CN113245969A

CN113245969A - Composite pipe machining system and machining method thereof

Info

Publication number: CN113245969A
Application number: CN202110542740.8A
Authority: CN
Inventors: 姜睿泓
Original assignee: Individual
Current assignee: Hunan Guangtong Plastic Industry Co ltd
Priority date: 2021-05-19
Filing date: 2021-05-19
Publication date: 2021-08-13
Anticipated expiration: 2041-05-19
Also published as: CN113245969B

Abstract

The invention relates to the field of pipe processing, in particular to a composite pipe processing system and a processing method thereof. The utility model provides a compound tubular product system of processing, includes arc clamp plate, cross slot and cutter, be provided with the cross slot on the arc clamp plate, cross slot department is provided with the cutter, and the cutter can insert the cross slot. The utility model provides a compound tubular product system of processing still includes cutter seat, guide arm and side seat, the equal fixedly connected with side seat in the left and right sides of arc clamp plate, equal fixedly connected with guide arm on two side seats, fixedly connected with cutter seat on the cutter, the both ends difference sliding connection of cutter seat is on two guide arms. A method for processing a composite pipe by a composite pipe processing system comprises the following steps: (A) grinding a plurality of triangular grooves on the outer peripheral surface of the pipe body; (B) respectively bonding a plurality of metal plates at a plurality of triangular grooves; (C) pressing the middle part of the metal plate into the triangular groove; (D) two collars are sleeved on the outer sides of the metal plates.

Description

Composite pipe machining system and machining method thereof

Technical Field

The invention relates to the field of pipe processing, in particular to a composite pipe processing system and a processing method thereof.

Background

The invention discloses a code spraying device for pipe processing, which is disclosed by the patent number 201811490093.5 and comprises a code spraying device body for pipe processing, wherein a transmission rod is connected to the left side of the lower part of the code spraying device body for pipe processing, a guide roller is fixed to the left side of the lower part of the transmission rod, a bearing frame is arranged on the left side of the lower part of the guide roller, a sleeve is arranged on the right side of the upper part of the bearing frame, a positioning bolt is connected to the left side of the lower part of the sleeve, a bearing foot bar is fixed to the right side of the lower part of the positioning bolt, an installation plate is connected to the right side of the upper part of the bearing foot bar, a cleaning block is fixed to the left side of the lower part of the installation plate, a transmission chain is fixed to the right side of the lower part of the cleaning block, a code spraying device is arranged on the left side of the upper part of the transmission chain, a workbench is fixed to the right side of the lower part of the code spraying device, and a moving device is arranged on the lower part of the workbench. This tubular product processing is with spouting yard device simple structure, the function is practical, can satisfy tubular product processing with spouting the practical demand that yard device trade was spouted with spouting yard device to tubular product processing. However, this patent fails to attach metal plates to the outside of the tubing to form a reinforced composite tubing.

Disclosure of Invention

The invention provides a composite pipe processing system and a processing method thereof to overcome the defects of the prior art, and has the beneficial effect that the metal plate can be conveniently connected to the outer side of the pipe to form a reinforced composite pipe.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the utility model provides a compound tubular product system of processing, includes arc clamp plate, cross slot and cutter, be provided with the cross slot on the arc clamp plate, cross slot department is provided with the cutter, and the cutter can insert the cross slot.

The utility model provides a compound tubular product system of processing still includes cutter seat, guide arm and side seat, the equal fixedly connected with side seat in the left and right sides of arc clamp plate, equal fixedly connected with guide arm on two side seats, fixedly connected with cutter seat on the cutter, the both ends difference sliding connection of cutter seat is on two guide arms.

The utility model provides a compound tubular product system of processing still includes telescopic link I, equal fixedly connected with telescopic link I on two guide arms, and the equal fixed connection of expansion end of two telescopic link I is on the cutter seat.

The composite pipe machining system further comprises slot seats and slots, the slot seats are arranged on the outer sides of the two side seats, and the slots are arranged on the slot seats.

