JP3238732U - Support leg for single pipe barricade - Google Patents

Abstract

[Problem] To provide a supporting leg for a single-tube barricade, which can increase the area of the leg surface and the leg back surface of a script body. SOLUTION: The present invention comprises a script body 1, a first clamp K1 and a second clamp K2. The leg body 1 has a recessed groove portion 15, and the recessed groove B15 is formed with a groove depth WA from the leg contact surface 10 of the leg body 1 in the leg length direction B of the leg body 1. The concave groove portion 15 is formed between the first and second leg side surfaces 7 and 8 of the leg body 1 in the leg width direction A of the leg body 1 . The concave groove portion 15 penetrates the leg body 1 in the leg thickness direction C of the leg body 1 . The first clamp K1 is fixed to the legwork 1 by bringing the first clamp body 57 into contact with the upper leg surface 9 of the legwork 1 . The second clamp K2 is arranged in the recessed groove portion 15, and is fixed to the leg body 1 by bringing the second clamp body 77 into contact with the groove bottom surface 21. As shown in FIG. [Selection diagram] Fig. 1

Description

There is an application for exception to loss of novelty

TECHNICAL FIELD The present invention relates to a single-pipe barricade support leg that constitutes a single-pipe barricade.

Patent Document 1 discloses a stand for a barricade as a technique for supporting legs for a single-pipe barricade. The stand consists of a stand main body, a pair of legs formed between the side surfaces of the legs of the stand main body and the concave groove, a middle opening formed between the stand upper surface of the stand main body and the concave groove, and placed on the upper surface of the stand. a clamp fixed to the stand main body, and a clamp arranged in the middle opening and fixed to the stand main body.

Japanese Patent No. 6844795

In Patent Document 1, since the clamp is placed in the middle opening formed between the upper surface of the leg and the concave groove portion and fixed to the stand main body, the surface area of the stand surface or the stand back surface of the stand main body is reduced. The display board must be placed on the surface of the stand, and there is a risk that the occupants of the vehicle running may not be able to recognize the information on the display board.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a support leg for a single-tube barricade, which can increase the area of the leg surface and the leg back surface of the leg body.

Claim 1 according to the present invention is a support leg for a single pipe barricade which is erected on an installation surface to constitute a single pipe barricade and supports the pipe end of the single pipe, wherein the leg width direction, the leg length direction and the A first leg side surface and a second leg side surface facing in the leg width direction, a leg upper surface and a leg contact surface facing in the leg length direction, and a leg contact surface facing in the leg thickness direction. It has a leg surface and a leg back surface, and is rotatably attached to a leg body erected on the installation surface with the leg contact surface in contact with the installation surface, a first clamp body, and the first clamp body. A single tube is inserted into a first tube insertion hole formed between the first clamp body and the first clamp opening and closing part, and the first clamp body and the first It has a first clamp that grips the single pipe at the clamp opening/closing part, a second clamp body, and a second clamp opening/closing part that is rotatably attached to the second clamp body, and the second clamp body and the second clamp body. a second clamp for inserting a single pipe into a second pipe insertion hole formed by two clamp opening/closing parts and holding the single pipe with the second clamp main body and the second clamp opening/closing part; The main body has a concave groove, and the concave groove is spaced apart on the first leg side surface and on the second leg side surface in the leg width direction so as to form the first leg side surface and the second leg side surface. It is formed between the second leg side surfaces, has a second concave groove depth from the leg contact surface toward the leg upper surface in the leg length direction, is opened to the leg contact surface, and is opened in the leg thickness direction. wherein the leg surface and the leg back surface are opened through the leg body, the first clamp is fixed to the leg body by bringing the first clamp body into contact with the leg upper surface, and 2 clamp is a supporting leg for a single pipe barricade, characterized in that it is arranged in the concave groove, and the second clamp body is fixed to the base by abutting the groove surface of the concave groove.

According to the present invention, the second clamp is arranged in the concave groove, and the first clamp body is fixed to the leg body by contacting the groove surface of the concave groove. It is possible to increase the area of the back side), and it is possible to place a large area display board or display sheet (display board or display sheet that displays visual information) on the leg surface and attach it to the script body. becomes.
As a result, even the occupants of the running vehicle can visually recognize the information on the display plate and the display sheet.

