KR101893218B1 - translate online - Google Patents

Abstract

The present invention relates to a stress distribution device for preventing cracks occurring at a corner formed by installing a window in a concrete building. In a stress distribution device, which is embedded in the placed concrete from a corner of an opening part, which is provided in a wall surface to form a window or a door when constructing a new building, so as to prevent the generation of cracks from the corner, the stress distribution device comprising: a support protrusion piece coming into contact with the corner of a form; a curved piece having a semicircular shape extending from the support protrusion piece to both sides and having a through hole, through which the concrete can be poured; and folded pieces integrally extended from both end surfaces of the curved piece and folded so as to come into contact with the side surface of the form, wherein such the curved pieces have fitting protrusions and insertion groove parts at the same positions on the upper and lower surfaces so as to be fitted and fastened to each other.

Description

Stress distribution device for crack prevention {translate online}

The present invention relates to a stress dispersing apparatus for preventing cracks, which can prevent cracks generated from corners of openings that are opened for installing windows, doors, and the like when a concrete building is expanded and retracted.

Generally, as shown in FIG. 1, a wall surface 1 of a building such as a single-family house, an apartment, a villa, a building or the like is provided with an opening 1a having a size suitable for a use purpose such as a door, a window 2, A fixing frame is provided on the inner circumferential surface of the opening, and then an access door or a window 2 is installed on the fixing frame.

There is a problem in that cracks 3 are generated in the concrete wall surface 2 starting from the corner of the opening edge when only the opening is provided on the wall surface of the building using the above concrete, As shown in FIG. 2, the reinforcing steel bars 12 are arranged in the openings formed in the transverse direction and the longitudinal direction, and two crack-preventing bars 12 are provided on the outer side of the reinforcing bar 12 at right angles to the direction of another crack. (13) to prevent cracks.

The crack-preventing reinforcing bars 13 can control a part of the cracks generated at the edges of the rectangular openings, but it is impossible to suppress the cracks completely, so that the cracks around the openings of the reinforced concrete structures are largely different, It is a fact that it is occurring.

In addition, the crack-preventing reinforcing bar 13 for preventing stress concentration, which is the cause of the cracks, is additionally disposed. The work for laying the crack-preventing reinforcing bars 13 is performed in the horizontal and vertical directions, The reinforcing bars 13 are disposed obliquely in addition to the outside of the reinforcing bars 12 which are separately disposed around the reinforcing bars 14 and the reinforcing bars 14 which are double-laid on the left and right sides of the wall. The work for laying the same anti-crack reinforcement 13 is difficult because of poor working conditions due to the interference between the wall reinforcement 14 and the reinforcement reinforcement 12 that are laid in advance and the installation space is narrow due to a narrow space for reinforcement. It is difficult to maintain the coating thickness.

Also, since the assembled dense structure obstructs the flow and filling of concrete, separation of concrete material occurs, which causes a decrease in concrete strength and promotes cracking.

Particularly, when such a crack occurs, there is a problem of indoor leakage due to the infiltration of rainwater. Also, when the inner reinforcing bar is corroded by the rainwater infiltrated into the gap of cracks, The cracks will accelerate the cracks of the part, and the cracks that are generated are difficult to repair and continue to be repeated due to the repeated shrinkage or expansion of the structure. Therefore, It will be clearly visible on the outside and will harm the aesthetics of the building.

In order to solve such a conventional problem, Patent Registration No. 10-1022708 has been introduced.

The conventional stress distribution plate has a rectangular stress distribution plate in which straight portions are formed on both sides in the cross direction and curved portions connecting the straight portions are integrally formed,

The stress distribution plate is formed with a through-hole of a concrete inflow hole, and a support foot protruding toward a rectangular opening of the structure is formed at one side of the stress distribution plate, so that the stress distributor is connected to the opening reinforcing steel It is confirmed that the stress distribution plate induces and disperses the shear stress exerted on the corner of the rectangular opening by fixing the concrete after the fixing, thereby preventing the cracking of the signatures at the corner of the rectangular opening.

