JP2019027061A - Leg base and work bench - Google Patents

Abstract

To allow a work bench to be grounded on a floor surface stably.SOLUTION: A leg base 100a is mounted on a leg part 33a of a portable type work bench 1, and is grounded on a floor surface. The leg base 100a has a grounded part 130 which has a size that cannot be inserted in a hole 200 whose diameter is equal to or greater than 75 mm formed on the floor surface.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a leg seat and a work table.

  2. Description of the Related Art Conventionally, a work table in which a leg seat is attached to the lower end of a leg portion of the work table is known in order to stably ground a work table such as a portable work table or a stepladder work table on the floor surface. Patent Document 1 discloses a work table in which rubber tubes are fitted and fixed to four legs, respectively.

Japanese Utility Model Publication No. 7-14100

In order to use such a workbench at, for example, a construction work site, it is necessary to completely ground the leg seat to the floor surface. However, since the floor of the work site is under construction, there are a number of obstacles that prevent the seat from contacting the floor. In particular, there may be a hole of an opening member called a sleeve on the floor surface. The sleeve is a hole that is opened in advance in order to allow water supply and drainage piping, electrical wiring, and the like to pass through a concrete floor or the like.
Here, it is assumed that an operator who wants to ground the work table places the leg seat on the hole without noticing the hole of the sleeve. In such a state, there is a problem that the leg seat is inserted into the hole of the sleeve and the work table cannot be stably grounded to the floor surface.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to enable a work table to be stably grounded on a floor surface.

The leg seat of the present invention is a leg seat that is attached to a leg portion of a work table and contacts the floor surface, and the leg seat has a size that cannot be inserted into a hole formed on the floor surface and having a diameter of 75 mm or more. It has a grounding part.
The work table of the present invention is a work table provided with a leg seat that is attached to a leg portion and contacts the floor surface, and the leg seat cannot be inserted into a hole formed in the floor surface and having a diameter of 75 mm or more. A grounding portion having a size is provided.

  According to the present invention, the work table can be stably grounded to the floor surface.

It is a perspective view which shows the structure of a work table. It is a front view which shows the structure of a work table. It is a top view which shows the structure of a work table. It is a side view of a leg seat. It is the enlarged view to which a part of leg seat was expanded. It is a bottom view of a leg seat. It is a rear view of a leg seat. It is a top view of a leg seat. It is a top view of a leg seat. It is sectional drawing of a leg seat. It is sectional drawing of a leg seat. It is a figure which shows the relationship between the grounding part of a leg seat and a hole.

Hereinafter, a leg seat and a work table according to the present embodiment will be described with reference to the drawings.
First, the portable workbench 1 as a workbench according to the present embodiment will be described.
FIG. 1A is a perspective view of the portable worktable 1. FIG. 1B is a front view of the portable work bench 1. FIG. 1C is a plan view of the portable work table 1. In the front view shown in FIG. 1B, the left-right direction is referred to as the width direction, the center side in the width direction is referred to as the inside, and the right side and the left side from the center are referred to as the outside. Moreover, as shown to FIG. 1C, let the side which approaches a dashed-dotted line be a front side, and let the side away from a dashed-dotted line be a back side. 1C is a center line in the length of the portable workbench 1 in the front-rear direction.

The portable work table 1 includes a top plate 10, an enclosure 20, a main leg 30, a stay 50, and a leg seat 100.
The top plate 10 serves as a scaffold when an operator works on the portable work table 1. The top plate 10 is a plate-like member and has a rectangular shape that is long in the front-rear direction when viewed from the vertical direction.

The enclosure 20 surrounds the worker so that the worker does not fall from the portable work table 1 when the worker is working on the top board 10. The enclosure 20 includes four support columns 21, a pair of long side beam members 22, and a pair of short side beam members 23. The four struts 21 are respectively erected at the four corners of the top plate 10. The pair of long-side beam members 22 are bridged between the columns 21 on the upper side of the four sides of the top plate 10. In addition, the long side crosspiece member 22 is divided into substantially the center in the longitudinal direction. The pair of short side crosspiece members 23 is bridged between the columns 21 on the upper side of the short side among the four sides of the top plate 10. The pair of short side crosspiece members 23 can be separated from the state where they are connected to the column 21, so that the operator can go back and forth between the main leg 30 and the top plate 10.
Further, the pair of long side beam members 22 and the pair of short side beam members 23 can be folded so as to be in a state along the support column 21. Further, the support column 21 can be folded so as to be in a state along the main leg 30.

