KR100296882B1 - Fixture for anchor in ground - Google Patents

Abstract

The present invention provides a tension anchor removal type internal fixing body for a ground anchor which can be easily removed without the help of a dedicated drawing machine, and improves fabrication and assembly performance according to the reduction of the number of parts, reduction of manufacturing cost, weight reduction, improvement of the reliability of removing the tension member, and a dedicated drawing machine. In order to provide, the cylinder 11 which drilled the tension material hole 12, the resin outflow hole 13, and the electric wire hole 14 in the bottom of the main body 1 is formed, and this wedge seat is provided in this cylinder 11; A sleeve 3 formed by embedding the electric heating element 32 from which the electric wire 34 is drawn is inserted into the thermoplastic resin 31 to which the wire 34 is attached, and the resin leakage preventing plate 6 is inserted into the wedge seat 33. Hold the circumferential split wedge (5), put the resin leakage preventing ring (6) on the sleeve (3) and the wedge spring (7) on the wedge (4) to place the diaphragm (21) and step (22) With cap (2).

Description

Fixture for anchor in ground

The present invention relates to an anchor fixing body of the ground that can remove the tension member, in particular, to improve the fabrication and assembly performance according to the reduction of the number of parts, reduce the manufacturing cost, light weight, improve the reliability of removal of the tension material, and easy without a dedicated drawing machine It is related with the anchor fixing body of the ground to be able to remove the tension material.

As a ground anchor fixing member, there is a patent publication No. 96-4273. This prior art compensates for the shortcomings of tension member-removable internal fixtures proposed to use tension members twice as large as anchor holes, such as Japanese Patent Application Laid-Open Nos. 1-278615 and 2-47234. It is possible to fix the temporary earth wall by using, the main body wedge seat is formed where the hollow inner peripheral surface is circumferentially divided, the solar wedge inserting the split wedge into the split center member to sandwich the tension member of the center, Satellite wedges inserted into the wedge seat around the sun wedge, the center wedge into which the solar wedges are inserted and the satellite wedges and the same number of spacers that the satellite wedges sandwich between them to maintain their position, and the solar wedges and the satellite wedges It consists of an upper cover to prevent upward departure and a cap that covers the body.

However, the internal fixture of such a structure is required because the towing tension member for retrieving these tension members, in addition to the satellite wedge side tension member that exerts a substantially tensile force, that is, the towing tension member to be fitted to the solar wedge and the wedge to sandwich it, is an essential component. The increase in the number of components of the anchor is difficult to manufacture and assembly, and the increase in manufacturing costs due to the addition of the tension pulling material and the pulling work when drawing up the tension pulling material.

In addition, the inner surface of each spacer is given a taper corresponding to the tapered core material, and the side surface is given a taper corresponding to the taper of two adjacent satellite wedges, and the outer surface is too complicated to have an arcuate surface corresponding to the hollow of the body. It also has the disadvantage of increasing processing and assembly difficulty.

In addition, the sun wedge and the satellite wedge are made up of three parts of the circumference, and in order to maintain the shape of the combination wedge from assembling the anchor to the after assembly, the elastic ring is inserted into the outer surface of the wedge assembly. Form must be maintained. According to this need, an outer ring surface for each wedge member was machined with a ring ring for elastic rings. The machining of such a ring groove on the outer surface of a split wedge is difficult for machining, and the elastic ring fitted to the ring groove is fitted when the tension member is fitted. Interlocking the tension member is also quite inconvenient because it becomes an obstruction.

In the main body, the rear end of the center hole drilled in the axial direction was inserted in the center to insert a C-shaped stop ring for the center material so that the center material inserted into the center hole did not fall to the rear of the main body while the tension force was not applied. As a result, the internal structure of the main body becomes more complicated and the processing process increases.

And the core material may slip off when the pulling force is applied to the towing tension member if the towing tension member is loosely bitten by a mistake of operation by the solar wedge before removing the tension material. If this happened in the first place, the core wedge would not be retracted by the solar wedge and, of course, the satellite wedge would not open, confronting the irrecoverability of all tension members.

