KR100538759B1 - Socket for reinforcing outer wall by anchor and reinforcement method and structure for outer wall using thereof - Google Patents

Abstract

The present invention relates to a socket used for reinforcing an outer wall using an anchor, and an outer wall reinforcing method and a reinforcing structure using the same. The object of the present invention is to protect the outer wall from cracks caused by shrinkage during construction of the outer wall. When constructing the anchor reinforcement structure and the socket structure that supports the fixing force of the anchor used in the exterior wall reinforcement structure and secures the installation space of continuous wire for seismic design, and also the reinforcement structure using the anchor and the socket The continuous construction is possible to provide a convenient construction method that can shorten the air. In the configuration of the present invention, one side of the hollow portion is formed to be opened so that the anchor is connected to the outer wall and the bearing wall is fixed, and the other side is cut in a predetermined length in the longitudinal direction so that the anchor is fixed, but the end is opened according to the diameter size of the anchor It is characterized in that it is formed to the cut portion, the at least two projections protrudingly formed in the circumferential direction, the anchor formed a space portion for installing the seismic design wire, and the reinforcing structure and reinforcement method using the same.

Description

Socket for reinforcing exterior wall using anchor, reinforcing outer wall using anchor and reinforcement method and structure for outer wall using

The present invention relates to a socket used when reinforcing an outer wall using an anchor, and an outer wall reinforcing method and a reinforcing structure using the same. Specifically, the socket includes a socket for inserting and fixing an anchor and easily installing a seismic wire. It is easy to insert and install anchors on the inner wall after the outer wall construction by the construction together with the outer wall construction and at the same time due to the protrusions formed around the surface of the socket, the wire installation space for earthquake is sufficiently secured to achieve a smooth construction.

In general, the outer wall not only supports the load of the building, but also serves to protect the interior of the building against the outside air. This protection role is the most representative example of the insulation, ventilation, shade.

As shown in FIG. 7, the outer wall of the building has a bearing frame 1, a heat insulating material 2, a heat insulating space 3, an exterior wall 4, and a window frame fixing part having a plurality of barrier blocks 5 at the upper and lower ends thereof. It is configured to include. The load bearing wall 1, the heat insulating material 2, the heat insulating space 3, and the exterior wall 4 are sequentially arranged from the inside of the building to the outside as shown.

At this time, the bearing wall 1 is a structure of concrete material, the heat insulating material 2 is applied to styrofoam, fiber material, glass fiber or the like. The exterior wall 4 takes the form of a wall by means of an masonry member 4a that is assembled in the vertical and horizontal directions as shown by an adhesive such as a mortar. Such, the masonry member 4a may be composed of an exterior brick or a slab.

Then, the pulverulent block 5 is attached to the lower portion of the masonry member 4a of the exterior wall 4 by an adhesive, to support the masonry member and the heat insulating material. And, as shown, the block 5 has a plurality of hollows 5a on the side at equal intervals.

As shown in the figure, the hollow 5a of the pulling block 5 is inserted with a reinforcing bar 5b for supporting the pulling block 5. The ring of the eye bolt 8a is fitted to the reinforcing bar 5b, and the eye bolt 8a is fixed to the L-shaped bracket 7 provided on the bearing wall 1 by the flange nut 8b. At this time, the eye bolt 8a is pulled upward by tightening the flange nut 8b. The reinforcing bar is firmly supported by the barrier block 5 while being tense. Of course, the masonry member 4a of the exterior wall 4 is indirectly supported by the rebar 5b by the pull-out block 5.

On the other hand, the window frame (W) as shown is fixed to the window frame fixing part located in the lower part of the room block (5). Meanwhile, reference numeral 9 in the drawings is caulking for waterproofing.

