阅读说明：本技术 解水布机 (Water-removing cloth machine ) 是由 杨才伟 于 2021-02-03 设计创作，主要内容包括：本发明实施例公开了一种解水布机,解水布机用于拆解胶管上所缠绕的水布。所述解水布机包括：第一牵引装置,设置有第一牵引通道,用于牵引所述胶管。拆解装置,包括机架、可转动连接于机架的主轴及连接于所述主轴的解水布组件和包装组件,所述解水布组件和包装组件背对设置于所述机架,所述包装组件配置有包装带,所述主轴的轴线位于所述第一牵引通道的延伸方向。所述解水布组件相对于所述主轴转动并卷绕所述水布,所述包装组件相对于所述主轴转动并将所述包装带缠绕于管体,所述管体为去除水布的胶管。包装组件背对解水布组件设置,以将包装带缠绕于管体,从而使胶管在拆除水布后能及时缠绕预制的包装带,提高管体的包装效率,包装效率高。(The embodiment of the invention discloses a water-removing cloth machine which is used for removing water cloth wound on a rubber tube. The cloth machine that hydrolysises includes: the first traction device is provided with a first traction channel and is used for traction of the rubber tube. The detaching device comprises a frame, a main shaft and a water-releasing cloth assembly and a packaging assembly, wherein the main shaft is rotatably connected to the frame, the water-releasing cloth assembly and the packaging assembly are oppositely arranged on the frame, the packaging assembly is provided with a packaging belt, and the axis of the main shaft is located in the extending direction of the first traction channel. The water-dispelling cloth assembly rotates relative to the main shaft and winds the water cloth, the packaging assembly rotates relative to the main shaft and winds the packaging belt on the pipe body, and the pipe body is a rubber pipe for removing the water cloth. The packing component sets up to the cloth subassembly that disassembles back to twine the strap in the body, thereby make the rubber tube can in time twine prefabricated strap after demolising the cloth, improve the packing efficiency of body, pack efficiently.)

1. The utility model provides a cloth machine of dissolving for disassemble the water cloth of twining on the rubber tube, its characterized in that, the cloth machine of dissolving includes:

the first traction device is provided with a first traction channel and is used for drawing the rubber tube;

the disassembling device comprises a rack, a main shaft which is rotatably connected to the rack, and a water-decomposing cloth assembly and a packaging assembly which are connected to the main shaft, wherein the water-decomposing cloth assembly and the packaging assembly are oppositely arranged on the rack, the packaging assembly is provided with a packaging belt, and the axis of the main shaft is positioned in the extending direction of the first traction channel;

the water-dispelling cloth assembly rotates relative to the main shaft and winds the water cloth, the packaging assembly rotates relative to the main shaft and winds the packaging belt on the pipe body, and the pipe body is a rubber pipe for removing the water cloth.

2. The water splitting machine of claim 1, wherein the water splitting cloth assembly comprises a servo motor mounted to the frame, a first drive assembly connected to the servo motor and the main shaft, a water splitting cloth disc connected to the main shaft, and at least one adjusting bar frame mounted to the water splitting cloth disc, the adjusting bar frame extending obliquely from the water splitting cloth disc toward the first traction device.

3. The cloth hydrolyzing machine of claim 2, wherein the cloth hydrolyzing assembly further comprises a brake assembly connecting the cloth hydrolyzing disk and the frame, the brake assembly being used for adjusting the rotation speed of the cloth hydrolyzing disk.

4. The water disintegrator of claim 3, wherein the brake assembly comprises a brake motor mounted to the frame, a first brake gear and a second brake gear rotatably connected to the spindle, a reversing gear set mounted to the water disintegrator cloth disc, a first brake belt connecting the first brake gear and the brake motor, a second brake belt connecting the first brake gear and the reversing gear set, and a third brake belt connecting the second brake gear and the reversing gear set, wherein the first brake gear and the second brake gear are respectively located on both sides of the water disintegrator cloth disc.

5. The cloth hydrolyzing machine of claim 2, wherein the cloth hydrolyzing assembly further comprises a detecting assembly mounted on the frame, and the detecting assembly is used for detecting the rotation parameters of the cloth hydrolyzing disc.

6. The water disintegrator of claim 1, wherein the packaging assembly includes a packaging tray rotatably mounted to the spindle, at least one packaging frame mounted to the packaging tray, a packaging motor mounted to the frame, and a second drive assembly connecting the packaging motor and the packaging tray, the packaging frame extending obliquely from the packaging tray in a direction away from the first traction device.

