KR102404231B1 - insert anchor for concrete structure - Google Patents

Abstract

The present invention relates to an insert anchor for earthquake resistance of concrete. More specifically, an installation groove is formed in a concrete structure to enable an anchor to be firmly fixated to prevent loosening of a fixed state of the anchor by vibration or earthquake which is continuously applied. In addition, a bolt member constituting the insert anchor can be easily replaced according to necessity.

Description

Insert anchor for concrete seismic resistance {insert anchor for concrete structure}

The present invention relates to a concrete seismic insert anchor, and more particularly, by forming an installation groove in a concrete structure to firmly fix the anchor, it is possible to prevent the fixed state from loosening even in the case of continuously applied vibration or earthquake. Instead, the bolt members constituting the anchor can be easily replaced if necessary, and an earthquake-resistant spring is inserted into the through hole to support the inner circumferential surface of the installation groove from all directions, so that the bolt member is not biased to one side in the installation groove and is as much as possible. It relates to an insert anchor for seismic concrete supporting so as to be located in the center.

In general, in the case of Korea, earthquake resistance is very low, so there is no need for seismic design, so seismic design was not implemented. As a result, the current seismic design standards are not satisfied, and casualties are expected in the event of an earthquake.

However, in recent years, even in our country, it has been found to be an area with a high possibility of earthquake damage, and there are reports of actual earthquakes occurring in some areas. This is being proven.

Accordingly, it is necessary to improve the seismic performance by performing additional seismic reinforcement on the existing bridge, which is most likely to cause the most serious damage in the event of an earthquake. is becoming

The seismic reinforcement method of piers can be broadly classified into three methods: cross-section enlargement method, member extension method, and reinforcement insertion and attachment method.

On the other hand, in the case of the earthquake-resistant reinforcement method by means of steel plate coating, the method of installing one or more metal steel plates on an existing concrete pier is mainly used.

The seismic reinforcement method is mainly used for bridges without a pedestal device. One or more installation grooves are formed in a pier made of concrete material, and then a filler (chemical solution) is filled in the installation grooves, and then an insert anchor is inserted. After the hardening process, a metal steel plate is inserted into the insert anchor protruding out of the installation groove, and then tightened with a nut.

However, in the earthquake-resistant reinforcement method, cracks occur in the chemical liquid hardened by earthquake resistance including vibration of vehicles traveling over the bridge, and there is a gap between the anchors. There is a problem in that the metal steel sheet is loosened and the load-bearing force due to vibration is lowered, so that the seismic efficiency is lowered.

The reason that the insert anchor is not securely fastened to the filler (chemical liquid) as described above is that the insert anchor is simply composed of a rod with a thread formed on the surface. This is because it cannot maintain the state it is in and is easily separated.

So, in order to solve this problem, the technology described in Korean Patent No. 10-1477954 as shown in FIGS. 1 and 2 has been proposed, and the technical feature is that the concrete structure 30 is chipped on the surface of the concrete structure. By forming a plurality of fixing grooves 31 in which the concave-convex portions 32 are formed on the surface and inside of the anchors are inserted into each of the fixing grooves 31, using a mesh formed of a plurality of bars 40 After wrapping the outside of the concrete structure 30, fixing the mesh to an anchor, configuring a connection reinforcing plate at the corner of the concrete structure 30, respectively, connecting the mesh and the connection reinforcing plate, respectively; , After the connection step, each panel is installed on the outer periphery of the concrete structure 30 , the panel and the anchor are combined using the fixing member 50 , and the mortar filler (m) in the space between the mesh and the concrete structure 30 In the concrete structure repair and reinforcement method comprising the step of filling in ) is formed, the coupling part 21 coupled to the coupling groove 11 is formed in the lower part, the connection groove 22 is formed in the upper part, and the body part 10 is coupled to the outer periphery. By inserting an anchor consisting of a fastening portion 20 in which a fixing jaw 23 is formed so that it can be fixed in contact with the upper surface of the body portion 10, a plurality of locking pieces 12 are inserted into the uneven portion 32 In the step of fixing and filling the panel 60, a concave-convex portion 61 continuously connected to the upper side of the panel 60 is formed, and a plurality of injection grooves 64 penetrating the upper and lower portions on one side and a fastening groove ( 65) to form each, characterized in that it is coupled to the side of the concrete structure (30).

By the way, the technology described in Korean Patent Registration No. 10-1477954 is formed on the inner peripheral surface of the fixing groove 31 of the structure 30 by forming the engaging piece 12 on the outside of the body portion 10 constituting the anchor. By allowing it to be supported on the part 32, there is an advantage of preventing arbitrarily separating, but the tightening part 20 coupled to the body part 10 by screwing is an earthquake or a bridge that periodically generates significant vibrations. In the structure, there is a problem in that the screw-coupled part is loosened by vibration and is easily separated.