It is a front view (surface view) which shows the support leg for single pipe barricades. It is a rear view (rear view) which shows the support leg for single pipe barricades. It is a top view (top view) which shows the support leg for single pipe barricades. It is a bottom view (bottom view) which shows the support leg for single pipe barricades. It is a left view which shows the support leg for single pipe barricades. It is a right view which shows the support leg for single pipe barricades. FIG. 4 is a cross-sectional view taken along the line AA of FIG. 3; (a) is an enlarged view of part B of FIG. 5, and (b) is an enlarged view of part C of FIG. (a) is an enlarged view of part D of FIG. 6, and (b) is an enlarged view of part E of FIG. (a) is an enlarged view of part F of FIG. 7, and (b) is an enlarged view of part G of FIG. (a) is an enlarged view of part H of FIG. 7, and (b) is an enlarged view of part I of FIG. (a) is an enlarged view of J part of FIG. 7, and (b) is an enlarged view of K part of FIG. Fig. 10 is a plan view (top view) in which a plurality of support legs for a single-tube barricade are connected; FIG. 14 is a cross-sectional view taken along line LL of FIG. 13; (a) is an enlarged view of the M part of FIG. 14, and (b) is an enlarged view of the N part of FIG. It is a side view which shows a single pipe barricade. (a) is a plan view (top view) showing the single-pipe barricade, and (b) is a bottom view (bottom view) showing the single-pipe barricade. It is a front view which shows a single pipe barricade. It is a top view (top view) which shows a single pipe|tube barricade apparatus. It is a bottom view (bottom view) which shows a single pipe|tube barricade apparatus. It is a front view which shows a single pipe|tube barricade apparatus.

A support leg for a single-pipe barricade according to the present invention will be described with reference to FIGS. 1 to 21. FIG.

1 to 21, the single-tube barricade support leg X includes a leg body 1, a plurality (two) of cylindrical portions M1 and M2, a first clamp K1, and a second clamp K2.

The script body 1 is made of synthetic resin. The leg body 1 is formed in a hollow three-dimensional shape having, for example, a leg width direction A, a leg length direction B, and a leg thickness direction C, as shown in FIGS. 1 to 7 .
The leg body 1 is formed into a hollow rectangular parallelepiped having a leg width H in the leg width direction A, a leg length L in the leg length direction B, and a leg thickness W in the leg thickness direction C. The script body 1 is formed into a hollow rectangular parallelepiped, for example, by blow molding.
The leg length direction B is a direction orthogonal to the leg width direction A. The leg thickness direction C is a direction orthogonal to the leg width direction A and the leg length direction B.
Further, the leg body 1 is not limited to a hollow three-dimensional shape, and may have a three-dimensional shape having a leg width direction, a leg length direction, and a leg thickness direction.

The leg body 1 has a leg surface 5 (leg surface plane) and a leg back surface 6 facing each other in the leg thickness direction C, as shown in FIGS. 1 to 6 . The leg surface 5 and the leg back surface 6 are arranged in parallel in the leg thickness direction C with the leg thickness W on the leg surface 5 and the leg back surface 6 .

The script body 1 has a first leg side surface 7 and a second leg side surface 8 facing each other in the leg width direction A, as shown in FIGS. 1 to 6 . The first and second leg side surfaces 7, 8 are arranged in parallel in the leg width direction A with a leg width H between the first and second leg side surfaces 7, 8. The first and second leg side surfaces 7 and 8 are arranged between the leg surface 5 and the leg back surface 6 perpendicular to the leg width direction A (leg thickness direction C). The first and second leg sides 7 , 8 are arranged perpendicular to the leg surface 5 and the leg back surface 6 .

The leg body 1 has a leg upper surface 9 and a leg contact surface 10 (leg bottom surface) facing each other in the leg length direction B, as shown in FIGS. The leg upper surface 9 (leg top surface) and the leg contact surface 10 are arranged in parallel with each other in the leg length direction B with the leg length L between the leg upper surface 9 and the leg contact surface 10 . A leg upper surface 9 and a leg contact surface 10 are arranged perpendicular to the leg length direction B and between the leg surface 5 and the leg back surface 6 .

The script body 1 has a concave groove portion 15, a first leg portion 16 and a second leg portion 17, as shown in FIGS.

As shown in FIGS. 1, 2 and 7, the recessed grooves 15 are spaced apart by a leg width interval δ on the first leg side surface 7 and on the second leg side surface 8 by a leg width interval δ in the leg width direction A. is formed between the first and second leg sides 7,8. The recessed groove portion 15 has a recessed groove depth WA from the leg ground surface 10 (leg bottom surface) in the leg length direction B and is opened to the leg ground surface 10 (leg bottom surface). The recessed groove portion 15 has a recessed groove width HA in the leg width direction A. The concave groove portion 15 penetrates the leg body 1 in the leg thickness direction C and is opened on the leg surface 5 and the leg back surface 6 . The concave groove portion 15 has groove surfaces 18 in the leg width direction A and the leg length direction B. As shown in FIG.
The groove surface 18 has a pair of groove side surfaces 19 and 20 facing each other in the leg width direction A and a groove bottom surface 21 in the leg length direction B (groove depth). The groove side surfaces 19 and 20 are arranged in parallel in the leg width direction A with a groove width HA between the groove side surfaces 19 and 20 . The groove bottom surface 21 is arranged with a groove depth WA in the leg length direction B from the leg contact surface 10 (leg bottom surface). A groove bottom surface 21 is formed perpendicular to each groove side surface 19 , 20 . The groove bottom surface 21 is arranged parallel to the leg upper surface 9 and the leg contact surface 10 (leg bottom surface).

