CN113263028A - Ultrathin groove oxygen-free copper pipe and pipe drawing method thereof - Google Patents

Abstract

The invention provides an ultrathin groove oxygen-free copper pipe and a pipe drawing method thereof, and relates to the technical field of copper pipes. The pipe clamping device solves the problem that the port of the pipe is clamped by the clamp, but the port of the pipe is damaged when the pipe is clamped, so that the subsequent use is influenced.

Description

Ultrathin groove oxygen-free copper pipe and pipe drawing method thereof

Technical Field

The invention relates to the technical field of copper pipes, in particular to an ultrathin groove oxygen-free copper pipe and a pipe drawing method thereof.

Background

The copper pipe is also called red copper pipe, one kind of non-ferrous metal pipe, and is a pressed and drawn seamless pipe. The copper pipe has the characteristics of good electrical conductivity and thermal conductivity, and the main materials of the conductive fittings and the heat dissipation fittings of electronic products are the first choice for modern contractors to install tap water pipelines, heat supply pipelines and refrigeration pipelines in all residential commodity rooms. The copper pipe has strong corrosion resistance, is not easy to oxidize, does not easily react with some liquid substances, and is easy to be subjected to bright bending modeling.

The copper pipe can be glued a large amount of dirt in the back surface after placing for a long time, need remove dirty with the help of tube drawing machine this moment, and tube drawing machine when pulling the pipe often utilizes the clip to clip the port of pipe, thereby often can lead to the port damage of pipe to influence follow-up use when nevertheless pressing from both sides the pipe like this.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an oxygen-free copper tube with an ultrathin groove and a tube drawing method thereof.

In order to achieve the purpose, the invention adopts the following technical scheme: the ultra-thin groove oxygen-free copper pipe comprises a pipe body and a pulling structure, wherein the pulling structure is arranged on the surface of the pipe body and comprises a semicircular ring, the inner wall of the semicircular ring is movably connected with the pipe body, a connecting groove is formed in the position, corresponding to the semicircular ring, of the pipe body, the size of the connecting groove is matched with the size of the semicircular ring, bolts are inserted into the two ends of the semicircular ring in a threaded mode, nuts are sleeved on the surface of the bolts in a threaded mode, the number of the semicircular rings is two, one ends, far away from each other, of the two semicircular rings are fixedly connected with cylinders, and a first long rod and a second long rod are respectively sleeved on the surfaces of the cylinders in a sliding mode.

Preferably, one end of the first long rod close to the second long rod is rotatably connected with a cylinder, and one end of the second long rod close to the first long rod is fixedly connected with a round bar.

Preferably, the surface of the round bar is in threaded connection with the inner wall of the cylinder, and the surfaces of the first long rod and the second long rod are fixedly connected with arc-shaped plates.

Preferably, the surface of pipe is equipped with connection structure, connection structure includes the lantern ring, the inner wall and the pipe swing joint of the lantern ring, the inside screw thread of the lantern ring is inserted and is equipped with the cutting, the surface cover of cutting has the sill bar, the sill bar is close to the one end fixedly connected with fixed plate of the lantern ring, the surperficial sliding connection of sill bar has the slide, the top of slide is rotated and is connected with the bull stick, the one end that the slide was kept away from to the bull stick has seted up the round hole, the top fixedly connected with long post of fixed plate, the inside screw thread of long post is inserted and is equipped with the inserted post.

Preferably, the sliding plate and the fixing plate are fixedly connected with a silica gel pad at one end close to each other, and the length of the rotating rod is matched with the diameter of the outer wall of the pipe in size.

Preferably, the length of inserting the post is greater than the size of bull stick surface round hole, the quantity of fixed plate is two, two the fixed plate uses the lantern ring to distribute as central symmetry.

