CN115164675B

CN115164675B - Cable coil length measuring device

Info

Publication number: CN115164675B
Application number: CN202211086817.6A
Authority: CN
Inventors: 孔天文; 翁晓明; 黄剑斌; 陈志根; 赵木华; 吴剑雄; 莫墩; 黎家麟; 邓信鹏
Original assignee: Zhaoqing Power Supply Bureau of Guangdong Power Grid Co Ltd
Current assignee: Zhaoqing Power Supply Bureau of Guangdong Power Grid Co Ltd
Priority date: 2022-09-07
Filing date: 2022-09-07
Publication date: 2023-01-20
Anticipated expiration: 2042-09-07
Also published as: CN115164675A

Abstract

The application discloses cable coil length measuring device includes: the device comprises a device main body, a winding assembly, a transmission assembly, a wire clamping device and a calculation assembly; the wire winding assembly comprises: a winding reel, a transmission shaft and a winding motor; the transmission assembly includes: the first gear, the second gear, the third gear, the connecting rod and the connecting plate; the wire grip includes: two pinch rollers and a slide plate; the computing component includes: a processor and a first counter; the first counter is used for calculating the number of turns of the routing of the clamping wheel; the processor is used for calculating the length of the cable passing through the clamping wheel according to the number of turns of the routing rotation of the clamping wheel. The cable clamp can clamp the cable for the cable to run; the wire coiling assembly can be used for coiling the cable; the transmission assembly can synchronously drive the sliding plate to slide along the winding direction when the winding core drum rotates; the calculation subassembly can drive when the cable is walked the line and press from both sides the round number of turns of wheel pivoted and calculate the line length of walking of cable, compares and to improve work efficiency effectively in the mode of manual measurement cable length.

Description

Cable coil length measuring device

Technical Field

The application relates to the technical field of line length measurement, in particular to a cable coiling length measuring device.

Background

Cables are a general term for articles such as electric wires and cables, and are used for connecting devices, transmitting electric power, and the like. When the cable winder is used, cables are usually wound on the cable winder, so that space is saved and transportation is facilitated. The existing cable winding device does not have the length measuring function, so that the length of the cable needs to be measured manually by workers when the length of the cable needs to be measured, and the working efficiency of the mode is low.

Disclosure of Invention

In view of this, an object of the present application is to provide a cable winding length measuring device, which is used to solve the problem that the conventional cable winding device has low efficiency in measuring the cable length.

In order to achieve the above technical object, the present application provides a cable coil length measuring device, including: the device comprises a device main body, a winding assembly, a transmission assembly, a wire clamping device and a calculation assembly;

the line reeling assembly comprises: a winding reel, a transmission shaft and a winding motor;

the winding reel is rotatably arranged on the device main body;

the transmission shaft is rotatably arranged in the device main body and is synchronously and rotatably connected with the winding reel;

the winding motor is arranged in the device main body, is in transmission connection with the transmission shaft and is used for driving the transmission shaft to rotate;

the transmission assembly includes: the first gear, the second gear, the third gear, the connecting rod and the connecting plate;

the first gear is fixed on the transmission shaft;

the second gear is rotatably arranged in the device main body and is vertically meshed and connected with the first gear;

the third gear is rotatably arranged in the device main body and is meshed with the second gear;

a convex column is eccentrically arranged on the third gear;

the connecting plate is slidably arranged in the device main body along the axial direction of the winding reel;

one end of the connecting rod is rotatably connected with the convex column, and the other end of the connecting rod is rotatably connected with the connecting plate;

the wire gripper comprises: two pinch rollers and a slide plate;

the sliding plate is arranged on the device main body in a sliding manner along the horizontal direction and is fixedly connected with the connecting plate;

the two clamping wheels can be rotatably arranged on the sliding plate and are used for clamping a cable;

the computing component includes: a processor and a first counter;

the first counter is arranged on the sliding plate, is connected with the clamping wheel and is used for calculating the number of turns of the routing of the clamping wheel;

the processor is electrically connected with the first counter and used for calculating the length of the cable passing through the clamping wheel according to the number of turns of the routing rotation of the clamping wheel.

