KR102234029B1 - Earthquake resistant circular angle system - Google Patents

Abstract

The present invention relates to an earthquake-resistant circular angle system comprising: a circular cylinder (110) constructed on an insulating material (20) attached to the wall (10) of a building in a rotational manner, formed in a cylindrical shape, having one open side and the other side coupled to a cover (111) and having a closed shape, and having an anchor hole (113) formed in the center of the cover (111); an anchor bolt (120) inserted and fixed to the wall (10) of the building through the anchor hole (113) of the circular cylinder (110) and the insulating material (20), and having a remaining portion protruding from the cover of the circular cylinder (110); an anchor cap (130) coupled to the anchor bolt (120) and disposed in the wall (10) of the building; and a fixing nut (140) fastened to an end of the anchor bolt (120) protruding from the cover (111) to fix the circular cylinder (110) to the insulating material (20). The present invention can safely install an exterior material while minimizing damage to the insulating material, and increase earthquake resistance by securing tensile force and support force by the anchor bolt.

Description

Earthquake resistant circular angle system

The present invention relates to a seismic type circular angle system, and more particularly, to a seismic type circular angle system for constructing an exterior material on a wall of a building.

Since the walls of the building are made of concrete, exterior materials are installed on the walls to make the exterior beautiful and maintain the exterior for a long time. As the exterior material, stone materials such as granite, mungyeongseok, marble, limestone, sandstone, or panels are used.

There are two types of exterior material construction, dry and wet, and currently, the dry method is mainly used to construct exterior materials using angles that do not use cement, sand, water, etc. and are not easily corroded. The dry method has the advantage of preserving the color of the exterior material, preventing earthquakes and impacts, and being easy to repair.

In addition, the exterior material forms a certain space between the wall of the building and the wall of the building is protected by rainfall and external moisture.

However, in the conventional construction of exterior materials, a wall fixing cap with an anchor hole is welded to a support frame having an L-shaped cross-sectional structure, and a fixing anchor is fastened to the anchor hole of the wall fixing cap and fixed to the wall of the building. There is a problem that the support frame may sag and deform as time passes, and the load bearing capacity for the exterior material is further weakened due to the welded joint structure. In addition, the welded structure has a fire risk and a complicated process.

In addition, when the insulation is placed on the wall of the building, the fixed anchor protrudes from the wall of the building more than the thickness of the insulation, and the load applied to the fixed anchor is further increased. Deformation easily occurs, and in severe cases, there is a problem in that the fixed anchor is removed from the wall.

In addition, in the case of arranging the insulating material on the wall of the building, there is a disadvantage in quality, performance, and maintenance because the insulating material is dug out, a fixed anchor is installed in the damaged state, and the insulating material is attached in pieces.

In addition, the conventional exterior material construction has a problem that can be constructed only when the insulating material is thin or the finishing distance between the wall and the exterior material is short due to the weak pulling force and sag of the fixed anchor.

Registered Patent Publication No. 1535770 (registered on Jul. 3, 2015)

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to provide a seismic type circular angle system in which anchor bolts are installed so that they do not fall out of the wall of a building.

Another object of the present invention is to apply a circular cylinder to minimize damage to the insulating material installed on the wall of a building, and the circular cylinder has a structure to prevent sagging of the anchor bolts, thereby improving the fixing power of the anchor bolts. Is to provide.

Another object of the present invention is to provide a seismic type circular angle system that has high convenience in construction of the exterior material, and enables the exterior material to be safely constructed, and allows the exterior material to be constructed even after finishing a certain distance or more.

Another object of the present invention is to provide a seismic type circular angle system having a structure capable of improving seismic resistance by securing a tensile force and a supporting force.

The seismic type circular angle system according to the embodiment of the present invention for solving the above problems is constructed in a rotational manner on an insulating material attached to the wall of a building, is formed in a cylindrical shape, one side is opened and the other side is coupled with a cover. An anchor bolt that is a closed shape and has an anchor hole formed in the center of the cover, and an anchor bolt inserted and fixed to the wall of the building through the anchor hole and the insulating material of the circular cylinder, and the remaining portion protrudes from the cover of the circular cylinder, and the An anchor cap coupled to the anchor bolt and disposed in the wall of the building, and a fixing nut fastened to an end of the anchor bolt protruding from the cover to fix the circular cylinder to the insulating material.

An L-shaped angle comprising one side portion in contact with the cover of the circular cylinder and the other side portion orthogonal to the one side portion, wherein a communication long hole communicating with the anchor hole is formed on the one side portion, and the anchor hole and the L shape of the circular cylinder Anchor nut that is fastened to the end of the anchor bolt that has passed through the communication hole of the angle so that the anchor bolt and the anchor cap are tightened together, and an anchor nut formed in a plate shape and seated on the other side of the L-shaped angle, and the L-shaped angle Fastening to the end of the proximal bolt through the length adjustment plate having the fastening hole formed on the other side of the plate and communicating with the fastening hole formed on the other side of the length adjustment plate, and the fitting hole formed at the tip, and the fastening length hole of the L-shaped angle and the fixing length hole of the length adjusting plate. And a fixed pin that is inserted into the fitting hole and partially protrudes to an upper portion of the length adjustment plate and partially protrudes to a lower portion of the length adjustment plate.