The first leg portion 16 is formed between the first leg side surface 7 and the recessed groove portion 15 in the leg width direction A, as shown in FIGS. The first leg 16 has a leg width δ (leg width interval) in the leg width direction and a leg thickness W (leg thickness) in the leg thickness direction C. As shown in FIG. The first leg portion 16 has a leg length WA (groove depth) in the leg length direction B and protrudes from the groove bottom surface 21 of the groove portion 15 .

The second leg portion 17 is formed between the second leg side surface 8 and the recessed groove portion 15 in the leg width direction A, as shown in FIGS. The second leg 17 has a leg width δ (leg width interval) in the leg width direction A and a leg thickness W (leg thickness) in the leg thickness direction C. As shown in FIG. The second leg portion 17 has a leg length WA (groove depth) in the leg length direction B and protrudes from the groove bottom surface 21 of the groove portion 15 .

The leg body 1 has a first leg hole 25 and a second leg hole 26, as shown in FIGS. The first and second leg holes 25 and 26 are formed in a rectangular shape (rectangular hole).
The first and second leg holes 25 and 26 are arranged between the recessed groove portion 15 (groove bottom surface 21) and the leg upper surface 9 in the leg length direction B. As shown in FIG.

As shown in FIGS. 1, 2 and 7, the first leg holes 25 are arranged on the leg upper surface 9 with a hole interval ε in the leg length direction B. As shown in FIG. The first leg hole 25 is formed in the leg body 1 with a leg hole length LX in the leg width direction A and a leg hole width HX in the leg length direction B.
The first leg hole 25 is arranged parallel to the leg upper surface 9 with one hole side surface 25A in the leg length direction B (the lateral direction of the first leg hole) located on the leg upper surface 9 side. One hole side surface 25A is arranged on the leg upper surface 9 with a hole interval ε in the leg length direction B. As shown in FIG. The first leg holes 25 pass through the leg body 1 in the leg thickness direction C and are opened in the leg surface 5 and the leg back surface 6 .

As shown in FIGS. 1, 2 and 7, the second leg holes 26 are arranged on the groove bottom surface 21 of the recessed groove portion 15 with a hole interval ε in the leg length direction B. As shown in FIG. The second leg hole 26 is formed in the leg body 1 with a leg hole length LX in the leg width direction A and a leg hole width HX in the leg length direction B.
The second leg hole 26 is arranged parallel to the groove bottom surface 21 (leg contact surface 10) with one hole side surface 26A in the leg length direction B (lateral direction of the second leg hole) located on the groove bottom surface 21 side. be done. One hole side surface 26A is arranged on the groove bottom surface 21 with a hole interval ε in the leg length direction B. As shown in FIG. The second leg hole 26 is opened in the leg surface 5 and the leg back surface 6 through the leg body 1 in the leg thickness direction C. As shown in FIG.

As shown in FIGS. 1 to 11, the script body 1 has a first connecting convex portion α, a second connecting convex portion β, a third connecting convex portion γ, and a fourth connecting convex portion σ.

As shown in FIGS. 1, 2, and 7, the first connecting projection α is arranged on the first leg side surface 7 with a gap on the leg upper surface 9 in the leg length direction B. As shown in FIGS. As shown in FIGS. 5, 8A, and 10A, the first connecting protrusion α has a protrusion width Hp in the leg width direction A and a protrusion length Lp in the leg length direction B. and a hollow shape having a convex thickness Wp in the leg thickness direction C, and protrudes in the leg width direction A from the first leg side surface 7 . The first connecting projection α is formed integrally with the first leg side surface 7 and fixed to the first leg side surface 7 .

As shown in FIGS. 1, 2 and 7, the second connecting protrusion β is arranged on the first leg side surface 7 with a gap from the leg contact surface 10 (leg bottom surface) in the leg length direction B. As shown in FIGS. The second connecting protrusion β is disposed between the first connecting protrusion α and the leg contact surface 10 (leg bottom surface) in the leg length direction B. As shown in FIG.
The second connecting protrusion β has the same protrusion width Hp as the first connecting protrusion α in the leg width direction A, and the same protrusion length Lp as the first connecting protrusion α in the leg length direction B. and has a convex thickness Wp in the leg thickness direction C that is the same as that of the first connecting protrusion α, and protrudes in the leg width direction A from the first leg side surface 7 . The second connecting protrusion β is formed integrally with the first leg side surface 7 and fixed to the first leg side surface 7 .

As shown in FIGS. 1, 2, and 7, the third connecting projection γ is arranged on the second leg side surface 8 with a gap on the leg upper surface 9 in the leg length direction B. As shown in FIGS.
As shown in FIGS. 6, 9A, and 11A, the third connecting protrusion γ has the same protrusion width Hp as the first connecting protrusion α in the leg width direction A, and the leg length It is formed in a hollow shape having a convex length Lq in the direction B, has the same convex thickness Wp as the first connection convex portion α in the leg thickness direction C, and extends from the second leg side surface 8 in the leg width direction A protruded to The third connecting protrusion γ is formed integrally with the second leg side surface 8 and fixed to the second leg side surface 8 .

