JP2013159976A - Anchor bolt construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inexpensive anchor bolt construction method for reducing the number of anchor bolts to be installed by improving an allowable shear capacity per anchor bolt.SOLUTION: In the anchor bolt construction method, a cylindrical hole 2 is formed in a concrete structure 1 in which a steelwork 5 is embedded, so that the steelwork 5 is exposed to the bottom surface, an anchor bolt 3 is inserted thereinto, and welded and fixed to the steelwork 5, and filler 4 is filled in the hole 2. An allowable shear capacity Qa1 per anchor bolt and bearing strength cσqa of concrete are previously found. The hole 2 is formed whose opening area is such that an allowable shear capacity Qa2 per anchor bolt determined by the bearing strength of the concrete found from the bearing strength cσqa of the concrete and the opening area of the hole is greater than the allowable shear capacity Qa1.

Description

  The present invention relates to an anchor bolt construction method for constructing anchor bolts for reinforcement work and expansion work on an existing concrete structure.

Anchor bolts are installed in existing concrete structures when reinforcing work such as improving the earthquake resistance, or when expanding work.
As a method for constructing the anchor bolt, a hole having a predetermined diameter and depth is formed on the surface of the concrete structure, the anchor bolt is inserted into the hole, and the anchor bolt and the inner peripheral surface of the hole A method of fixing the anchor bolt by filling the gap with a fixing material or the like is employed.

In such an anchor bolt construction method, various methods for improving the anchoring strength of the anchor bolt to the concrete structure have been studied.
For example, Patent Documents 1 and 2 describe a method for improving the tensile strength by using an anchor bolt whose tip is larger in diameter than the shaft as the anchor bolt.

However, when an anchor bolt having a large tip as described above is used, the tensile strength of the anchor bolt can be improved, but the strength in the direction perpendicular to the insertion direction of the anchor bolt, that is, the shear strength. It is difficult to improve.
Therefore, in order to improve the shear strength as a structure, the number of anchor bolts is increased, but there is a problem that the cost is increased.

In addition, when a steel material such as a reinforcing bar is embedded in an existing concrete structure, when the hole is formed at a position where the steel material is embedded, the hole is formed only to the depth where the steel material is embedded. Cannot be formed.
In such a case, for example, in Patent Document 3, a hole is formed to a depth at which the steel material is exposed, and the tip of the anchor bolt is welded to the steel material exposed on the bottom surface of the hole, thereby fixing the anchor bolt. It is described that it adheres firmly to a concrete structure.
However, even in this method, even if the tensile strength of the anchor bolt can be improved, it is difficult to improve the shear strength.

JP 2008-208597 A JP 2004-116128 A JP 2001-295478 A

  Accordingly, in view of the above-described conventional problems, the present invention provides a method that can improve the allowable shear strength of one anchor bolt and reduce the number of anchor bolts to be installed at a low cost. The issue is to provide.

The anchor bolt construction method according to the present invention is:
A cylindrical hole is formed in the surface of the concrete structure in which the steel frame is embedded, and the steel frame is exposed on the bottom surface. An anchor bolt is inserted into the hole, and the steel frame and the anchor bolt exposed on the bottom surface are connected. In the anchor bolt construction method of fixing the anchor bolt by welding, filling a filler between the inner peripheral surface of the hole and the anchor bolt, and constructing the anchor bolt on the concrete structure,
In advance, the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt and the bearing strength cσqa of the concrete of the concrete structure are obtained,
The allowable shear strength Qa2 per anchor bolt determined by the concrete bearing strength determined from the concrete bearing strength cσqa and the opening area of the hole is per anchor bolt determined by the anchor bolt shear strength. The opening area of the hole is set to be larger than the allowable shear strength Qa1,
The hole is formed to have the set opening area.

According to this configuration, when the anchor bolt is applied to a concrete structure, the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt and the bearing strength cσqa of the concrete are obtained in advance. The anchor bolt 1 determined by the bearing strength of the concrete determined from the bearing strength cσqa of the concrete and the opening area of the hole rather than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt By setting the opening area of the hole so that the permissible shear strength Qa2 per book becomes large, the shear strength between the anchor bolts applied to the concrete structure and the concrete structure can be improved.
That is, the shear strength between the anchor bolt and the concrete structure can be improved by adjusting the opening area of the hole suitable for the anchor bolt to be used and the concrete structure on which the anchor bolt is installed. The number of anchor bolts installed can be reduced.

