JP7052985B2 - Portable work table - Google Patents

Description

The present invention relates to a portable workbench.

Conventionally, a portable workbench for performing aerial work has been known. Patent Document 1 discloses a portable workbench provided with a top plate and a pair of legs.

Japanese Unexamined Patent Publication No. 2011-84944

Portable workbenches are required to be more stable so that workers can work safely at heights.
The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a portable workbench capable of improving stability.

The portable workbench of the present invention has a top plate portion, a first leg body and a second leg body rotatably connected to the top plate portion, the first leg body, and the second leg body. A portable workbench comprising a first rotation restricting body and a second rotation restricting body that regulate the rotation of each of the legs, the first leg body and the second leg body. Each has a plurality of horizontal members, and the first rotation restricting body and the second rotation restricting body are connected to the horizontal members of different stages and with respect to the top plate portion. The top plate portion is connected closer to the center in the longitudinal direction than the end portion in the longitudinal direction of the top plate portion .

According to the present invention, stability can be improved.

It is a front view which shows an example of the structure of the workbench which concerns on 1st Embodiment. It is a side view which shows an example of the structure of a workbench. It is a side view which shows an example of the structure of a workbench. It is a top view which shows an example of the structure of a workbench. It is a figure which shows an example of the structure of a horizontal member. It is a front view which shows an example of the state which the enclosure part was deformed. It is a front view which shows an example of the state which the enclosure part was deformed. It is a figure which shows an example of the structure of the rotating part in the open leg state. It is a figure which shows an example of the structure of the rotating part in a closed leg state. It is a figure which shows an example of the structure of the rotating part in the open leg state. It is a figure which shows an example of the structure of the rotating part in a closed leg state. It is a perspective view which shows an example of the structure of a stay part. It is a bottom view which shows an example of the structure around the top plate part. It is sectional drawing which shows an example of the structure around the top plate part. It is a front view which shows an example of the state which the leg part is folded. It is a bottom view which shows an example of the state which the leg part is folded. It is a side view which shows an example of the structure of the workbench which concerns on 2nd Embodiment.

Hereinafter, the portable workbench according to the present embodiment will be described with reference to the drawings.
(First Embodiment)
The portable workbench 100 is a workbench for workers to work at high places. The portable workbench 100 (hereinafter referred to as a workbench 100) of the present embodiment is assumed to have a height of, for example, approximately 1000 mm to approximately 1900 mm from the floor surface to the top plate portion 110 described later.
FIG. 1 is a front view showing an example of the configuration of the workbench 100. FIG. 2 is a right side view showing an example of the configuration of the workbench 100. FIG. 3 is a left side view showing an example of the configuration of the workbench 100. FIG. 4 is a plan view showing an example of the configuration of the workbench 100. For ease of explanation, the front side is shown as Fr, the rear side is shown as Rr, the right side is shown as R, and the left side is shown as L, as necessary.
The workbench 100 has a top plate portion 110, a leg portion 130, an enclosure portion 140, a rotation portion 150, and a rotation restriction portion 180.

The top plate portion 110 has a function as a scaffold for a worker who works at a high place. The top plate portion 110 has a rectangular shape that is long in the front-rear direction when viewed from above. The front-back direction is, for example, a length of about 1500 mm, and the left-right direction is, for example, a length of about 500 mm.
The top plate portion 110 is configured by connecting a plurality of long top plate members. Specifically, the top plate portion 110 connects a plurality of (for example, three) long length members 111a to 111c long in the front-rear direction side by side side by side, and sandwiches bolts between the short member 112a and the short member 112b from the front and back. It is configured by fixing with or rivets (see FIG. 4). The rivet includes a blind rivet. The longitudinal members 111a to 111c and the lateral members 112a and 112b are made of, for example, an aluminum alloy and are formed by extrusion molding. Further, the longitudinal members 111a to 111c are metallic colors such as silver. On the other hand, the short members 112a and 112b have a metallic color such as gold, and are colored differently from the longitudinal members 111a to 111c. Therefore, the operator can easily visually recognize the short members 112a and 112b, and can easily recognize the position of the end portion of the top plate portion 110. The extruded aluminum alloy is colored, for example, in the process of alumite treatment.
The top plate portion 110 has a plurality of protrusions 113 as non-slip on the upper surface serving as a work surface. The protrusions 113 are formed over the entire surface of the top plate portion 110 at intervals. The protrusion 113 projects upward, and a hole is formed in the center.

Next, the leg 130 will be described.
The leg portion 130 has a function of supporting the load of the top plate portion 110 and supporting the load of a worker working on the top plate portion 110. Further, the leg portion 130 is connected to the end portion of the top plate portion 110 in the front-rear direction and is rotatable with respect to the top plate portion 110. By rotating the leg portion 130, the leg portion 130 is folded so as to overlap the top plate portion 110.
Specifically, the leg portion 130 has a pair of leg bodies 131A and 131B. The leg 131A is located at the rear portion in the front-rear direction and extends from the top plate portion 110 toward the floor surface. Further, the leg body 131B is located at the front portion of the top plate portion 110 in the front-rear direction, and extends from the top plate portion 110 toward the floor surface. As shown in FIG. 1, the leg body 131A and the leg body 131B face each other at positions separated from each other in the front-rear direction, and are inclined so as to be separated from each other toward the lower end. The leg body 131A and the leg body 131B have a so-called ladder shape, and an operator can move up and down between the top plate portion 110 and the floor surface.

