CN113639127A - Adhesive composite pipe joint and manufacturing and mounting method and equipment thereof - Google Patents

Abstract

The invention discloses a cohesive composite pipe joint and a manufacturing and mounting method and equipment thereof. The invention discloses an adhesive composite pipe joint, which comprises two connected ACPs, wherein each ACP comprises an ACP inner layer, an ACP reinforcing layer and an ACP outer layer, the outer sides of the two connected ACP interfaces are coated with fiber reinforcing layers, fiber bundles are wound in a cross mode at a certain winding angle through a winding machine to form the fiber reinforcing layers, the ACP outer layers and the fiber bundle layers in the fiber reinforcing layers are bonded into a whole through hot melting, the fiber reinforcing layers are coated with coating layers, and the coating layers are made of thermoplastic high polymer materials and formed through injection molding of a coating mold. The adhesive composite pipe joint is used for pipe-pipe connection in an ACP pipeline system, the joint provided by the invention maintains higher strength, and simultaneously solves the problem that the traditional mechanical buckling-pressing type joint is not corrosion-resistant, and the joint is simple to manufacture and reliable in connection; the manufacturing and mounting method and equipment of the adhesive composite pipe joint are also provided.

Description

Adhesive composite pipe joint and manufacturing and mounting method and equipment thereof

Technical Field

The invention relates to the field of composite pipe and pipeline connection, in particular to a cohesive composite pipe joint and a manufacturing and installing method and equipment thereof.

Background

A Reinforced Thermoplastic Composite Pipe (RTP) is generally a three-layer structure, in which an inner layer and an outer layer are made of a Thermoplastic material such as High Density Polyethylene (HDPE), and an intermediate layer is made of a reinforcing material such as glass fiber, kevlar fiber, carbon fiber, or steel wire. The tube in which the inner layer, the intermediate layer and the outer layer of the RTP are completely bonded is called an Adhesive Composite tube (ACP). RTP has advantages such as intensity is high, corrosion-resistant, the quality is light, has extensive application prospect in fields such as oil gas transport, municipal water delivery.

The pipeline connection is a core link of a pipeline transportation system, and the connection problem of an RTP pipeline system restricts the engineering application of RTP. The RTP joint widely applied at present can be divided into a mechanical buckling-pressing type joint and an enhanced electric melting type joint, wherein the mechanical buckling-pressing type joint is made of metal materials, has higher strength, is not corrosion-resistant and has higher cost; the reinforced electric melting joint is generally composed of an electric heating wire, inner and outer layer plastics, a middle reinforcing material and the like, is simple to install, and has the problems of complex production process, low strength and the like.

Therefore, it is desirable to develop a new RTP connection method and apparatus to solve the above problems.

Disclosure of Invention

The invention aims to provide a cohesive composite pipe joint which is used for pipe-pipe connection in an ACP pipeline system, and the joint provided by the invention has the advantages that the problem that the traditional mechanical buckling-pressing type joint is not corrosion-resistant while keeping high strength is solved, the manufacture is simple, and the connection is reliable; the manufacturing and mounting method and equipment of the adhesive composite pipe joint are also provided.

The invention adopts the following technical scheme:

a cohesiveness composite pipe joint comprises two connected ACPs, wherein each ACP comprises an ACP inner layer, an ACP reinforcing layer and an ACP outer layer, the outer sides of the ACP interfaces of the two connected ACPs are coated with fiber reinforcing layers, fiber bundles are wound in a cross mode at a certain winding angle through a winding machine to form the fiber reinforcing layers, the ACP outer layers and the fiber bundle layers in the fiber reinforcing layers are bonded into a whole through hot melting, the fiber reinforcing layers are coated with coating layers, and the coating layers are made of thermoplastic high polymer materials through injection molding of a coating mold.

Preferably, the fiber reinforced layer and the ACP outer layer are made of thermoplastic plastics capable of being bonded by hot melting.

