CN113308769A

CN113308769A - Processing and winding device for fiber blended yarns

Info

Publication number: CN113308769A
Application number: CN202110872370.4A
Authority: CN
Inventors: 吴国华
Original assignee: Jiangsu Baisheng Home Textile Co ltd
Current assignee: Jiangsu Baisheng Home Textile Co ltd
Priority date: 2021-07-30
Filing date: 2021-07-30
Publication date: 2021-08-27
Anticipated expiration: 2041-07-30
Also published as: CN113308769B

Abstract

The invention relates to the technical field of spinning, in particular to a fiber blended yarn processing and winding device which comprises a winding mechanism, a driving mechanism, a positioning guide mechanism and a bottom plate, wherein the winding mechanism is arranged on the bottom plate; the invention can solve the problems that the existing winding device has poor fixing effect on the winding sleeves, cannot clamp and fix the winding sleeves with different diameters, has limitation on the winding range of yarns, cannot stably conduct guide transmission in the yarn transmission process, is easy to break due to abrasion in the yarn winding process, has poor stability in the transmission process, is easy to jump, has the phenomenon of unsmooth yarn conveying, directly influences the winding quality of the yarns, causes the inside of the wound yarns to be loose and not attractive, cannot meet the winding requirement of the yarns and the like.

Description

Processing and winding device for fiber blended yarns

Technical Field

The invention relates to the technical field of spinning, in particular to a processing and winding device for fiber blended yarns.

Background

The yarn is a textile, a continuous strip made of textile fibers, which is thin, soft and has certain mechanical properties, and can be used for various fabrics and braided fabrics. The yarns in the current market are various in variety, the technical requirements on the yarns are higher and higher, and the yarns with better functions are needed to meet the market demands. The blended yarn is made by mixed spinning of two or more fibers, and the strength of the whole yarn is increased by combining the original fiber raw materials with other fibers with high strength and high modulus.

The yarn winding is a key technology in the production of fiber filaments, and is a process for winding the yarn into various coils in textile production so as to facilitate the storage and transportation of the yarn and the processing of the next procedure; when to the yarn rolling, need use to take-up device, today's take-up device is relatively poor to the fixed effect of taking up the sleeve, can not carry out the centre gripping to the take-up sleeve of different diameter sizes fixed, make the rolling scope of yarn have the limitation, can not stably carry out the direction transmission in yarn data send process, make the yarn at the in-process of rolling, very easily break because of receiving wearing and tearing, the transmission stationarity is poor, take place to beat easily, and then the phenomenon of defeated line not smooth appears, the rolling quality of direct influence yarn, lead to the inside loose unaesthetic of yarn after the rolling, can't satisfy the rolling requirement of yarn.

In order to solve the problems, the invention provides a fiber blended yarn processing and winding device.

Disclosure of Invention

In order to achieve the purpose, the invention adopts the following technical scheme that the fiber blended yarn processing and winding device comprises a winding mechanism, a driving mechanism, a positioning and guiding mechanism and a bottom plate, wherein the driving mechanism is installed on the bottom plate, the winding mechanism is evenly arranged on the driving mechanism, the positioning and guiding mechanism is arranged right behind the driving mechanism, and the positioning and guiding mechanism is installed on the bottom plate.