7. The water splitting machine of claim 1, wherein the first traction device comprises a traction frame, a traction driving assembly and a guiding assembly mounted on the traction frame, and a first driving wheel set and a second driving wheel set connected to the guiding assembly, the first traction channel is formed between the first driving wheel set and the second driving wheel set, and at least one of the first driving wheel set and the second driving wheel set slides along the guiding assembly to adjust the space size of the first traction channel.

8. The cloth dissolving machine of claim 7, wherein the guiding assembly comprises guiding posts spaced apart from each other on the traction frame and a first telescopic driving member mounted on the traction frame, the first driving wheel set and the second driving wheel set are slidably connected to the guiding posts, and an output shaft of the first telescopic driving member is connected to the first driving wheel set.

9. The cloth dissolving machine of claim 7, wherein the traction drive assembly comprises a traction motor mounted on the traction frame, a transmission column rotatably mounted on the traction frame, and at least one transmission gear mounted on the transmission column, and the transmission gear is engaged with the first drive wheel set and/or the second drive wheel set.

10. The cloth dissolving machine of claim 1, further comprising a second traction device, wherein the second traction channel is provided with a second traction channel for drawing the hose, and the disassembling device is located between the second traction device and the first traction device.

Technical Field

The invention relates to the technical field of water-splitting cloth machines, in particular to a water-splitting cloth machine.

Background

The water-removing step machine is used for removing the water cloth belt wound on the surface of the rubber tube so as to finish the processing of the rubber tube and enter the processing procedure of the packaging belt. However, the existing disassembling of the water cloth tape and winding and packaging of the packaging tape cannot be flexibly matched, and even different devices are adopted for processing, the processing efficiency is low and the consistency is poor, so that improvement is needed.

Disclosure of Invention

In order to solve the technical problems, the embodiment of the invention provides a water splitting machine.

A first aspect of an embodiment of the present invention provides a water-removing cloth machine for detaching a water cloth wound around a rubber hose, the water-removing cloth machine including:

the first traction device is provided with a first traction channel and is used for drawing the rubber tube;

the disassembling device comprises a rack, a main shaft which is rotatably connected to the rack, and a water-decomposing cloth assembly and a packaging assembly which are connected to the main shaft, wherein the water-decomposing cloth assembly and the packaging assembly are oppositely arranged on the rack, the packaging assembly is provided with a packaging belt, and the axis of the main shaft is positioned in the extending direction of the first traction channel;

the water-dispelling cloth assembly rotates relative to the main shaft and winds the water cloth, the packaging assembly rotates relative to the main shaft and winds the packaging belt on the pipe body, and the pipe body is a rubber pipe for removing the water cloth.

In one embodiment, the water-removing cloth assembly comprises a servo motor mounted on the frame, a first driving assembly connected to the servo motor and the main shaft, a water-removing cloth disc connected to the main shaft, and at least one adjusting rod frame mounted on the water-removing cloth disc, wherein the adjusting rod frame extends from the water-removing cloth disc in an inclined manner towards the direction of the first traction device.

In one embodiment, the water-splitting cloth assembly further comprises a brake assembly connecting the water-splitting cloth disc and the machine frame, and the brake assembly is used for adjusting the rotating speed of the water-splitting cloth disc.

In one embodiment, the brake assembly includes a brake motor mounted to the frame, a first brake gear and a second brake gear rotatably connected to the spindle, a reversing gear set mounted to the water-removing cloth disc, a first brake band connected to the first brake gear and the brake motor, a second brake band connected to the first brake gear and the reversing gear set, and a third brake band connected to the second brake gear and the reversing gear set, wherein the first brake gear and the second brake gear are respectively located at two sides of the water-removing cloth disc.

In an embodiment, the water-splitting cloth assembly further comprises a detection assembly mounted on the frame, and the detection assembly is used for detecting the rotation parameters of the water-splitting cloth disc.

In one embodiment, the packaging assembly comprises a packaging disc rotatably mounted on the main shaft, at least one packaging frame mounted on the packaging disc, a packaging motor mounted on the frame, and a second driving assembly connected with the packaging motor and the packaging disc, wherein the packaging frame extends from the packaging disc in a direction away from the first traction device in an inclined mode.

In an embodiment, the first traction device comprises a traction frame, a traction driving assembly and a guide assembly which are installed on the traction frame, and a first driving wheel set and a second driving wheel set which are connected to the guide assembly, wherein the first traction channel is formed between the first driving wheel set and the second driving wheel set, and at least one of the first driving wheel set and the second driving wheel set slides along the guide assembly to adjust the space size of the first traction channel.

