KR101047503B1 - Branch pipe socket - Google Patents

Abstract

PURPOSE: A branch socket is provided to perform the dense bonding structure which connects a branch pipe and a main pipe. CONSTITUTION: A plurality of trimmed grooves, which is gradually tapered off to outside, is formed in each edge of an external packing(20). The external packing is installed at end part of a small diameter side of a socket housing(10). The external packing is arranged not to be overlapped with trimmed grooves. A plurality of trimmed grooves is formed in each inner circumference of an inner packing(30). The inner packing is installed at end part of the big diameter side of the socket housing. The inner packing is arranged not to be overlapped with multiple trimmed grooves.

Description

Branch pipe socket

The present invention relates to a branch pipe socket used when connecting a small diameter pipe to a large diameter pipe, and in particular, to prevent the folding phenomenon occurs when the packing wing formed in the branch socket is connected to the pipe connected to the pipe flow The present invention relates to a branch pipe socket that maintains a tight coupling force even if a pipe flows due to ground subsidence or external impact while preventing rainwater or sewage from leaking out.

Generally, sewage pipes are installed underground to transfer the collected sewage to the sewage treatment plant. These sewer pipes are largely divided into main pipes and branch pipes. Branch pipes are pipes of relatively small diameter that are transferred from the sewage generating point to the main pipe. Refers to a relatively large diameter pipe that is conveyed by The main pipe is molded from concrete and the branch pipe is formed from synthetic resin, concrete or cast iron.

These sewer pipes are buried by connecting the branch pipes after drilling holes in the main pipe so that branch pipes connected at irregular distances and angles can be easily connected to the main pipes according to site conditions. In connecting the branch pipe, a branch pipe socket is used to overcome the errors in the ease of operation, watertightness, and connection direction.

The conventional branch pipe socket is formed with a diameter larger than the branch pipe so that the branch pipe can be inserted into one side, the other side is formed with the same diameter as the outer diameter of the inserted branch pipe. As the diameters of both ends are different, a stepped portion is formed at a boundary thereof, and the insertion is made up to the stepped when the branch pipe is inserted. In addition, the upper and lower portions of the stepped jaw is formed to prevent the flow prevention jaw is in close contact with the main tube when inserted into the hole of the main tube to prevent shaking in the vertical direction. In addition, the one end is inserted into the hole of the main tube is fitted with a packing to maintain the watertight. In addition, in order to reduce the error caused when drilling the hole of the main tube, by installing a plurality of wings of different sizes around the packing to overcome the standard gap or clearance gap between the hole and the socket to allow a slight change of direction. .

Here, the wing formed around the packing for watertightness is simply made larger than the diameter of the hole to achieve watertightness, but because the outer diameter of the wing is large, the bending occurs as the outer surface of the hole is bent while being forced to shrink. As the wing is bent as described above, there is a problem in that a portion that does not come into close contact with a hole drilled in the main tube, that is, a gap is generated and the sewage leaks out to the portion and loses the function of watertightness.

In addition, since the packing inserted into the socket is simply a form in which the elastic packing is pushed into one end of the socket, when a slight force is applied during the operation, the packing may be easily removed from the socket and the packing may be performed again.

In addition, the diameter is different depending on the type of the branch pipe, if the diameter is changed in this way, the inner diameter of the packing should also be changed, so all the packing for each size must be produced and provided accordingly, there is a problem that takes a lot of cost. In addition, when the diameter of the branch tube is significantly small, the thickness of the packing should be very thick, in this case there was a problem such as a large amount of material.

Therefore, the present invention has been made to solve the above problems, and the watertight coupling is made when the branch pipe socket is connected to the main pipe and the branch pipe, as well as to maintain the watertight coupling force even under external impact or ground subsidence. Its purpose is to provide a branch socket that can be easily connected to different types of pipes of different diameters.

