KR100580233B1 - Fiberboard tensioner - Google Patents

Abstract

An object of the present invention relates to an external prestressing reinforcement method by a fiber board which is recently attracting attention, in particular, it can be installed while minimizing the damage of the concrete structure, which is a reinforcing parent, and is not limited by the size of the hydraulic cylinder, It is to provide a tension device that can be used for external prestressing reinforcement method using a fiber board that requires tension.

More specifically, the tension device 620 composed of the A-shaped tension frame or the tension device 600, 610 composed of the L-shaped tension frame and the horizontal tension frame and one end of the tension device are mounted, and the fiber board passes obliquely. Inclined sphere 200 to be able to do so, one end of the tension device is held by the gripping plate to hold the fiber board 300 is a linear movement, one end is fixed to the inclined sphere 200 and one end to the guide fixture 400 The tension is introduced into the fiberboard, which is used in the external prestressing reinforcement method, which is composed of a guide 635 fixed and holding a guide 300 inserted into a linear motion and a guide fixture 400 fixed at one end of the guide 635. To provide a set of tension devices.

Tensioner, fiberboard, concrete, prestressing                  

Description

Fiber Plate Tensioner {Equipment to tension a FRP plate}

1 is a bottom view of the arrangement state of both the tension device and the anchorage of the present invention.

Figure 2 is a perspective view of the arrangement of the inclined sphere, gripper, guide fixture of the present invention.

Figure 3 is a perspective view of the fiber board is held in the gripper of Figure 2;

Figure 4 is a perspective view of the tension device of the present invention mounted on the inclined sphere and grip of Figure 3;

5 is a perspective view of a state in which the fixing unit installation is completed.

FIG. 6 shows a cross section A-A of FIG. 4. FIG.

FIG. 7 shows a section B-B in FIG. 4. FIG.

Figure 8 is a perspective view of the inclined sphere of the present invention.

9 is a perspective view showing a gripper of the present invention.

10 is a perspective view of the guide fixture of the present invention.

Figure 11 is a perspective view of the tension device assembly arrangement state of the present invention.

Figure 12 is a perspective view of the assembly arrangement state of the roof-type elastic frame constituting the tension device of Figure 11;

Figure 13 is a perspective view of the state in which the tension device of Figure 11 is assembled.

14 is a perspective view of another tension device of the present invention.

15 is another perspective view of the tension device of the present invention.

Figure 16 is a perspective view of the assembly arrangement state of the roof-type elastic frame constituting the tension device of Figure 15.

FIG. 17 shows the hydraulic unit and cross section A-A of FIG. 15. FIG.

18 is a state diagram of the conventional tension device and both anchorage.

(Explanation of symbols for the main parts of the drawing)

100a, 100b: anchorage 110: anchoring bottom plate

120: fixing top plate 200: inclined sphere

201: sloped groove 202: fixed portion

300: Gripping strip 310: Gripping bottom plate

320: grip top 400: guide fixture

512: bolt 513a, 513b: bolt insertion opening

521: anchor bolt 522: anchor bolt

523: anchor bolt insertion opening 600, 610, 620: tension device

631, 632: roof type tension frame

631a, 632a: Inverted A-shaped force frame

631b, 632b: A-shaped force frame

633: horizontal tension frame 635: guide

636: hydraulic cylinder 637: push rod

641a, 641b, 641c, 642c: hinge shaft insert

642a, 643a, 643b, 643c, 644, 645: Hinge Shaft

646: pins 648a and 648b: guide insertion holes

649: hydraulic cylinder insert 642b: nut

651: bolt 700: fiberboard

800: concrete structure 900: conventional tension device

911: support 912: hydraulic cylinder

913: fiberboard grip 913a: gripping bottom plate

913b: phage tops

The present invention relates to an external prestressing reinforcing method for reinforcing a concrete structure so that prestress is introduced by tensioning and fixing a fiber board, and more particularly, by reinforcing integrally with a concrete structure using a fixing device in a state where tension is introduced into the fiber reinforcing plate. It relates to a separate designed fiberboard tension device used in the external prestressing reinforcement method.

The reinforcing material mainly used in the conventional method of reinforcing by introducing prestress is PC steel wire. PC steel wire prestressing reinforcement method using PC steel wire should install several strands of PC steel wire in a certain concrete member. In this case, several strands of the PC wire should be uniformly tensioned, but it is not easy to uniformly strain each PC wire at the construction site. In addition, the fixing system is very large and complex, and has a problem that the weight is increased. However, most importantly, PC steels need to be continuously maintained because of the possibility of corrosion, as in the case of rebars, and when corrosion occurs, it is cumbersome to replace the entire surface.