The main leg 30 supports the top plate 10 in a horizontal state. The main leg 30 has a first main leg 31 and a second main leg 32. The first main leg 31 and the second main leg 32 have the same configuration, and the first main leg 31 will be described here.
The first main leg 31 includes a leg portion 33 a, a leg portion 33 b, and a plurality of crosspiece members 36.
As shown in FIG. 1B, the leg portion 33 a and the leg portion 33 b are symmetric with respect to a center line Lc that is the center in the width direction of the portable worktable 1. Each of the leg portions 33a and 33b is a bar-like member having an upper portion connected to a corner portion of the top plate 10 and a lower portion extending to the floor surface (grounding surface) of the portable work table 1. The leg portions 33a and 33b are arranged with respect to the floor surface so that the distance from each other increases from the top plate 10 toward the floor surface of the portable work table 1.

  Each of the leg portion 33a and the leg portion 33b includes a support leg 34 and an extendable leg 35. The support leg 34 is a rod-like member that forms the upper part of the leg 33 and is hollow. The upper end of the support leg 34 is connected to the top plate 10. The telescopic legs 35 are rod-shaped members that extend downward along the support leg 34 from the lower end of the support leg 34. The upper part of the telescopic leg 35 is fitted into the support leg 34. The length of the telescopic legs 35 fitted into the support legs 34 can be adjusted. By adjusting the length of the extendable legs 35 that enter the support legs 34, the entire length of the legs 33a and 33b can be adjusted. The length can be adjusted. In FIG. 1B and FIG. 1C, it is locked by the lock member 37 in the state which adjusted the expansion-contraction leg 35 so that it might become the longest.

The crosspiece member 36 is bridged between the leg portion 33a and the leg portion 33b. The crosspiece member 36 is a rod-shaped member and improves the strength of the first main leg 31. Further, the crosspiece member 36 serves as a stepping crosspiece when the operator moves up and down the top plate 10. The crosspiece member 36 is fixed to the leg portion 33a and the leg portion 33b with a space in the vertical direction so that the operator can easily move up and down.
The stay 50 connects the top plate 10 and the first main leg 31, and the top plate 10 and the second main leg 32. The stay 50 reinforces the portable work table 1 by setting the angle between the top plate 10 and the first main leg 31 and the angle between the top plate 10 and the second main leg 32 to predetermined angles.

The first main leg 31 and the second main leg 32 can be folded. The second main leg 32 is rotated around the connecting portion between the second main leg 32 and the top plate 10 so that the crosspiece member 36 of the second main leg 32 approaches the lower surface of the top plate 10. Further, the first main leg 31 is rotated around the connecting portion between the first main leg 31 and the top plate 10 so that the crosspiece member 36 of the first main leg 31 approaches the lower surface of the top plate 10. . Thus, the first main leg 31 and the second main leg 32 are folded, and the operator can easily transport the portable work table 1.
The top plate 10, the first main leg 31, the second main leg 32 and the stay 50 are mainly formed of a metal material such as an aluminum alloy. Further, a member that requires strength in the enclosure 20 is formed of a metal material such as an aluminum alloy, and a member that does not require strength is formed of a synthetic resin.

The leg seats 100 are attached to the lower ends of the leg portions 33a and 33b of the first main leg 31 and the lower ends of the leg portions 33a and 33b of the second main leg 32, respectively. The leg seat 100 is sized so that the portable worktable 1 does not slide with respect to the floor surface and can be inserted into a hole having a predetermined diameter (inner diameter) or more formed on the floor surface.
The leg seat 100 of this embodiment includes two types of leg seats 100a and 100b. The leg seat 100 a is attached to the respective leg portions 33 a of the first main leg 31 and the second main leg 32. The leg seat 100 b is attached to each leg portion 33 b of the first main leg 31 and the second main leg 32. The leg seats 100a and 100b are made of a flexible material such as soft vinyl chloride. However, the leg seats 100a and 100b may be formed of other materials such as synthetic rubber and synthetic resin. The leg seat 100a and the leg seat 100b are symmetrical with respect to the center line Lc shown in FIG. 1B.

