KR102175266B1 - A piping connector for anti-seismic - Google Patents

Abstract

The present invention relates to a connector for an interlayer standing pipe for earthquake resistance, which is installed by penetrating an interlayer wall of a building and connected to a standing pipe placed between floors of the building so as to indirectly fix and connect the standing pipes placed in each floor to the interlayer wall to be standardized. According to the present invention, the connector for an interlayer standing pipe for earthquake resistance comprises: a standing connection pipe unit which is installed by penetrating a construction unit of the interlayer wall formed between floors of the building to connect an upper standing pipe formed on an upper side of the interlayer wall and a lower standing pipe formed on a lower side of the interlayer wall to communicate with each other; and a fixing base unit which is settled and fixed to an upper surface of the interlayer wall to fix the standing connection pipe unit to be penetrated. The fixing base unit has a standing support pipe formed to wrap around an external wall of the standing connection pipe unit in the center of a fixing support plate by a ring-shaped concentric structure.

Description

A piping connector for anti-seismic}

The present invention relates to a seismic-resistant interfloor upright pipe connector, and more particularly, it is installed through the interlayer wall of a building and connected to the upright pipes arranged between the floors of the building, and the upright pipes arranged on each floor are standardized. It relates to a seismic upright pipe connector for seismic resistance that is indirectly fixed and connected to the interlayer wall.

Buildings consisting of a multi-story structure, such as a building or apartment, are constructed with upright piping to connect each floor.

For the upright pipe, a through sleeve is installed to allow the upright pipe to penetrate into the slab (floor surface of a reinforced concrete structure) during the construction of the building, and then the through sleeve is embedded in the slab by pouring concrete to construct the slab. After making it possible, the upright pipe is installed through the multiple layers using a through sleeve penetrating each layer.

On the other hand, in the process of constructing the slab or embedding the sleeve, the sleeve is not accurately positioned at the design position of the upright piping, and interlayer deviation often occurs.

It is very difficult for the operator to correct the location of such a deviation in the construction of the upright piping between the floors, and in the case of this deviation, the airtightness of the upright piping cannot be guaranteed.

In particular, in the case of a multi-storey building, if there is even a slight difference in construction between floors, the deviation is very large due to the multi-story structure, so stability is very poor. It is important that the sleeve is buried in the correct position, as this may cause difficulty.

Therefore, in relation to this problem, in Korean Utility Model Registration No. 406563, a separate fixing frame for fixing the upright pipe is provided, and the fixing frame is mounted on the sleeve so that it can flow, so that the position of the upright pipe can be fixed by flowing to the side. It was proposed to have.

KR 10-1326388 B1 KR 10-1637197 B1

The object of the present invention, conceived to solve the above problems, is to be installed through the interlayer wall of the building, and in connection with the upright pipe disposed between the lower layer and the upper layer of the building, Depending on the height of the joints of the upright pipes, the elevation of the upright connection pipe part is lifted along the construction opening to adjust the height of the joints with the upright pipes. The purpose is to provide a seismic interlayer upright piping connector to prevent a phenomenon in which the fixed state is deteriorated by vibration provided in the longitudinal direction.

The above object is achieved by the following configuration provided in the present invention.

The seismic interlayer upright piping connector according to the present invention,

An upright connection pipe installed to penetrate through the construction opening of the interlayer wall formed between the layers of the building and connect the upper upright pipe formed on the upper side of the interlayer wall and the lower upright pipe formed on the lower side of the interlayer wall in communication;

It is seated and fixed on the upper surface of the interlayer wall, and comprises a fixed base portion for fixing the upright connection pipe portion through,

