KR100897535B1 - Simutaneous multi wire tension cylinder - Google Patents

Abstract

The present invention provides a simultaneous multiple tensioner that introduces a tension force (to give tensile stress by pre-reaxially pulling the tension member formed in the concrete structure so that the stress generated by the load given to the concrete structure to a desired degree). In particular, by forming a fluid supply pipe of the anchoring cylinder to prevent the slip of the tension material to the inside, thereby preventing the interference between the fixing unit and the fluid supply pipe of the concrete structure inherently, without damaging the concrete structure A simultaneous multiple tensioner is provided to facilitate tensioning of a number of prestressing tension members. The configuration of the present invention is connected to the hydraulic pump to operate and form a fluid supply pipe on one side of the outer surface, the fluid discharge pipe on the other side, the central portion and the tension side cylinder formed a center hole for receiving and coupling the tension disk module; A fixing side cylinder coupled to one end of the tension side cylinder, and having a center hole for receiving the fixing disc module as a central end of the other end; The tension piston of the tension-side cylinder and the fixing-side cylinder are each formed with a passage for a fixing operation, and each of the flow passages is characterized in that they are interconnected.

Tensioner, concrete, tension material, cylinder, tension

Description

Simultaneous Multi-Tensioner {SIMUTANEOUS MULTI WIRE TENSION CYLINDER}

1 is a view showing a separate conventional simultaneous multiple tensioner.

2 is a view showing a state of use of a conventional simultaneous multiple tensioner.

Figure 3 is a perspective view of the simultaneous multiple tensioner according to the present invention separated in a partial partial cross-sectional state.

4 is a view showing the assembled state of the simultaneous multiple tensioner shown in FIG.

5A, 5B, 5C, 5D, 5E, and 5F are cross-sectional views showing operating states of the simultaneous multiple tensioner according to the present invention.

※ Explanation of code about main part of drawing ※

300: simultaneous multiple tensioner 310: tension side cylinder

310a: center hole 310a-1: coupling jaw

310b: fluid supply pipe 310c: fluid discharge pipe

311: tension piston 311a: flow path

312 piston movement prevention 320 320 fixing cylinder

320a: Euro 321: fixing piston

330: tension disk module 331: upper tension disk

331a: push pin 331b: elastic body

331c: push pin insertion hole 332: medium tension disk

332a: tension wedge 332b: tension wedge insertion hole

333: lower tension disk 333a: guide pin

333b: guide pin insertion hole 340: fixing disk module

341: fixing wedge pressurizing disk 342: fixing disk

342a: fixing wedge 342b: fixing wedge insertion hole

343: fixing support plate 344: tension member

350: concrete structure 351: fixing unit

The present invention provides a simultaneous multiple tensioner that introduces a tension force (to give tensile stress by pre-reaxially pulling the tension member formed in the concrete structure so that the stress generated by the load given to the concrete structure to a desired degree). In particular, by forming a fluid supply tube of the anchoring cylinder to prevent the slip of the tension material to the inside, thereby preventing damage to the concrete structure by blocking the source of the interference between the fixing unit and the fluid supply tube of the concrete structure. And a simultaneous multiple tensioner to facilitate tensioning of a number of prestressing tension members.

In general, concrete is strong against compressive stress but very weak against tensile stress. Therefore, when one concrete structure is pulled in the axial direction, the concrete structure is cut even if not a great force.

However, if the pre-tightening in the reaxial direction gives an even compressive stress to the concrete cross section, even if it is pulled in the axial direction, it is pretightened, so that the given compressive stress is reduced but no tensile stress is generated in the cross section. As the axial tensile stress increases, the compressive stress given in advance decreases gradually, finally to zero, and when the load increases again, a tensile stress occurs in the cross section, and when it reaches the fracture strength of the concrete, the structure is cut.

In other words, by tightening the concrete structure in the re-axial direction in advance to give a tensile stress to greatly expand the range to resist the tensile force.

The use of this principle in concrete is called prestressed concrete (PSC) and is often abbreviated as PS concrete, PSC or PC.

In addition, the compressive force given by tightening in advance is called prestress force, and the internal stress of the concrete cross section created by the prestress force is called prestress.