In addition, the tension member cannot be removed without the use of a dedicated drawing machine.

It is an object of the present invention to remove the tension member very easily without removing the sun wedge and the center member, the tension member for pulling the center member and the dedicated drawing machine, the removal path of the tension member is high, and the weight of the structure is simplified, fabrication and assemblability. It is to provide an anchor fixture for improved ground.

According to the present invention, a reinforcing fiber and an electric heating element are embedded in a thermoplastic resin having a property of being thermally decomposed and melted or vaporized when subjected to high heat, and at the same time, a sleeve having a wedge seat formed at the center thereof is housed in a cylinder of the main body, and the resin leaks at the wedge seat. Insert the prevention plate, insert the circumferential split wedge into the resin leakage prevention plate, the wire connected to the electric heating element is drawn out by the wire hole drilled in the bottom of the cylinder, the resin leakage prevention ring on the upper surface of the sleeve and on the wedge A ground anchor anchoring fixture is provided with a wedge spring mounted thereon.

1 is a partial cutaway front view of a tension member removing internal fixing body according to an embodiment of the present invention;

2 is a cross-sectional exploded view of the main body and the cap

3 is a partial cutaway front view of the sleeve;

4 is a partial cutaway front view of a sleeve according to another embodiment;

5 is a partial cutaway front view of a plurality of wedge seat sleeves;

Figure 6 is an illustration of the case of fixing the temporary earth wall using the internal fixing body

7 is an enlarged cross-sectional view of the internal fixing body when the thermoplastic resin body is thermally decomposed;

8 is an enlarged cross-sectional view of the internal fixture when the tension member is inverted in a removable state;

9 is a partial cutaway front view of a multi-tension tension member-removable internal fixture.

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

1: body 2: cap

3: sleeve 4: wedge

5: resin leakage prevention plate 6: resin leakage prevention ring

7: wedge spring 11: cylinder

12: tension material work 13: resin outflow hole

14: wire work 31: thermoplastic resin body

32: electric heating element 33: electric wire

34: wedge seat 35: reinforcing fiber

In Fig. 1, the main body 1 and the cap 2 are joined by a screwing method, and a sleeve 3 is inserted into the cylinder 11 of the main body 1 and a wedge in which the resin leakage preventing plate 5 is inserted. The wedge 4 is saddled at the left 31. In addition, the resin leakage preventing ring 6 is placed on the sleeve 3 and the diaphragm 21 of the cap 2 is pressed on the wedge 4 with the wedge spring 7 mounted thereon. The sleeve 3 is stably held in the main body 1 by the resin leakage preventing ring 6 pressed by the cap 2 and the wedge 4 by the wedge spring 7.

In FIG. 2, a cylinder 11 for a sleeve is formed at the upper end of the main body 1, and a tension hole 12 is drilled at the bottom center of the cylinder 11. In addition, the resin outflow hole 13 and the electric wire hole 14 are also drilled around the tension material hole 12. The tension material hole 12 is a hole for inserting the tension material in the lower portion of the main body 1, and the resin discharge hole 13 has a portion in which the thermoplastic sleeve 3 is thermally decomposed into the gel or liquid phase and falls under the cylinder 11. The exit hole is an exit port, and the wire hole 14 is a hole for pulling out the wire 34 connected to the electric heating element 32 embedded in the sleeve 3. The lower portion of the cylinder 11 is formed with a resin inlet chamber 15 in which the thermoplastic resin powder exits the resin outlet hole 13, and a male screw 16 for cap fastening is formed at the upper end of the outer peripheral surface.

On the lower end of the inner surface of the cap 2, a diaphragm 21 for pressing the wedge spring 7, a step 22 for pressing the resin leakage preventing ring 6, and a female screw 23 for fastening the main body are formed.

1 and 3, the sleeve 3 supports the wedge 4 in a state of being inserted into the cylinder 11, and is composed of a thermoplastic resin 31 and an electric heating element 32. As shown in FIG. A tapered wedge seat 33 is formed in the center of the sleeve 3.