The cover of the circular cylinder forms a concave surface in which a certain area centered on the anchor hole is concave compared to an edge, and the fixing nut is in close contact with the concave surface, and one side of the L-shaped angle is in close contact with the edge. In addition, one side of the circular cylinder includes a plurality of uneven portions formed along the outer diameter at the end thereof, and construction is possible while reducing frictional force when rotated on the insulating material, and the recessed portions of the uneven portion extend obliquely outward than the outer diameter of the circular cylinder. Is formed.

The circular cylinder penetrates the insulating material by rotational force and contacts the wall of the building, and is fixed to the insulating material after installation of the anchor bolt.

The cover of the circular cylinder has a support force that does not bend against a load by forming a curved portion connecting the concave surface and the edge.

The circular cylinder, the anchor bolt, the L-shaped angle and the length adjustment plate are made of stainless steel.

The support plate is fixed to be spaced apart from the bottom of the length adjusting plate via a plurality of vibration absorbing rods, the support plate has a shape in which a through hole communicating with the fixing hole of the length adjusting plate is formed, and the vibration absorbing rod is made of glass fiber reinforced plastic and aluminum metal. It is a composite material formed by mixing.

A vibration absorbing member is interposed between the support plate and the length adjustment plate, and the vibration absorbing member has a shape in which a through hole communicating with a through hole of the support plate and a fastening hole of the L-shaped angle is formed, and the vibration absorbing member is rubber It is a 2mm-5mm thin plate made of a material.

The L-shaped angle is further formed with a bending portion bent downward at an end in contact with the support plate, and the proximal bolt is provided with a friction member for preventing reverse rotation in the screw portion to prevent loosening of the proximal bolt with respect to the proximal nut. , The friction member is a nylon patch attached to at least a portion of the screw portion of the proximal bolt in a coating manner so as to be the same as the bending of the screw portion.

In the present invention, since the circular cylinder is installed on the insulation material by rotation, it is possible to easily install the insulation material and has the effect of not damaging the insulation material.

In addition, since the present invention is a structure in which the anchor bolt passes through the anchor hole of the circular cylinder and is fixed to the wall of the building, the circular cylinder prevents sagging of the anchor bolt so that it is possible to finish the exterior material of a certain distance or more.

In addition, in the invention of the ball, since the anchor bolt is firmly fixed to the wall of the building by being fastened to the anchor cap, the tensile force is strong and the support force is very excellent by the circular cylinder.

In addition, the present invention has the effect that the curved cover shape of the circular cylinder reinforces the strength of the circular cylinder, and the uneven portion at one end reduces friction when the circular cylinder rotates, so that the circular cylinder can be more easily installed on the heat insulating material.

In addition, the present invention has the effect of improving the earthquake resistance by securing the tensile force and support force of the anchor bolt structure fastened to the circular cylinder.

In addition, since the present invention uses stainless steel and is highly corrosive, once installed, there is an effect that can be used up to the endurance limit.

In addition, in the present invention, the structure of fixing the L-shaped angle including the support plate and the vibration-absorbing rod and the length adjusting plate, and the structure in which the vibration-absorbing member is disposed between the support plate and the length adjusting plate prevents vibration at the fixed portion of the L-shaped angle and the length adjusting plate. The double structure that can absorb the vibration prevents the vibration transmitted to the slab from being transmitted to the circular cylinder, thereby preventing the vibration from being transmitted to the wall of the building, so it has excellent seismic resistance.

1 is a cross-sectional view showing a state in which an exterior material is constructed on a wall of a building using a seismic-resistant circular angle system according to an embodiment of the present invention.
2 is a perspective view of a seismic type circular angle system according to an embodiment of the present invention.
3 is an exploded perspective view of a seismic type circular angle system according to an embodiment of the present invention.
4 is a view showing a process of installing an exterior material on a wall of a building using a seismic circular angle system according to an embodiment of the present invention.
5 is a view showing a process of constructing an exterior material on a wall of a building using a circular angle system according to an embodiment of the present invention.
6 is a photograph showing a process of constructing an exterior material on a wall of a building using a circular angle system according to an embodiment of the present invention.
7 is a side view of a seismic type circular angle system according to another embodiment of the present invention.

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

1 is a cross-sectional view showing a state in which an exterior material is constructed on a wall of a building using a seismic-resistant circular angle system according to an embodiment of the present invention.

As shown in FIG. 1, the earthquake-resistant circular angle system 100 constructs an insulating material 20 on the wall 10 of a building and an exterior material 30 so that a certain space is formed between the insulating material 20 and the . The insulation material 20 is an external insulation material and is responsible for the insulation of the building, and a certain space between the insulation material 20 and the exterior material 30 protects the building wall 10 and the insulation material 20 from rainfall and external moisture. It extends the life of the wall (10) and the heat insulating material (20).

The separation distance between the insulation material 20 and the exterior material 30 for forming a certain space between the insulation material 20 and the exterior material 30 may be in the range of 20 mm to 60 mm, and the separation distance between the insulation material 20 and the exterior material 30 If is short, condensation may occur.

The wall 10 of the building is made of concrete. The insulating material 20 may be a urethane board, and the exterior material 30 may be a stone, panel, terracotta, or the like. The exterior material 30 constructed separately from the insulation material 20 in the wall 10 of the building forms the exterior wall of the building.

The seismic type circular angle system (hereinafter referred to as'circular angle system') 100 fixes the insulation material 20 to the wall 10 of the building, and installs the exterior material 30 spaced apart from the insulation material 20.