In an embodiment, the guiding assembly includes guiding posts distributed at intervals on the traction frame and a first telescopic driving member installed on the traction frame, the first driving wheel set and the second driving wheel set are slidably connected to the guiding posts, and an output shaft of the first telescopic driving member is connected to the first driving wheel set.

In one embodiment, the traction drive assembly comprises a traction motor mounted on the traction frame, a transmission column rotatably mounted on the traction frame, and at least one transmission gear mounted on the transmission column, wherein the transmission gear is connected to the first drive wheel set and/or the second drive wheel set in a meshing manner.

In an embodiment, the water splitting machine further comprises a second traction device, the second traction channel is provided with a second traction channel for traction of the rubber tube, and the disassembling device is located between the second traction device and the first traction device.

The technical scheme provided by the embodiment of the invention comprises the following steps: the water-decomposing cloth assembly faces the direction of the first traction device to disassemble the water cloth wound by the rubber tube conveyed by the first traction device, and the disassembling efficiency is high. Wherein, the water cloth subassembly of separating rotates for the main shaft to the water cloth that the rotatory rubber tube of disassembling twines. The packing component sets up the cloth subassembly that disassembles back to twine the wrapping tape in the periphery wall of body, thereby make the rubber tube can in time twine prefabricated wrapping tape after demolising the water cloth, improve the packing efficiency of body, pack efficiently.

Drawings

Fig. 1 is a schematic perspective view of the water splitting machine of the present invention.

Fig. 2 is a schematic front view of the water splitting machine of the present invention.

Fig. 3 is a schematic perspective view of the dismantling device of the present invention.

Fig. 4 is a schematic top view of the disassembling apparatus of the present invention.

Fig. 5 is a schematic sectional structure view of the adjusting lever bracket of the present invention.

Fig. 6 is a schematic structural view of the packaging holder of the present invention.

Fig. 7 is a schematic perspective view of the first traction device with a portion of the traction frame removed.

Fig. 8 is a side view of the first draft gear with a portion of the draft gear removed in accordance with the present invention.

Fig. 9 is a schematic view of the construction of the traction wheel according to the present invention.

In the figure: disassembling the apparatus 10; a frame 11; a packaging assembly 12; a packing tray 121; a packaging frame 122; a packing shaft 1221; a package base 1222; a slide groove 12221; a stopper 1223; a locking bracket 1224; a packing motor 123; a second drive assembly 124; a packing transmission wheel 1241; wrapping belts 1242; wrapping drive wheel 1243; a water-shedding cloth component 13; a servo motor 131; a first drive assembly 132; a water-releasing cloth tray 133; an adjustment lever bracket 134; mounting base 1341; a mounting groove 13411; an adjustment bracket 1342; an adjustment seat 13421; a mounting bar 134222; a first stopper surface 13423; a second stopper surface 13424; a third stopper surface 13425; a brake assembly 135; a brake motor 1351; a first braking band 1352; a first brake gear 1353; a reversing gear set 1354; a second brake gear 1355; a second braking band 1356; a third braking band 1357; a detection component 136; an inductor 1361; a sensing member 1362; a main shaft 14; a first traction device 20; a traction frame 21; a traction drive assembly 22; a traction motor 221; a drive post 222; a transmission gear 223; a guide assembly 23; the guide posts 231; a first telescoping drive member 232; a first drive wheel set 24; a gear carrier 241; a first mounting plate 2411; a second mounting plate 2412; a guide block 2413; a thrust bearing 2414; a support wheel 242; a central shaft 2421; a traction wheel 2422; a traction groove 24221; a traction bearing 2423; a traction drive wheel 243; a second driving wheel set 25; a second traction device 30; a chassis 40.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the following embodiments may be combined without conflict.

See fig. 1-3 for: the invention discloses a water-removing cloth machine, which is used for removing water cloth wound on a rubber tube, and comprises: a first pulling device 20 and a dismantling device 10. Wherein the first traction device 20 is provided with a first traction channel for traction of the hose. The hose is of a long-strip circular tubular structure, and in an initial state, the outer peripheral wall of the hose is wound with spirally distributed water cloth in an approximate winding mode. The first traction device 20 is used for conveying the rubber hose to the disassembling device 10 along the first traction channel, so as to realize continuous conveying and disassembling of the rubber hose.

