CN210061401U - Edge tearing machine - Google Patents

Abstract

The utility model discloses a tear limit machine, include microscler frame, guide roll, clamping mechanism, first drive mechanism, tear limit mechanism and second drive mechanism. The guide roller comprises a feeding roller, an intermediate roller and a discharging roller in sequence; the clamping mechanism is positioned between the feeding roller and the middle roller; the first traction mechanism comprises a first chuck and a first traction driver which are positioned between the clamping mechanism and the intermediate roller, and the first traction driver drives the first chuck to clamp the insulating outer sleeve between the intermediate roller and the blanking roller by the first chuck and convey the insulating outer sleeve to the blanking roller; the edge tearing mechanism is positioned beside the insulating sleeve between the blanking roller and the middle roller and tears off the edge material of the insulating sleeve between the blanking roller and the middle roller; the second traction mechanism comprises a second chuck and a second traction driver which are positioned between the blanking roller and the edge tearing mechanism, and the second traction driver drives the second chuck to clamp the insulating outer sleeve between the edge tearing mechanism and the blanking roller and convey the insulating outer sleeve to the blanking roller; to improve efficiency and reduce burden.

Description

Edge tearing machine

Technical Field

The utility model relates to a be applied to the equipment in electric heat membrane field, especially relate to a to the rim charge of the insulating overcoat of application in the electric heat membrane tear the limit machine.

Background

With the continuous development of economy and the continuous progress of society, various substance consumer goods are provided for the production and the life of people, and the electrothermal film is one of the substance consumer goods.

As is well known, the electric heating film mainly comprises an electric heating inner core and an insulating outer sleeve sleeved outside the electric heating inner core, and the electric heating inner core is insulated and protected by the insulating outer sleeve so as to ensure the working reliability of the electric heating film.

In the process of manufacturing the insulating sheath, a step of tearing off the edge material of the insulating sheath is involved. The existing method for tearing off the rim charge of the insulating jacket is manually completed by operators, so that the defects of large workload and low efficiency exist, and the manufacturing process of the electric heating film is indirectly influenced.

Accordingly, an edge ripper that improves efficiency and reduces operational burden is provided to overcome the above-described deficiencies.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an improve efficiency and reduce the limit machine that tears of operation burden.

In order to achieve the above purpose, the technical scheme of the utility model is that: the utility model provides a tear limit machine for tear off rim charge of insulating overcoat, including microscler frame, guide roll, clamping mechanism, first drive mechanism, tear limit mechanism and second drive mechanism. The guide roller is assembled at the top of the long frame, the guide roller sequentially comprises a feeding roller, a middle roller and a discharging roller along the length direction of the long frame, the feeding roller is positioned at one end of the long frame, the discharging roller is positioned at the other end of the long frame, and the middle roller is positioned in the middle of the long frame; the clamping mechanism is assembled on the long frame and positioned between the feeding roller and the middle roller, and the clamping mechanism clamps the insulating outer sleeve between the feeding roller and the middle roller along the height direction of the long frame; the first traction mechanism comprises a first chuck positioned between the clamping mechanism and the intermediate roller and a first traction driver for driving the first chuck to slide along the length direction of the long frame, the first traction driver is installed at the long frame, and the first traction driver drives the first chuck to clamp the first chuck to the insulating outer sleeve between the intermediate roller and the blanking roller and convey the insulating outer sleeve to the blanking roller; the edge tearing mechanism is assembled on the long frame and positioned beside the insulating sleeve between the blanking roller and the middle roller, and the edge tearing mechanism tears off the edge material of the insulating sleeve between the blanking roller and the middle roller; the second traction mechanism comprises a second chuck positioned between the discharging roller and the edge tearing mechanism and a second traction driver used for driving the second chuck to slide along the length direction of the long frame, the second traction driver is installed at the long frame, and the second traction driver drives the second chuck to clamp the second chuck tightly and an insulating outer sleeve between the edge tearing mechanism and the discharging roller is conveyed to the discharging roller.

Preferably, the feeding roller comprises a plurality of roller shafts which are spaced and arranged in an up-and-down mode along the height direction of the elongated frame.

Preferably, the clamping mechanisms are two and are spaced apart along the length of the elongate frame.

