KR101854790B1 - Piping structure for noise prevention of sewage movement - Google Patents

Abstract

The present invention relates to a piping structure for minimizing a noise of sewage movement. More specifically, a water level sensor is able to check whether a granular tube is blocked due to accumulation of sewage sludge drained from each house hold in real-time such that sewage is prevented from back flowing through a connecting tube connected to the granular tube while minimizing a noise generated in a process of sewage movement.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a piping structure for minimizing drainage noise,

The present invention relates to a piping structure that minimizes the noise of moving sewage among the technical fields of apartment houses. More particularly, the present invention relates to a piping structure capable of confirming whether or not the inlet correlation is closed due to the accumulation of sewage sludge drained from a household, To minimize the noise of the sewage movement to minimize the noise generated by the sewage movement while preventing the sewage from flowing back to the generation through the connection pipe connected to the inlet pipe.

Generally, apartment buildings such as townhouses and apartments have kitchens, utility rooms, toilets, and verandas located at the same location for each floor.

As the location where the sewage is generated is provided at the same location, the apartment house adopts a collecting / draining system.

Korean Patent Registration No. 10-1622371 (Aug. 18, 2016) discloses a structure for preventing backflow of sewage pipes in apartment buildings.

However, there is a problem that it is difficult to prevent the noise due to the movement of the sewage so as to prevent the backflow prevention structure of the conventional apartment house sewage pipe.

Korea Patent Registration No. 10-1622371 (2016.05.18.) 'Preventing backflow of sewage pipes in apartment buildings'

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a sewage sludge sewer system, And to minimize the noise of sewer movement to minimize the noise generated by sewage movement while preventing backflow to the generation through a connector connected to the correlation.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

In order to accomplish the above object, the present invention provides a sewing machine comprising: an inlet correlation (100) installed in a height direction of a high-rise apartment house, in which sewage generated from each household is collected and dropped; A connection pipe (200) connecting between each generation of the high-rise apartment house and the inlet correlation (100) and having a discharge hole (210) formed on one side thereof; An overpass pipe 300 buried horizontally in the basement of the high-rise apartment house, draining the sewage dropped from the inlet correlation pipe 100 to the outdoor sewage treatment plant and forming an inflow hole on one side thereof; A joint pipe (400) connecting the lower end of the inlet pipe (100) and the transverse pipe (300); A water level sensor 500 installed between the connection pipe 400 and the connection pipe of the lowermost layer of the apartment building for measuring a water level rising from the connection pipe 400 to the inlet pipe 100; A control unit 600 for transmitting a detected water level value to the water level sensor 500 to the management room and outputting a warning sound or warning light to the management room when the water level value exceeds a predetermined reference value; A drain pipe connected to the discharge pipe 210 of the connection pipe 200 and the inlet pipe 310 of the transverse pipe 300 for bypassing the drain pipe of the connection pipe 200 to the transverse pipe 300; ); A rotary plate 800 hinged to the upper portion of the coupling pipe 200 to open and close the coupling pipe 200; The discharge hole 210 of the coupling pipe 200 is shielded by the rotation force of the rotary plate 800 due to the sewage pressure flowing back from the inlet pipe 100 to the connection pipe 200, (900) that is moved along the pipe (210) to open the discharge hole (210), wherein the sewage passing through the inlet pipe (100) passes through the pipe (400) The noise preventing unit 10 further includes a support plate 20 positioned at a lower portion of the joint pipe 400 to prevent noise generated during the process of moving the joint pipe 400 to the noise suppression unit 300. A sound absorbing material 30 provided on the support plate 20; The upper part is connected to the coupling pipe 400 and the lower part is connected to the sound absorbing material 30 and the sewage falling from the inlet pipe 100 to the coupling pipe 400 collides with the coupling pipe 400 A plurality of connecting pipes 40 for transmitting a noise to the sound absorbing material 30 so as to be absorbed by the sound absorbing material 30; And a sound absorbing member (50) coupled to the outside of each of the connection pipes (40).

According to the present invention, it is possible to check in real time whether the clogging of the inlet correlation due to the accumulation of the sewage sludge discharged from the generation is blocked by the water level sensor, thereby preventing the reverse flow of the sewage to the generation through the connection pipe connected to the inlet correlation It is effective.

