KR102000140B1 - Automatic condensate water discharge system for landfill gas transfer pipe - Google Patents

Abstract

The present invention relates to a method of controlling a landfill, comprising the steps of: introducing one side of a manhole to be buried in a surface layer of a landfill and passing through the landfill; A gas impact tube which is formed so as to be bent with respect to the inflow conduit so that the landfill gas flowing out from the inflow conduit collides against the inner side so that moisture contained in the landfill gas is condensed by impact, And a condensed water discharge pipe branched from the gas impingement pipe to discharge the condensed water contained in the landfill gas, the condensed water discharge pipe being connected to the gas impingement pipe, And a condensed water discharge system.
According to the above description, in order to energize the landfill gas generated from the landfill, the condensed water generated in the landfill gas pipeline is automatically discharged in the non-power and non-power state during the accumulation and transfer of the landfill gas, It is possible to prevent the cross section from being reduced or the flow to be blocked, thereby enabling the landfill gas to be transported stably and smoothly.

Description

[0001] The present invention relates to an automatic condensate water discharge system for landfill gas transfer pipes,

The present invention relates to a system for automatically discharging condensed water generated during transfer of a landfill gas, and more particularly, to a system and method for automatically discharging condensate generated during the transfer of a landfill gas, The present invention relates to an automatic discharge system for condensate in a transfer pipe.

Generally, a waste disposal method in a landfill is a process in which the waste is buried at a certain height to be buried, and then the buried waste is covered with soil or a similar shield (usually called a "superficial layer"), A waste treatment method is used in which waste is spontaneously decomposed.

In such a waste disposal method, buried gas having flammability is generated in the course of the natural decomposition of the buried waste. A plurality of gas discharge pipes having gas inflow holes are installed in the waste landfill, and the buried gas generated from the waste is discharged to the outside To reduce the risk of fire or explosion at the landfill.

As an example of such a technology for discharging the landfill gas, Korean Patent Registration No. 10-1185139 discloses a waste tire slice layer composed of a waste tire slice formed of a filler layer laid on waste at a final final cover layer of a waste landfill, A landfill gas containing waste tires in a landfill comprising a barrier layer disposed at a predetermined thickness on the sliced layer, a drainage layer disposed on the barrier layer with a predetermined thickness, and a vegetation layer disposed on the drainage layer with a predetermined thickness, Collection and discharge structures have been disclosed.

On the other hand, the landfill gas discharged to the outside of the landfill is usually discarded by incineration, but in recent years, research has been actively carried out on the production of environmentally friendly and inexpensive energy using electricity from power generation using landfill gas.

However, since the landfill gas generated in the landfill contains a large amount of water, the efficiency of the power generation is lowered by supplying the landfill gas directly to the power plant, and the lifespan of the power generation facility is shortened. In addition to not being practical, it is difficult to transfer the landfill gas reliably because the flow cross-sectional area through which the landfill gas flows out is reduced due to the condensate generated in the transfer pipe during the capture and transfer of the landfill gas, .

Korean Patent No. 10-1185139

An object of the present invention is to provide an automatic condensate discharge system for a landfill gas transfer pipe capable of automatically and efficiently discharging condensed water generated during transfer of a landfill gas so that the flow of the landfill gas in the transfer pipe can be more stably and smoothly performed .

The present invention relates to a method of controlling an internal combustion engine, which is provided with an inlet passageway through which a buried manhole flows, an inlet passageway through which a manhole is buried in a surface portion of a landfill and one side of which is communicated with the other side of the inlet passageway The gas impingement tube being formed to be bent with respect to the inflow conduit such that the inflow gas flowing out from the inflow conduit collides against the inner side so that moisture contained in the buried gas is condensed by impact, A condensed water discharge pipe connected to the pipe and connected to the pipe to discharge the condensed water contained in the landfill gas and a portion including at least one of the gas impact pipe and the condensed water discharge pipe, And an outflow conduit through which the buried gas is drawn in and out. Provides an automatic condensate discharge system of the buried gas transfer tube in which.

