KR102393689B1 - The prestress hollow steel bar transforming by jacking force synchronizing tension and compression, self-prestress method reinforcing facilities using the same - Google Patents

Abstract

The present invention relates to a prestressed hollow steel bar introducing prestress force by linking tension and compression. A solid PS steel bar is inserted into a hollow PS steel pipe. The hollow PS steel pipe has a dead anchorage device and a screw drive anchorage device closely installed at both ends thereof. Stroke and pressure generated by the operation of a hydraulic device installed in a bi-jacking jig causes compressive strain on the solid PS steel bar, and tension is generated in the bi-jacking jig. Using the dead anchorage device and an abutment as reaction supports, tensile strain occurs in the hollow PS steel pipe in the section. The tensile strain is controlled through reaction so that the compressive strain acting on the solid PS steel bar is recovered. A bi-prestress force introduction mechanism links both tension and compression. Therefore, the prestressed hollow steel bar can use only one screw drive anchorage device to pressurize and restrain the solid PS steel bar inserted into the hollow PS steel pipe, thereby having a simple structure.

Description

A prestressed hollow PS steel bar that introduces prestressing force by interlocking tension and compression, and a method of introducing prestress to a facility using the same. SAME}

The present invention relates to a hollow PS steel bar body in which a prestress force is introduced by simultaneously interlocking pressurization, gain and reaction force of a steel pipe and a steel bar equipped with a screw live and a dead fixing device, and the section extension and load-bearing capacity enhancement And it relates to a method of introducing prestress into a facility such as a concrete structure or slope reinforcement that requires stability enhancement.

1 is a cross-sectional view showing a conventional pre-stress introduced hollow PS steel bar and a fixing structure.

As shown, the anchor bolt for stress introduction is disclosed in Patent Document 1, the hollow PS steel bar 10 and the end coupled to one end of the hollow PS steel bar 10 to close one end of the hollow PS steel bar 10 A holder 20, an anchor nut 30 and a tube 40 sequentially coupled to the outside of the other end of the hollow PS steel bar 10, and one end is in close contact with the end holder 20 and the other end is a hollow PS steel bar The reaction force PS steel rod 50 inserted into the hollow PS steel rod 10 to have a structure protruding from the other end of (10), and the reaction force PS steel rod 50 protruding from the hollow PS steel rod 10 Close to the end The press-fit piece 60 disposed inside the ear tube 40 as much as possible, and the press-fit piece 60 to keep the press-fit piece 60 in close contact with the reaction force PS steel bar 50 while preventing the detachment of the press-fit piece 60, the ear tube 40 It is composed of a stopper 70 fastened to the and resin filling the space between the hollow PS steel rod 10 and the reaction force PS steel rod 50 .

The pre-stress introduction hollow PS steel bar 10 and the mounting structure configured as described above are in a state in which the hollow PS steel bar 10 is fixed using an anchor nut 30, and the reaction force PS steel bar 50 is coupled to one end of the end holder 20 After adhering to the reaction force PS steel bar 50, when the press-fitting rod and the press-fitting piece 60 installed at the other end are pressed and advanced using the press-fitting rod and hydraulic device, the reaction force PS steel bar 50 is the press-fitted piece 60 and the end holder. It is compressed between (20).

In this state, when the stopper 70 is moved forward while being screwed to the ear tube 40 to bring the press-fit piece 60 into close contact, the reaction force PS steel bar 50 maintains the compressed state as it is, and the hydraulic device is removed. When the reaction force PS steel bar 50 is transferred to the hollow PS steel bar 10, the prestress introduced hollow PS steel bar 10 and the fixing structure, which maintains the state in which the tensile force, which is the reaction force, acts, the above state The maintained prestressed hollow PS steel bar 10 and the fixing structure are shipped from the factory.

In field work that requires cross-section expansion, strength enhancement, and synthesis with other members, the prestressed hollow PS steel bar 10 is placed in a required position, that is, the end holder 20 of the prestressed hollow PS steel bar 10 is drilled in the existing structure. Abut the end of the section or a fixed position where prestress introduction is required, and the other end anchor nut 30 of the prestressed hollow PS steel bar 10 is installed up to the live position where expansion or prestress introduction is required, and then the perforated section or the expanded section is concrete After pouring and injection with mortar or the like, curing to a predetermined strength and fixing is completed, when the stopper 70 fastened to the end of the ear tube 40 is separated from the ear tube 40, the press-fitting piece 60 At the same time, the compressive force applied to the reaction force PS steel bar 50 is released through the As it is compressed while transitioning, prestress is introduced into the surrounding facilities.

The anchor bolt for stress introduction according to Patent Document 1 is a device that transfers the compressive force introduced to the reaction force PS steel bar 50 to the hollow PS steel bar 10 to act as a tensile force, and the hollow PS steel bar 10 introduced There are problems in that the release device for introducing the prestress to the surrounding facilities is complicated, and the release of the PS steel bar 50 is not easy due to the time delay and the reaction force due to the step-by-step process.

That is, the pre-stress introduction anchor bolt according to Patent Document 1 is a reaction force PS steel bar 50 installed inside a state in which the anchor nut 30 and the second tube 40 are screwed to the other end of the hollow PS steel bar 10 is a press-fit piece. (60) and the pressing force is transmitted through the press-fit rod and compressed, and the reaction force PS steel bar 50 and the press-fit piece 60 in this state are fixed in close contact with the stopper 70 into the inside of the ear tube 40 by screwing. It will be produced by

In addition, the introduction of prestress to the surrounding facilities through the prestress introduction anchor bolt is to fix the prestress introduction anchor bolt to the structure to be expanded and reinforced through the anchor nut 30, and then release the stopper 70 from the tube 40 , the prestress is introduced into the facility through a process such as separating the tube 40 from the hollow PS steel bar 10 .

In the prior art, the fixing structure for introducing prestress is in close contact with the anchor nut 30, so that the tube 40 is screwed to the end of the hollow PS steel bar 10, and the stopper 70 is screwed to the tube 40, etc. 2 There is a problem in that it has a complicated structure, such as a device configuration and double screw coupling.

And when releasing, there is a problem in that it is complicated in two steps, such as separating the stopper 70 from the outer tube 40 and separating the outer tube 40 from the hollow PS steel bar 10 .

Transmission of the pressing force through the hydraulic device to the reaction force PS steel bar 50 is the press-fitting piece and the press-fit rod, and the end of the reaction force PS steel bar 50 is in the hollow PS steel bar 10, so the pre-stress introduction into the facility is completed.

