CN216737017U - Active control conveying belt structure of winding machine - Google Patents

Abstract

The utility model discloses an active control conveying belt structure of a winding machine, which comprises: the main shaft is horizontally arranged; the winding disc and the glass fiber disc are both arranged on the main shaft; the double-shaft magnetic powder clutch and the belt conveying speed reducer are both arranged on the winding disc; the first conductive slip ring and the second conductive slip ring are both fixedly connected with the main shaft, the first conductive slip ring is electrically connected with the double-shaft magnetic powder clutch, and the second conductive slip ring is electrically connected with the belt conveying speed reducer; the guide rods are fixedly arranged; the electric control system is electrically connected with the main shaft, the first conductive slip ring and the second conductive slip ring respectively; wherein, the winding has the glass fiber area on the glass fiber dish, and through inlayer polyethylene pipe in the main shaft, inlayer polyethylene pipe and the coaxial setting of main shaft, inlayer polyethylene pipe is coaxial with the main shaft, and the cladding is passed through the guide bar winding at inlayer polyethylene outside of tubes diameter to the glass fiber area. The utility model has stable winding tension output and adjustable torque, and solves the problem of core tube shaking caused by overlarge tension during winding.

Description

Active control conveying belt structure of winding machine

Technical Field

The utility model relates to the technical field of winding machines, in particular to an actively-controlled conveying belt structure of a winding machine.

Background

The upper band of present internal coiler is wrapped the structure comparatively tradition, is mostly passive form upper band structure, and the shortcoming is that self winding tension is big inhomogeneous, can influence the winding and take the effect.

The transmission of current coiler is taken the mode and is coiled the rotation for having power, derive through the guide bar on the winding dish that glass fiber takes over to the inlayer polyethylene pipe and carries out the cladding, unpowered as the follow-up subassembly when glass fiber coiled the winding, because the glass fiber dish is unpowered so drive the rotatory certain power that needs of glass fiber dish, tension has when leading to the fact glass fiber to take the upper band like this, tension causes the shake when too big winding to inlayer core pipe enhancement layer during the winding, the shake probably causes when serious to produce the unable production operation of line.

SUMMERY OF THE UTILITY MODEL

In view of the above, the utility model aims to provide an active control conveying belt structure of a winding machine.

In order to achieve the purpose, the utility model adopts the technical scheme that:

a winder active control feed belt structure, comprising:

the main shaft is horizontally arranged;

the glass fiber winding device comprises a winding disc and a glass fiber disc, wherein the winding disc and the glass fiber disc are both arranged on a main shaft and are coaxially arranged with the main shaft;

the double-shaft magnetic powder clutch and the belt conveying speed reducer are both arranged on the winding disc;

the first conductive slip ring and the second conductive slip ring are fixedly connected with the main shaft, the first conductive slip ring is electrically connected with the double-shaft magnetic powder clutch, and the second conductive slip ring is electrically connected with the belt-conveying speed reducer;

the guide rods are fixedly arranged;

the electric control system is electrically connected with the main shaft, the first conductive slip ring and the second conductive slip ring respectively;

wherein, the winding has the glass fiber area on the glass fiber dish, through inlayer polyethylene pipe in the main shaft, inlayer polyethylene pipe with the coaxial setting of main shaft, inlayer polyethylene pipe with the main shaft is coaxial, the glass fiber band-pass the guide bar winding is in on the inlayer polyethylene pipe external diameter.

Aforesaid winder active control send area structure wherein, still includes: the speed reducer is installed on the rack, the speed reducer is arranged below the main shaft, a main shaft chain is installed on the speed reducer, a main shaft chain wheel is installed on the main shaft, and the main shaft chain is in transmission connection with the main shaft chain wheel.

The active control conveying belt structure of the winding machine further comprises: the transmission shaft assembly is installed on the winding disc, the belt conveying speed reducer is in transmission connection with one end of the double-shaft magnetic powder clutch, and the other end of the double-shaft magnetic powder clutch is in transmission connection with the transmission shaft assembly.

The active control conveying belt structure of the winding machine further comprises: the bearing support is installed on the rack, and the main shaft is installed on the bearing support.

