CN211426857U - Joint and hose processing equipment - Google Patents

Abstract

The utility model provides a hose processing equipment, be used for hot melt shaping hose, hose processing equipment includes the shaping module, carry the module and cut the module, carry the module to be used for carrying the hose to cut in the module, the shaping module is processed the hose that cuts in the module, cut the module and cut the fashioned hose to required length, the shaping module includes drive arrangement, heating block and profiled sheeting, drive arrangement connects the heating block, the profiled sheeting is installed on the heating block, be equipped with a plurality of profile modeling bosss on the profiled sheeting, drive arrangement is used for driving the profile modeling boss and inserts inside the hose, heating block adds the hot forming sheeting, become the shape the same with the profile modeling boss with the one end hot melt of hose, a joint, be used for connecting data transmission line, including the crust, sheath and above-mentioned machine-shaping hose, the joint is used for protecting data transmission line.

Description

Joint and hose processing equipment

Technical Field

The utility model relates to a joint and hose processing equipment with hose.

Background

At present, in the processing procedure of hot-melt forming of the hose, the hose needs to be manually inserted into a high-temperature profiling boss to be formed through hot melting, the processing efficiency is low, and the problems of low yield, personnel burn and the like exist.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is desirable to provide a joint having a hose and a hose processing apparatus for processing the hose.

A joint for connecting a data transmission line comprises a hard shell and a sheath, wherein the hard shell is connected with the sheath, the joint further comprises a hose for the data transmission line to pass through, one end of the hose is larger than the other end of the hose, the larger end of the hose is accommodated in the hard shell, and the smaller end of the hose extends out of the sheath to protect the data transmission line.

Further, a hose processing equipment for the above-mentioned hose of hot melt shaping, including the shaping module, the shaping module includes drive arrangement, heating piece and profiled sheeting, drive arrangement connects the heating piece, the profiled sheeting install in on the heating piece, hose processing equipment still includes the profile modeling boss, the profile modeling boss install in on the profiled sheeting, drive arrangement is used for the drive the profile modeling boss inserts inside the hose, the heating piece heating the profiled sheeting, in order with the one end hot melt of hose becomes with the shape that the profile modeling boss is the same, makes the size of hose one end is greater than the size of the other end.

Further, the hose processing equipment still includes the transport module, carry the module orientation the profile modeling boss is placed, carry the module including drive mechanism and follower, drive mechanism includes motor, driving shaft, a plurality of driving gear and a plurality of initiative delivery wheel, the driving shaft is connected the motor, every initiative delivery wheel fixed connection one the driving gear is located with the cover on the driving shaft, follower includes a plurality of platforms, a plurality of minor axis, a plurality of elastic component, a plurality of driven gear and a plurality of driven delivery wheel, the platform install in the drive mechanism top, every the minor axis both ends are fixed on the platform, every driven delivery wheel fixed connection one driven gear overlaps and is established on one the minor axis, driven gear with the driving gear meshes mutually, the elastic component is connected the platform is used for supporting to push towards initiative delivery wheel direction driven delivery wheel to compress tightly the hose The motor drives the driving gear and the driving conveying wheel to rotate, the driving gear drives the driven gear and the driven conveying wheel to rotate, and the driving conveying wheel and the driven conveying wheel convey hoses through friction.

Further, carry the module still includes complementary unit, complementary unit arranges in the master mechanism deviates from one side of shaping module, complementary unit includes the support, goes up the auxiliary shaft, lower auxiliary shaft, goes up gyro wheel and lower gyro wheel, go up the auxiliary shaft and install down the auxiliary shaft both ends on the support, it establishes to go up the gyro wheel cover go up on the auxiliary shaft, the gyro wheel cover is established down on the auxiliary shaft, it hugs closely to go up the gyro wheel lower the gyro wheel is used for right the hose gets into master mechanism reaches lead before the follower.

