CN219602890U - Four-speed power-assisted wire feeding equipment - Google Patents

Abstract

The utility model discloses four-speed power-assisted wire feeding equipment which comprises a frame body and power-assisted rollers with two ends rotatably arranged on the frame body, wherein a motor for driving the power-assisted rollers to rotate is further arranged on the frame body, a middle support is arranged in the middle of the frame body, a first power-assisted structure and a second power-assisted structure are symmetrically arranged on two sides of the middle support respectively, and the second power-assisted structure comprises a box body which is arranged at intervals with the middle support. The first motor and the second motor on the first booster structure drive the first driven wheel and the second driven wheel to rotate respectively, so as to drive the first booster roller and the second booster roller to rotate, the second booster roller is rotationally sleeved on the rotating shaft of the first booster roller, and the first booster roller and the second booster roller do not influence each other during rotation; in addition, the second power-assisted structure is the same as the first power-assisted structure, and the four power-assisted rollers can be controlled at different speeds at the same time, so that the four copper wires with different wire diameters can be subjected to power-assisted wire feeding, and the practicability and the efficiency of the power-assisted roller are greatly improved.

Description

Four-speed power-assisted wire feeding equipment

Technical Field

The utility model relates to the technical field of power-assisted wire feeding equipment, in particular to four-speed power-assisted wire feeding equipment.

Background

Enameled wire is a main variety of winding wire, which is formed by two parts of conductor and insulating layer, and bare wire is annealed and softened, painted for many times and baked. Copper wire is fed through a booster drum before entering the annealing furnace.

The existing wire feeding and feeding equipment commonly uses a bilateral symmetry double-speed wire feeding assisting mode, namely, the wire feeding speed of a left assisting roller and a right assisting roller is independently controlled by a left motor and a right motor, so that the purpose of assisting and feeding wires is achieved. However, due to the continuous updating of the equipment and the continuous expansion of the scale, the traditional two-speed wire inlet booster equipment can only meet the production of wires with two wire diameters, cannot be matched with other large-scale annealing furnaces and other equipment, has low practicality and low efficiency, and therefore, the booster roller structure capable of feeding wires to copper wires with four different wire diameters is provided.

Disclosure of Invention

Aiming at the problems in the prior art, the utility model aims to provide a booster roller structure capable of feeding copper wires with four different wire diameters.

In order to solve the problems, the utility model adopts the following technical scheme. The four-speed power-assisted wire feeding equipment comprises a frame body and power-assisted rollers with two ends rotatably mounted on the frame body, wherein a motor for driving the power-assisted rollers to rotate is further mounted on the frame body, a middle support is arranged in the middle of the frame body, a first power-assisted structure and a second power-assisted structure which are symmetrically arranged are respectively arranged on two sides of the middle support, the second power-assisted structure comprises a box body which is arranged at intervals with the middle support, a first power-assisted roller and a second power-assisted roller are rotatably mounted between the box body and the middle support, one end of each first power-assisted roller is rotatably mounted on the middle support, the other end of each first power-assisted roller extends to the box body through a rotating shaft and is rotatably mounted on one surface of the box body far away from the middle support, a first driven wheel is mounted on the rotating shaft positioned in the part between the first power-assisted roller and the box body, one end of each second power-assisted roller far away from the first power-assisted roller is mounted on the same central shaft and is arranged at intervals; the box body is also provided with a first motor for driving the first driven wheel to rotate and a second motor for driving the second driven wheel to rotate; the first power assisting structure and the second power assisting structure are identical in structure.

By adopting the technical scheme, the first motor and the second motor on the first booster structure respectively drive the first driven wheel and the second driven wheel to rotate so as to drive the first booster roller and the second booster roller to rotate, and the second booster roller is rotationally sleeved on the rotating shaft of the first booster roller, so that the first booster roller and the second booster roller are not mutually influenced when rotating; in addition, the second power-assisted structure is the same as the first power-assisted structure, and the four power-assisted rollers can be controlled at different speeds at the same time, so that the four copper wires with different wire diameters can be subjected to power-assisted wire feeding, and the practicability and the efficiency of the power-assisted roller are greatly improved.

The second booster roller is further provided with sleeve holes penetrating through two ends of the second booster roller along the central shaft, and bearings sleeved on the rotating shaft are arranged at two ends of each sleeve hole.

