KR100613046B1 - Apparatus for tensiling steel wire strand by oil pressure type - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydraulic stranded tension device, wherein a piston (111) is installed in a cylindrical cylinder (101) so as to be reciprocated, and the piston (111) provides an A chamber 132 and a B chamber 131. The cylinder 101 is separated by a tension cylinder 100 having a chamber A 102 and a chamber B 103 connected to the chamber A 132 and the chamber B 131. 11) by minimizing the wear of the tension cylinder 100 to provide a conical steel wire guide array plate 200 to secure the space, the gripping and tensioning of the steel wire 11 can be made simply, the steel wire In addition, the guide array plate 200 and the tension cylinder 100 are easily mounted and dismantled, and even a simple structure allows a plurality of steel wires 11 to be tensioned with the same force so as to take the same force even if they are different from each other or have different elongations. Can be.

Anchor, hydraulic, stranded wire, tension, cylinder

Description

Hydraulic stranded tensioner {Apparatus for tensiling steel wire strand by oil pressure type}             

1 is a schematic view of a hydraulic tensioning device used in a conventional earthquake construction method.

Figure 2 is a cross-sectional view schematically showing a conventional hydraulic tension device for earthquake construction.

3 is a perspective view of a pulling head (or anchor head) applied to the hydraulic tensioning device of FIG.

4 is a cross-sectional view taken along the arrow A-A of FIG.

5 is a partial cross-sectional view showing a state in which the earthquake construction is adopted by employing a tensioning apparatus according to an embodiment of the present invention.

Figure 6 is a cross-sectional view showing the configuration of a hydraulic stranded tension cylinder according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

5: pressure plate 11: steel wire

13: Anchor head 17: Anchor choke

21: high pressure cylinder for pulling 23: piston

50: cylinder 53: top cover

55: piston 57: steel wire arrangement plate

200: steel wire guide array plate 201: lower array plate

203: steel wire guide pipe 205: upper array plate

207: pipe fixing plate 100: tension cylinder

101: cylinder 105: sleeve

111: piston 112: jaw phage sleeve

120: chalk 130: chalk cover

The present invention relates to a hydraulic twisted pair tension device for earthquake construction used to anchor so that the soil cut during underground excavation or cutting work in civil engineering or construction work, more specifically, the gripping and tensioning of the steel wire is made simple In addition, the installation and disassembly of the wire guide array plate and the tensioning cylinder can be easily performed, and a hydraulic stranded tension device that can be tensioned with the same force to take the same force even if a plurality of steel wires are different from each other or elongation is different. will be.

Conventional hydraulic tensioning device is a cylindrical cylinder 50, as shown in Figure 1 and 2, the upper cover 53 and the upper cover 53 and the upper cover 53 which is screwed with the threaded portion (50a) formed on the cylinder 50 Piston 55 is provided to be movable between the outer peripheral surface of the cylindrical portion (53a) and the inner peripheral surface of the cylinder (50), and the lower portion of the cylindrical portion (53a) of the piston (55) and the upper cover (53) 11 and a cover that is screwed with the threaded portion 50b formed in the opening of the cylinder 50 so as to restrict the movement of the steel wired array plate 57 by a predetermined length L. 59).

In addition, the conventional hydraulic tensioning device is provided with an oil chamber 61 to move the piston (55) up and down, the hydraulic chamber is introduced to the oil chamber (61). An oil passage 65 is connected to the second hydraulic port 33 via a nipple 63 so as to be discharged, and is disposed between the inner circumferential surface of the cylinder 50 and the outer circumferential surface of the cylindrical portion 53a of the upper cover 53. The first packing member 67 is installed in the oil chamber 61 so that the hydraulic pressure in the oil chamber 61 is not leaked. The oil is disposed between the inner circumferential surface of the piston 55 and the outer circumferential surface of the cylindrical portion 53a of the lower cover 53. The second packing member 69 is provided so that the hydraulic pressure in the chamber 61 does not leak.

Further, a third packing member 70 is provided between the inner circumferential surface of the cylinder 50 and the outer circumferential surface of the piston 55 so that the hydraulic pressure in the oil chamber 61 does not leak.

