CN220449420U - Cable winding device - Google Patents

Abstract

The utility model relates to a simple and easy adjustable radius is around cable equipment perpendicularly, around cable equipment includes the wire reel, around cable axle and locking screw, be provided with the scale groove on the wire reel, the scale groove is including many radial distribution of periphery that are the center and link up wire reel thickness direction's cell body, around cable axle erects on the scale groove, around the diameter of cable axle is greater than the width of scale groove, around the bottom of cable axle is equipped with the screw hole, locking screw passes the scale groove from the bottom of wire reel and cooperates with the screw hole, wherein, can adjust around the cable internal diameter through the distribution of adjusting around cable axle on the scale groove. The simple and easy adjustable radius of this application is perpendicular around cable equipment has utilized around the cable axle and has passed through locking screw position adjustable characteristic on the wire reel, makes the optical cable wind out and around the cable axle enclose the internal diameter that corresponds after closing, not only satisfies the customer to around the various requirements of cable internal diameter, has also improved simultaneously around cable efficiency, has reduced staff intensity of labour.

Description

Cable winding device

Technical Field

The application relates to the field of AOC optical fiber communication, in particular to simple and easy adjustable radius vertical cable winding equipment.

Background

The AOC is a transmission device which is composed of integrated photoelectric devices and is used for high-speed and high-reliability interconnection among data centers, high-performance computers, large-capacity memories and other devices, and generally meets the electrical interface of an industry standard, and the data is transmitted by using the superiority of an optical cable through internal electric-optical-electric conversion.

AOC jumper wire customers generally have requirements on the inner diameter of a winding cable, manual winding cables are generally adopted to meet the requirements of different inner diameters of the winding cables of the customers, but the inner diameter of the winding cable is unstable due to manual winding cables, and the production efficiency is low.

Disclosure of Invention

In order to solve the different problem of customer to the cable internal diameter requirement, also in order to reduce artifical manual working strength of winding the cable, improve work efficiency, this application provides a simple and easy adjustable radius and winds cable equipment perpendicularly.

The application adopts a technical scheme that: the utility model provides a simple and easy adjustable radius is around cable equipment perpendicularly, around cable equipment includes the wire reel, around cable axle and locking screw, be provided with the scale groove on the wire reel, the scale groove is including many radial distribution of periphery in the center and link up the cell body of wire reel thickness direction, around cable axle erects on the scale groove, around the bottom of cable axle is equipped with first screw hole, locking screw passes the scale groove from the bottom of wire reel and cooperates with first screw hole, wherein, can adjust around cable internal diameter through the distribution of adjusting around cable axle on the scale groove.

In a specific embodiment of the application, the cable winding device further comprises a support, a carrier plate, a connecting cylinder and a cable winding motor, wherein the carrier plate is arranged on the support and is provided with a first through hole corresponding to the wire spool, one end of the connecting cylinder is connected to the lower surface of the carrier plate, the cable winding motor is fixedly connected with the other end of the connecting cylinder, and the output end of the cable winding motor is in transmission connection with the wire spool.

In a specific embodiment of the present application, the cable winding device further includes a guide sleeve, the guide sleeve passes through the first through hole, one end of the guide sleeve is connected with the output end of the cable winding motor, and the other end of the guide sleeve is connected with the wire spool.

In a specific embodiment of the present application, a concave ring cavity is disposed on the lower surface of the wire spool, and the concave ring cavity is in nested fit with the upper end of the guide sleeve.

In a specific embodiment of the present application, a plurality of first fixing holes are formed at the top end of the guide sleeve, and a plurality of fourth through holes are formed in the wire spool corresponding to the concave ring cavity so as to pass through the fourth through holes through screws and to be in contact with the first fixing holes Xiang Suojin.

In a specific embodiment of the present application, the cable winding device further includes a wire harness device, the wire harness device is disposed on the carrier plate, the wire harness device includes two first roll shafts disposed at vertical intervals and a second roll shaft disposed transversely, and the first roll shaft and the second roll shaft enclose a channel for the regular optical cable.

In a specific embodiment of the present application, the wire harness further includes a base, the base includes two oppositely disposed substrates, and the second roller shaft transversely penetrates through the base and is rotatably assembled with the substrates.

