CN212446317U - Composite coating winding device - Google Patents

Abstract

The utility model provides a composite coating wind, its characterized in that: the winding device includes: the group of support frames are arranged in parallel and have the same axle center, and the support frames are connected through a connecting rod; a group of winding components and driving components are arranged between the group of supporting frames. The utility model discloses a composite coating wind has wholly realized storage, heating, winding, has rolled and combined treatment's process through a device. The device can automatically improve the adhesive property and the shearing strength of the polyolefin layer, and cannot damage the corrosion resistance of the epoxy powder layer in the 3PE anti-corrosion pipe, so that the limitation of the manufacturing process of the 3PE anti-corrosion pipe node is broken through, the problem that the sea pipe node anti-corrosion process is not high is solved, and a reliable sea pipe node anti-corrosion automatic winding equipment product is provided in a special environment.

Description

Composite coating winding device

Technical Field

The utility model relates to an on-spot anticorrosive coating technical field of sea pipe node, concretely relates to composite coating wind.

Background

3LPP/3LPE sea pipe node is on-spot polyolefin composite coating winding equipment of mending a mouthful, concretely relates to high shear force three-layer polyolefin anticorrosion sea pipe node and manufacturing process thereof, sea pipe node anticorrosion includes steel pipe body, epoxy powder layer, viscose knot layer and polyolefin layer from inside to outside in proper order, among the prior art, all carry out the manual winding usually, but the manual winding often can appear heating and roll inhomogeneous restriction to the manual efficiency is low.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a composite coating wind realizes the process of automatic winding and heating.

The utility model provides a composite coating wind, this wind includes: the group of support frames are arranged in parallel and have the same axle center, and the support frames are connected through a connecting rod; a group of winding components and driving components are arranged between the group of supporting frames.

Preferably, the drive assembly comprises at least one set of active drive assemblies.

Preferably, the driving assembly comprises a driving roller and a transmission assembly for driving the driving roller, and during operation, the driving roller is tangent to the outer wall of the circular tube.

Preferably, the drive assembly may further comprise a driven drive assembly.

Preferably, the driven driving assembly comprises a driven rotating shaft spanning the two support frames and two driven rollers fixedly arranged on the driven rotating shaft.

Preferably, the winding assembly comprises a discharging assembly and a pressing assembly; the discharging assembly comprises a storage bin and a conveying assembly which is arranged close to the storage bin.

Preferably, the conveying assembly comprises at least one group of driving conveying wheels and driven conveying wheels which are tangentially arranged, and the strip-shaped materials pass through the driving conveying wheels and the driven conveying wheels and are guided to the outer wall of the circular tube.

Preferably, the discharging assembly and the pressing assembly can also be provided with a heating assembly.

Preferably, the support frame comprises two symmetrical parts, the side surfaces of the two parts are semicircular, the semicircular parts are oppositely arranged to form a circle, one ends of the semicircular parts are oppositely and rotatably arranged, and the other ends of the semicircular parts are detachably connected.

Preferably, at least one of the two semicircular brackets is provided with an electric hydraulic rod.

The utility model has the advantages and positive effects that: the utility model discloses a composite coating wind has wholly realized storage, heating, winding, has rolled and combined treatment's process through a device. The device can automatically improve the adhesive property and the shearing strength of the polyolefin layer, and cannot damage the corrosion resistance of the epoxy powder layer in the 3PE anti-corrosion pipe, so that the limitation of the manufacturing process of the 3PE anti-corrosion pipe node is broken through, the problem that the sea pipe node anti-corrosion process is not high is solved, and a reliable sea pipe node anti-corrosion automatic winding equipment product is provided in a special environment.

Drawings

Fig. 1 is a schematic structural view of the composite coating winding device of the present invention;

FIG. 2 is a schematic side view of the composite coating winding apparatus of the present invention;

fig. 3 is a schematic structural view of the winding assembly of the present invention;

fig. 4 is a schematic structural view of the composite coating layer winding device of the present invention in an opened state.

Detailed Description

For a better understanding of the present invention, the following further description is given in conjunction with the following embodiments and accompanying drawings.

As shown in fig. 1, the utility model provides a composite coating wind, this wind includes: a group of support frames 10 which are arranged in parallel and have the same axle center, and the support frames 10 are connected through a connecting rod 101; between the supporting frames 10, a set of winding assemblies 20 and a driving assembly 30 are installed.

The supporting frame 10 is in a circumferential shape, is hollow inside, and is used for allowing a round pipe 40 to be processed to pass through; a certain distance is reserved between the two support frames 10, the two support frames 10 are fixedly connected through a plurality of connecting rods 101, and the two support frames 10 are identical in shape and are arranged coaxially; the utility model discloses the in-process of work, the support frame 10 cover is located the 40 outer walls of pipe of treating processing, and it is rotatory around the circumference of pipe 40 to drive this support frame 10 through drive assembly 30 to the winding subassembly 20 that the drive set up on support frame 10 rotates together, will expect to twine in the outer wall of pipe 40.