As an alternative to this, prestressing reinforcement methods for attaching unidirectional fiber boards such as carbon fiber boards (CFRP), which are completely free of corrosion, to the concrete in a tense state have been used abroad for many years. In the case of reinforcing concrete by this method, it is possible to significantly improve the load capacity by applying initial stress to the concrete to be reinforced in the opposite direction to the load direction, and also to restrain concrete from cracking. However, when a unidirectional fiber board such as carbon fiber board (CFRP) is installed by this prestressing method, a fixture for fixing the unidirectional fiber board to concrete and a tension device for introducing tension to the fiber board such as unidirectional fiber board are required.

FIG. 18 shows the arrangement of the tensioning device 900 and the reinforcing fiber board 700 such as the two fixing holes 100a and 100b and the one-way fiber board which are conventionally used.

Flat-shaped steel is mainly used for the fixing means 100a and 100b. The plate-like steel is pressed onto the upper and lower surfaces of the fibrous plate 700 such as a unidirectional fibrous plate using a bolt and fixed to the concrete structure. The fixing holes 100a and 100b are composed of a fixing lower plate 110 and a fixing upper plate 120. The fixing plate is placed on a concrete side to fix the lower plate 110 and the fibrous plate 700 such as a one-way fibrous plate thereon. The fixing plate is called the fixing top plate 120. The fixing unit configured as described above is installed at both ends of the fiber plate 700 to fix the fiber plate 700 to the concrete structure 800.

The fixing lower plate 110 is cut in a predetermined portion of the concrete structure 800 by the size of the fixing lower plate, embedded in the place and fixed by the anchor bolt 522 and the anchor nut 521. The fixing upper plate 120 is fixed and compressed to the fixing lower plate 110 by bolts 512. A fibrous plate 700 such as a unidirectional fibrous plate is fixed under pressure between the fixing lower plate 110 and the fixing upper plate 120. The fixing device 100b on the tension device 900 side and the fixing device 100a on the opposite side have the same configuration.

A tension device 900 for tensioning the fiber plate 700 is installed outside the fixing unit 100b. When the fiber plate 700 is tensioned, the fiber plate 700 positioned between both anchorages 100a and 100b is to be tensioned while maintaining a horizontal level, so that the tension device 900 is also installed after cutting the concrete by the size thereof. The tension device 900 includes a support 911, a hydraulic cylinder 912, and a fiber board gripper 913, and the gripper 913 is composed of a gripper lower plate 913a and a gripper upper plate 913b. The fiberboard is gripped on. When the hydraulic cylinder 912 is operated, the fiber plate 700 is tensioned while the rod end of the hydraulic cylinder 912 pushes the gripper 913.

Briefly explaining the process based on FIG. 18, the fixing lower plate 110 and the tensioning device 900 constituting the fixing holes 100a and 100b are provided. After placing one end of the fiber plate 700 on the fixing lower plate 110 of the fixing unit 100a, the fixing upper plate 120 is completely fixed to the fixing lower plate 110 with a bolt 512 to fix one end of the fiber plate 700. . The opposite end of the fiber board 700 is fixed by a bolt 512 between the gripping lower plate 913a and the gripping upper plate 913b of the gripper 913 constituting the tension device 900. After operating the hydraulic cylinder 912 constituting the tension device 900 to tension the fiber plate 700 to the target value, bolt the fixing top plate 120 constituting the fixing device 100b located on the tension device side to the fixing lower plate 110 Completely fixed by 512 to fix the fiber board 700 to the concrete structure (800). After dismantling the tension device 900, to repair the portion of the concrete cut out to install the tension device 900 to complete the process.

The conventional fiberboard tension device 900 as described above has a problem in that it can be installed only by applying a considerable amount of damage to the concrete structure to be reinforced, that is, by cutting out a considerable amount of concrete. In addition, since the depth that can be cut out from the coating portion of the existing concrete structure 800 is very limited, the diameter of the hydraulic cylinder 912 constituting the tension device 900 can not be limited within the range. If greater tension is required, a larger hydraulic cylinder should be used. However, the conventional tension device of the configuration as shown in FIG. 18 has a problem that the capacity of the hydraulic cylinder of the configuration is very limited.

