KR20110050235A - High speed assembling method of curved panel using a radial shape assembling device and conduit line construction process using the same - Google Patents

Abstract

PURPOSE: A high-speed assembling method of a curved panel using a radial assembling device and a pipeline construction method using the same are provided to rapidly arrange curved panels into the shape of an assembled pipe body with the simple extension motion of extension members. CONSTITUTION: A high-speed assembling method of a curved panel using a radial assembling device is as follows. A plurality of curved panels(20A,20B) are supplied into an assembly box through a transfer device which moves along an excavated tunnel. A radial assembling device, which comprises a body installed on the leading end of the transfer device as being aligned with the center of the excavated tunnel and extension members that are radially arranged around the body in the circumferential direction of the excavated tunnel, is prepared. The curved panels are respectively fixed to the extension members in the process of being transferred to the assembly box.

Description

High speed assembling method of curved panel using a radial shape assembling device and conduit line construction process using the same}

The present invention relates to a rapid assembly method and a pipeline construction method of the curved plate body using a radial assembly device, and more particularly, to reduce the assembly time of a plurality of curved plate bodies for forming the pipe assembly body using a radial assembly device. In addition, the present invention relates to a rapid assembling method of a curved plate body using a radial assembly device to improve the assemblability of the assembly tube in the excavation port, and to a pipeline promotion method including the same.

The propulsion method is one of the construction methods for constructing pipelines for water supply, sewerage, electricity, and gas, without digging the ground.

In this propulsion method, an excavation opening is formed from the oscillation opening to the reaching opening with the oscillation opening and the reaching opening formed on the two points of the prospective pipeline to be constructed. The pipeline is constructed by pushing it in to push it.

At this time, the propelling bodies are pushed one by one through the front propeller installed in the oscillator side, so that the front propulsion bodies previously inserted into the digging holes are pushed by the rear propulsion bodies during the propulsion operation of the new propulsion bodies. As a result, the propulsion body is propelled in a continuous row along the drill hole.

However, this propulsion method has a disadvantage that it cannot be used as a system when the propulsion of the propulsion pipe becomes difficult due to the excessive length of the propulsion tube being overloaded and the rear propeller being overloaded or a sharp curved section formed on the excavation port. .

Therefore, in recent years, the assembly cylinder is connected to the rear of the excavator and the plurality of curved plate bodies are interconnected along the circumferential direction of the excavator in the interior of the assembly cylinder secured through the propulsion operation of the rear propeller installed in the assembly cylinder. A curved plate assembly method has been introduced, in which assembly assemblies are installed.

In such a curved plate assembly method, the assembly cylinder is provided in a cylindrical shape having a diameter slightly smaller than the diameter of the excavation opening, and the curved plate body is supplied into the assembly cylinder through the oscillation opening and the rear side excavation opening, and the inside of the assembly cylinder is curved. The worker for assembling the plate is to be boarded.

When the assembly of the assembly tube is completed, the excavator is operated and the rear propeller of the assembly cylinder pushes the assembly assembly completed to secure space in the rear side of the assembly cylinder again. A new assembly tube is installed at the front side of the pre-installed assembly tube, and the assembly tube is continuously installed along the excavation hole by repeating this process.

Therefore, according to the curved plate assembly method, there is no risk of overloading the propeller, and by providing the curved plate body used for the curved section of the excavation hole in a different shape from the curved plate body used in the straight section, the pipeline can be smoothly even in the curved section of the excavation hole. Can be built.

However, in the case of the curved plate assembly method, in which the curved tube is assembled in a narrow space inside the assembly bin, the operator's motion is not unnatural in the assembly tube and it is difficult to input equipment that can effectively help the assembly of the curved plate. There was a disadvantage that the assembly work of the curved plate body is difficult and the assembly time is long, which is a major factor in delaying the construction period of the pipeline.

The present invention is to solve the above problems, an object of the present invention is to reduce the assembly time of the plurality of curved plate body for forming the pipe assembly by using a radial assembly device and at the same time of the assembly tube in the excavation It is to provide a rapid assembly method of the curved plate body using a radial assembly device to improve the assemblability, and a pipeline propulsion method including the same.

In order to solve this problem, the rapid assembling method of the curved plate body using the radial assembly device according to the present invention connects the assembly cylinder to the back of the excavator to form an excavation hole and the assembly secured through the propulsion operation of the rear propeller installed in the assembly cylinder. A method for assembling a curved plate body in which a plurality of curved plate bodies are interconnected along a circumferential direction of the excavation hole in an inner space of the barrel to install an assembly tube in the excavation hole, and the plurality of curved plate bodies are moved along the excavation hole. It is supplied through the equipment into the assembly barrel, and the front end of the transfer equipment is provided with a body centered to match the center of the rig, radially disposed along the circumferential direction of the rig around each of the body and is provided elastically A radial assembly device including a plurality of expansion and contraction members is provided, wherein the one assembly tube A plurality of curved plate body to be formed is fixed to each of the expansion and contraction members of the radial assembly apparatus in the process of being transferred to the assembly barrel, the radial assembly unit is a process of transferring the curved plate body to the assembly cylinder to the degree of expansion and contraction of the expansion member Among the plurality of curved plates, the vertical distance between the part farthest from the center of the body and the center of the body is smaller than the radius of the inner diameter of the assembled tubular body, and in the process of connecting between the curved plates, the center of the body and the It characterized in that the vertical distance between the curved plate body is adjusted to the radius of the inner diameter of the assembly pipe.

The body is characterized in that the retractable is provided.

The body includes a first body that is provided at the front end of the transfer equipment to be retractable, and a second body that is provided to be retractable at the tip of the first body, wherein some of the expansion and contraction members of the plurality of expansion members are around the first body Is provided in, the remaining elastic member of the plurality of elastic members is characterized in that provided around the second body.

