CN211284765U - Complicated to simple mechanism for large rotor rotation - Google Patents

Abstract

The utility model discloses a by numerous to simple mechanism for big rotor gyration, including the loom board, a side of loom board goes up the parallel and is equipped with two loom rotor devices, two on the surface the crisscross two slave units that are equipped with in bottom of loom rotor device, two slave unit and two be equipped with anti-skidding chain on the surface of loom rotor device, and two loom rotor device is including first bearing, first bearing is kept away from one side of loom board is equipped with the installation circle, the installation circle is kept away from one side of loom board is equipped with the rotor, slave unit is including the second bearing, the second bearing is kept away from one side of loom board is equipped with the installed part, the installed part is kept away from one side of second bearing is equipped with driven gear. The utility model discloses, through loom rotor device and slave unit operation and cooperation on anti-skidding chain, can reach and promote loom rotor rotation efficiency, and then improve the production efficiency of weaving machine.

Description

Complicated to simple mechanism for large rotor rotation

Technical Field

The utility model relates to a loom rotor field, in particular to a mechanism from numerous to simple for big rotor gyration.

Background

The textile machines are also called textile machines, weaving machines, cotton spinning machines and the like, and the ancient textile machines are weaving machines driven by manpower. The textile machine is a general name of a tool for processing raw materials such as threads, silks, hemp and the like into silk threads and then weaving the silk threads into cloth. Such as spinning pendants, spinning wheels, spindles, pedal looms, modern mechanical looms, modern numerical control automatic looms and the like. The development of textile processes and equipment has been designed according to the textile raw materials, and therefore, the raw materials have an important position in the textile technology. The fibers used for spinning in all countries in the ancient world are all natural fibers, generally three short fibers (wool, hemp and cotton), the fibers used for spinning in all countries in the ancient world are all natural fibers, generally the fibers are wool, hemp and cotton), and the fibers used for spinning in the ancient world are only wool and flax; cotton was used in the indian peninsula area;

in the process of weaving the fabric, sometimes the textile machine is required to carry out high-strength work, the service life of a rotor in the textile machine is greatly consumed, the rotor in the textile machine is even damaged, and the rotor is replaced, so that the work of the textile machine is usually stopped, therefore, the production efficiency is reduced, the production of the fabric is hindered, and the development of the clothing market is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a by numerous to simple mechanism for big rotor gyration to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a complex-to-simple mechanism for large rotor rotation comprises a loom plate, wherein two loom rotor devices are arranged on the surface of one side of the loom plate in parallel, two driven devices are arranged at the bottom ends of the two loom rotor devices in a staggered manner, anti-skid chains are arranged on the outer surfaces of the two driven devices and the two loom rotor devices, the two loom rotor devices comprise first bearings, a mounting ring is arranged on one side, away from the loom plate, of each first bearing, a rotor is arranged on one side, away from the loom plate, of each mounting ring, an adjustable shed disc is arranged on one side, away from the mounting ring, of each rotor, a crosshead connecting rod is arranged on one side, away from the rotor, of each adjustable shed disc, and a fixing piece is arranged on one side, away from the adjustable shed disc, of each crosshead connecting rod;

the driven device comprises a second bearing, one side, far away from the weaving machine plate, of the second bearing is provided with a mounting piece, and one side, far away from the second bearing, of the mounting piece is provided with a driven gear.

Preferably, the rotor comprises two driving gears, a magnetic yoke is arranged on one side, away from the adjustable shuttle-slot disc, of the two driving gears, and a connecting rod positioning hole is arranged on one side, close to the adjustable shuttle-slot disc, of the two driving gears.

Preferably, the rotor is connected to the crosshead link through the link positioning hole and the adjustable shuttle dial.

Preferably, the anti-skid chain comprises two inner chain plates, two outer chain plates are arranged on two sides of the inner chain plates, pin shafts are arranged on the outer surfaces of the two outer chain plates, and the anti-skid chain is meshed with the rotor through the pin shafts.

Preferably, two of the loom rotor devices are connected to the driven device by the anti-slip chain.

Preferably, a fixed shaft is arranged at the center of one side of the fixing part close to the crosshead connecting rod, and the fixed shaft penetrates through the fixing part and the adjustable shed disc to be connected with a connecting rod positioning hole at one side of the adjustable shed disc.

Preferably, one side of the loom board close to the loom rotor device is provided with two first connecting holes, and the bottom ends of the two first connecting holes are provided with two second connecting holes in a staggered manner.

Preferably, the loom plate is connected to the loom rotor device through two of the first connection holes, and the loom plate is connected to the driven device through two of the second connection holes.