Preferably, the fiber bundle is a glass fiber bundle.

A method for manufacturing and installing a cohesive composite pipe joint comprises the following steps:

s1, ACP end capping: respectively placing the two ACPs into a sealing end die, extruding molten plastic into a cavity of the sealing end die through a gate of the sealing end die by an injection molding machine, welding the molten plastic and the ACP into a whole at high temperature, and cooling the die to finish the sealing end of the ACP;

s2, hot-melting of the end-capped ACP: carrying out hot-melt welding on the ACP subjected to end capping at two ends through hot-melt butt welding equipment, and cleaning a flanging of a welding surface after the welding surface is cooled to finish the hot-melt welding of the ACP subjected to end capping;

s3, winding the fiber reinforced layer: fixing the ACP pipe subjected to the hot-melt welding in a pipe clamp of a winding machine, mounting a fiber bundle roll on a winding shaft of the winding machine, winding the fiber bundle to the ACP at a certain winding angle by the winding machine through the rotation of a reel and the horizontal movement of a moving platform, heating the fiber bundle by a hot air blower on the reel, and fusing the fiber bundle and the ACP outer layer into a whole to complete the winding of the fiber bundle and finally form a fiber reinforced layer;

s4, coating with a coating layer: and placing the ACP joint part which finishes the winding of the fiber reinforced layer into a coating die, extruding molten plastic into a die cavity of the coating die by an injection molding machine, cooling to form a coating layer, and finally finishing the manufacturing and installation of the adhesive composite pipe joint.

The manufacturing and mounting equipment for the adhesive composite pipe joint comprises a control system, a transmission system, an execution system and a fixing system, wherein the control system comprises a touch screen, a PLC (programmable logic controller), a servo driver A and a servo driver B; the transmission system comprises a servo motor A, a speed reducer A, a transmission gear A, a servo motor B, a speed reducer B and a transmission gear B; the execution system comprises a reel A, a reel B, a reel A, a tension roller 1-A, a tension roller 2-A, a hot air blower A, a winding roller, a reel B, a tension roller 1-B, a tension roller 2-B and a hot air blower B; the reel A is provided with two fiber bundle winding systems; the device comprises a reel A, a tension roller 1-A, a tension roller 2-A, an air heater A and a winding roller which form a set of fiber bundle winding system, a reel B, a tension roller 1-B, a tension roller 2-B, an air heater B and a winding roller which form a set of fiber bundle winding system, wherein the fixed system comprises a fixed platform, a movable platform, a fixed upright post A, a fixed upright post B, a reel support frame A, a reel support frame B, a reel support frame C, a pipe clamp A and a pipe clamp B, the fixed platform is fixed on the ground, a guide rail is processed on the upper end surface, a rack is processed on one side of the fixed platform, the movable platform is arranged on the fixed platform, a guide rail matched with the fixed platform is processed on the lower end surface of the movable platform, the pipe clamp A and the pipe clamp B are fixed at two ends of the guide rail, the pipe clamp A and the pipe clamp B are respectively clamped, and the control system and the transmission system are both arranged on the movable platform, the reel support frame A, the reel support frame B and the reel support frame C are used for supporting the reel A and the reel B and are in transmission with the reel A and the reel B through gears, so that the reel A and the reel B are guaranteed to stably complete rotation and are prevented from generating axial displacement;

PLC passes through servo driver A, servo driver B drives servo motor A simultaneously, servo motor B works, servo motor A drives drive gear A through speed reducer A and rotates, thereby drive reel A and reel B rotate, and servo motor B drives drive gear B through speed reducer B and rotates, drive gear B and fixed platform's rack cooperation, thereby realize the horizontal motion of moving platform on fixed platform, the tow is sent out by spool A, respectively walk around tension roller 1-A, tension roller 2-A and wind-up roll, wind to ACP joint department, simultaneously when rotatory, PLC control air heater work, heat the tow and make tow and ACP outer butt fusion.