The body is provided to be rotatable and characterized in that it is detachably coupled to the transfer equipment.

The curved plate body is made of a metal material, the assembly tube is continuously installed over a predetermined section along the longitudinal direction of the excavation opening, adjacent to each other along the circumferential direction between the adjacent assembly tube along the longitudinal direction of the excavation opening The curved plate body is characterized in that the stepped portion is formed along the outer side so that the curved plate body can be mutually stacked in the thickness direction of the curved plate body.

An index member is provided between the step portions overlapping each other between adjacent curved plate bodies.

The adjacent curved plate body is coupled to each other through a fastening member fastened to penetrate the index member in the radial direction from the center of the excavation hole to the stepped portion mutually overlapped, the fastening member is a screw type including a head portion and a fastening portion The stepped portion adjacent to the center of the excavation hole of the pair of stepped portions overlapping each other is provided with a fastening groove for accommodating the head portion, wherein the head portion is used to insert the tool used to fasten the fastening member. It is characterized in that it is provided with a tool insertion groove for a circular shape corresponding to the fastening hole.

The pair of stepped portions overlapping each other is characterized in that the thickness of the stepped portion adjacent to the inner wall of the excavation hole is greater than the thickness of the stepped portion adjacent to the center of the excavation hole.

The rear propeller is characterized in that it comprises a multi-stage flexible hydraulic jack.

The elastic member is connected to the center of the curved plate body, characterized in that at least some of the plurality of curved plate body forming the one assembly tube is provided with a circumferential side length of the excavation hole different from the other curved plate body.

The curved plate body is formed with a coupler penetrating the curved plate body in the thickness direction for coupling with the stretchable member, and a water stopper is filled between the outer surface of the assembly pipe and the inner wall of the excavation hole, the coupler is the stretch member And a connector provided to selectively connect the injection hole for filling of the water repellent agent.

In addition, the pipeline construction method including the rapid assembly method of the curved plate body using the radial assembly according to the present invention is a pipeline construction method for constructing a pipeline in the ground, the back of the excavator to form an excavation when at least part of the pipeline construction The assembly pipe is connected to each other, and a plurality of curved plate bodies are connected to each other along the circumferential direction of the excavator in the assembly cylinder internal space secured through the propulsion operation of the rear propeller installed in the assembly cylinder. A curved plate assembly method is used, and the assembly tube is continuously installed over a predetermined section along the longitudinal direction of the excavation hole by repeating the process according to the curved plate assembly method, wherein the plurality of curved surfaces in the curved plate assembly method The plate body is supplied into the assembly container through a conveying device moving along the excavation hole, At the tip of the transfer device, a body provided with a center coinciding with the center of the excavation hole, and a plurality of elastic members radially disposed along the circumferential direction of the excavation hole around the body to fix the plurality of curved plates to be radially stretchable. The radial assembly device is provided, wherein the radial assembly device is the farthest part from the center of the body in the plurality of curved plate body during the process of transferring the stretch degree of the elastic member toward the assembly barrel The vertical distance between the center of the body is smaller than the radius of the inner diameter of the assembly pipe, and in the process of connecting between the expansion and contraction member, the vertical distance between the center of the body and each curved plate body is adjusted to the radius of the inner diameter of the assembly pipe Characterized in that.

In addition, the pipeline construction method including the rapid assembly method of the curved plate body using a radial assembly according to the present invention further comprises a quick pipe installation step for forming a pipe in the inner wall of the pipe structure at least a portion of the assembly pipe by the heat, The quick pipe is provided with a flexible tube, and the quick pipe installation step includes a tube towing step of pulling a flexible tube impregnated with an epoxy resin into the pipe, and filling the fluid into the flexible tube towed into the pipe. It is characterized in that it comprises a tube adhesion step of closely contacting the inner wall of the pipe, and a tube curing step of curing the flexible tube in close contact with the inner wall of the pipe.

As described above, according to the rapid assembling method of the curved plate body using the radial assembly apparatus according to the present invention and the pipe line promotion method including the same, a plurality of curved plate bodies for forming one assembly tube is installed in the conveying equipment In the state fixed to the device is transferred to the inside of the assembly barrel, in this state each curved plate body is quickly aligned to maintain the shape of the assembly tube by the simple stretching operation of the expansion and contraction members, so as to use the pipeline construction method according to the present invention If so, it is possible to significantly shorten the assembly and assembly time of the curved plate body made in the narrow assembly cylinder.

Next will be described in detail with reference to Figures 1 to 14 attached to the rapid assembly method and the pipeline construction method using the curved plate body using a radial assembly according to an embodiment of the present invention.

The pipeline construction method according to the present embodiment is for the construction of pipelines for pipe construction such as water and sewage, electricity, and gas, and the preparation step and the application step of applying the propulsion method for constructing the pipeline in the initial section using a conventional propulsion method; It comprises a curved plate assembly method applying step of constructing the pipeline after the initial section using the curved plate assembly method, and the inner pipe installation step of forming the inner pipe on the inner wall of the constructed pipeline.

In the preparation step, as shown in FIG. 1, the oscillation opening 1 and the reaching opening 2 are respectively formed in the basement on the starting position and the intermediate position of the expected pipeline to be constructed, and in the state where the preparation step is completed, The application of the propulsion method is carried out. If the length of the conduit is not so long, the formation position of the arrival port 2 may be the end position of the conduit.

In the propulsion method application step, the front oscillator 1a is installed inside the oscillation port 1. Since the excavator (4) is introduced into the oscillation opening (1) from the ground to form the excavation opening (3) by the operation of the excavator (4), the curved surface in the state in which the excavation opening (3) of the predetermined length is formed The assembly cylinder 5 to be used in the plate assembly method application step is introduced into the excavator 4 to the rear to connect to the excavator (4).