Here, the inflow transfer pipe is disposed in a lateral direction, and the gas impact pipe is formed so as to be bent downward from the other side of the inflow transfer pipe. The upper portion of the inflow transfer pipe is vertically communicated with the gas impact pipe And the outflow conduit may be laterally disposed so as to form a "T" shape with respect to the gas impact pipe and the condensed water discharge pipe.

Further, the automatic discharge system for the condensed water of the buried gas transfer pipe may further include a nozzle unit installed in the inflow conduit in front of the gas impact pipe to increase the flow rate of the buried gas flowing out to the gas impact pipe.

The outflow conveying pipe is connected to the condensed water discharge pipe and one side to which the buried gas flows is inclined so as to be lower than the other side from which the buried gas flows out so that the condensed water contained in the buried gas flows by gravity, And may be formed to flow out.

In addition, the outflow conduit may be provided with a valve portion for regulating the flow of the flowing out of the buried gas.

The condensed water discharge pipe may be formed so that the sectional diameter gradually decreases downward.

Further, the condensed water discharged from the condensed water discharge pipe may be discharged to the receiving space of the excretory manhole and may be connected to the bottom portion of the excretory manhole to drain the condensed water in the receiving space to the landfill can do.

The drain portion may include a drain line extending from a bottom portion of the manhole so as to discharge the condensed water accumulated in the accommodation space and inclined downwardly and a settling portion provided at a discharge end of the drain line, Drain portion.

At this time, the settling part may be formed by filling up with crushed stone including gravel.

The drain may include a backflow prevention valve installed in the drain line to prevent groundwater in the landfill from flowing back into the accommodation space.

The condensate discharge pipe may be provided with a check valve that opens or closes the flow passage depending on the amount of the condensed water collected.

When the condensed water is filled in the upper part of the check valve and the set open water pressure is formed, the flow path is opened and the condensed water is discharged. When the condensed water is discharged and the water pressure is lower than the set shield water pressure, The discharge of the condensed water can be blocked.

At this time, the open water pressure may be set to be less than the water head pressure at which the condensed water is filled up to the bottom portion of the outflow pipe.

Furthermore, it is preferable that the maximum value of the open water pressure is limited to a pressure value obtained by subtracting the negative pressure in the pipe from the water head pressure at which the condensed water is filled up to the bottom portion of the outflow pipe.

Furthermore, the condensate discharge pipe may be provided with an on-off valve on the check valve so that the operator can selectively open and close the flow passage.

Meanwhile, the gas impact pipe may be bent downward in a direction perpendicular to the flow direction of the buried gas flowing into the inlet pipe.

The gas-impingement pipe may be bent downwardly so as to form an acute angle with respect to the flow direction of the buried gas flowing into the inlet pipe.

Here, the gas impingement pipe may be formed with a plurality of guide grooves for guiding the condensed water so that the condensed water formed on the inner surface of the gas impinging pipe flows out to the condensed water discharge pipe without being sucked into the outflow pipe.

In this case, the guide grooves are preferably formed so as to avoid the inlet port of the outlet port and to be spaced apart from the inlet port of the outlet port.

The automatic discharge system for condensed water of the landfill gas delivery pipe according to the present invention provides the following effects.

First, the condensate generated during the transfer of the landfill gas generated from the landfill is automatically discharged from the power plant (exclusion manhole) in the non-power and non-power state to increase the practicality for power generation and the inside of the landfill gas pipe It is possible to prevent the buried gas from being shrunk or blocked by the flow so that the buried gas can be transported stably and smoothly.

Second, the condensed water generated in the transfer pipe through the gas impact pipe and the condensed water discharge pipe formed vertically downward can be effectively discharged by its own weight, and at the same time, the landfill gas collides with the inner wall of the gas- The efficiency can be further improved and the combustion efficiency of the landfill gas can be improved by removing moisture in the landfill gas, thereby improving the efficiency of producing high-efficiency renewable energy.

Third, the check valve which is opened and closed by the water pressure of the condensate is installed in the discharge pipe of the condensate water. When the check valve receives the constant water pressure, it is set to be opened when the pressure value reaches the open pressure value so that the condensed water is automatically discharged. So that the inside of the entire transfer pipe including the inflow conduit and the gas impact pipe and the outflow conduit and the condensate discharge pipe is always kept in a sealed state to prevent the inflow of air and maintain the sound pressure formed by the suction of the blower have.