Furthermore, a plurality of hose grooves are respectively formed in the driving conveying wheel, the driven conveying wheel, the upper roller and the lower roller, and the plurality of hose grooves of the driving conveying wheel and the driven conveying wheel respectively correspond to the plurality of hose grooves of the upper roller and the lower roller one by one to accommodate the hoses.

Furthermore, the hose processing equipment also comprises a cutting module which is arranged between the forming die and the conveying module, the cutting module comprises a cutting plate, a first lifter, a plurality of guide posts, a positioning rod, a cutting frame and a blade, the first lifter is arranged at the top of the cutting frame in a penetrating way, the guide post is vertically arranged on the cutting frame, the cutting plate is arranged on the guide post in a penetrating way, the cutting plate is connected with the first lifter, two ends of the positioning rod are arranged on the cutting frame, the blade is arranged on one side of the cutting plate close to the positioning rod, the first lifter is used for driving the blade to move up and down to cut the hose, the cutting frame is provided with a plurality of corresponding cutting frame hose holes, and the positioning rod hose holes and the cutting frame hose holes are used for accommodating the hoses.

Furthermore, the cutting module further comprises an upper pressing plate, a plurality of pressing blocks and a second lifter, the second lifter is arranged below the cutting frame, the upper pressing plate penetrates through the guide pillar and is connected with the second lifter, the pressing blocks are fixed on the upper pressing plate, the second lifter drives the pressing blocks to move up and down, the cutting frame is provided with a plurality of hose upper pressing grooves, a plurality of corresponding hose lower pressing grooves are formed in the pressing blocks, the hose lower pressing grooves and the hose upper pressing grooves are used for pressing and fixing the hoses during cutting, and each hose upper pressing groove is connected with one hose hole of the cutting frame so as to fully press the hoses.

Further, the shaping module still includes temperature sensor, temperature sensor wears to locate the heat preservation frame top, and connect the heating piece is used for measuring and monitoring the heating piece reaches the temperature of shaping board.

Further, the hose processing equipment still includes the base station, be equipped with protection casing, discharge gate and control cabinet on the base station, the protection casing is used for the separation the high temperature of profiled sheeting is in order to protect the staff, the discharge gate is located cut the module below for the roll-off cuts the back and drops the hose, the control cabinet is used for operation control.

Compared with the prior art, the hose processing equipment utilizes the automatic hot melt shaping hose of shaping module to avoided personnel to scald because of the high temperature, improved the shaping efficiency of hose, reduced the human cost simultaneously.

Description of the main elements

Hose processing equipment 100

Hose 200

Joint 300

Hard shell 310

Sheath 320

Conveying module 10

Cutting module 20

Molding die set 30

Base 40

Active mechanism 11

Motor 111

Coupling 112

Drive shaft 113

Drive gear 114

Drive delivery wheel 115

Drive shaft sleeve 116

Driven mechanism 12

Hanging platform 121

Short shaft 122

Elastic member 123

Driven gear 124

Driven delivery wheel 125

Guide post 126

Fastener 127

Conveying frame 13

Auxiliary mechanism 14

Support 141

Upper auxiliary shaft 142

Lower auxiliary shaft 143

Upper roller 144

Lower roller 145

Auxiliary shaft sleeve 146

Hose grooves 1151, 1251, 1441, 1451

Cutting board 21

First lifter 22

A plurality of guide posts 23

Upper pressure plate 24

A plurality of compacts 25

Hose hold-down 251

Second lifter 26

Positioning rod 27

Positioning rod hose hole 271

Cutting frame 28

Cut frame hose hole 281

Hose upper pressure groove 282

Blade 29

Drive device 31

Translation plate 32

Slide rail 33

Heating block 34

Shaping plate 35

Profiling boss 351

Temperature sensor 36

Heat preservation frame 37

Heating rod 38

Protective cover 41

Discharge port 42

Console 43

Drawings

Fig. 1 is a schematic perspective view of the hose processing apparatus of the present invention.

Fig. 2 is a perspective view of the conveying module.