Therefore, the anchor bolt for stress introduction according to Patent Document 1 has a problem in that the manufacturing cost and construction cost are high because there are many components and processes, and the defect rate is increased due to many assembly parts and parts.

As described above, the reaction force steel bar inserted into the hollow steel bar is closely attached to the end holder coupled to one end, and then the press-fit rod and press-fit piece installed at the other end of the reaction force steel bar are pressed forward using the press-fit rod and hydraulic device. The conventional mechanism for compressing the reaction force bar between the end holders while transferring the compressive force to the hollow PC steel bar to apply the tensile force in one direction applies the compressive force to the reaction force bar in one direction, and the force is transferred to the hollow steel pipe to apply the tensile force. Accordingly, the loss due to elastic contraction of the hollow PS steel pipe increases, and the pressing force needs to be further increased, and it is difficult to reuse it due to plasticization due to the increase in the buckling phenomenon on the reaction force PC steel rod by the pressing force.

In addition, if the pressure is applied without a jacking jig, the axis of the hydraulic device, the pressure bar, the press-fit pin, and the reaction force PC steel bar do not match, so it is difficult to introduce the pressure as much as the design control value due to the occurrence of lateral buckling.

Japanese Laid-Open Patent Publication No. 2008-121226 (published on May 29, 2008)

The problem to be solved by the present invention is to insert a solid PS steel bar into a hollow PS steel pipe and then install a hollow PS steel pipe in close contact with both ends with a dead fixing device and a screw live fixing device, operating a hydraulic system installed in a bi-jacking jig The stroke and pressure generated by this cause compressive deformation in the solid PS steel bar, and generate tensile force in the bi-jacking jig to set the dead fixing device and the abutment as the reaction force, causing tensile deformation in the hollow PS steel pipe in the above section, The bi-prestress force introduction mechanism, which controls the deformation through the reaction force that the compressive deformation applied to the solid PS steel bar tries to recover, simultaneously interlocks the tension and compression, so that the compression deformation of the solid PS steel bar and the tensile deformation of the hollow PS steel pipe are designed It is to provide a prestressed hollow PS steel bar with a prestressed force that is manufactured to minimize loss by tightening the screw live fixing device in the abutment direction as much as the pressure stroke when it occurs as much as management.

Another solution of the present invention is to install and fix the prestressed hollow PS steel bar in the cross-section extension and ground reinforcement facility, and then simply release the screw live fixing device, the prestress force introduced into the steel pipe body is applied to the reinforcement facility By allowing pre-stress to be introduced while transitioning, to increase strength and to offset external stress, tension management is unnecessary at the site, and since there is no need for a jack for tension, it can be constructed in a narrow place, and it is economical because it does not require a large fixing device. , to provide a method for introducing prestress into a facility that further improves the convenience and accuracy of construction.

According to the present invention, a hollow PS steel bar body into which a pre-stress force is introduced by interlocking tension and compression includes: a hollow PS steel pipe 100 having an inner space open at both ends; A dead fixing device 200 coupled to close one end of the hollow PS steel pipe 100 and; It is inserted into the hollow PS steel pipe 100, one end is in close contact with the dead fixing device 200, and the other end protrudes more than a pressing stroke outward from the other end of the hollow PS steel pipe 100, and when pressurizing, the hollow PS steel pipe 100 ) and a solid PS steel bar 300 that is contracted to the inside; While positioning the solid PS steel bar 300 and the press-fitting support piece 600 inside, it has a space hole larger than the pressure stroke and is screwed to a part of the outer surface of the other end of the hollow PS steel pipe 100 and pressurizes the solid PS steel bar 300 a screw-live fixing device 400 in which a pressure rod hole 430 is formed to allow the rod 1400 to enter and exit; An abutment 500 that is screwed to the other end of the hollow PS steel pipe 100 and protrudes outward at a position spaced apart from the screw-live fixing device 400 by more than a pressurized stroke to serve as a reaction arm and a fixing device; and ; While positioned between the inner surface of the pressing jaw 420 of the screw live fixing device 400 and the solid PS steel rod 300, it is in close contact with the other end of the solid PS steel rod 300 to evenly deliver the pressurized pressure to the solid PS steel rod 300 It characterized in that it comprises a; press-fit support piece (600).

Preferably, it further comprises a bi-jacking jig 1000 for introducing a pre-stress force to the hollow PS steel rod body, wherein the bi-jacking jig 1000 is a jacking transmission side plate 1110 installed on both sides in the longitudinal direction, and jacking transmission A case 1100 including a jacking support plate 1120 installed horizontally from the lower portion of the side plate 1110, and a jacking pressure plate 1130 installed horizontally from an upper portion of the jacking transmission side plate 1110, and having a hollow inside; ; a through hole 1200 through which the hollow PS steel pipe 100 is mounted through the jacking support plate 1120 of the case 1100; A hydraulic cylinder 1300 for jacking pressure installed in contact with the inner surface of the jacking pressure plate 1130 of the case 1100 and; It includes a pressing rod 1400 extending downward from the hydraulic cylinder 1300 to press the solid PS steel rod 300 mounted in the through hole 1200, and the jacking support plate 1120 of the bi-jacking jig 1000 and Hollow PS steel pipe 100, dead fixing device 200, solid PS steel bar 300, press-fitting support piece 600, abutment 500, screw live fixing device 400 between jacking hydraulic plate 1130 By placing this combined hollow PS steel bar body between the jacking support plate 1120 and the jacking pressure plate 1130 of the bi-jacking jig 1000, the abutment 500 is attached to the jacking support plate 1120 of the case 1100. In a state in which the lower part of the hollow PS steel pipe 100 is installed to pass through the through hole 1200, the pressure of the hydraulic cylinder 1300 is transferred to the press-fitting support piece 600 through the pressure rod 1400 to be solid. When the PS steel bar 300 is pressurized, the pressing force transmitted by using the closed dead fixing device 200 as a reaction force causes the solid PS steel bar 300 to compressively deform, and the solid PS steel bar 300 ) in conjunction with the resistance reaction force that generates the compression deformation, the pressure stroke generates a tensile force in the bi-jacking jig, and at the same time, the dead fixing device 200 and the abutment 500 are used as the reaction force, and the device Tensile deformation is generated by the tensile force in the hollow PS steel pipe 100 between them, and the elastic reaction force of the solid PS steel bar 300 that has undergone compressive deformation by pressing this tensile deformation controls the tensile deformation recovery. , characterized in that it has a mechanism for allowing the prestress force to act on the hollow PS steel pipe 100 .