The fixed base portion is formed in a form in which a standing support pipe surrounding the outer wall of the upright connection pipe portion in an annular concentric structure is formed in the center of the fixed support plate seated and fixed on the upper surface of the interlayer wall,
An assembly hole for assembling the granular connection pipe part in communication is formed in the central part of the fixed support plate constituting the fixed base part, and a fixing hole which is an entry path of the anchor bolt fixed to the interlayer wall is formed on the outside,
The upper and lower ends of the upright connecting pipe part protrude to the upper and lower portions of the interlayer wall, respectively, and groove joints are formed at the protruding upper and lower portions, respectively, and the upright connection pipe part of the upper upright pipe in which a groove joint is formed through a groove joint. Each of the lower part and the upper part of the lower upright pipe is connected with a groove joint structure,
A screw fastening part is formed in the middle of the outer wall of the upright connector part, and a screw fastening part corresponding to the screw fastening part of the upright connector part is formed in the inner diameter of the upright support pipe surrounding the upright connector part, so that the upright connector part supports the upright It is characterized in that it is configured to set the height of the joint between the lower and upper upright pipes by raising and lowering according to the amount of screwing with the pipe.

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As described above, in the present invention, in connecting the lower upright pipe formed at the lower part of the interlayer wall and the upright pipe formed at the upper part of the interlayer wall through the upright connection pipe part, the upright connection pipe part through the upright support pipe A fixed base portion fixed in an annular concentric structure is added so that a fixed state of the upright connection pipe portion is formed by the fixed base portion.

And, in this embodiment, a fastening part is provided between the upright connection pipe part and the upright support pipe fixing it in an annular concentric structure, and the upright pipe part moves up and down according to the fastening distance with the upright support pipe, so that the lower upright pipe and the upper It is configured so that the height of the joint of the upright pipe can be set on site.

Therefore, according to the present invention, according to the field situation including the joint height of the lower and upper upright pipes, it is possible to establish and change the joint height of the upright connection pipe part, so that a standard connection between the lower upright pipe and the upper upright pipe is possible. .

In particular, the upright connecting pipe connecting the upper and lower upright pipes is surrounded by the outer wall of the upright support pipe of the fixed base and is fixed through fastening.When an earthquake occurs, the upright connecting pipe is vertically or horizontally The phenomenon of flow in the direction is suppressed, and as a result, deformation or damage caused by earthquakes can be prevented by fixing upright pipes in a standardized manner even when an earthquake occurs.

In addition, in this embodiment, by not directly providing a fastening part on the outer wall of the upright connection pipe part, but by adding a hollow reinforcing block and providing a fastening part to the hollow reinforcing block, the granular connection pipe part is fixed while adopting a thin-walled granular connector part Since it is stably fastened and fixed to the base part, it has the specificity that improved seismic performance can be exhibited.

1 is a view showing the construction state of the upright pipe through the seismic interlayer upright pipe connector proposed as an embodiment in the present invention,
2 and 3 show a detailed configuration of an interlayer upright pipe connector for seismic resistance proposed as an embodiment in the present invention,
4 to 6 are sequentially showing the construction state of the upright piping through the seismic interlayer upright piping connector proposed as an embodiment in the present invention,
7 and 8 show a detailed configuration of an interlayer upright pipe connector for seismic resistance proposed as another embodiment in the present invention and a construction state of the upright pipe through it,
9 is an enlarged view of the configuration of portion'A' in FIG. 8.

Hereinafter, with reference to the accompanying drawings will be described in detail the interlayer upright pipe connector for seismic resistance proposed as a preferred embodiment in the present invention.

Figure 1 shows the construction state of the upright piping through the seismic interlayer upright piping connector proposed as an embodiment in the present invention, Figures 2 and 3 are the seismic interlayer granularity proposed as an embodiment in the present invention It shows the detailed configuration of the pipe connector, and Figures 4 to 6 sequentially show the construction state of the upright pipe through the seismic interlayer upright pipe connector proposed as an embodiment in the present invention.

The seismic cross-floor upright pipe connector 1 proposed as a preferred embodiment in the present invention includes the upright pipes 110 and 120 arranged on the floor and the floor of the building as shown in FIG. It is a type of fixed connector that performs a function of fixedly connecting through the interlayer wall 200.