As shown in FIGS. 1, 2, and 7, the fourth connecting protrusion σ is arranged on the second leg side surface 8 with a gap from the leg contact surface 10 (leg bottom surface) in the leg length direction B. be. The fourth connecting protrusion σ is arranged in the leg length direction B between the third connecting protrusion γ and the leg contact surface 10 (leg bottom surface).
As shown in FIGS. 6, 9B, and 11B, the fourth connecting protrusion σ has the same protrusion width Hp as the first connecting protrusion α in the leg width direction A, and the leg length It is formed in a hollow shape having the same projection length Lq as the third connection projection γ in the direction B, and has the same projection thickness Wp as the first connection projection α in the leg thickness direction C, It protrudes in the leg width direction A from the second leg side surface 8 . The fourth connecting protrusion σ is formed integrally with the second leg side surface 8 and fixed to the second leg side surface 8 .

As shown in FIGS. 8(a) and 10(a), the first connecting convex portion α is provided at one convex length end α1 in the leg length direction B, on a first connecting plane αf perpendicular to the leg length direction B. have
As shown in FIG. 2, the first connecting projection α has the first connecting surface αf facing the leg ground surface 10 (bottom surface of the leg) in the leg length direction B, and the other convex length of the first connecting projection α It is arranged on the first leg side surface 7 with the upper end α2 facing the leg upper surface 9 .

As shown in FIGS. 8(a) and 10(b), the second connecting convex portion β is provided at one convex length end β1 in the leg length direction B, on a second connecting plane βf perpendicular to the leg length direction B. have
In the leg length direction B, the second connecting protrusion β has the second connecting surface βf facing the leg contact surface 10 (bottom surface of the leg), and the other convex length end β2 of the second connecting protrusion β being the first connection. It is arranged on the first leg side surface 7 toward the convex portion α.
The second connecting protrusion β is arranged in the leg length direction B between the other convex length end β2 of the second connecting protrusion β and the first connecting surface αf with a first protrusion spacing λ1.
The second connecting protrusion β is disposed between the second connecting surface βf and the first connecting surface αf in the leg length direction B with a first surface spacing λ2 therebetween.

The third connecting projection γ has a third connecting surface γf orthogonal to the leg length direction B at one convex length end γ1 in the leg length direction B, as shown in FIG.
As shown in FIGS. 1 and 2, in the leg length direction B, the third connecting protrusion γ has the third connecting surface γf facing the leg upper surface 9 and the other convex length end of the third connecting protrusion γ. It is arranged on the second leg side surface 8 with γ2 facing the leg contact surface 10 (bottom surface of the leg).
The third connecting convex portion γ is formed between the third connecting surface γf and the second connecting surface βf (the second connecting convex portion β) in the leg length direction B with a second surface interval λ3 between the first and second connecting surfaces. It is arranged between the projections α and β. The second surface spacing λ3 is narrower than the first surface spacing λ2 (slightly narrower than the first surface spacing λ2).
The third connecting surface γf is arranged with a gap (small gap) between the third connecting surface γf and the first connecting surface αf in the leg length direction B.

As shown in FIGS. 9(b) and 11(b), the fourth connecting convex portion σ is located at one convex length end σ1 in the leg length direction B and on a fourth connecting plane σf perpendicular to the leg length direction B. have
As shown in FIGS. 1 and 2, the fourth connecting projection σ has the fourth connecting surface σf directed toward the other convex length end γ2 of the third connecting projection γ in the leg length direction B, and the fourth connecting projection σ. The connecting convex portion σ is arranged on the second leg side surface 8 with the other convex length end σ2 facing the leg contact surface 10 (leg bottom surface).
As shown in FIG. 2, in the leg length direction B, the fourth connecting projection σ has a second convex spacing λA between the fourth connecting surface σf and the other convex length end γ2 of the third connecting projection γ. placed apart.
In the leg length direction B, the fourth connecting protrusion σ has a first surface spacing λ2 between the fourth connecting surface σf and the third connecting surface γf (which is the same as the spacing between the first and second connecting surfaces αf and βf). space).
The fourth connecting surface σf is arranged in the leg length direction B with a gap (small gap) between the fourth connecting surface σf and the second connecting surface βf.

The script body 1 has a first connecting shaft 31 , a second connecting shaft 32 , a first connecting hole 33 and a second connecting hole 34 .

The first and second connecting shafts 31 and 32 are formed to have circular cross-sections (circular shafts).

