CN115893084B - Novel cloth feeding mechanism - Google Patents

Abstract

The application relates to a novel cloth feeding mechanism which comprises a rotary seat, an inner gear ring, an outer gear ring, a first driving device, a second driving device, a cloth feeding roller linkage mechanism and a storage barrel, wherein the cloth feeding roller linkage mechanism and the storage barrel are connected to the rotary seat, the first driving device drives the rotary seat to rotate and drive the cloth feeding roller linkage mechanism and the storage barrel to synchronously rotate along the circumferential direction of the rotary seat, the inner gear ring and the outer gear ring are arranged up and down in concentric circles, a power input end of the cloth feeding roller linkage mechanism is meshed with the inner gear ring and the outer gear ring, and the power input end of the cloth feeding roller linkage mechanism is driven to perform differential motion by adjusting the rotating speed difference between the rotary seat and the inner gear ring and the outer gear ring. The application realizes the flexible cloth feeding effect of adjustable cloth feeding speed, controllable cloth feeding tension and controllable cloth feeding width of the cloth feeding roller linkage mechanism, and has the advantages of simple structure, reliable function, easy realization and strong practicability.

Description

Novel cloth feeding mechanism

Technical Field

The application relates to the technical field of plush knitting machines, in particular to a novel cloth feeding mechanism.

Background

The lower cloth mechanism of the plush knitting machine is one of important parts in the plush fabric knitting production process.

In the prior art, two lower cloth rollers respectively clamp cloth inwards in a relative rotation mode to form downward tensioning and dragging acting force, and the cloth is continuously collected into a storage device positioned below the lower cloth mechanism along with continuous operation of the knitting machine. The working power of the cloth feeding roller is transmitted by a main motor of the knitting machine through a series of transmission mechanisms with fixed speed ratios, the cloth feeding working speed is only related to the rotating speed of the main motor and is the fixed speed ratio, so that the speed of the cloth feeding roller of the cloth feeding mechanism in the prior art is fixed, the cloth feeding mechanism can only feed cloth according to the fixed speed ratio, and the cloth is collected in a coiled manner through the storage device.

However, unlike common fabric products, the cloth feeding speed of the lower cloth roller has direct influence on the stretching effect of cloth and the quality of the fabric product, but the existing cloth feeding mechanism cannot adjust the speed and tension of the lower cloth roller for collecting cloth according to the requirement, so that the plush fabric products with different color numbers and different parameters are influenced by the tension effect of the lower cloth roller when being pulled after passing through the lower cloth roller with no speed change, and the plush fabric products with different lengths can be caused to have the phenomena of inconsistent cloth widths, distorted patterns and the like, the cloth widths are stable and consistent, and the factors of distortion, deformation and the like are important product quality factors, so that the fixed-speed cloth feeding mechanism cannot meet the cloth feeding requirement of complicated and various plush fabric products, and cannot meet the quality requirement of the plush fabric products which are gradually improved.

Besides, improper collection of the long-wool fabric can bring secondary damage to the product quality of the long-wool fabric, for example, when the long-wool fabric is rolled up and collected together in a rolling manner, on one hand, long wool Mao Jiya of the fabric product can be deformed to affect the product quality, on the other hand, the thickness of the long-wool fabric is thicker, and a collection mode of the rolled up fabric needs to occupy a large amount of space, so that workers need to take out the product in the storage device frequently, the working efficiency is greatly reduced, and the collection requirement of the fabric product of the long cloth cannot be met.

Therefore, a new cloth feeding mechanism is needed.

Disclosure of Invention

The application aims to provide a novel cloth feeding mechanism to solve the problems that in the prior art, the cloth feeding speed is fixed, the cloth feeding tension is uncontrollable, the cloth feeding requirements of complex and various plush fabric products cannot be met, the quality requirements of the plush fabric products which are gradually improved cannot be met, and the like.

The embodiment of the application can be realized by the following technical scheme:

A novel cloth feeding mechanism, which comprises a rotary seat, a first driving device connected with the rotary seat, a cloth feeding roller linkage mechanism and a storage barrel, wherein the cloth feeding roller linkage mechanism is connected above the rotary seat, the storage barrel is positioned below the rotary seat, the top of the storage barrel is connected with the inner edge of the rotary seat, and the first driving device drives the rotary seat to rotate along the circumferential direction of the rotary seat and drives the lower cloth roller linkage mechanism and the storage barrel to synchronously rotate along the circumferential direction of the rotary seat;

The cloth feeding mechanism further comprises an inner tooth gear ring, an outer tooth gear ring and a second driving device, wherein the inner tooth gear ring and the outer tooth gear ring are arranged up and down in a concentric circle manner, the power input end of the cloth feeding roller linkage mechanism is meshed with the inner tooth gear ring and the outer tooth gear ring, and the second driving device drives the inner tooth gear ring and the outer tooth gear ring to rotate along the circumferential direction of the rotary seat;

And the rotating speed difference between the rotating seat and the inner and outer gear rings is adjusted, so that the power input end of the lower cloth roller linkage mechanism is driven to perform differential motion.