The circular angle system 100 includes a circular cylinder 110, an anchor bolt 120, an anchor cap 130, and a fixing nut 140. In addition, the circular angle system 100 further includes an L-shaped angle 150, an anchor nut 160, a length adjustment plate 170, a near angle bolt 180, a near angle nut 190, and a fixing pin 210.

The circular cylinder 110 is installed on the insulating material 20 to improve the fixing force of the anchor bolt 120.

The circular cylinder 110 is installed in a rotating manner on the insulating material 20 attached to the wall 10 of the building. Since the circular cylinder 110 is installed on the insulating material 20 in a rotating manner, it can be constructed without damaging the insulating material 20. When the insulation material 20 is damaged, a problem may occur in insulation performance and condensation may occur.

The circular cylinder 110 is formed in a cylindrical shape, and one side is opened and the other side is closed by coupling the cover 111. The cover 111 reinforces the sag by reinforcing the strength of the circular cylinder 110. The circular cylinder 110 has an anchor hole 113 formed in the center of the cover 111. An anchor bolt 120 is coupled to the anchor hole 113. The size of the anchor hole 113 corresponds to the diameter of the anchor bolt 1230. This circular cylinder 110 penetrates the heat insulating material 20 by the rotational force, contacts the wall of the building, and is fixed to the heat insulating material 20 after installation of the anchor bolt 120 through the anchor hole 113.

The anchor bolt 120 is fixed to the wall 10 of the building. In the anchor bolt 120, the head portion 121 is inserted and fixed to the wall 10 of the building through the anchor hole 113 and the insulating material 20 of the circular cylinder 110, and the remaining screw portion 122 is a circular cylinder ( It protrudes from the cover 111 of 110).

The anchor cap 130 is coupled to the anchor bolt 120 and is disposed within the wall 10 of the building. The anchor bolt 120 is tightened like the anchor cap 130 and is firmly fixed to the wall 10 of the building.

In order to fix the anchor bolt 120 to the wall 10 of the building, a drill is inserted through the anchor hole 113 and drilled into the wall 10 of the building. Next, when the anchor cap 130 and the anchor bolt 120 are inserted into the hole 11 through the anchor hole 113 and press the anchor bolt 120 with a punch, the anchor bolt 120 becomes the anchor cap 130 ), and is firmly fixed to the wall of the building (10).

The fixing nut 140 is fastened to the end of the anchor bolt 120 protruding from the cover 111 to fix the circular cylinder 110 to the heat insulating material 20. When the fixing nut 140 is fastened to the end of the anchor bolt 120 protruding from the cover 111, the anchor bolt 120 and the circular cylinder 110 are integrally fixed.

The finishing distance (distance separated from the insulation material) is installed differently depending on the thickness of the insulation material for the exterior material installed on the insulation material. For example, when the thickness of the insulation material increases, the finishing distance of the exterior material becomes longer, and as the finishing distance of the exterior material increases, sagging and the like are accelerated, which causes a sharp drop in performance. Therefore, an anchor bolt that passes through the circular cylinder 110 and the circular cylinder 110 and is firmly fixed to the wall 10 of the building in order to have earthquake resistance due to earthquakes, typhoons, impacts, etc. even if the finishing distance of the exterior material is thickened ( 120) Adopt a structure.

Since the circular cylinder 110 is constructed by rotational force, it is possible to construct the insulation material 20 without digging the insulation material 20. In addition, the circular cylinder 110 prevents the anchor bolt 120 from sagging by supporting the anchor bolt 120 with a uniform load.

As another example, a c-shaped angle may be installed on the insulation material 20 instead of the circular cylinder 110, but the c-shaped angle is difficult to install on the insulation material 20, and the more the nut is tightened after the anchor bolt 120 is combined, the higher it rises. As a result, workability is remarkably deteriorated and warpage may occur. In addition, the C-shaped angle is structurally unstable because it has a shape that presses the lower exterior material.

Therefore, in the embodiment, the circular cylinder 110 is installed on the insulating material 20, and the anchor bolt 120 is coupled with the circular cylinder 110 to be fixed to the wall 10 of the building. Since the circular cylinder 110 uses rotational force, it can be easily installed on the insulating material 20, and can be completely fixed to the wall of the building with the fixing nut 140, and the anchor bolt 120 combined with the circular cylinder 110 is Since it is inserted and fixed to the wall 10 of the building using a punch, the tensile force is strong and the supporting force is also very strong.

Since the anchor bolt 120 is fixed to the wall 10 of the building in parallel with the anchor hole 113 by using the central anchor hole 113 of the circular cylinder 110, it can be constructed while maintaining the horizontal. The circular cylinder 110 is installed on the insulating material 20 by rotation of a drill, and the anchor bolt 120 is inserted into the anchor hole 113 of the circular cylinder 110 and fixed to the wall 10 of the building to achieve a parallel level. There are no obstacles to be fitted separately, and the circular cylinder 110 and the anchor bolt 120 are integrated by the fixing nut 140, so that additional construction such as separately fixing the circular cylinder 110 to the wall 10 of the building is required. I don't need it.

The circular cylinder 110 and the anchor bolt 120 may be formed of a stainless material having excellent durability, and may be made strong from corrosion by galvanizing. For example, the circular cylinder 110 may be made of SUS430RE, and the anchor bolt 120 may be made of SUS201.