The utility model discloses a technological effect and advantage:

through operation and cooperation of loom rotor device and slave unit on anti-skidding chain, can reach and promote loom rotor rotation efficiency, and then improve the production efficiency of weaving machine, the concrete performance is: the friction force is reduced for the rotor through the first bearings in the two rotor devices of the weaving machine, so that the rotor arranged on one side of the mounting ring far away from the weaving machine plate is accelerated to rotate, when different patterns of the fabric are processed, the position of the crosshead connecting rod is adjusted only by the adjustable shuttle-slot disc arranged on one side of the rotor, which is far away from the mounting ring, and particularly, the fixed shaft penetrates through the fixing piece and the adjustable shuttle-slot disc to be connected with different connecting rod positioning holes on one side of the adjustable shuttle-slot disc, so that the effect of changing the running track of the crosshead connecting rod can be achieved, in the process of the operation of the anti-skid chains of the rotor devices of the weaving machine, the two driven devices which are staggered at the bottom ends of the two rotor devices of the weaving machine are driven by the anti-skid chains to rotate similarly, thereby constantly transmitting the moment of torsion that the loom rotor device transmitted to make the gyration efficiency of whole rotor device constantly promote.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the anti-slip chain of the present invention.

Fig. 3 is a schematic structural view of the rotor of the present invention.

In the figure: 1. a loom plate; 2. a loom rotor device; 2a, a first bearing; 2b, mounting a ring; 2c, a rotor; 2c-1, a driving gear; 2c-2, a magnet yoke; 2c-3, connecting rod positioning holes; 2d, an adjustable shuttle port disc; 2e, a crosshead link; 2f, fixing parts; 2g, fixing a shaft; 3. a driven device; 3a, a second bearing; 3b, mounting pieces; 3c, a driven gear; 4. an anti-slip chain; 4a, an inner chain plate; 4b, an outer chain plate; 4c, a pin shaft; 5. a first connection hole; 6. and a second connection hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a complex to simple mechanism for large rotor rotation as shown in figures 1-3, which comprises a loom plate 1, two loom rotor devices 2 are arranged on the surface of one side of the loom plate 1 in parallel, two driven devices 3 are arranged at the bottom ends of the two loom rotor devices 2 in a staggered manner, anti-skid chains 4 are arranged on the outer surfaces of the two driven devices 3 and the two loom rotor devices 2, the two loom rotor devices 2 comprise first bearings 2a, one side of the first bearing 2a far away from the loom plate 1 is provided with a mounting ring 2b, one side of the mounting ring 2b far away from the loom plate 1 is provided with a rotor 2c, one side of the rotor 2c far away from the mounting ring 2b is provided with an adjustable shuttle port disc 2d, one side of the adjustable shuttle port disc 2d far away from the rotor 2c is provided with a crosshead connecting rod 2e, a fixing part 2f is arranged on one side, away from the adjustable shuttle-slot disc 2d, of the crosshead connecting rod 2 e;

the driven device 3 comprises a second bearing 3a, a mounting part 3b is arranged on one side of the second bearing 3a far away from the weaving machine plate 1, and a driven gear 3c is arranged on one side of the mounting part 3b far away from the second bearing 3 a.

As shown in fig. 2, the antiskid chain 4 includes two inner chain plates 4a, two outer chain plates 4b are disposed on two sides of the two inner chain plates 4a, the inner chain plates 4a are located on inner sides of the outer chain plates 4b, and the inner chain plates 4a and the outer chain plates 4b are staggered and overlapped, so that the antiskid chain 4 can move at various angles conveniently, a pin shaft 4c is disposed on outer surfaces of the two outer chain plates 4b, and the antiskid chain 4 is engaged with the rotor 2c through the pin shaft 4 c; so that both of the loom rotor devices 2 are connected to the driven device 3 by the anti-slip chain 4.

As shown in fig. 3, the rotor 2c includes two driving gears 2c-1, a magnetic yoke 2c-2 is disposed on one side of the two driving gears 2c-1 away from the adjustable shed disk 2d, the magnetic yoke 2c-2 drives the driving gears 2c-1 to rotate, so that the rotor 2c continuously rotates, and a link positioning hole 2c-3 is disposed on one side of the two driving gears 2c-1 close to the adjustable shed disk 2 d; the rotor 2c is connected with the crosshead connecting rod 2e through the connecting rod positioning hole 2c-3 and the adjustable shuttle port disc 2 d; the rotor 2c continuously drives the crosshead connecting rod 2e to continuously perform eccentric movement, a fixed shaft 2g is arranged at the center of one side, close to the crosshead connecting rod 2e, of the fixing piece 2f, and the fixed shaft 2g penetrates through the fixing piece 2f and the adjustable shuttle port disc 2d to be connected with a connecting rod positioning hole 2c-3 at one side of the adjustable shuttle port disc 2 d.