The allowable shear strength Qa1 per anchor bolt when determined by the shear strength of the anchor bolt in the present invention and the allowable shear strength Qa2 per anchor bolt when determined by the bearing strength of the concrete are as follows: (1) and (2)

Qa1 (N) = 2/3 * ₁ × sσqa × sca (1)
Qa2 (N) = 1/3 * ₂ × cσqa × scA (2)

* ₁ : Reduction factor, for long-term load * ₂ : Reduction factor, long-term load sca: Anchor bolt cross-sectional area (mm ² )
scA: Opening area of the hole (mm ² )
sσqa: Anchor bolt shear strength (N / mm ² ), sσqa = 0.7 × sσy.
sσy: Standard yield strength of anchor bolt (N / mm ² )
cσqa: bearing strength of concrete (N / mm ² ), cσqa = 0.5 × (Fc × Ec) ^1/2
Fc: Design standard strength of concrete (N / mm ² )
Ec: Young's modulus of concrete (N / mm ² )

The standard yield point strength (sσy) of the anchor bolt refers to the yield point strength determined in accordance with JIS G3112.
Concrete compressive strength (Fc) refers to the actual measured compressive strength of concrete or the concrete design standard strength of a concrete structure.
The Young's modulus (Ec) of concrete is calculated from the measured Young's modulus of concrete or the compressive strength (Fc) of concrete according to the Architectural Institute of Japan “Standards for Calculation of Reinforced Concrete Structures / Description”, Ec = 3.35 × 10 ⁴ × (γ / 24) It is calculated from ² × (Fc / 60) ^1/3 . (Γ: Air dry unit volume weight of concrete t / m ³ )

That is, among the values used in the formulas (1) and (2), values other than scA: opening area (mm ² ) of the hole are the anchor bolt to be used and the concrete structure in which the anchor bolt is installed. It is a value that can be obtained from the object.
In the present invention, prior to constructing the anchor bolt on the concrete structure, the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt obtained from the formulas (1) and (2) and the concrete By setting the scA: opening area (mm ² ) of the hole so that the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of Qa1 <Qa2 is set, the anchor bolt is made into a concrete structure. Holes of a size (opening area) that can improve the shear strength when applied to an object can be formed.

Further, in the present invention, the tensile strength against the cone-shaped fracture of the concrete is determined, and the depth from the concrete surface to the steel frame is measured, and the tensile strength against the cone-shaped fracture of the concrete and the depth to the steel frame The allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete determined from the opening diameter of the hole and the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete are:
It is preferable to set the opening area of the hole so as to be larger than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt.

  The allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete and the allowable shear strength Qa2 per anchor bolt determined by the bearing pressure strength of the concrete are both determined by the shear strength of the anchor bolt. If the opening area of the hole is set so as to be larger than the allowable shear strength Qa1 per anchor bolt, the concrete structure in which the depth of the hole is limited by the depth in which the steel frame is embedded When the anchor bolt is installed on the hole, it is possible to set the opening area of the hole that can obtain the optimum shear strength for the depth of the steel frame.

The allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete is obtained by the following formula (3).

Qa3 = 1.5 * ₃ × cσt × Aqc (3)

* ₃ : Reduction factor cσt: Tensile strength (N) of concrete against cone-shaped fracture, cσt = 0.31 × Fc ^1/2 .
Aqc: Effective projected area (mm ² ) of the cone-shaped fracture surface with respect to shear force, Aqc = 0.5 × π × l ² + l × r
l: Depth to steel frame (mm)
r: Opening diameter of hole (mm)

In addition, the opening diameter of the hole as used in the field of this invention is the inner diameter of an opening part, and means the length of the longest location.
Moreover, the depth to the steel frame as used in the field of this invention means the depth from the concrete structure surface to a steel frame.

