KR101964712B1 - Conr shaped clamp based movable type spool manufacturing system - Google Patents

Abstract

The present invention relates to a conic clamp-based mobile spool manufacturing system which can automate the manufacture of unit spools based on a process piping and instrumentation diagram, improve manufacturing precision of unit spools, and facilitate their transport and arrangement by modularizing devices into unit modules. The conic clamp-based mobile spool manufacturing system comprises: a dispenser device to separate incoming pipes for each material and each pipe diameter to store the pipes; a blast device to perform a blasting process on pipes transferred from the dispenser device; a cutting device to cut pipes transferred from the blast device into unit pieces corresponding to unit spools or punch branch holes on unit pieces; a welding device to connect a pipe and a unit piece or connect two or more unit pieces or connect a unit piece and a fitting object or connect any one among a pipe, a unit piece, and a fitting object to a branch hole; and a pipe transport device to move at least one among a pipe and a unit piece between the devices. The device can be attached and detached from a floor to be transported and rearranged.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cone-type movable-

[0001] The present invention relates to a cone-type clamp-based movable spool manufacturing system, more specifically, to automate the production of a unit spool on the basis of a process-stage relation, improve the manufacturing accuracy of the unit spool, To a conical clamp-based movable spool production system for facilitating transportation and placement.

Generally, plant construction consists of pile construction, civil engineering, steel construction, mechanical construction, piping construction, electrical construction, instrument construction, and thermal insulation works. In the case of plant construction, air (construction period) by construction type is based on the input labor force of each type, such as piping construction (43%), pile / civil works (29%), machinery construction (13% %). Whether or not to comply with the air of the plant construction should depend on the piping construction.

The general process of piping consists of pipe construction process and pressure test process.

The piping construction process consists of a process of manufacturing a spool in a field workshop, a process of loading a spool made in a field factory on a yard, a process of moving a spool on a yard to a site, And installing the spool on the spot. The spool manufacturing process and the field installation process consist of a welding process, a non-destructive testing process, and a heat treatment process, respectively. The welding process in the spool manufacturing process is a process for manufacturing a spool, and the welding process in the field installation process is a process for connecting a spool. The non-destructive test process is a process for confirming the integrity of the spool welded part by naked eye or X-ray projection, and the heat treatment process is a process for preventing the cracks from being easily applied to the external impact due to strong hardness at the welded site.

The internal pressure test process consists of the client approval process and the internal pressure test process.

Korean Registered Patent No. 10-1739334 entitled " Plant piping spool process management system, "

It is an object of the present invention to solve the conventional problems, and it is an object of the present invention to automate the production of a unit spool on the basis of a relationship between a process and a part, improve a manufacturing accuracy of a unit spool, Shaped movable spool-making system for facilitating the operation of the conical clamp-based movable spool.

In particular, there is provided a conical clamp-based movable spool making system for clamping two mutually adjacent members for welding, matching the concentricity between the two members, and stably fixing the two members without a separate fit-up member .

According to a preferred embodiment of the present invention, a conical clamp-based movable spool manufacturing system according to the present invention is formed in accordance with the disassembly of a pipe line indicated in a process piping instrumentation chart (P & ID, Piping and Instrumentation Diagram) A system for manufacturing a movable spool with a cone-type clamp for manufacturing a unit spool, comprising: a dispenser device for separating and storing the incoming pipes according to materials and diameters; A blasting device for performing a blasting process on the pipe delivered from the dispenser device; A cutting device that cuts the pipe delivered from the blast device into a unit piece corresponding to the unit spool or punctures a branch hole in the pipe or the unit piece; A welding unit connecting the pipe and the unit piece, connecting two or more unit pieces, connecting the unit piece and a fitting, or connecting the pipe, the unit piece, and the fitting to the branch hole, Device; And a pipe transfer device for moving at least one of the pipe and the unit piece between the above-described devices, wherein the above-described devices are removable from the floor so as to be able to be carried and rearranged.

The welding apparatus may include a first welding unit connecting the pipe and the unit piece, connecting the unit piece to two or more, connecting the pipe and the fitting, or connecting the unit piece and the fitting, And a second welding unit connecting the pipe and the fitting, or connecting the unit piece and the fitting, Or the like.

Here, any one of the first welding unit and the second welding unit may include: a support unit in which the pipe or the hollow first member including the unit piece is supported; A supporting carriage on which a hollow second member including fittings corresponding to the first member supported by the supporting unit is supported; A fitting welding unit for welding a welded portion of the first member and the second member; And a second clamping unit for gripping and fixing the first member and the second member so that the concentricity of the first member and the second member coincides with each other.

Here, the second clamping unit may include: a cylindrical first expanding unit for holding the first member in a state of being inserted into the first member; A frusto-conical second expanding unit disposed on one side of the first expanding unit and holding the second member in a state of being inserted into the second member; A pipe support disposed on the other side of the first expansion unit; And an expansion control unit for expanding the diameter of the first expansion unit or expanding the diameter of the second expansion unit based on the pipe support.

At this time, the first expansion unit may include at least two first expansion members formed along the circumferential direction of the first member; And a first resilient ring member elastically supporting the first expanding member in a state of being wrapped along the circumferential direction of the first member such that the first expanding members come into contact with or come into contact with each other to form a cylindrical shape.

The second expansion unit may include at least two second expansion members formed along the circumferential direction of the second member; And a second resilient ring member elastically supporting the second expanding member in a state of being wrapped around the second member in a circumferential direction of the second member so as to be in a frustum shape in contact with or close contact with each other.

Here, the piping support may include a support body having a part of the expansion control unit and the first expansion unit disposed at one side thereof; And a spacing support protruding from the outer circumferential surface of the support body to support the inner surface of the first member.

The expansion control unit may include: a first piston reciprocally coupled to the first expansion unit for expanding the diameter of the first expansion unit; A second piston reciprocably coupled to the second expansion unit through a center of the first piston to expand the diameter of the second expansion unit; Hydraulic means for reciprocating at least one of the first piston and the second piston by a fluid to be delivered; And a hydraulic pressure supply unit for supplying a fluid to the hydraulic pressure unit.

Here, the expansion control unit may further include a clean unit for supplying a clean gas to a welded portion between the first member and the second member.

Here, the clean unit may include a plurality of ejection holes spaced apart from one another along a circumferential direction of the spacing member; A clean air passage for interconnecting the plurality of blow holes in a state of being embedded in the first piston to form a clean gas feed path; And a clean gas supply unit for supplying a clean gas to the clean channel.

Here, the second clamping unit may further include a control unit for controlling the operation of the expansion control unit to control whether the first expansion unit is expanded in diameter or whether the second expansion unit is expanded in diameter.

Here, the control unit may include: a controller for controlling an operation of the expansion control unit; An expansion control switch for selecting whether to extend the diameter of the first expansion unit or the diameter of the second expansion unit; And a packaging line connecting the controller and the expansion control unit to form a movement path of fluid or clean gas for operation of the expansion control unit.

Here, the second clamping unit further includes a cooling unit for cooling at least one of the first member, the welded portion of the first member and the second member, and the expansion control unit.

Here, the cutting apparatus includes: a vertical cutting unit that cuts the pipe into unit pieces using a cutting tool to form a cross section perpendicular to the longitudinal direction of the pipe; A slant cutting unit for cutting the pipe into unit pieces using a cutting tool so as to form a slanting section in the longitudinal direction of the pipe; A flame cutting unit that cuts the pipe into unit pieces using a flame or punctures the branch hole using a flame; And a fluid cutting unit that cuts the pipe into unit pieces using a high-pressure fluid or punctures the branch hole using a high-pressure fluid; And the like.

Here, the pipeline transfer device may include: an axial direction transfer unit for moving the pipe or the unit piece in the longitudinal direction; A cross direction transfer unit for moving the pipe or the unit piece in a direction crossing the longitudinal direction; And a fitting flow transfer unit for moving the fittings; And the like.

A cone-type movable spool manufacturing system according to the present invention comprises: a bending device for bending the pipe or the unit piece according to preset bending information; An inspection device for inspecting welded areas and specifications of the unit spools completed through the welding device; And a spool storage device for storing the unit spool completed through the welding device; As shown in FIG.

The conical clamp-based movable spool manufacturing system according to the present invention includes a plurality of unit bottom members arranged vertically and horizontally on the floor, and at least the blasting device, the cutting device, A welding device, the inspection device, and a bottom support unit in which the pipe transfer device is detachably arranged.

Here, the unit bottom member may include a unit plate portion having a predetermined area and thickness; A fitting groove portion formed on one side surface of the unit plate portion; A fitting portion protruding from the other side surface of the unit plate portion to be inserted into a fitting groove portion formed in another adjacent unit bottom member; And a mounting portion that is engaged with the fitting portion inserted into the fitting groove portion when the fitting portion is inserted into the fitting groove portion between mutually adjacent unit floor members.

Here, the fitting portion may include: a pivoting groove portion formed to be recessed on the other side surface of the unit plate portion corresponding to the fitting groove portion; A fitting projection portion rotatably coupled to the rotation groove portion via a fitting rotation shaft portion; And a mounting hole portion penetrating through the fitting projection to allow the mounting portion to pass therethrough.

Here, the mounting portion may include: a mounting rod portion slidably coupled to one side of the fitting portion; A rod path portion forming a slide movement path of the mounting rod portion so as to communicate with the fitting portion; A lift lever part coupled to intersect the longitudinal direction of the mounting rod part; And a path slit part forming a slide movement path of the lifting lever part to communicate with the rod path part.

According to the conical clamp-based movable spool manufacturing system having the dispenser apparatus according to the present invention, it is possible to automate the manufacture of the unit spool based on the relationship between the process and the stage, and to improve the manufacturing accuracy of the unit spool.

In addition, the present invention can be easily carried and rearranged by moving the apparatus, and can smoothly cope with the site conditions and shorten the construction period.

In addition, the present invention can measure the dimensions of the pipes to be received through the dispenser device, and store the pipes separately for each pipe diameter. Especially, it is possible to prevent the safety accident of workers by automating the separation of pipe by pipe diameter.

Further, in measuring the pipe dimension, the pipe can be dimensioned by using a distance change between the base and the lifting rod portion, that is, a lift distance of the lifting rod portion and a rotation angle of the support rod portion, It improves the dimensional accuracy of the pipe, and it is possible to store the pipe separately for each pipe diameter.

In addition, the present invention can measure the pipe dimension by using the first rotation angle of the rotary rod portion and the second rotation angle of the support rod portion, and can improve the dimensional accuracy of the calculated pipe, Pipes can be stored separately by pipe diameter.

Further, the present invention can simplify the calculation of the dimension of the pipe, and precisely control the position of the input delivery unit according to the calculated dimension.

Further, in the present invention, since the support rod portion exhibits the "V" shape, the contact state between the pipe and the support rod portion is stabilized, and the second rotation angle of the support rod portion has the effect of correcting the error with respect to the dimension of the pipe to be calculated .

Further, according to the present invention, it is possible to smoothly slide the support rod part with respect to the pipe, to prevent abrasion of the support rod part or the pipe, and to prolong the life of the support rod part with the additional constitution of the first support roller part and the second support roller part .

In addition, the present invention smoothes the transmission of pipes even when there is no external force, and facilitates the storage of the pipes by the diameters in the dispensing unit.

Further, according to the present invention, in the supply unit, the supply stopper and the single supply unit interlockedly discharge the corresponding pipe from the supply unit, as well as prevent the pipe from falling off from the supply unit.

In addition, the present invention stably supports the individual pipes in the process of delivering the pipes through the detailed configuration of the input delivery unit and the discharge delivery unit, and stably supports the pipes from the input side of the pipes toward the discharge side of the pipes, .

Further, in the dispensing unit, the supporting stopper and the single discharge unit interlock with each other to discharge the respective pipes from the dispensing unit, and also to prevent the pipes from falling off from the dispensing unit.

In addition, the present invention can remove residue from the pipe by blasting residues remaining in the pipe after the blasting process through the blast apparatus, and prevent defects generated by the residue in the subsequent process.

The present invention also prevents the pipe from rolling in the seating bracket through the detailed configuration of the seating bracket and prevents the pipe from separating from the seating bracket or bumping against the floor when the pipe is tilted.

Further, the present invention allows the residues separated from the mounting bracket or pipe to fall naturally through the detailed structure of the pipe supporting portion, and to prevent the residue from stagnating in the mounting bracket or pipe.

Further, the present invention can stabilize the rotation of the mounting bracket through the detailed configuration of the bracket rotation unit, and can easily adjust the inclination of the pipe.

In addition, when the eccentric rotation part is provided in the eccentric rotation part, the load generated in the eccentric rotation part can be reduced, the failure of the eccentric rotation part can be prevented, and the rotation of the mounting bracket can be smooth.

In addition, the present invention prevents the second support bracket from interfering with the periphery when the mount bracket is rotated through the detailed configuration of the second support bracket, prevents a safety accident caused by the second support bracket, The status can be visually confirmed.

The present invention also overcomes the structural limitations associated with the longitudinal discharge of the pipe through the detailed construction of the rolling unit and the rolling unit, and it is possible to roll the pipe to simplify the discharge of the pipe.

In addition, according to the present invention, when the seating bracket is rotated through the arrangement structure of the rolling driving portion, the load generated in the eccentric rotation portion is reduced, the failure of the eccentric rotation portion is prevented, and the rotation of the seating bracket is smooth.

Further, the present invention can clarify the rotation and vibration action of the seating bracket through the elimination control unit, adjust the rotation and vibration operation of the seating bracket according to the pipe according to the pipe diameter, and maximize the removal efficiency of the residue according to the pipes .

Further, according to the present invention, the residue discharged from the mounting bracket or pipe can be easily recovered through the residue collecting unit, and the surface treated particles contained in the residue can be recycled.

In addition, the present invention can improve the blasting process speed by facilitating the blasting process of the pipe in the blast apparatus through the blast discharge unit and the additional configuration of the blast transfer unit, and preventing the pipe from stagnating during the transfer of the pipe .

Further, the present invention simplifies the transfer of the inter-transfer pipe of the pipe, and allows the pipe to smoothly open without external force, thereby improving the transfer speed of the pipe.

In addition, the present invention can precisely cut a pipe, which is transmitted through a cutting device in correspondence with a unit spool, to a unit piece, or bore a branch hole in a pipe or a unit piece.

In addition, the present invention clamps two mutually adjacent members for welding through a welding apparatus to coincide the concentricity between the two members, and maintains the connection state of the two members stably even without a separate fit-up member. The fixing force of the member can be improved.

The first expansion unit and the second expansion unit may have a cylindrical shape or the first expansion unit may have a cylindrical shape and the second expansion unit may have a truncated conical shape so that the connection between the pipe and the pipe, Connection of pipe and flange, connection of flange and tee as well as connection of pipe and elbow, connection of tee and elbow, connection of flange and elbow, connection of pipe and reducer, connection of tee and reducer, The connection of the reducer, the connection state between the elbow and the reducer can be stabilized, and the second piston and the second expansion unit can be prevented from interfering with the member.

Further, in welding the two members, the present invention can omit the back purging process, the two-piece fat-up process, and the soft-welding process, and can save the clean gas used for back purging, .

Further, according to the present invention, it is possible not only to easily supply the fluid with the hydraulic means of the expansion control unit through the detailed structure of the pipe support, but also to prevent friction with the support body inside the member and to smooth the slide movement of the pipe clamping device.

Further, according to the present invention, it is possible to smoothly reciprocate between the first piston and the second piston coaxially disposed by one hydraulic means through the detailed configuration of the expansion control unit, and the first expansion unit It is possible to prevent the concentricity between the two members from being changed while matching the concentricity of the first expansion unit and the second expansion unit when the diameters of the first expansion unit and the second expansion unit are expanded.

Further, since the clean gas is directly supplied to the welded portions of the two members through the additional structure of the clean unit, the welded portions of the two members can be prevented from being oxidized, the foreign substances can be removed from the welded portions of the two members, The bonding force between the two members can be improved.

Further, the present invention can stabilize the transfer of the clean gas through the detailed configuration of the clean unit, and prevent the clean gas from leaking.

