CN219105203U - Fiber stripping equipment - Google Patents

Abstract

The utility model discloses fiber stripping equipment which comprises a cutting assembly, a stripping assembly and a base. Wherein the cutting component is assembled on the base and is used for forming a notch on a coating layer to be stripped of the optical fiber; the stripping component is assembled on the base and is used for being far away from the cutting component when the fiber stripping is performed so as to strip the coating layer to be stripped from the optical fiber from the notch, wherein the initial distance between the stripping component and the cutting component can be adjusted so as to adjust the distance from the notch to the end part of the optical fiber, and thus the stripping length of the optical fiber is adjusted. The stripping equipment provided by the utility model realizes stripping of the surface coating layers of the optical fibers with different lengths by flexibly adjusting the initial distance between the stripping assembly and the cutting assembly, and when the requirements of different stripping lengths of the optical fibers are met, the requirements can be met by adopting one equipment without replacing other equipment, so that the use cost is reduced.

Description

Fiber stripping equipment

Technical Field

The utility model relates to the technical field of optical fiber processing, in particular to fiber stripping equipment.

Background

In daily life, optical fibers are used for long distance information transmission because the conduction loss of light in the optical fibers is much lower than the conduction loss of electricity in the electric wires. When two optical fibers are connected with each other, the operation of stripping the coating layer is required to be carried out on the optical fibers to be connected with each other according to a certain length, so that the optical fiber cores at the connecting positions are exposed to the outside.

In the prior art, the coating layer outside the optical fiber is heated to be expanded and softened, and then the optical fiber is thermally stripped by cutting the coating layer by using an upper blade and a lower blade, and the equipment for carrying out the thermal stripping process is called fiber stripping equipment. The existing fiber stripping equipment mainly comprises a manual type and a semi-automatic type, when the equipment is used, a jig with the arranged fibers is required to be placed in a clamping groove manually, and after heating is completed, a fixing part of the jig is pulled outwards by adopting manpower or mechanical force, so that the fiber coating is stripped from the surface of the fiber core. However, the method generally requires manually tightly closing the upper and lower blades on the coating layer to be stripped of the optical fiber to form a notch, which not only increases the labor intensity of the manual work and affects the efficiency, but also easily causes incomplete stripping of the coating layer or fiber breakage due to uneven stress. In addition, the length of the coating layer to be peeled off in the prior art cannot be flexibly adjusted. In view of the above, there is a need to develop a technique suitable for stripping an optical fiber coating layer for improving the quality and efficiency of stripping operation.

Disclosure of Invention

The utility model provides fiber stripping equipment, which aims to solve the problem of low efficiency of fiber stripping operation in the prior art.

In order to solve at least one or more of the technical problems mentioned above, the present utility model provides the following technical solutions:

a fiber stripping device comprises a cutting component, a stripping component and a base; the cutting assembly is arranged on the base; the stripping component is movably arranged on the base and is far away from or close to the cutting component along a first direction.

In one embodiment, the stripping assembly includes a through slot along a first direction.

In one embodiment, the stripping assembly comprises one or more feeding jigs, each feeding jig is provided with a guide groove, and the feeding jigs are clamped in the through grooves.

In one embodiment, the stripping assembly comprises a compression block and a first power device, wherein the compression block is fixedly arranged on the first power device, and the power device drives the compression block to be close to or far away from the through groove along the second direction.

In one embodiment, the compression block is a silica gel pad.

In one embodiment, the cutting assembly comprises a fixed block and a cutter, the fixed block comprises an upper cutter fixed block and a lower cutter fixed block, the cutter comprises an upper stripping cutter arranged on the upper cutter fixed block and a lower stripping cutter arranged on the lower cutter fixed block; the lower stripping knife is arranged on the end face of the cutting assembly, which is contacted with the stripping assembly, along the second direction; the upper cutter fixing block drives the upper cutter and the lower cutter to be matched with each other.

In one embodiment, the cutting assembly includes a heating portion including a recess fixedly disposed on the lower blade fixing block in a first direction and a heating block located below the recess.