Among the values used in the formula (3), a value other than r: opening diameter (mm) of the hole can be obtained from the anchor bolt to be used and the concrete structure in which the anchor bolt is constructed. Value.
That is, the allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete obtained from the formula (3) and the allowable shear strength per anchor bolt determined by the concrete bearing strength as described above. Qa2 forms a hole having an opening area of a hole determined from an opening diameter of the hole such that Qa2 is larger than an allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. When the depth can be formed only up to a predetermined depth, it is possible to set the opening area of the hole that can obtain the optimum shear strength.
When the steel structure is embedded in the concrete structure, the depth of the hole is limited to the depth of the steel frame, but the hole with the opening area that satisfies the above conditions is formed and the anchor bolt is installed. By doing so, a required shear strength can be obtained at the joint portion between the concrete structure and the anchor bolt.

  In the present invention, the filler is preferably cement-based non-shrink mortar.

  When the filler is cement-based non-shrink mortar, there is little shrinkage of the filler after filling the hole with the filler, so that a gap is hardly generated between the filler and the inner peripheral surface of the hole. Therefore, the anchor bolt can be more firmly fixed to the concrete structure.

  Preferably, the anchor bolt includes a shaft and a tip portion having a diameter larger than that of the shaft, and the anchor bolt is installed in the hole with the tip portion disposed on the bottom side of the hole.

  The anchor bolt has a shaft and a tip portion having a larger diameter than the shaft, and the tip portion having the larger diameter is fixed to the inside of the hole by a filler by arranging the tip portion on the bottom side of the hole. The strength is increased, and the strength in the pulling direction of the anchor bolt, that is, the tensile strength can be improved.

  As described above, according to the present invention, by improving the allowable shear strength of one anchor bolt and reducing the number of anchor bolts installed, the anchor bolts can be applied to an existing concrete structure at a low cost. Can do.

(A) (b) The schematic sectional drawing which showed the state which constructs an anchor bolt. (A) (b) The top view which shows the state which constructed the anchor bolt.

Hereinafter, the anchor bolt construction method according to the present invention will be specifically described with reference to the drawings.
The anchor bolt construction method of this embodiment forms a cylindrical hole that opens on the surface of a concrete structure in which a steel frame is embedded and the steel frame is exposed on the bottom surface, inserts the anchor bolt into the hole, and The steel frame exposed to the metal and the anchor bolt are welded to fix the anchor bolt, and a filler is filled between the inner peripheral surface of the hole and the anchor bolt, and the anchor bolt is applied to the concrete structure. In the anchor bolt construction method, the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt and the bearing strength cσqa of the concrete of the concrete structure are obtained in advance, and the bearing pressure of the concrete is determined. Anchor bolt 1 determined by the bearing strength of concrete determined from the strength cσqa and the opening area of the hole The opening area of the hole is set so that the permissible shear strength Qa2 is larger than the permissible shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt, and the set opening area This is a method of forming the hole so as to be.

The concrete structure in which the anchor bolt is installed in the present embodiment is a concrete structure such as an existing building or a bridge.
In such a concrete structure, anchor bolts are installed in order to integrate new members into the concrete structure via anchor bolts for reinforcement or expansion.

In a general anchor bolt construction method, first, holes 2 are formed on the surface of a concrete structure 1 as shown in FIG.
Such holes 2 are generally formed with a drill or the like. Therefore, the hole 2 is formed in a cylindrical shape having a circular opening and the same cross-sectional shape in the depth direction.
A steel frame 5 is embedded in the concrete structure 1.
The hole 2 is formed from the surface of the concrete to the depth of the steel frame 5, and the steel frame is exposed at the bottom of the hole.
An anchor bolt 3 made of metal or the like is inserted into the hole 2, and the tip 3b of the anchor bolt 3 is welded to the steel frame 5 exposed on the bottom surface of the hole.

As the welding method, known means can be used. For example, stud welding using a stud welding machine is preferable because workability is good.
Further, before the welding, the surface of the steel frame 5 exposed on the bottom surface of the hole 2 may be cleaned using a wire brush or the like to facilitate welding.

  After fixing the anchor bolt 3 to the steel frame 5 by welding, the anchor bolt is applied to the concrete structure 1 by filling the hole 2 with a filler 4 as shown in FIG.