Next, the leg seat 100a will be described with reference to FIGS. 2A to 2F.
FIG. 2A is a side view of the leg seat 100a, as viewed from the A direction (inner side) shown in FIG. 1B. FIG. 2B is an enlarged view of a part of FIG. 2A. FIG. 2C is a bottom view of the leg seat 100a. FIG. 2D is a rear view of the leg seat 100a and is a view seen from the direction B of FIG. 2A. FIG. 2E is a plan view of the leg seat 100a. FIG. 2F is a plan view of the leg seat 100a viewed from the direction in which the leg portion 33a (extensible leg 35) is inserted. 2G is a cross-sectional view cut in the vertical direction so as to pass through the point C-C ′ in FIG. 2F. 2H is a cross-sectional view cut in the vertical direction so as to pass through the point E-E ′ in FIG. 2F.

The leg seat 100 a includes a mounting part 110, a grounding part 130, and a rib part 150.
First, the attachment part 110 will be described.
The attachment part 110 is a part for attaching the leg seat 100a to the leg part 33a. The attachment part 110 has a substantially block shape extending upward from the grounding part 130. Specifically, the attachment portion 110 is formed in a cylindrical shape having an upper side opened, and the lower side is closed by the grounding portion 130. As shown in FIG. 2A, when viewed from the inside, the attachment portion 110 is inclined so as to be inclined forward as it goes upward. That is, the attachment part 110 extends from the grounding part 130 in the direction of the arrow D1. Moreover, as shown to FIG. 2D, the attaching part 110 inclines so that it may incline inside as it becomes an upper side. That is, the attachment part 110 extends from the grounding part 130 in the direction of the arrow D2.

  The attachment part 110 has a front side wall 111, a rear side wall 112, an inner side wall 113, an outer side wall 114, and a bottom part 115. A space surrounded by the front side wall 111, the rear side wall 112, the inner side wall 113, and the outer side wall 114 is a mounting space 116 into which the telescopic legs 35 of the leg portion 33a are inserted.

  As shown in FIG. 2F, the front side wall 111 and the rear side wall 112 face each other with the mounting space 116 therebetween, and are parallel to each other. The front side wall 111 and the rear side wall 112 have a protrusion 117 that protrudes in a direction in which the approximate center in the width direction approaches each other toward the mounting space 116 side. The inner wall 113 and the outer wall 114 are opposed to each other with the mounting space 116 interposed therebetween, and are parallel to each other. Further, the distance between the front side wall 111 and the rear side wall 112 is longer than the distance between the inner side wall 113 and the outer side wall 114. Therefore, the attachment part 110 is formed longer in the front-rear direction along the horizontal direction than in the width direction along the horizontal direction. Further, the inner wall 113 and the outer wall 114 are each formed with an insertion hole 118 in the width direction. By inserting a bolt (not shown) through the expansion / contraction leg 35 inserted into the insertion hole 118 and the attachment space 116, the expansion / contraction leg 35 is fixed to the attachment portion 110 via the bolt.

Here, the telescopic legs 35 inserted into the mounting space 116 will be described.
In FIG. 2F, the cross-sectional shape of the extendable leg 35 is shown in gray. The telescopic leg 35 has a cylindrical shape in which the cross section shown in FIG. 2F is continuous along the extending direction of the telescopic leg 35. The extendable legs 35 are formed by extruding an aluminum alloy, for example, and are formed by cutting in a direction substantially orthogonal to the extending direction of the extendable legs 35.
As shown in FIG. 2F, the cross-sectional shape of the telescopic legs 35 is a shape obtained by substantially reducing the shape of the mounting portion 110 including the front side wall 111, the rear side wall 112, the inner side wall 113, and the outer side wall 114. The telescopic legs 35 are fitted into the mounting space 116 of the mounting portion 110 without backlash. The telescopic legs 35 have a front side plate 38, a rear side plate 39, an inner side plate 40, and an outer side plate 41. The front side plate 38 and the rear side plate 39 face each other, and the inner side plate 40 and the outer side plate 41 face each other. The front side plate 38 and the rear side plate 39 are each recessed so that the approximate center in the width direction matches the shape of the protruding portion 117 of the mounting portion 110. Therefore, in the state in which the telescopic legs 35 are inserted into the mounting space 116, the extending direction of the telescopic legs 35 coincides with the extending direction of the mounting portion 110 (arrow D1 in FIG. 2A and arrow D2 in FIG. 2D).