Although not shown through the drawings, at this time, between the excavator 4 and the ground of the oscillation port 1, a discharge passage or a power supply line for supplying power to the excavator is provided to discharge soil or rock generated in the excavation process to the ground. Connected.

The assembly cylinder 5 is provided in the cylindrical shape open to the rear side. In the inner space of the assembly cylinder 5, the rear oscillator 5a is installed at the front side, and around the inner diameter and the outer diameter side of the rear end of the assembly cylinder 5 at the time of introduction of the index agent 100, which will be described later, Seals 5b and 5c for sealing 100 are installed. The rear propeller 5a is provided with a pair of four in the vertical direction, the rear propeller 5a may be used as a hydraulic jack.

In this state, the oscillator 1 is operated by using the front oscillator 1a in the process of forming the excavator 3 extended from the oscillation port 1 toward the reaching port 2 by restarting the excavator 4. Push the propellant body 10 into the excavation hole 3 from the side to be propelled.

At this time, the propulsion body 10 is pushed one by one into the excavation hole (3), so that the front propulsion body 10 previously inserted into the excavation hole (3) is rearward when the new propulsion body (10) is propelled in operation. It is pushed by the side propulsion body (10). Accordingly, the propulsion body 10 is propelled in a continuous row along the excavation opening (3). The water stopper 100 is filled between the excavation hole 3 and the propulsion pipe 10 to waterproof the pipe. The water stopper 100 is filled between the propulsion pipe 10 and the excavation hole 3 located on the front side when the new propulsion body 10 is propelled.

In the application step of the propulsion method, as the length of the propulsion body 10 is increased, the rear propeller 1a is overloaded, or a sharp curved section is formed on the excavation hole 3 so that the propulsion work of the propulsion body 10 is performed. This becomes difficult until the point of time, after which the curved plate assembly method application step is performed. For convenience of explanation, hereinafter, the pipeline of the section constructed through the above-described propulsion method application step is referred to as 'A' as the primary pipe path, and is described as 'A'. A) The route of the section to be built forward will be referred to as 'B', referred to as 'secondary pipeline'.

In the application step of the curved plate assembly method, as shown in FIG. 2, the plurality of curved plate bodies 20A in the interior space of the assembly cylinder 5 secured through the propulsion operation of the rear thruster 5a installed in the assembly cylinder 5. The secondary pipe line (B) by using a curved plate assembly method in which 20B are interconnected along the circumferential direction of the excavation hole 3 to install the assembly tubes 30 one by one in the drill hole 3. ).

 In this curved plate assembly method, the curved plate bodies 20A and 20B are supplied into the rear side of the assembly cylinder 5 through the oscillation opening 1 and the primary pipe passage A, and the interior of the assembly cylinder 5 is The operator for the assembling work of the curved plate body (20A, 20B) is to board.

The curved plate bodies 20A and 20B are first conveyed into the assembly tube 5 through the transfer equipment 40 in a state in which the curved plate bodies 20A and 20B are supplied from the ground into the oscillation opening 1. As shown in FIG. 4, in the curved plate assembly method for the movement of the transfer device 40, the front thruster 1a is first removed from the outside of the oscillation port 1 to penetrate the primary pipe A. The rail 41 connecting the assembly cylinder 5 and the oscillation opening 1 is installed, and the rail 41 is assembled when one assembly pipe 30 is completed and the assembly cylinder 5 moves forward. It is hypothesized to extend gradually every time.

Therefore, when the first assembly pipe 30 is installed in front of the primary pipe line A by using the curved plate assembly method, the rear propeller 5a is extended to push the tip of the primary pipe line A, and then contracts with the excavator 4 And a plurality of curved plate bodies 20A and 20B in a state where a predetermined space is secured inside the assembly cylinder 5 between the rear propeller 5a and the primary pipe end by pushing the assembly cylinder 5 forward. Equipment 40 is moved along rail 41 into assembly bin 5. Then, the operator who was in the interior of the assembly tube 5 assembles the curved plate body 30 at the tip of the primary pipe passage A and installs the assembly tube body 30.

When the assembly of one assembly body 30 is completed, this time, the rear propeller 5a pushes the assembled assembly body 30 first and is fixed again between the rear propeller 5a and the preassembled assembly body 30. In order to ensure a space of, in this state is filled with the water stopper 100 between the assembled assembly body 30 and the inner wall of the excavation hole (3), when the installation of one assembly body 30 is completed in this way , Inside the assembly cylinder 5, new curved plate bodies 20A and 20B are supplied, and new assembly tubes 30 are further assembled in front of the assembled tube bodies 30 installed with the curved plate bodies 20. By the repetition of the process, the assembly pipe body 30 is continuously installed along the excavation hole 3 to form a secondary pipe line (B).

Therefore, as in the pipeline construction method according to the present embodiment, when the pipeline is constructed in parallel with the propulsion method and the curved plate assembly method, the advantages of the propulsion method and the curved plate assembly method can be utilized at the same time. It is possible to smoothly construct a pipeline having a section.

Referring to FIGS. 3 to 9, the structure of the curved plate bodies 20A and 20B and the assembly structure between the curved plate bodies 20A and 20B will be described.

The curved plate body 20A, 20B is provided with a metal material so as to be easily produced in large quantities by a mold, and in the case of the metal material, adhesion may be degraded, such curved plate body 20A, 20B has a structure for preventing leakage. .