Further, the swivel mount is annular rotation fluted disc, the outside holding of swivel mount is in the shell, just the lower part of shell is connected with the support frame under the supporting role of support frame, the bottom suspension of receiving barrel is in ground top.

Further, the second driving device is a variable-frequency speed regulation driving mechanism, and the rotating speed difference between the rotating seat and the inner and outer tooth gear rings is regulated by changing the rotating speed and/or the rotating direction output by the second driving device.

Further, lower cloth roller link gear includes first interior drive mechanism, second interior drive mechanism, transmission case and lower cloth roller, lower cloth roller is by two long running rollers be clearance fit's clamping assembly, lower cloth roller is followed the radial direction setting of swivel mount, lower cloth roller's both ends respectively through second interior drive mechanism the transmission case fixed connection in the mesa of swivel mount.

Further, the power input end of the second internal transmission mechanism is connected with the power output end of the first internal transmission mechanism and is used for transmission, the base of the first internal transmission mechanism is fixedly connected to the table top of the rotary seat, and the power input end of the first internal transmission mechanism is meshed with the internal gear ring and the external gear ring.

Further, the first inner transmission mechanism comprises a driver and an inner transmission gear, and the bottom of the driver is fixedly connected to the table top of the swivel seat;

The inner transmission gear is a power input end of the lower cloth roller linkage mechanism, the inner transmission gear is connected to the lower portion of the driver through a transmission shaft inside the driver and drives a gear at the top of the driver to rotate, and the gear at the top of the driver is connected with the power input end of the second inner transmission mechanism for transmission.

Further, the rotary seat comprises a rotary track and a containing groove, wherein the rotary track is a ladder groove arranged along the circumferential direction of the rotary seat, and the inner tooth gear ring and the outer tooth gear ring are contained at the rotary track;

The accommodating groove is a groove arranged on the table top of the swivel base, the accommodating groove is communicated with the rotating track in the radial direction, and the inner transmission gear is accommodated in the accommodating groove.

Further, the rotation track is disposed at an outer diameter of the swivel mount and adjacent to the outer teeth of the swivel mount.

Further, the housing includes a second drive connection groove in which an outer drive gear is accommodated, and the outer teeth of the inner and outer gear rings are connected with the second drive device through the outer drive gear.

Further, the inner transmission gear is meshed with the inner teeth of the inner and outer tooth gear rings.

The novel cloth feeding mechanism provided by the embodiment of the application has at least the following beneficial effects:

According to the application, the second driving device is additionally arranged to drive the inner and outer toothed gear rings to rotate, and the power input end of the lower cloth roller linkage mechanism fixedly connected to the swivel base is meshed and connected with the inner and outer toothed gear rings, so that under the respective driving actions of the first driving device and the second driving device, the swivel base can independently rotate on the swivel base while driving the lower cloth roller linkage mechanism to synchronously rotate, and the rotating speed difference formed between the lower cloth roller linkage mechanism and the inner and outer toothed gear rings drives the power input end of the lower cloth roller linkage mechanism to perform differential motion, thereby realizing that the rotating speed of the power input end of the lower cloth roller linkage mechanism can be regulated by changing the rotating speed and/or the rotating direction output by the second driving device, further realizing the flexible cloth discharging effect of continuously adjustable cloth discharging speed, controllable cloth discharging tension and controllable cloth discharging width of the lower cloth roller linkage mechanism, and having the advantages of simple structure, reliable function, easiness in realization and strong practicability.

