KR102622455B1 - Cavity plug for underground cavity recovery and monitoring - Google Patents

Abstract

The present invention relates to a cavity plug inserted into a sinkhole exploration hole (H) formed for sinkhole exploration under a road to repair the sinkhole exploration hole.
The cavity plug for joint exploration work of the present invention includes a cylindrical lower elastic body 100 with a diameter corresponding to the sinkhole exploration hole (H), an upper elastic body 200 obliquely extending outward from the top of the lower elastic body, and It includes at least one split groove 300 that equally divides the upper elastic body based on the center of the lower elastic body and provides a gap between the divided upper elastic bodies 200a.

Description

Joint investigation recovery and monitoring cavity plug {CAVITY PLUG FOR UNDERGROUND CAVITY RECOVERY AND MONITORING}

The present invention relates to a cavity plug that can be inserted into an exploration hole that may occur when exploring a cavity or sinkhole existing under a road.

In general, a sinkhole is a cavitation phenomenon that occurs in an underground space, and is caused by various direct or indirect causes such as groundwater development, leakage improvement work in old water supply and sewerage systems, subway construction, and high-rise building construction, or natural causes such as earthquakes or floods.

When such a sinkhole occurs on a road, it not only causes traffic accidents and casualties, but also requires a lot of effort and cost for recovery. Therefore, there is an emerging need to ensure safety through regular inspections on roads with high traffic volume, and as part of this, The "Special Act on Underground Safety Management" is in effect, which requires the use of ground penetrating radar (GPR) for underground facilities and surrounding ground to determine whether or not joints are distributed under the road.

The GPR exploration device (Ground Penetrating Radar) uses a transmitting antenna to incident electromagnetic waves inward from the surface of the ground or structure, then receives the waves reflected from the medium boundary and returned through a receiving antenna, stores them, and goes through various signal processing processes. It is a device that determines information such as the medium, location, size, depth, etc. of the exploration target. If a suspicious area is found as a result of the exploration, an exploration hole is drilled into the road to confirm whether there is an actual sinkhole.

At this time, when a sinkhole is confirmed, the exploration hole is temporarily blocked with a cavity plug made of rubber to prevent water from flowing into the underground through the exploration hole until full-scale sinkhole removal work is carried out.

If it is confirmed that it is not a sinkhole, a cavity plug is inserted into the exploration hole formed in the road to tightly block the exploration hole, and then asphalt concrete is poured on top of the cavity plug to repair the road to its original state.

However, the conventional cavity plug has a problem in that it cannot precisely block exploration holes because it is difficult to form exploration holes with a constant diameter due to the nature of roads made of gravel and soil.

Therefore, in the field, a separate work is performed to correct the diameter by wrapping an insulating tape around the cavity plug according to the diameter of the exploration hole, which is very inconvenient. Nevertheless, it is necessary to ensure that the inner wall of the cavity plug and the exploration hole are closely adhered. Problems with underground water flowing into the exploration hole frequently occur due to work defects such as failure to fit or the cavity plug slipping and falling inside the exploration hole. Improvements to this are required.

Republic of Korea Patent Publication No. 1914494

The present invention was conceived to solve the above-mentioned problem, and its purpose is to provide a cavity plug for joint exploration work that is tightly fitted into an exploration hole formed for exploration of a sinkhole under a road.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

The cavity plug for joint exploration work of the present invention includes a cylindrical lower elastic body with a diameter corresponding to the sinkhole exploration hole, an upper elastic body obliquely extending outward from the top of the lower elastic body, and the center of the lower elastic body. It includes at least one dividing groove that equally divides the upper elastic body as a standard and provides a gap between the divided upper elastic bodies.

Additionally, the split groove may be formed in a “V” shape that becomes narrower downward.

In addition, a first anti-slip member may be formed on the outer peripheral surface of the lower elastic body and supported in close contact with the sinkhole exploration hole.

In addition, the present invention may further include a circular groove formed along the outer peripheral surface of the lower elastic body, and a first anti-slip member inserted into the circular groove and supported in close contact with the sinkhole exploration hole.