In addition, in the process of inserting the insert anchor into the installation groove or the fixing groove formed in the concrete structure, the bolt member is not located in the center and is biased to one side, so that it is difficult to fasten the structure.

Korean Patent No. 10-1477954 "Concrete Structure Repair and Reinforcement Method"

The present invention for solving the above problems is to insert and fix an anchor member having a support pin on its outer circumferential surface into an installation groove formed in a concrete structure, and then insert and fix a bolt member to the anchor member, and the inner circumferential surface of the anchor member is guided in the longitudinal direction Grooves are formed, and locking grooves are formed at regular intervals on the side of the guide groove, and the end of the locking pin protrudes from the outer circumferential surface of the bolt member and is inserted through the guide groove, then rotated so that the locking protrusion is inserted into the locking groove. By inserting a fixing pin into the guide groove to prevent rotation of the locking pin, even when vibration is applied to the structure due to earthquake or vehicle movement, the bonding strength between the bolt member and the anchor member is not lowered, and, if necessary, the fixing pin It is to provide an insert anchor for concrete seismic resistance that can be easily replaced by removing the bolt member.

In addition, the present invention facilitates the fastening of the structure by guiding the bolt member to be located at the maximum center without being biased to one side when inserting the bolt member into the installation groove. aims to support

As a means of solving the above problems, the present invention is; It consists of an anchor member inserted into the installation groove of the concrete structure, and a bolt member inserted and fixed into the receiving groove of the anchor member, and a filler is filled between the anchor member and the installation groove.

Here, guide grooves are formed along the longitudinal direction on the inner circumferential surface of the anchor member, and locking grooves are formed at regular intervals on one side of the guide groove.

And, the outer peripheral surface of the bolt member is characterized in that the locking pin protrudes to correspond to the guide groove and the locking groove at regular intervals along the longitudinal direction.

At this time, the bolt member is characterized in that through-holes are formed at regular intervals along the longitudinal direction, and a locking pin is inserted into the through-holes.

Meanwhile, it is characterized in that a bar-shaped fixing pin is inserted into the guide groove.

Here, it is characterized in that a bent portion bent upward or downward is formed at an end of the fixing pin.

In addition, it is characterized in that the cutouts are formed at regular intervals on the outside of the guide groove.

And, it is characterized in that the support pins are formed at regular intervals on the outer peripheral surface of the anchor member.

In addition, the bolt member is characterized in that it consists of through-holes arranged to cross at regular intervals along the longitudinal direction, and an earthquake-resistant spring inserted into the through-hole, both ends are exposed to support the inner circumferential surface of the installation groove.

As described above, the present invention inserts and fixes an anchor member having a support pin on its outer circumferential surface into an installation groove formed in a concrete structure, and then inserts and fixes a bolt member into the anchor member. is formed, and locking grooves are formed at regular intervals on the side of the guide groove, and the end of the locking pin protrudes from the outer peripheral surface of the bolt member and is inserted through the guide groove, and then rotates so that the locking protrusion is inserted into the locking groove, By inserting a fixing pin into the guide groove to prevent rotation of the locking pin, even if vibration is applied to the structure, such as an earthquake or vehicle movement, the defect strength of the bolt member and anchor member is not reduced, and the fixing pin is removed if necessary. There is an effect that the bolt member can be easily replaced.

In addition, the present invention has an effect of supporting the bolt member so that it is located in the center of the installation groove as much as possible without being biased to one side in the installation groove because an earthquake-resistant spring is inserted into the through hole to maximize the earthquake-resistant effect to support the inner circumferential surface of the installation groove from all directions. have.

In addition, by inserting a wire into the seismic spring and drawing it out to both ends of the through hole, when the filler material is lightened in a state where the wire is located in all directions, the bolt member is fixed from all directions, so there is an effect of maintaining the firmly fastened state in the insertion groove.

1 is a perspective view of a conventional insert anchor for concrete.
Figure 2 is a perspective view of a conventional insert anchor for concrete.
Figure 3 is a perspective view of a seismic type insert anchor for concrete according to the present invention.
Figure 4 is a cross-sectional view showing a state installed in the structure of the concrete seismic insert anchor according to the present invention.
Figure 5 is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the concrete seismic insert anchor according to the present invention.
Figure 6 is a perspective view of a concrete seismic insert anchor according to another embodiment of the present invention.
7 is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the concrete seismic insert anchor according to the embodiment of FIG.
8 is a perspective view of an insert anchor for earthquake resistance in concrete according to another embodiment of the present invention.