Preferably, the surface of pipe is equipped with auxiliary structure, auxiliary structure includes solid fixed ring, gu fixed ring's inner wall and pipe swing joint, gu fixed ring's inside screw thread is inserted and is equipped with the screw rod, gu fixed ring's of screw rod surperficial rotation is connected with the gear, gu fixed ring has the draw runner for the position sliding connection of gear, the surperficial fixedly connected with of gear is long section of thick bamboo, the one end fixedly connected with rectangular rod of gear is kept away from to long section of thick bamboo.

Preferably, the inside of gear slides and inserts and is equipped with hexagonal prism, hexagonal prism's fixed surface is connected with the lug, gu fixed ring has seted up hexagonal groove for the position of gear, the size of hexagonal groove and the size looks adaptation of hexagonal prism, rectangular channel has been seted up on the surface of long section of thick bamboo, the size of rectangular channel and the size looks adaptation of lug.

Preferably, the number of the sliding strips is two, two grooves are formed in the ends, close to each other, of the sliding strips, the gear is meshed with the two sliding strips through the grooves, and the two sliding strips are symmetrically distributed by taking the gear as a central shaft.

Preferably, the method for drawing the oxygen-free copper tube with the ultrathin groove is used for drawing the copper tube and comprises the following steps:

s1, placing the tube drawing machine on a work site and connecting a power supply, and then placing the tube near the tube drawing machine at a position convenient to take;

s2, coating a layer of lubricating oil on the conveying belt on the surface of the pipe drawing machine by an operator, and then checking whether the pipe drawing machine is in error operation;

s3, sleeving the two semicircular rings on the surface of the pipe, and connecting the two semicircular rings together by means of bolts and nuts in the semicircular rings to enable the two semicircular rings to be firmly clamped on the surface of the pipe;

s4, connecting a dragging machine on the pipe drawing machine with the first long rod, and starting the pipe drawing machine to operate;

s5, when the dragging machine pulls the pipe, the surface of the pipe passes through the through hole on the surface of the pipe drawing machine, and at the moment, the scraper on the surface of the through hole scrapes dirt on the surface of the pipe;

s6, when the tube drawing is finished, closing the tube drawing machine, taking the tube out of the tube drawing machine, and putting the next tube;

and S7, when the dirty parts of the pipe are completely removed, sleeving the lantern ring on the surface of the pipe, and placing the pipe between the fixed plate and the sliding plate so as to carry the pipe together.

Compared with the prior art, the invention has the advantages and positive effects that,

1. according to the invention, through arranging the pulling structure, the two semicircular rings are firstly clamped in the connecting groove on the surface of the pipe, because the size of the semicircular rings is matched with that of the connecting groove, the two semicircular rings are difficult to shake left and right, then the bolt is inserted into the semicircular rings, the nut is screwed on the bolt, at the same time, the nut and the bolt firmly fix the two semicircular rings, then the first long rod is sleeved in the cylinder, then the second long rod is sleeved on the cylinder, meanwhile, the round bar on the surface of the second long rod is inserted in the cylinder, then the cylinder is rotated, because the inner wall of the cylinder is in threaded connection with the round bar, the cylinder drives the round bar to move, because the second long rod is limited by the cylinder, at the moment, the second long rod can only move up and down, at the moment, the round bar drives the second long rod to be close to the first long rod, the first long rod clamps the two semicircular rings with the second long rod through the cylinder, at this moment can insert the iron plate between arc and first stock, and the first stock and second stock are dragged to the tractor accessible through cliping the iron plate, avoid the direct clamp of tractor to get the pipe, and whole structure has solved the clip and has cliped the port of pipe, thereby often can lead to the port damage of pipe to influence the problem of follow-up use when nevertheless pressing from both sides the pipe like this.