The winding mechanism comprises a worm wheel, a straight cylinder, a compression spring, a first ball, a ring plate, a rocking handle rotating frame, a sliding frame, an upright rod, a floating block and a clamping unit; the worm wheel is arranged on the cross beam support through a bearing, a straight cylinder is arranged on an inner ring of the worm wheel in a sliding fit mode, the straight cylinder is of a cavity structure, a compression spring is arranged at the lower end of the straight cylinder and connected between the lower end of the straight cylinder and the bottom end face of the worm wheel, a first ball is rotatably arranged at the bottom of the straight cylinder and is abutted against a driving mechanism, a ring plate is arranged on an outer ring at the upper end of the straight cylinder and is positioned right above the worm wheel, a rocking handle rotating frame is arranged on the outer ring of the ring plate in a threaded fit mode, the top end of the rocking handle rotating frame is mutually connected with the bottom end of a sliding frame through a bearing, the sliding frame is arranged on the straight cylinder in a sliding fit mode, a vertical rod is arranged at the top end of the sliding frame and is positioned on the inner side of the straight cylinder, the vertical rod is mutually connected with the straight cylinder in a sliding fit mode, two floating blocks which are sequentially arranged along the length direction of the vertical rod are arranged on the vertical rod, the outer ring of the upper end of the straight cylinder is evenly provided with clamping units along the circumferential direction in a sliding fit mode.

Preferably, the clamping unit comprises a clamping plate, a supporting rod, a second ball and a cylindrical spring; splint pass through the sliding fit mode and install on a straight section of thick bamboo, the inner wall of splint is gone up the symmetry and is installed branch, the branch axle head is rotated and is installed ball two, and ball two supports and leans on the kicking block lateral wall, the outer lane of branch is provided with cylindrical spring, and cylindrical spring connects between the medial surface of the one end of keeping away from splint and a straight section of thick bamboo at branch.

Preferably, the driving mechanism comprises a beam support, a stepping motor, a straight rod, a worm, a cam, a chain wheel, a chain and a servo motor; crossbeam support mounting on the bottom plate, install step motor through the motor cabinet on crossbeam support's the left side outer wall, and step motor's output shaft passes through the shaft coupling and the axle head interconnect of straight-bar, the straight-bar passes through the bearing and installs on crossbeam support top, be provided with a plurality of worms of evenly arranging along its length direction on the straight-bar, and the worm passes through meshing mode and worm wheel interconnect, the cam has been put to the equipartition under the worm, the cam passes through the bearing and installs on crossbeam support's inner wall, the front end of cam runs through crossbeam support and installs the sprocket, connect through chain drive between the sprocket, servo motor passes through the motor cabinet and installs on crossbeam support front side middle part outer wall, and servo motor's output shaft passes through flange and sprocket interconnect.

Preferably, the positioning guide mechanism comprises a main beam support, an upright plate, a guide unit, a spur rack, a sliding plate, a base and a hand wheel screw; girder support mounting on the bottom plate, be provided with a plurality of upright plates of evenly arranging along its width direction on the terminal surface of girder support, be provided with a plurality of guide unit of evenly arranging along its length direction on the upright plate, be provided with a plurality of spur racks that are linear along its width direction through the sliding fit mode on the terminal surface of girder support, the spur rack is connected with guide unit through the meshing mode, and the one end of spur rack is connected with the outer wall of slide, the slide passes through the sliding fit mode and installs on the base, the pedestal mounting is on the lateral wall of girder support, install the hand wheel lead screw through the bearing on the base, and the hand wheel lead screw passes through screw-thread fit mode and slide interconnect.

Preferably, the guide unit comprises a gear disc, a slide rod, a roller and a pulley; the gear disc pass through the bearing and install on upright board, and the gear disc is connected with the spur rack through the meshing mode, the gear disc front side has evenly arranged the slide bar along its circumference, slide bar one end is connected with upright board lateral wall through the sliding fit mode, the gyro wheel is installed through the bearing to the other end of slide bar, the pulley is installed through the bearing to the slide bar rear side.

Preferably, grooves are uniformly formed in the circumferential direction of the outer ring at the lower end of the straight cylinder.

Preferably, the floating block is of a conical structure.

Preferably, a plurality of arc waist holes are formed in the circumferential direction of the gear disc, the pulley is connected with the arc waist holes in the gear disc in a rolling mode, and one end, far away from the pulley, of each arc waist hole is obliquely arranged towards the outer side face of the gear disc.

