CN112959650A - A assembly line equipment for producing flat PVC pyrocondensation pipe - Google Patents

Abstract

The production line equipment for producing the flat PVC heat-shrinkable tube has the advantages of uniform tube wall thickness, good shrinkage performance and large width after being folded. The PVC rubber tube production line comprises a mixer for mixing and stirring PVC main materials and auxiliary materials, an extruder for rubber materials, a forming die for a heat shrinkable tube, various heat preservation and cooling devices and a winding and packaging device for a flat heat shrinkable tube, wherein the moving track of the rubber materials or rubber tubes to be processed is linear movement in a horizontal plane from the extruder to the winding and packaging device, and the adopted device is a flat blowing type production line production device. A plurality of links in PVC heat-shrinkable tube production equipment are improved, so that the PVC heat-shrinkable tube adopting the production equipment has uniform wall thickness and better longitudinal and transverse shrinkage rates, the heat-shrinkable tube is folded and flattened into a flat heat-shrinkable tube, the width of the heat-shrinkable tube is larger, and the surface of the tube wall of the heat-shrinkable tube is flat, smooth and bright and has no flaws.

Description

A assembly line equipment for producing flat PVC pyrocondensation pipe

Technical Field

The invention relates to assembly line equipment for producing a PVC (polyvinyl chloride) heat-shrinkable tube, in particular to ultra-thin type large-diameter assembly line equipment for producing a flat PVC heat-shrinkable tube.

Background

The flat PVC heat-shrinkable tube occupies a small volume space on the package due to the flattening shape, thereby being convenient for transportation and reducing the transportation cost, and the flat PVC heat-shrinkable tube is also flattened during tube cutting so as to be convenient for cutting and improve the tube cutting quality.

When the flat PVC heat-shrinkable tube is applied, the flat PVC heat-shrinkable tube is sleeved on an object to be protected, has the special function of shrinking when heated, can be shrunk when heated to more than 98 ℃, and is convenient to use. The high-temperature-resistant aluminum alloy is used for the outer wrapping of electrolytic capacitors, inductors, battery monomers and battery packs, and has good high-temperature resistance and no secondary shrinkage.

In order to obtain the flat PVC heat-shrinkable tube with high smoothness, good heat-shrinkable performance and thin tube wall, the formula is complex, the manufacturing process difficulty is high, and the production line has more equipment procedures. Therefore, the production equipment and the production process used by each production manufacturer are different, the performance of the produced products is different due to different formulas, processes and equipment, and generally speaking, the flat PVC heat shrinkable tube on the market has thicker and uneven tube wall, so that the longitudinal shrinkage rate and the transverse shrinkage rate are lower, and a user generates cracks or wrinkles when the flat PVC heat shrinkable tube is used for outer packaging of applied products.

Disclosure of Invention

The invention aims to solve the technical problem of providing the assembly line equipment for producing the flat PVC heat-shrinkable tube, which has uniform tube wall thickness, good shrinkage performance and large width after being folded.

In order to solve the technical problems, the invention adopts the technical scheme that:

the assembly line equipment for producing the flat PVC heat-shrinkable tube comprises a mixer for mixing and stirring main PVC materials and auxiliary materials, a sizing material extruder, a heat-shrinkable tube forming die, various heat-preservation cooling equipment and flat heat-shrinkable tube rolling and packaging equipment, wherein the extruder is used for conveying the sizing material or the rubber tube to be processed to the rolling and packaging equipment, the moving track of the sizing material or the rubber tube to be processed is linear movement in a horizontal plane, and the adopted equipment is flat blowing type assembly line production equipment.

The forming die of the heat shrinkable tube consists of a primary forming die and a sizing die for secondary shaping, the primary forming die is connected to the discharge end of the extruder, and the sizing die is arranged behind the primary forming die; the sizing material extruded by the extruder is formed into tubular sizing material by the primary forming die and output, and the tubular sizing material with smaller pipe diameter and thicker pipe wall is formed into a heat-shrinkable semi-finished pipe with thinner pipe wall and meeting the pipe diameter requirement by the sizing die after being inflated and stretched.

The heat-preservation cooling equipment comprises an air-cooling section, a primary cooling section and a stretching and shaping section, wherein the air-cooling section is arranged behind a primary forming die, and an airflow column which is conical in shape and focused on the tubular rubber material is output by a temperature-control air disc fixedly connected to the primary forming die and is arranged around the circumference of the tubular rubber material; the primary cooling temperature reduction section is arranged between the primary forming die and the sizing die and is a water tank internally injected with cooling water, and the tubular rubber material penetrates through the water tank in a manner of being immersed in the water tank; the stretching and shaping section is arranged between the sizing die and the rolling and packaging equipment, and the heat-shrinkable semi-finished tube output by the sizing die is made into a finished heat-shrinkable tube through the stretching and shaping section.

The primary forming die is formed by sleeving and assembling an inner die and an outer die, a feeding port of the primary forming die is connected with a discharging port of the extruder, the inner die is composed of an injection guiding part and a positioning ring part, and the injection guiding part guides the glue extruded by the extruder to flow backwards along the surface of the glue from front to back; the positioning ring part fixedly sleeves the glue injection flow guide part in the outer die in a suspension manner, and a channel allowing the glue to pass through is arranged between the positioning ring part and the glue injection flow guide part; the front section part and the rear section part of the glue injection flow guide part are in a cone shape, the rear end of the rear section part of the glue injection flow guide part is a cylindrical glue injection shaping flow guide column which extends backwards along the axis, a central hole channel is arranged on the rear end surface of the outer die, the end part of the glue injection shaping flow guide column is arranged in the central hole channel, and a gap between the glue injection shaping flow guide column and the central hole channel forms a channel through which the glue material is extruded out of the primary forming die in a circular tube shape.

The glue injection flow guide part is internally provided with a gas flow channel, a gas inlet of the gas flow channel is arranged on the positioning ring part, a gas outlet of the gas flow channel is arranged on the end surface of the glue injection shaping flow guide column, and the main part of the gas flow channel is internally arranged in the glue injection flow guide part.

The sizing die is made of stainless steel materials and comprises three parts, namely a cylindrical outer shell cylinder, an inner shell tube and a tube inlet nozzle for allowing tubular sizing materials to enter the sizing die, wherein the outer shell cylinder and the inner shell tube are both hollow tube-shaped and are separable parts, the inner cavity of the outer shell cylinder is an axial cavity, the inner cavity of the inner shell tube is a raw tube moving channel, the axial cavity and the raw tube moving channel are coaxially arranged, the outer shell cylinder is sleeved outside the inner shell tube, two end faces of the outer shell cylinder and the inner shell tube are both open, a plug sealing plate of the tube inlet nozzle is hermetically connected to the front end faces of the outer shell cylinder and the inner shell tube, and a nozzle tube of the tube inlet nozzle is an inlet for allowing the tubular sizing materials to enter the raw tube moving channel; and a hot water heat preservation section, a cold and hot phase separation section and an ice water cooling section are arranged in the axial cavity between the inner wall of the outer shell barrel and the outer wall of the inner shell pipe from front to back.

The inner diameter of the original pipe moving channel is the same as the outer diameter of the heat-shrinkable semi-finished pipe.