Meanwhile, it is preferable that a metal member is attached to the bottom of the lower elastic body so that the GPR exploration device can sense it.

In addition, a second anti-slip member may be further provided that protrudes to the outside of the lower elastic body and is closely supported by the sinkhole exploration hole.

In this case, the second anti-slip member includes a pinion gear installed at the inner center of the lower elastic body, a pinion gear rotation shaft installed vertically at the center of the lower elastic body, and a plurality of racks installed inside the lower elastic body to engage with the pinion gear. Additionally, a support piece may be provided that is attached to the end of each rack and extends from the lower elastic body while moving linearly along the rack.

In the cavity plug for joint exploration work of the present invention as described above, the upper elastic bodies are movably divided through the split groove and are formed to be inclined outward, so the divided upper elastic bodies are independent to the inside or outside depending on the condition of the inner wall of the exploration hole. Not only does it flow in close contact with the outer wall of the exploration hole and fit firmly without slipping, but it can also be used immediately without having to correct the diameter on site as in the past, making exploration hole repair work quick and easy. There is a possible effect.

In addition, in the present invention, when the first anti-slip member is provided on the outside of the lower elastic body, slippage occurring in the lower elastic body with a smaller diameter than the upper elastic body is prevented, and thus the effect of more secure and solid contact with the exploration hole can be expected. there is.

In addition, in the case where the present invention further includes a second anti-slip member that protrudes to the outside of the lower elastic body and is closely supported by the sinkhole exploration hole, a strong supporting force is exerted against the inner wall of the exploration hole, making the sinkhole exploration hole more secure and sturdy. The effect of close contact with the exploration hole can be expected.

The effects of the present invention are not limited to those mentioned above, and may be clearly understood by those skilled in the art from the description throughout the specification, but also include other effects that are not explicitly mentioned.

Figure 1 is a perspective view of a cavity plug for joint exploration work according to the present invention.
Figure 2 is a front view of Figure 1.
Figure 3 is a plan view of Figure 1.
Figure 4 is a longitudinal cross-sectional view of Figure 1.
Figure 5 is a cross-sectional view of Figure 1.
Figure 6 is a cross-sectional view sequentially showing the state of use of the cavity plug for joint exploration work according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, and the present embodiments are merely intended to ensure that the disclosure of the present invention is complete and to include common knowledge in the technical field to which the present invention pertains. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless clearly specifically defined. The terms used in this specification are for describing embodiments and are not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context.

As used in the specification, “comprises” and/or “comprising” refers to the presence of one or more other components, steps, operations and/or elements. or does not rule out addition.

FIG. 1 is a perspective view of a cavity plug for joint exploration work according to the present invention, FIG. 2 is a front view of FIG. 1, FIG. 3 is a plan view of FIG. 1, FIG. 4 is a longitudinal cross-sectional view of FIG. 1, and FIG. 5 is a cross-sectional view of FIG. 1. It is a cross-sectional view, and Figure 6 is a cross-sectional view sequentially showing the state of use of the cavity plug for joint exploration work according to the present invention. As shown, the cavity plug for joint exploration work according to the present invention includes a lower elastic body 100 and an upper elastic body 200. ) and a split groove 300.

The lower elastic body 100 is configured in the form of a cylinder with a diameter corresponding to the sinkhole exploration hole (H). The lower elastic body 100 is made of a material with its own elastic force, such as rubber, so that it can expand and contract on its own and fit smoothly even if the diameter of the sinkhole exploration hole (H) is not constant.

The upper elastic body 200 is a member integrally formed at the top of the lower elastic body 100 and is preferably made of the same material as the lower elastic body 100, and is formed to extend obliquely outward from the upper end of the lower elastic body 100.

Therefore, the cavity plug for joint exploration work of the present invention has a shape whose diameter gradually increases toward the top when viewed from the front due to the upper elastic body 200.

At least one dividing groove 300 is formed based on the center of the lower elastic body 100 to equally divide the upper elastic body 200.

In this embodiment, the split groove 300 is formed in a cross shape based on the center of the lower elastic body 100 to equally divide the upper elastic body 200 into four parts, but it is not limited thereto.