Returning to the description of the mounting portion 110, the bottom portion 115 supports the telescopic leg 35 by the lower end of the telescopic leg 35 coming into contact therewith. The bottom portion 115 is a surface substantially orthogonal to the extending direction of the mounting portion 110 or the extending direction of the telescopic legs 35. The bottom portion 115 is formed from the front side wall 111 to the rear side wall 112 on the mounting space 116 side of the inner side wall 113, and is formed from the front side wall 111 to the rear side wall 112 on the mounting space 116 side of the outer side wall 114. Is done. On the other hand, the bottom 115 is not formed on the mounting space 116 side of the protruding portion 117 of the front side wall 111 and on the mounting space 116 side of the protruding portion 117 of the rear side wall 112. That is, the bottom part 115 is divided into right and left, and a concave part 119 is formed in the center as a lightening part that is recessed toward the grounding part 130 side (lower side).
The bottom 115 on the inner wall 113 side supports the lower end on the inner plate 40 side of the extendable legs 35, and the bottom 115 on the outer wall 114 side supports the lower end on the outer plate 41 side of the extendable legs 35.

Next, the grounding unit 130 will be described.
The grounding unit 130 is a part for grounding the leg seat 100a to the floor surface. The grounding part 130 is located below the attachment part 110 and is formed integrally with the attachment part 110.
The ground contact portion 130 of the present embodiment is formed in a size that cannot be inserted into a hole of a sleeve opened on the floor surface of the work site. A plurality of types of sizes are prepared for the sleeve according to the size and number of pipes and wires to be inserted. As a sleeve generally used for penetrating a floor of a building work, there are types such as diameters (inner diameters) of 50 mm, 75 mm, 90 mm, 100 mm, 125 mm, 150 mm, and 175 mm. When such a type of sleeve hole exists on the floor surface, it is assumed that the operator places the leg seat 100a on the sleeve hole without noticing the sleeve.

Therefore, the ground contact portion 130 of the leg seat 100a of the present embodiment is set to a size that cannot be inserted into the hole of the sleeve.
Specifically, the grounding portion 130 has a size that cannot be inserted into a hole having a diameter of 75 mm or more. Here, the diameter of 75 mm or more is defined as a hole having a diameter of 75 mm is relatively large. For example, in a conventional leg seat, the hole may be inserted into the hole.
Furthermore, it is preferable that the grounding portion 130 has a diameter of 75 mm or more and cannot be inserted into a hole having a diameter of 150 mm or less. Here, the reason why the hole is defined as a hole having a diameter of 150 mm or less is that a hole larger than the hole having a diameter of 150 mm is a size that is easily noticed by the operator in the first place.
Furthermore, it is preferable that the grounding portion 130 has a diameter of 75 mm or more and cannot be inserted into a hole having a diameter of 100 mm or less. Here, the reason why the hole is defined as a hole having a diameter of 100 mm or less is that it is often determined that a lid is installed in a hole having a diameter larger than 100 mm at the work site.
As described above, since the grounding portion 130 has a size that cannot be inserted into the hole having a predetermined diameter, even if the grounding portion 130 of the leg seat 100a is disposed on the hole, the grounding portion 130 is not inserted into the hole. Since the floor is grounded around the hole, the portable worktable 1 can be stably grounded.

Hereinafter, the grounding unit 130 will be specifically described.
The grounding portion 130 has a flat block shape located below the attachment portion 110. The grounding portion 130 is formed to extend in the front-rear direction and the width direction below the attachment portion 110. The grounding portion 130 of the present embodiment is formed in a substantially rectangular shape, and has a front end surface 131, a rear end surface 132, an inner end surface 133, an outer end surface 134, a surface portion 135, and a back surface portion 136. As shown in FIG. 2A, the front end surface 131 and the rear end surface 132 are surfaces that incline toward the front side toward the upper side, and are substantially parallel to each other. Further, as shown in FIG. 2D, the inner end surface 133 and the outer end surface 134 are surfaces that incline so as to incline toward the upper side, and are substantially parallel to each other. In addition, a curved surface is formed at a corner that is a boundary between the front end surface 131, the rear end surface 132, the inner end surface 133, and the outer end surface 134. Further, the surface portion 135 is a flat surface, and inclines upward as it goes outward, and inclines upward as it goes rearward. Therefore, the corner portion between the rear end surface 132 and the outer end surface 134 of the surface portion 135 is positioned on the uppermost side.
Further, the distance between the inner end surface 133 and the outer end surface 134 is longer than the distance between the front end surface 131 and the rear end surface 132. Therefore, the grounding portion 130 is formed longer in the width direction along the horizontal direction than in the front-rear direction along the horizontal direction.