However, in the conventional stress distribution plate, the shear stress generated from the corner portion due to the pain and impact generated in the building strikes the stress distribution plate as it is, and the shear stress exceeds the stress distribution plate due to the impact And cracks were generated on the surface of the substrate. Thus, the problem could not be solved efficiently.

In addition, since the conventional stress distributing plate places the concrete in a state where it is positioned at the corner portion, when the concrete is poured, it is pushed by the concrete in which the stress distributing plate is laid. Therefore, before placing the concrete, After that, it was necessary to use steel wires to cover the stress distribution plate and the reinforcing bars, which made the work less efficient.

Accordingly, it is an object of the present invention to effectively disperse and block cracks generated from corner portions of openings provided for installing a window or a door on a wall surface formed by pouring concrete in order to expand and contract a building .

In order to achieve the above object, the present invention provides a method for constructing a new building, which is constructed such that a window or an entrance door is formed at the time of construction, the stress applied to the interior of the concrete pouring from the corner of the opening, In the dispersing device,

Wherein the stress dispersing device includes a stress dispersing plate having through holes so that concrete and cement mortar can be inserted therethrough and a supporting plate integrally extending at both ends of the stress dispersing plate,

The stress distribution plate is formed in a semicircular shape so as to prevent the crack generated from the edge from further diffusing and to disperse and eliminate the stress causing the crack, and the stress having the semicircular shape And a stress dispersing member is provided on the inner surface of the dispersing plate so as to disperse the stress in a portion except for the through hole.

In addition, the stress dispersion material has a cylindrical shape in order to disperse the stress along a curved surface when a stress generated in a state of having a through hole communicating with the stress distribution plate is collided.

In addition, it is preferable that the front end of the stress dispersion body having the cylindrical shape is provided with an opening groove which is inwardly recessed from the front end thereof as a starting point, so that the concrete and the cement mortar placed in the through hole can be filled smoothly .

It is further characterized in that a shape-retaining plate for preventing a shape change of the stress distribution plate is formed by forming a curved surface on the inner side surface and the lower end of the stress distribution plate in the same manner as the stress distribution plate.

Further, the present invention is further characterized in that a fixing protrusion and a fixing groove are formed to connect the two stress distribution plates to each other at corresponding positions on both sides of the upper surface of the stress distribution plate.

The stress dispersing member is formed so as to be in a state of being integrally communicated with the inner and outer surfaces of the stress distribution plate.

In addition, a fixing part is provided integrally on both sides of the outer surface of the stress dispersing plate to fix the stress dispersing plate to the reinforcing bars by simple fitting.

The fixing part may be a tension fixing piece having a space so that the reinforcing bars can be inserted and fixed while the front part is opened with synthetic resin as a material.

The present invention is characterized in that, when a stress dispersing device is embedded in a wall surface from a point at which each corner of an opening formed at the time of construction is used as a starting point for installing a window or a door, Thereby preventing the cracks generated from the corners of the building from being formed. In addition, when the stresses generated when the cracks are generated are scattered, they are dispersed and can be annihilated to prevent the stress from diffusing to the entire building .

Further, a plurality of stress dispersing bodies integrally extending on the inner surface of the stress dispersing plate are further provided, so that the generated stress can be dispersed and destroyed by colliding with the stress dispersing body before reaching the stress dispersing plate. It is possible to effectively disperse and destroy the object.