Preferably, the clamping mechanism comprises a lower clamping plate block, an upper clamping plate block positioned right above the lower clamping plate block, and a clamping driver which is assembled on the elongated frame and drives the upper clamping plate block and the lower clamping plate block to move close to or away from each other.

Preferably, the first chuck includes a first lower chuck block, a first upper chuck block located right above the first lower chuck block, a first slide seat slidably disposed on the elongated frame along the length direction of the elongated frame, and a first chuck driver assembled on the first slide seat, and the first chuck driver drives the first upper chuck block and the first lower chuck block to slide toward or away from each other.

Preferably, the first traction driver is an air cylinder or a hydraulic cylinder arranged along the length direction of the elongated frame, and an output end of the air cylinder or the hydraulic cylinder penetrates through the lower part of the middle roller and is connected with the first sliding seat.

Preferably, the second chuck includes a second slide seat slidably disposed on the elongated frame along the length direction of the elongated frame and located below the first traction driver, a second lower chuck block located beside the first traction driver along the width direction of the elongated frame, a second upper chuck block located right above the second lower chuck block, and a second chuck driver assembled on the second slide seat, and the second chuck driver drives the second upper chuck block and the second lower chuck block to slide closer to or away from each other.

Preferably, the second traction driver is an air cylinder or a hydraulic cylinder arranged along the length direction of the elongated frame, and an output end of the air cylinder or the hydraulic cylinder is connected with the second sliding seat.

Preferably, the edge tearing mechanism comprises an edge tearing motor, a driving wheel and a driven wheel, the edge tearing motor is assembled on the long frame, an output shaft of the edge tearing motor is arranged along the height direction of the long frame, the driving wheel is mounted on the output shaft, and the driven wheel is mounted on the long frame and is tightly attached to the driving wheel.

Preferably, the edge tearing machine further comprises a recovery bin for collecting the insulating outer sleeve discharged by the discharging roller and a bearing mechanism for bearing the coil stock of the insulating outer sleeve, the bearing mechanism is located beside the charging roller along the length direction of the long frame, and the recovery bin is located beside the discharging roller along the length direction of the long frame.

Compared with the prior art, by means of the cooperation of the guide roller, the clamping mechanism, the first traction mechanism, the edge tearing mechanism and the second traction mechanism, when the device works, the starting end of the insulating outer sleeve is wound on the feeding roller and then passes through the clamping mechanism, then the starting end passes through the first chuck and then is wound on the middle roller, then the edge material of the insulating outer sleeve, which bypasses the starting end of the middle roller, is separated from the main body of the insulating outer sleeve, the separated main body passes through the second chuck and then is wound on the discharging roller, and the edge material is arranged at the edge tearing mechanism in a penetrating manner; therefore, the edge material of the insulating outer sleeve can be mechanically operated under the coordination of the first traction driver, the second traction driver, the clamping mechanism and the edge tearing mechanism, so that the efficiency is improved, and the operation burden is reduced.

Drawings

Fig. 1 is a schematic perspective view of the edge tearing machine of the present invention.

Fig. 2 is a schematic perspective view of the bearing mechanism and the clamping mechanism assembled on the long frame of the edge tearing machine of the present invention.

Fig. 3 is a schematic view of the three-dimensional structure of the edge tearing machine when the clamping mechanism, the intermediate roll, the first traction mechanism, the edge tearing mechanism, the second traction mechanism and the blanking roll are all assembled on the long frame.

Fig. 4 is a schematic view of a plane structure projected in a direction indicated by an arrow B in fig. 3.

Fig. 5 is a schematic perspective view of the clamping mechanism of the edge tearing machine of the present invention assembled to the long frame.

Fig. 6 is a schematic perspective view of a first traction mechanism in the edge tearing machine of the present invention.

Fig. 7 is a schematic perspective view of the edge tearing mechanism in the edge tearing machine of the present invention.

Fig. 8 is a schematic perspective view of the second traction mechanism of the edge tearing machine of the present invention assembled to the long frame.

Fig. 9 is a schematic view showing a plan structure of an insulating sheath.

Detailed Description

Embodiments of the present invention will now be described with reference to the drawings, wherein like element numerals represent like elements throughout.