Branch pipe socket according to the present invention for achieving the above object,

It has a pipe shape but both ends are formed with different diameters, one end having a small diameter is inserted into the hole of the main tube and the other end having a large diameter has a socket body into which the branch tube is inserted,

The outer diameter is formed larger than the hole of the main tube and the outer outboard packing formed with a plurality of cutout grooves that gradually widen toward the outside is installed at the end of the small diameter side of the socket body and arranged so that the cutout grooves do not overlap each other,

The inner diameter is formed to be smaller than the outer diameter of the branch pipe and the inner periphery is characterized in that the inward packing formed with a plurality of cutout grooves are installed in two or more layers at the end of the large diameter side of the socket body arranged so that the cutout grooves do not overlap each other.

In addition, the screw holes are formed at both ends of the socket body, and the outward packing and the inward packing are characterized in that the through-holes corresponding to the screw holes are formed to be coupled by the screws.

In addition, the socket body is characterized in that a plurality of protrusions projecting around the end of the inward packing is installed, and forming a screw hole in the coupling protrusion so that the inward packing is coupled by a screw.

In addition, the inward packing and the outgoing packing in close contact with the pressing ring, characterized in that coupled to the socket body with a screw.

In addition, the socket body is characterized in that it is coupled by forcing by forming a plurality of coupling pins corresponding to the through-holes of the outward packing and the inward packing at both ends.

The branch pipe socket according to the present invention having such a structure does not fold even when the packing is bent due to the cutting groove formed in the packing when the tube is inserted and does not generate a gap. It is effective to prevent leakage.

In addition, each connection part is flexible by a relatively wide packing, so that even if there is a flow of pipes during external impact or ground subsidence, the watertight coupling force is maintained and leakage does not occur.

In addition, even if an error occurs in the process of forming a hole in the main tube, the packing area maintains a tight coupling force even with a large error due to the large area and flexibility of the packing. It can be installed within the range, and there is no need for elaborate hole error, so assembly is easy and the construction time is very short.

In addition, the branch pipe and the socket body by the packing bent in the pipe insertion direction does not fall in the reverse direction has the effect of maintaining a strong bonding force.

1 is an exploded perspective view showing the structure of a branch pipe socket according to the first embodiment of the present invention.
Figure 2 is an exploded perspective view showing the assembly structure of the socket body and the packing according to the first embodiment of the present invention.
Figure 3 is a cross-sectional view showing a coupling state of the socket body and the packing according to the first embodiment of the present invention.
Figure 4 is a use state showing a state in which the branch pipe socket is connected according to the first embodiment of the present invention.
5 is an exemplary view showing a structure of a branch pipe socket according to a second embodiment of the present invention.
6 is an exemplary view showing a structure of a packing according to a third embodiment of the present invention.
7 is an exemplary view showing a structure of a crimping ring according to a fourth embodiment of the present invention.
8 is an exemplary view showing a coupling state of a crimping ring according to a fourth embodiment of the present invention.
9 is an exemplary view showing a structure of a socket body according to a fifth embodiment of the present invention.

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

1 is an exploded perspective view showing the structure of the branch pipe socket according to the first embodiment of the present invention, Figure 2 is an exploded perspective view showing the assembly structure of the socket body and the packing according to the first embodiment of the present invention, Figure 3 is a cross-sectional view showing a coupling state of the socket body and the packing according to the first embodiment of the present invention, Figure 4 is a use state diagram showing a state in which the branch pipe socket is connected according to the first embodiment of the present invention.

As shown in these figures, the branch pipe socket according to the present invention includes a socket body 10 connected between a hole 1 ′ and a branch pipe 2 of the main pipe 1, and the socket body 10 of the socket body 10. Each provided at both ends is composed of an outward packing 20 and an inward packing 30 to maintain a tight coupling.

The socket body 10 is formed in a tubular shape, and both ends thereof have different diameters, so that one end having a small diameter is inserted into the hole 1 'of the main tube 1 and the branch pipe is the other end having a large diameter. (2) is inserted. Therefore, the stepped portion 11 is formed at a portion having a different diameter, and the insertion is made up to the stepped portion 11 when the branch pipe 2 is inserted. Here the inner diameter of the side having a small diameter to have the same diameter as the inner diameter of the branch pipe (2) to be inserted to facilitate the flow of sewage and rainwater. In addition, an end inserted into the hole 1 ′ of the main tube 1 is formed as a curved surface in which both sides are slightly recessed to have the same curved surface as the inner circumference of the main tube 1. This is to prevent the socket body 10 from protruding into the main tube 1 when combined, and the rainwater and sewage flowing through the main tube 1 prevents interference with the socket body 10 to maintain a smooth flow. . In addition, the socket body 10 has an anti-flow jaw 12 protrudingly formed at an upper portion and a lower portion thereof, and the anti-flow jaw 12 is formed at the outer circumference of the main tube 1 when the socket body 10 is coupled to the main tube 1. This close contact prevents shaking in the vertical direction. The socket body 10 has a plurality of threaded holes 13 for coupling the outward packing 20 and the inward packing 30 to both ends thereof at equal intervals.