In addition, there is an effect that the noise generated due to the movement of sewage can be minimized.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side view of a piping structure that minimizes noise of sewage movement according to the present invention.
Fig. 2 is a partially cutaway perspective view showing an enlarged portion after cutting the portion "A" in Fig.
3 is a front sectional view showing a portion "A" in Fig.
4 is a side cross-sectional view showing a portion "A" in Fig.
5 and 6 are operational state diagrams illustrating a piping structure that minimizes noise of sewage movement according to the present invention.
And
FIG. 7 is a partial cross-sectional view illustrating a state where a noise preventing unit is provided in a piping structure that minimizes noise of sewage moving according to the present invention.

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

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. And should not be construed as limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein.

It should be understood that the embodiments according to the concept of the present invention are not limited to the particular mode of disclosure but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The present invention utilizes the same as that of the later-described Japanese Patent Publication No. 1622371, and thus all of the features of the device configuration described below can be understood as those described in Japanese Patent No. 1622371. [

However, the present invention is not limited to the structure disclosed in the above-mentioned Japanese Patent No. 1622371, in which the structure for preventing backflow of the sewage pipe of the apartment house is replaced with the pipe structure for minimizing the noise of sewage moving, The structure for preventing noise generated in the process of moving to the transverse pipe through the pipe and the operation explanation are further included, and this part is the most important constitutional feature.

Therefore, the device configuration, characteristics and operation relationship described below will be referred to as the contents of the above-mentioned Japanese Patent No. 1622371, and the configuration related to the main features of the present invention will be described in detail at the rear end.

1 and 2, a piping structure for minimizing the noise of sewage movement according to the present invention includes an inlet correlation 100, a connection pipe 200, an inner pipe 300, a connection pipe 400, a water level sensor 500, a control unit 600, a right side pipe 700, a pivot plate 800, and an opening / closing unit 900.

The inlet correlation 100 is installed in the height direction of the high-rise apartment house, and serves as a kind of collecting house for collecting the sewage generated by each household.

The connection pipe 200 is a pipe through which the sewage of each household is drained, and connects the drainage passage with the drainage passage of each household.

The connection pipe 200 is formed with a discharge hole 210 for discharging sewage water to a later-described waste water pipe.

The transverse pipe 300 provides a channel through which the sewage collected in the inlet pipe 100 flows to the outdoor sewage treatment plant and is buried horizontally in the underground of the high-rise apartment house.

The transverse pipe 300 is formed with an inflow hole 310 through which waste water flows from a right side pipe to be described later.

The coupling pipe 400 connects the inlet correlation 100 and the transverse pipe 300 and connects the lower end of the inlet correlation 100 and the end of the transverse pipe 300.

The coupling pipe 400 is preferably provided as a sextia and is coupled to the inlet correlation 100 via a sextier band.

The water level sensor 500 senses the water level of the water level sensor 100 and is installed at the lower end of the water level sensor 100.

The water level sensor 500 detects that water is discharged from the connection pipe 400 to the inlet pipe 100 because the drain water can not be drained through the connection pipe 400 when the connection pipe 400 is closed And is installed in the inlet correlation between the coupling pipe 400 and the coupling pipe 200 of the lowermost layer generation.

That is, the water level sensor 500 senses the water level sensor 500 in advance and takes measures before the water level sensor 500 reaches the connection pipe 200 of the lowest level.

The level sensor 500 is provided with a known level sensor.

The controller 600 controls the water level sensor 500 and transmits the water level value sensed by the water level sensor 500 to the management room.

The controller 600 monitors the water level in the inlet correlation 100 through the water level sensor 500 and transmits the water level to the management room in real time to check the water level in the inlet correlation 100 in real time.

When the water level sensor 500 receives a water level measurement value exceeding a reference value, the controller 600 transmits the water level measurement value to the management room and outputs an alarm through a speaker and a warning light provided in the management room.

The wastewater pipe 700 is installed between the connection pipe 200 and the transverse pipe 300 through which the sewage is drained and the wastewater flowing backward through the connection pipe 200 is bypassed to the transverse pipe 300 do.