First, the assembly pipes 30 adjacent to each other along the longitudinal direction of the excavation hole 3 and between the adjacent curved plate bodies 20A and 20B along the circumferential direction overlap each other in the thickness direction of the curved plate bodies 20A and 20B. Steps 21, 22, 23, 24, 25, 26, 27 and 28 are formed along the outer side of the curved plate body 20A and 20B.

In the case of the curved plate bodies 20A and 20B according to the present exemplary embodiment, the curved plate bodies 20A and 20B are provided in the form of curved rectangular plates along the circumferential direction of the assembly pipe body 30, and thus the stepped portions 21, 22, 23, 24, 25, 26, 27 28 is formed on all sides of the curved plate bodies 20A and 20B, and an index member 300 is provided between step portions overlapping each other between adjacent curved plate bodies 20A and 20B.

Therefore, although the curved plate body 20 is formed of a metal material, the adjacent curved plate bodies 20A and 20B overlap each other through the stepped portions, and the curved plated bodies 20 closely adhere to each other by the earth pressure. It is possible to reduce the risk of leakage through), and the leakage blocking effect between the curved plate body 20 is further increased through the index member 300 disposed between the stepped portion.

Considering the shortening of the assembly time of the curved plate bodies 20A and 20B, the index member 300 is one of the stepped portions of the stepped portions to be mutually superimposed with an adhesive or the like during the production of the curved plate bodies 20A and 20B. It is preferable to adhere to the surface.

In addition, among the pair of stepped portions that overlap each other, the thickness of the stepped portions 21, 25, 27, 28 adjacent to the inner wall of the excavation hole 3, which is directly affected by earth pressure, is determined by the step adjacent to the center of the excavation hole 3. Forming larger than the thickness of the parts 22, 23, 24, 26 is advantageous to prevent deformation between the assembly tubes 30.

In addition, the curved plate bodies 20A and 20B which are adjacent to each other in the longitudinal direction of the excavation hole 3 or the circumferential direction of the excavation hole 3 are fixed to each other by fastening the fastening member 200 to the stepped portion. The fastening member 200 is fastened to the radial direction from the center of the excavation hole 3 so that an operator inside the assembly barrel 5 can easily fasten the fastening member 200, and the fastening member 200 is an index member 300. Through).

The fastening member 200 is provided in the form of a screw including a head part 202 and the fastening part 201, and fastening grooves 29a, 29b, and 29c are provided in the stepped part for fastening the fastening member 200. do. Of the fastening grooves 29a and 29b, female threads are processed to be screwed to the external threads of the fastening portion 201, and the fastening groove 29c is provided to accommodate the head portion 202, and the head portion 202 is provided. Is provided with a tool insertion groove (202a) for the insertion of the tool used in the fastening of the fastening member 200 is provided in a circular shape matching the fastening groove (29c). Therefore, when the fastening member 200 is fastened, the fastening groove 29c is sealed through the head part 202 and the index member 300 is maintained in close contact with the fastening portion 201. It is possible to effectively reduce the risk of leakage through the fastening portion of the (200).

On the other hand, in the case of a curved plate assembly method in which the assembly pipe 30 is assembled with the plurality of curved pipe bodies 20A and 20B in a narrow assembly tube 5 interior space, the operation of the operator is unnatural in the assembly tube 5. Therefore, there is a fear that the assembling work of the curved plate bodies 20A and 20B is difficult and the assembling time becomes long.

Therefore, in order to solve this problem, the radial assembly device 50 is used to improve the assembling performance and the assembling speed of the curved plate bodies 20A and 20B formed in the assembly tube 5.

4 to 9, the structure of the radial assembly device 50 and a curved plate assembly process using the same will be described.

First, the radial assembly device 50 has a body 51 coupled to the transfer equipment 40 and a plurality of expansion and contraction are provided to be stretchable, respectively, and radially disposed along the circumferential direction of the excavation hole 3 around the body 51. It is configured to include the member 52.

The body 51 is provided at the front end of the transfer device 40 so that its center coincides with the center of the excavation hole 3, and each elastic member 52 can fix the curved plate body 20A, 20B at the end. To be arranged.

4 and 5 illustrate a structure in which a plurality of curved plate bodies 20A and 20B fixed to the radial assembly apparatus 50 are transferred into the assembly tube 5 through the transfer equipment 40. As shown in FIGS. 4 and 5, the curved plate bodies 20A and 20B are fixed to the one elastic member 52 in the curved plate bodies 20A and 20B in the process of being transferred into the assembly barrel 5. A plurality of assembly for forming one assembly tube 30 is installed in such a manner as to be fixed to the conveying equipment 40, each curved plate body 20A, 20B is stretched in the posture when forming the assembly tube 30 It is fixed to the end of the member 52.

At this time, the transfer equipment 50 is a curved surface fixed to the elastic member 52 so that the curved plate body (20A, 20B) fixed to the elastic member 52 through the stretching operation of the elastic member 52 can be immediately placed in the assembly position. The rear stepped portions 22 and 26 of the tubular bodies 20A and 20B may be aligned with the front stepped portions 21 and 25 of the curved plate bodies 20A and 20B of the assembled tubular body 30. It is desirable to be provided to be able to stop exactly at. Depending on the performance of the transfer equipment 40, it may be difficult to stop the transfer equipment 40 exactly in the above-described position, to compensate for this, the body 51 is preferably installed to be able to move forward and backward.

2 and 3, the adjacent curved plate bodies 20A and 20B along the longitudinal direction of the excavation hole 3 are alternately disposed so that the gaps formed between the curved plate bodies 20A and 20B do not continuously run. For this purpose, the body 51 is preferably provided to rotate in each curved plate assembly process. A hydraulic cylinder and a rotating motor may be built in the conveying equipment 40 at the rear of the body 51 to rotate and move the body 51 back and forth.