The temperature control air disc is assembled by a circular base disc, a disc cylinder and a disc cover in sequence from front to back to form a closed body with an internal cavity, a thickening layer extending towards the disc cover is arranged in the center of the base disc, an axial channel penetrating through the thickening layer is arranged on the thickening layer, and the discharge end of the primary forming die can be inserted into the axial channel; at least three air inlets are arranged on the circumferential wall of the disc barrel at intervals, and at least one partition plate capable of preventing cold air flow blown in from the air inlets from directly entering the inner cavity is arranged in the inner cavity in the radial direction of the disc barrel opposite to the air inlets; the thickening layer is characterized in that the outer contour of the thickening layer is in a circular truncated cone shape, a cover core hole channel in the circular truncated cone shape is arranged in the center of the disc cover, the inner diameter of the cover core hole channel is gradually increased from back to front, the thickening layer is inserted into the cover core hole channel from front to back, and an air flow channel capable of enabling cold air in the inner cavity to be focused on the tubular rubber material extruded by the primary forming die through a conical air flow column is formed between the thickening layer and the cover core hole channel.

The length of the stretching and sizing section is 4.5-5.5 m, and the finished heat shrinkable tube is formed by inflating and stretching the sizing heat shrinkable tube output by the sizing die in a room temperature environment.

And the finished heat shrinkable tube is manufactured into a flat heat shrinkable tube through a flat rolling device consisting of a front compression roller device and a rear compression roller device.

Compared with the prior art, the invention improves a plurality of links in the production equipment of the PVC heat-shrinkable tube production line, so that the PVC heat-shrinkable tube adopting the production equipment of the production line has uniform wall thickness and better longitudinal and transverse shrinkage rates, the width of the heat-shrinkable tube after being folded and flattened into the flat heat-shrinkable tube is larger, and the surface of the tube wall of the heat-shrinkable tube is flat, smooth and bright and has no flaws.

Drawings

FIG. 1 is a schematic view of the PVC heat shrinkable tube production line of the present invention.

FIG. 2 is an enlarged view of the outer contour of the primary molding die of the present invention (without a flange).

Fig. 2.1 is a schematic view of the inner mold of fig. 2.

Fig. 2.2 is a left side view of fig. 2.1.

Fig. 2.3 is a cross-sectional view of fig. 2.1.

Fig. 2.4 is a right side view of fig. 2.3.

Fig. 2.5 is a cross-sectional view of the outer die of fig. 2.

Fig. 2.6 is a left side view of fig. 2.5.

FIG. 3 is an enlarged view of the temperature-controlled air plate of the present invention.

Fig. 3.1 is a right side view of fig. 3.

Fig. 3.2 is an exploded view of fig. 3.

Fig. 4 is a schematic view of a sizing die of the present invention.

Fig. 4.1 is a state diagram of the outer shell and the inner shell pipe in fig. 4.

Fig. 4.2 is a vertical sectional view of fig. 4.

The reference numbers are as follows:

the primary forming die 1, the inner die 11, the glue injection flow guide part 111, the front side part 1111, the transition part 1112, the rear side part 1113, the glue injection shaping flow guide column 112, the outer die 12, the central pore passage 121, the positioning ring part 13, the positioning block 14, the glue material flow passage 15, the gas flow passage 16, the tubular glue material 2, the front stage raw pipe 21, the rear stage raw pipe 22, the temperature control air disc 3, the base disc 31, the thickening layer 311, the central hole 312, the axial passage 313, the disc cylinder 32, the cylinder part 321, the cylinder edge 322, the closed cover plate 323, the air inlet 324, the air inlet cylinder 325, the disc cover 33, the cover core pore passage 331, the wind blocking wall 34, the base partition 341, the cylinder partition 342, the primary cooling section 4, the water tank 41, the double-rolling primary compression roller 42, the sizing die 5, the outer shell cylinder 51, the inner shell pipe 52, the axial cavity 53, the raw pipe moving passage 54, the partition 55, the hot water insulation section 56, the hot, The device comprises a hot water backwater small hole 571, a hot water overflow opening 572, an ice water cooling section 58, an ice water inlet 581, an ice water outlet 582, a shaping heat-shrinkable tube 6, a stretching shaping section 7, a supporting water filtering device 71, a front press roll device 81, a rear press roll device 82, a flat heat-shrinkable tube 9, a production line production device 100 and an extruder 101.

Detailed Description

The following is the assembly line production equipment for producing the flat PVC heat shrinkable tube and the corresponding process flow. The in-line production apparatus and the method of manufacturing a heat shrinkable tube according to the present invention will now be described in detail with reference to fig. 1 to 4.2.

As shown in fig. 1, the assembly line production equipment 100 for the flat PVC heat shrinkable tube of the present invention is manufactured by a blown film production process, the thickness of the production line can be as thin as 30 micrometers to 40 micrometers, the width of the folded flat PVC heat shrinkable tube (i.e. flattened round tube) can reach 110mm, and the width of the folded flat PVC heat shrinkable tube produced by the blown film process in the prior art is usually less than 90 mm.

The thinner the thickness of the heat shrinkable tube, the higher the grade, and when the heat shrinkable tube is used for the outer package of a consumer product, the thinner the heat shrinkable tube, the better the transparency, and the thinner the cost.

The longitudinal shrinkage rate of the flat heat-shrinkable tube 9 is 10-30%; the transverse shrinkage is 45-55%. The longitudinal shrinkage rate refers to the shrinkage proportion of the finished flat PVC heat-shrinkable tube after being immersed in hot water with the temperature of more than 95 ℃ and taken out, and the longitudinal length of the finished flat PVC heat-shrinkable tube is compared with the length before being immersed in the hot water; the transverse shrinkage rate is the proportion of shrinkage of the finished flat PVC heat-shrinkable tube when the finished flat PVC heat-shrinkable tube is taken out after being immersed in hot water with the temperature of more than 95 ℃, and the folded width of the finished flat PVC heat-shrinkable tube is compared with the folded width before being immersed in the hot water.

The flow line production equipment 100 adopts a flat blowing type flow line production line, that is, a PVC rubber material is extruded by an extruder 101 until a flat PVC heat shrinkable tube is rolled into a horizontally arranged linear flow line (and the produced heat shrinkable tube is completed by a tube film blowing and stretching process, compared with a process of biaxially stretching a PVC film and then closing the tube as a heat shrinkable tube, no folding line mark is formed on the tube wall of the heat shrinkable tube manufactured by the film blowing process), and compared with a vertical blowing type flow line production line (a plurality of process flows adopt vertically arranged linear flow line production), the rubber material or rubber tube is influenced by the weight of the rubber material or rubber tube to easily cause the defects of bending of the rubber tube, uneven thickness of the tube wall and the like, so that the flat blowing type flow line production equipment has higher difficulty, but has obvious advantages, and if a higher layer of a factory building is not needed, the equipment is convenient to install, and the operation surface of the operator is safe and convenient.

The assembly line production equipment 100 adopts a plurality of special processes, so that the product defects that flat PVC heat-shrinkable tubes are bent, the tube walls are thick and uneven, the width after folding is narrow, and the longitudinal and transverse shrinkage rates are small, which are easily caused by a flat blowing type assembly line, are overcome. The assembly line production equipment can produce the flat heat shrinkable tube 9 with the width of 13.5mm-110mm after being folded.

1. Mixer (including hot pot and cold pot)

The mixer adopts a cone-shaped funnel mixer, main materials and auxiliary materials for manufacturing the heat shrink tube are added into a hot pot for mixing, powder main materials and auxiliary materials are added at normal temperature, liquid auxiliary materials are added when powder is stirred to 85 ℃, then the powder is stirred at high speed to 130 ℃, the powder is discharged into a cold pot, and the powder is cooled to 45 ℃ for standby discharge.

2. Extruder 101

A horizontal type extruder, which is an extruder 101 conventionally used, is used, and the temperature of the extruded gum is set at 175-200 c, preferably 180 c.

3. Primary forming die 1 (also called hot die)

As shown in fig. 2-2.6, the primary forming mold 1 is fixed to the frame of the in-line production apparatus 100 by a flange (also called a die cover).

