JP2015063816A - Hole-in anchor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hole-in anchor capable of suppressing a situation in which grout leaks from an anchor hole.SOLUTION: In a hole-in anchor having a rod-like bolt buried in an anchor hole formed in an existing concrete structure, a space part with a substantially truncated cone-shaped undercut is formed in a bottom side of the anchor hole. The hole-in anchor includes: an expansion member fixed to the bolt 3 and expanding in the space part with the undercut when being pushed into the anchor hole and facing to an inclined plane of the space part with the undercut; and encapsulation means 50 having a leakage stopping packing 51 having an insertion hole for insertion of the bolt 3 and encapsulating the anchor hole in a state in which the bolt 3 is inserted in the insertion hole and a holding ring 52, and suppressing leakage of grout inside of the anchor hole by making the leakage stopping packing 51 and the holding ring 52 encapsulate the anchor hole.

Description

  The present invention relates to a post-installed anchor having a rod-like anchor body embedded in an anchor hole of an existing concrete structure.

  There is a post-installation anchor construction method in which an anchor hole is formed upward (vertical direction) or sideways (horizontal direction) with respect to an existing concrete structure, and the anchor body is inserted into the anchor hole and then the filler material is filled into the anchor hole. It describes in Unexamined-Japanese-Patent No. 2004-162295. In the construction method described in this publication, first, a small amount of filler is injected into the tip portion of the anchor hole, the anchor body is inserted into the anchor hole, and then a filler is further added to the gap between the anchor body and the anchor hole. I am injecting.

JP 2004-162295 A

  As described above, when the method of injecting the filler after the anchor body is inserted is adopted, the filler is injected by installing a cap at the inlet portion of the anchor hole, so that the filler leaks from the anchor hole. Never leave. Further, when a high-viscosity plastic grout is used as the filler, it is possible to fill the anchor hole with grout so that the grout does not hang down from the anchor hole even when the anchor hole is upward or sideways. However, in the case where the anchor hole is upward or sideways and the anchor hole is filled with grout, a situation may occur where the grout leaks from the anchor hole if vibration or the like due to driving of the anchor body is applied. When the grout leaks from the anchor hole in this way, there is a possibility that the expected durability and the desired strength due to the grout cannot be obtained.

  An object of the present invention is to provide a post-construction anchor that can suppress a situation in which a grout leaks from an anchor hole.

  The present invention relates to a post-installed anchor having a rod-shaped anchor body with a screw embedded in an anchor hole formed in an existing concrete structure, and a substantially frustoconical space with an undercut is formed on the bottom side of the anchor hole. An expansion member that is fixed to the anchor body, expands in the space portion with the undercut when the anchor body is pushed into the anchor hole, and faces the inclined surface of the space portion with the undercut, and the anchor body. It has an insertion hole to be inserted, and has a lid portion that seals the anchor hole in a state where the anchor main body is inserted into the insertion hole, and seals the anchor hole in the lid portion to suppress grout leakage in the anchor hole. Sealing means.

  Thereafter, in the construction anchor, the anchor main body is inserted into the insertion hole, the lid portion is attached to the anchor main body, and the anchor hole is sealed with the lid portion, thereby suppressing grout leakage from the anchor hole. Thus, the lid portion seals the anchor hole in a state where the anchor main body is inserted into the insertion hole, so that the anchor body is driven into the anchor hole and the anchor hole is sealed by the lid portion independently. It can be carried out. In addition, since the anchor body can be driven in a state where the anchor hole is sealed by the lid portion attached to the anchor body, it is possible to suppress the situation where the grout leaks from the anchor hole even if vibration due to the anchor body is driven. it can. Moreover, since it can suppress that a grout leaks by sealing an anchor hole with a cover part, the structure for the leak prevention of a grout can be simplified.

  The sealing means may include a spring portion that urges the lid portion in the pushing direction of the anchor body, and a support portion that supports the spring portion on the front side of the lid portion. In this case, since the spring portion urges the lid portion in the pushing direction of the anchor body, the anchor hole can be more reliably sealed by the lid portion.

  Moreover, the cover part, the spring part, and the support part may be detachable from the anchor body. In this way, when the lid portion, the spring portion, and the support portion are detachable with respect to the anchor body, the anchor body is inserted into the anchor hole, the grout in the anchor hole is solidified, and the construction is completed. The spring part and the support part can be detached from the anchor body. Therefore, the lid, the spring, and the support can be reused, and the sealing means can be diverted.

