JPH08338783A - Detection technique for damage part in water blocking sheet at waste disposal place - Google Patents

Abstract

PURPOSE: To obtain a detection technique by which a damage part in a water blocking sheet is detected by arranging an optical fiber, laying the water blocking sheet so as to cover the optical fiber, heaping up wastes on the water blocking sheet, and detecting temperature at a time when permeated water raised by heat generated in the process of the change with time of the wastes is leaked, by using the optical fiber as a sensor. CONSTITUTION: A composite layer 15 which is composed of a water permeable mat 8 and a water nonpermeable layer 9 is laid on the bottom face 16, the slope 17 in its circumference and the small step part 18 of a waste disposal place 2, an optical fiber 6 is housed inside a porous sheath pipe 7 composed of a porous stainless steel pipe or the like, the optical fiber is connected, and an optical fiber cable 12 is arranged and installed. The cable 12 is arranged in a loop shape at equal intervals on the bottom face 16, the slope 17 and the small step part 18. The optical fiber 6 is used as a sensor. Wastes 3 are dumped on a water blocking sheet 4, heaped up, and covered with several layers of earth and sand layers 21. When a damage part A exists in the sheet 4, permeated water which has crept into the water permeable mat 8 flows down in the water- nonpermeable layer 9 so as to come into contact with the optical fiber 6, and temperature is detected by a temperature measuring instrument.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for detecting a damaged portion of a water blocking sheet of a waste disposal site, which detects a damaged portion of a water blocking sheet laid to block the ground and the waste at the waste disposal site.

[0002]

2. Description of the Related Art At a waste disposal site, waste is properly stored by a method that does not hinder the preservation of the living environment and is disposed of in landfill from the viewpoint of stabilizing and detoxifying the natural metabolic function. ing. The waste includes general waste and industrial waste, and among them, organic waste such as raw garbage, wood waste, paper waste, fiber waste, organic sludge, and incineration ash generated at home or in industrial activities. It is miscellaneous, including those that contain hazardous substances, and when those hazardous substances are contained, there is a risk of degrading and eluting, etc. when these wastes are landfilled, and polluting the environment. It is necessary to dispose of things with sufficient management.

[0003] Generally, in a managed final disposal site for industrial waste or a general waste disposal site, the waste landfilled in the waste disposal site is decomposed by microorganisms in the soil in the process of changing with time. However, because there is a risk of producing harmful substances due to chemical reactions, etc., these will become leachate along with rainwater, etc., and in order to prevent pollution of public water areas and groundwater and adverse effects on the surrounding environment due to these, A water barrier sheet made of synthetic resin or synthetic rubber is used to block the mountains from waste.

Further, the water-blocking sheet made of synthetic resin-based or synthetic rubber-based material is, for example, a structural defect at the joint of the water-blocking sheet, insufficient maintenance of the excavated surface of the waste disposal site, and waste. If it should be damaged due to operator's mistake when dumping the water, there is a risk that harmful substances in the waste will leak into the groundwater and pollute drinking water and agricultural water. The outflow of leachate due to the breakage of the slab should be detected at an early stage, and if it is found, the damaged part must be repaired promptly.

One of the methods for discovering the outflow of leachate from a waste disposal site is to dig an observation well around the waste disposal site.
Although there is a method of inspecting the water quality, this method cannot identify the location of water leakage, so it takes a considerable period of time to find and repair the damaged part of the impermeable sheet.

Further, as a method for detecting the damaged position of the water blocking sheet laid in the waste disposal site, a potential measuring method and an electric current measuring method to which electric exploration is applied are known. The potential measurement method is to apply a voltage to the inside and outside of the waste disposal site and detect the water leakage position from the distortion of the potential distribution generated inside the disposal site. In addition, the current measurement method is to install line electrodes that are orthogonal to each other at equal intervals on the upper and lower parts of the impermeable sheet,
The current flowing through the electrodes above and below the water-blocking sheet is measured, and the position of water leakage is detected from the change in this current.
However, all of these methods have a problem that they are uncertain, lack reliability, and are difficult to put into practical use.

By the way, Japanese Laid-Open Patent Publication No. 04-168335 discloses, "A liquid leakage monitoring device for monitoring liquid leakage (leakage) from a conduit such as a water pipe is generally known as follows. The scattered light increases at the part where the temperature rises, so the pulsed light is incident from one end of the optical fiber, the backscattered light returning to that end is observed, and the temperature is measured by the intensity of the backscattered light. Also, the position where the temperature rises is measured by the time from the incidence of pulsed light to the return of backscattered light. An optical fiber for temperature sensing is laid along a pipeline such as a water pipe, and this optical fiber is installed. Is thermally insulated from the conduit and is immersed in a liquid such as water that has leaked from the conduit. Part of Therefore, by connecting a backscattered light measuring device to one end of this temperature sensing optical fiber and measuring the backscattered light of the optical fiber, no matter where the leak occurs in the entire length of the pipeline. , The leak,
It becomes possible to detect it together with the position of the place. "
Is described.