The seismic interlayer upright pipe connector 1 is installed to penetrate through the construction hole 210 formed in the interlayer wall 200 formed between the lower layer and the upper layer of the building, and the upper upright pipe formed on the upper layer of the interlayer wall 200 It includes a granular connection pipe portion (10) connecting the lower upright pipe 110 formed in the lower portion of the interlayer wall 200 and 120 in communication.

The upright connection pipe part 10 according to the present embodiment is composed of a hollow pipe body having groove joints 11 and 12 integrally formed with grooved grooves at the lower and upper portions as shown in FIGS. 1 to 3, and the Groove joints 111 and 121 are formed to correspond to the upper and lower ends of the upright pipes 110 and 120.

And the upright connection pipe portion 10 is bound in a groove joint structure with the upper and lower ends of the upright pipes 110 and 120 through the groove joint 130, and the upper upright pipe 120 formed on the upper part of the interlayer wall 200 And the lower upright pipe 110 formed under the interlayer wall 200 are connected in communication with each other.

Thus, the lower upright pipe 110 formed under the interlayer wall 200 and the upper upright pipe 220 formed at the upper part of the interlayer wall 200 are the upright connecting pipe part 10 penetrating the interlayer wall 200 It is connected through a grooved joint structure that enables elastic flow and absorbs vibration through elastic flow in case of an earthquake.

On the other hand, in this embodiment, the upright connecting pipe portion 10 connecting the upright pipes 110 and 120 through the grooved joint 130 is installed in an elevating structure on the interlayer wall 200, and a connection as shown in FIG. 5 is required. According to the height of the joint between the lower upright pipe 110 and the upper upright pipe 120, the height of the upright connection pipe part 10 is easily adjusted to secure precision according to construction.

In particular, in the present embodiment, the upright connecting pipe portion 10 connecting the lower upright pipe 110 and the upper upright pipe 120 is fixedly formed through the interlayer wall 200 so as to be fixed in the left and right transverse directions when an earthquake occurs, By preventing the phenomenon that the up-and-down pipes 110 and 120 flow up and down by vibrations generated in the vertical and vertical directions, the connection between the up-and-down pipes 110 and 120 and the upright connection pipe 10 is Prevents the phenomenon of becoming poor.

To this end, the present embodiment further includes a fixed base portion 20 fixed to the upper surface of the interlayer wall 200 to formally fix the upright connection pipe portion 10 passing through the interlayer wall 200.

Here, the fixed base portion 20 is a fixed support plate 21 that is seated and fixed on the upper surface of the interlayer wall 200, and is formed to penetrate up and down in the central portion of the fixed support plate 21 to form the interlayer wall 200. It includes a granular support pipe 22 surrounding the outer wall of the passing granular connection pipe portion 10 in an annular concentric structure.

In this embodiment, the standing support pipe 22 is arranged upright at the center of the fixed support plate 21 on which the assembly hole 21a is formed, and then the standing support pipe 10 is welded to the edge of the assembly hole 21a. By fixing, the fixed base part 20 in which the standing support tube 22 is arrange|positioned in the center part of the fixed support plate 21 is formed.

In addition, a plurality of fixing holes 21b are formed outside the fixing support plate 21, so that the fixing support plate 21 seated on the upper surface of the interlayer wall 200 enters and fixes the fixing hole 21b. It is fixedly fixed to the upper surface of the interlayer wall 200 through the anchor bolt (B).

In addition, the upright connection pipe portion 10 is wrapped in an annular concentric structure through the upright support pipe 22 formed on the fixed base portion 20 and is stably fixed in the left and right transverse directions.

In this embodiment, as shown in Fig. 5, a raised and lowered assembly structure is provided between the concentrically assembled upright connection pipe portion 10 and the upright support pipe 22, so that the upright pipes 110 and 120 are assembled. 10) makes it possible to adjust the height at the site according to the construction conditions including the construction height of the lower upright pipe 110 and the upper upright pipe 120.

