KR100395772B1 - An wedge for a PC steel wire for fixing construction structure - Google Patents

Abstract

The present invention is a construction structure for fixing the construction structure with a ground anchor installed on the ground to prevent the construction structure collapse and fall by external forces such as earthquake, wind power, hydraulic pressure, soil pressure during construction of various construction structures Part of the fixing ground anchor, more specifically, the PC (stranded strand) curvature of three jaw inner circumferential arcs formed in a collet chuck form for clamping and fixing the strand (PC) strand of the ground anchor The three outer circumferential curvatures of the three (3) outer circumferential curvatures are made to be larger than the outer circumferential curvatures corresponding to the free state before compression by the jaws so that the PC strand becomes the same as the outer diameter curvature when the wedge is compressed by the wedge. By forming a curvature larger than the circular outer circumferential curvature formed by two jaws, the PC strand is pressed inside the wedge. When the shaft is in contact, the entire inner circumferential surface of the three jaws tightens the entire outer circumference of the PC strand in the form of surface contact, while the outer circumference of the three jaws and the entire tapered hole of the socket are surface contacted. Concentrates acting on the circumference of the PC strand and the wedge, thereby allowing the wedge and the entire surface of the PC strand inserted into the wedge to be tightened with a uniform compressive load. The present invention relates to a wedge for a PC steel wire for fixing a structural structure to prevent breakage of the PC strand and the positional change of the wedge due to a load, and to maintain a stable state of the structural structure.

Wedge for fish (PC) steel wire according to the present invention, the ground (1) on which the construction structure is constructed, the anchor 17 in which the uneven pipe 2 of the predetermined length is inserted into the distal end thereof is ground by the grout material (4). (1) is fixed to the inside of the anchor (6) the fixing means for holding the front end of the PC (stranded steel) strands (3) is inserted into and fixed to the inside of the ground (1) And the fixing means includes a socket 8 into which the exposed end side of the PC strand 3 exposed to the outside of the anchor bracket 6 is inserted through the tapered hole 7, and the socket ( It consists of a wedge 16 of the collet chuck form that is inserted into the tapered hole (7) of the wedge type, the wedge (16) is one incision (9) in which the entire thickness of the body is cut in the longitudinal direction ) And two waves in which a thin cutout portion 11 is formed in the inner portion by forming the cutout groove 10 in the longitudinal direction only outside the flesh thickness of the body. The incision groove 12 is divided into a predetermined angle and has three jaws 13 by each incision 9 and a fracture incision groove 12, and the inside of the jaws 13 is a PC (PC). In the case where a plurality of clamping teeth 15 for clamping the strand 3 are formed along the inner circumference of the through hole 14, the three jaws 13 have the inner circumferential curvature of the through hole 14 of the wedge 16. The outer periphery curvature of the three jaws 13 is formed at a ratio of 70 to 90% larger than the outer diameter curvature of the pre-compression of the fish (PC) strand wire (3) inserted through the respective incisions (9) and fracture incisions It is formed at a ratio of 70 to 90% larger than the outer diameter curvature of the virtual outer circumference formed by the groove 12, and is equal to the shrinkage ratio of the PC strand 3 when the outer diameter of the PC strand 3 is contracted. Thus, the curvature of the inner circumferential arcs of the three jaws (13) is formed to clamp the entire outer circumferential surface of the fish (PC) strand (3) by surface contact, and the outer circumferential arcs of the three jaws (13) and the The taper hole 7 of the socket 8 also has three jaws (3) which make the wedge 16 smaller by the curvature of the shrinkage of the thickness of the jaws 13 with the shrinkage of the PC strands 3. The outer circumferential surface of 13) and the taper hole 7 of the socket 8 are in surface contact, and can tighten each jaw 13 at a uniform pressure.

