CN216444797U - High-dimensional-precision copper-silver alloy wire take-up device - Google Patents

Abstract

The utility model relates to the field of alloy wire production equipment, in particular to a high-dimensional-precision copper-silver alloy wire take-up device which comprises a bottom plate, wherein a stand column is arranged on the bottom plate, a rotating shaft extending along the front-back direction is rotatably arranged on the stand column, a rotating mechanism connected with the rotating shaft is arranged at the rear end of the stand column, a cross beam is radially arranged at the front end of the rotating shaft, installation mechanisms are respectively arranged at the outer ends of the cross beams, each installation mechanism comprises a support shaft which is fixed on the cross beam and extends along the front-back direction, a plurality of bearings are respectively sleeved on the support shafts, an installation cylinder is sleeved on the outer side of each bearing, a driving mechanism connected with the installation cylinder is arranged on each support shaft, a flanging is respectively arranged at the rear end of the installation cylinder, a limiting bolt parallel to the installation cylinder is in threaded connection with each flanging, and a limiting box is arranged at the front end inside the installation cylinder.

Description

High-dimensional-precision copper-silver alloy wire take-up device

Technical Field

The utility model relates to the field of alloy wire production equipment, in particular to a high-dimensional-precision copper-silver alloy wire take-up device.

Background

The silver-copper alloy is one of the most used copper alloys for electric wire and cable conductors, the copper-silver alloy wire needs to be wound after production is completed, a winding machine is used for winding in a common mode, when a winding roller is wound, the winding machine needs to be shut down, an empty winding roller needs to be replaced, the series of work is completed manually, efficiency is low, delay time is long, and winding efficiency is affected, so that the development of the high-size-precision copper-silver alloy wire winding device with short shutdown time and high efficiency is particularly necessary.

Disclosure of Invention

The utility model aims to provide a high-dimensional-precision copper-silver alloy wire take-up device which has the advantages of short downtime and high efficiency.

The technical scheme is as follows:

a high-dimensional-precision copper-silver alloy wire take-up device comprises a bottom plate, wherein a stand column is arranged on the bottom plate, a rotating shaft extending along the front-back direction is arranged on the stand column in a rotating mode, a rotating mechanism connected with the rotating shaft is arranged at the rear end of the stand column, a cross beam is arranged at the front end of the rotating shaft in the radial direction, an installing mechanism is arranged at the outer end of the cross beam, the installing mechanism comprises a supporting shaft fixed on the cross beam and extending along the front-back direction, a plurality of bearings are sleeved on the supporting shaft, an installing cylinder is sleeved on the outer side of each bearing, a driving mechanism connected with the installing cylinder is arranged on each supporting shaft, a flanging is arranged at the rear end of each installing cylinder, a limiting bolt parallel to the installing cylinder is connected onto each flanging in a threaded mode, a limiting box is arranged at the front end inside each installing cylinder, a limiting shaft extending along the front-back direction is arranged on each limiting box in a rotating mode, a second gear is arranged at the rear end of each limiting shaft, limiting pins extending from two ends of the limiting boxes to the outer sides of the corresponding limiting box are arranged in a sliding mode, and racks meshed with the second gear are arranged on the limit pins in the limit boxes.

Preferably, the rotating mechanism comprises an electric motor and a speed reducer connected with the electric motor.

Preferably, the driving mechanism comprises a motor arranged at the upper end of the supporting shaft, an inner gear ring is coaxially arranged at the rear end in the mounting cylinder, and the motor is provided with a first gear meshed with the inner gear ring.

Preferably, the bearings are cylindrical roller bearings, and three bearings are sleeved on each supporting shaft.

Preferably, the bottom plate is provided with a plurality of vertically arranged through holes.

Preferably, the front end of the flanging is provided with a limiting ring in a sliding manner, and an extension spring is arranged between the rear end of the limiting ring and the flanging.

Preferably, the left side of the bottom plate is provided with a supporting column, the supporting column is provided with a telescopic mechanism parallel to the mounting cylinder, and the front end of the telescopic mechanism is provided with a guide ring.

Preferably, the telescopic mechanism is an electric push rod.