On the other hand, it is easy to introduce prestress without jacking and fixing work in the field to reinforcing facilities that require cross-section expansion and enhancement of strength and load-bearing capacity of hollow PS steel rods with manufactured pre-stressing force. Positioning the rear end of the prestressed hollow PS steel pipe 100 to protrude from the drilling hole by attaching the front end of the hollow PS steel pipe 100 and the dead fixing device 200 to the inner end of the drilling hole; To fix the prestressed hollow PS steel pipe 100 to the drilling hole by first injecting a grouting agent into the drilling hole so that the front end of the prestressed hollow PS steel pipe 100 installed in the drilling hole and the dead fixing device 200 are fixed to the drilling hole step; When the front end of the prestressed hollow PS steel pipe 100 is fixed to the drilling hole, the rear end of the prestressed hollow PS steel pipe 100 protruding from the drilling hole to communicate with the lower drilling hole is installed, but the prestressed hollow PS steel pipe 100 is installed at the other end of the The tension force formed in the tension hollow PS steel pipe 100, including the step of performing the cross-section extension so that the butt is located at a certain depth on the end surface of the cross-sectional extension part to form the anchorage, is dead anchoring device 200 and the abat It is characterized in that the prestress is introduced to the facility while transitioning between the ment 500.

In addition, the manufactured hollow PS steel bar with pre-stress force is installed on slopes, rocky areas, and facilities that require increased load-bearing capacity and stability in facilities requiring increased strength, but the diameter at which the abutment 500 is inserted into the facility forming an upper drilling hole (H2) of the , and forming a lower drilling hole (H1) having a smaller diameter than the upper drilling hole (H2) while communicating with the upper drilling hole (H2); The step of attaching the dead fixing device 200 of the prestressed hollow PS steel pipe 100 to the inner end of the lower drilling hole H1, and inserting the abutment 500 into the upper drilling hole H2 so that the abutment 500 is in close contact with the fixing step and ; Injecting a grouting agent, etc. into the lower drilling hole (H1) and curing it to a predetermined strength to integrate the front end of the prestressed hollow PS steel pipe 100 and the dead fixing device 200 into the facility; The tension force formed in the tension hollow PS steel pipe 100 including the step of releasing and separating the screw coupling from the tension hollow PS steel pipe 100 by rotating the screw live fixing device 400 is the dead fixing device 200 and the abat It is characterized in that the prestress is introduced to the facility while transitioning between the ment 500.

The present invention has the advantage of a simple configuration because it can be used only with one screw-live fixing device to pressurize and constrain the solid PS steel bar inserted into the hollow PS steel pipe.

In addition, since the operation of separating the screw-live fixing device consists of one step of separating the screw-live fixing device by rotating the tension hollow PS steel pipe, there is an advantage that the separation operation is performed quickly.

In addition, there is no need for on-site tension management for the tension hollow PS steel pipe, and since there is no need for a jack for tension, it can be installed even in a narrow place, and economic efficiency, convenience and accuracy of construction can be improved because it does not need a large fixing device. there is.

In addition, since the prestressed hollow PS steel bar manufactured in the factory is shipped in a tense state, it is not necessary to perform tension work for installation in facilities that require increased load-bearing capacity and stability in the slope or rocky area.

In addition, since tension hollow PS steel pipes with pre-stress force introduced in the factory are manufactured uniformly, constant and accurate pre-stress introduction performance can be expected.

In addition, it is possible to significantly improve the adhesion ability and corrosion resistance of the surrounding ground or structures by injecting a grouting agent into the hollow PS steel pipe from which the solid PS steel bar has been removed.

In addition, since it can be separated very quickly by rotating the screw live fixing device screwed to the tension hollow PS steel pipe, prestress can be quickly introduced to the surrounding or attached facilities and structures, so that the efficiency of field work is improved. can be greatly improved.

In addition, compression deformation in the solid PS steel bar, tensile deformation in the hollow PS steel pipe due to the tensile force in the bi-jacking jig, and the bi-prestress force to control the tensile deformation through the reaction force that the compressive deformation applied to the solid PS steel bar tries to recover As the mechanism is simultaneously interlocked, it is possible to pursue the optimal pre-stress introduction technology that maximizes the effective pre-stress force and achieves the minimum pressing force by significantly minimizing the amount of elastic contraction loss compared to the prior art.

In addition, there is an effect that can be reused by preventing the buckling phenomenon and plasticization occurring in the solid PS steel bar through the minimum pressing force.

In addition, since the tension force is introduced using a bi-jacking jig, the hydraulic device, pressure bar, press-fit pin and solid PS steel bar axis can match, so it is an effective technology to introduce tension force by controlling lateral buckling, It has the effect of securing the first technicality of tension by simultaneously interlocking the tension and tension in both directions.

1 is a cross-sectional view showing a conventional pre-stress introduced tension hollow PS steel bar and a fixing structure.
Figure 2a is a cross-sectional view of a hollow PS steel bar before the solid PS steel bar is compressed according to an embodiment of the present invention.
Figure 2b is a cross-sectional view of a hollow PS steel bar after the solid PS steel bar is compressed according to an embodiment of the present invention.
Figure 3a is a cross-sectional view of a hollow PS steel bar before the solid PS steel bar is compressed according to another embodiment of the present invention.
Figure 3b is a cross-sectional view of a hollow PS steel bar after the solid PS steel bar is compressed according to another embodiment of the present invention.
Figure 4 is an exploded perspective view of Figure 2;
Figure 5 is a perspective view of the coupled state of Figure 2a.
6 is a plan view of a bi-jacking jig according to the present invention;
7a is a cross-sectional view showing a state before the hydraulic device installed on the bi-jacking jig according to the present invention interlocks the compression of the solid PS steel bar and the tension of the hollow PS steel pipe at the same time.
Figure 7b is a cross-sectional view showing a state in which the hydraulic device installed in the bi-jacking jig of the present invention is simultaneously interlocked with the compression of the solid PS steel bar and the tension of the hollow PS steel pipe.
Figure 7c is a cross-sectional view showing a state in which the screw-live fixing device is installed after the hydraulic device installed in the bi-jacking jig of the present invention simultaneously interlocks the solid PS steel bar compression and the hollow PS steel pipe tension.
8a and 8b are exemplary views showing a process in which prestress is introduced during cross-section expansion using the prestressed hollow PS steel bar of the present invention;
9a and 9b are exemplary views showing a process in which prestress is introduced when reinforcing the ground using a prestressed hollow PS steel bar according to the first embodiment of the present invention;