Fourth, by installing a check valve that is automatically opened and closed by the water pressure of the condensate in the discharge pipe of the condensed water, unexpected obstacles such as leakage of condensed water or evaporation, which may occur when the internal air pressure of the transfer gas pipe is shut off only to the condensate water And the condensate outlet is exposed to the atmosphere to prevent the inflow of air which seriously affects the landfill gas.

Fifth, it is easy to maintain and manage the landfill gas concentration and so on by allowing the operator to selectively block and open the flow of the landfill gas by installing the valve portion in the outflow pipe and opening / closing valve in the condensed water discharge pipe.

1 is a view showing a configuration of a landfill gas discharge system in which a condensed water automatic discharge system of a landfill gas delivery pipe according to an embodiment of the present invention is installed.
2 is a cross-sectional view showing a configuration of an automatic condensate discharge system of the buried gas transfer pipe of FIG.
Fig. 3 is a front sectional view showing another embodiment of the gas impacting tube of Fig. 2; Fig.
Figs. 4 and 5 are views showing guide grooves formed in the gas impact tube of Fig. 2. Fig.
Fig. 6 is a front sectional view showing the case where the nozzle portion is provided in the gas impacting tube of Fig. 2;

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

The automatic drainage system for condensate water (hereinafter, referred to as 'automatic drainage system for condensate water') of the gas discharge pipe according to the embodiment of the present invention is installed in the landfill gas discharge system for discharging the landfill gas from the landfill, It collects and condenses the contained water to generate condensed water and discharges it to smooth the flow of the landfill gas. Here, it should be understood that the water may not only refer to moisture composed of water particles contained in the landfill gas but may also include both suspended matter in a liquid state and liquid in a landfill gas.

Referring to FIG. 1, the buried gas discharge system includes a plurality of conveyance branch pipes 10 installed in a landfill and fed with a landfill gas, and a plurality of conveyance branch pipes 10 connected to the conveyance branch pipes 10, And a blower unit (30) connected to the conveyance header pipe (20). The conveyance header pipe (20) Therefore, it is preferable that the automatic discharge system of condensate is located at the low point of the conveyance pipe in which the discharge of the condensed water is advantageous in the landfill gas discharge system, but it can be installed anywhere in the pipe where the landfill gas is transported. 1, reference numeral 40 denotes a power generation facility.

The condensed water automatic discharge system will be described in detail with reference to FIG. The automatic condensate discharge system includes an inlet transfer pipe 100, a gas impact pipe 200, a condensed water discharge pipe 400, and a drain part 500 to automatically discharge condensate generated during the transfer of the flushing gas .

The condensed water automatic discharge system forcibly flows the landfill gas by the suction force of the blower unit 30 and the suction force of the blower unit 30 causes the inlet / The internal pressure of the condensed water discharge pipe 400 and the discharge pipe 300 is maintained at a negative pressure lower than the atmospheric pressure.

The inflow canal 100 is disposed in the lateral direction and flows into the inside of the inflow canal 100. The infiltrated manhole 50 is installed in the surface layer of the landfill to protect the buried gas discharge system. And one side is provided so as to penetrate into the space 51.

The gas impact pipe 200 is located in the accommodation space 51 and is formed to be bent downward from the other side of the inflow conduit 100. In detail, the gas impact pipe 200 is connected to the other side of the inflow conduit 100 so that one end thereof is connected to the other side of the inflow conduit 100, and the inflow gas is introduced from the inflow conduit 100, Is bent with respect to the inflow conduit 100 so as to collide with the inner side.

Here, the gas impact tube 200 causes the buried gas to collide with the inner surface, so that moisture contained in the buried gas is condensed by the impact. This is because when the buried gas flows through the inlet pipe 100 at a constant pressure and then collides with the gas impact pipe 200, the pressure is increased, the distance between the buried gas molecules becomes closer, the intermolecular attraction increases and the evaporated water condenses This is because the condensation water is generated as the phenomenon occurs, and the condensed water thus generated flows downward due to its own weight.

In the drawing, the gas impact pipe 200 is formed so as to bend in a downward vertical direction so that condensed water formed on the inner wall surface is discharged smoothly downward by its own weight.