Preferably, the reel A and the reel B are separable gear plates, and are fastened and connected by bolts through a reel mounting support.

Preferably, the reel support frame A, the reel support frame B and the reel support frame C are in regular triangle position transmission and support the reel A and the reel B to stably complete the rotation action.

Preferably, the reel supporting frame A, the reel supporting frame B and the reel supporting frame C respectively comprise a protection frame and a gear for transmission between the protection frames.

Preferably, the mobile platform is fixedly connected with a control cabinet, and the touch screen, the PLC, the servo driver A and the servo driver B are respectively installed on the control cabinet.

The invention has the beneficial effects that: the invention designs a cohesive composite pipe joint for pipe-pipe connection in an ACP pipeline system, which solves the problem that the traditional mechanical buckling-pressing type joint is not corrosion-resistant while keeping higher strength, and has simple manufacture and reliable connection; the manufacturing and mounting method and equipment of the adhesive composite pipe joint are also provided.

Drawings

FIG. 1 is a schematic view of an ACP capping treatment according to the present invention;

FIG. 2 is a schematic diagram of a structure of the present invention after the end-capping of ACP;

FIG. 3 is a schematic view of a structure of the present invention for performing hot-melt welding of the end-capped ACP;

FIG. 4 is a schematic structural view of the bonded composite pipe joint of the present invention after completion of winding of the fiber-reinforced layer;

FIG. 5 is a schematic view of a construction of the bonded composite pipe joint during a cladding process according to the present invention;

FIG. 6 is a schematic view of a construction of the bonded composite pipe joint of the present invention;

FIG. 7 is a schematic structural view of the apparatus for manufacturing and installing an adhesive composite pipe joint according to the present invention;

FIG. 8 is a schematic view of a rear view of the FIG. 7;

FIG. 9 is a schematic view of another angle of the apparatus for manufacturing and installing an adhesive composite pipe joint according to the present invention; (ii) a

FIG. 10 is a schematic view of a reel B according to the present invention;

in the figure: 1. ACP, 2, end-capping die, 3, end-capping die gate, 4, ACP outer layer, 5, ACP reinforcing layer, 6, ACP inner layer, 7, ACP-A, 8, ACP-B, 9, fiber reinforcing layer, 10, coating die, 11, coating die gate, 12, coating layer, 13, control system, 14, transmission system, 15, execution system, 16, fixing system, 17, touch screen, 18, PLC, 19, servo driver A, 20, servo driver B, 21, servo motor A, 22, speed reducer A, 23, transmission gear A, 24, servo motor B, 25, speed reducer B, 26, transmission gear B, 27, reel A, 28, reel B, 29, reel A, 30, tension roller 1-A, 31, tension roller 2-A, 32, hot air blower A, 33, winding roller, 34, reel B, 35, tension roller 1-B, 36. tension rollers 2-B, 37, air heaters B, 38, a reel mounting support 39, a fixed platform 40, a movable platform 41, fixed columns A, 42, fixed columns B, 43, reel support frames A, 44, reel support frames B, 45, reel support frames C, 46, pipe clamps A, 47, pipe clamps B, 48, guide rails, 49 and racks.

Detailed Description

The technical scheme of the invention is further described in detail by the following specific embodiments in combination with the attached drawings:

example (b): as shown in fig. 6, the adhesive composite pipe joint comprises two connected ACP1, wherein the ACP comprises an ACP inner layer 6, an ACP reinforcing layer 5 and an ACP outer layer 4, a fiber reinforcing layer 9 is coated on the outer side of the ACP interface of the two connected ACP connectors, fiber bundles are wound in a cross mode at a certain winding angle through a winding machine by the fiber reinforcing layer 9, the fiber bundles in the fiber reinforcing layer 9, the ACP outer layer 4 and the fiber reinforcing layer 9 are bonded into a whole through hot melting, a coating layer 12 is coated outside the fiber reinforcing layer, and the coating layer 12 is made of thermoplastic polymer materials through injection molding through a coating mold 10.