The disassembling device 10 comprises a frame 11, a main shaft 14 rotatably connected to the frame 11, and a water-removing cloth assembly 13 and a packaging assembly 12 connected to the main shaft 14, wherein the water-removing cloth assembly 13 and the packaging assembly 12 are oppositely arranged on the frame 11. The wrapping assembly 12 is provided with a wrapping band, and the axis of the spindle 14 is located in the extending direction of the first drawing channel. The water cloth-removing component 13 rotates relative to the main shaft 14 and winds the water cloth, the packaging component 12 rotates relative to the main shaft 14 and winds the packaging belt around a pipe body, and the pipe body is a rubber pipe for removing the water cloth. The main shaft 14 is provided with a through shaft hole, and the rubber tube is inserted into the shaft hole along the first traction channel. The water-releasing cloth component 13 releases the water cloth wound when the hose is inserted, and the packaging component 12 winds the packaging belt on the pipe body penetrating out of the main shaft 14.

The water-dispelling cloth assembly 13 faces the direction of the first traction device 20 to disassemble the water cloth wound by the rubber hose conveyed by the first traction device 20, and the disassembling efficiency is high. Wherein, the water cloth assembly 13 rotates relative to the main shaft 14 to rotationally disassemble the water cloth wound by the hose. The packing component 12 is back to the setting of the water cloth subassembly 13 of separating to twine the periphery wall of packing area in the body, thereby make the rubber tube can in time twine prefabricated packing area after dismantling water cloth, improve the packing efficiency of body, it is smooth and easy to pack.

The water-cloth-releasing assembly 13 rotates relative to the frame 11 to wind the water cloth wound on the surface of the rubber hose and wind the disassembled water cloth into a disc. The water-removing cloth assembly 13 includes a servo motor 131 mounted on the frame 11, a first driving assembly 132 connected to the servo motor 131 and the main shaft 14, a water-removing cloth disc 133 connected to the main shaft 14, and at least one adjusting rod frame 134 mounted on the water-removing cloth disc 133, wherein the adjusting rod frame 134 extends from the water-removing cloth disc 133 in an inclined manner toward the first traction device 20.

The water-splitting cloth assembly 13 adopts the servo motor 131 to control the rotating speed of the water-splitting cloth disc 133, so that the flexible adjustment of parameters such as driving speed, driving power and the like can be realized, and the processing flexibility of the water-splitting cloth assembly 13 is improved. The first driving assembly 132 comprises a main driving wheel fixedly connected to the main shaft 14, a main driving wheel installed on the servo motor 131, and a main driving belt connecting the main driving wheel and the main driving wheel, wherein the servo motor 131 drives the main shaft 14 to rotate through the main driving belt and the main driving wheel. The servo motor 131 can adjust the rotation speed and the torque force according to the control signal, so as to make the rotation of the main shaft 14 and the corresponding accessories flexible. Optionally, the main driving wheel and the water-removing cloth disc 133 are distributed on two sides of the frame 11, so that the rotational connection position of the water-removing cloth disc 133 is close to the frame 11, and the rotational stability of the water-removing cloth disc 133 is improved.

See fig. 3-5 for illustration: the water-discharging cloth disc 133 is fixedly connected to the main shaft 14 so that the water-discharging cloth disc 133 and the main shaft 14 rotate synchronously. The adjusting rod frame 134 is installed on the water-releasing cloth disc 133 and extends obliquely towards the first traction device 20 to wind the water cloth on the hose conveyed by the first traction device 20, and the winding is convenient. The adjusting rod frame 134 includes a mounting base 1341, an adjusting frame 1342 rotatably connected to the mounting base 1341, and at least one locking member connected to the mounting base 1341, wherein the locking member abuts against the adjusting frame 1342 to lock the unfolding angle of the adjusting frame 1342. The mounting base 1341 is fixed to the water-splitting cloth disc 133, a mounting groove 13411 is provided on the mounting base 1341, and one end of the adjusting bracket 1342 is inserted into the mounting groove 13411 and connected to the groove wall of the mounting groove 13411 through a pin shaft to form a rotatable connecting structure, so that the angle of the adjusting bracket 1342 can be flexibly adjusted. The locking piece is mounted to the mounting base 1341 for defining the rotation angle of the adjusting bracket 1342, so that the adjusting bracket 1342 can mount a winding core for winding the water band. Optionally, the locking member is configured as a fastener such as a bolt, a latch, etc. that is coupled to the mounting base 1341 and abuts the adjustment bracket 1342, thereby defining the angle of rotation of the adjustment bracket 1342.