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

2 to 5, the prestressed hollow PS steel bar of the present invention includes: a hollow PS steel pipe 100 in which the inner space is opened at both ends; A dead fixing device 200 coupled to close one end of the hollow PS steel pipe 100 and; It is inserted into the hollow PS steel pipe 100, one end is in close contact with the dead fixing device 200, and the other end protrudes more than a pressing stroke outward from the other end of the hollow PS steel pipe 100, and when pressurizing, the hollow PS steel pipe 100 ) and a solid PS steel bar 300 that is contracted to the inside; While positioning the solid PS steel bar 300 and the press-fitting support piece 600 inside, it has a space hole larger than the pressure stroke and is screwed to a part of the outer surface of the other end of the hollow PS steel pipe 100 and pressurizes the solid PS steel bar 300 a screw-live fixing device 400 in which a pressure rod hole 430 is formed to allow the rod 1400 to enter and exit; An abutment 500 that is screwed to the other end of the hollow PS steel pipe 100 and protrudes outward at a position spaced apart from the screw-live fixing device 400 by more than a pressurized stroke to serve as a reaction arm and a fixing device; and ; While positioned between the inner surface of the pressing jaw 420 of the screw live fixing device 400 and the solid PS steel rod 300, it is in close contact with the other end of the solid PS steel rod 300 to evenly deliver the pressurized pressure to the solid PS steel rod 300 It includes a press-fitting support piece (600). At this time, the screw-live fixing device 400 of the hollow PS steel bar body is introduced into the prestressed hollow PS steel bar body by maintaining the state before pressurization and restraining the prestress force introduced by the bi-prestress force tension mechanism, and releasing it on the spot. The applied prestress force introduces prestress around the reinforcing facility to offset external stress stress and improve strength.

Accordingly, when the pressing rod 1400 of the hydraulic device installed through the pressing rod hole 430 presses the press-fitting support piece 600 and the solid PS steel rod 300 by the pressure of the hydraulic cylinder, the solid PS steel rod 300 is compressed. Deformation is generated, and at the same time, the tensile force generated in the bi-jacking jig sets the abutment 500 and the dead fixing device 200 as a reaction force to generate tensile deformation in the hollow PS steel pipe 100 . The tensile deformation generated in the hollow PS steel pipe 100 is to minimize the elastic contraction loss as the compression deformation generated in the solid PS steel bar 300 is resistance-constrained by the reaction force to be recovered. In order to maintain the above state, the screw-live fixing device 400 is rotated and moved in the direction of the abutment 500 by a pressure stroke to tighten the hollow PS steel pipe 100, so that the pre-stressed hollow PS steel bar can be maintained.

The hollow PS steel pipe 100 is configured in the form of a pipe in which the inner space is opened at both ends so that the solid PS steel bar 300 is embedded, and a thread to which the dead fixing device 200 is fastened is formed on the inner or outer surface of one end, A screw thread is formed on the outer surface of the other end so that the screw-live fixing device 400 and the abutment 500 are fastened.

The dead fixing device 200 is fastened to one end of the hollow PS steel pipe 100 and closes the steel pipe to serve as a fixed end when the solid PS steel bar 300 is pressed and serves as a reaction force band where tensile force acts at the same time. When the size of the reinforcing cross-section and the reinforcing force is large, the external type dead fixing device 200 can be fastened, and when the size of the reinforcing force is small, the internal type dead fixing device 200 can be fastened.

As shown in Figure 2, the external dead fixing device 200 is a hollow socket part 210, the socket part (210), the screw thread formed on the inner surface of the hollow PS steel pipe 100 is screwed together. 210) is integrally formed with a head 220 that closes one end of the hollow PS steel pipe 100 and is in close contact with one end of the solid PS steel bar 300.

As shown in FIG. 3, the internal dead fixing device 200 is an internal type, and a thread is formed on the outer surface, and a bolt part 250 that is screwed to the thread formed on the inner surface of the hollow PS steel pipe 100, and a bolt part It consists of a head part 260 which is integrally formed with 250 and closes one end of the hollow PS steel pipe 100 and is in close contact with one end of the solid PS steel bar 300 .

The head 220 of the external and internal dead fixing device 200 has a lower portion to form an inclined cross-section, so that the prestressed hollow PS steel rod is securely seated on the irregular perforated end formed in the reinforcement facility, and the head 220 ) The grouting holes 230 and 270 are formed in the center and grouted to the end of the perforation to ensure sufficient adhesion.

On the other hand, the solid PS steel bar 300 is installed so as to be drawn out by more than a pressure stroke than the other end of the hollow PS steel pipe 100 and is located inside the hollow PS steel pipe 100 to coincide with the central axis. That is, when the solid PS steel bar 300 is inserted into the hollow PS steel pipe 100, one end of the solid PS steel bar 300 is in close contact with the dead fixing device 200, and the other end of the hollow PS steel pipe 100 is more than a pressurized stroke at the other end. In the protruding state, the press-fitting support piece 600 and the screw-live fixing device are installed in close contact with the pressing jaw of the fixing device. When the hollow PS steel bar manufactured in the above state is installed in close contact with the bi-jacking jig and a hydraulic device composed of a hydraulic cylinder and a load gauge in the bi-jacking jig is operated to generate a stroke, the solid PS steel bar 300 has compression deformation. At the same time, the tensile force generated in the bi-jacking jig causes tensile deformation in the hollow PS steel pipe 100 between the abutment 500 and the dead fixing device 200 .

In a state for constraining the tensile deformation generated in the hollow PS steel pipe 100 to be maintained by the reaction force to recover from the compressive deformation generated in the solid PS steel bar 300, screw fastening to the hollow PS steel pipe 100 by the stroke When the coupled screw live fixing device 400 is rotated toward the abutment 500 and constrained, the solid PS steel rod 300 and the hollow PS steel pipe 100 maintain the generated compression and tensile deformation states. A prestressed hollow PS steel bar body with prestressing force introduced will be manufactured.

The screw live fixing device 400 has a pressurized stroke space hole formed therein, and the solid PS steel bar and the press-fit support piece 600 are positioned therein, and the body part 410 screwed to a part of the outer surface of the other end of the hollow PS steel pipe 100 . ) and a pressing jaw part 420 that covers the upper end of the body part 410 and closes the press-fit support piece 600 to constrain the compression deformation of the solid PS steel rod 300, and the solid PS steel rod 300 is pressed. A pressing rod hole 430 formed in the central portion of the pressing jaw 420 is formed so that the pressing rod 1400 can enter and exit. At this time, it is preferable to form the outer surface of the body portion 410 in a hexagonal shape so that the torque tension is easily operated when the screw-live fixing device 400 is fastened and released. In addition, the body portion 410 and the pressing jaw portion 420 should have a thickness and length of sufficient rigidity to support the pressing force.