  Further, the anchor body may be pulled in a direction opposite to the pushing direction of the anchor body in a state where the lid portion seals the anchor hole before the grout in the anchor hole is solidified. As described above, when the bottomed anchor body is pulled in the direction opposite to the pushing direction before the grout is hardened, the expansion member comes into contact with and comes into close contact with the inclined surface of the space portion with the undercut. Even if the anchor body is pulled before the grout is hardened, the anchor hole is sealed by the lid portion, so that the situation where the grout leaks from the anchor hole is suppressed. If the anchor body is pulled before the grout is hardened to bring the expansion member into close contact with the inclined surface, the anchor main body is more firmly fixed to the concrete structure when the grout is hardened. That is, since the anchor body is fixed in a state where the expansion member is in close contact with the concrete structure, fatigue of the anchor body can be suppressed even after a long time has passed, and the quality of the anchor body can be secured in the future. Can contribute to improving performance.

  Moreover, the cover part may have a recessed part which receives the grout which came out of the anchor hole. In this case, even if the grout comes out from the anchor hole, the recess formed in the lid receives the grout, so that the situation where the grout droops can be avoided.

  According to the present invention, it is possible to suppress the situation where the grout leaks from the anchor hole.

It is sectional drawing which shows one Embodiment of the post-construction anchor which concerns on this invention. It is a perspective view which shows an expansion member. It is a perspective view which shows a piece member. It is sectional drawing which shows the state after the completion of construction of the post-construction anchor shown by FIG. It is sectional drawing which shows the state which drilled the anchor hole to the existing concrete structure. It is a perspective view which shows the sealing means which concerns on 1st Embodiment. It is a perspective view which shows the sealing means which concerns on 2nd Embodiment. It is a perspective view which shows the sealing means which concerns on 3rd Embodiment. It is a perspective view which shows the sealing means which concerns on 4th Embodiment. It is a perspective view which shows the sealing means which concerns on 4th Embodiment. It is a perspective view which shows the sealing means which concerns on 5th Embodiment, and the sealing means which concerns on 6th Embodiment. It is a perspective view which shows the sealing means which concerns on 7th Embodiment.

  Hereinafter, a preferred embodiment of a post-construction anchor according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
As shown in FIG. 1, the post-construction anchor 1 has a bolt (an anchor body with a screw) 3 implanted in an anchor hole S formed by a drill in an existing concrete structure 2, and the bolt 3 is an existing concrete structure. 2 so as to be exposed from the surface. The anchor hole S is formed by excavating the existing concrete structure 2 upward by drilling, and the bolt 3 is planted in the anchor hole S from below. The anchor hole S communicates with the columnar anchor hole main body S1 and the end portion of the anchor hole main body S1, and a substantially frustoconical space portion S2 with an undercut formed on the bottom side of the anchor hole S. Have.

  The post-installed anchor 1 includes a rod-shaped bolt 3 embedded in the anchor hole S, a piece member 10 having a second inclined surface P2 facing the first inclined surface P1 of the space portion S2 with an undercut, and an undercut And an expansion member 20 having an expansion piece 22 that enters so as to fill a gap R between the first inclined surface P1 of the attached space portion S2 and the second inclined surface P2 of the piece member 10. Yes. The piece member 10 has an insertion hole 10a into which the bolt 3 is inserted while being set in the space portion S2 with an undercut. The expansion member 20 is fixed to the bolt 3 and causes the expansion piece 22 to enter the gap R by pushing the bolt 3 into the insertion hole 10 a of the piece member 10.

  As shown in FIGS. 1 and 2, the expansion member 20 has a female through central through hole 20 a that can be screwed to the bolt 3 and extends in the axis L direction of the bolt 3. The expansion member 20 includes a cylindrical head 21, an expansion piece 22 extending in the direction of the axis L of the bolt 3 on the end side of the head 21, and a circumferential direction between the head 21 and the expansion piece 22. And a thin bent portion 23 created by forming the concave portion 23a. In the expansion member 20, the head portion 21 and the expansion piece 22 are connected via a thin bent portion 23.

  A plurality of (for example, four) extended pieces 22 are arranged at equal intervals in the circumferential direction of the head 21. Each extension piece 22 is formed as a rectangular parallelepiped plate piece, the inner wall surface of the extension piece 22 is separated from the bolt 3, and the outer wall surface of the extension piece 22 coincides with the outer peripheral surface of the head 21 in the axis L direction. ing. The inner wall surface of the extension piece 22 is a surface that faces the second inclined surface P2 when the extension piece 22 enters the gap R, and the inner wall surface of the extension piece 22 has triangular wave-like irregularities continuous in the direction of the axis L. A portion 22a is formed. Further, a third inclined surface P3 that is temporarily fixed to the second inclined surface P2 of the piece member 10 before the bolt 3 is pushed into the insertion hole 10a of the piece member 10 is formed at the tip of the extension piece 22. ing.