1 is a perspective view of a conventional insert anchor for concrete.
Figure 2 is a perspective view of a conventional insert anchor for concrete.
Figure 3 is a perspective view of a seismic type insert anchor for concrete according to the present invention.
Figure 4 is a cross-sectional view showing a state installed in the structure of the concrete seismic insert anchor according to the present invention.
Figure 5 is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the concrete seismic insert anchor according to the present invention.
Figure 6 is a perspective view of a concrete seismic insert anchor according to another embodiment of the present invention.
7 is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the concrete seismic insert anchor according to the embodiment of FIG.
8 is a perspective view of an insert anchor for earthquake resistance in concrete according to another embodiment of the present invention.

In order to achieve the above objects and effects, the present invention will be described in detail with reference to the accompanying drawings as follows.

3 is a perspective view of a concrete seismic insert anchor according to the present invention, FIG. 4 is a cross-sectional view showing a state installed in the structure of the concrete seismic insert anchor according to the present invention, and FIG. 5 is a concrete seismic insert anchor according to the present invention It is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the It is a partial cross-sectional view showing a state in which the fixing pin is inserted into the receiving groove of the , and FIG. 8 is a perspective view of an insert anchor for seismic resistance in concrete according to another embodiment of the present invention.

The present invention relates to a concrete seismic insert anchor, and as shown in FIGS. 3 to 5, the structure is an anchor member 200 inserted into an installation groove 110 formed in a concrete structure 100 such as a bridge made of concrete. ) and a bolt member 300 inserted and fixed in the receiving groove 210 of the anchor member 200 .

Here, the anchor member 200 is formed in a cylindrical shape, and the receiving groove 210 into which the bolt member 300 is inserted is formed. The anchor member 200 is larger than the diameter of the anchor member 200 . It is filled and fixed between the formed installation grooves 110 .

So, the anchor member 200 is inserted and fixed in the installation groove 110 formed in the concrete structure 100 , and the bolt member 300 is detachably installed in the receiving groove 210 of the anchor member 200 . , it is possible to easily replace the bolt member 300 as necessary.

In addition, the support pins 220 are formed on the outer peripheral surface of the anchor member 200 at regular intervals, and the anchor members 220 are supported by the support pins 220 at regular intervals from the inner peripheral surface of the installation groove 110 . are spaced apart

Therefore, in a state in which the filler between the installation groove 110 and the anchor member 200 is filled, the position of the anchor member 220 is stable even without a separate support for positioning it in the center of the installation groove 110 . can be placed in the center.

In addition, when the filler filled inside the installation groove 110 is hardened, the support pin 220 formed on the outside of the anchor member 220 is located inside the filler, so vibration or earthquake applied to the structure from the outside, etc. It is possible to stably maintain the installed state inside the installation groove 110 despite the impact of the.

On the other hand, the guide groove 230 is formed along the longitudinal direction on the inner peripheral surface of the anchor member 200, the guide groove 230, as shown in FIG. It is formed to protrude to the outside of the member 200 .

Here, although not shown in the drawings, when the thickness of the anchor member 200 is thicker than the depth of the guide groove 230 , it is formed so as not to protrude to the outside of the anchor member 200 .

At this time, a locking groove 232 is formed on one side of the guide groove 230 , and a plurality of the locking grooves 232 are formed at regular intervals along the longitudinal direction of the guide groove 230 .

And, on the outer peripheral surface of the bolt member 300 inserted into the receiving groove 210 of the anchor member 200, locking pins 320 are formed to protrude at regular intervals, and the end of the locking pin 320 is the guide groove. It is formed to correspond to the positions of the 230 and the locking groove 232 .

Here, through-holes 310 are formed at regular intervals along the longitudinal direction of the bolt member 300 , and pin-shaped locking pins 320 are inserted into the through-holes 310 to both ends of the locking pins 320 . is protruded to both ends of the through hole 310 .

So, when the bolt member 300 is inserted into the receiving groove 210 of the anchor member 200 , both ends of the locking pin 320 are inserted into the guide groove 230 , and the receiving groove 210 . ), when the bolt member 300 is rotated after being completely inserted to the inner end, the locking pin 320 is inserted into the locking groove 232 .

At this time, the through hole 310 and the locking pin 320 may be formed in four directions of the bolt member 300 up, down, left and right, or may be formed only in two directions, up and down or left and right. In the upper and lower direction through-holes 310 and left and right through-holes 310 are formed to be spaced apart from each other in the longitudinal direction so as not to interfere with each other.

On the other hand, the depth of the locking groove 232 is formed to correspond to the diameter of the locking pin 320 , so that the bolt member 300 is inserted into the receiving groove 210 of the anchor member 200 and then rotated. When the end of the locking pin 320 is inserted into the locking groove 232 , nothing remains in the guide groove 230 .

