KR102441816B1 - Prestress-measurable anchorage - Google Patents

Abstract

The present invention relates to an anchorage capable of measuring prestress, comprising: a wire wound around an outer circumferential surface of a column structure; a fixing member provided at both ends of the wire to fix the wire; and an elastic member provided between the fixing members to measure prestressing applied to the wire, wherein a restraining force is generated in the column structure when the fixing member is fastened and prestressing is applied, thereby capable of generating prestressing to the wire to generate the restraining force on a cross section of a concrete column.

Description

Prestress-measurable anchorage {Prestress-measurable anchorage}

The present invention relates to a fixing device capable of measuring prestress, and more particularly, it is installed on the outer circumferential surface of a non-seismic reinforced concrete column structure to apply a restraining force to a cross section of a concrete column, and a fixation capable of measuring a prestress capable of calculating the prestress acting on a wire It's about the device.

In general, concrete structures are composed of a mixture of materials with different properties, such as cement, aggregate, and admixture. The demand for seismic reinforcement of structures is increasing according to the reinforcement of

As the shape of concrete structures becomes more diversified and complicated in recent years, loads more than the design load are often applied. There is also a risk of escalation into a major accident, such as a decrease in seismic performance.

On the other hand, there are three main methods for seismic reinforcement of existing non-seismic concrete structures. First, the method of increasing the toughness of the concrete structure, the second method of increasing the horizontal bearing capacity of the concrete structure, and the earthquake of the concrete structure There are ways to reduce the input.

Among them, the method of increasing the toughness of a concrete structure is known to improve the strength of the concrete column and improve the toughness at the same time when the concrete column is restrained. A method of improving the strength or toughness of a structure by constructing it as a fiber-reinforced plastic (FRP) is being made.

However, in this seismic reinforcement method, the FRP cannot be wound over the front section of the column for a square column, so the strength of the fiber cannot be sufficiently exhibited when an external force is applied. there was

Recently, a spacer for surface restraint on the cross section of a concrete structure and a wire are installed on the outer peripheral surface of the spacer and prestressing is applied to the wire. A seismic reinforcement method capable of increasing ductility has been proposed.

However, this seismic reinforcement method has the advantage of being easy to construct, but when the shape or size of the non-seismic concrete column and the spacer to be constructed are different, it is difficult to calculate the prestressing strength required to apply the necessary restraint force to the cross section of the concrete column. there is

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a fixing device capable of measuring a prestress for generating a prestress on a wire in order to generate a restraining force on a cross section of a concrete column.

Another object of the present invention is to provide a fixing device capable of measuring the prestress of the wire by fixing the wire and calculating the prestressing of the wire by changing the length of the elastic member between the fixing devices.

A fixing device capable of measuring prestress according to the present invention for achieving the above object is a wire wound around the outer circumferential surface of a column structure, a fixing member provided at both ends of the wire to fix the wire, and the wire provided between the fixing member It comprises an elastic member for measuring the prestressing applied to the, characterized in that when the fixing unit is fastened to apply the prestressing force to the column structure is generated.

In addition, the fixing member includes a cylindrical first anchorage mounted on one end of the wire, a second anchorage mounted on the other end of the wire, and one end of the wire inside the first and second anchorages. It is characterized in that the wire fixing portion for fixing is provided.

In addition, the wire fixing portion is a hollow wire insertion portion in which the inner diameter is reduced in one direction of each of the first and second anchorages, and the wire insertion portion has a smaller diameter of the outer circumferential surface in one direction, and is combined to form a hollow It is characterized in that one or more fixing pieces are provided.

In addition, it is characterized in that the friction portion is provided on the inner surface of the fixing piece and the end of the wire.

In addition, a fastening bolt is formed on one side of the elastic member and the other side is fastened to the second anchorage, a fastening nut is formed inside the other side of the first anchorage, and the fastening bolt of the elastic member is fastened to the first anchorage It is coupled to the nut to fasten the first anchorage and the second anchorage.

In addition, the first anchorage includes a rotatable cylindrical body, the cylindrical body is integrated with the fastening nut characterized in that the displacement of the elastic member changes when the cylindrical body is rotated.