The L-shaped angle 150 is coupled to the cover 111 of the circular cylinder 110. The L-shaped angle 150 is for fixing the insulating material 20 and the exterior material 30 to be spaced apart. The L-shaped angle 150 is formed in an L-shape including one side portion 151 in contact with the cover 111 of the circular cylinder 110 and the other side portion 152 orthogonal to the one side portion 151. The L-shaped angle 150 has a communication long hole 151a communicating with the anchor hole 113 of the circular cylinder 110 on one side portion 151.

Anchor nut 160 is fastened to the end of the anchor bolt 120 passing through the anchor hole 113 of the circular cylinder 110 and the communication hole 151a of the L-shaped angle 150. When the anchor nut 160 is fastened to the end of the anchor bolt 120 and tightened, the anchor bolt 120 and the anchor cap 130 are tightened together, and the anchor bolt 120 is firmly fixed to the concrete wall 10.

The cover 111 of the circular cylinder 110 forms a concave surface 111a in which a certain area centered on the anchor hole 113 is concave compared to the edge, and the fixing nut 140 is in close contact with the concave surface 111a. do. Then, one side portion 151 of the L-shaped angle 150 is in close contact with the edge of the cover 111.

The principle is that when the anchor nut 160 is fastened to the anchor bolt 120, the anchor bolt 120 is pulled in the direction of the anchor nut 160, and the head 121 of the anchor bolt 120 becomes the anchor cap 130. The anchor bolt 120 may be firmly fixed to the concrete wall 10 because it is inserted into and adheres to the concrete while the anchor cap 130 is opened.

The first washer 165 is coupled to the outer periphery of the anchor bolt 120 corresponding to the L-shaped angle 150 and the anchor nut 160. The first washer 165 prevents loosening of the anchor nut 160 fastened to the anchor bolt 120. The first washer 165 may be a circular flat washer or a spring washer. Among them, the spring washer is more effective in preventing loosening of the anchor nut 160 because it presses the anchor nut 160 with a force perpendicular to the direction in which the anchor nut 160 is rotated.

In addition, the spring washer can vibrate up and down and absorb the vibration of the building to prevent the stone from shaking. Alternatively, the first washer 165 may be more effective in preventing loosening by forming a protrusion on the upper or lower surface.

The length adjustment plate 170 is formed in a plate shape. The length adjustment plate 170 is seated in surface contact with the other side portion 152 of the L-shaped angle 150 and fixed with the other side portion 152 of the L-shaped angle 150 and the proximal bolt 180 and the proximal nut 190 do. The length adjustment plate 170 may adjust a position fixed to the other side of the L-shaped angle 150 to reduce or increase the separation distance between the insulation material 20 and the exterior material 30.

The length adjustment plate 170 is formed with a fixing hole 170a communicating with a fastening hole 152a formed in the other side portion 152 of the L-shaped angle 150.

The proximal bolt 180 penetrates the fastening long hole 152a of the L-shaped angle 150 and the fixed long hole 170a of the length adjusting plate 170, and the proximal nut 190 is the fastening long hole of the L-shaped angle 150 ( 152a) and the length adjustment plate 170 is fastened to the end of the proximal bolt 180 penetrating through the fixing long hole 170a of the length adjustment plate 170 to fix the length adjustment plate 170 to the L-shaped angle 150.

A second washer 195 is coupled to the outer periphery of the proximal bolt 180 corresponding between the length adjustment plate 170 and the proximal nut 190. The second washer 195 prevents loosening of the proximal nut 190 fastened to the proximal bolt 180. The second washer 195 may be a circular flat washer or a spring washer. The spring washer is more effective in preventing loosening of the proximal nut 190 because it presses the proximal nut 190 with a force perpendicular to the direction in which the proximal nut 190 is rotated.

The length adjustment plate 170 has a fitting hole (reference numeral 170b in FIG. 2) formed at the tip. The fixing pin 210 is inserted into the fitting hole 170b. A part of the fixing pin 210 inserted into the fitting hole 170b protrudes from the upper portion of the length adjustment plate 170 and the remaining portion of the fixing pin 210 protrudes from the lower portion of the length adjustment plate 170.

Of the fixing pins 210 fitted in the fitting hole 170b, the upper exterior material 30a is fitted to the portion protruding upward of the length adjustment plate 170, and the lower exterior material ( 30b) is fitted.

The upper exterior material 30a and the lower exterior material 30b have pin holes 31 to which the fixing pins 210 are coupled. The pin hole 31 is formed to have a relatively margin compared to the width and length of the fixing pin 210 protruding from the upper and lower portions of the length adjustment plate 170 so that the exterior material 30 installed in an earthquake or other shock wave is a certain part. Try to withstand the shock while shaking.

The above-described circular angle system 100 rotates the circular cylinder 110 to the insulating material 20 using an electric drill, and inserts a drill into the anchor hole 113 of the circular cylinder 110 to rotate the wall of the building. A perforated groove 11 is formed in (10), and the head of the anchor cap 130 and the anchor bolt 120 is inserted into the perforated groove 11 and fixed by pressing, and then to the outside through the anchor hole 113. It has a structure to fasten the fixing nut 140 to the screw portion of the protruding anchor bolt 120. In addition, the end of the anchor bolt 120 to which the fixing nut 140 is fastened is through the communication hole 151a of the L-shaped angle 150, and at the end of the anchor bolt 120 passing through the communication hole 151a. It has a structure in which the first washer 165 and the anchor nut 160 are fastened.

2 is a combined perspective view of a seismic type circular angle system according to an embodiment of the present invention, Figure 3 is an exploded perspective view of the seismic type circular angle system according to the embodiment of the present invention.

