KR101361472B1 - Drain system for rainwater and polluted water - Google Patents

Abstract

The present invention includes a rainwater flow path (a) and a wastewater flow path (b) formed so that rainwater and sewage flow separately, respectively, and has a sewage flow path closing part (c) formed to close up, down, left, and right of the sewage flow path (b). One drain 10; Rainfall inlet portion 20 formed in the drainage path 10 so that rainwater flows through the storm flow path (a); Sewage inlet 30 formed in the drainage path 10 so that the effluent flows through the effluent passage (b); by presenting a drainage system of sewage and rainwater, reducing the excavation work for the formation of the pipeline It is efficient structure considering the characteristics of sewage pipe and rainwater pipe, and make maintenance work simple.

Description

Drainage system of drainage and rainwater {DRAIN SYSTEM FOR RAINWATER AND POLLUTED WATER}

FIELD OF THE INVENTION The present invention relates to the field of environment, and in particular, to sewage and rainwater drainage systems.

Since sewage (sewage) and rainwater are treated in different ways, the flow paths must be configured separately.

For this reason, in the related art, a buried position is secured by a separate excavation work, and a separate pipeline is formed.

However, this conventional method requires a plurality of excavation works for the sewage pipe and the rainwater pipe, and a certain amount of sewage flows through the sewage pipe at all times, and rainwater flows only in the rainwater pipe, but it is inefficient because there is no consideration about this. There was a problem that maintenance work on the pipeline was cumbersome.

The present invention has been derived to solve the above problems, it is possible to reduce the excavation work for the formation of the pipeline, an efficient structure in consideration of the characteristics of the sewage pipe and storm pipe, sewage and excellent to simplify the maintenance work The purpose is to present a drainage system of.

In order to solve the above problems, the present invention includes a rainwater flow path (a) and a wastewater flow path (b) formed so that rainwater and sewage flow separately, each of the sewage formed so that the top, bottom, left and right of the sewage flow path (b) is closed A drain passage 10 having a flow path closing portion c; A rainwater inlet 20 formed in the drainage passage 10 so that rainwater flows through the rainwater passage a; Sewage and rainwater drainage system formed in the drainage path 10 so that filthy water flows through the filthy water passage (b);

The sewage flow path closing part (c) is preferably formed by interconnecting a plurality of sewage flow path closing members 100 in the front and rear directions.

The sewage flow path closing member 100 includes a side closure part 110 having a lower end coupled to a bottom surface of the drainage path 10 so as to close the side of the sewage flow path b; An upper closure part 120 extending laterally from an upper end of the side closure part 110 so as to close the upper portion of the sewage passage b, and having a side end coupled to an inner side surface of the drainage passage 10; It includes, the sewage flow path closing portion (c) is preferably formed by the bottom and the inner surface of the side closure portion 110 and the upper closure portion 120 and the drain passage (10).

The sewage passage closing member 100 is preferably formed to be bent or curved.

It is preferable that the rain inlet hole 121 is formed through the upper closure portion 120.

The rainwater inlet 121 is preferably equipped with a filter 121a.

A coupling protrusion 122 is formed upward at a side end of the upper closure portion 120 of the sewage passage closing member 100, and the coupling protrusion 122 is an inner side surface of the drainage passage 10 by a coupling mechanism. It is preferable to bind to.

A coupling protrusion 112 is formed at a lower end of the side closure portion 110 of the sewage passage closing member 100, and the coupling protrusion 112 is coupled to a bottom surface of the drainage passage 10 by a coupling mechanism. It is preferable to combine.

It is preferred that the front and rear ends of the sewage flow path closing member 100 protrude to the outside for the coupling wing 130 for coupling with the other sewage flow path closing member 100 to be adjacently coupled.

A plurality of coupling holes 131 are formed in the coupling wing portion 130, and the sewage passage closing member 100 and the other sewage passage closing member 100 are installed through the coupling hole 131. It is preferable to bind by.

The sewage passage closing member 100 is preferably formed of a synthetic resin or a steel sheet material.

A coupling groove 11 is formed on the bottom of the drainage passage 10, and a lower end of the side closure 110 of the sewage passage closing member 100 is coupled to the coupling groove 11.

The drainage path 10 is preferably formed by interconnecting a plurality of precast boxes 10a open in front and rear in the front and rear directions.

The present invention can reduce the excavation work for the formation of the pipeline, and is an efficient structure in consideration of the characteristics of the sewage pipe and rainwater pipe, and proposes a drainage system of sewage and rainwater to simplify maintenance work.