The first connecting shaft 31 is arranged on the first connecting protrusion α, as shown in FIGS. The first connecting shaft 31 is integrally formed with the first connecting projection α and fixed to the first connecting projection α.
The first connecting shaft 31 is fixed to the first connecting protrusion α with the axial center line ω1 of the first connecting shaft 31 directed in the leg length direction B.
The first connecting shaft 31 is disposed on the first connecting protrusion α in the leg width direction A with a protrusion width interval λ4 from the projecting end α3 of the first connecting protrusion α.
The first connecting shaft 31 is arranged in the leg width direction A between the convex width center line q of the first connecting convex portion α and the projecting end α3 of the first connecting convex portion α. The first connecting shaft 31 is arranged on the width center line s of the first leg side surface 7 in the leg thickness direction C, as shown in FIG. The first connecting shaft 31 is disposed on the first connecting protrusion α such that the shaft center line ω1 coincides (positions) with the surface width center line s of the first leg side surface 7 .

As shown in FIGS. 8A and 10A, the first connecting shaft 31 has an axial length Lk in the leg length direction B and extends from the first connecting surface αf to the second connecting protrusion β. projected towards. The axial length Lk of the first connecting shaft 31 is shorter than the convex length Lq of the third connecting convex portion γ. The first connecting shaft 31 protrudes in the leg length direction B between the first connecting surface αf and the other convex length β2 of the second connecting convex portion β.
In the second connecting convex portion β, the first convex interval λ1 is set to an interval exceeding the sum of the convex length Lq of the third connecting convex portion γ and the axial length LK of the first connecting shaft 31 [λ1> (Lq+LK)].

The second connecting shaft 32 is arranged on the second connecting protrusion β as shown in FIGS. 1, 2, 8(b) and 10(b). The second connecting shaft 32 is integrally formed with the second connecting protrusion β and fixed to the second connecting protrusion β.
The second connecting shaft 32 is fixed to the second connecting protrusion β with the axial center line ω2 of the second connecting shaft 32 directed in the leg length direction B.
The second connecting shaft 32 is arranged in the second connecting protrusion β in the leg width direction A with a protrusion width interval λ4 from the projecting end β3 of the second connecting protrusion β.
The second connecting shaft 32 is arranged in the leg width direction A between the convex width center line q of the second connecting convex portion β and the projecting end β3 of the second connecting convex portion β. As shown in FIG. 3, the second connecting shaft 32 is arranged on the width center line s of the first leg side surface 7 in the leg thickness direction C. As shown in FIG. The second connecting shaft 32 is disposed on the second connecting protrusion β such that the shaft center line ω2 coincides (positions) with the surface width center line s of the first leg side surface 7 .

As shown in FIGS. 8(b) and 10(b), the second connecting shaft 32 has an axial length Lk in the leg length direction B and extends from the second connecting surface βf toward the leg contact surface 10. protruding. The axial length Lk of the second connecting shaft 32 is shorter than the convex length Lq of the fourth connecting convex portion σ. The second connecting shaft 32 protrudes between the second connecting surface βf and the leg contact surface 10 in the leg length direction B. As shown in FIG.
In the fourth connecting convex portion σ, the second convex interval λA is set to an interval exceeding the sum of the convex length Lp of the second connecting convex portion β and the axial length Lk of the second connecting shaft 32 [λA> (Lp+LK)].

The first and second connecting holes 33 and 34 are formed in a circular shape (circular hole) having a diameter larger than the shaft diameter (outer diameter) of the first and second connecting shafts 31 and 32 .

The first connecting hole 33 is arranged on the third connecting protrusion γ, as shown in FIGS. 9(a) and 11(a). The first connecting hole 33 is formed in the third connecting protrusion γ with the hole center line ω3 of the first connecting hole 33 directed in the leg length direction B.
The first connecting hole 33 is arranged in the third connecting protrusion γ in the leg width direction A with a protrusion width interval λ4 from the projecting end γ3 of the third connecting protrusion γ.
The first connecting hole 33 is arranged in the leg width direction A between the protrusion width center line q of the third connecting protrusion γ and the projecting end γ3 of the third connecting protrusion γ. The first connecting hole 33 is arranged on the surface width center line s of the second leg side surface 8 in the leg thickness direction C. As shown in FIG. The first connecting hole 33 is arranged in the third connecting protrusion γ such that the hole center line ω3 coincides (positions) with the surface width center line s of the second leg side surface 8 .

The first connecting hole 33 opens to the third connecting surface γf in the leg length direction B and communicates with the inside of the third connecting protrusion γ.

The second connecting hole 34 is arranged at the fourth connecting projection σ as shown in FIGS. 9B and 11B. The second connecting hole 34 is formed in the fourth connecting protrusion σ so that the hole center line ω4 of the second connecting hole 34 faces the leg length direction B. As shown in FIG.
The second connecting hole 34 is arranged in the fourth connecting protrusion σ in the leg width direction A with a protrusion width interval λ4 from the projecting end σ3 of the fourth connecting protrusion σ. The second connecting hole 34 is arranged in the leg width direction A with a convex width interval λ4 between the hole center line ω4 and the projecting end σ3 of the fourth connecting convex portion σ.
The second connecting hole 34 is arranged in the leg width direction A between the convex width center line q of the fourth connecting convex portion σ and the projecting end σ3 of the fourth connecting convex portion σ. The second connecting hole 34 is arranged on the surface width center line s of the second leg side surface 8 in the leg thickness direction C. As shown in FIG. The second connecting hole 34 is arranged in the fourth connecting protrusion σ such that the hole center line ω4 coincides (positions) with the surface width center line s of the second leg side surface 8 .