As shown in fig. 7-10, the manufacturing and installation equipment for the adhesive composite pipe joint comprises a control system 13, a transmission system 14, an execution system 15 and a fixing system 16, wherein the control system comprises a touch screen 17, a PLC18, a servo driver a19 and a servo driver B20; the transmission system comprises a servo motor A21, a speed reducer A22, a transmission gear A23, a servo motor B24, a speed reducer B25 and a transmission gear B26; the execution system comprises a reel A27, a reel B28, a reel A29, a tension roller 1-A30, a tension roller 2-A31, a hot air blower A32, a winding roller 33, a reel B34, a tension roller 1-B35, a tension roller 2-B36 and a hot air blower B37, the fixing system comprises a fixed platform 39, a movable platform 40, a fixed upright A41, a fixed upright B42, a reel supporting frame A43, a reel supporting frame B44, a reel supporting frame C45, a pipe clamp A46 and a pipe clamp B47, the fixed platform is fixed on the ground, a guide rail 48 is machined on the upper end face, a rack 49 is machined on one side of the fixed platform, the movable platform is mounted on the fixed platform, and a guide rail matched with the fixed platform is machined on the lower end face of the movable platform.

When the manufacturing and mounting equipment of the adhesive composite pipe joint is used, as shown in attached 1, ACP1 is placed into a blocking die 2, molten plastic enters a die cavity from a blocking die sprue 3, and ACP blocking is completed after cooling, as shown in FIG. 2; carrying out hot-melt welding on the ACP-A7 and the ACP-B8 with the two ends sealed into a whole, cleaning the flanging plastics of the welding surface after the welding is finished, and obtaining the ACP shown in the figure 3 after the welding is finished; clamping and fixing a pipe clamp A46 and a housekeeper clamp B47 of a winding machine for ACP shown in FIG. 3, enabling an ACP hot melting welding surface to be basically positioned at the middle position of a moving platform 40 of the winding machine, respectively enabling fiber bundles of a fiber roll arranged on a reel A29 to pass through tension rollers 1-A30, tension rollers 2-A31 and a winding roller 33, and pre-fixing the fiber bundles on the ACP, controlling a starting servo motor A23 and a servo motor B24 by a servo driver A19 and a servo driver B20 by a PLC18, respectively, driving a reel A27 and a reel B28 to rotate by a speed reducer A22 and a transmission gear A23 after the servo motor A23 is started, enabling a transmission gear B26 and a rack 49 of the fixed platform 39 to generate relative motion by a speed reducer B25 after the servo motor B24 is started, and enabling the moving platform 40 to horizontally move along the rack 49, under the combined action of the horizontal movement of the moving platform 40 and the circular movement of the reel A27 and the reel B28, the fiber bundle is wound at the ACP joint at a certain winding angle, and in addition, the PLC simultaneously controls the hot air blower A32 to be started, so that the fiber bundle is heated to a certain temperature and is welded with the ACP outer layer 4 into a whole, and the winding of the ACP joint fiber reinforcement layer is completed, as shown in FIG. 4; placing the ACP with the joint fiber reinforced layer into a coating mould 10, as shown in fig. 5, enabling molten plastic to flow into a mould cavity through a coating mould sprue 11, cooling to obtain a coating layer of the adhesive composite pipe joint, and finishing manufacturing and mounting of the adhesive composite pipe joint, wherein the structural schematic diagram of the novel joint is shown in fig. 6.

