KR100975388B1 - Separation prevention structure of water pipe with under the ground - Google Patents

Abstract

PURPOSE: A separation preventing structure of water supply pipes buried under the ground is provided to display a dangerous situation according to the tension change of a wire through a strain gage and a distinguishable indicator unit. CONSTITUTION: A separation preventing structure of water supply pipes buried under the ground comprises a pipe body(10), a joint ring(20), a wire(30), a strain gauge(40), a distinguishable indicator unit(50), and a hanger member(60). The wire is inserted in the pipe body and bound by the joint ring. The strain gauge outputs tension change of the wire to a controller. The distinguishable indicator unit includes an LED(Light Emitting Diode) and the controller. The LED emits the light through a light transmission unit to outside. The controller receives a tension sensing signal from the strain gauge and controls the LED. The hanger member is detachably installed in the pipe body to keep the pipe body from drooping.

Description

Separation Prevention Structure Of Water Pipe With Under The Ground}

The present invention, underground sewage pipes to prevent the sewage pipes buried in the ground segregation or fall due to ground sedimentation in advance, and to inform the facility manager before separation, the facility manager can quickly process It relates to a structure for preventing the separation of water and sewage pipes.

Generally, water pipes for supplying water to factories, houses, and various facilities, and sewage pipes for transporting used sewage water to remote sewage treatment facilities are buried underground to secure ground space and beautify living environment.

The embedding of the water and sewage pipe is usually cut in the ground with enough space so that the structure connecting the plurality of water pipes having a constant diameter and length in series can be seated, and the water and sewage pipe in the incision in the longitudinal direction sequentially This is done by burying in earth and sand after being seated.

Looking at the conventional method of embedding simply because digging the ground and then put the water and sewage pipes to cover the ground again, the construction is easy and widely used.

In particular, in urban areas, the soil is located at the periphery of the sewage pipes to increase the density of the soils, and concrete or asphalt is applied to the ground where the sewage pipes are buried. The risk of breakage can be minimized.

However, in places where there is frequent ground collapse and partial subsidence, such as river basins or mountainous areas with heavy rainfall, water and sewage pipes are long connected in one direction, so the bearing capacity for lateral pressure and longitudinal pressure is weak, and water and sewer pipes, especially soft ground Even with slight ground subsidence, the sewage pipe could not overcome the limitations, and the joints were easily separated, causing a leak.

In addition, when ground subsidence occurs, the joint part of the water pipe is separated and falls, but the water and sewer pipe is easily damaged by the impact at this time, and the cost of the installation is increased because the broken water pipe is not recycled. there was.

On the other hand, before the water and sewage pipes are separated, there is no means to inform the facility manager in advance so that research is being actively conducted to solve them.

The present invention has been made in order to solve the above problems, the sewage pipes buried in the ground to prevent the separation of the joints from each other due to the ground subsidence, and to prevent the damage caused by falling through the hanger member in advance The purpose of this is to provide facility managers with an opportunity to prevent the sewage pipes from being separated before they can be separated, so that the facility managers can take prompt action.

The present invention for achieving the above object,

A convex portion provided with a first settling groove at one end, a recessed portion provided with a second settling groove at the other end, a plurality of wire installation holes penetrating along the longitudinal direction and interconnecting the first settling groove and the second settling groove, A pipe main body having a groove formed therein and embedded in the ground;

A binding ring having a plurality of binding grooves opened outwardly and selectively coupled to the first settling groove or the second settling groove of the tube body;

A wire inserted into the wire installation hole of the pipe main body having a locking portion supported on the binding groove of the binding ring at both ends;

A strain gauge installed on the wire and configured to detect a tension of the wire and output a tension detection signal to the controller;

A protective case buried in the ground, installed inside the protective case so as to be movable, and having a main body which is elastically supported upward by a spring, a cover installed on the protective case so as to be exposed to the outside, and having a light transmitting part It is installed on the upper surface of the battery to supply power, is installed on the upper surface of the main body, the LED is turned on when the power is supplied to emit light to the outside through the light-transmitting part, and is installed on the upper surface of the main body to receive power from the battery An identification display unit configured to receive a tension sensing signal from a strain gauge and to control operation of the LED;

A pair of semicircular bands arranged opposite to each other and folded and deployed through a hinge, the fixing portion surrounding and fixing the groove portion of the tube body, a support plate disposed horizontally on the upper portion of the tube body, and embedded in the ground; It is installed vertically, one end is installed in the fixed portion, the other end is composed of a hanger member having a connection portion is installed on the support plate.

