KR102482402B1 - Anchor Bolt - Google Patents

Abstract

The present invention relates to an anchor bolt with improved on-site workability, and more particularly, has a cross-sectional structure of upper and lower sides, a cone body inserted into a hole perforated in a certain size on a wall surface, and one lower end of the cone body at the upper end. Including an expansion sleeve in which a seating hole into which the insertion is inserted is formed and an incision groove cut downward at regular intervals is formed on the outer edge of the upper end, the cone body is press-fitted into the expansion sleeve, and the upper end of the expansion sleeve is widened to open the perforation. In the anchor bolt to be press-fitted, the expansion sleeve is formed with a diameter corresponding to or smaller than the perforation, and an insertion portion having the cut groove formed along one end thereof in a longitudinal direction and inserted into the perforation; Doedoe extending along the longitudinal direction downward at the other end, formed with a larger diameter than the perforation and exposed to the outside, the other end is provided with a fastening portion in which a fastening groove for fastening the bolt is formed.
According to the present invention as described above, the expansion sleeve is composed of two stages, an insertion part inserted into the hole and a fastening part exposed to the outside of the hole, so that the diameter of the hole for fastening the anchor bolt can be reduced while using the existing standard bolt. By reducing the perforation speed by drastically reducing the perforation speed by making the perforation even with one drilling operation, there is an effect of significantly improving the anchor bolt fastening work performance on the ceiling surface.
In addition, as the cone body is press-fitted into the expansion sleeve, the anchor bolt is pressurized in close contact with the inner wall of the hole due to the expansion of the end cut surface of the expansion sleeve, and the expansion diameter of the expansion sleeve is further widened by the first auxiliary expansion unit to pressurize. In addition, the angled distal end of each expansion wing is inserted into the inner wall of the perforation in a wedge structure by the second auxiliary expansion unit, so that the anchor bolt does not easily fall off even when the pulling load is applied downward. By being supported by the distal end of the expansion wing, there is an effect that it can be used stably even at a site where a structure to which a high pulling load is applied is installed.

Description

Anchor Bolt {Anchor Bolt}

The present invention relates to an anchor bolt with improved workability in the field, and more particularly, by reducing the diameter of the anchor bolt inserted into the ceiling surface to facilitate drilling work with less force, thereby increasing the perforation speed by 3 It relates to anchor bolts with improved on-site constructability that can be improved more than twice.

Generally, set anchors, chemical anchors, strong anchors, etc. are used as anchor bolts. As shown in FIG. Then, a dedicated punch is placed on the cap and hit with a hammer to expand the cap so that the anchor bolt is press-fitted to the concrete surface.

In addition, chemical anchors are divided into injection type and capsule type, and are fixed by injecting a chemical into the inside after drilling or by inserting a capsule and then fastening a bolt. The capsule chemical anchor shown in FIG. 1 (b) has a shorter hardening time compared to the general injection type chemical anchor that does not harden in winter, enabling rapid work, and the load bearing capacity is reflected in the seismic design, and the injection type chemical is used for both reinforcing bars and bolts It is possible, and the capsule type chemical anchor is optimized for bolt use, and it is possible to use reinforcing bars, but it is somewhat difficult to construct.

And the strong anchor is a structure in which the body (strong) and the anchor pin (cone body) are separated, and is mainly used to fix the bolt by fixing it on the ceiling. This strong anchor has a built-in cone part, and a drop in anchor that strikes and fixes the cone in the body using a separate striking equipment (anchor punch), and as shown in (c) of FIG. The cone part is exposed, and it consists of a cut anchor that fixes the anchor by hitting the concrete with a hammer from the cone part.

Here, the cut anchor has lower load-bearing capacity than the drop-in anchor in which the cone is in the body, but the cut anchor is mainly used to install a plurality of computerized bolts on the ceiling surface due to the shortened working time.

2 is a view showing in detail an anchor bolt (strong anchor) in a state in which a generally 9 mm diameter power bolt is fastened, and FIG. 3 is a view briefly showing the order in which these power bolts are fixed to the ceiling surface.

Looking at the drawings, the sheathed bolts fixed to support various structures on the ceiling surface have various specifications, but these sheathed bolts (A) are more expensive as the diameter is smaller, and currently, sheathed bolts with a diameter of 9mm are widely used there is.