  By adopting the third inclined surface P3, when the bolt 3 is pushed into the insertion hole 10a of the piece member 10, the tip of the expansion piece 22 of the expansion member 20 is connected to the first inclined surface P1 of the space portion S2 with an undercut. And the second inclined surface P2 of the piece member 10 can smoothly enter the gap R. Thereby, an excessive load is not applied to the expansion piece 22, and the expansion piece 22 is arranged at a predetermined position without being separated from the head 21.

  In addition, a screw insertion hole 24 for fixing the expansion member 20 at a predetermined position of the bolt 3 is formed in the head portion 21. The expansion member 20 is fixed at a predetermined position of the bolt 3 by screwing the screw 25 from the screw insertion hole 24 toward the bolt 3 and crimping the tip of the screw 25 to the bolt 3. The diameter of the expansion member 20, that is, the diameter of the head 21 is formed to be slightly smaller than the diameter of the columnar anchor hole main body S <b> 1, whereby the expansion member 20 can be moved along the anchor hole main body S <b> 1. .

  As shown in FIGS. 1 and 3, the piece member 10 having the insertion hole 10a extending in the direction of the axis L includes a cylindrical seating portion 10A that contacts the bottom surface Sa of the anchor hole S, and an end of the seating portion 10A. A truncated cone-shaped reduced diameter portion 10B having a second inclined surface P2 continuous with the portion. Thus, the piece member 10 has a simple structure constituted by the cylindrical seating portion 10A and the truncated cone-shaped reduced diameter portion 10B, and has a shape that is easy to manufacture.

  In addition, a triangular wave-shaped uneven portion 10d is formed on the inclined surface P2 located on the front side of the reduced diameter portion 10B, and when the expansion piece 22 enters the gap R, it expands to the uneven portion 10d of the reduced diameter portion 10B. When the concavo-convex portion 22a formed on the inner wall surface of the piece 22 meshes, the extended piece 22 is caught on the piece member 10 (see FIG. 4). That is, the catching means 30 for catching the expansion piece 22 on the piece member 10 is configured by the unevenness portion 10 d of the piece member 10 and the unevenness portion 22 a of the extension piece 22.

  The seat portion 10A of the piece member 10 is formed with a discharge portion 10b that communicates with the insertion hole 10a and is located on the bottom side of the seat portion 10A of the piece member 10. Each discharge portion 10b has a groove shape in which the bottom surface 10c of the seating portion 10A is cut out in a U shape in the axis L direction, and is formed at equal intervals with a phase angle of 90 degrees. By adopting such a configuration, the grout G (see FIG. 1) filled in the insertion hole 10a of the piece member 10 can be discharged to the outside through the discharge portion 10b. The grout G can be filled into the anchor hole S before being inserted into the anchor hole S of the concrete structure 2 (see FIG. 5).

  In this way, by pre-filling the anchor hole S with the grout G, it is possible to reliably fill the grout G around the construction anchor 1 in the anchor hole S. Accumulation is unlikely to occur, thereby making it difficult for the construction anchor 1 to corrode later and making the grout G contribute to the improvement of the pull-out strength of the bolt 3. Further, as the grout G, a high-viscosity plastic grout, which is a cement grout material, is used, so that the grout G can be filled in the insertion hole 10a of the piece member 10 in advance. The grout G in the insertion hole 10a is discharged to the outside through the discharge portion 10b.

  As shown in FIG. 6, a sealing means 50 for sealing the anchor hole S from below is provided in the vicinity of the entrance of the anchor hole S in order to suppress leakage of the grout G filled in the anchor hole S. The sealing means 50 includes a ring-shaped leak-proof packing (lid portion) 51, a ring-shaped pressing ring (lid portion) 52 positioned below the leakage-proof packing 51, and a coil spring positioned below the pressing ring 52 ( And a clip portion (support portion) 54 that supports the coil spring 53 below the coil spring 53. The leak-proof packing 51 and the pressing ring 52 have insertion holes for allowing the bolts 3 to pass therethrough. The leak-proof packing 51, the holding ring 52, the coil spring 53, and the clip portion 54 are integrated by adhesion or the like, and are detachable from the bolt 3. The leak-proof packing 51, the holding ring 52, the coil spring 53, and the clip portion 54 may not be integrated.

  The leak-proof packing 51 has an insertion hole 51a through which the bolt 3 is passed, and is attached to the bolt 3 by inserting the bolt 3 through the insertion hole 51a. The leak-proof packing 51 is movable in the direction of the axis L with the bolt 3 passed through the insertion hole 51a. Sealing the anchor hole S in this state prevents leakage of the grout G in the anchor hole S. Suppress. The leak-proof packing 51 is made of a relatively flexible material such as felt or rubber, and the inner periphery of the leak-proof packing 51 is in close contact with the bolt 3. A pressing ring 52 is fixed to the lower surface of the leak-proof packing 51 by adhesion or the like.