Further, as shown in fig. 1 and fig. 2, in a specific embodiment of the present invention, the driving assembly 30 includes at least one set of driving assembly 31, in this embodiment, the driving assembly 31 is driven by a gear transmission, including a driving gear 311, the driving gear 311 is driven by a motor 312, and further includes a driven gear 313, the driven gear 313 is fixed on a main rotating shaft 314, the main rotating shaft 314 crosses over two supporting frames 10, and is rotatably disposed relative to the supporting frame 10, two ends of the main rotating shaft 314 are provided with driving rollers 315 on the outer side of the supporting frame 10, and in the working process of the driving rollers 315 are tangent to the outer wall of the circular tube 40.

Specifically, the motor 312 drives the driving gear 311 to rotate, and the driving gear 311 drives the driven gear 313 and the main rotating shaft 314 fixedly connected to the driven gear 313 to rotate together, so as to drive the driving roller 315 disposed outside the supporting frame 10 to rotate along the outer wall of the circular tube 40, thereby driving the whole supporting frame 10 to rotate along the axis of the circular tube 40.

Further, the outer diameters of the driving gear 311 and the driven gear 313 are set to be smaller than the outer diameter of the driving roller 315, so as to prevent the driving gear 311 and the driven gear 313 from contacting the circular tube 40 during the operation process and damaging the circular tube 40.

Further, the motor 312 is fixedly disposed between the two support frames 10 through a motor support frame 316.

In another specific embodiment of the present invention, in order to ensure the overall balance, the supporting frame 10 is provided with two sets of active driving assemblies 31, and the two sets of active driving assemblies 31 are symmetrically arranged relative to the axis of the supporting frame 10.

In another specific embodiment, a plurality of sets of driven driving assemblies 32 can be further provided, the driven driving assemblies 32 do not need to be provided with a transmission assembly, and specifically, the driven driving assemblies 32 can include a driven rotating shaft 321 crossing the two supporting frames 10 and two driven rollers 322 fixedly arranged on the driven rotating shaft 321, the two driven rollers 322 can be arranged inside or outside the two supporting frames, the height and the outer diameter of the driven rollers 322 and the driving rollers 315 are equal, and the driven rollers and the driving rollers 315 are all cut on the outer wall of the circular tube 10 during the operation.

Further, in a specific embodiment, to ensure the balance of the whole, the driving assembly 31 and the driven driving assembly 32 are both symmetrically arranged.

The number of driving assemblies 31 and driven assemblies 32 can be specifically selected according to specific needs and the size of the whole device, again without limitation.

In yet another embodiment of the present invention, as shown in fig. 1 and 3, the winding assembly 20 includes a discharging assembly 21 and a compacting assembly 22.

Further, the discharging assembly 21 and the compressing assembly 22 are disposed in a storage bin 23; specifically, the discharging assembly 21 includes a material belt wheel 211 and a conveying assembly 212; the material belt wheel 211 is rotatably arranged at two sides of the storage bin 23, the material belt is in a belt shape and is wound on the material belt wheel 211 arranged in the storage bin 23, and the free end of the belt-shaped material is conveyed to the outer wall of the circular tube 40 through the conveying assembly 212.

Further, the transfer assembly 212 includes at least one set of driving transfer wheel 2121 and driven transfer wheel 2122 arranged tangentially, and the belt-like material passes between the driving transfer wheel 2121 and the driven transfer wheel 2122 and is guided to the outer wall of the tube 40.

Further, the driving transmission wheel 2121 is driven by a winding motor 2123, and an output shaft of the winding motor 2123 is fixedly connected to a winding driving wheel 2124, and the winding driving wheel 2124 is in transmission connection with the driving transmission wheel 2121 through a belt 2125.

In operation, the winding motor 2123 drives the winding driving wheel 2124 to rotate, the winding driving wheel 2124 drives the driving transmission wheel 2121 to rotate via the belt 2125, and the driving transmission wheel 2121 drives the driven transmission wheel 2122 tangent to the driving transmission wheel 2121 to rotate, so as to convey the belt-shaped material to the outer wall of the circular tube 40.

Specifically, the transmission assembly 212 is provided with the number of driving transmission wheels 2121 and driven transmission wheels 2122 according to specific needs and installation positions, and is not limited herein.

Further, the pressing component 22 is a pressing wheel, specifically, the pressing wheel is rotatably disposed on two sides of the storage bin 23 through a pressing rotating shaft 221, the pressing wheel spans two sides of the storage bin 23, and the pressing wheel is tangent to the outer wall of the circular tube 40 in the working process; the pinch roller is disposed at the discharge end of the conveying assembly 212, and is used for rolling the material attached to the outer wall of the circular tube 40.