The rubber material extruding machine is connected with a rubber material outlet of an extruder 101, the rubber material extruded by the extruder 101 is extruded by the primary forming die 1 to form a tubular rubber material 2 in a round tube shape and is output, and the temperature of the output tubular rubber material 2 is 160-200 ℃.

Compared with the primary forming die 1 which is complex in the prior art and is formed by sleeving a plurality of parts layer by layer, the primary forming die 1 has the advantages of shortening the disassembly and assembly time, prolonging the single use period and greatly prolonging the use time after cleaning (after the die is used for a long time, a large amount of sizing materials losing effectiveness can be accumulated in the inner cavity of the die and need to be cleaned).

The primary forming die 1 is made of steel, the front end of the primary forming die is connected to a discharge port of a sizing material extruder 101, the rear end of the primary forming die is suspended and used for forming the sizing material into a tubular sizing material 2 (hereinafter, the tubular sizing material 2 just extruded by the primary forming die 1 is called a front-stage original pipe 21, and the pipe material cooled by the procedure of a subsequent primary cooling section 4 of the front-stage original pipe 21 is called a rear-stage original pipe 22, namely a shaping original pipe) to be output, and the primary forming die is formed by sleeving and assembling an inner die 11 and an outer die 12 together.

1) Inner mold 11

The input end of the internal mold 11 is fixedly connected with the rubber material output end of the extruder 101 in a sealing way through a clamping connection block, and the output end of the internal mold is sleeved in the external mold 12.

The inner mold 11 is composed of two parts, namely a glue injection flow guide part 111 and a positioning ring part 13, the glue injection flow guide part 111 guides glue extruded by the extruder 101 to flow backwards along the surface of the glue injection flow guide part from front to back (the side of the extruder 101 extruding the glue is front, the side of the glue moving direction is back, and the same applies below), the positioning ring part 13 fixedly fixes the glue injection flow guide part 111 in the outer mold 12 in a suspension manner, and a channel (hereinafter referred to as a glue material channel 15) allowing the glue to pass through is arranged between the positioning ring part 13 and the glue injection flow guide part 111.

a. The glue injection flow guide part 111 is divided into a front side part 1111, a transition part 1112 and a rear side part 1113.

The front side 1111 is a cone with a short cone height, the apex of which points forward.

The back part 1113 is a cone with a longer cone height, the vertex of the cone points backwards, a cylindrical glue injection shaping guide column 112 which extends backwards along the axis is arranged at the vertex of the cone, and the length of the glue injection shaping guide column 112 is 20-40 mm.

The transition portion 1112 is a cylinder having two ends respectively connected to the front-side portion 1111 and the rear-side portion 1113, i.e., it is a transition region between the front-side portion 1111 and the rear-side portion 1113. For easy assembly and disassembly, the preferred transition portion 1112 of the present invention has two sections, namely, a front transition section and a rear transition section, wherein the front transition section and the front side portion 1111 are integrated into a whole, the rear transition section and the rear side portion 1113 are integrated into a whole, and the front transition section and the rear transition section can be fixedly connected through a threaded connection or a male-female buckle connection structure.

The taper height of the front side portion 1111 is 1/5-1/4 of the taper height of the back side portion 1113, and the bottom surface diameter of the front side portion 1111, the outer diameter of the transition portion 1112 and the bottom surface diameter of the back side portion 1113 are the same.

b. Positioning ring part 13

The positioning ring part 13 is in a ring shape and circumferentially arranged around the outer wall of the transition part 1112, the thickness of the positioning ring part 13 in the radial direction is 10-20mm, the width of the positioning ring part 13 in the axial direction is 15-25mm, and the gap between the inner side of the positioning ring part 13 and the outer wall of the transition part 1112 (namely the sizing material runner 15) is 5-10mm (the specific thickness dimension or width dimension of the positioning ring part 13 in the radial direction and the axial direction and the radial dimension of the sizing material runner 15 are determined according to the dies used for manufacturing the tubular sizing materials 2 with different diameters).

At least three positioning blocks 14 are arranged between the inner side peripheral wall of the positioning ring part 13 and the outer peripheral wall of the transition part 1112 at intervals along the circumferential direction, and the positioning ring part 13, the positioning blocks 14 and the transition part 1112 are of an integrated structure. The preferred mode of the invention is as follows: the positioning ring part 13 is arranged at the periphery of the front transition section of the transition part 1112, and the number of the positioning blocks 14 is four.

The glue is injected from the front side portion 1111 to the back side portion 1113 through a glue flow passage 15 between two adjacent positioning blocks 14.

c. Gas flow channel 16

In order to avoid shrinkage adhesion between the inner walls of the tubes and sizing of the tube-shaped rubber material 2 caused when the rubber material is formed into the tube-shaped rubber material 2 for the first time, the inner die 11 is provided with an air flow channel 16 for spreading the tube-shaped rubber material 2.

The gas flow passage 16 is constituted by three sections from front to rear.

The first segment is disposed between the positioning ring portion 13 and the transition portion 1112. At least one of the positioning blocks 14 is provided with a built-in channel along the radial direction, the transition portion 1112 connected with the positioning block 14 is also provided with a built-in channel along the radial direction, meanwhile, the positioning ring portion 13 connected with the positioning block 14 is provided with an air inlet, and the air inlet on the positioning ring portion 13, the built-in channel on the positioning block 14 and the built-in channel on the transition portion 1112 are communicated to form the gas flow channel 16 of the first section. The air inlet is connected with air supply equipment through an external air pipe, an air regulating valve and a pressure relief valve.

The second section is disposed within the cone of the posterior portion 1113. A conical inner channel extending from front to back along the axial direction is arranged in the back part 1113, the front end of the conical inner channel is communicated with the gas flow channel 16 of the first section, and the back end of the conical inner channel extends to the glue injection shaping guide column 112.

The third section is arranged in the glue injection shaping guide column 112. The glue injection shaping guide column is internally provided with an inner column channel along the axial direction, the air outlet of the inner column channel is arranged on the rear end surface of the glue injection shaping guide column, and the front end of the inner column channel is communicated with the gas flow channel 16 of the second section. The aperture of the air outlet is 2.0-4.0 mm.

The process of blowing gas into the rubber material filled in the pipe comprises the following steps: the air enters the air flow channel 16 from the air inlet hole and is blown out through the air outlet hole, so that the air pressure in the tubular rubber material 2 is kept within a set range (note: in order to keep the air in the tubular rubber material 2 from leaking, a double-grinding primary compression roller 42 is arranged at the tail part of the subsequent primary cooling temperature reduction section 4, the double-grinding primary compression roller 42 is formed by tangency of a primary compression upper roller and a primary compression lower roller, and the tubular rubber material 2 passes through the primary compression upper roller and the primary compression lower roller, so that the air in the tubular rubber material 2 is prevented from leaking out), and when the air pressure in the tubular rubber material 2 exceeds a set value, the pressure is released through a pressure release valve arranged on an external air. The air pressure in the tubular rubber material 2 is adjusted according to the transverse shrinkage rate of the final finished thermoplastic pipe. When the transverse shrinkage rate is large, the air inflow is adjusted to be large, and otherwise, the air inflow is adjusted to be small.

The transverse shrinkage rate is the shrinkage rate of the finished thermoplastic pipe after stretching, expansion and shaping relative to the original shaping pipe, and the degree of shrinkage of the finished thermoplastic pipe is observed by immersing the finished thermoplastic pipe in hot water. The temperature at which the sizing log is formed into a tube is room temperature (15-30 deg.C), and the finished thermoplastic tube is heated to a temperature of 95 deg.C to shrink its diameter to substantially the size of the sizing log. Namely: the transverse shrinkage rate of the finished thermoplastic pipe (the thermoplastic pipe with the diameter meeting the design requirement) is large, which means that the diameter of the shaping original pipe is small, and the blowing amount should be adjusted to be large at the moment, so that the diameter of the shaping original pipe is large.