Further, the line reeling assembly further comprises: a wire pressing plate;

the wire pressing plate is arranged on the device main body in a sliding mode along the radial direction of the winding reel, and the wire pressing plate is in crimping connection with the cable on the winding reel.

Further, the computing component further comprises: the device comprises a first distance sensor, a second distance sensor and a second counter;

the first distance sensor is arranged on the clamping wheels and used for acquiring the clamping distance between the two clamping wheels;

the second distance sensor is arranged on the line pressing plate and used for acquiring the winding distance between the line pressing plate and the winding reel;

the second counter is arranged on the device main body, is connected with the winding reel and is used for acquiring the number of winding turns of the winding reel;

the processor is electrically connected with the first distance sensor and the second distance sensor and used for calculating the length of the cable wound or unwound by the winding reel according to the clamping distance, the winding distance and the number of turns of the winding.

Furthermore, the line pressing plate is connected with the device main body through a telescopic rod and a return spring.

Furthermore, in the two pinch rollers, a first pinch roller is fixed on the sliding plate, and a second pinch roller is arranged on the sliding plate in a sliding manner along the horizontal direction;

an elastic piece is arranged between the sliding plate and the clamping wheel.

Further, the third gear is a bevel gear;

the third gear is arranged on the device main body in a lifting manner.

Further, the transmission assembly further comprises: a lifting plate and an adjusting gear;

the device main body is provided with a regulating shaft which can horizontally rotate and can lift;

the lifting plate is rotatably connected with the adjusting shaft;

the third gear is rotatably arranged on the lifting plate;

a rack is arranged on the adjusting shaft along the axial direction;

the adjusting gear is rotatably arranged on the device main body and is meshed and connected with the rack of the adjusting shaft.

Furthermore, the position of the sliding plate corresponding to the first clamping wheel is provided with scale marks;

and the device main body is provided with scale marks corresponding to the positions of the adjusting gears.

Furthermore, the first gears comprise two gears which are respectively arranged on two sides of the second gear.

Further, the first gear and the second gear are both bevel gears.

It can be seen from above technical scheme that this application provides a cable coil length measuring device, includes: the device comprises a device main body, a winding assembly, a transmission assembly, a wire clamping device and a calculation assembly; the wire coiling assembly comprises: a winding reel, a transmission shaft and a winding motor; the transmission assembly includes: the first gear, the second gear, the third gear, the connecting rod and the connecting plate; the wire grip includes: two pinch rollers and a slide plate; the computing component includes: a processor and a first counter; the first counter is used for calculating the number of turns of the routing of the clamping wheel; the processor is used for calculating the length of the cable passing through the clamping wheel according to the number of turns of the routing rotation of the clamping wheel.

The cable can be clamped through the cable clamp for cable routing; the wire coiling assembly can be used for coiling the cable; the transmission assembly can synchronously drive the sliding plate to slide along the winding direction when the winding core drum rotates; the calculation subassembly can drive when the cable is walked the line and press from both sides the round number of turns pivoted and calculate the line length of walking of cable, realizes the automatic measure to cable length, compares in the mode of manual measurement cable length and can effectively improve work efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the description below are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive labor.

Fig. 1 is a schematic external structural view of a cable winding length measuring device according to an embodiment of the present disclosure;

fig. 2 is a perspective view of a device for removing a side plate of a main body of a cable winding length measuring device provided in an embodiment of the present application, in which a connecting plate is in a transparent line state;

fig. 3 is a front view of a wire holder in a cable winding length measuring device according to an embodiment of the present disclosure;

fig. 4 is a top view of the cable winding length measuring device provided in the embodiment of the present application after removing a side plate of the device body;

fig. 5 is a perspective view of a partial structure of a cable winding length measuring device according to an embodiment of the present application.

Detailed Description

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

In the description of the embodiments of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the embodiments of the present application and simplifying the description, but do not indicate or imply that the referred devices or elements must have specific orientations, be configured in specific orientations, and operate, and thus, should not be construed as limiting the embodiments of the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present application, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected" and "connected" should be interpreted broadly, and may be, for example, a fixed connection, an exchangeable connection, an integrated connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection through an intermediate medium, and a communication between two elements. Specific meanings of the above terms in the embodiments of the present application can be understood as specific cases by those of ordinary skill in the art.

