JP7014404B2 - Overbed table - Google Patents

Description

The present invention relates to an overbed table used by disposing a table plate on a bed.

Conventionally, an overbed table used by arranging a table plate on a bed is widely known, and for example, Patent Document 1 discloses an example thereof. The overbed table (hereinafter, abbreviated as a table) disclosed in Patent Document 1 includes a table main body provided with a table plate, legs provided at both ends of the table main body in the longitudinal direction, and legs. It includes a caster device provided at the lower end portion of the portion, and an operation unit disposed at the central portion in the longitudinal direction of the table plate to operate the caster device. Further, the caster device switches between the wheel, the holder member that rotatably supports the wheel and is rotatably supported around the axis perpendicular to the leg, and the lock / unlock of the wheel. It has a mechanism. By operating the operation unit, the table can be moved in all directions along the floor surface by putting it in the unlocked state, and the table can be prevented from moving by putting it in the locked state, making it convenient to use.

Utility Model Registration No. 3187234 Gazette

However, in Patent Document 1, for example, when a patient gets off the bed, the table can be moved in all directions even if the table is unlocked and the table is moved along the bed (longitudinal direction). Therefore, depending on the direction of the wheels and how to apply force, the table may move in an unintended direction and the legs may hit the bed, which may be a little troublesome.

Further, since the operation unit is arranged in the central portion in the longitudinal direction of the table plate, it may be difficult to access when, for example, a nurse or a caregiver operates from the outside of the bed.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an overbed table that is easier to handle and has better operability.

In order to solve the above problems, the present invention is provided at a table main body provided with an elongated table plate, legs provided at both ends of the table main body in the longitudinal direction, and lower ends of each leg. An overbed table including a caster device and an operation unit for operating the caster device, wherein the caster device rotatably supports a wheel and the wheel and rotates around a vertical axis with respect to a leg portion. A holder member that is swivelably supported, a free state that allows omnidirectional table movement along the floor surface, a course lock state that allows unidirectional table movement along the floor surface, and a lock that prevents table movement. A switching mechanism for switching the caster device between states is provided, and the operating unit operates the switching mechanism, and is located on both outer sides of the table body portion of the table main body portion with respect to the central portion in the longitudinal direction. Each of the positions is provided, and the switching mechanism is characterized in that, in the course locked state, only table movement in a direction orthogonal to the longitudinal direction is allowed as the one direction.

According to this configuration, the switching mechanism can switch to a course lock state that allows only the table movement in the direction orthogonal to the longitudinal direction of the table plate, so that the table can be smoothly and stably along the longitudinal direction of the bed. It can be moved, and there is no need to bother with the legs hitting the bed. Therefore, it is easy to handle.

In addition, since the operation units are provided on both outer sides of the table body from the central portion in the longitudinal direction, it can be easily accessed by nurses and caregivers, for example, when operating from the outside of the bed. , It will be easy to operate.

In the overbed table, the operation unit includes a first operation unit arranged on one side in the width direction orthogonal to the longitudinal direction and a second operation unit arranged on the other side in the width direction. The first operation unit and the second operation unit may be arranged at positions symmetrical with respect to the center of the table plate.

According to this, even if the direction of the overbed table is reversed, the position of the operation unit itself can be kept constant only by exchanging the positions of the first operation unit and the second operation unit. Therefore, the degree of freedom in the installation direction of the overbed table can be increased, and the convenience is improved.

Further, in the overbed table, the first link connected to the caster device, the second link arranged in parallel with the first link, and the first link and the second link are one end thereof. A third link rotatably connected with the third link and a fourth link rotatably connected to the first link and the second link at the other end thereof and arranged in parallel with the third link. Further, the third link and the fourth link are rotatably held by the table main body portion, and the first operation unit has the third link at the end of the third link. The second operation unit may be rotatably connected, and the fourth link may be rotatably connected to the end of the fourth link.

If the operation unit is connected to the caster device via a single rod (link), the rod body may be deformed due to the operation of the operation unit, making it difficult to smoothly switch the caster device. Can occur. However, as described above, according to the configuration in which the parallel motion mechanism is configured by the first link to the fourth link and the operation unit is arranged at the end of the third link and the end of the fourth link, respectively, the operation is performed. The parallel motion mechanism is activated by the operation of the portion, and the caster device can be appropriately switched between the free state, the course lock state, and the locked state at the time of the operation. Therefore, the caster device can be switched more smoothly and surely.