2. In the invention, by arranging a connecting structure, a sleeve ring is sleeved on a pipe, then a cutting bar in the sleeve ring is screwed, the cutting bar extrudes the pipe to limit the movement of the sleeve ring, then the pipe is horizontally placed on the ground, at the same time, a bottom rod on the surface of the sleeve ring is expanded, meanwhile, the other two pipes are placed on the bottom rod, then a rotating rod pulls a sliding plate to slide, at the same time, the sliding plate moves towards the direction of a fixed plate, because the ends, close to each other, of the sliding plate and the fixed plate are fixedly connected with a silica gel pad, at the same time, the fixed plate and the sliding plate extrude the subsequently placed pipes by the silica gel pad, at the same time, the placed pipes are limited to move, at the same time, the rotating rod is sleeved on the surface of a long column through a circular hole on the surface of the rotating rod, at the same time, because the size of the circular hole on the surface of the rotating rod is larger than that of the long column, at the long column is sleeved without limitation, then the cutting bar is inserted into the long column, because the length of inserting the post is greater than the size of round hole, insert the post and will restrict the bull stick and outwards rotate this moment, the both ends of pipe all are equipped with connection structure simultaneously, and whole structure has solved in the semicircle pipe, because the easy roll of pipe, when carrying a plurality of pipes simultaneously, because do not restrict easy relative roll between pipe and the pipe to lead to the workman to be difficult to control the pipe when the transport, the easy landing leads to pounding oneself.

3. In the invention, the auxiliary structure is arranged, the fixing ring is sleeved on the pipe, the screw rod is screwed at the same time, the screw rod firmly extrudes the pipe so as to limit the movement of the fixing ring, then the convex block slides upwards through the convex block, the convex block drives the hexagonal prism to slide out of the hexagonal groove on the surface of the fixing ring when sliding upwards, then the long cylinder is rotated through the rectangular rod, the gear is driven to rotate when the long cylinder rotates, the gear drives the two sliding strips to slide towards the direction far away from each other, meanwhile, the ends of the sliding strips, which are far away from each other, are fixedly connected with a silica gel pad, when the pipe is placed between two walls, thereby can firmly support two walls and prop up the pipe, avoid the pipe to drop, whole structure has solved when the pipe need be installed between two walls, often need use the screw to punch fixedly, and the screw can destroy the problem of wall this moment.

Drawings

FIG. 1 is a schematic view of a three-dimensional structure of an oxygen-free copper tube with an ultrathin groove and a tube drawing method thereof;

FIG. 2 is a schematic view of the bottom side structure of FIG. 1 in an oxygen-free copper tube with an ultra-thin groove and a tube drawing method thereof according to the present invention;

FIG. 3 is a partial schematic view of a drawing structure of an oxygen-free copper tube with an ultrathin groove and a tube drawing method thereof according to the present invention;

FIG. 4 is a schematic view of the structure at B of FIG. 1 in the method for drawing an oxygen-free copper tube with ultra-thin grooves according to the present invention;

FIG. 5 is a partial schematic view of a connection structure of an oxygen-free copper tube with an ultra-thin groove and a tube drawing method thereof according to the present invention;

FIG. 6 is a schematic view of the structure at the position A in FIG. 5 in the method for drawing an oxygen-free copper tube with ultra-thin grooves according to the present invention;

FIG. 7 is a partial schematic view of an auxiliary structure of an oxygen-free copper tube with an ultra-thin groove and a tube drawing method thereof according to the present invention;

fig. 8 is a schematic view of a portion of the structure of fig. 7 in an oxygen-free copper tube with an ultrathin trench and a tube drawing method thereof according to the present invention.

Illustration of the drawings: 1. a tube; 2. pulling the structure; 21. a semicircular ring; 22. a cylinder; 23. a bolt; 24. connecting grooves; 25. a first long rod; 26. an arc-shaped plate; 27. a cylinder; 28. round bars; 29. a second long rod; 3. a connecting structure; 31. a collar; 32. cutting; 33. a bottom bar; 34. a slide plate; 35. a fixing plate; 36. a rotating rod; 37. a long column; 38. inserting a column; 4. an auxiliary structure; 41. a fixing ring; 42. a screw; 43. a slide bar; 44. a gear; 45. a hexagonal prism; 46. a bump; 47. a long cylinder; 48. a rectangular bar.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and thus the present invention is not limited to the specific embodiments of the present disclosure.