The second connecting hole 34 opens in the leg length direction B at the fourth connecting surface σf and communicates with the inside of the fourth connecting protrusion σ.

As shown in FIG. 12(a), the cylindrical portion M1 is arranged at the center of the leg width of the script body 1 in the leg width direction A. As shown in FIG. The cylindrical portion M1 is arranged in the leg body 1 between the leg upper surface 9 and the first leg hole 25 (hole side surface 25A) in the leg length direction B. The cylindrical portion M1 passes through the leg body 1 from the leg upper surface 9 in the leg length direction B and is fixed to the leg body 1 . The cylindrical portion M1 opens to the leg upper surface 9 and the first leg hole 25 (hole side surface 25A). The cylindrical portion M1 is formed integrally with the script body 1. As shown in FIG.

As shown in FIG. 12(b), the cylindrical portion M2 is arranged at the center of the leg width of the script body 1 in the leg width direction A. As shown in FIG. The cylindrical portion M2 is arranged in the leg length direction B between the groove portion 15 and the second leg hole 26 (hole side surface 26A). The cylindrical portion M2 passes through the leg body 1 from the groove bottom surface 21 of the recessed groove portion 15 in the leg length direction B and is fixed to the leg body 1 . The cylindrical portion M2 is opened to the concave groove portion 15 (groove bottom surface 21) and the second leg hole 26 (hole side surface 26A). The cylindrical portion M2 is formed integrally with the script body 1. As shown in FIG.

As shown in FIGS. 1 to 3, 5, 6, and 12(a), the first clamp K1 (first clamp fitting) includes a first clamp main body 57, a first clamp opening/closing portion 58, and a first clamp. It has a threaded shaft 59 and a first clamp nut 60 .

The first clamp opening/closing part 58 is rotatably attached to the first clamp main body 57, as shown in FIG. 12(a). The first clamp opening/closing part 58 is connected to the first clamp main body 57 by a rotating shaft 61 . The first clamp body 57 and the first clamp opening/closing part 58 form a first tube insertion hole 62 between the first clamp body 57 and the first clamp opening/closing part 58 .

The first clamp screw shaft 59 is rotatably attached to the first clamp main body 57, as shown in FIG. 12(a). The first clamp screw shaft 59 is connected to the first clamp main body 57 by a rotating shaft 63 . The first clamp screw shaft 59 is detachably inserted into the cut groove 64 of the first clamp opening/closing part 58 . The first clamp screw shaft 59 penetrates the cut groove 64 and protrudes outside the first clamp opening/closing portion 58 . The first clamp nut 60 is screwed onto the first clamp screw shaft 59 protruding outside the first clamp opening/closing portion 58 .

The first clamp K1 is placed on the upper leg surface 9 of the leg 1 and fixed to the leg 1, as shown in FIGS. 1, 2 and 12(a). The first clamp K1 is arranged with the hole center line a of the first tube insertion hole 62 directed in the leg thickness direction C. As shown in FIG.
The first clamp K1 is fixed to the leg body 1 by bringing the first clamp body 57 (clamp bottom surface 57A) into contact with the leg upper surface 9. As shown in FIG.

The first clamp K1 is fixed to the leg body 1 by a fixing bolt 65 and a fixing nut 66 and installed on the upper leg surface 9, as shown in FIG. 12(a).
In the first clamp K1, the screw shaft 65A of the fixing bolt 65 penetrates from the inside of the first clamp main body 57 through the clamp bottom surface 57A and the cylindrical portion M1 in this order, and projects the screw shaft 65A into the first leg hole 25. The screw shaft 65A protrudes into the first leg hole 25 through the clamp bottom surface 57A of the first clamp main body 57 and the cylindrical portion M1. A bolt head 65B of the fixing bolt 65 abuts against the first clamp body 57 inside the first clamp body 57 . A clamp bottom surface 57A of the first clamp body 57 abuts on the leg top surface 9 .
A locking nut 66 is positioned within the first leg hole 25 . The fixing nut 66 is screwed onto the screw shaft 65A projecting into the first leg hole 25 . The fixing nut 66 is rotated with respect to the screw shaft 65A (fixing bolt 65) and comes into contact with the hole side surface 25A (leg body 1) of the first leg hole 25. As shown in FIG.
The first clamp K1 is placed on the leg upper surface 9 and fixed to the leg 1 by tightening the leg 1 between the leg upper surface 9 and the hole side 25A with a fixing bolt 65 and a fixing nut 66 .