By the above configuration, the bearing wall 1 forms the exterior of the building, supports the load of the building, the heat insulator 2 blocks the outdoor air from entering the interior, and the heat insulation space 3 is the outside air. And serves to compromise the temperature difference of the bet. In addition, the exterior wall 4 directly blocks external air and rainwater, and the barrier block 5 prevents rainwater flowing down from the upper portion of the window frame W.

However, in the general outer wall as described above, since the masonry member 4a of the exterior wall body 4 expands and contracts according to the external temperature, a crack occurs in the exterior wall body 4. In order to prevent such a problem, a pair of masonry members 4a horizontally arranged side by side may be connected by reinforcing bars. That is, an adhesive is applied to the upper surfaces of the two masonry members 4a, and reinforcing bars connecting the two masonry members 4a are disposed on the adhesive to connect the two masonry members 4a with rebars. Of course, the reinforcing bar is connected to the masonry member 4a while forming the same as the masonry member 4a as the adhesive is cured. However, even in such a method, the material of the reinforcing bar is different from the elasticity of the masonry 4a and the adhesive, and it does not respond quickly to the expansion and contraction of the masonry 4a. Therefore, there is a problem that the crack still occurs in the exterior wall 4 due to the expansion and contraction member 4a.

Prior art for solving the problems of crack generation as described above Utility Model Registration No. 291469, Utility Model Registration No. 291470, Utility Model Registration No. 347343, all such prior art after the crack occurs in the outer wall body The present invention relates to a reinforcing technique, and has a disadvantage in that it does not include a structure that can prevent cracks in advance during construction.

A common construction procedure of the prior art is shown in FIG. 8. Referring to the corresponding drawing, the construction procedure is performed by drilling a proof pilot hole, attaching anchor rods A and B, and closing the remainder. It can be seen. However, the problem of the construction procedure is that there is a risk that new cracks may be generated in other exterior wall structures that are not cracked due to the vibration by drilling directly into masonry members such as red bricks instead of horizontal joints. . Due to such a risk factor, there is a problem that repair work may cause a risk to the safety of the entire exterior wall.

Patent application to provide a structure that can prevent the separation of the exterior wall by absorbing the elastic force of the exterior wall by the external temperature, while maintaining the state of the exterior exterior wall to solve the problems of the conventional repair work as described above 10-2004-83304, which discloses an anchor that supports a wall during construction and a cylindrical connector that serves as a guide upon insertion of the anchor.

However, the connector disclosed herein has a flat cylindrical shape, which makes it difficult to secure space for the construction of continuous wires used in earthquake-resistant design, and after the curing of the mortar in which the connector is installed, the fixed bearing capacity of the connector is weak. There is also a problem that the fixing force of the anchor to be coupled is also reduced to make it difficult to reinforce the outer wall.

In addition, when looking at the structure upgraded in the specification of the application, when reinforcing the masonry member and the bearing wall of the outer wall with anchors and connectors, one reinforcement structure is completed only after the curing of the mortar, there is a problem that the overall air is consumed a lot. In addition, the construction method using the anchor and the connector is drilled to the wall with a certain depth when stacking stucco bricks, and then insert the anchor into the inner wall by using a hand tool in the horizontal wall when laying the external brick, and opposite the embedded anchor After installing the connector by screwing it in the direction of the screw groove, insert the continuous wire into the hole formed in the connector and stack the bricks on it. The drawing force and the compressive force are exhibited to the maximum, but the position of the joint does not match, so the anchor is not installed horizontally, and the drawing and compressing force cannot be obtained. There is a problem that does not properly exhibit the decorative brick structure.

In addition, the patent application is merely a guide as described above rather than the connector to support the anchor due to the difference in the diameter size of the connector and anchor. Of course, in order to solve such a problem, it is described that a shape such as a fixing protrusion is formed on the connector.

An object of the present invention for solving the above problems is to provide an anchor reinforcement structure that can protect the exterior wall from cracks, etc. caused by shrinkage during construction of the exterior wall.