In one embodiment, a collection assembly is included, the collection assembly including a collection box disposed below the stripping assembly and a projection of the lower stripper blade along a first direction is located within the collection box.

In one embodiment, the collection assembly includes a blow tube disposed in an end of the recess in the lower blade mounting block remote from the blade; the inflation tube is rotatable in a second direction.

In one embodiment, the collection assembly includes a cleaning member disposed on a side of the cutting assembly remote from the cutter and adjacent to the lower stripper blade in a first direction.

The fiber stripping device is provided with a cutting assembly and a stripping assembly, wherein the cutting assembly is used for forming a notch on a coating layer to be stripped of the optical fiber, and the stripping assembly is used for being away from the cutting assembly when stripping the optical fiber so as to strip the coating layer to be stripped from the optical fiber from the notch. Wherein an initial distance between the stripping assembly and the cutting assembly can be adjusted to adjust a distance from the cut to the end of the optical fiber, thereby achieving adjustment of the stripped length of the optical fiber. The stripping equipment provided by the utility model realizes stripping of the surface coating layers of the optical fibers with different lengths by flexibly adjusting the initial distance between the stripping assembly and the cutting assembly, and when the requirements of different stripping lengths of the optical fibers are met, the requirements can be met by adopting one equipment without replacing other equipment, so that the use cost is reduced.

Further, in some embodiments, the through groove of the fiber stripping device of the utility model comprises one or more feeding jigs, and each feeding jig is provided with a guide groove. When a plurality of feeding jigs are provided, a plurality of optical fibers can be correspondingly inserted into the guide grooves of the plurality of feeding jigs to perform fiber stripping operation; for the cable of which the two ends of one optical fiber need to be stripped, the two ends of the cable can be respectively inserted into the guide grooves of two different feeding jigs, so that the two ends of one optical fiber can be stripped simultaneously, and the stripping efficiency is improved.

Further, in some embodiments, the stripping assembly of the fiber stripping apparatus of the present utility model includes a first power device for compressing the feeding jig, so that the feeding jig can be kept fixed during the fiber stripping apparatus. This first power device has replaced the operation of traditional use manual fixed material loading tool, has reduced artificial intensity of labour, has effectively promoted work efficiency.

Further, in yet another embodiment, the fiber stripping apparatus of the present utility model includes a collection assembly including a collection box disposed below the stripping assembly and adjacent to the cutting assembly, such that the stripped fiber coating can fall into the collection box, avoiding a cleaning process.

Drawings

The above, as well as additional purposes, features, and advantages of exemplary embodiments of the present utility model will become readily apparent from the following detailed description when read in conjunction with the accompanying drawings. In the drawings, embodiments of the utility model are illustrated by way of example and not by way of limitation, and like reference numerals refer to similar or corresponding parts and in which:

fig. 1 is a schematic diagram showing an overall structure of a fiber stripping apparatus according to an embodiment of the present utility model;

FIG. 2 shows a schematic view of a portion of the stripping apparatus of FIG. 1 including a stripping assembly;

FIG. 3 is a schematic view showing a partial structure of the fiber stripping apparatus of FIG. 1 including a cutting assembly;

fig. 4 shows a right side view of fig. 2;

FIG. 5 is a schematic view showing a portion of the structure of the stripping apparatus of FIG. 1 including a stripping assembly;

FIG. 6 shows a schematic view of a portion of the stripping apparatus of FIG. 1 including a collection assembly;

fig. 7 is a schematic view showing a partial structure of a fiber stripping apparatus including a collection assembly according to another embodiment of the present utility model.

Reference numerals illustrate:

1. a housing; 2. a temperature controller; 3. a switch button; 4. an emergency stop button; 5. feeding jig; 6. compressing the fixed cylinder; 7. a correlation photoelectric part; 8. a collection box; 9. a base; 10. an upper stripping knife and a lower pressing cylinder; 11. a floating joint; 12. a linear guide rod; 13. an upper cutter fixing block; 14. a lower cutter fixing block; 15. a top stripping knife; 16. a heating block; 17. a lower stripping knife; 18. a silica gel pad; 19. a blowing rotary joint; 20. an air blowing pipe; 21. a thermocouple; 22. a connecting block; 23. a linear guide rail; 24. a screw rod stepper; 25. a brush; 26. and (5) cushion blocks.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Specific embodiments of the present utility model are described in detail below with reference to the accompanying drawings.