In addition, the present invention simplifies the linking operation with the first piston through the detailed configuration of the first piston and the second piston, and makes the first rod member and the second rod member coaxial, The concentricity of the second expansion unit can be stably matched.

Further, the present invention can clarify the operation of the expansion control unit through the control unit, stably maintain the gripping force for clamping the two members, and can stably expand the first expansion unit and the second expansion unit .

Further, according to the present invention, it is possible to cool the welding portion of the hydraulic means or the two members of the expansion control unit through the cooling unit, and to perform the stable welding work in a high temperature or high temperature region.

Further, the present invention facilitates the movement of pipes or unit pieces between the devices through the pipeline transfer device, and can prevent worker safety accidents in response to process automation.

In addition, the present invention improves the precision of welding of the unit spool and the specification of the unit spool through the inspection apparatus and makes errors in the manufacturing process of the unit spool indicative of errors to prevent errors or defects in each unit have.

In addition, the present invention can systematically manage and store the unit spools corresponding to the length of the process line through the spool storage device, and the unit spools can be easily applied at the installation site of the unit spools.

In addition, the present invention can stabilize the transportation and rearrangement of the respective devices at the work site through the floor support unit, simplify the horizontal adjustment of each device, and simplify the management of each device at the work site.

In addition, the present invention stabilizes the bonding force between adjacent unit floor members through the detailed structure of the unit floor member, prevents the unit floor member from flowing, and can stably support the respective units.

In addition, the present invention can prevent breakage of the fitting protrusion during the transportation of the unit floor member through the detailed structure of the fitting portion, and stabilize the connection with the mounting portion when the unit floor members are assembled together.

Further, according to the present invention, the rotation of the fitting protrusion can be restricted through the rotation guide protrusion, and the rotation state of the fitting protrusion can be stabilized.

Further, according to the present invention, the fitting protrusion can be stably fixed in the fitting groove portion through the detailed configuration of the mounting portion, and the fitting and attachment of the fitting projection and the mounting portion can be facilitated.

Further, according to the present invention, it is possible to prevent the flow of the mounting rod portion and the flow of the fitting projection portion in a state where the unit bottom members are coupled to each other through the rod supporting groove portion.

Further, according to the present invention, the protrusion of the lifting lever portion can be prevented in a state where the unit floor members are coupled to each other through the lever insertion slot portion, and the lifting lever portion can be prevented from interfering with each device and the operator.

It is another object of the present invention to prevent the unit plate portions from interfering with each other or from spreading between the unit plate portions during the process of loading the unit floor member through the interference preventing groove portion and to improve the coupling force between the unit plate portions, It can be prevented from flowing.

1 is a block diagram showing a spool production system according to an embodiment of the present invention.
2 is a view showing a dispenser apparatus of a pipe according to an embodiment of the present invention.
3 is a view illustrating an operation state of a supply unit in a dispenser apparatus of a pipe according to an embodiment of the present invention.
4 is a view showing a first example of a dimension measuring unit in a dispenser apparatus of a pipe according to an embodiment of the present invention.
5 is a view showing an operation state of a first example of a dimension measuring unit in a dispenser apparatus of a pipe according to an embodiment of the present invention.
6 is a view showing a second example of the dimension measuring unit in the dispenser apparatus of the pipe according to the embodiment of the present invention.
7 is a view showing an operation state of a second example of the dimension measuring unit in the dispenser apparatus of the pipe according to the embodiment of the present invention.
FIG. 8 is a view showing an input delivery unit in a dispenser apparatus of a pipe according to an embodiment of the present invention.
FIG. 9 is a view illustrating an operation state of the input delivery unit in the dispenser apparatus of the pipe according to the embodiment of the present invention.
10 is a plan view showing a blast apparatus of a pipe according to an embodiment of the present invention.
11 is a side view showing a pipe residue removing unit in a blast apparatus of a pipe according to an embodiment of the present invention.
12 is a side view showing a state in which the pipe is inclined in the residue removing unit of the pipe shown in Fig.
13 is a view showing a moving state of a pipe after blasting in a blast apparatus of a pipe according to an embodiment of the present invention.
14 is a view showing a pipe clamping apparatus according to an embodiment of the present invention.
FIG. 15 is a cross-sectional view illustrating a coupling state of a first expansion unit in a pipe clamping apparatus according to an embodiment of the present invention. FIG.
16 is a partial cross-sectional view showing a detailed configuration of a gap supporting part in a pipe clamping device according to an embodiment of the present invention.
17 is a partial cross-sectional view showing a detailed configuration of an expansion control unit in a pipe clamping apparatus according to an embodiment of the present invention.
18 is a configuration diagram showing a detailed configuration of a cooling unit in a pipe clamping apparatus according to an embodiment of the present invention.
19 is a view showing a diameter expansion state of a first expansion unit in a pipe clamping apparatus according to an embodiment of the present invention.
FIG. 20 is a cross-sectional view of a first expansion unit in a pipe expanding state in a pipe clamping apparatus according to an embodiment of the present invention. FIG.
FIG. 21 is a view showing a diameter expansion state of a second expansion unit in a pipe clamping apparatus according to an embodiment of the present invention. FIG.
22 is a view showing a pipe clamping apparatus according to another embodiment of the present invention.
23 is a view showing a pipe and an elbow connected through a pipe clamping device according to another embodiment of the present invention.
24 is a view showing a unit floor member in a spool production system according to an embodiment of the present invention.
25 is a longitudinal sectional view showing a combined state of a unit floor member according to a first example in a spool production system according to an embodiment of the present invention.
26 is a longitudinal sectional view showing an operating state of the fitting portion and the mounting portion with respect to the fitting groove portion of the first example in the spool production system according to the embodiment of the present invention.
27 is a longitudinal sectional view showing a combined state of a unit floor member according to a second example in a spool production system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a conical clamp-based movable spool manufacturing system according to the present invention will be described with reference to the accompanying drawings. Here, the present invention is not limited or limited by the examples. Further, in describing the present invention, a detailed description of well-known functions or constructions may be omitted for clarity of the present invention.

1 to 27, a conical clamp-based movable spool manufacturing system according to an embodiment of the present invention includes a unit spool formed according to a disassembly of a pipe line indicated in a process piping instrumentation chart (P & ID, Piping and Instrumentation Diagram) It is a system for making.

A movable spool manufacturing system according to an embodiment of the present invention includes a dispenser device 100, a blast device 200, a cutting device 400, a welding device 500, a pipe transfer device 300, And may further include at least one of a bending apparatus 600, an inspection apparatus 700, a spool storage apparatus 800, and a bottom support unit 900. Thus, in the cone-type clamp-based movable spool production system according to the embodiment of the present invention, the above-described devices may be modularized into unit units, or each unit unit may be divided into unit modules to be modularized, So as to be detachable from the floor or floor supporting unit 900.

The dispenser device 100 separates and stores the pipes P to be received by materials and diameters. The dispenser apparatus 100 can discharge the stored pipes P individually. The dispenser apparatus 100 is described as a dispenser apparatus for pipes according to an embodiment of the present invention. Further, a pipe sizing unit according to an embodiment of the present invention is described as a dimension measuring unit 120 of a dispenser apparatus of a pipe according to an embodiment of the present invention.

The dispenser apparatus for pipes according to an embodiment of the present invention includes a supply unit 110 in which pipes P are sequentially supplied, a dispensing unit 180 in which pipes P are stored for each pipe diameter, And an input transfer unit 130 for moving the input transfer unit 130 in accordance with the dimension of the pipe P supported by the input transfer unit 130. The input transfer unit 130 transfers the input / A discharge transmission unit 150 including a lifting unit 140 and supporting a single pipe P transmitted from the dispensing unit 180 and a discharge pipe 150 connected to the pipe P to be supported by the discharge transfer unit 150 And a discharge lifting unit 160 for lifting and moving the discharge transmission unit 150 corresponding to the dimension.

Then, the pipe P is stored in the dispensing unit 180 having a plurality of stages in a state of being separated by the diameter of the pipe.

The supply unit 110 is provided with a dimension measurement unit (not shown) which is disposed on the lower side of the supply stopper 113 and calculates the dimension of the pipe P based on the deformation information generated by the contact with the pipe P 120 may be included.

The supply unit 110 may further include a pipe seating part 111 for supporting the pipe P and a supply stopper 113 for supporting the pipe P on the pipe seating part 111. [

The supply unit 110 may further include a separate supply unit 115 for individually discharging the pipes P supported by the supply stopper 113. It is possible to prevent two or more pipes P from being supplied to the input delivery unit 130 through the supply stopper 113 or the individual supply part 115. [

The pipe fitting part 111 is inclined downward from the input side of the pipe P toward the discharge side of the pipe P so that the sequential supply of the pipes P can be smoothly performed. The supply unit 110 may further include a delivery inclining part 112 which is inclined downward from the discharge side of the pipe seating part 111 toward the input delivery unit 130.

The supply stopper 113 temporarily stops the sequential supply of the pipes P to the dispensing unit 180 or temporarily stops the sequential discharge of the pipes P from the supply unit 110. The supply stopper 113 may be rotated or moved up and down along the moving direction of the pipe P with respect to the supply unit 110 through a separate stopper driving unit (not shown).

The individual feeder 115 is provided with a feed stopper rod 1151 provided in the feed unit 110 and a feed stopper rod 1151 provided in the feed unit 110 via a feed pivot shaft 1152 corresponding to the pipe seat part 111, And a feed pivot drive 1153 for pivoting the feed pivot axis 1152. [ The individual feeder 115 can vary the length of the feed stopper rod 1151 extending to the feed side of the pipe P with respect to the feed pivot axis 1152, It is possible to lift up only the single pipe P corresponding to the dimension and to prevent the supply of the following pipe P at the same time.

3, the supply stopper rod 1151 is pivotally moved about the supply pivot shaft 1152 in correspondence with the pipe P supported by the supply stopper 113, The supply stopper rod 1151 is inclined downward toward the input delivery unit 130 and the pipe supported by the supply stopper 113 is lifted away from the pipe seating part 111 and the pipe P Is hooked on the end of the supply stopper rod 1151 to block the supply of the subsequent pipe P. [ At this time, when the support of the pipe P is released by the supply stopper 113, the following pipe P is retained by the supply stopper rod 1151, (P) is rolled by the inclination of the supply stopper rod (1151) and is transferred to the input delivery unit (130). Here, the inclination angle of the supply stopper rod 1151 is equal to or larger than the inclination angle of the delivery inclined portion 112, so that the pipe P can be smoothly rolled. However, even if the inclination angle of the supply stopper rod 1151 is smaller than the inclination angle of the delivery inclined portion 112, the pipe P rolls, the moving speed of the pipe P becomes slow, The pipe P can be impacted by the step between the first and second portions 112 and 112.

The supply stopper 113 and the supply stopper rod 1151 are returned to their original positions and the pipe P which has been hooked to the supply stopper rod 1151 is returned to the supply stopper rod 1151, (Not shown). When the supply of the pipe P is subsequently required, the above-described operation is repeated.

The dimensional measurement unit 120 includes a dimensional measurement unit of the pipe according to an embodiment of the present invention.

In one embodiment of the present invention, the pipe sizing unit according to the first example measures the dimensions of the pipe P that is seated on the base in parallel with the elevating method and the rotating method. Here, the base may be constituted by the supply unit 110.

The pipe dimension measuring unit according to the first example includes a lifting rod portion 121a spaced apart from the pipe P and a support rod portion 121a rotatably coupled to the lifting rod portion 121a via the support rotary shaft 121. [ An initial position elastic part 123 for holding the initial position of the support rod part 122 by elastically supporting the support rod part 122 with respect to the lifting rod part 121a, A lifting and lowering driving part 124a for lifting and lowering the lifting rod part 121a when the free end of the supporting rod part 122 is in contact with or close to the pipe P And a lift controller 125a for calculating the dimension of the pipe P by using the rotation angle S of the support rod 122 and the rotation angle S of the support rod 122 as shown in Fig.

The support rod portion 122 includes a first support rod portion 1221 provided at one side with respect to the support rotation shaft 121 and a second support rod portion 1222 provided at the other side with respect to the support rotation shaft 121 ). At this time, the first support rod portion 1221 and the second support rod portion 1221 (refer to FIG. 7) are formed on the basis of the portion facing the pipe P (the engagement portion of the first support rod portion 1221 and the second support rod portion 1222) The free end portion of the first support rod portion 1221 and the free end portion of the second support rod portion 1222 are connected to each other by the pipe P Or the outer circumferential surface of the base material.

The support rod portion 122 includes a first support roller portion 1223 rotatably coupled to the free end of the first support rod portion 1221 so that the pipe P is in contact or in close contact therewith, And a second support roller portion 1224 rotatably coupled to the free end of the second support rod portion 1222 so as to be in contact or in contact with the second support rod portion 1222. [

The first support roller portion 1223 is rotatable at the free end of the first support rod portion 1221 via the first roller shaft. Further, the second supporting roller portion 1224 is rotatable at the free end of the second supporting rod portion 1222 via the second roller shaft. This allows the support rod portion 122 to smoothly slide on the pipe P when the rotation angle is changed while the support rod portion 122 is in contact with or close to the pipe P, It is possible to prevent the support rod portion 122 or the pipe P from being worn when the free end of the support rod portion 122 moves from the outer peripheral surface of the pipe P and to improve the measurement accuracy with respect to the rotation angle of the support rod portion 122, The life of the support rod portion 122 can be prolonged.

The initial elastic portion 123 is provided at a portion where the support rotary shaft 121 is engaged.

The elevation driving section 124a may include a cylinder for moving the lifting rod section 121a by hydraulic pressure or may include a motor for moving the lifting rod section 121a by hydraulic pressure or a power source.

The lifting and lowering control unit 125a includes a lifting distance measuring unit 1251a for measuring the lifting distance H of the lifting rod 121a and a lifting distance measuring unit 1251b for measuring the rotation angle S The dimensions of the pipe P are measured by using the measurement unit 1252a and the elevation distance H measured by the elevation distance measurement unit 1251a and the measurement S measured by the rotation angle measurement unit 1252a And a dimension calculating unit 1253 for calculating the dimension of the workpiece.

The lifting and lowering control unit 125a further includes a unit control unit 1255 for controlling an input unit for delivering the pipe P to the storage position of the pipe P corresponding to the dimension calculated by the dimension calculating unit 1253 . The charging unit may include at least one of the charging inlet 133 and the charging / discharging unit 140, which will be described later.

The lifting control unit 125a may further include a pipe matching unit 1254 for matching the dimension calculated by the dimension calculating unit 1253 with the storage position of the pipe P. [ Then, the unit controller 1255 controls the input unit so that the pipe P can be stably transferred from the pipe matching unit 1254 to the matched storage position.

When the elevation driving unit 124a is operated in a state where the supporting rod unit 122 is positioned with respect to the elevating rod unit 121a, the operation of the pipe dimension measuring apparatus according to the first example will be described. The free end portion of the first support rod portion 1221 and the free end portion of the second support rod portion 1222 are connected to the pipe P by the rotation of the support rod portion 122 with respect to the lifting rod portion 121a, As shown in Fig. Since the lifting rod portion 121a ascends toward the pipe P while being eccentric from the center of the pipe P, the free end portion of the first supporting rod portion 1221 and the free end portion of the second supporting rod portion 1222 All the free ends can stably come into contact with or come into close contact with the outer peripheral surface of the pipe P.

At this time, in the elevation control part 125a, the elevation distance H of the lifting rod part 121a is measured by the elevating distance measuring part 1251a, and the rotation angle measuring part 1252a measures (S, see Fig. 5). The dimension calculating unit 1253 calculates the dimension of the pipe P using the measured lift distance H and the rotation angle S (see FIG. 5).

When the pipe P is seated in the input transfer unit 130, the unit control unit 1255 controls the input and the lift unit 140 corresponding to the calculated dimension of the pipe P, The pipe P seated in the input delivery unit 130 is moved to the dispensing unit 180 by moving the corresponding pipe P seated on the dispensing unit 180 to the corresponding storage position of the dispensing unit 180, 180). ≪ / RTI >

Finally, when the pipe P seated in the input transfer unit 130 is transferred to the dispensing unit 180, each unit returns to the initial position, measures the dimension of the following pipe P, P can be transported and stored in the storage position of the dispensing unit 180. [

In an embodiment of the present invention, the pipe sizing unit according to the second example measures the dimensions of the pipe P seated on the base in parallel with the primary rotation method and the secondary rotation method. Here, the base may be constituted by the supply unit 110.