To this end, in this embodiment, an inner diameter fastening portion 22a is formed on the inner diameter surface of the upright support pipe 22, and an inner diameter formed on the upright support pipe 22 is formed on the outer diameter surface of the upright connection pipe portion 10 facing it. Each of the outer diameter fastening portions 13b that are fastened in correspondence with the fastening portions 22a are formed, so that the upright connecting pipe portion 10 penetrating the upright support tube 22 is fastened and fixed in the upright support tube 22. .

As in the present invention, the upper and lower upright pipes 120 and the lower upright pipes 110 through a groove joint 130 through a grooved joint structure connected through the upright connection pipe portion 10 through fastening to the fixed base portion 20 When fixed, as shown in Fig. 6, the granular connection pipe part 10, which is wrapped with the outer diameter of the granular support pipe 22, is stably fastened in the vertical direction by fastening to prevent shaking in the vertical direction when an earthquake occurs. The vertical height is adjusted according to the fastening distance with the standing support pipe 22.

Accordingly, according to the present invention, the up-and-down connection pipe portion 10 and the up-and-down pipes 110 and 120 connected up and down through it are stably fixed up and down to the fixed base portion 20 so as to prevent the phenomenon from flowing up and down when an earthquake occurs.

In particular, in the present invention, the outer diameter of the granular connection pipe part 10 is not physically pressed through the upright support pipe 22 to be fixed, but the granular connection pipe part 10 is fixed to the granular support pipe 22 through fastening. , When an earthquake occurs, the up-and-down connection pipe part 10 and the up-and-down pipes 110 and 120 connected up and down through the vibration provided in the vertical direction are prevented from flowing up and down, resulting in a poor connection between them.

In this way, when the granular connection pipe part 10 is fixed to the granular support pipe 22 formed on the fixed base part 20 through fastening, the granular connection pipe part 10 is prevented from being physically changed or ruptured by pressure on the outer diameter. As a result, it is possible to stably secure durability.

In addition, in this embodiment, the outer diameter fastening part is not directly formed on the outer wall of the upright connection pipe part 10, and the outer wall of the connection pipe part 10 is locally reinforced on the outer wall of the connection pipe part 10 as shown in FIG. By further arranging the hollow reinforcing block 13, the overall thickness of the connection pipe portion 10 is not formed to be thick, yet has a stable support.

In this way, if the hollow reinforcing block 13 is concentrically assembled and welded to the outer diameter of the granular connector 10 without thickening the thickness of the granular connector 10, the hollow reinforcing block 13 is formed The connection pipe part 10 is section reinforced.

In addition, the outer diameter of the hollow reinforcing block 13 installed in a concentric structure on the outer wall of the upright connection pipe portion 10 is formed with an outer diameter fastening portion 13b, and the hollow that is concentrically fixed to the outer wall of the upright connection pipe portion 10 The reinforcing block 13 is fixed to the inner diameter of the standing support pipe 22 formed on the fixing bracket 20 through fastening.

Therefore, the upright connection pipe portion 10 is locally reinforced in strength through the hollow reinforcing block 13 arranged concentrically on the outer wall, and the upright support pipe 22 through the hollow reinforcing block 13 reinforcing the outer wall. ) And it is fixed to be fixed, and adjusts the height of the connection pipe part 10 according to the amount of fastening.

Thus, the seismic interlayer upright pipe connector 1 according to the present embodiment, as shown in Fig. 5, the upright connection pipe part 10 is fastened according to the construction height of the upright pipes 110 and 120 formed on the lower layer and the upper layer. The height is adjusted up and down to be standardized.

In particular, the upper and lower upright pipes 120 and the lower upright pipes 110 are connected to each other in a groove joint structure, and the upright connection pipe portion 10 is directly fastened to the upright support pipe 22 formed on the fixed base portion 20 and is not fixed. No, since it is fastened to and fixed to the upright support pipe 22 through the hollow reinforcing block 13 assembled in a concentric structure, the upright connection pipe 10 or the connection pipe part 10 fixed to the upright support pipe 22 when an earthquake occurs. ) Is prevented from being damaged or the connection pipe part being deformed.