The utility model provides a compound tubular product system of processing still includes side post and arc bullet pole, the equal fixedly connected with side post in the outside of two side seats, and two slot seats are sliding connection respectively on two side posts, the equal fixedly connected with arc bullet pole of the tip of two side posts, and the other end of two arc bullet poles is fixed connection respectively on two slot seats.

The composite pipe processing system is used for processing a composite pipe and comprises a pipe body and metal plates, wherein the metal plates are arranged on the outer side of the pipe body.

The composite pipe further comprises triangular grooves, a plurality of triangular grooves are evenly distributed on the outer peripheral surface of the pipe body, a plurality of metal plates are respectively bonded at the positions of the triangular grooves, and the middle parts of the metal plates are pressed into the triangular grooves, so that the metal plates are conveniently connected.

The composite pipe further comprises lantern rings, wherein lantern rings are sleeved at two ends of the pipe body, and the lantern rings are sleeved on the metal plates.

The utility model provides a compound tubular product system of processing still includes crossbeam, slide bar, rolls over frame and telescopic link II, rolls over the upper end fixed connection of frame and at the downside of arc clamp plate, rolls over the lower part of frame and is fixed with the slide bar, and slide bar sliding connection is on the crossbeam, fixedly connected with telescopic link II on the crossbeam, and telescopic link II's expansion end links firmly on rolling over the frame.

A method for processing a composite pipe by a composite pipe processing system comprises the following steps:

(A) grinding a plurality of triangular grooves on the outer peripheral surface of the pipe body;

(B) respectively bonding a plurality of metal plates at a plurality of triangular grooves;

(C) pressing the middle part of the metal plate into the triangular groove;

(D) two collars are sleeved on the outer sides of the metal plates.

Thus, according to some embodiments of the present disclosure,

the invention can facilitate the connection of the metal plate to the outer side of the pipe to form the reinforced composite pipe.

Drawings

The present disclosure may be more clearly understood from the following detailed description, taken with reference to the accompanying drawings, in which:

FIG. 1 is a first schematic structural view of a composite pipe processing system;

FIG. 2 is a schematic structural diagram II of a composite pipe processing system;

FIG. 3 is a first schematic structural view of the arc pressing plate and the socket base;

FIG. 4 is a second schematic structural view of the arc pressing plate and the socket base;

FIG. 5 is a schematic structural view of a cross beam;

FIG. 6 is a schematic structural view of the stand;

FIG. 7 is a schematic structural view of the undercarriage and the grinding carriage;

FIG. 8 is a schematic view of the structure of the grinding wheel frame;

FIG. 9 is a schematic structural view of the tube;

fig. 10 is a schematic view of a pipe body installed on a composite pipe processing system.

In the figure: an arc pressing plate 101; a transverse slot 102; a cutter holder 103; a cutter 104; a telescopic rod I105; a guide rod 106; a side seat 107; a socket base 201; a slot 202; side posts 203; an arc-shaped elastic rod 204; a cross beam 301; a slide bar 302; a folding frame 303; a telescopic rod II 304; a stand 401; a motor I402; a shaft 403; a rotating rod 404; a stop projection 405; an inner clip 406; a chassis 501; a support 502; a motor II 503; a lead screw 504; a column 505; a telescopic rod III 506; a slider 507; a wheel carrier 601; a motor III 602; a grinding wheel 603; a pipe body 701; a triangular groove 702; a collar 703; a metal plate 704.

Detailed Description

As an example, as shown in fig. 3 to 4 and fig. 9 to 10, this example solves the problem of mounting the metal plate 704 on the pipe body 701,

because the arc pressing plate 101 is provided with the transverse groove 102, the cutter 104 is arranged at the transverse groove 102, and the cutter 104 can be inserted into the transverse groove 102 when moving, when the metal plate 704 is required to be installed on the pipe body 701, the metal plate 704 is placed on the outer side of the pipe body 701, then the arc pressing plate 101 is pressed to the metal plate 704 on the pipe body 701, then the cutter 104 is moved into the transverse groove 102, then the metal plate 704 is inserted into the triangular groove 702 on the pipe body 701, further the metal plate 704 is prevented from moving relative to the pipe body 701, and the metal plate 704 can reinforce the pipe body 701, so that the composite pipe is formed.