As shown in FIGS. 2 and 3, the circular cylinder 110 is formed in a cylindrical shape, and one side is opened and the other side is closed by coupling the cover 111. The circular cylinder 110 has an anchor hole 113 formed in the center of the cover 111.

The cover 111 forms a concave surface 111a in which a certain area centered on the anchor hole 113 is concave compared to the edge, and the fixing nut 140 is in close contact with the concave surface 111a. One side portion 151 of the L-shaped angle is in close contact with the edge of the cover 111.

The cover 111 forms a curved portion connecting the concave surface 111a and the edge 111b to have a support force that does not bend against a heavy load.

One side of the circular cylinder 110 includes a plurality of uneven portions 115 formed along an outer diameter at an end thereof. The uneven portion 115 enables construction while reducing friction when the circular cylinder 110 is rotated on the heat insulating material 20. The concave portion of the uneven portion 115 is formed to extend obliquely outward than the outer diameter of the circular cylinder 110. In order to prevent the uneven portions 115 from being bitten when the uneven portions 115 penetrate the heat insulating material 20, the concave portions of the uneven portions 115 are formed to be inclined to the outside of the outer diameter of the circular cylinder 110.

The head portion 121 of the anchor bolt 120 has a shape that gradually increases in diameter toward the end, and the anchor cap 130 has a shape that partially opens in a direction coupled with the head portion of the anchor bolt 120. The head portion 121 of the anchor bolt 120 is inserted into the anchor cap 130 to expand the inner diameter of the anchor cap 130. For example, the anchor cap 130 has a shape in which a gentle slope of the head portion 121 of the anchor bolt 120 can expand its inner diameter by a force inserted into the anchor cap 130.

In the anchor bolt 120, a thread is formed in a portion opposite to the head portion 121.

In addition, the circular angle system 100 is the upper surface of the other side surface portion 152 of the L-shaped angle 150 so that the fastening hole 152a of the L-shaped angle 150 and the fixing hole 170a of the length adjusting plate 170 communicate with each other. In the length adjustment plate 170 is disposed, the end of the proximal bolt 180 passes through the fastening hole (152a) of the L-shaped angle 150 and the fixed length hole (170a) of the length adjustment plate (170). The second washer 195 and the proximal nut 190 are fastened to the ends of the proximal bolt 180 passing through the fastening long hole 152a and the fixed long hole 170a.

The communication long hole 151a is formed to be long vertically, and the fastening long hole 152a and the fixed long hole 170a are formed to be long to be disposed in the same direction.

When the communication hole (151a) is formed vertically long, it is possible to move and fix the L-shaped angle 150 to the cover 111 of the circular cylinder 110 by the length of the communication hole (151a), so the exterior material 30 It is easy to precisely match the spacing between the exterior materials 30 during the construction of. When connecting the upper exterior material 30a and the lower exterior material 30b with a fixing pin 210 to be described later, the position of the fixing pin 210 and a pin hole formed by perforating the upper exterior material 30a and the lower exterior material 30b When the position of (31) is correct, the upper exterior material 30a and the lower exterior material 30b can be connected without a step difference. In this process, while finely adjusting the relative fixing position of the L-shaped angle 150 with respect to the circular cylinder 110, the spacing between the exterior materials 30 may be precisely aligned.

In addition, the fastening hole (152a) and the fixing hole (170a) are arranged in the same direction to adjust the position of the length adjustment plate 170 and the other side portion 152 of the L-shaped angle 150 and mutually fixed through this The separation distance between (20) and the exterior material (30) can be adjusted. The fastening hole (152a) and the fixed length hole (170a) are respectively long on the other side portion 152 of the L-shaped angle 150 and the length adjustment plate 170 in a direction defining the separation distance between the insulation material 20 and the exterior material 30. Is formed. When the fastening long hole 152a and the fixed long hole 170a are formed in a circular shape, the separation distance between the heat insulating material 20 and the exterior material 30 cannot be shortened or largely adjusted.

In addition, the circular angle system 100 has a structure in which a fitting hole 170b is formed at the front end of the length adjustment plate 170 and a fixing pin 210 is coupled to the fitting hole 170b to protrude upward and downward.

The length adjustment plate 170 may have rounded fillet portions 171 formed on both sides of the front end. The fillet portion 171 provides a relatively large area between the upper and lower exterior materials 30a and 30b coupled to the fixing pin 210 to facilitate joint construction and have a beautiful appearance.

The fixing pin 210 is formed in a cylindrical shape. The fixing pin 210 is inserted into the fitting hole 170b in a press-fitting manner so that it does not fall out to the bottom.

Circular cylinder 110 constituting the circular angle system 100, anchor bolt 120, anchor cap 130, fixing nut 140, L-shaped angle 150, anchor nut 160, length adjustment plate 170 ), the proximal bolt 180, the proximal nut 190, and the fixing pin 210 are preferably formed of carbon steel or stainless and galvanized to prevent corrosion.

4 is a perspective view showing a circular cylinder according to an embodiment of the present invention.

As shown in Figure 4, the circular cylinder 110 is formed in a cylindrical shape, one side is open and the other side is a closed shape by coupling the cover 111. The circular cylinder 110 includes a plurality of uneven portions 115 formed along an outer diameter at one end thereof. The circular cylinder 110 can be easily constructed on an insulating material using a rotational force, and can be completely fixed to the wall 10 of the building with a fixing nut 140.