The winding machine is characterized in that the winding machine is provided with a glass fiber disc, and the glass fiber disc is arranged on the glass fiber disc.

The winder actively controls the conveying belt structure, wherein at least one guide rod is arranged in the radial direction of the glass fiber disc.

The active control conveying belt structure of the winding machine is characterized in that each guide rod comprises a fixing portion and a rod-shaped portion, the fixing portion is fixedly arranged, and one end of the rod-shaped portion is rotatably connected with the fixing portion.

Due to the adoption of the technology, compared with the prior art, the utility model has the following positive effects:

(1) the winding part of the utility model adopts a rotating part to supply power by adopting a conductive slip ring, the speed reducer outputs power to the double-shaft magnetic powder brake after being electrified, the magnetic powder brake is of a concentric and non-coaxial structure, the output torque of the speed reducer is in a constant mode, and the output torque can not be controlled, but the magnetic powder clutch can effectively control the output torque within a certain range after being output by the magnetic powder clutch, so that the power structure can be controlled by using an electric brake system, and the stable output of winding tension and the adjustable torque can be realized.

(2) The utility model solves the problem of core tube shaking caused by overlarge tension during winding, can ensure that the winding is more stable, avoids inconsistent winding gaps caused by shaking, changes a passive upper belt structure into an active belt conveying and coating structure, and belongs to great improvement of equipment.

(3) The utility model changes the original transmission structure, one end of the magnetic powder clutch is associated with the speed reducer, and the other end of the magnetic powder clutch is associated with the glass fiber disc through transmission, thereby changing the magnetic powder clutch into a controllable tension.

(4) The utility model adds the conductive slip ring for power supply and provides power supply for the magnetic powder brake of the speed reducer.

Drawings

FIG. 1 is a schematic view of the winder actively controlling the feed belt structure of the present invention.

FIG. 2 is a schematic view of the winder active control feed belt configuration of the present invention.

In the drawings: 1. a frame; 2. a speed reducer; 3. a main shaft chain; 4. a first conductive slip ring; 5. a bearing support; 6. a main shaft; 7. a main shaft sprocket; 8. a second conductive slip ring; 9. a biaxial magnetic powder clutch; 10. a belt conveying speed reducer; 11. a driveshaft assembly; 12. a winding disc; 13. a glass fiber disc; 14. a guide bar; 15. a glass fiber tape; 16. an inner polyethylene tube; 17. an electrical control system.

Detailed Description

The utility model will now be further described with reference to the accompanying drawings and specific examples, without limiting the utility model thereto, fig. 1 is a schematic view of the active control belt structure of a winder according to the utility model; fig. 2 is a schematic view of an actively controlled feeding belt structure of a winding machine of the present invention, shown in fig. 1 to 2, showing a winding machine actively controlled feeding belt structure of a preferred embodiment, including:

the main shaft 6 is horizontally arranged;

the glass fiber winding device comprises a winding disc 12 and a glass fiber disc 13, wherein the winding disc 12 and the glass fiber disc 13 are both installed on a main shaft 6, and the winding disc 12 and the glass fiber disc 13 are both arranged coaxially with the main shaft 6;

the double-shaft magnetic powder clutch 9 and the belt conveying speed reducer 10 are both arranged on the winding disc 12;

the first conductive slip ring 4 and the second conductive slip ring 8 are both fixedly connected with the main shaft 6, the first conductive slip ring 4 is electrically connected with the double-shaft magnetic powder clutch 9, and the second conductive slip ring 8 is electrically connected with the belt conveying speed reducer 10;

the guide rods 14 are fixedly arranged;

the electric control system 17, the electric control system 17 is electrically connected with the main shaft 6, the first conductive slip ring 4 and the second conductive slip ring 8 respectively;

wherein, the winding has glass fiber belt 15 on the fine dish 13 of glass, and through inlayer polyethylene pipe 16 in the main shaft 6, inlayer polyethylene pipe 16 and the coaxial setting of main shaft 6, inlayer polyethylene pipe 16 is coaxial with main shaft 6, and glass fiber belt 15 passes through guide bar 14 winding on inlayer polyethylene pipe 16 external diameters.