The pipe dimension measuring unit according to the second example includes a rotating rod portion 121b spaced apart from the pipe P and a supporting rod portion 121b rotatably coupled to the rotating rod portion 121b via the supporting rotating shaft 121. [ An initial position elastic part 123 for holding the initial position of the support rod part 122 by elastically supporting the support rod part 122 with respect to the rotation rod part 121b, A rotation drive part coupled to the rotation rod part 121b via the rotation rod part 121b to rotate the rotation rod part 121b; And a rotation control section 125b for calculating the dimension of the pipe P using the rotation angle S1 (see Fig. 7) and the second rotation angle S2 of the support rod section 122 (see Fig. 7) .

The support rod portion 122 includes a first support rod portion 1221 provided at one side with respect to the support rotation shaft 121 and a second support rod portion 1222 provided at the other side with respect to the support rotation shaft 121 ). At this time, the first support rod portion 1221 and the second support rod portion 1221 (refer to FIG. 7) are formed on the basis of the portion facing the pipe P (the engagement portion of the first support rod portion 1221 and the second support rod portion 1222) The free end portion of the first support rod portion 1221 and the free end portion of the second support rod portion 1222 are connected to each other by the pipe P Or the outer circumferential surface of the base material. In other words, the distance between the free end of the first support rod portion 1221 contacting or coming into contact with the outer circumferential surface of the pipe and the free end of the second support rod portion 1222 may be less than the minimum outer diameter of the incoming pipe.

The support rod portion 122 includes a first support roller portion 1223 rotatably coupled to the free end of the first support rod portion 1221 so that the pipe P is in contact or in close contact therewith, And a second support roller portion 1224 rotatably coupled to the free end of the second support rod portion 1222 so as to be in contact or in contact with the second support rod portion 1222. [

The first support roller portion 1223 is rotatable at the free end of the first support rod portion 1221 via the first roller shaft. Further, the second supporting roller portion 1224 is rotatable at the free end of the second supporting rod portion 1222 via the second roller shaft. This allows the support rod portion 122 to smoothly slide on the pipe P when the rotation angle is changed while the support rod portion 122 is in contact with or close to the pipe P, The support rod portion 122 or the pipe P is prevented from being worn out when the free end of the support rod portion 122 is moved from the surface of the pipe P and the measurement accuracy with respect to the rotation angle of the support rod portion 122 is improved, The life of the support rod portion 122 can be prolonged.

The initial elastic portion 123 is provided at a portion where the support rotary shaft 121 is engaged.

The rotation drive unit 124b may include a motor that rotates the rotation rod unit 121b by an oil pressure or a power source.

The rotation control section 125b includes a first rotation angle measurement section 1251b for measuring the first rotation angle S1 of the rotation rod section 121b (see Fig. 7), a second rotation angle measurement section 1251b (See Fig. 7) measured by the first rotational angle measuring unit 1251b and the second rotational angle measuring unit 1252b measuring the second rotational angle measured by the second rotational angle measuring unit 1251b, And a dimension calculating section 1253 for calculating the dimension of the pipe P by using the second rotation angle S2 (see Fig. 7) measured by the second rotation angle sensor 1252b.

The rotation control unit 125b further includes a unit control unit 1255 for controlling an input unit for transferring the pipe P to the storage position of the pipe P corresponding to the dimension calculated by the dimension calculation unit 1253 . The charging unit may include at least one of the charging inlet 133 and the charging / discharging unit 140, which will be described later.

The rotation control unit 125b may further include a pipe matching unit 1254 for matching the dimension calculated by the dimension calculation unit 1253 with the storage position of the pipe P. [ Then, the unit controller 1255 controls the input unit so that the pipe P can be stably transferred from the pipe matching unit 1254 to the matched storage position.

When the rotation driving part 124b is operated in a state where the support rod part 122 is positioned with respect to the rotation rod part 121b, the rotation rod part 121b And the free end of the first support rod portion 1221 and the free end of the second support rod portion 1222 are connected to each other by the rotation of the support rod portion 122 with respect to the rotation rod portion 121b, (P).

At this time, the rotation control unit 125b measures the first rotation angle S1 (see Fig. 7) of the rotation rod portion 121b by the first rotation angle measurement unit 1251b and the second rotation angle measurement unit 1252b measures the first rotation angle The second rotation angle S2 (see Fig. 7) of the support rod portion 122 is measured. The dimension calculating unit 1253 calculates the dimension of the pipe P using the measured first rotation angle S1 (see Fig. 7) and the second rotation angle S2 (see Fig. 7).

When the pipe P is seated in the input transfer unit 130, the unit control unit 1255 controls the input and the lift unit 140 corresponding to the calculated dimension of the pipe P, The pipe P seated in the input delivery unit 130 is moved to the dispensing unit 180 by moving the corresponding pipe P seated on the dispensing unit 180 to the corresponding storage position of the dispensing unit 180, 180) in the storage location.

Finally, when the pipe P seated in the input transfer unit 130 is transferred to the dispensing unit 180, each unit returns to the initial position, measures the dimension of the following pipe P, P can be transported and stored in the storage position of the dispensing unit 180. [

The input transfer unit 130 includes a loading and unloading unit 131 that is moved up and down along the height direction of the dispensing unit 180 in accordance with the operation of the loading and unloading unit 140 in a state where the pipe P is seated, A feed support portion 132 coupled to the discharge side of the feed portion 131 for supporting the pipe P and a feed support portion 132 for discharging the pipe P seated in the feed lift portion 131 And an input driving unit 133 for moving the input supporting unit 132 up and down.

Although not shown, the input transmitting unit 130 may include the above-described dimensional measurement unit 120. Here, the base may be configured as the input delivery unit 130. As a result, the above-described dimensional measurement unit may be included in at least one of the supply unit 110 and the input transfer unit 130.

The first loading seat 135 may be provided on the upper surface of the loading / The first input seating part 135 is formed by a pipe P which is seated on the input lifting part 131 and is inclined downward from the input side of the input lifting part 131 toward the discharge side of the input lifting part 131, Unit 180 so that it is smoothly transferred.

7, the input supporting portion 132 is rotatably coupled to the input elevating portion 131 via the input driving shaft 137 when the input driving portion 133 rotates the input supporting portion 132. As shown in FIG. At this time, the input transfer unit 130 may further include an input bracket 134. One side of the closing bracket 134 is rotatably coupled to the loading and elevating part 131 via the driving driving shaft 137 and the other side of the closing bracket 134 is fixed to the loading supporting part 132. Here, the second loading seating part 136 may be provided on the surface of the insertion support part 132 where the pipe P is supported. The second input seating part 136 is located on the exhaust side of the pipe P from the input side of the pipe P when the input supporting part 132 is rotated to connect the input elevating part 131 and the dispensing unit 180 So as to form a downward slope.

The input supporting portion 132 serves as a bridge connecting the loading elevating portion 131 and the dispensing unit 180 when the loading opening portion 133 rotates the loading supporting portion 132, The gap between the dispensing units 180 can be secured. In the state in which the insertion support portion 132 is rotated, the second insertion seat portion 136 is inclined downward from the insertion side of the insertion support portion 132 toward the discharge side of the insertion support portion like the first insertion seat portion 135 So that the pipe P seated on the loading and elevating portion 131 is smoothly transferred to the dispensing unit 180.

When the input driving shaft 133 moves up and down the input supporting portion 132, the input supporting portion 132 can be operated like the above-described elevating and lowering movement of the feeding stopper 113. [

It is sufficient that the loading and unloading unit 140 can move the input delivery unit 130 to the corresponding storage position in accordance with the dimension of the pipe P. [

The discharge transfer unit 150 may have the same configuration as the input transfer unit 130. [ More specifically, the discharge transmission unit 150 includes a discharge elevating portion that is moved up and down along the height direction of the dispensing unit 180 in accordance with the operation of the discharge elevating and lowering unit 160 in a state where the pipe P is seated, A discharge support portion coupled to the discharge side of the discharge portion for supporting the pipe P and a discharge outlet portion for rotating the discharge support portion or lifting and moving the discharge support portion for discharging the pipe P seated in the discharge elevation portion .

And a first discharge seat portion may be provided on an upper surface of the discharge elevating portion. The first discharge seat portion is inclined downward from the input side of the discharge elevating portion toward the discharge side of the discharge elevating portion so that the pipe P seated on the discharge elevating portion is smoothly transferred to the pipe transfer unit 170.

When the discharge port portion rotates the discharge support portion, the discharge support portion is rotatably coupled to the discharge elevation portion via the discharge drive shaft, as in the case where the discharge drive portion 133 rotates the discharge support portion 132. [ At this time, the discharge transmission unit 150 may further include a discharge bracket. One side of the discharge bracket is rotatably coupled to the discharge elevating portion via the discharge driving shaft, and the other side of the discharge bracket is fixed to the discharge supporting portion. Here, a second discharge seat may be provided on a surface of the discharge support portion where the pipe P is supported. The second discharge seat portion is inclined downward from the input side of the pipe P toward the discharge side of the pipe P when the discharge support portion is rotated to connect the discharge elevation portion and the pipe transfer unit 170. [

When the discharge port portion rotates the discharge supporting portion, the discharge supporting portion serves as a bridge connecting the discharge elevating portion and the pipe transfer unit 170, so that the interval between the discharge elevating portion and the pipe transfer unit 170 can be secured. Further, in the state that the discharge support portion is rotated, the second discharge seat portion has a downward inclination from the input side of the discharge support portion toward the discharge side of the discharge support portion like the first discharge seat portion, So that it is smoothly transferred to the transfer unit 170.

When the outlet opening portion moves up and down the discharge supporting portion, the discharge supporting portion can be operated as the above-described lifting / lowering movement of the supply stopper 113. [

It is sufficient that the discharge lifting unit 160 can move the discharge transmission unit 150 to the storage position corresponding to the dimension of the pipe P.

The dispensing unit 180 is configured to have a multi-stage structure along the height direction so that the pipe P for each pipe diameter is accommodated individually corresponding to the pipe P dimension. The bottom where the pipe P is seated in the dispensing unit 180 so that the pipe P is sequentially stored and supported at the discharge side of the pipe P is discharged from the discharge side of the pipe P Downward inclination can be achieved.

The dispensing unit 180 is provided with a support stopper 181 for supporting the pipe P at the discharge side of the pipe P and a separate discharge port 181 for discharging the pipe P supported by the support stopper 181, 182 may be further included.

The support stopper 181 may have the same configuration as the supply stopper 113 described above. More detail. The support stoppers 181 may be individually provided on the discharge side of the pipes P corresponding to the respective ends of the dispensing unit 180. The support stopper 181 temporarily stops the discharge of the pipes P from the dispensing unit 180 to prevent two or more pipes P from being supplied to the discharge transmission unit 150. [ The support stopper 181 may be rotated or moved up and down along the moving direction of the pipe P with respect to the dispensing unit 180 via a separate stopper driving unit (not shown).

The individual discharge portion 182 may have the same configuration as the individual supply portion 115 described above. The individual discharge portions 182 can be individually installed on the discharge side of the pipe P corresponding to the respective ends of the dispensing unit 180. The individual discharge portion 182 has a discharge stopper rod provided in the dispensing unit 180 via a discharge pivot shaft corresponding to the bottom end of the corresponding end of the dispensing unit 180 and a discharge stopper rod provided in the discharge pivot axis for pivotal movement of the discharge stopper rod. And may include a discharge pivot drive for pivoting motion. The individual discharge portion 182 varies the length of the discharge stopper rod extending to the input side of the pipe P with respect to the discharge pivot axis so that the dispensing unit 180 (corresponding to the dimension of the pipe P supported on the discharge stopper) , It is possible to lift up only the single pipe P and to prevent the supply of the following pipe P at the same time.

The operation of the individual discharging unit 182 is operated in the same manner as the operation of the individual supplying unit 115 described above. More specifically, when the discharge stopper rod pivots about the discharge pivot axis in correspondence with the pipe P supported by the support stopper, the discharge stopper rod is inclined downward toward the discharge transmission unit 150, The pipe P is lifted away from the bottom of the corresponding end of the dispensing unit 180 and the succeeding pipe P is hooked on the end of the discharge stopper rod to block the discharge of the following pipe P . At this time, when the support of the pipe P is released by the support stopper 181, the succeeding pipe P is kept hooked on the discharge stopper rod, and the pipe P supported by the support stopper 181, Is rolled by the inclination of the discharge stopper rod and is transferred to the discharge transmission unit 150.

When the pipe P is supplied to the discharge transfer unit 150, the support stopper 181 and the discharge stopper rod return to their original positions, and the pipe P which has been hooked on the discharge stopper rod is supported by the support stopper 181 . When the discharge of the pipe P is subsequently required, the above-described operation is repeated.

Unexplained reference numeral 170 is a pipe transfer unit for transferring the pipe P delivered by the discharge transfer unit 150 to the next process. The pipe transfer unit 170 may be constituted by the axial transfer unit 310 among the pipe transfer units 300.

The dispenser apparatus 100 is modularized for each unit or each unit is divided into unit modules to be modularized so that the dispenser apparatus 100 can be carried and rearranged and can be detached and attached to the floor or floor support unit 900.

The blasting device 200 performs a blasting process on the pipe P delivered from the dispenser device 100. The blast apparatus 200 will be described as a blast apparatus for pipes according to an embodiment of the present invention. Further, the pipe residue removal unit according to an embodiment of the present invention is described as a residue removal unit 250 in a blast apparatus of a pipe according to an embodiment of the present invention.

The blast apparatus for a pipe according to an embodiment of the present invention includes a blasting unit 210 for performing a blasting process on a pipe P supplied along a longitudinal direction, a blasting unit 210 disposed on a discharge side of the blasting unit 210, And a tilting of the pipe P discharged from the pipe (210).

Thereby, the remaining residue of the pipe P can be dropped by at least one of the impact caused by the operation of the residue removing unit 250 and the inclination of the pipe P. [

The apparatus for blasting pipes according to an embodiment of the present invention includes a blasting input unit 220 disposed at the input side of the blasting unit 210 for inputting the pipe P into the blasting unit 210, And a blast discharge unit (230) supporting the pipe (P) discharged from the discharge pipe (210).

The blast apparatus of the pipe according to an embodiment of the present invention may further include a blast transfer unit 240 for transferring the pipe P supported by the blast discharge unit 230 to the residue removal unit 250 have.

A pipe P is longitudinally inserted into the blasting unit 210 and a blasting input unit 220 and a blasting discharge unit 230 are capable of transporting the pipe P in the longitudinal direction.

The blasting unit 210 includes a blasting cavity 211 for spraying the surface treatment particles on the pipe P to remove foreign matter including rust, scale and blackness on the surface of the pipe P, The blasting control unit 212 may control the operation of the blasting unit 211 corresponding to the diameter of the pipe P, the material of the pipe P, the dimensions of the pipe P, and the like. At this time, residues including surface treated particles, foreign matter separated from the pipe (P), etc. may be introduced into the interior of the pipe (P) at the end of the pipe (P).

The blasting input unit 220 includes an input table 221 disposed at the input side of the blasting unit 210, an input roller unit 222 rotatably coupled to the input table 221, And an input roller driving unit 223 that rotates the input roller unit 222 to rotate the input roller unit 222.

Here, the loading roller portion 222 is disposed on the loading table 221 in such a manner that two or more of them are spaced apart from each other. In addition, since the center of the insertion roller portion 222 is inclined toward the center in the longitudinal direction at both ends thereof, the central portion of the insertion roller portion 222 is concavely recessed. Thus, in the process of conveying the pipe P, It can be prevented from being detached from the main body. The longitudinal direction of the loading roller portion 222 is perpendicular or inclined to the longitudinal direction of the pipe P and the center portion of the loading roller portion 222 is disposed in a straight line, It is possible to prevent the pipe P from being separated from the input roller portion 222 even if the pipe P rolls while the pipe P is being conveyed as well as the pipe P is positioned.

