CN219342686U - Winding equipment for production of armor-covered push-pull rope core - Google Patents

Abstract

The utility model relates to winding equipment for producing a covered armor push-pull rope core, which comprises a winding rack, wherein a rotary cylinder body and a folding line pressing die are sequentially arranged on the winding rack, and two flat wire paying-off assemblies symmetrically distributed along the axis of the rotary cylinder body are arranged in the rotary cylinder body; the flat wire paying-off assembly comprises a rotating shaft, the rotating shaft and the rotating cylinder body are coaxially arranged, a wire core in the rotating cylinder body is located outside the spool, after flat wires on the spool are consumed, the spool can be directly detached, a new spool for winding the flat wires is installed to continue conveying the flat wires, the wire core can be prevented from being sheared, the flat wires are wound on the spool again to carry out flat wire feeding, and therefore working efficiency can be improved.

Description

Winding equipment for production of armor-covered push-pull rope core

Technical Field

The utility model relates to winding equipment for producing a covered armor push-pull rope core, and belongs to the technical field of production of covered armor push-pull rope cores.

Background

In recent years, the armor push-pull cable core is more and more widely applied to automobile push-pull cables than the conventional steel wire twisted push-pull cable core. The high-strength steel has the advantages of good flexibility, high roundness, multiplied service life and the like.

The utility model patent with the application number of CN201921636155.9 discloses a sheath tube production device, which comprises a frame, a main shaft support is arranged on the frame, a hollow main shaft is arranged on the main shaft support in a penetrating manner, the main shaft is connected with a servo motor through a first transmission mechanism, the main shaft is connected with a wire feeding mechanism through a gear mechanism, the hollow main shaft is connected with a variable frequency motor through a second transmission mechanism, a machine head is arranged at the rear end of the main shaft, a semicircular mould device is arranged at the rear end of the machine head, a wire guide mechanism is arranged at the rear of the semicircular mould device, and a damping disc support is arranged at the bottom of the wire guide mechanism. The sheath tube production device can solve the problems that the existing sheath tube is poor in flexibility and large in inner and outer diameter size fluctuation, and cannot meet high load efficiency. However, in the prior art, when the flat wire on the spool is consumed, the flat wire can be fed only by replacing the spool with the flat wire or winding the flat wire on the spool, and when the spool is replaced, the twisted strands sequentially pass through the spindle, the machine head, the semicircular die device and the wire guide mechanism from front to back and finally go out from the rear end of the wire guide spindle, so that the spool cannot be directly taken down, the spool can be replaced only after the twisted strands are completely discharged from the wire guide spindle or cut off, and a large amount of time is required to be consumed by both flat wire feeding modes, thereby influencing the production efficiency.

Therefore, winding equipment for producing the armor push-pull rope core is needed, and the production efficiency is improved.

Disclosure of Invention

The utility model aims to solve the technical problems that: in order to overcome the defects of the prior art, the winding equipment for producing the covered armor push-pull rope core is provided for improving the production efficiency.

The utility model solves the problems by adopting the following technical scheme: the winding equipment for the production of the armor push-pull cable core comprises a winding rack, wherein a rotary cylinder body and a folding line pressing die are sequentially arranged on the winding rack, and two flat wire paying-off assemblies symmetrically distributed along the axis of the rotary cylinder body are arranged in the rotary cylinder body;

the flat wire paying-off assembly comprises a rotating shaft, the rotating shaft and a rotating cylinder body are coaxially arranged, a rotating disc and a connecting disc are arranged on the rotating shaft through bearing seats, an I-shaped wheel is coaxially arranged at one end of the rotating shaft, the rotating disc and the connecting disc are fixedly connected with the rotating cylinder body, a flat wire outlet is formed in the rotating cylinder body, a plurality of through holes which are circumferentially distributed are formed in the connecting disc, and round holes are formed in the rotating disc.

Preferably, a blocking rod is arranged on the rotating disc.

Preferably, a roller is arranged at the flat wire outlet.

Preferably, dampers are mounted on both rotation shafts.

Preferably, in the two flat wire pay-off assemblies, the two spools are located between the two dampers.

Preferably, one end of the rotary cylinder is started by the first motor, and the other end of the rotary cylinder is connected with a folding line pressing die.

Preferably, the plurality of through holes are circumferentially distributed.

Compared with the prior art, the utility model has the advantages that:

the wire core in the rotary cylinder body is located the outside of spool, after the flat filament on the spool finishes consuming, can directly dismantle the spool, install the new spool that continues the flat filament with winding flat filament, can avoid cutting the wire core and twine flat filament again on the spool and carry out flat filament pay-off, thereby can improve work efficiency, in addition, because of spool and rotary cylinder body are in coaxial state, the centrifugal force that the spool received reduces in eccentric installation's running wheel, thereby can increase rotary cylinder body's rotational speed, and then further improve flat filament winding efficiency.

Drawings

FIG. 1 is a schematic structural view of a winding device for producing a covered push-pull rope core;

FIG. 2 is a schematic diagram of the internal structure of a winding device for producing a covered push-pull rope core;

fig. 3 is an enlarged view of a portion a of fig. 2;

FIG. 4 is a schematic structural view of a flat wire payout assembly;

wherein: the winding frame 12.1, the rotary cylinder 12.2, the folding line pressing die 12.3, the first motor 12.5, the flat wire paying-off assembly 12.6, the rotary shaft 12.61, the rotary disc 12.62, the connecting disc 12.63, the spool 12.64, the damper 12.65, the flat wire outlet 12.66, the roller 12.661, the through hole 12.67, the round hole 12.68 and the baffle roller 12.69.