FIG. 3 is a perspective view of a cutting module.

FIG. 4 is an exploded view of the cutting module.

Fig. 5 is a perspective view of the cutting frame of fig. 4.

Fig. 6 is an exploded view of the forming module.

Fig. 7 is an exploded view of the joint.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work all belong to the protection scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical", "horizontal", "left", "right" and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "or/and" includes any and all combinations of one or more of the associated listed items.

Some embodiments of the present invention will be described in detail below with reference to the accompanying drawings. In the following embodiments, features of the embodiments may be combined with each other without conflict.

Referring to fig. 1, a hose processing apparatus 100 is used for processing a hose 200, and the hose processing apparatus 100 includes a conveying module 10, a cutting module 20, a forming module 30 and a base 40. The conveying module 10, the cutting module 20 and the forming module 30 are mounted on the base 40. The base 40 is placed on the bottom surface. The delivery module 10 is used to deliver the hose 200 to the cutting module 20. The forming module 30 processes the hose 200 in the cutting module 20. The cutting module 20 cuts the formed hose 200 to a desired length.

Referring to fig. 2, the conveying module 10 includes a driving mechanism 11, a driven mechanism 12, a conveying frame 13 and an auxiliary mechanism 14. The driving mechanism 11 and the driven mechanism 12 are mounted on the conveying frame 13. The auxiliary mechanism 14 is mounted on the base 40. The driving mechanism 11 and the driven mechanism 12 are used for conveying the hose 200. The auxiliary mechanism 14 is used for guiding the hose 200 before entering the driving mechanism 11 and the driven mechanism 12.

The drive mechanism 11 includes a motor 111, a coupling 112, a drive shaft 113, a plurality of drive gears 114, a plurality of drive transmission wheels 115, and a drive shaft sleeve 116. The motor 111 is mounted on the base 40. The driving shaft 113 is movably installed on the conveying frame 13. The driving shaft 113 is connected to the motor 111 through a coupling 112, and a driving gear 114, a driving transmission wheel 115 and a driving shaft sleeve 116 are fixedly sleeved on the driving shaft 113. The motor 111 drives the driving shaft 113 to rotate through the coupling 112, and the driving shaft 113 drives the driving gear 114, the driving transmission wheel 115 and the driving shaft sleeve 116 to rotate. One driving gear 114 is installed at one side of each driving transmission wheel 115, and the driving transmission wheel 115 is fixedly connected with the driving gear 114, so that the driving transmission wheel 115 and the driving gear 114 rotate together. The driving shaft sleeve 116 is installed between the conveying frame 13 and the driving conveying wheel 115 and between the driving conveying wheels 115, and the driving shaft sleeve 116 is used for ensuring the distance between the driving conveying wheels 115 and limiting.

The follower mechanism 12 includes a plurality of hangers 121, a plurality of stub shafts 122, a plurality of elastic members 123, a plurality of follower gears 124, a plurality of follower conveyor wheels 125, a plurality of guide posts 126, and a plurality of fastening members 127. Each stub shaft 122 is fixed at both ends to the side walls of the platform 121. Each stub shaft 122 is sleeved with a driven conveying wheel 125 and a driven gear 124. One driven gear 124 is installed at one side of each driven conveying wheel 125, and the driven conveying wheels 125 are fixedly connected with the driven gears 124, so that the driven conveying wheels 125 and the driven gears 124 rotate together. The driven gears 124 correspond to the driving gears 114 one by one, and the driven transport wheels 125 correspond to the driving transport wheels 115 one by one.

The fastener 127 is arranged on the top of the conveying frame 13 in a penetrating way, and the lower end of the fastener 127 is in threaded connection with the top of the hanging platform 121. The fastener 127 is used to connect the hanging platform 121 and the conveying frame 13, and can adjust the distance between the hanging platform 121 and the conveying frame 13 through screw threads. The elastic member 123 is disposed between the hanging platform 121 and the conveying frame 13, and is sleeved on the fastening member 127. The elastic member 123 pushes the hanging platform 121 downwards, and the hanging platform 121 pushes the driven delivery wheel 125 and the driven gear 124 downwards through the stub shaft 122, so that the driven delivery wheel 125 is tightly attached to the driving delivery wheel 115, and the driven gear 124 is engaged with the driving gear 114.