The structure of the fiber stripping device provided by the utility model is shown in fig. 1 to 7, and the fiber stripping device integrally comprises a shell 1 and an internal structure of the fiber stripping device arranged in the shell 1. As shown in fig. 1, a temperature controller 2, a switch button 3 and an emergency stop button 4 which are connected with the internal structure are arranged on a shell 1, the temperature controller 2 is used for displaying the temperature and time of fiber stripping, and a button for adjusting the temperature and time of fiber stripping is also arranged on the temperature controller 2. The switch button 3 is used for opening or closing the temperature controller 2 and a circuit connected with the temperature controller 2, so as to control the heating temperature and the heating time of the fiber stripping equipment. The emergency stop button 4 is used for closing the whole fiber stripping equipment in an emergency, so that accidents are avoided.

The internal structure of the fiber stripping device comprises a cutting component, a stripping component and a base 9, wherein the cutting component and the stripping component are assembled on the base 9. The cutting component is used for forming a notch on the coating layer to be stripped of the optical fiber, and the stripping component is used for being away from the cutting component when the stripping action is performed so as to strip the coating layer to be stripped of the optical fiber from the formed notch. And, the initial distance between the stripping assembly and the cutting assembly can be adjusted for adjusting the distance from the cut to the end of the optical fiber, thereby adjusting the stripping length of the optical fiber. By initial distance, it can be considered the original distance between the stripping assembly and the cutting assembly before the operation of the fiber stripping apparatus. The initial distance may be zero, i.e. the contact between the aforesaid stripping assembly and the cutting assembly. It will be appreciated that the initial distance may be other than zero, i.e., the non-contact arrangement between the stripping assembly and the cutting assembly described above. When the requirements of different stripping lengths are met, the fiber stripping equipment disclosed by the utility model can flexibly adjust the initial distance between the stripping assembly and the cutting assembly, so that the initial distance is set according to the different stripping lengths of the optical fibers, and the requirements of different working conditions are met.

Fig. 2 shows a schematic partial structure of the stripping apparatus of fig. 1 including a stripping assembly. The stripping assembly may specifically include a through slot for extending the optical fiber in a first direction to a device location of the through slot and securing the optical fiber. In one embodiment, the through groove may include one or more feeding jigs 5, and a guide groove is provided on each feeding jig 5. Further, a guiding groove for placing the optical fiber along the first direction may be provided on each feeding jig 5, so that the optical fiber extends along the first direction. The front end and the rear end of the guide groove of the feeding jig 5 are opened, and when the specific operation is performed, the fiber arranging operation can be completed only by putting the optical fiber of which the coating layer is to be stripped into the guide groove of the feeding jig 5 and enabling the optical fiber to extend to the set position of the through groove along the first direction. The feeding jig 5 can limit the optical fiber in the first direction and guide the optical fiber to extend along the first direction.

As shown in fig. 2, in an application scenario, two feeding jigs 5 in the fiber stripping apparatus may be provided. The two feeding jigs 5 are arranged at intervals along the second direction and extend along the first direction, and the first direction is perpendicular to the second direction. The two feeding jigs 5 can fix two optical cables or two ends of one optical cable at the same time, so that a plurality of optical fibers contained in the optical cables are arranged in the guide grooves of the feeding jigs 5. It will be appreciated that in another application, the feeding jig 5 may be provided as one. It will be appreciated that in other embodiments, the first direction and the second direction may be non-perpendicular, such as in an obtuse or acute relationship.