Compared with the prior art, the beneficial effects are that:

1. the winding device is provided with two independent mounting cylinders, each mounting cylinder can be provided with a winding roller, and the two winding rollers can be used alternately, so that the downtime can be reduced, and the winding efficiency can be improved.

2. The telescopic mechanism controls the guide ring to slide back and forth so as to guide the alloy wire to be uniformly wound on the winding roller.

Drawings

FIG. 1 is a schematic structural view of the right front side of a high dimensional accuracy copper-silver alloy wire take-up device of the present invention,

figure 2 is a schematic view of the structure at a in figure 1,

FIG. 3 is a schematic structural view of the left rear side of a high dimensional accuracy copper-silver alloy wire take-up device of the present invention,

FIG. 4 is a schematic structural diagram of a limiting box of the high-dimensional-precision copper-silver alloy wire take-up device,

in the figure: 1. the device comprises a bottom plate, 2, a stand column, 3, a rotating shaft, 4, a rotating mechanism, 5, a cross beam, 6, a supporting shaft, 7, an installation cylinder, 8, a motor, 9, a flanging, 10, a limiting bolt, 11, a limiting ring, 12, an extension spring, 13, a limiting box, 14, a limiting shaft, 15, a second gear, 16, a limiting pin, 17, a rack, 18, a supporting column, 19, a telescopic mechanism, 20 and a guide ring.

Detailed Description

The utility model will be further described with reference to specific embodiments, as shown in fig. 1 to 4: a high-dimensional-precision copper-silver alloy wire take-up device comprises a bottom plate 1, wherein a plurality of through holes which are vertically arranged are formed in the bottom plate 1, the bottom plate 1 is convenient to fix the bottom plate 1 by bolts, an upright post 2 is arranged on the bottom plate 1, a rotating shaft 3 which extends along the front-back direction is rotatably arranged on the upright post 2, a rotating mechanism 4 connected with the rotating shaft 3 is arranged at the rear end of the upright post 2, the rotating mechanism 4 comprises a motor 8 and a speed reducer connected with the motor 8, the rotating mechanism 4 drives the rotating shaft 3 to rotate,

the front end of the rotating shaft 3 is provided with a crossbeam 5 along the radial direction, the outer end of the crossbeam 5 is provided with an installation mechanism, the installation mechanism comprises a support shaft 6 which is fixed on the crossbeam 5 and extends along the front-back direction, the support shaft 6 is sleeved with a plurality of bearings, the bearings are cylindrical roller bearings, each support shaft 6 is sleeved with three bearings, the cylindrical roller bearings can bear larger axial force, the outer sides of the bearings are sleeved with an installation cylinder 7, the support shaft 6 is provided with a driving mechanism connected with the installation cylinder 7, the driving mechanism comprises a motor 8 which is arranged at the upper end of the support shaft 6, the rear end inside the installation cylinder 7 is coaxially provided with an inner gear ring, the motor 8 is provided with a first gear which is meshed with the inner gear ring, the motor 8 drives the first gear ring to rotate so as to drive the inner gear ring to rotate, and drive the installation cylinder 7 to rotate,

the rear end of the mounting cylinder 7 is provided with a flange 9, the flange 9 is in threaded connection with a limit bolt 10 parallel to the mounting cylinder 7, the front end of the flange 9 is provided with a limit ring 11 in a sliding manner, an extension spring 12 is arranged between the rear end of the limit ring 11 and the flange 9, the limit bolt 10 is rotated so as to adjust the interval between the flange 9 and the limit ring 11,

a limiting box 13 is arranged at the front end inside the mounting cylinder 7, a limiting shaft 14 extending in the front-back direction is rotatably arranged on the limiting box 13, a second gear 15 is arranged at the rear end of the limiting shaft 14, limiting pins 16 extending from two ends of the limiting box 13 to the outer side of the mounting cylinder 7 are slidably arranged on two sides of the limiting shaft 14 respectively, racks 17 meshed with the second gear 15 are arranged on the limiting pins 16 inside the limiting box 13, and the limiting shaft 14 is rotated to enable the second gear 15 to be meshed with the two racks 17 so as to control the two limiting pins 16 to extend out of the mounting cylinder 7 or retract back into the mounting cylinder 7, so that the winding roller sleeved on the mounting cylinder 7 is limited;

the left side of the bottom plate 1 is provided with a supporting column 18, a telescopic mechanism 19 parallel to the mounting cylinder 7 is arranged on the supporting column 18, the front end of the telescopic mechanism 19 is provided with a guide ring 20, the telescopic mechanism 19 controls the guide ring 20 to slide back and forth so as to guide the alloy wire to be uniformly wound on the winding roller, and the telescopic mechanism 19 is an electric push rod.