By adopting the technical scheme, the second booster roller is installed with the rotating shaft by adopting the bearing, so that the structure is more stable, and the rotation is smoother.

The output end of the first motor is provided with a first driving wheel which is in the same vertical plane with the first driven wheel and is linked with the first driven wheel through a belt; the output end of the second motor is provided with a second driving wheel which is in the same vertical plane with the second driven wheel and is linked through a belt.

By adopting the technical scheme, the structure is simple and reasonable.

The frame body comprises a bottom plate, a first booster roller and a second booster roller, wherein a cross beam is connected between the two cases, and the middle support is arranged at the center of the cross beam.

By adopting the technical scheme, the whole structure is stable.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the internal structure of the case of the present utility model;

fig. 3 is a partial cross-sectional view of the present utility model.

The reference numerals in the figures illustrate:

1. a frame body; 11. a bottom plate; 12. a case; 13. a cross beam; 2. a middle support; 3. a first booster structure; 4. a second assist structure; 5. a first booster roller; 51. a rotating shaft; 52. a first driven wheel; 53. a bearing; 6. a second assist roller; 61. a second driven wheel; 62. trepanning; 7. a first motor; 71. a first drive wheel; 72. a second driving wheel; 8. a second motor; 9. a belt.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in figures 1-3, the four-speed power-assisted wire feeding equipment comprises a frame body 1 and power-assisted rollers with two ends rotatably arranged on the frame body 1, wherein a motor for driving the power-assisted rollers to rotate is further arranged on the frame body 1. The frame body 1 comprises a bottom plate 11, a first booster roller 5 and a second booster roller 6, a box body 12, a cross beam 13 is connected between the two box bodies 12, and the middle support 2 is arranged on the center of the cross beam 13. The middle part of the frame body 1 is provided with a middle support 2, the two sides of the middle support 2 are respectively provided with a first power assisting structure 3 and a second power assisting structure 4 which are symmetrically arranged, the second power assisting structure 4 comprises a box body 12 which is arranged at intervals with the middle support 2, a first power assisting roller 5 and a second power assisting roller 6 are rotatably arranged between the box body 12 and the middle support 2, one end of the first power assisting roller 5 is rotatably arranged on the middle support 2, a bearing is embedded in the middle support 2 in a rotatable manner, and a connecting shaft is arranged at one end of the first power assisting roller 5 and inserted into the bearing, or one end of the first power assisting roller 5 is directly inserted into the bearing. The other end extends to the case 12 through the rotary shaft 51 and is rotatably mounted on the side of the case 12 away from the center support 2, and similarly, a bearing 53 is mounted on the side of the case 12 away from the center support 2, and the rotary shaft 51 is inserted into the bearing. The first driven wheel 52 is arranged on the rotating shaft 51 in the box body 12, the second booster roller 6 is rotatably sleeved on the rotating shaft 51 positioned between the first booster roller 5 and the box body 12, and the second driven wheel 61 positioned in the box body 12 is arranged at one end far away from the first booster roller 5. The first driven wheel 52 and the second rotating shaft 51 are on the same central axis and are arranged at intervals, for example: the first driven wheel 52 is mounted in the case 12 on the side remote from the second booster roller 6, and the second driven wheel is mounted in the case 12 on the side close to the second booster roller 6. The box body 12 is also provided with a first motor 7 for driving the first driven wheel 52 to rotate and a second motor 8 for driving the second driven wheel 61 to rotate; the first assistance structure 3 and the second assistance structure 4 have the same structure.