Embodiment 1, as shown in fig. 1 to 8, the present invention provides an ultra-thin groove oxygen-free copper tube and a tube drawing method thereof, including a tube 1 and a drawing structure 2, wherein the drawing structure 2 is provided on the surface of the tube 1.

The method comprises the following steps:

s1, placing the tube drawing machine on a work site and connecting a power supply, and then placing the tube 1 at a position which is convenient to take near the tube drawing machine;

s2, coating a layer of lubricating oil on the conveying belt on the surface of the pipe drawing machine by an operator, and then checking whether the pipe drawing machine is in error operation;

s3, sleeving the two semicircular rings 21 on the surface of the pipe 1, and connecting the two semicircular rings 21 together by means of the bolts 23 and the nuts in the semicircular rings 21 so as to firmly clamp the two semicircular rings 21 on the surface of the pipe 1;

s4, connecting a dragging machine on the pipe drawing machine with the first long rod 25, and starting the pipe drawing machine to operate;

s5, when the dragging machine pulls the pipe 1, the surface of the pipe 1 passes through the through hole on the surface of the pipe drawing machine, and at the moment, the scraper on the surface of the through hole scrapes dirt on the surface of the pipe 1;

s6, after the tube drawing is finished, closing the tube drawing machine, taking the tube 1 out of the tube drawing machine, and putting the next tube 1;

s7, when the pipe 1 is completely cleaned, the lantern ring 31 is sleeved on the surface of the pipe 1, and the pipe 1 is placed between the fixed plate 35 and the sliding plate 34 to be carried together.

The specific arrangement and function of the pulling structure 2, the connecting structure 3 and the auxiliary structure 4 will be described in detail below.

As shown in fig. 1 and fig. 3, the pulling structure 2 includes a semicircular ring 21, the inner wall of the semicircular ring 21 is movably connected with the pipe 1, the pipe 1 is provided with a connecting groove 24 corresponding to the position of the semicircular ring 21, the size of the connecting groove 24 is matched with the size of the semicircular ring 21, bolts 23 are inserted into both ends of the semicircular ring 21, a nut is screwed on the surface of each bolt 23, the number of the semicircular rings 21 is two, a cylinder 22 is fixedly connected to each end of the two semicircular rings 21 far away from each other, a first long rod 25 and a second long rod 29 are respectively slidingly sleeved on the surface of the cylinder 22, the two semicircular rings 21 are firstly clamped in the connecting groove 24 on the surface of the pipe 1, due to the matching between the size of the semicircular rings 21 and the size of the connecting groove 24, the two semicircular rings 21 are difficult to shake left and right, then the bolts 23 are inserted into the semicircular rings 21, the nuts are simultaneously screwed on the bolts 23, at this time, the nuts and the bolts 23 firmly fix the two semicircular rings 21, then the first long rod 25 is sleeved into the cylinder 22, then the second long rod 29 is sleeved on the cylinder 22, meanwhile, the round bar 28 on the surface of the second long rod 29 is inserted into the cylinder 27, one end of the first long rod 25 close to the second long rod 29 is rotatably connected with the cylinder 27, one end of the second long rod 29 close to the first long rod 25 is fixedly connected with the round bar 28, the surface of the round bar 28 is in threaded connection with the inner wall of the cylinder 27, the surfaces of the first long rod 25 and the second long rod 29 are both fixedly connected with the arc-shaped plate 26, then the cylinder 27 is rotated, as the inner wall of the cylinder 27 and the round bar 28 are in threaded connection, the cylinder 27 drives the round bar 28 to move, as the second long rod 29 is limited by the cylinder 22, at this time, the second long rod 29 can only move up and down, at this time, the round bar 28 drives the second long rod 29 close to the first long rod 25, the first long rod 25 and the second long rod 29 clamp two semicircular rings 21 through the cylinder 22, in this case, it is possible to insert an iron block between the arc 26 and the first long rod 25, and the dragging machine can drag the first long rod 25 and the second long rod 29 by gripping the iron block, avoiding the dragging machine from gripping the pipe 1 directly.