Further, Japanese Patent Application Laid-Open No. 04-294236 discloses, "Reactive substances which chemically react with water to generate heat or endotherm, such as calcium chloride (CaCl ₂ ) and ferrous chloride which generate heat by chemically reacting with water. (FeCl ₂ ) etc. and the moisture that has penetrated into the optical fiber composite overhead ground wire are detected by the optical fiber type temperature distribution sensor via the optical fiber, and the temperature change at the position where heat is absorbed is detected. "Detecting the flooded position of".

[0009]

All of the conventional methods that apply electric exploration require specialized knowledge for analysis, have many uncertainties such as underground current or earth leakage, and are affected by disturbance factors. It is easy and therefore lacks reliability. Furthermore, it is possible to accurately respond to fluctuation factors such as changes in the landfill status of wastes over time, and to quickly and accurately detect damaged parts of the impermeable sheet at the waste disposal site. Not a thing.

Further, in the one disclosed in Japanese Patent Laid-Open No. 04-168335, an optical fiber for temperature sensing is laid along a conduit such as a water pipe, and this optical fiber is called a heat pipe. Insulation is performed, and the backscattered light measuring device is connected to one end of this temperature sensing optical fiber to keep the temperature of the part soaked in water. By measuring the backscattered light of the optical fiber, the position of the leaked area is detected.As waste materials containing organic substances such as organic sludge and incinerated ash change over time, they are decomposed by microorganisms in the soil. The heat generated in the process causes the temperature of the waste to be different from the rock temperature around the waste disposal site, and cuts off the rock and the waste, which was previously impossible. Laid to Not that detects the damaged part of the water-impervious sheet, is also not being able to directly use in the detection of the damaged part of the water-impervious sheet.

Further, in the one disclosed in Japanese Patent Application Laid-Open No. 04-294236, the reaction substance is a substance which chemically reacts with moisture to generate heat or endotherm, for example, calcium chloride (heat generating calcium chloride which chemically reacts with moisture to generate heat). CaC
l ₂ ), ferrous chloride (FeCl ₂ ), etc., to determine the position of water that has entered the optical fiber composite overhead ground wire, and is disclosed in the above-mentioned JP-A-04-168335. Similarly to the above, it is not intended to detect the damaged portion of the water blocking sheet laid to cut off the ground and waste, and it cannot be directly used to detect the damaged portion of the water blocking sheet.

According to the present invention, as wastes containing organic substances such as organic sludge and incineration ash change with time, the temperature of the wastes is increased by the heat generated in the process of being decomposed by microorganisms in the soil. Focusing on the fact that the temperature is different from the rock mass temperature, we have specialized knowledge in the analysis of the breakage point of the water shield sheet that was laid to cut off the ground rock and waste, which was previously impossible. Detecting the location of damage to the impermeable sheet at a waste disposal site that can be reliably detected at low cost with simple equipment without the need for environmental protection, without being affected by disturbance factors such as underground current and earth leakage. The purpose is to provide a construction method.

[0013]

In order to achieve the above object, a method for detecting a damaged portion of a waterproof sheet of a waste disposal site according to the present invention is to dispose an optical fiber at the waste disposal site and cover the optical fiber. As shown in the figure, laying a water-blocking sheet as described above, raising waste on the water-blocking sheet, and using the optical fiber as a sensor to measure the temperature when the leachate rises due to the heat generated in the process of time-varying waste containing organic substances. The temperature is measured by a temperature measuring device to detect the damaged portion of the water-blocking sheet.

In order to achieve the above object, the method for detecting a damaged portion of a water blocking sheet of a waste disposal site according to the present invention forms a permeable layer on the slope and bottom surface of the waste disposal site where groundwater flows down, Optical fiber is installed in the layer, and a water-blocking sheet that prevents leakage of leachate from the waste outside the waste disposal site is laid so as to cover the optical fiber, and the waste is piled up on the water-blocking sheet. , A temperature measuring device using an optical fiber sensor detects the temperature when leaked leachate rises due to the heat generated in the process of waste containing organic substances, and detects the damaged part of the water-blocking sheet. Is.