Here, a fixing pin 240 having a diameter corresponding to the inner diameter of the guide groove 230 is inserted into the guide groove 230 to support the side of the locking pin 320 inserted into the locking groove 232 . do.

So, as described above, even if vibrations generated by the movement of vehicles on piers, etc. or vibrations generated by earthquakes act on the insert anchor of the present invention, since the fixing pins 240 support the side of the locking pins 320, By preventing rotation, it is possible to stably prevent the coupled state of the bolt member 300 from loosening.

At this time, the end of the fixing pin 240 is formed with a bent portion 242 bent upward or downward, and the fixing pin 240 is prevented from being inserted more than a certain amount by the bent portion 242 .

Therefore, when the operator installs the anchor, the fixing pin 240 is inserted into the guide groove 230 to be firmly fixed, and when the bolt member 300 needs to be replaced for various reasons, the bent part 242 After separating the fixing pin 240 from the guide groove 230 by gripping the bolt member 300 , the locking pin 320 comes out of the locking flaw 232 so that it can be easily separated.

On the other hand, the locking pin 320 protruding to the outside of the bolt member 300 is inserted into the through hole 310 formed in the bolt member 300 as shown in FIG. 3 and may be formed so that both ends protrude. Also, as shown in FIG. 8 , the locking pin 320 may be formed integrally with the bolt member 300 or may be formed by attaching to the outer peripheral surface of the bolt member 300 by welding or the like.

And, as another embodiment of the present invention, as shown in FIGS. 6 and 6 , the anchor is an anchor member 200 inserted into the installation groove 110 of the concrete structure 100 and a receiving groove of the anchor member 200 ( It consists of a bolt member 300 inserted and fixed to 210).

Here, at one side of the guide flaw 230 formed along the longitudinal direction on the inner circumferential surface of the anchor member 200 formed in a cylindrical shape, locking grooves 232 are formed at regular intervals along the longitudinal direction.

At this time, cutouts 234 are formed on the outside of the guide groove 230 at regular intervals, and the cutouts 234 are formed in a portion in contact with the locking groove 232 to install the concrete structure 100 . (110) and the inner side of the guide groove 230 to communicate with each other.

Therefore, when inserting the bolt member 300 into the receiving groove 210 of the anchor member 200, both ends of the locking pin 320 are inserted into the locking groove 232, as in the above-described embodiment. Without inserting the fixing pin 240 , the filler 120 is filled to the outside of the anchor member 200 , and through the cutout 234 formed on the outside of the guide groove 230 , the filler 120 is inside the guide groove 230 . to be inserted into

So, when the filler 120 inserted into the guide groove 230 is cured, the filler 120 supports the side of the locking pin 320 inserted into the locking groove 232 and the locking pin 320 . By preventing this rotation, it is possible to stably prevent the coupling state of the bolt member 300 and the anchor member 200 from loosening.

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Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the scope of the present invention extends to those substantially equivalent to the embodiments of the present invention. Various modifications can be made by those skilled in the art to which the invention pertains without departing from the scope of the invention.

The present invention relates to a concrete seismic insert anchor, and more particularly, by forming an installation groove in a concrete structure to firmly fix the anchor, it is possible to prevent the fixed state from loosening even in the case of continuously applied vibration or earthquake. Rather, it relates to an insert anchor for earthquake-resistant concrete that can easily replace the bolt members constituting the anchor if necessary.

100: concrete structure 110: installation groove
120: filler 200: anchor member
210: receiving groove 220: support pin
230: guide groove 240: fixing pin
300: bolt member 310: through hole
320: locking pin

Claims (10)

An anchor member inserted into the installation groove of the concrete structure and having guide grooves formed along the longitudinal direction on the inner circumferential surface, and having locking grooves formed at regular intervals on one side of the guide groove;
It consists of a bolt member inserted and fixed in the receiving groove of the anchor member,
On the outer peripheral surface of the bolt member, locking pins are formed to protrude at regular intervals along the longitudinal direction, and in the process of accommodating the bolt member as an anchor member, the locking pin is inserted into the guide groove and positioned in the locking groove,
In the insert anchor for earthquake-resistant concrete filled with a filler between the anchor member and the installation groove,
Cutouts are formed on the outside of the guide groove at regular intervals to prevent the locking pin from rotating backwards by filling the filler inside the guide groove, and support pins are formed on the outer peripheral surface of the anchor member at regular intervals to anchor the bolt member. Concrete earthquake-resistant insert, characterized in that it is accommodated in a member and supported so that the ball-to-member is positioned in the center when inserted into the installation groove



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