In addition, since the radial assembly device 50 may need to be replaced with a different type of the body 51 or the elastic member 52 according to the diameter size or weight of the pipeline to be constructed, the radial assembly device 50 For replacement, the body 51 is preferably detachably coupled to the tip of the transfer device 40.

And the radial assembly device 40 is to adjust the degree of expansion and contraction of the elastic member 52 according to the situation accurately so that the assemblability of the curved plate body 20A, 20B can be more effectively improved.

That is, in the transfer process of the curved plate bodies 20A and 20B transferred to the assembly barrel 5 by the transfer equipment 40, the radial assembly device 40 is a pipe line in which the transfer equipment 40 is installed as shown in FIGS. 4 and 5. In the plurality of curved plate bodies 20A and 20B, the vertical distance between the part farthest from the center of the body 51 and the center of the body 51 in the plurality of curved plate bodies 20A and 20B is smaller than the radius of the inner diameter of the assembly tube 30. The stretching length of the expansion and contraction member 52 is adjusted. Since the conveying equipment 40 to which the curved plate bodies 20A and 20B are fixed should also pass through the primary pipe A provided as the propelling tube 10, the inner diameter of the propelling tube 10 is the inner diameter of the assembly tube 30. It is preferable to be provided larger than or equal to the inner diameter of the assembly pipe 30.

In the process of extending the elastic member 52 to align the curved plate bodies 20A and 20B transferred into the assembly cylinder 5 to the assembly position, as shown in FIG. 6, adjacent curved plate bodies 20A and 20B. Some of the expansion and contraction members 52 of the plurality of expansion and contraction members 52 are first extended so as not to cause interference between them. A hydraulic cylinder for the expansion and contraction operation of the expansion and contraction member 52 may be built in the front end of the body 51 for the expansion and contraction operation of the expansion and contraction member 52.

After that, as shown in FIGS. 7 and 8, the other stretchable members 52 are even stretched, and the stretched lengths of the stretchable members 52 in this state are the center of the body 51 and the curved plate bodies 20A, The vertical distance between 20B) is adjusted to be the radius of the inner diameter of the assembly tube 30. Therefore, the plurality of curved plate bodies 20A and 20B fixed to the elastic member 52 are aligned so as to take the form of the assembled tubular body 30, and in this state, adjacent to the longitudinal direction and the circumferential direction of the excavation opening 3. Between the curved plate body 20A, 20B is fixed through the fastening member 200. Thus assembled between the outer surface of the assembly pipe 30 and the inner surface of the assembly cylinder 5 is preferably spaced apart a predetermined interval so that the forward operation of the assembly cylinder by the oscillator 5a to be performed later.

In the assembling of the curved plate body, the movement of the body 51 and the expansion and contraction of the expansion and contraction member 52 are performed by the hydraulic cylinder, and an operation part is required for the operation of the hydraulic cylinder. Considering the size of the work space, when such a control unit is provided on the radial assembly unit 50 or the transfer equipment 40 side, the operation unit also operates on the transfer unit 40 side separately from the operator who is in the assembly box 5. An operator may be required.

Therefore, in order to prevent this, in the present embodiment, the operator can easily operate the operation of the radial assembly device 50 regardless of the size of the workspace in the assembly container 5, the remote control (not shown) Is prepared.

The remote control (not shown) may be provided in a wireless type or a wired type. When the remote control is provided in a wired type, a connection between a cable (not shown) and a radial assembly device 50 connected to the remote control (not shown) is provided. It is preferable to provide a connection port 42 to the front end side of the transfer equipment 40 so that an operator inside the assembly tube 5 can easily connect the cable (not shown) to the connection port 42.

As described above, in the pipeline construction method according to the present embodiment, a plurality of curved plate bodies 20A and 20B for forming one assembly tube 30 are fixed to the radial assembly apparatus 50 installed in the transfer equipment 40. Since the curved plate body 20A, 20B is conveyed to the inside of the assembly cylinder 5 in this state, it arranges quickly so as to maintain the shape of the assembly tube 30 by the simple extension | stretching motion of the expansion-contraction member 52, and this embodiment By using the pipe construction method according to the example it is possible to significantly shorten the assembly and assembly time of the curved plate body (20A, 20B) made in the narrow assembly barrel (5).

In addition, the elastic member 52 is preferably connected to be fixed to the center of the curved plate body 20A, 20B so that the curved plate body 20A, 20B can be stably fixed to the elastic member 52, and later elongated. A plurality of curved surfaces forming one assembly tubular body 30 so that the curved plate body 20A, 20B on the stretchable member 52 is not caught by the curved plate body 20A, 20B on the stretchable member 52, which has been elongated in advance. At least some of the assembly tubes 20A of the plate bodies 20A and 20B may be provided differently from the curved plate body 20B having different lengths in the circumferential direction of the excavation hole 3.

When the fastening of the fastening member 200 is completed, as shown in FIG. 9, each of the elastic members 52 is separated from the curved plate bodies 20A and 20B, and the radial assembly device 50 in this state is a transfer equipment. Together with 40, it is conveyed toward the oscillation opening 1 again. The new curved plate bodies 20A and 20B supplied from the ground are fixed to each of the expansion and contraction members 52 of the radial assembly device 50 transferred to the oscillation hole 1 to prepare for assembly of the next assembly tube 30.