In one application scenario, the stripping assembly comprises a first power device for compacting the feeding jig 5. Specifically, the aforementioned first power means may press the fixed cylinder 6. When the feeding jig 5 is specifically used, the feeding jig 5 with the fiber arranged is placed in the base of the through groove, and the pressing fixing cylinder 6 moves downwards to press the feeding jig 5, so that the feeding jig 5 cannot move relatively in the base of the through groove. In practical application, a cushion block 26 can be arranged at one end of the pressing and fixing cylinder 6, and the pressing and fixing cylinder 6 presses the feeding jig 5 through the cushion block 26. In particular, referring to fig. 2, when there are two feeding jigs 5, a "concave" cushion block may be provided, and the convex portion of the cushion block corresponds to the position of the feeding jigs 5, so that the compression fixing cylinder 6 applies as much pressure as possible to the feeding jigs 5 through the cushion block. In addition, it is understood that other driving mechanisms, such as a motor, may be used in addition to the cylinder when the feeding jig 5 is pressed.

It should be noted that, the setting of the feeding jig 5 is to accomplish the fiber arrangement outside, to improve the fiber arrangement convenience, in other embodiments, a special feeding jig may not be provided, for example, a guiding groove for guiding the optical fiber to be arranged along the first direction is directly provided on the base of the through groove, and the optical fiber may be placed in the through groove.

Further, in another application scenario, the utility model can be provided with a fool-proof design to increase the use safety of the fiber stripping equipment. Specifically, the base of the through groove can be provided with the correlation photoelectric part 7, the correlation photoelectric part 7 comprises two correlation sensors, the two correlation sensors are respectively arranged on two sides of the base of the through groove, and when a worker installs the feeding jig 5, the pressing fixed cylinder 6 is in misoperation and downward movement to cause injury to the worker. In the fiber stripping apparatus of the present utility model, the correlation photoelectric portion 7 may not be provided for the sake of simplicity.

Fig. 3 shows a schematic view of a part of the fiber stripping apparatus shown in fig. 1, which comprises a cutting assembly, which may comprise a fixed block and a cutter. The fixing block may include an upper cutter fixing block 13 and a lower cutter fixing block 14, and the cutter may include an upper cutter 15 disposed on the upper cutter fixing block 13 and a lower cutter 17 disposed on the lower cutter fixing block 14, where the upper cutter fixing block 13 drives the upper cutter 15 and the lower cutter 17 to cooperate with each other to form a cut on a coating layer to be stripped of the optical fiber. In one embodiment, through holes may be formed at corresponding positions of the upper blade fixing block 13 and the lower blade fixing block 14, the through holes are assembled with linear guide rods 12, and the arrangement of the linear guide rods 12 ensures a movement track of the upper blade fixing block 13, and further ensures a movement track of the upper stripping blade 15, so as to ensure that the upper stripping blade 15 corresponds to a cut position of the lower stripping blade 17 on a coating layer to be stripped of the optical fiber. In one application scenario, the cutting assembly includes a second power device for driving the upper blade 15 up and down, which in one particular embodiment may be an upper blade hold down cylinder 10 fixedly mounted to the upper blade mount 13 by a floating joint 11. The floating joint 11 can ensure the driving function of the upper broach pressing cylinder 10 on the upper broach fixing block 13 in the vertical direction, and further reduces the requirements on the machining precision such as the flatness of the contact surface between the upper broach pressing cylinder 10 and the upper broach fixing block 13. It can be understood that the floating joint 11 is not required to be arranged in the fiber stripping equipment, so that the upper stripping knife lower pressing cylinder 10 and the upper knife fixing block 13 are directly assembled, and the upper knife fixing block 13 can be driven by the upper stripping knife lower pressing cylinder 10 to move up and down. The second power device is additionally arranged to replace the traditional process that the upper stripping knife and the lower stripping knife are tightly combined on the coating layer to be stripped of the optical fiber to form a notch, so that the problem that the coating layer to be stripped is not cleanly stripped or the problem that the fiber is broken due to overlarge force application caused by too small manual force application is effectively avoided.