1 shows an embodiment of the present invention,
1 is a cross-sectional view of a drainage system.
2 is a perspective view of a first embodiment of a sewage passage closing member;
3 is a sectional view of a second embodiment of a sewage passage closing member;
4 is a perspective view of a third embodiment of a sewage passage closing member;
Fig. 5 is a sectional view of a fourth embodiment of the sewage passage closing member.

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

As shown in Figure 1 below, the drainage system of sewage and rainwater according to the present invention basically comprises a rainwater flow path (a) and a sewage flow path (b) formed so that rainwater and sewage flow separately, a drain passage 10 having a sewage flow channel closing part c formed to close all of the upper, lower, left, and right sides of (b); Rainfall inlet portion 20 formed in the drainage path 10 so that rainwater flows through the storm flow path (a); And a sewage inlet 30 formed in the drainage path 10 so that the sewage flows through the sewage flow path b.

That is, instead of forming the sewage pipe and the rainwater pipe separately as in the prior art, one drainage path 10 is formed at the buried position secured by one excavation operation, and the rainwater flow path a and the wastewater flow path ( b) is included.

However, since the sewage of the sewage flow path (b) should not be mixed with rainwater, the sewage flow path closing portion (c) is formed so that all the top, bottom, left, and right sides of the sewage flow path (b) are closed (only the front and rear sides are opened).

Therefore, the following effects can be obtained.

First, since a plurality of excavation work is not required for a sewage pipe and an excellent pipe as in the related art, labor and cost required for construction can be reduced.

Second, considering the characteristic that a certain amount of sewage always flows through the sewage pipe, and rainwater flows only during rainfall, the overall drainage path 10 is largely formed (because two pipes are conventionally combined). In addition, since the sewage flow path (b) having a required size is formed only in a part of the area, it is possible to secure an excellent flow path (a) of a sufficient size, thereby reducing the damage caused by the overflow of rainwater during heavy rain.

Third, unlike the conventional sewage pipe, the rainwater passage (a) can freely enter and exit, and enter the rainwater passage (a) to facilitate the maintenance work of the sewage passage (b).

The drainage passage 10 may form the sewage flow channel closing part c in any configuration, but a plurality of precast boxes 10a having a front and rear opening are mutually connected in the front and rear directions. As an example, an embodiment of the present invention will be described.

The sewage flow path closing part (c) is preferably in view of convenience of construction so that a plurality of sewage flow path closing members 100 are interconnected in the front and rear directions (FIG. 2).

Specifically, the sewage flow path closing member 100 includes a side closure part 110 having a lower end coupled to a bottom surface of the drainage path 10 so as to close the side of the sewage flow path b; And an upper closure part 120 extending laterally from an upper end of the side closure part 110 so as to close the upper side of the sewage passage b, and having a side end coupled to an inner side surface of the drainage path 10. The sewage flow path closing part (c) is formed by the side closure part 110, the upper closing part 120, and the bottom and the inner side surface of the drainage path 10. It is preferable at the point which can be formed.

The sewage passage closing member 100 may have a structure formed to be bent or curved (FIGS. 2 to 5).

When the rainwater inlet hole 121 penetrates the upper closure portion 120 of the sewage flow path closing member 100, a part of the rainwater blown during heavy rain flows into the sewage flow path b through the rainwater inlet hole 121. In this case, the rainwater flowing in will naturally clean the sewage passage (b), which is preferable in terms of maintenance (FIG. 2).

However, in order to prevent large contaminants due to heavy rain from flowing into the sewage flow path (b), it is preferable that the filter inlet hole 121 is equipped with a filter 121a.

The drainage system according to the present invention may be implemented by a new installation, but may also be implemented by a method (repair) of installing a sewage flow path closing member 100 in an existing rainwater pipe.

A coupling protrusion 122 is formed upward at a side end of the upper closure portion 120 of the sewage passage closing member 100, and the coupling protrusion 122 is formed in the drainage path 10 by a coupling mechanism such as an anchor. It may take a configuration to engage the side (Figs. 2, 3).

In addition, a coupling protrusion 112 is formed at the lower end of the side closure portion 110 of the sewage passage closing member 100, and the coupling protrusion 112 is connected to the bottom surface of the drainage passage 10 by a coupling mechanism. It may take a configuration to combine.

This coupling structure is suitable for implementing the drainage system according to the present invention by the latter method (repair) because it is a structure that can install the sewage flow path closing member 100 with respect to the existing drainage path (10).

The sewage flow path closing member 100 may be formed of a precast concrete material, but may be sufficiently implemented by other materials such as synthetic resin and (waveform) steel sheet.

In the former case, the plurality of sewage passage closing members 100 may be coupled to each other by a method of fixing the PS strand through the fixing unit 101.

