KR101103762B1 - Air Pressure Pipe Device of Auto Waste Collection System - Google Patents

Abstract

The present invention relates to a pneumatic piping device of an automatic waste collection facility, and more particularly, to an air supply line for efficient utilization and maintenance of a pneumatic line for driving a pneumatic valve installed in a transport line of an automatic waste collection facility. .

The pneumatic piping device of the automatic waste collection facility according to the present invention includes a pneumatic line provided to drive a pneumatic valve of the transfer pipe used in the automatic waste collection facility or a pneumatic valve of the waste inlet;

The pneumatic line is composed of two pneumatic lines of the main air pressure line and the auxiliary air pressure line, it is characterized in that it is configured to supply air through one pneumatic line through the other pneumatic line when one pneumatic line failure .

Garbage collection facility, main air pressure line, auxiliary air pressure line, pressure gauge, manhole.

Description

Air Pressure Pipe Device of Auto Waste Collection System

The present invention relates to a pneumatic piping device of an automatic waste collection facility, and more particularly, to an air supply line for efficient utilization and maintenance of a pneumatic line for driving a pneumatic valve installed in a transport line of an automatic waste collection facility. .

Garbage collection facilities, such as apartments, officetels, commercial complexes, residential complexes, or complex complexes, bury transfer pipelines from garbage dumps to household inputs or indoor / outdoor public inputs, and feed from them. It is a system that transfers the waste to the garbage dump by vacuum suction force formed in the transport pipe.

1 is a schematic diagram of a general garbage collection facility.

Garbage input from a plurality of garbage inlets 2 installed in various places on the ground to inject wastes is transported along a transport pipeline 3 embedded in the basement and collected at the waste storage 1, and air is sucked into the blower. It is aspirated to si) and discharged to outside through environmental pollution prevention facilities.

The conveying conduit 3 is a main conveying passage extending from the trash can 1 and communicates with the chute 6 which is branched from the conveying conduit 3 and connected to a plurality of waste inlets 2, and is conveyed. The pipe 3 and the inlet 2 are provided with a pneumatic valve (not shown).

In addition, an air inlet 4 for sucking external air at the time of transporting waste is installed at the front end of the transfer pipe 3, and a pneumatic line for driving a pneumatic valve is embedded along the transfer pipe 3.

Garbage put into the garbage inlet 2 is placed in the temporary storage part formed by the chute 6, and when the storage amount reaches the set range, the waste air is sucked into the garbage storage 1 through the transfer pipe 3 by suction of external air. Is sent.

That is, the waste of the conveying pipe 3 is conveyed to the waste storage 1 by suction of external air.

Such automatic waste collection facility can be convenient for users because it does not need to carry the garbage to the storage box (1) one by one, so that most of the facilities except the garbage inlet (2) can be provided. Since it is buried underground, it can provide a comfortable living environment, and it can process wastes automatically in a batch, which is very advantageous in terms of treatment efficiency and resource recycling.

However, if there is not enough air pressure due to leakage of the pneumatic line, the pneumatic valve cannot be driven, and thus there is a problem in that the opening and closing of the feed conduit 3 or the inlet 2 is impossible.

The present invention has been made in order to solve the above problems, by connecting a double pneumatic line to the pneumatic valve of the transfer pipe or inlet, in the event of an abnormality in the main pneumatic line to drive the pneumatic valve through the auxiliary pneumatic line transfer Pneumatic piping system of automatic waste collection facility that can open and close pipelines and inlets, and efficiently utilize and maintain the pneumatic lines buried underground by replacing the main air pressure lines while supplying air pressure through the auxiliary pneumatic lines. The purpose is to provide.

Pneumatic piping device of the automatic waste collection facility according to the present invention for achieving the above object is in the pneumatic line provided for driving the pneumatic valve of the conveying pipe used in the automatic waste collection facility or the pneumatic valve of the waste inlet;

The pneumatic line is composed of two pneumatic lines of the main air pressure line and the auxiliary air pressure line, it is characterized in that it is configured to supply air through one pneumatic line through the other pneumatic line when one pneumatic line failure .

According to the above-described problem solving means, it is possible to control the opening and closing of the conveying line and the inlet at all times, and to efficiently utilize and maintain the pneumatic line embedded in the basement.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

2 is an installation diagram of a pneumatic line according to an embodiment of the present invention.

As shown, the pneumatic piping apparatus according to the present invention includes two pneumatic lines 10 and 12, a three-way valve 30, a pressure gauge 40, a control line 50, and a controller 60.

The pneumatic line provided for driving the pneumatic valve 84 of the conveying pipe 80 or the pneumatic valve 84 of the waste inlet 82 is composed of a main air pressure line 10 and an auxiliary air pressure line 12. The pneumatic line 10 is buried underground and penetrates through the inspection manhole 20a, the section manhole 20b, and the pipeline blocking manhole 20c.

The auxiliary air pressure line 12 is branched from the main air pressure line 10 at the front manhole of the two manholes and buried side by side with the main air pressure line 10 and installed to meet the main air pressure line 10 at the next manhole.

As a result, air is normally supplied through the main air pressure line 10, and when the main air pressure line 10 fails, the air is supplied to the auxiliary air pressure line 12.

