CN219859818U

CN219859818U - Mica tube coiling machine

Info

Publication number: CN219859818U
Application number: CN202320653083.9U
Authority: CN
Inventors: 张学云; 于士玲; 张逸超
Original assignee: YANGZHOU YONGXIN INSULATION DUST EQUIPMENT PLANT
Current assignee: YANGZHOU YONGXIN INSULATION DUST EQUIPMENT PLANT
Priority date: 2023-03-29
Filing date: 2023-03-29
Publication date: 2023-10-20
Anticipated expiration: 2033-03-29

Abstract

The utility model discloses a mica tube coiling machine, which comprises: the device comprises a coiled pipe platform, a heat treatment box and a shaping wheel set, wherein a discharging frame is arranged on one side of the coiled pipe platform, a viscose pipe folding component, the shaping wheel set and an output component are sequentially arranged on the surface of the coiled pipe platform, the heat treatment box is fixedly installed on the surface of the coiled pipe platform and located between a conduction conveying component and the output component, a through pipe culvert is formed in the surface of the heat treatment box, an electric heating pipe is embedded into the inner wall of the through pipe culvert, heat conducting fins are arranged on the surface of the through pipe culvert, and a plurality of guide wheel frames are fixedly installed on the inner side of the through pipe culvert. According to the utility model, the heat treatment box structure is arranged between the conduction conveying assembly and the output assembly, the formed mica tube is conducted and heated by utilizing the heating structure in the heat treatment box to soften, and the formed mica tube is guided out for air cooling after being shaped by the shaping wheel set, so that the fold ironing of the mica tube is realized, the crease structure on the surface of mica paper is eliminated, the structural strength of the mica paper is improved, and the bending is avoided, so that the mica tube is prevented from collapsing.

Description

Mica tube coiling machine

Technical Field

The utility model relates to the technical field of tube rolling machines, in particular to a mica tube rolling machine.

Background

The mica tube is made up by using sheet mica or mica paper and making it be combined with proper adhesive and stuck on the single-face reinforcing material, and adopting the processes of rolling and making them into the invented hard tubular insulating material. It has high mechanical strength and is suitable for insulating electrodes, bars or outlet bushings in various motors and electric appliances. Most of mica pipes need to be used in a pipe coiling machine in the processing process.

The existing mica tube coiling machine is mainly used for folding a mica sheet and a reinforcing material into a quadrangular or polygonal column-shaped structure through a folding manner to bond two sides, so that a tubular structure is formed, a plurality of crease structures are remained on the surfaces of the mica sheet and the reinforcing material in the operation, the crease structures are difficult to eliminate, and in the use of the mica tube, the resistance of the flat collapse structure of the mica tube is reduced, the quality is poor and certain defects exist.

Disclosure of Invention

The present utility model aims to solve one of the technical problems existing in the prior art or related technologies.

The technical scheme adopted by the utility model is as follows: a mica tube coiling machine comprising: the automatic feeding and shaping machine comprises a coiled pipe platform, a heat treatment box and a shaping wheel set, wherein a discharging frame is arranged on one side of the coiled pipe platform, a viscose pipe folding assembly, a shaping wheel set and an output assembly are sequentially arranged on the surface of the coiled pipe platform, the heat treatment box is fixedly arranged on the surface of the coiled pipe platform and located between a conduction conveying assembly and the output assembly, a through pipe culvert is arranged on the surface of the heat treatment box, an electric heating pipe is embedded in the inner wall of the through pipe culvert, heat conducting fins are arranged on the surface of the through pipe culvert, a plurality of guide wheel frames are fixedly arranged on the inner side of the through pipe culvert, the shaping wheel set comprises a shaping supporting wheel and a shaping driving wheel, the shaping supporting wheel and the shaping driving wheel are rotatably arranged on the surface of the guide wheel frames, and the shaping supporting wheel and the shaping driving wheel are arranged in a mutually perpendicular mode.

The present utility model may be further configured in a preferred example to: the discharging frame, the viscose glue folding pipe assembly, the conduction conveying assembly, the heat treatment box and the output assembly are positioned on the same straight line and are sequentially arranged.

The present utility model may be further configured in a preferred example to: the electric heating pipe is located on two sides of the through pipe duct, the heat conducting fins are made of aluminum or metal copper, and the heat conducting fins face to the surface of the shaping wheel set.

The present utility model may be further configured in a preferred example to: the internal temperature of the through pipe culvert and the conveying speed of the uniform-length conduction conveying component and the output component of the through pipe culvert are in direct proportion.

The present utility model may be further configured in a preferred example to: the number of the forming supporting wheels and the number of the shaping driving wheels are two, the two forming supporting wheels and the two shaping driving wheels are symmetrically arranged, and the two forming supporting wheels are horizontally arranged in the same plane.