When the expansion and contraction member 52 is separated from the assembly pipe 30, the rear propeller 5a is driven to re-space the space inside the assembly cylinder 5 between the rear drive 5a and the assembly pipe 30 where the assembly is completed. In this state, the inlet 510 for the filling of the water stopper 100 is connected to each curved plate body 20A, 20B of the assembly tube 30 in this state, as shown in FIG. Each injection hole 510 is connected between the connection pipe 520, the valve 530 to control the flow of the water between the water tank and the connection pipe 520, not shown on one side of the connection pipe 520 Is installed. Therefore, as the valve 530 is opened, the water stopper 100 is filled between the outer surface of the assembly pipe assembly 30 where the assembly is completed and the inner wall of the excavation hole 3 corresponding thereto, wherein the assembly pipe assembly is completed. The tip circumference of the 30 is sealed by the seals 5b and 5c of the assembly cylinder 5 to prevent leakage of the water agent.

Referring to FIG. 9 again, the curved plate body 20A, 20B is formed with a coupler 29d penetrating the curved plate body 20A, 20B in the thickness direction for coupling with the elastic member 52. (29d) is fastened to the connector (410, 420) for connecting and fixing the elastic member 52, the connector (410, 420) is the elastic member 52, as well as the injection hole (510) for the filling of the water stopper (100) It is also provided to be connected to the coupler (29d).

The connector 410 is provided in a hollow for the passage of the water-repellent agent 100 and is provided with first and second spirals at one end and the other end of the outer periphery, respectively, and screwed to the coupling member 29d through the first spiral. In this state, the second helix is first connector 410 protruding into the coupler 29d, and one end is fixed to the distal end of the elastic member 52 or the injection port 510 and the second end is fixed. It is configured to include a second connector 420 is fastened to the two screws in a screw method.

Therefore, the curved tube assembly method according to the present embodiment through the structure of the connector (410, 420) is convenient because it is not necessary to separate the first connector 410 during the connection of the injection port for the injection of the index agent (100). A locking portion 52a is provided on an outer surface of the elastic member 52 so as to be caught by the second connector 420, and the locking portion is also provided at the end of the injection hole 510 so that the connectors 410 and 420 can be used in common. The same structure as 52a is provided.

The connectors 410 and 420 are removed from the coupler 29d in the state where injection of the water agent 100 is completed, and the coupler 29d from which the connectors 410 and 420 have been removed is the sealing member 500 as shown in FIG. 11. Sealed through. The sealing member 500 may be fastened to the coupler 29a by a screw method. For this purpose, the tool inserting groove 501 is formed in the sealing member 500 so that a tool used when the sealing member 500 is fastened is inserted. do.

12 shows a structure in which the secondary pipe line B is completed by repeating the above-described curved plate assembly method.

The pipes constructed as such may be used as electric pipes for the installation of electric wire cables, but are not suitable for use as water and sewage pipes or gas supply pipes that require thorough waterproofing.

Therefore, in the pipeline construction method according to the present embodiment, after the application of the curved plate assembly method is completed, the rapid pipe installation step of forming the inner pipe on the inner wall of the pipeline is additionally performed. Become available.

In general, when the inner pipe is installed in the pipeline, a separate unit pipe for forming the inner pipe inside the pipeline is pushed into the pipeline to fill the mortar between the inner wall of the pipeline and the pipe to fix the core pipe. Due to the propulsion operation of the inner pipe, it is difficult to form the inner pipe, and the inner diameter of the inner pipe is difficult to be secured by the mortar filling layer filled between the inner pipe and the inner wall of the pipe.

Therefore, in the fast pipe installation step according to the present embodiment, the fast pipe 600 is provided with a flexible tube, and the fast pipe 600 provided with the flexible tube is not only easy to install but also has an internal diameter having a large difference from the diameter of the inner wall of the pipeline. It is not difficult to secure the diameter.

In the present embodiment, the quick pipe installation step includes a tube towing step for pulling a flexible tube impregnated with an epoxy resin into the pipeline, and filling the fluid into the flexible tube towed into the pipeline to closely adhere the flexible tube to the inner wall of the pipeline. It is simply installed through a tube adhesion step to make, and a tube curing step of curing the flexible tube in close contact with the inner wall of the pipe.

As shown in FIG. 13, in the tube towing step, the tube feeder 620 on the ground side of the oscillation opening 1 side to the oscillation opening 1 using the winch 610 installed on the ground of the reaching opening 2 side. The supplied flexible tube is pulled toward the arrival port 2 and placed on the conduit. During the tube towing process, the flexible tube is impregnated with an epoxy resin so that the flexible tube adhered to the inner wall of the conduit can be easily attached to the inner wall of the conduit in a subsequent tube contact step.

In the tube contacting step, as shown in FIG. 14, the liquid or gas is filled into the flexible tube through the end of the flexible tube toward the oscillation opening 1 to attach the outer surface of the flexible tube to the inner wall in close contact with the inner wall of the tube. In the tube curing step, the flexible tube in close contact with the inner wall of the pipe is thermally cured for a predetermined time to complete the installation of the inner pipe 600. Both ends of the inner tube 600 extending out of the pipeline may be cut to an appropriate length after the tube elapsed step.

Therefore, according to the fast pipe installation step, the propulsion work of the unit pipe is deleted, so that the fast pipe 600 can be easily formed, and the fast pipe 600 installed by the fast pipe installation step has an outer surface closely adhered to the inner wall of the pipe while A large inner diameter close to can be secured.

Pipeline construction method according to this embodiment is terminated as soon as the rapid pipe installation step is completed.

On the other hand, in the curved plate assembly process using the radial assembly device 50, the length of the curved plate body in the longitudinal direction of the excavation hole 3 can be formed longer than the diameter of the excavation hole (3), in this case assembled by the curved plate body As the length of the assembly pipe body 30 is increased, the construction speed of the pipeline can be further improved. Thus, in order to form the length of the assembly pipe body 30, the rear propeller 5a has two or more stages. It is preferable to use a flexible hydraulic jack, in which case the rear inner space of the assembly barrel (5) should also be secured to the corresponding length.

