KR100410614B1 - A pulling apparatus for stainless steel wire mesh - Google Patents

Abstract

According to the present invention, the first and second towing wires are coupled to clamp the transverse lines of the stainless wire mesh by clamping means, and to pull the clamped stainless wire mesh, and the winch means can reinforce the stainless steel wire mesh. Tow the clamp means to tension tightly on the surface of the concrete structure, and to engage the ring formed in the second traction wire of the clamp means with the ring formed in the winch wire of the winch means by a veneer. do.

Therefore, the present invention can maintain the tension force of the stainless steel wire mesh required in the repair site of the concrete structure, the structure is simple, and the structure is simple can reduce the manufacturing cost.

Description

Traction device for stainless steel wire mesh {A PULLING APPARATUS FOR STAINLESS STEEL WIRE MESH}

The present invention relates to a traction device for stainless steel wire mesh, in particular, to maintain the tension of the stainless steel wire mesh required in the repair site when repairing the aging concrete structure using the stainless steel wire mesh stainless steel wire mesh It relates to a traction device for a stainless steel wire mesh to pull the.

Recently, due to the development of a permeable polymer that is similar in physical properties to the existing concrete structure and excellent adhesion, it is often used to repair the aged concrete structure using a stainless steel wire mesh.

However, repairing aging concrete structures using stainless steel wire mesh simplifies the construction process, shortens the air and reduces maintenance costs, but there is no suitable device to pull the stainless steel wire mesh. There was a problem that it is difficult to maintain the tension of the stainless steel wire mesh required in the repair site of the concrete structure.

Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide a traction apparatus for a stainless steel wire mesh that can maintain the tension force of the stainless steel wire mesh required in the repair site of the concrete structure.

Another object of the present invention is to provide a traction device for a stainless steel wire mesh with a simple structure.

Another object of the present invention is to provide a traction device for a stainless steel wire mesh that can reduce the manufacturing cost.

In order to achieve the above object, the present invention is clamping the horizontal line of the stainless wire mesh, at the same time, the clamping means is coupled to the traction wire to pull the clamped stainless wire mesh, and the surface of the concrete structure to reinforce the stainless steel wire mesh And a winch means for pulling the clamp means so as to be tightly tensioned thereon, and a binner for engaging a ring formed in the second traction wire of the clamp means and a ring formed in the winch wire of the winch means.

1 is a partially exploded perspective view schematically showing a traction device for a stainless steel wire mesh according to an embodiment of the present invention,

2 is a plan view schematically showing the winch means for pulling the clamp means for clamping the stainless steel wire mesh in FIG.

3 is a rear view of the winch means for pulling the clamp means for clamping the stainless steel wire mesh in FIG.

4 is a side view of the winch means for pulling the clamp means for clamping the stainless steel wire mesh in FIG.

5 is a perspective view schematically showing a state in which the stainless steel wire mesh is clamped by the clamping means of the traction apparatus for the stainless steel wire mesh according to the embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10: clamp means 11: bottom plate

12: Bolt 13: clamper

14: Rubber plate 15: first traction wire

15a, 15b :: Ring 16a, 16b: Clamper

17a, 17b: clamper 18: second traction wire

18a, 18b: Ring 19: upper plate

19a: screw hole 20: rubber plate

21: Knob 21a: Screw hole

30: winch means 50: bin

31a: left wall portion 31b: right wall portion

32a, 32b: Hole 32: Mounting plate

33: Bracket 34: Handle

34a: rotating shaft 35: ratchet gear

36a: rotary shaft 37: winch wire drum

38: winch wire 38a: ring

39: Gear 40: Drum

40a: rotary shaft

Hereinafter, a traction apparatus for a stainless steel wire mesh according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a partially exploded perspective view schematically showing a traction device for a stainless steel wire mesh according to an embodiment of the present invention, Figure 2 is a winch means for pulling the clamp means for clamping the stainless steel wire mesh in Figure 1 Is a plan view schematically illustrating FIG. 3 is a rear view of the winch means for pulling the clamp means for clamping the stainless steel wire mesh in FIG. 2, and FIG. 4 is a view for clamping the stainless steel wire mesh in FIG. 2. Figure 5 is a side view of the winch means for pulling the clamp means, Figure 5 is a perspective view schematically showing the state of clamping the stainless steel wire mesh by the clamp means of the traction apparatus for a stainless steel wire mesh according to an embodiment of the present invention.

1 to 5, the traction device for a stainless steel wire mesh according to an embodiment of the present invention, while clamping the horizontal line of the stainless steel wire mesh 100, at the same time clamped stainless steel wire mesh 100 Clamp means (10) is coupled to the traction wire to tow and winch means (30) to pull the clamp means (10) to tightly tension on the surface of the concrete structure to reinforce the stainless steel wire mesh (100) ) And a looper 50 for coupling the ring 18b formed on the second traction wire 18 of the clamp means 10 and the ring 38a formed on the winch wire 38 of the winch means 30. Equipped.