Description

An wedge for a PC steel wire for fixing construction structure

The present invention is a construction structure for fixing the construction structure with a ground anchor installed on the ground to prevent the construction structure collapse and fall by external forces such as earthquake, wind power, hydraulic pressure, soil pressure during construction of various construction structures Part of the fixing ground anchor, more specifically, the PC (stranded strand) curvature of three jaw inner circumferential arcs formed in a collet chuck form for clamping and fixing the strand (PC) strand of the ground anchor The three outer circumferential curvatures of the three (3) outer circumferential curvatures are made to be larger than the outer circumferential curvatures corresponding to the free state before compression by the jaws so that the PC strand becomes the same as the outer diameter curvature when the wedge is compressed by the wedge. By forming a curvature larger than the circular outer circumferential curvature formed by two jaws, the PC strand is pressed inside the wedge. When the shaft is in contact, the entire inner circumferential surface of the three jaws tightens the entire outer circumference of the PC strand in the form of surface contact, while the outer circumference of the three jaws and the entire tapered hole of the socket are surface contacted. Concentrates acting on the circumference of the PC strand and the wedge, thereby allowing the wedge and the entire surface of the PC strand inserted into the wedge to be tightened with a uniform compressive load. The present invention relates to a wedge for a PC steel wire for fixing a structural structure to prevent breakage of the PC strand and the positional change of the wedge due to a load, and to maintain a stable state of the structural structure.

As shown in Fig. 1, the stabilization construction of (a) and the tunnel reinforcement construction of (b), the retaining wall protection construction of (c), the suspension bridge installation construction of (d), and the stabilization construction of the piers of d) During the construction of the fall prevention works of steel towers and large chimneys, and other civil engineering and building structures that build various buildings such as high-rise buildings, the civil structures to be constructed are subject to external forces such as earthquakes, wind power, hydraulic pressure, and pneumatic pressure. In order to prevent collapse or fallover, the ground anchors 17 are used to support and fix various civil structures.

As shown in FIG. 2, the ground anchor 17 used to support and fix various civil structures as described above has a concrete pour layer having a predetermined thickness on an upper surface or a side surface of the ground 1 on which the civil structures are constructed. 5) After the hole is formed from the concrete placing layer 5 to the ground 1 to a predetermined depth, and after the hole is drilled into the ground 1, the uneven pipe 2 is formed by a predetermined length at the distal end thereof. Insert the extrapolated PC strand (3).

Then, the liquid or gel grout material 4 is injected into the perforated hole to fix the PC strand 3 in the perforated hole, and the concrete exposed to the outside of the concrete pouring layer 5. An anchor plate and an anchor bracket 6 made of an “H” beam or a metal plate are installed on the surface of the pour layer 5, and the outside of the anchor bracket 6 is exposed to the outside of the anchor bracket 6 and various civil structures And a PC (PC) strand wire clamping fixing means for clamping and fixing the exposed end of the PC (PC) strand wire (3) is connected and fixed.

As described above, the PC (stranded) wire (3) having a long length and a large tensile strength is buried deeply in the ground (1), and then the tip of the fish (PC) strand (3) exposed to the outside of the ground (1) is anchor bracket ( 6) and the PC (PC) strands (3) is fixed as a clamping means, even if the construction structure is shaken by external forces such as earthquake, wind, hydraulic pressure, earth pressure, including the PC (stranded steel) (3) The ground anchors 17 hold firmly the construction structures to prevent the construction structures from collapsing or falling over.

As described above, the conventional clamping fixing means for the PC strand PC 3 installed at the tip exposed portion of the ground anchor 17 is exposed to the outside of the anchor bracket 6, as shown in FIGS. The collet chuck which is inserted into the socket 8 and the tapered hole 7 of the socket 8 is inserted in the exposed end side of the PC strand strand 3 to be inserted through the tapered hole 7. It consists of a wedge 16 in the form.

The wedge 16 is composed of three jaws 13 by respective incisions 9 formed at a predetermined angle, and the PC (stranded wire) 3 is inserted into the inner surface of each jaw 13. A plurality of clamping teeth 15 are formed to clamp the PC strands 3 along the inner circumference of the through hole 14.

When clamping the PC strand 3 using the conventional socket 8 and the wedge 16 having the above configuration, as shown in Figures 2 and 4, the anchor bracket ( In the state where the PC stranded wire 3 is inserted through the tapered hole 7 of the socket 8 provided on 6), the wedge 16 is socketed outward of the PC stranded wire 3. The wedge is inserted into and installed on the (8), but the wedge 16 is strongly pushed in the "a" direction while pulling the PC strand 3 in the "b" direction as shown in FIG. .

As the wedge 16 is pushed toward the tapered hole 7 side of the socket 8 while pulling the PC stranded wire 3 to the outside as described above, the wedge 16 formed in the collet chuck shape is tapered hole 7. Wedge 16 is inserted into the wedge 16, the three jaws (13) in the contraction inwardly as the first incision in the incision (9) in which the entire thickness of the body is cut into the incision (9) ) Both ends of the grooves are in close contact with each other, so that the three jaws 13 contract more and more, and the three jaws 13 that contract in this way firmly bite the fish (PC) strands (3) and the fish (PC) strands (3) The end exposed to the outside of the is firmly fixed.