According to the application, the lower cloth roller linkage mechanism, the storage barrel and the rotary seat are synchronously rotated, so that the lower cloth roller linkage mechanism and the storage barrel are relatively static, when the lower cloth roller linkage mechanism clamps the fabrics to move downwards, the long wool fabrics can be continuously stacked in the storage barrel under the action of gravity, the space for collecting long wool fabric products in the transverse direction is effectively enlarged, long wool fabric products of longer cloth can be collected in the same space, workers do not need to frequently participate in taking materials, and in addition, compared with the storage mode of collecting the long wool fabrics by rolling, the phenomenon that the long wool fabrics are extruded and deformed due to the fact that the lower and upper stacked fabrics do not have extrusion force is effectively avoided, the product quality is improved, and the long wool fabric collecting machine has the advantages of high production efficiency, strong practicability and the like.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a novel cloth feeding mechanism of the present application;

FIG. 2 is a schematic diagram of the upper structure of a novel cloth feeding mechanism according to the present application;

FIG. 3 is a schematic view of the internal transmission structure of the present application;

FIG. 4 is an exploded view of the internal transmission structure of the present application;

Fig. 5 and 6 are schematic views of the transmission of the internal and external gear rings engaged with the internal transmission gear at different directions.

Reference numerals in the figures

S-shell, S1-first driving connecting groove, S2-second driving connecting groove, 1-swivel seat, 11-rotating track, 12-containing groove, 2-inner tooth gear ring, 3-first driving device, 4-second driving device, 5-first inner transmission mechanism, 51-driver, 52-inner transmission gear, 6-second inner transmission mechanism, 7-transmission case, 8-lower cloth roller, 9-main transmission mechanism, 10-outer transmission gear, 20-containing barrel and 30-supporting frame.

Detailed Description

The present application will be further described below based on preferred embodiments with reference to the accompanying drawings.

In addition, various components on the drawings have been enlarged (thick) or reduced (thin) for ease of understanding, but this is not intended to limit the scope of the application.

The singular forms also include the plural and vice versa.

In the description of the embodiments of the present application, it should be noted that, if the terms "upper," "lower," "inner," "outer," and the like indicate an azimuth or a positional relationship based on that shown in the drawings, or an azimuth or a positional relationship that a product of the embodiments of the present application conventionally put in use, it is merely for convenience of describing the present application and simplifying the description, and does not indicate or imply that the device or element to be referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present application. Furthermore, in the description of the present application, terms first, second, etc. are used herein for distinguishing between different elements, but not limited to the order of manufacture, and should not be construed as indicating or implying any relative importance, as such may be different in terms of its detailed description and claims.

The terminology used in the description presented herein is for the purpose of describing embodiments of the application and is not intended to be limiting of the application. It should also be noted that unless explicitly stated or limited otherwise, the terms "disposed," "connected," and "connected" should be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, directly connected, indirectly connected via an intermediate medium, or communicating between two elements. The specific meaning of the above terms in the present application will be specifically understood by those skilled in the art.

Fig. 1 is a schematic diagram of the overall structure of a novel cloth feeding mechanism of the present application, fig. 2 is a schematic diagram of the upper structure of the novel cloth feeding mechanism of the present application, as shown in fig. 1 and fig. 2, the novel cloth feeding mechanism comprises a rotary seat 1, an inner gear ring and an outer gear ring 2, a first driving device 3, a second driving device 4, a lower cloth roller linkage mechanism and a storage barrel 20, wherein the lower cloth roller linkage mechanism and the storage barrel 20 are connected with the rotary seat 1, and the first driving device 3 drives the rotary seat 1 to rotate and drives the lower cloth roller linkage mechanism and the storage barrel 20 to synchronously rotate along the circumferential direction of the rotary seat 1;

The inner and outer gear rings 2 and the rotary seat 1 are arranged up and down in a concentric circle manner, the power input end of the lower cloth roller linkage mechanism is meshed with the inner and outer gear rings 2, and the second driving device 4 drives the inner and outer gear rings 2 to rotate along the circumferential direction of the rotary seat 1;

The rotating speed difference between the rotary seat 1 and the inner and outer gear rings 2 is adjusted, so that the rotating speed difference is formed between the lower cloth roller linkage mechanism and the inner and outer gear rings 2, and the power input end of the lower cloth roller linkage mechanism is driven to perform differential motion. .

Specifically, the rotary seat 1 is an annular rotary fluted disc, the middle part of the rotary seat 1 is vertically penetrated, the radial direction of the rotary seat 1 is followed, two ends of the lower cloth roller linkage mechanism are respectively connected to the upper part of the rotary seat 1, the outer part of the rotary seat 1 is accommodated in the shell S, the lower part of the shell S is connected with the support frame 30, and the rotary seat 1 is positioned above the ground and is not contacted with the ground under the supporting action of the support frame 30.