In a specific embodiment of the present application, the first roller includes a first shaft body and a first connecting block, the first connecting block is disposed at the lower end of the first shaft body, the first shaft body and the first connecting block are connected to each other, and a threaded through hole is disposed on the first connecting block.

In a specific embodiment of the application, the wire harness device further comprises a distance adjusting screw, the distance adjusting screw transversely penetrates through the base body and is rotatably assembled with the base plate, two sections of distance adjusting threads with opposite directions are arranged on the distance adjusting screw, the first roll shafts are in threaded assembly through threaded through holes and the distance adjusting threads, and when the first roll shafts are arranged next to the base body, the distance adjusting screw can conduct distance adjustment along the reverse displacement of the distance adjusting screw through the two first roll shafts.

In this application a concrete embodiment, the wire binding still includes auxiliary fixing rod, is equipped with spacing through-hole on the connecting block, and auxiliary fixing rod runs through spacing through-hole and transversely sets up on the base plate, and when first roller unsettled setting, rotatory roll adjustment screw, auxiliary fixing rod play the rotatory effect of restriction first roller, make two first rollers can only do reverse displacement along the roll adjustment screw, and first roller also can set up immediately adjacent pedestal bottom, alright not need set up auxiliary fixing rod this moment.

The beneficial effects of this application are: the characteristic that the cable winding shaft is adjustable in position on the wire spool through the locking screw is utilized, so that the optical cable is wound out of the corresponding inner diameter after being wound around the cable winding shaft, various requirements of customers on the inner diameter of the cable winding are met, the cable winding efficiency is improved, and the labor intensity of staff is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic perspective view of a cable winding device according to an embodiment of the present application;

FIG. 2 is a schematic view of the structure of the bracket portion of the cabling apparatus shown in FIG. 1;

FIG. 3 is a schematic view of the structure of the spool and the spool portion of the cabling arrangement shown in FIG. 1;

FIG. 4 is a schematic structural view of the spool portion of the cabling arrangement shown in FIG. 1 from another perspective;

FIG. 5 is a schematic view of the cable winding shaft portion of the cable winding apparatus shown in FIG. 1;

FIG. 6 is a schematic view of the carrier plate portion of the cabling apparatus shown in FIG. 1;

FIG. 7 is a schematic view of the construction of the cabling motor and its associated parts in the cabling apparatus shown in FIG. 1;

FIG. 8 is a schematic view of the construction of the cable winding motor portion of the cable winding device shown in FIG. 1;

FIG. 9 is a schematic view of the guide sleeve and connecting barrel portions of the cable winding apparatus shown in FIG. 1;

FIG. 10 is a schematic view of the structure of the harness portion of the cabling arrangement shown in FIG. 1;

fig. 11 is a schematic structural view of a first roller portion in the wire harness shown in fig. 10;

reference numerals illustrate: 10. a cable winding device; 100. a wire spool; 110. a scale groove; 111. a tank body; 112. scale marks; 113. size numbers; 120. a concave annular cavity; 130. a fourth through hole; 200. winding a cable shaft; 210. a circular cap; 220. a first threaded hole; 230. a locking screw; 300. a bracket; 310. a support column; 320. shaping columns; 321. a first set of sizing columns; 322. a second set of sizing columns; 330. a chute; 340. a foot cup; 341. a support leg; 342. a support post; 350. an angle code; 400. a carrier plate; 410. a first through hole; 420. a second through hole; 430. a sixth through hole; 500. a connecting cylinder; 510. a third through hole; 600. a cable winding motor; 610. a rotation shaft; 620. a convex column; 630. a second threaded hole; 700. guide sleeve; 710. a first fixing hole; 720. a second fixing hole; 730. a groove; 800. a wire harness; 810. a first roller shaft; 811. a first shaft body; 812. a first connection block; 813. a threaded through hole; 814. limiting through holes; 820. a second roller shaft; 830. a base; 831. a substrate; 832. a bottom plate; 833. a fifth through hole; 840. a distance adjusting screw; 841. a circular adjusting cap; 842. distance-adjusting screw threads; 850. auxiliary fixing rod.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

It should be noted that, in the embodiment of the present application, directional indications (such as up, down, left, right, front, and rear … …) are referred to, and the directional indications are merely used to explain the relative positional relationship, movement conditions, and the like between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present application, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a 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 addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be regarded as not exist and not within the protection scope of the present application.