The invention has the beneficial effects that: according to the invention, the gear disc is pushed and rotated through the engagement of the spur rack, so that the gear disc rotates anticlockwise, the gear disc rotates to move to abut against the pulley, the pulley moves according to the inclined guide track of the arc-shaped waist hole, the slide rods are synchronously controlled to adjust the distance, and the rollers on the slide rods are in rolling contact with the surfaces of yarns, so that the guide transmission effect is achieved, and the guide transmission requirements of yarns with various diameters can be met.

The yarn conveying device has the advantages that the roller is in rolling contact with the yarns in the conveying process, so that the friction resistance can be reduced, the yarns are prevented from being broken due to the increase of the friction force, the yarns can be kept in a straightening state in the conveying process, the phenomenon that the yarns are not smoothly conveyed due to the shake in the conveying process is prevented, the stability in the conveying process of the yarns is improved, the yarns are prevented from being wound loosely, the winding requirement of the yarns is met, and the inner parts of the wound yarns are kept in a tight state.

The tapered outer ring with the continuously increased floating block is abutted against the clamping unit, so that the clamping unit is expanded outwards, the inner wall of the take-up sleeve is clamped and fixed, the stability of the yarn in the winding process can be improved, the clamping and fixing requirements of take-up sleeves with various diameters can be met, the take-up sleeve is prevented from slipping during winding, and the winding quality can be effectively improved.

The worm is meshed with the driving worm wheel to rotate, so that the worm wheel synchronously drives the straight cylinder to rotate, then the cam rotates to abut against the first ball, the straight cylinder performs reciprocating lifting action, the yarn is wound on the winding sleeve uniformly and tightly, the yarn winding neatness and attractiveness are improved, and the yarn winding quality is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the left side perspective of the home position of the present invention.

FIG. 2 is a schematic perspective view of the right side orientation of the home position of the present invention.

Fig. 3 is a perspective view of the rear view position of the present invention.

Fig. 4 is a partial enlarged view of the invention at a in fig. 3.

Fig. 5 is a schematic perspective view of a part of the positioning and guiding mechanism of the present invention.

Fig. 6 is a schematic perspective view of a portion of the home position of the present invention.

Fig. 7 is a schematic perspective view of the winding mechanism of the present invention.

Fig. 8 is a three-dimensional structural section view of the winding mechanism of the invention.

Fig. 9 is a partial enlarged view of the invention at B in fig. 8.

Fig. 10 is a partial enlarged view of the invention at C in fig. 8.

Fig. 11 is a schematic perspective view of the carriage and the straight tube of the present invention.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further described below by combining with the specific drawings, and it is to be noted that the embodiments and the features in the embodiments can be combined with each other in the application without conflict.

As shown in fig. 1 to 11, a fiber blended yarn processing winding device comprises a winding mechanism 1, a driving mechanism 2, a positioning guide mechanism 3 and a bottom plate 4, wherein the bottom plate 4 is provided with the driving mechanism 2, the winding mechanism 1 is uniformly arranged on the driving mechanism 2, the positioning guide mechanism 3 is arranged right behind the driving mechanism 2, and the positioning guide mechanism 3 is arranged on the bottom plate 4.

The driving mechanism 2 comprises a beam bracket 20, a stepping motor 21, a straight rod 22, a worm 23, a cam 24, a chain wheel 25, a chain 26 and a servo motor 27; the cross beam support 20 is installed on the bottom plate 4, a stepping motor 21 is installed on the outer wall of the left side of the cross beam support 20 through a motor base, an output shaft of the stepping motor 21 is connected with the shaft end of a straight rod 22 through a coupler, the straight rod 22 is installed at the top end of the cross beam support 20 through a bearing, a plurality of worms 23 evenly distributed along the length direction of the straight rod 22 are arranged on the straight rod 22, the worms 23 are connected with a worm wheel 10 in a meshing mode, cams 24 are evenly arranged right below the worms 23, the cams 24 are installed on the inner wall of the cross beam support 20 through bearings, the front end of each cam 24 penetrates through the cross beam support and is provided with a chain wheel 25, the chain wheels 25 are in transmission connection through a chain 26, a servo motor 27 is installed on the outer wall of the middle of the front side of the cross beam support 20 through the motor base, and the output shaft of the servo motor 27 is connected with the chain wheels 25 through flanges; the straight rod 22 is driven to rotate by the stepping motor 21, the worm 23 is meshed with the transmission worm wheel 10 to perform a rotating action, the chain wheel 25 is driven to rotate by the servo motor 27, and the plurality of cams 24 are linked to perform a rotating action under the transmission action of the transmission chain 26.