  The holding ring 52 has an insertion hole through which the bolt 3 is inserted, and is attached to the bolt 3 by inserting the bolt 3 through the insertion hole. The pressing ring 52 is movable in the direction of the axis L of the bolt 3 in a state where the bolt 3 is inserted through the insertion hole of the pressing ring 52. The holding ring 52 has a larger diameter than the outer diameter of the leak-proof packing 51 and the outer diameter of the anchor hole S, and functions to hold the leak-proof packing 51 at the lower part of the leak-proof packing 51 and seal the anchor hole S. Also have. The holding ring 52 is made of a relatively rigid material such as metal, ceramic, or plastic. One end of a coil spring 53 is fixed to the lower surface of the pressing ring 52 by bonding or the like. Note that the coil spring 53 may not be fixed to the holding ring 52.

  The coil spring 53 has a spiral shape in which the bolt 3 is wound around the lower part of the holding ring 52, and the inner diameter of the coil spring 53 is slightly larger than the outer diameter of the bolt 3. The coil spring 53 is provided to urge the leak-proof packing 51 and the pressing ring 52 in the pushing direction of the bolt 3 (in this case, upward). The coil spring 53 is attached to the bolt 3 when the bolt 3 is inserted through the coil spring 53. By this coil spring 53, the leak-proof packing 51 and the pressing ring 52 are pressed against the anchor hole S from below, and the leak-proof packing 51 and the pressing ring 52 seal the anchor hole S. The other end of the coil spring 53 is fixed to the clip portion 54 by adhesion or the like. Note that the coil spring 53 may not be fixed to the clip portion 54.

  The clip portion 54 sandwiches the bolt 3 between the leak-proof packing 51, the holding ring 52, and the coil spring 53. The clip portion 54 is provided to support the coil spring 53 on the front side (in this case, the lower side) of the anchor hole S. The clip portion 54 includes a spring portion 54a, a knob portion 54b, and a pinching portion 54c. The clip portion 54 is pinched with the pinch portion 54b held by hand against the biasing force of the spring portion 54a and the pinching portion 54c opened. The bolt 3 is sandwiched between the portions 54c, and then the hand is released from the knob portion 54b, so that the sandwiched portion 54c sandwiches the bolt 3. In this manner, the bolt 3 can be easily sandwiched by the clip portion 54, and the clip portion 54 can be sandwiched at an arbitrary position of the bolt 3 as necessary.

  Next, driving of the bolt 3 into the anchor hole S filled with the grout G and sealing of the anchor hole S by the sealing means 50 will be described. As shown in FIG. 1, in the post-installed anchor 1, first, the expansion member 20 is fixed with screws 25 in the middle of the bolt 3, and the piece member is formed on the third inclined surface P <b> 3 positioned at the tip of the expansion piece 22. Ten second inclined planes P2 are lightly temporarily fixed (see a two-dot chain line). In such an assembled state, the post-construction anchor 1 is inserted into the anchor hole S of the existing concrete structure 2. Then, the bottom surface 10 c of the piece member 10 is installed on the bottom surface Sa of the anchor hole S.

  Then, after the bolt 3 is inserted into the anchor hole S from below, the leak-proof packing 51, the holding ring 52, and the coil spring 53 are attached to the bolt 3 from below. Then, after the vertical positions of the leak-proof packing 51, the holding ring 52 and the coil spring 53 with respect to the bolt 3 are determined, the bolt 3 is sandwiched by the clip portion 54, and the anchor hole S is sealed by the leak-proof packing 51 and the holding ring 52. It is also possible to insert the bolt 3 into the anchor hole S in a state where the leak-proof packing 51, the holding ring 52 and the coil spring 53 are attached to the bolt 3 in advance. In FIG. 1 and FIG. 4, only the pressing ring 52 of the sealing means 50 is shown for simplification of illustration.

  When the bolt 3 is struck from below with the hammer H in a state where the anchor hole S is sealed with the leak-proof packing 51 and the holding ring 52, the bolt 3 is pushed into the insertion hole 10a of the piece member 10 as shown in FIG. The bolt 3 and the expansion member 20 move upward together with the piece member 10. Then, after the temporary fixing of the third inclined surface P3 to the second inclined surface P2 of the piece member 10 is released by hitting the hammer H, the extension piece 22 is bent under the thin bent portion 23 while being It enters so that the clearance gap R between the 1st inclined surface P1 of the space part S2 with a cut and the 2nd inclined surface P2 of the piece member 10 may be filled.

