KR102558747B1 - Toxic gas discharge device of sewage pipe with seismic function and its construction method - Google Patents

Abstract

The present invention relates to a toxic gas discharge device for a sewer pipe with an earthquake-resistant function, which can maintain a comfortable environment, and to a construction method thereof. The toxic gas discharge device for a sewer pipe with an earthquake-resistant function, comprises: an excavation hole forming step; a work protection pipe fastening step; a blocking protection net installation step; a sewer pipe through-hole forming step; a water supply and sewage pipe discharge device installing step; a discharge device demonstration driving step; an excavation hole work protection pipe separating and demolishing step; and an excavation hole burying step.

Description

Toxic gas discharge device of sewage pipe with seismic function and its construction method }

The present invention relates to a toxic gas discharge device of a sewer pipe having an earthquake-resistant function in the field of sewage pipe technology and a method of constructing the same, and more particularly, by providing a gas or air discharge device in a sewage pipe that guides sewage to effectively discharge toxic gas inside the sewer pipe, environmental pollution and discomfort due to the outflow of toxic gas do not occur and a pleasant environment can be maintained, and a seismic elastic shock absorber is provided to damage the sewer pipe by earthquake or external shock It relates to a toxic gas discharge device of a sewer pipe having an earthquake-resistant function and a construction method thereof.

In general, a combined sewer pipe buried underground is connected to a sewage connection pipe for transporting sewage generated from each home, building, factory, etc., and a rainwater connection pipe connected to a rainwater receiver for collecting rainwater flowing along a road.

These sewage pipes inevitably generate toxic gases and odors due to organic substances and contaminants mixed in sewage and rainwater.

Typically, manholes are installed at regular intervals in sewage pipes. The manholes are buried in the ground, the top is open, a sewage inlet pipe connected to the upstream sewer pipe is formed on the upstream wall, and the downstream wall is composed of a manhole body having a sewage outlet connected to it and a manhole cover covering the top opening of the manhole body.

Here, the manhole cover is composed of an iron support ring seated on the top of the manhole body and an iron gate installed to be able to open and close on the iron support ring, so that a gap is inevitably generated between the iron support ring and the iron gate, so that toxic gases and odors generated in the sewage pipe are released through the gap, resulting in a problem of contaminating the surroundings with toxic gas and odor.

The foregoing invention refers to the background art in the technical field to which the present invention belongs, and does not mean the prior art.

Registered Patent No. 10-1735790

The present invention has been made to solve the above conventional problems, and an object of the present invention is to provide a discharge device in a sewer pipe that guides sewage, to effectively discharge toxic gas inside the sewer pipe, so that environmental pollution and discomfort due to the outflow of toxic gas do not occur and to maintain a pleasant environment, and to provide an earthquake-resistant elastic shock absorber to prevent damage to the sewer pipe due to earthquake or external shock. The purpose is to provide a device and its construction method.

The present invention is a method of constructing a discharge device for discharging toxic gas inside a sewage pipe, wherein a drilling hole forming step is formed by excavating the ground to expose the sewer pipe, a work protection pipe is inserted into the drilling hole to support the inner surface of the drilling hole, and a work protection pipe fastening step of blocking foreign matter or soil from entering the sewer pipe exposed, and installing a blocking protection net on top of the work protection pipe to block foreign matter from entering the work protection pipe A blocking protection net installation step, a sewage pipe through-hole forming step of drilling the sewer pipe to form a through hole to discharge toxic gas, a sewage discharge device installation step of installing a discharge device in the sewer pipe to discharge toxic gas inside the sewer pipe, a pilot operation step of discharging device installed in the sewer pipe to discharge toxic gas from the sewer pipe, and a drilling hole work protection pipe separation and removal step of separating the work protection pipe installed in the excavation hole. And, it consists of an excavation hole embedding step of filling the excavation hole by inserting soil into the excavation hole from which the work protection pipe is separated, preventing foreign matter or soil from entering the excavation hole by the work protection pipe and the blocking protection net, and also discharging toxic gas from the sewer pipe by the discharge device. In the installation step of the sewage pipe discharge device, a situation awareness work guide step is further included to identify the work situation at the site by situation awareness work guide means and send a danger signal in the event of an emergency. to be characterized