The whole pulling structure 2 has the effects that by arranging the pulling structure 2, the two semicircular rings 21 are clamped in the connecting groove 24 on the surface of the pipe 1, because the size of the semicircular rings 21 is matched with that of the connecting groove 24, the two semicircular rings 21 are difficult to shake left and right at the moment, then the bolt 23 is inserted into the semicircular rings 21, the nut is screwed on the bolt 23, the nut and the bolt 23 are firmly fixed on the two semicircular rings 21 at the moment, then the first long rod 25 is sleeved in the cylinder 22, then the second long rod 29 is sleeved on the cylinder 22, meanwhile, the round bar 28 on the surface of the second long rod 29 is inserted in the cylinder 27, then the cylinder 27 is rotated, because the inner wall of the cylinder 27 and the round bar 28 are in threaded connection, at the moment, the cylinder 27 drives the round bar 28 to move, because the second long rod 29 is limited by the cylinder 22, at the moment, the second long rod 29 only can move up and down, at the moment, the round bar 28 drives the second long rod 29 to be close to the first long rod 25, first stock 25 will clip two semicircle rings 21 through cylinder 22 with second stock 29, can insert the iron plate at this moment between arc 26 and first stock 25, and the first stock 25 and second stock 29 are dragged to the dilatory machine accessible clip iron plate, avoid the direct clamp of dilatory machine to get pipe 1, and the port of pipe 1 is cliied to the clip has been solved to whole structure, thereby often can lead to the port damage of pipe 1 to influence the problem of follow-up use when nevertheless pressing from both sides pipe 1 like this.

As shown in fig. 1 and 5, a connecting structure 3 is provided on the surface of a pipe 1, the connecting structure 3 includes a collar 31, the inner wall of the collar 31 is movably connected with the pipe 1, an insert strip 32 is inserted into the internal thread of the collar 31, a bottom rod 33 is sleeved on the surface of the insert strip 32, one end of the bottom rod 33 close to the collar 31 is fixedly connected with a fixing plate 35, the surface of the bottom rod 33 is slidably connected with a sliding plate 34, the top end of the sliding plate 34 is rotatably connected with a rotating rod 36, one end of the rotating rod 36 far from the sliding plate 34 is provided with a round hole, the top end of the fixing plate 35 is fixedly connected with a long column 37, the internal thread of the long column 37 is inserted with an insert column 38, the collar 31 is firstly sleeved on the pipe 1, then the insert strip 32 inside the collar 31 is screwed, at this time, the insert strip 32 will press the pipe 1 to limit the movement of the collar 31, then the pipe 1 is laid on the ground, at this time, the bottom rod 33 on the surface of the collar 31 will be opened, and at the same time two other pipes 1 are placed on the bottom rod 33, then the sliding plate 34 is pulled to slide by the rotating rod 36, at this time, the sliding plate 34 will move towards the direction of the fixing plate 35, because the ends of the sliding plate 34 and the fixing plate 35 close to each other are fixedly connected with a silica gel pad, at this time, the fixing plate 35 and the sliding plate 34 will press the subsequently placed tube 1 by means of the silica gel pad, at this time, the placed tube 1 will be limited to move, at this time, the rotating rod 36 will be sleeved on the surface of the long column 37 through the circular hole on the surface thereof, because the size of the circular hole on the surface of the rotating rod 36 is larger than that of the long column 37, at this time, the long column 37 will not be sleeved, the ends of the sliding plate 34 and the fixing plate 35 close to each other are fixedly connected with a silica gel pad, the length of the rotating rod 36 is matched with the size of the outer wall diameter of the tube 1, the length of the insert column 38 is larger than that of the circular hole on the surface of the rotating rod 36, the number of the fixing plates 35 is two, and the two fixing plates 35 are symmetrically distributed with the lantern ring 31 as the center, the post 38 is then inserted into the long post 37, and since the length of the post 38 is greater than the size of the circular hole, the post 38 will restrict the rotation of the rotating rod 36 and the connecting structures 3 are provided at both ends of the pipe 1.