Further, the back surface portion 136 is a portion that contacts the floor surface and has a plurality of protrusions 137.
The protrusion 137 is formed so that the force for moving the leg seat 100a to the front side in the horizontal direction is smaller than the force for moving the leg seat 100a to the rear side in the state of being grounded to the floor surface.
As shown in FIG. 2A, the protrusion 137 is formed to extend obliquely rearward toward the tip, that is, downward and rearward. The cross section of the lower end of the protrusion 137 has a semicircular shape. A plurality of (for example, ten) protrusions 137 are arranged from the front end surface 131 to the rear end surface 132.

The cross-sectional shape of the protrusion 137 is substantially the same at any position. Therefore, the cross-sectional shape of the protrusion 137 will be described with reference to the side surface of the protrusion 137 shown in FIG. 2B.
The protrusion 137 is formed to extend obliquely rearward. The protrusion 137 extending obliquely rearward means that the center line Ln of the protrusion 137 extends obliquely rearward. The center line Ln is an arbitrary point at the end of the front surface 138a of the projection 137 and the rear surface of the projection 137 at the same height as the sectional view of the projection 137. It is a line made up of an intermediate point between the point 138b.

  As shown in FIG. 2C, when the grounding portion 130 is viewed from the back side, the protrusion 137 is formed from the inner end surface 133 to the outer end surface 134 of the grounding portion 130. Here, the front side and the center side (eight projecting parts 137 from the front side) of the projecting parts 137 are formed so as to pass through three arcs protruding rearward from the inner end face 133 to the outer end face 134. Is done. Further, a drain hole 139 is formed at a position of the protrusion 137 that is biased inward and forward. The drain hole 139 communicates with the concave portion 119 of the mounting portion 110 and discharges the water accumulated in the concave portion 119 to the outside. Further, the rear side (two protrusions 137 from the rear side) of the protrusions 137 is linear from the inner end surface 133 to the outer end surface 134. Between the linear protrusions 137, a recess 140 is formed as a hollow portion that is recessed upward.

Next, the relationship between the size of the grounding portion 130 and the hole of the sleeve will be described.
FIG. 3 is a cross-sectional view taken along the line I-I in FIG. 2A, and is a view of the grounding portion 130 of the leg seat 100a as viewed from the vertical direction with respect to the floor surface. Further, a circle 200 shown by a two-dot chain line in FIG. 3 indicates a hole having a diameter of 75 mm or more of the sleeve described above.
As shown in FIG. 3, when the grounding unit 130 is viewed from the vertical direction, the grounding unit 130 overlaps the circle 200. Here, the ground contact portion 130 can completely cover and close the circle 200 without a gap without protruding from the circle 200. In the ground contact portion 130, the longest distance L1 of the distance between the front end surface 131 and the rear end surface 132 (horizontal and front-rear direction distance) when viewed from the vertical direction is larger than the diameter (hole diameter) of the circle 200. Is also set to be long. Further, the grounding portion 130 has a longest distance L2 among the distances (the distances in the horizontal direction and the width direction) between the inner end surface 133 and the outer end surface 134 when viewed from the vertical direction. ) Is set to be longer. The grounding portion 130 has the longest distance L3 among the distances (horizontal distances) between the corners of the front end surface 131 and the outer end surface 134 and the corners of the rear end surface 132 and the inner end surface 133. It is set to be longer than the diameter of the circle 200 (the diameter of the hole). Further, the grounding unit 130 has the longest distance L4 among the distances (horizontal distances) between the corners of the front end surface 131 and the inner end surface 133 and the corners of the rear end surface 132 and the outer end surface 134. It is set to be longer than the diameter of the circle 200 (the diameter of the hole).