The present invention is a discharge device for discharging toxic gas inside a sewer pipe, comprising: a connection panel having a communication hole formed in communication with a through hole formed in the sewer pipe and fastened and fixed to the outer surface of the sewer pipe; a connection pipe having one end connected and fixed to an upper surface of the connection panel to communicate with the communication hole; It consists of a gas discharge pipe fitted and fixed and the other end disposed outside, a discharge fan fastened to the gas discharge pipe to discharge toxic gas inside the sewer pipe, and a control valve fastened to the gas discharge pipe to control the movement of toxic gas in the gas discharge pipe. After detecting gas, a gas detection sensor for transmitting a detection signal to the control valve and the discharge fan is further fastened, and the control valve and the discharge fan receiving the signal of the gas detection sensor are driven to discharge the toxic gas inside the sewage pipe to the outside.

Toxic gas discharge device of a sewer pipe having an earthquake-resistant function and a construction method thereof according to the present invention provide a discharge device in a sewage pipe that guides sewage, thereby effectively discharging toxic gas inside the sewer pipe, thereby preventing environmental pollution and discomfort due to the outflow of toxic gas and maintaining a pleasant environment, and providing an earthquake-resistant elastic shock-absorbing means to prevent damage to the sewer pipe due to earthquakes or external shocks.

1 is a view showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention.
2 is a cross-sectional view showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention.
3 is a connection state diagram showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention.
4 is a toxic gas discharge state diagram showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention.
5 is a view showing a blocking protective pipe and a blocking protective net of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention.
6 is a view showing an earthquake-resistant elastic shock-absorbing means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention.
7 is a view showing a situation-aware work guide means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention.
8 is a view showing another embodiment of a situation-aware operation guidance means of a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention.
9 is a conceptual diagram showing a situation-aware operation guidance means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention.

Since the description of the present invention is only an embodiment for structural or functional description, the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, since the embodiment can be changed in various ways and can have various forms, it should be understood that the scope of the present invention includes equivalents capable of realizing the technical idea.

On the other hand, the meaning of terms described in the present invention should be understood as follows.

Terms such as "first" and "second" are used to distinguish one component from another, and the scope of rights should not be limited by these terms. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element.

It should be understood that when an element is referred to as being “connected” to another element, it may be directly connected to the other element, but other elements may exist in the middle. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that no intervening elements exist. Meanwhile, other expressions describing the relationship between components, such as “between” and “immediately between” or “adjacent to” and “directly adjacent to” should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly dictates otherwise, and terms such as "comprise" or "having" are intended to designate that an embodied feature, number, step, operation, component, part, or combination thereof exists, and it should be understood that the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof is not precluded.

In each step, the identification code (eg, a, b, c, etc.) is used for convenience of explanation, and the identification code does not describe the order of each step, and each step is context-specific. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless defined otherwise. Terms defined in commonly used dictionaries should be interpreted as consistent with meanings in the context of related art, and cannot be interpreted as having ideal or excessively formal meanings unless explicitly defined in the present invention.

1 is a view showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention. 2 is a cross-sectional view showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention. 3 is a connection state diagram showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention. 4 is a toxic gas discharge state diagram showing a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention. 5 is a view showing a blocking protective pipe and a blocking protective net of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention. 6 is a view showing an earthquake-resistant elastic shock-absorbing means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention. 7 is a view showing a situation-aware work guide means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention. 8 is a view showing another embodiment of a situation-aware operation guidance means of a toxic gas discharge device of a sewage pipe having an earthquake-resistant function according to the present invention. 9 is a conceptual diagram showing a situation-aware operation guidance means of a toxic gas discharge device of a sewer pipe having an earthquake-resistant function according to the present invention.

As shown in the drawing, the toxic gas discharge device 10 of the sewer pipe having an earthquake-resistant function according to the present invention (hereinafter referred to as a toxic gas discharge device for convenience of explanation) is a discharge device for discharging toxic gas inside the sewer pipe 100. Accordingly, such a discharge device 10 is composed of a connection panel 20, a connection pipe 30, and a toxic gas discharge unit 40.