Therefore, the general definition of prestressed concrete is concrete that has secured the internal strength by the distribution and magnitude of the external force in advance so that the stress generated by a given load can be offset to a desired degree.

The most common method of applying prestress to the concrete cross section is the post tension method. In prestressed concrete, after the concrete is hardened, tension is applied to the tension material and the end part is fixed to the concrete to prevent the prestress. How to give.

The tension member is a high tensile strength steel (strand wire), and is referred to as a PSC steel or a prestressed tension member separately from reinforcing bars.

Since the ultimate purpose of the prestress is to introduce favorable stresses or deformations in the structure, the prestressed concrete pre-tensions the tension member and compresses the concrete to prevent elongation caused by the design load or the overload, and the concrete caused by the tensile stress. To prevent cracking.

Conventional simultaneous multiple tensioner used to tension the tension member formed in such a concrete structure to have a permanent prestress, as shown in Figure 1, in connection with the hydraulic pump (not shown), the tension piston (111) inside And a fluid supply pipe 110b on one side of the outer surface, and a fluid discharge pipe 110c on the other side thereof, and a push pin 131 as a center portion and an upper tension disk 132 for receiving the push pin 131. A tension disk module comprising a tension wedge 133, an intermediate tension disk 134 for receiving the tension wedge 133, a guide pin 135, and a lower tension disk 136 for receiving the guide pin 135. A tension side cylinder (110) forming a center hole (110a) for accommodating and engaging with (130); It is coupled to one side of the tension side cylinder 110, the other end portion of the fixing wedge pressing disk 141, fixing wedge 142 and fixing disk 143 to easily fix the tension member 144 to the concrete structure It consists of a fixing side cylinder 120 for receiving a fixing disk module 140 made of a).

However, the conventional simultaneous multiple tensioner 100 configured as described above, as shown in Figure 2 during the tensioning operation of the tension member 144, in the fixing unit 351 of the concrete structure 350, the fixing side cylinder There was a problem that the fluid supply pipe (120a) for fixing is formed on one side of the outer surface of 120 can not be achieved smoothly.

Therefore, in order to smooth the tension work, there is a problem in that the fixing unit 351 of the concrete structure 350 that interferes with the fluid supply pipe 120a of the fixing side cylinder 120 or the cut-off part only needs to be cut.

Accordingly, there is a problem that the work time is long, deteriorates the quality of the concrete structure, increases the weight of the simultaneous multiple tensioner and increases the cost.

In addition, each disk of the tension disk module and the fixing disk module is arranged such that the holes for receiving the tension and fixing wedges are roughly pentagonal or polygonal.

Therefore, stress is concentrated in the conventional tension disk module and the fixing disk module, which causes problems such as damage or destruction of the disk, or hastening the replacement time of the disk.

Accordingly, the present invention was created to solve the above problems, and an object of the present invention is to block the interference of the concrete structure and the multiple tensioner at the same time, so that the tension work can be quickly and easily without damaging or changing the design of the concrete structure. In order to achieve this, it is to provide a simultaneous multi-tensioner to achieve the improvement of the quality of the concrete structure, the improvement of work efficiency and the cost reduction due to the damage of the concrete structure.

Another object of the present invention is to provide a simultaneous multiple tensioner to simplify the pipe in and out of the fluid to reduce the convenience and weight of the operation.

It is still another object of the present invention to provide a simultaneous multiple tensioner for arranging the holes of the tension disk module and the fixing disk module in a circular shape to significantly reduce stress concentration and to improve durability.

The present invention for achieving the above object is connected to the hydraulic pump operates to form a fluid supply pipe on one side, the fluid discharge pipe on the other side, the center portion to form a center hole for receiving and coupling the tension disk module With tension side cylinder; A fixing side cylinder coupled to one end of the tension side cylinder, and having a center hole for receiving the fixing disc module as a central end of the other end; The tension piston of the tension-side cylinder and the fixing-side cylinder are each formed with a passage for a fixing operation, and each of the flow passages is characterized in that they are interconnected.

Optionally, the fixing operation of the simultaneous multiple tensioner is performed by supplying the fluid through the flow path of the tension piston to the flow path of the fixing side cylinder by the settling pressure generated during the locking of the fluid supply pipe and the opening of the fluid discharge pipe. It is characterized in that it is made by operating the fixing piston.