The specific working process is as follows: controlling the rotating mechanism 4 to enable the beam 5 to be in a horizontal state, rotating the limiting shaft 14 to enable the second gear 15 to be meshed with the two racks 17 to control the two limiting pins 16 to extend out of the mounting cylinder 7 and retract back into the mounting cylinder 7, sleeving the winding roller on the mounting cylinder 7 close to the supporting column 18, rotating the limiting shaft 14 to enable the second gear 15 to be meshed with the two racks 17 to control the two limiting pins 16 to extend out of the mounting cylinder 7 and extend out of the mounting cylinder 7, enabling the front end of the winding roller to be tightly attached to the limiting pins 16, simultaneously rotating the limiting bolt 10 to enable the limiting ring 11 to be pressed on the winding roller, winding an alloy wire on the winding roller through the guide ring 20, starting a corresponding driving mechanism, enabling the mounting cylinder 7 to drive the winding roller to rotate to further wind the alloy wire on the winding roller, when the winding roller is fast wound fully, mounting an empty winding roller on another mounting cylinder 7 in the same mode, stopping when the winding roller is fully wound, an operator cuts off the alloy wire, the rotating mechanism 4 drives the beam 5 to rotate 180 degrees to replace the two mounting cylinders 7, and the winding roller fully wound with the alloy wire is taken down, so that the machine has short stop time and high efficiency.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention is not limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are within the protection scope of the present invention.

Claims (8)

1. The utility model provides a high dimensional accuracy copper silver alloy wire take-up which characterized in that: the gear rack mounting device comprises a base plate, a stand column is arranged on the base plate, the stand column is rotatably provided with a rotating shaft extending along the front-back direction, the rear end of the stand column is provided with a rotating mechanism connected with the rotating shaft, the front end of the rotating shaft is provided with a crossbeam along the radial direction, the outer end of the crossbeam is provided with an installing mechanism, the installing mechanism comprises a supporting shaft fixed on the crossbeam and extending along the front-back direction, a plurality of bearings are sleeved on the supporting shaft, an installing cylinder is sleeved on the outer side of each bearing, a driving mechanism connected with the installing cylinder is arranged on the supporting shaft, the rear end of the installing cylinder is provided with a flange, a limiting bolt parallel to the installing cylinder is connected onto the flange in a threaded mode, the front end inside of the installing cylinder is provided with a limiting box, the limiting box is rotatably provided with a limiting shaft extending along the front-back direction, the rear end of the limiting shaft is provided with a second gear, two sides of the limiting shaft are provided with limiting pins extending from two ends of the limiting box to the outer side of the installing cylinder respectively in a sliding mode, and racks meshed with the second gear are arranged on the limiting pins inside of the limiting box.

2. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the rotating mechanism comprises a motor and a speed reducer connected with the motor.

3. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the driving mechanism comprises a motor arranged at the upper end of the supporting shaft, an inner gear ring is coaxially arranged at the rear end in the mounting cylinder, and the motor is provided with a first gear meshed with the inner gear ring.

4. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the bearing be cylindrical roller bearing and every back shaft on the cover be equipped with three bearing.

5. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the bottom plate is provided with a plurality of vertically arranged through holes.

6. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the front end of the flanging is provided with a limiting ring in a sliding manner, and an extension spring is arranged between the rear end of the limiting ring and the flanging.

7. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 1, wherein: the bottom plate left side be provided with the support column, be provided with the telescopic machanism parallel with the installation section of thick bamboo on the support column, the telescopic machanism front end is provided with the guide ring.

8. The high dimensional accuracy copper-silver alloy wire take-up device as claimed in claim 7, wherein: the telescopic mechanism is an electric push rod.

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