The connection panel 20 has a communication hole 21 formed to communicate with the through hole 200 formed in the sewer pipe 100, and is attached to the outer surface of the sewer pipe 100 or fastened by screwing to be fixed.

The connection panel 20 is formed in a curved panel structure, and the material is made of a synthetic resin material or a metal material.

At this time, it is also possible to maintain airtightness by placing an O-ring between the connection panel 20 and the sewer pipe 100, and it is also possible to maintain airtightness by applying silicone between the edge portion of the connection panel 20 and the outer surface of the sewer pipe 100.

One end of the connection pipe 30 is welded or attached to the upper surface of the connection panel 20 so as to communicate with the communication hole 21 and is fixed.

The connection pipe 30 is formed in a hollow circular tubular structure, and the material is made of a metal material or a synthetic resin material.

The toxic gas discharge unit 40 is fastened to the connection pipe 30 to discharge the toxic gas inside the sewage pipe 100 to the outside.

The toxic gas discharge unit 40 includes a gas discharge pipe 41 having one end inserted into and fixed to the connection pipe 30 and having the other end disposed outside, a discharge fan 42 fastened to the gas discharge pipe 41 to discharge toxic gas inside the sewage pipe 100, and a control valve 53 fastened to the gas discharge pipe 41 to control the movement of toxic gas in the gas discharge pipe 41.

The gas discharge pipe 41 is fixed by being glued or screwed after the lower end is fitted into the connection pipe 30, and the discharge fan 42 is fixed by being screwed to the inner surface after being fitted into the gas discharge pipe 41.

At this time, one end of the support shaft 211 is screwed and fixed to the inner surface of the communication hole 21, the other end of the support shaft 211 is disposed inside the sewage pipe 100, and the other end of the support shaft 211 detects toxic gas inside the sewer pipe 100 and then transmits a detection signal to the control valve 53 and the discharge fan 42. A gas detection sensor 50 is further attached, or It is screwed in and fixed.

The gas detection sensor 50 detects toxic gas and odor inside the sewer pipe 100, and then transmits the detection signal to the control valve 53 and the discharge fan 42 to drive them. After the control valve 53 opens the sewer pipe 100, the discharge fan 42 discharges the toxic gas inside the sewer pipe 100 to the outside.

At this time, an opening/closing door or a strainer is fastened to the upper end of the gas discharge pipe 41 to prevent rainwater or foreign substances from entering.

A purifier, which is a filter, is further fastened to the gas discharge pipe 41 to purify and discharge harmful gases, thereby preventing harmful gases from leaking out and corroding the inner surface of the sewage pipe 100 by harmful gases.

The construction method of the discharge device for discharging toxic gas inside the sewer pipe 100 configured as described above includes a drilling hole forming step (S1) of forming a drilling hole 300 so that the sewer pipe 100 is exposed by excavating the ground, and inserting a work protection pipe 60 into the drilling hole 300 to support the inner surface of the drilling hole 300 and to introduce foreign matter or soil into the sewer pipe 100 exposed A work protection pipe fastening step (S2) to block the work protection pipe 60, and a blocking protection net 70 on the top of the work protection pipe 60 to protect the worker by blocking the inflow of foreign substances into the work protection pipe 60. It goes through a blocking protection net installation step (S3) of installing.

The work protection pipe 60 is press fit into the drilling hole 300, and it is also possible to fasten the flange wings to the upper outer surface by screwing, so that the flange wings are caught on the ground.

The blocking protective net 70 covers the upper part of the work protection pipe 60 and is fixed by screwing.

Here, it is preferable to further form an inlet groove at the lower end of the work protection pipe 60 so that a part of the sewage pipe 100 is introduced.

Thereafter, a sewage pipe 100 through-hole 200 forming step (S4) of drilling the sewer pipe 100 to form a through-hole 200 to discharge toxic gas, a sewage pipe 100 discharge device installation step (S5) of installing a discharge device in the sewer pipe 100 to discharge toxic gas inside the sewer pipe 100, and a discharge device installed in the sewage pipe 100 It goes through a pilot driving step (S6) of the discharge device for discharging the toxic gas of the sewage pipe 100 by driving the.

