JP2012233395A - Support device of bearing angle for architectural stone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a support device of a bearing angle for an architectural stone that can maximize the insulating effect of an insulator by minimizing damage to the insulator when the bearing angle is attached to a wall body.SOLUTION: A support device of a bearing angle for an architectural stone includes a supporter having a screw hole formed at the center thereof and being movable along a spiral thread of an anchor bolt fixed to a wall body, and a cutting blade part being formed on one side of the supporter and penetrating into an insulator by a rotational force generated by movement of the screw hole so as to be supported in contact with the wall body.

Description

  The present invention relates to a support device for a building stone support angle, and more specifically, a screw hole is formed in the center of a support body, and the support body moves along a thread of an anchor bolt fixed to a wall body. The cutting edge portion is formed on the support body, and the cutting edge portion is inserted through the heat insulating material by the rotational force generated by the movement of the screw hole, and is supported in contact with the wall body. In addition, the insulation blade is inserted in a circular shape by the cutting edge of the support and is supported in contact with the wall, so that the support angle to be joined thereafter is fixed in a stable state without bending or tilting. Since the heat insulating material cut by the cutting edge of the support body is located inside the support body without falling to the outside, the support angle wall body can be obtained. Minimize insulation damage when adhering to It relates to a support device for building stone support angles the insulating effect of the thermal material can be utilized to the maximum.

1 and 2 show conventional support angles.
In the conventional support angle, in order to fix the stone material 8 such as marble on the surface of the wall 7 of the building, the vertical plate 1 is brought into contact with the surface of the heat insulating material 6 attached to the wall 7 and then the wall. The vertical elongated hole 2 is inserted into the anchor bolt 5 fixed to 7 and fixed by the nut 4, and the stone plate 8 is mounted on the horizontal plate 3.

  In the prior art as described above, after the heat insulating material 6 is attached to the surface of the wall body 7, the vertical long hole 2 having a support angle is inserted into the anchor bolt 5 exposed on the surface of the heat insulating material 6, so that the vertical plate 1 is attached. A nut 4 is fastened to the anchor bolt 5 that is brought into contact with the heat insulating material 6 and inserted into the vertical long hole 2 to fix the support angle.

  However, in the middle of fastening the nut 4 to the anchor bolt 5, the support angle is not fixed firmly by the elasticity of the heat insulating material 6 but is fixed in a bent or inclined state.

Therefore, when the support angle is fixed in a bent or inclined state, there is a problem that when the stone material 8 as a subsequent process is fixed to the horizontal plate 3, it cannot be fixed in an orderly manner.
Further, since the support angle does not maintain a firm fixed state, there is a dangerous problem that the stone material adheres in an unstable state or the stone material 8 is detached.

  In order to solve the above-described problems, recently, in order to directly contact the support angle with the wall body 7, a portion of the heat insulating material 6 with which the support angle contacts is cut into a square to form a through hole. There is also a work site that uses a method in which the vertical plate 1 having a support angle is inserted into the through-hole and directly brought into contact with the wall 7 to be fixed.

  However, tens to hundreds of support angles adhere to one building, and in order to attach tens to hundreds of support angles, dozens to hundreds of through holes are cut. Because it had to be done, it was a very inefficient work.

  In particular, as described above, cutting several tens to several hundreds of through-holes reduces the heat insulation effect, and thus there is a problem that it is troublesome and inconvenient to take separate heat insulation measures. It was.

  In order to solve such a conventional problem, the present invention is inserted while cutting the heat insulating material into a circular shape by the cutting edge portion of the support and is supported in contact with the wall, so that it will be combined in the future. The support angle can be fixed in a stable state without any bending or tilting phenomenon, so that a firm support force can be obtained, and the insulation that is cut by the cutting edge of the support can be dropped to the outside. Therefore, when the support angle is attached to the wall body, the damage of the heat insulating material is minimized so that the heat insulating effect of the heat insulating material can be utilized to the maximum.

  In order to achieve the above object, the present invention forms a screw hole in the center of the support so that the support can move along the thread of the anchor bolt fixed to the wall. The blade portion is formed, and the cutting blade portion is inserted through the heat insulating material by the rotational force generated by the movement of the screw hole, and is supported in contact with the wall body.

  According to the present invention, since the heat insulating material is inserted in a circular shape by the cutting edge portion of the support and is supported in contact with the wall, the support angle to be combined in the future can be obtained without bending or tilting. Since it can be fixed in a stable state, a firm support force can be obtained.

  In the present invention, since the heat insulating material cut by the cutting edge portion of the support body is located inside the support body without falling outside, damage to the heat insulating material is minimized when the support angle is attached to the wall body. The heat insulating effect of the heat insulating material can be utilized to the maximum.

FIG. 1 is a partial cutaway perspective view showing the structure of a conventional support angle. FIG. 2 is a view for explaining a conventional coupling state of support angles. FIG. 3 is a perspective view showing the structure of the support device for the building stone support angle of the present invention. FIG. 4 is a diagram for explaining a process of joining the support device for the building stone support angle of the present invention. FIG. 5 is a view for explaining a process of connecting the support device for the building stone support angle of the present invention. FIG. 6 is a view for explaining the position adjusting action of the support angle supported by the building stone support angle support device of the present invention. FIG. 7 is a view showing a state in which a stone is mounted on a support angle supported by the building stone support angle support device of the present invention.

