 74 installed in the leg 30 as shown in FIGS. May be installed.

  Further, as shown in FIG. 8, each lower end side guide portion (the lower end of the first guide member 211) of the telescopic guide structure 21 (21 A, 21 B) is fixed to the leg 30 side. Specifically, the lower end of the first guide member 211 is fixed to the leg 30 by a fixing structure 72 such as a resin binding band. The lower part of the wire fixing structure 71 is prevented by a fixing structure 71a such as a binding band.

  As shown in FIGS. 5 and 7, the operation lever 53 is provided integrally with the operation shaft 54 and the wire lever 55, and is disposed below the table plate 10 near the end of the table base 10 of the table base 11. ing.

  The operation shaft 54 is provided across the width of the table base 11 and is rotatably attached to the table base 11. At both ends of the operation shaft 54, projections are provided from side portions of the table base 11, and flat operation levers 53 are integrally provided at the protruding ends so as to extend rearward.

  A wire lever 55 is provided integrally near the central portion of the operation shaft 54 in the longitudinal direction, so that the wire lever 55 rotates integrally with the rotation of the operation shaft 54.

  The wire lever 55 has one ends of the operation wires 511 and 512 connected thereto, and the operation wire 512 is branched and the operation wire 52 is connected thereto. The lock mechanism of the caster 41 with a lock mechanism provided on the first leg frame 301 of the leg 30 to which the other end of the 52 is connected, and the brake mechanism 42 provided on the second leg frame 302 are simultaneously operated.

  As shown in FIG. 5, the operation lever 53 is formed in an approximately L-shape having one end portion as an operation portion 53a and projecting outward while widening in the width direction, and the other end portion is integrally formed with the operation shaft 54. Provided to rotate the operation shaft 54. In the present embodiment, the operation levers 53 are provided symmetrically at both ends of the operation shaft 54.

  When the operation lever 53 is in a normal non-operation state, as shown in FIG. 4, the operation portion 53a is positioned below by the weight of the operation lever 53 itself.

  As shown in FIG. 5, a lock lever 56 for holding the operation lever in the released state is provided at one end of the table base 11 adjacent to the operation lever 53. The lock lever 56 functions as a brake release holding member that holds the lock release state of the lock mechanism of the caster 41 with the lock mechanism by the brake release mechanism 50 and the brake release state of the brake mechanism 42.

  As shown in FIG. 5, the lock lever 56 has one end protruding outside the table base 11 as an operation part 56a, and the other end is disposed close to the operation lever 53 as a lock part 56b. It is provided so as to be rotatable around 57 as a fulcrum.

  When the lock lever 56b is operated so as to hold the brake release state in which the operation lever 53 has been operated upward, the lock portion 56b goes under the operation lever 53 and partially overlaps. Is configured such that the lock portion 56b of the lock lever 56 overlaps the lock portion 53b of the operation lever 53, that is, is positioned on the return direction side.

  The lock lever 56 is normally urged by a coil spring (spring member) 58 so that the lock portion 56b and the operation lever 53 do not interfere with each other as shown in FIG.

  Next, when the movable table 1 is moved, the brake release mechanism 50 releases the lock mechanism of the caster 41 with the lock mechanism and the brake mechanism 42 to release the brake, and the operation for making the movable table 1 movable is described with reference to the drawings. I will explain.

  When the movable table 1 is moved, first, the operation lever 53 of the brake release mechanism 50 is gripped (positioned downward as shown in FIG. 4 or the like at the time of braking) and is rotated upward by a predetermined amount. .

  The inner wire of the operation wires 511, 512, and 52 is pulled by a predetermined amount by rotating the wire lever 55 forward in conjunction with the operation of the operation lever 53.

  In the first leg frame 301 of the leg 30, as shown in FIG. 10, when the operation wires 511 and 512 are pulled, the lock mechanism operation wires 511 and 512 connected to the lock mechanism of the caster 41 with the lock mechanism are pulled. The lock mechanism is released by being pulled in the direction of arrow A1.

  In the second leg frame 302 of the leg 30, when the operation wire 52 is pulled, the brake mechanism operation wires 521 and 522 connected to the brake mechanism 42 are pulled in the direction of arrow B1 shown in FIG. As shown in (a), the stopper 421 of the brake mechanism 42 is separated from the floor surface, and the brake is released.

  At this time, with the operation lever 53 being operated, the lock lever 56 is rotated in the direction for locking the operation lever 53 as shown in FIG. When the gripped operating lever 53 is released at a position where a part of the operating lever 53 contacts (a position where the locking portion 56b of the locking lever 56 overlaps the locking portion 53b of the operating lever 53), a part of the operating lever 53 is locked. And the operating state is maintained.