In addition, the present invention provides a socket structure that can easily secure a space for installing a continuous wire for seismic design while supporting anchoring force used in an exterior wall reinforcement structure.

In addition, the construction of the reinforcement structure using the anchor and the socket is possible to provide a convenient construction method capable of shortening the air by the continuous construction.

Referring to the configuration of the present invention to achieve the object as described above and to perform the problem for eliminating the conventional drawbacks are as follows.

The socket of the present invention is open to one side is formed by the hollow portion is formed so that the anchor is connected to the outer wall and the anchoring wall is fixed and the other side is cut in a predetermined length in the longitudinal direction so that the anchor is fixed, but the end is opened according to the diameter size of the anchor It is characterized in that the incision is formed, and at least two projections (circular projections) protrudingly formed in the circumferential direction to form a space in which the earthquake-resistant design wire is installed.

The other end shape cut in the longitudinal direction is finished to have a round semicircle shape.

The inner diameter of the socket is formed to be smaller than the outer diameter of the anchor is inserted is formed by the spiral groove is formed by the rotation of the inserted anchor is configured to strengthen the compression force.

The inner diameter material of the socket is configured to be softer than the anchor so that the spiral groove is formed by the rotating anchor.

The circular protrusion protruding in the circumferential direction of the socket serves as a locking jaw when the mortar is cured to exert a strong fixing force.

In addition, since the circular protrusion does not directly contact the wire, external force applied to the wire is not directly transmitted, thereby preventing the socket from being easily damaged.

The construction method of the exterior wall reinforcement structure using the socket as described above is as follows.

First, installing a masonry member (decorated brick) constituting the exterior wall using a cement masonry horizontal mortar to install wires and sockets in a horizontal joint formed by the horizontal mortar at regular intervals;

After the step, when the masonry horizontal mortar is cured, the hole is drilled through the socket with an electric drill to a predetermined depth toward the bearing wall;

Inserting the anchor through the hole in the socket of the bearing wall after the step;

After the step consists of finishing the socket portion with a mortar or caulking material.

When the masonry mortar is cured, the step of drilling holes with a predetermined depth through the socket with an electric drill is to process the holes on the same axis as the socket.

In the step of inserting the anchor into the hole processing portion of the bearing wall by rotating through the socket, the inner diameter portion of the socket is a step in which a spiral groove is formed by the outer diameter of the socket larger than the inner diameter portion, thereby increasing the pull compression force.

In the step of inserting the anchor into the hole processing portion of the bearing wall by rotating through the socket, the anchor is inserted while being rotated by using a hand tool.

The function of the socket is to strengthen the binding between the mortar and the socket due to the circular projections, and the seismic design capability is provided by installing a continuous wire between the circular projections. In addition, it prevents the socket from being easily damaged by the circular protrusion, and when the anchor is inserted, a spiral groove is formed inside the socket by the screw thread of the anchor to strengthen the pull compression force, and the end of the socket is opened by the anchor insertion to open the masonry. It can be tightly attached, so it has much better pulling and pressing force than the existing anchor system.

The reinforcing structure of the building exterior wall of the present invention by the construction method using the socket as described above is as follows.

Of a building exterior wall having a load bearing wall, a heat insulating material, an insulation space, and an exterior wall having a plurality of masonry members assembled thereon in order toward the outside, and having a plurality of pulmonary blocks formed by forming a hollow and joined to the masonry member of the exterior wall. In the reinforcement structure,

One side is formed by opening a hollow part so that an anchor for connecting and fixing the exterior wall body and the bearing wall installed at regular intervals in a horizontal motor made of a mortar that bonds between the upper and lower masonry members to be joined is opened and the other side has a length such that the anchor is fixed and supported. A socket formed with a space portion in which the cutting portion is cut in a predetermined length so that an end is opened according to the diameter of the anchor, and at least two or more circular protrusions are protruded in the circumferential direction so that a seismic design wire is installed; An anchor having a spiral shape that rotates through the socket to form a spiral groove in the inner diameter of the socket and fixes the masonry member and the heat insulator to the bearing wall while forming an outer wall; One end of the anchor is characterized in that consisting of a hole formed on the same axis as the socket on the bearing wall to be inserted and fixed.