As shown in Figs. 3 and 4, the pulling head 25 or the anchor head 13, which is conventionally used, is manufactured in the same shape, and the tapered choke insertion holes 25a and 13a are formed in the pulling head. 25 or the anchor head 13, respectively.

This conventional hydraulic tensioning device is generally placed in the underground at the beginning of the construction work to prevent the soil cut down as shown in Figure 1 even in underground construction of civil engineering or construction site Then, one soil of the vertical H-beams 1 is cut out while being scooped out with a fork-lane or the like, and after the soil is excavated to a certain depth, the vertical H-beams 1 do not fall down toward the excavated soil. The horizontal H beam 3 is fixed to one side of the.

Then, the horizontal H beam 3 is supported by a support beam or the like not shown on the cut side.

After temporarily supporting the soil cut in this manner so as not to collapse, and after the cutting operation is completed, the soil cut by the vertical and horizontal H beams 1 and 3 may not be collapsed to the horizontal H beam 3. Through holes (not shown) are drilled at predetermined lengths, and the pressure plate 5 having the through holes 5a formed on the outside (cut side) of the through holes is fixed by welding or screwing.

Next, a through hole formed in the horizontal H beam 3 using a pneumatic drill toward the soil wall 7 through the through hole 5 a formed in the pressure plate 5 and the through hole formed in the horizontal H beam 3. After drilling a hole 9 of a predetermined depth toward the soil wall 7 through the steel wire 11, the steel wire 11 is introduced into the hole 9, and then cement mortar is injected to the mounting place in the hole 9 and grounded. To fix the steel wire 11 to soil or rock around the hole 9.

Thereafter, the anchor head 13 is fixed to the upper end of the pressure plate 5, and then the choke 17 for holding the steel wire 11 in the plurality of choke insertion holes 13a formed in the anchor head 13 is provided. Insert).

The steel wires 11 are respectively inserted into the through-holes 57a formed in the steel wire arrangement plate 57 of the hydraulic tension device for earthquake construction, and at the same time, the high pressure cylinder 21 and the pulling head 25 for pulling the hydraulic tension device. After penetrating into each through hole 25a formed in the c), each of the steel wires 11 is clamped by the pulling choke 27 and inserted into the through hole 25a.

In this state, when the hydraulic pressure is supplied to the first hydraulic chamber 31 through the first hydraulic port 29, the piston 23 moves upward in FIG. 1, whereby the pulling choke 27 pulls the head. It is intimately inserted into the tapered through hole 25a formed at 25.

Thereby, the free field part of the steel wire 11 inserted in the hole 9 formed in the soil wall 7 is tensioned. When the tensioning operation of the steel wire 11 is completed, while closing the valve (not shown) of the first hydraulic port 29, the hydraulic pressure is supplied through the second hydraulic port (33).

At this time, since the first hydraulic port 29 is closed, the hydraulic pressure supplied to the second hydraulic port 33 is in the nipple 63 and the oil passage 65 in FIG. 2 because the piston 23 is in a stopped state. Through the cylinder 50 of the hydraulic stranded tension device and the cylindrical portion (53a) of the upper cover 53 is supplied into the oil chamber 61 is formed.

Therefore, as the piston 55 moves downward, the steel wire arrangement plate 57 presses the anchor choke 17 and closely presses it into the tapered choke insertion hole 13a formed in the anchor head 13. As a result, the steel wire 11 is firmly clamped by the click formed on the inner circumferential surface of the choke 17, thereby completing the anchoring work of the earthwork.

Thereafter, when the first hydraulic pressure port 29 of the pulling high pressure cylinder 21 is opened to drain the hydraulic pressure in the first hydraulic pressure chamber 31, the piston 23 moves downward in FIG. At this time, the pulling choke 27 is pulled up and removed from the pulling head 25, and then the pulling head 25, the high pressure cylinder 21 for pulling and the conventional hydraulic tensioning device are pulled up.