  As the expansion piece 22 enters the gap R, the end surface of the bolt 3 becomes substantially the same as the bottom surface 10c of the piece member 10, and the expansion piece 22 is sandwiched between the first inclined surface P1 and the second inclined surface P2. Thus, the entry of the extension piece 22 into the gap R is completed. At this time, the leak-proof packing 51 enters the anchor hole S, the upper surface 51 b of the leak-proof packing 51 comes into contact with the grout G in the anchor hole S, and the upper surface 52 a of the holding ring 52 is applied to the existing concrete by the biasing force of the coil spring 53. It is pressed against the surface 2 a of the structure 2. Further, the uneven portion 22a formed on the inner wall surface of the extension piece 22 meshes with the uneven portion 10d formed on the inclined surface P2 of the piece member 10, and the extension piece 22 is caught by the piece member 10, so that the extension member 20 and the bolt 3 Is firmly fixed in the anchor hole S, and the bolt 3 is prevented from coming off.

  Further, the bolt 3 is pulled downward in a state in which the leak-proof packing 51 and the pressing ring 52 seal the anchor hole S before the grout G in the anchor hole S is hardened. When a tensile load is applied to the bolt 3 in this way, the extension piece 22 is sandwiched between the first inclined surface P1 and the second inclined surface P2, and the extension piece 22 is caught by the catching means 30. Since it is caught by the piece member 10, the load can be firmly received by the first inclined surface P1 of the space portion S2 with an undercut, and the wall surface of the anchor hole S is hardly distorted or cracked.

  Next, the construction method of the post-construction anchor 1 will be briefly described.

  As shown in FIG. 5A, a columnar anchor hole body S1 is formed in the existing concrete structure 2 by a normal drilling process. Next, as shown in FIG. 5B, an undercut portion U is formed by drilling at the end of the anchor hole body S1. For the formation of the undercut portion U, a special rotary tool called an under cutter is used. By such drilling, the anchor hole S has an existing concrete structure so as to have a columnar anchor hole main body S1 and a space portion S2 with an undercut in a substantially truncated cone shape communicating with the anchor hole main body S1. 2 is formed.

  After forming the anchor hole S with a drill, about 80% of the grout G is injected into the anchor hole S into the entire space in the anchor hole S. Further, as shown in FIG. 1, the grout G is filled into the insertion hole 10 a of the piece member 10 from above. Thereafter, the post-construction anchor 1 is inserted into the anchor hole S. Then, as shown in FIG. 6, the leakage-preventing packing 51, the holding ring 52 and the coil spring 53 are attached to the bolt 3 from below and the bolt 3 is clamped by the clip portion 54, and the bolt 3 is hammered from below with the hammer H .

  As shown in FIGS. 1 and 4, the grout G filled in the insertion hole 10a of the piece member 10 is struck with a hammer H from below to push the bolt 3 into the insertion hole 10a. Then, it is discharged from the discharge portion 10b into the space portion S2 with an undercut. Further, when the bolt 3 is struck with the hammer H, the extended piece 22 enters the thin bent portion 23 so as to fill the gap R while spreading outward, and the uneven portion 22a of the extended piece 22 enters the uneven portion 10d of the piece member 10. The engagement of the extension piece 22 into the gap R is completed in a state where the extension piece 22 is caught by the piece member 10.

  At this time, the grout G reaches the surface 2a of the existing concrete structure 2 and may overflow from the surface 2a, but the leak-proof packing 51 and the pressing ring 52 seal the anchor hole S. The leakage of the grout G from the anchor hole S is suppressed. In addition, the grout G in the anchor hole S may move downward by pulling the bolt 3 downward after completion of the entry of the expansion piece 22, but the leak-proof packing 51 and the holding ring 52 seal the anchor hole S. Therefore, leakage of the grout G from the anchor hole S is suppressed.

  Even if the leak-proof packing 51 is pushed downward by the grout G, the coil spring 53 biases the leak-proof packing 51 and the holding ring 52 upward, so that the anchor hole S is formed by the leak-proof packing 51 and the holding ring 52. It can seal more reliably. That is, the force that pushes back the leak-proof packing 51 and the holding ring 52 is exerted by the reaction force of the coil spring 53, so that the leakage of the grout G from the anchor hole S can be suppressed more reliably.

  As described above, in the post-construction anchor 1, leakage of the grout G from the anchor hole S is suppressed by sealing the anchor hole S with the leak-proof packing 51 and the pressing ring 52. As described above, the leak-proof packing 51 and the holding ring 52 seal the anchor hole S in a state where the bolt 3 is inserted into each insertion hole, so that the bolt 3 is driven into the anchor hole S, the leak-proof packing 51 and Sealing of the anchor hole S by the pressing ring 52 can be performed independently.

  Further, since the bolt 3 can be driven in a state where the anchor hole S is sealed by the leak-proof packing 51 and the holding ring 52, the grout G leaks from the anchor hole S even if vibration due to the driving of the bolt 3 is applied. Can be suppressed. In addition, since the anchor hole S is sealed by the leak-proof packing 51 and the pressing ring 52, it is possible to prevent the grout G from leaking, so that the structure for preventing the grout G from leaking can be simplified.