As shown in fig. 1 to 11, the embodiment of the present application discloses a simple radius-adjustable vertical cable winding device 10, wherein the cable winding device 10 includes a wire spool 100, a cable winding shaft 200, and a locking screw 230 (not shown in the drawings).

The wire spool 100 is provided with the scale groove 110, the scale groove 110 comprises a plurality of groove bodies 111 which are radially distributed from the center to the periphery and penetrate through the thickness direction of the wire spool 100, the groove bodies 111 are distributed in a strip shape, the scale groove 110 uniformly divides the wire spool 100 into a plurality of parts, the scale groove 110 further comprises scale marks 112, each scale mark 112 is positioned on one side of each groove body 111, size numbers 113 are marked beside each scale mark 112, the size numbers 113 correspond to the scale marks 112, each size number 113 is composed of a digital groove 730, the units of the size numbers 113 are millimeters (mm), the length between every two scale marks 112 is 20mm, one scale mark 112 is arranged between every two size numbers 113, the size numbers 113 start from 60mm to 260mm, the length of the whole groove body 111 is approximately 200mm, and the size numbers 113 beside the groove body 111 can intuitively enable a user to observe the inner diameter of a winding cable.

The cable winding shaft 200 is erected on the scale groove 110, the cable winding shaft 200 is in a long bar shape, a round cap 210 is arranged at the upper end of the cable winding shaft 200, the diameter of the cable winding shaft 200 is slightly larger than the width of the scale groove 110 so as to prevent the cable winding shaft 200 from falling from the scale groove 110, besides the technical scheme, the diameter of the cable winding shaft 200 can be not larger than the diameter of the scale groove 110, other assembly schemes can be adopted between the cable winding shaft 200 and the scale groove 110, each cable winding shaft 200 is arranged at the position marked with the same size number 113 on each scale groove 110, a plurality of cable winding shafts 200 are surrounded into a circular ring, the inner diameter of the circular ring is the cable winding inner diameter of the cable winding device 10, and a first threaded hole 220 is formed in the bottom of the cable winding shaft 200 and used for being assembled with the locking screw 230.

The locking screw 230 passes through the scale groove 110 from the bottom of the wire spool 100 and is matched with the threaded hole at the bottom of the cable winding shaft 200, so that the cable winding shaft 200 is vertically fixed on the wire spool 100, when the inner diameter of a cable needs to be changed, the locking screw 230 is firstly loosened from the cable winding shaft 200, the cable winding shaft 200 is adjusted to a proper position on the scale groove 110, and then the cable winding shaft 200 is re-fixed on the wire spool 100 by the locking screw 230, so that the change of the inner diameter of the cable winding can be completed.

The cable winding device 10 further comprises a bracket 300, a carrier plate 400, a connecting cylinder 500 and a cable winding motor 600.

In an embodiment of the present application, the support 300 may include four vertically disposed support columns 310 and eight horizontally disposed shaping columns 320, the side surfaces of the support columns 310 and the shaping columns 320 are respectively provided with a chute 330, so that the support columns 310 and the shaping columns 320 may be assembled with each other through the chute 330, the four vertically disposed support columns 310 enclose a rectangle, the support columns 310 are located at four corners of the rectangle, a foot cup 340 is disposed at the lower end of each support column 310, the foot cup 340 includes a support leg 341 and a support leg 342, the support leg 342 and the support leg 341 are fixedly assembled, the support leg 342 is cylindrical and the lower end of the support leg 342 is disposed at the central position of the support leg 341, the surface of the support leg 342 is provided with threads, corresponding assembly holes are disposed at the central position of the lower surface of the support column 310, the support leg 342 is embedded into the support column 310 through the threads and the screws on the surface of the support leg 342, and the position of the support column 310 is fixed by the screws, and the position of the adjustment screws on the support leg 342 can adjust the length of the support leg 342 to a proper height, thereby facilitating the operation of the user. In other embodiments, the structure and number of the holders 300 are not limited thereto.