The whole connecting structure 3 achieves the effect that by arranging the connecting structure 3, the lantern ring 31 is firstly sleeved on the pipe 1, then the inserting strips 32 in the lantern ring 31 are screwed, at the moment, the inserting strips 32 press the pipe 1 to limit the movement of the lantern ring 31, then, the pipe 1 is flatly placed on the ground, at the moment, the bottom rod 33 on the surface of the lantern ring 31 is opened, at the same time, the other two pipes 1 are placed on the bottom rod 33, then, the sliding plate 34 is pulled by the rotating rod 36 to slide, at the moment, the sliding plate 34 moves towards the direction of the fixing plate 35, because the silicon rubber pad is fixedly connected to one end of the sliding plate 34, which is close to the fixing plate 35, at the moment, the fixing plate 35 and the sliding plate 34 press the subsequently placed pipe 1 by the silicon rubber pad, at the moment, the placed pipe 1 is limited to move, at the moment, the rotating rod 36 is sleeved on the surface of the long column 37 by the circular hole on the surface of the rotating rod 36, and because the circular hole on the surface of the rotating rod 36 is larger than the size of the long column 37, at this moment, the long column 37 is sleeved without limitation, then the inserting column 38 is inserted into the long column 37, because the length of the inserting column 38 is larger than the size of a round hole, at this moment, the inserting column 38 limits the rotating rod 36 to rotate outwards, and meanwhile, the two ends of the pipe 1 are respectively provided with the connecting structure 3, the whole structure solves the problems that when the semicircular pipe 1 is carried, the pipe 1 is easy to roll, when a plurality of pipes 1 are carried simultaneously, the pipe 1 and the pipe 1 are easy to roll relatively due to no limitation, so that a worker is difficult to control the pipe 1 when carrying the pipe, and the pipe 1 is easy to slide down to injure the worker.

Example 2, on the basis of example 1, as shown in fig. 1 and 7, an auxiliary structure 4 is disposed on the surface of a tube 1, the auxiliary structure 4 includes a fixing ring 41, the inner wall of the fixing ring 41 is movably connected with the tube 1, a screw rod 42 is inserted into the inner thread of the fixing ring 41, a gear 44 is rotatably connected to the surface of the fixing ring 41 of the screw rod 42, a slide bar 43 is slidably connected to the position of the fixing ring 41 relative to the gear 44, a long cylinder 47 is fixedly connected to the surface of the gear 44, a rectangular rod 48 is fixedly connected to one end of the long cylinder 47 far from the gear 44, the fixing ring 41 is firstly sleeved on the tube 1, the screw rod 42 is simultaneously screwed, the screw rod 42 firmly presses the tube 1 to limit the movement of the fixing ring 41, then the lug 46 slides upwards, the lug 46 drives the hexagonal prism 45 to slide out of the hexagonal groove on the surface of the fixing ring 41 when sliding upwards, then the lug 46 rotates the long cylinder 47 through the rectangular rod 48, the rotation of the long tube 47 will drive the gear 44 to rotate, at this time, the gear 44 will drive the two sliding strips 43 to slide in the direction away from each other, while the ends of the slides 43 remote from each other are fixedly connected with a silicone pad, when the tube 1 is placed between two walls, can firmly support two walls thereby prop up pipe 1, avoid pipe 1 to drop, the inside slip of gear 44 is inserted and is equipped with hexagonal prism 45, hexagonal prism 45's fixed surface is connected with lug 46, six edge grooves have been seted up to fixed ring 41 for gear 44's position, six edge grooves's size and hexagonal prism 45's size looks adaptation, the rectangular channel has been seted up on long section of thick bamboo 47's surface, the size of rectangular channel and the size looks adaptation of lug 46, the quantity of draw runner 43 is two, the recess has all been seted up to the one end that two draw runners 43 are close to each other, gear 44 meshes with two draw runners 43 with the help of the recess, two draw runners 43 use gear 44 to be the central axis symmetric distribution.

