JP3078732B2 - Fixing method of base plate and anchor bolt of steel column base - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a method of fixing a base plate and an anchor bolt of a column base having a steel structure.

[0002]

2. Description of the Related Art Conventionally, anchor bolts are tightened only from the upper surface of a base plate in order to act only on tensile force. In this case, a washer is used so that the bolt screw portion does not contact the base plate hole. Use a double nut to prevent the nut from loosening. The gap between the lower surface of the base plate and the foundation is filled with mortar or the like, and the shear force is expected to be the frictional force of the contact surface between the lower surface of the base plate and the mortar. In contrast to this method, for example, a method using a receiving nut as a level positioning of a base plate as described in the Architectural Institute of Japan Steel Construction Technical Guidelines.

[0003] A method of filling grout around a bolt hole using a special washer.

[0004] There was.

[0005]

However, these methods of fixing the base plate and the anchor bolt have the following problems.

A receiving nut method.

(1) If the position of each bolt hole is not the same on the lower surface of the base plate, it is difficult to secure the vertical position accuracy of the column, and it is difficult for the receiving nut to achieve the purpose of level positioning.

(2) When the bolt thread receives shearing force and the thread contacts the side surface of the sliding bolt hole, the shear strength of the bolt is reduced.

(3) If there is a receiving nut, the theoretical basis for evaluating the degree of fixation (ie, the rotation angle of the column base with respect to the bending moment) is weak.

(4) A double nut is required to prevent loosening.

[0011] Grout method.

(1) At the stress level of the axial force and bending moment of the column, the center of rotation of the column pedestal tends to change as the concentricity of the compression reaction force moves. That is, the degree of fixation (the rotation angle of the column base with respect to the bending moment) is not stable at the stress level.

(2) A special washer for grout injection is required.

(3) The compression-side anchor bolt is idle when it is bent.

Therefore, the conventional column base has the following problems.

(1) The compression-side anchor bolt does not bear stress, and acts only on tensile force.

(2) With respect to the shearing force, the friction on the bottom surface of the base is cut, and the bolt shaft portion bears after the displacement, and slip deformation is inevitable.

(3) When the column pedestal is greatly bent and the anchor bolt is stretched, a gap is formed between the base and the base surface even with a double nut, and the energy absorbing power is reduced. Since the anchor bolt works only for tensile force, it has no energy absorbing ability for compressive force.

(4) The level adjustment of the column pedestal uses the mortar of the foundation surface, and the accuracy is largely dependent on the skill of the plasterer on the site.

An object of the present invention is to solve these problems.

[0021]

[ MEANS FOR SOLVING THE PROBLEMS] Base play of steel column base
When connecting the anchor bolt
Tighten the nut screwed into the anchor bolt
The nut mounting part on the upper surface of the base plate in advance.
Provide a depression larger than the outer diameter of the
That develops strength around anchor bolts and bolt holes
While filling with a solidifying agent,
Around the bolt hole on the bottom surface, at least from the nut outer diameter
Only the perimeter of the large bolt is finished flush
Base plate and anchor bolt for steel column base
The gist is that the method is fixed.

[0022]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below.
It will be described step by step.

With respect to a base plate made of a casting or die forging or a steel plate, (1) An arbitrary recess is formed in a bolt pedestal for an adhesive pool.

(2) Finish so that only the receiving nut portion on the lower surface of the base plate is coplanar.

(3) Other parts may be rough.

(4) It is unnecessary to prefill the depression with the adhesive, but when the adhesive is post-filled, chamfering is performed to facilitate the inflow of the adhesive.

FIG. 1A is a view showing the fixing of the base plate and the anchor bolt.

1 is an anchor bolt, 2 is a base plate, 3 is a lower nut, 4 is an upper nut, 5 is an adhesive, 6 is a lower groove of the upper nut, 7 is a recess formed in the upper nut base, and 8 is a lower nut. The surface 9 finished to the same plane at each of the contacting bolt positions indicates a chamfer for improving the flow of the adhesive. (B)
Is a top view showing an example of an upper nut, and (c) is a side view.

For anchor bolts, (1) For round steel, deformed round steel, and foundation concrete, any of a bond type and an unbond type may be used.

(2) With a hook at the tip of the anchor bolt,
Use a fixing plate or U-shaped anchor bolt.

(3) The length of the upper screw has an extra length so that the receiving nut can be installed.

(4) The bolt material has a yield ratio of 0.8 (= yield strength / tensile strength) or less for the purpose of preventing early fracture of the thread groove. This value is equal to or less than the thread groove sectional area / shaft sectional area.

With respect to the nut, (1) The receiving nut can use a normal JIS standard product.

(2) When the bolt hole is large, a flanged nut 10 as shown in FIG. 2 or a washer 11 as shown in FIG. 3 is used.

(3) As the upper nut, a special nut for adhesive inflow is used.

