JP2021018166A - Spark inspection device - Google Patents

Abstract

To provide a spark inspection device for a water-shielding sheet put on a face of a slope.SOLUTION: The spark inspection device is for inspecting a water-shielding sheet put on a face of a slope for a spark, and includes: a wire supporting body having a metal wire extending in a lengthwise direction of the face of the slope to be in contact with the water-shielding sheet, the wire supporting body supporting the metal wire so that the metal wire can move in the lateral direction of the face of the slope; an inspection machine electrically connected to the metal wire, the inspection machine applying a voltage to the metal wire; and a carrying car arranged in an upper flat surface above the face of the slope, the carrying car moving the wire supporting body to the lateral direction of the face of the slope by moving in the flat surface in the upper lateral direction and connecting to the wire supporting body in the face of the slope.SELECTED DRAWING: Figure 1

Description

The present invention relates to a spark inspection device for detecting pinholes in an impermeable sheet laid at a disposal site such as a waste disposal site.

Impermeable sheets are laid at disposal sites such as waste disposal sites to install an artificial impermeable layer. Since the water-impervious sheet may have holes due to damage caused by the laying work or poor bonding between the water-impervious sheets, it is necessary to carry out an inspection to confirm the water-impervious performance at the time of construction. In particular, in order to confirm the presence or absence of damage that is difficult to see, such as a small hole (pinhole) in the impermeable sheet, a spark inspection for electrically detecting the pinhole is performed (Patent Documents 1 and 2). ).

In the spark inspection, a conductive layer is provided on the lower surface side of the impermeable sheet, and scanning is performed while pressing the electrode brush from above the impermeable sheet. When pinholes are present, sparks are generated by energizing between the electrode brush and the conductive layer, and the presence or absence of pinholes in the impermeable sheet is confirmed by electrically detecting the occurrence of these sparks. The conductive layer provided on the lower surface side of the water-impervious sheet is, when a water-impervious sheet having an insulating layer on the front surface and a conductive layer on the back surface is used, a conductive layer forming the back surface of the water-impervious sheet, or a front surface. When a combination of a water-impervious sheet that forms an insulating layer on both the back surface and a mat (conductive mat) that has a conductive function and is laid under it is adopted, the conductivity that is laid under the water-impervious sheet. It is a conductive layer of the mat.

Japanese Unexamined Patent Publication No. 10-288563 Japanese Unexamined Patent Publication No. 2014-158990

In the spark inspection, it is necessary for the worker to scan the entire surface of the laid impermeable sheet without omission while walking on the impermeable sheet with the electrode brush, which puts a heavy load on the worker and requires a long inspection time. In particular, the disposal site formed by excavation is surrounded by a slope, and since a water-impervious sheet is laid on this slope as well, workers can move up and down even on a slope. However, it is necessary to carry out a spark inspection, which requires a great deal of labor by workers, and there is a problem that the work is not performed efficiently.

Therefore, the present invention has been made focusing on such a problem, and an object of the present invention is to provide a novel spark inspection apparatus for efficiently performing a spark inspection of an impermeable sheet laid on a slope. ..

The spark inspection device of the present invention for achieving the above object is a spark inspection device for spark inspection of a water-impervious sheet laid on a slope, and extends along the vertical direction of the slope. A wire support having a metal wire arranged in contact with the metal wire and supporting the metal wire so as to be movable in the lateral direction of the slope, and electrically connecting the metal wire to apply a voltage to the metal wire. The wire support is subjected to the method by arranging the inspection machine to be applied and the upper flat surface on the upper side of the slope, moving the upper flat surface in the lateral direction, and connecting with the wire support arranged on the slope. It is characterized by being provided with a carrier that moves the surface in the lateral direction.

In the above configuration, preferably, the wire support has a main body frame and a plurality of spring bodies attached to the main body frame, and the metal wire is attached to the main body frame via the spring body to shield the metal wire. Arranged to urge and contact the water sheet. Further, the spring body is a pull spring. Further, the wire support has a rotating body that is movable in the lateral direction of the slope, and preferably the rotating body is an omni wheel. The inspection machine is mounted on the carrier.

In the above configuration, the spark inspection apparatus of the present invention further has another metal wire extending along the longitudinal direction of the slope and arranged so as to come into contact with the impermeable sheet, and the other metal wire. The other wire support is provided with another wire support that movably supports the surface of the slope, and the other wire support is connected in series with the wire support along the vertical direction of the slope. It is characterized in that it moves laterally along the slope together with the wire support.