Eight horizontally arranged shaping columns 320 are divided into four first groups of shaping columns 321 and four second groups of shaping columns 322, wherein the first groups of shaping columns 321 are horizontally arranged in the middle of the supporting column 310 and fixedly assembled with the supporting column 310, the first groups of shaping columns 321 are positioned on four sides of a rectangle surrounded by the supporting column 310, the second groups of shaping columns 322 are horizontally arranged at the upper end of the supporting column 310 and fixedly assembled with the supporting column 310, and the two groups of shaping columns 320 are used for jointly acting to keep the stability of the supporting column 310.

The bracket 300 further comprises a plurality of corner brackets 350, wherein the corner brackets 350 are arranged at the corners of the forming column 320 and the supporting column 310, which are connected with each other, so as to prevent the forming column 320 from sliding on the supporting column 310, thereby facilitating the maintenance of the stability of the whole bracket 300.

The carrier 400 is a rectangular plate, the area of the carrier 400 is approximately the same as the rectangular area surrounded by the support columns 310, the carrier 400 is arranged on the upper surface of the support 300, a first through hole 410 is arranged at the center of the carrier 400, four second through holes 420 are further arranged around the first through hole 410, the first through hole 410 and the second through hole 420 are all circular, and the diameter of the first through hole 410 is larger than that of the second through hole 420.

The connecting cylinder 500 is cylindrical, a circular third through hole 510 is arranged at the center of the connecting cylinder 500, the four third through holes 510 on the four connecting cylinders 500 correspond to the four second through holes 420 on the carrier plate 400, the diameters of the second through holes 420 and the third through holes 510 are the same, the upper end of the connecting cylinder 500 is close to the lower surface of the carrier plate 400, and the lower end of the connecting cylinder 500 is close to the upper surface of the cable winding motor 600.

The cable winding motor 600 is fixedly connected with the connecting cylinder 500, the output end of the cable winding motor 600 is in transmission connection with the wire spool 100, a rotary shaft 610 is arranged at the upper end of the cable winding motor 600, the rotary shaft 610 is cylindrical, a convex column 620 is arranged on the side surface of the rotary shaft 610, the convex column 620 is convenient for better transmission of the cable winding motor 600, and the cable winding motor 600 can drive other mechanisms to rotate through the rotary shaft 610. The four corners of the upper surface of the cable-winding motor 600 are provided with second threaded holes 630, and the third through holes 510 on the connecting cylinder 500 correspond to the second threaded holes 630, the connecting cylinder 500 is arranged between the motor and the carrying platform and used for determining the relative position between the cable-winding motor 600 and the carrying platform, and the cable-winding motor 600 can be fixed on the carrying board 400 by threaded assembly of the second through holes 420 on the carrying board 400 and the third through holes 510 on the connecting cylinder 500 and then the second threaded holes 630 on the motor.

The cable winding device 10 further includes a guide sleeve 700, the guide sleeve 700 passes through the first through hole 410, one end of the guide sleeve 700 is connected with the output end of the cable winding motor 600, the other end of the guide sleeve 700 is connected with the wire winding disc 100, a concave annular cavity 120 is arranged at the central position of the lower surface of the wire winding disc 100, the concave annular cavity 120 is in nested fit with the upper end of the guide sleeve 700 so as to ensure the connection stability of the wire winding disc 100 and the guide sleeve 700, the guide sleeve 700 is integrally cylindrical, the guide sleeve 700 includes a first fixing hole 710, the first fixing hole 710 is arranged on the upper surface of the guide sleeve 700, the first fixing holes 710 are distributed in a rectangular shape, a fourth through hole 130 corresponding to the first fixing hole 710 is arranged in the concave annular cavity 120 of the wire winding disc 100, and when the screw passes through the fourth through hole 130 and the first fixing hole 710 to be locked, the wire winding disc 100 and the guide sleeve 700 can be fixedly assembled together, and the cable winding motor 600 can be conveniently driven to rotate. The guide sleeve 700 further comprises a plurality of second fixing holes 720 arranged on the side face of the guide sleeve 700, the second fixing holes 720 are close to the lower end of the guide sleeve 700, a groove 730 is arranged in the center of the lower surface of the guide sleeve 700, the groove 730 can be embedded with the rotating shaft 610 of the cable winding motor 600, after the groove 730 and the rotating shaft 610 are embedded with each other, the guide sleeve 700 and the rotating shaft 610 are fixedly assembled through the second fixing holes 720 by using screws, and then the connection between the guide sleeve 700 and the output end of the cable winding motor 600 can be achieved.