That is, even if the sewage water flows back to the connection pipe 200 from the inlet pipe 100 due to malfunction and failure of the water level sensor 500, the right pipe 700 is not introduced into the generation pipe, .

The right tube 700 is connected between the discharge hole 210 of the coupling tube 200 and the inlet hole 310 of the transverse tube 300.

The right-side pipe 700 is not necessarily installed in the connection pipes 200 of all the generations, but is preferably limited to the lower-level generation.

Accordingly, the discharge hole 210 need not be formed in all the connection pipes 200.

The rotary plate 800 is rotatably hinged to the inside of the coupling pipe 200 to open and close the pipe of the coupling pipe 200.

The rotary plate 800 need not be provided for every connection pipe 200 but is installed in a connection pipe provided with the right pipe 700.

The rotary plate 800 is hinged to be rotated in both directions on the channel of the connection part 200, and the diameter thereof corresponds to the inner diameter of the connection pipe 200.

The opening and closing part 900 opens and closes the discharge hole 210 formed in the connection pipe 200 and is installed in the discharge hole 210.

The opening / closing part 900 opens the discharge hole 210 by the water pressure of the sewage water flowing backward from the inlet correlation 100, and normally closes the discharge hole 210.

The opening and closing part 900 includes a stopper 910, a shielding surface 920, a curved surface 930, and a spring 940 as shown in FIGS.

Preferably, the stopper 910 is supported at a tip end of the discharge hole 210 and corresponds to the thickness of the discharge hole 210.

The shielding surface 920 shields the discharge hole 210 and prevents sewage drained from a generation from escaping to the right hall tube 700 at a normal time.

The shielding surface 920 forms a curved surface from the upper end of the stopper 910 toward the rear end of the discharge hole 210 and has a curvature corresponding to the inner diameter curvature of the coupling tube 200.

The bent surface 930 allows the shielding surface 920 to be pushed from the discharge hole 210 to the rear end by the water pressure of the sewage flowing back to the connection pipe 200.

The bent surface 930 interferes with one surface of the rotary plate 800 so that the rotary plate 800 is rotated only in one direction, that is, the drain direction, by the water pressure of the sewage drained from the generation.

The bent surface 930 is formed by rotating the rotary plate 800 toward the rear end by the water pressure of the sewage flowing backward when the sewage water flows back to the connection pipe 200 from the inlet pipe 100 And receives the turning force of the rotary plate 800 to move the shielding surface 920.

The curved surface 930 is bent upward from the rear end of the shielding surface 920 and corresponds to a surface of the rotary plate 800 facing the direction in which the sewage is drained from the generation.

The spring 940 is installed between the stopper 910 and the rear end edge of the discharge hole 210 and pushes the stopper 910 toward the end edge of the discharge hole 210, So that the discharge hole 210 is closed.

Hereinafter, the operation of the backflow preventing structure of the sewage pipe of the apartment house constructed as described above will be described with reference to FIGS. 5 and 6 attached hereto.

The sewage drained from each generation is collected by the inlet correlation 100 through the connection pipe 200 and the collected sewage is drained along the transverse pipe 300 through the joint pipe 400.

That is, the sewage is drained from the generation to the connection pipe 200 at the normal time. In this process, the rotary plate 800 is rotated by the drain pressure to open the pipe of the connection pipe 200 naturally.

Thereafter, as time passes, deposits such as sludge accumulate in the joint pipe 400, and the pipe of the joint pipe 400 can be closed by the deposit.

The sewage drained through the inlet pipe 100 gradually increases in the height direction of the inlet pipe 100 from the connecting pipe 400 as it can not flow through the pipe pipe 400.

The water level sensor 100 continuously monitors the level of water through the water level sensor 500 so that if the water level of the water level sensor 100 becomes equal to or higher than the reference level, steps such as steps are taken, And the cleaning operation is performed.

Accordingly, it is possible to prevent the reverse flow of the sewage to the connection pipe 200 of the low-rise building in advance, so that generation damage due to the reverse flow of the sewage does not occur.