The outward packing 20 has a thin ring shape, the inner diameter of which is equal to the inner diameter of the small diameter side of the socket body 10, the outer diameter of which is slightly larger than the hole 1 ′ of the main tube 1. Is formed. And the outer periphery is formed with a plurality of cutting grooves 21 which are gradually widened toward the outer side is formed at equal intervals to prevent bending and folding when the edge is bent and reduced when inserted into the main tube (1). In addition, a plurality of through-holes 23 corresponding to the screw holes 13 of the socket body 10 are formed around the inner circumference and are coupled to the socket body 10 with screws S. The outward packing 20 is installed at least two overlapping but arranged so that the cutting grooves 21 do not overlap each other. This is to close the other outgoing packing 20 in close contact with the gap generated by the cutting groove (21).

The inward packing 30 has a thin ring shape and its outer diameter is the same as that of the larger diameter side of the socket body 10, and the inner diameter thereof is formed to have a smaller diameter than the outer diameter of the branch pipe 2. And the inner periphery is formed by a plurality of cutting grooves 31 are formed at equal intervals so that the cutting groove 31 is opened when inserting the branch pipe is smooth insertion. In addition, a plurality of through-holes 33 corresponding to the screw holes 13 of the socket body 10 are formed on the outer circumference thereof and coupled to the socket body 10 with screws S. At least two such inward packings 30 are installed to overlap each other, but the cutout grooves 31 are arranged so that they do not overlap each other, and the inward packings 30 closely contact the gaps generated by the cutout grooves 31.

Referring to the installation process of the branch pipe socket according to the present invention having such a structure as follows.

First, the small diameter side of the socket body 10, that is, the outward packing 20 is inserted into the main pipe (1), but the flow preventing jaw 12 of the socket body 10 is positioned in the upper and lower state Insert the end of the socket body 10 is inserted into the curved surface of the inner diameter of the main tube (1) to form the same curved surface. In this process, the outer periphery of the outward packing 20 which is larger than the hole 1 'of the main tube 1 is bent and inserted into the hole 1' of the main tube 1, with a plurality of cutouts opening toward the outside. By 21, they are bent without being folded together. In addition, the gap between the cutting groove 21 is closed by the other outgoing packing 20 in close contact is made of a tight coupling. The socket body 10 coupled as described above is in close contact with the outer surface of the main tube 1 at the upper and lower flow preventing jaw 12 to prevent shaking.

Next, the branch pipe 2 is inserted into the large diameter side of the socket body 10, that is, the portion where the inward packing 30 is installed. In this process, while the inner diameter of the inward packing 30 smaller than the outer diameter of the branch pipe 2 is expanded, the branch pipe 2 is forcedly inserted. At this time, the inner circumference of the inward packing 30 has a plurality of cutout grooves ( 31) it is naturally expanded and inserted. The gap between the cutout groove 31 that is opened here is closed by another inward packing 30 in close contact with the watertight coupling.

FIG. 5 is a view illustrating a structure of a branch pipe socket according to a second embodiment of the present invention. As shown in the drawing, the inward packing 30 and the outward packing 20 may be installed without a separate screw. It is a structure that can be combined with).

Instead of screw holes at both ends of the socket body 10, a plurality of coupling pins 15 are formed to protrude, but an extension 16 is formed at the end thereof. The coupling pin 15 has a diameter the same as or slightly smaller than the through holes 23 and 33 of the outward packing 20 and the inward packing 30. Therefore, when the coupling pin 15 of the socket body 10 is inserted into the through holes 23 and 33 of the outward packing 20 or the inward packing 30, the through hole 23 ( The inward packing 30 and the outward packing 20 which are penetrated and inserted while the 33 is forcibly expanded, the through holes 23 and 33 are reduced by the self restoring force and are caught by the extension 16 so that the socket body 10 Does not depart from By such a structure, the outward packing 20 and the inward packing 30 can be attached quickly and simply.