FIGS. 4, 5 and 6 show examples of these special nuts. A plurality of grooves may be provided. The grooves also have a locking effect.

(4) When the bolt hole is large, a special nut having the above-mentioned groove in the flanged nut is used. (Japanese Patent Application No. 7-3668
(Refer to 4) For the bolt hole, (1) Bolt shaft diameter + 5mm or more, the larger one is better for filling with adhesive.

Next, the construction order will be described step by step.

(1) Install the anchor bolt. (There is no problem with the method).

(2) Pour foundation concrete up to the lower end of the lower nut.

(3) In a set of anchor bolts of one column base, level adjustment of at least two lower nuts is performed.

(4) Install the base plate of the column base.

(5) Tighten the upper nut to stabilize the steel column.

When the upper nut is tightened, the column is self-supported, and safety in operation can be ensured.

When joining the column and the beam, the upper nut of the column base may be loosened to make it easier to attach the beam.

The building is not advanced without all the upper bolts. With the upper nut loosened, an adhesive injection is possible.

(6) For example, an adhesive is injected from the base of the upper nut. (In the case of FIG. 4) For example, an adhesive is injected from the top of the nut and overflows from the depression of the pedestal. (Cases of FIGS. 5 and 6) (7) The method of filling mortar into the gap between the base lower surface and the foundation is not particularly limited.

Next, the reason why the rotational rigidity of the method for fixing the base plate and the anchor bolt of the present invention is increased will be described using theoretical formulas.

(1) Symbol (see FIG. 10) N = Compression force applied to column base M = Bending moment applied to column base T = Tension force of tension side anchor bolt group α · d = From tension side anchor bolt to rotation center = Β · d = distance from tension anchor bolt to resultant force of compression reaction force C = resultant force of compression reaction force K = rotational rigidity = M / R R = rotation angle = ΔL / α · d ΔL = elongation of anchor bolt (2) Rotational rigidity is an index indicating the rotation angle of the base plate when a bending moment is applied to the column base. Practical general expressions for evaluating rotational stiffness have been derived and used in the following manner.

From FIG. 10,

[0051]

(Equation 1)

[0052]

(Equation 2)

[0053] Here the base plate and rigid, E ₀ = value of Jikudan area thus rotational stiffness K of the number A _b = anchor bolt length n = tension side anchor bolt of the equivalent Young's modulus L = anchor bolt of the anchor bolt ,

[0054]

(Equation 3)

[0055] The center of rotation in the prior above equation a pillar center, the resultant force of the compression side reaction force above α · d = d _t equation is just below the compression-side flange of the _{column, β · d = d t +} d c anchor bolt The normal position of is that d _c ≒ 0.7 _dt The equivalent Young's modulus of the anchor bolt is equivalent to E ₀ ≒ 0.85E, where E is the Young's modulus of the steel material due to the effect of the threaded portion.

By substituting these into equation (3) and rearranging, the following practical evaluation equation is obtained.

[0057]

(Equation 4)

(3) When the method of fixing the anchor bolt and the base plate according to the present invention is used, the bending moment M
Is added and tensile force acts on one of the anchor bolts,
When the base plate is rigid, the center of rotation is the position of the compression-side anchor bolt. The center of the compression force is use because the position of the compression side anchor bolt compressive force is concentrated, α · d = β · d = d t + d t = 2d t thus joining method of the anchor bolt bets base plate of the present invention The obtained rotational rigidity K _F is shown as follows.

[0059]

(Equation 5)

(4) In order to compare the effects, equations (5) and (4)
The formula ratio is

[0061]

(Equation 6)

In the equation (4), if d _t + d _c ≒ d _t +0.7 d _t = 1.7 d _t ,

[0063]

(Equation 7)

Since (1 + 0.4 N / T) <(1 + 0.5 N / T), K _F > K is always satisfied, and the column pedestal using the present invention has a higher rotational rigidity than the conventional column pedestal. Was proved to be about 2-3 times larger.

(5) By the way, when the axial force N = 0 of the column where the rotational rigidity becomes the smallest is estimated, an example when the column is 300 mm (see FIG. 10)

[0066]

(Equation 8)

An example in which the height of the pillar is 600 mm (see FIG. 11)

[0068]

(Equation 9)

In comparison with the above, the rigidity when the present invention is used is 2-3 times or more the effect of the conventional method, and has an effect of increasing the fixing degree of the column base.

[0070]

The effects of the present invention are as follows.

In the conventional column-base construction method, the anchor bolt does not bear the compressive force, and the shearing force depends on the frictional force of the bottom surface of the base. However, in the present invention, all the anchor bolts are subjected to the bending applied to the column base. The moment M, the axial force N, and the shear force Q can be borne, and the mechanical rationality of the column base and the rationalization of construction have been promoted.

Therefore, the object can be achieved by using a combination of a solidifying agent, such as an adhesive, which develops strength in the anchor bolt and the base plate. The effects will be described below in comparison with the problems to be solved.

