KR102614028B1 - Installed pipe structure installed in transfer layer of building and construction method thereof - Google Patents

Abstract

The present invention relates to a facility piping structure and construction method constructed on the transition floor of a building. More specifically, the present invention relates to a transition slab of a transition floor in a state accommodated in a pipe duct installed on the outer surface of the upper wall of the transition floor of a building. As a facility pipe that penetrates upward and downward, a bending portion bent at a certain angle is formed in the facility pipe so that the facility pipe penetrating the transition slab does not interfere with the transition beam in the lower layer of the transition layer, and the bending portion is formed in the upper layer of the transition layer. It relates to the facility piping structure constructed on the transition floor of a building with special features.
According to the present invention, when constructing the transition floor of a building, the transition slab and transition beam are constructed using the same construction method as the existing one, but since the facility pipe constructed on the transition layer is constructed by bending at a certain angle on the upper side of the transition slab, the transition slab is constructed. Equipment piping passing through may not interfere with the transition beam.

Description

Equipment pipe structure installed in the transfer layer of a building and its construction method {Installed pipe structure installed in transfer layer of building and construction method thereof}

The present invention relates to a facility piping structure constructed in the transition layer of a building. In particular, the transition layer of a building can be constructed by bending the facility piping at a certain angle so that the facility piping passing up and down through the transition slab does not interfere with the transition beam. It relates to the facility piping structure and construction method to be constructed.

In general, the arrangement of columns at the top and bottom may be different depending on the purpose of the building or for the purpose of changing the elevation. In this case, a transfer layer system is used to safely transfer the axial force and horizontal load of the upper floor to the lower floor for structural stability. will be adopted.

That is, in a residential-commercial building or an apartment designed with an underground parking lot, the lower lower floor is formed as an office, shopping mall, resident convenience facility or parking lot with a column-shaped ramen structure, and the upper upper floor is formed as an apartment (main building) with a wall structure.

At this time, most of the walls of the high-rise apartment and the column columns of the low-rise do not match, so a transition layer is formed at the upper floor of the low-rise where the apartment begins in order to stably transfer the load from the upper to the lower.

Typically, the transition layer is constructed by arranging reinforcing bars on site, forming a form surrounding the placed reinforcing bars using plywood or square lumber, installing system supports or braces at the bottom, and then pouring concrete inside the form. .

On the other hand, a pipe duct is a structure in which a space is formed for various pipes in mechanical equipment (main pipes that rise vertically to the top floor). The inside of the pipe duct contains water supply pipes, drainage pipes, sewage pipes, and Firefighting pipes, etc. are accommodated.

Figures 1 and 2 are cross-sectional views showing the construction state of facility piping constructed on the transition floor of a conventional building.

Referring to FIG. 1, conventionally, when constructing facility piping on the transition floor of a building, a pipe duct ( When the equipment pipe 100 accommodated inside the pipe duct (P.D) penetrates the transition slab 12 of the transition layer 10 up and down and descends from the transition layer 10 to the lower layer 10b, which has a ramen structure, There was a problem with the facility pipe 100 interfering with the transition beam 13 poured in the lower layer 10b.

In this way, since the equipment pipe 100 is blocked by the transition beam 13 of the lower layer 10b, in order to solve this, the equipment pipe 100 penetrates the transition beam 13 or the cross-sectional width (L) of the transition beam 13 is changed. It is necessary to reduce the transition beam (13) by pouring construction.

However, it is very difficult in construction to construct the transition beam 13 by allowing the facility pipe 100 to penetrate the transition beam 13 or reducing the cross-sectional width (L) of the transition beam 13.

Accordingly, in order to solve the above-mentioned problem, recently, as shown in FIG. 2, the facility pipe 100 constructed through the transition slab 12 of the transition layer 10 penetrates the transition beam 13 or the transition beam 13. ) A method of pouring construction by forming a gap of about 200 mm to about 300 mm between the transition slab (12) and the transition beam (13) has been proposed.

However, compared to the method of pouring and constructing the transition beam 13 integrally with the existing transition slab 12, the floor height increases by about 400 mm to about 500 mm, causing a problem that affects the height of the building.

In other words, if the floor height becomes higher than the existing construction method, not only does a problem arise in which stair construction becomes difficult when planning the stairs for the corresponding floor, but also it is difficult to reflect actual construction because the transition slab (12) and transition beam (13) are separated from each other. there is a problem.

Korean Registered Utility Model Publication No. 20-0139081 (announced on April 1, 1999)

The problem of the present invention, which was devised to solve the above-mentioned problems, is to construct the transition floor of a building, where the transition slab and transition beam are constructed using the same construction method as the existing one, but the facility pipe constructed on the transition floor is installed on the upper side of the transition slab. The purpose is to provide a facility piping structure and construction method for construction on the transition floor of a building where the facility piping penetrating the transition slab may not interfere with the transition beam because it is constructed by bending at a certain angle.

In addition, the problem of the present invention is that since the facility pipes constructed on the transition floor of a building are bent at a certain angle on the upper side of the transition slab, there is no need to thicken the existing floor finishing material constructed on the upper surface of the transition slab, thereby eliminating the need to thicken the existing floor finishing material. The purpose is to provide a facility piping structure and construction method to be constructed on the transition floor of a building that can reduce the floor height compared to the construction method of .