The other wire support has another body frame and a plurality of other spring bodies attached to the other body frame, and the other metal wire has the other body frame via the other spring body. It is attached to the main body frame, urged by the impermeable sheet and arranged so as to come into contact with the metal wire of the wire support.

According to the spark inspection device of the present invention, the spark inspection of the impermeable sheet laid on the slope of the disposal site can be performed with high accuracy and efficiency.

It is a figure which shows the schematic structure example of the spark inspection apparatus in embodiment of this invention. It is a figure which shows the structure of the wire support 10. It is a figure which shows the inspection method by the spark inspection apparatus in embodiment of this invention. It is a figure which shows another structural example of the spark inspection apparatus in embodiment of this invention. It is a figure which shows still another structural example of the spark inspection apparatus in embodiment of this invention. It is a figure which shows still another structural example of the spark inspection apparatus in embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, such embodiments do not limit the technical scope of the invention.

FIG. 1 is a diagram showing a schematic configuration example of a spark inspection device according to an embodiment of the present invention, FIG. 1 is a front view, and FIG. 1 (b) is a side view. The spark inspection device includes a wire support 10, an inspection machine 20, and a carrier 30.

2A and 2B are views showing the configuration of the wire support 10, FIG. 2A is a perspective view, and FIG. 2B is a side view. Note that FIG. 2A shows a state in which the two wire supports 10 are connected. In FIGS. 1 and 2, the wire support 10 is for attaching the metal wire 12 extending along the vertical direction of the slope 3, the main body frame 14 for supporting the metal wire 12, and the metal wire 12 to the main body frame 14. It is configured to have a spring body 16 and a rotating body 18 for moving the main body frame 14 in the lateral direction of the slope 3 (the direction of the arrow in FIG. 1A).

The metal wire 12 is, for example, a thin brass wire having a diameter of about 5 mm. The main body frame 14 is a frame body assembled by a pipe made of a synthetic resin such as vinyl chloride resin. Further, the structure may be composed of plate (plate-shaped) members. The main body frame 14 is provided with an edge portion 14a along the vertical direction of the slope 3. The metal wire 12 is attached to the edge portion 14a via a plurality of spring bodies 16 along the longitudinal direction thereof.

The plurality of spring bodies 16 are, for example, pull springs, which are attached to the edge portions 14a of the main body frame 14 at equal intervals, and the metal wires 12 are attached so as to be spread over the tips of the spring bodies 16 and springs are attached to the main body frame 14. It is supported via the body 16. By the spring body 16, the metal wire 12 is arranged so as to be pressed (urged) into contact with the impermeable sheet 5 covering the slope 3, as shown in FIG. The spring body 16 can press the metal wire 12 against the impermeable sheet 5 so as to urge the metal wire 12, and the metal wire 12 can follow the unevenness of the impermeable sheet 5 and press against the impermeable sheet 5. It is possible to scan in a state of constant contact.

Since the impermeable sheet 5 is usually laid on the slope 3 so as to have some slack, it is laid in a state where irregularities and wrinkles are formed. In the spark inspection device of the present invention, the metal wire 12 is scanned in a state of being pressed (urged) against the impermeable sheet 5 by the spring body 16, so that the metal wire 3 is uneven on the impermeable sheet. It moves following the wrinkles and can always be scanned in close proximity to the impermeable sheet, so that spark inspection can be performed with high accuracy.

Further, the wire support 10 has a rotating body 18 attached to the main body frame 14. The rotating body 18 is a wheel, preferably an omni wheel, capable of moving the wire support 10 laterally to the slope 3, and the wire support 10 capable of moving the metal wire 12 laterally to the slope. It becomes a structure that supports the wheel.

The inspection machine 20 is a device that generates a high voltage, and is electrically connected to a metal wire 12 attached to a wire support 10 by an electric cord (not shown) to apply a voltage to the metal wire 12. A conductive layer (not shown) is provided on the lower surface (back surface) of the impermeable sheet 5 laid on the slope 3, and one electrode of the inspection machine is connected to this conductive layer, and the inspection machine 20 , The generation of spark (discharge) generated in the vicinity of the metal wire 12 that is pressed against and contacts the upper surface of the impermeable sheet 5 is detected. When a spark is detected, it also has a notification function to notify by sound (buzzer sound) or light (lamp). When the water-impervious sheet 5 has no pinholes, the conductive layer provided on the lower surface side of the water-impervious sheet 5 and the metal wire 12 pressed against the upper surface of the water-impervious sheet 5 are insulated by the water-impervious sheet 5. Therefore, no spark occurs. When the water-impervious sheet 5 has a pinhole, the metal wire 12 and the conductive layer of the water-impervious sheet 5 conduct with each other through the pinhole, and sparks occur. By detecting this spark, the presence or absence of a pinhole can be detected.