The cable winding device 10 further comprises a wire buncher 800, the wire buncher 800 is arranged at one corner of the upper surface of the carrier plate 400, the wire buncher 800 comprises two first roll shafts 810 and one second roll shaft 820 which are vertically arranged at intervals, the first roll shafts 810 and the second roll shafts 820 enclose a channel for the regular optical cable, the first roll shafts 810 are perpendicular to the carrier plate 400 and are used for the regular optical cable to enter the wire winding disc 100, the second roll shafts 820 are parallel to the carrier plate 400 and are used for feeding the regular optical cable into the wire winding disc 100, the first roll shafts 810 comprise first shaft bodies 811 and first connecting blocks 812, the first connecting blocks 812 are arranged at the lower ends of the first shaft bodies 811, the first shaft bodies 811 and the first connecting blocks 812 are connected with each other, the first shaft bodies 811 and the first connecting blocks 812 can be fixedly assembled by adopting the scheme of the two, the first connecting blocks 812 are integrally formed into an L shape, a threaded through hole 813 and a limit through hole 814 are formed in the first connecting blocks 812, and the thread 813 and the limit through hole 814 are mutually limited by the linear through hole.

The wire harness 800 further comprises a base 830, the base 830 comprises two oppositely arranged base plates 831 and a bottom plate 832, a fifth through hole 833 is formed in the bottom plate 832, a sixth through hole 430 is formed in the position, corresponding to the fifth through hole 833, of the carrier 400, the base 830 is fixed to the carrier 400 through the fifth through hole 833 and the sixth through hole 430 by screws, and the second roller shaft 820 transversely penetrates through the base 830 and is rotatably assembled with the two base plates 831.

The wire harness 800 further includes a distance adjusting screw 840, the distance adjusting screw 840 is disposed parallel to the carrier plate 400 and transversely penetrates through the base plate 830, and is rotatably assembled with the two base plates 831, a circular adjusting cap 841 is disposed at one end of the distance adjusting screw 840 away from the base plate 830, so that the distance adjusting screw 840 can be manually rotated, two distance adjusting threads 842 (not shown in the figure) with opposite directions are disposed on the distance adjusting screw 840, the first roll shaft 810 is threaded and assembled through the threaded through hole 813 and the two distance adjusting threads 842 on the distance adjusting screw 840, when the first connecting block 812 on the first roll shaft 810 is disposed next to the base plate 832, the distance adjusting screw 840 is rotated at this time, due to the limiting effect of the base plate 832, the two first roll shafts 810 cannot rotate along with the distance adjusting screw 840, and can be reversely displaced along the distance adjusting screw 840, so that the first roll shafts 810 can be used for adjusting optical cables with different diameters.

The wire harness 800 further includes an auxiliary fixing rod, the auxiliary fixing rod is parallel to the distance adjusting screw 840, the auxiliary fixing rod penetrates through the limiting through hole 814 and is transversely assembled on the base plate 831, when the first roll shafts 810 are arranged in a suspended mode, the distance adjusting screw 840 is rotated, the auxiliary fixing rod plays a role in limiting the rotation of the first roll shafts 810 along with the distance adjusting screw 840, so that the two first roll shafts 810 can also perform reverse displacement along with the distance adjusting screw 840 to adjust the distance, and therefore the first roll shafts 810 are convenient for adjusting optical cables with different diameters, in sum, the first roll shafts 810 can be arranged next to the base plate 832, and the auxiliary fixing rod is not needed to be arranged at this time, and the scheme can save materials and simplify the structure of the wire harness 800; the first roller 810 can also be suspended, and an auxiliary fixing rod is required to be arranged at the moment, so that the friction force during distance adjustment can be reduced by adopting the scheme, and the distance adjustment is more labor-saving.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (10)

1. A cabling arrangement (10), characterized in that the cabling arrangement (10) comprises:

the wire spool (100), the wire spool (100) is provided with scale grooves (110), and the scale grooves (110) comprise a plurality of groove bodies (111) which are radially distributed from the center to the periphery and penetrate through the thickness direction of the wire spool (100);

the cable winding shaft (200) is vertically arranged on the scale groove (110), and a first threaded hole (220) is formed in the bottom of the cable winding shaft (200);

a locking screw (230) passing through the scale groove (110) from the bottom of the spool (100) and being engaged with the first screw hole (220);

wherein, the inner diameter of the cable is adjustable by adjusting the distribution of the cable winding shaft (200) on the scale groove (110).