Specific tests are as follows: the percentage of the ratio of the width of a cut piece of flat heat shrinkable tube 9 after it is placed in hot water at 95 ℃ to the width before it is immersed in the hot water.

2) Outer mold 12

The outer contour of the outer die 12 is cylindrical. The front end face of the hollow cavity is open, the rear end face of the hollow cavity is a closed plane, the hollow cavity is provided with a conical hollow inner cavity, and the cavity wall of the hollow inner cavity and the outer wall of the glue injection flow guide part 111 of the inner mold 11 are smooth surfaces, so that glue can flow conveniently. A cylindrical central hole 121 is arranged in the center of the cavity bottom of the hollow inner cavity, and the length of the central hole 121 is the same as that of the glue injection shaping diversion column 112 arranged at the rear end of the inner mold 11.

The outer diameter of the outer mold 12 is the same as the outer diameter of the positioning ring part 13, and the wall thickness of the opening of the outer mold 12 is preferably the same as the wall thickness of the positioning ring part 13, so that the rubber material can smoothly flow along the surface of the rubber injection flow guide part 111 of the inner mold 11, and the appearance of a cylindrical shape with a neat outline can be obtained.

3) Assembling the inner mold 11 and the outer mold 12.

The rear transition sections of the rear side part 1113 and the transition part 1112 of the inner mold 11 are inserted into the hollow inner cavity of the outer mold 12, the glue injection shaping guide column 112 at the end part of the rear side part 1113 is inserted and positioned in the central hole channel 121 at the bottom of the hollow inner cavity of the outer mold 12, the rear end surface of the glue injection shaping guide column 112 is flush with the rear end surface of the outer mold 12, a gap is left between the outer wall of the glue injection shaping guide column 112 and the inner hole wall of the central hole channel 121, hereinafter, an annular space body formed by the gap is referred to as a glue tube forming flow channel, the size of the outer edge diameter of the glue tube forming flow channel determines the size of the outer diameter of the glue material for the first time forming into the outer diameter of the backing tube 21, the radial gap size of the glue tube forming flow channel determines the density of the extruded backing tube 21, the glue tube forming flow channel with the structure can effectively control the density of the. The radial clearance of the rubber tube forming runner is preferably 0.5 mm.

The length of the central hole 121 is slightly less than the length of the glue injection shaping guide column 112 arranged at the rear end of the inner mold 11, and the difference is 2-3mm, so that the glue can smoothly flow into the rubber tube forming flow passage without bottleneck resistance.

The conical shape of the back side part 1113 of the inner mold 11 is similar to that of the hollow cavity, but the size is different, and a glue flowing channel for the glue to be extruded to move from front to back is formed between the outer wall of the cone of the back side part 1113 and the inner wall of the cavity of the hollow cavity.

For further improvement of the positioning block 14: in order to reduce the resistance of the positioning block 14 to the flowing of the glue, the positioning block 14 is configured in a prism shape, two bases of the prism shape are respectively connected with the inner wall of the positioning ring part 13 and the outer wall of the transition part 1112, and each side surface of the prism shape is an inclined surface relative to the flowing direction of the glue.

4) The formation of the foreline 21.

The extruder 101 injects molten rubber material into the primary forming die 1, the rubber material flows down through the cone of the front side portion 1111 of the inner die 11, and is extruded under high pressure from front to back through the rubber material flowing channel to the rubber tube forming flow channel at the bottom of the hollow inner cavity to form a round tubular rubber material, meanwhile, under the action of air blown out from the air outlet and tensile force, the tubular rubber material 2 from the primary forming die 1 is lengthened from thick to thin, and the thinned and lengthened tubular rubber material 2 is called as the backing primary pipe 21.

4. Temperature control air plate 3

As shown in fig. 3 to 3.2, the molded foreline 21 has a high temperature (usually about 180 ℃) and a large plastic repulsive force, and therefore, it is necessary to cool it so that its contractibility is restricted to a certain extent.

There are two cooling methods in the prior art: water cooling and air cooling.

Water cooling in the prior art: the backing pipe 21 is passed through by cold water, and when the diameter of the backing pipe 21 is large and the hollow volume in the pipe is large, it floats on the water surface of the cold water, and thus, the effect of uniform cooling cannot be achieved. In addition, only water cooling is used, so that water flow marks are easily generated on the tube wall of the heat shrinkable tube, and the appearance of the finished heat shrinkable tube is affected.

Air cooling in the prior art: the primary backing tube 21 is cooled by the fan, which has the disadvantages that the wind power is not well controlled, and the blowing force applied to the primary backing tube 21 in the circumferential direction is not uniform.

The temperature control air disk 3 of the invention is sleeved on the primary forming die 1, and the cold air generated by the temperature control air disk is focused on a set section of the backing-stage original pipe 21 in the shape of a hollow cone (the set section is preferably positioned within 100mm from the discharge hole of the primary forming die 1), so that the backing-stage original pipe 21 can obtain cold air flow with controllable air speed and uniformity, the backing-stage original pipe 21 can be positioned and intensively cooled, the plastic deformation of the backing-stage original pipe 21 can be reduced as soon as possible in a short time after forming, and the bad deformation caused by the influence of gravity can be avoided. Its advantages are uniform and concentrated wind speed, gentle feeling and quick cooling.

After the temperature control air disc 3 is adopted to cool the preceding-stage original pipe 21, the pipe wall thickness of the produced PVC heat-shrinkable pipe can be as thin as 30-40 microns, and the PVC heat-shrinkable pipe is an ultrathin product. In the prior art, the wall thickness of the heat shrinkable tube is not uniform due to uneven cooling of water cooling and air cooling, so that the wall thickness of the heat shrinkable tube is difficult to be made thin (due to uneven thickness, that is, if a stretching traction force is set for a thick portion, the thin portion is easily torn).

The invention relates to a specific structure of a temperature control air disc 3:

the base plate 31, the drum 32 and the cover 33 are made of aluminum alloy or stainless steel materials, the outer diameter of the base plate 31 is 40-80cm, preferably 60cm, the axial length of the drum 32 is 8-20cm, preferably 10cm, the outer diameter of the drum 32 is smaller than the outer diameter of the base plate 31, and the inner diameter of the drum is 35-75 cm.

After the base plate 31, the disk cylinder 32 and the disk cover 33 are assembled together, the base plate 31 and the disk cover 33 are respectively and fixedly connected with the front end part and the rear end part of the disk cylinder 32, an internal cavity can be formed between the base plate 31 and the disk cover 33, an air inlet 324 is arranged on the peripheral wall of the disk cylinder 32, and the air inlet 324 is connected with an external air cooler through an air inlet cylinder 325. A choke wall 34 is disposed in the internal cavity at a position close to the circumferential wall of the drum 32 to prevent the air inlet drum 325 from directly blowing into the central area of the internal cavity from the air inlet 324 (the choke wall 34 may be a plurality of dot-matrix short-side partition walls (intermittent) extending along the inner circumference of the drum 32, or a plurality of annular closed-loop partition walls along the inner circumference of the drum 32), and the cooling air blown from the air inlet 324 needs to turn several turns to enter the central area of the internal cavity.

1) Base plate 31

The base plate 31 is fixed on the frame of the production line equipment 100, the base plate 31 is disc-shaped, the center of the base plate 31 is provided with a central hole 312, the periphery of the central hole 312 on the inner side surface of the base plate 31 is provided with a thickening layer 311 (integrated with the base plate 31) extending to the inner cavity, the thickening layer 311 is in a truncated cone shape along the axial outer contour shape, the major diameter bottom surface of the truncated cone shape is connected with the base plate 31, the minor diameter bottom surface of the truncated cone shape extends to the inner cavity, the thickening layer 311 is provided with an axial channel 313 which has the same axis with the central hole 312 and is communicated with the central hole, and the inner diameter of the axial channel 313 is slightly smaller than the aperture of the central hole 312.