Thereafter, the excavation hole 300 and the work protection pipe 60 separation and removal step (S7) of separating the work protection pipe 60 installed in the excavation hole 300, and the excavation hole 300 embedding step (S8) of filling the excavation hole 300 by inserting soil into the excavation hole 300 from which the work protection pipe 60 is separated, thereby completing a series of processes,

Foreign matter or soil is prevented from entering the excavation hole 300 by the work protection pipe 60 and the blocking protection net 70, and the toxic gas of the sewage pipe 100 is discharged by the discharge device.

At this time, after the sewage pipe 100 discharge device installation step (S5), the earthquake-resistant elastic shock-absorbing means 80 is further installed in the sewer pipe 100 so as to buffer vibration or shock caused by the earthquake from being transmitted to the sewer pipe 100. An earthquake-resistant elastic shock-absorbing means 80 installation step (S5-2) is further added.

The earthquake-resistant elastic shock-absorbing means 80 includes an earthquake-resistant reinforcing pipe 81 attached and fixed after being inserted into the sewer pipe 100, an elastic buffer spring 82 having one end screwed and fixed to an outer surface of the earthquake-resistant reinforcing pipe 81, an earthquake-resistant buffer panel 83 having an inner surface screwed and fixed to the other end of the elastic buffer spring 82, and the earthquake-resistant buffer panel 8 3) is attached to and fixed to the outer surface and consists of an elastic buffer panel 84 made of a synthetic resin material having elasticity, vibration or shock caused by an earthquake due to the elasticity of the elastic buffer spring 82 and the elastic buffer panel 84. In addition to buffering the transmission to the sewer pipe 100, the sewer pipe 100 is supported to prevent it from being moved by external force or sagging by its own weight.

Here, by attaching or welding one end of a support pin made of a metal material to the outer surface of the gas discharge pipe 41, the supporting force of the gas discharge pipe 41 is improved by the support pin buried in the ground, thereby preventing the gas discharge pipe 41 from being moved by an external force.

In addition, by further screwing and fixing a vibrator, which is a vibrator, to the outer surface of the gas discharge pipe 41, the vibration of the vibrator is transmitted to the gas discharge pipe 41 and foreign substances adhering to the inner surface of the gas discharge pipe 41. It is preferable to increase the removal efficiency of foreign substances, prevent the gas discharge pipe 41 from being clogged by foreign substances, and quickly reduce maintenance costs due to the removal of foreign substances.

In the sewage pipe 100 discharge device installation step (S5), the situation awareness work guidance step (S5-1) is further included to grasp the work situation at the site by the situation awareness work guide means 90 and transmit a danger signal in case of an emergency.

The situation awareness operation guide means 90 includes a connection fixing module unit 91 screwed to and fixed to the sewer pipe 100, a pair of guide shafts 92 whose lower ends are connected to and fixed to the upper surface of the connection fixing module unit 91, a first panel transfer module 931 and a second panel transfer module 9 inserted through the guide shaft 92 and guided along the guide shaft 92 32) and a third panel transfer module 933, a first lift guide unit 941 whose lower end is screwed and fixed to the upper surface of the connection fixing module unit 91, and whose lifting shaft is screwed and fixed to the lower surface of the first panel transfer module 931; A second lift guide unit 942 fixed by screwing to the lower surface of the transmission module 932, a lift guide unit 94 composed of a third lift guide unit 943 whose lower end is screwed and fixed to the upper surface of the second lift guide unit 942 and whose lifting shaft is screwed and fixed to the bottom surface of the third panel transfer module 933, and the lower surface of the first panel transfer module 931 The first rotation guide units 951 to which the first rotation module unit 951-1 is screwed to the rotation shaft, the second rotation guidance units 952 to which the second panel transfer module 932 is screwed to the bottom surface and the second rotation module unit 952-1 to the rotation shaft, and the third panel transfer module 933 to which the bottom surface is screwed to and fixed to the rotation shaft The third rotation module unit 953-1 includes a rotation guide unit 95 composed of third rotation guide units 953 to which the third rotation module unit 953-1 is screwed together, first situation recording units 961 screwed and fixed to the lower surface of the first rotation module unit 951-1, second situation recording units 962 screwed and fixed to the bottom surface of the second rotation module unit 952-1, and the third rotation module unit The situational photographing unit 96 composed of third situational photographing units 963 screwed and fixed to the bottom surface of the 953-1, screwed and fixed to the connection fixing module unit 91, electrically connected to and controlled by the elevation guide part 94 and the rotation guide part 95, and taking pictures of the first situational photographing units 961, the second situational photographing units 962, and the third situational photographing unit 963 A control unit 97 that receives information, a transmission/reception unit 98 that is screwed and fixed to the third panel transfer module 933, and that transmits shooting information of the first situation capturing units 961, second situation capturing units 962, and third situation capturing units 963 transmitted from the control unit 97, and the third panel transfer module 933 that is screwed and fixed to the signal of the control unit 97. It consists of a status guide speaker 99 that receives and guides voice or generates an alarm.