The present utility model may be further configured in a preferred example to: the surface of the forming supporting wheel is provided with annular protrusions, the surface of the forming driving wheel is provided with a forming surface groove, and the forming surface groove is of a circular arc concave surface structure.

The present utility model may be further configured in a preferred example to: the inner side of the guide wheel frame is fixedly provided with a driving motor sleeved on the inner side of the shaping driving wheel, and the surface of the shaping surface groove is of a rough surface structure.

The beneficial effects obtained by the utility model are as follows:

1. according to the utility model, the heat treatment box structure is arranged between the conduction conveying assembly and the output assembly, the formed mica tube is conducted and heated by utilizing the heating structure in the heat treatment box to soften, and the formed mica tube is guided out for air cooling after being shaped by the shaping wheel set, so that the fold ironing of the mica tube is realized, the crease structure on the surface of mica paper is eliminated, the structural strength of the mica paper is improved, and the bending is avoided, so that the mica tube is prevented from collapsing.

2. According to the utility model, a novel shaping structure is adopted, and the surface extrusion and the shape limitation of the tube body are respectively carried out by the shaping supporting wheel and the shaping driving wheel to convert the prismatic tube body into a circular tube structure, so that the structure is simple, the working efficiency is high, and the continuous long tube coiling operation can be carried out.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic diagram of a conductive transfer assembly, an output assembly and a thermal processing tank arrangement according to one embodiment of the present utility model;

FIG. 3 is a schematic view showing an internal structure of a heat treatment tank according to an embodiment of the present utility model;

FIG. 4 is a schematic diagram illustrating the operation of a truing wheel set according to one embodiment of the present utility model;

fig. 5 is a schematic view showing an arrangement structure of a forming support wheel and a forming driving wheel according to an embodiment of the present utility model.

Reference numerals:

100. a coiled pipe platform; 110. a discharging frame; 120. an adhesive folding pipe assembly; 130. a conductive transport assembly; 140. an output assembly;

200. a heat treatment tank; 210. a through pipe duct; 220. an electric heating tube; 230. a guide wheel frame; 211. a heat conduction fin;

300. shaping wheel sets; 310. forming a supporting wheel; 320. shaping driving wheels; 330. a driving motor; 321. and a molding surface groove.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be noted that, without conflict, the embodiments of the present utility model and features in the embodiments may be combined with each other.

A mica tube coiling machine provided in some embodiments of the present utility model is described below with reference to the accompanying drawings.

Referring to fig. 1 to 5, the mica tube coiling machine provided by the present utility model includes: the plastic rolling machine comprises a rolling pipe platform 100, a heat treatment box 200 and a shaping wheel set 300, wherein a discharging frame 110 is arranged on one side of the rolling pipe platform 100, an adhesive rolling pipe assembly 120, a shaping wheel set 300 and an output assembly 140 are sequentially arranged on the surface of the rolling pipe platform 100, the heat treatment box 200 is fixedly arranged on the surface of the rolling pipe platform 100 and is positioned between a conduction conveying assembly 130 and the output assembly 140, a through pipe culvert 210 is arranged on the surface of the heat treatment box 200, an electric heating pipe 220 is embedded and arranged on the inner wall of the through pipe culvert 210, heat conducting fins 211 are arranged on the surface of the through pipe culvert 210, a plurality of guide wheel frames 230 are fixedly arranged on the inner side of the through pipe culvert 210, the shaping wheel set 300 comprises a shaping supporting wheel 310 and a shaping driving wheel 320, the shaping supporting wheel 310 and the shaping driving wheel 320 are rotatably arranged on the surface of the guide wheel frames 230, and the shaping supporting wheel 310 and the shaping driving wheel 320 are arranged in a mutually perpendicular mode.

In this embodiment, the discharge rack 110, the adhesive folding tube assembly 120, the conductive transfer assembly 130, the heat treatment box 200, and the output assembly 140 are positioned in a straight line and sequentially arranged.

Specifically, the mica paper on the surface of the discharging frame 110 is pulled through the viscose glue folding pipe assembly 120 and the inside of the heat treatment box 200 under the conveying operation of the conductive conveying assembly 130 and the output assembly 140, and the mica paper is guided to move in the viscose glue folding pipe assembly 120 to generate folds to form a quadrangular prism structure and is glued and bonded at the joint, and then conveyed through the inside of the heat treatment box 200 under the conduction of the conductive conveying assembly 130.

In this embodiment, the electric heating tubes 220 are located at two sides of the through tube duct 210, the heat conducting fins 211 are made of aluminum or metal copper, and the heat conducting fins 211 face the surface of the shaping wheel set 300.