The conductive layer provided on the lower surface side of the water-impervious sheet 5 is a conductive layer forming the back surface of the water-impervious sheet when a water-impervious sheet having an insulating layer on the front surface and a conductive layer on the back surface is used. When a combination of a water-impervious sheet 5 that forms an insulating layer on both the front and back surfaces and a mat (conductive mat) that has a conductive function and is laid under the water-impervious sheet 5, is laid under the water-impervious sheet 5. It is a conductive layer of a conductive mat to be sewn.

The inspection machine 20 is mounted on the carrier 30 and moves together with the carrier 30 and the wire support 10 connected to the carrier 30. The inspection machine 20 may be in a form in which the inspection machine 20 is not mounted on the transport vehicle 30 and is placed at a predetermined position without moving.

The carrier 30 is a moving body that is arranged on the upper flat surface 4 on the upper side of the slope 3 and moves laterally on the upper flat surface 4, for example, a so-called crawler carrier, which is driven by an engine, a motor, or the like. It is a vehicle that can run on its own by driving means. The vehicle may be moved by human power without being provided with a driving means. The transport vehicle 30 has a loading platform, on which the inspection machine 20 is mounted, and various devices such as a generator are mounted as needed.

The carrier 30 is connected to the wire support 10 by a connecting means such as a rope 11, and as the carrier 30 moves laterally on the upper flat surface 4 of the slope 3, the wire support 10 also has a slope. Move 3 laterally.

FIG. 3 is a diagram showing an inspection method using a spark inspection device according to an embodiment of the present invention. As shown in FIG. 3A, first, the transport vehicle 30 is arranged at the start position of the upper flat portion 4 of the slope 3, and the wire support 10 connected to the transport vehicle 30 is arranged on the slope 3. The wire support 10 is arranged so that the carrier 30 and the slope 3 are aligned in the vertical direction, and the metal wire 12 of the wire support 10 is oriented in the direction along the vertical direction of the slope 3. Further, in the example shown in FIG. 5, the wire support 10 moves in the lateral direction (arrow direction) from, for example, the upper end portion of the slope 3 in order to scan the impermeable sheet 5 laid on the slope 3 without omission. To start. The starting position can be anywhere. The metal wires 12 are in contact with each other so as to be pressed against the impermeable sheet 5.

The inspection machine 20 mounted on the carrier 30 is electrically connected to the metal wire 12 of the wire support 10, the other electrode is connected to the conductive layer of the impermeable sheet 5, and a voltage is applied to the metal wire 12. To do.

As shown in FIG. 3B, the transport vehicle 30 is moved along the lateral direction of the upper flat portion 4 of the slope 3. As the carrier 30 moves, the wire support 10 also moves along the slope 30 in the lateral direction, and the metal wire 12 to which the voltage is applied scans while contacting the surface of the impermeable sheet 5. When the impermeable sheet 5 has pinholes, sparks occur when the metal wire 12 scans the pinholes.

As shown in FIG. 3C, the carrier 30 is further moved, and scanning by the metal wire 12 is performed to the folding position. Then, when the folded position is reached, as shown in FIG. 3D, the wire support 10 is shifted to a lower position, specifically, the rope 11 connecting the carrier 30 and the wire support 10. The length of the wire support 10 is extended by approximately the length in the vertical direction of the wire support 10, and the wire support 10 is arranged so as to be shifted downward by the length in the vertical direction. The length of the rope 11 can be adjusted by, for example, winding and unwinding with a reel, and the length can be appropriately adjusted by changing the knot position of the rope without using a reel.

Then, as shown in FIG. 3 (E), the carrier 30 is moved in the opposite direction to the conventional one, the wire support 10 is also moved in the opposite direction accordingly, and the metal wire 12 is within the scanning range so far. Scan adjacent areas. Further, as shown in FIG. 3 (F), the carrier 30 is further moved, scanning by the metal wire 12 is continued, and the vehicle returns to the start position in FIG. 3 (A).