As shown in FIGS. 1, 2 and 12B, the second clamp K2 (second clamp fitting) includes a second clamp main body 77, a second clamp opening/closing portion 78, a second clamp screw shaft 79 and a second clamp K2. It has a clamp nut 80 .

The second clamp opening/closing part 78 is rotatably attached to the second clamp main body 77 as shown in FIG. 12(b). The second clamp opening/closing part 78 is connected to the second clamp main body 77 by a rotating shaft 81 . The second clamp body 77 and the second clamp opening/closing part 78 form a second tube insertion hole 82 between the second clamp body 77 and the second clamp opening/closing part 78 .

The second clamp screw shaft 79 is rotatably attached to the second clamp main body 77 as shown in FIG. 12(b). The second clamp screw shaft 79 is connected to the second clamp main body 77 with a rotating shaft 83 . The second clamp screw shaft 79 is detachably inserted into the cut groove 84 of the second clamp opening/closing portion 78 . The second clamp screw shaft 79 passes through the cut groove 84 and protrudes outside the second clamp opening/closing portion 78 . The second clamp nut 80 is screwed onto the second clamp screw shaft 79 protruding outside the second clamp opening/closing portion 78 .

The second clamp K2 is arranged in the groove 15 as shown in FIGS. 1, 2 and 12(b). The second clamp K2 is arranged with the hole center line b of the second tube insertion hole 82 directed in the leg thickness direction C. As shown in FIG. The second clamp K<b>2 is fixed to the leg body 1 by bringing the second clamp body 77 (clamp bottom surface 77</b>A) into contact with the groove surface 18 of the groove portion 15 in the groove portion 15 .
The second clamp K2, for example, faces the second clamp opening/closing portion 78 toward the leg contact surface 10, and the second clamp main body 77 (clamp bottom surface 77A) is brought into contact with the groove bottom surface 21 of the recessed groove portion 15 to fix it to the legwork 1. be done.

The second clamp K2 is fixed to the leg body 1 by a fixing bolt 85 and a fixing nut 86 and arranged in the concave groove portion 15, as shown in FIG. 12(b).
In the second clamp K2, the threaded shaft 85A of the fixing bolt 85 penetrates from the second clamp body 77 through the clamp bottom surface 77A and the cylindrical tube M2 in this order, and projects the threaded shaft 85A into the second leg hole 26. The screw shaft 85A protrudes into the first leg hole 26 through the clamp bottom surface 77A of the second clamp body 77 and the cylindrical portion M2. A bolt head 85B of the fixing bolt 85 abuts against the second clamp body 77 inside the second clamp body 77 . The second clamp body 77 abuts on the groove surface 18 (groove bottom surface 21 ) of the concave groove portion 15 .
A locking nut 86 is positioned within the first leg hole 26 . The fixing nut 86 is screwed onto the screw shaft 85A projecting into the second leg hole 26 . The fixing nut 86 is rotated with respect to the screw shaft 85A (fixing bolt 85) and comes into contact with the hole side surface 26A (leg body 1) of the second leg hole 26. As shown in FIG.
The second clamp K2 is brought into contact with the groove surface 18 (groove bottom surface 21) of the recessed groove portion 15, and clamps the leg body 1 between the groove bottom surface 21 and the hole side surface 26A with a fixing bolt 85 and a fixing nut 86. It is fixed to the script body 1.

13 to 15, a plurality of single-pipe barricade support legs Xa, Xb (X, X) are arranged such that the first connecting shaft 31 of one of the single-pipe barricade support legs Xa (framework 1) extends in the leg length direction B. into the first connection hole 33 of the other single-pipe barricade support leg Xb (framework 1), and the first connection projection α of the single-pipe barricade support leg Xa is inserted into the first connection projection α of the single-pipe barricade support leg Xb. It is placed on the 3-connected convex portion γ. One of the single-pipe barricade support legs Xa is arranged so that the first connection surface αf of the first connection projection α is extended from the leg length direction B to the third connection surface of the third connection projection γ of the other single-pipe barricade support leg Xb. It is placed in contact with γf.
Each of the single-pipe barricade support legs Xa and Xb guides the second connection shaft 32 of one of the single-pipe barricade support legs Xa (leg 1) at the same time as the first connection shaft 31 is introduced into the first connection hole 33. The second connecting projection β of the single-pipe barricade support leg Xa is inserted into the second connection hole 34 of the other single-pipe barricade support leg Xb (framework 1), and the second connection convex portion β of the single-pipe barricade support leg Xa is connected to the fourth single-pipe barricade support leg Xb. It is placed on the connecting convex portion σ. One of the single-pipe barricade support legs Xa is connected to the second connection surface βf of the second connection projection β from the leg length direction B to the fourth connection surface of the fourth connection projection σ of the other single-pipe barricade support leg Xb. It is placed in contact with σf.
In this way, each of the single-pipe barricade support legs Xa and Xb connects the first and second connecting shafts 31 and 32 of one of the single-pipe barricade support legs Xa (framework 1) to the other single-pipe barricade support leg. Xb (leg body 1) is inserted into the first and second connecting holes 33 and 34, and the first and second connecting convex portions α and β of one of the single-pipe barricade supporting legs Xa are connected to the other single-pipe barricade support leg Xa. The supporting legs Xb are connected by being placed on the third and fourth connecting protrusions γ and σ.
By inserting the first and second connecting shafts 31 and 32 into the first and second connecting holes 33 and 34, one of the single-pipe barricade support legs Xa is moved 180 degrees from the other single-pipe barricade support leg Xb. It is rotatable in an angular range of degrees (180°).