The overbed table further includes a connecting member that connects the first operation unit, the second operation unit , and the switching mechanism, and the switching mechanism is movably arranged with respect to the wheel. A switching operation member for switching the wheel to the free state, the course lock state, and the locked state is provided, the switching operation member includes a rack, and the connecting member has a rotatable pinion that meshes with the rack. The caster device may be configured to include a rack escape restricting member that restricts the rack from escaping to the pinion in the out-of-diameter direction of the pinion when the rack moves with the rotation of the pinion. ..

According to this configuration, the rack escape restricting member can regulate the rack from escaping to the pinion in the out-of-diameter direction when the rack moves due to the rotation of the pinion, and the distance between the rotation center of the pinion and the rack can be controlled. It can always be maintained at the set distance. Therefore, the rack can be reliably moved in a desired direction while the pinion and the rack are properly engaged with each other.

In the overbed table, the pinion has a substantially fan shape having an arcuate outer circumference, and the arcuate outer circumference may be provided with a gear that meshes with the rack.

According to this configuration, the pitch circle of the pinion gear can be increased to increase the meshing ratio between the pinion and the rack in a small space, and the rack can be moved and operated with a large rotational torque.

According to the present invention, it is possible to provide an overbed table that is easier to handle and has better operability.

It is a perspective view seen from the diagonally upper side of the overbed table which concerns on embodiment of this invention. It is a perspective view seen from the diagonally lower side of an overbed table. It is a front view of an overbed table. It is a perspective view of the overbed table with the table plate removed. It is a perspective view of the internal mechanism of an overbed table. FIG. 5 is a plan view of FIG. It is an enlarged view of the 1st leg side of FIG. It is an enlarged view of the 2nd leg side of FIG. It is a side view of the main part of the caster device used for an overbed table. 9 is an exploded perspective view of a main part of the caster device of FIG. 9. It is sectional drawing of the main part of the locked state of a caster device. It is sectional drawing of the main part of the course locked state of a caster device. It is sectional drawing of the main part of the caster device in a free state. It is a perspective view of a stopper member and a turning braking body used for a caster device. It is a perspective view of the main part which looked at the caster device, the connecting member, and the damper main body from diagonally above. It is a perspective view of the main part which looked at the caster device, the connecting member, and the damper main body from diagonally below. It is a perspective view of the main part which looked at the caster device, the connecting member and the damper main body in the state which were arranged in the horizontal leg main body of the horizontal leg used for a caster device from diagonally above.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view seen from an obliquely upper side of the overbed table according to the embodiment of the present invention, and FIG. 2 is a perspective view seen from an obliquely lower side of the overbed table. FIG. 3 is a front view of the overbed table, and FIG. 4 is a perspective view of the overbed table with the table plate removed. In the figure, an XY direction index is shown in order to clarify the directional relationship.

The overbed table 1 of this embodiment includes a table main body 2 and legs 3 and 4 (first leg 3 and 2nd leg 4) provided at both ends of the table main body 2, respectively. It includes a caster device 5 provided at the lower ends of the legs 3 and 4, and operation units 61 and 62 (first operation unit 61, second operation unit 62) for operating the caster device 5.

The table main body 2 includes an elongated table plate 21 that overhangs the upper part of the bed 10 (see FIG. 3), and a casing 22 for accommodating the parallel motion mechanism provided on the lower side of the table plate 21.

As shown in FIG. 4, a parallel motion mechanism 7 connected to the operation units 61 and 62 is provided in the casing 22. As shown in FIGS. 5 and 6, the parallel motion mechanism 7 has the same length as the first link 71 and the first link 71, and is arranged in parallel with the first link 71. 72, a third link 73 rotatably connecting the first link 71 and the second link 72 at one end thereof, and the first link 71 and the second link 72 rotatably at the other end thereof. A fourth link 74 connected and arranged in parallel with the third link 73 is provided, and the parallel motion mechanism 7 has a rectangular shape as a whole due to these links 71 to 74.

The parallel motion mechanism 7 is arranged along the lower surface of the table plate 21 by pivotally supporting the central portions of the third link 73 and the fourth link 74 in the longitudinal direction on the inner bottom surface of the casing 22, respectively. One end of the third link 73 projects outward (Y1 side) from the second link 72, and the first operation unit 61 is fixed to the one end. Further, one end of the fourth link 73 projects outward (Y2 side) from the first link 71, and the second operation unit 62 is fixed to the one end.

With this configuration, the first operation unit 61 is on one end side (X1 side) in the longitudinal direction (X direction) of the table body portion 2 (table plate 21) and in the width direction (Y direction) orthogonal to the longitudinal direction. Arranged at a position on one side (Y1 side), the second operation unit 62 is located on the other end side (X2 side) in the longitudinal direction of the table plate 21 and on the other side (Y2 side) in the width direction. It is arranged in. That is, the first operation unit 61 and the second operation unit 62 are both outer sides of the center O (central portion) in the longitudinal direction of the table main body portion 2 and are point-symmetrical with respect to the center O. It is arranged at the position.