In this way, in order to fasten the 9mm diameter sheath bolt to the anchor bolt, the diameter of the anchor bolt should be formed to about 12mm. Accordingly, a plurality of holes with a diameter of 12 mm for fastening the anchor bolts should be formed at intervals of approximately 90 to 120 cm on the concrete ceiling surface.

Accordingly, the worker drills a hole with a diameter of 12 mm in the concrete surface using a drill as shown in (a) of FIG. However, this drilling work is inevitably caused by concrete powder falling downward from the ceiling, which is very disadvantageous to the work. Such drilling work is most avoided. Moreover, in the fastening of these computerized bolts, the labor cost required for the drilling operation occupies a large part in the entire process.

After such a ceiling surface drilling (B) is made, as shown in (b) of FIG. Insert part (10) into the perforated part and hit the ceiling with the end of the bolt (A) using a hammer or other hitting tool. Then, as shown in (c) of FIG. 3, while the cone body 10 is press-fitted into the sleeve 20, the end of the sleeve 20 is widened so that the anchor bolt is fixed to the ceiling.

In order to improve the workability of anchor bolt fastening, it is possible to fasten a smaller diameter bolt, but as described above, the smaller the diameter, the higher the cost of the bolt itself. It is coming.

Therefore, there is a very high demand for anchor bolts that can overcome the disadvantages of drilling work for fixing these anchor bolts to the ceiling surface and can fix the same 9mm diameter computerized bolts.

Korean Patent Publication No. 2020-0059793

The present invention has been made to solve the above problems, and an object of the present invention is to fasten a 9mm diameter bolt that is mainly used in the past, and to reduce the perforation diameter of the ceiling surface from 12mm, thereby improving the perforation workability. is intended to improve.

Another object of the present invention is to improve the fastening force of the anchor bolt while reducing the diameter of the hole.

According to one aspect of the present invention for achieving the above object, a cone body has a cross-sectional structure of upper and lower narrows and is inserted into a hole perforated in a predetermined size on a wall surface, and one lower end of the cone body is inserted into the upper end. Including an extension sleeve in which a seating hole is formed and an incision groove cut downward at regular intervals is formed on the outer edge of the upper end, while the cone body is press-fitted into the extension sleeve, the upper end of the extension sleeve opens and is press-fitted into the perforation. In the anchor bolt, wherein the expansion sleeve is formed with a diameter corresponding to or smaller than the perforation, and the incision is formed at one end along the longitudinal direction, and an insertion portion inserted into the perforation, and the other end of the insertion portion It extends downward along the longitudinal direction, is formed with a larger diameter than the perforation and is exposed to the outside, and is provided including a binding part in which a fastening groove for fastening the bolt is formed on the inside of the other end.

Here, the outer diameter of the insertion part is within 9 mm, and the diameter of the bolt fastened to the fastening groove is 9 mm or more.

In addition, the cone body is formed with an expansion hole passing vertically along the longitudinal direction at the center, the expansion hole is formed inclined so that the diameter further expands downward, and the expansion hole and the expansion hole downward from the top along the outer edge of the cone body. It is cut to a certain length so as to be in communication so that the upper end of the cone body is divided into a plurality of pieces, and at the inner center of the extension sleeve, an extension guide protrusion inserted into the expansion hole protrudes upward with a certain length, and the cone When the body is pressed and moved into the expansion sleeve, the expansion guide protrusion slides into the inclined expansion hole, and the upper end of the cone body spreads outward.

Moreover, the outer edge of the cone body is cut downward at the upper end along the outer edge at regular intervals to form a plurality of expansion pieces, and an expansion hole formed of an inclined surface penetrates the center of the cone body to increase the passage downward. A first auxiliary extension portion formed and an extension portion extending downward from the first auxiliary extension portion and inserted into the seating hole formed between the inner surface of the extension sleeve and the extension guide protrusion are provided.

In addition, the extension part further includes a second auxiliary extension section in which a plurality of extension wings are formed along the outer edge by being cut upward at regular intervals at the outer edge of the distal end, and an interval corresponding to the formation position of the extension wings is formed on the outer edge of the lower end of the insertion part. Sliding balls communicating with the seating holes are formed, respectively, so that the extension wings protrude outward from the extension sleeve along the sliding holes, and the extension guide protrusions are integrally formed on the inner surface of the extension sleeve, It is formed as a sliding slope whose diameter goes downward along the lengthwise direction, and each expansion wing slides along the sliding slope to the outside of the sliding hole and spreads.