Referring to fig. 1 and fig. 2, a cable winding length measuring device 1 provided in an embodiment of the present application is characterized by including: the device comprises a device body 10, a winding assembly 20, a transmission assembly 30, a wire clamping device 40 and a calculation assembly 50.

The device body 10 is used as a bearing and supporting component for other components, and may be formed by assembling a bottom plate, a plurality of side plates, and a top plate, and a plurality of supporting columns are disposed between the top plate and the bottom plate. The inside of the device body 10 may form a mounting cavity. The bottom of bottom plate can be provided with the universal wheel, the holistic removal of being convenient for, correspondingly, can set up the brake block on the universal wheel.

A line reeling assembly 20, comprising: a winding reel 21, a transmission shaft 22 and a winding motor 23; the spool 21 is provided for winding the cable and is rotatably provided on the apparatus main body 10. Wherein, the device body 10 may be provided with a support base 12, and the winding reel 21 may be rotatably provided on the support base 12. The transmission shaft 22 is rotatably disposed in the device body 10 and is synchronously rotatably connected with the winding reel 21; the winding motor 23 is disposed in the device body 10, and is in transmission connection with the transmission shaft 22 for driving the transmission shaft 22 to rotate.

Wherein, the transmission shaft 22 and the winding motor 23 are disposed in the installation cavity, and the winding reel 21 is disposed at the top of the device body 10. The transmission shaft 22 can be fixedly connected with a gear and is meshed with an output shaft of the winding motor 23 through the gear; meanwhile, the transmission shaft 22 and the winding reel 21 can be connected through a conveyor belt, so that synchronous rotation of the transmission shaft and the winding reel is realized.

The transmission assembly 30 includes: a first gear 31, a second gear 32, a third gear 33, a connecting rod 34 and a connecting plate 35. The first gear 31 is fixed on the transmission shaft 22; the second gear 32 is rotatably arranged in the device body 10 and is vertically meshed with the first gear 31; the third gear 33 is rotatably disposed in the apparatus main body 10 and is meshed with the second gear 32; a convex column 331 is eccentrically arranged on the third gear 33; the connection plate 35 is slidably provided in the apparatus main body 10 in the horizontal direction; one end of the connecting rod 34 is rotatably connected to the protruding column 331, and the other end is rotatably connected to the connecting plate 35.

Specifically, the spool 21 and the transmission shaft 22 may be both arranged in the axial direction in the horizontal direction. The first gear 31 is axially identical to the transmission shaft 22. The axial directions of the second gear 32 and the first gear 31 are perpendicular to each other, that is, the axial direction of the second gear 32 is a vertical direction. The third gear 33 and the second gear 32 have the same axial direction and are both in the vertical direction. The convex column 331 is eccentrically disposed, and specifically, may be disposed at a circumferential outer edge position of the third gear 33. Through the matching of the convex column 331, the connecting rod 34 and the connecting plate 35, when the third gear 33 rotates, one end of the connecting rod 34 follows the convex column 331 to make a circular motion, and the other end pushes the connecting plate 35 to slide along the axial direction of the winding reel 21.

Referring to fig. 1 to 3, the wire gripper 40 includes: two pinch rollers 41 and a slide plate 42; the slide plate 42 is slidably disposed on the apparatus main body 10 in the horizontal direction and is fixedly connected to the connection plate 35; both clamping wheels 41 can be rotatably arranged on the sliding plate 42 for clamping the cable.

Specifically, after the cable is clamped by the two clamping wheels 41, when the cable is wound or unwound by the spool 21, the rotation of the spool 21 is converted into the linear motion of the connecting plate 35 through the transmission assembly 30, and the sliding plate 42 is driven by the connecting plate 35 to slide linearly, so that the sliding plate 42 can slide along the axial direction of the spool 21 during routing. In practical application, by calculating the transmission ratio between the winding reel 21 and the transmission shaft 22 and combining the transmission ratio calculation of the first gear 31, the second gear 32 and the third gear 33, the sliding speed of the clamping wheel 41 can be adapted to the winding speed of the winding reel 21, so that the cable can be uniformly wound on the winding reel 21.