As shown in FIGS. 1 to 4, the first leg portion 3 includes a vertical leg 3a that supports the table main body portion 2 from below, and a horizontal leg 3b arranged at the lower end of the vertical leg 3a.

The vertical leg 3a is composed of an outer cylinder 3A fixed to the table main body 2 (casing 22) and an inner cylinder 3B fixed to the horizontal leg 3b, and the outer cylinder 3A slides up and down. It is externally fitted to the inner cylinder 3B so as to be possible. The horizontal leg 3b includes a long horizontal leg main body 41 (see FIG. 5) that has a U-shaped front view that opens upward and extends in the Y direction, and a horizontal leg cover 42 that covers the horizontal leg main body 41 from above. I have.

The configuration of the second leg portion 4 is substantially the same as that of the first leg portion 3, and includes the vertical leg 3a and the horizontal leg 3b of the first leg portion 3 and the vertical leg 4a and the horizontal leg 4b configured symmetrically with each other. ..

Inside each of the vertical legs 3a and 4a (outer cylinder 3A and inner cylinder 3B) of the legs 3 and 4, as shown in FIG. 5, the damper body 300 of the damper device that assists the raising and lowering of the table body 2 Is built in. The damper device is a so-called gas damper.

As shown in FIGS. 5 and 15, each damper main body 300 is fitted into a shaft-shaped elevating operation main body portion 301a extending in the vertical direction so as to be able to appear and disappear below the elevating operation main body portion 301a. It is provided with a rod 301b. The upper end of the elevating operation main body 301a is fixed to the table main body 2, and the lower end of the rod 301b is fixed to the horizontal leg main body 41 of the horizontal legs 3b and 4b.

The damper body 300 is connected to a damper lock member 303 that locks its operation. The damper lock member 303 includes a rotatable shaft portion 303a connected to the damper main body 300 via a pulley 301c provided on each damper main body 300, and a lock portion 303b that locks the shaft portion 303a so as not to rotate. And.

Further, the damper lock member 303 is connected to the damper lock release lever 302. As shown in FIG. 4, the damper lock release lever 302 is on one end side (X1 side) in the longitudinal direction of the table plate 21 and on the opposite side (Y2) of the first operation unit 61 in the width direction (Y direction). It is arranged at a position on the side) and a position on the other end side (X2 side) of the table plate 21 in the longitudinal direction and on the side opposite to the second operation unit 62 (Y1 side). That is, each damper lock release lever 302 is also arranged on both outer sides of the table main body portion 2 with respect to the center O (central portion) in the longitudinal direction thereof and at a position point-symmetrical with respect to the center O. ..

These damper lock release levers 302 are operably connected to the lock portion 303b via a wire 302a. In FIG. 5, the damper lock release lever 302 and the wire 302a are omitted.

In this damper device, when the damper lock release lever 302 is unlocked, the shaft portion 303a is unlocked by the lock portion 303b, whereby the shaft portion 303a becomes rotatable. When the shaft portion 303a becomes rotatable, the rod 301b protrudes from the elevating operation main body portion 301a due to the gas pressure of the damper main body 300, that is, the damper main body 300 extends, and the outer cylinder body 3A becomes the inner cylinder body accordingly. It slides upward along 3B. As a result, the table body 2 rises. 1 to 5 show a state in which the table main body 2 is set at the lowest position.

When the damper lock release lever 302 is locked, the shaft portion 303a is non-rotatably locked by the lock portion 303b, and the position of the rod 301b with respect to the elevating operation main body portion 301a is maintained accordingly. As a result, the table body 2 is locked at the height position at that time.

When the table main body 2 is pressed downward against the gas pressure while the damper lock release lever 302 is unlocked, the rod 301b is housed in the elevating operation main body 301a, that is, the damper main body. As the 300 shrinks, the outer cylinder 3A slides downward along the inner cylinder 3B. As a result, the table body 2 is lowered.

Inside each of the vertical legs 3a and 4a (outer cylinder 3A and inner cylinder 3B) of the legs 3 and 4, the parallel motion mechanism 7 and the caster device 5 are for connecting the switching operation member 31 described later. A connecting shaft (connecting member) 36 extending in the vertical direction is rotatably arranged.

As shown in FIG. 5, each connecting shaft 36 is inserted into the outer cylinder shaft body 36A whose upper end is supported by the table main body 2 so that it can appear and disappear below the outer cylinder shaft body 36A. The lower end is composed of an inner cylinder shaft body 36B supported by the horizontal legs 3b and 4b.