When the optical fiber stripping machine is specifically used, the upper stripping knife pressing cylinder 10 drives the upper knife fixing block 13 to move up and down along the linear guide rod 12, and when the upper knife fixing block 13 falls to a certain distance from the lower knife fixing block 14, the upper stripping knife 15 is meshed with the lower stripping knife 17 up and down, so that a notch can be formed at the stripping position of the coating layer to be stripped of the optical fiber. That is, the length of one end of the optical fiber from the notch is the set length of the coating layer to be stripped, and the notch is located at the stripping position of the coating layer to be stripped. It can be understood that the cutters forming the incisions at the stripping positions of the coating layers to be stripped of the optical fibers can also be arranged at intervals along the second direction, that is, the cutters and the feeding jig are arranged in one-to-one correspondence, a plurality of groups of cutters can be arranged to form the incisions at the stripping positions of the coating layers to be stripped of the optical fibers at the same time, and the fiber stripping efficiency is improved.

As shown in fig. 3, in one embodiment, the cutting assembly may further include a heating portion provided on the lower blade fixing block 14, and a heating block 16 may be disposed at the bottom of the heating portion. Specifically, corresponding to the two feeding jigs 5 shown in fig. 2, when the number of the feeding jigs 5 is two, the number of the heating portions provided in the corresponding cutting assembly is also two. Each heating part is internally provided with a heating block 16 arranged at the bottom of the heating block, each heating block 16 is in a strip shape and extends along the first direction, and the heating block 16 is arranged on the lower cutter fixing block 14. Specifically, the heating block 16 may be a ceramic heating block. The heating block 16 is also provided with a heating element and a temperature measuring device, and the temperature measuring device is also connected with a control circuit. Specifically, the temperature measuring device may be a thermocouple 21, and the thermocouple 21 detects the temperature of the heating block 16 and transmits the detected temperature to the control circuit, and finally displays the current temperature of the heating block 16 on the display screen of the temperature controller 2. An adjusting button can be arranged on the temperature controller 2 for setting the temperature required by fiber stripping, and the temperature controller 2 controls the working temperature of the heating block 16 through a control circuit. When the optical fiber is located at the set position, the coating layer to be stripped of the optical fiber is located within the heating portion, specifically, the coating layer to be stripped of the optical fiber is located on the heating block 16. In one application scenario, after the cutter forms a notch at the stripping position of the coating layer to be stripped of the optical fiber, the heating part heats and softens the coating layer to be stripped to enable the notch to form a fusion fracture, so that the coating layer to be stripped can be conveniently stripped from the optical fiber in the follow-up process.

As shown in fig. 4 and 5, the stripping assembly may further include a pressing block for pressing the coating layer to be stripped of the optical fiber. In one application scenario, the compression block may specifically use a silicone pad 18. The silica gel pad 18 presses the optical fiber between the heating portion and the silica gel pad 18 when pressing on the coating layer to be peeled of the optical fiber. Specifically, a silica gel pad 18 is provided at the bottom of the upper blade fixing block 13, and its set position corresponds to the heating block 16 in the heating section. The silica gel pad 18 is arranged to effectively avoid incomplete stripping or fiber breakage of the coating layer to be stripped of the optical fiber caused by uneven stress of the optical fiber. As shown, the stripping assembly may also include a drive member for driving the through slot toward or away from the cutting assembly. Specifically, the driving member includes a connection block 22, a linear guide 23, and a screw stepper 24, and the extending direction of the linear guide 23 is the same as the first direction. The screw stepper 24 is slidably connected to the base 9 through a connection block 22, and the through groove slides back and forth along the linear guide rail 23 under the drive of the screw stepper 24, i.e. the through groove slides in the first direction.

When the device is specifically used, the feeding jig 5 with the fiber arranged is placed in the base of the through groove, the pressing and fixing cylinder 6 moves downwards to press and fix the cushion block 26 to the feeding jig 5, then the screw rod stepper 24 drives the through groove to move to the set position, and the coating layer to be stripped of the optical fiber is placed on the heating block 16 which keeps the set temperature. The upper broach pushing cylinder 10 drives the upper broach fixing block 13 to move towards the lower broach fixing block 14 so as to drive the upper broach 15 and the silica gel pad 18 to move towards the lower broach 15. The upper and lower stripping blades 15 and 17 cooperate to form a cut in the coating layer to be stripped of the optical fiber, and stay for a period of time to allow the heating block 16 to heat the coating layer to be stripped. After a set time, the screw stepper 24 drives the through groove to move along the linear guide rail 23 in a direction away from the cutting assembly, so that the coating to be stripped is stripped from the optical fiber at the notch. After the fiber stripping action is completed, the upper stripping knife and lower pressing cylinder 10 drives the upper stripping knife 15 and the silica gel pad 18 to move towards the direction away from the lower stripping knife 17, and finally the optical fiber is taken down.