The thermoplastic resin 31 is a resin that exists in a solid state at room temperature but is thermally decomposed and melted or vaporized once subjected to high heat so that the shape disappears. Such resins include polyamide-based MC nylon (trade name), polyacetal resins, polycarbonate resins, and the like. Since the thermoplastic resin 31 must be seated in the cylinder 11 as tightly as possible, it does not leak into the gap even when subjected to high fixing pressure, so that the outer diameter of the sleeve 3 is made to fit the inner diameter of the cylinder 11 closely. To be inserted.

The electric heating element 32 is for thermally decomposing the thermoplastic resin 31, but is shown as a nichrome wire coil in the drawing, but a nichrome plate is also possible. Here, the drawn wire 34 is for energizing the electric heating element 32 outside the anchor hole, and draws it short and connects the long conductor before fixing and pulls it out of the anchor hole to be connected to the external power source.

In Fig. 1, the resin leakage preventing plate 5 is made of high tensile steel sheet. While the wedge 4 is seated on the wedge seat 34, the thermoplastic resin 31 cannot withstand this while the sleeve 3 acts as a fixing load of the tension member and is pushed into the gap between the divided surfaces of the fixing wedge 4 When leaking, so-called creep phenomenon appears that the shape of the sleeve 3 itself is deformed. If this happens, however, the sleeve itself will inevitably lose its volume, and the sleeve will not be able to constrain the wedge completely, so it will not be able to fix the tension member. Even the possibility of extreme deterioration of the wedge's binding force to the tension member cannot be excluded. In the worst case, there is a possibility that the wedge bite deteriorates and the tension member detaches from the wedge by itself by contracting action corresponding to the settling load. Such a creep phenomenon never helps to fix the tension member, so it is necessary to prevent the thermoplastic resin 31 from leaking into the crack of the wedge 5 in any form. The resin leak prevention plate 5 does just that. The resin leakage preventing plate 5 is divided into circumferences by the number of wedges 4 and the like, and C type with a part of the circumferences.

In Fig. 4, another embodiment of the sleeve 3 is formed by laying the reinforcing fibers 35 on the wedge seat 33 or by impregnating the reinforcing fibers 35 on the thermoplastic resin 31 so that the sleeve 3a is placed on the wedge seat side. Can be mentioned. The reinforcing fibers 35 are preferably non-tacky fibers such as glass fibers, carbon fibers, and Kevlar fibers, which are not burned. When heat is applied to the sleeve 3 reinforced with the reinforcing fiber 35, the thermoplastic resin 31 is thermally decomposed so that the elongation change (shrinkage of the tensile material) due to the fixing load is pushed when the wedge 4 is pulled, so that the resin inlet chamber 15 is applied. Pushed out and only the remains of the reinforcing fibers 35 remain. Since the reinforcing fibers 35 are not quantitative, the function of the sleeve 3 relative to the wedge 4 is not impeded.

In FIG. 5, a sleeve 3b according to another embodiment is provided with two or more wedge seats 33 and a modified embodiment in which a reinforcing fiber 35 is embedded in a portion of the wedge seat 31 of the thermoplastic resin 31. will be. This sleeve 3 is for a multi-gut internal fixing body made to apply two or more strands of tension material.

In FIG. 1 again, the resin leakage preventing ring 6, which tightly presses the upper surface of the sleeve 3, is pushed toward the cap 2 by the thermoplastic resin 31 while the wedge 4 is subjected to a fixing load through the tension member. It prevents you from going.

Next, a method of sandwiching the tension member will be described.

First, the leaf-shaped sheet 8 is placed on the bottom of the cylinder 11. The sheet 8 is formed by drilling the tension material hole 81, the resin discharge hole 82, and the wire hole 83, which are in the same center as the tension material hole 12, the resin discharge hole 13, and the wire hole 14. will be. At this time, the tension material hole (12, 81), the resin outflow hole (13, 82) and the wire hole (14, 83) to match their centers, respectively.