The blast discharge unit 230 includes a discharge table 231 disposed at the discharge side of the blasting unit 210, a discharge roller 232 rotatably coupled to the discharge table 231, And a discharge roller driving unit 233 for rotating the discharge roller unit 232 for the discharge roller unit 232.

Here, the discharge roller portions 232 are disposed in the discharge table 231 in such a manner that two or more discharge roller portions 232 are mutually spaced. The discharge roller portion 232 is inclined toward the center in the longitudinal direction at both ends so that the central portion is concavely recessed so that the pipe P is rolled in the course of conveyance of the pipe P and the discharge roller portion 232 It can be prevented from being detached from the main body. The longitudinal direction of the discharge roller portion 232 is perpendicular or inclined to the longitudinal direction of the pipe P and the center portion of the discharge roller portion 232 is disposed in a straight line, It is possible to prevent the pipe P from being detached from the discharge roller portion 232 even if the pipe P rolls while the pipe P is being transported as well as the pipe P is positioned.

The blasting transmission unit 240 includes a blast pivot rod 241 that is pivotable via a blast pivot axis 242, a blast spacing member 243 that separates the blasting pivot rod 241 from the floor, And a blast pivot drive 245 for pivotally moving the pivot 241.

Here, the blasting spacing member 243 is coupled to the blasting discharge unit 230 so that the blasting discharge unit 230 and the blasting transfer unit 240 can be integrated. Further, the blasting spacing member 243 may be supported on the floor so that the blasting discharge unit 230 and the blasting transfer unit 240 may be separately constructed.

The residue removal unit 250 may include a pipe residue removal unit according to one embodiment of the present invention.

The residue removing unit of the pipe according to an embodiment of the present invention removes the residue including the surface treatment particles remaining in the pipe P which is transferred via the blasting process.

The residue removing unit of the pipe P according to the embodiment of the present invention includes a seating bracket 251 in which the pipe P is seated in a lengthwise direction corresponding to the longitudinal direction of the pipe P, A first support bracket 252 which is spaced apart from the first support bracket 251 and is coupled to the mount bracket 251 via an eccentric rotation shaft 2532 disposed eccentrically to one side of the pipe P, And a second bracket 252 which is spaced apart from the first support bracket 252 and spaced apart from the bottom of the seating bracket 251 and connected to the seating bracket 251, And a second support bracket 254 detachable from the floor in the state of FIG.

Then, the impact due to the operation of the bracket rotating unit 253 or the inclination of the mounting bracket 251 causes the residue remaining on the mounting bracket 251 or the pipe P to fall, Can be removed.

The seating bracket 251 includes a first seating bracket portion 2511 inclined to support one side of the pipe P with respect to the pipe P seated on the seating bracket 251, A second mounting bracket portion 2512 inclined to support the other side of the pipe P with respect to the pipe P to be connected to the pipe P, And a pipe support portion 2514 coupled to at least one of the seating bracket portions 2512. The first seating bracket 251 and the second seating bracket 251 may be separate or integral. The first seating bracket part 2511 may be provided with a bracket passing groove 2511a through which the blasting pivot rod 241 passes according to the pivoting motion of the blasting pivot rod 241. [

The second inclination angle S2 of the second mounting bracket 251 (see Fig. 13) is equal to the first inclination angle S1 of the first mounting bracket 251 (see Fig. 13) The second mounting bracket 251 stops the pipe P which is rolled through the blast transmission unit 240 so that the pipe P is prevented from flowing to the seating bracket 251 while reducing the flow of the pipe P. .

The seating bracket 251 is provided with a rod bracket portion 2510 to which at least one of the first seating bracket portion 2511 and the second seating bracket portion 2512 on both sides of the pipe P is coupled, (2513). The rod bracket 2513 may be integrally formed with the first and second seating brackets 2511 and 2512 or may be integrally formed with only the second seating bracket 2512. A rolling axis 2563, which will be described later, may be fixed to the rod bracket portion 2513.

The pipe support portion 2514 includes a support extension portion 2515 extending from the seating bracket 251, an extension fork portion 2516 extending from the support extension portion 2515 in a mutually separated state, an extension fork portion 2516, A bending portion 2517 that supports the end portion of the pipe P when the pipe P is bent at the bending portion 2511b. The pipe supporting portion 2514 includes a support extending portion 2515 extending from the mounting bracket 251 and a bending portion 2515 formed in a state of being separated from the support extending portion 2515 to support the end portion of the pipe P, (2517).

As another example, the pipe support portion 2514 includes a support extension portion 2515 extending from the seating bracket 251 and a support bend portion (not shown in the figure) 2515 formed in the support extension portion 2515, (Not shown) through which the residue passes, at least at the support bend of the support extension 2515 and the support bend (not shown, see the bended bend 2517) .

As another example, the pipe support portion 2514 may be provided on at least one of the first and second seating bracket portions 2511 and 2512. [ The pipe support portions 2514 are spaced from each other when the pipe support portions 2514 are disposed in the first and second placement bracket portions 2511 and 2512 so that the residues pass through the pipe support portions 2514 .

The bracket rotating unit 253 includes at least one of an eccentric rotation portion 2531 for rotating the eccentric rotary shaft 2532 and an eccentric rotary portion 2533 for pushing or pulling the seating bracket 251 at a portion spaced apart from the eccentric rotary shaft 2532 And may include any one of them.

The eccentric reciprocating unit 2533 is spaced apart from the eccentric rotary shaft 2532 with respect to the eccentric rotary shaft 2532 and pulls one side of the seating bracket 251 to tilt the seating bracket 251. The eccentric reciprocating unit 2533 is spaced apart from the eccentric rotary shaft 2532 with respect to the eccentric rotary shaft 2532 so as to push the other side of the seating bracket 251 to tilt the seating bracket 251.

For example, when the mounting bracket 251 is tilted, the inclination angle S of the pipe P (see FIG. 12) may be 30 degrees or more and 60 degrees or less. As another example, when the mounting bracket 251 is inclined, the inclination angle S of the pipe P (refer to FIG. 12) can be set to 40 degrees or more and 60 degrees or less. As another example, when the mounting bracket 251 is inclined, the inclination angle S of the pipe P (refer to FIG. 12) may be set to be not less than 40 degrees and not more than 50 degrees. When the inclination angle S of the pipe P (see Fig. 12) is smaller than the permissible range, it is necessary to delay the falling of the residue and take a time unnecessary for removing the residue, The pipe supporting portion 2514 formed at the end of the mounting bracket 251 may be damaged by contact with the floor or the pipe supporting portion 2514 may be brought close to the first supporting bracket 252, (257). ≪ / RTI > However, if the inclination angle (S, see Fig. 12) of the pipe P falls within the permissible range, the falling of the residue is smooth, the time required for removing the residue is reduced and the pipe supporting portion 2514 is prevented from being damaged And the residue can be stably recovered.

When the bracket rotation unit 253 includes both the eccentric rotation portion 2531 and the eccentric rotation portion 2533, the eccentric rotation portion 2533 is rotated about the eccentric rotation axis 2532 A first eccentric reciprocating portion 2534 which pushes or pulls the seating bracket 251 in conjunction with the eccentric rotation portion 2531 and a second eccentric reciprocating portion 2534 which is eccentric from a portion of the eccentric rotary shaft 2532, And a second eccentric reciprocating unit 2535 for pushing or pulling the seating bracket 251 in conjunction with the rotation unit 2531. [

The first eccentric reciprocating unit 2534 includes a first piston unit rotatably coupled to a portion of the eccentric rotary shaft 2532 spaced apart from the eccentric rotary shaft 2532 and a second piston unit coupled to the first supporting bracket 252 And a first cylinder portion rotatably coupled to reciprocate the first piston portion.

The second eccentric reciprocating portion 2535 includes a second piston portion rotatably coupled to the other portion of the eccentric rotary shaft 2532 spaced apart from the eccentric rotary shaft 2532 with respect to the eccentric rotary shaft 2532, And a second cylinder portion rotatably coupled to reciprocate the second piston portion.

The second support bracket 254 includes a fixed bracket portion 2541 coupled to the seating bracket 251 and a pivot bracket portion 2543 rotatably coupled to the fixed bracket portion 2541 via the pivot shaft 2542. [ . ≪ / RTI > The fixing bracket 2541 is rotatably coupled to the seating bracket 251 via a rolling shaft 2563 and is engaged with a rolling bracket 2561 to be described later, 2 Positioning bracket 251 is stably pivoted.

The pipe residue removing unit according to an embodiment of the present invention may further include a vibration unit 255 that vibrates the seating bracket 251 in a state where the seating bracket 251 is rotated.

Even if there is no impact due to the operation of the bracket rotating unit 253, the remaining residue on the mounting bracket 251 or the pipe P drops due to the vibration of the vibration unit 255, Water can be removed.

The pipe residue removing unit according to an embodiment of the present invention further includes a rolling unit 256 for rolling the seating bracket 251 based on the longitudinal direction of the pipe P seated on the seating bracket 251 can do.

The rolling unit 256 includes a rolling bracket portion 2561 to which the seating bracket 251 is rolled so as to be capable of rolling motion via a rolling axis 2563, (Not shown). The first supporting bracket 252 and the second supporting bracket 254 are coupled to the rolling bracket 2561 to restrict the flow of the residual water removing unit 250 and the rolling motion of the mounting bracket 251 You can do it smoothly. The rolling driver 2562 is disposed on the left side of the eccentric rotation axis 2532 with respect to the eccentric rotation axis 2532 in the lengthwise direction of the pipe P shown in Figs. The load generated in the eccentric rotation portion 2531 when the seating bracket 251 rotates can be reduced and the failure of the eccentric rotation portion 2531 can be prevented.

The pipe residue removal unit according to an embodiment of the present invention may further include a removal control unit 258 for controlling the operation of the bracket rotation unit 253 and the operation of the vibration unit 255. [ Then, the elimination control unit 258 can control the operation of the bracket rotating unit 253 to adjust the inclination of the pipe P. [ The removal control unit 258 operates the vibration unit 255 in the process of tilting the mounting bracket 251 in conjunction with the operation of the bracket rotation unit 253 or the state in which the mounting bracket 251 is fully inclined The vibration unit 255 can be operated. In addition, the elimination control unit 258 can also control the operation time of the vibration unit 255. [

The residue removing unit of the pipe according to an embodiment of the present invention may further include a residue collecting unit 257 in which the residue separated from the seating bracket 251 or the pipe P is collected. The residual water collecting unit 257 is disposed on the left side of the eccentric rotary shaft 2532 with respect to the eccentric rotary shaft 2532 in the longitudinal direction of the pipe P in FIGS. (Corresponding to the end portion of the main body). The residue collecting unit 257 includes a particle separating unit (not shown) for separating the surface treated particles from the residue, and a particle collecting unit (not shown) for transmitting the separated surface treated particles to the blasting unit 210 . ≪ / RTI > The separated surface treated particles are transferred to the blasting unit 210 through the particle collecting line, so that the surface treated particles separated from the residue can be recycled.

Hereinafter, the horizontal direction moving operation of the pipe will be described with reference to FIG.

When the blast pivot drive 245 is operated in the normal direction with the pipe P positioned in the blast discharge unit 230, the blast pivot rod 241 is moved to the blast discharge unit 230 as it is inclined at a predetermined angle. And the pipe P is caused to roll along the blast pivot rod 241 by the predetermined angle and the load of the pipe P to move to the residue removal unit 250. [ At this time, since the blast pivot rod 241 passes through the bracket passing groove 2511a at the discharge side end, it does not interfere with the seating bracket 251. [

When the blast pivot drive 245 is operated in the opposite direction, the blast pivot rod 241 is tilted to the home position, and when the pipe P moves in the blast discharge unit 230 in the longitudinal direction, .

When the pipe P is returned to the horizontal state after the residues are separated from the seating bracket 251 or the pipe P by the residue removing unit 250, The bracket 251 rolls. Then, the pipe P is rolled by the load and the inclination of the second seating bracket portion 2512, and is transferred to the next process after leaving the residue removing unit 250. Since the rolling axis 2563 is rotatable by the first support bracket 252, the second support bracket 254 and the rolling bracket 2561, the rolling motion of the seating bracket 251 can be stabilized.

The blast apparatus 200 is modularized for each unit or each unit is divided into unit modules to be modularized so that the blast apparatus 200 can be transported and rearranged and detachably attached to the floor or floor support unit 900.

The cutting device 400 cuts the pipe P delivered from the blast device 200 into a unit piece corresponding to the unit spool or punctures a branch hole in the pipe P or a unit piece. The cutting apparatus 400 may include at least one of a vertical cutting unit 410, a warp cutting unit 420, a flame cutting unit 430, and a fluid cutting unit (not shown).

The vertical cutting unit 410 cuts the pipe P into unit pieces using a cutting tool to form a cross section perpendicular to the longitudinal direction of the pipe P. [ The vertical cutting unit 410 includes a vertical cutting unit 411 that includes a cutting tool and operates the cutting tool in correspondence with predetermined cutting information, a vertical supporting unit 412 that supports the pipe P to be transferred, 412 to prevent the movement of the pipe P. In this case, Here, the pipe P is supported by the vertical support portion 412 along the longitudinal direction, and the vertical support portion 412 can move the pipe P in the longitudinal direction. The vertical cutting unit 410 can stably cut the pipe P supported by the vertical supporting portion 412 to a unit piece so that a cross section perpendicular to the longitudinal direction of the pipe P is formed at one end or both ends of the unit piece . At least one of the vertical cutting portion 411 and the vertical supporting portion 412 can fix the pipe P in correspondence with the predetermined cutting information. The vertical cutting portion 411 can rotate the cutting tool along the periphery of the pipe P in response to the operation of the cutting tool. The vertical support portion 412 can rotate the pipe P in response to the operation of the vertical cut portion 411.

The slant cutting unit 420 cuts the pipe P into unit pieces using a cutting tool so as to form an inclined cross section in the longitudinal direction of the pipe P. [ The slant cutting unit 420 includes a slant cutting portion 421 that includes a cutting tool and operates the cutting tool in correspondence with predetermined cutting information, a slant support portion 422 to which the pipe P to be delivered is supported, 422 to prevent the movement of the pipe P transmitted from the slant stopper 423. Here, the pipe P is supported on the inclined support portion 422 along the longitudinal direction, and the inclined support portion 422 can move the pipe P in the longitudinal direction. The inclined cutting unit 420 can stably cut the pipe P supported on the inclined support portion 422 by a unit piece so that a section inclined in the longitudinal direction of the pipe P is formed at one end or both ends of the unit piece . At least one of the inclined cut portion 421 and the inclined portion 422 can fix the pipe P in correspondence with predetermined cutting information. The slant cut portion 421 can rotate the cutting tool along the circumference of the pipe P in response to the operation of the cutting tool. The inclined support portion 422 can rotate the pipe P in accordance with the operation of the inclined cut portion 421. [

The inclined cutting portion 421 is formed at one end or both ends of the unit piece by adjusting the inclination angle between the cutting tool and the pipe P so that a cross section perpendicular to the longitudinal direction of the pipe P is formed like the vertical cutting unit 410 .

The flame cutting unit 430 cuts the pipe P into a unit piece using a flame or punctures a branch hole in the pipe P or a unit piece using a flame. The flame cutting unit 430 includes a flame cutting unit 431 for generating a flame corresponding to predetermined cutting information, a flame supporting unit 432 for supporting the pipe P to be delivered, And a flame stopper 433 for blocking the movement of the substrate P. Here, the flame support part 432 is long supported along the longitudinal direction of the pipe P, and the flame support part 432 can move the pipe P in the longitudinal direction. Then, the flame cutting unit 430 can cut the pipe P supported by the flame supporting part 432 into unit pieces, or can bore the branch hole into the pipe P or the unit piece. At least one of the flame cutting portion 431 and the flame supporting portion 432 can fix the pipe P in correspondence with the predetermined cutting information. The flame cutting portion 431 can adjust the position of the flame along the circumference of the pipe P. [ The flame support part 432 can rotate the pipe P in accordance with the operation of the flame cutting part 431. [

The flame cutting unit 430 may be formed at one end or at both ends of the unit piece such that a vertical section perpendicular to the longitudinal direction of the pipe P is formed like the vertical cutting unit 410 as the position of the flame is adjusted in the pipe P, A slanting section in the longitudinal direction of the pipe may be formed as in the case of the slant cutting unit 420, or the branch hole may be easily formed.