In one embodiment, the adjusting bracket 1342 comprises an adjusting seat 13421 rotatably connected to the mounting base 1341 and a mounting rod 13422 protruding from the surface of the adjusting seat 13421. The adjusting seat 13421 is installed on the installation groove 13411, and the installation base 1341 is rotatably connected. The mounting bar 13422 extends out from the mounting seat 13421 to mount the roll core. Wherein, the locking piece cooperates with the peripheral wall of adjusting seat 13421 and locks to flexibly adjust the inclination angle of mounting rod 13422. Specifically, the adjusting seat 13421 is configured with a first limiting surface 13423 and a second limiting surface 13424 that are oppositely disposed, and a third limiting surface 13425 that is inclined from the first limiting surface 13423 toward the mounting rod 13422, wherein the first limiting surface 13423 and/or the second limiting surface 13424 are located in the extending direction of the locking member, and the third limiting surface 13425 is used to limit the maximum rotation position of the adjusting bracket 1342 relative to the mounting base 1341. The locking piece is provided as one piece, and the end wall of the locking piece abuts against the first limiting surface 13423 or the second limiting surface 13424. Alternatively, two or more locking pieces are provided, and the locking pieces are respectively abutted against the first limiting surface 13423 and the second limiting surface 13424, so that the flexibility and the stepless variability of the adjusting angle of the adjusting bracket 1342 are improved.

Further, the water-splitting cloth assembly 13 further comprises a brake assembly 135 connecting the water-splitting cloth disc 133 and the frame 11, and the brake assembly 135 is used for adjusting the rotation speed of the water-splitting cloth disc 133. The brake assembly 135 is mounted to the frame 11 and coupled to the water discharging cloth 133 to regulate the rotation of the water discharging cloth 133. Meanwhile, the braking assembly 135 also transmits braking force to the main shaft 14 through the water-breaking cloth disc 133 so as to adjust the rotating speed of the main shaft 14, and the adjustment is flexible. In addition, the braking component 135 brakes the water-releasing cloth disc 133, and the power requirement of the braking component 135 can be reduced by utilizing the characteristic of large torque of the water-releasing cloth disc 133, so that the braking efficiency is improved, the operation of the packaging component 12 is not interfered, and the matching operation effect of the water-releasing cloth component 13 and the packaging component 12 is realized. For example, the water-releasing cloth disc 133 is decelerated, and the packaging component 12 rotates at a constant speed, so that the packaging pitch of the winding tube of the packaging tape can be adjusted.

Specifically, the brake assembly 135 comprises a brake motor 1351 mounted to the frame 11, a first brake gear 1353 and a second brake gear 1355 rotatably connected to the spindle 14, a reversing gear set 1354 mounted to the water-removing cloth disc 133, a first brake belt 1352 connecting the first brake gear 1353 and the brake motor 1351, a second brake belt 1356 connecting the first brake gear 1353 and the reversing gear set 1354, and a third brake belt 1357 connecting the second brake gear 1355 and the reversing gear set 1354, wherein the first brake gear 1353 and the second brake gear 1355 are respectively located at two sides of the water-removing cloth disc 133.

The brake motor 1351 is mounted to the frame 11 and is connected to the first brake gear 1353 through the first brake band 1352 such that the brake motor 1351 transmits a braking force to the first brake gear 1353 while also supporting the first brake gear 1353 through the main shaft 14 to keep the first brake gear 1353 smoothly running. The first brake gear 1353 is connected to the reversing gear set 1354 through a second brake band 1356 to apply a braking force. The reversing gear set 1354 comprises a connecting shaft rotatably mounted on the water-removing cloth disc 133, and a first reversing wheel and a second reversing wheel mounted at two ends of the connecting shaft, the second braking belt 1356 is connected with the first reversing wheel, and the third braking belt 1357 is connected with the second reversing wheel and the second braking wheel 1355, so that the braking of the main shaft 14 and the water-removing cloth disc 133 is realized, the stable braking and the torque balance of the water-removing cloth disc 133 can be ensured, and the generation of unbalance loading is avoided.