In the latter case, the coupling wing 130 for engaging with the other sewage flow path closing member 100 coupled adjacent to the front and rear ends of the sewage flow path closing member 100 is formed to protrude outward, The sewage flow path closing part c may be formed by mutual coupling of the wing parts 130 (FIG. 4).

Specifically, a plurality of coupling holes 131 are formed in the coupling wing portion 130, and the sewage flow channel closing member 100 and the other sewage flow channel closing member 100 are bolts, nuts, etc. through the coupling hole 131. It is possible to take the configuration to be coupled by the installation of the coupling mechanism of.

When implementing the drainage system according to the present invention by the new installation, it may take the above-described manner, but the coupling groove portion 11 is formed on the bottom surface of the drainage passage 10, the side closure portion of the sewage passage closing member 100 More preferably, the lower end of the 110 is coupled to the coupling groove 11.

When the side end of the upper closure portion 120 of the sewage passage closing member 100 is coupled to the inner surface of the drainage passage 10, the lower end of the side closure portion 110 naturally contacts the bottom surface of the drainage passage 10 due to its own weight. In the case of forming the joining groove 11 on the bottom of the drainage passage 10, the bottom of the side closure 110 is inserted into the joining groove 11, and it is sufficient to simply apply an index agent, an adhesive, or the like. This is because it is possible to achieve a stable coupling can reduce the amount of work for installation of the sewage flow path closing member 100.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

a: Excellent Euro b: Wastewater Euro
c: sewage flow path closing part 10: drainage path
10a: precast box 20: rainwater inlet
30: sewage inlet 100: sewage flow path closing member
110: side closure 112: coupling protrusion
120: upward closure 121: rainwater inlet hole
121a: filter 122: coupling protrusion
130: coupling wing 131: coupling hole

Claims (13)

A drainage passage including a rainwater flow passage (a) and a wastewater flow passage (b) formed so that rainwater and sewage flow separately, and the sewage flow passage closing part (c) formed to close all the upper, lower, left, and right sides of the wastewater passage (b). 10;
A rainwater inlet 20 formed in the drainage passage 10 so that rainwater flows through the rainwater passage a;
And a sewage inlet part 30 formed in the drainage path 10 so that the sewage flows through the sewage flow path b.
The sewage flow path closing part (c) is formed by a plurality of sewage flow path closing members 100 are interconnected in the front and rear directions,
The sewage passage closing member 100 is
A side closure part 110 having a lower end coupled to a bottom surface of the drainage path 10 so as to close the side of the sewage flow path b;
An upper closure part 120 extending laterally from an upper end of the side closure part 110 so as to close the upper portion of the sewage passage b, and having a side end coupled to an inner side surface of the drainage passage 10; Including,
The sewage flow path closing part (c) is formed by the side closure part 110, the upper closure part 120, and the bottom and the inner surface of the drainage passage 10,
The sewage passage closing member 100 is formed to be bent or curved,
A coupling protrusion 122 is formed upward at a side end of the upper closure portion 120 of the sewage passage closing member 100, and the coupling protrusion 122 is an inner side surface of the drainage passage 10 by a coupling mechanism. To,
A coupling protrusion 112 is formed at a lower end of the side closure portion 110 of the sewage passage closing member 100, and the coupling protrusion 112 is coupled to a bottom surface of the drainage passage 10 by a coupling mechanism. Combine,
The superior inlet hole 121 is formed through the upper closure portion 120,
The drainage system of sewage and rainwater, characterized in that the rainwater inlet 121 is equipped with a filter (121a).
delete delete delete delete delete delete delete The method of claim 1,
Sewage and rainwater drainage system, characterized in that the front and rear ends of the sewage flow path closing member 100 is coupled to the other sewage flow path closing member 100 to be adjacently coupled to protrude outward. . 10. The method of claim 9,
A plurality of coupling holes 131 are formed in the coupling wing portion 130, and the sewage passage closing member 100 and the other sewage passage closing member 100 are installed through the coupling hole 131. Sewage and rainwater drainage system, characterized in that coupled by. The method of claim 10,
The sewage passage closing member 100 is sewage and rainwater drainage system, characterized in that formed by synthetic resin or steel plate material. The method of claim 1,
A coupling groove 11 is formed at the bottom of the drainage passage 10.
The lower end of the side closure portion 110 of the sewage passage closing member 100 is sewage and rainwater drainage system, characterized in that coupled to the coupling groove (11). The method according to any one of claims 1 and 9 to 12,
The drainage system 10 is a drainage system of sewage and rainwater, characterized in that a plurality of precast box (10a) is opened in front and rear interconnected in the front and rear directions.

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