As described above, after firmly fixing the exposed end of the PC strand 3, the wedge 16, which is a clamping fixing means of the PC strand, is removed when the force to pull the PC strand 3 is removed. ), And the installation work of the socket (8) is completed, the PC strand (3) buried in the ground is to pull the construction structure with a strong tensile force and by external forces such as earthquake, wind, water pressure, pneumatic pressure It is possible to prevent the civil structure from collapse or fall over.

In the process of installing the wedge 16 and the socket 8 as described above, the initial step of installing the wedge 16 into which the PC (PC) strand 3 is inserted into the socket 8, that is, the wedge 16 is In the initial stage without wedge action, the outer circumferential surface of the wedge 16 and the entire inner circumference of the tapered hole 7 are in contact with each other in the form of surface contact, as shown in FIG. 5 (a), into the through hole 14 of the wedge 16. The inserted PC strands 3 are also in overall contact with the inner circumferential surfaces of the three jaws 13, but as the PC strands 3 are pulled outward, the wedge 16 is inserted into the wedge. After completing the installation work of the wedge 16 and the socket 8, that is, the clamping work on the PC strand 3, the three jaws 13 as shown in FIG. Both of the peripheral edges do not maintain a rounded state, and the parts contacting both ends of the three arcs (c, d) of the jaws 13 have a shape where the angles meet each other.

In this way, the three arcs do not maintain the original state, and the contact portions at both ends meet at an angle, so that the wedge 16, which maintains the original state in the initial plane, clamps the PC strand 3. The spaces of the jaws 13 adjacent to each other in each of the gaps are removed from each other by removing three spaces corresponding to the cutouts 9 and the cutouts 10 formed in the wedge 16. To meet each other.

As described above, when the angle at each of the jaws 13 meets each other, as shown in (b) of FIG. 5, a predetermined distance is formed between the inner circumferential surface of the tapered hole 7 and the outer circumferential surfaces of the three jaws 13. A gap e is formed, which causes three points of contact between the inner circumferential surface of the tapered hole 7 and the outer circumferential surface of the wedge 16 at the point f indicated by a dot in FIG. Instead of tightening the entire jaw 13 at a uniform pressure, the concentrated load acts on three point contact areas, which causes the first problem of lowering the tightening force of the jaw 13.

In addition, since the inner circumference of the three jaws 13 clamping the PC strand 3 is not in the same circular state as the outer circumference, the entire outer circumferential surface of the PC strand 3 cannot be contacted. This is because the curvature of each jaw 13 inner circumferential arc d is formed to have the same curvature as the free outer diameter before the PC strand 3 is compressed. In the clamping process, the outer diameter of the PC strand 3 is reduced by the three jaws 13, while the curvature of the inner peripheral arc of each jaw 13 is maintained at an initial state, and thus the clamping is completed. The inner circumferential curvature of the jaw (13) is smaller than the outer diameter curvature of the reduced PC strand (3) so that the outer circumferential surface of the fish (PC) strand 3 and the inner circumferential surfaces of the three jaws 13 do not come into contact as a whole. will be.

As such, since the outer circumferential surface of the PC strand 3 and the inner circumferential surface of the three jaws 13 do not come into contact with each other, the outer circumferential surface of the PC strand 3 and the inner circumferential surface of the three jaws 13 are partially. In this way, the concentrated load acts only on the contact portion that makes point contact, and thus, the PC strands 3 are easily damaged from the contact portion subjected to the concentrated load, and as the state continues, the PC (PC) There was a problem that the strand 3 gradually breaks, and the outer circumferential surface of the wedge 16 also had a problem in that the concentrated load due to the point contact occurs to maintain the fixed state stably.

The present invention has been made to solve the above conventional problems, the inner circumference of the wedge clamping the fish (PC) strands when the fish (PC) strands are compressed contacting the outer circumference of the PC strands as a whole The outer peripheral surface of the wedge and the tapered hole inner circumferential surface of the socket also make contact with the entire surface during clamping of the PC strand, thereby stably maintaining the fixed state of the PC strand and at the same time forming a wedge. The three jaws and the PC strands clamped inside the jaws can be tightened to a uniform pressure as a whole, which increases the breaking load of the PC strands at the portion where the wedge is clamped. It is therefore a technical task to be able to withstand even greater tensile forces pulled from the ground.