According to the present invention as described above, the expansion sleeve is composed of two stages, an insertion part inserted into the hole and a fastening part exposed to the outside of the hole, so that the diameter of the hole for fastening the anchor bolt can be reduced while using the existing standard bolt. By reducing the perforation speed by drastically reducing the perforation speed by making the perforation even with one drilling operation, there is an effect of significantly improving the anchor bolt fastening work performance on the ceiling surface.

In addition, as the cone body is press-fitted into the expansion sleeve, the anchor bolt is pressurized in close contact with the inner wall of the hole due to the expansion of the end cut surface of the expansion sleeve, and the expansion diameter of the expansion sleeve is further widened by the first auxiliary expansion unit to pressurize. In addition, the angled distal end of each expansion wing is inserted into the inner wall of the perforation in a wedge structure by the second auxiliary expansion unit, so that the anchor bolt does not easily fall off even when the pulling load is applied downward. By being supported by the distal end of the expansion wing, there is an effect that it can be used stably even at a site where a structure to which a high pulling load is applied is installed.

1 is a view showing various types of anchor bolts.
Figure 2 is a view showing in detail the anchor bolt (strong anchor) in a state in which the bolt generally has a diameter of 9 mm is fastened.
3 is a diagram briefly showing the order in which these electric bolts are fixed to the ceiling surface.
4 is a perspective view showing an anchor bolt according to an embodiment of the present invention.
5 is a view showing the steps in which anchor bolts according to the present invention are fixed to the ceiling surface.
6 is a perspective view showing an anchor bolt according to another embodiment of the present invention.
7 is an exploded perspective view of an anchor bolt according to another embodiment of the present invention.
8 is a view showing the cross-sectional structure of an anchor bolt according to another embodiment of the present invention.
9 is a view showing steps in which anchor bolts are fixed to the ceiling surface according to another embodiment of the present invention.

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

Figure 4 is a perspective view showing an anchor bolt according to an embodiment of the present invention, Figure 5 is a view showing the step of fixing the anchor bolt according to the present invention to the ceiling surface.

Referring to the drawings, an anchor bolt according to an embodiment of the present invention includes a cone body 100 and an extension sleeve 200 into which a lower portion of the cone body 100 is inserted.

The cone body 100 has a cross-sectional structure of upper and lower narrows, and is inserted into the hole B perforated in a certain size on the wall surface. In general, the maximum diameter of the cone body 100 is the same as or slightly smaller than the diameter of the hole. do.

The expansion sleeve 200 has a seating hole 201 into which one side of the lower end of the cone body 100 is inserted is formed at the upper end, and an incision groove 202 cut downward at regular intervals is formed at the outer edge of the upper end. ) Including, while the cone body 100 is press-fitted into the expansion sleeve 200, the upper end of the incised expansion sleeve 200 is widened and the outer surface diameter is increased to be press-fit into the hole (B).

The extension sleeve 200 according to one practical example of the present invention includes an insertion portion 210 inserted into the hole B and a coupling portion 220 exposed to the outside of the ceiling surface.

The insertion portion 210 may be formed with a diameter corresponding to the perforation B, or may be formed with a slightly smaller diameter than the perforation B to facilitate insertion, and a cutout 202 is formed at one end along the longitudinal direction. It is formed with a certain length and is inserted into the hole (B) when the anchor bolt is fastened.

The coupling part 220 extends downward along the longitudinal direction from the other end of the insertion part 210, and is formed with a larger diameter than the hole B perforated in the concrete ceiling surface, so that it is not inserted into the hole B. It is exposed to the outside when the anchor bolt is fastened, and a fastening groove 221 for fastening the computerized bolt (A) is formed on the inside of the other end.

In one embodiment of the present invention, the diameter of the coupling groove 221 of the coupling portion 220 is formed to be 9 mm or more, so that the ready-made 9 mm bolt A can be fastened, and the insertion portion 210 The outer diameter is formed within 9 mm, approximately 7 mm. That is, without the need to drill (B) the concrete ceiling with a diameter of 12 mm in order to fasten the existing 9 mm bolt (A), the hole (B) is formed to a much smaller extent of 7 mm.

The drilling (B) with a diameter of 7mm is a size that allows the worker to drill a hole sufficiently with one drilling operation by placing a drill on the ceiling surface, and the perforation speed is more than three times faster than that of the 12mm drilling (B). it will be done Accordingly, the labor cost can be reduced by more than three times compared to the previous one, and the fastening workability is very excellent.