In addition, as an example, as shown in fig. 3 to 4, this example solves the problem of allowing the cutting blade 104 to be inserted into the lateral groove 102 while moving,

because the left and right sides of arc pressing plate 101 is provided with side seat 107, all fixedly connected with guide arm 106 on every side seat 107, and fixedly connected with cutter seat 103 on cutter 104, sliding connection is on two guide arms 106 respectively at the both ends of cutter seat 103, and then make cutter seat 103 slide around on two guide arms 106, and then drive cutter 104 and slide around, can insert cross slot 102 when making cutter 104 remove, then make arc pressing plate 101 press to the metal sheet 704 on body 701, then make cutter 104 remove to cross slot 102, then insert the triangle groove 702 on the body 701 with metal sheet 704.

In addition, as an example, as shown in fig. 3 to 4, this example solves the problem of driving the cutter holder 103 to slide back and forth on the two guide rods 106,

because the two guide rods 106 are fixedly connected with the telescopic rods I105, the telescopic rods I105 can conveniently drive the cutter seat 103 to slide back and forth on the two guide rods 106 when extending. So that the cutting knife 104 can be inserted into the transverse groove 102 when moving, then the arc pressing plate 101 is pressed against the metal plate 704 on the pipe body 701, then the cutting knife 104 is moved into the transverse groove 102, and then the metal plate 704 is inserted into the triangular groove 702 on the pipe body 701.

In addition, as an example, as shown in fig. 3 to 4 and fig. 9 to 10, this example solves the problem of facilitating the pressing of the metal plate 704 toward the tubular body 701,

because the slot seats 201 are arranged on the outer sides of the two side seats 107, and the slots 202 are arranged on the slot seats 201, when the metal plate 704 is installed on the pipe body 701, the two ends of the metal plate 704 can be inserted into the slots 202 on the two side seats 107 respectively, then the arc pressing plate 101 is moved to press the pipe body 701, at this time, the metal plate 704 can also press the pipe body 701 along with the movement, and further the metal plate 704 can be pressed to the pipe body 701 conveniently.

In addition, as an example, as shown in fig. 3-4, this example solves the problem that two slot housings 201 are close to each other, so as to clamp and fix different sizes of metal plates 704,

because two jambs 203 are fixed connection respectively in the outside of two side seats 107, equal sliding connection has slot seat 201 on two jambs 203, and the equal fixedly connected with arc bullet pole 204 of the tip of two jambs 203, the other end of two arc bullet poles 204 is fixed connection respectively on two slot seats 201, make at this moment two arc bullet poles 204 give the power that two slot seats 201 are close to each other respectively, make two slot seats 201 close to each other, be convenient for press from both sides the fixed with not equidimension metal sheet 704.

In addition, as an example, as shown in fig. 9, this example solves the problem of reinforcing the outside of the pipe body 701 by a plurality of metal plates 704,

since the plurality of metal plates 704 are bonded to the outer side of pipe 701, the outer side of pipe 701 is reinforced by the plurality of metal plates 704.

In addition, as an example, as shown in fig. 9, this example solves the problem of avoiding the movement of the metal plate 704 with respect to the tubular body 701,

because a plurality of triangular grooves 702 are uniformly distributed on the outer peripheral surface of the pipe body 701, and a plurality of metal plates 704 are respectively arranged at the plurality of triangular grooves 702, the middle parts of the metal plates 704 are pressed into the triangular grooves 702, so that the metal plates 704 are prevented from moving relative to the pipe body 701, and the metal plates 704 can reinforce the pipe body 701 to form the composite pipe.

In addition, as an example, as shown in fig. 9, this example solves the problem of fixing a plurality of metal plates 704 to the outside of the pipe body 701,

since collar 703 is fitted around the outer sides of metal plates 704, metal plates 704 are fixed to the outer side of pipe 701.