In order to achieve the above-mentioned object, the method for detecting the damaged portion of the water blocking sheet of the waste disposal site according to the present invention is a permeable layer and an impermeable layer on the slope and the bottom surface of the waste disposal site where groundwater flows down. A composite layer composed of a water-impermeable layer is provided, and an optical fiber housed in a porous sheath tube is arranged on the composite layer, and the leachate from the waste covers the porous sheath tube and leaks out of the waste disposal site. A waterproof sheet is laid to prevent this from happening, waste is piled up on the waterproof sheet, and the temperature at the time when the leachate rises due to the heat generated in the process of the waste containing organic substances changing over time is detected using an optical fiber sensor. The temperature measuring device is used to detect the damaged part of the waterproof sheet.

In order to achieve the above-mentioned object, the method for detecting the damaged portion of the water blocking sheet of the waste disposal site according to the present invention is to form a water permeable layer on the base layer provided on the slope and bottom of the excavated ground. Then, an optical fiber is arranged in the water permeable layer, a water blocking layer is formed so as to cover the water permeable layer, and the temperature at which the leachate leaked from the water permeable layer passes through the water permeable layer uses the optical fiber as a sensor. The temperature is measured by a temperature measuring device to detect the damaged portion of the water-blocking sheet.

The base layer in the method for detecting a damaged portion of the impermeable sheet of the waste disposal site according to the present invention is to prevent groundwater leached from the natural ground from penetrating into the permeable layer and to prevent leakage of leached water from the impermeable layer to the ground. It protects the mountains from entering.

The base layer in the method of detecting a damaged portion of the water blocking sheet of the waste disposal site according to the present invention is a layer of a water blocking sheet made of a synthetic resin or synthetic rubber material or a bentonite-impregnated mat.

The base layer in the method for detecting a damaged portion of the water blocking sheet of the waste disposal site according to the present invention is a spray layer of mortar or rubber asphalt.

The impermeable layer in the method of detecting a damaged part of the impermeable sheet of the waste disposal site according to the present invention is a single impermeable sheet or a laminated impermeable sheet and a foamed polyethylene sheet.

The water-permeable layer in the method of detecting a damaged portion of the water-blocking sheet of the waste disposal site according to the present invention is a non-woven mat,
It is a single mat for drain or a combination of them.

[0022]

[Function] As wastes containing organic substances such as organic sludge and incineration ash change over time, the temperature of the wastes is higher than the ground temperature around the waste disposal site due to the heat generated in the process of being decomposed by microorganisms in the soil. Is also rising.

The temperature when the leachate rises due to the heat generated in the process of time-dependent change of the waste containing the organic matter that is piled up and stored on the water-blocking sheet leaks from the damaged portion of the water-blocking sheet is disposed of as waste. The temperature is measured by a temperature measuring device using an optical fiber as a sensor.

An optical fiber housed in a porous sheath tube is arranged on the composite layer, impermeable layer or impervious layer, and the permeated water from the waste leaks out of the waste disposal site to cover the porous sheath tube. Since a water barrier sheet is installed to prevent such damage, the elasticity of the water permeable mat and the undeveloped or dumped ground of the waste disposal site formed by excavating due to the cushioning effect,
Further, the projections contained in the waste to be piled up prevent further breakage of the water-impervious sheet, and the impermeable layer or the impervious layer ensures that the water is flowed down below these layers or is shielded from the groundwater existing below them. Therefore, the temperature of only the leaked leachate is detected by the temperature measuring device using the optical fiber as a sensor, so that the damaged portion of the water shield sheet can be detected more accurately.

Since the water-permeable mat facilitates the flow of groundwater, it prevents the groundwater from leaching into the waste disposal site and prevents the groundwater from coming into contact with the optical fibers arranged on the lower surface of the impermeable sheet. .

The optical fiber is used as a temperature sensor. That is, when a laser pulse is incident on the optical fiber, Raman scattered light is generated by the movement of the glass molecules that make up the optical fiber, and this Raman scattered light largely depends on the temperature. The temperature at the position where the scattered light is generated can be obtained by measuring the delay time of. And its measuring distance is possible over several kilometers.

The leachate leaked from the damaged portion of the water-permeable sheet flows down the gap between the impermeable layer or the impervious layer and the impermeable sheet, and enters the porous sheath tube laid on the impermeable layer or the impervious layer. The temperature of the leachate is measured by a temperature measuring device using the stored optical fiber as a sensor.

The base layer formed on the slope and bottom of the waste disposal site constructed by excavation prevents groundwater leached from the ground from penetrating into the permeable layer in which the optical fiber is arranged. It is possible to prevent the seepage sheet from being damaged due to some reason and infiltrating water leaking from the damaged portion from entering the natural ground 1.