2. The cabling arrangement (10) of claim 1, wherein the cabling arrangement (10) further comprises:

a bracket (300);

the carrier plate (400) is arranged on the bracket (300) and is provided with a first through hole (410) corresponding to the wire spool (100);

a connecting cylinder (500), one end of which is connected to the lower surface of the carrier plate (400);

and the cable winding motor (600) is fixedly connected with the other end of the connecting cylinder (500), and the output end of the cable winding motor (600) is in transmission connection with the wire spool (100).

3. The cable winding device (10) according to claim 2, wherein the cable winding device (10) further comprises a guide sleeve (700), the guide sleeve (700) passes through the first through hole (410), one end of the guide sleeve (700) is connected with the output end of the cable winding motor (600), and the other end of the guide sleeve (700) is connected with the wire spool (100).

4. A cable winding device (10) according to claim 3, wherein the lower surface of the spool (100) is provided with a concave annular cavity (120), the concave annular cavity (120) being in nesting engagement with the upper end of the guide sleeve (700).

5. The cable winding device (10) according to claim 4, wherein a plurality of first fixing holes (710) are formed at a top end of the guide sleeve (700), and a plurality of fourth through holes (130) are formed in the wire spool (100) corresponding to the concave annular cavity (120) so as to pass through the fourth through holes (130) through screws and be locked with the first fixing holes (710).

6. The cabling apparatus (10) of claim 5, wherein the cabling apparatus (10) further comprises a wire harness (800), the wire harness (800) being disposed on the carrier plate (400), the wire harness (800) comprising two vertically spaced first rollers (810) and a transversely disposed second roller (820), the first rollers (810) and the second rollers (820) enclosing a channel for routing the fiber optic cable.

7. The cabling apparatus (10) of claim 6, wherein the harness (800) further comprises a housing (830), the housing (830) comprising two oppositely disposed base plates (831), the second roller (820) extending transversely through the housing (830) and being rotatably mounted with the base plates (831).

8. The cable winding device (10) according to claim 6, wherein the first roller shaft (810) comprises a first shaft body (811) and a first connecting block (812), the first connecting block (812) is arranged at the lower end of the first shaft body (811), the first shaft body (811) and the first connecting block (812) are connected with each other, and a threaded through hole (813) is formed in the first connecting block (812).

9. The cable winding device (10) according to claim 8, wherein the wire harness device (800) further comprises a distance adjusting screw (840), the distance adjusting screw (840) transversely penetrates through the base (830) and is rotatably assembled with the base plate (831), two distance adjusting threads (842) with opposite directions are arranged on the distance adjusting screw (840), the first roll shaft (810) is in threaded assembly with the distance adjusting threads (842) through the threaded through holes (813), and when the first roll shaft (810) is arranged next to the base (830), the distance adjusting screw (840) is adjusted to enable the two first roll shafts (810) to be in reverse displacement along the distance adjusting screw (840) for distance adjustment.

10. The cable winding device (10) according to claim 9, wherein the wire harness device (800) further comprises an auxiliary fixing rod (850), the connecting block is provided with a limiting through hole (814), the auxiliary fixing rod (850) penetrates through the limiting through hole (814) and is transversely arranged on the base plate (831), when the first roll shaft (810) is arranged in a suspended mode, the auxiliary fixing rod (850) rotates the distance adjusting screw (840), the auxiliary fixing rod (850) plays a role in limiting the rotation of the first roll shaft (810), the two first roll shafts (810) can only reversely move along the distance adjusting screw (840), the first roll shaft (810) can also be arranged next to the bottom of the base body (830), and the auxiliary fixing rod (850) is not needed at this time.