In the present invention having the above-described configuration, since a plurality of pipe bodies embedded in the ground are interconnected via wires, the connection parts of the pipe bodies are separated from each other by wires connecting the pipe bodies even when ground subsidence occurs. Can be suppressed as much as possible.

In addition, since the hanger member is provided on the tube body to hold the tube body, even if ground subsidence occurs, the tube body can be prevented from falling down and being damaged.

In addition, the strain gauge and the identification display part visually represent the danger situation due to the tension change of the wire, so that the facility manager can intuitively recognize the current state on the pipe main body embedded in the soft ground and respond quickly. can do.

In addition, since the main body and the cover are installed inside the protective case and are elastically supported by a spring, even if a person or a vehicle steps on the cover, the body can easily receive the stress in the longitudinal direction, and thus the cover is caused by the stress in the longitudinal direction. The damage can be prevented beforehand.

1 is a front sectional view showing an installation state of the separation prevention structure of the underground buried sewage pipe according to the present invention.
Figure 2 is an exploded perspective view of the separation prevention structure of the underground buried sewage pipe according to the present invention.
3a to 3b is a front cross-sectional view and an operation view taken separately from the identification display in the separation prevention structure of the underground buried sewage pipe according to the present invention.
Figure 4 is a block diagram showing the interrelationship between some components in the separation prevention structure of the underground buried sewage pipe according to the present invention.
Figure 5 is a perspective view showing a separate extractor hanger member from the structure of preventing the underground buried sewage pipe according to the present invention.
6 to 9 is a flow diagram of the installation prevention structure of the underground buried sewage pipe according to the present invention.
Figure 10 is a state of use of the separation prevention structure of the underground buried sewage pipe according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail.

1 is a front sectional view showing an installation state of the separation prevention structure of the underground buried sewage pipe according to the present invention, Figure 2 is an exploded perspective view of the separation prevention structure of the underground buried sewage pipe according to the present invention, Figure 3 Figure 4 is a front sectional view and an operation view taken separately from the identification display in the separation prevention structure of the underground buried sewage pipe according to the invention, Figure 4 is the correlation between some components in the separation prevention structure of the underground buried sewage pipe according to the present invention Figure 5 is a block diagram showing the relationship, Figure 5 is a perspective view showing a separate extraction of the hanger member in the structure of the sewer sewer pipe sewer according to the present invention, Figure 6 to Figure 9 of the underground buried sewage pipe according to the present invention This is a flow chart of the separation prevention structure.

Leaving prevention structure of the underground buried water and sewage pipe according to the present invention, the tube body (10) buried in the ground; A binding ring (20) installed in the tube body (10); A wire 30 inserted into the tube body 10 and bound by the binding ring 20; Strain gauge 40 is installed in the wire 30, and detects the tension change of the wire 30 and outputs it to the control unit 56; A protective case 51 embedded in the ground, a main body 52 which is installed in the protective case 51 so as to be movable, and is elastically supported upward by a spring S, and a light-transmitting portion 53a. And a cover 53 installed on the protective case 51 and an upper surface of the main body 52 so as to be exposed to the outside, and a battery 54 for supplying power and an upper surface of the main body 52. The LED is supplied with power and is turned on to emit light to the outside through the light-transmitting part 53a, and is installed on the upper surface of the main body 52 to receive power from the battery 54, and the strain gauge 40 An identification display unit (50) having a control unit (56) for receiving the tension detection signal from the control unit and controlling the LED (55); It is disposed on the upper part of the tube body 10, is detachably installed on the tube body 10 is composed of a hanger member 60 to prevent the deflection of the tube body 10, as shown in FIG.