If the water level sensor 500 malfunctions or malfunctions, the management room can not recognize the closure of the coupling pipe 400, and the sewage that can not flow through the coupling pipe 400 is discharged to the inlet pipe 100 It will continue to come through.

The sewage is firstly backwept to the connection pipe 200 of the bottom layer and the swash plate 800 installed on the connection pipe 200 is rotated in the opposite direction of the sewage backwashed by the hydraulic pressure of the backwash water.

The rotary plate 800 pivots while pushing out the bent surface 930 corresponding to the rotary plate 800. [

The shielding surface 920 is moved along the curved surface 930 to open the discharge hole 210.

The spring 940 contracts as the stopper 910 is pushed to the rear end of the discharge hole 210. [

The sewage flowing backward flows through the discharge hole 210 to the right pipe 700 and flows to the transverse pipe 300 so that the sewage does not flow back to the generation.

When the sewage is no longer backwashed through the connection pipe 200, the shielding surface 920 is retracted by the restoring force of the spring 940 that has been retracted, so that the discharge hole 210 of the connection pipe 200 is shielded And the rotary plate 800 is also returned to its original position.

In the present invention, as shown in FIG. 7, the noise generated in the process of moving the sewage passing through the inlet correlation pipe 100 to the transverse pipe 300 through the coupling pipe 400, The structure of the noise preventing part 10 for preventing the noise is further realized.

The noise preventing unit 10 absorbs noise generated when the sewage falling from the inlet pipe 100 collides with the coupling pipe 400 to minimize the noise.

The noise preventing unit 10 includes a support plate 20 positioned at a lower portion of the joint pipe 400 and a sound absorbing material 30 disposed at an upper portion of the support plate 20 and an upper portion connected to the joint pipe 400 The lower portion of the noise absorbing member 30 is connected to the sound absorbing material 30 and the noise generated when the sewage falling from the input correlation pipe 100 to the coupling pipe 400 collides with the coupling pipe 400 is transmitted to the sound absorbing material 30, A plurality of connection pipes 40 for absorbing sound in the sound absorbing member 30 and a sound absorbing member 50 connected to the outside of the connection pipes 40.

The support plate 20 is extended in the longitudinal direction of the joint pipe 400 to stably support the sound absorbing material 30.

The support plate 20 can be stably supported on the sound absorbing material 30 while being fixed to another external structure.

The sound absorbing material 30 is made of any one of porous, textured, felt, cotton, lacquer, glass wool, polyol, and foamed resin so that noise can be absorbed and reduced.

The connection pipe 40 is disposed in the longitudinal direction of the joint pipe 40 so that the noise generated from the joint pipe 400 can be transmitted to the sound absorbing member 30 while both ends are opened.

The coupling pipe 40 is connected to the coupling pipe 400 and the sound absorbing material 30 so that the noise generated from the coupling pipe 400 is transmitted to the sound absorbing material 30.

In addition, the connection pipe 40 may transmit the noise generated in the coupling pipe 400 to the sound absorbing material 30 through the inside thereof.

Accordingly, the sound absorbing material 30 can minimize the noise caused by the movement of the sewage while absorbing the noise generated in the joint pipe 400.

The noise preventing unit 10 may further include a buffer member 60 provided between the coupling pipe 40 and the coupling pipe 400.

The buffer member 60 may be made of silicone or rubber and may be connected to the coupling pipe 400 by an adhesive or the like while having a semicircular cross section.

Accordingly, the shock absorbing member 60 can prevent vibration of the coupling pipe 40 due to vibration by buffering vibrations generated in the coupling pipe 400, and prevent noise from being generated.

The buffer member 60 may be formed with a plurality of coupling holes 61 through which the upper portion of the coupling pipe 40 is inserted.

The lower portion of the connection pipe 40 is preferably inserted into the upper portion of the sound absorbing member 30.

The sound-absorbing member 50 may be made of silicone or rubber, so as to absorb vibrations transmitted from the joint pipe 400 to prevent noise from being generated.

The sound absorbing member 50 may be provided on the outside of the coupling pipe 30, but may be provided on the inside or outside of the coupling pipe 40 to more effectively cushion the vibration.