Optionally, the water splitting cloth assembly 13 further comprises a detection assembly 136 mounted on the frame 11, and the detection assembly 136 is configured to detect a rotation parameter of the water splitting cloth disc 133. The detecting component 136 is used for detecting the rotation parameters of the water-splitting cloth disc 133 so as to facilitate the linkage control of the servo motor 131 and the brake component 135. For example, the detecting component 136 is used to detect the rotation speed, the jitter property, the offset load property, the interval time, and the like of the water-removing cloth disc 133. Specifically, the detecting assembly 136 includes a sensor 1361 mounted on the frame 11 and a sensor 1362 mounted on the water-splitting cloth tray 133, and the sensor 1361 is located on a revolving path of the sensor 1362. The sensor 1361 can be configured as a hall sensor, a photoelectric sensor and other sensors, and the sensing member 1362 is configured as a magnet, a through hole and other sensing structures, so that the detection component 136 can detect the rotating position and the rotating interval time of the water splitting cloth disc 133, thereby facilitating the acquisition of the rotating parameters and having good linkage effect.

See fig. 3, 4 and 6 for an illustration: the packing component 12 and the water-releasing cloth disc 133 are oppositely arranged on the frame 11, so that the rubber tube is wound by the packing component 12 after the water cloth is released by the water-releasing cloth disc 133, the working continuity is high, and the processing efficiency is high. The packing assembly 12 includes a packing tray 121 rotatably mounted on the main shaft 14, at least one packing frame 122 mounted on the packing tray 121, a packing motor 123 mounted on the frame 11, and a second driving assembly 124 connecting the packing motor 123 and the packing tray 121, wherein the packing frame 122 extends obliquely from the packing tray 121 in a direction away from the first traction device 20.

The wrapping motor 123 drives the wrapping tray 121 to rotate relative to the spindle 14 through the second driving assembly 124, so that the wrapping frame 122 can rotate independently relative to the spindle 14, and the wrapping tape is wound around the tube of the output spindle 14 at a preset winding speed. The second driving assembly 124 includes a wrapping driving wheel 1241 rotatably connected to the spindle 14, a wrapping driving wheel 1243 installed on the wrapping motor 123, and a wrapping driving belt 1242 connected to the wrapping driving wheel 1241 and the wrapping driving wheel 1243, wherein the wrapping driving wheel 1241 is fixedly connected to the wrapping tray 121. The wrapping driving wheel 1241 is sleeved on the spindle 14 to transmit the tension to the spindle 14. The packing frame 122 protrudes from the packing tray 121 and is used for installing the reel wound with the packing tape, so that the packing tape is wound on the tube body during the rotation of the packing tray 121, and the winding control of the packing tape is flexible. The packing driving wheel 1241 is integrally connected with the packing tray 121, so that the packing motor 123 drives the packing tray 121 to independently rotate, and the winding speed of the packing tape has good controllability.

Optionally, the packing rack 122 includes a packing base 1222, a packing shaft 1221 rotatably installed on the packing base 1222, a limiting rack 1223 installed on the packing shaft 1221, and a locking rack 1224, the limiting rack 1223 is slidably connected to the packing base 1222 and locks an assembling angle of the packing shaft 1221 with respect to the packing base 1222, and the locking rack 1224 is disposed opposite to the packing base 1222. The packing base 1222 is fixed to the packing reel 121, and the packing shaft 1221 is used to install the reel, so that the reel is replaceable. The packing shaft 1221 is rotatably connected to the packing base 1222 by a pin shaft to adjust a mounting angle of the packing shaft 1221.

Spacing 1223 install in packing axle 1221 and with packing base 1222 sliding connection to balanced packing axle 1221 other end is installed the moment of torsion power that the belt dish transmitted to packing axle 1221, improves packing axle 1221 angle modulation's stability. Optionally, the packing base 1222 is provided with an arc-shaped sliding groove 12221, and the limiting frame 1223 is configured as a shaft-like fitting or a bar-like fitting fixed to the packing shaft 1221 and fittingly connected to the sliding groove 12221. Optionally, the limiting frame 1223 and the tape reel are respectively located at two sides of the pin shaft on which the packing shaft 1221 is mounted. A locking bracket 1224 is mounted to the packing shaft 1221 for restraining the reel to the packing shaft 1221. Optionally, the locking bracket 1224 includes a locking nut that is threadably connected to the packing shaft 1221, the locking nut abutting against the reel.