The clamp means 10 is a lower plate 11 of a predetermined length made of a metal material, a plurality of bolts 12 vertically placed at a predetermined interval with respect to the lower plate 11 and one side of the lower plate 11 A plurality of U-shaped clampers 13 fixed vertically at regular intervals and attached to the upper surface of the lower plate 11 so that the stainless steel wire mesh 100 does not slip when the stainless steel wire mesh is pulled out. The first traction wire 15 clamped to the U-shaped clamper 13 while the ring 15a is formed by the rubber plate 14 and the clamper 16a, and the first traction adjacent thereto. The two loops 15b respectively formed by the clamper 16b on the other side of the wire 15 are clamped by the loops 18a formed by the clamper 17a, and at the same time, the clamper 17b is clamped by the binner 50. A wire 18 having a ring 18b formed by The stainless steel wire mesh 100 does not slip when the upper plate 19 having the screw holes 19a is formed to engage the plurality of bolts 12 installed in the 11 and the stainless steel wire mesh 100 is pulled out. The rubber plate 20 attached to the lower surface of the upper plate 19 and the plurality of bolts 12 provided on the lower plate 11 in the screw holes 19a formed in the upper plate 19, respectively, The knob 21 is formed with a screw hole 21a for firmly coupling the lower plate 11 and the upper plate 19.

The winch means 30 is welded and fixed vertically to one side end of the left and right side wall portions 31a and 31b and the left and right side wall portions 31a and 31b at regular intervals, and has two holes 32a for the anchor bolts 90. A bracket 33 having an attachment plate 32 having a 32b formed thereon, a handle 34 for rotating the rotating shaft 34a provided on the left and right side wall portions 31a and 31b of the bracket 33, and the rotating shaft 34a. Ratchet gear 35 fixed to one side of the rotary shaft (34a) so as to interlock according to the rotation of the) and the rotary shaft (36a) installed at a predetermined distance from the rotary shaft (34a) to pull the stainless steel wire mesh (100). The winch wire drum (37) rotatably installed at one side, and the ring (18b) formed on the second traction wire (18) of the clamp means 10 on the other side is coupled to the winch wire drum 37 and the other side A winch wire 38 having a ring 38a coupled by a vener 50, and the winch wire drum Gear 39 is provided on one side of the winch wire drum 37 to engage and engage the ratchet gear 35 to wind and rewind the winch wire 38 to (37) to rotate the winch wire drum 37. And, it is installed between the rotary shaft 36a and the attachment plate 32, and is installed on the rotary shaft 40a provided on the left and right side wall portions 31a, 31b of the bracket 33 to the winch wire drum 37 It is comprised by the guide drum 40 which guides the winch wire 38 wound up.

Next, the operation and effects of the traction apparatus for the stainless steel wire mesh according to the embodiment of the present invention configured as described above will be described.

First, the ring formed at one end of the ring (not shown) formed at both ends of the main root of the stainless steel wire mesh 100 is fixed to the surface of the aging concrete structure to be repaired using an anchor bolt.

Next, the knob 21 of the clamp means 10 is loosened to remove the upper plate 19 from the plurality of bolts 12 installed on the lower plate 11 and the upper plate 19 is then balanced. The lateral roots of the stainless steel wire mesh 100 are evenly hung on the plurality of bolts 12 provided in the lower plate 11, and then the lower plate 11 is formed in the screw hole 19a formed in the upper plate 19. After inserting each of the plurality of bolts 12 installed, the plurality of bolts 12 installed on the lower plate 11 are firmly screwed into the screw holes 21a formed in the knob 21.

Then, the attachment plate of the winch wire 38 at a distance from the ring formed on the side of the upper plate 19 of the clamp means 10, which is not fixed by the anchor bolt of the stainless steel wire mesh 100. The anchor bolt 90 is firmly anchored to the concrete wall through the holes 32a and 32b formed in the (32).

Thereafter, as shown in FIG. 1, the hook 38a of the other end of the winch wire 38 having one end fixed to the winch wire drum 37 of the winch means 30 and the second of the clamp means 10. The ring 18b formed in the traction wire 18 is coupled to the binner 50.

As such, the hook 38a of the other end of the winch wire 38 having one end fixed to the winch wire drum 37 of the winch means 30 and the second traction wire 18 of the clamp means 10 respectively. While rotating the handle 34 of the winch means 30 counterclockwise in a state in which the formed ring 18b is coupled to the binner 50, the winch is rotated by rotating the gear 39 while the ratchet gear 35 is rotated. The wire drum 37 is rotated.