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

The building stone support angle support device of the present invention firmly fixes the support angle 11 supporting the stone material 16 to the wall 14 of the building, and also attaches the support angle 11 to the wall 14 when the heat insulating material 15 is attached. In order to minimize the damage and enhance the heat insulation effect, a support body 101 having a screw hole 104 formed in the center so as to move along the thread of the anchor bolt 12 fixed to the wall body 14; And a cutting edge portion 102 formed on the support body 101 so as to be inserted through the heat insulating material 15 by the rotational force generated by the rotation and to be supported in contact with the wall body 14.

  In addition, a flange 105 formed on the outer peripheral surface of the support 101 is further provided in order to prevent a heat insulation effect from being lowered due to air flowing between the cutting edge portion 102 and the heat insulating material 15.

Further, a recess 103 into which the tool 17 is inserted is further provided on the outer peripheral surface portion of the screw hole 104 of the support 101 so that the support 101 is screwed into the anchor bolt 12 using the tool 17.
The operation of the present invention will be described as follows.

FIG. 3 is a partially cut perspective view showing the configuration of the support device for the building stone support angle of the present invention. First, the support body 101 of the present invention is screwed into the anchor bolt 12 exposed on the surface of the heat insulating material 15 attached to the wall body 14.
Then, when the vertical elongated hole formed in the vertical plate of the support angle 11 is coupled to the anchor bolt 12 and the nut 13 is fastened, the coupling is completed.

  That is, FIG.4 and FIG.5 is a figure for demonstrating the joining process of the support apparatus of the stone support angle for construction of this invention. The screw hole 104 formed in the center of the support body 101 of the present invention is screwed into the anchor bolt 12 exposed on the heat insulating material 15 of the wall body 14.

At this time, if the screw hole 104 is screwed into the anchor bolt 12, the support body 101 moves and rotates along the thread, and the cutting edge portion 102 formed on the support body 101 makes the heat insulating material 15 circular. Cut.
The cutting edge portion 102 penetrates the heat insulating material 15 by repeated rotation and comes into contact with the wall body 14, and the support body 101 stops without further rotation by the wall body 7.
As described above, the support 101 of the present invention fills the internal space without dropping the cut heat insulating material 15 to the outside.
Since the inside of the support body 101 is filled with the heat insulating material 6 cut as described above, the heat insulating effect is not lowered.

Further, the support body 101 can be coupled to the anchor bolt 12 by being manually rotated by an operator, but it is impossible because the number is very large.
Thereby, this invention forms the recessed part 103 in the outer peripheral surface part of the screw hole 104 of the support body 101 so that the electric tool 17 etc. may be inserted.
That is, the assembly work of the support body 101 can be performed more quickly by inserting the electric tool 17 or the like into the recess 103 and automatically rotating it.

As described above, when the assembly operation of the support body 101 is completed, the existing support angle 11 is coupled to the anchor bolt 12 exposed in the screw hole 104 of the support body 101 that is firmly supported. A vertical slot formed in the vertical plate may be inserted into the anchor bolt 12 and the nut 13 may be fastened and fixed.
At this time, as shown in FIG. 6, the support angle 11 can be fixed after adjusting its position by easily moving up and down within the vertical slot.
Then, after the support angle 11 is firmly fixed to the support 101, a stone 16 may be mounted on the support angle 11 and fixed as shown in FIG.

  On the other hand, in the flange 105 formed on the outer peripheral surface of the support 101 of the present invention, air flows into a gap generated between the cutting edge portion 102 and the boundary surface of the heat insulating material 15 by the cutting operation of the cutting edge portion 102. Prevents the heat insulation effect from being lowered.

101 Support 103 Recess 105 Flange 102 Cutting Edge 104 Screw Hole

Claims (3)

The support angle (11) that supports the stone (16) is firmly fixed to the building wall (14), and the heat insulation (15) is damaged when the support angle (11) is attached to the wall (14). The support body (101) which forms a screw hole (104) in the center so as to move along the thread of the anchor bolt (12) fixed to the wall body (14) in order to minimize the heat insulation effect. When,
The support (101) is formed so as to be inserted through the heat insulating material (15) and supported in contact with the wall (14) by the rotational force generated by the rotation of the support (101). A building stone support angle support device, comprising: a cutting edge portion (102).   A flange (105) formed on the outer peripheral surface of the support (101) in order to prevent the heat insulation effect from deteriorating due to air flowing between the cutting edge (102) and the heat insulating material (15). The building stone support angle support device according to claim 1, further comprising:   The tool (17) is inserted into the outer peripheral surface of the screw hole (104) of the support (101) so that the support (101) is screwed into the anchor bolt (12) using the tool (17). The building stone support angle support device according to claim 1, further comprising a recess (103).