CN113345650A - Wire coil frame structure of composite cradle type cable former - Google Patents

Abstract

The invention discloses a cable tray frame structure of a composite cradle type cable former, which comprises a first mounting disc, a second mounting disc, a third mounting disc and a fourth mounting disc which are fixedly sleeved on a driving beam, wherein three first cable tray frames are rotatably mounted between the first mounting disc and the second mounting disc, and three first cable tray frames are rotatably mounted between the second mounting disc and the third mounting disc; six second bobbin racks are rotatably arranged between the third mounting disc and the fourth mounting disc and are distributed in an annular array; and intersection points of the rotating shafts of the first reel frame and the second reel frame and the plane where the fourth mounting disc is located are distributed on the third mounting disc in an annular array manner. According to the invention, the first cable tray and the second cable tray are distributed in a 3-3-6 manner, so that one-time cabling can be realized while the wiring is not influenced, and compared with a charging pile cable processing device in the prior art, the situation of twice or even three-time cabling can be avoided, and the cabling efficiency is greatly improved.

Description

Wire coil frame structure of composite cradle type cable former

Technical Field

The invention belongs to the technical field of cable processing devices, and particularly relates to a cable tray frame structure of a composite cradle type cable former.

Background

The cable former is a wire and cable device for cabling and armouring of multi-core rubber sleeve cables, plastic cables, cross-linked cables, telephone cables and control cables with various cross sections, and the cradle type cable former can twist a plurality of single wires with circular, fan-shaped or special-shaped wire sections together to form a cable.

The charging pile cable is of a multilayer cable structure, and usually needs to be repeatedly stranded for 2-3 times through a cabling machine during processing, so that the production efficiency is greatly reduced, and in order to solve the problems and realize one-time cabling, the invention provides the following technical scheme.

Disclosure of Invention

The invention aims to provide a wire coil frame structure of a composite cradle type cabling machine.

The purpose of the invention can be realized by the following technical scheme:

a composite cradle type cable-former cable tray frame structure comprises a first mounting tray, a second mounting tray, a third mounting tray and a fourth mounting tray which are fixedly sleeved on a driving beam, wherein three first cable tray frames are rotatably mounted between the first mounting tray and the second mounting tray, and first cables are rotatably mounted on the first cable tray frames;

three first reel frames are distributed in an annular array between the first mounting disc and the second mounting disc;

three first reel racks are rotatably arranged between the second mounting disc and the third mounting disc;

the three first reel frames between the second mounting disc and the third mounting disc are distributed in an annular array, and the three first reel frames between the second mounting disc and the third mounting disc and the three first reel frames between the first mounting disc and the second mounting disc are arranged in a staggered mode;

six second bobbin racks are rotatably arranged between the third mounting disc and the fourth mounting disc and are distributed in an annular array;

and intersection points of the rotating shafts of the first reel frame and the second reel frame and the plane where the fourth mounting disc is located are distributed on the third mounting disc in an annular array manner.

As a further scheme of the invention, a plurality of round holes are uniformly formed on the second mounting plate and the third mounting plate.

As a further scheme of the invention, three lead structures are rotatably mounted on one surface of the second mounting disc close to the first mounting disc, three lead structures are fixedly mounted on one surface of the third mounting disc close to the second mounting disc, and six lead structures are fixedly mounted on one surface of the fourth mounting disc close to the third mounting disc;

the wire structure comprises a support shaft, the support shaft is of a hollow tubular structure, one end of the support shaft penetrates through the second mounting disc and then is rotatably mounted on the second mounting disc, and a rolling shaft is rotatably mounted at the other end of the support shaft through a U-shaped frame;

the number of the U-shaped frame and the number of the rolling shafts are four, two ends of each rolling shaft are rotatably arranged at two ends of the U-shaped frame, two opposite rolling shafts are arranged in parallel, and the two opposite rolling shafts are positioned below the other pair of rolling shafts;

the first cable tray and the second cable tray are fixedly sleeved on the supporting shaft at the ends close to the wire structure.

As a further aspect of the invention, the second reel frame has a size smaller than that of the first reel frame.

As a further scheme of the invention, rollers are fixedly arranged on one surface of the fourth mounting disc, which is far away from the third mounting disc, and the rollers are distributed on the fourth mounting disc in an annular array.

The invention has the beneficial effects that:

according to the invention, the first cable tray and the second cable tray are distributed in a 3-3-6 manner, so that one-time cabling can be realized while wiring is not influenced, compared with a charging pile cable processing device in the prior art, the situation of twice or even three-time cabling can be avoided, the cabling efficiency is greatly improved, and meanwhile, the torsion change of a semi-finished cable can be reduced by one-time cabling, and the cabling quality is improved.