The tube body 10 embedded in the ground includes: an iron portion 11 having a first settling groove 11a at one end thereof; A main portion 12 provided with a second settling groove 12a at the other end; A wire installation hole 13 connecting the first settling groove 11a and the second settling groove 12a and arranged radially; Consists of a groove portion 14 formed on the circumferential surface, it is shown as shown in Figs.

In the present embodiment, the groove 14 is preferably formed in the center for the center of gravity of the tube body 10, a plurality of grooves 14 depending on the number of the fixing portion 61 of the hanger member 60 is installed It may be formed on the peripheral surface of the tube body (10).

The binding ring 20 is installed in the first settling groove 11a or the second settling groove 12a of the pipe main body 10. In the present embodiment, the binding ring 20 is the first settling groove 11a. And a diameter equal to the diameter of the second settling groove 12a, and the material is metal, and a binding groove 21 cut to a predetermined depth is formed along the circumferential surface.

The number of the binding grooves 21 is preferably formed to be the same as the number of the wire installation hole 13 formed in the tube body (10).

The wire 30 inserted into the tube body 10 and bound by the binding ring 20 is provided with locking portions 31 at both ends, and the locking portion 31 is a binding groove of the binding ring 20. 21) are bound and bound.

The wire 30 is made by twisting a plurality of strands of wire with known roughening, and preferably made of a material having a certain elastic restoring force.

A well-known strain gauge 40 is attached to and fixed to a wire 30 inserted into the lower wire installation hole 13 of the tube body 10 among the plurality of wires 30 installed in the tube body 10.

The strain gauge 40 inserts the wire 30 into the tube body 10 and then cuts the tube body 10 so that the wire 30 is exposed, and the strain gauge 40 is exposed to the exposed wire 30. ) Is fixed by attaching the wires connected to the strain gauge 40 to the outside, and then sealing is performed.

Since the method for attaching the strain gauge 40 to the wire 30 is already known, a detailed description thereof will be omitted.

According to the present embodiment, when settlement of the soft ground occurs, the pipe body 10 continuously installed along the longitudinal direction causes the interconnection part to deflect downward due to its own weight or earth pressure. In this case, tension is generated in the wires 30 interconnecting the plurality of tube bodies 10, and the strain gauge 40 detects a change in tension, that is, tension, generated at this time. At 56, the tension detection signal is output.

Meanwhile, the identification display unit 50 shown in FIGS. 3A to 3B includes a protective case 51 embedded in the ground; A main body 52 which is installed in the protective case 51 so as to be movable, and which is elastically supported upward by a spring S; A cover 53 provided with a light-transmitting part 53a and installed on the protective case 51 to be exposed to the outside; A battery 54 installed on an upper surface of the main body 52 to supply power; An LED 55 installed on an upper surface of the main body 52 and turned on by receiving power to emit light to the outside through the light-transmitting part 53a; Is installed on the upper surface of the main body 52 is supplied with power from the battery 54, and receives a tension detection signal from the strain gauge 40, it is composed of a control unit 56 for controlling the operation of the LED (55).

In the present embodiment, the light-transmitting portion 53a provided on the upper and side surfaces of the cover 53 is a known lens that can increase the diffusion rate of light.

In addition, a stepped portion protruding inwardly is provided at an inner upper portion of the protective case 51, and ascending of the main body 52 is restricted by the stepped portion and at the same time, departure from the upper portion is prevented.

As shown in FIG. 3B, the main body 52 and the cover 53 are installed inside the protective case 51, and a normal spring S is inserted between the protective case 51 and the main body 52. Thus, the body 52 and the cover 53 are elastically supported.

Therefore, even if a person or a vehicle traverses the cover 53, the cover 53 can easily accommodate the stress in the longitudinal direction, thereby preventing the cover 53 from being damaged.

A battery 54, an LED 55, and a controller 56 are installed on an upper surface of the main body 52. As mentioned above, the controller 56 receives a tension change signal from the strain gauge 40, This is compared with the setting reference value, and, if it is higher than the setting reference value of the control unit 56, the LED 55 is operated to control the lighting.