The base layer allows the groundwater of the waste disposal site to flow down below the base layer, and shields the optical fiber arranged in the permeable layer above the base layer from the groundwater. In addition, since the base layer is also provided in the step portion where the ground water of the waste disposal site flows down, the ground water flows down below this base layer, and the optical fiber of the permeable layer is cut off from the ground water.

When the impermeable sheet is damaged, it is possible to prevent the leachate that has infiltrated the permeable layer from leaking to the ground due to the base layer, and the organic sludge, incineration ash, and other wastes containing organic substances change over time. The leachate whose temperature is higher than the rock temperature around the waste disposal site due to the heat generated in the process of being decomposed by microorganisms in the soil
The water-permeable sheet flows down from the damaged part of the water-permeable sheet, contacts the optical fiber arranged in the water-permeable layer, and the temperature is detected by the temperature measuring device that uses the optical fiber as a sensor. To be done.

Groundwater is led to the lower drainage pipe through a water-permeable mat that is easily penetrated.

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of an invention of a method for detecting a damaged portion of a water blocking sheet in a waste disposal site according to the present invention will be described based on an embodiment with reference to the drawings. FIG. 1 is a cross-sectional view showing a main part of the waste disposal site, FIG. 2 is a plan view of the waste disposal site showing the laying condition of the optical fiber cables arranged in the waste disposal site, and FIG. 3 is a waste product. It is sectional drawing which expands and shows a part of 1st Example of a disposal site, FIG. 4 is a sectional view which expands and shows a part of 2nd Example of a waste disposal site, and FIG. It is sectional drawing which expands and shows a part of 3rd Example of a waste disposal site, and FIG. 6 is a waste disposal which shows the condition of the broken part of a water-blocking sheet, and the optical fiber which detects the leaking part of leachate. It is sectional drawing which expands and shows a part of field, and FIG.
Is an enlarged sectional view showing a part of the fourth example of the waste disposal site, and FIG. 8 is an enlarged sectional view showing a part of the fifth example of the waste disposal site; FIG. 9 is an enlarged sectional view showing a part of the sixth embodiment of the waste disposal site, and FIG.
FIG. 11 is a cross-sectional view showing an enlarged part of the seventh embodiment of the waste disposal site, and FIG. 11 is a broken part of the water-blocking sheet and a leakage part of leachate in the fifth embodiment of the waste disposal site. FIG. 12 is an enlarged cross-sectional view showing a part of the waste disposal site showing the relationship between the optical fiber for detecting the temperature and the relationship between the base layer and the groundwater, and FIG. 12 is a graph showing the relationship between the detected temperature of the optical fiber and the measured distance. It is a figure.

As shown in FIG. 1, a water-permeable mat 8 is provided on the bottom surface 16, the peripheral inclined surface 17 and the stepped portion 18 of the waste disposal site 2 formed by excavating in accordance with the topography of the natural ground 1. A composite layer 15 including an impermeable layer or a water impermeable layer 9 provided on the upper surface or the lower surface of the water permeable mat 8 is provided. Then, on the composite layer 15, an optical fiber 6 is housed in a porous sheath tube 7 made of a perforated stainless steel tube or the like, and an optical fiber cable 12 connecting these is arranged.

The temperature measuring device 14 shown in FIG. 2 transmits a laser pulse to the optical fiber 6, the optical fiber 6 acts as a temperature sensor, and receives the generated Raman scattered light. The optical fiber cable 12 includes a bottom surface 16 of the waste disposal site 2, an inclined surface 17 around the waste disposal area 18, and an inclined surface 17 on the step portion 18.
Are arranged in a loop shape along the contour line and on the bottom surface 16 and the stepped portion 18 at substantially equal predetermined intervals.

The optical fiber 6 is used as a temperature sensor, as described in the above-mentioned known documents. When a laser pulse is incident on the optical fiber 6, Raman scattered light is generated by the movement of the glass molecules forming the optical fiber 6, and the Raman scattered light largely depends on the temperature. The temperature at the position where the scattered light is generated is obtained by the temperature measuring device 14 by measuring the delay time of. And the measuring distance is possible over several kilometers.

The water-blocking sheet 4 is for preventing the leachate from the waste 3 from being discharged out of the waste disposal site 2 together with the groundwater, covers the optical fiber cable 12, and then the water-blocking sheet. The upper end of the ground material 1 of 4 is bent and fixed to the ground material 1 by bending so that rainwater or the like does not flow down under the water blocking sheet 4. Then, the waste 3 is dumped and piled up on the laid water-blocking sheet 4. On the waste material 3, several layers 21 of earth and sand are covered. In addition, in FIG. 1, A is a damaged portion of the water-impervious sheet 4, and an arrow indicates a situation where the leachate 13 is flowing down. Further, FIG. 1 shows a state in which the waste 3 is in the process of being piled up, and a plurality of layers of earth and sand 21 which are covering soils are usually formed, but in FIG. 1, one layer is shown. There is.