In the circular angle system 100 described above, after passing the insulation material 20 through the circular cylinder 110 without removing the insulation material 20, the anchor bolt 120 is inserted into the anchor hole 113 of the circular cylinder 110. Insert and fix the anchor bolt 120 to the wall of the building. Thereafter, a fixing nut 140, an L-shaped angle, and an anchor nut 160 are fastened to the end of the anchor bolt 120 and constructed.

Hereinafter, a process of fixing the insulating material and installing the exterior material using a circular angle system will be described in detail.

5 is a view showing a process of constructing an exterior material on a wall of a building using a circular angle system according to an embodiment of the present invention.

As shown in (a) of FIG. 5, the circular cylinder 110 is rotated on the heat insulating material 20 using an electric drill (D).

Next, as shown in (b) of FIG. 5, by inserting a drill into the anchor hole 113 of the circular cylinder 110 installed on the heat insulating material 20 and rotating it, an anchor bolt ( 120) to form a perforated groove (11) to be inserted.

Next, as shown in Figure 5 (c), by passing through the anchor hole 113, inserting the head of the anchor cap 130 and the anchor bolt 120 into the perforated groove 11, and pressurized with a punch. The anchor cap 130 and the head of the anchor bolt 120 are fixed to the wall 10 of the building. Next, by fastening the fixing nut 140 to the screw portion of the anchor bolt 120 protruding to the outside through the anchor hole 113 of the circular cylinder 110, the circular cylinder 110 is attached to the wall 10 of the building. Fix it.

Next, as shown in (d) of FIG. 5, the cover 111 of the circular cylinder 110 is in close contact with the cover 111 of the circular cylinder 110 and one side of the L-shaped angle 150. Now fix the angle 150. Specifically, the L-shaped angle 150 is disposed so that the end of the anchor bolt 120 to which the fixing nut 140 is fastened passes through the communication long hole 151a of the L-shaped angle 150, and the communication long hole 151a is The first washer 165 and the anchor nut 160 are fastened to the end of the penetrating anchor bolt 120 to closely fix the L-shaped angle 150 to the cover 111 of the circular cylinder 110. In the process of tightening the anchor nut 160 to the end of the anchor bolt 120, the anchor bolt 120 is firmly fixed to the wall 10 of the building. Specifically, when the anchor nut 160 is tightened, the end of the anchor cap 130 located in the wall 10 of the building is opened by the anchor bolt 120 and is supported in the wall, so that the anchor bolt 120 is 10) can be firmly fixed.

Next, as shown in (e) of FIG. 5, the other of the L-shaped angle 150 so that the fastening hole 152a of the L-shaped angle 150 and the fixing hole 170a of the length adjusting plate 170 communicate with each other. The length adjustment plate 170 is disposed on the upper surface of the side portion 152. Next, the proximal bolt 180 is inserted from the bottom to the upper so as to penetrate the fastening long hole 152a and the fixed long hole 170a, and the end of the proximal bolt 180 passing through the fastening long hole 152a and the fixed long hole 170a The second washer 195 and the proximal nut 190 are fastened to firmly fix the length adjustment plate 170 to the L-shaped angle 150. The fixing pin 210 is inserted into the fitting hole 170b of the length adjustment plate 170 in a press-fitting manner so that a part of the fixing pin 210 protrudes to the upper and lower portions of the length adjustment plate 170, respectively.

Next, the lower exterior material 30 is coupled to the fixing pin 210 protruding from the lower portion of the length adjustment plate 170. That is, the lower exterior material 30 is coupled to the fixing pin 210 so that the fixing pin 210 is inserted into the pin hole 31 of the lower exterior material 30.

Next, as shown in (f) of FIG. 5, the upper exterior material 30 is coupled to the fixing pin 210 protruding upward of the length adjustment plate 170. That is, the upper exterior material 30 is coupled to the fixing pin 210 so that the fixing pin 210 is inserted into the pin hole 31 of the upper exterior material 30.

A space is formed between the upper and lower casings 30 and 30 respectively coupled to the fixing pins 210 protruding from the top and bottom of the length adjustment plate 170. In this space, a joint (m) is constructed to fill the boundary space between the upper and lower exterior materials 30 and 30 using a joint material (eg, silicone) such as Tenax.

In the length adjustment plate 170, the distance between the upper and lower casings 30 and 30 is maintained at about 1 mm, and the fixing pins 210 are pin holes 31 formed in the upper and lower casings 30, respectively. ), and the depth of the pin hole 31 is formed relatively deeper than the length of the fixing pin 210 protruding from the top and the bottom of the length adjusting plate 170, so that the weight of the upper exterior material 30 is lower than the length of the lower exterior material. It should not be passed to (30).

The exterior material 30 may be made of stone, and the stone may be constructed of a waterproof stone. Silicone caulking (joint construction) the gap between the upper and lower exterior materials 30 and 30 prevents the occurrence of cracks in the upper and lower exterior materials 30.

6 is a view showing a process of constructing an exterior material on a wall of a building using a circular angle system according to an embodiment of the present invention.

As shown in Fig. 6, a circular cylinder is rotated on an insulation material using an electric drill (a), a perforated groove is drilled in the wall of the building through the anchor hole of the circular cylinder, and an anchor bolt is installed (b), Fastening the fixing nut to the anchor bolt to fix the circular cylinder to the wall of the building with insulation (c), fixing the L-shaped angle to the circular cylinder (d), and connecting the length adjustment plate to the L-shaped angle and installing the exterior material ( Through a series of processes e,f), it is possible to construct exterior materials with a certain space on the walls of the building.