Referring to fig. 1 to 4 and fig. 9, the edge tearing machine 100 of the present invention is used for tearing off the edge 211 of the insulating sheath 210 to meet the production requirement of the insulating sheath 210. Wherein, the utility model discloses an edge tearing machine 100 includes microscler frame 10, guide roll, clamping mechanism 30, first drive mechanism 40, tears limit mechanism 50 and second drive mechanism 60. The guide roller is assembled at the top of the long frame 10, the guide roller sequentially comprises a feeding roller 21, an intermediate roller 22 and a discharging roller 23 along the length direction (i.e. the direction indicated by the arrow a) of the long frame 10, the feeding roller 21 is located at one end of the long frame 10, the discharging roller 23 is located at the other end of the long frame 10, and the intermediate roller 22 is located in the middle of the long frame 10, so that the arrangement of the guide roller on the long frame 10 is more reasonable, the length of the long frame 10 is more effectively utilized, and the production requirement of the insulating outer sleeve 210 is further met. The clamping mechanism 30 is mounted on the elongated frame 10 and located between the feeding roller 21 and the intermediate roller 22, and the clamping mechanism 30 clamps the insulating sheath 210 between the feeding roller 21 and the intermediate roller 22 along the height direction (i.e., the direction indicated by the arrow C) of the elongated frame 10. The first traction mechanism 40 includes a first chuck 41 located between the clamping mechanism 30 and the intermediate roller 22, and a first traction driver 42 for driving the first chuck 41 to slide along the length direction of the elongated frame 10, the first traction driver 42 is installed at the elongated frame 10, and the first traction driver 42 drives the first chuck 41 to clamp the first chuck 41 between the intermediate roller 22 and the blanking roller 23 and convey the insulating sheath 210 to the blanking roller 23, so as to provide traction power for conveying the insulating sheath 210. The edge tearing mechanism 50 is assembled on the long frame 10 and positioned at the side of the insulating sleeve 210 between the feeding roller 23 and the middle roller 22, and the edge tearing mechanism 50 tears off the edge 211 of the insulating sleeve 210 between the feeding roller 23 and the middle roller 22; preferably, the edge tearing mechanisms 50 are spaced along the width direction of the elongated frame 10 (i.e. the direction indicated by the arrow B), so that the insulating sheath 210 between the feeding roller 23 and the intermediate roller 22 is located between the edge tearing mechanisms 50, so as to meet the requirement of tearing off the edge material 211 at the two sides of the insulating sheath 210; when the insulating outer sleeve 210 needs to tear the edge material 211 on one side, the edge tearing mechanism 50 at this time is located beside the edge material 211 of the insulating outer sleeve 210, so the invention is not limited thereto. The second traction mechanism 60 includes a second chuck 61 located between the discharging roller 23 and the edge tearing mechanism 50, and a second traction driver 62 for driving the second chuck 61 to slide along the length direction of the long frame 10, the second traction driver 62 is installed at the long frame 10, and the second traction driver 62 drives the second chuck 61 to clamp the second chuck 61 to convey the insulating outer sleeve 210 between the edge tearing mechanism 50 and the discharging roller 23 to the discharging roller 23, so as to provide traction power. In order to facilitate the recovery of the insulating outer sleeve 210 after the edge tearing and facilitate the bearing and placing of the coil stock 200, the utility model discloses an edge tearing machine 100 further comprises a recovery bin 70 for collecting the insulating outer sleeve 210 blanked by the blanking roller 23 and a bearing mechanism 80 for bearing the coil stock 200 of the insulating outer sleeve 210, the bearing mechanism 80 is located beside the feeding roller 21 along the length direction of the long frame 10, the recovery bin 70 is located beside the blanking roller 23 along the length direction of the long frame 10, preferably, the bin mouth 71 of the recovery bin 70 is arranged upwards and is lower than the blanking roller 23, so that the insulating outer sleeve 210 automatically drops in the recovery bin 70 along the blanking roller 23, but not limited thereto. It is understood that at least one of the recycling bin 70 and the carrying mechanism 80 can be omitted according to actual needs, and the disclosure is not limited thereto. More specifically, the following:

as shown in fig. 2, the feeding roller 21 includes a plurality of roller shafts 211 spaced apart and arranged in an undulating manner in a height direction of the elongated frame 10 to ensure smooth reliability of feeding of the roll material 200, but is not limited thereto.