A conventional hydraulic tensioning device is installed between the high pressure cylinder 21 for pulling and the angle head 13 to press-fit the anchor choke 17 in the earthwork, so that the anchor choke 17 is anchored head 13 The steel wire 11 was clamped while being inserted into a plurality of tapered choke insertion holes 13a formed in the anchoring work.

The conventional hydraulic tensioning device as described above is installed between the high-pressure cylinder 21 for pulling and the anchor head 13 for hydraulic tensioning in the tapered choke insertion hole 13a formed in the anchor head 13 in the earth work. The steel wire 11 is anchored tightly by the anchor choke 17 by pressing and pushing the anchor choke 17 by the steel wire arrangement plate 57 of the apparatus, so that the anchor wire can be reliably anchored, and accordingly, Although it is possible to perform anchor work with high efficiency in construction, it is difficult to precisely pull the pulling force or the degree of elongation of the steel wire 11 for the steel wires 11 of different lengths, thereby applying the correct tensile force to each steel wire 11. There is a problem that it becomes difficult, and furthermore, there is a problem that its management is not easy.

In addition, the above-described hydraulic tension device for earthquake construction has a problem that not only the structure is complicated but also the mounting and dismantling of the earthquake construction is complicated and the productivity is lowered.

Accordingly, an object of the present invention is to solve the problems of the prior art, the gripping and tensioning of the steel wire 11 can be made simply, the wire guide array plate 200 and the tension cylinder 100 of the In addition to the simple installation and disassembly, even a simple structure is to provide a hydraulic stranded tension device that can be tensioned with the same force to take the same force even if a plurality of steel wires 11 or different elongation.

One aspect of the present invention for achieving the above object, in the hydraulic stranded tension device, to minimize the wear of the tensioned steel wire 11 and from the anchor head 13 to secure the space of the tension cylinder 100 A steel wire guide arrangement plate 200 extending in a truncated conical shape in the longitudinal direction of the steel wire 11 so that a group of exposed cylinders 11 are provided correspondingly to the number of exposed steel wires 11; And the piston 111 is installed in the cylindrical cylinder 101 so as to be reciprocated while being in oiltight, and the cylinder 101 is separated into the A chamber 132 and the B chamber 131 by the piston 111. It relates to a hydraulic stranded tension device comprising a tension cylinder (100) in which an A chamber port (102) and a B chamber port (103) connected to the A chamber 132 and the B chamber 131 are formed.

Hereinafter, a hydraulic stranded tension device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a partial cross-sectional view showing a state in which the earthquake construction is carried out by employing a hydraulic stranded tension device according to an embodiment of the present invention, Figure 6 is a cross-sectional view showing the configuration of a tension cylinder according to an embodiment of the present invention. As such, the hydraulic twisted pair tension device for a masonry construction according to an embodiment of the present invention radially rearranges the steel wire 11 protruding through the anchor head 13 to facilitate the installation of the tension cylinder 100 in the masonry construction. 1 is provided with a tension cylinder 100 for tensioning the steel wire 11 using hydraulic pressure with respect to the steel wire guide arrangement plate 200 and the steel wire 11 arranged on the steel wire guide arrangement plate 200. It is different from one conventional cladding.

To this end, the present invention provides a truncated steel wire guide array plate 200, the steel wire guide array plate 200 according to an embodiment of the present invention is a steel wire 11 can penetrate into the shape of the anchor head 13 The through hole is formed at the same position as the anchor head 13, and the choke 17 is a space for gripping and releasing the steel wire 11, the lower array plate 201 and the lower array plate (circle groove) The same number of through-holes as the lower array plate 201 is formed in each of the steel wires 11 through the through-holes of 201 so as to be rearranged in a circle at intervals for easy installation of the tension cylinder 100 vertically. The steel wire guide pipe 203 and the steel wire guide pipe welded and fixed to lead the steel wire 11 penetrating the upper and lower heat dissipation plates 205 and 201 to the respective through holes of the upper and lower heat dissipation plates 205. In each wire to prevent bending or deformation Pipe 203 consists of a pipe fixing plate 207 of which a circular fixed by welding to the middle part.