As shown in fig. 1 and 2, the first traction device 20 is used for pulling the hose to be conveyed toward the disassembling device 10, so that the hose can automatically extend along the first traction channel. Further, the water-splitting cloth machine further comprises a second traction device 30, a second traction channel is arranged on the second traction channel and used for traction of the rubber tube, and the disassembling device 10 is located between the second traction device 30 and the first traction device 20. The second traction device 30 and the first traction device 20 jointly draw the hose to move, so that both ends of the hose are supported, and the packing assembly 12 and the dewatering cloth assembly 13 run smoothly. Alternatively, second traction device 30 may operate substantially the same as first traction device 20 and may be understood with reference to the operation and structure of first traction device 20. Further, the water splitting machine further comprises a base frame 40, and the first traction device 20, the disassembling device 10 and the second traction device 30 are all mounted on the base frame 40. The underframe 40 is in a rigid frame structure, and the first traction device 20, the disassembling device 10 and the second traction device 30 are all arranged on the underframe 40 to form a temperature-fixed rigid basic platform, so that the running stability of the water-splitting cloth machine is improved.

The first traction device 20 is exemplified below.

As shown in fig. 7 and 8, the first traction device 20 includes a traction frame 21, a traction driving assembly 22 and a guiding assembly 23 mounted on the traction frame 21, and a first driving wheel set 24 and a second driving wheel set 25 connected to the guiding assembly 23, wherein the first traction channel is formed between the first driving wheel set 24 and the second driving wheel set 25. At least one of the first driving wheel set 24 and the second driving wheel set 25 slides along the guide assembly 23 to adjust the space size of the first traction passage.

The first driving wheel set 24 and the second driving wheel set 25 are oppositely arranged at intervals to form a first traction channel for the movement of the rubber pipe. The first driving wheel set 24 and/or the second driving wheel set 25 drive the rubber tube to move towards the disassembling device 10, and the driving is convenient. At least one of the first driving wheel set 24 and the second driving wheel set 25 can move relative to the other one, so that the relative spacing position between the first driving wheel set and the second driving wheel set is adjustable, namely the size of the first traction channel is adjustable, the first traction channel is adapted to rubber pipes with different pipe diameters, the driving is convenient, and the universality is high.

Optionally, the guiding assembly 23 includes guiding posts 231 spaced apart from each other and distributed on the traction frame 21, and a first telescopic driving member 232 mounted on the traction frame 21, the first driving wheel set 24 and the second driving wheel set 25 are slidably connected to the guiding posts 231, and an output shaft of the first telescopic driving member 232 is connected to the first driving wheel set 24.

The guide posts 231 are vertically spaced apart from each other in the traction frame 21 to realize a multi-point support structure. Alternatively, the guide posts 231 are configured with three and are distributed in a triangular shape on both sides of the first driving wheel set 24. Alternatively, the guide posts 231 are arranged in four and distributed in a parallelogram shape on both sides of the first driving wheel set 24. The output shaft of the first telescopic driving member 232 is connected with the first driving wheel set 24 to drive the first driving wheel set 24 to slide along the guiding column 231, so that the distance between the first driving wheel set 24 and the second driving wheel set 25 can be adjusted conveniently. Optionally, the first telescopic drive 232 is configured as a hydraulic assembly, a pneumatic assembly, a screw pusher assembly or an electric pusher assembly.

Further, the guiding assembly 23 further comprises a second telescopic driving member rotatably connected to the traction frame 21, and an output shaft of the second telescopic driving member is connected to the second driving wheel set 25. The second telescopic driving member is connected to the second driving wheel set 25 to drive the second driving wheel set 25 to slide along the guiding column 231, so that the distance between the second driving wheel set 25 and the first driving wheel set 24 can be adjusted, and the adjustment is convenient. Optionally, the second telescopic drive is configured as a hydraulic assembly, a pneumatic assembly, a screw pusher assembly or an electric pusher assembly. The first and second telescopic driving members 232 and 232 are respectively mounted on two opposite sides of the traction frame 21.

The traction drive assembly 22 drives the hose to move along the first traction path for delivery of the hose. Optionally, the traction drive assembly 22 includes a traction motor 221 mounted on the traction frame 21, a transmission column 222 rotatably mounted on the traction frame 21, and at least one transmission gear 223 mounted on the transmission column 222, wherein the transmission gear 223 is engaged and connected to the first driving wheel set 24 and/or the second driving wheel set 25.