An object of the present invention relates to an external pre-stressing reinforcement method that is recently attracting attention, and in particular to provide a tension device that solves the problems discussed in the prior art. In other words, it is possible to install while minimizing damage of concrete structure, which is a reinforcing parent, and is not limited by the size of the hydraulic cylinder, thereby providing a tension device that can be used for external prestressing reinforcement method using fiberboard which requires a large amount of tension. .

In order to achieve the above object, in the present invention, the inclined curved groove 201 through which the fiber board is inclined to pass through the lower surface is formed, the guide inserting hole (648b) is processed to the predetermined depth from the rear side of the groove 201 Anchor bolt through the anchor bolt insertion hole 523 through the four corners are formed in the hinge shaft 645 of the cylindrical shape in which the tension device (600 or 610 or 620) is mounted in the center of both sides An inclined sphere 200 fixed to the concrete structure 800 by 522;

An anchor bolt insertion hole 523 having a threaded guide insertion hole 648a at a position corresponding to the guide insertion hole 648b of the inclined hole 200 is penetrated through the front and rear surfaces, and is penetrated through the upper and lower surfaces adjacent to both ends thereof. A guide fixture 400 fixed to the concrete structure 800 by an anchor bolt 522;

The upper center is formed with a groove for assembling the gripping top plate 320, and the bottom of the groove is a plurality of bolt insertion holes (513a) having a threaded width in the longitudinal direction of the fiber plate on both sides of the fiber plate, Guide grooves 648b pass through the front and rear surfaces at positions corresponding to the guide insertion holes 648b of the inclined holes 200 on both sides of the grooves, and tension devices 600 or 610 or 620 are provided at the centers of both side outer surfaces. ) Is inserted into a groove of the gripping lower plate 310 and the gripping lower plate 310 which are linearly moved along the guide 635, in which a cylindrical hinge axis 645 is mounted. A gripping tool 300 composed of a gripping top plate 320 which is fixed to the bolt insertion hole 513a and which is bolted through the upper and lower surfaces of the bolt insertion hole 513b at a position where the bolt insertion hole 513a encounters the fiber plate 700. Wow;

The guide insertion hole 648a of the guide fixture 400 and the guide insertion hole 648b of the gripping lower plate 310 are sequentially inserted to the guide insertion hole 648b of the inclined sphere 200, and the guide of the guide fixture 400 A guide 635 fixed by fastening the bolt 651 to the insertion hole 648a;

A tension device (600 or 610 or 620) mounted on the hinge shaft (645) of the inclined sphere (200) and the hinge shaft (645) of the gripping lower plate (310);

Provides a tension device set for introducing tension to the fiber plate 700 consisting of.

1 is a bottom view showing the installation arrangement state of the tension device 600 set and the both anchorages (100a, 100b) of the present invention.

Figure 2 is a perspective view showing the installation arrangement state of the inclined sphere 200, the gripper 300, the guide fixture 400 and the tensioner side fixing device 100b constituting the tension device 600 set of the present invention.

1 and 2 will be briefly described a method of prestressing the concrete structure 800 by tensioning the fiber plate 700.

The fixing lower plate 110 constituting the fixing device 100a on the opposite side of the tension device and the fixing device 100b on the tension device side is installed at each position. Briefly explaining the installation procedure, after cutting the concrete by the size of the fixing lower plate 110, install the anchor bolt 522 in accordance with the position of the anchor bolt insertion hole 523 of the fixing lower plate 110, the fixing portion The lower plate 110 is inserted and the anchor nut 521 is fastened to the anchor bolt 522 to fix the fixing lower plate 110 to concrete.

Next, install the inclined sphere 200, the gripper 300, the guide fixture 400 constituting the tension device of the present invention. Anchor bolt insertion hole 523 for processing the anchor bolt is inserted into the inclined sphere 200 and the guide fixture 400, respectively, anchor bolt 522 to the concrete of the position corresponding to the anchor bolt insertion hole 523 ), The anchor bolt 522 is inserted into the anchor bolt insertion hole 523 of each component, and the anchor nut 521 is fastened to fix each component to concrete. Guide 635 through the guide insertion hole 648a, which is penetrated by the guide fixture 400, and the guide insertion hole 648b, which is penetrated by the gripping lower plate 310, in order to the guide insertion hole 648b of the inclined hole 200. Insert and fasten the bolt 651 to the guide insertion hole (648a) of the guide fixture 400 to secure the guide 635.