The outer cylinder shaft body 36A of each connecting shaft 36 is connected to the parallel motion mechanism 7 via the first connecting link 37a and the second connecting link 37b. Specifically, one end of the first connecting link 37a is fixed to the outer cylinder shaft body 36A, while the other end of the first connecting link 37a is rotatably connected to one end of the second connecting link 37b. .. Further, the other end of the second connecting link 37b is pivotally supported with respect to the shaft support portion of the first link 71 and the third link 73 in the parallel motion mechanism 7. Regarding the connecting shaft 36 of the second leg portion 4, the other end of the second connecting link 37b is pivotally supported with respect to the shaft support portion of the first link 71 and the fourth link 74 in the parallel motion mechanism 7. ..

The lower end of the inner cylinder shaft body 36B of each connecting shaft 36 is rotatably supported by the horizontal leg main body 41 of the horizontal legs 3b and 4b, which will be described later. Further, a pinion 38 is provided at the lower end of the inner cylinder shaft body 36B as shown in FIGS. 7, 8 and 15.

The pinion 38 is formed in a substantially fan shape, and is provided with a plurality of gears 381 on the outer periphery of the arc shape. The pinion 38 is fixed to the lower end of the inner cylinder shaft body 36B and rotates integrally with the inner cylinder shaft body 36B.

The outer cylinder shaft body 36A and the inner cylinder shaft body 36B are connected by a spline, whereby the relative axial direction (vertical direction) movement between the outer cylinder shaft body 36A and the inner cylinder shaft body 36B can be performed. While allowed, relative rotation (rotation around the central axis) is prevented. Therefore, the outer cylinder shaft body 36A and the inner cylinder shaft body 36B rotate together, and when the table body 2 is raised and lowered, only the outer cylinder shaft body 36A moves up and down following the table body 2.

Next, the caster device 5 will be described. The caster device 5 has a wheel 19, a holder member 18 that rotatably supports the wheel 19, a free state that allows omnidirectional table movement along the floor surface, and a direction orthogonal to the longitudinal direction of the table plate 21. It is provided with a switching mechanism for switching the caster device 5 between a course lock state that allows only table movement along the floor surface and a lock state that prevents table movement.

The wheels 19 are arranged at both ends of the horizontal leg main body 41 of the horizontal legs 3b and 4b in the Y direction.

The holder member 18 is rotatably supported around each horizontal leg main body 41 around a vertical axis. Specifically, as shown in FIGS. 11 to 13, recesses 13d are formed at both ends of the horizontal leg main body 41, and oval-shaped caulking holes 13e are formed in the recesses 13d. Has been done. A spindle member 15 is attached to the horizontal leg main body 41. The spindle member 15 is composed of a cylindrical body extending in the vertical direction, and has a central hole 15a penetrating in the vertical direction. The shaft member 17 is inserted into the central hole 15a and can move up and down freely. It is supported. The shaft member 17 is inserted into the spindle member 15 (center hole 15a) and is height-regulated by the sliding portion 32 described later, so that the shaft member 17 is movably supported in three stages of upper, middle and lower. 11 shows a state in which the shaft member 17 is arranged in the lower stage (lock position), FIG. 12 shows the middle stage (course lock position), and FIG. 13 shows the upper stage (free position).

A semi-cylindrical sliding body 30 having a downward hemispherical cross section is fitted in the upper head 17a of the shaft member 17 projecting upward from the recessed portion 13d.

As shown in FIGS. 9 to 13, a sliding portion 32 is arranged on the lower side of the sliding body 30, so that the sliding body 30 can slide relative to the sliding portion 32. ..

As shown in FIGS. 7 and 8, the sliding portion 32 has a long shape (Y direction) arranged in the horizontal leg main body 41 of the horizontal legs 3b and 4b so as to be able to reciprocate along the Y direction. (Extended to) are provided at both ends of the switching operation member 31.

As shown in FIGS. 9 to 13, a plurality of portions having different heights, specifically, a lower portion 32a, a middle portion 32b, and an upper portion 32c are formed in a stepped shape on the upper surface of the sliding portion 32. .. As shown in FIG. 10, a slit 32d extending in the Y direction is formed in the sliding portion 32, and the shaft member 17 is inserted into the spindle member 15 (center hole 15a) through the slit 32d. That is, when the sliding portion 32 moves in the Y direction, the position of supporting the sliding body 30 in the sliding portion 32 is switched between the lower portion 32a, the middle portion 32b, and the upper portion 32c, and as a result, the shaft member 17 has already been described. It is supported by three levels of height, upper, middle and lower. In FIGS. 9 to 13, only one end of the switching operation member 31 of the first leg 3 on the Y1 side is shown.