A gap corresponding to the split groove 300 is formed between the divided upper elastic bodies 200a due to the split groove 300, and due to the gap formed in this way, the divided upper elastic bodies 200a are divided into sinkhole exploration holes ( Depending on the change in diameter of H), it flows independently inward or outward and is naturally closely supported on the inner wall of the sinkhole exploration hole (H).

In this case, the split groove 300 is preferably formed in a “V” shape that narrows downward.

When the split groove 300 forms a “V” shape that narrows downward, the divided upper elastic bodies 200a flow outward or outward only based on the center of the lower elastic body 100, and this flow occurs. Since the direction is normal to the inner wall surface of the sinkhole exploration hole (H), it is possible to maximize the adhesion support for the sinkhole exploration hole (H).

Meanwhile, since the lower elastic body 100 has a smaller outer diameter than the upper elastic body 200, it has disadvantageous conditions for being in relatively close contact with the sinkhole exploration hole (H). In consideration of this point, it is preferable that a first anti-slip member 400 is formed on the outer peripheral surface of the lower elastic body 100 in close contact with the sinkhole exploration hole (H).

The first slip prevention member 400 protrudes from the outer peripheral surface of the lower elastic body 100 and is supported in close contact with the sinkhole exploration hole (H), thereby bringing the lower elastic body 100 into closer contact with the sinkhole exploration hole (H). give.

The first slip prevention member 400 may be integrally molded with the lower elastic body 100, or may be formed as a separate body.

In this case, a circular groove 110 is formed along the outer peripheral surface of the lower elastic body 100, and the circular groove 110 is provided with a ring-shaped first slip prevention member ( 400) are inserted and combined.

In this way, if the first anti-slip member 400 is composed of a separate body, it is possible to manufacture in advance the first anti-slip members 400 with various thicknesses, and at the site, the first anti-slip member 400 can be manufactured in advance, and the first anti-slip member 400 can be manufactured in advance at the site. 1By selecting and installing the slip prevention member 400, the lower elastic body 100 can be more tightly fitted into the sinkhole exploration hole (H).

Meanwhile, it is preferable that a metal member 500 is attached to the bottom of the lower elastic body 100 so that the GPR exploration device can sense it.

In this case, when re-checking the presence of a sinkhole using a GPR exploration device in the future, the GPR exploration device can easily identify the exploration area that is difficult to detect with the naked eye by sensing the metal member 500 on the ground, so the sinkhole can be detected. Inspection work can be performed efficiently. When using a GPR exploration device, the signal may be different when passing through a metallic structure and when passing through a non-metallic structure. By using this characteristic and providing the metal member 500, underground cavity exploration at the corresponding location has already been completed. You can find out later that you lost.

Meanwhile, a second anti-slip member 600 may be further provided that protrudes to the outside of the lower elastic body 100 and is actively supported in close contact with the sinkhole exploration hole (H).

In this case, the second anti-slip member 600 includes a pinion gear 610 installed in the inner center of the lower elastic body 100, a pinion gear rotation shaft 620 installed vertically in the center of the lower elastic body 100, and A plurality of racks 630 installed inside the lower elastic body 100 to engage with the pinion gear 610, and attached to the end of each rack 630 to move linearly along the rack 630, lower elastic body 100 It may be provided with a support piece 640 that protrudes from.

In addition, an avoidance groove 210 is formed in the vertical direction at the inner edge of the divided upper elastic body 200a so that the divided upper elastic body 200a does not interfere with the pinion gear rotation axis 620 when it flows inward.

When the support piece 640 protrudes from the lower elastic body 100, it is preferable to have a sharp end so that it can exert a strong support force while being embedded in the inner wall of the sinkhole exploration hole (H).

It is preferable that the top of the pinion gear rotation shaft 620 be provided with a head portion 621 or a hexagonal head portion formed with a straight groove or a cross groove so that the worker can easily and conveniently rotate it left and right using a rotary tool such as a driver. do.