  Further, the leak-proof packing 51, the holding ring 52, the coil spring 53, and the clip portion 54 are detachable from the bolt 3. Therefore, after the bolt 3 is inserted into the anchor hole S and the grout G in the anchor hole S is solidified and the construction is completed, the leak-proof packing 51, the holding ring 52, the coil spring 53, and the clip portion 54 can be removed from the bolt 3. it can. Therefore, the leak-proof packing 51, the holding ring 52, the coil spring 53, and the clip portion 54 can be reused, and the sealing means 50 can be diverted.

  Further, since the bolt 3 is pulled downward before the grout G in the anchor hole S is solidified, as shown in FIG. 4, the expansion piece 22 of the expansion member 20 has the first inclination of the space portion S2 with an undercut. It comes into contact with and closely contacts the surface P1. Even if the bolt 3 is pulled before the grout G is solidified, the anchor hole S is sealed by the leak-proof packing 51 and the pressing ring 52, so that the situation where the grout G leaks from the anchor hole S is suppressed. If the bolt 3 is pulled before the grout G is hardened to bring the expansion piece 22 into close contact with the inclined surface P1, the bolt 3 is more firmly fixed to the existing concrete structure 2 when the grout G is hardened. That is, since the bolt 3 is fixed in a state where the extension piece 22 is in close contact with the existing concrete structure 2, the fatigue of the bolt 3 can be suppressed even after a long time has passed, and the quality of the bolt 3 can be improved in the future. It can be ensured and contributes to performance improvement.

(Second Embodiment)
As shown in FIG. 7, the post-construction anchor of the second embodiment is different from the first embodiment in that a separate sealing means 60 is used. Therefore, in the following, the sealing means 60 will be described with emphasis, and description overlapping with the first embodiment will be omitted.

  The sealing means 60 includes a ring-shaped leak-proof packing 61, a ring-shaped pressing ring 62 positioned under the leakage-proof packing 61, a coil spring 63 positioned under the pressing ring 62, and a coil spring at the lower part of the coil spring 63. A disc-shaped support ring 65 that supports 63, and a clip portion 64 that sandwiches the bolt 3 at a lower portion of the support ring 65. The configurations of the leak-proof packing 61, the holding ring 62, and the coil spring 63 are the same as the configurations of the leak-proof packing 51, the holding ring 52, and the coil spring 53 of the first embodiment. Further, the leak-proof packing 61, the holding ring 62, the coil spring 63, the clip portion 64, and the support ring 65 are separate bodies.

  Regarding the attachment of the sealing means 60 to the bolt 3, after the bolt 3 is inserted into the anchor hole S from below, the leakage-proof packing 61 and the holding ring 62 are bolted from the bottom, as in the sealing means 50 of the first embodiment. Attach to 3. And after attaching the coil spring 63 to the volt | bolt 3 from the bottom, the support ring 65 and the clip part 64 are attached to the volt | bolt 3 from the bottom. Thereafter, the upper surface of the holding ring 62 is pressed against the surface 2a of the existing concrete structure 2, and the coil spring 63 is lightly pushed upward by the support ring 65 to be compressed and the bolt 3 is sandwiched by the clip portion 64, thereby sealing the sealing ring. The attachment of the stopping means 60 to the bolt 3 is completed.

  As described above, in the post-construction anchor according to the second embodiment, the grout G from the anchor hole S is sealed by sealing the anchor hole S with the leak-proof packing 61 and the holding ring 62 as in the post-construction anchor 1 according to the first embodiment. Control leaks. Therefore, the same effect as the post-construction anchor 1 after the first embodiment can be obtained.

(Third embodiment)
As shown in FIG. 8, in the post-construction anchor of the third embodiment, the leak-proof packing 51 and the clip portion 54 of the first embodiment are omitted, and a nut 73 is used as a support portion for supporting the spring portion. Is different from the post-construction anchor 1 of the first embodiment.

  The sealing means 70 includes a ring-shaped pressing ring 71, a coil spring 72 positioned under the pressing ring 71, and a nut 73 that supports the coil spring 72 under the coil spring 72. The structure of the pressing ring 71 and the coil spring 72 is the same as the structure of the pressing ring 52 and the coil spring 53 of the first embodiment. The nut 73 can be moved up and down with respect to the bolt 3 by being screwed into the bolt 3 from below. The holding ring 71, the coil spring 72, and the nut 73 may be separate or integrated.

  In the sealing means 70, as with the sealing means 50 of the first embodiment, after the bolt 3 is inserted into the anchor hole S from below, the pressing ring 71 is attached to the bolt 3 from below. Then, after attaching the coil spring 72 to the bolt 3 from below, the nut 73 is screwed onto the bolt 3 from below to move the nut 73 upward. Thereafter, the upper surface of the holding ring 71 is pressed against the surface 2a of the existing concrete structure 2, and the coil spring 72 is slightly pushed upward by the nut 73 to be in a contracted state, whereby the sealing means 70 is applied to the bolt 3. Installation is complete.