The fluid cutting unit (not shown) cuts the pipe P into a unit piece by using a high-pressure fluid or punctures the branch hole by using a high-pressure fluid. A fluid cutting unit (not shown) includes a fluid ejecting unit (not shown) for ejecting a high-pressure fluid corresponding to predetermined cutting information, a fluid supporting unit (not shown) for supporting a pipe P to be conveyed, And a fluid stopper (stopper) for stopping the movement of the pipe P transmitted from the pipe (not shown). Here, the fluid supporting portion (not shown) is supported long along the longitudinal direction of the pipe P, and the fluid supporting portion (not shown) can move the pipe P in the longitudinal direction. Then, the fluid cutting unit (not shown) can cut the pipe P supported by the fluid supporting portion (not shown) into a unit piece or puncture the branch hole in the pipe P or the unit piece. At least one of the fluid cutting portion (not shown) and the fluid supporting portion (not shown) can fix the pipe P in the fluid supporting portion (not shown) corresponding to the predetermined cutting information. The fluid cutting portion (not shown) can adjust the injection position of the fluid along the periphery of the pipe P. The fluid supporting portion (not shown) can rotate the pipe P in response to the operation of the fluid cutting portion (not shown).

A fluid cutting unit (not shown) forms a cross section perpendicular to the longitudinal direction of the pipe P, such as the vertical cutting unit 410, at one end or both ends of the unit piece as the injection position of the fluid is adjusted in the pipe P Or a section that is inclined in the longitudinal direction of the pipe such as the slant cutting unit 420 may be formed, or the branch hole may be easily formed.

The fluid cutting unit (not shown) may further include a fluid recovery unit (not shown) for recovering the fluid ejected from the pipe or the unit piece. The fluid cutting unit (not shown) may further include a drying unit (not shown) for drying the fluid ejected from the pipe or the unit piece.

The cutting apparatus 400 is modularized for each unit or each unit is separated into unit modules so as to be modularized so as to be able to be transported and rearranged and to be removably attached to the floor or floor support unit 900.

The welding apparatus 500 connects the pipe P with a unit piece, connects two or more unit pieces, connects unit pieces and fittings, or connects a pipe, a unit piece, and a fitting to a branch hole .

The welding apparatus 500 includes a first welding unit 500a for connecting a pipe P with a unit piece, connecting two or more unit pieces or connecting pipes P and fittings, or connecting unit pieces and fittings, And a second welding unit 500b connecting the pipe P and the fittings or connecting the unit pieces and the fittings.

The first welding unit 500a includes a first seating unit 581a on which a hollow first member M1 including a pipe P or a unit piece is supported and a second seating unit 581b supported on the first seating unit 581a A second seating unit 582a supporting a hollow second member M2 including a pipe P or a unit piece corresponding to the member M1 and a second seating unit 582b supporting the first member M1 and the second member M2, A pipe welding unit 570a for welding the welded portion of the first member M1 and the second member M2 to each other (a portion where the end portion of the first member M1 and the end portion of the second member M2 face each other) And a first clamping unit 580a for grasping and fixing the first member M1 and the second member M2 so that the concentricity of the first member M1 and the second member M2 coincide with each other. The second seating unit 582a is disposed between the cutting device 400 and the first seating unit 581a or disposed between the pipeline conveying apparatus 300 and the first seating unit 581a to transmit the first member M1 To the first seating unit 581a. The first clamping unit 580a is provided corresponding to the first seating unit 581a.

Here, the first seating unit 581a and the second seating unit 582a can move the pipe P or the unit pieces in the longitudinal direction while being supported by the floor or floor support unit 900, respectively. In other words, the first seating unit 581a and the second seating unit 582a can each apply a conveyor system that moves the pipe P or the unit pieces according to the rotation of the rollers.

The first welding unit 500a includes a first driving unit 530a for turning the pipe welding unit 570a on the basis of the first clamping unit 580a in correspondence with the welding portions of the first member M1 and the second member M2, (583a).

In addition, the pipe welding unit 570a may include a welding unit 570 according to one embodiment of the present invention. Further, the first clamping unit 580a may include a pipe clamping device according to an embodiment of the present invention. Further, the first clamping unit 580a may include a pipe clamping device according to another embodiment of the present invention. Further, the first drive unit 583a may include a swivel drive unit 573 included in the welding unit 570 according to an embodiment of the present invention.

The second welding unit 500b includes a support unit 581b on which a hollow first member M1 including a pipe P or a unit piece is supported and a first member M1 supported on the support unit 581b, And a supporting member 582b for supporting a hollow second member M2 including fittings corresponding to the welded portions of the first member M1 and the second member M2 A fitting member 570b for welding a first member M1 and a second member M2 to each other so that the concentricity of the first member M1 and the second member M2 coincides with each other; And a second clamping unit 580b for gripping and securing the second member M2. The support carriage 582b is disposed between the cutting device 400 and the support unit 581b or disposed between the pipe conveyance apparatus 300 and the support unit 581b to transmit the first member M1 to the support unit 581b ). And the second clamping unit 580b is provided corresponding to the support unit 581b.

Here, the support unit 581b can move the pipe P or the unit pieces in the longitudinal direction while being supported by the floor or floor support unit 900. [ In other words, a conveyor system that moves the pipe P or the unit pieces according to the rotation of the rollers can be applied. Further, the support carriage 582b can be reciprocated along a rail provided on the floor or floor support unit 900. [

The second welding unit 500b includes a second drive unit 570b for turning the fitting welding unit 570b on the basis of the second clamping unit 580b in correspondence with the welding position of the first member M1 and the second member M2, Unit 583b.

In addition, the fitting welding unit 570b may include a welding unit 570 according to one embodiment of the present invention. Further, the second clamping unit 580b may include a pipe clamping device according to an embodiment of the present invention. Further, the second clamping unit 580b may include a pipe clamping device according to another embodiment of the present invention. In addition, the second drive unit 583b may include a swivel drive unit 573 included in the welding unit 570 according to an embodiment of the present invention.

The pipe clamping apparatus according to the embodiment of the present invention clamps the hollow first member M1 and the hollow second member M2 so that the first expansion unit 510 and the second expansion unit 520 are clamped, A piping support 530 and an expansion control unit 540 and may further include at least one of a control unit 550 and a cooling unit 560. [

Here, when the first member M1 is a pipe, the second member M2 may be a pipe, a tee, or a flange. Further, when the first member M1 is a flange, the second member M2 may be a pipe or a tee. At this time, the first member M1 and the second member M2 are not limited to the above, but the first member M1 and the second member M2 may be hollow in the axial direction.

The first expansion unit 510 grasps the first member M1 while being inserted into the first member M1. The first expansion unit 510 has a cylindrical shape with a diameter smaller than the inner diameter of the first member M1. The first expansion unit 510 includes a first expansion member 511 formed along the circumferential direction of the first member M1 and a second expansion member 511 surrounding the first expansion member 511 along the circumferential direction of the first member M1 And a first resilient ring member 512 elastically supporting the first resilient ring member 512 in a state where the first resilient ring member 512 resiliently supports the resilient member.

At least two of the first expansion members 511 are arranged along the circumferential direction of the first member M 1 to exhibit a cylindrical shape. The first expansion member 511 is provided with a first inclined portion 5414 inclined toward the center of the other side of the first expansion unit from one side facing the second expansion unit, And a concentric support portion 5112 which is in close contact with the inner wall of the first member M1 at a portion opposed to the extended inclined portion 5111. [ The ring seating portion 5113, into which the first elastic ring member 512 is inserted, is recessed in the concentric support portion 5112. The ring seating portion 5113 has a sufficient depth so that the first elastic ring member 512 does not protrude from the concentric support portion 5112 toward the inner wall of the first member M1.

The first expansion member 511 may be expanded or contracted in a concentric shape around the first piston 541. [

Here, the concentric supporter 5112 of the first expansion member 511 may exhibit a shape of arc corresponding to the inner surface of the first member M 1 in a cross-sectional state perpendicular to the axial direction of the first expansion unit 510. The concentric support portion 5112 of the first expansion member 511 may exhibit a straight line shape parallel to the inner surface of the first member M1 in a cross-sectional state parallel to the axial direction of the first expansion unit 510. [ When the first expansion unit 510 is expanded, the contact area between the first expansion member 511 and the first member M 1 is increased, and the contact area between the first member M 1 and the first expansion unit 510 It is possible to stabilize the coincidence of the coincidence.

The first elastic ring member 512 can be stretched and contracted with an elastic force, and the first expansion members 511 are brought into contact with or close to each other to have a cylindrical shape.

In one embodiment of the present invention, the first expanding member 511 has eight cylinders in a state where the first expanding member 511 is in contact with or closely contacted by two first elastic ring members 512 spaced from each other.

The second expansion unit 520 grasps the second member M2 while being inserted into the second member M2. The second expansion unit 520 is disposed on one side of the first expansion unit 510 in correspondence with the welded portion of the first member M1 and the second member M2. Like the first expansion unit 510, the second expansion unit 520 has a cylindrical shape having a smaller diameter than the inner diameter of the second member M2. The second expansion unit 520 includes a second expansion member 521 formed along the circumferential direction of the second member M2 and a second expansion member 521 surrounding the second expansion member 521 along the circumferential direction of the second member M2 And a second resilient ring member 522 elastically supporting the first resilient ring member 522 in a state where the second resilient ring member 522 is resiliently supported.

At least two of the second expansion members 521 are arranged along the circumferential direction of the second member M2 so as to exhibit a cylindrical shape. Like the first expansion member 511, the second expansion member 521 is inclined toward the other side edge of the second expansion unit 520 from the center of one side facing the first expansion unit 510, The second inclined portion 5424 of the second piston 542 and the concentric support portion which is in close contact with the inner wall of the second member M2 at a portion opposed to the extended inclined portion. A ring seating portion 5113, into which the second elastic ring member 522 is inserted, is recessed in the concentric support portion. The ring seating portion 5113 has a sufficient depth so that the second elastic ring member 522 does not protrude from the concentric supporting portion toward the inner wall of the second member M2.

The second expansion member 512 may be expanded or contracted in a concentric shape around the second piston 542.

Here, the concentric support portion of the second expansion member 521 may show a shape of a arc corresponding to the inner surface of the second member M2 in a cross-sectional state perpendicular to the axial direction of the second expansion unit 520. [ The concentric support portion of the second expansion member 521 may have a straight line shape parallel to the inner surface of the second member M2 in a cross-sectional state parallel to the axial direction of the second expansion unit 520. [ When the second expansion unit 520 is expanded, the contact area between the second expansion member 521 and the second member M2 is increased, and the contact area between the second member M2 and the second expansion unit 520 is increased, Can be matched.

The second elastic ring member 522 can be stretched and contracted with an elastic force, and the second expansion members 521 are brought into contact with or close to each other to have a cylindrical shape.

In an embodiment of the present invention, the second expansion member 521 is constituted of eight cylinders in a state in which the two second elastic members 522 are in contact or close contact with each other by two spaced apart second elastic ring members 522.

The piping support 530 is disposed on the other side of the first expansion unit 510. The pipe support 530 can be slid inside the first member M1 through a separate transporting means (not shown).

The piping support 530 includes a support body 531 having a first expansion unit 510 disposed at one side thereof and a gap supporting portion 531 protruding from the outer circumferential surface of the support body 531 to support the inner surface of the first member M1 And a support rod 532 extending from the support body 531 to the other side.

A part of the expansion control unit 540 is incorporated in the support body 531. [ Particularly, the hydraulic pressure means 543 of the expansion control unit 540 is incorporated in the support body 531.

The gap support portion 533 includes a support groove portion 5331 formed in the support body 531 and a support ball portion 5332 partially inserted into the support groove portion 5331 so as to reciprocate in the support groove portion 5331, A support cap portion 5333 for supporting the support ball portion 5332 in a state of being coupled to the support body 531 so as to close the support groove portion 5331 in a state where the support body 5332 protrudes from the support body 531, And a support spring portion 5334 for resiliently supporting the support ball portion 5332 with respect to the base plate 531. [ The support ball 533 is protruded from the support body 531 while being supported by the support cap 5333. The support ball portion 5332 is rotatable in a state of being supported by the support cap portion 5333 and is reciprocatable along the depth direction of the support groove portion 5331. The support spring portion 5334 presses the support ball portion 5332 to the outside of the support body 531 while being inserted into the support groove portion 5331.

The provision of the gap supporting portion 533 prevents friction between the support body 531 and the first member M1 and smooths the sliding movement of the support body 531 inside the first member M1 .

The support rod 532 is provided with an expansion path portion connected to the expansion line 5533 of the packaging line 553 to be described later, a return line 5534 and a clean line 5535, a return path portion, . By providing the support rod 532, the packaging line 553 can be prevented from being damaged by the first member M1.

The expansion control unit 540 expands the diameter of the first expansion unit 510 or the diameter of the second expansion unit 520 based on the pipe support 530. The expansion control unit 540 includes a first piston 541 reciprocally coupled to the first expansion unit 510 for expanding the diameter of the first expansion unit 510, A second piston 542 passing through the center of the first piston 541 for expansion to be reciprocally coupled to the second expansion unit 520 and a second piston 542 reciprocally coupled to the second expansion unit 520 via the first piston 541 and the second piston 542, A hydraulic pressure means 543 for reciprocating at least one of the pistons 542 and a hydraulic pressure supply portion 544 for supplying a fluid to the hydraulic pressure means 543.

The first piston 541 includes a first rod member 5411 which is reciprocated by the hydraulic means 543 and a second rod member 5411 which is coupled to the first rod member 5411, An adjustment member 5412 and a spacing member 5413 coupled to the first adjustment member 5412. [

Here, the first adjusting member 5412 is formed with a first adjusting inclined portion 5414 that is inclined from the peripheral edge of the gap member 5413 toward the center of the first rod member 5411. The inclination of the first adjusting slope part 5414 substantially coincides with the inclination of the extended slope part 5111 provided on the first extending member 511 so that surface contact is possible and the first adjusting member 5412 or the first Wear of the expansion member 511 can be minimized or prevented. The first adjusting member 5412 may be provided with a friction preventing groove 5412a that is recessed along the first adjusting inclined portion corresponding to the longitudinal direction of the first rod member. The friction preventing groove 5412a may be elongated along the longitudinal direction of the first adjusting slope.

In an embodiment of the present invention, the first adjusting member 5412 may have an octahedral shape corresponding to the first extending member 511 composed of eight.

The second expansion unit 520 may be supported on the spacer 5413 to maintain a gap between the first expansion unit 510 and the second expansion unit 520. [ The welding portions of the first member M 1 and the second member M 2 are disposed around the interval member 5413 in a state where the first expansion unit 510 grasps the first member M 1, It is possible to prevent the first expansion unit 510 and the second expansion unit 520 from being damaged when the first member M1 and the second member M2 are welded.

The second piston 542 includes a second rod member 5421 reciprocally moved by the hydraulic means 543 while being reciprocally coupled to the center of the first piston 541, And a second adjustment member 5422 coupled to the second expansion unit 520 to expand the diameter of the second expansion unit 520.

Here, the second adjusting member 5422 is formed with a second adjusting inclined portion 5424 which is inclined from the peripheral edge of the free end side toward the center of the second rod member 5421. The inclination of the second adjusting slope portion 5424 substantially coincides with the inclination of the extended slope portion provided in the second extending member 521 to enable surface contact and the second adjusting member 5422 or the second extending member 521 Can be minimized or prevented. The second adjusting member 5422 may be provided with a friction preventing groove that is recessed along the second adjusting slope in correspondence with the longitudinal direction of the second rod member 5421. The friction preventing groove may be elongated along the longitudinal direction of the second adjusting slope part 5424. The inclination of the second adjusting slope portion 5424 is substantially coincident with the inclination of the first adjusting slope portion 5414 so that the reciprocating movement of the first adjusting member 5412 and the reciprocating movement of the second adjusting member 5422 The diameter expansion amount of the first expansion unit 510 and the diameter expansion amount of the second expansion unit 520 can be equalized.