The effect that its whole auxiliary structure 4 reaches is, through setting up auxiliary structure 4, first fixed ring 41 overlaps on pipe 1, twist screw rod 42 simultaneously, screw rod 42 will firmly extrude pipe 1 at this moment and thus restrict the removal of fixed ring 41, upwards slide lug 46 through lug 46, lug 46 can drive hexagonal prism 45 from the hexagon inslot roll-off on fixed ring 41 surface when upwards sliding, then rotate long section of thick bamboo 47 through rectangular rod 48, long section of thick bamboo 47 will drive gear 44 to rotate when rotating, gear 44 can drive two slivers 43 to slide towards the direction of keeping away from each other this moment, the one end that slivers 43 kept away from each other all is fixedly connected with the silica gel pad simultaneously, at this moment when pipe 1 is being placed between two walls, can firmly support two walls and thus prop up pipe 1, avoid pipe 1 to drop, whole structure has solved when pipe 1 needs to install between two walls, the screw is often used for punching and fixing, and the screw can damage the wall at the moment.

The above description is only a preferred embodiment of the present invention, and not intended to limit the present invention in other forms, and any person skilled in the art may apply the above modifications or changes to the equivalent embodiments with equivalent changes, without departing from the technical spirit of the present invention, and any simple modification, equivalent change and change made to the above embodiments according to the technical spirit of the present invention still belong to the protection scope of the technical spirit of the present invention.

Claims (10)

1. The utility model provides an ultra-thin slot oxygen-free copper pipe, includes pipe (1) and draws and get structure (2), its characterized in that: the surface of pipe (1) is equipped with to draw and gets structure (2), draw and get structure (2) including semicircle ring (21), the inner wall and pipe (1) swing joint of semicircle ring (21), spread groove (24) have been seted up for the position of semicircle ring (21) in pipe (1), the size of spread groove (24) and the size looks adaptation of semicircle ring (21), the equal screw thread in both ends of semicircle ring (21) is inserted and is equipped with bolt (23), the surperficial screw thread cover of bolt (23) has the nut, the quantity of semicircle ring (21) is two, two the equal fixedly connected with cylinder (22) of one end that semicircle ring (21) kept away from each other, the surface of cylinder (22) slip the cover respectively has first stock (25), second stock (29).

2. The ultra-thin groove oxygen-free copper tube of claim 1, wherein: one end of the first long rod (25) close to the second long rod (29) is rotatably connected with a cylinder (27), and one end of the second long rod (29) close to the first long rod (25) is fixedly connected with a round bar (28).

3. The ultra-thin groove oxygen-free copper tube of claim 2, wherein: the surface of the round bar (28) is in threaded connection with the inner wall of the cylinder (27), and the surfaces of the first long rod (25) and the second long rod (29) are fixedly connected with an arc-shaped plate (26).

4. The ultra-thin groove oxygen-free copper tube of claim 1, wherein: the surface of pipe (1) is equipped with connection structure (3), connection structure (3) are including the lantern ring (31), the inner wall and pipe (1) swing joint of the lantern ring (31), the inside screw thread of the lantern ring (31) is inserted and is equipped with cutting (32), the surface cover of cutting (32) has sill bar (33), sill bar (33) are close to one end fixedly connected with fixed plate (35) of the lantern ring (31), the surperficial sliding connection of sill bar (33) has slide (34), the top of slide (34) is rotated and is connected with bull stick (36), the round hole has been seted up to the one end that slide (34) were kept away from in bull stick (36), the top fixedly connected with long post (37) of fixed plate (35), the inside screw thread of long post (37) is inserted and is equipped with inserted post (38).