The noise preventing unit 10 may further include a protection plate 70 provided on the sound absorbing member 30 and having a plurality of through holes 71 through which the lower portion of the connection pipe 40 passes.

The protection plate 70 protects the sound absorbing material 30 from the outside and effectively absorbs noise in the sound absorbing material 30 disposed between the protection plate 70 and the support plate 20.

Therefore, the noise preventing unit 10 can minimize noise caused by the sewage movement by absorbing the noise generated when the sewage falling in the inlet pipe 100 collides with the coupling pipe 400.

100: inlet correlation 200: connector
210: Exhaust hole 300: Transverse pipe
310: Inflow hole 400: Coupling pipe
500: water level sensor 600:
700: Woo hall 800: Rotary board
900: opening and closing part 910: stopper
920: shielding surface 930: bent surface
940: Spring S: Detection sensor
10: Noise prevention part 20: Support plate
30: Sound absorbing material 40: Connection pipe
50: sound-absorbing member 60: buffer member
61: engaging hole 70: shield plate
71: Through hole

Claims (1)

(100) installed in a height direction of a high-rise apartment house, where sewage generated from each household is collected and dropped;
A connection pipe (200) connecting between each generation of the high-rise apartment house and the inlet correlation (100) and having a discharge hole (210) formed on one side thereof;
An overpass pipe 300 buried horizontally in the basement of the high-rise apartment house, draining the sewage dropped from the inlet correlation pipe 100 to the outdoor sewage treatment plant and forming an inflow hole on one side thereof;
A joint pipe (400) connecting the lower end of the inlet pipe (100) and the transverse pipe (300);
A water level sensor 500 installed between the connection pipe 400 and the connection pipe of the lowermost layer of the apartment building for measuring a water level rising from the connection pipe 400 to the inlet pipe 100;
A control unit 600 for transmitting a detected water level value to the water level sensor 500 to the management room and outputting a warning sound or warning light to the management room when the water level value exceeds a predetermined reference value;
A drain pipe connected to the discharge pipe 210 of the connection pipe 200 and the inlet pipe 310 of the transverse pipe 300 for bypassing the drain pipe of the connection pipe 200 to the transverse pipe 300; );
A rotary plate 800 hinged to the upper portion of the coupling pipe 200 to open and close the coupling pipe 200;
The discharge hole 210 of the coupling pipe 200 is shielded by the rotation force of the rotary plate 800 due to the sewage pressure flowing back from the inlet pipe 100 to the connection pipe 200, And an opening / closing part (900) that is moved along the opening (210) to open the discharge hole (210)
The noise generated when the sewage falling in the inlet pipe 100 collides with the coupling pipe 400 is absorbed, Further comprising a noise prevention unit (10) for preventing noise generated during the process of moving the sewage passing through the inlet correlation pipe (100) to the transverse pipe (300) through the coupling pipe (400)
The noise preventing portion (10)
A support plate (20) located under the joint pipe (400);
A sound absorbing material 30 provided on the support plate 20;
The upper part is connected to the coupling pipe 400 and the lower part is connected to the sound absorbing material 30 and the sewage falling from the inlet pipe 100 to the coupling pipe 400 collides with the coupling pipe 400 A plurality of connecting pipes 40 for transmitting a noise to the sound absorbing material 30 so as to be absorbed by the sound absorbing material 30;
A sound absorbing member (50) provided on the inside and outside of each of the connection pipes (40) for absorbing vibration transmitted from the joint pipe (400) to prevent noise from being generated;
A buffer member 60 provided between the coupling pipe 40 and the coupling pipe 400; And
The sound absorbing material 30 is installed on the upper part of the sound absorbing material 30 to protect the sound absorbing material 30 from the outside while smoothly absorbing noise from the sound absorbing material 30 disposed between the sound absorbing material 30 and the support plate 20, (70) in which a plurality of through holes (71) through which a lower portion of the pipe (40) passes are formed,
The connection pipe (40)
The lower portion is drawn into the upper portion of the sound absorbing member 30,
The buffer member (60)
And a plurality of coupling holes (61) connected to the coupling pipe (400) and having an upper portion connected to the coupling pipe (40) are formed in a semicircular shape in the vertical section. Plumbing structures.

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