The central hole 312 is hereinafter referred to as a die-entering hole, i.e. the die-entering hole is a platform for precisely aligning the primary forming die 1 with the temperature-controlled air plate 3, and the rear end of the outer die 12 of the primary forming die 1 is embedded in the die-entering hole during installation. The outer diameter of the outer die 12 of the primary forming die 1 is slightly smaller than the aperture of the die hole, and the difference between the outer diameter and the aperture is 3.0 mm-7.0 mm. The axial length of the central hole 312 is 20mm-30mm, the axial length of the axial channel 313 is 20mm-30mm, and the axial length of the axial channel 313 is preferably short or short, so that after the outer die 12 of the primary forming die 1 is placed in the die-in hole position, the rear end surface of the outer die 12 of the primary forming die 1 is close to the air outlet surface of the temperature control air disc 3 (i.e. close to the rear end surface of the disc cover 33), and thus, the foreline 21 extruded by the primary forming die 1 cannot be exposed for too long time under a room temperature environment (i.e. too long moving stroke in an environment without cold air cooling) and cannot be cooled in time to cause rapid shrinkage.

The choke wall 34 (hereinafter referred to as a base partition 341) extending axially rearward and having a ring shape is provided on the inner disk surface (i.e., the bottom surface disposed in the internal cavity) of the base disk 31 at a position adjacent to the disk edge of the base disk 31, and the base partition 341 may be provided in two, three or more ways in the radial direction of the base disk 31.

2) Disc cartridge 32

The hollow cylinder is divided into three parts, namely a cylinder part 321, a cylinder edge 322 and a closed cover plate 323.

The cylindrical portion 321 is a hollow cylinder.

The cylindrical edge 322 is provided on the front end surface (the surface that contacts the base disk 31) of the cylindrical portion 321 and projects radially outward.

The closed cover plate 323 is a disc which is arranged on the rear end face of the barrel part 321 and extends to the axis of the barrel part 321 along the radial direction, a rear cover hole is formed in the center of the closed cover plate 323, the aperture of the rear cover hole is 100mm-300mm, the periphery of the rear cover hole is a rear cover barrel which extends to the inner cavity along the axial direction, and internal threads are arranged on the inner wall of the rear cover barrel.

The air inlets 324 are arranged on the wall of the tube portion 321, and at least two air inlets 324 are arranged at intervals along the circumferential direction of the tube portion 321. Four intake ports 324 are preferred in the present invention, wherein the central angle between two adjacent intake ports 324 is 90 degrees.

Screw holes are arranged at intervals on the peripheries of the cylinder edge 322 and the base disk 31, and the cylinder edge 322 and the base disk 31 are fixedly connected together in a sealing way through bolts (an annular sealing gasket can be arranged between the cylinder edge 322 and the base disk 31).

The choke wall 34 (hereinafter referred to as a cylindrical partition 342) extending forward in the axial direction and having a ring shape is provided on the inner plate surface of the closed cover plate 323 (i.e., the plate surface placed in the internal cavity) in a position close to the edge side of the closed cover plate 323, the cylindrical partition 342 and the base partition 341 are arranged to overlap in the radial direction of the drum 32 (in order to prevent air blown in from the air inlet 324 from directly entering the central region in the internal cavity, the air inlet 324 is covered by the cylindrical partition 342 or the base partition 341 in the radial direction), and the axial lengths of the cylindrical partition 342 and the base partition 341 are each smaller than the distance between the inner plate surface of the closed cover plate 323 and the inner disk surface of the base disk 31, i.e., when the cylindrical portion 321 and the base disk 31 are mounted together, an air flow hole for allowing air to flow from one side of the cylindrical partition 342 to the other side is left between the front end surface of the cylindrical, similarly, an air flow window for allowing air to flow from one side of the base partition 341 to the other side is also provided between the rear end surface of the base partition 341 and the inner plate surface of the closing cover 323.

Namely: at least one air inlet curve is formed between the air inlet 324 and the middle area in the internal cavity due to the staggered arrangement of the base partition 341 and the cylinder partition 342, that is, under the blocking of the base partition 341 and the cylinder partition 342, the air blown by the air inlet 324 consumes part of wind energy and reduces the flow rate thereof on one hand, and on the other hand, part of choked flow flows along the circumferential direction of the base partition 341 and the cylinder partition 342 to be distributed (avoiding the turbulence formed by directly blowing the plurality of air inlets 324 into the central area) and then passes through the air inlet curve to slowly enter the central area, so that a stable gas space with uniform gas flow and near constant pressure is formed in the middle area.

The distance between the cylinder partition 342 or the base partition 341 and the air inlet 324 is 30mm-60 mm.

3) Dish cover 33

Which is installed on the rear cover hole of the closing cover plate 323 of the drum 32, is connected with the internal thread on the inner wall of the rear cover drum in a threaded screwing way and can move back and forth in the rear cover drum.

The shape of the cover can be a flat plate with a certain thickness or a flat plate with a peripheral cylinder (the peripheral cylinder is a circumferential wall which is arranged on the periphery of the flat plate and extends for a short length along the axial direction of the cover plate 33, the peripheral cylinder and the flat plate are of an integral structure), external threads are arranged on the circumferential wall of the cover plate 33, a plurality of handles or poking columns which are beneficial to an operator to screw the cover plate to rotate are arranged on the outer surface (namely the outer surface of the rear side) of the cover plate 33, and when the cover plate 33 is screwed in the rear cover cylinder, the operator can screw the cover plate 33 in the rear cover cylinder by rotating and poking the handles or the poking columns.

A circular cover core hole path 331 is arranged at the center of the disk cover 33, the cover core hole path 331 and the axial passage 313 arranged in the thickening layer 311 on the base disk 31 are coaxially arranged, the inner diameter of the cover core hole path 331 from back to front is increased from small to large, the hollow shape is a circular truncated cone shape, the circular truncated cone shape is similar to the circular truncated cone shape of the thickening layer 311 in size, after the disk cover 33, the disk cylinder 32 and the base disk 31 are combined and installed together, the cover core hole path 331 is sleeved on the outer wall of the thickening layer 311, the rear end of the axial passage 313 in the thickening layer 311 is close to the rear end face of the cover core hole path 331, a hollow circular truncated cone-shaped cavity passage with a certain thickness is formed in the circumferential direction by the radial gap between the cover core hole path 331 and the outer wall of the thickening layer 311, the cavity passage is an airflow passage for blowing out cooling gas from the inner cavity, and the shape of the blown out cooling gas can be changed into a conical airflow, preferably the width of the gap of the gas flow channel is between 5 and 25 mm. This structure can make the air current of the cooling gas that is used for carrying out the cooling to former pipe 21 that is blown out by accuse temperature wind dish 3 evenly, steady and focus on the position of setting for on former pipe 21 of preceding stage along former pipe 21 circumference, and it has better effect to reducing the plastic resilience force of former pipe 21 of preceding stage fast.

The size of the gap of the airflow channel can be adjusted by adjusting the moving distance of the disk cover 33 in the rear cover cylinder, and meanwhile, the axial length of the cooling airflow focused on the front-stage original pipe 21 is also adjusted, the axial length is set according to the pipe diameter of the produced heat-shrinkable pipe, namely when the pipe diameter is required to be larger, the heat capacity of the front-stage original pipe 21 is high, and the axial length and the airflow pressure can be properly adjusted to be larger, so that the effect of quickly cooling is achieved, and the preferred axial length of the invention is 20mm-40 mm.