5. The ultra-thin groove oxygen-free copper tube of claim 4, wherein: the one end that slide (34) and fixed plate (35) are close to each other all fixedly connected with silica gel pad, the size looks adaptation of length and pipe (1) outer wall diameter of bull stick (36).

6. The ultra-thin groove oxygen-free copper tube of claim 4, wherein: the length of inserting the post (38) is greater than the size of bull stick (36) surface round hole, the quantity of fixed plate (35) is two, two fixed plate (35) use lantern ring (31) as central symmetry distribution.

7. The ultra-thin groove oxygen-free copper tube of claim 1, wherein: the surface of pipe (1) is equipped with auxiliary structure (4), auxiliary structure (4) are including solid fixed ring (41), the inner wall and pipe (1) swing joint of solid fixed ring (41), the internal thread of solid fixed ring (41) is inserted and is equipped with screw rod (42), the surperficial rotation of solid fixed ring (41) of screw rod (42) is connected with gear (44), gu fixed ring (41) have draw runner (43) for the position sliding connection of gear (44), the fixed surface of gear (44) is connected with long section of thick bamboo (47), the one end fixedly connected with rectangular rod (48) of gear (44) are kept away from to long section of thick bamboo (47).

8. The ultra-thin groove oxygen-free copper tube of claim 7, wherein: the novel gear box is characterized in that a hexagonal prism (45) is inserted into the gear (44) in a sliding mode, a convex block (46) is fixedly connected to the surface of the hexagonal prism (45), a hexagonal groove is formed in the position, corresponding to the gear (44), of the fixing ring (41), the size of the hexagonal groove is matched with that of the hexagonal prism (45), a rectangular groove is formed in the surface of the long cylinder (47), and the size of the rectangular groove is matched with that of the convex block (46).

9. The ultra-thin groove oxygen-free copper tube of claim 7, wherein: the number of the sliding strips (43) is two, grooves are formed in the ends, close to each other, of the two sliding strips (43), the gear (44) is meshed with the two sliding strips (43) through the grooves, and the two sliding strips (43) are symmetrically distributed by taking the gear (44) as a central shaft.

10. A tube drawing method of an oxygen-free copper tube with an ultrathin groove is used for drawing the copper tube, and is characterized in that: the method comprises the following steps:

s1, placing the tube drawing machine on a work site and connecting a power supply, and then placing the tube (1) at a position which is convenient to take near the tube drawing machine;

s2, coating a layer of lubricating oil on the conveying belt on the surface of the pipe drawing machine by an operator, and then checking whether the pipe drawing machine is in error operation;

s3, sleeving the two semicircular rings (21) on the surface of the pipe (1), and connecting the two semicircular rings (21) together by means of bolts (23) and nuts inside the semicircular rings (21) so as to firmly clamp the semicircular rings on the surface of the pipe (1);

s4, connecting a dragging machine on the pipe drawing machine with the first long rod (25), and starting the pipe drawing machine to operate;

s5, when the dragging machine pulls the pipe (1), the surface of the pipe (1) passes through the through hole on the surface of the pipe drawing machine, and at the moment, the scraper on the surface of the through hole scrapes dirt on the surface of the pipe (1);

s6, when the tube drawing is finished, closing the tube drawing machine, taking the tube (1) out of the tube drawing machine, and putting the next tube (1) on the tube drawing machine;

s7, when the pipe (1) is completely cleaned, the lantern ring (31) is sleeved on the surface of the pipe (1), and the pipe (1) is placed between the fixing plate (35) and the sliding plate (34) to be carried together.

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