A state in which the above process is completed, that is, the assembling arrangement of the tension device side fixing unit 100b, the inclined hole 200, the holding plate 310, the guide fixture 400 and the guide 635 is shown in FIG.

As shown in FIG. 2, one end of the fiber board 700 is placed on the gripping lower plate 310, and then one end of the fiber plate 700 is fixed by fastening the gripping upper plate 320 to the gripping lower plate 310 by bolts 512. The gripper 300 is gripped. The state in which the above process is completed is shown in FIG.

Figure 4 shows a state in which the assembly to the tension device 600 in a state where one end of the fiber plate is held in the gripping hole 300 as described above. When the hydraulic cylinder 636 is operated in the state in which the tension device 600 is assembled, the fiber plate 700 is tense. When the tension is completed, the fixing top plate 120 is fastened by fastening to the fixing bottom plate 110 by bolts 512, and the tensioner 600 and the gripper top plate 320 are dismantled, and then the fiber board on the tensioner side is removed. After cutting off, the process is completed by dismantling the inclined sphere 200, the guide fixture 400, and the gripping lower plate 310. A process of further applying an adhesive may be added between the fiberboard 700 and the concrete surface between both anchorages 100a and 100b.

5 shows the fixing holes 100a and 100b in the state where fixing is completed.

FIG. 6 shows cross section A-A of FIG. 4, and FIG. 7 shows cross section B-B of FIG. 4. The fixing lower plate 110 constituting the fixing unit is embedded in the concrete, the inclined sphere 200, the gripper 300, the guide fixture 400 and the tension device 600 constituting the tension device is installed on the concrete surface can see.

FIG. 8 illustrates an inclined sphere 200 having a function in which the tension device 600 is mounted and the fiber plate 700 passes obliquely. Figure 8a is shown from the top side, Figure 8b is shown from the bottom side. An open groove 201 having an inclined curved surface through which the fiber plate 700 passes obliquely is formed in the center of the lower surface, and the inclined curved groove 201 is shallower from the front side and deeper toward the rear side. Guide grooves 648b into which guides 635 are inserted are formed at both outer sides of the grooves 201. Anchor bolt insertion hole 523 through which the anchor bolt is inserted is penetrated at four corners of the inclined hole 200, and a cylindrical hinge shaft 645 in which the tension device 600 is mounted is processed at both centers of the outer surface. have. The guide insertion hole 648b is processed to a predetermined depth from the rear side. (Hereafter, the side facing the concrete is the lower side, the opposite side is the upper side, the tensioner side is the rear side, and the opposite side is the front side, the side perpendicular to the front and rear side.)

FIG. 9 illustrates a gripper 300 that grips the fibreboard 700 and includes a gripper lower plate 310 and a gripper upper plate 320.

The gripping lower plate 310 is formed in the center of the upper surface of the gripping top plate is assembled, the bottom of the groove has a width as much as the fiber board and the bolt insertion hole (513a) having a thread in the fiber plate length direction on both sides is perforated. . The fiber plate 700 is gripped between the gripping upper plate 320 and the gripping lower plate 310 by fastening and tightening the bolt 512 through the bolt insertion hole 513b of the gripping upper plate 320. Guide grooves 648b are formed through the front and rear surfaces on both sides of the groove, and cylindrical hinge shafts 645 are processed on both side outer surface centers of the gripping lower plate 310, and the tension device 600. Is mounted.

10 illustrates a guide fixture 400. Adjacent to both ends, the anchor bolt insertion hole 523 is through the upper and lower surfaces, and the guide insertion hole 648a with a thread at the position corresponding to the guide insertion hole 648b of the holding plate 310 is penetrated through the front and rear surfaces have.

11 shows the tension device 600 of the present invention, and shows the state before mounting on the inclined sphere 200 and the gripper 300.

The tension device 600 of the present invention is a roof-shaped tension frame 631 and the horizontal tension frame 633, hinge axis consisting of an inverted a-shaped force frame 631a and a-shaped force frame 631b. 643a, the hydraulic cylinder 636 is comprised.

As shown in FIG. 12, the roof-type resilient frame 631 is assembled with an inverted a-shape resilient frame 631a having male connections and a-shape resilient frame 631b having a female connection. By inserting the male (♂) connecting portion to the female (♀) connecting portion, the hinge shaft (642a) is inserted, and the nut 642b is fastened by connecting to form a roof-type resilient frame (631). The hinge shaft inserting holes 641a into which the hinge shaft 642a is inserted are respectively machined in the male (♂) connecting portion and the female (♀) connecting portion.