The purpose that should be reached of accuse temperature wind dish 3 is as follows:

1) the backing-stage original pipe 21 extruded by the primary forming die 1 has high temperature, and needs to be cooled, so that the rigidity of the backing-stage original pipe 21 can be effectively improved after cooling, and the bending of the original pipe and the uneven thickness of the pipe wall caused by the gravity action in the backward transferring process can be avoided.

2) After the temperature-controlled air plate 3 and the primary forming die 1 are assembled, the extruded pre-stage original pipe 21 is pulled by the stretching device to pass through the cover core hole 331 on the plate cover 33, at this time, the cooling air blown in by the air inlet 324 arranged on the wall of the cylinder part 321 of the plate cylinder 32 is uniformly dispersed by the base partition 341 and the cylinder partition 342, and then an air constant pressure area is formed in the central area in the internal cavity, and the air in the area is blown out at a constant speed by the airflow channel under the action of pressure difference.

3) The blown air flow forms a conical air flow column, and the conical vertex of the air flow column is focused at a set position on the primary pipe 21, so that the aim of uniformly and stably cooling the primary pipe 21 in the circumferential direction is fulfilled.

5. Initial cooling section 4

As shown in figure 1, a water tank 41 with a length of 80-120 cm and filled with circulating cooling water is mainly adopted, the temperature of the cooling water is 15-30 ℃, and a foreline 21 cooled by a temperature control air plate 3 penetrates through the water tank 41 in a manner of immersing in the water tank 41 to be cooled again.

The structure can prevent the cooling water in the water tank 41 from flowing out quickly from the gap, and can ensure that the preceding stage raw pipe 21 is completely immersed in the cooling water, thereby obtaining better cooling effect.

The former-stage original pipe 21 passes through the initial cooling section 4 to form a basically-shaped later-stage original pipe 22 (also called a heat-shrinkable original pipe), and the later-stage original pipe 22 is the size of the original pipe which is shrunk by heat when the later-stage finished heat-shrinkable pipe is applied.

Before entering the sizing die 5, the temperature of the rear original pipe 22 of basic sizing is equivalent to the room temperature, the rear original pipe passes through the upper and lower double-rolling initial pressing rollers 42 with large diameters, the double-rolling initial pressing rollers 42 are composed of initial pressing upper rollers and initial pressing lower rollers, the initial pressing upper rollers are tangent to the initial pressing lower rollers, the initial pressing upper rollers are rubber wheels, the initial pressing lower rollers are steel wheels, the initial pressing upper rollers and the initial pressing lower rollers adopt rollers with rigid-flexible matching structures, the heat of the rear original pipe 22 can be quickly guided away (the steel wheels conduct heat quickly), the rear original pipe 22 can be compacted and water drops on the pipe wall can be removed (after the rear original pipe 22 is compacted, when the pipe is inflated in a later stretching and sizing procedure, the air leakage of the gas in the pipe from the positions between the initial pressing upper rollers and the initial pressing lower rollers to the front original pipe 21 direction can be avoided).

The diameters of the upper primary pressing roller and the lower primary pressing roller are preferably 180mm (the diameters are larger, heat dissipation is easy), and the upper primary pressing roller and the lower primary pressing roller rotate oppositely.

6. Sizing die 5 (also called water mould)

As shown in fig. 4-4.2, the sizing die 5 functions to: the later-stage original pipe 22 with smaller pipe diameter and thicker pipe wall is inflated and stretched to become the shaped heat-shrinkable pipe 6 (also called a heat-shrinkable semi-finished pipe) with thinner pipe wall and the pipe diameter meeting the requirement.

The sizing die 5 is made of stainless steel and is composed of three parts, namely a cylindrical outer shell cylinder 51, an inner shell pipe 52 and an inlet nozzle for the rear-stage raw pipe 22 to enter the sizing die 5. The outer casing 51 and the inner casing 52 are hollow cylinders, which are separable parts, the outer casing 51 is fitted over the inner casing 52, both end surfaces of the outer casing 51 and the inner casing 52 are open, hereinafter, the hollow cavity of the outer casing 51 is referred to as an axial cavity 53, and the hollow cavity of the inner casing 52 is referred to as a raw pipe moving passage 54.

The axial cavity 53 is arranged coaxially with the raw pipe moving passage 54. The inner diameter of the original tube moving passage 54 determines the outer diameter of the produced shaped heat shrinkable tube 6.

1) Inner casing 52

The outer diameter of the inner shell tube 52 is smaller than the inner diameter of the axial cavity 53 by a difference of 10mm-40mm, the inner diameter of the original tube moving passage 54 is slightly larger than the outer diameter of the shaped heat shrinkable tube 6, and the outer diameter of the shaped heat shrinkable tube 6 is preferably 99% of the inner diameter of the original tube moving passage 54.

A plurality of partition plates 55 are fixedly connected to the outer circumferential wall of the inner shell 52 at intervals along the axial direction thereof, and when the inner shell 52 is inserted into the outer shell 51, the outer circumferential edge of each partition plate 55 is in sealed contact with the inner wall of the outer shell 51, so that the axial cavity 53 between the outer wall of the inner shell 52 and the inner wall of the outer shell 51 is divided into a plurality of mutually sealed cavity sections along the axial direction, the cavity sections are respectively a hot water heat preservation section 56, a cold heat preservation section 57 and an ice water cooling section 58 from front to back (the direction in which the rear-stage raw tube 22 enters the sizing die 5 is front, and the direction in which the rear-stage raw tube 22 exits from the sizing die 5 is back, the hot water heat preservation section 56 is used for softening the rear-stage raw tube 22 entering the raw tube moving passage 54, and the cold heat preservation section 57 is used for expanding the softened rear-stage raw tube 22 into the rear-stage raw tube 22 of the required thickness and diameter of the shaped heat shrinkable tube 6 under the action of the gas filled in the rear-stage raw tube 22, the ice water cooling section 58 is used for cooling and shaping the rear-stage original pipe 22 with the thickness and the pipe diameter basically meeting the requirements.

2) Housing tube 51

The front part of the wall of the outer shell tube 51 corresponding to the hot water heat preservation section 56 is provided with a hot water inlet 561 (the temperature of hot water is controlled at 95 +/-2 ℃), the rear part of the wall of the inner shell tube 52 corresponding to the hot water heat preservation section 56 is provided with a plurality of hot water inlet apertures 562, and hot water entering the hot water heat preservation section 56 from the hot water inlet 561 enters the original tube moving channel 54 through the hot water inlet apertures 562.

A hot water overflow opening 572 is provided at the rear portion of the wall of the outer shell 51 corresponding to the cold-hot separation section 57 (the hot water insulation section 56 and the cold-hot separation section 57 can be filled with hot water by adopting an overflow mode), a plurality of hot water return small holes 571 are provided at the front portion of the wall of the inner shell 52 corresponding to the cold-hot separation section 57, and hot water entering the original pipe moving channel 54 enters the cold-hot separation section 57 from the hot water return small holes 571 and is then discharged out of the outer shell 51 through the hot water overflow opening 572.

The front part and the rear part of the wall of the outer shell barrel 51 corresponding to the ice water cooling section 58 are respectively provided with an ice water inlet 581 (the water temperature of ice water is controlled at 10-15 ℃) and an ice water outlet 582, and a sealing structure is arranged between the ice water cooling section 58 and the original pipe moving channel 54 in the inner shell barrel, namely, the ice water entering the ice water cooling section 58 enters the ice water cooling section 58 from the ice water inlet 581, passes through the cavity of the ice water cooling section 58 and is discharged out of the outer shell barrel 51 from the ice water outlet 582.