In the anchor bolt construction method of the present embodiment, before forming the hole as described above, the opening area of the hole that can increase the allowable shear strength of the anchor bolt is set in advance.
In addition, when forming a hole using a drill etc. as mentioned above, the opening diameter and opening area of a hole can be adjusted by using a thing with a predetermined diameter as a drill.
Among the drills, the core drill is particularly preferable because it has less noise and dust.

Specifically, first, an allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt is obtained from the concrete structure and the anchor bolt installed in the concrete structure.
Further, the bearing strength cσqa of the concrete is obtained.
Then, the anchor shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete obtained from the bearing strength cσqa of the concrete and the opening area of the hole is one anchor bolt determined by the shear strength of the anchor bolt. The opening area scA of the hole that is larger than the permissible permissible shear strength Qa1 is obtained.

The allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt and the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete are expressed by the following equations (1) and (2). Desired.

Qa1 (N) = 2/3 * ₁ × sσqa × sca (1)
Qa2 (N) = 1/3 * ₂ × cσqa × scA (2)

* ₁ : Reduction factor, for long-term load * ₂ : Reduction factor, long-term load sca: Anchor bolt cross-sectional area (mm ² )
scA: Opening area of the hole (mm ² )
sσqa: Anchor bolt shear strength (N / mm ² ), sσqa = 0.7 × sσy.
sσy: Standard yield strength of anchor bolt (N / mm ² )
cσqa: bearing strength of concrete (N / mm ² ), cσqa = 0.5 × (Fc × Ec) ^1/2
Fc: Design standard strength of concrete (N / mm ² )
Ec: Young's modulus of concrete (N / mm ² )

The standard yield point strength (sσy) of the anchor bolt refers to the yield point strength determined in accordance with JIS G3112.
That is, a predetermined yield point strength is defined by the material of the anchor bolt. For example, when a D16 SD295S type anchor bolt is used as the anchor bolt, the standard yield point strength is 295 N / mm ² .
The anchor bolt cross-sectional area sca indicates the cross-sectional area of the narrowest portion of the portion inserted into the hole of the anchor bolt. For example, the shaft 3a as shown in FIG. 1 has a diameter larger than that of the shaft 3a. In the case of an anchor bolt provided with the tip 3b, the cross-sectional area of the shaft 3a is the anchor bolt cross-sectional area sca.

The concrete compressive strength (Fc) refers to the actual measured compressive strength of concrete or the concrete design standard strength of a concrete structure.
The Young's modulus of the concrete (Ec), the Architectural Institute of Japan "reinforced concrete structural calculation criteria, same explanation" from the measured Young's modulus or compressive strength of the concrete of the concrete (Fc), Ec = 3.35 × 10 4 × (γ / 24) It is calculated from ² × (Fc / 60) ^1/3 . (Γ: Air dry unit volume weight of concrete t / m ³ )
That is, the concrete compressive strength (Fc) and the concrete Young's modulus (Ec) can be derived from the design specifications of the concrete structure.

That is, the values used in the formulas (1) and (2) are all values obtained from the concrete structure and the anchor bolts, except for the opening area of the holes.
Therefore, the opening area of the hole is such that the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete is larger than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. Can be set.

  The opening area of the hole is such that the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete is larger than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. By setting the area, the strength for installing a specific anchor bolt in a specific concrete structure, particularly the shear strength in the direction X perpendicular to the insertion direction of the anchor bolt as shown in FIG. be able to.

In addition, the effect is improved, so that the opening area of the hole is larger than the area satisfying Qa2> Qa1 from the viewpoint of suppressing bearing fracture.
That is, as shown in FIGS. 2 (a) and 2 (b), when the opening area is large (FIG. 2 (a)), the anchor bolt is smaller than when the opening area is small (FIG. 2 (b)). The area of the concrete (shown as lengths d and d 'of the opening edge of the hole in the figure) to which the shear strength is applied in the direction X perpendicular to the insertion direction is increased, and the shear strength is improved.

However, when the opening area of the hole is excessively large, a large amount of filler is required, which is expensive and not preferable.
Further, since the allowable shear strength per anchor bolt is Qa1, even if Qa2 is increased, there is no effect in improving the allowable shear strength per anchor bolt.
Therefore, the opening area of the hole is preferably near the minimum area of the opening area of the hole satisfying Qa2> Qa1.