Each guide post 126 is disposed through the top of the conveying frame 13 and the top of the platform 121. The guide posts 126 are used to position the platform 121 to prevent the platform 121 from rotating eccentrically.

The auxiliary mechanism 14 includes a bracket 141, an upper auxiliary shaft 142, a lower auxiliary shaft 143, an upper roller 144, a lower roller 145, and an auxiliary shaft sleeve 146. The holder 141 is fixed to the base 40. The upper auxiliary shaft 142 and the lower auxiliary shaft 143 are mounted at both ends on the bracket 141. The upper roller 144 is sleeved on the upper auxiliary shaft 142, and the lower roller 145 is sleeved on the lower auxiliary shaft 143. The auxiliary shaft sleeve 146 is respectively sleeved on the upper auxiliary shaft 142 and the lower auxiliary shaft 143 for positioning the upper roller 144 and the lower roller 145. Upper roller 144 and lower roller 145 are used to guide hose 200 before it enters drive mechanism 11.

It is noted that the driving feed wheel 115 is provided with a plurality of hose grooves 1151, the driven feed wheel 125 is provided with a plurality of hose grooves 1251, the upper roller 144 is provided with a plurality of hose grooves 1441, and the lower roller 145 is provided with a plurality of hose grooves 1451. The hose grooves 1151 of the driving feed wheel 115 and the hose grooves 1251 of the driven feed wheel 125 correspond to each other one by one to accommodate the hoses 200. Hose grooves 1441 of upper roller 144 and hose grooves 1451 of lower roller 145 correspond one-to-one to receive hoses 200, respectively.

One way of operating the delivery module 10 is to first insert the hose 200 into the hose groove 1441 of the upper roller 144 and the hose groove 1451 of the lower roller 145, and then insert the hose 200 into the corresponding hose groove 1151 of the driving delivery wheel 115 and hose groove 1251 of the driven delivery wheel 125. The motor 111 drives the driving conveying wheel 115 and the driving gear 114 to rotate, the driving gear 114 drives the driven gear 124 to rotate, the driven gear 124 drives the driven conveying wheel 125 to rotate, and the hose groove 1151 of the driving conveying wheel 115 and the hose groove 1251 of the driven conveying wheel 125 convey the hose 200 through friction. Hose 200 frictionally moves upper roller 144 and lower roller 145.

Referring to fig. 3 and 4, the cutting module 20 is used for cutting the hot-melt formed hose 200. The cutting module 20 includes a cutting plate 21, a first lifter 22, a plurality of guide pillars 23, an upper press plate 24, a plurality of press blocks 25, a second lifter 26, a positioning rod 27, a cutting frame 28, and a blade 29. The first lifter 22 is inserted into the top of the cutting frame 28. The guide post 23 is vertically installed between the base 40 and the cutting frame 28. The cutting plate 21 is movably disposed on the guide post 23, and the cutting plate 21 is connected to the first lifter 22. A blade 29 is mounted on the cutting plate 21 on the side thereof adjacent the locating bar 27 with its edge facing downward for cutting the hose 200. The first elevator 22 drives the cutting plate 21 to move up and down along the guide post 23, and the cutting plate 21 drives the blade 29 to move up and down.

The positioning rod 27 is mounted at both ends on the cutting frame 28. A plurality of positioning rod hose holes 271 are formed in the positioning rod 27, a plurality of corresponding cutting frame hose holes 281 are formed in the cutting frame 28, and the positioning rod hose holes 271 and the cutting frame hose holes 281 are used for allowing the hose 200 to pass through.