1 is an exemplary view showing a window of a general building;
2 is a plan sectional view showing a conventional construction state.
3 is a perspective view showing a configuration of a stress dispersing apparatus according to the present invention.
4 is a plan sectional view showing the structure of a stress distribution plate according to the present invention.
5 is a cross-sectional view showing a state in which a stress distribution plate according to the present invention is installed.
Fig. 6 is an enlarged view of part A of Fig. 4,
6A is a state before concrete is poured.
6B is a state in which concrete is poured.
Figure 6c is a state in which the form is demolished after the concrete is laid.
7 is a sectional view taken along the line AA in Fig. 6A,
FIG. 7A is a state before the concrete is poured in a state where the fixing part is coupled to the reinforcing bars; FIG.
7B is a state after the concrete is poured in a state where the fixing part is coupled to the reinforcing bars.
8 is a sectional view showing another embodiment of the present invention.

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

FIG. 3 is a perspective view showing the structure of a stress dispersing apparatus according to the present invention, FIG. 4 is a sectional view showing the structure of a stress dispersing plate according to the present invention, FIG. 5 is a cross sectional view showing a state in which a stress dispersing plate according to the present invention is installed, The stress distribution device 100 according to the present invention is embedded in a wall surface with each corner 12 of an opening 11 formed in a wall surface 10 as a starting point, (200), a support plate (300) curved outwardly in a state of being integrally extended at both side ends of the stress distribution plate, and a support plate (300) which is integrally extended on the inner side of the stress distribution plate And a fixing part 500 integrally formed on both sides of the outer side of the stress distribution plate to fix the stress distribution plate by simple fitting to the reinforcing bars It is sex.

The stress dispersing apparatus 100 is formed by injection molding using a synthetic resin as a material. The stress dispersing apparatus 100 may be formed using any material capable of performing the function of the stress dispersing apparatus.

The stress distribution plate 200 is for covering the periphery of the edge 12 where cracks are prone to occur due to stress concentration. The stress distribution plate 200 is formed in a semicircle shape so as to cover the edge 12 in the same range from both sides So that the crack generated from the edge 12 due to the concentration of stress is blocked by the stress dispersing plate 200 wrapped around the corner 12 starting from the edge 12, The crack generated from the edge 12 due to stress concentration is struck against the stress dispersing plate 200 so that no more cracks are generated and the stress generated at the time of cracking is formed into a curved surface of a semicircle The stress is dispersed along the curved surface and collapses to generate a crack due to the stress. As shown in FIG.

At this time, the stress distribution plate 200 is provided with a plurality of through-holes 210 for allowing concrete and cement mortar to be laid to construct the wall surface 10 to pass therethrough, The concrete and the cement mortar to be laid when the weir concrete and the cement mortar are poured can be poured through the through hole 210.

The shape of the stress distributing plate 200 is formed at the midpoint between the inner and the lower ends of the stress dispersing plate 200 and is shaped like a curved surface. So that the shape of the stress dispersing plate 200 having a semicircular shape having a synthetic resin as a material is not deformed.

The support plate 300 is formed to be curved outwardly in a state of being integrally extended to both end portions of the stress distribution plate 200 having a semicircular shape. The support plate 300 is made of concrete and cement mortar And is brought into contact with the outer surface of the formwork (1) provided for forming the hour opening (11).

In addition, when the fixing projections 230 and the fixing grooves 240 are provided at positions corresponding to both sides of the top surface of the stress dispersing plate 200 and two sheets of the stress distribution plates are connected to be used, So that the prepared fixing protrusions 230 can be inserted and fixed in the fixing grooves 240 of the other stress distribution plates.

The stress dispersion body 400 is integrally formed on the inner surface of the stress dispersing plate 200 excluding the through hole 210 provided in the stress dispersing plate 200 and is integrally formed with the edge 12 of the wall surface 10 When the stress due to the cracks generated by the cracks is encountered, the stress is dispersed so as to have a circular shape so as to be annihilated.

At this time, the stress dispersion body 400 is integrally formed on the inner surface of the stress dispersing plate 200 having a semicircular shape, and a plurality of the stress dispersing bodies 400 formed on the stress dispersing plate 200 are arranged at the corners As shown in Fig.