In an embodiment of the present invention, the second adjusting member 5422 may have an octahedral shape corresponding to the second extending member 521 composed of eight. As a result, the second adjusting member 5422 exhibits a truncated cone shape or a polygonal truncated cone shape. The axial center of the first adjusting member 5412 and the axial center of the second adjusting member 5422 coincide with each other.

The hydraulic means 543 is built in the support body 531 of the pipe support 530 so as not to receive external interference. The hydraulic means 543 may be applied to various known types of cylinders.

When the fluid for clamping is supplied to the hydraulic means 543, the first piston 541 is first inserted into the hydraulic means 543 to expand the first expansion unit 510, and then the second piston (542) is inserted into the hydraulic pressure means (543) to expand the second expansion unit (520). At this time, when the first piston 541 is inserted into the hydraulic means 543, the second expansion unit 520 and the second piston 542 together with the first piston 541 are moved together.

When the fluid for extension release is supplied to the hydraulic pressure means 543, first, the second piston 542 is protruded from the hydraulic pressure means to release the diameter expansion of the second expansion unit 520, The piston 541 protrudes from the hydraulic pressure means 543 to release the diameter expansion of the first expansion unit 510. [ At this time, when the first piston 541 is inserted into the hydraulic means 543, the second expansion unit 520 and the second piston 542 together with the first piston 541 are moved together.

The expansion control unit 540 may further include a clean unit for supplying a clean gas to a welded portion of the first member M1 and the second member M2. Here, the clean gas is an inert gas used for welding, and may include argon or helium.

The clean unit includes a plurality of ejection holes 5416 spaced apart from each other along the circumferential direction of the interval member 5413 and a plurality of ejection holes 5416 embedded in the first piston 541, And a clean gas supply unit 545 for supplying a clean gas to the clean channel 5417. The clean gas supply unit 545 can supply a clean gas to the clean channel 5417. [ The clean gas supply unit 545 is connected to the clean channel 5417 via a clean line 5535 of a packaging line 553 to be described later.

The cleaning unit further includes a concave portion 5415 which is recessed in a ring shape along the circumferential direction of the spacing member 5413 so that the first member M1 and the second member M2 are welded M1 and the inner side of the second member M2 to form a space in which the clean gas stagnates, so that stable welding can be performed by the clean gas.

The control unit 550 controls the operation of the expansion control unit 540 to control the diameter expansion of the first expansion unit 510 or the diameter expansion of the second expansion unit 520. [ The control unit 550 includes a controller 551 for controlling the operation of the expansion control unit 540 and an expansion unit 550 for selecting whether the diameter of the first expansion unit 510 is expanded or the diameter of the second expansion unit 520 is expanded And a packaging line 553 connecting the controller 551 and the expansion control unit 540 to form a path for fluid or clean gas for operation of the expansion control unit 540 have.

The controller 551 is provided with a first indicator I1 indicating the fluid pressure for expanding the diameter of the first expansion unit 510 or for expanding the diameter of the second expansion unit 520, ) Or a second indicator (I2) indicative of the pressure of the fluid for opening the diameter expansion of the second expansion unit (520).

The controller 551 is further provided with a first clamping confirmation unit C1 for indicating a supply state of the fluid for expanding the diameter of the first expansion unit 510 and a second clamping confirmation unit C1 for indicating the state of the fluid for expanding the diameter of the second expansion unit 520 A first release confirmation unit R1 for indicating a supply state of the fluid for expanding the diameter of the first expansion unit 510 and a second release confirmation unit R1 for indicating the supply state of the fluid for expanding the diameter of the first expansion unit 510, And a second release confirmation unit R2 for indicating the supply state of the fluid for expanding the diameter of the first release confirmation unit R2.

The expansion control switch 552 is provided with a first clamping unit 5521 for allowing the fluid for expanding the diameter of the first expansion unit 510 to be supplied to the hydraulic means 543, A second clamping portion 5522 for allowing the fluid for expansion to be supplied to the hydraulic means 543 and a second release portion 5522 for allowing the fluid for expanding the diameter of the first expansion unit 510 to be supplied to the hydraulic means 543. [ And a second release portion 5524 for allowing the fluid for expanding the diameter of the second expansion unit 520 to be supplied to the hydraulic means 543.

The packaging line 553 includes a first connector 5531 coupled to the hydraulic means 543 or the support rod 532, a second connector 5532 coupled to the controller 551, An extension line 5533 connecting the second connector 5532 and the second connector 5532 to form a fluid path for expanding the diameter of the first expansion unit 510 or the diameter of the second expansion unit 520, The connector 5531 and the second connector 5532 are connected to each other to connect the return line 5534 forming the transfer path of the fluid for the diameter expansion release of the first expansion unit 510 or the expansion expansion release of the second expansion unit 520 And a clean line 5535 connecting the first connector 5531 and the second connector 5532 to form a clean gas transfer path. At this time, the extension path portion, the return path portion, and the clean path portion built in the support rod 532 are connected to the first connector 5531.

 The cooling unit 560 cools at least one of the first member M1, the welded portion of the first member M1 and the second member M2, and the expansion control unit 540. [ The cooling unit 560 is provided to cool the pipe support 530 to cool at least one of the first member M1, the welded portion of the first member M1 and the second member M2, A cooling line 562 connected to the cooling means 561 to form a conveyance path of the cooling medium and a cooling line 562 connected to the cooling means 561 to supply the cooling medium to the cooling means 561, And a media supply unit 563. The cooling medium is a fluid for cooling, and a refrigerant, cooling water, or the like can be used.

The cooling line 562 includes a first supply connector 5621 coupled to the support body 531 or the support rod 532 of the piping support 530, a second supply connector 5622 coupled to the controller 551, A first collection connector 5623 separated from the first supply connector 5621 and coupled to the support body 531 or the support rod 532 of the pipe support body 530 and a second collection connector 5623 spaced apart from the second supply connector 5622 A second recovery connector 5624 coupled to the controller 551 and a second recovery connector 5621 connected to the second supply connector 5621 and the second supply connector 5622 to form a transfer path of the cooling medium supplied to the cooling means 561 And a cooling recovery line 5626 for connecting the first recovery connector 5623 and the second recovery connector 5624 to form a transfer path of the cooling medium discharged from the cooling means 561 can do. At this time, the support rod 532 is provided with a supply path portion for connecting the first supply connector 5621 and the cooling means 561, and a recovery path portion for connecting the first collection connector 5623 and the cooling means 561 .

A welding unit according to an embodiment of the present invention welds welded portions of the first member (M1) and the second member (M2). The welding unit 570 is spaced apart from the first member M1 or the second member M2 in correspondence with the position of the welded portion or the spacing member 5413 of the first member M1 and the second member M2 And a welder 572 arranged to face the welded portions of the first and second members M1 and M2 in a state of being coupled to the welding body 571 . The welding unit 570 may include a swivel drive unit 573 that swivels the welder 572 with respect to the clamping device corresponding to the welded portion of the first member M1 and the second member M2. Here, the swivel drive unit 573 can adjust the distance between the welded portion of the first member M1 and the second member M2 and the welder 572. [

The piping support 530 and the first expansion unit 510 are inserted into the first member M1 and the second member M2 (M2) is inserted into the first member M1, So that the second expansion unit 520 is inserted into the second expansion unit 520. At this time, the separate transporting means (not shown) may move the pipe support body 530 in the first member M1 or move the first member M1 to move the pipe support body 530 and the first expansion member 511 may be inserted into the first member M1. Further, a separate conveying means (not shown) moves the second member M2 so that the second expansion unit 520 is inserted into the second member M2.

When the first clamping part 5521 is pressed, the fluid in the hydraulic pressure supply part 544 is transmitted to the hydraulic pressure device 543 via the expansion line 5533 of the packaging line 553, (543). The fluid discharged from the hydraulic pressure means 543 can be recovered from the hydraulic pressure supply portion 544 via the return line 5534 of the packaging line 553 in accordance with the operation of the first piston 541. [ At this time, the fluid pressure is displayed on the first indicator I1, and the first clamping confirmation unit C1 is operated. As the first piston 541 is inserted into the hydraulic means 543, the first adjusting member 5412 is inserted into the first expanding unit 510 and the expanded inclined portion 5111 of the first expanding member 511 The first adjustment member 5414 of the first adjustment member 5412 is slid and the first expansion member 511 moves toward the inner surface of the first member M1 while being spaced from each other, M1. Further, the welding portion of the first member M1 is arranged around the spacing member 5413. [

Next, the welding portion of the second member (M2) is positioned at the welding portion of the first member (M1), and then the second clamping portion is pressed, the fluid of the hydraulic pressure supply portion (544) And the second piston 542 is inserted into the hydraulic pressure means 543 through the hydraulic pressure means 5533 and the hydraulic pressure means 543. The fluid discharged from the hydraulic means 543 in accordance with the operation of the second piston 542 can be recovered in the hydraulic pressure supply portion 544 via the return line 5534 of the packaging line 553. At this time, the pressure of the fluid is displayed on the first indicator I1, and the second clamping confirmation unit C2 is operated. As the second piston 542 is inserted into the hydraulic means 543, the second adjusting member 5422 is inserted into the second expanding unit 520 and the second adjusting member 5422 is inserted into the second expanding unit 520, The second adjusting slope portion 5424 of the adjusting member 5422 is slid and the second extending members 521 move toward the inner surface of the second member M2 while being spaced from each other, Respectively.

At this time, the second expansion unit 520 and the second adjustment member 5422 are not interfered with the second member M2, so that the interior of the second member M2 can be prevented from being damaged.

The first member M1 and the second member M2 have the same concentricity and the contact force between the first member M1 and the first expansion unit 510 and the contact force between the second member M2 and the second expansion unit 510, The engagement state of the first member M1 and the second member M2 is maintained by the adhesion force between the first member M1 and the second member M2.

Next, the welding unit 570 is positioned at the welded portion of the first member M1 and the second member M2. Then, the welding unit 570 can weld the welded portions of the first member M1 and the second member M2 by main welding in a state in which the pick-up operation or the wetting operation is omitted.

When the control unit 550 operates the clean unit, the clean gas of the clean gas supply unit 545 is supplied to the packaging line 553 The clearance between the welded portion and the spacing member 5413 is filled with clean gas inside the first member M1 and the second member M2, And it is possible to smoothly weld the welded portion.

When the welding is completed, the control unit 550 stops the supply of the clean gas.

Next, when the second release portion 5524 is pressed, the fluid in the hydraulic pressure supply portion 544 is transferred to the hydraulic means 543 via the return line 5534 of the packaging line 553, and the second piston 542 And is protruded from the hydraulic means 543. The fluid discharged from the hydraulic pressure means 543 can be recovered from the hydraulic pressure supply portion 544 through the expansion line 5533 of the packaging line 553. At this time, the pressure of the fluid is displayed on the second indicator I2, and the second release confirmation unit R2 is operated. The second adjusting member 5422 protrudes from the second expanding unit 520 and the second adjusting member 5422 protrudes from the second expanding member 521 as the second piston 542 protrudes from the hydraulic means 543, The second adjusting slope portion 5424 of the adjusting member 5422 is slid and the second extending member 521 is brought into contact with or brought into close contact with each other due to the elastic force of the second elastic ring member 522, 2 expansion member 521 is spaced from the inner surface of the second member M2.

Finally, when the first release portion 5523 is pressed, the fluid in the hydraulic supply portion 544 is transferred to the hydraulic means 543 via the return line 5534 of the packaging line 553, and the first piston 541 And is protruded from the hydraulic means 543. The fluid discharged from the hydraulic pressure means 543 can be recovered in the hydraulic pressure supply portion 544 through the expansion line 5533 of the packaging line 553 in accordance with the operation of the first piston 541. [ At this time, the fluid pressure is displayed on the second indicator I2, and the first release confirmation unit R1 is operated. As the first piston 541 protrudes from the hydraulic means 543, the first adjusting member 5412 protrudes from the first expanding unit 510 and the extended inclined portion 5111 of the first expanding member 511 The first adjustment member 5414 of the first adjustment member 5412 is slid by the reference and the first expansion member 511 is brought into contact with or brought into close contact with each other by the elastic force of the first elastic ring member 512, And the first expansion member 511 is spaced from the inner surface of the first member M1.

Finally, the clamping device is pulled out with reference to the first member (M1) and the second member (M2), and the first member (M1) and the second member (M2) Or the spool storage unit 800 to the next process.

The pipe clamping apparatus according to another embodiment of the present invention clamps the hollow first member M1 and the hollow second member M2 so that the first expansion unit 510 and the second expansion unit 520, A piping support 530 and an expansion control unit 540 and may further include at least one of a control unit 550 and a cooling unit 560. [

Here, when the first member M1 is a pipe, the second member M2 may be a pipe, a tee, or a flange. Further, when the first member M1 is a flange, the second member M2 may be a pipe or a tee. At this time, the first member M1 and the second member M2 are not limited to the above, but the first member M1 and the second member M2 may be hollow in the axial direction.

In the pipe clamping apparatus according to another embodiment of the present invention, the same reference numerals are assigned to the same components as those of the pipe clamping apparatus according to the embodiment of the present invention, and a description thereof will be omitted.

However, in another embodiment of the present invention, the first expansion unit 510 shows a cylindrical shape having a diameter smaller than the inner diameter of the first member M1. Further, the second expansion unit 520 shows a truncated cone shape having a smaller diameter than the inner diameter of the second member M2. Then, at least two of the second expansion members 521 are disposed along the circumferential direction of the second member M2 so as to exhibit a frustum shape. In addition, a ring seating portion 5113, into which the second elastic ring member 522 is inserted, is recessed in the inclined concentric portion 5214. The inclined concentric portion 5214 of the second expansion member 521 does not interfere with the inner surface of the second member M2 and can improve the adhesion between the concentric ring portion 5212 and the second member M2 . Further, in another embodiment of the present invention, the second expansion member 521 is composed of six, and shows a truncated conical shape in a state in which the two second elastic ring members 522 are mutually contacted or closely contacted with each other.

A welding unit 570 according to another embodiment of the present invention may include a welding body 571 and a welder 572 and may include a swivel drive unit 573. [ In the welding unit 570 according to another embodiment of the present invention, the same reference numerals are assigned to the same components as those of the welding unit 570 according to the embodiment of the present invention, and a description thereof will be omitted.

The operation of the pipe clamping apparatus according to an embodiment of the present invention is the same as that of the pipe clamping apparatus according to an embodiment of the present invention, and a description thereof will be omitted.

The first clamping unit 580a in the spool manufacturing system according to the embodiment of the present invention is a pipe clamping apparatus according to an embodiment of the present invention in which the first expansion member 511 and the second expansion member 521 are both And the second clamping unit 580b is a pipe clamping apparatus according to another embodiment of the present invention in which the first expansion member 511 is cylindrical and the second expansion member 521 is a truncated cone shape .

The welding apparatus 500 may be configured such that when the pipe P is connected to the unit piece, two or more unit pieces are connected to each other, the pipe P is connected to the fitting or the unit piece and the fittings are connected to each other, And a connecting unit 500c for connecting and holding the connecting unit 500c.

The attaching unit 500c includes a positioner 500c-1 in which a pipe P or a unit piece is horizontally supported and a positioner 500c-1 for moving a unit piece or a fitting in correspondence with a member of the positioner 500c- 2) and a member (not shown) for partially welding the members of the positioner 500c-1 and members of the reception car 500c-2. At least one of the positioner 500c-1 and the recipient car 500c-2 is provided with a push-up portion (not shown) for maintaining the concentricity between the member of the positioner 500c-1 and the member of the recipient car 500c- ) May be included. (Not shown) may be manually operated by an operator, or may be automatically operated through a configuration such as the first welding unit 500a or the second welding unit 500b described above.

The welding apparatus 500 may further include a first worksite 500d for automatically or manually welding two members connected by the contact unit 500c. The first worksite 500d may have the same configuration as the first welding unit 500a or the second welding unit 500b described above.