Therefore, the facility manager can intuitively recognize the current state in the pipe main body 10 embedded in the ground by looking at the light of the lighted LED 55, and through this, it is possible to respond quickly and to deal with it. 4 is shown.

The hanger members 60 disposed above the tube body 10 and detachably installed on the tube body 10 to prevent sagging of the tube body 10 are disposed to face each other and are hinged. A fixed portion 61 having a pair of semi-circular bands 61a and 61b that are folded and deployed, surrounding and fixing the groove portion 14 of the tube body 10; A support plate 62 disposed horizontally above the pipe main body 10 and embedded in the ground; It is installed vertically, one end is installed in the fixing portion 61, the other end is composed of a connecting portion 63 is installed on the support plate 62, as shown in FIG.

Holes are formed in the upper ends of the pair of semi-circular bands 61a and 61b, and the connection portion 63, which is a known wire, is penetrated and knotted through the holes, or fixed through a fixing member such as a clamp.

In addition, although the connecting portion 63 suggests a wire, a metal rod or a metal bar may be installed as necessary, and when the metal rod or the metal bar is installed, it may be easily broken when a lateral force is applied, so that it is hinged or pivoted. It is preferable to prevent the breakage of the lateral force by connecting.

In the present embodiment, only one connection part 63 is illustrated to connect the fixing part 61 and the support plate 62 to each other, but a plurality of connection parts 63 may be provided as necessary.

The support plate 62 is a rectangular plate having a predetermined thickness, which is slightly smaller in length than the tube body 10, and has a wider width in the ground, and allows maximum surface contact between the bottom surface of the support plate 62 and the ground surface. It is preferable.

Referring to Figures 6 to 9 the installation process of the separation prevention structure of the underground buried water and sewage pipe according to the present invention.

First, excavate the soft ground in the longitudinal direction, seat the tube body 10 in the excavated portion, insert the binding ring 20 into the first seating groove (11a) of the seated tube body 10, The wire 30 is inserted into the wire installation hole 13, and the wire 30 having the locking portion 31 is inserted, but not all the wire 30 is inserted into the wire installation hole 13, but at a predetermined interval, more clearly. Insert the wire 30 into the wire installation hole 13 corresponding to 0˚, 90˚, 180˚, 270˚.

In addition, in the case of the other tube body 10 ', the main part of the initial tube body 10 in a state in which the wire 30 is inserted into the wire installation hole 13 corresponding to 45 °, 135 °, 225 °, and 315 ° Insert the convex portion 11 of the other tube body 10 'to (12) and interconnect with each other, and at this time, wire installation holes not corresponding to 45, 135, 225, or 315 degrees Insert the wire 30 of the initial tube body 10 to the outside (13) to draw out, the end of the drawn wire 30 is tied to the end of the other tube body 10 ' The tube bodies 10 and 10 'are connected to each other so as to be caught by the binding groove 21 of the binding ring 20 installed in the second settling groove 12a.

The wire 30 is preferably connected with a slight margin so that the tube body 10 and the tube body 10 ', which are interconnected to each other, are not separated from each other by settlement of the soft ground, rather than being pulled too tightly.

In the same manner as described above, another pipe main body 10 "connected to the main portion 12 of the other main body 10 'may be connected.

After the connection process is completed, the fixing portion 61 consisting of a pair of semi-circular bands 61a, 61b are respectively installed in the groove portion 14 provided on the circumferential surface of each tube body 10, 10 ', 10 ". And, one end of the connection portion 63 is fixed to a hole (not shown) of the fixing portion 61 is installed and then covered with earth and sand, the other end of the connection portion 63 is covered with sand so that it can be installed on the bottom surface of the support plate 62 Withdraw to the top of.

Then, the earth and sand may be covered so that the support plate 62 is completely buried in the state where the other end of the connecting portion 63 is fixed to the bottom of the support plate 62. Such a series of installation processes are illustrated in FIGS. 6 to 9.

In the present embodiment, the two tube bodies 10 and 10 'are connected in pairs, but a plurality of tube bodies 10 may be connected in pairs using wires 30 as necessary.