In addition, the steel wires 11 having different thicknesses are formed to penetrate the steel wire guide array plate 200, and the through-holes and steel wire guide pipes of the lower heat dissipation plate 201 and the upper heat dissipation plate 205 through which the wires 11 pass. It is preferable that 2-20 pieces are formed in the number of 203.

On the other hand, in the cylindrical fluid cylinder of the present invention; the cylinder 101 is installed so as to reciprocate while the piston 111 is oiltight, and the A chamber 132 and the B chamber 131 by the piston 111. The chamber 132 and chamber B 131 are fluidly communicated to an external valve, pump, fluid tank, etc. via chamber A port 102 and chamber B 103.

The bottom plate 104 is installed to close one side of the cylinder 101, and a through hole 133 through which the steel wire 11 passes is formed in the center thereof.

The sleeve 105 is fixed to the bottom plate 104 and is formed to extend toward the other side of the cylinder 101. The sleeve 105 penetrates through the steel wire 11 in the longitudinal direction at the center thereof, and the outer circumferential surface thereof is , The piston 111 is formed between the inner circumferential surface of the cylinder 101 to be oiltight and reciprocally installed, the free end of which is inserted into the choke 120 to open the jaw opening (a jaw opening portion ( 106 is formed. Therefore, the jaw opening portion 106 is preferably formed in a truncated cone shape or truncated polyhedron shape with the outer circumferential surface of the sleeve 105 inclined inward from the end. In addition, as shown in FIG. 6, the sleeve 105 and the bottom plate 104 may be integrally formed.

The jaw gripping sleeve 112 is fixed to the piston 111 and protrudes through the other side of the cylinder 101 in an oil-tight and reciprocating manner at the outer circumference of the sleeve 105, and the inner surface of the protruding end portion. In the truncated cone to truncated cone-shaped cone (tilt) inner surface 114 is formed. As shown in FIG. 6, the piston 111 and the jaw gripping sleeve 112 may be integrally formed.

The choke 120 is formed by a plurality of jaws 121 are arranged in the circumferential direction, the outer surface of the jaw 121 is in interaction with the cone (inclined) inner surface 114 of the jaw gripping sleeve 112. Cone (inclined) outer surface corresponding to the conical (inclined) inner surface 114 of the jaw phage sleeve 112 so that when the jaw phage sleeve 112 is extended, it is tightened to the center side to strongly grip the steel wire 11 passing through the center. 124) is formed in the shape. Further, when the jaw grip sleeve 112 is retracted, the insertion portion of the jaw opening portion 106 is released radially in interaction with the jaw opening portion 106 of the sleeve 105 to release the steel wire 11. 122 is formed. The insertion portion 122 has an extended structure than the steel wire gripping surface 123 for gripping the steel wire 11 so that the jaw opening portion 106 can be inserted at least. Can be formed. In addition, the steel wire gripping surface 123 is preferably formed with teeth so that the steel wire 11 can be strongly gripped. In addition, it is preferable that the elastic ring 125 is installed in the outer circumferential surface receiving groove as shown in FIG. 6 so that the plurality of jaws 121 can stably form and maintain the choke 120.

The hydraulic twisted pair tension device is preferably provided with a circumferential spacing of the jaws 121 to grip the steel wire 11 having a different thickness, and also the steel wire gripping surface 123 to grip the steel wire 11 having a different thickness. It is desirable to be formed to be.

The choke cover 130 is inserted into the outer circumference of the jaw grip sleeve 112 protruding to contact the upper outer surface of the choke 120 as shown in FIG. 6.

Next, operation | movement of the hydraulic stranded tensioning apparatus for earthscreen construction comprised in this way is demonstrated.

In general, the hydraulic twisted-line tension device is installed in the underground construction site of the civil engineering construction site or underground construction site in order to prevent the soil cut down. After cutting one side of the soil with a fork-lane or the like, and digging the soil to a certain depth, the horizontal H-beam (1) on one side of the vertical H-beam (1) so that the vertical H-beam (1) does not fall to the digging side. 3) Secure it.

Then, the horizontal H beam 3 is supported by a support beam or the like not shown on the cut side.