In addition, as shown in FIG. 15, in which the fixing structure of the curved plate body 20 ′ and the radial assembly device 50 ′ according to another embodiment of the present invention is formed, the elastic member when the length of the curved plate body 20 ′ is formed to be somewhat longer. 52 'is provided with a connecting portion 52b that is elastically connected to the body 51 and a plurality of fixing portions 52c provided to be simultaneously fixed to various portions on the curved plate body 20' along the longitudinal direction. Can be. Accordingly, the radial assembly device 50 'according to the present embodiment can more stably fix the curved plate body 20' having a longer length.

In addition, as shown in FIGS. 16 and 17 showing the structure of the curved plate body 20 'and the radial assembly apparatus 50' according to another embodiment of the present invention, the body 51 'of the radial assembly apparatus 50' is shown. Is a multi-stage retreat structure including a first body (51a) rotatably and retractable at the distal end of the transfer equipment 40, and a second body (51b) removably at the distal end of the first body (51a) It may be provided to have. In addition, the elastic member 52 is divided into the first and second bodies 51a and 51b in such a manner that a part thereof is provided around the first body 51a and the other part is provided around the second body 51b. In this case, it is preferable that the elastic member 52 provided in the first body 51a and the elastic member 52 provided in the second body 51b cross each other.

Therefore, the radial assembly device (50 ') is fixed to the elastic member 52 provided around the first body (51a) of the plurality of curved plate body (20') to form one assembly tube, the rest If the curved plate body 20 'is fixed to the elastic member 52 provided around the second body 51b, the interference between the curved plate body 20' may occur during the expansion and contraction of each of the elastic members 52. Can be further reduced.

In addition, when aligning the curved plate body 50 s fixed in the form as shown in FIGS. 16 and 17 in the form of an assembled tubular body, the elastic member 52 provided in the second body 51b is elongated and fixed to the second body 51b. The curved plate body 20 'fixed to the first body 51a is positioned between the curved plate body 20' fixed to the second body 51b while the curved plate body 20 'is first moved to the assembly position. After advancing the first body 51a as much as possible, the stretchable member 52 provided in the first body 51a is elongated so that each curved plate body 20 'is aligned to the position of the assembly tube. Since the fastening operation of the fastening member is the same as the first embodiment described above will be omitted.

1 is a cross-sectional view showing a state in which the propulsion method applying step in the pipeline construction method according to an embodiment of the present invention.

Figure 2 is a cross-sectional view showing a state in which the curved plate assembly method in the pipeline construction method according to an embodiment of the present invention.

Figure 3 is a perspective view showing the structure of the secondary pipe line constructed by the curved plate assembly method in the pipe construction method according to an embodiment of the present invention, showing the structure of the curved plate body.

4 is a cross-sectional view illustrating a state in which a curved plate body is transferred into an assembly tube through a conveying device in a curved plate body assembly method in a pipeline construction method according to an exemplary embodiment of the present invention.

5 is a cross-sectional view of the state of FIG. 4 as viewed from a direction different from that of FIG. 4.

6 is a cross-sectional view illustrating a state in which a stretchable member to which some curved plate bodies are fixed is extended.

FIG. 7 is a cross-sectional view illustrating a state in which a stretchable member to which the remaining curved plate body is fixed in the state of FIG. 6 is extended, and is viewed from a direction different from that of FIG. 6.

8 is a cross-sectional view of the state of FIG. 7 viewed from a direction different from that of FIG. 7.

9 is a cross-sectional view showing a coupling structure between the curved plate body and the elastic member of the radial assembly device in the pipeline construction method according to an embodiment of the present invention.

FIG. 10 is a cross-sectional view illustrating a state in which an index agent is injected between an assembly pipe and an excavation hole assembled through a curved plate body in the pipeline construction method according to the preferred embodiment of the present invention.

11 is a main sectional view showing a state in which the coupling sphere of the curved plate body is sealed by the sealing member in the state in which the water injection is completed between the assembly pipe and the excavation hole in the pipeline construction method according to an embodiment of the present invention. to be.

12 is a cross-sectional view showing a pipeline structure in a state in which a curved plate assembly method is completed in a pipeline construction method according to an embodiment of the present invention.

13 is a cross-sectional view showing a state in which the tube towing step of the quick pipe installation step in the pipeline construction method according to an embodiment of the present invention.

14 is a cross-sectional view showing a state in which the tube adhesion step of the quick pipe installation step in the pipeline construction method according to an embodiment of the present invention.

15 is a cross-sectional view showing a fixing structure of the curved plate body and the radial assembly according to another embodiment of the present invention.

16 is a cross-sectional view showing a fixing structure of the curved plate body and the radial assembly according to another embodiment of the present invention.

17 is a cross-sectional view showing a fixing structure of the curved plate body and the radial assembly device according to another embodiment of the present invention as seen in a direction different from that of FIG. 16.