The hole is pre-drilled with a drill through the socket so that the anchor is inserted and fixed on the same axis as the socket.

The end shape of the incision is rounded off.

The inner diameter of the socket is formed to be smaller than the outer diameter of the anchor is inserted is formed by the spiral groove is formed by the rotation of the inserted anchor is configured to strengthen the compression force.

The material of the socket is configured to be softer than the anchor so that the spiral groove is formed by the rotating anchor.

The circular protrusion protruding in the circumferential direction of the socket serves as a locking jaw when the mortar is cured to exert a strong fixing force.

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

Figure 1 shows a perspective view showing a socket of the present invention, the socket 8 used in reinforcing the exterior wall of the present invention is formed to have a hollow portion 83 inside, one side is fully open to have a circular cross section And the other side was composed of a cylindrical tube shape, most of which is not a circular section. However, the other blocked end is formed with an incision 82 cut in a predetermined length in the longitudinal direction of the socket, so that the incision is elastically opened according to the diameter size of the anchor to be inserted.

Due to this incision 82 is to strengthen the fixed bearing capacity of the inserted anchor.

In addition, at least two circular protrusions 81 are formed to protrude in the circumferential direction of the socket, thereby securing a space in which a plurality of seismic design wires can be installed in the space formed by the circular protrusions when the exterior wall is reinforced.

In the illustrated socket, a total of four circular protrusions are shown. In the present invention, the circular protrusion needs only at least two circular protrusions to which wires are installed. Only when the number of the circular protrusions increases there is an advantage that the structural stability is increased.

Figure 2 shows a perspective view showing the combination of the socket and the anchor of the present invention, the anchor 7 inserted from one hollow portion 83 of the socket (8) is shown passing through the other incision (82) In this case, the cutout 82 is opened by the insertion of the anchor 7. The reason for this opening is that the hollow portion 83, which starts at one side of the socket and extends to a certain length, is not formed, and there is no force to control the gap in the circumferential direction due to the incision, so that the cut portion has a structure that naturally opens upon insertion of the anchor. do. As the incision is opened, the socket and the anchor have a strong coupling force.

In addition, the outer diameter of the anchor is formed larger than the inner diameter of the socket to form a spiral groove (not shown) while rotating in the hollow portion 83 inside the socket 8 will have a stronger coupling force.

Figure 3 shows a perspective view showing a construction embodiment of the present invention, from this perspective it can be seen the reinforcing structure of the building exterior wall of the present invention. The reinforcing structure of the present invention is configured to have a cylindrical tube shape, one side is opened and the other side is blocked so that the anchor (7) installed at fixed intervals is inserted into the horizontal motor made of a mortar for bonding between the upper and lower masonry member (4a) to be bonded, The other end of the clogged end is cut in a predetermined length in the longitudinal direction to form an incision 82 to open the end according to the diameter size of the insert, at least two circular protrusions 81 protruded in the circumferential direction to the seismic design wire A socket 8 formed to secure a space in which the 9 is installed; Anchor 7 having an outer shape of a spiral structure for fixing the masonry member 4a and the heat insulator 2 to the bearing wall 1 while rotating the socket 8 to form a spiral groove in the socket inner diameter. Wow; It can be seen clearly that the structure of the hole 11 formed on the same axis as the socket on the bearing wall such that one end of the anchor is inserted and fixed.

In FIG. 3, a mortar for adhering the masonry members 4a is not shown for convenience. As can be seen from this perspective it can be seen that the continuous earthquake-resistant design wire 9 is installed in the space provided by the circular projection 81 in the lower portion of the socket (8). Since the wire 9 is provided in the space provided by the circular protrusion 81, damage to the socket 8 due to the wire can be prevented.