The stress dispersing body 400 has a through hole 410 communicating with the stress dispersing plate 200 so that the concrete and the cement mortar can be buried in the through hole 410. The stress dispersing body 400 has a distal end portion, The concrete and the cement mortar to be poured are smoothly introduced into the through hole 410 of the stress dispersing body 400 through the opening groove 420 to be filled with the open groove 420, .

It is preferable that the cutout groove 420 has a cone-shaped "V" -shaped shape. The shape of the cutout groove 420 is not limited to the above-described shape, and any shape such that the concrete or the cement mortar can be smoothly filled in the through hole 410 It will be possible.

The fixing part 500 is integrally provided on both sides of the outer surface of the stress distribution plate 200 so that the fixing part 500 is inserted and fixed to the reinforcing bar 20 so that the stress distribution plate 200 can be fixed It is composed of a tension fixing piece 510 having a space portion 520 so that a reinforcing bar can be inserted and fixed in a state where a front part is opened with a synthetic resin as a material. Before the concrete is placed between the molds, The stress distributor 200 is pushed in a state where the opening portion of the fixing portion 500 provided on both sides of the outer surface of the stress dispersing plate 200 is positioned on the reinforcing bar 20 The tension fixing piece 510 is pulled out by its own tension force and the tension fixing piece 510 which is forcibly opened when the reinforcing bar 20 is inserted into the space portion 520 is returned to its original state by its own tension force As a result, Piece 510 is standing because the condition for holding the reinforcement 20, to which the stress distribution plate 200 is fixed.

As shown in FIG. 6A, the stress dispersing apparatus 100 of the present invention having the above-described structure is an opening for the purpose of forming an opening 11 for accommodating an entrance door, a window, and the like at the time of constructing the wall surface 10 The mold 1 is installed at the point and the reinforcing bars 20 are connected to each other in the transverse and longitudinal directions within the point where the wall 10 is formed. The stress dispersing apparatus 100 according to the present invention is positioned at the corner.

More specifically, before the concrete and the cement mortar are placed, the stress dispersing apparatus 100 is positioned outward from the corner of the mold 1 installed to form the opening 11, The stress distributing plate 200 is integrally formed on both sides of the outer surface of the stress dispersing plate 200 in such a state that the outer surface of the stress dispersing plate 200 is in contact with the reinforcing bars 20 provided so as to cross each other horizontally and vertically on the outer periphery of the die 1 So that the reinforcing bars 20 are inserted and fixed in the fixing part 500 equipped with the reinforcing bars.

More specifically, when the stress dispersing plate 200 is pushed in a state where the reinforcing bars 20 are positioned at the open end of the tension fixing piece 510 of the fixing unit 500, The reinforcing bars 20 are inserted into the space 520 with the fixing pieces 510 forced outwardly and the reinforcing rods 20 are inserted into the space portions so that the tension fixing pieces 510, The reinforcing bars 20 are fixed in a state where they are held by the tension fixing pieces 510 in the space portion 520. As shown in FIG.

At this time, the support plate 300, which is integrally extended to the outer circumferential edge of the stress dispersing plate 200 and bent outward, is in a state of being in contact with the outer surface of the die 1.

When the concrete and the cement mortar are poured into the space between the dies 1 in this state, the concrete and the cement mortar to be laid are filled with the space formed by the dies. At this time, (See FIG. 6B) in a state in which they are filled in the through holes 210 formed in the through holes 210 and the through holes 410 formed in the stress dispersion body 400. (See FIG. 6B)

At this time, the concrete and the cement mortar are smoothly inserted into the through-hole 210 provided in the stress dispersing plate 200, and the through hole 210 in the stress dispersing plate 400, The concrete and the cement mortar are introduced into the through hole 410 through the opening groove 420 provided at the tip end of the through hole 410 to be filled in the through hole.