A pair of the racks 630 are arranged side by side with the pinion gear 610 in between and are configured to simultaneously operate in opposite directions according to the rotation direction of the pinion gear 610.

Although not shown, the rack 630 may be arranged vertically. In this case, if the directions of the rack 630 placed at the top and the rack 630 placed at the bottom are different, the support piece 640 appears at various angles, so the lower elastic body 100 is connected to the sinkhole exploration hole (H). It is possible to adhere more tightly and stably.

Meanwhile, a space 101 in which the pinion gear 610 and the rack 630 are installed is formed inside the lower elastic body 100, and the pinion gear rotation axis 620 is located at the center of the lower elastic body 100. A vertical through hole 102 to be inserted is formed to communicate with the space 101. In addition, a groove 103 communicating with the space 101 is formed on the side of the lower elastic body 100 so that the support piece 640 appears.

The cavity plug for joint exploration work of the present invention configured as described above is manufactured to fit the diameter of the sinkhole exploration hole (H) using an elastic body, so it can be used immediately without having to correct the diameter in the field. This allows the sinkhole exploration hole to be used directly. Repair work can be performed quickly.

In addition, in the cavity plug for joint exploration work of the present invention, the upper elastic bodies 200a, which are movably divided through the split groove 300, are formed to be inclined outward, so that the cavity plug according to the condition of the inner wall of the sinkhole exploration hole (H) The divided upper elastic bodies (200a) flow independently inward or outward and are closely adhered to the outer wall surface of the sinkhole exploration hole (H) and are firmly fitted without slipping.

In addition, when the first slip prevention member 400 is provided on the outside of the lower elastic body 100, slipping occurring in the lower elastic body 100, which has a smaller diameter than the upper elastic body 200, is prevented, making it more secure and sturdy. It is inserted into the sinkhole exploration hole (H).

In addition, when the lower elastic body 100 is provided with the second anti-slip member 600, when the worker rotates the pinion gear rotation shaft 620 to one side on the ground, the pinion gear 610 rotates to one side and the rack 630 ) moves straight in both directions, and the support pieces 640 attached to both ends of the rack 630 are embedded in the inner wall of the sinkhole exploration hole (H), thereby exerting a strong support force.

Therefore, in order to restore the road to its original state, even if the asphalt concrete (A) is poured into the sinkhole exploration hole (H) after inserting the cavity plug for joint exploration work of the present invention into the sinkhole exploration hole (H), the asphalt concrete (A) The sinkhole exploration hole (H) processing work can be performed smoothly without sagging due to the weight.

In addition, the asphalt concrete (A) poured into the sinkhole exploration hole (H) flows into the split groove 300 and is strongly bound to the upper elastic body 200, and at the same time uniformly presses the divided upper elastic body 200a in the outward direction. This doubles the adhesion between the upper elastic body 200 and the sinkhole exploration hole (H).

Although embodiments of the present invention have been described above with reference to the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. You will be able to understand it. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

100; lower elastic body
110; circular groove
200; upper elastic body
200a; Split upper elastic body
300; Split groove
400; First slip prevention member
500; metal member
600; Second slip prevention member
610; pinion gear
620; pinion gear rotation shaft
630; rack
640; support piece
H; sinkhole explorer

Claims (5)

A cylindrical lower elastic body with a diameter corresponding to the sinkhole exploration hole;
an upper elastic body obliquely extending outward from the top of the lower elastic body;
At least one split groove equally dividing the upper elastic body based on the center of the lower elastic body and providing a gap between the divided upper elastic bodies;
A metal member attached to the bottom of the lower elastic body and sensed by a GPR exploration device;
A first anti-slip member formed on the outer peripheral surface of the lower elastic body and supported in close contact with the sinkhole exploration hole;
a second anti-slip member provided so that a support piece emerges from a groove formed on a side of the lower elastic body by rotation of a pinion gear rotation axis installed vertically in the center of the lower elastic body;
Including,
The split groove is formed in a "V" shape that narrows downward, and the diameter gradually increases toward the top due to the upper elastic body,
Cavity plug for joint exploration work. delete delete delete delete