The bottom surface 16 of the waste disposal site 2 is gently inclined so that the water collected there is collected.
A drainage drainage groove 20 is provided at the lowest portion of 6, and a drainage drainage pipe 10 made of a perforated pipe or the like is buried via a water permeable material 11 such as sand.

The plane shape is circular according to the topography of the natural ground 1,
It is formed by excavating in an oval shape or a polygonal shape, and the water-blocking sheet 4 is the inclined surface 17 formed by excavation in the waste disposal site 2 and the stepped portion 1.
8 and the bottom surface 16 are laid. Impermeable sheet 4
Is laid in a watertight manner so that rainwater flowing down inside the raised waste 3 does not infiltrate into the underground of the waste disposal site 2 or becomes surface water and does not flow down.

In the first embodiment of the waste disposal site 2 shown in FIG. 3, the water permeable mat 8 is laid on the slope 17, the step portion (not shown) and the bottom surface 16 of the waste disposal site 2, A porous sheath tube 7 accommodating the optical fiber 6 is disposed on the water permeable mat 8, and the waste 3 is covered so as to cover the porous sheath tube 7.
A water-blocking sheet 4 that prevents leakage of leachate from the plant to the outside of the waste disposal site is laid, and the waste 3 is piled up on the water-blocking sheet 4. The water-blocking sheet 4 is laid so as to keep water-tightness so that rainwater flowing down inside the raised waste 3 does not permeate into the underground of the waste disposal site 2 or becomes surface water and flows down. The water blocking sheet 4 is for preventing the leachate from the waste 3 from being discharged out of the waste disposal site 2 together with the groundwater. Water-permeable mat 8
Is a water-permeable non-woven mat, drain mat, or the like. Further, the impermeable layer or the impermeable layer 9
Is a water-impermeable sheet, a spray layer of mortar or rubber asphalt, or a mat impregnated with bentonite.

In the second embodiment of the waste disposal site 2 shown in FIG. 4, the impermeable layer or the impermeable layer 9 is formed on the slope 17, step (not shown) and bottom surface 16 of the waste disposal site 2. The water-permeable mat 8 is laid on the water-impermeable layer or the water-impermeable layer 9, and the water-permeable mat 8 and the water-impermeable layer or the water-impermeable layer 9 that are laid below the water-permeable mat 8 are laminated. Thus, the composite layer 15 is formed. Then, the porous sheath tube 7 accommodating the optical fiber 6 is arranged on the water permeable mat 8, and the leachate from the waste 3 leaks out of the waste disposal site so as to cover the porous sheath tube 7. A water blocking sheet 4 is laid to prevent it. The impermeable layer or the impervious layer 9 is provided on the inclined surface 17 and the bottom portion 16 where the groundwater 19 of the waste disposal site 2 flows down, and the underground water 19 is caused to flow down under the impermeable layer or the impervious layer 9 to form the composite layer 15 The optical fiber 6 housed in the porous sheath tube 7 is arranged on the
It is cut off from 9. In addition, groundwater 1 of waste disposal site 2
In the step portion 18 (not shown in FIG. 4) through which 9 flows down, the impermeable layer or the impermeable layer 9 is provided, and the groundwater 19 is made to flow under the impermeable layer or the impermeable layer 9, The optical fiber 6 is cut off from the groundwater 19. The waste 3 is piled up on the water blocking sheet 4.

In the third embodiment of the waste disposal site 2 shown in FIG. 5, the water permeable mat 8 is laid on the slope 17, the step (not shown) and the bottom surface 16 of the waste disposal site 2, A water impermeable layer or a water impermeable layer 9 is laid thereon, and a porous sheath tube 7 accommodating an optical fiber 6 is disposed on the water impermeable layer or the water impervious layer 9, and the porous sheath tube 7 is attached to the porous sheath tube 7. A water-blocking sheet 4 is laid so as to cover the water leaking from the waste 3 to the outside of the waste disposal site so that the waste 3 is heaped up on the water-blocking sheet 4. Water-permeable mat 8
The composite layer 15 is formed by the impermeable layer or the impervious layer 9 that is laid on top of that and the impermeable layer or the impermeable layer 9.