As such, in one embodiment of the present invention, the shape of the sleeve is composed of two stages consisting of a cylindrical insertion portion 210 with a diameter of 7 mm and a fastening portion to which the bolt A is fastened in a cylindrical shape with a diameter of 12 mm. It is possible to improve the fastening workability while using the 9mm bolt (A) as it is.

Figure 6 is a perspective view showing an anchor bolt according to another embodiment of the present invention, Figure 7 is an exploded perspective view of an anchor bolt according to another embodiment of the present invention, Figure 8 is an anchor bolt according to another embodiment of the present invention It is a view showing a cross-sectional structure, and FIG. 9 is a view showing a step in which anchor bolts according to another embodiment of the present invention are fixed to the ceiling surface.

Referring to the drawings, in another embodiment of the present invention, when the anchor bolt is fixed to the ceiling surface, in addition to the expansion of the sleeve by the cone body 100, other auxiliary expansion means are press-fitted to the ceiling surface so that the diameter of the hole (B) is Even if it is small, the pulling load does not fall and the clamping force can be improved.

To this end, in another embodiment of the present invention, the first and second auxiliary extensions 110 and 120 are formed on the upper and lower ends of the cone body 100 to extend from the upper and lower ends of the anchor bolt to the inner surface of the hole B. to make it adhere strongly.

The first auxiliary extension part 110 is cut into a plurality of pieces at the upper end of the cone body 100, and is inserted into the extension sleeve 200 so that the plurality of pieces spread outward, so that the extension sleeve 200 Allow the upper part to expand further.

The first auxiliary extension part 110 is formed on the upper side of the cone body 100, the outer edge of which is formed to become narrower downward in the upper and lower sides, and vertically in the center of the cone body 100 along the lower longitudinal direction. Penetrating expansion holes 111 are formed, and these expansion holes 111 are made of inclined surfaces so that the passage becomes larger downward, and expansion holes extend downward from the upper end at regular intervals along the outer edge of the cone body 100. It is cut to a certain length so as to communicate with (111) so that the upper end of the cone body 100 is formed into a plurality of expansion pieces 112.

In addition, an expansion guide protrusion 211 inserted into the expansion hole 111 protrudes upward with a certain length at the inner center of the expansion sleeve 200, and extends downward at the lower end of the first auxiliary expansion part 110. and an extension part 120 inserted into the seating hole 201 formed between the inner surface of the extension sleeve 200 and the extension guide protrusion 211.

When the cone body 100 is pushed into the expansion sleeve 200 and moved, the first auxiliary expansion unit 110 slides into the expansion hole 111 with the expansion guide protrusion 211 inclined, and the cone body As the expansion piece 112 formed at the upper end of 100 is widened outward, the cut surface of the upper end of the expansion sleeve 200 in close contact with it opens wider than the angle widened by the maximum diameter of the cone body 100.

As described above, in another embodiment of the present invention, even if the maximum diameter of the cone body 100 is equal to the diameter of the perforation (B), the cone body 100 is inserted into the extension guide protrusion 211 and the maximum diameter of the cone body 100 In the above, the expansion sleeve 200 is further spread. Accordingly, the pressure in contact with the inner surface of the perforation B is applied more strongly, thereby improving the bearing capacity according to the pulling load.

Moreover, the extension part 120 further includes a second auxiliary extension part 120 in which a plurality of extension wings 121 are formed along the outer edge by being incised upward at regular intervals at the distal edge, so that the cone body 100 Along with being press-fitted into the expansion sleeve 200, the second auxiliary expansion part 120 formed at the lower end of the cone body 100 is spread outward, so that the bearing capacity can be further reinforced.

To this end, sliding holes 213 communicating with the seating holes 201 are formed on the outer edge of the lower end of the insertion part 210 at intervals corresponding to the formation positions of the extension wings 121, so that the extension wings 121 slide. Along the ball 213, the distal end of the extension blade 121 protrudes outward from the extension sleeve 200, and the extension guide protrusion 211 is integrally formed on the inner surface of the extension sleeve 200, and extends in the longitudinal direction. It is formed with a sliding slope 212 whose diameter goes downward along the sliding slope 212, so that each expansion wing 121 slides along the sliding slope 212 to the outside of each sliding ball 213 and unfolds.