Accordingly, when the winch wire 38 begins to be wound on the winch wire drum 37 while being guided by the guide drum 40, the towing force is maintained at the repair site when the winch wire 38 starts to be towed. At the same time, the ring of the stainless steel wire mesh 100 formed on the towing side is fixed to the anchor bolt with the spacer inserted therein, and the spacer formed on the towing side with a predetermined interval in the transverse muscle of the stainless steel wire mesh 100 is fitted. By fixing with anchor bolts, the stainless steel wire mesh 100 can be easily installed on the wall surface of the concrete structure to be repaired.

When the stainless steel wire mesh 100 is pulled out, since the rubber plates 14 and 20 are respectively provided on the upper surface of the lower plate 11 and the lower surface of the upper plate 19, the transverse roots of the stainless steel wire mesh 100 are provided. There is no fear of slipping.

In the above description, the specific embodiments have been shown and described, but the present invention is not limited thereto, for example, by those skilled in the art without departing from the concept of the present invention. Of course, the design can be changed in various ways.

As described above, according to the traction apparatus for the stainless steel wire mesh of the present invention, the first and second traction wires are coupled to clamp the transverse of the stainless wire mesh by the clamping means and to pull the clamped stainless wire mesh. And by the winch means to pull the clamp means tightly on the surface of the concrete structure to reinforce the stainless steel wire mesh, and by means of a binner the loop formed on the second tow wire of the clamp means and the winch means. Since it is configured to join the ring formed in the winch wire, it is possible to maintain the tension force of the stainless steel wire mesh required for the repair site of the concrete structure, the structure is simple, and the structure is simple, so that the manufacturing cost can be reduced. It works.

Claims (3)

At the same time as clamping the horizontal line of the stainless steel wire mesh 100, reinforcing the clamp means (10) and the stainless steel wire mesh (100) to which the towing wire is coupled to pull the clamped stainless steel wire mesh (100). Winch means 30 for pulling the clamp means 10 to tightly tension the surface of the concrete structure to be connected, a ring 18b formed on the second traction wire 18 of the clamp means 10 and the winch. Traction apparatus for stainless steel wire mesh, characterized in that it comprises a binner (50) for engaging the ring (38a) formed in the winch wire (38) of the means (30). According to claim 1, The clamp means 10 is a lower plate 11 of a predetermined length made of a metal material, a plurality of bolts 12 vertically placed at a predetermined interval with respect to the lower plate 11 and the lower plate The plurality of U-shaped clampers 13 fixed vertically at one side of the side 11 and the stainless steel wire mesh 100 so as not to slip when the stainless steel wire mesh 100 is towed. Rubber plate 14 attached to the upper surface of the lower plate 11 and the first traction wire 15 is clamped while the ring 15a is formed by the clamper 16a on the U-shaped clamper 13. And clamping the two hooks 15b respectively formed by the clamper 16b on the other side of the adjacent first traction wire 15 with the hooks 18a formed by the clamper 17a, and at the same time. A second with ring 18b formed by clamper 17b to be clamped to 50; The stainless steel wire mesh 100 is pulled out of the stainless steel wire mesh 100 when the traction wire 18 and the upper plate 19 having a screw hole 19a are formed to engage the plurality of bolts 12 installed in the lower plate 11. In order to prevent the steel wire mesh 100 from slipping, a plurality of rubber plates 20 attached to the lower surface of the upper plate 19 and a plurality of lower plates 11 installed in the screw holes 19a formed in the upper plate 19 are provided. Traction for stainless steel wire mesh comprising a knob 21 having a screw hole 21a for firmly coupling the lower plate 11 and the upper plate 19 to each other after the bolts 12 are inserted. Device. According to claim 1, The winch means 30 is welded and fixed vertically to one side end of the left and right side wall portions (31a, 31b) and the left and right side wall portions (31a, 31b) at regular intervals and two holes for anchor bolts A bracket (33) having an attachment plate (32) on which (32a, 32b) is formed, a handle (34) for rotating the rotating shaft (34a) provided on the left and right side wall portions (31a, 31b) of the bracket (33), and A ratchet gear 35 fixed to one side of the rotary shaft 34a to be interlocked with the rotation of the rotary shaft 34a and a rotary shaft installed at a predetermined distance from the rotary shaft 34a to pull the stainless steel wire mesh 100. A winch wire drum 37 rotatably installed at 36a, and one side coupled to the winch wire drum 37, and at the same time, a ring 18b formed at the second traction wire 18 of the clamp means 10 on the other side. ) Winch wire (38) having a ring (38a) coupled by the binner (50), Gear is installed on one side of the winch wire drum 37 to engage and cooperate with the ratchet gear 35 to wind and rewind the winch wire 38 to the chi wire drum 37 to rotate the winch wire drum 37. 39 and the rotary shaft 36a and the attachment plate 32, and are installed on the rotary shaft 40a provided on the left and right side wall portions 31a and 31b of the bracket 33 to form the winch wire drum ( Traction device for stainless steel wire mesh, characterized in that it is composed of a guide drum (40) for guiding the winch wire (38) wound on 37.