The winding mechanism 1 comprises a worm wheel 10, a straight cylinder 11, a compression spring 12, a first ball 13, a ring plate 14, a rocking handle rotating frame 15, a sliding frame 16, a vertical rod 17, a floating block 18 and a clamping unit 19; the worm wheel 10 is arranged on the cross beam support 20 through a bearing, the inner ring of the worm wheel 10 is provided with a straight cylinder 11 in a sliding fit mode, the straight cylinder 11 is of a cavity structure, grooves are uniformly arranged in the circumferential direction of the outer ring of the lower end of the straight cylinder 11, and the straight cylinder 11 is in concave-convex fit connection with the worm wheel 10 through the grooves, so that the straight cylinder 11 can perform rotating action along with the worm wheel 10 while sliding and lifting; the lower end of the straight cylinder 11 is provided with a compression spring 12, the compression spring 12 is connected between the lower end of the straight cylinder 11 and the bottom end face of the worm wheel 10, the bottom of the straight cylinder 11 is rotatably provided with a first ball 13, the first ball 13 abuts against the upper end of the cam 24, the annular plate 14 is arranged on the outer ring of the upper end of the straight cylinder 11, the annular plate 14 is positioned right above the worm wheel 10, the outer ring of the annular plate 14 is provided with a rocking handle rotating frame 15 in a threaded fit mode, the top end of the rocking handle rotating frame 15 is connected with the bottom end of the sliding frame 16 through a bearing, the sliding frame 16 is arranged on the straight cylinder 11 in a sliding fit mode, the top end of the sliding frame 16 is provided with a vertical rod 17, the vertical rod 17 is positioned on the inner side of the straight cylinder 11, the vertical rod 17 is connected with the straight cylinder 11 in a sliding fit mode, the vertical rod 17 is provided with two floating blocks 18 which are sequentially arranged along the length direction of the vertical rod 17, and the floating blocks 18 are in a conical structure; clamping units 19 are uniformly arranged on the outer ring of the upper end of the straight cylinder 11 along the circumferential direction in a sliding fit mode; the clamping space is adjusted according to the diameter size of the take-up sleeve, the rocking handle rotating frame 15 is rotated by workers to enable the rocking handle rotating frame 15 to rotate and rise along the thread guide track of the annular plate 14, the pushing sliding frame 16 floats and rises along the guide groove formed on the straight cylinder 11 to enable the floating block 18 on the upright rod 17 to synchronously float and rise, then the conical outer ring continuously increased by the floating block 18 pushes against the clamping unit 19 to enable the clamping unit 19 to expand outwards, so that the inner wall of the take-up sleeve is clamped and fixed, the stability in the take-up process of yarns can be improved, the clamping and fixing requirements of the take-up sleeve with various diameter sizes are met, after the take-up sleeve is clamped and fixed, the worm 23 is meshed with the driving worm wheel 10 to perform a rotating action to enable the worm wheel 10 to drive the straight cylinder 11 to rotate, then the cam 24 is rotated to abut against the ball I13 to enable the straight cylinder 11 to perform reciprocating lifting action along the vertical direction, therefore, the yarn can be uniformly and tightly wound on the take-up sleeve, the compression spring 12 always pushes the straight cylinder 11 in the process, and the first ball 13 at the bottom end of the straight cylinder 11 is tightly contacted with the cam 24.