It should be noted that, on the basis that the fiber stripping process of the fiber can be realized on the fiber stripping device provided by the utility model, the fiber stripping device provided by the utility model can further adjust the stripping length of the fiber. In one application scenario, the initial distance between the stripping assembly and the cleaving assembly is adjusted to adjust the distance of the cleave to the end of the optical fiber, thereby adjusting the stripped length of the optical fiber. Specifically, as shown in fig. 2 to 5, the distance between the end surface of the through groove in the peeling assembly facing the lower cutter 17 and the lower cutter 17 in the cutting assembly is adjusted to achieve the adjustment of the peeling length. The specific process for adjusting the stripping length of the optical fiber comprises the following steps: the length of the coating layer to be stripped of the optical fiber is determined according to the required stripping length, namely, the screw rod stepper 24 is adopted to drive the through groove along the first direction so as to adjust the distance between the through groove and the stripping assembly, so that the through groove is close to or far away from the stripping assembly, namely, the distance between the end face of the fixture fixing assembly, which faces the lower stripping knife 17, and the lower stripping knife 17 is adjusted, and the length (namely, the stripping length) of the coating layer to be stripped of the optical fiber on the heating block 16 is changed. The optical fiber is fixed so as to be unchanged in position in the through groove, and when the distance between the through groove and the lower stripping blade 17 is increased by the screw rod stepper 24, the distance between the end surface of the through groove facing the lower stripping blade 17 and the lower stripping blade 17 is increased, that is, the length of the optical fiber in the heating block 16 is reduced, and the length of the coating to be stripped is reduced, that is, the stripping length is reduced. On the contrary, when the stripping length of the optical fiber is increased, the distance between the end face of the through groove facing the lower stripping knife 17 and the lower stripping knife 17 is reduced, and the stripping length is increased, so that the aim of adjusting the length of the coating layer to be stripped is fulfilled.

For timely cleaning and collecting of the stripped coating layer, as shown in fig. 6, a collecting assembly may be provided on the base 9 in one embodiment. Wherein the collection assembly may comprise a collection box 8, the collection box 8 being located below the stripping assembly and a projection of the lower stripper blade in a first direction being located within the collection box for collecting stripped fiber coating on the optical fiber. Specifically, the collection assembly is disposed on a side of the heating portion away from the cutter for causing the stripped optical fiber coating layer remaining in the heating portion to fall into the collection box 8. Specifically, the collecting box 8 may be mounted on the base 9 in a drawing manner, and when the peeling assembly moves in a direction away from the cutting assembly, the box opening of the collecting box 8 is exposed between the peeling assembly and the cutting assembly, so to speak, the box opening of the collecting box 8 is located between the through groove and the heating portion. As shown in the figures, the collection assembly may further comprise a cleaning member disposed on a side of the cutting assembly remote from the stripping blade so that the stripped fiber coating on the optical fiber falls into the collection box 8. That is, the cleaning member is disposed on a side of the cutting assembly remote from the cutter and adjacent to the lower stripper blade 17 in the first direction. Specifically, the cleaning member may include a blower rotary joint 19 and a blower tube 20, and the blower tube 20 is rotatably fitted to the base 9 through the blower rotary joint 19. That is, the air blowing pipe 20 is disposed at an end of the groove on the lower blade fixing block 14 away from the cutter, and the air blowing pipe 20 is rotatable in the second direction. In use, the blowing direction of the blowing pipe 20 is the same as the extending direction of the heating portion, and the stripped optical fiber coating layer is blown into the collecting box 8. When the collection box 8 is full of waste materials, workers only need to take out the collection box to pour the waste materials, so that the time for manual cleaning after fiber stripping every time is saved, and the working efficiency is improved.