To this end, the three-way valve 30 and the pressure gauge 40 are provided in the manholes 20a, 20b, and 20c, respectively, and the three-way valve 30 has a branching point where the auxiliary air pressure line 12 branches from the main air pressure line 10. And the main air pressure line 10 and the auxiliary air pressure line 12 are installed, that is, the main air pressure line 10 and the auxiliary air pressure line 12 are connected to the three-way valve 30 to supply air. The direction is reversed.

At this time, the three-way valve 30 of the branch point is provided with two inlets and one outlet, the three-way valve 30 of the meeting point is provided with one inlet and two outlets.

In addition, a pressure gauge 40 is installed in the main air pressure line 10 between the three-way valve 30 in each manhole 20a, 20b, and 20c to measure the air pressure formed in the main air pressure line 10 by the inflow of air. .

In this way, the three-way valve 30 is installed in front of and behind the one manhole 20a, 20b, 20c, and the pressure gauge 40 is positioned between the front and rear three-way valves 30 of the manhole 20a, 20b, 20c. Installed in the main air pressure line 10, the operator can check the pressure of the pressure gauge 40 through the manholes 20a, 20b, and 20c or manually operate the 3-way valve 30 to switch the air supply direction. Can be.

The pressure of the pressure gauge 40 may be remotely checked or the three-way valve 30 may be automatically operated remotely, and the three-way valve 30 and the pressure gauge 40 may be provided at a controller in a central control station. 60 is connected to the control line 50 to transmit and receive a signal and the air pressure measured by the pressure gauge 40 is transmitted to the controller 60 is output to the pressure display unit 70, the three-way valve 30 is a controller By the control of 60, the air supply direction is switched.

Hereinafter, the operation according to the above configuration will be described with an example of remotely checking the pressure and operating the three-way valve 30.

Normally, the pneumatic valve 84 of the inlet 82 or the transfer conduit 80 is driven by the air pressure of the main air pressure line 10, and the air pressure at this time is measured by the pressure gauge 40 and transmitted to the controller 60. And displayed on the pressure display unit 70.

Then, when the air pressure is lowered due to leakage of air in the main air pressure line 10, the lower air pressure is displayed on the pressure display unit 70.

In addition, the controller 60 compares the measured air pressure with the reference air pressure and determines that there is an abnormality in the main air pressure line 10 when the measured air pressure is lower than the reference air pressure, and operates the 3-way valve 30 to supply air. By switching from the main air pressure line 10 to the auxiliary air pressure line 12, thereafter, the pneumatic valve 84 is driven by the air pressure of the auxiliary air pressure line 12.

As such, the main air pressure line 10 which is abnormal while supplying air through the auxiliary air pressure line 12 is replaced with a new main air pressure line 10.

As described above, when a problem occurs in the main air pressure line 10, the air flow may be easily switched using the auxiliary air pressure line 12, and at the same time, the air pressure measured by the pressure gauge 40 may be converted into a pressure display unit 70. ) Can be monitored in real time, so problems in the pneumatic lines (10, 12) can be immediately identified to respond quickly to emergency situations.

While specific embodiments of the present invention have been described and illustrated above, it will be apparent that the present invention may be embodied in various modifications by those skilled in the art. Such modified embodiments should not be understood individually from the technical spirit or prospect of the present invention, but should fall within the claims appended to the present invention.

1 is a schematic diagram of a general garbage collection facility,

Figure 2 is an installation of the pneumatic line according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: main air pressure line 12: auxiliary air pressure line

20: manhole 30: 3-way valve

40: pressure gauge 50: control line

60: controller 70: pressure display

80: conveying line 82: inlet

84: pneumatic valve

Claims (5)

In the pneumatic line provided to drive the pneumatic valve of the conveying line or the pneumatic valve of the waste inlet used in the automatic waste collection facility; The pneumatic line is composed of two pneumatic lines of the main air pressure line and the auxiliary air pressure line, the main air pressure line is buried underground to pass through the inspection manhole, section manhole, pipeline blocking manhole, the auxiliary air pressure line is two manhole Branched from the main pneumatic line in the front manhole of the middle and buried side by side with the main pneumatic line, and is installed to meet the main pneumatic line in the next manhole, A pneumatic piping device for an automatic garbage collection facility, characterized in that the air supply through one pneumatic line is configured to supply air through another pneumatic line when one pneumatic line breaks. The method of claim 1, The main air pressure line and the auxiliary air pressure line is connected to the three-way valve pneumatic piping device of the automatic waste collection facility, characterized in that the supply direction of air is switched. The method of claim 2, And the three-way valve is installed in front of and behind a manhole where the main air pressure line and the auxiliary air pressure line meet or branch. The method of claim 3, wherein Pneumatic piping device of the automatic waste collection facility, characterized in that the pressure gauge is installed in the main air pressure line between the front and rear three-way valve of the manhole. The method of claim 4, wherein The three-way valve and the pressure gauge are connected through a controller and a control line so that the air pressure measured by the pressure gauge is transmitted to the controller and output to the pressure display unit, and the three-way valve switches the air supply direction under the control of the controller. Pneumatic plumbing equipment for automatic garbage collection facility.

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