In addition, as an example, as shown in fig. 7 to 8, this example solves the problem of facilitating the pressing of the arc pressing plate 101 against the pipe body 701,

because the upper end of the folding frame 303 is fixedly connected to the lower side of the arc pressing plate 101, the lower part of the folding frame 303 is fixedly connected with a sliding rod 302, the sliding rod 302 is slidably connected to the middle part of the cross beam 301, the middle part of the cross beam 301 is fixedly connected with a telescopic rod II304, and the movable end of the telescopic rod II304 is fixedly connected to the folding frame 303; and then the telescopic rod II304 drives the sliding rod 302 to move back and forth when being telescopic, so as to drive the folding frame 303 and the arc pressing plate 101 to move, and further conveniently drive the arc pressing plate 101 to press the pipe body 701.

(A) grinding a plurality of triangular grooves 702 on the outer peripheral surface of the pipe body 701;

(B) a plurality of metal plates 704 are respectively bonded at the plurality of triangular grooves 702;

(C) pressing the middle part of the metal plate 704 into the triangular groove 702;

(D) two collars 703 are fitted over the outside of the plurality of metal plates 704.

The composite pipe machining system further comprises a vertical frame 401, a motor I402, a shaft rod 403, a rotating rod 404, a blocking protrusion 405 and an inner clamping piece 406, wherein the vertical frame 401 is provided with one left side and one right side, the upper portion of the vertical frame 401 is connected with the shaft rod 403 in a rotating mode, the shaft rod 403 is driven through the motor I402, the inner end of the shaft rod 403 is fixedly connected with the rotating rod 404, the two ends of the rotating rod 404 are respectively connected with the inner clamping piece 406 in a sliding mode, the blocking protrusion 405 is arranged on the outer side of the inner clamping piece 406, and the inner clamping piece 406 is fixedly pressed on the rotating rod 404 through screws.

In addition, as an example, as shown in fig. 1 to 10, this example solves the problem that it is convenient to rotate the pipe body 701 about its own axis, change the position of the pipe body 701, cut triangular grooves 702 at different positions of the pipe body 701,

two interior folder 406 all can slide on bull stick 404, and then adjust the interval between two interior folders 406, make two interior folders 406 can press from both sides in body 701, two keep off protruding 405 can block in the side of body 701, make two interior folders 406 insert a fixed distance of body 701, be convenient for fix body 701, fix the both sides of body 701 through four interior folders 406, then drive axostylus axostyle 403 through motor I402, bull stick 404 and two interior folders 406 rotate, and then drive body 701 and rotate, conveniently make body 701 rotate with the axis of self, change the position of body 701, the triangular groove 702 is surely cut out in the different positions of body 701.

The composite pipe machining system further comprises a base frame 501 and supports 502, the lower portions of the two vertical frames 401 are respectively connected to the left portion and the right portion of the base frame 501 in a sliding mode, the supports 502 are fixedly connected to the left end and the right end of the base frame 501, the vertical frames 401 are fixedly connected to the base frame 501 in a screw pressing mode, and the cross beam 301 is fixedly connected between the two supports 502.

In addition, as an example, as shown in fig. 1 to 10, this example solves the problem of fixing pipe bodies 701 of different lengths,

the two vertical frames 401 can move left and right on the bottom frame 501, so that the distance between the two vertical frames 401 is adjusted, and the pipe bodies 701 with different lengths are fixed.

The composite pipe machining system further comprises an upright post 505, a telescopic rod III506, a sliding block 507, a grinding wheel frame 601, a motor III602 and a grinding wheel 603, wherein the sliding block 507 is connected to the middle of the base frame 501 in a sliding mode, the lower portion of the upright post 505 is fixedly connected to the rear portion of the sliding block 507, the grinding wheel frame 601 is vertically connected to the upright post 505 in a sliding mode, the telescopic rod III506 is fixedly connected to the upright post 505, the movable end of the upright post 505 is fixedly connected to the grinding wheel frame 601, the grinding wheel frame 601 is connected with the grinding wheel 603 in a rotating mode, and the grinding wheel 603 is driven by the motor III 602.

In addition, as an example, as shown in fig. 1 to 10, this example solves the problem of facilitating the machining of a plurality of triangular grooves 702 on a pipe body 701,

when the telescopic rod III506 is telescopic, the grinding wheel frame 601 and the grinding wheel 603 are driven to move up and down, and when the sliding block 507 slides left and right on the base frame 501, the grinding wheel 603 is driven to move left and right, so that a plurality of triangular grooves 702 can be conveniently machined on the pipe body 701.