The present invention, which was developed to achieve the above problem, is a facility piping structure constructed on the transition floor of a building, and is accommodated in a pipe duct installed on the outer surface of the upper wall of the transition floor of the building. As a facility pipe constructed to penetrate the transition slab up and down, a bending portion bent at a certain angle is formed in the facility pipe so that the facility pipe penetrating the transition slab does not interfere with the transition beam of the lower layer of the transition layer, and the bending portion is formed in the transition section. It is characterized by being formed in the upper layer of the layer.

The bending portion of the facility pipe is characterized in that it is formed inside the pipe duct.

The facility pipe includes a first bending portion bent at a predetermined angle toward the outside of the wall, and a second bend formed at a rear end of the first bending portion and bent at a predetermined angle toward the transition slab so that the facility pipe penetrates the transition slab. It is characterized by including wealth.

A floor finishing material is further constructed on the upper surface of the transition slab, and the second bending portion is formed between the floor finishing material and the transition slab.

The bending part is characterized as a piping elbow that connects each unit pipe to each other.

In addition, the present invention is a method of constructing equipment piping constructed on the transition floor of a building, wherein the equipment piping penetrating the transition slab of the transition layer is installed at a certain angle on the upper side of the transition slab so that it does not interfere with the transition beam of the lower part of the transition layer. It is characterized by being bent and constructed in a curved shape.

In the present invention, in constructing the transition floor of a building, the transition slab and transition beam are constructed using the same construction method as the existing one, but the facility pipe constructed on the transition layer is constructed by bending at a certain angle on the upper side of the transition slab, so it does not penetrate the transition slab. There is an effect that the equipment piping does not interfere with the transition beam.

In addition, in the present invention, since the facility pipes constructed on the transition floor of a building are constructed by bending at a certain angle on the upper side of the transition slab, there is no need to increase the thickness of the existing floor finishing material constructed on the upper surface of the transition slab, thereby eliminating the need for existing construction. Compared to other methods, it has the effect of reducing floor height.

Figures 1 and 2 are cross-sectional views showing the construction state of equipment piping constructed on the transition floor of a conventional building;
Figure 3 is a cross-sectional view showing the facility piping structure constructed on the transition floor of a building according to an embodiment of the present invention;
Figure 4 is a cross-sectional view showing the facility piping structure constructed on the transition floor of a building according to another embodiment of the present invention;
Figure 5 is an enlarged view showing an example of a bending portion in a facility piping structure constructed on the transition floor of a building according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the facility piping structure constructed on the transition floor of a building according to the present invention will be described in detail with reference to the attached drawings.

Figure 3 is a cross-sectional view showing the facility piping structure constructed on the transition floor of a building according to an embodiment of the present invention.

Referring to FIG. 3, the facility piping structure constructed on the transition floor of a building according to a preferred embodiment of the present invention is the structure of the wall 11 poured into the upper part 10a, which is a wall-type structure, on the transition floor 10 of the building. Regarding the structure and construction method of the facility pipe 100, which is accommodated inside the pipe duct (P.D) installed on the outer surface and constructed vertically through the transition slab 12 of the transition layer 10 It's an invention.

Here, when the facility pipe 100 is constructed by penetrating the transition slab 12 of the transition layer 10, the transition beam 13 poured into the lower layer 10b, which has a ramen structure, in the transition layer 10 of the building. Since there is a problem of interference with the equipment pipe 100, a bending portion 110 bent at a certain angle (θ) is formed in the equipment pipe 100 so that the equipment pipe 100 does not interfere with the transition beam 13. This bending portion 110 is formed on the upper side of the transition slab 12, that is, in the upper layer 10a of the transition layer 10.

And, the bending angle (θ) of the bending portion 110 is preferably set to about 30° to about 45°. When the bending angle (θ) is less than about 30°, the facility pipe 100 penetrates the transition slab 12 without being sufficiently bent, causing a problem of the facility pipe 100 interfering with the transition beam 13. You can.

In addition, when the bending angle (θ) exceeds about 45°, the facility pipe 100 is excessively bent, so if the facility pipe 100 is a water supply/drain pipe, the flow of fluid flowing inside the pipe is reduced. may occur.

At this time, the bending portion 110 formed in the facility pipe 100 is preferably formed inside the pipe duct (P.D.) before the facility pipe 100 penetrates the transition slab 12.

Meanwhile, the facility pipe 100 includes a first bending portion 110a bent at a certain angle θ toward the outside of the wall 11, and a transition slab 12 formed at the rear end of the first bending portion 110a. It may be configured to include a second bending portion 110b bent at a certain angle θ toward the transition slab 12 so that the facility pipe 100 penetrates.