The computing component 50 includes: the processor 51 and the first counter 52; the first counter 52 is arranged on the sliding plate 42, connected with the pinch wheel 41, and used for counting the number of turns of the routing of the pinch wheel 41; the processor 51 is electrically connected to the first counter 52 for calculating the length of the cable passing through the pinch wheel 41 according to the number of turns of the routing wire of the pinch wheel 41.

The processor 51 may be disposed in the installation cavity of the device main body 10, or may be disposed on another terminal used by the worker, without limitation. Accordingly, the device body 10 may be provided with a display screen for displaying the real-time calculation result of the processor 51, which is convenient for the staff to view.

Specifically, the diameter of the contact position between the clamping wheel 41 and the cable is stored in the processor 51, and the cable routing length can be calculated by obtaining the number of rotation turns of the clamping wheel 41 caused by cable routing in the cable routing process, that is, the number of rotation turns of the cable, so that a worker can obtain the cable outgoing or incoming length of the cable in real time when winding or unwinding the cable.

In a more specific embodiment, referring to fig. 1, the winding assembly 20 further includes: a tension plate 24; the tension plate 24 is slidably provided on the device body 10 in the radial direction of the spool 21, and the tension plate 24 presses the wire on the spool 21. The cable winding leveling degree in the winding process can be improved through the wire pressing plate 24.

The wire pressing plate 24 is connected with the device body 10 through the telescopic rod 241 and the return spring 242. So that the tension plate 24 abuts against the wire on the spool 21 by the urging force of the return spring 242. Meanwhile, the telescopic rod 241 can support and guide the wire pressing plate 24 and meanwhile helps the whole end face of the wire pressing plate 24 to be flush when sliding and not to be partially inclined.

In a further refined embodiment, the calculation component 50 further comprises: a first distance sensor 53, a second distance sensor 54, and a second counter (not shown); the first distance sensor 53 is arranged on the pinch wheels 41 and is used for acquiring the clamping distance between the two pinch wheels 41; the second distance sensor 54 is arranged on the tension disc 24 and used for acquiring the winding distance between the tension disc 24 and the winding reel 21; the second counter is arranged on the device main body 10, is connected with the winding reel 21 and is used for acquiring the winding rotation number of the winding reel 21; the processor 51 is electrically connected to both the first distance sensor 53 and the second distance sensor 54 for calculating the length of the cable wound up or unwound by the rotation of the spool 21 according to the clamping distance, the winding distance and the number of turns of the winding.

Specifically, the first distance sensor 53 may include two first distance sensors respectively disposed on the pinch wheels 41 for acquiring a distance between the two pinch wheels 41 so that the processor may calculate a radius of the cable according to the pinch distance. The number of the second distance sensors 54 may be two, and the second distance sensors are respectively disposed on the winding reel 21 and the tension plate 24, so as to obtain the distance between the tension plate 24 and the winding reel 21. The diameter of the winding reel 21 is a fixed value, so that the processor can obtain the winding diameter of the cable at the moment after subtracting the diameter of the winding reel 21 according to the winding distance; and the processor can calculate the outgoing length or the incoming length of the winding reel 21 in the rotating process according to the radius of the cable and the number of winding rotation turns.

By comparing the calculation results of the first distance sensor 53, the second distance sensor 54 and the second counter with the calculation result of the first counter 52, when the error between the first distance sensor and the second distance sensor exceeds a preset degree, the possibility that the first counter 52 is in fault, the clamping wheel 41 is not tightly clamped, the clamping wheel is not easy to rotate and the like is indicated, and a worker is reminded to carry out maintenance.

In a further modified embodiment, referring to fig. 3, of the two pinch rollers 41, a first pinch roller 41 is fixed on the sliding plate 42, and a second pinch roller 41 is slidably disposed on the sliding plate 42 along a horizontal direction; an elastic member 43 is provided between the slide plate and the pinch roller 41.

Specifically, one of the clamping wheels 41 is slidably arranged to adapt to cables with different wire diameters. Correspondingly, the sliding plate 42 may be provided with a sliding slot 421 for the first pinch roller 41 to slide. The elastic member 43 is disposed in the sliding slot 421, one end of the elastic member is connected to a slot wall of the sliding slot 421, and the other end of the elastic member is connected to the first pinch roller 41.