In addition, the other end of the connecting portion 63 is described as connecting to the bottom of the support plate 62, but if necessary, penetrates the center of the support plate 62, the other end of the connecting portion 63, the threaded portion formed on the outer peripheral surface of the support plate The washer may be inserted into the other end of the connecting portion 63 while the lead is drawn through the center of the 62, and the bolt may be fixed by filling it.

Looking at the operation of the present invention made of such a configuration as follows.

As shown in FIG. 1, when the ground subsidence occurs in a state in which a plurality of pipe bodies 10, 10 ', 10 ", 10"' are continuously connected along the longitudinal direction, the pipes are installed continuously along the longitudinal direction. The main body 10, 10 ', 10 ", 10 "' causes the interconnection part to deflect downward due to its own weight or earth pressure. Tension is generated in the wire 30 to be connected, and the strain gauge 40 detects the change in tension generated at this time and outputs a tension change signal to the controller 56.

In addition, because the hanger member 60 is held by the hanger member 60, the pipe main bodies 10, 10 ', 10 ", 10"' are sagging due to settlement. The occurrence of deflection of ') can be suppressed as much as possible.

On the other hand, the control unit 56 receives the tensile change signal from the strain gauge 40, and compares it with the setting reference value, if the higher than the setting reference value of the control unit 56, the LED 55 to the control unit 56 Lights up.

Therefore, the facility manager can intuitively recognize the current state in the pipe main body 10 embedded in the soft ground by looking at the light of the lighted LED 55, and through this, it can be quickly responded and processed.

In addition, since the hanger member 60 is installed on the tube bodies 10, 10 ', 10 ", 10"' and holds the tube bodies 10, 10 ', 10 ", 10"', ground subsidence occurs. Even if the pipe main body (10, 10 ', 10 ", 10"') can be prevented from falling to the submerged part to be damaged.

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be apparent to those skilled in the art that various modifications and changes can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended claims. .

10: main body 11: iron 12: main body
13: wire mounting hole 14: groove 20: binding ring
21: binding groove 30: wire 31: locking portion
40: strain gauge 50: identification mark 51: protective case
52: main body 53: cover 54: battery
55: LED 56: control unit 60: hanger member
61: fixing part 62: support plate 63: connecting part

Claims (1)

A convex portion 11 having a first settling groove 11a at one end thereof, a recessed portion 12 provided with a second settling groove 12a at the other end thereof, and a first settling groove 11a and a second penetrating along the longitudinal direction. A pipe body (10) having a plurality of wire installation holes (13) interconnecting the settling grooves (12a) and a groove portion (14) formed on a circumferential surface and embedded in the ground;
A binding ring 20 having a plurality of binding grooves 21 opened outwardly and selectively coupled to the first settling groove 11a or the second settling groove 12a of the tube body 10;
A wire 30 provided at both ends with a locking portion 31 supported over the binding groove 21 of the binding ring 20 and inserted into the wire installation hole 13 of the tube body 10;
A strain gauge 40 installed on the wire 30 to sense the tension of the wire 30 and output a tension detection signal to the controller 56;
A protective case 51 embedded in the ground, a main body 52 which is installed in the protective case 51 so as to be movable, and is elastically supported upward by a spring S, and a light-transmitting portion 53a. And a cover 53 installed on the protective case 51 and an upper surface of the main body 52 so as to be exposed to the outside, and a battery 54 for supplying power and an upper surface of the main body 52. The LED is supplied with power and is turned on to emit light to the outside through the light-transmitting part 53a, and is installed on the upper surface of the main body 52 to receive power from the battery 54, and the strain gauge 40 An identification display unit (50) having a control unit (56) for receiving the tension detection signal from the control unit and controlling the LED (55);
A fixing portion 61 disposed to face each other and having a pair of semi-circular bands 61a and 61b folded and deployed through a hinge to surround and fix the groove portion 14 of the tube body 10; It is arranged horizontally on the upper portion of the main body 10, and the support plate 62 embedded in the ground, and is installed vertically, one end is installed in the fixing portion 61, the other end is installed in the support plate 62 Breakaway structure of the underground buried water and sewage pipe, characterized in that it comprises a hanger member (60) having.

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