The clamping unit 19 comprises a clamping plate 191, a support rod 192, a second ball 193 and a cylindrical spring 194; the clamp plate 191 is arranged on the straight cylinder 11 in a sliding fit mode, the support rods 192 are symmetrically arranged on the inner wall of the clamp plate 191, the shaft ends of the support rods 192 are rotatably provided with the second balls 193, the second balls 193 abut against the side wall of the floating block 18, the outer ring of the support rods 192 is provided with the cylindrical spring 194, and the cylindrical spring 194 is connected between one end of the support rods 192, far away from the clamp plate 191, and the inner side face of the straight cylinder 11; along with the change of the relative position of the floating block 18 and the second ball 193, the supporting rod 192 slides and translates outwards, the inner wall of the take-up sleeve is clamped and fixed through the clamping plate 191, the cylindrical spring 194 always supports and pushes the supporting rod 192 in the process, and the second ball 193 on the supporting rod 192 is in close contact with the outer ring surface of the floating block 18, so that the stability of clamping the take-up sleeve is guaranteed.

The positioning guide mechanism 3 comprises a main beam bracket 30, an upright plate 31, a guide unit 32, a spur rack 33, a sliding plate 34, a base 35 and a hand wheel screw 36; the main beam support 30 is installed on the bottom plate 4, a plurality of vertical plates 31 which are uniformly distributed along the width direction of the main beam support 30 are arranged on the end face of the main beam support 30, a plurality of guide units 32 which are uniformly distributed along the length direction of the vertical plates 31 are arranged on the end face of the main beam support 30, a plurality of straight racks 33 which are linearly distributed along the width direction of the main beam support are arranged on the end face of the main beam support 30 in a sliding fit mode, the straight racks 33 are connected with the guide units 32 in a meshing mode, one ends of the straight racks 33 are connected with the outer wall of a sliding plate 34, the sliding plate 34 is installed on a base 35 in a sliding fit mode, the base 35 is installed on the side wall of the main beam support 30, a hand wheel lead screw 36 is installed on the base 35 through a bearing, and the hand wheel lead screw 36 is connected with the sliding plate 34 in a thread fit mode; according to the different of the diameter size of the conveyed yarn, a worker shakes the hand wheel screw 36 to enable the hand wheel screw 36 to control the horizontal position of the sliding plate 34 on the base 35, the sliding plate 34 pushes against the spur rack 33, the spur rack 33 is meshed with the push-turn guide unit 32, the distance between the guide units 32 is adjusted, and the yarn can be stably conveyed in the winding process.

The guide unit 32 comprises a gear disc 321, a slide rod 322, a roller 323 and a pulley 324; the gear disc 321 is mounted on the vertical plate 31 through a bearing, the gear disc 321 is connected with the spur rack 33 through a meshing mode, sliding rods 322 are uniformly arranged on the front side of the gear disc 321 along the circumferential direction of the gear disc, one end of each sliding rod 322 is connected with the side wall of the vertical plate 31 through a sliding fit mode, a roller 323 is mounted at the other end of each sliding rod 322 through a bearing, a pulley 324 is mounted on the rear side of each sliding rod 322 through a bearing, a plurality of arc-shaped waist holes are formed in the circumferential direction of the gear disc 321, the pulleys 324 are connected with the arc-shaped waist holes in the gear disc 321 through a rolling mode, and one end, far away from the pulleys 324, of each arc-shaped waist hole is obliquely arranged towards the outer side face of the gear disc 321; the spur rack 33 is meshed with the push-turn gear disc 321 to make the gear disc 321 rotate, the gear disc 321 pushes against the pulley 324 when rotating, the pulley 324 moves according to the inclined guide track of the arc waist hole, thereby synchronously controlling the position of the slide rod 322, and making the roller 323 on the slide rod 322 contact with the surface of the yarn in a rolling way, thereby playing a role of guiding yarns with various diameters.