Further, the third gear 33 is a bevel gear; the third gear 33 is disposed on the device body 10 in a liftable manner.

Specifically, when the wire diameter of the cable changes, the sliding speed of the clamping wheel 41 affects the uniformity of the cable wound on the winding reel 21, for example, the cable winding of the clamping wheel 41 on the winding reel 21 is sparse and uneven at the original sliding speed due to the decrease of the wire diameter of the cable, which affects the calculation results of the first distance sensor 53, the second distance sensor 54 and the second counter.

In this embodiment, in order to maintain different wire diameters of the cables, the sliding speed of the clamping wheel 41 can be changed along with the change of the wire diameter to maintain uniform wire winding of the winding reel 21, and the third gear 33 is set as a bevel gear. Wherein the third gear 33 may be a bevel gear with a cross-sectional area that tapers from top to bottom. Meanwhile, the third gear 33 can be arranged in a lifting manner, so that the height of the third gear 33 can be adjusted when the wire diameter is changed, and the transmission ratio between the third gear 33 and the second gear 32 can be further adjusted, so that the sliding speed of the clamping wheel 41 can be adjusted. The specific transmission ratio and the calculation of the change of the line diameter can be adjusted according to the actual situation, and are not described herein.

In an embodiment, referring to fig. 1, fig. 4 and fig. 5, the transmission assembly 30 further includes: the lifting plate 36 and an adjusting gear (not shown); the device body 10 is provided with a liftable adjusting shaft 11; the lifting plate 36 is rotatably connected with the adjusting shaft 11; the third gear 33 is rotatably arranged on the lifting plate 36; a rack is arranged on the adjusting shaft 11 along the axial direction; the adjusting gear is rotatably disposed on the device main body 10 and is engaged with the rack of the adjusting shaft 11.

In particular, the adjustment shaft 11 may be arranged on a telescopic support bar. The adjusting gear can drive the adjusting shaft 11 to lift, so that the lifting plate 36 can lift. The third gear 33 is axially fixedly connected with the lifting plate 36 while being rotatably connected with the lifting plate 36, so that when the lifting plate 36 is lifted, the third gear 33 can lift along with the lifting plate 36, and the adjustment of the transmission ratio is realized.

Meanwhile, the lifting plate 36 can rotate around the adjusting shaft 11, so as to drive the third gear 33 to approach or separate from the second gear 32, and avoid interference with the second gear 32 when the third gear 33 is adjusted. Accordingly, the lifting plate 36 may be connected to the device body through a tension spring (not shown), so as to provide the lifting plate 36 with an elastic force approaching to the second gear 32, so that after the lifting height is adjusted, the lifting plate 36 may drive the third gear 33 to engage with the second gear 32.

It should be noted that, in order to avoid interference between the rotation of the lifting plate 36 and the connecting rod 34, a sandwich plate 332 may be further disposed on the third gear 33. The sandwich plate 332 is fixedly connected with the third gear 33, and forms an empty layer with the third gear 33 for the installation of the lifting plate 36. The protruding column 331 and the connecting rod 34 can be disposed on the interlayer plate 332.

Furthermore, in order to facilitate adjustment by a worker, scale marks are arranged on the sliding plate 42 corresponding to the first pinch roller 41; the position of the device main body 10 corresponding to the adjusting gear is provided with a scale mark, so that a worker can adjust the height of the adjusting shaft 11 according to the sliding distance of the first clamping wheel 41 along the scale mark, and the sliding speed of the sliding plate 42 can be accurately controlled.

Meanwhile, in order to improve the stability of the transmission, the first gear 31 and the second gear 32 may be both bevel gears, and the first gear 31 may include two gears and be disposed on two sides of the second gear 32, respectively.

Although the present invention has been described in detail with reference to the examples, it will be apparent to those skilled in the art that modifications, equivalents, improvements and the like can be made on the technical solutions described in the foregoing examples or on partial technical features of the technical solutions.