In a preferred embodiment, the method further comprises: the speed reducer 2 is arranged on the rack 1, the speed reducer 2 is arranged below the main shaft 6, the main shaft chain 3 is arranged on the speed reducer 2, the main shaft chain wheel 7 is arranged on the main shaft 6, and the main shaft chain 3 is in transmission connection with the main shaft chain wheel 7.

In a preferred embodiment, the method further comprises: the transmission shaft assembly 11, the transmission shaft assembly 11 is installed on winding dish 12, send the one end transmission of belting speed reducer 10 and biax magnetic powder clutch 9 to be connected, and the other end and the transmission shaft assembly 11 transmission of biax magnetic powder clutch 9 are connected.

The above are merely preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

The present invention also has the following embodiments in addition to the above:

in a further embodiment of the present invention, the method further comprises: bearing support 5, bearing support 5 installs on frame 1, and main shaft 6 installs on bearing support 5.

In a further embodiment of the utility model, the drive shaft assembly 11 is in driving connection with the fiberglass disc 13.

In a further embodiment of the utility model, at least one guide rod 14 is arranged in the radial direction of the glass fiber disc 13.

In a further embodiment of the present invention, each guide bar 14 includes a fixing portion fixedly disposed and a rod portion having one end rotatably connected to the fixing portion.

In a preferred embodiment, when the speed reducer 2 outputs power, the main shaft 6 rotates to drive the transmission shaft assembly 11 to rotate, at this time, the belt feeding speed reducer 10 outputs power to the biaxial magnetic powder clutch 9, one end of the biaxial magnetic powder clutch 9 outputs power to the belt feeding speed reducer 10, the belt feeding speed reducer 10 outputs power to the glass fiber disc 13, the glass fiber disc 13 rotates to actively discharge the glass fiber belt 15, the glass fiber belt 15 is guided and wound on the inner polyethylene pipe 16 through the multiple groups of guide rods 14, and the electrical control system 17 controls the electric part of the whole linkage structure.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (7)

1. A winder active control feed belt structure, comprising:

the main shaft is horizontally arranged;

the glass fiber winding device comprises a winding disc and a glass fiber disc, wherein the winding disc and the glass fiber disc are both arranged on a main shaft and are coaxially arranged with the main shaft;

the double-shaft magnetic powder clutch and the belt conveying speed reducer are both arranged on the winding disc;

the first conductive slip ring and the second conductive slip ring are both fixedly connected with the main shaft, the first conductive slip ring is electrically connected with the biaxial magnetic powder clutch, and the second conductive slip ring is electrically connected with the belt-conveying speed reducer;

the guide rods are fixedly arranged;

the electric control system is electrically connected with the main shaft, the first conductive slip ring and the second conductive slip ring respectively;

wherein, the winding has the glass fiber area on the glass fiber dish, through inlayer polyethylene pipe in the main shaft, inlayer polyethylene pipe with the coaxial setting of main shaft, inlayer polyethylene pipe with the main shaft is coaxial, the glass fiber band-pass the guide bar winding cladding is in on the inlayer polyethylene pipe external diameter.

2. The winder active control feed belt structure of claim 1, further comprising: the speed reducer is installed on the rack, the speed reducer is arranged below the main shaft, a main shaft chain is installed on the speed reducer, a main shaft chain wheel is installed on the main shaft, and the main shaft chain is in transmission connection with the main shaft chain wheel.

3. The winder active control feed belt structure of claim 1, further comprising: the transmission shaft assembly is installed on the winding disc, the belt conveying speed reducer is in transmission connection with one end of the double-shaft magnetic powder clutch, and the other end of the double-shaft magnetic powder clutch is in transmission connection with the transmission shaft assembly.

4. The winder active control feed belt structure of claim 2, further comprising: the bearing support is installed on the rack, and the main shaft is installed on the bearing support.

5. The winder active control feed belt structure of claim 3, wherein the drive shaft assembly is drivingly connected to the glass fiber disc.

6. The winder active control feed belt structure of claim 1, wherein at least one of the guide bars is provided in a radial direction of the glass fiber disc.

7. The winding machine active control feed belt structure of claim 1, wherein each of the guide bars includes a fixing portion fixedly provided and a rod portion having one end rotatably connected to the fixing portion.

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