First, the leg body 131A will be described.
The leg body 131A has leg members 132a and 132b, and a plurality of horizontal members 138a to 138d (see FIG. 2). The leg member 132a and the leg member 132b are located at both ends of the top plate portion 110 in the left-right direction. Further, the leg member 132a and the leg member 132b face each other with a gap in the left-right direction, and are inclined so as to be separated from each other toward the lower end.
The landing gear members 132a and 132b each have a main landing gear 133 and a telescopic leg 134.
The main landing gear 133 is a main member of the landing gear members 132a and 132d. The main landing gear 133 is made of, for example, an aluminum alloy and is formed by extrusion molding. The main landing gear 133 is a metallic color such as silver. Further, the main landing gear 133 is, for example, a hollow or solid member having a substantially rectangular cross section. The main landing gear 133 has a rotating member 155a described later at a position close to the upper end.

The telescopic leg 134 is a member that expands and contracts the leg members 132a and 132b along the longitudinal direction. The telescopic landing gear 134 fits inside the main landing gear 133 and is slidable along the longitudinal direction of the main landing gear 133. The telescopic legs 134 are made of, for example, an aluminum alloy and are formed by extrusion molding. The telescopic leg 134 is a metallic color such as silver. Further, the telescopic leg 134 is, for example, a hollow or solid member having a substantially rectangular cross section in which the cross-sectional shape of the main landing gear 133 is reduced. The telescopic leg 134 expands and contracts the lengths of the leg members 132a and 132b by changing the length protruding from the lower end of the main landing gear 133. In FIG. 1, a state in which the leg member 132a is shortened is shown by a two-dot chain line. Further, the telescopic leg 134 has a leg seat 135 at the lower end. The leg seat 135 is a member that stably grounds the lower ends of the leg members 132a and 132b to the floor surface. The leg seat 135 is made of, for example, a soft synthetic resin. The leg seat 135 is colored, for example, orange, blue, green, or the like. Further, the leg seat 135 is fixed to the outer periphery of the lower end of the telescopic leg 134 by using bolts, rivets, or the like.
The height of the top plate portion 110 can be adjusted by expanding and contracting the leg members 132a and 132b with the telescopic legs 134. The leg 130 can be adjusted stepwise in the height direction, for example, between 0 mm and 400 mm at intervals of, for example, approximately 60 mm.
Further, the main landing gear 133 has a lock mechanism 136. The locking mechanism 136 gradually locks the length of the telescopic legs 134 protruding from the lower ends of the leg members 132a and 132b. The lock mechanism 136 is attached to the side surface where the leg member 132a and the leg member 132b face each other.

The horizontal members 138a to 138d are so-called treads, and are members on which the operator puts his / her feet when going up and down. The horizontal members 138a to 138d are horizontally bridged between the main landing gear 133 of the landing gear 132a and the main landing gear 133 of the landing gear 132b. Further, the horizontal members 138a to 138d can also improve the rigidity of the leg body 131A.
Specifically, between the main landing gear 133 of the landing gear 132a and the main landing gear 133 of the landing gear 132b, the first-stage horizontal member 138a, the second-stage horizontal member 138b, and the third-stage horizontal member Four of the 138c and the fourth-stage horizontal member 138d are arranged. The horizontal members 138a to 138d have a shorter left-right length in the upper row and a longer left-right length in the lower row. The horizontal members 138a to 138d are fixed to the main landing gear 133 via brackets using bolts, rivets, or the like.
The horizontal members 138a to 138d are made of, for example, an aluminum alloy, and are formed by extrusion molding. Further, the horizontal members 138a to 138d are, for example, hollow or solid members. Here, the horizontal members 138a to 138db are colored differently from the leg members 132a and 132b. The horizontal members 138a to 138d have a metallic color such as gold. Therefore, the operator can easily see the horizontal members 138a to 138d and can prevent the horizontal members 138a to 138d from being stepped off when moving up and down. In this embodiment, the horizontal members 138a to 138d and the short members 112a and 112b are colored in the same color.

FIG. 5 is a diagram showing an example of the configuration of the horizontal member 138a. Here, the horizontal member 138a will be described, but the shape is the same as that of the horizontal members 138b to 138d except that the length is different.
FIG. 5A is a plan view of the horizontal member 138a. FIG. 5B is a side view of the horizontal member 138a. FIG. 5C is a front view (cross-sectional view) of the horizontal member 138a, and the main landing gear 133 is shown by a two-dot chain line. FIG. 5D is an enlarged cross-sectional view of the recess 126 of the horizontal member 138a.
The horizontal member 138a has an upper portion 121, mounting portions 122 and 123, and a lower portion 124. The upper surface of the upper portion 121 is a surface on which the legs of the worker are placed. The front portion of the upper portion 121 protrudes to the front side of the main landing gear 133, and the rear portion protrudes to the rear side of the main landing gear 133. Therefore, the area of the upper surface of the upper surface portion 121 can be expanded, and the operator can easily put his / her foot on it. Further, the upper portion 121 has a plurality of ridges 125 (or dents) along the longitudinal direction of the horizontal member 138a. The ridge 125 can prevent the worker's foot from slipping in the front-rear direction on the upper portion 121. The ridge 125 can be formed at the time of extrusion molding.

Further, the upper surface portion 121 has a plurality of recesses 126 on the upper surface along a direction intersecting the longitudinal direction of the horizontal member 138a, specifically, a direction substantially orthogonal to each other. The recess 126 is formed from the front end to the rear end of the upper portion 121. Here, the dimension from the upper surface of the upper portion 121 to the deepest position of the recess 126 is larger than the dimension from the upper surface of the upper portion 121 to the highest position of the ridge 125. As shown in FIG. 5D, the deeper the recess 126, the smaller the width gradually becomes, and the bottom becomes flat. The recess 126 can prevent the worker's foot from slipping left and right on the upper portion 121. The recess 126 is formed by extruding and then pressing the upper portion 121 so as to crush it from above. However, the recess 126 may be formed by cutting the upper surface of the upper portion 121.