Here, the first bending portion 110a and the second bending portion 110b formed in the facility pipe 100 are formed on the inside of the pipe duct (P.D.) before the facility pipe 100 penetrates the transition slab 12. It is desirable to form

To elaborate, when the cross-sectional width L1 of the transition beam 13 is narrow and the gap between the transition beam 13 and the pipe duct P.D is sufficiently secured, the first bending portion 110a is formed on the inside of the pipe duct P.D. ) and the second bending portion 110b are formed, allowing the equipment pipe 100 to penetrate up and down the transition slab 12, and the height of the floor finishing material 12a installed on the upper surface of the transition slab 12 ( This has the effect of eliminating the need to change the thickness.

Figure 4 is a cross-sectional view showing the facility piping structure constructed on the transition floor of a building according to another embodiment of the present invention.

Referring to FIG. 4, when the cross-sectional width (L1) of the transition beam is wider than the cross-sectional width (L2) of the pipe duct (P.D.) and the gap between the transition beam (13) and the pipe duct (P.D.) is not secured, the pipe It is desirable to construct the floor finishing material 12a on the upper surface of the transition slab 12 outside the duct (P.D.) to be about 100 mm thicker than the thickness of the previously installed floor finishing material 12a.

At this time, the second bending portion 110b formed in the facility pipe 100 is formed between the floor finishing material 12a and the transition slab 12.

To elaborate, the first bending portion 110a of the facility pipe 100 is formed on the inside of the pipe duct (P.D), and then the facility pipe 100 is exposed to the outside of the pipe duct (P.D) and is applied to the floor finishing material. A second bending portion 110b is formed between (12a) and the transition slab 12.

At this time, since the thick floor finishing material 12a covers the facility pipe 100, the facility pipe 100 is not exposed in the upper part of the transition layer 10, and the floor height is increased by at least about 300 mm compared to the existing construction method. You can achieve a reduction effect.

Figure 5 is an enlarged view showing an example of a bending portion in a facility piping structure constructed on the transition floor of a building according to an embodiment of the present invention.

Referring to FIG. 5, the bending portion 110 may be a piping elbow 111 that connects unit pipes 100a, 100b, and 100c to each other.

To elaborate, the unit pipes 100a, 100b, and 100c constituting the facility pipe 100 include a first pipe 100a accommodated inside the pipe duct P.D., and a second pipe penetrating the transition slab 12. It may be configured to include (100b) and a connection pipe (100c) connecting the first pipe (100a) and the second pipe (100b).

Here, in order to connect one end of the first pipe (100a) and one end of the connecting pipe (100c), one pipe elbow 111 bent at an angle of about 30° to about 45° is used to connect the pipe. In order to connect one end of the second pipe 100b and the other end of the connection pipe 100c, another pipe elbow 111 is bent at an angle of about 30° to about 45°. It can be joined.

Hereinafter, the construction method of the equipment piping constructed in the transition layer of the building according to the present invention will be described. The upper layer 10a of the building transition layer 10 is accommodated in the pipe duct (P.D.) installed on the outer surface of the wall 11. The upper side of the transition slab (12) so that the equipment pipe (100), which is constructed by penetrating the transition slab (12) of the transition layer (10) upward and downward, does not interfere with the transition beam (13) of the lower layer of the transition layer (10). The facility pipe 100 is constructed by bending it in a shape bent at a certain angle.

In the above, the present invention has been described based on preferred embodiments, but the technical idea of the present invention is not limited thereto, and modifications or modifications may be made within the scope set forth in the claims by those skilled in the art. It is clear to everyone that such modifications or changes fall within the scope of the appended patent claims.

10: transition layer 10a: upper layer
10b: lower layer 11: wall
12: Transition slab 12a: Floor finishing material
13: Transition beam 100: Facility piping
100a, 100b, 100c: unit piping
110: bending part 110a: first bending part
110b: second bending portion 111: plumbing elbow
PD: pipe duct

Claims (6)

As a facility pipe constructed to penetrate vertically through the transition slab of the transition layer while being accommodated in a pipe duct installed on the outer surface of the upper wall of the transition layer of a building,
A bending portion bent at a certain angle is formed in the facility pipe so that the facility pipe passing through the transition slab does not interfere with the transition beam of the lower layer of the transition layer, and the bending portion is formed in the upper layer of the transition layer,
The facility pipe includes a first bending portion bent at a predetermined angle toward the outside of the wall, and a second bend formed at a rear end of the first bending portion and bent at a predetermined angle toward the transition slab so that the facility pipe penetrates the transition slab. A facility piping structure constructed in the transition layer of a building, wherein a floor finishing material is further constructed on the upper surface of the transition slab, and the second bending portion is formed between the floor finishing material and the transition slab. According to paragraph 1,
A facility piping structure constructed in the transition layer of a building, wherein the bending portion of the facility piping is formed inside the pipe duct. delete delete According to paragraph 1,
The bending part is a facility piping structure constructed on the transition floor of a building, characterized in that the bending part is a piping elbow that connects each unit pipe to each other. As a construction method for equipment piping constructed on the transition floor of the building of paragraph 1,
Equipment constructed on the transition floor of a building, characterized in that the equipment pipe penetrating the transition slab of the transition floor is constructed by bending at a certain angle on the upper side of the transition slab so that it does not interfere with the transition beam of the lower layer of the transition floor. Piping construction method.

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