The fixing device capable of measuring the prestress according to the present invention as described above can provide a fixing device capable of measuring the prestress of prestressing and fixing the wire so that it can be wound around the cross section of the concrete structure to be constructed and can easily apply a restraining force to the cross section of the structure.

In addition, the fixing device capable of measuring prestress according to the present invention applies prestressing to the cross section of the column, and a fixing device capable of measuring the prestress that can easily calculate the required restraint force applied to the cross section of the column by changing the length of the elastic member interposed between the anchors. can provide

1 is a view showing that the anchorage according to the present invention is constructed on a circular column;
2 is a view showing that the anchorage according to the present invention is constructed on a prismatic column;
3 is a view showing the overall configuration of a fixing device capable of measuring prestress according to the present invention;
4 is a view showing the internal structure of the anchorage according to the present invention,
Figure 5a, Figure 5b is a view for explaining the operation of the wire fixing unit according to the present invention, and
6A and 6B are views for explaining the operation of the elastic member according to the present invention.

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

Like reference numerals in each figure indicate like elements. In addition, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, when a part "includes" a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

1 is a view showing that the anchorage according to the present invention is constructed on a circular column, Figure 2 is a view showing that the anchorage according to the present invention is constructed on a prismatic column, Figure 3 is a prestress according to the present invention according to the present invention It is a view showing the overall configuration of the anchorage capable of measuring, Figure 4 is a view showing the internal structure of the anchorage according to the present invention.

As shown in FIG. 3, the fixing device 100 capable of measuring the prestress includes a wire 110 wound around the outer circumferential surface of the column structure, and a fixing member ( 120 and 130 , and an elastic member 200 provided between the fixing members 120 and 130 to measure the prestressing applied to the wire 110 .

The fixing device 100 configured as described above is constructed on the outer circumferential surface of the non-seismic reinforced concrete column structure to apply a restraining force to the cross section of the concrete column. As shown, the wire 110 is wound around the outer circumferential surface of the circular column structure 1, and the fixing members 120 and 130 at both ends of the wire 110 are fastened to apply pre-stressing to the cross section of the column structure 1 . In addition, if the non-seismic reinforced concrete to be constructed is a prismatic column structure 2, the wire 110 may be wound around the outer circumferential surface of the column structure 2 similarly, but sufficient restraining force is not applied to the corner portion of the prismatic column. In this case, as shown in FIG. 2 , a spacer 2a having a circular outer circumferential surface or a separate protective member is installed between the pillar structure 2 and the anchorage 100 to reduce the binding force generated by the anchorage 100 by the spacer. (2a) can be transmitted to the cross section of the column structure (2).

In this way, a plurality of fixing devices 100 installed on the cross-section of the column structures 1 and 2 are installed in the height direction of the column structures 1 and 2 to apply a restraining force to the overall cross-section of the column structures 1 and 2 have.

The wire 110 is wound around the outer circumferential surface of the non-seismic reinforced concrete column structures 1 and 2, which is the subject of seismic reinforcement, to generate a binding force on the surface of the column structures 1 and 2). The wire 110 may be formed by twisting a steel wire or a plurality of fiber bundles, and the fiber may use a reinforcing fiber exhibiting high tensile strength such as glass fiber, and other aramid fibers, basalt fibers, metal fibers, silica fibers can be used alone or as a composite material.

The anchoring members 120 and 130 include a first anchorage 120 and a second anchorage 130, and each anchorage is provided with a first insertion hole 121b to which an end of the wire 110 is mounted on one side of each anchorage. A hollow (121a) is formed inside the at least one anchorage.

A wire fixing part 122 is provided inside each anchorage. The wire fixing unit 122 is a cylinder that extends from one hollow side of the anchoring unit 120, 130 toward the center, and inside the wire fixing unit 122, the anchoring unit 120, 130 has a first insertion hole at one end of the first insertion hole (121b). A hollow communicating with is formed, and the inner diameter of the wire inserting part 122a decreases toward one end of the anchorage 120, 130 and movable along the inner circumferential surface of the wire inserting portion 122a, the anchorage 120, It includes one or more fixing pieces (122b) having a tapered shape that reduces the diameter of the outer circumferential surface toward one end of the 130).