Claims

1. A cable coil length measuring device, comprising: the device comprises a device body (10), a winding assembly (20), a transmission assembly (30), a wire clamping device (40) and a calculation assembly (50);

the line reeling assembly (20) comprises: a winding reel (21), a transmission shaft (22), a winding motor (23) and a wire pressing plate (24);

the winding reel (21) is rotatably arranged on the device main body (10);

the transmission shaft (22) is rotatably arranged in the device main body (10) and is synchronously and rotatably connected with the winding reel (21);

the winding motor (23) is arranged in the device main body (10), is in transmission connection with the transmission shaft (22) and is used for driving the transmission shaft (22) to rotate;

the wire pressing plate (24) is slidably arranged on the device main body (10) along the radial direction of the winding reel (21), and the wire pressing plate (24) presses and connects the wire on the winding reel (21);

the transmission assembly (30) comprises: a first gear (31), a second gear (32), a third gear (33), a connecting rod (34), a connecting plate (35), a lifting plate (36) and an adjusting gear;

the first gear (31) is fixed on the transmission shaft (22);

the second gear (32) is rotatably arranged in the device main body (10) and is vertically meshed with the first gear (31);

the third gear (33) is rotatably arranged in the device main body (10) and is meshed with the second gear (32);

a convex column (331) is eccentrically arranged on the third gear (33);

the connecting plate (35) is slidably provided in the apparatus main body (10) in the axial direction of the spool;

one end of the connecting rod (34) is rotatably connected with the convex column (331), and the other end of the connecting rod is rotatably connected with the connecting plate (35);

the third gear (33) is a bevel gear;

the third gear (33) is arranged on the device main body (10) in a lifting manner;

the device main body (10) is provided with a liftable adjusting shaft (11);

one end of the lifting plate (36) is rotatably connected with the adjusting shaft (11);

the third gear (33) is rotatably arranged at the other end of the lifting plate (36);

a rack is arranged on the adjusting shaft (11) along the axial direction;

the adjusting gear is rotatably arranged on the device main body (10) and is meshed and connected with the rack of the adjusting shaft (11);

the wire gripper (40) comprises: two pinch rollers (41) and a slide plate (42);

the sliding plate (42) is slidably arranged on the device main body (10) and is fixedly connected with the connecting plate (35);

the two clamping wheels (41) can be rotatably arranged on the sliding plate (42) and are used for clamping cables;

of the two clamping wheels (41), the first clamping wheel (41) is fixed on the sliding plate (42), and the second clamping wheel (41) is arranged on the sliding plate (42) in a sliding manner along the horizontal direction;

an elastic piece (43) is arranged between the sliding plate (42) and the clamping wheel (41);

the computing component (50) comprises: a processor (51), a first counter (52), a first distance sensor (53), a second distance sensor (54), and a second counter;

the first counter (52) is arranged on the sliding plate (42), is connected with the clamping wheel (41) and is used for counting the number of turns of the routing rotation of the clamping wheel (41);

the first distance sensor (53) is arranged on the pinch wheels (41) and is used for acquiring the clamping distance between the two pinch wheels (41);

the second distance sensor (54) is arranged on the line pressing plate (24) and used for acquiring the winding distance between the line pressing plate (24) and the winding reel (21);

the second counter is arranged on the device main body (10), is connected with the winding reel (21) and is used for acquiring the winding rotation number of the winding reel (21);

the processor (51) is electrically connected with the first distance sensor (53) and the second distance sensor (54) and is used for calculating the length of the cable wound or unwound by the rotation of the winding reel (21) according to the clamping distance, the winding distance and the number of turns of winding.

2. A cable reeling length measuring device according to claim 1, wherein the tension plate (24) is connected to the device body (10) by a telescopic rod (241) and a return spring (242).

3. The cable reeling length measuring device according to claim 1, wherein the slide plate (42) is provided with a scale mark corresponding to a position of the first pinch roller (41);

and scale marks are arranged on the device main body (10) corresponding to the position of the adjusting gear.

4. The cable take-up line length measuring device according to claim 1, wherein the first gear (31) includes two gears and is disposed on both sides of the second gear (32), respectively.

5. A cable reel length measuring device according to claim 1, wherein the first gear (31) and the second gear (32) are bevel gears.