The connection fixing module unit 91 has a panel structure made of a metal material and is disposed on the ground.

The first panel transfer module 931, the second panel transfer module 932, and the third panel transfer module 933 are formed of metal or synthetic resin panels, and a transfer hole is formed to be inserted through the guide shaft 92.

The first lift guide unit 941, the second lift guide unit 942, and the third lift guide unit 943 are cylinders, the first rotation guide unit 951, the second rotation guide unit 952, and the third rotation guide unit 953 are motors, and the first situation capture units 961, the second situation capture units 962, and the third situation capture unit ( 963) is a camera.

In addition, the first rotation module unit 951-1, the second rotation module unit 952-1, and the third rotation module unit 953-1 are formed in a circular or square panel structure.

The first situation photographing units 961, the second situation photographing units 962, and the third situation photographing unit 963 can change their heights by driving the first elevator guide unit 941, the second elevator guide unit 942, and the third elevator guide unit 943, and can photograph the ground or field situations or risk factors.

The control unit 97 receives the signal received by the transmission/reception unit 98 through the manager terminal and controls the status guide speaker 99 to transmit voice or generate an alarm.

That is, after recognizing a dangerous situation of a phenomenon through the photographing information, a danger signal is transmitted through the status guide speaker 99 to prevent safety accidents in the field.

In addition, the control unit 97 receives signals received by the transmitting and receiving unit 98 through the manager terminal and controls driving of the lift guide unit 94 and the rotation guide unit 95, so that the positions of the first situation capture units 961, the second situation capture units 962, and the third situation capture unit 963 can be changed.

Although the present invention has been described in detail so far, it is clear that the embodiments mentioned in the process are only illustrative and not limiting, and the present invention is provided by the following claims. Within the scope of not departing from the technical spirit or field of the present invention, component changes to the extent that they can be equally coped with will fall within the scope of the present invention.

10: discharge device 20: connection panel
21: communication hole 211: support shaft
30: connection pipe 40: toxic gas discharge unit
41: gas discharge pipe 42: discharge fan
53: control valve 50: gas detection sensor
60: work protection pipe 70: blocking protection net
80: earthquake-resistant elastic shock-absorbing means 81: earthquake-resistant reinforcing pipe
82: elastic buffer spring 83: earthquake-resistant buffer panel
84: elastic buffer panel 90: situation awareness operation guidance means
91: connection fixing module unit 92: guide shaft
93: transfer module unit 931: first panel transfer module
932: second panel transfer module 933: third panel transfer module
94: lift guide unit 941: first lift guide unit
942: second lift guide unit 943: third lift guide unit
95: rotation guide unit 951: first rotation guide unit
951-1: first rotation module unit 952: second rotation guide unit
952-1: second rotation module unit 953: third rotation guide unit
953-1: 3rd rotation module unit 96: situation shooting unit
961: first situation recording unit 962: second situation recording unit
963: third situation shooting unit 97: control unit
98: transmission and reception unit 99: status information speaker
100: sewer pipe 200: through hole
300: excavator

Claims (2)