The fixing piece 122b may be assembled by moving in the direction of the insertion hole of the anchoring ports 120 and 130 along the inner circumferential surface of the wire insertion part 122a, and the inner surface of the fixing piece 122b is assembled with the end of the wire 110 and A hollow through which it can pass is formed. At this time, the inner surface of the fixing piece (122b) is preferably to form a screw thread, a protrusion, etc. to increase the friction force coupled with the end of the wire (110), in this case, the end of the wire (110) also the inner surface of the fixing piece (122b) and Threads, protrusions, etc. may be formed to increase the coupling friction force. The size of the hollow formed by assembling the fixing piece 122b is preferably the same as or smaller than the diameter of the end of the wire 110 .

The elastic member 200 is a member for connecting and fixing the first anchorage 120 and the second anchorage 130, and a spring 210 for measuring prestressing caused by fixing the first and second anchorages 120 and 130. ) is included.

A first support plate 220 and a second support plate 230 for supporting the spring are provided on one side and the other side of the spring 210 , respectively, and the first support plate 220 has a second insertion hole on the other side of the first anchorage hole 120 . A connection bolt 240 connected to the (121c) is formed. At this time, a nut may be formed in the second insertion hole 121c of the other side of the first anchorage 120 to fasten the connection bolt 240 . The second support plate 230 is coupled to the other side of the second anchorage 130 . At this time, the second support plate 230 and the second anchorage 130 may be fastened by screw coupling, etc., but may be integrally formed, but is not limited thereto.

Hereinafter, an operation of fixing the wire 110 to the fixing members 120 and 130 will be described. 5A and 5B are views for explaining the operation of the wire fixing unit according to the present invention. The fixing of the anchorage of the wire 110 below will be described based on the first anchorage 120 , but may be equally applied to the second anchorage 130 .

First, the end of the wire 110 is put into the first insertion hole 121b formed on each side of the first anchorage 120 and the second anchorage 130 to insert the end of the wire 110 into the wire insertion portion 122a inside. placed in

As shown in FIG. 5A , the wire 110 is pushed into the space of the wire inserting part 122a and the fixing piece 122b inside the wire inserting part 122a is retracted in the other direction of the first anchorage 120 . At this time, the inner surface of the fixing piece (122b) forms a thread or protrusion to increase the frictional force coupled with the end of the wire (110), so that the inner surface of the fixing piece (122b) is in contact with the end of the wire (110) and the first anchorage ( 120) can be retreated in the other direction.

After that, when the wire 110 is wound around the column structures 1 and 2 and prestressing is applied to the wire 110, the wire 110 is subjected to a force in a direction drawn out from the first anchorage 120, at this time the fixing piece ( 122b) moves along the wire 110 in one direction of the first anchorage 120 , that is, in a direction in which the inner diameter of the wire insertion part 122a decreases.

The fixing piece 122b presses the end of the wire 110 as shown in FIG. 5b as the inner diameter of the wire insertion part 122a decreases while moving. Due to the pressure of the end of the wire 110 and the friction member formed on the inner surface of the fixing piece 122b, the wire 110 does not slip from the fixing piece 122b, and it is possible to prevent the wire 110 from being pulled out from the anchorage.

Hereinafter, the operation of the elastic member 200 according to the prestressing of the fixing members 120 and 130 will be described. 6A and 6B are views for explaining the operation of the elastic member 200 according to the present invention.

The fixing device 100 capable of measuring prestress according to the present invention calculates the tensile force value for each stretch volume of the spring 210 of the elastic member 200 in advance, and when fixing the fixing members 120 and 130, the elastic member 200 ), it is possible to calculate the prestressing of the fixing device 100 by securing the amount of stretching.