In addition, the screw live fixing device 400 is preferably formed with a flange portion 440 extending outwardly of the body portion (410). The flange portion 440 may serve as a handle for facilitating the fastening and disengagement of the screw live fixing device 400 from the hollow PS steel pipe 100 and for keeping the pressure bar horizontal.

This screw live fixing device 400 is a hydraulic device that is installed in close contact with the bi-jacking jig in a state in which a part of the screw portion of the body 410 is not fastened to the other end of the hollow PS steel pipe 100 before pressurization by more than the pressure stroke. When a stroke is generated by operating When a tensile strain is generated in the PS steel pipe, the body 410 of the screw live fixing device 400 screwed to the hollow PS steel pipe 100 is rotated by a stroke and tightened in the abutment 500 direction to tighten the solid PS. Compressive deformation occurring in the steel bar 300 and tensile deformation occurring in the hollow PS steel pipe 100 are constrained. Accordingly, the generated tensile deformation is resisted by the reaction force to recover the compressive deformation occurred in the solid PS steel bar 300, so that the elastic contraction loss of the hollow PS steel pipe 100 is minimized, thereby achieving a very excellent pre-stress force introduction mechanism. do.

The abutment 500 is screwed to the hollow PS steel pipe 100 at a position spaced apart from the lower end of the screw live fixing device 400 by more than a pressure stroke to protrude to the outside and installed. When the pre-stress force is introduced, the abutment 500 operates the hydraulic device installed in close contact in the bi-jacking jig in a state in close contact with the jacking support plate 1120 of the bi-jacking jig 1000 to generate a stroke. When this occurs, compression deformation is generated in the solid PS steel bar 300, and at the same time, the tensile force generated in the bi-jacking jig causes tensile deformation in the hollow PS steel pipe 100 between the dead fixing device 200 and the abutment 500. It acts as a reaction force band to cause the prestress force to be introduced and serves as a fixing device for fixing the rear end of the hollow PS steel bar to the structure or facility when installing the prestressed hollow PS steel bar to the structure or facility to introduce the prestress. will do

The press-fitting support piece 600 is formed to be larger than the diameter of the solid PS steel rod 300 to evenly transmit the pressure of the pressing rod 1400 for pressing the solid PS steel rod 300 to the solid PS steel rod 300 . The cross-section of the press-fit support piece 600 is to have a diameter similar to the inner diameter of the body portion 410 of the screw live fixing device 400 to maintain a vertical axis when pressed, and the lower surface of the press-fit support piece 600 has a groove 610. It is preferable that this is formed so that a part of the end of the solid PS steel bar 300 is kept in a pinched state so that it can be performed not eccentric with the central vertical axis when pressing. In addition, the upper surface is formed horizontally so as to remain parallel to the cross-sections of the pressing part 420 and the pressing rod 1400 of the screw-live fixing device 400 .

On the other hand, as shown in Figure 6, the bi-jacking jig 1000 of the present invention is a jacking transmission side plate 1110 installed on both sides in the longitudinal direction, a jacking support plate 1120 installed horizontally under the jacking transmission side plate 1110. ) and an opening box-type case 1100 having a hollow inside and including a jacking pressure plate 1130 installed horizontally on the top of the jacking transmission side plate 1110, and the jacking support plate 1120 of the case 1100 A through hole 1200 through which the hollow PS steel pipe 100 is mounted, a hydraulic cylinder 1300 for jacking pressure installed in contact with the inner surface of the jacking pressure plate 1130 of the case 1100, and a through hole 1200 ) includes a pressure bar (1400) extending downward from the hydraulic cylinder (1300) to press the solid PS steel bar (300) mounted on it.

At this time, the abutment 500 of the hollow PS steel pipe 100 is prevented from moving on the jacking support plate 1120 and the jacking transmission side plate 1110 having a through hole installed on the upper surface of one side of the case 1100 from moving, and jacking A bracket 1500 is installed to transmit the tensile force generated during the operation without loss.

In addition, it is preferable that a load gauge 1310 is mounted between the hydraulic cylinder 1300 and the jacking pressure plate 1130 to check the jacking force.

In the inner space of the case 1100 of the bi-jacking jig 1000, a part of the hollow PS steel pipe 100 in which the screw-live fixing device 400 and the abutment 500 are installed is a through hole 1200 of the case 1100. ), but installed so that the abutment 500 is in close contact with the jacking support plate 1120 of the case 1100.

Accordingly, the lower portion of the pressure rod 1400 passes through the pressure rod hole 430 of the screw live fixing device 400 and is positioned in close contact with the press-fitting support piece 600 positioned above the solid PS steel rod 300 . And, the upper part of the hydraulic cylinder 1300 or the load gauge 1310 is adjusted and installed so as to be in close contact with the jacking pressure plate 1130 of the bi-jacking jig 1000, so that the compression and tensile forces according to the operation of the hydraulic system are applied to the press-fit piece and the abutment. positioned to work.

That is, the central axis including the load gauge 1310, the hydraulic cylinder 1300, the pressure rod 1400, the press-fit support piece 600 and the solid PS steel rod 300 so that the pressing force of the hydraulic device is transmitted to the hollow PS steel rod without eccentricity. installed to match.

7A to 7D, referring to the method of introducing prestress to the hollow PS steel bar using the bi-jacking jig 1000, first, the aforementioned hollow PS steel pipe 100, the dead fixing device 200, The hollow PS steel bar in which the solid PS steel bar 300, the press-fitting support piece 600, the abutment 500, and the screw live fixing device 400 are combined, the bi-jacking support plate 1120 of the jacking jig 1000 and It is positioned between the jacking hydraulic plates 1130 so that the abutment 500 is in close contact with the jacking support plate 1120 of the case 1100, and the lower part of the hollow PS steel pipe 100 passes through the through hole 1200. .

Accordingly, the central axis of the hydraulic cylinder 1300, the pressure rod 1400 and the screw live fixing device 400, the press-fitting support piece 600, and the solid PS steel rod 300 of the bi-jacking jig 1000 are aligned in the state , When the pressure of the hydraulic cylinder 1300 is transmitted to the press-fitting support piece 600 through the pressing rod 1400 and the solid PS steel rod 300 is pressurized, the solid PS steel rod 300 is closed dead fixing device 200 As the reaction force, the transmitted pressing force causes compressive deformation of the solid PS steel bar 300, and the solid PS steel bar 300 simultaneously interlocks with the resistance reaction force that generates compressive deformation, so that the pressure stroke is a tensile force on the bi-jacking jig will occur

At the same time, with the dead fixing device 200 and the abutment 500 as the reaction force, tensile deformation is generated by the tensile force in the hollow PS steel pipe 100 between the apparatuses, and this tensile deformation is applied by pressing Since the elastic reaction force of the solid PS steel bar 300 in which the compression deformation has occurred controls the tensile deformation recovery, it is configured as a mechanism for allowing the prestress force to act on the hollow PS steel pipe 100 .