As shown in FIG. 6, when the impermeable sheet 4 is damaged by the undeveloped or dumped ground in the waste disposal site 2 or the protrusions contained in the waste 3 that is piled up, organic sludge,
As the waste 3 containing organic matter such as incinerated ash changes over time, the temperature of the waste 3 is raised by the heat generated in the process of being decomposed by microorganisms in the soil,
The temperature is higher than the temperature, and the leachate 13 indicated by the arrow is from the damaged portion A of the water blocking sheet 4 to the water blocking sheet 4 and the composite layer 15.
Temperature measuring device 14 which is made to flow down between the impermeable layer or the impermeable layer 9 and uses the optical fiber 6 in the porous sheath tube 7 as a sensor.
The temperature is detected by the A
Is accurately detected.

The optical fiber 6 housed in the porous sheath tube 7 is disposed on the composite layer 15, the impermeable layer or the impervious layer 9 to cover the porous sheath tube 7 and to leach water 1 from the waste 3.
Since the water-impervious sheet 4 that prevents the leakage of the water 3 outside the waste disposal site 2 is laid, the ground of the waste disposal site 2 formed by excavating due to the elasticity and cushioning action of the water-permeable mat 8. The water-impermeable sheet 4 is less likely to be damaged due to improper maintenance, dumping, or protrusions contained in the waste 3 that is piled up. In addition, since the impermeable layer or the hardly permeable layer 9 flows down below the layers 9 or blocks the groundwater 19 existing thereunder reliably, the temperature of only the leaked leachate 13 is reduced. Is detected by the temperature measuring device 14 using the optical fiber 6 as a sensor, and more accurately the water blocking sheet 4
The damaged part A can be detected.

In the fourth embodiment of the waste disposal site 2 shown in FIG. 7, the sloped surface 1 formed by excavation of the waste disposal site 2 is formed.
7. A water-permeable mat 8 is laid on the stepped portion (not shown) and the bottom surface 16, and an optical fiber 6 is arranged on the water-permeable mat 8. The leachate from the waste 3 covers the optical fiber 6. A water blocking sheet 4 is laid to prevent the water from leaking out of the waste disposal site. Then, the waste 3 is piled up on the water blocking sheet 4. The water-blocking sheet 4 is laid so as to keep water-tightness so that rainwater flowing down inside the raised waste 3 does not permeate into the underground of the waste disposal site 2 or becomes surface water and flows down. The waterproof sheet 4 is
Leachate from waste 3 along with groundwater at waste disposal site 2
The optical fiber 6 is disposed in the water-permeable mat 8 as it is, without being housed in the porous sheath tube.

In the fifth embodiment of the waste disposal site 2 shown in FIG. 8, the waste disposal site 2 excavated and constructed has an inclined surface 17, a step (not shown) and a bottom surface 16. Base layer 2
2 is formed. The base layer 22 prevents groundwater 19 leached from the natural ground 1 from permeating into the water permeable layer 8 in which the optical fiber 6 is arranged, and the impermeable sheet 4 is damaged for some reason, and the leached water 13 leaked from the damaged part is Natural ground 1
It is to prevent the invasion of.

In the fifth embodiment, the base layer 22 is constructed by laying a water-blocking sheet material 23 made of synthetic resin or synthetic rubber material or bentonite-impregnated mat.

The base layer 22 is the groundwater 19 of the waste disposal site 2.
Is flowed under the base layer 22, and the optical fiber 6 arranged on the base layer 22 is shielded from the groundwater 19. It should be noted that the ground step 19 of the waste disposal site 2 where the groundwater 19 flows down
Also in (not shown in FIG. 4), the base layer 22
Is provided to allow the groundwater 19 to flow under the base layer 22 to shut off the optical fiber 6 from the groundwater 19.

In the sixth embodiment of the waste disposal site 2 shown in FIG. 9, the sloped surface 1 formed by excavation of the waste disposal site 2 is formed.
7. A base layer 22 made of a water-blocking sheet material 23 is provided on the step portion (not shown) and the bottom surface 16. The optical fiber 6 is arranged on the water-permeable mat 8 on the water-blocking sheet material 23, and the water-blocking sheet for preventing the leachate from the waste 3 from leaking out of the waste disposal site so as to cover the optical fiber 6. 4 and the foamed polyethylene sheet 24 are laid on top of each other. The waste 3 is piled up on the water blocking sheet 4. The optical fiber 6 is provided on the water-permeable mat 8 as it is without being housed in the porous sheath tube.