In a particular embodiment of the invention, the storage silo 23 is mounted between the support frames 10 by a silo rotation shaft 24 and is driven in rotation about the silo rotation shaft 24 by means of an electric cylinder 25.

Further, a vertex angle of the storage bin 23 is erected between the support frames 10 through a storage bin rotating shaft 24, and a vertex angle adjacent to the vertex angle is rotatably connected with the electric hydraulic cylinder 25, specifically, one end of the electric hydraulic cylinder 25 is rotatably erected between the support frames 10, and the other end is rotatably connected with the storage bin 23.

Specifically, the compressing assembly 22 is in a suspended state before working, and when the working is needed, the electric hydraulic cylinder 25 is driven to contract, so that the material attached to the outer wall of the circular tube 40 by the compressing assembly 22 is rolled; after winding, the electric hydraulic cylinder 25 is driven to extend, so that the pressing component 22 is separated from the circular tube 40, and the automatic opening and closing function is achieved.

Heating components, such as heating wires, can also be disposed inside the material belt wheel 211 and inside the pressing component 22 to heat or maintain the temperature of the material. Specifically, for example, a heating wire is arranged in the material belt wheel 211, or a storage bin 211 which is relatively sealed is arranged, and a heating component is additionally arranged in the storage bin 211; the heating wires can be embedded in the pressing wheels.

Further, in the utility model discloses a still another concrete embodiment, support frame 10 can open and shut, and specifically, support frame 10 includes the two parts of symmetry, and the side of two parts is semi-circular, and semi-circular sets up relatively, constitutes a circular, and the setting of relative rotation of two semicircular one end can be realized opening and shutting by the other end.

Specifically, the support frame 10 includes two symmetrically disposed semicircular supports, one end of each of which is hinged, and the other end of each of which is opened and closed through a brake plate 102.

Specifically, the two semicircular brackets may be directly hinged or hinged through a stop plate 103.

Further, a lifting point is arranged at the position of the upper half part 2/3 of each semicircular bracket, and the semicircular brackets are respectively opened towards two sides from the hinged position of the stop plate 103 through the pulling force when the crane is lifted.

In another specific embodiment of the present invention, a connection box 50 is further disposed on the supporting frame 10, and is erected between the two supporting frames 10, so as to implement power supply and automatic control of the whole device.

The utility model discloses a composite coating wind has wholly realized storage, heating, winding, has rolled and combined treatment's process through a device. The device can automatically improve the adhesive property and the shearing strength of the polyolefin layer, and cannot damage the corrosion resistance of the epoxy powder layer in the 3PE anti-corrosion pipe, so that the limitation of the manufacturing process of the 3PE anti-corrosion pipe node is broken through, the problem that the sea pipe node anti-corrosion process is not high is solved, and a reliable sea pipe node anti-corrosion automatic winding equipment product is provided in a special environment.

The embodiments of the present invention have been described in detail, but the description is only for the preferred embodiments of the present invention and should not be construed as limiting the scope of the present invention. All equivalent changes and modifications made within the scope of the present invention should be covered by the present patent.

Claims (8)

1. A composite coating wind, its characterized in that: the winding device includes: the group of support frames are arranged in parallel and have the same axle center, and the support frames are connected through a connecting rod; a group of winding assemblies and driving assemblies are arranged between the groups of supporting frames; the driving assembly comprises at least one group of active driving assemblies; the driving assembly comprises a driving roller and a transmission assembly for driving the driving roller, and the driving roller is tangent to the outer wall of the circular tube in the working process.

2. The composite coating winding apparatus of claim 1, wherein: the drive assembly may also include a driven drive assembly.

3. The composite coating winding apparatus of claim 2, wherein: the driven driving assembly comprises a driven rotating shaft crossing the two support frames and two driven rollers fixedly arranged on the driven rotating shaft.

4. The composite coating winding apparatus of any one of claims 1 to 3, wherein: the winding assembly comprises a discharging assembly and a pressing assembly; the discharging assembly comprises a storage bin and a conveying assembly which is arranged close to the storage bin.

5. The composite coating winding apparatus of claim 1, wherein: the conveying assembly comprises at least one group of driving conveying wheels and driven conveying wheels which are arranged in a tangent mode, and the strip-shaped materials penetrate through the driving conveying wheels and the driven conveying wheels and are guided to the outer wall of the circular tube.

6. The composite coating winding apparatus of claim 5, wherein: the discharging assembly and the pressing assembly can also be provided with heating assemblies.

7. The composite coating winding apparatus of claim 1, wherein: the support frame comprises two symmetrical parts, the side surfaces of the two parts are semicircular, the semicircular parts are oppositely arranged to form a circle, one end of each semicircular part is oppositely and rotatably arranged, and the other end of each semicircular part is detachably connected.

8. The composite coating winding apparatus of claim 1, wherein: at least one of the two semicircular brackets is provided with an electric hydraulic rod.

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