The distal end of the extended wing 121 protrudes outward from the extended sleeve 200 so as to be press-fitted into the inner wall of the perforation B.

As described above, in another embodiment of the present invention, as described above, basically, the cone body 100 is press-fitted into the expansion sleeve 200, and the end cut surface of the expansion sleeve 200 expands to form a perforation B on the inner side wall. In addition to allowing the anchor bolt to be closely pressed, the expanded diameter of the expansion sleeve 200 is wider by the first auxiliary extension 110 to increase the pressure adhesion, and furthermore, the second auxiliary extension 120 As a result, the angled distal end of each expansion wing 121 is inserted into the inner wall of the perforation (B) in a wedge structure, so that the anchor bolt does not easily fall off even when a pulling load acts downward, and the distal end of the expansion wing 121 to be supported by

That is, the anchor bolt according to another embodiment of the present invention is installed at a site where a high pull-out load is applied to the structure than the pull-out load acting on the general ceiling surface, so that the structure is stably supported.

Although the present invention has been described with respect to the preferred embodiments mentioned above, various modifications and variations are possible without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims will include such modifications and variations as fall within the scope of this invention.

100: cone body
110: first auxiliary expansion unit 111: expansion hole
112: Expansion piece
120: extension
120: second auxiliary extension 121: extension wing
200: expansion sleeve 201: seating hole
202: cutting groove
210: insertion part 211: extension guide protrusion
212: sliding slope 213: sliding ball
220: coupling part 221: fastening groove
A: Threaded bolt B: Drilled

Claims (5)

It has a cross-sectional structure of upper and lower sides, and a cone body inserted into the hole perforated to a certain size on the wall surface, and a seating hole into which one side of the lower end of the cone body is inserted is formed at the upper end, and the upper outer edge is cut downward at regular intervals. In the anchor bolt, including an expansion sleeve in which an incision groove is formed, the cone body is press-fitted into the expansion sleeve and the upper end of the expansion sleeve is widened to be press-fit into the hole,
The extension sleeve
An insertion portion formed with a diameter corresponding to or smaller than the perforation and having one end of the incision groove formed along the longitudinal direction to be inserted into the perforation;
It extends downward along the longitudinal direction at the other end of the insertion portion, is formed with a larger diameter than the perforation and is exposed to the outside, and includes a binding portion in which a fastening groove for fastening a computerized bolt is formed inside the other end,
The cone body is formed with an expansion hole passing vertically along the longitudinal direction at the center, the expansion hole is formed inclined so that the diameter further expands downward,
Along the outer edge of the cone body, a certain length is cut from the top to the bottom to communicate with the expansion hole so that the upper end of the cone body is divided into a plurality of pieces,
An extension guide protrusion inserted into the expansion hole protrudes upward with a predetermined length at the inner center of the extension sleeve,
An anchor bolt, characterized in that when the cone body is pressed and moved into the expansion sleeve, the upper end of the cone body spreads outward as the expansion guide protrusion slides into the inclined expansion hole.
According to claim 1,
The outer diameter of the insertion part is within 9 mm,
Anchor bolts, characterized in that the bolt fastened to the fastening groove has a diameter of 9mm or more.
delete According to claim 1,
The cone body
The outer edge is cut downward at the upper end along the outer edge at regular intervals along the outer edge to form a plurality of expansion pieces, and in the center of the cone body, an expansion hole made of an inclined surface is formed through the cone body so that the passage becomes larger downward. wealth,
The anchor bolt characterized in that it comprises an extension portion extending downward from the first auxiliary extension portion and inserted into a seating hole formed between the inner surface of the extension sleeve and the extension guide protrusion.
According to claim 4,
the extension
Further comprising a second auxiliary extension section in which a plurality of extension wings are formed along the outer edge by being incised upward at regular intervals on the outer edge of the distal end,
Sliding holes communicating with the seating holes are formed at the outer edge of the lower end of the insertion part at intervals corresponding to the formation positions of the extension wings, so that the extension wings protrude outward from the extension sleeve along the sliding holes,
The extension guide protrusion is integrally formed on the inner surface of the extension sleeve, and is formed as a sliding slope whose diameter goes downward in the longitudinal direction, so that each extension wing moves along the sliding slope to the outside of the sliding hole. An anchor bolt characterized in that it unfolds while sliding.

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