Two hinge shaft insertion holes 641b and 641c are respectively penetrated in the vertical portions of the inverted a-shape resilient frame 631a and the a-shape resilient frame 631b. The hinge shaft insertion hole 641c into which the hinge shaft 645 or the hinge shaft 645 of the gripper 300 is inserted is penetrated, and the hinge shaft 644 of the horizontal force frame 633 is located near the center of the vertical portion. The hinge shaft insertion hole 641b to be inserted is penetrated.

A head is formed at one end of the hinge shaft 642a, and a thread is machined at the opposite end thereof, and a hinge shaft insertion hole 642c having a rectangular cross section is machined through the entire length. The inverted a-shape resilient frame 631a and the a-shape resilient frame 631b rotate about the hinge axis 642a.

The tension device 600 is composed of two pairs of roof-like tensioning frame 631, as described above, two horizontal tensioning frame 633, one hinge shaft 643a, one hydraulic cylinder 636. Fig. 11 shows the assembly arrangement state between them.

The horizontal resilient frame 633 has a rectangular cylindrical shape, and a cylindrical hinge shaft 644 is machined at both ends thereof, and a pin hole for inserting a pin 646 is machined at an end of the hinge shaft 644. have.

The rear part of the hydraulic cylinder 636 is bolted to the rear center of one horizontal force frame 633, and the cylinder rod tip is connected to the front center of the opposite horizontal force frame 633. One of the hinge shafts 644 of the horizontal tension frame 633 is inserted into the hinge shaft insertion hole 641b of the roof type tension frame 631, and the pin hole of the hinge shaft 644 protrudes out of the roof type tension frame 631. Pin 646 to the wall to secure it.

Hinged in the inlet 642c of the rectangular cross section which is processed in the hinge a-shape force frame 631a and the hinge axis 642a inserted in the connection of the a-shape force frame 631b constituting the roof-like force frame 631. Insert the shaft 643a and fasten the pin 646. The hinge shaft 643a has a cylindrical center portion, and a square pillar-shaped portion is integrated on both sides of the cylindrical shape. The square pillar-shaped portion is inserted into the insertion opening 642c of the square cross section. The pin hole into which the pin 646 is inserted is processed adjacent to the edge part of a square pillar shape part.

The tension device 600 is installed in the process following the process shown in FIG. 3, and the reverse a-shape force frame (에서) is formed in a state where the roof type force frame 631 is assembled to only one side of the horizontal force frame 633 as described above. The hinge shaft insertion hole 641c, which is processed at 631a), is inserted into one hinge shaft 645 of the inclined hole 200, and the hinge shaft insertion hole 641c, which is processed in the a-shape reinforcement frame 631b, is a gripper ( 300, the pin 646 is inserted into a pin hole which is machined adjacent to the tip of the hinge shaft 645.

Another roof-like elastic frame 631 is assembled to the opposite side of the assembled roof-like elastic frame 631. The opposite end of the hinge shaft 643a is inserted into the insertion hole 642 of the square cross section processed on the hinge shaft 642a, and the pin 646 is fastened. The hinge shaft 644 opposite to the horizontal tension frame 633 is inserted into the hinge shaft insertion hole 641b of the roof type tension frame 631, and the pin hole of the hinge axis 644 protrudes out of the roof type tension frame 631. Insert pin 646 to fix it. The hinge shaft insertion hole 641c, which is processed in the inverted a-shape reinforcement frame 631a, is inserted into one hinge shaft 645 of the inclined hole 200, and the hinge that is processed in the a-shape reinforcement frame 631b. The shaft insertion hole 641c is inserted into one of the hinge shafts 645 of the grip plate 300 and the lower plate 310, and then the pin 646 is inserted into the pin hole which is processed adjacent to the tip of the hinge shaft 645. The installation of the tension device 600 is completed.

When the hydraulic cylinder 636 is operated in this state, the reverse a-shape force frame 631a and the a-shape force frame 631b receive a rotational force with respect to the hinge axis 642a as a reference point. Since the connection point of the inverse a-shape resilient frame 631a and the inclined sphere 200 is a fixed hinge point, the connection point of the a-shape resilient frame 631b and the gripper 300 is a moving hinge point, so the rotation force is a wave. Earth 300 is transformed into a force that linearly slides along guide 635. Therefore, when the hydraulic cylinder 636 is operated, that is, when the cylinder rod is advanced, the grip plate 300 is linearly moved toward the guide fixture 400, whereby the fiber plate 700 is tensioned.