In addition, each of the holes formed in the tension disk module and the fixing disk module is characterized in that arranged in a circle.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

3 is a perspective view showing the simultaneous multiple tensioner in partial partial cross-sectional state according to the present invention, Figure 4 is a view showing the assembled state of the simultaneous multiple tensioner shown in FIG.

As shown in the respective figures, the simultaneous multiple tensioner 300 of the present invention, the tension side cylinder 310, the tension side cylinder 320 and the tension disk module coupled to the tension side cylinder 310 ( 330).

The tension side cylinder 310, the lower side is formed with a center hole (310a) having a coupling jaw 310a-1 for coupling with the tension disk module 330, the hydraulic pump (not shown) on one side of the outer peripheral surface ) Is connected to the fluid supply valve formed on the hydraulic pump and the fluid discharge valve (not shown) by the on / off operation of the fluid supply pipe 310b is formed, the other side is a fluid for discharging the introduced fluid The discharge pipe 310c is formed.

The tension piston 311 which is moved by the fluid introduced through the fluid supply pipe 310b is accommodated in the tension side cylinder 310, and the fluid supply is provided in the tension piston 311. In the locking operation of the tube 310b and opening of the fluid discharge tube 310c, a flow path 311a through which the fluid moves is formed.

At one end side of the tension side cylinder 310, the piston support 312 is coupled by a fastener (b) to prevent the tension piston 311 to move more than a certain distance when moving by the hydraulic pressure.

In addition, the fixing cylinder (320) is formed in engagement with the lower end of the tension piston (311).

One side of the upper surface of the fixing side cylinder 320 is formed with a flow path 320a which is connected to the flow path 311a formed in the tension piston 311, and inside the fluid flows through the flow path 320a. The fixing piston 321 which moves by is formed.

A center hole 320b for accommodating the fixing disk module is formed at the other end central portion of the fixing side cylinder 320.

The flow path 311a formed in the tension piston 311 coupled to the tension side cylinder 310 and the flow path 320a formed in the fixing side cylinder 320 may be locked with the fluid supply pipe 310b. At the same time, during the opening operation of the fluid discharge pipe 310c, the fluid is moved to push the fixing piston 321 of the fixing side cylinder 320.

Thus, by forming the flow path 311a in the tension piston 311 of the tension side cylinder 310, and also forming the flow path 320a so that the fixation side cylinder 320 may communicate with the flow path 311a, When the fixing piston 321 can be moved, when the tension member 344 installed through the fixing disk module 340 accommodated in the center hole 320b formed at the center of the other end of the fixing side cylinder 320, The fixing wedge 342a of the fixing disk module 340 separated from the conical hole 342b of the fixing disk 342 along the tension members 344 can be easily and effectively fixed.

Accordingly, in addition to the fluid supply pipe conventionally formed on the tension side cylinder for tension, the fluid supply pipe that has been separately formed on one side of the outer surface of the fixing side cylinder for the fixing operation can be eliminated.

In addition, by eliminating the fluid supply pipe formed in the fixing cylinder, it is possible to prevent the occurrence of interference between the fixing unit 351 of the concrete structure 350 and the fluid supply pipe formed in the fixing cylinder at the time of tension work, Tension of the tension member 344 can be achieved without damaging and changing the fixing unit 351 of the concrete structure 350.

That is, since the fluid supply pipe formed on one side of the outer surface of the conventional fixing side cylinder can be removed, when the simultaneous multiple tensioner 300 is seated on the fixing unit 351 of the concrete structure 350, the fluid supply pipe Interference between the fixing unit and the fixing unit is prevented at the source, thereby quickly and easily performing tension work without damaging the fixing unit 351 of the concrete structure 350 or changing the design.

In addition, by removing the fluid supply pipe formed on one side of the outer surface of the fixing cylinder, the weight of the simultaneous multiple tensioner is reduced.