The present invention for achieving the above technical problem, the socket is provided with a tapered hole in the exposed end of the PC (stranded) strand that the end is inserted into the ground and the tip is exposed to the outside of the ground surface, and the collet chuck in the socket In the wedge type clamping fixation of the wedge (PC) strands while being inserted in the form, the three jaw inner circumferential curvature formed in the wedge is inserted into the through hole of the wedge (PC) strand The outer circumferential curvature of the three jaws is formed at a ratio greater than the outer circumferential curvature of the virtual outer circumference formed by each of the cutouts and the fracture cutting grooves.

Figure 1 (a) to (bar) is an exemplary view showing an embodiment for fixing various construction structures as ground anchors.

2 is a cross-sectional view showing a state of use of the ground anchor.

3 is an exploded perspective view showing a conventional wedge and a socket.

4 is an assembled cross-sectional view of the conventional wedge and the socket shown in FIG.

5A is a cross sectional plan view showing a state of use of a conventional wedge and a socket, (A) is a plan sectional view of an assembled state before the wedge clamps the PC strand, and (b) is Flat sectional view of the wedge and socket assembled when the wedge clamps the PC strand.

Figure 6 is a plan view showing the assembled state of the wedge and the socket of the present invention.

Figure 7 (a) (b) is a plan view of the wedge and the socket according to the present invention.

8 is a cross-sectional view of the coupled state of the present invention.

<Explanation of symbols for main parts of drawing>

1: Ground 2: Uneven pipe 3: PC strand

4: grout material 5: concrete pouring layer 6: anchor bracket

7: taper hole 8: socket 9: incision

10: incision groove 11: breaking portion 12: breaking incision groove

13: jao 14: through hole 15: clamping

16: Wedge 17: Ground Anchor

The present invention for achieving the above object will be described with reference to FIGS. 6 to 8.

The ground anchor for anchoring a construction structure according to the present invention is a socket having a tapered hole (7) at an exposed end of a PC strand (3) in which its distal end is inserted and fixed to the ground and its tip is exposed to the outside of the ground surface. (8) and a wedge (16) for clamping the PC (stranded) strand 3 while being inserted in the form of a collet chuck in the socket (8) is clamped in a wedge fashion.

The wedge 16 has one incision 9 in which the entire flesh thickness of the body is cut in the longitudinal direction, and the cutout 10 is formed in the longitudinal direction only in the outer part of the flesh thickness of the body to form a thin fracture portion at the inner part. Two break incision grooves 12 are formed at a predetermined angle to form three jaws 13 by the respective incisions 9 and the break incision grooves 12. 13, a plurality of clamping teeth 15 for clamping the PC strand 3 are formed along the inner circumference of the through hole 14.

In addition, the three jaws 13 formed in the wedge 16 have an inner circumferential curvature that is smaller than the outer diameter curvature of the PC strands 3 inserted through the through holes 14 of the wedge 16. The outer periphery curvature of the three jaws 13 is also formed at a larger ratio than the outer diameter curvature of the virtual outer periphery formed by each of the cutouts 9 and the breakaway cutouts 12.

Referring to Figures 6 to 8 the operational relationship of the present invention configured as described above is as follows.

When clamping the PC strand 3 using the socket 8 and the wedge 16 according to the invention, as shown in Figs. 2 and 8, on the anchor bracket 6 In the state where the PC stranded wire 3 is inserted through the tapered hole 7 of the installed socket 8, the wedge 16 is placed on the socket 8 outside the PC stranded wire 3. The wedge is inserted into the installation, but as shown in FIG. 8, the wedge 16 is strongly pushed in the "a" direction while pulling the PC strand 3 in the "b" direction.

As the wedge 16 is pushed toward the tapered hole 7 side of the socket 8 while pulling the PC strand 3 to the outside as described above, the wedge 16 formed in the collet chuck shape is tapered hole 7. Wedge (16) is inserted into the wedge (16), the three wedges in the three incisions into the grooves of the incision (9) is in close contact and pull the PC (PC) strands (3) in the "b" direction In proportion to the three jaws 13 are further contracted.

In addition, the wedge 16 according to the present invention has a ratio of three inner jaw curvature of the three jaws 13 is larger than the outer diameter curvature of the pre-compression of the PC (PC) strand wire 3 is inserted into the through hole 14 of the wedge 16. And the outer periphery curvature of the three jaws 13 is formed at a ratio greater than the outer diameter curvature on the virtual outer periphery formed by each of the cutouts 9 and the break incision grooves 12 so that the inside of the wedge 16 The outer periphery is not formed as a garden, and the inner and outer diameters are reduced as three wedges are retracted in the process of the wedge 16 is inserted into the wedge through the tapered holes 7, The outer and inner circumference of the wedge 16 is almost a garden by the outer diameter.