In the above-described embodiment of the present invention, the circular cylinder penetrates the insulating material by rotation and comes into contact with the wall in the building. This circular cylinder can be easily installed on the insulation material using the rotational force, does not damage the insulation material, and can be completely fixed to the wall of the building with a fixing nut.

In addition, in the above-described embodiment of the present invention, since the circular cylinder prevents sagging of the anchor bolt, it is possible to even finish the exterior material of a certain distance or more.

In addition, in the above-described embodiment of the present invention, the construction distance can be adjusted with the L-shaped angle fixed to the circular cylinder and the length adjusting plate fixed to the L-shaped angle.

In addition, in the above-described embodiment of the present invention, since the anchor bolt is firmly fixed to the wall of the building by fastening the anchor cap to the wall of the building, the tensile force is strong and the support force is very strong by the circular cylinder.

In addition, since the above-described embodiment of the present invention uses stainless steel and is highly corrosive, once installed, maintenance is not required until the end of the life span of the building.

The circular angle system according to the embodiment of the present invention described above can be manufactured by adjusting the thickness of stainless steel and the circular cylinder (outer diameter) according to the finishing distance so as to support 5 times (200 kg) or more per place. As a result of the experiment, the embodiment of the present invention was found to secure a target seismic performance according to the effective ground acceleration corresponding to an earthquake of 6.5 on the Richter scale.

Sufficient shear strength and tensile strength must be secured in order to firmly fix and support heavy exterior materials. In order to verify the performance of the circular angle system according to the embodiment of the present invention, when there is an external impact, the exterior material must be stably supported, and thus a seismic test was conducted in consideration of the worst condition, such as an earthquake.

The circular angle system used in the experiment is an exterior material in stone construction (installing two angles), and the force supported by one angle is usually about 30kg (0.6×1.2m×0.03m), but the stone construction is below. Since it is being constructed in the form of stacking stones, the circular angle system 100 adjusts the thickness of stainless steel and the outer diameter of the circular cylinder according to the finishing distance of the stone so that it can support 5 times (200 kg) or more per place. Was produced. After that, it was found that the target seismic resistance according to the effective ground acceleration corresponding to an earthquake of 6.5 on the Richter scale: 0.22g) was secured when the construction was carried out within the range of the proposed structural statement and applied to the site.

In the above-described embodiment of the present invention, a circular cylinder and an anchor bolt are installed without digging the insulation material, and the outer material is constructed by installing a circular cylinder and an anchor bolt, firmly fixed to the wall with a fixing nut, and an L-shaped angle. After construction, the circular cylinder prevents the anchor bolts from sagging, so even heavy exterior materials can be applied to finish over a certain distance.

In this embodiment of the present invention, a circular cylinder is manufactured in a circular shape, rotated and fixed to the wall of a building, thereby preventing damage to the insulating material and preventing sagging of the anchor bolt.

7 is a side view of a seismic type circular angle system according to another embodiment of the present invention.

As shown in FIG. 7, the earthquake-resistant circular angle system 100-1 according to another embodiment has a support plate 220, a vibration absorbing rod 230, a vibration absorbing member 240, and a bent portion in contrast to the embodiment. There is a difference in the structure further including the 155 and the friction member 250. Hereinafter, overlapping descriptions will be omitted, and only parts that are different from the embodiments will be described.

The support plate 220 is fixed to be spaced apart from the bottom surface of the length adjustment plate 170 via a plurality of vibration absorbing rods 230. The support plate 220 has a shape formed with a through hole 220a communicating with the fixed hole 170a of the length adjustment plate 170, and the fastening hole 152a of the L-shaped angle 150 and the through hole of the support plate 220 The proximal bolt 180 is fastened through the fixing long hole 170a of the length adjustment plate 170 and can be tightened with the proximal nut 190.

The vibration absorbing rod 230 is formed of a material capable of absorbing vibration. In the embodiment, the vibration absorbing rod 230 is made of a composite material formed by mixing aluminum metal with glass fiber reinforced plastic. The composite material formed by mixing aluminum metal with glass fiber reinforced plastic has a vibration-absorbing function and has excellent strength, so that it can perform a vibration-absorbing function between the length adjustment plate 170 and the L-shaped angle 150.

A vibration absorbing member 240 is interposed between the support plate 220 and the length adjustment plate 170.

The vibration absorbing member 240 has a shape in which a through hole 220a of the support plate 220 and a through hole 240a communicating with the fastening hole 152a of the L-shaped angle 150 are formed. In more detail, the vibration absorbing member 240 is formed of a thin plate having a thickness of 2mm to 5mm made of a rubber material. The thickness of the vibration absorbing member 240 is preferably formed of a thin plate having a thickness of 2 mm to 5 mm so as to have a vibration absorbing effect without affecting the fastening force of the near-angle bolt 180.

The L-shaped angle 150 is further formed with a bending portion 155 bent downward at an end in contact with the support plate 220. The bent part 155 reinforces the strength of the L-shaped angle 150 to support the stone more stably.

The proximal bolt 180 is provided with a friction member 250 for preventing reverse rotation at the screw portion 181 to prevent loosening of the proximal bolt 180 with respect to the proximal nut 190. The friction member 250 is a nylon patch attached to at least a portion of the screw portion 181 of the proximal bolt 180 in a coating manner so as to be the same as the bending of the screw portion 181. The nylon patch increases the frictional force by contacting the metal-to-non-metal to increase the anti-loosening performance of the near-angle bolt 180 and the near-angle nut 190.