Here, the case where the upper side portion 121 has the concave portion 126 has been described, but the present invention is not limited to this case, and the upper portion portion 121 may have at least one of the concave portion 126 and the convex portion. A plurality of convex portions are provided along a direction intersecting the longitudinal direction of the horizontal member 138a, specifically, a direction substantially orthogonal to each other. Further, the convex portion may have a substantially circular shape in a plan view and may be arranged over the entire surface of the upper portion 121 of the horizontal member 138a. In the case of forming a convex portion, it is preferable that the member is different from the horizontal member 138a.
Here, the leg body 131A has been described, but the leg body 131B also has the same configuration. The leg body 131B has leg members 132c and 132d, and a plurality of horizontal members 138a to 138d (see FIG. 3). That is, the leg member 131B has a structure in which the leg member 132a is replaced with the leg member 132d and the leg member 132b is replaced with the leg member 132c, and has the same number of stages of horizontal members 138a to 138d as the leg member 131A. When viewed from the front-rear direction, the horizontal members 138a to 138d of the leg body 131A and the horizontal members 138a to 138d of the leg body 131B overlap each other and are located at substantially the same height.

Next, the enclosure 140 will be described.
The enclosure 140 has a function of surrounding the work area of the top plate 110. The enclosure 140 has columns 141a to 141d, a pair of longitudinal rail members 142, and a pair of short side rail members 143. The columns 141a to 141d are respectively arranged at the corners of the top plate portion 110 along a substantially vertical direction. The columns 141a to 141d are rotatably connected to the upper ends of the leg members 132a to 132d, respectively. The pair of longitudinal crosspiece members 142 are bridged between the support column 141a and the support column 141c and between the support column 141b and the support column 141d on the upper side of the longitudinal end portion of the outer peripheral edge of the top plate portion 110. The longitudinal crosspiece member 142 is divided and configured at substantially the center in the longitudinal direction, and is rotatably connected to the upper ends of the columns 141a to 141d, respectively. The pair of short side rail members 143 are bridged between the pair of long side rail members 142 on the upper side of the short side end portion of the outer peripheral edge of the top plate portion 110.

The enclosure 140 can separate the short side rail member 143 from the state of being bridged to one longitudinal side rail member 142 and shift to the first state along the other longitudinal side rail member 142. .. In the first state, the operator can move back and forth between the top plate portion 110 and the leg body 131A, or between the top plate portion 110 and the leg body 131B.
Further, as shown in FIG. 6, the enclosure portion 140 can shift from the first state to the second state along the columns 141a to 141d by rotating the divided longitudinal crosspiece members 142, respectively. ..
Further, as shown in FIG. 7, the enclosure 140 can shift from the second state to the third state along the leg members 132a to 132d by rotating the columns 141a to 141d, respectively. In the third state, the longitudinal rail member 142 overlaps the main landing gear 133 in the left-right direction. In this way, by shifting to the third state, when the leg body 131A and the leg body 131B are rotated to be folded with respect to the top plate portion 110, the columns 141a to 141d constituting the enclosure portion 140 are included. The member to be used also rotates together with the leg body 131A and the leg body 131B.

Next, the rotating portion 150 will be described.
The rotating portion 150 has a function of rotating the leg portion 130 with respect to the top plate portion 110. By rotating the leg 130 via the rotating portion 150, the leg 130 has an open leg posture in which the leg 130 supports the top plate 110, and the leg 130 has a closed leg posture in which the leg 130 overlaps the top plate 110 and is folded. Change.
Specifically, the rotating portion 150 has rotating bodies 151a to 151d. The rotating bodies 151a to 151d are arranged between the leg members 132a to 132d and the top plate portion 110, respectively. That is, the rotating bodies 151a to 151d are located close to the corners of the top plate portion 110, respectively.
First, the rotating body 151a will be described. The rotating body 151a and the rotating body 151b have a substantially symmetrical configuration.

FIG. 8A (a) is a cross-sectional view showing a configuration around the rotating body 151a seen from the front side in the open leg state. FIG. 8A (b) is a diagram showing a configuration around the rotating body 151a viewed from the left-right direction in the open leg state. Note that FIG. 8A is shown by omitting the enclosure 140.
The rotating body 151a has a rotating support member 152a, a rotating member 155a, a rotating shaft 159, and a stopper mechanism 160a.
The rotation support member 152a is a member that supports the rotation of the leg member 132a. The rotation support member 152a is made of, for example, iron or titanium, and has a substantially plate shape. The rotation support member 152a is a metal color such as silver. The rotation support member 152a is fixed to the side surface of the top plate portion 110 by using bolts, rivets, or the like. The rotation support member 152a has a support hole 153a at the lower part into which the rotation shaft 159 is inserted. Further, the rotation support member 152a has a stopper hole 154 in the upper part into which the stopper member 165 described later is inserted. The rotation support member 152a may be appropriately formed with ribs having irregularities in the plate thickness direction in order to improve the rigidity.

The rotating member 155a is a member that engages with the stopper member 165, which will be described later. The rotating member 155a is made of, for example, iron or titanium, and has a substantially plate shape. The rotating member 155a is a metallic color such as silver. The rotating member 155a is located close to the upper end of the main landing gear 133, and is fixed to the outer side surface of the landing gear 132a by using bolts, rivets, or the like. Further, the rotating member 155a has a communication hole 156a communicating with the support hole 153a, a first engagement hole 157a, and a second engagement hole 158a. The first engaging hole 157a is located in the upper part of the rotating member 155a, and the second engaging hole 158a is located in the front part of the rotating member 155a. The distance from the communication hole 156a to the first engagement hole 157a and the distance to the second engagement hole 158a are the same. When the rotating member 155a is fixed to the side surface of the leg member 132a, the first engaging hole 157a and the second engaging hole 158a are positioned so as not to overlap with the leg member 132a when viewed from the left and right. ing. The first engaging hole 157a and the second engaging hole 158a are not limited to the through holes, and may be bottomed holes. Further, the rotating member 155a may be appropriately formed with ribs having irregularities in the plate thickness direction in order to improve the rigidity.
The rotation shaft 159 is a member that becomes the center of rotation when the leg member 132a rotates. The rotation shaft 159 inserts the support hole 153a of the rotation support member 152a and the communication hole 156a of the rotation member 155a. The rotating shaft 159 is, for example, a bolt, and is attached so as not to come off by screwing a nut. In this way, the rotating body 151a rotates the leg member 132a around the rotating shaft 159 supported by the rotating support member 152a via the rotating member 155a.