The second lifter 26 is disposed below the base 40. The upper press plate 24 is movably arranged on the guide post 23 in a penetrating way, and the upper press plate 24 is connected with a second lifter 26. The briquette 25 has a substantially rectangular parallelepiped shape. A press block 25 is fixed to the upper press plate 24. The second lifter 26 drives the upper press plate 24 to move up and down along the guide post 23, and the upper press plate 24 drives the press block 25 to move up and down.

Referring to fig. 5 and 4, the cutting frame 28 has a plurality of upper hose pressing grooves 282, and the pressing block 25 has a plurality of lower hose pressing grooves 251. The hose hold-down groove 251 and the hose hold-down groove 282 are used to hold the hose 200 during cutting, and prevent the hose 200 from moving backward during hot-melt molding, so as to ensure the processing quality of the hose 200. The hose upper pressure grooves 282 correspond to the cutting frame hose holes 281 one by one, and the hose lower pressure grooves 251 correspond to the hose upper pressure grooves 282 one by one. And the hose upper groove 282 is connected to the cutting frame hose hole 281 so that the hose lower groove 251 can press the hose 200 better.

It is noted that a gap is left between the positioning rod 27 and the cutting frame 28, the blade 29 is suspended above the gap, and the width of the gap is consistent with the thickness of the blade 29. The first lifter 22 drives the blade 29 to move downward, and the hose 200 is cut off by inserting the clearance between the positioning rod 27 and the cutting frame 28.

One way of operating the cutting module 20 is to extend the hose 200 delivered from the delivery module 10 into the cutting frame hose hole 281 and the positioning rod hose hole 271, and to extend a small section from the positioning rod hose hole 271 for hot melt forming. Before hot melt molding, the second lifter 26 drives the pressing block 25 to move upward, and presses the hose 200 through the hose lower pressing groove 251 and the hose upper pressing groove 282, thereby preventing the hose 200 from moving. After the hot melt molding, the conveying module 10 conveys the hose 200 to a desired length, and the first lifter 22 drives the blade 29 to move down to cut the hose 200. After the cut hose 200 falls down by its own weight, the conveying module 10 conveys the hose 200, stretches the hose 200 out of the hose hole 271 of the positioning rod for hot melt molding, and the cutting module 20 repeats the above operations to obtain a plurality of required hoses 200.

Referring to fig. 6, the forming module 30 is used for hot-melting and forming the hose 200. The forming module 30 includes a driving device 31, a translation plate 32, a slide rail 33, a heating block 34, a forming plate 35, a temperature sensor 36, a heat-preserving frame 37 and a heating rod 38. The driving device 31 and the slide rail 33 are attached to the base 40. The translation plate 32 is installed on the slide rail 33, and the driving device 31 drives the translation plate 32 to slide on the slide rail 33 to move closer to or away from the cutting module 20. The heating block 34, the forming plate 35, the temperature sensor 36, the heat-preserving frame 37 and the heating rod 38 are all installed on the translation plate 32 and move horizontally along with the translation plate 32.

The heating rod 38 is installed inside the heating block 34, the forming plate 35 is installed at a side surface of the heating block 34, and the heating rod 38 is used to heat the heating block 34 and thus the forming plate 35. The heating block 34 is installed in the hollow portion of the heat-insulating frame 37, and the heat-insulating frame 37 is fixed on the translation plate 32 and used for insulating the heating block 34. The temperature sensor 36 is inserted through the top of the heat-insulating frame 37 and connected to the heating block 34 for measuring and monitoring the temperature of the heating block 34 (and the forming plate 35).

It is noted that the forming plate 35 is provided with a plurality of profiling bosses 351. The contoured ledge 351 is generally trumpet shaped. Each profiling boss 351 corresponds to the positioning rod hose hole 271 one by one. The profiling boss 351 is inserted into the hose 200 for hot-melt molding one end of the hose 200, and one end of the hose 200 is processed into the same (horn) shape as the profiling boss 351. In addition, the contoured bosses 351 may have a variety of shapes to form different types of hoses 200.