As a result, the present invention is the upright pipes (110, 120) and the upright connection pipe portion 10 connected in a groove joint structure is fastened by a fastening portion formed between the hollow reinforcing block 13 and the upright support pipe 22 As a result, the vertical flow is suppressed, and the outer diameter is enclosed by the upright support pipe 22 to suppress the occurrence of left and right flow, so that when an earthquake occurs, the up and down and left and right flows of the up and down pipes separated from the building are stably prevented.

7 and 8 show a detailed configuration of an interlayer upright pipe connector for seismic resistance proposed as another preferred embodiment in the present invention, and a construction state of the upright pipe through it, and FIG. 9 is a part'A' in FIG. It is to show the composition of the enlarged.

On the other hand, the upright pipe connector (1') proposed as another embodiment of the present invention, as shown in Figs. 7 to 9, to divide the outer diameter of the upright connector portion 10 and the upright connector portion 10 It includes a fixed base portion 30 wrapped and fixed.

Here, the fixed base part 30 is fixed to the upper surface of the interlayer wall 200 to formally fix the upright connection pipe part 10 passing through the interlayer wall 200. In this embodiment, the fixed base The part 30 is composed of two or more divided bases 31A and 31B, and the divided bases 31A and 31B have an arc-shaped divided support cover that divides the outer diameter surface of the granular connection pipe part 10 penetrating the interlayer wall. (32) is prepared to be upright.

At this time, each of the divided bases 31A and 31B is fixed to the upper surface of the interlayer wall 200 through anchor bolts B, and the divided divided bases 31A and 31B are attached to the assembly bolts B'passing through. The joint pieces 34 which are in close contact with each other are formed correspondingly.

Therefore, the divided bases 31A and 31B constituting the fixed base part 30 are mutually assembled by joint pieces 34 that are in close contact with each other by an assembly bolt B'to form a single structure, and a single structure The fixed base portion 30 formed of is fixed to be fixed to the upper surface of the interlayer wall through anchor bolts (B).

By the connection of the divided bases 31A, 31B, the granular connection pipe part 10 penetrating the interlayer wall 200 is attached to the divided support cover 32 of each divided base 31A, 31B forming a single structure. It is fixed in a state wrapped so that the outer diameter is divided.

In particular, in the present embodiment, the protruding jaws 33 are formed vertically apart on the inner wall of the divided support cover 32 of each of the divided bases 31A and 31B constituting the fixed base part 30, On the outer diameter surface of the granular connection pipe part 10 wrapped by the inner diameter surface of the support cover 32, an annular yaw protrusion 14 is formed correspondingly.

Here, the yaw protrusion 14 and the yodol shaft jaw 33 are formed of a triangle, trapezoidal, arc, tapered, etc. that are narrowed apart while entering each other as shown in FIG. 9, and the divided bases are in close contact with each other. The fixed clearance between the protruding rim 14 and the yodol shaft jaw 33 is reduced so that the fixed base part 30 and the upright connection pipe part 10 are formed in a fixed state.

Therefore, the annular yaw protrusions 14 formed on the outer diameter surface of the upright connecting pipe part 10 and the yaw protrusions 33 formed on the inner wall of each of the divided support covers 32 are assembled up and down so that they are attached in multiple stages. Form a state

Thus, in the present invention, by the divided support covers 32 formed on the divided bases 31A and 31B that are annularly connected, the granular connection pipe part 10 is wrapped in an annular shape by the divided bases 31A and 31B. It is supported from the left and right, and is stably fixed up and down by the yaw protruding rim 14 and the yaw protruding jaw 33 that are rallyed and shouldered in multi-stage vertically.