In addition, the circular protrusions reinforce the fixing force of the socket when the mortar is cured, thereby reinforcing the fixing support force between the exterior wall and the bearing wall.

4 to 6 illustrate a longitudinal cross-sectional view according to the construction procedure of the present invention. As shown in FIG. 4, the masonry member 4a constituting the exterior wall 4 is cement-horizontal mortar as shown in FIG. 4. (6) installing the wire (9) and the socket (8) in the horizontal joint formed by the horizontal mortar (6) at regular intervals when stacked using;

As shown in Fig. 5, when the masonry horizontal mortar is cured, the hole 11 is drilled through the socket 8 with an electric drill (not shown) to the bearing wall 1 at a predetermined depth;

As shown in FIG. 6, the anchor 7 is inserted into the hole 11 of the bearing wall 1 by rotating the inside of the socket 8 from one side to the other side. Thereafter, the socket portion is finished with a mortar or caulking material (not shown). At this time, the cutting portion 82 of the socket is shown to be opened to both sides by the anchor (7).

In the above, when the hole is drilled through the socket with a predetermined depth on the bearing wall side, the hole is machined so that the position is located on the same axis as the socket.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

The present invention as described above has the advantage of providing in advance the anchor reinforcing structure that can protect the exterior wall from cracks, etc. caused by shrinkage during construction of the exterior wall.

In addition, there is an advantage that the socket structure is easy to secure the installation space of the continuous wire for the seismic design while supporting the fixing force of the anchor used in the exterior wall reinforcement structure.

In addition, there is an advantage in that the continuous construction is possible in the construction of the reinforcement structure using the anchor and the socket, and the effect of improving the quality, air shortening, and construction cost due to the simplicity of construction and thereby the construction precision.

More specifically, the effect of the present invention is to install the socket at horizontal intervals at a regular interval when stacking the masonry member (decorated brick) and after the construction of the stucco masonry masonry masonry mortar is cured through the socket with an electric drill Mortar or caulking finish after driving the bearing wall to a predetermined depth increases the simplicity of construction, improves the quality of construction and has the advantage that the stucco structure has stability. In addition, the function of the socket of the present invention used in this construction has the advantage of strengthening the binding between the mortar and the socket due to the circular projections and has the ability to seismic design by installing a continuous wire between the circular projections. This prevents the socket from being easily damaged by the circular projections, and has the advantage that spiral grooves are formed inside the socket by the thread of the anchor when inserting the anchor to strengthen the pull compression force, and the spiral groove inside the socket by the anchor insertion. It is formed to enhance the pull compression force, and the end of the socket by the insertion of the anchor can be tightly adhered to the masonry tank is a useful invention with the advantage that it has a much better pull force and compression force than the existing anchor system is expected to use the industrial greatly It is an invention to be.

1 is a perspective view showing a socket of the present invention,

Figure 2 is a perspective view showing a combination of the socket and the anchor of the present invention,

3 is a perspective view showing a construction embodiment of the present invention,

4 to 6 is a longitudinal cross-sectional view according to the construction procedure of the present invention,

7 is a longitudinal sectional view showing a conventional general outer wall,

8 is a view showing a conventional general exterior wall reinforcement construction procedure.

<Explanation of symbols for the main parts of the drawings>

(1): bearing wall (2): insulation

(3): Insulation space (4): Exterior wall

(4a): masonry member (6): horizontal motor

(7): anchor (8): socket

(9): seismic design wire (11): hole

(81): circular protrusion (82): incision

(83): hollow part

Claims (11)