As shown in fig. 1 to 5, the two clamping mechanisms 30 are spaced apart along the length of the elongated frame 10 to meet the process requirement of the insulating sheath 210 for temporary clamping stability during transportation. Specifically, as shown in fig. 5, the clamping mechanism 30 includes a lower clamping block 31, an upper clamping block 32 located right above the lower clamping block 31, and a clamping driver 33 which is assembled to the elongated frame 10 and drives the upper clamping block 32 and the lower clamping block 31 to move closer to or away from each other, so that the clamping mechanism 30 can move in the height direction of the elongated frame 10 to clamp the insulating housing 210 more reliably, and the structure of the clamping mechanism 30 is simplified; preferably, the lower clamping plate block 31 and the upper clamping plate block 32 are respectively arranged along the width direction of the long frame 10, and the two clamping drivers 33 are arranged at intervals along the width direction of the long frame 10, the output end of each clamping driver 33 is fixedly connected with the upper clamping plate block 32, and the lower clamping plate block 31 is assembled at the long frame 10, so that the upper clamping plate block 32 is applied with force from two positions, and the reliability of the clamping mechanism 30 for clamping the insulating outer sleeve 210 can be further improved; for example, the clamping actuator 33 is selected to be a linear actuator, such as, but not limited to, a pneumatic cylinder, a hydraulic cylinder, or a linear motor. It will be appreciated that the upper clamping block 32 may be fixed to the elongated frame 10 as desired, and the lower clamping block 31 is mounted to the output end of the clamping actuator 33.

As shown in fig. 1 to 4 and fig. 6, the first chuck 41 includes a first lower chuck block 41a, a first upper chuck block 41b located right above the first lower chuck block 41a, a first slide 41c slidably disposed on the elongated frame 10 along the length direction of the elongated frame 10, and a first chuck driver 41d mounted on the first slide 41c, wherein the first chuck driver 41d drives the first upper chuck block 41b and the first lower chuck block 41a to slide toward or away from each other, so that the first chuck 41 can move along the height direction of the elongated frame 10 to clamp the insulating sheath 210 more reliably, and the structure of the first chuck 41 is simplified; preferably, the first lower chuck block 41a, the first upper chuck block 41b and the first slide 41c are respectively arranged along the width direction of the long frame 10, and the first chuck drivers 41d are two and arranged at intervals along the width direction of the long frame 10, the output end of each first chuck driver 41d is fixedly connected with the first upper chuck block 41b, and the first lower chuck block 41a is assembled at the long frame 10, so that the first upper chuck block 41b is forced from two places, and the reliability of the first chuck 41 clamping the insulating sheath 210 can be further improved; for example, the first chuck driver 41d is selected to be a linear driver, such as, but not limited to, an air cylinder, a hydraulic cylinder, or a linear motor. It is understood that, according to actual needs, the first upper chuck block 41b can be fixed at the elongated frame 10, and at this time, the first lower chuck block 41a is installed at the output end of the first chuck driver 41 d. In order to improve the sliding stability and reliability of the first clamping head 41 along the length direction of the elongated frame 10, the first traction driver 42 is a pneumatic or hydraulic cylinder arranged along the length direction of the elongated frame 10, and the output end of the pneumatic or hydraulic cylinder passes through the lower part of the middle roller 22 and is connected with the first sliding base 41d, so as to more reliably pull the insulating sheath 210 to be conveyed to the blanking roller 23, but not limited thereto.

As shown in fig. 1 to 4 and fig. 8, the second chuck 61 includes a second slide seat 61c slidably disposed on the elongated frame 10 along the length direction of the elongated frame 10 and located below the first traction driver 42, a second lower chuck block 61a located beside the first traction driver 62 along the width direction of the elongated frame 10, a second upper chuck block 61b located right above the second lower chuck block 61a, and a second chuck driver 61d mounted on the second slide seat 61c, wherein the second chuck driver 61d drives the second upper chuck block 61b and the second lower chuck block 61a to slide closer to or away from each other, so that the second chuck 61 can perform a more reliable motion of clamping the insulating sheath 210 along the height direction of the elongated frame 10, and the structure of the second chuck 61 is simplified; preferably, the second lower chuck block 61a, the second upper chuck block 61b and the second slide seat 61c are respectively arranged along the width direction of the long frame 10, and the second chuck drivers 61d are two and arranged at intervals along the width direction of the long frame 10, the output end of each second chuck driver 61d is fixedly connected with the second upper chuck block 61b, and the second lower chuck block 61a is assembled at the long frame 10, so that the second upper chuck block 61b is forced from two places, and the reliability of the second chuck 61 clamping the insulating sheath 210 can be further improved; for example, the second chuck driver 61d is selected to be a linear driver, such as, but not limited to, an air cylinder, a hydraulic cylinder, or a linear motor. It is understood that, according to actual needs, the second upper chuck block 61b may be fixed to the elongated frame 10, and at this time, the second lower chuck block 61a is installed at the output end of the second chuck driver 61 d. Meanwhile, the second traction drive 62 is a pneumatic or hydraulic cylinder disposed along the length direction of the elongated frame 10, and an output end of the pneumatic or hydraulic cylinder is connected to the second carriage 61 c.