The storage barrel 20 is a barrel with an accommodating space inside, the storage barrel 20 is located below the rotary seat 1, the top of the storage barrel 20 is connected to the inner edge of the rotary seat 1, the bottom of the storage barrel 20 is suspended above the ground and is not contacted with the ground, and the friction resistance is generated between the ground and the storage barrel 20 when the rotary seat 1 drives the storage barrel 20 to synchronously rotate.

In some preferred embodiments, the housing S includes a first driving connection slot S1, where the main transmission mechanism 9 is accommodated in the first driving connection slot S1, and the swivel base 1 is connected to the first driving device 3 through the main transmission mechanism 9, so that the swivel base 1 can rotationally displace along the circumferential direction thereof under the driving action of the first driving device 3.

In some preferred embodiments, the housing S further includes a second driving connection slot S2, an outer driving gear 10 is accommodated in the second driving connection slot S2, and the inner and outer gear rings 2 are connected with the second driving device 4 through the outer driving gear 10, so that the outer driving gear 10 drives the inner and outer gear rings 2 to independently rotate above the swivel base 1 under the driving action of the second driving device 4.

The power input end of the lower cloth roller linkage mechanism is meshed with the inner and outer gear rings 2, and as the lower cloth roller linkage mechanism is fixedly connected to the table top of the rotary seat 1, the power input end of the lower cloth roller linkage mechanism is meshed with the inner and outer gear rings 2, when the rotary speed between the rotary seat 1 and the inner and outer gear rings 2 forms a rotary speed difference, the rotary speed can be compensated by rotating the gear at the power input end of the lower cloth roller linkage mechanism, so that the rotary speed difference between the rotary seat 1 and the inner and outer gear rings 2 can be adjusted by changing the rotary speed and/or steering of the second driving device 4 to drive the inner and outer gear rings 2, and then the rotary speed of the power input end of the lower cloth roller linkage mechanism is adjusted, so that the cloth discharging speed of the lower cloth roller linkage mechanism can be continuously adjusted.

In some preferred embodiments, the second driving device 4 is a variable-frequency speed-adjusting driving mechanism capable of continuously changing speed, for example, the second driving device 4 may be a direct-current speed-adjusting motor or an alternating-current variable-frequency speed-adjusting motor, or may be a variable-frequency speed-adjusting mechanism matched by a speed reducer and a servo motor, and the specific structure is not further limited herein, so long as the rotation speed and/or the rotation direction output by the second driving device 4 can be adjusted, and the rotation speed and/or the rotation direction of the outer driving gear 10 driven by the second driving device 4 can be adjusted.

Specifically, as shown in fig. 1, the lower cloth roller linkage mechanism includes a first inner transmission mechanism 5, a second inner transmission mechanism 6, a transmission case 7 and a lower cloth roller 8, the rotary base 1 is of a ring-shaped fluted disc structure, the lower cloth roller 8 is arranged along the radial direction of the rotary base 1, the lower cloth roller 8 is a clamping assembly with two long rollers being in variable clearance fit, two ends of the lower cloth roller 8 are fixedly connected to the table top of the rotary base 1 through the second inner transmission mechanism 6 and the transmission case 7 respectively, and under the action of the second inner transmission mechanism 6 and the transmission case 7, the two long rollers of the lower cloth roller 8 are driven to reversely rotate inwards to form acting force for clamping fabrics to be tensioned downwards and towed, so that the fabrics are stacked and retracted into the storage barrel 20.

The power input end of the second inner transmission mechanism 6 is connected with the power output end of the first inner transmission mechanism 5 and is used for transmission, the base of the first inner transmission mechanism 5 is fixedly connected to the table top of the rotary seat 1, the power input end of the first inner transmission mechanism 5 is meshed with the inner and outer tooth gear rings 2 and transmits power to the second inner transmission mechanism 6 through the power output end of the first inner transmission mechanism, and the second inner transmission mechanism 6 drives the lower cloth roller 8 to rotate and clamp fabrics.

Fig. 3 is a schematic view of an internal transmission structure in the present application, and fig. 4 is an exploded view of the internal transmission structure in the present application, as shown in fig. 3 and 4, the rotary base 1 includes a rotation track 11, the rotation track 11 is a ladder groove disposed along the circumference of the rotary base 1, and the inner and outer gear ring 2 is accommodated in the rotary base 1, so that the rotary base 1 can stably rotate on the rotary base 1.