Drawings

The invention is described in further detail below with reference to the figures and specific embodiments.

Fig. 1 is a schematic structural view of a composite cradle type cabling machine;

fig. 2 is a schematic structural diagram of a conductive line structure.

Reference numerals: 1. a drive motor; 2. a gear case; 3. a coupling; 4. a second bearing frame; 6. a first mounting plate; 8. a first reel stand; 9. a first wire coil; 11. a second mounting plate; 12. a circular hole; 14. a wire structure; 141. a support shaft; 142. a U-shaped frame; 143. a roller; 16. a second reel holder; 17. a second wire coil; 18. a fourth mounting plate; 19. a roller; 20. a drive beam; 21. a main rotary bearing; 22. a first bearing frame; 23. and a third mounting plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. 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 protection scope of the present invention.

A composite cradle type cable former is shown in figures 1 and 2 and comprises a driving beam 20, wherein two ends of the driving beam 20 are fixedly sleeved with main rotating bearings 21, the main rotating bearing 21 on one end of the driving beam 20 is installed on a first bearing frame 22, the main rotating bearing 21 on the other end of the driving beam 20 is installed on a second bearing frame 4, one end, close to the second bearing frame 4, of the driving beam 20 is connected with an output end of a gear box 2 through a coupler 3, and an input end of the coupler 3 is connected with a driving motor 1;

a bobbin holder structure is fixedly mounted on the driving beam 20;

the bobbin loader structure comprises a first mounting disc 6, a second mounting disc 11, a third mounting disc 23 and a fourth mounting disc 18 which are fixedly sleeved on a driving beam 20, wherein three first bobbin loaders 8 are rotatably mounted between the first mounting disc 6 and the second mounting disc 11, and first bobbins 9 are rotatably mounted on the first bobbin loaders 8;

the second mounting disc 11 and the third mounting disc 23 are uniformly provided with a plurality of round holes 12, so that the strength of the second mounting disc 11 and the third mounting disc 23 is ensured, and the use of raw materials and the self weight of the mounting discs are reduced;

three first reel frames 8 are distributed in an annular array between the first mounting plate 6 and the second mounting plate 11;

three wire structures 14 are rotatably mounted on one surface, close to the first mounting plate 6, of the second mounting plate 11, each wire structure 14 comprises a support shaft 141, each support shaft 141 is of a hollow tubular structure, one end of each support shaft 141 penetrates through the second mounting plate 11 and is rotatably mounted on the second mounting plate 11, and a roller 143 is rotatably mounted at the other end of each support shaft 141 through a U-shaped frame 142;

the number of the U-shaped frame 142 and the number of the rollers 143 are four, two ends of each roller 143 are rotatably mounted at two ends of the U-shaped frame 142, the two rollers 143 are arranged in parallel, and two opposite rollers 143 are positioned below the other pair of rollers 143;

in operation, due to the protection of the rollers 143, when a wire passes through the wire guiding structure 14, no matter which direction the wire is moved, rolling friction occurs with one of the rollers 143, and because two opposite rollers 143 are located below the other pair of rollers 143, the wire is not transmitted along the corners of two adjacent rollers 143, so that sliding friction occurs with the structures such as the U-shaped frame 142 and the mounting disc;

the lead can be guided through the lead structure 14, so that the lead is prevented from directly sliding and rubbing with the mounting disc, and the lead is prevented from being abraded and stretched to deform, so that the quality of the formed cable is influenced;

one end of the first reel frame 8 between the first mounting disc 6 and the second mounting disc 11 is fixedly sleeved on the supporting shaft 141, and the other end of the first reel frame 8 is rotatably mounted on the first mounting disc 6;

three first bobbin racks 8 are rotatably mounted between the second mounting plate 11 and the third mounting plate 23, three lead structures 14 are fixedly mounted on one surface of the third mounting plate 23 close to the second mounting plate 11, and one end of each first bobbin rack 8 between the second mounting plate 11 and the third mounting plate 23 is fixedly sleeved on a support shaft 141 on the third mounting plate 23;

the three first reel frames 8 between the second mounting plate 11 and the third mounting plate 23 are distributed in an annular array, and the three first reel frames 8 between the second mounting plate 11 and the third mounting plate 23 and the three first reel frames 8 between the first mounting plate 6 and the second mounting plate 11 are arranged in a staggered manner;

six second wire coil frames 16 are rotatably mounted between the third mounting disc 23 and the fourth mounting disc 18, second wire coil frames 17 are rotatably mounted on the second wire coil frames 16, and the six second wire coil frames 16 are distributed in an annular array;

the second reel rack 16 is smaller in size than the first reel rack 8;