As shown in fig. 1, 3, 4 and 7, the edge tearing mechanism 50 includes an edge tearing motor 51, a driving wheel 52 and a driven wheel 53, the edge tearing motor 51 is assembled on the long frame 10, the output shaft 51 of the edge tearing motor 51 is arranged along the height direction of the long frame 10, the driving wheel 52 is installed on the output shaft 51, and the driven wheel 53 is installed on the long frame 10 and is closely attached to the driving wheel 52, so as to tear off the edge material 210 of the insulating sheath 210 more reliably.

The working principle of the edge tearing machine of the utility model is explained by combining the attached drawings: initially, the starting end of the insulating sheath 210 is wound around the feeding roller 21 and then passes through the clamping mechanism 30, then the starting end passes through the first chuck 41 and then passes through the middle roller 22, then the rim material 211 of the insulating sheath 210, which passes through the starting end of the middle roller 22, is separated from the main body 212 of the insulating sheath 210, the separated main body 212 passes through the second chuck 61 and then passes through the discharging roller 23, and the rim material 211 is threaded at the edge tearing mechanism 50; then, under the action of the first traction driver 42, the insulating outer sleeve 210 between the clamping mechanism 30 and the intermediate roller 22 is conveyed to the discharging roller 23, and the clamping mechanism 30 temporarily clamps the insulating outer sleeve 210 before the first traction driver 42 drives the first chuck 41 to reset and slide, so as to prevent the insulating outer sleeve 210 conveyed to the discharging roller 23 by the first traction mechanism 40 from accidentally retracting towards the feeding roller 21; meanwhile, under the action of the second traction driver 62, the second chuck 61 is conveyed to the discharging roller 23, so that the main body 212 of the insulating outer sleeve 210 is conveyed to the discharging roller 23; in the process that the second traction driver 62 drives the second chuck 61 to convey towards the discharging roller 23, when the first traction driver 42 is required to drive the first chuck 41 to slide towards the discharging roller 23 to the limit position, and the first chuck 41 keeps clamping the insulating outer sleeve 210, the second traction driver 62 drives the second chuck 61 to slide towards the discharging roller 23, so as to meet the requirement of orderly conveying of the insulating outer sleeve 210. In the process of conveying the second chuck 61 to the discharging roller 23, the edge tearing mechanism 50 gradually separates the edge 211 from the main body 212 of the insulating outer sleeve 210, so as to tear the edge 211. It should be understood that the above description is provided by sequentially and sequentially operating the first pulling mechanism 40 and the second pulling mechanism 60, and of course, the first pulling mechanism 40 and the second pulling mechanism 60 can be operated simultaneously according to actual requirements, so the disclosure is not limited thereto.

Compared with the prior art, by means of the cooperation of the guide roller, the clamping mechanism 30, the first traction mechanism 40, the edge tearing mechanism 50 and the second traction mechanism 60, during operation, the starting end of the insulating outer sleeve 210 is wound around the feeding roller 21 and then passes through the clamping mechanism 30, then the starting end passes through the first chuck 41 and then winds around the middle roller 22, then the edge material 211 of the insulating outer sleeve 210, which bypasses the starting end of the middle roller 22, is separated from the main body 212 of the insulating outer sleeve 210, the separated main body 212 passes through the second chuck 61 and then winds around the discharging roller 23, and the edge material 211 is penetrated at the edge tearing mechanism 50; therefore, the edge material 211 of the insulating outer sleeve 210 can be mechanically operated under the coordination of the first traction driver 40, the second traction driver 60, the clamping mechanism 30 and the edge tearing mechanism 50, so that the efficiency is improved and the operation burden is reduced.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the invention, which is defined by the appended claims.