The transmission column 222 is parallel to the guide column 231, and is used for guiding the transmission gear 223 to move and transmitting the power output by the traction motor 221 to the first driving wheel set 24 and/or the second driving wheel set 25. That is, when only one of the first driving wheel set 24 and the second driving wheel set 25 has a function of driving the hose to move, the transmission gear 223 is engaged with the first driving wheel set 24 or the second driving wheel set 25. When the first driving wheel set 24 and the second driving wheel set 25 have the function of driving the hose to move, the transmission gear 223 is engaged with the first driving wheel set 24 and the second driving wheel set 25. The transmission gear 223 is slidably connected to the transmission post 222, so that the first driving wheel set 24 and the second driving wheel set 25 maintain a meshed state when moving along the guide assembly 23, and the power transmission effect is good.

The second driving wheel set 25 is arranged opposite to the first driving wheel set 24 and used for limiting the moving range of the rubber pipe. Alternatively, one of the second driving wheel set 25 and the first driving wheel set 24 drives the hose to move, and the second driving wheel set 25 and the first driving wheel set 24 are approximately the same in structure except that one is connected to the transmission gear 223. Alternatively, the second driving wheel set 25 and the first driving wheel set 24 both drive the hose to move together, and the transmission gears 223 are configured as two and respectively engage with the second driving wheel set 25 and the first driving wheel set 24. Optionally, the second driving wheel set 25 and the first driving wheel set 24 are symmetrically arranged to improve convenience of assembly and adjustment.

The first driving wheel set 24 is exemplified. The first driving wheel set 24 includes a gear frame 241 slidably connected to the transmission column 222, at least two supporting wheels 242 spaced apart from each other on the gear frame 241, and a traction driving wheel 243 connected to one of the supporting wheels 242, wherein the traction driving wheel 243 is connected to the transmission gear 223 in a meshing manner, and the first traction passage is formed between two or more of the supporting wheels 242 and the second driving wheel set 25.

As shown in fig. 7 and 9, the supporting wheels 242 are rotatably connected to the gear frame 241 and are spaced apart along the length direction of the gear frame 241 to support the hose at multiple points, thereby improving the reliability of supporting and connecting the hose. For example, the support wheels 242 are provided in four along the length direction of the carrier 241, and are uniformly distributed along the carrier 241. Optionally, the support wheel 242 includes a central shaft 2421, a traction wheel 2422 sleeved on the central shaft 2421, and a traction bearing 2423 connecting the central shaft 2421 and the traction wheel 2422, wherein the outer peripheral wall of the traction wheel 2422 is configured with traction grooves 24221 distributed at intervals. The traction groove 24221 is parallel to the axis of the central shaft 2421, and the traction drive wheel 243 is connected to the central shaft 2421 of one of the support wheels 242. A drag bearing 2423 connects the center shaft 2421 and the carrier 241 to improve the flexibility of the driving and the reliability of the rotation of the support wheel 242.

The traction wheel 2422 is a cylindrical structure, and traction grooves 24221 are formed in the outer circumferential wall of the traction wheel 2422 at intervals to improve the gripping force of the traction wheel 2422 when guiding the movement of the hose. Optionally, the traction grooves 24221 are parallel to the axis of the central shaft 2421 and evenly distributed along the outer peripheral wall of the traction wheel 2422. The central shaft 2421 of one of the traction wheels 2422 is connected to the traction driving wheel 243, and then is meshed with the transmission gear 223 through the traction wheel 2422, so that power driving is realized, and a power wheel is formed.

Optionally, the transmission gear 223 and the transmission gear 223 are configured as bevel gears, so that the transmission axes of the two are perpendicular to each other, and the flexibility of installation of the transmission mechanism is improved. Alternatively, the traction drive wheel 243 and the transfer gear 223 are configured as spur gears to cooperate with each other.

The gear carrier 241 constitutes a rigid structure for mounting the support wheel 242 and supporting the hose. The gear rack 241 includes a first mounting plate 2411 and a second mounting plate 2412 disposed opposite to each other, a guide block 2413 fixed to the first mounting plate 2411, and a thrust bearing 2414 mounted to the guide block 2413, wherein the guide block 2413 is slidably connected to the transmission column 222, and the transmission gear 223 is sleeved on the transmission column 222 and connected to the thrust bearing 2414.

The first and second mounting plates 2411 and 2412 are oppositely disposed to mount the drag bearing 2423 so that the center shaft 2421 is coupled with the carrier 241. A guide block 2413 is disposed on the outer side of the first mounting plate 2411 for guiding and mounting the driving post 222. The guide block 2413 cooperates with the drive post 222 to bring the traction drive wheel 243 into meshing engagement with the drive gear 223. A thrust ball bearing is located between the guide block 2413 and the drive gear 223 to improve the flexibility of rotation of the drive gear 223.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.