The method specifically comprises the following steps: s1, clamping and adjusting: the clamping distance of the winding mechanism 1 is adjusted according to the diameter size of the winding sleeve, a worker rotates the rocking handle rotating frame 15 to enable the rocking handle rotating frame 15 to rotate and rise along the thread guide track of the annular plate 14, the pushing sliding frame 16 floats and rises along a guide groove formed in the straight cylinder 11 to enable the floating block 18 on the vertical rod 17 to float and rise synchronously, then the conical outer ring continuously increased through the floating block 18 pushes against the clamping unit 19, and the clamping unit 19 expands outwards to clamp and fix the inner wall of the winding sleeve.

S2, guiding and adjusting: the position of the positioning guide mechanism 3 is adjusted according to the diameter of the yarn, a worker shakes the hand wheel screw 36, the hand wheel screw 36 controls the sliding plate 34 to horizontally move on the base 35, the sliding plate 34 pushes against the spur rack 33, the spur rack 33 pushes the guide unit 32, the distance between the guide units 32 is adjusted, and the yarn can be stably transmitted in the winding process.

S3, reciprocating rolling: the worm 23 is meshed with the driving worm wheel 10 to perform a rotating action, the worm wheel 10 drives the straight cylinder 11 to rotate, and then the cam 24 rotates to abut against the first ball 13, so that the straight cylinder 11 performs reciprocating lifting action in the vertical direction, and yarns can be uniformly and tightly wound on the winding sleeve.

S4, rolling replacement: and when the wire coil with the specified size is wound on the wire winding sleeve, replacing a new wire winding sleeve and continuing to perform winding operation.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims; the scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a fibre blended yarn processing coiling mechanism, includes winding mechanism (1), actuating mechanism (2), location guiding mechanism (3) and bottom plate (4), its characterized in that: the winding device is characterized in that a driving mechanism (2) is installed on the bottom plate (4), winding mechanisms (1) are uniformly arranged on the driving mechanism (2), a positioning guide mechanism (3) is arranged right behind the driving mechanism (2), and the positioning guide mechanism (3) is installed on the bottom plate (4); wherein:

the winding mechanism (1) comprises a worm wheel (10), a straight cylinder (11), a compression spring (12), a first ball (13), a ring plate (14), a rocking handle rotating frame (15), a sliding frame (16), an upright rod (17), a floating block (18) and a clamping unit (19); the worm wheel (10) is arranged on the driving mechanism (2) through a bearing, the inner ring of the worm wheel (10) is provided with a straight cylinder (11) in a sliding fit mode, the straight cylinder (11) is of a cavity structure, the lower end of the straight cylinder (11) is provided with a compression spring (12), the compression spring (12) is connected between the lower end of the straight cylinder (11) and the bottom end face of the worm wheel (10), the bottom of the straight cylinder (11) is rotatably provided with a ball I (13), the ball I (13) is abutted against the driving mechanism (2), a ring plate (14) is arranged on the outer ring of the straight cylinder (11), the ring plate (14) is positioned right above the worm wheel (10), a rocking handle rotating frame (15) is arranged on the outer ring of the ring plate (14) in a thread fit mode, the top end of the rocking handle rotating frame (15) is mutually connected with the bottom end of the sliding frame (16) through a bearing, and the sliding fit mode is arranged on the straight cylinder (11), upright stanchion (17) is installed on the top of balladeur train (16), and upright stanchion (17) are located the inboard of straight section of thick bamboo (11), and upright stanchion (17) through sliding fit mode and straight section of thick bamboo (11) interconnect, are provided with two kickboards (18) of arranging in proper order along its length direction on upright stanchion (17), straight section of thick bamboo (11) upper end outer lane evenly is provided with through sliding fit mode along its circumference and presss from both sides fixed unit (19).