13 shows the assembled tension device 600.

14 is the same structure as the tension device 600 of FIG. 13 except that two hydraulic cylinders 636 are installed side by side between the horizontal tension frame 633 as another tension device 610 of the present invention. A rear portion of the hydraulic cylinder 636 is fixed to the rear end of either of the two horizontal force frames 633, respectively, and a hydraulic cylinder 636 rod tip is adjacent to the front both ends of the opposite horizontal force frame 633. It is a structure that is connected.

15 illustrates another tensioning device 620 of the present invention. The tension device 620 is a roof type frame 632, a hinge shaft (643c), a hydraulic cylinder 636 consisting of an inverted a-shaped force frame (632a) and an a-shaped force frame (632b). It is made, and has a feature that the hydraulic cylinder 636 is installed directly on the roof-type elastic frame 632.

FIG. 16 illustrates a roof type tension frame 632 constituting the tension device 620 of FIG. 15.

As shown in FIG. 16, the roof type tension frame 632 is assembled with an inverted a-shape force frame 632a having a male (♂) connection portion and an a-shape force frame 632b having a female (♀) connection portion. Insert the male (♂) connector into the female connector, insert the cylindrical hinge shaft 643b, and insert the pin 646 into the pinhole that is machined adjacent to both ends of the hinge shaft that emerges from the female connector. When fitted, it becomes a roof-shaped elastic frame 631. The hinge shaft inserting holes 641a into which the hinge shaft 643b is inserted are respectively machined in the male (♂) connecting portion and the female (♀) connecting portion. The inverted a-shape force frame 632a and the a-shape force frame 632b rotate about the hinge axis 643b.

The hinge axis 645 of the inclined sphere 200 or the hinge axis 645 of the gripper 300 is inserted into the lower ends of the vertical portions of the inverse a-shaped elastic frame 631a and the a-shaped elastic frame 631b. The hinge shaft insertion hole 641c is penetrated, and an insertion hole 649 into which the push rod 637 integrated into the hydraulic cylinder 636 is inserted is disposed on the inner surface near the center of the vertical portion. The insertion hole 649 has a shape protruding by the depth.

As shown in FIG. 17A, the push rod 637 is integrated at the rear portion of the hydraulic cylinder 636 and the end of the cylinder rod, respectively. One surface of the push rod 637, that is, the surface in contact with the inner surface of the hydraulic cylinder insertion port 649 is a curved surface. In addition, the inner surface of the hydraulic cylinder insertion hole 649 which is respectively processed in the vertical portion of the inverted a-shaped force frame 632a and the a-shaped force frame 632b is also a curved surface. FIG. 17B illustrates a cross-sectional view A-A of FIG. 15, in which the curved surface of the push rod 637 of the hydraulic cylinder 636 and the inner surface of the hydraulic cylinder insertion hole 649 are in contact with each other. When the hydraulic cylinder 636 is operated, the curved center points of both push rods 637 contact one point of the inner surface of the hydraulic cylinder insertion hole 649, and the reverse a-shape force frame 632a and a-shape force frame 632b are operated. Push to rotate.

15 is a perspective view showing the tension device 620 is assembled. The installation of the tension device 620 will be described with reference to FIGS. 15 and 3. The hinge shaft inserting hole 641c, which is processed at the lower end of the vertical part of the inverted a-shape tensioning frame 632a constituting the roof type tensioning frame 632, is inserted into the hinge shaft 645 on one side of the inclined hole 200, The pin 646 is inserted into and fixed to the pin hole processed near the tip of the hinge shaft 645 protruding out of the frame. The pin 300 is inserted into one of the hinge shafts 645 of the earth 300, and the pins 646 are fixed to the pin holes which are machined near the tip of the hinge shaft 645 protruding out of the force frame. At this time, the hydraulic cylinder 636 is inserted between the two pressing frames (632a, 632b). In the same way as above, the opposite slope 200, the hinge shaft 645 and the gripper 300, the hinge shaft 645 is inserted into the roof-type resilient frame 632. Next, the hinge shaft 643c is inserted into the hinge shaft insertion hole 641a, and pins 646 are inserted from the outside of the elastic frame to connect both roof type elastic frames 632.