When the concrete and the cement mortar have been put in a state as described above and a predetermined time has elapsed, a door frame is installed on the inner circumferential surface of the opening 11 after the form 1 is removed, and then a window or a door is provided. (See Fig. 6C)

When a stress is concentrated at the time of occurrence of such vibration and impact, cracks are generated with the corner 12 as a starting point. In the stress concentration The crack generated due to the edge 12 is buried in the wall surface 10 with the corner 12 as a starting point. The crack generated due to the corner 12 is diffused to the entire wall surface 10 with the corner 12 as a starting point. The stress is dispersed and lost in the stress dispersing apparatus 100, and the crack is blocked, so that the stress is not diffused to the entire wall surface 10.

More specifically, cracks are generated starting from the corner 12 due to the concentration of stress. When stress and cracks propagate in an arbitrary direction starting from the corner 12, The stress is dispersed and destroyed by colliding with the stress dispersing plate 200 having the shape of a semicircle embedded in the wall surface 10 and the stress dispersing body 400 and the crack is no longer diffused .

That is, since the stress dispersing plate 200 is formed of a curved surface of a semicircle, the crack is blocked by the stress dispersing plate 200, and the stress is no longer diffused. The stress dispersing plate 200 is dispersed to both sides in the tangential direction while being collided with the inner surface of the stress dispersing plate 200.

In addition, since the stress dispersion body 400 integrally extending on the inner surface of the stress dispersing plate 200 has a circular shape, the stress generated by the stress dispersing body 400 has an outer surface, that is, a circular shape So that the stress and cracks to be diffused to the entire wall surface can be effectively blocked and dissipated by the fracture in the stress dispersing plate 200. [

As another embodiment of the present invention, as shown in FIG. 8, the stress dispersion body 400 may be used in a state in which the stress dispersion body 400 is integrally extended to the inside and the outside of the stress injection plate 200. So that the stress distribution can be further increased when the inner and outer plates 400 are provided inside and outside the stress distribution plate 200.

100: Stress distribution device 200: Stress distribution plate
210: through hole 300: support pin
400: Stress dispersion element 410: Through hole
420: open groove 500:
510: a tension fixing piece 520:

Claims (8)

The cracks generated from the corners are prevented from diffusing further, and a semicircular shape is formed so as to disperse and extinguish the stress causing the cracks, so that the concrete and the cement mortar can be penetrated through A stress distribution plate provided,
A support plate extending integrally with both end portions of the stress distribution plate;
The stress dispersing element is formed on the inner surface of the stress distributing plate having the semicircular shape so as to disperse the stress in the portion except the through hole so that the stretchable structure is provided on the wall surface to form a window or a door at the time of construction. And a stress dispersing device embedded in the concrete to be installed with the corner of the open opening as a starting point to block cracks generated from the edges,
A stress distribution plate having a through-hole communicating with the stress dispersing plate, and when the stress is generated, the stress distribution plate has a cylindrical shape so that the stress can be dispersed along the curved surface, And an opening groove formed in the distal end portion of the dispersion body so as to be inwardly protruded from a front end surface thereof so that the concrete and the cement mortar laid in the through hole can be filled smoothly, And a shape-retaining plate for preventing a shape change of the stress-distribution plate from being formed in the same curved surface as the stress-distribution plate at an intermediate point of the lower end, wherein two stress distribution plates are connected to each other at positions corresponding to both sides of the upper surface of the stress- The stress distribution plate is integrally provided on both sides of the outer side of the stress distribution plate, Additional stress balancer for crack prevention, characterized in that the coupling to the fixed plate so as to be fixed by a simple stress distribution fitted to the reinforcement. delete delete delete delete The method according to claim 1,
Wherein the stress dispersing member is formed so as to be in a state of being in communication with the inner and outer surfaces of the stress distribution plate integrally. delete The method according to claim 1,
Wherein the fixing portion comprises a tension fixing piece having a space portion so that the reinforcing bars can be inserted and fixed while the front portion is opened with synthetic resin as a material.

Images