3) Inlet nozzle

The inlet nozzle is integrally formed by a plug seal plate and a nozzle pipe arranged on the plug seal plate and extending outwards, the plug seal plate is hermetically connected on the front end surfaces of the outer shell 51 and the inner shell 52, the inner diameter of the nozzle pipe is matched with the outer diameter of the rear-stage raw pipe 22 conveyed by the primary forming die 1, and the rear-stage raw pipe 22 enters the raw pipe moving channel 54 of the sizing die 5 through the nozzle pipe during production.

4) Forming process of shaped heat shrink tube 6

The raw pipe transfer passage 54 is used to transfer the undrawn next-stage raw pipe 22 transferred from the primary cooling section 4 (the process section after the primary molding die 1). The hot water temperature-retaining section 56 and the cold-hot phase-separating section 57 are filled with hot water for retaining the temperature of the subsequent-stage raw pipe 22 in the raw pipe moving passage 54 corresponding to the sections (to place the subsequent-stage raw pipe 22 in a soft expanded state). The temperature of the rear-stage original tube 22 entering the original tube moving passage 54 is at room temperature, the rear-stage original tube 22 needs to be heated and softened before becoming the shaped heat shrinkable tube 6, and under the action of gas inflation and tensile force (the gas is inflated by the secondary-shaped stretching and shaping section 7, and the inflated gas is inflated from back to front), the tube diameter of the softened rear-stage original tube 22 is enlarged to be close to the inner diameter of the original tube moving passage 54, and the tube wall is thinned to the specification required for the shaped heat shrinkable tube 6. The ice water cooling section 58 injects cold water to rapidly cool the rear-stage original tube 22 with the enlarged inner diameter in the original tube moving channel 54 corresponding to the section, so as to reduce the plastic resilience of the softened rear-stage original tube 22, i.e. improve the rigidity (ice water sizing) of the rear-stage original tube 22, and after the sizing die 5 is moved out, the tube diameter and the tube wall thickness of the rear-stage original tube 22 basically reach the size specification required by the sizing heat shrinkable tube 6. The heat shrinkable tube shaped by the sizing die 5 has the advantages of stable shape, small axial deviation, moderate softness and hardness of the tube wall, good shaping and no distortion after being placed for a long time.

Since the rear-stage raw pipe 22 entering the raw pipe moving passage 54 expands under the action of the gas injected into the rear-stage raw pipe 22, when the rear-stage raw pipe 22 moves to the ice water cooling section 58, the pipe wall of the rear-stage raw pipe 22 of this section moves backward in a manner of being substantially closely attached to the inner wall of the raw pipe moving passage 54, so that the hot water entering the raw pipe moving passage 54 from the hot water inlet 561 is subjected to resistance at the boundary between the ice water cooling section 58 and the cold and hot separation section 57, and the part of the hot water cannot enter the raw pipe moving passage 54 corresponding to the ice water cooling section 58 but can be discharged only from the hot water return small holes 571 with relatively small resistance.

The length of the sizing die 5 is preferably 280-330 mm, the lengths of the hot water heat preservation section 56 and the cold and hot phase separation section 57 are basically the same, the length of the ice water cooling section 58 is equal to the sum of the lengths of the hot water heat preservation section 56 and the cold and hot phase separation section 57, and the longer the length of the ice water cooling section 58 is, the better the cooling and shaping are.

The hot water and the cold water both enter from the front and flow out from the back, and both enter from the bottom and flow out from the top. Lower in and upper out benefits: the hot water and the cold water entering the three sections are in a state of being filled with the three sections of cavities, and if the hot water and the cold water are in a state of being filled with the three sections of cavities, the water in the three sections of cavities is easy to be discharged under the condition that the corresponding cavities are not filled with the water. Benefits of forward and backward play: the hot and cold sequence is favorable for softening, expanding and shaping the rear-stage original pipe 22.

The heat shrinkable tube produced by the sizing die 5 has good shaping performance and is not easy to bend and deform.

7. Stretch-forming section 7

As shown in fig. 1, the shaped heat shrinkable tube 6 outputted from the sizing die 5 is moved by a backward stretching force for 4.5 to 5.5 meters in an inflated state and in a room temperature environment, thereby further thinning the wall of the shaped heat shrinkable tube 6 to lower the temperature thereof to the room temperature, and at the same time, further increasing the longitudinal shrinkage rate of the shaped heat shrinkable tube 6 by a pulling force.

In the stretching and shaping section 7 in the heat shrinkable tube manufacturing process in the prior art, the movement distance of the shaped heat shrinkable tube 6 is 1-1.5 m at room temperature, and the shorter distance is because the tube wall is softer and the heat shrinkable tube can be bent and deformed under the action of gravity. The length of the former-stage original pipe 21 can be 4.5-5.5 meters, the rigidity of the pipe wall of the former-stage original pipe 21 is fully reduced by the primary cooling temperature reduction section 4 and the elongated ice water cooling section 58 of the sizing die 5, so that the rigidity of the pipe wall of the former-stage original pipe is improved, the former-stage original pipe does not bend and deform when the former-stage original pipe moves in suspension for a long distance, in addition, the longer the length of the stretching and shaping section 7 is, the longer the time for filling air (purifying compressed gas) into the pipe for one time is (the air can be maintained for 8-12 hours by filling air once in the invention), namely, the frequent air filling into the pipe by operators is not needed.

In order to ensure that the shaping heat shrinkable tube 6 stably moves in the stretching and shaping section 7, a supporting water filtering device 71 is arranged in the middle of the stretching and shaping section 7 and consists of a supporting rod supported on the ground and water filtering cotton arranged at the top of the supporting rod, and the moving shaping heat shrinkable tube 6 passes through a pipe hole formed by winding the water filtering cotton and moves from front to back.

8. Flattening device

As shown in fig. 1, the shaped heat shrinkable tube 6 moved to the end of the stretching shaped section 7 is called a finished heat shrinkable tube, and since the tubular heat shrinkable tube is difficult to package and transport, it is necessary to flatten it, roll it, and package it for storage.

The in-line production apparatus 100 of the present invention is provided with a front press roller device 81 and a rear press roller device 82 at the rear end of the stretch-setting section 7.

1) The front compression roller device 81 consists of a front compression roller and a front compression roller with large diameters, the front compression roller and the front compression roller are arranged up and down and are tangent, the front compression roller and the front compression roller adopt rollers with rigid-flexible matching structures, heat of finished product heat shrinkage can be conducted away quickly (the heat conduction of the steel roller is fast), and the finished product heat shrinkage pipe can be compacted and residual water drops on the pipe wall of the finished product heat shrinkage pipe can be removed (after the finished product heat shrinkage pipe is compacted, the gas filled into the shaped heat shrinkage pipe 6 by the stretching and shaping section 7 can be ensured to be remained in the shaped heat shrinkage pipe 6 between the double-rolling primary compression roller 42 and the front compression roller device 81).

The diameter of the front rubber-pressing roller and the diameter of the front steel-pressing roller are preferably 180mm (the diameters are larger, so that heat dissipation is easy), and the front rubber-pressing roller and the front steel-pressing roller rotate oppositely.

2) And the rear compression roller device 82 is positioned behind the front compression roller device 81 and is spaced at a distance of about 30-50cm, and consists of a rear compression roller with a large diameter and a rear compression roller, the rear compression roller and the rear compression roller are arranged up and down and are tangent to each other, and the main function of the rear compression roller device is to perform rolling and sizing again on the heat-shrinkable tube which is rolled by the front compression roller device 81, has water beads removed and is flat, so that the heat-shrinkable tube can be packaged into a flat heat-shrinkable tube 9 which can be packaged in a roll and is in a room temperature state.