Therefore, the compressive deformation occurring in the solid PS steel bar 300, the tensile deformation occurring in the hollow PS steel pipe 100, and the reaction force occurring in the solid PS steel bar 300 controlling the tensile deformation are simultaneously interlocked and thus prestressed. It is a valid technique with minimal force loss.

And, when the compressive deformation of the solid PS steel bar 300 and the tensile deformation of the hollow PS steel pipe 100, which is a reaction force thereof, occur by design management as described above, the body portion 410 or the plan of the screw live fixing device 400 The press-fitting support piece 600 and the solid PS steel rod 300 are rotated and moved in the direction of the abutment 500 as much as the pressing stroke using the branch 440, etc. When constrained, the compression deformation generated in the solid PS steel bar 300 introduced by the above mechanism, the tensile deformation generated in the hollow PS steel pipe 100, and the recovery reaction force are simultaneously interlocked and controlled, so that the loss such as elastic contraction is minimized It is possible to make the pressing force small by using this, and it is possible to improve the effectiveness of the management of the pre-stress force, such as securing the elastic capacity of the pressurized solid PS steel bar.

And in the prestressed hollow PS steel pipe state as described above, after first releasing the pressure of the cylinder 1300, which is the hydraulic device, the hydraulic device and the pressure rod 1400 and the bi-jacking jig 1000 are separated, the prestress force is introduced It is manufactured as a pre-stressed hollow PS steel bar and shipped from the factory.

On the other hand, as shown in Figs. 8a to 8b, using the hollow PS steel bar to which the prestress force of the present invention is introduced, which is manufactured at the factory through the above-described process, cross-section extension, strength and load-bearing capacity enhancement, etc. are required. shows the process of easily introducing prestress without jacking and fixing work in the field.

In the case of a structure requiring cross-section extension, a perforation hole is formed in an existing facility such as a concrete structure requiring cross-section extension, and the front end of the hollow PS steel pipe 100 and the dead fixing device 200 of the pre-stressed hollow PS steel bar are drilled. The rear end of the prestressed hollow PS steel pipe 100 is placed in close contact with the inner end of the hole to protrude from the drilling hole.

Then, a grouting agent is first injected into the drilling hole so that the front end of the prestressed hollow PS steel pipe 100 installed in the drilling hole and the dead fixing device 200 are fixed to the drilling hole, and the prestressed hollow PS steel pipe 100 is placed in the drilling hole. Fix it.

After that, when the front end of the prestressed hollow PS steel pipe 100 is fixed to the perforated hole, the rear end of the prestressed hollow PS steel pipe 100 protruding from the perforated hole to communicate with the lower perforated hole is installed, but the other end of the prestressed hollow PS steel bar The abutment is installed at a certain depth from the end face of the cross-section extension and the cross-section is extended so that the anchorage is formed.

In addition, in the case of a concrete structure requiring load-bearing capacity and strength enhancement, a perforated hole is formed in the existing facility to be reinforced, and the front end of the prestressed hollow PS steel pipe 100 and the dead fixing device 200 are in close contact with the inner end of the perforated hole, , the abutment installed at the other end of the prestressed hollow PS steel bar is positioned at a certain depth from the end face of the reinforcing existing facility to form an anchorage.

In other words, as shown in FIG. 9 , an upper drilling hole H2 having a diameter into which the abutment 500 is inserted is formed and communicating with the upper drilling hole H2, a lower drilling hole having a smaller diameter than the upper drilling hole H2 ( H1) is formed.

Then, a grouting agent is injected into the drilling hole so that the prestressed hollow PS steel pipe 100 installed in the drilling hole is fixed to the drilling hole between the abutment and the dead fixing device 200 to insert the prestressed hollow PS steel pipe 100 into the drilling hole. Fix it.

As described above, the prestressed hollow PS steel pipe 100 is fixed in the drilling hole so that the abutment serves as a reaction arm fixing device. Release the screw connection from the PS steel bar and separate it.

Accordingly, as the prestress force introduced into the hollow PS steel pipe 100 of the prestressed hollow PS steel bar is transferred to the reinforcement facility between the dead fixing device 200 and the abutment 500, the structure requiring cross-section extension, reinforcement By automatically converting prestress to necessary concrete structures and facilities to be synthesized, prestress and restraint stresses are introduced to reinforcing facilities to offset external tensile stress or improve strength and integration performance of surrounding facilities.

At this time, since the compression force of the pressurized solid PS steel bar in the hollow PS steel bar is lost when the screw live fixing device is separated from the hollow PS steel bar, the solid PS steel bar can be removed or kept according to the purpose of reinforcement. That is, in the case of reinforcement for the purpose of synthesis, etc., by removing the solid PS steel rod 300, the separated solid PS steel rod 300 can be used again as a pressurized solid PS steel rod for manufacturing another prestressed hollow PS steel rod body. , it is also meaningful in terms of recycling of resources.

In addition, in the case of reinforcement for the purpose of improving flexural strength, the solid PS steel bar 300 in which the pressure has been lost can be retained and used as a steel for flexural strength enhancement, so it is also meaningful in terms of saving resources.

On the other hand, due to the removal of the PS steel rod 300, it is possible to improve the adhesion ability of the surrounding ground or structure by injecting a grating agent into the hollow PS steel pipe 100 that is empty.

At this time, when the perforation hole is small, such as the reinforcement of the concrete structure, it is preferable to use a hollow PS steel bar to which the dead fixing device 200 of the internal type is applied.

On the other hand, as shown in Figs. 9a to 9b, the hollow PS steel rod body to which the pre-stress force produced at the factory is introduced through the above-described process is used in the field for reinforcement facilities that require load-bearing capacity and stability enhancement on slopes or bedrock areas. It shows the process of easily introducing prestress without jacking and fixing work.

First, an upper drilling hole (H2) of a diameter into which the abutment 500 is inserted is formed in the ground and facilities such as tunnels, and a lower drilling of a diameter smaller than the upper drilling hole (H2) while communicating with the upper drilling hole (H2) A hole H1 is formed.