As a construction method of a discharge device for discharging toxic gas inside the sewer pipe,
An excavation hole forming step of excavating the ground to form an excavation hole to expose the sewage pipe;
A work protection pipe fastening step of inserting a work protection pipe into the excavation hole to support the inner surface of the excavation hole and to block foreign substances or soil from flowing into the exposed sewage pipe;
A blocking protection net installation step of installing a blocking protection net on the upper part of the work protection tube to block foreign substances from entering the inside of the work protection tube;
A sewage pipe through-hole forming step of perforating the sewer pipe to form a through-hole through which toxic gas is discharged;
A sewage discharge device installation step of installing a discharge device in the sewer pipe to discharge toxic gas inside the sewer pipe;
A pilot driving step of a discharge device for discharging toxic gases in the sewer pipe by driving the discharge device installed in the sewer pipe;
A drilling hole work protection pipe separation removal step of separating the work protection pipe installed in the drilling hole; and
It consists of an excavation hole embedding step of filling the excavation hole by introducing soil into the excavation hole from which the work protection pipe is separated,
The work protection pipe and the blocking protection net prevent foreign matter or soil from entering the excavation hole, and the discharge device discharges toxic gas from the sewer pipe,
In the construction method of the toxic gas discharge device,
The discharge device has a communication hole formed in communication with the through hole formed in the sewer pipe, and a connection panel fastened to and fixed to the outer surface of the sewer pipe;
a connection pipe having one end connected to and fixed to an upper surface of the connection panel so as to communicate with the communication hole; and
It is made of a toxic gas discharge part that is fastened to the connection pipe and discharges toxic gas inside the sewer pipe to the outside,
The toxic gas discharge unit,
A gas discharge pipe having one end fitted and fixed to the connection pipe and the other end disposed outside;
A discharge fan fastened to the gas discharge pipe to discharge toxic gas inside the sewer pipe;
It is made of a control valve fastened to the gas discharge pipe to control the movement of toxic gas in the gas discharge pipe,
One end of a support shaft is connected and fixed to the inner surface of the connection pipe, and the other end of the support shaft is disposed inside the sewer pipe,
A gas detection sensor is further fastened to the other end of the support shaft to detect toxic gas inside the sewer pipe and transmit a detection signal to the control valve and the discharge fan,
The control valve and the discharge fan receiving the signal of the gas detection sensor are driven to discharge the toxic gas inside the sewer pipe to the outside,
The situation recognition operation guide means,
A connection fixing module unit that is screwed and fixed to the sewer pipe;
A pair of guide shafts having lower ends connected to and fixed to the upper surface of the connection fixing module unit;
A transfer module unit composed of a first panel transfer module, a second panel transfer module, and a third panel transfer module that are inserted through the guide shaft and guided along the guide shaft;
A first lift guide unit whose lower end is screwed and fixed to the upper surface of the connection fixing module unit and whose lower end is screwed and fixed to the lower surface of the first panel transfer module, a second lift guide unit whose lower end is screwed and fixed to the upper surface of the first panel transfer module and whose lift shaft is screwed and fixed to the bottom surface of the second panel transfer module, and whose lower end is screwed and fixed to the upper surface of the second lift guide unit, An elevation guide portion composed of a third elevation guide unit having a strong shaft screwed and fixed to the bottom surface of the third panel transfer module;
The first rotation guide units screwed and fixed to the bottom surface of the first panel transfer module, the first rotation module unit is screwed to the rotating shaft, the second rotation guide units to which the second panel transfer module is screwed and fixed to the bottom surface and the second rotation module unit is screwed to the rotation shaft, and the third rotation guide unit composed of the third rotation guide units to which the third panel transfer module is screwed to the bottom surface and the third rotation module unit is screwed to the rotation shaft ,
A situation capturing unit composed of first situation capturing units screwed and fixed to the bottom of the first rotation module unit, second situation recording units screwed and fixed to the bottom of the second rotation module unit, and third situation recording units screwed and fixed to the bottom of the third rotation module unit;
A control unit that is screwed to and fixed to the connection fixing module unit, electrically connected to and controlled by the elevation guide unit and the rotation guide unit, and receives photographing information of first situation capture units, second situation capture units, and third situation capture units;
Transmitters and receivers screwed to and fixed to the third panel transfer module and transmitting photographing information of the first situation photographing units, second situation photographing units, and third situation photographing units transmitted from the control unit;
A method of constructing a toxic gas discharge device for a sewage pipe with an earthquake-resistant function, characterized in that it is screwed and fixed to the third panel transfer module and consists of a status guide speaker that receives a signal from the control unit to guide a voice or generate an alarm.


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