3 is a view showing another embodiment of the gas impacting tube 200. As shown in FIG. Referring to the drawings, the gas impact pipe 200 is bent downwardly at an acute angle with respect to the flow direction of the buried gas flowing into the inlet pipe 100. This can effectively prevent the backflow of the condensed water generated in the gas impact pipe 200 to the inflow conduit 100 and also prevent the inclination direction of the gas impact pipe 200 from being different from the outlet of the outflow pipe 300 The flow direction of the condensed water can be effectively prevented from flowing into the pipeline 300 when the condensed water flows down.

FIGS. 4 and 5 are views showing another embodiment of the gas impact tube 200. FIG. Referring to the drawings, the gas impact pipe 200 includes a plurality of guide grooves (not shown) for guiding the condensed water to be discharged into the condensate discharge pipe 400 without being sucked into the discharge pipe 300, 210 may be formed.

The guide grooves 210 guide the condensed water formed on the inner wall of the gas impact pipe 200 to flow down to the condensate discharge pipe 400 without flowing into the discharge pipe 300, So that the outflow is formed on the outer side of the inlet of the pipeline 300.

The guide groove 210 may extend downwardly from the gas impact pipe 200 through the condensed water discharge pipe 400 and may be spaced apart from each other to form a plurality of layers as shown in FIG. It is possible.

Meanwhile, the condensed water automatic discharge system can increase the flow rate of the buried gas flowing into the gas impact pipe 200, thereby increasing the impact energy of the buried gas inside the gas impact pipe 200, thereby improving the efficiency of collecting condensed water. To this end, the inflow passageway 100 forms a nozzle unit 220 in front of the gas impact pipe 200 as shown in FIG.

The nozzle unit 220 is installed in the forward inflow passageway 100 of the gas impact pipe 200 to increase the flow rate of the landfill gas flowing out to the gas impact pipe 200, And is formed into a cylindrical shape gradually decreasing.

The nozzle unit 200 may be integrally formed with the inflow conduit 100 or may be formed in a separate structure from the inflow conduit 100 as shown in the figure so that the front inflow conduit 100 ).

The outflow conduit 300 is communicatively connected to a portion including at least one of the gas impact pipe 200 and the condensed water discharge pipe 400 and passes through the gas impact pipe 200 so that the moisture content So that the buried gas in a lowered state is sucked and discharged.

In the drawing, the outflow duct 300 is formed to be bent in the lateral direction from the other side of the gas impact pipe 200, and is installed so as to penetrate outwardly from the accommodation space. Specifically, the outflow conduit 300 extends laterally in a portion where the gas impact pipe 200 and the condensed water discharge pipe 400 are connected to each other, so that the gas impinging pipe 200 and the condensed water discharge pipe 400 have a T Quot; shaped < / RTI >

The outflow conduit 300 is disposed such that one side of the outflow conduit 300 is lower than the other side where the buried gas flows out, and the condensed water contained in the buried gas flows to one side due to gravity and flows out to the condensed- .

In the meantime, although the outflow canal 300 is located at a lower height than the inflow canal 100, the infiltration canal and the outflow canal are arranged in a line with each other, 100 and the outflow pipe 300 are arranged horizontally in a line.

To this end, the gas impact pipe 200, the condensed water discharge pipe 400, and the inclined connection pipe (not shown), which is disposed obliquely and connected to the existing discharge pipe, are connected to each other so as to communicate with each other, Through the piping connection means, the existing outflow and overflow can be used in the receiving space by fastening to the pipeline.

The outflow conduit 300 may be provided with a valve portion 310 for controlling the flow of the flowing out inflow gas. The valve unit 310 includes a ball valve 311 and a wiping valve 312 to block the flow of the buried gas and flow of the buried gas, thereby facilitating the maintenance.

The condensed water discharge pipe 400 is branched from the other side of the gas impact pipe 200 to which the discharge pipe 300 is connected and is disposed downwardly in a 'T' shape. The condensed water discharge pipe 400 is connected to the gas impact pipe 200 and is installed in a vertical direction so that the condensed water contained in the landfill gas flows out due to its own weight.