The stopper mechanism 160a is a mechanism for holding the leg member 132a in either the open leg state or the closed leg state. The stopper mechanism 160a is provided inside the top plate portion 110.
The stopper mechanism 160a has a stopper member 165, an urging member 168, and a lever portion 167.
The stopper member 165 is a member that engages with the first engaging hole 157a or the second engaging hole 158a of the rotating member 155a. The stopper member 165 is made of iron, for example, and has a substantially bar shape. The stopper member 165 is a metal color such as silver. The stopper member 165 is arranged along the left-right direction of the top plate portion 110. At this time, the stopper member 165 penetrates the rib 115 of the longitudinal member 111a and is slidable along the left-right direction through the rib 115. Specifically, the stopper member 165 has an engaging portion 166 and a lever portion 167. The engaging portion 166 is located at the tip of the stopper member 165 and engages with the rotating member 155a by being inserted into either the first engaging hole 157a or the second engaging hole 158a. The lever portion 167 is located on the opposite side of the engaging portion 166 and close to the substantially center of the top plate portion 110 in the left-right direction. The lever portion 167 extends in a direction substantially orthogonal to the left-right direction. The engaging portion 166 is always urged toward the rotating member 155a by the urging member 168 arranged between the engaging portion 166 and the lever portion 167. The urging member 168 is, for example, a coil spring, which is arranged between the intermediate position of the stopper member 165 and the rib 115 of the longitudinal member 111a. The lever portion 167 is a portion where an operator performs an operation of sliding the stopper member 165 in the left-right direction against the urging of the urging member 168 to disengage the engagement by the engaging portion 166. Here, the outer periphery of the lever portion 167 is covered with the operating lever 170. Therefore, in reality, the operator disengages the engagement by the engaging portion 166 by operating the operating lever 170.

The operating lever 170 is made of, for example, a synthetic resin. Further, the operating lever 170 is colored differently from the stopper member 165. Further, the operation lever 170 is colored differently from the top plate member of the top plate portion 110. Specifically, the operating lever 170 is, for example, blue. The operation lever 170 is colored, for example, by mixing a resin material with a colorant and injection molding. Further, the operating lever 170 has a plurality of non-slip ribs 171 protruding radially from the outer peripheral surface in an annular shape.
As described above, since the diameter of the portion to be gripped is increased by covering the lever portion 167 with the operating lever 170, the operator can easily perform the operation of disengaging. Further, by coloring the operation lever 170, the operator can easily recognize the operation lever 170.

Here, with reference to FIGS. 8A and 8B, the operation when the leg member 132a rotates from the open leg state to the closed leg state will be described.
FIG. 8B (a) is a cross-sectional view showing a configuration around the rotating body 151a seen from the front side in a closed leg state. FIG. 8B (b) is a diagram showing a configuration around the rotating body 151a viewed from the left-right direction in the closed leg state. Note that FIG. 8B is shown by omitting the enclosure 140.
First, the operator operates the operating lever 170 against the urging of the urging member 168 from the state shown in FIG. 8A to slide the stopper member 165 in the left-right direction. When the stopper member 165 slides, the engaging portion 166 of the stopper member 165 is disengaged from the first engaging hole 157a of the rotating member 155a, and the engagement between the stopper member 165 and the rotating member 155a is released. .. In this state, the leg member 132a can be rotated with respect to the top plate portion 110. The operator rotates the leg member 132a around the rotation shaft 159 of the rotating body 151a in the direction of overlapping with the top plate portion 110. While the leg member 132a is rotating, the rotating member 155a also rotates with the rotation of the leg member 132a. While the leg member 132a is rotating, the operator releases the operating lever 170, and the engaging portion 166 of the stopper member 165 comes into contact with the surface of the rotating member 155a due to the urging of the urging member 168. .. Therefore, the rotating member 155a rotates while being in contact with the engaging portion 166 of the stopper member 165.

As shown in FIG. 8B, the leg member 132a rotates until it is substantially parallel to the top plate portion 110, so that the second engaging hole 158a of the rotating member 155a communicates with the stopper hole 154. Therefore, the engaging portion 166 of the stopper member 165 is inserted into the second engaging hole 158a by the urging of the urging member 168, and the stopper member 165 engages with the rotating member 155a. In this way, the leg member 132a is held in the closed leg state. In order to shift the leg member 132a from the closed leg state to the open leg state, the engagement between the stopper member 165 and the rotating member 155a is released.
Here, the leg member 132a has been described, but since the leg member 132a and the leg member 132b are integrally configured via the horizontal members 138a to 138d, the leg member 132b also rotates in the same manner. The operating lever 170 that disengages the rotating member 155a fixed to the leg member 132a from the stopper member 165, and the rotating member 155a fixed to the leg member 132b and the stopper member 165 are engaged with each other. The operating levers 170 to be released are located adjacent to each other in the center of the top plate portion 110 in the left-right direction. Therefore, the operator can disengage both the leg member 132a side and the leg member 132b side by performing an operation such as grasping the two operating levers 170 with one hand.