The forming module 30 operates in a manner that the driving device 31 drives the forming plate 35 to move to the positioning rod 27. The profiling boss 351 on the forming plate 35 performs hot melting forming on one end of the hose 200 extending out of the positioning rod hose hole 271. The post-mold drive device 31 drives the mold plate 35 away from the positioning rod 27.

Referring to fig. 1, a protection cover 41, a discharge hole 42 and a console 43 are disposed on the base 40. The protection cover 41 is used for blocking the high temperature of the forming plate 35 and protecting workers. The discharge port 42 is disposed below the positioning rod 27, and is in a slope shape for sliding out the hose 200 to be cut and dropped. The console 43 is used for controlling the operation of the apparatus, such as controlling the rotation speed and rotation angle of the motor 111, the temperature of the heating rod, and the like.

In the present embodiment, the hose processing apparatus 100 is provided with three driving feed wheels 115 and driven feed wheels 125 side by side, each driving feed wheel 115 is provided with three hose grooves 1151, and 9 hoses 200 can be simultaneously fed and processed, it is understood that in other embodiments, the hose processing apparatus 100 may be provided with other numbers of driving feed wheels 115 and driven feed wheels 125, and each driving feed wheel 115 may be provided with other numbers of hose grooves 1151, so as to simultaneously process a desired number of hoses 200.

Meanwhile, in other embodiments, the forming module 30 may be used alone to fix the hose 200 at a corresponding position of the profiling boss 351, and the driving device 31 drives the profiling boss 351 to extend into the hose 200 to perform hot-melt forming on the hose, and then manually conveys the hose 200 and cuts the hose 200 to a desired length.

Referring to fig. 7, a connector 300 for connecting data transmission lines includes a hard shell 310 and a sheath 320. The sheath 320 is a flexible material that is easily bent. Hard shell 310 is attached to jacket 320. The coupling 300 further includes the hose 200 processed by the hose processing apparatus 100 described above. The hose 200 is penetrated by a data transmission line. One end of the hose 200, which is thermally fused, is installed inside the hard case 310 for restraining the hose 200, and the other end of the hose 200, which extends out of the sheath 320, is used for eliminating a gap between the data transmission line and the sheath 320, so as to prevent the data transmission line from being worn or broken when being bent. The data transmission line is typically an optical fiber.

Compared with the prior art, hose processing equipment 100 utilizes and carries module 10 can accurate control transport length, thereby utilizes to cut module 20 and can cut hose 200 automatically and reduce the manpower, utilizes the automatic hot melt shaping hose 200 of shaping module 30 to avoid personnel because of the scald of high temperature, improved hose 200's shaping efficiency, reduced the human cost simultaneously.

The above embodiments are only used to illustrate the technical solutions of the present invention and not to limit the same, and although the present invention has been described in detail with reference to the above preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced equivalently without departing from the spirit and scope of the technical solutions of the present invention. Those skilled in the art can also make other changes and the like in the spirit of the present invention, and the design of the present invention can be used as long as the technical effects of the present invention are not deviated. Such variations are intended to be included within the scope of the invention as claimed.

Claims (9)

1. A joint is used for connecting a data transmission line and comprises a hard shell and a sheath, wherein the hard shell is connected with the sheath.

2. A hose processing equipment for hot melt shaping claim 1 the hose, including the shaping module, the shaping module includes drive arrangement, heating block and profiled sheeting, its characterized in that: the driving device is connected with the heating block, the forming plate is arranged on the heating block, the hose processing equipment further comprises a profiling boss, the profiling boss is arranged on the forming plate, the driving device is used for driving the profiling boss to be inserted into the hose, the heating block heats the forming plate, one end of the hose is hot-melted into the shape which is the same as the profiling boss, and the size of one end of the hose is larger than that of the other end of the hose.