The switching operation member 31 operates the wheel 19 in a free state, a course lock state, and a locked state, and as shown in FIGS. 7 and 8, a rack 321 that meshes with the pinion 38 is provided in the central portion in the longitudinal direction. ing. In addition, in FIGS. 7 and 8, the sliding body 30 is omitted.

The switching operation member 31 includes contact pieces 322 formed so as to project in the width direction at both ends in the longitudinal direction. When the switching operation member 31 moves in the Y direction, the contact piece 322 abuts on the inner wall surface 41a of the horizontal leg main body 41 of each of the horizontal legs 3b and 4b, and the switching operation member 31 is moved along the inner wall surface 41a. It will guide you. That is, the inner wall surface 41a of the horizontal leg main body 41 is the guide portion of the switching operation member 31, and the contact piece 322 is the guided portion of the switching operation member 31.

The switching operation member 31 is arranged so as to be movable in the Y direction in the horizontal legs 3b and 4b of the leg portions 3 and 4, respectively. As shown in FIG. 7, the sliding portion 32 of the switching operation member 31 of the first leg portion 3 (horizontal leg 3b) has an upper portion 32c, a middle portion 32b, and a lower portion 32a in this order from the Y1 side to the Y2 side. It is arranged. On the other hand, as shown in FIG. 8, the sliding portion 32 of the switching operation member 31 of the second leg portion 4 (horizontal leg 4b) has a lower portion 32a, a middle portion 32b, and an upper portion 32c from the Y1 side to the Y2 side. They are arranged in order.

The switching operation member 31 is guided by the rack escape restricting member 323 provided in the caster device 5 when reciprocating in the horizontal legs 3b and 4b along the Y direction.

As shown in FIGS. 15 to 17, the rack escape restricting member 323 is interposed between the pinion 38 and the inner bottom surface of the horizontal leg main body 41, and is fixed to the horizontal leg main body 41. A circular opening is formed in the rack escape restricting member 323, and the boss portion of the pinion 38 is rotatably fitted in the opening. With this configuration, the inner cylinder shaft body 36B and the pinion 38 are rotatably supported by the horizontal leg main body 41 in a positioned state.

Further, the rack escape restricting member 323 includes a rack escape receiving portion 323a that regulates the pinion 38 so that the rack 321 does not escape in the outer diameter direction thereof. The rack escape receiving portion 323a abuts on the side surface on the anti-pinion side of the switching operation member 31, so that the distance L between the rotation center of the pinion 38 and the rack 321 (distance in the X direction / illustrated in FIGS. 7 and 8). Is always maintained at the set distance.

Returning to FIG. 11, a large-diameter flange portion 15b and an oval-shaped caulking portion 15c that is fitted into the caulking hole 13e of the horizontal leg main body 41 from below are formed on the upper portion of the spindle member 15. Then, the flange portion 15b is applied to the lower surface of the recessed portion 13d of the horizontal leg main body 41, and the caulking portion 15c fitted into the caulking hole 13e is crimped outward, so that the spindle member 15 is positioned around the axis. Then, it is integrally fixed to the horizontal leg main body 41.

As shown in FIGS. 10 and 11, a hexagonal caulking portion 15d is formed in the lower portion of the spindle member 15, and the caulking portion 15d has a hexagonal caulking hole 16a of the plate-shaped swivel braking body 16. Is inserted from below. Then, by caulking the caulked portion 15d outward, the swivel braking body 16 is integrally fixed to the spindle member 15 in a state of being positioned around the axis (non-rotatable state).

As shown in FIG. 14, the swivel braking body 16 is formed with engaging protrusions 16b at two positions on the left and right sides of the caulking hole 16a in the direction orthogonal to the axis.

Further, as shown in FIGS. 10 and 11, the holder member 18 is held by the spindle member 15. The holder member 18 has a diameter slightly smaller than that of the wheel 19 and is formed in a thick substantially disk shape, and a lightening recess 18b is formed around the axle hole 18a. The wheels 19 are rotatably held by the axle 20 which is rotatably supported by the axle hole 18a.

The holder member 18 is formed with a through hole 18c that penetrates in the vertical direction at a position eccentric from the axle hole 18a. By fitting the through hole 18c into the spindle member 15 from below, the holder member 18 that rotatably supports the wheel 19 around the axle 20 is rotatably held by the spindle member 15. A spacer 21a and a cap 21b are interposed between the flange portion 15b of the spindle member 15 and the upper end of the holder member 18.