And again, the waste disposal site 2 shown in FIG.
In the seventh embodiment, the slope 1 on which the groundwater 19 of the waste disposal site 2 flows down on the natural ground 1 of the waste disposal site 2.
7. A base layer 22 composed of a spray layer 25 of mortar or rubber asphalt is formed on the step portion 18 (not shown) and the bottom portion 16. The groundwater 19 flows down below the base layer 22 composed of the spray layer 25 of mortar or rubber asphalt, and the optical fiber 6 disposed in the water permeable layer 8 on the base layer 22.
Is cut off from groundwater 19. Since the foamed polyethylene sheet 24 is laid so as to overlap the water-permeable sheet 4 between the water-permeable sheet 4 and the water-permeable layer 8 in which the optical fiber 6 is arranged, the elasticity of the sheet 24
Waste 3 formed by excavating due to cushioning
The water-impervious sheet 4 is less likely to be damaged by the protrusions included in
Since the foamed polyethylene sheet 24 itself is a material having poor water permeability, the water blocking property of the water blocking sheet 4 is improved and the heat insulating property of the water blocking layer is improved.

As shown in FIG. 11, when the water-blocking sheet 4 is damaged, the leachate 13 that has infiltrated the water-permeable layer 8 becomes the base layer 2.
2 can prevent leakage to the natural ground 1,
While the waste 3 containing organic matter such as organic sludge and incineration ash changes with time, the temperature of the waste 3 is raised by the heat generated in the process of being decomposed by the microorganisms in the soil, and the temperature of the ground 1 around the waste disposal site 2 Leachate 1 indicated by the arrow that is higher than the temperature
3 flows down the water-permeable layer 8 from the damaged portion A of the water-permeable sheet 4, contacts the optical fiber 6 arranged in the water-permeable layer 8, and the temperature is detected by the temperature measuring device 14 using the optical fiber 6 as a sensor, The damaged portion A of the water shield sheet 4 is accurately detected.

The groundwater 13 is guided to the collecting and draining pipe 10 below the bottom surface 16 through the easily permeable mat 8 and the leachate 13 in the waste disposal site 2 is a leachate drainage pipe (not shown).
After that, the water is treated and discharged to the outside of the waste treatment plant 2.

From the temperature detected by the temperature measuring device 14 using the optical fiber 6 as a sensor and the distance from the temperature measuring device 14, the damaged portion A of the impermeable sheet 4 which is the leak position of the leachate 13 can be detected.

Therefore, as shown in FIG. 2, the leachate 13 from the damaged portion A of the water shield sheet 4 is detected at the flowing-down portion B as indicated by the arrow.

[0053]

EFFECTS OF THE INVENTION The method of detecting water leakage at a waste disposal site according to the present invention is used to analyze a damaged portion of a water-blocking sheet laid to block ground and waste, which was previously impossible. There is an effect that it is possible to detect reliably without requiring specialized knowledge, without being influenced by disturbance factors such as underground current and earth leakage, and with simple equipment at low cost.

The method for detecting water leakage at a waste disposal site according to the present invention is based on the elasticity of the water permeable mat and the undeveloped or dumped ground of the waste disposal site formed by excavating due to the cushioning action,
The protrusions contained in the waste to be piled up prevent further damage to the water-blocking sheet, and the water-permeable mat facilitates the flow of groundwater, while the impermeable layer or the impervious layer flows down those layers or The groundwater existing under the water is surely shut off, and therefore, the temperature of only the leaked leachate is measured by the optical fiber, so that the damaged portion of the water-blocking sheet can be accurately detected.

In the method of detecting water leakage at the waste disposal site according to the present invention, the impermeable layer or the impermeable layer reliably flows down below these layers or blocks the groundwater existing below them. In addition, the temperature of only the leaked leachate can be accurately detected by the optical fiber, and the damaged portion of the waterproof sheet can be detected.

In the method for detecting water leakage at a waste disposal site according to the present invention, a water permeable layer is formed on a base layer provided on the slope and bottom of the excavated ground, and an optical fiber is arranged on the water permeable layer.
Since the water blocking layer made of the water blocking sheet and the foamed polyethylene sheet is formed so as to cover the water permeable layer, the water blocking of the water blocking layer and the water blocking property are improved, and the heat insulating property is improved.
The effect of being able to improve the detection performance of the leachate from the damaged portion of the water-proof sheet of the optical fiber is exerted.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a main part of a waste disposal site.

FIG. 2 is a plan view of a waste disposal site showing a laying condition of optical fiber cables arranged in the waste disposal site.

FIG. 3 is an enlarged sectional view showing a part of the first embodiment of the waste disposal site.

FIG. 4 is an enlarged sectional view showing a part of a second embodiment of the waste disposal site.

FIG. 5 is an enlarged sectional view showing an enlarged part of the third embodiment of the waste disposal site.

FIG. 6 is a cross-sectional view showing an enlarged part of the waste disposal site showing the situation of the damaged part of the water blocking sheet and the optical fiber for detecting the leakage part of the leachate in the first example of the waste disposal site. Is.