  In this manner, the locked state of the lock mechanism of the caster 41 with the lock mechanism and the released state of the brake state of the brake mechanism 42 are maintained, so that the user can move the table without holding the operation lever 53. Can be performed continuously. Thus, the burden of operating the operation lever 53 when moving the movable table 1 can be reduced.

  Next, an operation of terminating the movement of the movable table 1 and bringing the lock mechanism of the caster 41 with a lock mechanism and the brake mechanism 42 into a locked state (brake state) will be described with reference to the drawings.

  When the movement of the movable table 1 is completed and the lock mechanism of the caster 41 with the lock mechanism and the brake mechanism 42 are returned to the locked state (brake state), the operating lever 53 held at a predetermined position is further squeezed.

  When the operation lever 53 is further squeezed, the operation lever 53 and the lock portion 56b of the lock lever 56 are separated from each other, so that the locked state between the operation lever 53 and the lock lever 56 is released, and the lock lever 56 is It returns to the normal position shown in FIG. 4 by the spring force (not shown).

Then, when the gripping state of the operation lever 53 is released and returned to the original state, as shown in FIG. 10, the lock mechanism of the caster 41 with the lock mechanism causes the lock mechanism operation wires 511 and 512 to return in the direction of arrow A2. Is locked.
Also, the brake mechanism 42 exerts a frictional force when the brake mechanism operation wires 521 and 522 return in the direction of the arrow B2, and as shown in FIG. 11B, the stopper portion 421 projects from the floor surface. Then, the vehicle enters the braking state.

  In this manner, the user releases the holding state of the operation lever 53 by the lock lever 56 simply by further squeezing the operation lever 53 from the brake release state, and easily locks the lock mechanism of the caster 41 with the lock mechanism in the lock state. And the brake mechanism 42 can be returned to the brake state.

  With the above-described configuration, according to the movable table of the present embodiment, the plurality of operation wires 511 and 512 for transmitting the operation of the operation lever to the lock mechanisms of the plurality of casters 41 with lock mechanisms, respectively, An operation wire 52 for transmitting the operation of the lever 53 to the brake mechanism 42 of the friction brake mechanism. An accommodation body for accommodating the operation wires 511 and 512 in the space is provided in the lower part of the table plate 10 in the table base 11, and is provided in the support 20 when the support 20 is expanded and contracted. Are provided with a plurality of guide structures 21 (21A, 21B) for guiding the operation wires 511 and 512, so that the operation wires can smoothly enter and exit, and there is no entanglement, so the brakes by the operation wires 511 and 512 are provided. Operation can be transmitted reliably.

  In addition, at least one of the plurality of operation wires 511 and 512 is provided with an operation wire (second transmission wire member) that branches off at the lower portion of the support 20 or the leg 30 and transmits to the friction brake mechanism. In addition, the operation wire does not move up and down in the support portion 20 and does not hinder expansion and contraction of the support portion 20. Even if the operation wire is broken, the wire may be replaced by a broken wire (if it is a branch wire, only the broken wire), and replacement is easy and maintenance is high.

  The guide wire 21 (21A, 21B) has a curved portion that faces the space of the table base 11 (container), and the operation wire 511 guided from the space to the guide structure 21 (21A, 21B). , 512 can be adjusted and guided by the curved forming portion, so that the bending of the transmission wire member does not become too tight at the curved forming portion. Therefore, the operation wires 511 and 512 can smoothly enter and exit, and the durability of the operation wires 511 and 512 also improves. Eventually, the frequency of maintenance is reduced, and the maintainability is further improved.

  In this case, if the curved portion is formed to have a radius larger than the bending radius allowed for the operation wires 511 and 512, the bending of the operation wires 511 and 512 can be made larger than the allowable bending. The durability is further improved, and the maintainability is improved.

  The operation wires 511 and 512 passing through the support portion 20 have a structure in which an inner wire moves forward and backward in the outer wire, and the outer wires of the operation wires 511 and 512 are fixed to the lower side of the support portion. As a result, the operation wires 511 and 512 cannot freely enter and exit the leg 30 due to the expansion and contraction of the support 20, and the operation wire is prevented from becoming entangled in the leg 30. Operation, smooth expansion and contraction of the support portion 20, and improvement in durability of the operation wires 511 and 512 can be achieved.