A quadrangular storage recess 18d wider than the through hole 18c is formed at the lower position of the through hole 18c of the holder member 18, and the braking block 23 can be moved up and down in the storage recess 18d so as not to rotate. It is stored in. The braking block 23 is urged in the downward movement direction by a coil spring 24 arranged so as to be compressed between the upper wall of the storage recess 18d and the upper surface of the braking block 23.

The braking block 23 is formed with a small-diameter through hole 23b through which the lower portion of the spindle member 15 penetrates. A large-diameter tubular hole 23c opened downward is formed below the through hole 23b, and a turning brake body 16 crimped by the caulked portion 15d of the spindle member 15 is located in the tubular hole 23c. is doing.

A large-diameter sleeve 26a is fitted and fixed to the lower opening of the tubular hole 23c, and a small-diameter sleeve 26b is fitted to the center hole of the sleeve 26a from below. Then, the lower portion of the shaft member 17 is projected downward from the center hole of the sleeve 26b having a small diameter, and the E-ring 27 is attached to this protruding portion to prevent the shaft member 17 from coming off upward. ..

Therefore, when the shaft member 17 (sliding body 30) is moved upward to a position corresponding to the middle portion 32b or the upper portion 32c of the sliding portion 32, that is, to the middle and upper stages, the E ring 27, the small diameter sleeve 26b, and the large diameter sleeve 26a are moved upward. The braking block 23 is moved up against the urging force of the coil spring 24. Further, if the shaft member 17 is not forcibly moved upward by the middle portion 32b and the upper portion 32c of the sliding portion 32, the shaft member 17 is also moved downward together with the braking block 23 by the urging force of the coil spring 24.

A downward comb tooth 23d protruding laterally is formed in the lower portion of the braking block 23, and the comb tooth is formed in the circumferential direction of the wheel 19 facing the comb tooth 23d when the braking block 23 is lowered. A plurality of engaging portions 191 with which 23d is engaged with each other are formed.

Therefore, when the shaft member 17 (sliding body 30) is moved downward to a position corresponding to the lower portion 32a of the sliding portion 32, that is, to the lower stage, the comb teeth 23d of the braking block 23 mesh with the engaging portion 191 of the wheel 19 and the wheel. The rotation of 19 is blocked (locked state). On the other hand, when the shaft member 17 (sliding body 30) is moved upward to a position corresponding to the middle portion 32b or the upper portion 32c of the sliding portion 32, that is, to the middle stage / upper stage, the braking block 23 moves upward and the comb teeth of the braking block 23 are moved upward. Since the 23d does not mesh with the engaging portion 191 of the wheel 19, the wheel 19 is allowed to rotate (free state).

An insertion groove 23e penetrating the tubular hole 23c is formed in the upper portion of the braking block 23, and a stopper member 28 of a rectangular plate is inserted into the insertion groove 23e from the side. The stopper member 28 is prevented from coming off in the insertion groove 23e by storing the braking block 23 in the storage recess 18d of the holder member 18.

The stopper member 28 is located above the turning braking body 16 crimped to the lower part of the spindle member 15. As shown in FIG. 14, the stopper member 28 includes an engaging recess 28b to which two engaging protrusions 16b on the left and right of the swivel braking body 16 can be engaged.

The engaging concave portion 28b of the stopper member 28 and the engaging convex portion 16b of the turning braking body 16 are oriented in the direction of the wheel 19 that moves the overbed table 1 in the Y direction, that is, the axial direction of the axle 20 holding the wheel 19 is X. Its orientation is set so that it engages only when it is along the direction and prevents the holder member 18 from turning.

Further, the stopper member 28 and the turning braking body 16 engage with each other when the shaft member 17 (sliding body 30) moves to a position corresponding to the middle portion 32b or the lower portion 32a of the sliding portion 32, that is, to the middle stage and the lower stage. This prevents the holder member 18 from turning (course lock state), while the shaft member 17 (sliding body 30) is disengaged when it moves to a position corresponding to the upper portion 32c of the sliding portion 32, that is, to the upper stage. As a result, the vertical positions of the holder members 18 are set so as to allow the holder members 18 to rotate.

Then, when the sliding body 30 is located at the lower portion 32a of the sliding portion 32 with the movement of the switching operation member 31 (see FIG. 11), the shaft member 17 moves to the lower stage accordingly, and the sliding body 30 moves to the sliding portion. When it is located in the middle portion 32b of 32 (see FIG. 12), the shaft member 17 moves to the middle stage accordingly, and when the sliding body 30 is located in the upper portion 32c of the sliding portion 32 (see FIG. 13), the shaft member follows it. 17 moves to the upper stage.