Moreover, it was constructed on the concrete structure from the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of the concrete and the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. In order to obtain the area of the hole where the shear strength of the anchor bolt is improved, the filling material filled between the hole and the anchor bolt has higher bearing strength than the concrete of the concrete structure, and does not break the bearing. A filler is preferred.
That is, the bearing strength of the filler is higher than the concrete bearing strength of the concrete structure and does not break the bearing, so that the compressive strength can be maximized without considering the influence of the filler. The opening area of the hole such that the allowable shear strength Qa2 per anchor bolt determined by the bearing strength of weak concrete and the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt have the above relationship By setting, the shear strength between the anchor bolt and the concrete structure when installed in the concrete structure can be improved.

  In the anchor bolt construction method of the present embodiment, the opening area of the hole satisfying Qa2> Qa1, and the allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete and the concrete The opening area of the hole is set so that the allowable shear strength Qa2 per anchor bolt determined by the bearing strength is greater than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. It is preferable to do.

The allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete is obtained by the following formula (3).
Qa3 = 1.5 * ₃ × cσt × Aqc (3)
* ₃ : Reduction factor cσt: Tensile strength (N) of concrete against cone-shaped fracture, cσt = 0.31 × Fc ^1/2 .
Aqc: Effective projected area (mm ² ) of the cone-shaped fracture surface with respect to shear force, Aqc = 0.5 × π × l ² + l × r
l: Depth to steel frame (mm)
r: Opening diameter of hole (mm)

Among the values used in the formula (3), a value other than r: opening diameter (mm) of the hole can be obtained from the anchor bolt to be used and the concrete structure in which the anchor bolt is constructed. Value.
That is, the allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete obtained from the formula (3) is larger than the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt. By forming a hole having an opening area determined from the opening diameter of the hole so as to be large, when the depth of the hole is a predetermined depth, an opening area of the hole capable of obtaining an optimum shear strength is set. Can be set.

In the concrete structure of the present embodiment, a steel frame is embedded, a hole having a depth to the steel frame is formed, and the steel frame and the anchor bolt are welded, whereby the strength in the drawing direction Y (tensile) (Strength) is improved, the depth of the hole is limited to the depth to the steel frame.
Thus, even when the depth of the hole is limited by the depth of the steel frame, the necessary shear strength can be obtained at the joint portion between the concrete structure and the anchor bolt by adjusting the opening area of the hole. .

The hole diameter satisfying the above-mentioned Qa2> Qa1 and the hole diameter (hole opening area) satisfying the above-mentioned Qa3> Qa1 at the same time is set, and the hole of this size is made into a concrete structure. Form on the surface.
Furthermore, an anchor bolt is inserted into the hole, and a filler is filled between the inner peripheral surface of the hole and the anchor bolt.

The filler is not particularly limited as long as it has a compressive strength higher than that of the concrete of the concrete structure, but has a small shrinkage after filling, and adhesiveness with the concrete (integration). In particular, cement-based non-shrink mortar is preferable because it is a nonflammable material.
Specific examples of the cement-based non-shrink mortar include, for example, an inorganic injection material, and more specifically, a ceme force anchor (manufactured by Sumitomo Osaka Cement Co., Ltd.).

Moreover, as said anchor bolt, although a well-known anchor bolt can be used, metal things, such as iron and stainless steel, are preferable, for example.
Furthermore, as a preferable shape of the anchor bolt, one having a shaft 3a as shown in FIG. 1 and a tip portion 3b having a larger diameter than the shaft 3a is preferable.
As shown in FIG. 1, the anchor bolt having such a shape is disposed on the bottom side of the hole 2 so that the strength in the pulling direction Y (tensile strength) after the anchor bolt 2 is constructed. Can be further improved.

The anchor bolt construction method of the present embodiment is particularly optimal when reinforcing an existing concrete structure.
When the existing concrete structure has low strength, for example, in the case of low-strength concrete having a compressive strength of 30 N / mm ² or less, anchor bolts may be installed for the purpose of improving earthquake resistance.
Even when anchor bolts are installed on such low-strength concrete, by setting the design strength of the concrete and the optimum hole opening area according to the anchor bolt to be used in advance, more anchor bolts can be installed than necessary. Since it does not need to be used, the existing concrete structure can be reinforced at low cost.