The gas inlet pipe 100 and the gas impingement pipe 200 are connected to each other through a connection flange and the gas impact pipe 200 and the outlet pipe 300 and the condensed water discharge pipe 400 The T-shaped pipe may be formed integrally with each other. However, in an embodiment, the inlet pipe 100, the gas impact pipe 200, the outlet pipe 300, and the condensed water discharge pipe 400 It is needless to say that the present invention can be applied to a variety of configurations such as manufacturing each one integrally with the design, separating at least one or more, assembling each other on the site.

The condensed water discharge pipe 400 is formed so that the sectional diameter gradually decreases toward the downward direction so as to reduce the size of the check valve 410 and the opening and closing valve 420 which will be described later, So that it is possible to be sensitive to the water pressure of water.

The condensate discharge pipe 400 may be provided with a check valve 410 that opens or closes the flow passage depending on the amount of condensed water collected. The check valve 410 is adapted to block the upward and downward flow corresponding to the condensed water discharge pipe 400 arranged in the vertical direction so that the flow from the upper part to the lower part is possible but the flow from the lower part to the upper part is blocked.

When the condensed water is filled in the upper part of the check valve 410 and the set open water pressure is formed, the flow path is opened to discharge the condensed water. When the condensed water is discharged and the water pressure is lower than the set water pressure, So that the discharge of the condensed water can be blocked. At this time, when the valve using the spring is applied, the check valve 410 is opened to open the flow path when the open water pressure is higher than the spring force, and the flow path is closed by the spring force when the shield water pressure is lower than the spring force.

Hereinafter, the opening and closing of the check valve 410 will be described. The check valve 410 sets the open water pressure to less than the water head pressure at which the condensed water is filled up to the bottom portion of the outflow pipe 300. Further, the maximum value of the open water pressure is determined by taking into account the rise of the water head due to the negative pressure in the pipe by the blower unit 30, and by subtracting the negative pressure in the pipe from the water head pressure filled with condensed water to the bottom face of the outflow pipe 300, ) To a certain pressure value.

For example, if the opening pressure of the check valve 410 is determined to be 0.042 kgf / cm 2, it is 420 mmH ₂ O in terms of the water pressure, so the water level at which the check valve 410 opens is 420 mm So that the condensate is discharged automatically only when the condensate exceeds the set water level. When the predetermined water level of the condensed water discharge pipe 400 for opening the check valve 410 is equal to the inlet port of the discharge pipe 300, the condensed water flows into the discharge pipe 300 by the suction force of the fan unit 30 In order to prevent this, the condensed water discharge pipe 400 is constructed by setting a condensate overflow preventing height h of a predetermined height. In general, when the sound pressure by the air blowing unit 30 in the inside of the general buried gas conveying pipe is 300 considering that the ㎜H ₂ O is made up of condensed water overflow prevention of choices 300㎜.

The check valve 410 may be a check valve that is opened by a known spring force and is opened when a predetermined opening pressure is applied. However, various configurations can be applied as long as the above- A description thereof will be omitted.

The condensate discharge pipe 400 may be provided with an on-off valve 420 on the check valve 410 so that the operator can selectively open and close the flow passage. The opening / closing valve 420 is always open during normal operation, and when the check valve 410 needs to be repaired or replaced and the flow path of the condensed water discharge pipe 400 needs to be shut off, .

When the check valve 410 is opened, the condensed water collected in the condensed water discharge pipe 400 is dropped to the bottom of the accommodation space 51 of the rejection manhole 50, 500).

The drain portion 500 is provided to communicate with the bottom portion of the reject manhole 50 to drain and discharge the condensed water in the receiving space 51. Specifically, the drain portion 500 includes a drain line 510, a settling portion 520, and a check valve 530. The drain line 510 is formed to penetrate from the bottom portion of the reject manhole 50 so as to discharge the condensed water accumulated in the receiving space 51, and is formed to be inclined downward.

The sedimenting unit 520 is installed at the discharge end of the drain line 510 and is buried in the landfill so that the condensate discharged from the drain line 510 can quickly flow out to the landfill. The sedimenting unit 520 may be filled with crushed stone containing gravel, but is not limited thereto.