Next, the rotating body 151c will be described. Since the rotating body 151c and the rotating body 151d have a substantially symmetrical configuration, the rotating body 151c will be mainly described below. Further, the rotating body 151c will be mainly described in terms of differences from the configuration of the rotating body 151a, and the same components will be designated by the same reference numerals and description thereof will be omitted as appropriate.
FIG. 9A (a) is a diagram showing a configuration around the rotating body 151c seen from the left-right direction in the open leg state. FIG. 9A (b) is a cross-sectional view showing the configuration around the rotating body 151c seen from the rear side in the open leg state. Note that FIG. 9A is shown by omitting the enclosure 140.
The rotating body 151c has a rotating support member 152c, a rotating member 155c, a rotating shaft 159, and a stopper mechanism 160c.
The rotation support member 152c is a member that supports the rotation of the leg member 132c. The rotation support member 152c is made of, for example, iron or titanium, and has a substantially plate shape. The rotation support member 152c is a metal color such as silver. The rotation support member 152c has a support hole 153c at the lower part into which the rotation shaft 159 is inserted. The support hole 153c is located below the support hole 153a of the rotation support member 152a described above. However, the stopper hole 154 is located at the same height as the stopper hole 154 of the rotation support member 152a described above. The rotation support member 152c may be appropriately formed with ribs having irregularities in the plate thickness direction in order to improve the rigidity.

The rotating member 155c is a member that engages with the stopper member 165. The rotating member 155c is made of, for example, iron or titanium, and has a substantially plate shape. The rotating member 155c is a metallic color such as silver. The rotating member 155c is located close to the upper end of the main landing gear 133, and is fixed to the outer side surface of the landing gear 132c by using bolts, rivets, or the like. Further, the rotating member 155c has a communication hole 156c communicating with the support hole 153c, a first engagement hole 157c, and a second engagement hole 158c. The first engaging hole 157c is located above the rotating member 155c and the second engaging hole 158c is located behind the rotating member 155c. The distance from the communication hole 156c to the first engagement hole 157c and the distance to the second engagement hole 158c are the same. When the rotating member 155c is fixed to the side surface of the leg member 132c, the first engaging hole 157c and the second engaging hole 158c are positioned so as not to overlap with the leg member 132c when viewed from the left and right. ing. The first engaging hole 157c and the second engaging hole 158c are not limited to the through holes, and may be bottomed holes. Further, the rotating member 155c may be appropriately formed with ribs having irregularities in the plate thickness direction in order to improve the rigidity.
The rotating body 151c rotates the leg member 132c around the rotating shaft 159 supported by the rotating support member 152c via the rotating member 155c. However, since the support hole 153c is located below the support hole 153a described above, the rotating body 151c supports the rotation of the leg member 132c at a position below the rotating body 151a described above. In this way, the position where the leg member 132c is rotated is set to the lower side because the leg member 132c does not directly overlap with the top plate portion 110 but overlaps with the leg member 132a in the closed leg posture. Is. That is, in the closed leg posture, the top plate portion 110, the leg member 132a, and the leg member 132c are overlapped in this order, and the position to rotate the leg member 132c in the closed leg posture is set to the front and back of the leg member 132a. It is offset downward by approximately the thickness in the direction.

The stopper mechanism 160c has a stopper member 165, an urging member 168, and a lever portion 167.
Here, with reference to FIGS. 9A and 9B, the operation when the leg member 132c rotates from the open leg state to the closed leg state will be described. The same operation as the operation when the leg member 132a rotates from the open leg state to the closed leg state will be omitted as appropriate.
FIG. 9B (a) is a diagram showing the configuration around the rotating body 151c seen from the left-right direction in the closed leg state. FIG. 9B (b) is a cross-sectional view showing a configuration around the rotating body 151c seen from the rear side in a closed leg state. Note that FIG. 9B is shown by omitting the enclosure 140.
First, the operator operates the operating lever 170 against the urging of the urging member 168 from the state shown in FIG. 9A to slide the stopper member 165 in the left-right direction. When the stopper member 165 slides, the engaging portion 166 of the stopper member 165 is disengaged from the first engaging hole 157c of the rotating member 155c, and the engagement between the stopper member 165 and the rotating member 155c is released. .. The operator rotates the leg member 132c around the rotation shaft 159 of the rotating body 151c in the direction of overlapping with the leg member 132a.

As shown in FIG. 9B, the leg member 132c rotates until it is substantially parallel to the leg member 132a and the top plate portion 110, so that the second engaging hole 158c of the rotating member 155c communicates with the stopper hole 154. do. Therefore, the engaging portion 166 of the stopper member 165 is inserted into the second engaging hole 158c by the urging of the urging member 168, and the stopper member 165 engages with the rotating member 155c. In this way, the leg member 132c is held in the closed leg state. In order to shift the leg member 132c from the closed leg state to the open leg state, the engagement between the stopper member 165 and the rotating member 155c is released.
Here, the leg member 132c has been described, but since the leg member 132c and the leg member 132d are integrally configured via the horizontal members 138a to 138d, the leg member 132d also rotates in the same manner. The operating lever 170 that disengages the rotating member 155c fixed to the leg member 132c from the stopper member 165, and the rotating member 155c fixed to the leg member 132d and the stopper member 165 are engaged with each other. The operating levers 170 to be released are located adjacent to each other in the center of the top plate portion 110 in the left-right direction. Therefore, the operator can disengage both the leg member 132c side and the leg member 132d side by performing an operation such as grasping the two operating levers 170 with one hand.