The welding apparatus 500 may be configured such that the operator manually connects the pipe P and the unit piece, connects two or more unit pieces, connects the pipe P and the fittings, connects the unit pieces and the fittings, And a second work area 500e connecting the pipe P with any one of the unit pieces and the fittings. The second worksite 500e may have the same construction as the above-described abutment (not shown).

The welding apparatus 500 is modularized for each unit or each unit is divided into unit modules so as to be modularized so as to be able to be carried and rearranged and to be detachably attached to the floor or floor support unit 900.

The piping transfer device 300 moves at least one of the pipe P, the unit pieces, and the fittings among the above-described devices.

The pipe transfer apparatus 300 includes an axial direction transfer unit 310 for moving the pipe P or the unit pieces in the longitudinal direction, a cross direction transfer unit 310 for moving the pipe P or the unit pieces in the direction crossing the longitudinal direction, (320), and a fitting flow transfer unit (not shown) for moving the fitting flow.

The axial direction transfer unit 310 is arranged along the longitudinal direction of the pipe P or the unit piece so as to move the pipe P or the unit piece in the longitudinal direction according to the rotation of the pipe P or the roller on which the unit piece is supported .

The cross direction transfer unit 320 may be arranged along the direction intersecting the longitudinal direction of the pipe P or the unit piece to move the bracket supporting the pipe P or the unit piece in the arrangement direction. The brackets are arranged at least two in the longitudinal direction of the pipe (P) or the unit pieces, so that the support of the movement of the pipe (P) can be stabilized.

The pipeline transfer device 300 is capable of being carried and relocated by the units described above or unit-modularized as described above, and can be detachably attached to the floor or floor support unit 900.

Any one of the pipe P, the unit piece, and the fittings in the pipeline transfer device 300 may be arranged in a direction intersecting the longitudinal direction of the roller or pipe P rotatably arranged along the longitudinal direction of the pipe P And can be moved while being supported by brackets arranged to be movable along the guide rails. Such movement can be expressed by a pipe conveying device operated in a conveyor manner.

In the pipe transfer apparatus 300, any one of the pipe P, the unit pieces, and the fittings is moved to a unit of the apparatus in accordance with the movement of the grip portion (not shown) while being gripped by a separate grip portion And can be seated in the unit of the device according to the release of the grip. This movement can be expressed as a pipeline transfer device 300 operated by a crane method.

Any one of the pipe P and the unit pieces and the fittings can be moved in the pipe transfer apparatus 300 while being supported on the support carriage 582b or the recipient carriage 500c-2 which is moved along the rail. This movement can be expressed as a pipeline transfer device 300 operated in a bogie method.

The pipeline transfer device 300 is modularized for each unit, or each unit is separated into unit modules to be modularized so that transportation and rearrangement can be performed, and detachment and attachment are possible at the floor or floor support unit 900.

The bending apparatus 600 bends the pipe P or the unit piece according to predetermined bending information. The bending apparatus 600 includes a conveying carriage 610 for conveying a pipe P or a unit piece to be bent and a pipe P or unit piece conveyed through the conveying carriage 610 or a bending supporting unit 620 A first bending unit 630 supporting a bending portion of the pipe P or the bending portion of the unit piece supported by the bending support unit 620 and a second bending unit 630 supported by the first bending unit 630 to bend the pipe P or the unit piece, And a second bending unit 640 pivoting with respect to the unit 630.

The inspection apparatus 700 inspects the welded parts and specifications of the completed unit spool through the welding apparatus 500. The inspection apparatus 700 can inspect the welding position and specifications of the unit spools including the nondestructive inspection, the visual inspection, and the like.

The inspection apparatus 700 is modularized for each unit or each unit is separated into unit modules so as to be modularized so as to be able to be transported and rearranged and detachably attached to the floor or floor support unit 900.

The spool storage device 800 stores the unit spool completed through the welding device 500. The spool storage device 800 is provided between the welding unit and the spool storage space described above or between the welding unit and the inspection apparatus 700 described above or between the work storage space and the spool storage space described above or between the above- And is movable between the apparatus 700 and the spool storage location. The spool storage device 800 is provided with the above-mentioned bogie type so that it can be automatically or manually operated in accordance with the operation of the operator. In addition, the spool storage device 800 is provided with a traveling means (not shown) for generating power, so that the spool storage device 800 can freely travel on the work site according to the operation of the operator. Further, the spool storage device 800 is provided with an autonomous drive unit (not shown) for recognizing a predetermined path other than the rail, so that the autonomous drive can be automated.

The spool storage device 800 is modularized for each unit or each unit is separated into unit modules so as to be modularized so that the spool storage device 800 can be transported and rearranged and detached and attached to the floor or floor support unit 900.

The floor support unit 900 includes a plurality of unit floor members 900a arranged in a longitudinal direction on the floor. The bottom support unit 900 is provided with at least a blasting device 200, a cutting device 400, a welding device 500, an inspection device 700, a pipe transfer device (300) is detachably arranged.

The unit floor member 900a includes a unit plate portion 910 having a predetermined area and thickness, a fitting groove portion 920 formed to be recessed on one side of the unit plate portion 910, The fitting portion 930 protrudes from the other side of the unit plate portion 910 to be inserted into the fitting groove portion 920 and the fitting portion 930 is inserted into the fitting groove portion 920 between the mutually adjacent unit bottom member 900a And a mounting portion 940 that is engaged with the fitting portion 930 inserted into the fitting groove portion 920 when the fitting portion 930 is inserted into the fitting groove portion 920.

The fitting portion 930 is rotatable with respect to the rotation groove portion 931 through the fitting rotary portion 932 and a rotary groove portion 931 formed corresponding to the fitting groove portion 920 on the other side of the unit plate portion 910 And a mounting hole portion 935 penetrating through the fitting protrusion 933 to allow the mounting portion 940 to pass therethrough.

The fitting portion 930 may further include a rotation guide protrusion 934 extending from the fitting protrusion 933 and rotatable in a state of being inserted into the rotation groove portion 931. For example, the rotation guide projection 934 may extend along the longitudinal direction of the fitting projection 933. As another example, the rotation guide projection 934 may extend along the direction intersecting with the longitudinal direction of the fitting projection 933.

The mounting portion 940 includes a mounting rod portion 941 slidably coupled to one side of the fitting portion 930 and a rod portion 941 forming a slide path of the mounting rod portion 941 so as to communicate with the fitting portion 930. [ A lifting lever portion 945 coupled to the longitudinal direction of the loading rod portion 941 so as to intersect with the longitudinal direction of the loading rod portion 941 and a sliding movement path of the lifting lever portion 945 to communicate with the rod path portion 942 And may include a path slit portion 944.

The mounting portion 940 may further include a rod support groove portion 943 communicating with the fitting groove portion 920 and disposed to face the rod path portion 942. The rod support groove portion 943 allows the end portion of the mounting rod portion 941, which has passed through the mounting hole portion 935, to be inserted. Then, the flow of the mounting rod portion 941 and the flow of the fitting projection 933 can be suppressed or prevented.

Here, the lifting lever portion 945 can reciprocate in a direction intersecting with the longitudinal direction of the mounting rod portion 941. The mounting portion 940 may further include a lever insertion groove portion 946 into which the lift lever portion 945 is inserted and supported while the mounting rod portion 941 is inserted into the mounting hole portion 935. After the mounting portion 940 is operated in the state where the fitting portion 930 is inserted into the fitting groove portion 920, the lifting lever portion 945 is inserted into the lever insertion groove portion 946 and inserted into the unit plate portion 910, It is possible to prevent the elevating lever portion 945 from protruding from the upper portion of the unit plate portion 910 and to smoothly arrange and move the above-described devices in the unit plate portion 910, 910 can be confirmed.

Further, the lifting lever portion 945 may be protruded from the unit plate portion 910 at an initial position. The mounting portion 940 may further include an interference preventing groove portion 947 formed in the unit plate portion 910 so as to insert the protruding lifting lever portion 945 therein. Since the elevating lever portion 945 protruding from the initial position to the unit plate portion 910 is inserted into the interference preventing groove portion 947 in accordance with the loading of the unit plate portion 910, The clearance between the plate portions 910 can be prevented. Also, it is possible to prevent the flow between the unit plate portions 910 in a state where the unit plate portion 910 is loaded.

The floor support unit 900 is modularized for each unit or each module is separated into unit modules to be modularized so that the floor support unit 900 can be carried and rearranged and detached and attached to the floor or floor support unit 900.

According to the above-described cone type clamp-based movable spool production system, it is possible to automate the production of the unit spool based on the relationship between the process and the package, improve the manufacturing accuracy of the unit spool, .

In addition, it is possible to easily carry and rearrange the devices and to smoothly cope with the on-site conditions, thereby shortening the construction period.

In addition, the dimensions of the pipe P to be received through the dispenser device 100 can be measured and stored separately for each pipe diameter. Particularly, in the case of separating and storing the pipes P by the pipe diameters, it is possible to prevent a safety accident of an operator through automation.

The distance between the base and the lifting rod 121a or the distance between the lifting distance H of the lifting rod 121a and the rotation angle of the supporting rod 122, It is possible to calculate the dimension of the pipe P by using the pipe S (see FIG. 5), improve the dimensional accuracy of the calculated pipe P, and store the pipe P separately for each pipe diameter.

7) of the rotation rod portion 121b and the second rotation angle S2 (see Fig. 7) of the support rod portion 122 (see Fig. 7) , The dimensions of the pipe P can be calculated, the dimensional accuracy of the calculated pipe P can be improved, and the pipe P can be separately stored for each pipe diameter.

Further, it is possible to simplify the calculation of the dimension of the pipe P, and precisely control the position of the input delivery unit 130 according to the calculated dimensions.

The support rod portion 122 has a V shape to stabilize the contact state between the pipe P and the support rod portion 122 and to adjust the second rotation angles S2, 7) can exhibit the effect of correcting the error with respect to the dimension of the pipe P to be calculated.

The sliding movement of the support rod portion 122 is smooth with respect to the pipe P through the additional configuration of the first support roller portion 1223 and the second support roller portion 1224, Or the wear of the pipe (P) can be prevented, and the life of the support rod part (122) can be prolonged.

In addition, it is possible to smoothly transmit the pipe P without external force, and to easily store the pipe P in the dispensing unit 180 by the pipe diameters.

The supply unit 110 discharges the pipe P from the supply unit 110 through the interlocking action of the supply stopper 113 and the individual supply part 115, (P) can be prevented from falling.

It is also possible to stably support the individual pipes P in the process of delivering the pipes P through the detailed configuration of the input transfer unit 130 and the discharge transfer unit 150, So that the pipe P can be stably transferred without an external force toward the discharge side of the pipe P.

The dispensing unit 180 discharges the respective pipes P individually from the dispensing unit 180 through the interlocking action of the support stopper 181 and the individual discharge unit 182, 180 to prevent the pipe P from falling off.

In addition, after blasting through the blasting device 200, residues remaining in the pipe P can be removed to remove residues from the pipe P, and the defects generated by the residue in the subsequent process Can be prevented.

It is also possible to prevent the pipe P from rolling in the seating bracket 251 through the detailed configuration of the seating bracket 251 and to prevent the pipe P from being separated from the seating bracket 251 when the pipe P is inclined It is possible to prevent the pipe P from hitting the floor.

It is also possible to allow the residue separated from the seating bracket 251 or the pipe P to fall naturally through the detailed structure of the pipe supporting portion 2514 and to prevent the residue from being stagnated in the seating bracket 251 or the pipe P .

Further, the rotation of the seating bracket 251 can be stabilized through the detailed configuration of the bracket rotating unit 253, and the inclination of the pipe P can be easily adjusted.

In addition, when the eccentric rotation part 2533 is attached to the eccentric rotation part 2531, the load generated in the eccentric rotation part 2531 is reduced, the failure of the eccentric rotation part 2531 is prevented, You can soften it.

The second support bracket 254 prevents the second support bracket 254 from interfering with the surroundings when the mount bracket 251 is rotated through the detailed configuration of the second support bracket 254, The accident can be prevented, and the rotation state of the seating bracket 251 can be visually confirmed.

It is also possible to overcome the structural limitations due to the longitudinal discharge of the pipe P through the detailed configuration of the rolling unit 256 and the rolling unit 256 and to simplify the discharge of the pipe P by rolling the pipe P. have.

Also, when the seating bracket 251 is rotated through the arrangement structure of the rolling driving part 2562, the load generated in the eccentric rotation part 2531 is reduced, the failure of the eccentric rotation part 2531 is prevented, ) Can be smoothly rotated.

Further, the rotation and vibration operation of the seating bracket 251 is clarified through the elimination control unit 258, the rotation and vibration operation of the seating bracket 251 is controlled according to the pipe according to the pipe diameter, The removal efficiency of the residue can be maximized.

In addition, residues discharged from the seating bracket 251 or the pipe P can be easily recovered through the residue collecting unit 257, and the surface treated particles contained in the residue can be recycled.

Further, the blast discharge unit 230 and the additional structure of the blast transfer unit 240 facilitate the blasting process of the pipe P in the blast apparatus, and the pipe P is stagnated during the transfer of the pipe P. The blasting process speed can be improved.

In addition, it is possible to simplify the transfer of the inter-transfer pipe P of the pipe P and to smoothly open the pipe P without external force, thereby improving the transfer speed of the pipe P.

Further, the clamping unit 570 clamps the mutually adjacent two members M1 and M2 for welding, thereby making the concentricity between the two members M1 and M2 coincide with each other, and even if there is no separate fit- It is possible to stably maintain the connection state of the first and second members M1 and M2 and improve the fixing force of the two members M1 and M2.

The first expansion unit 510 and the second expansion unit 520 may have a cylindrical shape or the first expansion unit 510 may have a cylindrical shape and the second expansion unit 520 may have a truncated cone shape, Connections between pipe and pipe, connection between pipe and flange, connection between pipe and flange, connection between flange and tee as well as connection of pipe and elbow, connection of tee and elbow, connection of flange and elbow, The connection between the tee and the reducer, the connection between the flange and the reducer, the connection between the elbow and the reducer can be stabilized, and the second piston 542 and the second expansion unit 520 can be prevented from interfering with the member .

Further, in welding the two members M1 and M2, the back purging process, the fat-up process and the wet-process process of the two members M1 and M2 can be omitted, and the clean gas used for back purging can be saved , The welding operation time can be shortened.

The piping support body 530 can easily supply the fluid to the hydraulic means 543 of the expansion control unit 540 through the detailed structure of the piping support body 530 and can prevent friction with the support body 531 inside the member, Movement can be smooth.

Further, through the detailed configuration of the expansion control unit 540, the reciprocal movement of the first piston 541 and the second piston 542 coaxially disposed by the single hydraulic pressure device 543 is facilitated, and the first piston 541 and the second piston 542 of the first expansion unit 510 and the second expansion unit 520 when the diameters of the first expansion unit 510 and the second expansion unit 520 are expanded, It is possible to prevent the concentricity between the two members M1 and M2 from being changed.

Further, since the clean gas is directly supplied to the welded portions of the two members M1 and M2 through the additional structure of the clean unit, the welded portions of the two members M1 and M2 are prevented from being oxidized and the two members M1 and M2 The foreign matter can be removed from the welded portion of the first and second members M1 and M2.

Further, the detailed configuration of the cleaning unit can stabilize the transfer of the clean gas and prevent the leakage of the clean gas.

The first piston 541 and the second piston 542 are configured to simplify the linkage with the first piston 541 and the first rod member 5411 and the second rod member 5421 And the coaxiality of the first and second expansion units 510 and 520 can be stabilized to coincide with each other.

The operation of the expansion control unit 540 is clarified through the control unit 550 and the gripping force for clamping the two members M1 and M2 can be stably maintained. The second expansion unit 520 can be stably expanded.

It is also possible to cool the welded portions of the hydraulic means 543 or the two members M1 and M2 of the expansion control unit 540 through the cooling unit 560 and perform a stable welding operation in a high temperature or high temperature region can do.

In addition, it is possible to smoothly move the pipe P or the unit pieces between the apparatuses through the pipeline transfer device 300, and to prevent a worker's safety accident in response to the process automation.