  Note that the longer distance Lh of the distance L3 and the distance L4 corresponds to the longest distance in the horizontal direction in the ground contact portion 130. Therefore, by setting the distance Lh to be larger than at least 75 mm, the ground contact portion 130 is not inserted into a hole having a diameter of 75 mm or more. If the distance Lh is too large, the volume of the ground contact portion 130 increases and the manufacturing cost increases, so the distance Lh can be set to 200 mm or less, and further to 150 mm or less.

Next, the relationship between the attaching part 110 and the grounding part 130 is demonstrated.
In the leg seat 100a of the present embodiment, the grounding portion 130 is positioned outwardly in the horizontal direction with respect to the mounting portion 110 when viewed from the vertical direction. In other words, the mounting part 110 is located inwardly in the horizontal direction with respect to the grounding part 130.
Here, with reference to FIG. 2H and FIG. 2G, the state in which the grounding portion 130 is biased with respect to the mounting portion 110 will be compared with reference to the telescopic legs 35 fixed in the mounting space 116.
First, as shown in FIG. 2H, the longest distance among the distances from the lower end of the inner plate 40 of the extendable leg 35 to the inner end surface 133 that extends in the horizontal direction and the width direction is defined as Lin. Further, the longest distance among the distances from the lower end of the outer plate 41 of the telescopic legs 35 to the outer end surface 134 that extends in the horizontal direction and the width direction is Lout. At this time, the distance Lin is shorter than the distance Lout. Here, the ratio between the distance Lout and the distance Lin is, for example, 0.2 to 0.8: 1. In this way, the grounding portion 130 is located on the outer side with respect to the mounting portion 110.
The fact that the grounding part 130 is located in the horizontal direction with respect to the mounting part 110 means that when the leg seat 100a is attached to the telescopic legs 35 of the portable worktable 1, the grounding part 130 of the leg seat 100a is attached. It means projecting outward from the telescopic legs 35.

  Further, as shown in FIG. 2G, the longest distance among the distances from the lower end of the front side plate 38 of the extendable leg 35 to the front end face 131 in the horizontal direction and the front-rear direction is Lf. Further, the longest distance among the distances from the lower end of the rear plate 39 of the telescopic leg 35 to the rear end surface 132 in the horizontal direction and the front-rear direction is defined as Lr. At this time, the ratio of the distance Lf to the distance Lr is, for example, 2 to 4: 3. The distance Lin and the distance Lf are substantially the same. Furthermore, the distance Lf and the distance Lr are shorter than the distance Lout. As described above, the grounding portion 130 is positioned so as not to be biased forward or rearward with respect to the mounting portion 110.

Next, the rib part 150 will be described.
The rib part 150 is a part which improves the intensity | strength of the leg seat 100a. The rib part 150 includes a plurality of ribs 151. The ribs 151 are plate-shaped, and the adjacent ribs 151 are arranged with a space therebetween. The rib 151 connects the outer peripheral surface of the mounting part 110 and the surface part 135 of the grounding part 130. Specifically, the rib 151 coupled to the front side wall 111 of the mounting part 110 extends toward the front side, and the rib 151 coupled to the rear side wall 112 of the mounting part 110 extends toward the rear side. The rib 151 coupled to the inner wall 113 of the mounting portion 110 is in the width direction and extends toward the inner end surface 133 side, and the rib 151 coupled to the outer wall 114 of the mounting portion 110 is in the width direction and is outer. It extends toward the end face 134 side. Here, as described above, since the distance Lout is longer than other distances, the rib 151 that couples the outer wall 114 of the mounting portion 110 and the surface portion 135 of the grounding portion 130 is smaller than the other ribs. Largely formed.

  The leg seat 100a is configured as described above. Since the leg seat 100b has a symmetrical shape with respect to the center line Lc, the description thereof is omitted. However, the leg seat 100b is not necessarily limited to being symmetrical, and can be appropriately changed so that the function of the leg seat 100b of the present embodiment can be exhibited.