6 is an exemplary view showing a structure of a packing according to a third embodiment of the present invention, as shown in the figure may be configured by forming a plurality of wings in the outward packing. That is, the outward packing 20 'is made of a tubular ring, and a plurality of wings 25 are provided on the outer circumference thereof. The outward packing 20 'is formed to be slightly smaller than the outer diameter of the socket body 10 to be slightly expanded when coupled to the socket body 10 to be coupled by interference fit.

7 is an exemplary view showing a structure of a crimping ring according to a fourth embodiment of the present invention, Figure 8 is an exemplary view showing a coupling state of the crimping ring according to a fourth embodiment of the present invention.

As shown in these drawings, the compression ring 40 is installed on the outer side of the inward packing 30 so that the inward packing 30 is more tightly coupled with the socket body 10.

The pressing ring 40 has the same diameter as the inner diameter and the outer diameter of the socket body 10, and a through hole 43 corresponding to the screw hole 13 is formed. In addition, the outer diameter extends in the direction of the socket body 10 so as to partially wrap the circumference of the two inward packings 30 and the socket body 10. The compression ring 40 having such a structure closely adheres the two inward packings 30 to one end of the socket body 10, and then closes the compression ring 40. In this process, both the screw hole 13 and the through hole 33 and 43 of the socket body 10 are positioned on the same axis. When the screw S is inserted into and fastened to the through holes 33 and 43 arranged as described above, the compressive ring 40 may be forced to press the inward packing 30 so that deformation may occur when the branch pipe 2 is inserted. This will prevent partial lifting.

9 is a view illustrating a structure of a socket body according to a fifth embodiment of the present invention. As shown in the drawing, a coupling protrusion 17 having a screw hole 13 formed around the socket body 10 is illustrated. Protruding to form, it is configured by coupling the inward packing (30). By forming the coupling protrusion 17 as described above, the thickness of the socket body 10 is formed to be thin while preventing the breakage of the screw hole 13 to maintain a stable coupling.

1: main tube 1 ': hole 2: branch tube
10 socket body 11 stepped jaw 12 flow prevention jaw
13 screw hole 15 coupling pin 16 extension
17: engaging protrusion 20: outward packing 21, 31: cutting groove
23, 33, 43: through hole 30: inward packing 40: crimp ring
S: screw

Claims (5)

The socket body having a tubular shape, but both ends are formed with different diameters, one end having a small diameter is inserted into the hole 1 'of the main pipe 1, and the other end having a large diameter is the branch pipe 2 inserted therein. 10)
At least two layers of the outward packing 20 having an outer diameter larger than a hole of the main tube 1 and formed with a plurality of cutout grooves 21 which gradually become wider toward the outside at the edge thereof at the smaller diameter end of the socket body 10. Install but arrange so that the cutting grooves 21 do not overlap each other,
The inner diameter is formed smaller than the outer diameter of the branch pipe (2) and at the inner circumference to install two or more layers of inward packing (30) formed with a plurality of cutting grooves 31 at the large diameter end of the socket body (10) Branch sockets, characterized in that they are arranged not to overlap each other. The method of claim 1, wherein the threaded holes 13 are formed at both ends of the socket body 10, and the outward packing 20 and the inward packing 30 correspond to the through holes 23 corresponding to the threaded holes 13 ( 33) forming a branch pipe socket, characterized in that is coupled by a screw (S). delete According to claim 1 or 2, characterized in that the pressing ring 40 is in close contact with the outer side of the inward packing 30 and the outward packing 20, it is coupled to the socket body 10 with a screw (S). Branch socket. The method of claim 1, wherein the socket body 10 is formed by projecting a plurality of coupling pins 15 corresponding to the through-holes 23, 33 of the outward packing 20 and the inward packing 30 at both ends, Branch socket, characterized in that the coupling by the interference fit.

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