A fixed structure of the L-shaped angle 150 including the support plate 220 and the vibration absorbing rod 230 and the length adjustment plate 170 and the vibration absorbing member 240 between the support plate 220 and the length adjustment plate 170 The arranged structure prevents the vibration transmitted to the slab from being transmitted to the circular cylinder 110 through a double structure capable of absorbing vibration at the connection part between the L-shaped angle 150 and the length adjustment plate 170. Prevents vibration from being transmitted to the wall. In addition, vibration transmitted to the wall of the building is also prevented from being transmitted to the stone through the L-shaped angle 150 and the length adjustment plate 170. In addition, by attaching the friction member 250 to the screw thread 181 of the proximal bolt 180 in order to prevent the bolt from loosening due to the absorption of vibration at the connection part between the L-shaped angle 150 and the length adjustment plate 170, the proximal nut 190 ) Is prevented from loosening of the near-angle bolt 180 to further increase the vibration absorption effect.

The above-described other embodiment is a configuration additionally included in the configuration of the embodiment, and has excellent vibration absorption effect and a sturdy fixing structure compared to the embodiment, so that the stone material is stably supported and has excellent seismic resistance.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and the present invention is not departing from the gist of the present invention claimed in the claims. Of course, various modifications may be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

10: building wall 11: perforated groove
20: insulation material 30: exterior material
100: earthquake-resistant circular angle system 110: circular cylinder
111: cover 111a: concave elevation
111b: edge 113: anchor hole
115: concave-convex portion 116: concave portion
120: anchor bolt 121: head
122: screw portion 130: anchor cap
140: fixing nut 150: L-shaped angle
151: one side portion 152: the other side portion
151a: communication length 152a: fastening length
165: first washer 160: anchor nut
170: length adjustment plate 170a: fixed length hole
170b: fitting hole 180: near angle bolt
190: root nut 195: second washer
210: fixing pin 220: support plate
230: vibration absorbing rod 240: vibration absorbing member
155: bending portion 250: friction member

Claims (2)

A circular cylinder constructed in a rotating manner on an insulating material attached to a wall of a building, formed in a cylindrical shape, one side opened and the other side closed by coupling a cover, and an anchor hole formed in the center of the cover;
An anchor bolt inserted and fixed to the wall of the building through the anchor hole of the circular cylinder and the heat insulator, and the remaining portion protrudes from the cover of the circular cylinder;
Anchor cap coupled to the anchor bolt and disposed within the wall of the building; And
A fixing nut fastened to an end of the anchor bolt protruding from the cover to fix the circular cylinder to the heat insulating material;
Including,
An L-shaped angle including one side portion in contact with the cover of the circular cylinder and the other side portion orthogonal to the one side portion, and in which a communication long hole communicating with the anchor hole is formed on the one side portion;
An anchor nut that is fastened to an end of the anchor bolt passing through the anchor hole of the circular cylinder and the communication length hole of the L-shaped angle so that the anchor bolt and the anchor cap are tightened together;
A length adjustment plate formed in a plate shape, seated on the other side of the L-shaped angle, and having a fixing hole communicating with the fastening hole formed on the other side of the L-shaped angle, and having a fitting hole at the tip;
A proximal nut fastened to an end of the proximal bolt passing through the fastening long hole of the L-shaped angle and the fixed long hole of the length adjusting plate;
A fixing pin that is inserted into the fitting hole and partially protrudes to the upper portion of the length adjustment plate and partially protrudes to the lower portion of the length adjustment plate;
Including more,
The cover of the circular cylinder
A certain area centered on the anchor hole forms a concave indentation surface compared to the edge,
The fixing nut is in close contact with the concave surface,
One side of the L-shaped angle is in close contact with the edge,
One side of the circular cylinder includes a plurality of uneven portions formed along the outer diameter at the end thereof, and it is possible to construct while reducing friction when rotated on the insulating material,
The concave portion of the uneven portion is formed to extend obliquely outward than the outer diameter of the circular cylinder,
The circular cylinder penetrates the insulation material by rotational force, contacts the wall of the building, and is fixed to the insulation material after installation of the anchor bolts,
The cover of the circular cylinder has a support force that does not bend against a load by forming a curved portion connecting the concave surface and the edge,
The circular cylinder, the anchor bolt, the L-shaped angle and the length adjustment plate are made of stainless material,
A support plate is fixed to be spaced apart from the bottom of the length adjustment plate through a plurality of vibration absorbing rods,
The support plate has a shape in which a through hole communicating with a fixed length hole of the length adjustment plate is formed,
The vibration absorbing rod is a composite material formed by mixing aluminum metal with glass fiber reinforced plastic,
A vibration absorbing member is interposed between the support plate and the length adjustment plate,
The vibration absorbing member has a shape in which a through hole communicating with a through hole of the support plate and a fastening hole of the L-shaped angle is formed,
The vibration absorbing member is a 2mm to 5mm thin plate made of a rubber material,
The L-shaped angle is further formed with a bending portion bent downward at an end in contact with the support plate,
The proximal bolt is provided with a friction member for preventing reverse rotation in the screw portion to prevent loosening of the proximal bolt with respect to the proximal nut,
The friction member is a nylon patch attached to at least a portion of the threaded portion of the proximal bolt in a coating manner to be the same as the bending of the threaded portion,
Earthquake-resistant circular angle system. delete

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