Next, an operation when the leg seat 100a is attached to the portable work table 1 will be described.
The operator attaches the leg seat 100a and the leg seat 100b having the grounding portion 130 having a size that cannot be inserted into the hole having a diameter of 75 mm or more, to each of the telescopic legs 35 of the portable work table 1. Therefore, even when the operator places either of the leg portions 33a and 33b of the portable worktable 1 over a hole having a diameter of 75 mm or more, the leg seat 100a and the leg seat 100b are inserted into the hole. Can be prevented. Specifically, since the leg seat 100a or the leg seat 100b contacts the floor surface around the hole so as to block the hole, the portable work table 1 can be stably grounded.

  Further, as described above, since the grounding portion 130 is located to be offset outward in the horizontal direction with respect to the mounting portion 110, the grounding portion 130 of the leg seat 100a has the telescopic legs 35 as shown in FIGS. 1B and 1C. Project outside. The grounding portion 130 projecting outward supports the portable workbench 1 so that the portable workbench 1 does not fall down in the width direction when an external force is applied in the width direction. That is, when the grounding part 130 is formed in a size that cannot be inserted into a hole having a predetermined diameter, the grounding part 130 is projected outward from the telescopic legs 35 to prevent the portable worktable 1 from falling over. Can be achieved.

  Further, the grounding portion 130 does not project to the front side and the rear side compared to the projecting to the outside with respect to the mounting portion 110. Thus, by preventing the grounding part 130 from projecting to the front side and the rear side, it is possible to prevent the grounding part 130 from becoming unnecessarily large, and the manufacturing cost can be reduced. In particular, since the grounding portion 130 does not protrude to the front side, the grounding portion 130 can be easily brought close to the work wall when the portable worktable 1 is moved in the front-rear direction, and work around the work wall is easily performed. be able to. Further, when transporting the portable worktable 1 easily, casters may be attached to the front side or the rear side of the leg seats 100a, 100b, and by preventing the grounding part 130 from protruding to the front side and the rear side, A caster can be easily attached.

As mentioned above, although this invention was demonstrated by embodiment mentioned above, this invention is not limited only to embodiment mentioned above, A change etc. are possible within the scope of the present invention.
In the present embodiment, the portable workbench 1 has been described as a workbench, but the present invention is not limited to this, and may be applied to a stepladder workbench. Even when applied to a stepladder-type work table, the configuration of the first main leg 31 or the second main leg 32 can be applied.
Moreover, although this embodiment demonstrated the case where the leg seats 100a and 100b were attached to the expansion-contraction leg 35, it is not restricted to this case. For example, in the case of the leg portions 33a and 33b not provided with the telescopic legs 35, the leg seats 100a and 100b may be directly attached to the support leg 34.

  1: Portable work table 33a, 33b: Leg 34: Strut leg 35: Telescopic leg 100 (100a, 100b): Leg seat 110: Mounting part 130: Grounding part 150: Rib part

Claims (8)

A pedestal that is attached to the leg of the workbench and contacts the floor,
The pedestal is
A leg seat having a grounding portion formed on the floor and having a size that cannot be inserted into a hole having a diameter of 75 mm or more. The grounding part is
The leg seat according to claim 1, wherein the leg seat has a size that is not less than 75 mm and cannot be inserted into a hole having a diameter of 150 mm or less. The grounding part is
The leg seat according to claim 1 or 2, wherein the leg seat has a size that is not less than 75 mm and cannot be inserted into a hole having a diameter of 100 mm or less. When the leg seat is viewed from the vertical direction in a state where the grounding portion is grounded to the floor surface,
The grounding part is
The leg seat according to any one of claims 1 to 3, wherein the hole has a shape that closes the hole without a gap. The grounding part is
The leg seat according to any one of claims 1 to 4, wherein the longest length in the horizontal direction is larger than the diameter of the hole. The pedestal is
Having an attachment part attached to a leg part of the work table;
The leg seat according to any one of claims 1 to 5, wherein the attachment portion is located above the grounding portion. In a state where the grounding portion is grounded to the floor surface,
The mounting portion is
The length in the front-rear direction is longer than the length in the width direction along the horizontal direction,
The grounding part is
The leg seat according to claim 6, wherein the length in the width direction is longer than the length in the front-rear direction along the horizontal direction. A workbench with a leg seat attached to the leg and grounded to the floor,
The pedestal is
A workbench having a grounding portion formed on the floor and having a size that cannot be inserted into a hole having a diameter of 75 mm or more.