16 to 18, the single-pipe barricade support leg X constitutes a single-pipe barricade Z1 and supports the pipe ends of the single pipes PU, PU.
As shown in FIGS. 16 and 17, the single-pipe barricade Z1 includes a pair of single-pipe barricade support legs X, X and two single-pipe PUs, PU. Each of the single-pipe barricade support legs X, X is arranged with a space between each of the single-pipe barricade support legs X, X, and the leg back surface 6 and the leg surface of each single-pipe barricade support leg X, X 5 are arranged in parallel with each other. Each of the single-tube barricade support legs X, X is erected on the installation surface FL with the leg contact surface 10 of the leg body 1 in contact with the installation surface FL.
The single pipes PU, PU are bridged between the first clamps K1, K1 and bridged between the second clamps K2, K2 between the single pipe barricade support legs X, X. . The end portions of the single pipes PU, PU are gripped by the first clamps K1, K1 of the single pipe barricade support legs X, X, and the second clamps K2 of the single pipe barricade support legs X, X. , K2.
In each single pipe barricade support leg X, X, the first clamps K1, K1 are inserted into the first pipe insertion hole 62 between the first clamp main body 57 and the first clamp opening/closing part 58. The first clamp main body 57 and the first clamp opening/closing part 58 grip the single tube PU. The first clamp K1 rotates the first clamp nut 60 and presses it against the first clamp opening/closing part 58 to tighten and grip the single pipe PU with the first clamp main body 57 and the first clamp opening/closing part 58 .
In each single pipe barricade support leg X, X, the second clamps K2, K2 are inserted into the second pipe insertion hole 82 between the second clamp main body 77 and the second clamp opening/closing part 78. The second clamp main body 77 and the second clamp opening/closing part 78 grip the single tube PU. The second clamp K2 rotates the second clamp nut 80 and presses it against the second clamp opening/closing part 78 to clamp and grip the single tube PU with the second clamp main body 77 and the second clamp opening/closing part 78 .

19 to 21, the single-pipe barricade device Y may be configured by a plurality (pairs) of single-pipe barricades Z1, Z1, .
In the single-pipe barricade device Y, the single-pipe barricades Z1, Z1 are arranged in parallel in the leg width direction A, and the single-pipe barricades Z1, Z1 for each of the single-pipe barricades Z1, Z1 are installed in the same manner as described with reference to FIGS. It is configured by connecting support legs X, X.

The present invention is most suitable for constructing a single-pipe barricade.

X single pipe barricade support leg 1 leg body 15 concave groove portion 18 groove surface 21 groove bottom surface K1 first clamp (clamp fitting)
K2 Second clamp (clamp fitting)

Claims (1)

A support leg for a single pipe barricade that is erected on an installation surface to constitute a single pipe barricade and supports a pipe end of the single pipe,
A first leg side surface and a second leg side surface facing in the leg width direction, and a leg upper surface and a leg contact surface facing in the leg length direction. a leg body having a leg surface and a leg back surface facing each other in the leg thickness direction, and standing on the installation surface with the leg contact surface in contact with the installation surface;
a first clamp body and a first clamp opening/closing part rotatably attached to the first clamp body; a first clamp for inserting a single tube and gripping the single tube with the first clamp main body and the first clamp opening/closing portion;
It has a second clamp body and a second clamp opening/closing part rotatably attached to the second clamp body, and a single tube is inserted into a second tube insertion hole formed by the second clamp body and the second clamp opening/closing part. and a second clamp that holds the single tube with the first clamp body and the first clamp opening and closing part by inserting
The script body has a concave groove,
The concave groove portion is
Formed between the first leg side surface and the second leg side surface in the leg width direction, with a leg width interval on the first leg side surface and a leg width interval on the second leg side surface,
In the leg length direction, the leg groove has a depth from the leg contact surface toward the leg upper surface and is opened to the leg contact surface,
openings in the leg surface and the leg back surface through the leg body in the leg thickness direction,
The first clamp is
The first clamp body is abutted against the top surface of the leg and fixed to the leg body,
The second clamp is
A support leg for a single pipe barricade, characterized in that it is arranged in the recessed groove, and is fixed to the scaffold by abutting the second clamp body against the groove surface of the recessed groove.

Images