Here, the transmission between the first motor 7 and the second motor 8 and the first driven wheel 52 and the second driven wheel 61 may adopt the following structure: the output end of the first motor 7 is provided with a first driving wheel 71 which is in the same vertical plane with the first driven wheel 52 and is linked by a belt 9; the output end of the second motor 8 is provided with a second driving wheel 72 which is in the same vertical plane with the second driven wheel 61 and is linked with the second driven wheel through a belt 9. Since the first driving wheel 71 and the second driving wheel 72 are arranged at staggered intervals, the first driving wheel 71 and the second driving wheel 72 are also arranged at staggered intervals. If the first motor 7 and the second motor 8 are both installed at the outer side of the case 12, the second driving wheel 72 may extend the output shaft of the second motor 8 so that the second driving wheel 72 can be connected with the second driven wheel 61 through the belt 9. As shown in fig. 3, the second booster roller 6 is provided with sleeve holes 62 penetrating through two ends of the second booster roller 6 along the central axis, and two ends of the sleeve holes 62 are respectively provided with bearings 53 sleeved on the rotating shaft 51. Of course, when the diameter of the sleeve hole 62 is smaller than the diameter of the outer ring of the bearing 53, the sleeve hole 62 may be reamed at both ends, and the bearing 53 may be fitted in the reamed hole. The first motor 7 drives the first driving wheel through the first driving wheel 71 to drive the rotating shaft 51 and the first booster roller 5 to rotate, the second motor 8 drives the second driven wheel 61 through the second driving wheel 72 to directly drive the second booster roller 6 to rotate, and the second booster roller 6 is connected with the rotating shaft 51 through the bearing 53, so that the rotation of the second booster roller 6 and the rotating shaft 51 is not affected, and the rotation can be performed at different speeds. Moreover, the second booster structure 4 at the other end is symmetrical and identical to the first booster structure 3, so that the four booster rollers can rotate at different speeds, and further booster copper wires with four wire diameters can be boosted. The utility model greatly improves the production efficiency and the production range, has multiple functions and high practicability.

The above description is only of the preferred embodiments of the present utility model; the scope of the utility model is not limited in this respect. Any person skilled in the art, within the technical scope of the present disclosure, may apply to the present utility model, and the technical solution and the improvement thereof are all covered by the protection scope of the present utility model.

Claims (4)

1. Four-speed power-assisted wire feeding equipment comprises a frame body (1) and power-assisted rollers with two ends rotatably mounted on the frame body (1), wherein a motor for driving the power-assisted rollers to rotate is further mounted on the frame body (1), and the four-speed power-assisted wire feeding equipment is characterized in that: the middle part of the frame body (1) is provided with a middle support (2), two sides of the middle support (2) are respectively provided with a first power-assisted structure (3) and a second power-assisted structure (4) which are symmetrically arranged, the second power-assisted structure (4) comprises a box body (12) which is arranged at intervals with the middle support (2), a first power-assisted roller (5) and a second power-assisted roller (6) are rotatably arranged between the box body (12) and the middle support (2), one end of the first power-assisted roller (5) is rotatably arranged in the middle support (2), the other end of the first power-assisted roller extends to the box body (12) through a rotating shaft (51) and is rotatably arranged on one surface, far away from the middle support (2), of the box body (12), a first driven wheel (52) is arranged on the rotating shaft (51) in the box body (12), the second power-assisted roller (6) is rotatably sleeved on the rotating shaft (51) which is positioned between the first power-assisted roller (5) and the box body (12), one end, far away from the first power-assisted roller (5), is provided with a second driven wheel (61) which is positioned in the box body (12), and the first driven wheel (52) is positioned at intervals with the same rotating shaft (52). The box body (12) is also provided with a first motor (7) driving the first driven wheel (52) to rotate and a second motor (8) driving the second driven wheel (61) to rotate, and the first power assisting structure (3) and the second power assisting structure (4) are identical in structure.

2. A four-speed booster wire feeding apparatus as defined in claim 1, wherein: the second booster roller (6) is provided with sleeve holes (62) penetrating through two ends of the second booster roller (6) along the central shaft, and bearings (53) sleeved on the rotating shaft (51) are arranged at two ends of each sleeve hole (62).

3. A four-speed booster wire feeding apparatus as defined in claim 1, wherein: the output end of the first motor (7) is provided with a first driving wheel (71) which is in the same vertical plane with the first driven wheel (52) and is linked through a belt (9); the output end of the second motor (8) is provided with a second driving wheel (72) which is in the same vertical plane with the second driven wheel (61) and is linked through a belt (9).

4. A four-speed booster wire feeding apparatus as defined in claim 1, wherein: the frame body (1) comprises a bottom plate (11) and a box body (12) of a first booster roller (5) and a second booster roller (6), a cross beam (13) is connected between the two box bodies (12), and the middle support (2) is arranged on the center of the cross beam (13).