Detailed Description

As shown in fig. 1-4, the winding device for producing the covered armor push-pull cable core in this embodiment includes a winding frame 12.1, a rotating cylinder 12.2 and a folding line pressing die 12.3 are sequentially arranged on the winding frame 12.1, one end of the rotating cylinder 12.2 is started by a first motor 12.5, two flat wire paying-off assemblies 12.6 symmetrically distributed along the axis of the rotating cylinder 12.2 are arranged in the rotating cylinder 12.2, a wire core is input from one end of the rotating cylinder 12.2 and then discharged from the other end, during the period, the rotating cylinder 12.2 is driven by the first motor 12.5, the folding line pressing die 12.3 is connected to the other end of the rotating cylinder 12.2, flat wires are conveyed to the folding line pressing die 12.3 by the flat wire paying-off assemblies 12.6, and the flat wires are preliminarily wound and formed by the folding line pressing die 12.3, and gaps among the flat wires are uniform;

the flat wire paying-off assembly 12.6 comprises a rotating shaft 12.61, the rotating shaft 12.61 and a rotating cylinder 12.2 are coaxially arranged, a rotating disc 12.62 and a connecting disc 12.63 are installed on the rotating shaft 12.61 through bearing seats, a damper 12.65 is installed at one end of the rotating shaft 12.61, an I-shaped wheel 12.64 is coaxially installed at the other end of the rotating shaft 12.61, the rotating disc 12.62 and the connecting disc 12.63 are fixedly connected with the rotating cylinder 12.2, and in the two flat wire paying-off assemblies 12.6, two I-shaped wheels 12.64 are located between the two connecting disc dampers 12.65;

the flat wire paying-off assembly 12.6 further comprises a flat wire outlet 12.66 arranged on the rotary cylinder 12.2, a roller 12.661 is arranged at the position of the flat wire outlet 12.66, a plurality of circumferentially distributed through holes 12.67 are formed in the connecting disc 12.63, a round hole 12.68 is formed in the rotary disc 12.62, and a blocking rod 12.69 is arranged on one side, close to the spool 12.64, of the rotary disc 12.62;

the wire core sequentially passes through the through hole 12.67 and the round hole 12.68 and then is conveyed to the folding line pressing die 12.3, the flat wire is wound on the spool 12.64 in advance, the flat wire on the spool 12.64 passes through the flat wire outlet 12.66 and bypasses the roller 12.661 and then is conveyed to the folding line pressing die 12.3, the flat wire is wound on the wire core through the folding line pressing die 12.3, the flat wire pulls the spool 12.64 to rotate, the rotation of the spool 12.64 drives the rotating shaft 12.61 to rotate, in the flat wire conveying process, the flat wire abuts against one side of the stop roller 12.69, the flat wire is prevented from being deflected due to centrifugal force, the damper 12.65 is used for passively providing tension when the flat wire is unwound, the wire core in the rotary cylinder 12.2 is positioned outside the spool 12.64, after the flat wire on the spool 12.64 is consumed, the spool 12.64 can be directly disassembled, the novel spool 12.64 is installed for continuously conveying the flat wire, the wire core is prevented from being sheared, the flat wire is wound on the spool 12.64 again, the flat wire is driven to rotate, and the rotating efficiency of the spool 12.64 is further improved compared with the rotary cylinder 12.64, and the rotating cylinder is further, and the rotating efficiency is further improved.

In addition to the above embodiments, the present utility model also includes other embodiments, and all technical solutions that are formed by equivalent transformation or equivalent substitution should fall within the protection scope of the claims of the present utility model.

Claims (7)

1. The utility model provides a cover first push-and-pull rope core production is with coiling equipment which characterized in that: the winding machine comprises a winding machine frame (12.1), wherein a rotary cylinder body (12.2) and a folding line pressing die (12.3) are sequentially arranged on the winding machine frame (12.1), and two flat wire paying-off assemblies (12.6) symmetrically distributed along the axis of the rotary cylinder body (12.2) are arranged in the rotary cylinder body (12.2);

the flat wire paying-off assembly (12.6) comprises a rotating shaft (12.61), the rotating shaft (12.61) and a rotating cylinder body (12.2) are coaxially arranged, a rotating disc (12.62) and a connecting disc (12.63) are arranged on the rotating shaft (12.61) through bearing seats, an I-shaped wheel (12.64) is coaxially arranged at one end of the rotating shaft (12.61), the rotating disc (12.62) and the connecting disc (12.63) are fixedly connected with the rotating cylinder body (12.2), a flat wire outlet (12.66) is arranged on the rotating cylinder body (12.2), a plurality of through holes (12.67) which are circumferentially distributed are formed in the connecting disc (12.63), and round holes (12.68) are formed in the rotating disc (12.62).

2. The winding device for producing a covered push-pull rope core according to claim 1, wherein: a blocking rod (12.69) is arranged on the rotating disc (12.62).

3. The winding device for producing a covered push-pull rope core according to claim 1, wherein: a roller (12.661) is arranged at the flat wire outlet (12.66).

4. The winding device for producing a covered push-pull rope core according to claim 1, wherein: dampers (12.65) are mounted on both rotating shafts (12.61).

5. The winding device for producing a covered push-pull rope core according to claim 4, wherein: in the two flat wire paying-off assemblies (12.6), two spool (12.64) are positioned between two dampers (12.65).

6. The winding device for producing a covered push-pull rope core according to claim 1, wherein: one end of the rotary cylinder body (12.2) is started through a first motor (12.5), and the other end of the rotary cylinder body (12.2) is connected with a folding line pressing die (12.3).

7. The winding device for producing a covered push-pull rope core according to claim 1, wherein: the plurality of through holes (12.67) are circumferentially distributed.

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