 In addition, the tension disk module 330 has a lower tension disk 333 having a guide pin insertion hole 333b into which a guide pin 333a for guiding the tension member 344 straightly tensioned and fixed is inserted at the bottom thereof. A middle tension having a tension wedge insertion hole 332b formed in a conical shape to receive a tension wedge 332a which firmly supports the tension member 344 inserted through the guide pin 333a. The disk 332 is formed, and the tension wedge 332a while pressing the tension wedge 332a while being stretched so that the tension member 344 can be easily inserted into the tension wedge 332a above the intermediate tension disk 332. An upper tension disk 331 having a push pin 331a having an elastic body 331b and a push pin insertion hole 331c for receiving the push pin 331a.

Here, the tension wedge 332a is composed of a plurality of wedges are combined into one wedge.

The conical formation of the tension wedge 332a and the tension wedge insertion hole 332b forms a solid support when accommodating the tension member 344, and provides a binding and separation property for easy separation after the tension work is completed. This is to make it good.

The intermediate tension disk 332 and the upper tension disk 331 are formed to be coupled at intervals to facilitate the operation of the push pin 331a by the elastic force.

That is, when the tension member 344 is inserted into the tension disk module 330, when the push pin 331a of the upper tension disk 331 is pressed, an elastic body 331b supporting the push pin 331a is provided. Is formed at a distance so that it can be easily stretched operation.

When the push pin 331a is pressed, the push pin 331a presses one end of the tension wedge 332a, and the tension wedge 332a opens to widen the interval.

At this time, when the tension member 344 is easily inserted, and after being completely inserted, when the pressing operation of the pressing pin 331a is released, the tension wedge 332a is widened and the hole is narrowed back to its original position. To firmly support the tension member 344.

In addition, the tension disk module 330 of such a configuration, when the tension side cylinder 310 is moved to the rear when the tension, the tension wedge 332a is automatically moved to the rear at the same time in conjunction with this tension tension ( 344) with strong adhesion.

On the contrary, when the tension side cylinder 310 moves forward, the push pin 331a coupled to the upper tension disk 331 of the tension disk module 330 simultaneously moving forward in conjunction with this tension wedge ( 332a is pressed, and the tension wedge 332a slightly releases the tension member 344, which is firmly supported, so that the tension wedge 332a is easily separated from the tension member 344.

In addition, the holes formed in the tension disk module 330 and the fixing disk module 340 are arranged to form a circular shape, so that they are arranged to form a substantially pentagon, or compared to the structure arranged to form a polygon, Upon receipt, less stress was concentrated in each of the holes.

When the concentration of the deformation force is reduced in this manner, the cause of breakage or breakage of each disc having a hole for accommodating the tension member 344 is significantly reduced, thereby prolonging the replacement time of the disc.

Referring to Figures 5a 5b, 5c, 5d, 5e, 5f the operating state of the simultaneous multiple tensioner according to the present invention configured as described above are as follows.

First, the fixing support plate 343 and the fixing disk 342 are inserted into the tension members 344 to be tensioned in the fixing unit 351 of the concrete structure 350, and the respective tension members 344 are sequentially inserted. After inserting the fixing wedge 342a while pulling tautly, the fixing support plate 343 is installed as close as possible.

Next, the anchoring wedge pressing disk 341 is inserted at the end of the tension member 344 and aligned so that the arrangement of the simultaneous multiple tensioner 300 matches the arrangement of the tension member 344.

The tension disk module 330 coupled to the inner diameter of the tension-side cylinder 310 after aligning the simultaneous multiple tensioner 300 in which the cylinder is operated two to three times in advance with the arrangement of the tension member 344. The tension member 344 is inserted through the guide pin 333a and the lower tension disk 333 of the upper tension disk 331, and then the pressing pin 331a of the upper tension disk 331 is pressed to The tension member 344 is easily inserted by widening the inner diameter of the tension wedge 332a formed in the conical hole 332b.

After the tension member 344 is completely inserted into the upper tension disk 331, the pressing pin 331a is released, thereby allowing the tension wedge 332a to firmly support the tension member 344. .

At this time, one end of the fixing side cylinder 320 of the simultaneous multiple tensioner 300 is first in close contact with the fixing wedge pressurizing disk 342, and also close to the fixing support plate 343 as close as possible to complete the tension work preparation do.

When the preparation for tension work is completed as described above, the hydraulic pump (not shown) is operated to supply fluid through the fluid supply pipe 310b formed at one side of the outer circumferential surface of the tension side cylinder 310 of the simultaneous multiple tensioner 300. do.