Next, the rotation control unit 180 will be described.
The rotation restricting portion 180 has a function of restricting the rotation of the leg portion 130 with respect to the top plate portion 110.
Specifically, the rotation restricting unit 180 has rotation restricting bodies 181A and 181B (see FIG. 1). The rotation restricting body 181A is located at the rear portion in the front-rear direction, and is connected to the top plate portion 110 and the leg body 131A. Therefore, the rotation restricting body 181A restricts the rotation of the leg body 131A. Further, the rotation restricting body 181B is located at the front portion in the front-rear direction and is connected to the top plate portion 110 and the leg body 131B. Therefore, the rotation restricting body 181B restricts the rotation of the leg body 131B.

The rotation restricting body 181A has a stay portion 182a and a stay portion 182b (see FIG. 2). Since the stay portion 182a and the stay portion 182b have a substantially symmetrical configuration, the stay portion 182a will be described here.
As shown in FIGS. 1 and 2, the stay portion 182a is arranged between the top plate portion 110 and the horizontal member 138b on the second stage from the upper side.
FIG. 10 is a perspective view of an example of the configuration of the stay portion 182a as viewed from diagonally above.
FIG. 10A shows a state in which the angle α of the stay portion 182a is smaller than 180 degrees, and FIG. 10B shows a state in which the angle α of the stay portion 182a is larger than 180 degrees.
The stay portion 182a has a first stay member 183, a second stay member 185a, and a cover member 188. The first stay member 183 is rotatably connected to the lower surface of the top plate portion 110 via the bracket 184. The second stay member 185a is rotatably connected to the mounting portion 122 of the horizontal member 138b on the second stage from the upper side via the bracket 186. The first stay member 183 is a linear member, and has, for example, a U-shaped cross section. The second stay member 185a is a linear member, and has, for example, a U-shaped cross section or a C-shaped cross section. The first stay member 183 and the second stay member 185a are made of, for example, an aluminum alloy, and are formed by extrusion molding. Further, the first stay member 183 and the second stay member 185a have a metallic color such as silver color. The rotation shaft 187 is inserted at a position where the first stay member 183 and the second stay member 185a overlap. The first stay member 183 and the second stay member 185a are rotatable via the rotation shaft 187.

The cover member 188 is a member that prevents a hand from being pinched between the first stay member 183 and the second stay member 185a. The cover member 188 has a substantially plate shape. The cover member 188 is made of, for example, a synthetic resin. Further, the cover member 188 is colored differently from the first stay member 183 and the second stay member 185a. Specifically, the cover member 188 is red, orange, yellow, or the like. The cover member 188 is colored, for example, by mixing a resin material with a colorant and injection molding. The cover member 188 is attached to the end of the first stay member 183 on the rotation shaft 187 side in the longitudinal direction. Further, the cover member 188 is attached so as to protrude outward from the end portion.

Here, in order to make the workbench 100 usable, as shown in FIG. 1, the angle α between the first stay member 183 and the second stay member 185a exceeds 180 degrees and is 180 degrees. Greater than a given angle (eg 185 degrees). In this state, since the first stay member 183 and the second stay member 185a come into contact with each other, the angle α does not rotate in a direction larger than a predetermined angle. Further, when the temperature exceeds 180 degrees, resistance is generated in the stay portion 182a, and it is necessary to rotate against the resistance. Therefore, once the angle α exceeds 180 degrees, it is difficult to rotate in a direction smaller than 180 degrees. In this way, since the rotation is restricted by the angle α of the stay portion 182a exceeding 180 degrees, the distance between the top plate portion 110 connected to the stay portion 182a and the leg body 131A is maintained. The rotation of the leg 131A with respect to the top plate 110 can be restricted.

In order for the operator to rotate the stay portion 182a so as to exceed 180 degrees against the resistance, the first stay member 183 and the second stay member 185a are shown in FIG. 10 (a). The cover member 188 located at the portion where the and overlaps with each other is pressed in the direction of the arrow. As shown in FIG. 10B, rotation is restricted when the angle α of the stay portion 182a exceeds 180 degrees and becomes a predetermined angle. At this time, the operator can prevent the operator from pinching his / her hand between the first stay member 183 and the second stay member 185a by pressing the cover member 188.
On the other hand, by setting the angle α of the stay portion 182a to an angle smaller than 180 degrees, the leg 131A can approach toward the top plate 110 side, so that the leg 131A is folded with respect to the top plate 110. Can be rotated like this.

Further, the rotation restricting body 181B has a stay portion 182c and a stay portion 182d (see FIG. 3). Since the stay portion 182c and the stay portion 182d have a substantially symmetrical configuration, the stay portion 182c will be described here.
As shown in FIGS. 1 and 3, the stay portion 182c is arranged between the top plate portion 110 and the horizontal member 138a which is the first stage from the upper side.
The stay portion 182c has a first stay member 183, a second stay member 185c, and a cover member 188. The stay portion 182c has a configuration in which the above-mentioned second stay member 185a is replaced with a second stay member 185c having a short length. The second stay member 185c is rotatably connected to the mounting portion 122 of the horizontal member 138a on the first stage from the upper side via the bracket 186.
Similar to the stay portion 182a, the stay portion 182c can restrict the rotation of the leg body 131B with respect to the top plate portion 110.
On the other hand, by setting the angle α of the stay portion 182c to an angle smaller than 180 degrees, the leg member 132c and the leg member 132d can approach toward the top plate portion 110, so that the leg member 132c with respect to the top plate portion 110 can be approached. And the leg member 132d can be rotated so as to be folded.