Further, it is possible to improve the precision of welding of the unit spool and the specification accuracy of the unit spool through the inspection apparatus 700 and to prevent errors or defects from occurring in each apparatus by indexing the errors generated in the process of manufacturing the unit spool have.

In addition, the unit spools corresponding to the process-related relation shafts can be systematically managed and stored through the spool storage device 800, and the unit spools can be easily applied at the installation site of the unit spools.

In addition, the floor support unit 900 can stabilize the transportation and rearrangement of the devices at the worksite, simplify the horizontal adjustment of each device, and simplify management of each device at the worksite.

Further, through the detailed structure of the unit bottom member 900a, the coupling force between adjacent unit bottom members 900a can be stabilized, the unit bottom member 900a can be prevented from flowing, and each unit can be stably supported .

It is also possible to prevent breakage of the fitting protrusion 933 during the transportation of the unit bottom member 900a through the detailed configuration of the fitting portion 930 and to prevent the connection of the unit bottom member 900a with the mounting portion 940 Can be stabilized.

Further, the rotation of the fitting projection 933 can be restricted through the rotation guide projection 934, and the rotation state of the fitting projection 933 can be stabilized.

Further, the fitting projection 933 can be stably fixed in the fitting groove 920 through the detailed configuration of the fitting portion 940, and the fitting and attachment of the fitting projection 933 and the fitting portion 940 can be facilitated.

In addition, it is possible to prevent the flow of the mounting rod portion 941 and the flow of the fitting projection portion 933 in a state where the unit bottom members 900a are coupled to each other through the rod support groove portion 943. [

It is also possible to prevent the elevating lever portion 945 from protruding in the state where the unit floor members 900a are coupled with each other through the lever insertion groove portion 946 and to prevent the elevating lever portion 945 from interfering with each device and the operator can do.

It is also possible to prevent the unit plate portions 910 from interfering with each other or from spreading between the unit plate portions 910 in the process of loading the unit floor member 900a through the interference preventing groove portion 947, It is possible to prevent the unit plate portion 910 from flowing in the process of conveying the unit bottom member 900a.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Modify or modify the Software.

100: dispenser device 110: supply unit 111: pipe fitting part
112: transfer slope part 113: supply stopper 115:
1151: Feed stopper rod 1152: Feed pivot shaft 1153: Feed pivot drive part
120: Dimension measurement unit 121a: Lift rod part 121b:
121: support rotating shaft 122: support rod part 1221: first support rod part
1222: second support rod portion 1223: first support roller portion 1224: second support roller portion
123 initial elastic portion 124a elevation driving portion 124b rotational driving portion
124: Driving rotation shaft 125a: Raising / lowering controller 125b:
1251a: Lift-up distance measuring unit 1251b: First rotation angle measuring unit 1252a:
1252b: second rotation angle measuring section 1253: dimension calculating section 1254: pipe matching section
1255: Unit control unit 130: Input transfer unit 131:
132: input supporting part 133: input driving part 134: input bracket
135: first input seating part 136: second input seating part 137: input driving shaft
140: input / lift unit 150: exhaust transfer unit 160: discharge / lift unit
170: Pipe transfer unit 180: Dispensing unit 181: Support stopper
182: Individual discharge part P: Pipe H: Lift distance
S: rotation angle S1: first rotation angle S2: second rotation angle
200: blast apparatus 210: blasting unit 211: blast fixing unit
212: blasting control unit 220: blasting input unit 221: input table
222: input roller portion 223: input roller driving portion 230: blast discharge unit
231: discharge table 232: discharge roller section 233: discharge roller drive section
240: blasting transmission unit 241: blasting pivot rod 242: blasting pivot shaft
243: Blasting spacing member 245: Blasting pivot driving unit 250: Residue removing unit
251: seating bracket 2511: first seating bracket part 2511a: bracket passing groove
2512: second mounting bracket part 2513: rod bracket part 2514: pipe supporting part
2515: support extension part 2516: extension fork part 2517: fork bend part
252: first support bracket 253: bracket rotation unit 2531: eccentric rotation part
2532: eccentric rotation shaft 2533: eccentric reciprocating unit 2534: first eccentric reciprocating unit
2535: second eccentric reciprocating unit 254: second supporting bracket 2541: fixed bracket unit
2542: Pivot shaft 2543: Pivot bracket part 255: Vibration unit
256: Rolling unit 2561: Rolling bracket part 2562: Rolling drive part
2563: rolling axis 257: residue collecting unit 258:
S: pipe inclination angle S1: first inclination angle S2: second inclination angle
300: Piping transfer device 310: Axial transfer unit 320: Cross direction transfer unit
400: cutting device 410: vertical cutting unit 411: vertical cutting part
412: vertical support portion 413: vertical stopper 420: oblique cutting unit
421: slant cutting portion 422: inclined support portion 423: inclined stopper
430: flame cutting unit 431: flame cutting unit 432:
433: Flame stopper
500: welding apparatus 500a: first welding unit 570a: pipe welding unit
580a: first clamping unit 581a: first seating unit 582a: second seating unit
583a: first driving unit 500b: second welding unit 570b: fitting welding welding unit
580b: second clamping unit 581b: support unit 582b: support carriage
583b: second driving unit 500c: contact unit 500c-1:
500c-2: a reception car 500d: a first worksite 500e: a second workplace
510: first expansion unit 511: first expansion member 5111:
5112: concentric support portion 5113: ring seating portion 512: first elastic ring member
520: second expansion unit 521: second expansion member 5212: concentric ring part
5214: inclined concentric part 522: second elastic ring member 530: pipe support body
531: Support body 532: Support rod 533:
5331: support groove portion 5332: support ball portion 5333: support cap portion
5334: support spring portion 540: expansion control unit 541: first piston
5411: first rod member 5412: first adjusting member 5413:
5414: first adjusting slope part 5415: concave part 5416:
5417: Clean channel 542: Second piston 5421: Second rod member
5422: second adjusting member 5424: second adjusting slope 543: hydraulic adjusting means
544: Hydraulic pressure supply unit 545: Clean gas supply unit 550: Control unit
551: controller I1: first indicator I2: second indicator
C1: first clamping confirmation part C2: second clamping confirmation part R1: first release confirmation part
R2: second release confirmation unit 552: expansion control switch 5521: first clamping unit
5522: second clamping part 5523: first release part 5524: second release part
553: packaging line 5531: first connector 5532: second connector
5533: extension line 5534: return line 5535: clean line
560: cooling unit 561: cooling means 562: cooling line
5621: first supply connector 5622: second supply connector 5623: first withdrawal connector
5624: Second collection connector 5625: Cooling supply line 5616: Cooling collection line
563: Cooling medium supply unit 570: Welding unit 571: Welding body
572: Welding machine 573:
M1: first member M2: second member
600: Bending apparatus 610: Transport truck 620: Bending support unit
630: first bending unit 640: second bending unit
700: Inspection device
800: Spool storage device
900: bottom support unit 900a: unit bottom member
910: unit plate portion 920: fitting groove portion 930:
931: Pivoting tongue portion 932: Fitting pivot shaft portion 933:
934: rotation guide projection portion 935: mounting hole portion 940:
941: mounting rod portion 942: rod path portion 943: rod supporting groove portion
944: Path slit portion 945: Lift lever portion 946: Lever insertion groove portion
947: interference prevention groove

Claims (16)

A fixed spool production system based on a cone type clamp for manufacturing a unit spool formed according to the disassembly of piping lines indicated in a process piping (P & ID, Piping and Instrumentation Diagram)
A dispenser device (100) for separating and storing the pipes to be received by materials and diameters; A blasting device (200) for performing a blasting process on the pipe delivered from the dispenser device (100); A cutting device 400 cutting the pipe delivered from the blast device 200 to a unit piece corresponding to the unit spool or puncturing a branch hole in the pipe or the unit piece; A welding unit connecting the pipe and the unit piece, connecting two or more unit pieces, connecting the unit piece and a fitting, or connecting the pipe, the unit piece, and the fitting to the branch hole, Device 500; And a pipe transfer device (300) for transferring at least one of the pipe and the unit piece between the above-described devices,
The welding apparatus (500)
A first welding unit (500a) for connecting the pipe and the unit piece, connecting the unit piece to two or more, connecting the pipe and the fitting, or connecting the unit piece and the fittings; And a second welding unit (500b) connecting the pipe and the fitting, or connecting the unit piece and the fitting, And at least one of < RTI ID = 0.0 >
Wherein one of the first welding unit (500a) and the second welding unit (500b)
A support unit (581b) to which the pipe or the hollow first member including the unit piece is supported; A support carriage (582b) supported by a hollow second member including fittings corresponding to the first member supported by the support unit (581b); A fitting welding unit (570b) for welding a welded portion of the first member and the second member; And a second clamping unit (580b) holding and fixing the first member and the second member so that the concentricity of the first member and the second member is equal to each other,
The above-described devices are removable from the floor so that they can be transported and rearranged,
The dispenser apparatus 100 includes a supply unit 110 in which the pipes P are sequentially supplied,
The supply unit (110)
A feed stopper 113 for supporting the pipe P on the pipe seat 111 and a feed stopper 113 for separating the feed stopper 113 from the feed stopper 113, And a dimensional measurement unit (120) for calculating the dimension of the pipe (P) based on deformation information generated by contact with the pipe (P)
The dimensional measurement unit (120)
A lifting rod portion 121a spaced apart from the pipe P and a support rod portion 122 rotatably coupled to the lifting rod portion 121a through a support rotary shaft 121; An initial position elastic portion 123 for elastically supporting the support rod portion 122 with respect to the support rod portion 121a to maintain the initial position of the support rod portion 122, A lifting and lowering driving part 124a for lifting and lowering the load part 121a and a lifting and lowering part 124a for lifting and lowering the lifting and lowering part 121a of the lifting rod part 121a when the free end of the supporting rod part 122 is in contact or close contact with the pipe P, And a lift controller (125a) for calculating the dimension of the pipe (P) by using the rotation angle (S) of the support rod part (122). The method according to claim 1,
The second clamping unit 580b,
A cylindrical first expansion unit (510) for holding the first member in a state of being inserted into the first member;
A truncated conical second expansion unit (520) disposed on one side of the first expansion unit (510) and holding the second member in a state of being inserted into the second member;
A pipe support body 530 disposed on the other side of the first expansion unit 510; And
And an expansion control unit 540 for expanding the diameter of the first expansion unit 510 or expanding the diameter of the second expansion unit 520 based on the pipe support 530,
The first expansion unit (510)
At least two first expansion members (511) formed along the circumferential direction of the first member; And
A first elastic ring member (512) elastically supporting the first expansion member (511) in a state of being wrapped around the first expansion member (511) along the circumferential direction of the first member such that the first expansion members (511) / RTI >
The second expansion unit (520)
At least two second extending members (521) formed along the circumferential direction of the second member; And
A second elastic ring member (522) elastically supporting the second expanding member (521) in a state of being wrapped around the second expanding member (521) along the circumferential direction of the second member so as to be in a frustum shape; Shaped movable spool manufacturing system. 3. The method of claim 2,
The piping support 530 includes:
A support body 531 in which a part of the expansion control unit 540 is embedded and the first expansion unit 510 is installed on one side; And
And a gap supporting portion (533) protruding from an outer circumferential surface of the support body (531) to support an inner surface of the first member (533). The method of claim 3,
The expansion control unit 540 controls the expansion /
A first piston (541) reciprocally coupled to the first expansion unit (510) for expanding the diameter of the first expansion unit (510);
A second piston (542) reciprocally coupled to the second expansion unit (520) through the center of the first piston (541) for expanding the diameter of the second expansion unit (520);
A hydraulic means (543) reciprocating at least one of the first piston (541) and the second piston (542) by a fluid to be delivered; And
And a hydraulic supply (544) for supplying fluid to the hydraulic means (543). 5. The method of claim 4,
The expansion control unit 540 controls the expansion /
And a clean unit for supplying a clean gas to a welded portion of the first member and the second member. 6. The method of claim 5,
The cleaning unit includes:
A plurality of ejection holes 5416 spaced apart from each other along the circumferential direction of the spacing member 5413;
A clean flow path 5417 for interconnecting the plurality of spray holes 5416 in a state of being embedded in the first piston 541 to form a clean gas transfer path; And
And a clean gas supply unit (545) for supplying a clean gas to the clean channel (5417). 7. The method according to any one of claims 2 to 6,
The second clamping unit 580b,
And a control unit (550) for controlling the operation of the expansion regulating unit (540) to control whether the first expansion unit (510) is expanded in diameter or whether the second expansion unit (520) is expanded in diameter Wherein the movable spool is mounted on the spool. 8. The method of claim 7,
The control unit (550)
A controller 551 for controlling the operation of the expansion control unit 540;
An expansion control switch 552 for selecting whether to extend the diameter of the first expansion unit 510 or extend the diameter of the second expansion unit 520; And
And a packaging line 553 connecting the controller 551 and the expansion control unit 540 to form a flow path for fluid or clean gas for operation of the expansion control unit 540 Conical Clamp Based Mobile Spool Production System. 7. The method according to any one of claims 2 to 6,
The second clamping unit 580b,
Further comprising a cooling unit (560) for cooling at least one of the first member, the welded portion of the first member and the second member, and the expansion control unit (540) Spool production system. The method according to claim 1,
The cutting device (400)
A vertical cutting unit (410) for cutting the pipe into unit pieces using a cutting tool to form a cross section perpendicular to the longitudinal direction of the pipe;
A slant cutting unit (420) for cutting the pipe into unit pieces using a cutting tool so as to form an inclined cross section in the longitudinal direction of the pipe;
A flame cutting unit (430) for cutting the pipe into unit pieces by using a flame or for puncturing the branch hole by using a flame; And
A fluid cutting unit that cuts the pipe into unit pieces using a high-pressure fluid or punctures the branch hole using a high-pressure fluid;
Wherein the at least one of the first, The method according to claim 1,
The pipeline transfer device 300 includes:
An axial direction transfer unit (310) for moving the pipe or the unit piece in the longitudinal direction;
A cross direction transfer unit (320) for moving the pipe or the unit piece in a direction crossing the longitudinal direction; And
A fitting flow transfer unit for moving the fittings;
Wherein the at least one of the first, The method according to claim 1,
A bending device 600 for bending the pipe or the unit piece according to preset bending information;
An inspection apparatus 700 for inspecting welded areas and specifications of the unit spools completed through the welding apparatus 500; And
A spool storage device (800) for storing the unit spool completed through the welding device (500);
Wherein the at least one of the first, 13. The method of claim 12,
And a plurality of unit bottom members 900a arranged longitudinally and horizontally on the floor, wherein at least the blasting device 200, the cutting device 400, and the welding device 500), the inspection apparatus (700), and a bottom support unit (900) to which the pipe transfer apparatus (300) is detachably installed. 14. The method of claim 13,
The unit bottom member (900a)
A unit plate portion 910 having a predetermined area and thickness;
A fitting groove portion 920 formed on one side of the unit plate portion 910;
A fitting portion 930 protruding from the other side of the unit plate portion 910 so as to be inserted into the fitting groove portion 920 formed in another adjacent unit bottom member 900a; And
A mounting portion 940 which is engaged with the fitting portion 930 inserted into the fitting groove portion 920 when the fitting portion 930 is inserted into the fitting groove portion 920 between mutually adjacent unit bottom members 900a, And wherein the movable spool assembly comprises: 15. The method of claim 14,
The fitting portion 930,
A tilting groove portion 931 formed in the other side surface of the unit plate portion 910 in correspondence with the fitting groove portion 920;
A fitting protrusion 933 rotatably coupled to the pivoting groove 931 through the fitting pivot shaft 932; And
And a mounting hole portion (935) formed through the fitting protrusion (933) to allow the mounting portion (940) to pass therethrough. 15. The method of claim 14,
The mounting portion 940,
A mounting rod portion 941 slidably coupled to one side of the fitting portion 930;
A rod path portion 942 forming a slide movement path of the mounting rod portion 941 so as to communicate with the fitting portion 930;
A lifting lever portion 945 coupled to cross the longitudinal direction of the mounting rod portion 941; And
And a path slit part (944) forming a slide movement path of the lifting lever part (945) so as to communicate with the rod path part (942).

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