  In the post-construction anchor of the third embodiment, as with the post-construction anchor 1 of the first embodiment, the pressing ring 71 is attached to the bolt 3 and the anchor hole S is sealed by the pressing ring 71 to remove the anchor hole S from the anchor hole S. Suppress leakage of grout G. Therefore, the same effect as the post-construction anchor 1 after the first embodiment can be obtained. Further, the configuration of the sealing means 70 can be simplified by omitting the leak-proof packing 51 and using the nut 73 screwed into the bolt 3.

(Fourth embodiment)
As shown in FIG. 9, in the post-construction anchor of the fourth embodiment, the first point is that instead of the sealing means 50 of the first embodiment, a ring-shaped sealing means 80 that functions as a lid is used. It differs from the construction anchor 1 after embodiment. The sealing means 80 is made of rubber or a thin metal plate. As shown in FIG. 9 (a), the sealing means 80 in the initial state has a bowl shape extending obliquely downward as it goes radially inward, and the inner peripheral side of the sealing means 80 is connected to the bolt 3. It is in close contact.

  The sealing means 80 is attached from below after inserting the bolt 3 into the anchor hole S from below, as in the first embodiment. Thereafter, when the bolt 3 is struck from below with a hammer H or the like, the sealing means 80 is pushed upward from the inside in the radial direction, and the sealing means 80 is deformed as shown in FIG. 9B. The deformed sealing means 80 has a ring shape with a flat surface extending in a direction orthogonal to the axis L of the bolt 3.

  In the post-construction anchor according to the fourth embodiment, the sealing means 80 seals the anchor hole S in the same manner as the post-construction anchor 1 according to the first embodiment, thereby suppressing leakage of the grout G from the anchor hole S. Thus, in 4th Embodiment, since the leakage of grout G is suppressed using the sealing means 80 which functions as a cover part, the structure of the sealing means 80 can be simplified further.

  In addition, in 4th Embodiment, the sealing means 80 was the vertical shape extended diagonally downward as it goes to radial direction inner side in an initial state. However, as shown in FIG. 10, instead of the sealing means 80, a ring-shaped sealing means 85 having a flat surface extending in the direction perpendicular to the axis L of the bolt 3 in the initial state may be used. In this case, the material of the sealing means 85 is, for example, silicon rubber.

  The sealing means 85 is attached from the bottom of the bolt 3 after the bolt 3 is inserted into the anchor hole S from below. When the bolt 3 is subsequently struck from below with a hammer H or the like, the radially inner portion of the sealing means 85 is attached. 85a is pushed upward. Therefore, the deformed sealing means 85 has a shape in which the radially inner portion 85a is recessed upward, and is removed from the bolt 3 by tearing after completion of construction. Even when such a sealing means 85 is used, leakage of the grout G from the anchor hole S can be suppressed.

(Fifth embodiment)
As shown in FIG. 11 (a), the post-construction anchor of the fifth embodiment has crests 92 and troughs 93 formed continuously in the circumferential direction in place of the leak-proof packing 51 and the pressing ring 52. The point which used the corrugated ring-shaped cover part 90 differs from the post-construction anchor 1 of 1st Embodiment. The lid 90 is made of silicon, tin, or the like. For example, a portion near the center of the lid 90 is made of hard silicon.

  The lid 90 has an insertion hole 91 through which the bolt 3 is inserted, and the diameter of the insertion hole 91 is slightly longer than the outer diameter of the bolt 3. The crest 92 and the trough 93 formed continuously in the circumferential direction form a recess 94 that receives the grout G overflowing from the surface 2 a of the existing concrete structure 2. As described above, in the fifth embodiment, even if the grout G comes out of the anchor hole S, the concave portion 94 formed in the lid portion 90 receives the grout G, so that the situation where the grout G droops can be avoided. .

(Sixth embodiment)
As shown in FIG. 11 (b), the post-construction anchor of the sixth embodiment is replaced with a leak-proof packing 51 and a pressing ring 52, and an insertion hole 101 for inserting the bolt 3 and a recess 104 extending in the circumferential direction. The point which used the ring-shaped cover part 100 which has is different from the post-construction anchor 1 of 1st Embodiment. The diameter of the insertion hole 101 is slightly longer than the outer diameter of the bolt 3.

  The lid part 100 has an outer edge part 102 projecting upward and a convex part 103 projecting in a ring shape on the outer peripheral side of the insertion hole 101, and a concave part 104 is formed between the outer edge part 102 and the convex part 103. Has been. In the sixth embodiment, as in the fifth embodiment, even if the grout G comes out from the anchor hole S, the grout G is firmly held by the convex portion 103 and the concave portion 104 receives the grout G. The situation of dripping from the lid 100 can be avoided.