The backflow prevention valve 530 is installed in the drain line 510 to prevent the groundwater from flowing back into the accommodation space 51 when the water level of the landfill increases.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: feed branch tube 20: transfer header tube
30: blower unit 40: power generating facility
50: Exclusion manhole 51: Capacity space
100: Inflow pipe 200: Gas impact pipe
210: guide groove 220: nozzle part
300: outflow conduit 310: valve portion
311: Ball valve 312: Drain valve
400: condensate discharge pipe 410: check valve
420: opening / closing valve 500: drain part
510: drain line 520:
530: Backflow prevention valve

Claims (12)

An inflow passageway through which the buried manhole is installed, the one side of which is penetrated into the receiving space of the rejected manhole buried in the surface layer of the landfill;
The inflow port is formed in the receiving space and is connected to the other side of the inflow port, and the inflow port is formed to be bent with respect to the inflow port, so that the inflow gas from the inflow port collides with the bent inner surface, A gas impingement tube for causing the contained moisture to condense by impact;
A condensate discharge pipe located in the accommodation space and connected to the gas impact pipe to discharge condensed water contained in the buried gas;
An outflow duct connected to the condensed water discharge pipe at the lower portion of the gas impact pipe and installed to penetrate outwardly from the accommodation space to allow the buried gas to flow in and out; And
And a drain portion communicating with the bottom portion of the manhole for discharging the condensed water in the receiving space and discharging the condensed water to the landfill,
Said inflow conduit being arranged in a transverse direction,
Wherein the gas impingement tube is formed to be bent downward from the other side of the inflow conduit,
The condensed water discharge pipe has a top communicating with the gas impingement tube and standing up in a vertical direction,
The outflow conduit is laterally disposed to form a "T" shape with respect to the gas impact tube and the condensate outlet tube, and is positioned below the inlet conduit and the gas impact tube,
Wherein the outflow conveying pipe comprises:
And the condensed water flowing out of the condensed water discharge pipe is discharged from the condensed water discharge pipe, and the condensed water discharged from the condensed water discharge pipe is discharged from the condensed water discharge pipe,
The gas impingement tube
Wherein the inlet is bent at an acute angle with respect to the flow direction of the buried gas flowing into the interior of the pipeline;
A plurality of guide grooves are formed in the side surface of the gas-impingement tube for guiding the movement path of the condensed water to the condensed-water discharge pipe so as to prevent the condensed water formed on the gas-impingement tube side from being sucked into the out-
The guide grooves
The outflow avoiding the inlet port of the delivery port and the outflow being formed outwardly from the inlet port of the delivery port,
The drain portion
A drain line formed to penetrate from the bottom portion of the manhole so as to discharge the condensed water accumulated in the receiving space and inclined downward;
A backflow prevention valve installed in the drain line to prevent the groundwater of the landfill from flowing back to the accommodation space; And
And a settling portion formed by filling crushed stone including gravel at the discharge end of the drain line.
delete The method according to claim 1,
Further comprising a nozzle unit installed in the inflow conduit at a front side of the gas impacting tube to increase a flow rate of the buried gas flowing out to the gas impacting tube.
delete The method according to claim 1,
Wherein the outflow conveying pipe comprises:
Wherein a valve portion for regulating the flow of the flowing out of the buried gas is installed.
The method according to claim 1,
The condensed-
And the cross-sectional diameter gradually decreases toward the downward direction.
delete The method according to claim 1,
The condensed-
Wherein a check valve is provided to open or close the flow path depending on the amount of the condensed water collected.
9. The method of claim 8,
The check valve
The condensed water is discharged and the condensed water is discharged. If the condensed water is discharged and the water pressure is lower than the set water pressure, the flow passage is closed and the discharge of the condensed water is blocked Automatic discharge system for condensate of landfill gas pipeline. 10. The method of claim 9,
The open water pressure,
Wherein the outlet is set to be less than a water head pressure filled with condensed water to the bottom portion of the pipeline. 11. The method of claim 10,
The maximum value of the open-
Wherein the outlet is limited to a pressure value obtained by subtracting the negative pressure in the pipe from the water head pressure filled with condensed water to the bottom of the pipeline. delete

Images