The composite pipe machining system further comprises a motor II503 and a lead screw 504, the motor II503 is fixedly connected to the bottom frame 501, the lead screw 504 is fixedly connected to an output shaft of the motor II503, and the lead screw 504 is matched with the sliding block 507 through threads.

In addition, as an example, as shown in fig. 1 to 10, this example solves the problem of the drive slider 507 sliding left and right on the base frame 501,

the motor II503 drives the lead screw 504 to rotate, and when the lead screw 504 rotates, the sliding block 507 can be driven to slide left and right on the bottom frame 501.

Claims

1. The utility model provides a compound tubular product system of processing, includes arc clamp plate (101), cross slot (102) and cutter (104), its characterized in that: the arc pressing plate (101) is provided with a transverse groove (102), a cutter (104) is arranged at the transverse groove (102), and the cutter (104) can be inserted into the transverse groove (102).

2. A composite pipe machining system as claimed in claim 1, wherein: still include cutter seat (103), guide arm (106) and side seat (107), the equal fixedly connected with side seat (107) of the left and right sides of arc clamp plate (101), equal fixedly connected with guide arm (106) on two side seats (107), fixedly connected with cutter seat (103) on cutter (104), the both ends difference sliding connection of cutter seat (103) is on two guide arms (106).

3. A composite pipe machining system as claimed in claim 2, wherein: still include telescopic link I (105), equal fixedly connected with telescopic link I (105) on two guide arms (106), the equal fixed connection of expansion end of two telescopic link I (105) is on cutter seat (103).

4. A composite pipe machining system as claimed in claim 3, wherein: the side seat structure is characterized by further comprising slot seats (201) and slots (202), the slot seats (201) are arranged on the outer sides of the two side seats (107), and the slots (202) are arranged on the slot seats (201).

5. The composite pipe machining system of claim 4, wherein: still include side post (203) and arc bullet pole (204), the equal fixedly connected with side post (203) in the outside of two side seats (107), sliding connection is on two side posts (203) respectively for two slot seats (201), the equal fixedly connected with arc bullet pole (204) of tip of two side posts (203), the other end difference fixed connection of two arc bullet poles (204) is on two slot seats (201).

6. The composite pipe machining system of claim 5, wherein: the composite pipe machining system is used for machining a composite pipe and comprises a pipe body (701) and metal plates (704), and the metal plates (704) are bonded on the outer side of the pipe body (701).

7. The composite pipe machining system of claim 6, wherein: the composite pipe further comprises triangular grooves (702), a plurality of triangular grooves (702) are uniformly distributed on the outer peripheral surface of the pipe body (701), a plurality of metal plates (704) are respectively arranged at the triangular grooves (702), and the middle parts of the metal plates (704) are pressed into the triangular grooves (702).

8. The composite pipe machining system of claim 7, wherein: the composite pipe further comprises lantern rings (703), the lantern rings (703) are sleeved at two ends of the pipe body (701), and the lantern rings (703) are sleeved on the outer sides of the metal plates (704).

9. The composite pipe machining system of claim 8, wherein: still include crossbeam (301), slide bar (302), roll over frame (303) and telescopic link II (304), the upper end fixed connection of rolling over frame (303) is at the downside of arc clamp plate (101), the lower part fixedly connected with slide bar (302) of rolling over frame (303), slide bar (302) sliding connection is at the middle part of crossbeam (301), the middle part fixedly connected with telescopic link II (304) of crossbeam (301), the expansion end fixed connection of telescopic link II (304) is on rolling over frame (303).

10. A method of processing composite pipe by a composite pipe processing system according to claim 9, comprising the steps of:

(A) grinding a plurality of triangular grooves (702) on the outer peripheral surface of a pipe body (701);

(B) respectively bonding a plurality of metal plates (704) at a plurality of triangular grooves (702);

(C) pressing the middle part of the metal plate (704) into the triangular groove (702);

(D) two collars (703) are fitted on the outer sides of the plurality of metal plates (704).