3. The hose processing apparatus of claim 2, wherein: the hose processing equipment further comprises a conveying module, the conveying module is placed towards the profiling boss and comprises a driving mechanism and a driven mechanism, the driving mechanism comprises a motor, a driving shaft, a driving gear and a driving conveying wheel, the driving shaft is connected with the motor, the driving conveying wheel is fixedly connected with the driving gear and sleeved on the driving shaft, the driven mechanism comprises a hanging platform, a short shaft, an elastic part, a driven gear and a driven conveying wheel, the hanging platform is arranged above the driving mechanism, two ends of the short shaft are fixed on the hanging platform, the driven conveying wheel is fixedly connected with the driven gear and sleeved on the short shaft, the driven gear is meshed with the driving gear, the elastic part is connected with the hanging platform and used for pushing the driven conveying wheel towards the driving conveying wheel to compress the hose, the motor drives the driving gear and the driving conveying wheel to rotate, the driving gear drives the driven gear and the driven conveying wheel to rotate, and the driving conveying wheel and the driven conveying wheel convey hoses through friction.

4. The hose processing apparatus of claim 3, wherein: carry the module still includes complementary unit, complementary unit arranges in the drive mechanism deviates from one side of shaping module, complementary unit includes the support, goes up the auxiliary shaft, lower auxiliary shaft, goes up the gyro wheel and lower gyro wheel, go up the auxiliary shaft and install down the auxiliary shaft both ends on the support, it establishes to go up the gyro wheel cover go up on the auxiliary shaft, the gyro wheel cover is established down on the auxiliary shaft, it hugs closely to go up the gyro wheel lower the gyro wheel is used for right the hose gets into drive mechanism reaches guide before the follower.

5. The hose processing apparatus of claim 4, wherein: hose grooves are respectively formed in the driving conveying wheel, the driven conveying wheel, the upper roller and the lower roller, and the hose grooves of the driving conveying wheel and the driven conveying wheel respectively correspond to the hose grooves of the upper roller and the lower roller one by one to accommodate hoses.

6. The hose processing apparatus of claim 5, wherein: the hose processing equipment also comprises a cutting module which is arranged between the forming die and the conveying module, the cutting module comprises a cutting plate, a first lifter, a guide post, a positioning rod, a cutting frame and a blade, the first lifter is arranged at the top of the cutting frame in a penetrating way, the guide post is vertically arranged on the cutting frame, the cutting plate is arranged on the guide post in a penetrating way, the cutting plate is connected with the first lifter, two ends of the positioning rod are arranged on the cutting frame, the blade is arranged on one side of the cutting plate close to the positioning rod, the first lifter is used for driving the blade to move up and down to cut the hose, the cutting frame is provided with a cutting frame hose hole, and the cutting frame hose hole are used for accommodating the hose.

7. The hose processing apparatus of claim 6, wherein: the cutting module further comprises an upper pressing plate, a pressing block and a second lifter, the second lifter is arranged below the cutting frame, the upper pressing plate penetrates through the guide pillar and is connected with the second lifter, the pressing block is fixed on the upper pressing plate and drives the pressing block to move up and down, the cutting frame is provided with a hose upper pressing groove, the pressing block is provided with a corresponding hose lower pressing groove, the hose lower pressing groove and the hose upper pressing groove are used for pressing and fixing the hose during cutting, and the hose upper pressing groove is connected with a hose hole of the cutting frame so as to fully press the hose.

8. The hose processing apparatus of claim 2, wherein: the molding module further comprises a temperature sensor, and the temperature sensor is connected with the heating block and used for measuring and monitoring the temperature of the heating block and the molding plate.

9. The hose processing apparatus of claim 7, wherein: hose processing equipment still includes the base station, be equipped with protection casing, discharge gate and control cabinet on the base station, the protection casing is used for the separation the high temperature of profiled sheeting is in order to protect the staff, the discharge gate is located cut the module below for the roll-off cuts the back and drops the hose, the control cabinet is used for operation control.

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