5A and 5B, the end of the wire 110 is mounted on the fixing members 120 and 130 and the wire 110 on the pillar structures 1 and 2 to apply prestressing to the wire 110. Wind the first anchorage 120 and the second anchorage 130 as close to each other as possible. At this time, the length of the wire 110 is designed so that the first anchorage 120 and the second anchorage 130 do not contact each other, but preferably the connection bolt 240 of the elastic member 200 to be described later is the first anchorage 120 . ) may select the length of the wire 110 to contact the second insertion hole (121c).

The connection bolt 240 of the elastic member 200 interposed between the first anchorage 120 and the second anchorage 130 is screwed into the second insertion hole 121c of the first anchorage 120 as shown in FIG. 6a. As described above, the first anchorage 120 and the second anchorage 130 are fastened. At this time, prestressing begins to be applied to the wire 110 and a binding force to the column structures 1 and 2 is generated.

In this case, the coupling of the connection bolt 240 and the first anchorage 120 may be performed by rotating the cylindrical body of at least one anchorage of the first anchorage 120 or the second anchorage 130 in the forward direction.

As the anchorage is rotated in the forward direction, the connecting bolt 240 moves into the hollow 121a of the first anchorage 120 in a state where the anchoring members 120 and 130 do not move as shown in FIG. 6b . As the connection bolt 240 moves to the first anchorage 120 , the spring 210 of the elastic member 200 is extended. Thereafter, the amount of stretching of the spring 210 is adjusted by rotating the anchor so that the tensile force value by the first anchorage 120 and the second anchorage 130 may have a previously designed value.

In this way, when the first anchorage 120 and the second anchorage 130 are constructed on the non-seismic concrete column structures 1 and 2, which are construction targets, using the anchorage device 100 capable of measuring the prestress according to the present invention, Calculate the tensile force value for each amount of stretching of the spring in advance, so that the amount of stretching of the spring 210 of the elastic member 200 secures a predetermined displacement when the first anchorage 120 and the second anchorage 130 are fastened. By adjusting the wire 110 or the fixing members 120 and 130, the tensile force value applied to the column structures 1 and 2, that is, the binding force can be checked.

In addition, the fixing device 100 capable of measuring the prestress according to the present invention checks the elongation amount of the spring 210 in order to check whether the restraining force applied to the column structures 1 and 2 is equal to or greater than the design load value as described above. A typical displacement sensor may be included in any one of the first anchorage 120 and the second anchorage 130 so as to be able to do so.

110: wire 120: first anchorage
130: second anchorage 200: elastic member

Claims (6)

a wire wound around the outer periphery of the column structure;
a fixing member provided at both ends of the wire to fix the wire; and
and an elastic member provided between the fixing members to measure prestressing applied to the wire,
A fixing device capable of measuring prestress, characterized in that when the fixing unit is fastened and prestressing is applied, a binding force is generated on the column structure. The method of claim 1,
The fixing member is a cylindrical first anchorage mounted on one end of the wire,
and a second anchorage mounted on the other end of the wire,
A fixture capable of measuring prestress, characterized in that a wire fixing part for fixing the end of the wire is provided inside one side of the first and second anchorages. 3. The method of claim 2,
The wire fixing portion is a hollow wire insertion portion in which the inner diameter is reduced in one direction of each of the first and second anchorages, and the wire insertion portion has a smaller diameter of the outer circumferential surface in one direction, and is combined to form a hollow A fixture capable of measuring prestress, characterized in that the above fixing piece is provided. 4. The method of claim 3,
A fixture capable of measuring prestress, characterized in that a friction part is provided on the inner surface of the fixing piece and the end of the wire. 3. The method of claim 2,
A fastening bolt is formed on one side of the elastic member and the other side is fastened with the second anchorage,
A fastening nut is formed inside the other side of the first anchorage,
A fixture capable of measuring prestress, characterized in that the fastening bolt of the elastic member is coupled to the fastening nut of the first anchorage to fasten the first anchorage and the second anchorage. 6. The method of claim 5,
The first anchorage includes a rotatable cylindrical body, wherein the cylindrical body is integrated with the fastening nut so that when the cylindrical body is rotated, the displacement of the elastic member is changed.

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