(Seventh embodiment)
As shown in FIG. 12, the post-construction anchor of the seventh embodiment is that the sealing means 110 using the repulsive force of the magnet is used in place of the sealing means 50 of the first embodiment. It differs from construction anchor 1 after form. The sealing means 110 includes a ring-shaped leak-proof packing 111, a ring-shaped press ring 112 with a magnet positioned below the leak-proof seal 111, and a bolt grip with a magnet that sandwiches the bolt 3 at the bottom of the press ring 112 with magnet 113. The configuration of the leak-proof packing 111 is the same as the configuration of the leak-proof packing 51 of the first embodiment.

  The shape of the retaining ring 112 with magnet and the bolt grip 113 with magnet can be the same as the shape of the retaining ring 52 and clip portion 54 of the first embodiment, but the materials are different. The holding ring 112 with a magnet and the bolt grip 113 with a magnet are comprised with the magnet, and the force which repels mutually is acting. Moreover, the bolt grip 113 with a magnet is provided with the pinching part 113a and the knob | pick part 113b similar to the clip part 54 of 1st Embodiment.

  In the post-construction anchor of the seventh embodiment, as in the post-construction anchor 1 of the first embodiment, the leak-proof packing 111 and the magnet retaining ring 112 are attached to the bolt 3 from below, and the anchor hole S is formed by the leak-proof packing 111. By sealing, leakage of grout G from the anchor hole S is suppressed. And since the force which pushes up the leak-proof packing 111 works by the repulsive force which acts between the holding ring 112 with magnet and the bolt grip 113 with magnet, the leakage of the grout G from the anchor hole S is more reliably suppressed. Can do.

  The present invention is not limited to the above-described embodiment, and various modifications as described below are possible without departing from the gist of the present invention.

  For example, in the first embodiment, the leak-proof packing 51 and the holding ring 52 function as a lid, but the leak-proof packing 51 can be omitted depending on the size of the diameter of the anchor hole S.

  Moreover, in the said embodiment, although the coil spring was used as a spring part, various springs other than a coil spring, such as a disc spring, can be substituted, for example.

  Moreover, in the said embodiment, although the anchor hole S extended to the perpendicular direction and the post-construction anchor 1 was inserted from the bottom, the aspect which inserts the post-construction anchor 1 from diagonally upward or the side may be sufficient.

  Moreover, in the said embodiment, although the anchor main body was demonstrated as the volt | bolt 3, what cut | disconnected the screw | thread at the front-end | tip of a round bar-shaped reinforcing bar etc. may be used, and various things other than the volt | bolt 3 shall be an anchor main body. Is possible.

DESCRIPTION OF SYMBOLS 1 ... Post-construction anchor, 2 ... Existing concrete structure, 2a ... Surface, 3 ... Bolt (anchor main body with a screw), 20 ... Expansion member, 50, 60, 70, 80, 85, 100, 110 ... Sealing means, 51, 61 ... leak-proof packing (lid), 51a ... insertion hole, 52, 62, 71 ... pressing ring (lid), 53, 63, 72 ... coil spring (spring), 54, 64 ... clip (support) Part), 73 ... nut (support part), 90, 100 ... lid part, 94, 104 ... concave part, P1 ... inclined surface, S ... anchor hole, S2 ... space part with undercut.

Claims (5)

In post-construction anchors having rod-shaped threaded anchor bodies embedded in anchor holes formed in existing concrete structures,
On the bottom side of the anchor hole, a substantially frustoconical space with an undercut is formed,
An expansion member that is fixed to the anchor body, expands in the space portion with the undercut when the anchor body is pushed into the anchor hole, and faces the inclined surface of the space portion with the undercut;
It has an insertion hole through which the anchor body is inserted, and includes a lid portion that seals the anchor hole in a state in which the anchor body is inserted through the insertion hole, and by sealing the anchor hole in the lid portion, Sealing means for suppressing leakage of grout in the anchor hole;
Post-construction anchor characterized by comprising   The said sealing means is provided with the spring part which urges | biases the said cover part in the pushing direction of the said anchor main body, and the support part which supports the said spring part on the front side of the said cover part, The post-construction anchor described in 1.   The post-construction anchor according to claim 2, wherein the lid, the spring, and the support are detachable from the anchor body.   The anchor body is pulled in a direction opposite to a pushing direction of the anchor body in a state where the lid portion seals the anchor hole before the grout in the anchor hole is solidified. Post-construction anchor as described in 2 or 3.   The post-construction anchor according to any one of claims 1 to 4, wherein the lid portion has a recess for receiving a grout from the anchor hole.

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