This practical theory of operation:

in the process of spinning, the magnetic yoke 2c-2 arranged at one side of the driving gear 2c-1 cuts the magnetic field continuously, so that the magnetic yoke 2c-2 drives the driving gear 2c-1 to rotate continuously, the friction force of the driving shaft is reduced continuously by the first bearings 2a in the two loom rotor devices 2 to accelerate the rotating speed of the driving gear 2c-1, then the driving gear 2c-1 rotates continuously to drive the anti-skid chain 4 to run, so that the torque generated by the driving gear 2c-1 in the loom rotor devices 2 is transmitted to the driven device 3, then the driven gear 3c arranged at one side of the mounting piece 3b far away from the second bearing 3a is meshed with the anti-skid chain 4, further transmitting the torque, and meanwhile, the change of the motion track of the crosshead connecting rod 2e is realized by connecting the fixed shaft 2g penetrating through the fixed part 2f and the adjustable shuttle port disc 2d with different connecting rod positioning holes 2c-3 at one side of the adjustable shuttle port disc 2d, thereby achieving the simplification of the loom rotor device 2.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and variations can be made in the embodiments or in part of the technical features of the embodiments without departing from the spirit and the scope of the invention.

Claims (8)

1. A from numerous to simple mechanism for big rotor gyration, including loom board (1), its characterized in that: the loom is characterized in that two loom rotor devices (2) are arranged on the surface of one side of a loom plate (1) in parallel, two driven devices (3) are arranged at the bottom ends of the two loom rotor devices (2) in a staggered mode, an anti-skidding chain (4) is arranged on the outer surfaces of the two driven devices (3) and the two loom rotor devices (2), the two loom rotor devices (2) comprise first bearings (2a), an installation ring (2b) is arranged on one side, away from the loom plate (1), of each first bearing (2a), a rotor (2c) is arranged on one side, away from the loom plate (1), of each installation ring (2b), an adjustable shuttle disk (2d) is arranged on one side, away from the installation ring (2b), of each adjustable shuttle disk (2d) is provided with a crosshead connecting rod (2e), a fixing piece (2f) is arranged on one side, away from the adjustable shuttle-slot disc (2d), of the crosshead connecting rod (2 e);

the driven device (3) comprises a second bearing (3a), one side, far away from the weaving machine plate (1), of the second bearing (3a) is provided with a mounting piece (3b), and one side, far away from the second bearing (3a), of the mounting piece (3b) is provided with a driven gear (3 c).

2. A complex to simple mechanism for large rotor revolution as claimed in claim 1, wherein: the rotor (2c) comprises two driving gears (2c-1), a magnetic yoke (2c-2) is arranged on one side, away from the adjustable shuttle opening disc (2d), of the two driving gears (2c-1), and a connecting rod positioning hole (2c-3) is arranged on one side, close to the adjustable shuttle opening disc (2d), of the two driving gears (2 c-1).

3. A complex to simple mechanism for large rotor revolution as claimed in claim 2, wherein: the rotor (2c) is connected with the crosshead connecting rod (2e) through the connecting rod positioning hole (2c-3) and the adjustable shuttle port disc (2 d).

4. A complex to simple mechanism for large rotor revolution as claimed in claim 1, wherein: anti-skidding chain (4) are including two inner chain plates (4a), two the both sides of inner chain plate (4a) are equipped with two outer chain plates (4b), two be equipped with round pin axle (4c) on the surface of outer chain plate (4b), just anti-skidding chain (4) pass through round pin axle (4c) with rotor (2c) mesh mutually.

5. A complex to simple mechanism for large rotor revolution as claimed in claim 1, wherein: the two loom rotor devices (2) are connected with the driven device (3) through the anti-skid chains (4).

6. A complex to simple mechanism for large rotor revolution as claimed in claim 3, wherein: and a fixed shaft (2g) is arranged at the center of one side, close to the crosshead connecting rod (2e), of the fixing piece (2f), and the fixed shaft (2g) penetrates through the fixing piece (2f) and the adjustable shuttle-slot disc (2d) to be connected with a connecting rod positioning hole (2c-3) on one side of the adjustable shuttle-slot disc (2 d).

7. A complex to simple mechanism for large rotor revolution as claimed in claim 4, wherein: one side of the loom plate (1) close to the loom rotor device (2) is provided with two first connecting holes (5), and the bottom ends of the two first connecting holes (5) are provided with two second connecting holes (6) in a staggered manner.

8. A complex to simple mechanism for large rotor revolution as claimed in claim 7, wherein: the loom plate (1) is connected with the loom rotor device (2) through the two first connecting holes (5), and the loom plate (1) is connected with the driven device (3) through the two second connecting holes (6).

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