The steps of FIGS. 3A to 3F are repeated until the lower end of the slope is reached, and the entire range of the slope 3 is scanned with the metal wire 12 to carry out a spark inspection. With the spark inspection device of the present invention, the spark inspection of the impermeable sheet laid on the slope of the disposal site can be efficiently performed in a short time and with high accuracy without the manual operation of a worker.

FIG. 4 is a diagram showing another configuration example of the spark inspection device according to the embodiment of the present invention. In another configuration example, the spark inspection device includes a plurality of wire supports 10, and the plurality of wire supports 10 are arranged in series along the vertical direction of the slope 3. The wire supports 10 may be connected to each other by any connecting means such as a rope. The configuration of each wire support 10 is the same. By connecting the plurality of wire supports 10, the scanning range in one-way movement is expanded in the spark inspection, and the entire range of the slope 3 can be scanned with a smaller number of turns. The inspection time can be shortened and the inspection work can be made more efficient. The metal wires 12 of the wire support 10 are overlapped with each other or connected to each other so that there is no gap in the scanning range. Further, the number of wire supports 10 to be connected is not limited to two, and three or more may be connected.

One wire support 10 having a length in which a plurality of wire supports 10 are connected may be configured, but if the wire support 10 is too long, a truck or the like may be used when transporting the wire support 10 to the disposal site. The length of the wire support 10 in the longitudinal direction is preferably about 2 m from the viewpoint of workability and transportability because the wire support 10 cannot be mounted on the vehicle.

5 and 6 are diagrams showing still another configuration example of the spark inspection device according to the embodiment of the present invention. In yet another configuration example, in the configuration of FIG. 4, the wire support 10 traveling on the impermeable sheet laid on the upper flat surface 4 of the slope 3 is connected to the carrier 30. Will be done. A spark inspection can be performed on the slope 3 and the upper flat surface 4 at the same time.

The present invention is not limited to the above-described embodiment, and there are design changes within a range that does not deviate from the gist including various modifications and modifications that can be conceived by a person having ordinary knowledge in the field of the present invention. Of course, it is also included in the present invention.

3: Slope, 4: Upper flat surface, 5 Impermeable sheet, 10: Wire support, 11: Rope, 12: Metal wire, 14: Body frame, 14a: Edge part, 16: Spring body (pull spring), 18: Rotating body (omni wheel) 20: Inspection machine, 30: Carrier

Claims (9)

In the spark inspection device for spark inspection of the impermeable sheet laid on the slope
A wire support having a metal wire extending along the longitudinal direction of the slope and arranged so as to contact the impermeable sheet, and supporting the metal wire so as to be movable in the lateral direction of the slope.
An inspection machine that electrically connects to the metal wire and applies a voltage to the metal wire.
The wire support is arranged on the upper flat surface on the upper side of the slope, moves laterally on the upper flat surface, and is connected to the wire support arranged on the slope to move the wire support laterally on the slope. A spark inspection device characterized by being provided with a carrier to be used. The wire support has a main body frame and a plurality of spring bodies attached to the main body frame.
The spark inspection device according to claim 1, wherein the metal wire is attached to the main body frame via the spring body and is arranged so as to be urged and contacted with the impermeable sheet. The spark inspection device according to claim 2, wherein the spring body is a pull spring. The spark inspection apparatus according to any one of claims 1-3, wherein the wire support has a rotating body that can move in the lateral direction of the slope. The spark inspection device according to claim 4, wherein the rotating body is an omni wheel. Another wire that has another metal wire that extends along the longitudinal direction of the slope and is arranged to contact the impermeable sheet, and that supports the other metal wire movably in the lateral direction of the slope. Equipped with a support
The other wire support is connected in series with the wire support along the vertical direction of the slope, and moves laterally along the slope together with the wire support as the carrier moves. The spark inspection apparatus according to any one of claims 1-5. The other wire support has another body frame and a plurality of other spring bodies attached to the other body frame.
The other metal wire is attached to the other main body frame via the other spring body, is arranged so as to be urged and contacted with the impermeable sheet, and is connected to the metal wire of the wire support. The spark inspection apparatus according to claim 6. A wire support for a spark inspection device that sparks an impermeable sheet laid on a slope.
A metal wire that extends along the longitudinal direction of the slope and is arranged so as to contact the impermeable sheet.
A body frame that supports the metal wire and
A spring body for attaching the metal wire to the main body frame is provided.
A wire support characterized in that the metal wire is attached to the main body frame via the spring body and is arranged so as to be urged and contacted with a water-impervious sheet. The wire support according to claim 8, further comprising a rotating body for moving the main body frame in the lateral direction of the slope.