In another embodiment, as shown in FIG. 7, the cleaning assembly may also be a brush 25. When the optical fiber collecting box is used, the handle of the brush 25 is controlled under the action of manpower or machinery to push the brush heads of the brush 25 to move along the extending direction of the heating part, and the stripped optical fiber coating layer falls into the collecting box 8 under the cleaning action of the brush heads.

In the foregoing description of the present specification, the terms "fixed," "mounted," "connected," or "connected" are to be construed broadly, unless explicitly stated or limited otherwise. For example, in terms of the term "coupled," it may be fixedly coupled, detachably coupled, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intermediaries, or in communication with each other or in interaction with each other. Therefore, unless otherwise specifically defined in the specification, a person skilled in the art can understand the specific meaning of the above terms in the present utility model according to the specific circumstances.

Those skilled in the art will also appreciate from the foregoing description that terms such as "upper," "lower," "front," "rear," "left," "right," "length," "width," "thickness," "vertical," "horizontal," "top," "bottom," "inner," "outer," "axial," "radial," "circumferential," "center," "longitudinal," "transverse," "clockwise," or "counterclockwise" and the like are used herein for the purpose of facilitating description and simplifying the description of the present utility model only, and do not necessarily require that the particular orientation, configuration and operation be construed or implied by the terms of orientation or positional relationship shown in the drawings of the present specification, and therefore the terms of orientation or positional relationship described above should not be interpreted or construed as limiting the scope of the present utility model.

In addition, the terms "first" or "second" and the like used in the present specification to refer to the numbers or ordinal numbers are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present specification, the meaning of "plurality" means at least two, for example, two, three or more, etc., unless explicitly defined otherwise.

While various embodiments of the present utility model have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous modifications, changes, and substitutions will occur to those skilled in the art without departing from the spirit and scope of the utility model. It should be understood that various alternatives to the embodiments of the utility model described herein may be employed in practicing the utility model. The appended claims are intended to define the scope of the utility model and are therefore to cover all equivalents or alternatives falling within the scope of these claims.

Claims (8)

1. The fiber stripping equipment is characterized by comprising a cutting assembly, a stripping assembly and a base;

the cutting assembly is arranged on the base and comprises a fixed block and a cutter;

the stripping assembly is movably arranged on the base and is far away from or close to the cutting assembly along a first direction, and the stripping assembly is provided with a through groove along the first direction;

the stripping assembly comprises a compression block and a first power device, wherein the compression block is fixedly arranged on the first power device, and the first power device drives the compression block to be close to or far away from the through groove along the second direction.

2. The fiber stripping apparatus of claim 1, wherein the stripping assembly comprises one or more feeding jigs, each feeding jig is provided with a guide groove, and the feeding jigs are clamped in the through grooves.

3. The fiber stripping apparatus of claim 1, wherein the compression block is a silica gel pad.

4. The fiber stripping apparatus of claim 1 wherein the fixed block comprises an upper knife fixed block and a lower knife fixed block, the knife comprising an upper knife disposed on the upper knife fixed block and a lower knife disposed on the lower knife fixed block; the lower stripping knife is arranged on the end face of the cutting assembly, which is contacted with the stripping assembly, along the second direction; the upper cutter fixing block drives the upper cutter and the lower cutter to be matched with each other.

5. The fiber stripping apparatus of claim 4 wherein the cutting assembly includes a heating section including a recess fixedly disposed on the lower blade mounting block in a first direction and a heating block positioned below the recess.

6. The fiber stripping apparatus as recited in claim 4, including a collection assembly including a collection box disposed below the stripping assembly and a projection of the lower stripper blade in a first direction is positioned within the collection box.

7. The fiber stripping apparatus of claim 6 wherein the collection assembly comprises a blow tube disposed in an end of the recess in the lower blade mounting block remote from the blade; the inflation tube is rotatable in a second direction.

8. The fiber stripping apparatus as recited in claim 6, wherein said collection assembly includes a cleaning member disposed on a side of said cutting assembly remote from said cutter and adjacent said lower stripper in a first direction.

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