1, 1'. Seismic-resistant floor-standing piping connector
10. Upright connector section 11, 12. Groove joint section
13. Hollow reinforcement block 13a. Welding layer
13b. Outer diameter joint 14. Yaw protrusion
20. Fixed base part 21. Fixed support plate
21a. Assembler 21b. Fixed ball
22. Standing support tube 22a. Inner diameter fastener
30. Fixed base portion 31A, 31B. Split base
32. Split support cover 33, protruding jaw
34. Joint
B. Anchor bolt B'. Assembly bolt
110. Lower upright pipe 111. Groove joint
120. Upper upright pipe 121. Groove joint
130. Groove Joint
200. Interlayer walls 210. Construction area

Claims (5)

An upright connection pipe installed to penetrate through the construction opening of the interlayer wall formed between the layers of the building and connect the upper upright pipe formed on the upper side of the interlayer wall and the lower upright pipe formed on the lower side of the interlayer wall in communication; It is fixed to the interlayer wall, is configured to include a fixed base portion for fixing the granular connection pipe portion through,
The fixed base portion is formed in a form in which a standing support pipe surrounding the outer wall of the upright connection pipe portion in an annular concentric structure is formed in the center of the fixed support plate seated and fixed on the upper surface of the interlayer wall,
An assembly hole for assembling the granular connection pipe part in communication is formed in the central part of the fixed support plate constituting the fixed base part, and a fixing hole which is an entry path of the anchor bolt fixed to the interlayer wall is formed on the outside,
The upper and lower ends of the upright connecting pipe part protrude to the upper and lower portions of the interlayer wall, respectively, and groove joints are formed at the protruding upper and lower portions, respectively, and the upright connection pipe part of the upper upright pipe in which a groove joint is formed through a groove joint. Each of the lower part and the upper part of the lower upright pipe is connected with a groove joint structure,
A screw fastening part is formed in the middle of the outer wall of the upright connector part, and a screw fastening part corresponding to the screw fastening part of the upright connector part is formed in the inner diameter of the upright support pipe surrounding the upright connector part, so that the upright connector part supports the upright Seismic upright pipe connector for seismic resistance, characterized in that it is configured to set the height of the joint between the lower and upper upright pipes by raising and lowering according to the screw connection amount with the pipe. delete delete delete An upright connection pipe installed to penetrate through the construction opening of the interlayer wall formed between the layers of the building and connect the upper upright pipe formed on the upper side of the interlayer wall and the lower upright pipe formed on the lower side of the interlayer wall in communication;
It is fixed to the interlayer wall, is configured to include a fixed base portion for fixing the granular connection pipe portion through,
The fixed base portion is composed of two or more divided bases that are seated and fixed on the upper surface of the interlayer wall, and each divided base has an arc-shaped division support cover that divides and surrounds the outer diameter surface of the granular connection pipe portion penetrating the interlayer wall. Formed,
The upper and lower ends of the upright connecting pipe part protrude to the upper and lower portions of the interlayer wall, respectively, and groove joints are formed at the protruding upper and lower portions, respectively, and the upright connection pipe part of the upper upright pipe in which a groove joint is formed through a groove joint. Each of the lower part and the upper part of the lower upright pipe is connected with a groove joint structure,
On the inner wall of the divided support cover of each divided base constituting the fixed base part, the yaw protruding jaws are formed to be vertically spaced apart in multiple stages, and the yaw in the middle of the outer diameter surface of the granular connection pipe part wrapped by the inner diameter surface of each divided support cover An annular yaw protruding rim corresponding to the protruding jaw is formed, and a standardized assembly fixed state is formed between the inner wall of the divided support cover and the outer diameter surface of the upright connecting pipe part by the assembly between the yaw protruding jaw and the yaw protruding rim. It is configured to set the height of the connection between the lower and upper upright pipes by raising and lowering the installation height of the upright connection pipe in stages according to the annular yaw protrusion of the upright connection pipe part and the upper and lower rally of the yaw projections of the split support cover,
The divided bases constituting the fixed base part are assembled to form a single structure by wrapping the outer diameter surface of the upright connector part, and the fixed base part forming the single structure is fixed to the upper surface of the interlayer wall through anchor bolts. Seismic interfloor upright piping connector, characterized in that.

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