Next, a state in which the rotation restricting portion 180 and the top plate portion 110 are connected will be described.
FIG. 11 is a bottom view of the top plate portion 110 and the rotation restricting portion 180 as viewed from below. FIG. 12 is a cross-sectional view taken along the line I-I of FIG. 11 cut in the vertical direction and viewed from the direction of the arrow.
The stay portions 182a and 182b and the stay portions 182c and 182d are indirectly connected to the lower surface of the top plate portion 110 via the reinforcing members 190a and 190b. Since the reinforcing member 190a and the reinforcing member 190b have a front-to-back symmetrical configuration, the reinforcing member 190a will be mainly described here.
The reinforcing member 190a is a member that disperses the load from the top plate portion 110 and transmits it to the stay portion 182a and the stay portion 182b. The reinforcing member 190a is made of, for example, synthetic resin, iron or titanium. Further, the reinforcing member 190a is a metal color such as silver color. The reinforcing member 190a is formed by bending a strip-shaped plate, and is arranged along the left-right direction of the top plate portion 110. The reinforcing member 190a is fixed to the top plate portion 110 by using bolts, rivets, or the like.

Specifically, the reinforcing member 190a has a bulging portion 191 located at the center in the left-right direction and connecting portions 192 located on both sides of the bulging portion 191. The bulging portion 191 bulges downward and is fixed in contact with the rib 115 of the top plate portion 110. The connection portion 192 is fixed in a state where the top plate portion 110 is in contact with the upper surface and the stay portion 182a and the bracket 184 of the stay portion 182b are in contact with the lower surface. Further, the end portion 193 in the left-right direction of the reinforcing member 190a is located below the connecting portion 192 and is fixed to the top plate portion 110.
Here, the effect of the reinforcing member 190a will be described. Here, it is assumed that a load is received from the top plate portion 110 directly above the stay portion 182a. First, when there is no reinforcing member 190a, most of the load from the top plate portion 110 is received by one stay portion 182a. On the other hand, when there is a reinforcing member 190a, the load from the top plate portion 110 is also transmitted to the stay portion 182b through the reinforcing member 190a and can be received by the two stay portions 182a and 182b. Therefore, the strength of the workbench 100 can be improved by having the reinforcing member 190a. Although the case where the reinforcing member 190a and the reinforcing member 190b are separate bodies has been described, the reinforcing member 190a and the reinforcing member 190b may be connected and integrally configured.

Next, a closed leg state in which the leg portion 130 is folded with respect to the top plate portion 110 will be described.
FIG. 13 is a front view showing a closed leg state of the workbench 100. FIG. 14 is a bottom view showing a closed leg state of the workbench 100. When the leg portion 130 is folded, the lengths of the leg members 132a to 132d are shortened in advance. Further, when the leg portion 130 is folded, the top plate portion 110 is folded so as to be in contact with the floor surface, so that the top plate portion 110, the leg member 132a, and the leg member 132c are overlapped in this order from the lower side. In the folded state, the horizontal members 138a to 138d of the leg 131A and the horizontal members 138a to 138d of the leg 131B overlap each other in the vertical direction. Specifically, the first-stage horizontal member 138a of the leg 131A and the fourth-stage horizontal member 138d of the leg 131B overlap each other, and the second-stage horizontal member 138b and the leg 131B of the leg 131A overlap. The third-stage horizontal member 138c of the leg body 131A overlaps, the third-stage horizontal member 138c of the leg body 131A and the second-stage horizontal member 138b of the leg body 131B overlap, and the fourth-stage horizontal member of the leg body 131A overlaps. The horizontal member 138d and the first-stage horizontal member 138a of the leg 131B overlap each other. By overlapping the horizontal members 138a to 138d in the vertical direction in this way, when the other workbenches 100 and the like are stacked, the horizontal members 138a to 138d of the leg 131B and the horizontal members 138a of the leg 131A are stacked. It is possible to prevent the leg 130 from being damaged because the load is applied to both the 138d and the 138d. It should be noted that at least one of the horizontal members 138a to 138d of the leg body 131A and the horizontal members 138a to 138d of the leg body 131B may overlap each other, and a part thereof may be partially displaced in the front-rear direction. They may overlap.

Further, in the closed leg state, the stay portions 182a and 182b connected to the leg body 131A are positioned so as to overlap the top plate portion 110 in the left-right direction. Here, since there is nothing intervening between the leg body 131A and the top plate portion 110, the second stay member 185a of the stay portions 182a and 182b is the second-stage horizontal member 138b of the leg body 131A. Can be connected to.
On the other hand, the stay portions 182c and 182d connected to the leg body 131B are positioned so that the first stay member 183 overlaps the top plate portion 110 in the left-right direction, and the second stay member 185c is positioned with the top plate portion 110 and the legs. It is located between the body 131B. Here, since the leg body 131A is interposed between the leg body 131B and the top plate portion 110, there is a possibility of interfering with the second stay member 185c. Therefore, by connecting the second stay member 185c of the stay portions 182c and 182d to the horizontal member 138a of the first stage of the leg body 131B, it is possible to prevent interference with the leg body 131A.
Therefore, the leg portion 130 can be rotated and folded with respect to the top plate portion 110 so that the rotation restricting portion 180 and the leg portion 130 do not interfere with each other.

In the workbench 100 of the present embodiment, the rotation restricting body 181A is connected to the second-stage horizontal member 138b of the leg body 131A. The lower the horizontal members 138a to 138d, the closer they are to the floor surface, so that there is less shaking and the horizontal members are stable. Therefore, by connecting the rotation restricting body 181A to the horizontal member 138b of the second stage instead of the first stage, the stability of the top plate portion 110 can be improved. The rotation restricting body 181A is not limited to the case where it is connected to the second-stage horizontal member 138b, but is connected to the second-stage or lower, that is, the third-stage horizontal member 138c or the fourth-stage horizontal member 138d. You may.
On the other hand, the rotation restricting body 181B is connected to the first-stage horizontal member 138a of the leg body 131B. In this way, by connecting the rotation restricting body 181B to the horizontal member 138a of the first stage, the leg body 131B can be rotated and folded without interfering with the leg body 131A. The rotation restricting body 181B is not limited to the case where it is connected to the first-stage horizontal member 138a, and may be connected to the horizontal member on the upper stage than the horizontal member to which the rotation restricting body 181A is connected. can. For example, when the rotation restricting body 181A is connected to the third stage horizontal member 138c of the leg body 131A, the rotation restricting body 181B is the first stage horizontal member 138a or the second stage of the leg body 131B. It can be connected to the horizontal member 138b of the eye.
Therefore, by connecting the rotation restricting body 181A and the rotation restricting body 181B to the horizontal members 138a to 138d of different stages, the rotation restricting body connected to the lower horizontal member causes the top plate portion 110. The stability of the can be further improved.