  In addition, as a configuration of the operation lever 53, the operation lever 53 is provided below the table plate 10, and the operation portion 53a is provided so as to be vertically swingable with the operation shaft 54 as a fulcrum. In addition, the lock lever 56 has a configuration in which a lock mechanism is provided in a normal state by providing the lock portion 56b so as to be able to protrude and retract within an operation range of the operation lever 53, with one end side being an operation portion 56a and the other end being a lock portion 56b. The lock mechanism of the caster 41 and the brake mechanism 42 are always in a braked state, so that the movable table 1 in use can be prevented from moving. Therefore, the safety of the movable table 1 can be improved, and when releasing the brake, the brake release state can be easily maintained by a simple operation of operating the operation lever 53 and the lock lever 56 at two places. Can be. Therefore, the brake release operation and the brake release holding operation can be performed easily and reliably, and the movable table 1 with improved operability of the brake release operation can be realized.

  In the present embodiment, the operation state of the operation wires 511, 512, and 52 is maintained by holding the operation lever 53 by the lock lever 56. However, the present invention provides an operation wire for operating the brake mechanism. The present invention is not limited to this as long as it holds the operation state. For example, a stopper pin that holds the operation state of the operation lever may be provided so as to protrude, or a rotation restriction that restricts the rotation operation of the operation shaft 54. It may be provided with a member or the like.

Further, the present invention is not limited to the above-described embodiments and examples, and various modifications can be made within the scope of the claims. That is, embodiments obtained by combining technical means appropriately changed without departing from the spirit of the present invention are also included in the technical scope of the present invention.
That is, in the above embodiment, as the brake mechanism for restricting the movement of the movable table, a plurality of caster brake mechanisms for locking each of the plurality of casters and restricting the movement, and between the legs and the floor surface. Although two types of the brake mechanism are described, namely, a friction brake mechanism that generates the frictional force to restrict the movement, it is within the scope of the present invention to use the same type of brake mechanism. It is also within the scope of the present invention to use one or more types of brake mechanisms other than the caster brake mechanism and the friction brake mechanism.
The brake shoe of the brake mechanism 42 (friction brake mechanism) shown in the embodiment may be a pair or a plurality as shown in FIGS. 6B and 10 or a single brake shoe as shown in FIG. 6C. The selection of the friction brake mechanism in the present invention can be variously selected according to the required frictional force.
Further, in the above-described embodiment, the telescopic guide structure 21 is configured such that the operation wires 511 and 512 (transmission wire members) are inserted into and guided by the two (21A and 21B), respectively. It is also possible to insert and guide a plurality of operating wires in the structure.

  The transfer table of the present invention can be used for medical and nursing beds.

Reference Signs List 1 movable table 10 table plate 11 table base 20 support 21 (21A, 21B) guide structure 30 leg 41 caster with lock mechanism 42 brake mechanism 43 caster 50 brake release mechanism 53 operation lever 56 lock lever 511, 512 for lock mechanism Operation wire 52 for the brake mechanism

Claims (4)

A table plate, a support portion that supports the table plate on the upper side and expands and contracts as required to adjust the position of the table plate with respect to the leg portion, a leg portion that supports a lower side of the support portion, and the leg portion. In a movable table provided with a caster for moving to be in contact with the floor and a brake mechanism for restricting the movement,
The brake mechanism has a plurality of members that regulate the movement by a plurality of casters,
A brake operating mechanism for a user to release the brake of the brake mechanism,
The brake operation mechanism includes:
An operation lever for performing a brake release operation of the brake mechanism;
A plurality of first transmission wire members for transmitting the operation of the operation lever to a plurality of brake mechanisms, respectively;
A second transmission wire member that branches at least one of the plurality of first transmission wire members at a lower portion of the support column and transmits the branched transmission wire member to the brake mechanism;
A plurality of third transmission wire members for branching the second transmission wire member at the leg portion and transmitting the branched to the brake mechanism;
With
At the lower portion of the table plate, provided is a housing body for accommodating the plurality of first transmission wire members in a space portion by being slackened,
A guide structure for guiding the plurality of first transmission wire members at the time of expansion and contraction of the support portion is provided in the support portion ,
The brake mechanism includes a plurality of caster brake mechanisms that lock each of a plurality of casters and regulates the movement, and a friction brake mechanism that regulates the movement by generating a frictional force between the legs and the floor. And has
Providing a plurality of guides in one support section
Mobile table according to claim. The portion of the guide structure facing the space of the container is formed in a curved shape, and the bending of the first transmission wire member guided from the space to the guide structure is adjusted by the curved formed portion. The movable table according to claim 1 , wherein the movable table is configured to be able to be guided. The movable table according to claim 2 , wherein the curved forming portion is formed to have a radius larger than a bending radius allowed for the first transmission wire member. The first transmission wire member passing through the support portion has a structure in which an inner wire advances and retreats in an outer wire, and the outer wire of the first transmission wire member is fixed to a lower side of the support portion. The mobile table according to any one of claims 1 to 3 , characterized in that:

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