FIG. 7 is an enlarged sectional view showing a part of the fourth embodiment of the waste disposal site.

FIG. 8 is an enlarged sectional view showing a part of a fifth embodiment of the waste disposal site.

FIG. 9 is an enlarged sectional view showing a part of a sixth embodiment of the waste disposal site.

FIG. 10 is an enlarged sectional view showing a part of a seventh embodiment of the waste disposal site.

[Fig. 11] Part of the waste disposal site showing the condition of the optical fiber for detecting the damaged part of the impermeable sheet and the leakage site of the leachate in the fourth example of the waste disposal site and the relationship between the base layer and groundwater It is sectional drawing which expands and shows.

FIG. 12 is a graph showing the relationship between the detection temperature of the optical fiber and the measurement distance.

[Explanation of symbols]

1 Ground 2 Waste landfill 3 Waste 4 Impermeable sheet 6 Optical fiber 7 Perforated sheath tube 8 Water permeable mat 9 Impervious or poorly permeable layer 12 Optical fiber cable 13 Leachate 14 Temperature measuring instrument 15 Composite layer 16 Bottom 17 Slope 18 Small steps 19 Groundwater 22 Base layer 23 Synthetic resin-based or synthetic rubber-based material or waterproof sheet material made of bentonite impregnated mat 24 Foamed polyethylene sheet 25 Mortar or rubber asphalt spray layer

Claims (9)

[Claims] 1. An optical fiber is installed at a waste disposal site,
A water-blocking sheet is laid so as to cover the optical fiber, the waste is piled up on the water-blocking sheet, and the temperature at which the leachate rises due to the heat generated during the time course of the waste containing organic substances leaks A method for detecting the location of damage to the impermeable sheet at a waste disposal site, which is characterized by detecting the location of damage to the impermeable sheet by using a temperature measuring device as a sensor. 2. A permeable layer is formed on a slope and a bottom surface of the waste disposal site where groundwater flows down, and an optical fiber is arranged in the layer so that leachate from the waste is leaked out of the waste disposal site. A water-blocking sheet to prevent the above-mentioned optical fiber from being laid, and waste is piled up on the water-blocking sheet, and when the leachate rises due to heat generated in the process of time-varying waste containing organic matter, A method for detecting the location of damage to the impermeable sheet at a waste disposal site, which detects the location of damage to the impermeable sheet by detecting the temperature with a temperature measuring device that uses an optical fiber sensor. 3. A composite layer comprising a water-permeable layer and an impermeable layer or a water-impermeable layer is provided on the slope and the bottom surface where the groundwater of the waste disposal site flows down, and the optical fiber housed in the porous sheath tube is provided on the composite layer. Laying a water-blocking sheet that covers the porous sheath tube and prevents the leachate from the waste from leaking out of the waste disposal site, raises the waste on the water-blocking sheet, and discards containing organic matter. Disposal characterized by detecting the temperature at the time when the leachate rises due to the heat generated in the process of aging the substance leaking out is detected by a temperature measuring device using an optical fiber sensor to detect the damaged part of the impermeable sheet A method for detecting the location of damage to the impermeable sheet at the landfill site. 4. A water-permeable layer is formed on a base layer provided on the slope and bottom surface of the excavated ground, an optical fiber is arranged on the water-permeable layer, and a water-impervious layer is formed so as to cover the water-permeable layer. , Disposal of wastes characterized in that the temperature when the leachate leaked from the impermeable layer passes through the impermeable layer is detected by the temperature measuring device using the optical fiber sensor to detect the damaged part of the impermeable sheet. Method for detecting the location of damage to the impermeable sheet at the site. 5. The base layer prevents groundwater leached from the ground mass from infiltrating into the permeable layer, and prevents leachate water leaked from the impermeable layer from entering the ground mass. Item 4. A method for detecting a damaged portion of the water-blocking sheet according to Item 4. 6. The water shield according to claim 4 or 5, wherein the base layer is laid with a water shield sheet material made of a synthetic resin or synthetic rubber material or a bentonite-impregnated mat. Sheet damage detection method. 7. The base layer is a spray layer of mortar or rubber asphalt, wherein the base layer is a spray layer of mortar or rubber asphalt.
The method for detecting the location of damage to the waterproof sheet described in. 8. The water-impervious sheet is a single water-impermeable sheet, or a water-impermeable sheet and a foamed polyethylene sheet are superposed on each other, and the damaged portion of the water-impermeable sheet according to claim 4 or claim 5. Detection method. 9. The water permeable layer is a non-woven mat, a mat for drain, or a combination of these mats, and the water permeable layer according to claim 2, claim 3, claim 4, or claim 5. Method for detecting damaged parts of water-blocking sheet.