The tension side cylinder 310 coupled with the tension piston 311 moves rearward.

Accordingly, the tension members 344 firmly supported by the tension disk module 330 are also tensioned at the same time.

At this time, the fixing wedge 342a is also separated from the conical hole 342b of the fixing disk 342 while slightly moving backward along the tension members 344.

This tension operation is the hydraulic pump after the tension side cylinder 310 is moved to the rear to the maximum movement distance of the tension piston 311, or after obtaining the required elongation amount or the total required tension amount of the tension member 344, The fluid supply valve of the valve is turned off to stop the fluid supply and simultaneously open the fluid discharge valve.

Accordingly, the fluid supplied into the tension side cylinder 310 escapes through the fluid discharge pipe 310c by the locking operation of the fluid supply valve and the opening operation of the fluid discharge valve, and at the same time, the tension piston 311. It is also moved through the flow path 311a formed in the interior. At this time, the pressure does not exceed 100kg f / ㎠ (10MPa).

In this way, the fluid moving through the flow path 311a formed in the tension piston 311 enters the flow path 320a of the fixing side cylinder 320 which is connected to the flow path 311a of the tension piston 311. Done.

At this time, the fluid entering the flow path 320a of the fixing side cylinder 320 moves the fixing piston 321.

The fixing piston 321 presses the fixing wedge pressing disk 341 and the fixing wedge pressing disk 341 is a conical hole 342b of the fixing disk 342 along the tension members 344. The fixing wedge 342a, which has been separated from it, is pushed so that the fixing wedge 342a is fitted into the conical hole 342b, thereby biting the tension members 344, thereby establishing the fixation.

When the fixing operation is completed as described above, the fluid supply valve and the fluid discharge valve of the hydraulic pump are simultaneously opened to simultaneously supply and discharge the fluid.

 Accordingly, the tension side cylinder 310 is moved rearward by the fluid supplied, and the fixing piston 321 of the fixing side cylinder 320 is discharged to the fluid discharge pipe 310c through the flow path 320a. To move backward along the fluid.

After the tension side cylinder 310 and the fixing piston 321 are completely retracted, the simultaneous multiple tensioner 300 is separated to complete the tensioning operation.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes to other exemplary embodiments may be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art to which the invention pertains.

As described above, according to the simultaneous multiple tensioner according to the present invention, it is possible to effectively achieve the tension work of the concrete structure without damaging and changing the design of the concrete structure, there is an effect to improve the stability of the concrete structure.

In addition, by eliminating the occurrence of interference between the fixing unit formed in the concrete structure and the fluid supply pipe formed in the cylinder on the fixing side, the work can be performed quickly, easily and more precisely.

In addition, there is an effect of simplifying the pipe from which the fluid supplied from the hydraulic pump flows in and out, thereby making it easier to operate and at the same time lighter in weight, thereby making the installation and transportation of the simultaneous multiple tensioner easier.

In addition, there is an effect of extending the replacement time of the tension disk and the fixing disk and at the same time reducing the risk of breakage or breakage.

Claims (3)

It operates in connection with the hydraulic pump and forms a fluid supply pipe 310b on one side of the outer surface, a fluid discharge pipe 310c on the other side, and a center hole 310a for receiving and coupling the tension disk module 330 to the center portion. A tension side cylinder 310 formed; A fixing side cylinder 320 coupled to one end of the tension side cylinder 310 and having a center hole 320b for accommodating the fixing disc module 340 as a central end of the other end; Including, The tension piston 311 of the tension side cylinder 310 is formed with a flow path 311a for a fixing operation, and the fixing side cylinder 320 has a flow path 320a for a fixing operation, and the respective flow paths ( 311a), 320a are interconnected. According to claim 1, The fixing operation of the simultaneous multiple tensioner 300, through the flow passage 311a of the tension piston 311 at the time of locking the fluid supply pipe 310b and opening the fluid discharge pipe 310c. Simultaneous multiple tensioner, characterized in that made by operating the fixing piston 321, as supplied to the flow path (320a) of the fixing side cylinder (320). 2. The simultaneous multiple tensioner as claimed in claim 1, wherein each of the holes formed in the tension disk module (330) and the fixing disk module (340) is arranged to have a circular shape.

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