the intersection points of the rotating shafts of the first reel stand 8 and the second reel stand 16 and the plane of the fourth mounting plate 18 are distributed on the third mounting plate 23 in an annular array;

the structure can fully utilize the space, and ensure that the wire coils on each layer of wire coil rack cannot interfere with each other when the wire coils are wired while the multilayer wire coil rack is arranged, thereby completing one-time wire forming of multilayer cables;

when the structure of cable changes, also can correspond the structure of adjusting the cable-former, it is concrete, when the number of piles of the cable of producing changes, the accessible promotes the mounting disc radius, promotes operatable space, then adds the quantity of establishing the mounting disc and changes the line effect, if the single-deck single line quantity of the cable of producing changes, then can change the line effect through the quantity of the cable drum frame between the radius of adjusting the mounting disc and two mounting discs.

Six wire structures 14 are fixedly mounted on one surface, close to the third mounting plate 23, of the fourth mounting plate 18, one end of the second wire plate rack 16 is fixedly mounted on the support shaft 141, rollers 19 are fixedly mounted on one surface, far away from the third mounting plate 23, of the fourth mounting plate 18, and the rollers 19 are distributed on the fourth mounting plate 18 in an annular array manner to guide wire routing of the wire plates;

according to the invention, the first cable tray 8 and the second cable tray 16 are distributed in a 3-3-6 manner, so that one-time cabling can be realized while wiring is not influenced, compared with a charging pile cable processing device in the prior art, the situation of twice or even three-time cabling can be avoided, the cabling efficiency is greatly improved, and meanwhile, the torsion change of semi-finished cables can be reduced by one-time cabling, and the cabling quality is improved.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (5)

1. A composite cradle type cable-former cable tray frame structure comprises a first mounting tray (6), a second mounting tray (11), a third mounting tray (23) and a fourth mounting tray (18) which are fixedly sleeved on a driving beam (20), and is characterized in that three first cable tray frames (8) are rotatably mounted between the first mounting tray (6) and the second mounting tray (11), and first cables (9) are rotatably mounted on the first cable tray frames (8);

three first reel frames (8) between the first mounting disc (6) and the second mounting disc (11) are distributed in an annular array;

three first reel racks (8) are rotatably arranged between the second mounting plate (11) and the third mounting plate (23);

three first line disk frames (8) between the second mounting disk (11) and the third mounting disk (23) are distributed in an annular array, and the three first line disk frames (8) between the second mounting disk (11) and the third mounting disk (23) and the three first line disk frames (8) between the first mounting disk (6) and the second mounting disk (11) are arranged in a staggered mode;

six second wire coil frames (16) are rotatably mounted between the third mounting disc (23) and the fourth mounting disc (18), second wire coil frames (17) are rotatably mounted on the second wire coil frames (16), and the six second wire coil frames (16) are distributed in an annular array;

the intersection points of the rotating shafts of the first reel frame (8) and the second reel frame (16) and the plane where the fourth mounting disc (18) is located are distributed on the third mounting disc (23) in an annular array.

2. The composite cradle type cabling machine wire tray structure according to claim 1, wherein a plurality of round holes (12) are uniformly formed in the second mounting plate (11) and the third mounting plate (23).

3. The composite cradle type cabling machine wire tray structure according to claim 1, wherein three wire structures (14) are rotatably mounted on one surface of the second mounting plate (11) close to the first mounting plate (6), three wire structures (14) are fixedly mounted on one surface of the third mounting plate (23) close to the second mounting plate (11), and six wire structures (14) are fixedly mounted on one surface of the fourth mounting plate (18) close to the third mounting plate (23);

the wire structure (14) comprises a support shaft (141), the support shaft (141) is of a hollow tubular structure, one end of the support shaft (141) penetrates through the second mounting disc (11) and then is rotatably mounted on the second mounting disc (11), and the other end of the support shaft (141) is rotatably mounted with a roller (143) through a U-shaped frame (142);

the number of the U-shaped frame (142) and the number of the rollers (143) are four, two ends of each roller (143) are rotatably arranged at two ends of the U-shaped frame (142), two opposite rollers (143) are arranged in parallel, and the two opposite rollers (143) are positioned below the other pair of rollers (143);

the ends of the first reel rack (8) and the second reel rack (16) close to the wire structure (14) are fixedly sleeved on the supporting shaft (141).

4. A composite cradle cabling drum structure according to claim 1, characterized in that the second cable drum (16) has smaller dimensions than the first cable drum (8).

5. A composite cradle cable-former drum frame structure according to claim 1, characterized in that the side of the fourth mounting plate (18) far from the third mounting plate (23) is fixedly mounted with rollers (19), and the rollers (19) are distributed on the fourth mounting plate (18) in an annular array.

Images