The front pressure roller in the front pressure roller device 81 and the rear pressure roller in the rear pressure roller device 82 move up and down through the cylinder transmission mechanism, and the pressure-bearing roller device has the advantages that the stress on the rollers is uniform and balanced, so that the front pressure roller and the front pressure roller can be in contact with each other in a tangent mode, and the rear pressure roller can be in contact with each other in a tangent mode.

9. Slip structure

In the process of winding the flat heat shrinkable tube 9 (also called winding), the degree of tightness of the wound tape (the flat heat shrinkable tube 9) is different sometimes, and loose results in the incompact winding of the finished product, so that the flat heat shrinkable tube 9 is easily damaged in the packaging and transportation process. If the heat shrinkable tube is tightened, the flat heat shrinkable tube 9 is easily broken in the winding process. The slip structure is arranged on the output shaft of the winding motor, and when the belt winding resistance is large, the slip structure enables the motor to idle so as to prevent the pipe belt from being broken.

Claims (10)

1. The utility model provides an assembly line equipment for producing flat PVC pyrocondensation pipe, includes the blendor that is used for mixing PVC major ingredient and auxiliary material stirring, extruder (101) of sizing material, the forming die of pyrocondensation pipe, the rolling equipment of various heat preservation cooling device and flat pyrocondensation pipe (9), its characterized in that: from the extruder (101) to a rolling and packaging device, the movement track of the sizing material or the rubber tube to be processed is linear movement in the horizontal plane, and the adopted device is a flat blowing type flow line production device (100).

2. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 1, wherein: the forming die of the heat shrinkable tube comprises a primary forming die (1) and a sizing die (5) for secondary shaping, wherein the primary forming die (1) is connected to the discharge end of the extruder (101), and the sizing die (5) is arranged behind the primary forming die (1); the primary forming die (1) forms the rubber material extruded by the extruder (101) into tubular rubber material (2) and outputs the tubular rubber material, and the sizing die (5) forms the tubular rubber material (2) with smaller pipe diameter and thicker pipe wall into a heat-shrinkable semi-finished pipe with thinner pipe wall and pipe diameter meeting the requirements after inflation and stretching.

3. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 2, wherein: the heat-preservation cooling equipment comprises an air-cooling section, a primary cooling section (4) and a stretching and shaping section (7), wherein the air-cooling section is arranged behind a primary forming die (1), and an airflow column which is conical in shape and focused on the tubular rubber material (2) is output by a temperature-control air disc (3) fixedly connected to the primary forming die (1) and is circumferentially arranged around the tubular rubber material (2); the primary cooling temperature reduction section (4) is arranged between the primary forming die (1) and the sizing die (5) and is a water tank (41) internally injected with cooling water, and the tubular rubber material (2) penetrates through the water tank (41) in a manner of being immersed in the water tank (41); the stretching and shaping section (7) is arranged between the sizing die (5) and the rolling and packaging equipment, and the heat-shrinkable semi-finished tube output by the sizing die (5) is made into a finished heat-shrinkable tube through the stretching and shaping section (7).

4. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 3, wherein: the primary forming die (1) is formed by sleeving and assembling an inner die (11) and an outer die (12), a feeding port of the primary forming die (1) is connected with a discharging port of an extruder (101), the inner die (11) is composed of a glue injection flow guide part (111) and a positioning ring part (13), and the glue injection flow guide part (111) guides glue extruded by the extruder (101) to directionally flow backwards along the surface of the glue injection flow guide part from front to back; the positioning ring part (13) fixedly sleeves the glue injection flow guide part (111) in the outer mold (12) in a suspension mode, and a channel allowing the glue to pass through is arranged between the positioning ring part (13) and the glue injection flow guide part (111); the front section and the rear section of the glue injection flow guide part (111) are in a cone shape, the rear end of the rear section of the glue injection flow guide part (111) is a cylindrical glue injection shaping flow guide column (112) which extends backwards along the axis, a central hole passage (121) is formed in the rear end face of the outer die (12), the end part of the glue injection shaping flow guide column (112) is arranged in the central hole passage (121), and a gap between the glue injection shaping flow guide column (112) and the central hole passage (121) forms a channel through which the glue is extruded out of the primary forming die (1) in a circular tube shape.

5. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 4, wherein: a gas flow channel (16) is arranged in the glue injection flow guide part (111), a gas inlet of the gas flow channel (16) is arranged on the positioning ring part (13), a gas outlet of the gas flow channel (16) is arranged on the end face of the glue injection shaping flow guide column (112), and the main body part of the gas flow channel (16) is arranged in the glue injection flow guide part (111).

6. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 3, wherein: the sizing die (5) is made of stainless steel materials and comprises three parts, namely a cylindrical outer shell cylinder (51), an inner shell pipe (52) and a pipe inlet nozzle for allowing tubular rubber (2) to enter the sizing die (5), wherein the outer shell cylinder (51) and the inner shell pipe (52) are both hollow cylindrical parts and are separable parts, the inner cavity of the outer shell cylinder (51) is an axial cavity (53), the inner cavity of the inner shell pipe (52) is a raw pipe moving channel (54), the axial cavity (53) and the raw pipe moving channel (54) are coaxially arranged, the outer shell cylinder (51) is sleeved outside the inner shell pipe (52), and two end faces of the outer shell cylinder (51) and the inner shell pipe (52) are both open, the plug closing plate of the inlet nozzle is hermetically connected to the front end surfaces of the outer shell cylinder (51) and the inner shell tube (52), and the nozzle pipe of the inlet nozzle is an inlet of the tubular sizing material (2) entering the raw pipe moving channel (54); a hot water heat preservation section (56), a cold and hot separation section (57) and an ice water cooling section (58) are arranged in the axial cavity (53) between the inner wall of the outer shell cylinder (51) and the outer wall of the inner shell pipe (52) from front to back.

7. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 6, wherein: the inner diameter of the raw pipe moving channel (54) is the same as the outer diameter of the heat-shrinkable semi-finished pipe.

8. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 3, wherein: the temperature control air disc (3) is formed by assembling a circular base disc (31), a disc cylinder (32) and a disc cover (33) from front to back in sequence to form a closed body with an internal cavity, a thickening layer (311) extending towards the disc cover (33) is arranged in the center of the base disc (31), an axial channel (313) penetrating through the thickening layer (311) is arranged on the thickening layer (311), and the discharge end of the primary forming die (1) can be inserted into the axial channel (313); at least three air inlets (324) are arranged on the circumferential wall of the drum (32) at intervals, and at least one partition plate (55) capable of preventing cold air flow blown by the air inlets (324) from directly entering the inner cavity is arranged in the inner cavity in the radial direction of the drum (32) opposite to the air inlets (324); the outer contour shape of the thickening layer (311) is a circular truncated cone, a cover core hole channel (331) which is in the shape of a circular truncated cone is arranged in the center of the disc cover (33), the inner diameter of the cover core hole channel (331) is gradually increased from back to front, the thickening layer (311) is inserted into the cover core hole channel (331) from front to back, and an air flow channel which can focus cold air in an internal cavity on tubular glue (2) extruded by the primary forming die (1) in a conical air flow column is formed between the thickening layer (311).

9. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 3, wherein: the length of the stretching and shaping section (7) is 4.5-5.5 m, and the shaping heat shrinkable tube (6) output by the sizing die (5) is inflated and stretched to form a finished heat shrinkable tube at room temperature.

10. The line apparatus for producing a flat PVC heat shrinkable tube according to claim 9, wherein: and the finished heat shrinkable tube is manufactured into a flat heat shrinkable tube (9) through a flat rolling device consisting of a front compression roller device (81) and a rear compression roller device (82).

Images