And, the dead fixing device 200 of the hollow PS steel pipe 100 of the pre-stressed hollow PS steel bar body is in close contact with the inner end of the lower drilling hole H1, and the abutment 500 is in close contact with the upper drilling hole H2. Insert it as much as possible and fix it.

After that, a grouting agent is injected into the lower drilling hole H1 and cured to a predetermined strength, and the front end of the hollow PS steel pipe 100 and the dead fixing device 200 are integrated into the ground and facilities such as tunnels. At this time, the abutment 500 fixed to the hollow PS steel pipe 100 is supported by the upper perforated hole H2 formed to communicate with the lower perforated hole H1 and is in a fixed state.

Then, the screw live fixing device 400 is rotated to release and separate the screw coupling from the hollow PS steel pipe 100 . Accordingly, as the tension force formed in the hollow PS steel pipe 100 is compressed while being transferred to the ground between the dead fixing device 200 and the abutment 500, it is automatically converted to prestress in the surrounding facilities, so that the hollow PS steel pipe 100 is compressed. By introducing pre-stress and restraint stress to the surrounding facilities of

At this time, since the compression force of the solid PS steel rod 300 is lost in the hollow PS steel pipe 100 when the screw live fixing device 400 is separated from the hollow PS steel pipe 100, the PS steel rod 300 is removed or kept. can Since the removed PS steel bar 300 can be used again for another hollow PS steel bar 300, it is meaningful in terms of recycling of resources, and when it is retained, it can be used as a steel for flexural strength enhancement, so it is also meaningful in terms of saving resources, etc. there is

Then, a protective cap (no number assigned) for protecting the hollow PS steel pipe 100 is installed in the upper perforated hole H2 and the exposed surface where the abutment 500 is installed, and grouting injection or rust preventive agent is installed inside the protective cap. It can be protected from corrosion by lubricating it and finishing it.

On the other hand, it is possible to significantly improve the adhesion ability and corrosion resistance of the surrounding ground or structure by injecting a grouting agent into the hollow PS steel pipe 100 from which the solid PS steel bar 300 is removed.

And, when the cross section of the drilling hole is large, such as for reinforcement of the ground, the external type dead fixing device 200 may be applied.

As described above, after inserting the solid PS steel bar 300 into the prestressed hollow PS steel pipe 100 according to the embodiment of the present invention, the screw live fixing device 400 is screwed into the hollow PS steel pipe 100 by a simple operation such as screwing. Since it becomes one module by fixing it, the structure of the prestressed hollow PS steel bar can be simplified.

Moreover, since the screw live fixing device 400 can be separated from the hollow PS steel pipe 100 very quickly, prestress can be introduced around or attached to facilities and structures, so that the efficiency of field work can be greatly improved.

In addition, since the hollow PS steel rod body with pre-stress force introduced in the factory is manufactured and tension-managed, if the screw-live fixing device 400 is simply released at the site, pre-stress is introduced into the facility and integration performance is improved, etc. It is a useful technology that does not require management and can provide constant and accurate prestress introduction performance, thereby ensuring simplicity, accuracy, and economic feasibility of construction and quality control.

In addition, since a separate tension device is not required in the field, work in a narrow field is possible.

As compression and tension are simultaneously interlocked in both directions to introduce tension, the pressing force can be minimized by minimizing the loss of tension, so that the elastic state of the hollow PS steel pipe 100 can be maintained and ductile failure can be induced.

Those skilled in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their equivalents Any changes or modifications derived from it should be construed as being included in the scope of the present invention.

100: hollow PS steel pipe 200: dead fixing device
300: solid PS steel bar 400: screw live fixing device
410: body 420: pressing part
430: pressure bar hole 440: flange portion
500: abutment 600: press-fit support piece
610: groove
1000: bi-jacking jig 1100: case
1110: jacking transmission side plate 1120: jacking support plate
1130: jacking pressure plate 1200: through hole
1300: hydraulic cylinder 1400: pressure bar
2000: protective cap

Claims (11)