  Hereinafter, the present invention will be described in more detail with reference to examples.

(Shear strength test)
A hardened concrete body having a size of 1800 mm × 900 mm × 200 mm using ordinary concrete was prepared as a test body.
As the reinforcing bar, an L-shaped member having a thickness of 6 mm and a width of 65 mm was prepared and embedded at a depth of 80 mm and 120 mm from the surface of each of the hardened concrete bodies.

Compressive strength of ordinary concrete of the test specimen is 14N / mm ² and 30 N / mm ² in design strength.
D16 SD345 (manufactured by JFE Steel) was prepared as an anchor bolt.
The anchor bolt has a nominal cross-sectional area of 1.986 cm ² and a yield strength of 345 N / mm ² .

The Qa1 of the test body obtained from the above values was 32.0.
From the above-mentioned values, the opening diameters 20 mm and 52 mm were set as scA: opening area (mm ² ) of the holes to be Qa2 and Qa3 described in Table 1.
Holes having such an opening area were formed in the surface of each test body.
The depths of the holes were 80 mm and 120 mm, which are the depths at which the steel frame was exposed.
After forming the hole, the hole was cleaned with a wire brush, and the anchor bolt was welded to the steel frame with a stud welding machine (device name: NSW25T, manufactured by Nippon Stud Welding).
Thereafter, a filler (inorganic cartridge cement material, trade name: ceme force anchor, manufactured by Sumitomo Osaka Cement Co., Ltd.) was filled into the holes.
The test specimens 1 and 2 were subjected to a shear test in accordance with the 3 post-construction anchor site confirmation test method (draft) with the design and construction guidelines of the Japan Architecture Post-Construction Anchor Association.
Table 1 shows the results (average value of three specimens).

From Table 1, the shear strength in the case of Qa1 <Qa2 is all good, and the anchor bolt broke in the final fracture type.
Furthermore, particularly good results were obtained for test bodies 2 to 4 in which both Qa2 and Qa3 were larger than Qa1. For example, in the test body 5 where Qa1 <Qa2 and Qa1 = Qa3 and the test body 2 having the same drilling diameter and drilling depth, the shear strength was particularly good.

1: Concrete structure,
2: hole,
3: Anchor bolt,
4: Filler.

Claims (4)

A cylindrical hole is formed in the surface of the concrete structure in which the steel frame is embedded, and the steel frame is exposed on the bottom surface. An anchor bolt is inserted into the hole, and the steel frame and the anchor bolt exposed on the bottom surface are connected. In the anchor bolt construction method of fixing the anchor bolt by welding, filling a filler between the inner peripheral surface of the hole and the anchor bolt, and constructing the anchor bolt on the concrete structure,
In advance, the allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt and the bearing strength cσqa of the concrete of the concrete structure are obtained,
The allowable shear strength Qa2 per anchor bolt determined by the concrete bearing strength determined from the concrete bearing strength cσqa and the opening area of the hole is per anchor bolt determined by the anchor bolt shear strength. The opening area of the hole is set to be larger than the allowable shear strength Qa1,
The hole is formed so that it may become the set opening area, The anchor bolt construction method characterized by the above-mentioned. Obtain the tensile strength against the cone-like fracture of the concrete, and measure the depth from the concrete surface to the steel frame, the tensile strength against the cone-like fracture of the concrete, the depth to the steel frame and the opening diameter of the hole The allowable shear strength Qa3 per anchor bolt determined by the cone-shaped fracture of the concrete and the allowable shear strength Qa2 per anchor bolt determined by the bearing pressure strength of the concrete,
The anchor bolt construction method according to claim 1, wherein an opening area of the hole is set so as to be larger than an allowable shear strength Qa1 per anchor bolt determined by the shear strength of the anchor bolt.   The anchor bolt construction method according to claim 1, wherein the filler is cement-based non-shrink mortar.   The anchor bolt includes a shaft and a tip portion having a diameter larger than that of the shaft, and the tip portion is disposed on a bottom side of the hole and the anchor bolt is inserted into the hole. The anchor bolt construction method according to claim 1.

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