* Description of the symbols for the main parts of the drawings *

1: oscillation port 2: reaching port

3: excavator 4: excavator

5: assembly tube 10: propulsion tube

20A, 20B: curved plate body 30: assembly tube

40: transfer equipment 50: radial assembly device

Claims (13)

The assembly cylinder is connected to the rear of the excavator to form an excavation hole and the plurality of curved plate bodies are interconnected along the circumferential direction of the excavation hole in the assembly cylinder inner space secured through the propulsion operation of the rear propeller installed in the assembly cylinder. In the assembling method of the curved plate body for installing the assembly pipe to the excavation port, The plurality of curved plate bodies are supplied into the assembly barrel through a transfer device moving along the excavation opening, At the tip of the transfer equipment is a radial assembly device comprising a body provided so that its center coincides with the center of the excavation hole, and a plurality of elastic members disposed radially along the circumferential direction of the excavation hole around the body and being elastically arranged. Prepared, The plurality of curved plate bodies for forming the one assembly tube body is fixed to each of the expansion and contraction members of the radial assembly device in the process of being transferred to the assembly cylinder, The radial assembly device is a vertical distance between the body farthest from the body center and the body center in the plurality of curved plate body during the process of transferring the stretched degree of the elastic member toward the assembly barrel The radial diameter of the tubular body is smaller than the radius of the inner diameter, and in the process of connecting between the curved plate body using a radial assembly device characterized in that the vertical distance between the center of the body and each curved plate body is adjusted to the radius of the inner diameter of the assembled tubular body. Rapid assembly method of curved plate body. The method of claim 1, Rapid assembly method of the curved plate body using a radial assembly device, characterized in that the body is provided retractable. 3. The method of claim 2, The body includes a first body that is provided at the front end of the transfer equipment retractable, and a second body that can be provided at the front end of the first body, Rapid assembly of the curved plate body using a radial assembly device, characterized in that some of the plurality of elastic members are provided around the first body, and the remaining elastic members of the plurality of elastic members are provided around the second body. Way. The method of claim 1, The body is rotatably provided rapid assembly method of the curved plate body using a radial assembly device, characterized in that detachably coupled to the transfer equipment. The method of claim 1, The curved plate body is provided with a metal material, the assembly tube is continuously installed over a predetermined section along the longitudinal direction of the excavation opening, The stepped portion is formed along the outer side so that the curved plate between the mutually adjacent assembly pipe body along the longitudinal direction of the excavation hole and mutually adjacent curved plate body along the circumferential direction can be superimposed in the thickness direction of the curved plate body Rapid assembly method of the curved plate body using a radial assembly. The method of claim 5, Rapid assembly method of the curved plate body using a radial assembly device, characterized in that the index member is provided between the stepped portion overlapping each other between the adjacent curved plate body. The method of claim 6, Between the adjacent curved plate body is coupled to each other through a fastening member which is fastened to penetrate the index member in the radial direction from the center of the drilling hole to the stepped portion overlapping each other, The fastening member is provided in the form of a screw including a head and the fastening portion, A fastening groove for accommodating the head portion is provided at a step portion adjacent to the center of the excavation hole among the pair of step portions overlapped with each other. The head unit has a tool insertion groove for inserting the tool used to fasten the fastening member to provide a rapid assembly method of the curved plate body using a radial assembly device, characterized in that provided in a circular shape corresponding to the fastening hole. The method of claim 5, The pair of stepped parts overlapped with each other is faster than the thickness of the stepped portion adjacent to the center of the excavation, the rapid assembly method of the curved plate body using a radial assembly device, characterized in that the thickness of the stepped portion adjacent to the inner wall of the excavation. The method of claim 5, The rear propeller is a rapid assembly method of the curved plate body using a radial assembly device, characterized in that it comprises a multi-stage stretchable hydraulic jack. The method of claim 1, The stretching member is connected to the center of the curved plate body, At least a portion of the plurality of curved plate body forming the one assembly pipe is rapid assembly method of the curved plate body using a radial assembly device, characterized in that the circumferential side length of the excavation hole is provided different from the other curved plate body. The method of claim 1, The curved plate body is formed with a coupler penetrating the curved plate body in the thickness direction for coupling with the elastic member, Between the outer surface of the assembly pipe and the inner wall of the excavation hole is filled with an index agent, The fastener assembly method of the curved plate body using a radial assembly device, characterized in that the coupling member is fastened to the coupling member provided to selectively connect the expansion member and the injection hole for filling of the index agent. As a pipeline construction method for constructing a pipeline in the ground, the assembly is secured through the propulsion operation of the rear propeller installed in the assembly cylinder by connecting the assembly cylinder to the back of the excavator to form an excavation when at least a portion of the pipeline construction A curved plate assembly method is used in which a plurality of curved plate bodies are interconnected along the circumferential direction of the excavation hole in an inner space of the cylinder to install an assembly tube in the excavation hole, and the assembly tube is repeated in the process according to the curved plate assembly method. To be continuously installed over a predetermined section along the longitudinal direction of the excavation, In the curved plate assembly method, the plurality of curved plate bodies are supplied into the assembly barrel through a transfer device moving along the excavation hole, At the tip of the transfer device, a body provided with a center coinciding with the center of the excavation hole, and a plurality of elastic members provided radially along the circumferential direction of the excavation hole around the body to fix the plurality of curved plates to be radially stretchable. Is provided with a radial assembly comprising a, The radial assembly device is a vertical distance between the body farthest from the body center and the body center in the plurality of curved plate body during the process of transferring the stretched degree of the elastic member toward the assembly barrel It is smaller than the radius of the inner diameter of the tube, in the process of connecting between the elastic member using a radial assembly device characterized in that the vertical distance between the center of the body and each curved plate body is adjusted to the radius of the inner diameter of the assembly tubular body. Pipeline construction method including rapid assembly method of curved plate body. The method of claim 12, Further comprising a quick pipe installation step for forming a quick pipe on the inner wall of the pipeline consisting of at least a portion of the heat pipe assembly, The inner tube is provided with a flexible tube, The quick pipe installation step includes a tube towing step of pulling a flexible tube impregnated with an epoxy resin into the pipe line, and a tube close contact with the flexible tube to be in close contact with the inner wall of the pipe by filling a fluid into the flexible tube towed into the pipe line. Pipe construction method including the rapid assembling method of the curved plate body using a radial assembly device, characterized in that it comprises a step and a tube curing step of curing the flexible tube in close contact with the inner wall of the pipe.

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