In some preferred embodiments, the rotating track 11 is disposed at the outer diameter of the rotary seat 1 and is adjacent to the outer teeth of the rotary seat 1, and the outer driving gear 10 is meshed with the outer teeth of the inner and outer tooth gear rings 2, so as to optimize layout and avoid occupying the inner space of the rotary seat 1, so that the fabric with a wider breadth can be clamped under the condition that the volume of the cloth feeding mechanism is the same.

In some preferred embodiments, the rotary base 1 further includes a receiving groove 12, where the receiving groove 12 is a groove formed on a table top of the rotary base 1, the power input end of the first inner transmission mechanism 5 is received in the receiving groove 12, and the receiving groove 12 is radially penetrated with the rotating track 11, so that the power input end of the first inner transmission mechanism 5 can be meshed with the inner and outer toothed ring gear 2.

Specifically, the first inner transmission mechanism 5 includes a driver 51 and an inner transmission gear 52, the inner transmission gear 52 is a power input end of the lower cloth roller linkage mechanism, the inner transmission gear 52 is accommodated in the accommodating groove 12, the inner transmission gear 52 is meshed with inner teeth of the inner and outer gear rings 2 to transmit, the inner transmission gear 52 is connected to the lower part of the driver 51 through a transmission shaft inside the driver 51 and drives a gear at the top of the driver 51 to rotate, and the bottom of the driver 51 is fixedly connected to a table top of the rotary seat 1, so that under the action of a rotation speed difference between the rotary seat 1 and the inner and outer gear rings 2, the inner transmission gear 52 can perform differential rotation in the accommodating groove 12 and transmit a rotation speed to the gear at the top of the inner transmission gear 52.

In some preferred embodiments, the inner transmission gear 52 is a magnetic transmission device, and a gear at the top of the inner transmission gear 52 is a magnetic gear, so that compared with other transmission devices, the magnetic transmission device has the advantages of simple structure, fewer component members, fewer failure points, strong power transmission capability, automatic over-torque slipping protection and the like, and can improve transmission accuracy.

In some preferred embodiments, the power input end of the second internal transmission mechanism 6 is connected with the gear at the top of the first internal transmission mechanism 5 through a belt for transmission, and compared with chain and gear transmission, belt transmission can avoid the phenomenon of blocking of transmission to a certain extent, and has the advantage of high transmission precision.

In some preferred embodiments, the rotary base 1 is in gear engagement with the main transmission mechanism 9, and the main transmission mechanism 9 is connected to the first driving device 3 through a belt, so as to provide a power source for the rotation of the rotary base 1 through the first driving device 3.

The acceleration and deceleration of the novel cloth feeding mechanism of the application is described in detail below by referring to the transmission schematic diagrams of the inner and outer gear rings in fig. 5 and 6 which are matched with the inner transmission gear in different directions.

As shown in fig. 5, when the outer driving gear 10 drives the inner and outer gear rings 2 to rotate along the direction of the arrow, the first driving device 3 drives the rotary base 1 to rotate along the direction of the arrow through the main driving mechanism 9, and drives the driver 51 fixedly connected to the rotary base 1 to rotate synchronously, the rotary base 1 and the inner and outer gear rings 2 turn the same direction, if the rotation speed of the rotary base 1 is greater than the rotation speed of the inner and outer gear rings 2, the inner driving gear 52 rotates clockwise along the arrow, at this time, the rotation speed transmitted to the top output end of the driver 51 through the inner driving gear 52 is lower, the lower cloth roller linkage mechanism is equivalent to performing deceleration rotation, and if the rotation speed of the rotary base 1 is less than the rotation speed of the inner and outer gear rings 2, the inner driving gear 52 rotates anticlockwise, and the rotation speed transmitted to the top output end of the driver 51 through the inner driving gear 52 is greater, and the lower cloth roller linkage mechanism is equivalent to performing acceleration rotation.

On the contrary, as shown in fig. 6, when the outer driving gear 10 drives the inner and outer gear rings 2 to rotate along the direction of the arrow shown in the drawing, the first driving device 3 drives the rotary base 1 to rotate along the direction of the arrow shown in the drawing through the main driving mechanism 9, and drives the driver 51 fixedly connected to the rotary base 1 to rotate synchronously, the rotary base 1 rotates in the opposite direction to the inner and outer gear rings 2, the inner driving gear 52 rotates clockwise along the arrow shown in the drawing, at this time, the rotation speed transmitted to the top output end of the driver 51 through the inner driving gear 52 is higher, and the lower cloth roller linkage mechanism is equivalent to performing accelerated rotation.

While the foregoing is directed to embodiments of the present application, other and further embodiments of the application may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.