Next, the operation of the overbed table 1 will be described. First, when any one of the operation units 61 and 62 is rotated counterclockwise from the state shown in FIGS. 5 and 6 (course lock state), the parallel motion mechanism 7, the second connecting link 37b, and the first The connecting shaft 36 disposed in the vertical leg 3a of the first leg portion 3 and in the vertical leg 4a of the second leg portion 4 via the one connecting link 37a rotates counterclockwise.

Along with the counterclockwise rotation of the connecting shaft 36, the switching operation member 31 disposed in the horizontal leg 3b of the first leg portion 3 moves in the Y2 direction, whereby, as shown in FIG. 13, The shaft member 17 (sliding body 30) moves to the upper portion 32c of the sliding portion 32. Further, the switching operation member 31 disposed in the horizontal leg 4b of the second leg portion 4 moves in the Y1 direction, whereby the shaft member 17 (sliding body 30) is similarly moved to the upper portion 32c of the sliding portion 32. Moving.

In this state, the comb teeth 23d of the braking block 23 are disengaged from the engaging portion 191 of the wheel 19, and the stopper member 28 and the turning braking body 16 are disengaged. That is, the caster device 5 is in a "free state" in which the holder member 18 is rotatable and the wheels 19 are rotatable.

At this time, if it is assumed that the operation units 61 and 62 are connected to each connecting shaft 36 by a single rod body (link), the rod body bends and deforms when the operation units 61 and 62 are operated. As a result, the two connecting shafts 36 are not synchronized, which causes a delay in the movement of one of the switching operation members 31, and the shaft member 17 (sliding body 30) of each caster device 5 does not move to the central portion 32b at the same time. Is possible. However, in this embodiment, since each connecting shaft 36 is connected to the operation units 61 and 62 via the parallel motion mechanism 7, the two connecting shafts 36 rotate more reliably in synchronization. Therefore, the shaft member 17 (sliding body 30) of each caster device 5 can be more reliably moved to the upper portion 32c in synchronization. In other words, it is possible to more reliably synchronize the switching of the caster devices 5 of the legs 3 and 4 from the "course lock state" to the "free state".

Moreover, the position (position in the X direction) of the rack 321 that meshes with the pinion 38 is regulated by the rack escape restricting member 323, so that the distance L between the rotation center of the pinion 38 and the rack 321 (FIGS. 7 and 8). Since (shown) is always maintained at the set distance, phenomena such as tooth skipping are reliably prevented. Further, since the contact piece 322 of the switching operation member 31 comes into contact with the inner wall surface 41a of the horizontal leg main body 41 and is guided along the inner wall surface 41a, the switching operation member 31 is more stably Y. It will move in the direction. Therefore, the switching operation member 31 of each caster device 5 can be moved more reliably at the same time by a set amount, and the shaft member 17 of each caster device 5 can be moved more smoothly to the upper stage.

Further, when any one of the operation units 61 and 62 is rotated clockwise from the "free state", the two connecting shafts 36 rotate clockwise. As a result, the switching operation member 31 of the first leg portion 3 moves in the Y1 direction, and as shown in FIG. 12, the position of the shaft member 17 (sliding body 30) moves to the central portion 32b of the sliding portion 32. Further, the switching operation member 31 of the second leg portion 4 moves in the Y2 direction, and similarly, the shaft member 17 (sliding body 30) moves to the middle portion 32b of the sliding portion 32. As a result, the caster device 5 is in a "course lock state" in which the holder member 18 cannot turn and the wheels 19 can rotate. That is, in this state, the comb teeth 23d of the braking block 23 are maintained in a state of being disengaged from the engaging portion 191 of the wheel 19, but the stopper member 28 and the turning braking body 16 are in an engaged state, and as a result, the wheel. While the 19 can be rotated, the holder member 18 cannot be rotated. In this state, the axial direction of the axle 20 of the wheel 19 is arranged in the direction along the X direction (states 1 to 5). Therefore, the overbed table 1 can be moved only in the longitudinal direction of the bed 10.

In this case as well, for the same reason as described above, it is possible to more reliably synchronize the switching of the caster devices 5 of the legs 3 and 4 from the “free state” to the “course lock state”.

On the other hand, when any one of the operation units 61 and 62 is further rotated clockwise from the "course lock state", the two connecting shafts 36 rotate clockwise. As a result, the switching operation member 31 of the first leg portion 3 further moves in the Y1 direction, and as shown in FIG. 11, the shaft member 17 (sliding body 30) moves to the lower portion 32a of the sliding portion 32. Further, the switching operation member 31 of the second leg portion 4 moves in the Y2 direction, and similarly, the shaft member 17 (sliding body 30) moves to the lower portion 32a of the sliding portion 32. As a result, the caster device 5 is in a "locked state" in which the holder member 18 cannot turn and the wheels 19 cannot turn. That is, the engaging convex portion 16b of the turning braking body 16 is inserted into the engaging concave portion 28b of the stopper member 28, and the comb teeth 23d of the braking block 23 are inserted into the engaging portion 191 of the wheel 19. ..