One side is formed by opening the hollow part so that the anchor is connected and fixed between the exterior wall and the bearing wall, and the other side is cut in a predetermined length in the longitudinal direction so that the anchor is fixed, but forms an incision to open the end according to the diameter of the anchor At least two protrusions protrudingly formed in the circumferential direction, the socket used when reinforcing the exterior wall using an anchor, characterized in that formed a space portion for installing the seismic design wire. The method of claim 1, The protrusion is a socket used when reinforcing the exterior wall using an anchor, characterized in that formed with a circular protrusion. The method of claim 1, The inner diameter of the socket is formed to be smaller than the outer diameter of the anchor is inserted socket used for reinforcing the exterior wall using the anchor, characterized in that the spiral groove is formed by the rotation of the inserted anchor. The method of claim 3, wherein The inner diameter of the socket material is a socket used when reinforcing the exterior wall using an anchor, characterized in that the spiral groove is formed by an anchor that is configured to be softer than the anchor. A building exterior wall having a bearing wall, a heat insulating material, an insulation space, and an exterior wall having a plurality of masonry members assembled thereon are sequentially provided to the outside, and having a plurality of pulmonary blocks that are hollowed and joined to the masonry member of the exterior wall. In the method of reinforcing using an anchor, Installing wires and sockets on horizontal joints formed by horizontal mortars at regular intervals when stacking masonry members (decorated bricks) constituting an exterior wall using a cement masonry horizontal mortar; After the step, when the masonry horizontal mortar is cured, the hole is drilled through the socket with an electric drill to a predetermined depth toward the bearing wall; Inserting the anchor through the hole in the socket of the bearing wall after the step; Exterior wall reinforcement method using a socket used for reinforcing the exterior wall using an anchor, characterized in that the step of finishing the socket portion with a mortar or caulking material after the step. The method of claim 5, When the masonry mortar is cured, the outer wall using the socket used for reinforcing the exterior wall using an anchor, characterized in that the hole is drilled on the same axis as the socket when the hole is drilled to a predetermined depth on the bearing wall side by an electric drill. Reinforcement method. The method of claim 5, The inner diameter of the socket in the step of inserting the anchor through the hole processing portion of the bearing wall by rotating the inside of the socket is a step of forming a spiral groove by the outer diameter of the socket larger than the inner diameter portion outer wall using an anchor Exterior wall reinforcement method using socket used for reinforcement. Of a building exterior wall having a load bearing wall, a heat insulating material, an insulation space, and an exterior wall having a plurality of masonry members assembled thereon in order toward the outside, and having a plurality of pulmonary blocks formed by forming a hollow and joined to the masonry member of the exterior wall. In the reinforcement structure, One side of the hollow is formed to open and the other side is fixed so that the anchor is connected to the horizontal wall made of a mortar for bonding between the upper and lower constituting members to be bonded to each other and fixed between the outer wall and the bearing wall installed at regular intervals. A socket having a predetermined length in the longitudinal direction, the incision being formed so that the end is opened according to the diameter of the anchor, and a space formed at least two circular protrusions protruding from the circumferential direction to form a space for installing a seismic design wire; An anchor having a spiral shape that rotates through the socket to form a spiral groove in the inner diameter of the socket and fixes the masonry member and the heat insulator to the bearing wall while forming an outer wall; An outer wall reinforcement structure using a socket used when reinforcing an exterior wall using an anchor, characterized in that the one end of the anchor is configured to have a hole formed on the same axis as the socket on the bearing wall to fix the insertion. The method of claim 8, The hole is the outer wall reinforcement structure using a socket used for reinforcing the exterior wall using an anchor, characterized in that the line is drilled through the socket so that the anchor is inserted and fixed on the same axis as the socket. The method of claim 8, The inner diameter of the socket is formed to be smaller than the outer diameter of the anchor is inserted into the outer wall reinforcement structure using a socket used for reinforcing the exterior wall using an anchor, characterized in that the spiral groove is formed by the rotation of the anchor is inserted. The method of claim 8, The material of the socket is configured to be softer than the anchor outer wall reinforcement structure using a socket used when reinforcing the exterior wall using an anchor, characterized in that the spiral groove is formed by a rotating anchor.