Claims (6)

1. Novel cloth mechanism down, including swivel mount (1) and first drive arrangement (3) that are connected with it, cloth roller link gear, storage barrel (20) down, its characterized in that:

the lower cloth roller linkage mechanism is connected to the upper part of the rotary seat (1), the storage barrel (20) is positioned below the rotary seat (1), the top of the storage barrel (20) is connected to the inner edge of the rotary seat (1), and the first driving device (3) drives the rotary seat (1) to rotate along the circumferential direction of the rotary seat and drives the lower cloth roller linkage mechanism and the storage barrel (20) to synchronously rotate along the circumferential direction of the rotary seat (1);

The cloth feeding mechanism further comprises an inner tooth gear ring and an outer tooth gear ring (2) and a second driving device (4), wherein the inner tooth gear ring and the outer tooth gear ring (2) are arranged up and down in a concentric circle mode with the rotary seat (1), the power input end of the cloth feeding roller linkage mechanism is meshed with the inner tooth gear ring and the outer tooth gear ring (2), and the second driving device (4) drives the inner tooth gear ring and the outer tooth gear ring (2) to rotate along the circumferential direction of the rotary seat (1);

the rotating speed difference between the rotating seat (1) and the inner and outer gear rings (2) is adjusted, so that the power input end of the lower cloth roller linkage mechanism is driven to perform differential motion;

the rotary seat (1) is an annular rotary fluted disc, the outer part of the rotary seat (1) is accommodated in the shell (S), the lower part of the shell (S) is connected with the support frame (30), and under the supporting action of the support frame (30), the bottom of the storage barrel (20) is suspended above the ground;

the second driving device (4) is a variable-frequency speed regulation driving mechanism, and the rotating speed difference between the rotating seat (1) and the inner and outer tooth gear rings (2) is regulated by changing the rotating speed and/or the rotating direction output by the second driving device (4);

The lower cloth roller linkage mechanism comprises a first inner transmission mechanism (5), a second inner transmission mechanism (6), a transmission box (7) and a lower cloth roller (8), wherein the lower cloth roller (8) is a clamping assembly formed by two long rollers in clearance fit, the lower cloth roller (8) is arranged along the radial direction of the rotary seat (1), and two ends of the lower cloth roller (8) are fixedly connected to the table top of the rotary seat (1) through the second inner transmission mechanism (6) and the transmission box (7) respectively;

the power input end of the second internal transmission mechanism (6) is connected with the power output end of the first internal transmission mechanism (5) and is used for transmission, the base of the first internal transmission mechanism (5) is fixedly connected to the table top of the rotary seat (1), and the power input end of the first internal transmission mechanism (5) is meshed with the internal gear ring and the external gear ring (2).

2. The novel cloth feeding mechanism according to claim 1, wherein:

the first inner transmission mechanism (5) comprises a driver (51) and an inner transmission gear (52), and the bottom of the driver (51) is fixedly connected to the table top of the swivel base (1);

The inner transmission gear (52) is a power input end of the lower cloth roller linkage mechanism, the inner transmission gear (52) is connected to the lower portion of the driver (51) through a transmission shaft inside the driver (51) and drives a gear at the top of the driver (51) to rotate, and the gear at the top of the driver (51) is connected with the power input end of the second inner transmission mechanism (6) for transmission.

3. The novel cloth feeding mechanism according to claim 2, wherein:

the rotary seat (1) comprises a rotary track (11) and a containing groove (12), the rotary track (11) is a ladder groove arranged along the circumferential direction of the rotary seat (1), and the inner tooth gear ring and the outer tooth gear ring (2) are contained at the rotary track (11);

The accommodating groove (12) is a groove arranged on the table top of the rotary seat (1), the accommodating groove (12) is communicated with the rotary track (11) along the radial direction, and the inner transmission gear (52) is accommodated in the accommodating groove (12).

4. A novel cloth feeding mechanism according to claim 3, wherein:

the rotating track (11) is arranged at the outer diameter of the rotary seat (1) and is adjacent to the outer teeth of the rotary seat (1).

5. The novel cloth feeding mechanism according to claim 4, wherein:

The shell (S) comprises a second driving connecting groove (S2), an outer transmission gear (10) is arranged in the second driving connecting groove (S2), and the outer teeth of the inner and outer tooth gear rings (2) are connected with the second driving device (4) through the outer transmission gear (10).

6. The novel cloth feeding mechanism according to claim 5, wherein:

the inner transmission gear (52) is meshed with the inner teeth of the inner and outer tooth gear rings (2).