(1) Since the adhesive is filled around the bolt screw portion and the base bolt hole and solidified integrally, a shearing force can be transmitted to the bolt.

(2) Conventionally, it was necessary to prevent the nut from being loosened. However, since the base plate pedestal is provided with a recess and chamfered around the hole, if the adhesive is solidified, the upper nut is removed from the groove. by the filler was solidified to the inside groove of the nut Tsu <br/> restraining the rotation, the loosening. The effect is ensured by the adhesive filled in the groove of the upper nut.

(3) The injection of the adhesive does not require a special washer or the like because a recess provided in a base (a pedestal in the case of casting or die forging) or a groove with a nut is used.

(4) Since the periphery of the bolt hole on the lower surface of the base plate is finished in the same plane, it is easy to maintain the installation accuracy, and the other parts may be rough surfaces, so that the cost of the base plate itself can be reduced.

(5) If the lower nut is tightened with the upper nut in order to maintain the installation level of the column base, the column can be kept stable and safe in operation.

(6) The lower nut is convex with respect to the foundation concrete, has a shear cotter, and resists shearing force.

(7) Since the lower nut and the upper nut are tightened with the base plate sandwiched therebetween, when the alternating bending moment of the column acts during an earthquake, the conventional method only absorbs energy due to the extension of the anchor bolt. Since this also absorbs energy, it is possible to increase the energy absorption capacity of the column base and increase the earthquake resistance of the entire steel frame.

(8) The rotational rigidity (fixing degree) of the column base with respect to the bending moment can be made larger than before. This means that the point of inflection rises, which has the effect of reducing the bending moment generated in the upper-floor beams during an earthquake, reducing the stress load on the beams on the immediately higher floors, increasing the seismic resistance and the framework. This is effective in increasing the overall horizontal rigidity. That is, the horizontal displacement is reduced. FIG. 7 is a bending moment diagram of the steel frame structure due to the seismic force or wind force when the column base fixing degree is small, and FIG. 8 is a bending moment diagram due to the seismic force or wind force of the steel frame structure when the column base fixing degree is large.

[Brief description of the drawings]

FIG. 1 is a view showing fixing of a base plate and an anchor bolt.

FIG. 2 is a view of a flanged nut.

FIG. 3 is a view using a washer.

FIG. 4 is a view of an example of a special nut having a groove penetrating a bottom surface.

FIG. 5 is a view of an example of a special nut having a vertically penetrating groove.

FIG. 6 is a view showing a nut having a groove penetrating the bottom surface and a groove penetrating vertically as an example of a special nut.

FIG. 7 is a diagram illustrating a bending moment of a steel frame structure due to seismic force or wind force when a column base fixing degree is small.

FIG. 8 is a bending moment diagram of a steel frame structure due to seismic force or wind force when the degree of fixing of a column base is large.

FIG. 9 is a diagram showing symbols.

FIG. 10 is a diagram for obtaining rotational rigidity when the length of a column is 300 mm.

FIG. 11 is a diagram for obtaining rotational rigidity when the length of a column is 600 mm.

[Explanation of symbols]

1. Anchor bolt, 2. Base plate, 3.
Lower nut, 4 ··· Upper nut, 5 ··· Adhesive, 6 ··· Bottom groove of upper nut, 6a ··· Vertical groove, 7 ··· Dent on upper nut pedestal, 8 ··· Each of which bottom nut contacts Surfaces finished identically at bolt positions, 9 chamfers to improve the flow of adhesive, 10 nuts with collars, 11 washers

────────────────────────────────────────────────── ─── Continuation of the front page Examiner Toshihiko Kuribayashi (56) References JP-A-5-25382 (JP, A) JP-A-7-102639 (JP, A) JP-A 8-232939 (JP, A) Japanese Utility Model Application No. 52-90904 (JP, U) Japanese Utility Model Application No. 7-10104 (JP, U) Japanese Utility Model Application No. 63-5916 (JP, U) Japanese Utility Model Application No. 5-38412 (JP, U) Japanese Utility Model Application No. Hei 7-14685 JP, U) JP 5545310 (JP, Y2) JP 54-31272 (JP, Y2) JP 49-13814 (JP, B1) (58) Fields surveyed (Int. Cl. ⁷ , (DB name) E04B 1/24 F16B 39/02 F16B 35/04

Claims (1)

(57) [Claims] 1. A per the bonding of the base plate and anchor bolts of steel column base, the anchor across the base plate
-Tighten the nut to be screwed to the bolt , previously provide a recess larger than the nut outer diameter in the nut mounting part on the upper surface of the base plate, and fill the recess, the nut, the anchor bolt and the periphery of the bolt hole with a filling solidifying agent that expresses strength Around the bolt holes on each lower surface of the base plate.
Around the bolt at least larger than the nut outer diameter
Steel columns characterized in that only one is finished in the same plane
How to fix the leg base plate and anchor bolts.