(Second embodiment)
In the first embodiment, the workbench 100 in which the leg body 131A and the leg body 131B have the four-stage horizontal members 138a to 138d has been described, but even if a workbench having the horizontal members other than the four stages is prepared. good. In this case, it is possible to select a workbench according to the height at which the worker works at a high place.
FIG. 15A is a diagram showing a configuration of a workbench 200 in which the leg body 131A is a two-stage horizontal member 138a and 138b. Here, the first-stage horizontal member 138a of the workbench 200 and the first-stage horizontal member 138a of the workbench 100 of the first embodiment have the same configuration. In other words, the first-stage horizontal member 138a of the workbench 200 and the first-stage horizontal member 138a of the workbench 100 are common members that can be attached to each other even if they are replaced. Similarly, the second-stage horizontal member 138b of the workbench 200 and the second-stage horizontal member 138b of the workbench 100 are common members that can be attached to each other even if they are replaced. In this way, the reason why they can be replaced is that the main landing gear 133 of the leg member 132a and the main landing gear 133 of the leg member 132b are made of the same member only having different lengths between the workbench 100 and the workbench 200. be. Further, the distance and inclination between the main landing gear 133 of the landing gear 132a and the main landing gear 133 of the landing gear 132b are the same for the workbench 100 and the workbench 200. As described above, the management cost and the manufacturing cost can be reduced by using the horizontal member 138a and the horizontal member 138b that are common to the different workbenches 100 and 200.

FIG. 15B is a diagram showing a configuration of a workbench 210 in which the leg body 131A is a three-stage horizontal member 138a, 138b, and 138c. Here, as in FIG. 15C, the horizontal members 138a to 138c of the workbench 210 and the horizontal members 138a to 138c of the workbench 100 are common members that can be attached to each other even if they are replaced. .. As described above, by using the horizontal members 138a to 138c common to the different workbenches 100 and 210, the management cost and the manufacturing cost can be reduced.
Such a configuration having a workbench 100, a workbench 200, a workbench 210, and the like is referred to as a workbench system.

Although the present invention has been described above with respect to the above-described embodiment, the present invention is not limited to the above-mentioned embodiment and can be modified within the scope of the present invention.
In the above-described embodiment, the case where the leg members 132a to 132d have the telescopic legs 134 has been described, but the case is not limited to this case, and the telescopic legs 134 may not be provided.

In the above-described embodiment, the case where the leg portion 130 has four leg members 132a to 132d has been described, but the present invention is not limited to this case, and the leg portion 130 may have five or more leg members.
In the present embodiment, the case where the rotation restricting body 181A and the rotation restricting body 181B are connected to the horizontal members 138a to 138d of different stages has been described, but the present invention is not limited to this case and may be changed according to a problem or the like. It can be changed as appropriate.

100: Portable work table 110: Top plate part 130: Leg part 131A: Leg body 131B: Leg body 132a to 132d: Leg member 138a to 138d: Horizontal member 150: Rotating part 180: Rotation restricting part 181A: Times Motion control body 181B: Rotation control body 200: Portable work table 210: Portable work table

Claims (9)

Top plate and
The first leg body and the second leg body rotatably connected to the top plate portion,
A portable workbench provided with a first rotation restricting body and a second rotation restricting body that regulate the rotation of the first leg body and the second leg body, respectively.
The first leg body and the second leg body each have a plurality of horizontal members.
The first rotation restricting body and the second rotation restricting body are connected to horizontal members of different stages, and from the end portion of the top plate portion in the longitudinal direction with respect to the top plate portion. Is also a portable workbench characterized in that it is connected to the center of the top plate portion in the longitudinal direction . The first rotation restricting body is
The portable workbench according to claim 1, wherein the workbench is connected to the second or lower horizontal member from the upper side among the plurality of horizontal members of the first leg. The second rotation restricting body is
The portable work according to claim 1 or 2, wherein the first rotation restricting body is connected to a horizontal member at an upper stage of the horizontal member connected to the first leg. Platform. The first leg and the second leg are foldable and
The first leg body overlaps with the top plate portion and is also
The portable workbench according to any one of claims 1 to 3, wherein the second leg body is folded so as to overlap with the first leg body. In a plan view, when the first leg and the second leg are folded, the horizontal member of the first leg and the horizontal member of the second leg overlap each other. The portable workbench according to any one of claims 1 to 4. The portable workbench according to any one of claims 1 to 5, wherein the rotation restricting body is connected to the top plate portion via a reinforcing member. The rotation restricting body has a plurality of stay portions and has a plurality of stay portions.
The portable workbench according to any one of claims 1 to 6, wherein the plurality of stay portions are connected to the top plate portion via one reinforcing member. The portable type according to any one of claims 1 to 7, wherein the horizontal member has at least one of a concave portion and a convex portion on the upper surface along a direction intersecting the longitudinal direction. Workbench. In the side view in the direction orthogonal to the longitudinal direction of the top plate portion,
The distance from the center in the longitudinal direction of the top plate portion to the position where the first rotation restricting body is connected to the top plate portion.
Any of claims 1 to 8, wherein the distance from the center of the top plate portion in the longitudinal direction to the position where the second rotation restricting body is connected to the top plate portion is substantially the same. Or the portable workbench described in item 1.

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