After temporarily supporting the soil cut in this manner so as not to collapse, and after the cutting operation is completed, the soil cut by the vertical and horizontal H beams 1 and 3 may not be collapsed to the horizontal H beam 3. Through holes (not shown) are drilled at predetermined lengths, and the pressure plate 5 having the through holes 5a formed on the outside (cut side) of the through holes is fixed by welding or screwing.

Next, a through hole formed in the horizontal H beam 3 using a pneumatic drill toward the soil wall 7 through the through hole 5 a formed in the pressure plate 5 and the through hole formed in the horizontal H beam 3. After drilling a hole 9 of a predetermined depth toward the soil wall 7 through the steel wire 11, the steel wire 11 is introduced into the hole 9, and then cement mortar is injected to the mounting place in the hole 9 and grounded. To fix the steel wire 11 to soil or rock around the hole 9.

Thereafter, the anchor head 13 is fixed to the outside of the pressure plate 5, and then the choke 17 for holding the strand 11 in the plurality of choke insertion holes 13a formed in the anchor head 13. Insert).

Next, the lower array plate 201 of the steel wire guide arrangement plate 200 in which the steel wire 11 fixed by the choke 17 of the anchor head 13 is formed at the same position as the anchor head 13. Inserted into the through hole, the inserted steel wire 11 is penetrated at regular intervals to facilitate the installation of the tension cylinder vertically along the steel wire guide pipe 203 in the form of a spline curve so as not to cause damage or resistance due to friction. Holes protrude into the top array plate 205 rearranged in a circle.

At this time, in order to prevent bending or deformation of the stranded wire guide pipe 207, the middle portion of each steel wire guide pipe 203 is fixed by welding with a circular pipe fixing plate 207.

Tensile cylinder 100, first, as shown in Figure 5 is fixed to the steel wire guide array plate 200, removably, the steel wire 11 in the longitudinal direction of the center in the state in which the jaw grip sleeve 112 is contracted Is inserted. Subsequently, when hydraulic pressure is supplied to chamber A 132 through chamber A port 102, the piston 111 and jaw grip sleeve 112 are raised by the action of the hydraulic pressure, and the portion protrudes from cylinder 101. Is extended, and fluid is drained from the B chamber 131 via the B chamber port 103.

At the beginning of the expansion of the piston 111 and the jaw grip sleeve 112, the inner surface 114 of the cone (tilt) contacts the outer surface 124 of the cone (tilt), and the cam action strongly contracts the many jaws 121 toward the center. The steel wire 11 penetrates strongly through the center thereof, and then stretches until the hydraulic pressure of the chamber A 132 becomes a predetermined hydraulic pressure P, as shown in FIG. (11) becomes tension. Accordingly, in FIG. 5, each tension cylinder 100 has the same adjusted hydraulic pressure in each tension cylinder 100, even if steel wires 11 of different lengths are bited or the steel wires 11 have different elongations. It extends until it acts on this chamber A 132, and the force acting on the steel wire 11 is determined by the hydraulic action area of the piston 111, and the piston 111 and the jaw grip sleeve 112 protrude. Even if the distances are different from each other, the force acting on the steel wire 11 is the same.

As a result, the force can be evenly distributed to each steel wire so that concentrated load can be prevented and designed in a minimum quantity.

Then, when curing for the grounding is completed, to supply the hydraulic pressure through the chamber B port 103 to disassemble the static pressure strand cable tension cylinder 100, the hydraulic pressure acts on the chamber B (131) piston ( 111 and jaw gripping sleeve 112 contract from the state of FIG. 6, at which point gripping of steel wire 11 of choke 120 is released, thereby choking 120 is retracted together by choke carver 130. When the jaw opening portion 106 of the sleeve 105 is inserted into the insertion portion 122 provided at the lower end of the choke 120, the jaws 121 of the choke 120 are opened to make it easier. Not only can be dismantled, it is easy to insert the steel wire 11 when reworking.