The method for manufacturing and installing the adhesive composite pipe joint comprises the following specific steps:

(1) end capping of ACP: placing ACP1 into a capping mold 2 for capping as shown in FIG. 1, and obtaining ACP-A7 as shown in FIG. 2;

(2) end capping of ACP: repeating the step (1) to obtain ACP-B8;

(3) ACP hot melt welding: carrying out hot-melt welding on the ACP-A7 and the ACP-B8, and cleaning the flanging plastics on the welding surface after cooling to obtain the ACP shown in the figure 3;

(4) preparing for winding the joint fibers: placing the ACP obtained in the step (3) into a coiler reel A27, fixing the ACP on a pipe clamp A46 and a pipe clamp B47, tightly connecting a reel B28 with the reel A27 through a reel mounting support 38 by using bolts, taking the fiber bundle out of a reel A29 and bypassing the tension rollers 1-A30, the tension rollers 2-A31 and the winding roller 33, and pre-fixing the fiber bundle on the ACP;

(5) winding the joint fibers: the PLC18 respectively controls and starts a servo motor A23 and a servo motor B24, after the servo motor A23 is started, the reel A27 and the reel B28 are driven to rotate, after the servo motor B24 is started, the transmission gear B26 and the rack 49 of the fixed platform 39 generate relative motion, so that the movable platform 40 horizontally moves along the rack 49, the fiber bundle is wound at an ACP joint at a certain winding angle under the combined action of the horizontal motion of the movable platform 40 and the circular motion of the reel A27 and the reel B28, and in addition, the PLC simultaneously controls the hot air blower A32 to be started, so that the fiber bundle is heated to a certain temperature and is welded with the ACP outer layer 4 into a whole, and the winding of the ACP joint fiber reinforcement layer is completed, as shown in figure 4;

(6) as shown in fig. 5, placing the ACP obtained in the step (5) into a coating die 10, extruding molten plastics into a die cavity by an injection molding machine through a coating die gate 11, and cooling to obtain a coating layer of an ACP joint;

(7) and (3) completing: and completing the manufacture and installation of the novel ACP connector, wherein the structural schematic diagram of the novel ACP connector is shown in FIG. 6.

The above-described embodiments are only preferred embodiments of the present invention, and are not intended to limit the present invention in any way, and other variations and modifications may be made without departing from the spirit of the invention as set forth in the claims.

Claims (9)

1. The adhesive composite pipe joint is characterized by comprising two connected ACPs, wherein each ACP comprises an ACP inner layer, an ACP reinforcing layer and an ACP outer layer, the outer sides of the joints of the two connected ACPs are coated with fiber reinforcing layers, fiber bundles are wound in a cross mode at a certain winding angle through a winding machine to form the fiber reinforcing layers, the ACP outer layers and the fiber bundle layers in the fiber reinforcing layers are bonded into a whole through hot melting, the fiber reinforcing layers are coated with coating layers, and the coating layers are made of thermoplastic high polymer materials and formed through injection molding of a coating mold.

2. The adhesive composite pipe joint according to claim 1, wherein said fiber-reinforced layer and said ACP outer layer are heat-fusible thermoplastic.

3. The bonded composite pipe joint according to claim 1, wherein said fiber bundle is a glass fiber bundle.

4. A method of manufacturing and installing an adhesive composite pipe joint according to any one of claims 1 to 3, comprising the steps of:

s1, ACP end capping: respectively placing the two ACPs into a sealing end die, extruding molten plastic into a cavity of the sealing end die through a gate of the sealing end die by an injection molding machine, welding the molten plastic and the ACP into a whole at high temperature, and cooling the die to finish the sealing end of the ACP;

s2, hot-melting of the end-capped ACP: carrying out hot-melt welding on the ACP subjected to end capping at two ends through hot-melt butt welding equipment, and cleaning a flanging of a welding surface after the welding surface is cooled to finish the hot-melt welding of the ACP subjected to end capping;