According to the overbed table 1 configured as described above, each caster device 5 can be switched to a course lock state that allows only table movement in a direction orthogonal to the longitudinal direction of the table plate 21 by the switching mechanism. When the overbed table 1 is moved, if each caster device 5 is in the course locked state, the overbed table 1 can be smoothly and stably moved along the longitudinal direction of the bed 10. Therefore, the overbed table 1 does not move in an unintended direction, and the legs 3 and 4 do not hit the bed 10. Therefore, it is possible to provide an overbed table 1 that is easier to handle.

Further, according to the overbed table 1, since the first operation unit 61 and the second operation unit 62 are provided at positions on both outer sides of the table main body portion 2 from the central portion in the longitudinal direction, for example, nursing care. Even when the teacher or caregiver operates from the outside of the bed, it is easy to access, and therefore the operability is very good.

In particular, since the first operation unit 61 and the second operation unit 62 are arranged at positions symmetrical with respect to the center O of the table main body unit 2 (table plate 21), the orientation of the overbed table 1 is Even if the front and back are reversed, the positions of the first operation unit 61 and the second operation unit 62 are only exchanged, and the position of the operation unit itself is maintained at a constant position. Therefore, there is an advantage that the overbed table 1 has a high degree of freedom in the installation direction and is convenient.

Further, since the pinion 38 that meshes with the rack 321 of the switching operation member 31 has a substantially fan shape, the pitch circle of the gear of the pinion 38 is increased in a small space to engage the pinion 38 and the rack 321. The rate can be increased, and the rack 321 can be moved and operated with a large rotational torque. Therefore, it is advantageous in suppressing the structure of the overbed table 1, particularly the lateral legs 3b and 4b of the legs 3 and 4, from becoming large.

1 Overbed table 2 Table body 3 1st leg 4 2nd leg 3a, 4a Vertical leg 3b, 4b Horizontal leg 16 Swivel brake body 18 Holder member 19 Wheel 21 Table plate 36 Connecting shaft 38 Pinion 61 1st operation unit 62 Second operation unit 321 Rack 323 Rack escape control member

Claims (5)

An operation for operating the table main body having an elongated table plate, legs provided at both ends of the table main body in the longitudinal direction, caster devices provided at the lower ends of each leg, and the caster device. It ’s an overbed table with a part,
The caster device allows a wheel, a holder member that rotatably supports the wheel and is rotatably supported about an axis perpendicular to the legs, and omnidirectional table movement along the floor surface. It is equipped with a switching mechanism for switching the caster device between a free state, a course lock state that allows one-way table movement along the floor surface, and a locked state that prevents table movement.
The operation unit operates the switching mechanism, and is provided at positions on both outer sides of the table main body portion with respect to the central portion in the longitudinal direction.
The overbed table is characterized in that, in the course locked state, the switching mechanism allows only table movement in a direction orthogonal to the longitudinal direction as one direction. The operation unit includes a first operation unit arranged on one side in the width direction orthogonal to the longitudinal direction and a second operation unit arranged on the other side in the width direction.
The overbed table according to claim 1, wherein the first operation unit and the second operation unit are arranged at positions symmetrical with respect to the center of the table plate. A first link connected to the caster device, a second link arranged in parallel with the first link, and a third link rotatably connecting the first link and the second link at one end thereof. A link and a fourth link rotatably connected to the first link and the second link at the other end thereof and arranged in parallel with the third link are further provided.
The third link and the fourth link are rotatably held by the table main body portion.
The first operation unit is connected to the end of the third link so that the third link can be rotatably operated.
The overbed table according to claim 2, wherein the second operation unit is rotatably connected to the end of the fourth link. A connecting member for connecting the first operation unit and the second operation unit to the switching mechanism is further provided.
The switching mechanism includes a switching operation member that is movably arranged with respect to the wheel and that switches the wheel to the free state, the course lock state, and the locked state.
The switching operation member includes a rack.
The connecting member comprises a rotatable pinion that meshes with the rack.
The caster device is characterized by comprising a rack escape restricting member that regulates the rack so that the rack does not escape to the pinion in the out-of-diameter direction when the rack moves with the rotation of the pinion. The overbed table according to claim 3 . The overbed table according to claim 4, wherein the pinion has a substantially fan shape having an arcuate outer circumference, and the arcuate outer circumference is provided with a gear that meshes with the rack.

Images