Hollow PS steel pipe 100 with the inner space opened at both ends and;
A dead fixing device 200, which is closed to close one end of the hollow PS steel pipe 100, and has grouting holes 230 and 270 extending inwardly in the center of the lower end;
It is inserted into the hollow PS steel pipe 100, one end is in close contact with the dead fixing device 200, and the other end protrudes more than a pressing stroke outward from the other end of the hollow PS steel pipe 100, and when pressurizing, the hollow PS steel pipe 100 ) and a solid PS steel bar 300 that is contracted to the inside;
The solid PS steel bar 300 and the press-fitting support piece 600 are positioned therein, the hollow PS steel pipe 100 having a space hole equal to or greater than the pressure stroke, and a cylindrical body 410 screwed to a part of the outer surface of the other end of the hollow PS steel pipe 100 and the body; The pressing jaw 420 for closely supporting the press-fitting support piece 600 while covering the upper end of the portion 410 and the pressing rod 1400 for pressing the solid PS steel rod 300 while penetrating the upper end of the pressing jaw 420 of the a screw-live fixing device 400 having a pressure bar hole 430 and a flange 440 extending outwardly of the body 410 to enable entry and exit;
An abutment 500 that is screwed to the other end of the hollow PS steel pipe 100 and protrudes outside the screw-live fixing device 400 at a position spaced apart from the lower part of the screw live fixing device 400 by more than a pressure stroke to act as a reaction arm and fixing device; ;
While positioned between the inner surface of the pressing jaw 420 of the screw live fixing device 400 and the solid PS steel rod 300, it is in close contact with the other end of the solid PS steel rod 300 to evenly deliver the pressurized pressure to the solid PS steel rod 300 A prestressed hollow PS steel bar in which a prestress force is introduced by interlocking tension and compression, characterized in that it includes a press-fitting support piece (600). The method according to claim 1, It is configured in the form of a pipe in which the inner space is opened at both ends so that the solid PS steel bar 300 is embedded, a thread to which the dead fixing device 200 is fastened is formed on the inner surface or outer surface of one end, and the other end A prestressed hollow PS steel bar body in which a prestress force is introduced by interlocking tension and compression, characterized in that the screw thread is formed so that the screw live fixing device 400 and the abutment 500 are fastened to the outer surface of the. The method according to claim 2, A thread is formed on the outer surface of one end of the hollow PS steel pipe 100, and the dead fixing device 200 is threaded on the inner surface, the thread formed on the outer surface of the hollow PS steel pipe 100 is screwed The hollow socket part 210 and the socket part 210 are integrally formed to close one end of the hollow PS steel pipe 100 and the head 220 which is in close contact with one end of the solid PS steel bar 300, and the head ( 220) A prestressed hollow PS steel bar in which a prestress force is introduced by interlocking tension and compression, characterized in that it is an external dead fixing device 200 in which a grouting hole 230 is formed in the center. The method according to claim 2, A thread is formed on the inner surface of one end of the hollow PS steel pipe (100), and the dead fixing device 200 is an internal type, and a thread is formed on the outer surface of the hollow PS steel pipe (100). The bolt part 250 to be screwed, and the head part 260 which is integrally formed with the bolt part 250 and closes one end of the hollow PS steel pipe 100 to be in close contact with one end of the solid PS steel bar 300, and the head part Prestressed hollow PS steel bar body in which tension and compression interlock and prestress force is introduced, characterized in that it is an internal dead fixing device 200 in which a grouting hole 270 is formed in the center of 220. delete delete The method according to claim 1, The lower surface of the press-fit support piece (600) is characterized in that the groove (610) is formed so that a part of the end of the solid PS steel bar (300) is interlocked Prestressed hollow PS in which the prestress force is introduced in conjunction with the tension and compression steel rod. The method according to any one of claims 1, 2, 3, 4, and 7, further comprising a bi-jacking jig (1000) for introducing a pre-stressing force to the hollow PS steel bar, the bi-jacking jig (1000) is a jacking transmission side plate 1110 installed on both sides in the longitudinal direction, a jacking support plate 1120 installed horizontally under the jacking transmission side plate 1110, and a jacking installed horizontally on the top of the jacking transmission side plate 1110 a case 1100 including a pressure plate 1130 and having a hollow inside; a through hole 1200 through which the hollow PS steel pipe 100 is mounted through the jacking support plate 1120 of the case 1100; A hydraulic cylinder 1300 for jacking pressure installed in contact with the inner surface of the jacking pressure plate 1130 of the case 1100 and; It includes a pressure rod 1400 extending downward from the hydraulic cylinder 1300 to press the solid PS steel rod 300 mounted in the through hole 1200,
Between the jacking support plate 1120 and the jacking pressure plate 1130 of the bi-jacking jig 1000, a hollow PS steel pipe 100, a dead fixing device 200, a solid PS steel bar 300, a press-fitting support piece 600, The abutment 500 and the screw-live fixing device 400 are combined with the hollow PS steel rod body between the jacking support plate 1120 and the jacking pressure plate 1130 of the bi-jacking jig 1000 to place the abutment ( 500) is in close contact with the jacking support plate 1120 of the case 1100, and in a state in which the lower part of the hollow PS steel pipe 100 passes through the through hole 1200, the pressure of the hydraulic cylinder 1300 is applied to the pressure rod ( When the solid PS steel bar 300 is pressurized by passing it to the press-fitting support piece 600 through 1400), the pressurizing force transmitted by using the dead fixing device 200 in which the solid PS steel bar 300 is closed as a reaction force is applied to the solid PS steel bar ( 300) causes compression deformation, and the solid PS steel bar 300 is simultaneously interlocked with the resistance reaction force that generates compression deformation, so that the pressure stroke generates a tensile force in the bi-jacking jig, and at the same time, the dead fixing device 200 With the abutment 500 and the abutment 500 as the reaction force, tensile deformation is generated by the tensile force in the hollow PS steel pipe 100 between the devices, and the compressive deformation is generated by applying the tensile deformation to the solid PS steel bar. As the elastic reaction force of 300 controls the recovery of the tensile strain, the prestressed hollow PS steel bar in which the prestress force is introduced by interlocking tension and compression, characterized in that it has a mechanism for allowing the prestress force to act on the hollow PS steel pipe 100 sifter. The method according to claim 8, The abutment 500 of the hollow PS steel pipe 100 is prevented from moving on the jacking support plate 1120 and the jacking transmission side plate 1110 having a through hole installed on the upper surface of one side of the case 1100. And, a pre-stressed hollow PS steel bar in which a pre-stress force is introduced by interlocking tension and compression, characterized in that a bracket 1500 is further formed to transmit the tensile force generated during jacking without loss. Jacking and fixing the prestressed hollow PS steel bar to which the prestressing force manufactured according to any one of claims 1, 2, 3, 4, and 7 is introduced to a reinforcing facility requiring cross-section extension and enhancement of strength and load-bearing capacity at the site Introduce prestress easily without work,
A perforated hole is formed in the existing facility, and the front end of the hollow PS steel pipe 100 and the dead fixing device 200 of the prestressed hollow PS steel bar are in close contact with the inner end of the perforated hole, so that the rear end of the prestressed hollow PS steel pipe 100 is a drilled hole. positioning to protrude from;
To fix the prestressed hollow PS steel pipe 100 to the drilling hole by first injecting a grouting agent into the drilling hole so that the front end of the prestressed hollow PS steel pipe 100 installed in the drilling hole and the dead fixing device 200 are fixed to the drilling hole step;
When the front end of the prestressed hollow PS steel pipe 100 is fixed to the perforated hole, the rear end of the prestressed hollow PS steel pipe 100 protruding from the perforated hole to communicate with the lower perforated hole is installed, but the prestressed hollow PS steel pipe 100 is installed at the other end of the Tension and compression comprising a; A pre-stress introduction method using a pre-stressed hollow PS steel bar in which the pre-stress force is introduced in conjunction. The prestressed hollow PS steel bar to which the prestress force manufactured according to any one of claims 1, 2, 3, 4, and 7 is introduced is applied to slopes, rocky areas, and facilities requiring strength enhancement, etc. to improve load-bearing capacity and stability installed in necessary facilities,
Forming an upper drilling hole (H2) of a diameter into which the abutment 500 is inserted into the facility, and communicating with the upper drilling hole (H2) to form a lower drilling hole (H1) having a smaller diameter than the upper drilling hole (H2) step;
The dead fixing device 200 of the hollow PS steel pipe 100 of the pre-stressed hollow PS steel bar is attached to the inner end of the lower drilling hole H1, and the abutment 500 is inserted into the upper drilling hole H2 to be in close contact. and fixing it;
Injecting a grouting agent, etc. into the sub-perforated hole (H1) and curing it to a predetermined strength to integrate the front end of the hollow PS steel pipe 100 and the dead fixing device 200 into the ground and facilities such as a tunnel;
A prestress introduction method using a prestressed hollow PS steel bar body in which a prestress force is introduced by interlocking tension and compression comprising the step of releasing and separating the screw coupling from the hollow PS steel pipe 100 by rotating the screw live fixing device 400 .

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