The sleeve 3 is placed on the seat 8 and the wire 34 is pulled out by matching wire holes 83 and 14. Subsequently, the tension member (a) is inserted into the wedge seat (33) so as to deviate from the upper end of the wedge seat (33) of the sleeve (3) through the tension hole (12, 81) at the rear end of the main body (1). ) And insert the wedge (4) therein to bite the tension member (a). The resin leakage preventing ring 6 is placed on the sleeve 3, and the wedge spring 7 is placed on the wedge 4, and then the cap 2 is closed on the main body 1 and locked.

When the cap 2 is placed on the main body 1, the sleeve 3 is stabilized in the cylinder 11 by the pressing pressure of the cap 2 transmitted through the resin leakage preventing ring 6, and the wedge 4 is wedge. The pressing force of the cap 2 transmitted through the spring 7 stabilizes the posture on the sleeve 3 and at the same time urges the tension member a more strongly.

After inserting the internal fixing body (b) with the tension member (a) mounted in the anchor hole (h) as shown in FIG. 6 and curing the concrete (c), the temporary earth wall (d) is fixed and the external fixing body (e). A method of removing the tension member (a) after constructing an underground structure in a state where the outer end of the tension member (a) is fixed is described.

In FIG. 7, when the wire 34 drawn out of the temporary earth wall d is connected to the external power source and energized, the electric heating element 32 generates heat. The heat generation causes the thermoplastic resin 31 to be thermally decomposed to change into a gel, a liquid phase or vaporize. The thermally decomposed resin powder of the thermoplastic resin 31 is pushed by the shrinkage force according to the elongation corresponding to the anchoring load of the tension member and the force by which the wedge spring 7 presses the wedge 4 to press the sleeve 3 so that the resin outflow hole 13 Exit to). The volume of the sleeve 3 decreases as the thermally decomposed resin powder escapes. The wedge 4 is drawn by the contracting action of the wedge spring 7 and the tension member a to return to its original state, and stops at the moment when the bottom face touches the seat 8. After that, the thermal decomposition of the thermoplastic resin 31 continues and the elongation of the tension member a is still in effect.

In FIG. 8, the volume reduction of the sleeve 3 by the amount of the thermoplastic resin 31 which is pyrolyzed and disappears after the wedge 4 is stopped means a weakening of the restraining force on the wedge 4. The wedge 4 freed from the sleeve 3 has a weak force that forces the tension member a. Since the tension member (a) is still in a state of strong contraction force, the tension member (a) slides in the wedge (4) as if the wedge (4) did not overcome this force. It is thrown out and stays in the hose (f). This state is so free that it can be pulled out by hand from the outer fixing body (e). This eliminates the need for a dedicated drawer to remove the tension.

FIG. 9 relates to a multi-tension remover type internal fixture to which the sleeve 3b of FIG. 5 described above is applied.

As described above, the present invention reduces the volume of the thermoplastic resin sleeve by thermal decomposition due to the energization of the electric heating element, thereby reducing the pressure on the wedge, thereby reducing the force to pull the tension member and shrinking action according to the fixing load. It is configured to separate the tension member from the internal fixing by itself, the tension member removal internal fixing structure of the simple structure without the solar wedge, the center material supporting it and the tension member for the traction of the core material, the low-cost and lightweight tension material removal It is possible to provide a tension member-removable internal fixture capable of easily and reliably removing the tension member without mobilizing the mold internal fixture and the dedicated drawing machine.

Claims (2)

At the bottom of the main body 1, a cylinder 11 having punched the tension material hole 12, the resin outflow hole 13, and the electric wire hole 14 was formed, and the wires were connected to the thermoplastic resin 31 to which the wedge seat 33 was attached. 34 is inserted into the sleeve (3) formed by embedding the electric heating element 32, a resin leakage preventing plate (5) is inserted into the wedge seat (33), and the columnar wedge (4) is seated therein. A ground anchor anchored with a resin leakage prevention ring (6) on the sleeve (3) and a wedge spring (7) on the wedge (4), followed by a cap (2) with a diaphragm (21) and step (22). Dragon fixture. The anchoring fixture for ground according to claim 1, wherein the thermoplastic resin (31) of the sleeve (3) is reinforced with reinforcing fibers (35).