The present invention is not limited to the above-described embodiments, and it will be apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

According to the hydraulic stranded tension device according to the present invention as described above, the gripping and tensioning of the steel wire can be made easily, and the installation and disassembly of the wire guide arrangement plate and the tension cylinder is also made simple, and with a simple structure Even if a plurality of steel wires can be stretched with the same force to take the same force even if they are different from each other or elongation, it is possible to evenly distribute the forces such as soil walls, shafts, etc. to each steel wire to collapse even a small number of steel wires It is possible to prevent the risk.

Claims (5)

In hydraulic stranded tensioning device, In order to minimize wear of the tensioned steel wires 11 and to secure space of the tensioning cylinders 100, a group of tension cylinders 100 installed correspondingly to each of the number of steel wires 11 exposed from the anchor head 13 may be placed. A steel wire guide array plate 200 extending in the shape of a truncated cone in the longitudinal direction of the steel wire 11; And The piston 111 is installed in the cylindrical cylinder 101 so as to be reciprocated while being in oiltight, and the cylinder 101 is separated into the A chamber 132 and the B chamber 131 by the piston 111. Tension cylinder 100 having chamber A 102 and chamber B 103 connected to chamber A 132 and chamber B 131. Hydraulic twisted pair tension apparatus comprising a. According to claim 1, wherein the truncated steel wire guide array plate 200; A lower heat dissipation plate 201 in which a through hole through which the steel wire 11 can penetrate is formed in a disc shape, and the choke 17 grips and releases the steel wire 11; An upper array plate 205 having the same number of through holes as the lower array plate 201 so as to be rearranged in a circle at intervals to facilitate the installation of the tension cylinder 100 vertically; A steel wire guide pipe 203 welded and fixed to lead the steel wire 11 penetrating the lower array plate 201 to each through hole of the upper array plate 205; A circular pipe fixing plate 207 fixed by welding an intermediate portion of the steel wire guide pipe 203; Hydraulic stranded tension device, characterized in that consisting of. The method of claim 1, wherein the tension cylinder (100); A bottom plate 104 which closes one side of the cylinder 101 and has a through hole through which the steel wire 11 passes; An outer circumferential surface is formed between the inner circumferential surface of the cylinder 101 so that the piston 111 is installed in an oil-tight and reciprocating manner, the steel wire 11 passes through the center, and is fixed to the bottom plate 104, and the cylinder ( A sleeve 105 formed to extend toward the other side of the 101 and having a jaw open portion 106 formed at an end thereof; A jaw grip sleeve (112) fixed to the piston (111) and protruding from the outer circumference of the sleeve (105) in an oil-tight and reciprocating manner through the other side of the cylinder (101); And When the jaw phage sleeve 112 is extended by the interaction with the conical (inclined) inner surface 114 of the jaw gripping sleeve 112, the conical outer surface for tightening the steel wire 11 passing through the center is strongly tightened. 124 is formed, the steel wire gripping surface 123 is configured to include a choke 120 consisting of a plurality of jaws 121 formed on the inner surface; A plurality of jaws 121 are formed on the jaw phage sleeve 112 at the inner surface of each protruding end, and the jaw opening of the sleeve 105 when the jaw phage sleeve 112 is contracted. An insertion portion 122 for releasing the steel wire 11 radially apart in interaction with the portion 106 is formed; A plurality of jaws (121) of the choke (120) is a hydraulic twisted pair tension device, characterized in that it is stably maintained by the elastic ring (125) on the outer peripheral surface of the choke (120). According to claim 1 or 2, wherein the steel wire guide array plate 200 is formed so that the steel wire 11 of different thicknesses penetrate; Hydraulic stranded tension device, characterized in that the number of the through-holes and the wire guide pipe 203 of the lower array plate 201, the upper array plate 205 through which the steel wire (11) is formed. 4. The tension cylinder according to claim 1 or 3, wherein the tension cylinder (100) is formed to hold steel wires (11) of different thicknesses; The sleeve 105 and the bottom plate 104 are integrally formed, and the piston 111 and the jaw grip sleeve 112 are integrally formed; Hydraulic stranded tension device, characterized in that the choke carver 130 is installed on the outside of the choke (120).

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