At this time, the inner diameter (inner circumference of three jaws connected) of the reduced garden state as described above is the fish (PC) strands (PC) to improve the tightening force of the fish (PC) strands 3 by the wedge 16 to the maximum ( 3) is preferably the same as the outer diameter reduced to 2 or 5% or less, but the compression ratio and wedge of the PC (PC) strands (3) inserted through the tapered hole (7) of the socket (8) Considering the thickness that can be safely applied to each jaw 13 of 16), the inner circumferential curvature of each jaw 13 is 70 to 90% greater than the outer diameter curvature of the PC strand 3 before compression. It is most preferable to improve the tightening force of the PC strand (3) by the wedge (16). In addition, the inner surface of the tapered hole (7) is a through hole (14) through which the PC (stranded strand) 3 is inserted. (C) when clamping the PC strands (3) because they are formed as inclined surfaces that form concentric circles with respect to the center point of In order to make the outer circumferential surface of each jaw 13 constituting the paper 16 with the inner surface of the tapered hole 7 forming a planar garden as a whole, each jaw (C) is compressed while compressing the PC strand 3. 13) the curvature capable of concentric circles with the inner circumferential surface, that is, the outer circumferential curvature of the three jaws 13 is formed by each of the cutouts 9 and the breakaway cutouts 12 formed in the wedge 16 in the longitudinal direction. It is preferable to form it in 70 to 90% larger ratio than the outer diameter curvature of a virtual outer periphery.

As described above, the inner and outer diameters of the wedges 16 are reduced to form a garden, so that the outer circumferential surface of the wedge 16 including three jaws 13 is generally formed with the inner circumferential surface of the tapered hole 7 of the socket 8. The surface contact is made, and as a result, the compressive load generated by the wedge action acts uniformly inward from the entire outer circumference of the wedge 16, thereby increasing the tightening force for tightening the three jaws 13.

In addition, since the inner diameter of the wedge 16 also forms a garden in a reduced state, the outer periphery of the PC strand 3 inserted into the inner through hole 14 of the wedge 16 and the three jaws 13. Since the inner circumferential surface of the entire surface contact, it is possible to clamp the PC strand (3) at a uniform pressure.

As described above, after firmly fixing the end exposed to the outside of the PC strand (3) to remove the force to pull the PC strand (3) is a clamping fixing means of the PC (strand) PC (3) The installation work of the wedge 16 and the socket 8 is completed, and the PC strand 3 embedded in the ground pulls the civil structure with a strong tensile force, such as earthquake, wind, hydraulic pressure, and pneumatic pressure. It is possible to prevent the civil structures from collapsing or falling over by external forces.

As described above, the ground anchor for fixing a civil structure according to the present invention is tightened while the inner circumference of the wedge clamping the PC strand is in contact with the outer circumference of the PC strand when the PC strand is reduced. The outer circumferential surface of the wedge and the tapered hole inner circumference of the socket also allow the three jaws to be tightened while being in surface contact with each other when clamping the PC strand. It can be clamped by pressure, which increases the breaking load of the part of the PC strand that the wedge is clamping, and reduces the positional change of the wedge by the line contact due to the stable fixing of the wedge. There is an effect that allows the civil structures to withstand even greater tensile forces.

Claims (1)

(Correct) The socket 8 having a tapered hole 7 at the exposed end of the PC strand 3 in which the distal end is inserted into and fixed to the ground and the distal end thereof is exposed to the outside of the ground surface, and the socket 8 In the ground anchor for clamping the construction of the construction of the construction of the wedge (16) which is clamped to the wedge (16) for clamping the fish (PC) strand (3) while being inserted in the form of a collet chuck, The inner circumferential curvature of the three jaws 13 formed in the wedge 16 is 70 to 90% greater than the outer diameter curvature of the PC strand 3 inserted through the through hole 14 of the wedge 16. Formed in a large proportion, Civil structure, characterized in that the outer circumferential curvature of the three jaws 13 is formed in a ratio of 70 to 90% greater than the outer diameter curvature of the virtual outer circumference of each incision 9 formed in the longitudinal direction in the wedge 16 Wedges for PC steel wire for fixing.