When the hydraulic cylinder 636 is operated in this state, the reverse a-shape force frame 632a and the a-shape force frame 632b receive a rotational force with respect to the hinge axis 643b as a reference point. Since the connection point of the inverse a-shape resilient frame 632a and the inclined sphere 200 is a fixed hinge point, the connection point of the a-shape resilient frame 632b and the gripper 300 is a moving hinge point, so the rotational force is a wave. Earth 300 is transformed into a force that linearly slides along guide 635. Therefore, when the hydraulic cylinder 636 is operated, that is, when the cylinder rod is advanced, the grip plate 300 is linearly moved toward the guide fixture 400, whereby the fiber plate 700 is tensioned.

According to the present invention, the pre-stressing can be performed while minimizing the damage of the concrete structure which is the reinforcing parent, and is not limited by the size of the hydraulic cylinder of the structure, and the external prestressing using the fiber plate having the tension device capable of exerting a large amount of tension force. The reinforcement method became possible.

Claims (4)

The inclined curved groove 201 through which the fiber board is inclined to pass through the lower surface is formed, and the guide inserting hole 648b is machined from both sides of the groove 201 from the rear to a predetermined depth, and both sides of the outer surface have a tension device ( A cylindrical hinge shaft 645 on which 600 or 610 or 620 is mounted is formed on the concrete structure 800 by the anchor bolt 522 through the anchor bolt insertion hole 523 which is formed through the four corners. An inclined sphere 200 fixed thereto; An anchor bolt insertion hole 523 having a threaded guide insertion hole 648a at a position corresponding to the guide insertion hole 648b of the inclined hole 200 is penetrated through the front and rear surfaces, and is penetrated through the upper and lower surfaces adjacent to both ends thereof. A guide fixture 400 fixed to the concrete structure 800 by an anchor bolt 522; The upper center is formed with a groove for assembling the gripping top plate 320, and the bottom of the groove is a plurality of bolt insertion holes (513a) having a threaded width in the longitudinal direction of the fiber plate on both sides of the fiber plate, Guide grooves 648b pass through the front and rear surfaces at positions corresponding to the guide insertion holes 648b of the inclined holes 200 on both sides of the grooves, and tension devices 600 or 610 or 620 are provided at the centers of both side outer surfaces. ) Is inserted into a groove of the gripping lower plate 310 and the gripping lower plate 310 which are linearly moved along the guide 635, in which a cylindrical hinge axis 645 is mounted. A gripping tool 300 composed of a gripping top plate 320 which is fixed to the bolt insertion hole 513a and which is bolted through the upper and lower surfaces of the bolt insertion hole 513b at a position where the bolt insertion hole 513a encounters the fiber plate 700. Wow; The guide insertion hole 648a of the guide fixture 400 and the guide insertion hole 648b of the gripping lower plate 310 are sequentially inserted to the guide insertion hole 648b of the inclined sphere 200, and the guide of the guide fixture 400 A guide 635 fixed by fastening the bolt 651 to the insertion hole 648a; A tension device (600 or 610 or 620) mounted on the hinge shaft (645) of the inclined sphere (200) and the hinge shaft (645) of the gripping lower plate (310); Tension device set used in the external prestressing reinforcement method, which introduces tension to the fiber plate 700 consisting of. According to claim 1, the tension device 600 is; The hinge shaft insertion hole 641c is disposed at the bottom of the vertical portion, and the hinge shaft insertion hole 641b is disposed near the center of the vertical portion, and a male connection part is formed at the upper right end thereof, and a hinge shaft insertion hole is formed at the male connection part. An inverted a-shape resilient frame 631a on which 641a is processed; The hinge shaft insertion hole 641c at the bottom of the vertical portion, the hinge shaft insertion hole 641b is machined near the center of the vertical portion, an arm connection is formed at the upper left end, and the hinge connection hole is formed at the arm connection part. A-shaped elastic frame 631b having 641a processed therein; Insert the male (♂) connecting portion into the female (♀) connecting portion, and inserted into the hinge shaft insertion hole (641a) formed in the connecting portion to form a roof-shaped resilient frame 631, the hinge hole insertion hole of the rectangular hole shape in the center ( A cylindrical hinge axis 642a on which 642c) is processed; Inserted into the hinge shaft insertion hole (642c) of the hinge shaft (642a) constituting the roof-like elastic frame (631), connecting the two roof-like elastic frame (631), the central portion is a cylindrical shape and to the roof-like elastic frame (631) Hinge shaft (643a) that is inserted into both