2. The fiber blended yarn processing and winding device according to claim 1, characterized in that: the clamping unit (19) comprises a clamping plate (191), a support rod (192), a second ball (193) and a cylindrical spring (194); splint (191) install on straight section of thick bamboo (11) through sliding fit, the symmetry install branch (192) on the inner wall of splint (191), branch (192) axle head is rotated and is installed ball two (193), and ball two (193) support and lean on floating block (18) lateral wall, the outer lane of branch (192) is provided with cylindrical spring (194), and cylindrical spring (194) are connected between the medial surface of the inner of branch (192) and straight section of thick bamboo (11).

3. The fiber blended yarn processing and winding device according to claim 1, characterized in that: the driving mechanism (2) comprises a beam support (20), a stepping motor (21), a straight rod (22), a worm (23), a cam (24), a chain wheel (25), a chain (26) and a servo motor (27); the beam support (20) is installed on the bottom plate (4), the stepping motor (21) is installed on the outer wall of the left side of the beam support (20) through a motor base, the output shaft of the stepping motor (21) is connected with the shaft end of the straight rod (22) through a coupler, the straight rod (22) is installed at the top end of the beam support (20) through a bearing, a plurality of worms (23) evenly distributed along the length direction of the straight rod (22) are arranged on the straight rod (22), the worms (23) are connected with the worm wheel (10) through a meshing mode, cams (24) are evenly arranged below the worms (23), the cams (24) are installed on the inner wall of the beam support (20) through bearings, chain wheels (25) are installed at the front end of the cams (24), the chain wheels (25) are in transmission connection through chains (26), the servo motor (27) is installed on the outer wall of the middle of the front side of the beam support (20) through the motor base, and the output shaft of the servo motor (27) is connected with the chain wheel (25) through a flange.

4. The fiber blended yarn processing and winding device according to claim 1, characterized in that: the positioning guide mechanism (3) comprises a main beam support (30), an upright plate (31), a guide unit (32), a spur rack (33), a sliding plate (34), a base (35) and a hand wheel lead screw (36); the main beam support (30) is arranged on the bottom plate (4), a plurality of upright plates (31) which are uniformly distributed along the width direction of the main beam support (30) are arranged on the end surface of the main beam support (30), a plurality of guide units (32) which are uniformly distributed along the length direction of the upright plates (31), a plurality of straight racks (33) which are linearly distributed along the width direction of the main beam support are arranged on the end surface of the main beam support (30) in a sliding fit mode, the straight racks (33) are connected with the guide units (32) in a meshing mode, one end of the spur rack (33) is connected with the outer wall of the sliding plate (34), the sliding plate (34) is arranged on the base (35) in a sliding fit mode, the base (35) is arranged on the side wall of the main beam support (30), a hand wheel screw rod (36) is arranged on the base (35) through a bearing, and the hand wheel lead screw (36) is connected with the sliding plate (34) in a thread matching mode.

5. The fiber blended yarn processing and winding device according to claim 4, characterized in that: the guide unit (32) comprises a gear disc (321), a sliding rod (322), a roller (323) and a pulley (324); gear disc (321) install on upright plate (31) through the bearing, and gear disc (321) are connected with spur rack (33) through the meshing mode, gear disc (321) front side has evenly arranged slide bar (322) along its circumference, the one end of slide bar (322) is connected with upright plate (31) lateral wall through sliding fit mode, gyro wheel (323) are installed through the bearing to the other end of slide bar (322), pulley (324) are installed through the bearing to slide bar (322) rear side.

6. The fiber blended yarn processing and winding device according to claim 1, characterized in that: grooves are uniformly formed in the circumferential direction of the outer ring of the lower end of the straight cylinder (11).

7. The fiber blended yarn processing and winding device according to claim 1, characterized in that: the floating block (18) is of a conical structure.

8. The fiber blended yarn processing and winding device according to claim 5, characterized in that: a plurality of arc waist holes are formed in the circumferential direction of the gear disc (321), the pulley (324) is connected with the arc waist holes in the gear disc (321) in a rolling mode, and one end, far away from the pulley (324), of each arc waist hole is obliquely arranged towards the outer side face of the gear disc (321).