s3, winding the fiber reinforced layer: fixing the ACP pipe subjected to the hot-melt welding in a pipe clamp of a winding machine, mounting a fiber bundle roll on a winding shaft of the winding machine, winding the fiber bundle to the ACP at a certain winding angle by the winding machine through the rotation of a reel and the horizontal movement of a moving platform, heating the fiber bundle by a hot air blower on the reel, and fusing the fiber bundle and the ACP outer layer into a whole to complete the winding of the fiber bundle and finally form a fiber reinforced layer;

s4, coating with a coating layer: and placing the ACP joint part which finishes the winding of the fiber reinforced layer into a coating die, extruding molten plastic into a die cavity of the coating die by an injection molding machine, cooling to form a coating layer, and finally finishing the manufacturing and installation of the adhesive composite pipe joint.

5. The manufacturing and installation equipment of the adhesive composite pipe joint according to any one of claims 1 to 3, which comprises a control system, a transmission system, an execution system and a fixing system, wherein the control system comprises a touch screen, a PLC, a servo driver A and a servo driver B; the transmission system comprises a servo motor A, a speed reducer A, a transmission gear A, a servo motor B, a speed reducer B and a transmission gear B; the execution system comprises a reel A, a reel B, a reel A, a tension roller 1-A, a tension roller 2-A, a hot air blower A, a winding roller, a reel B, a tension roller 1-B, a tension roller 2-B and a hot air blower B; the reel A is provided with two fiber bundle winding systems; the device comprises a reel A, a tension roller 1-A, a tension roller 2-A, an air heater A and a winding roller which form a set of fiber bundle winding system, a reel B, a tension roller 1-B, a tension roller 2-B, an air heater B and a winding roller which form a set of fiber bundle winding system, wherein the fixed system comprises a fixed platform, a movable platform, a fixed upright post A, a fixed upright post B, a reel support frame A, a reel support frame B, a reel support frame C, a pipe clamp A and a pipe clamp B, the fixed platform is fixed on the ground, a guide rail is processed on the upper end surface, a rack is processed on one side of the fixed platform, the movable platform is arranged on the fixed platform, a guide rail matched with the fixed platform is processed on the lower end surface of the movable platform, the pipe clamp A and the pipe clamp B are fixed at two ends of the guide rail, the pipe clamp A and the pipe clamp B are respectively clamped, and the control system and the transmission system are both arranged on the movable platform, the reel support frame A, the reel support frame B and the reel support frame C are used for supporting the reel A and the reel B and are in transmission with the reel A and the reel B through gears, so that the reel A and the reel B are guaranteed to stably complete rotation and are prevented from generating axial displacement;

PLC passes through servo driver A, servo driver B drives servo motor A simultaneously, servo motor B works, servo motor A drives drive gear A through speed reducer A and rotates, thereby drive reel A and reel B rotate, and servo motor B drives drive gear B through speed reducer B and rotates, drive gear B and fixed platform's rack cooperation, thereby realize the horizontal motion of moving platform on fixed platform, the tow is sent out by spool A, respectively walk around tension roller 1-A, tension roller 2-A and wind-up roll, wind to ACP joint department, simultaneously when rotatory, PLC control air heater work, heat the tow and make tow and ACP outer butt fusion.

6. The manufacturing and installation equipment of an adhesive composite pipe joint according to claim 5, wherein the reel A and the reel B are separable gear plates, and are fastened and connected by bolts through a reel mounting support.

7. The apparatus for manufacturing and installing an adhesive composite pipe joint as claimed in claim 5, wherein the reel support frame A, the reel support frame B and the reel support frame C are driven in a regular triangle position and support the reel A and the reel B to smoothly perform a rotating motion.

8. The apparatus of claim 5, wherein the reel support frame A, the reel support frame B and the reel support frame C respectively comprise gears for driving between the protection frames.

9. The manufacturing and installation equipment of the adhesive composite pipe joint as claimed in claim 5, wherein the moving platform is fixedly connected with a control cabinet, and the touch screen, the PLC, the servo driver A and the servo driver B are respectively installed on the control cabinet.

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