Specifically, the electric heating pipe 220 is used for heating the inside of the through pipe duct 210, and the heat conducting fin 211 is used for heating the inside of the through pipe duct 210 by heat radiation, so that the surface temperature of the formed mica tube is increased, and the formed mica tube is softened, so that crease marks are eliminated conveniently.

In this embodiment, the internal temperature of the through-tube duct 210 is directly proportional to the delivery rate of the uniform length conduction delivery assembly 130 and the output assembly 140 of the through-tube duct 210.

Specifically, the higher the delivery rate of the conductive delivery assembly 130 and the output assembly 140, the greater the operating temperature of the electric heating tube 220 and the length of the through-tube duct 210 are required to sufficiently soften the tube surface by heat.

In this embodiment, the number of the forming supporting wheels 310 and the shaping driving wheels 320 is two, and the two forming supporting wheels 310 and the two shaping driving wheels 320 are symmetrically arranged, and the two forming supporting wheels 310 are horizontally arranged in the same plane.

Further, the surface of the forming supporting wheel 310 is provided with an annular bulge, the surface of the forming driving wheel 320 is provided with a forming surface groove 321, and the forming surface groove 321 is in a circular arc concave structure.

Specifically, the mica tube is extruded to deform under the surface abutting action of the forming abutting wheel 310, and the deformation of the mica tube is limited by the fixed surface groove 321, so that the mica tube is shaped into a circular tube structure, and surface folds are eliminated.

In this embodiment, the inner side of the guide wheel frame 230 is fixedly provided with a driving motor 330 sleeved on the inner side of the shaping driving wheel 320, and the surface of the shaping surface groove 321 is of a rough surface structure.

Specifically, the driving motor 330 is used to realize the driving rotation of the shaping driving wheel 320, and friction is carried on the rough surface of the shaping surface groove 321 to actively convey the pipe fitting so as to compensate the kinetic energy after the abutting resistance of the shaping abutting wheel 310 is limited, so that the key can be stably conveyed inside the shaping abutting wheel 310.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims

1. A mica tube coiling machine, comprising: the utility model provides a coil pipe platform (100), heat treatment case (200) and plastic wheelset (300), one side of coil pipe platform (100) is equipped with blowing frame (110), viscose folding tube subassembly (120), plastic wheelset (300) and output subassembly (140) have been arranged in proper order to the surface of coil pipe platform (100), heat treatment case (200) fixed mounting is in the surface of coil pipe platform (100) and is located between conduction conveying subassembly (130) and output subassembly (140), siphunculus duct (210) have been seted up to the surface of heat treatment case (200), electric heating pipe (220) are installed in the inner wall embedding of siphunculus duct (210), the surface of siphunculus duct (210) is equipped with heat conduction fin (211), inboard fixed mounting of siphunculus duct (210) has a plurality of guide wheel frame (230), plastic wheelset (300) are including shaping supporting wheel (310) and shaping drive wheel (320), shaping supporting wheel (310) and shaping drive wheel (320) rotate the surface of installing in guide wheel frame (230), and shaping supporting wheel (310) and shaping drive wheel (320) become mutually perpendicular and arrange into.

2. The mica tube coiling machine as in claim 1 wherein the unreeling rack (110), the glue folding tube assembly (120), the conductive conveying assembly (130), the heat treatment box (200) and the output assembly (140) are positioned in a straight line and are arranged in sequence.

3. The mica tube coiling machine as in claim 1, wherein the electric heating tubes (220) are located at two sides of the tube culvert (210), the heat conducting fins (211) are made of aluminum or metal copper, and the heat conducting fins (211) face the surface of the shaping wheel set (300).

4. The mica tube coiling machine as recited in claim 1, wherein the internal temperature of the tube culvert (210) is directly proportional to the conveying speed of the uniform length conductive conveying assembly (130) and the output assembly (140) of the tube culvert (210).

5. The mica tube coiling machine as recited in claim 1, wherein the number of the forming supporting wheels (310) and the shaping driving wheels (320) is two, the two forming supporting wheels (310) and the two shaping driving wheels (320) are symmetrically arranged, and the two forming supporting wheels (310) are horizontally arranged in the same plane.

6. The mica tube coiling machine as in claim 1, wherein the surface of the shaping supporting wheel (310) is provided with annular protrusions, the surface of the shaping driving wheel (320) is provided with shaping surface grooves (321), and the shaping surface grooves (321) are in a circular arc concave structure.

7. The mica tube coiling machine as recited in claim 6, wherein a driving motor (330) sleeved on the inner side of the shaping driving wheel (320) is fixedly installed on the inner side of the guide wheel frame (230), and the surface of the shaping surface groove (321) is in a rough surface structure.