ends are processed into a square pillar shape and the pin insertion hole for inserting the pin (646) at both ends; It is inserted into the hinge shaft insertion opening (641b) of the two roof-like elastic frame 631, between the inverse a-shape elastic frame 631a and the inverse a-shape elastic frame 631a, a-shape elastic frame ( 631b) and the a-shaped resilient frame 631b, the central portion is a square pillar shape and both ends are formed of a cylindrical hinge shaft 644, the horizontal of the structure inserted into the hinge shaft insertion opening (641b) An tension frame 633; A hydraulic cylinder 636 having a rear portion fixed to a rear center of one of the two horizontal tension frames 633 and a rod end connected to a front center of an opposite horizontal tension frame 633; Tension device used in the external prestressing reinforcement method to introduce tension to the fiberboard consisting of. The tension device (610) of claim 1; The hinge shaft insertion hole 641c is disposed at the bottom of the vertical portion, and the hinge shaft insertion hole 641b is disposed near the center of the vertical portion, and a male connection part is formed at the upper right end thereof, and a hinge shaft insertion hole is formed at the male connection part. An inverted a-shape resilient frame 631a on which 641a is processed; The hinge shaft insertion hole 641c at the bottom of the vertical portion, the hinge shaft insertion hole 641b is machined near the center of the vertical portion, an arm connection is formed at the upper left end, and the hinge connection hole is formed at the arm connection part. A-shaped elastic frame 631b having 641a processed therein; Insert the male (♂) connecting portion into the female (♀) connecting portion, and inserted into the hinge shaft insertion hole (641a) formed in the connecting portion to form a roof-shaped resilient frame 631, the hinge hole insertion hole of the rectangular hole shape in the center ( A cylindrical hinge axis 642a on which 642c) is processed; Inserted into the hinge shaft insertion hole (642c) of the hinge shaft (642a) constituting the roof-like elastic frame (631), connecting the two roof-like elastic frame (631), the central portion is a cylindrical shape and to the roof-like elastic frame (631) Hinge shaft (643a) that is inserted into both ends are processed into a square pillar shape and the pin insertion hole for inserting the pin (646) at both ends; It is inserted into the hinge shaft insertion opening (641b) of the two roof-like elastic frame 631, between the inverse a-shape elastic frame 631a and the inverse a-shape elastic frame 631a, a-shape elastic frame ( 631b) and the a-shaped resilient frame 631b, the central portion is a square pillar shape and both ends are formed of a cylindrical hinge shaft 644, the horizontal of the structure inserted into the hinge shaft insertion opening (641b) An tension frame 633; Two hydraulic cylinders each having a rear portion fixed to both rear ends of one of the two horizontal tension frames 633 and rod ends connected to both front ends of the opposite horizontal tension frame 633, respectively ( 636); Tension device used in the external prestressing reinforcement method to introduce tension to the fiberboard consisting of. According to claim 1, wherein the tension device (620); The hinge shaft insertion hole 641c at the bottom of the vertical part, the hinge shaft insertion hole 641a at the top of the vertical part, and the curved hydraulic cylinder insertion hole 649 inside the center of the vertical part are machined. Is formed, the male (♂) connecting portion is a reverse (축) a-shape force frame (632a) is processed a hinge shaft insertion hole (641a); The hinge shaft insertion hole 641c at the bottom of the vertical part, the hinge shaft insertion hole 641a at the upper part of the vertical part, and the curved hydraulic cylinder insertion hole 649 inside the center of the vertical part are machined, and the female connection part is provided at the upper left end. Is formed, the female (♀) connecting portion is a hinge frame insertion hole (641a) is processed a-shaped force frame 632b; A cylindrical hinge shaft 643b inserted into the male connecting portion and inserted into a hinge shaft inserting hole 641a formed in the connecting portion to form a roof-type resilient frame 632; One end is inserted into the hydraulic cylinder insertion hole 649 of the inverted a-shape force frame 632a, and the opposite end is inserted into the hydraulic cylinder insertion hole 649 of the a-shape force frame 632b. A hydraulic cylinder 636 which is integrally provided at the rear end and the rod end with a push rod 637 which is processed into this curved surface; The hinge shaft 643c, which is inserted into the hinge shaft insertion hole 641a of the roof-like resilient frame 632, connects two roof-like resilient frames 632, and has a pin insertion hole into which pins 646 are inserted at both ends. ); A tension device used in an external prestressing reinforcement method for introducing tension into a fibrous plate consisting of:

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