Claims (10)

1. The utility model provides a tear limit machine for tear off the rim charge of insulating overcoat, a serial communication port, tear the limit machine and include:

an elongated frame;

the guide roller is assembled at the top of the long frame and sequentially comprises a feeding roller, a middle roller and a discharging roller along the length direction of the long frame, the feeding roller is positioned at one end of the long frame, the discharging roller is positioned at the other end of the long frame, and the middle roller is positioned in the middle of the long frame;

the clamping mechanism is assembled on the elongated frame, is positioned between the feeding roller and the middle roller and clamps the insulating outer sleeve between the feeding roller and the middle roller along the height direction of the elongated frame;

the first traction mechanism comprises a first chuck positioned between the clamping mechanism and the intermediate roller and a first traction driver used for driving the first chuck to slide along the length direction of the long frame, the first traction driver is installed at the long frame, and the first traction driver drives the first chuck to clamp the first chuck to the insulating outer sleeve between the intermediate roller and the blanking roller and convey the insulating outer sleeve to the blanking roller;

the edge tearing mechanism is assembled on the long frame and positioned beside the insulating sleeve between the blanking roller and the middle roller, and the edge tearing mechanism tears off the edge material of the insulating sleeve between the blanking roller and the middle roller; and

and the second traction mechanism comprises a second chuck positioned between the edge tearing mechanism and the discharging roller and a second traction driver used for driving the second chuck to slide along the length direction of the long frame, the second traction driver is installed at the long frame, and the second traction driver drives the second chuck to clamp the second chuck tightly and an insulating outer sleeve between the edge tearing mechanism and the discharging roller is conveyed to the discharging roller.

2. The edge tearing machine of claim 1, wherein the loading roller comprises a plurality of rollers spaced apart and arranged in an undulating manner along the height of the elongated frame.

3. An edge tearing machine according to claim 1, wherein the clamping mechanisms are two and are spaced apart along the length of the elongate frame.

4. The edge tearing machine of claim 1, wherein the clamping mechanism comprises a lower clamp block, an upper clamp block located directly above the lower clamp block, and a clamping actuator mounted to the elongate frame and urging the upper and lower clamp blocks towards and away from each other.

5. The edge tearing machine according to claim 1, wherein the first chuck comprises a first lower chuck block, a first upper chuck block located directly above the first lower chuck block, a first slide slidably disposed on the elongated frame along a length direction of the elongated frame, and a first chuck driver mounted on the first slide, wherein the first chuck driver drives the first upper chuck block and the first lower chuck block to slide toward or away from each other.

6. A machine as claimed in claim 5, wherein the first traction drive is a pneumatic or hydraulic cylinder disposed along the length of the elongate frame, the output of the cylinder passing beneath the intermediate roller and being connected to the first carriage.

7. The edge tearing machine according to claim 6, wherein the second chuck comprises a second slide seat slidably disposed on the elongated frame along the length direction of the elongated frame and located below the first traction driver, a second lower chuck block located beside the first traction driver along the width direction of the elongated frame, a second upper chuck block located directly above the second lower chuck block, and a second chuck driver assembled on the second slide seat, wherein the second chuck driver drives the second upper chuck block and the second lower chuck block to slide toward or away from each other.

8. A machine as claimed in claim 7, wherein the second traction drive is a pneumatic or hydraulic cylinder disposed along the length of the elongate frame, the output of which is connected to the second carriage.

9. The edge tearing machine according to claim 1, wherein the edge tearing mechanism comprises an edge tearing motor, a driving wheel and a driven wheel, the edge tearing motor is assembled on the long frame, an output shaft of the edge tearing motor is arranged along the height direction of the long frame, the driving wheel is installed on the output shaft, and the driven wheel is installed on the long frame and clings to the driving wheel.

10. The edge tearing machine according to claim 1, further comprising a recycling bin for collecting the insulating sheath fed by the feeding roller and a carrying mechanism for carrying the roll material of the insulating sheath, wherein the carrying mechanism is located beside the feeding roller along the length direction of the elongated frame, and the recycling bin is located beside the feeding roller along the length direction of the elongated frame.

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