CN113584658A - Wool and tree fiber mixed spinning yarn processing device - Google Patents

Abstract

The invention relates to the technical field of spinning, in particular to a processing device for blending wool and tree fibers into yarns. The invention solves the problem that cotton threads are always in a soft state after being reeled from a thread cylinder and large winding gaps can be generated among processed yarns through the structural matching of the extrusion assembly and the transmission assembly in the prior art.

Description

Wool and tree fiber mixed spinning yarn processing device

Technical Field

The invention relates to the technical field of spinning, in particular to a processing device for blending wool and tree fibers into yarn.

Background

The blended spinning is a textile product which is made by mixing and spinning chemical fiber and other natural fibers such as cotton wool, silk, hemp and the like, has the advantages of both the style of terylene and the strength of cotton fabrics, such as polyester cotton cloth, polyester wool and gabardine and the like, the existing textile machine twists a plurality of animal and plant fibers together to be spun into threads or yarns which can be used for weaving into cloth.

Present weaving machine is mostly direct with wool and the direct doubling of fibre twists into the yarn, in the process of spinning, the release will be followed bobbin surface to wool cotton thread and tree fibre cotton thread rolling, twist into a line with two lines through weaving machine again, because at the twisting in-process, wool cotton thread and tree fibre cotton thread are the soft state after the bobbin surface is rolled up from the bobbin surface always, after the weaving machine twists the line again, great winding space will appear between the yarn that wool cotton thread and tree fibre cotton thread processing came out, the gauze that adopts this type of yarn spinning to be not pleasing to the eye enough, the phenomenon of pilling easily appears simultaneously, in view of this, we have proposed a processing apparatus that wool and tree fibre mixed spun into yarn.

Disclosure of Invention

The invention aims to provide a processing device for blending wool and tree fibers into yarns, which solves the problems that wool cotton threads and tree fiber cotton threads proposed in the background technology are always in a soft state after being wound and unwound from the surface of a bobbin, and large winding gaps are formed between the wool cotton threads and the yarns processed by the tree fiber cotton threads after the wool cotton threads and the tree fiber cotton threads are twisted by a textile machine.

In order to achieve the purpose, the invention provides the following technical scheme: a processing device for blending wool and tree fibers into yarns comprises a base, a support A, a support B, a support C, a support D and a wire block A, wherein the support A is fixedly installed on one side of the upper surface of the base, the support B is fixedly installed on one side of the upper surface of the base corresponding to the support A, the support C is fixedly installed between the support A and the support B on the upper surface of the base, the support D is fixedly installed between the support C and the support A on the upper surface of the base, the wire block A is fixedly installed on the upper surface of the support D, a driving component is transversely arranged above the base, a pay-off component is arranged on the inner side surface of the support A close to the end part of the support A, an extrusion component is arranged on the side surface of the support A below the pay-off component, a transmission component is arranged below the extrusion component and structurally matched with the extrusion component, and a doubling component is arranged on one side of the end part of the support C, and a wire feeding assembly is arranged on one side of the support C, which is far away from the doubling assembly, and a wire winding assembly is arranged on one side of the support B, which is close to the wire feeding assembly.

Preferably, drive assembly includes axis of rotation, gear A, motor and gear B, rotate between support A and the support C and run through and establish the axis of rotation, the axis of rotation tip is located the coaxial fixed mounting gear A in support A one side, the base upper surface is located gear A one side fixed mounting motor, motor output tip fixed mounting gear B, and gear B is connected with the motor meshing.

Preferably, the paying-off assembly comprises a bobbin A, a bobbin B, a mounting bar and a reversing wheel, the inner side of the support A is close to the end parts and is symmetrically and fixedly mounted with the bobbin A and the bobbin B respectively, the side surface of the support A is located below the bobbin A and is fixedly mounted with the mounting bar, and the two ends of the side surface of the mounting bar are symmetrically and fixedly mounted with the reversing wheel.

Preferably, the extrusion assembly comprises a connecting frame, a guide post A, a sliding block, a spring A, a rotating sleeve, a guide post B, a spring B and a bevel block, the side surface of the bracket A is positioned below the pay-off component and is fixedly provided with a connecting frame, the side wall of the connecting frame is symmetrically and fixedly provided with guide posts A, the outer surfaces of the guide posts A are all sleeved with sliding blocks in a sliding manner, springs A are sleeved on the outer surfaces of the guide posts A between the sliding blocks and the side walls of the connecting frame, the sliding block is elastically connected with the side wall of the connecting frame through a spring A, the inner side surface of the sliding block is rotatably provided with a rotating sleeve, a guide post B is vertically fixed on the side surface of the bracket A between the rotating sleeves, the outer surface of the guide post B is sleeved with a bevel block in a sliding way, and the inclined plane block is in sliding extrusion fit with the rotating sleeve, the outer surface of the guide pillar B is positioned between the inclined plane block and the end part of the guide pillar B, and the inclined plane block is elastically connected with the end part of the guide pillar B through the spring B.

Preferably, transmission assembly includes bull stick A, pinion rack, half tooth piece and pulley group A, support A side surface is located bevel block below and rotates installation bull stick A, guide pillar B surface is located bevel block below slip cap and establishes the pinion rack, and pinion rack upper surface and bevel block fixed connection, half tooth piece of bull stick A tip fixed mounting, and half tooth piece is connected with the meshing of pinion rack.

Preferably, the doubling assembly comprises a rotating rod B, a wire guide block B, a wire guide hole A, a belt pulley set B and a wire guide hole B, the wire guide hole B is formed in the position, close to the end part, of the side surface of the support C, the rotating rod B is rotatably installed at the position, below the wire guide hole B, of the side surface of the support C, the wire guide hole A is formed in the side surface of the wire guide block B in a symmetrical mode, the belt pulley set B is arranged between the rotating rod B and the rotating shaft, and the rotating rod B is in transmission connection with the rotating shaft through the belt pulley set B.

Preferably, send line subassembly to include guide arm C, send line piece, wire guide C and pneumatic cylinder, support C is close to support B one side fixed surface installation fixed block, fixed surface installation guide arm C on the fixed block, guide arm C surface slip cap establishes and sends the line piece, send line piece surface to be close to tip position and open wire guide C, fixed block side fixed surface installation pneumatic cylinder, and the flexible tip of pneumatic cylinder with send line piece end fixed connection.

Preferably, the winding assembly comprises a rotary column, a bevel gear A, a bevel gear B and a winding reel, the rotary column is rotatably installed between the end part of the support B and the base, the winding reel is fixedly sleeved on the outer surface of the rotary column close to the end part of the support B, the bevel gear A is fixedly installed on the end part of the rotary shaft, the bevel gear B is fixedly sleeved on the outer surface of the rotary column corresponding to the bevel gear A, and the bevel gear B is meshed with the bevel gear A.

Compared with the prior art, the invention has the beneficial effects that:

1. through the structural cooperation of the extrusion assembly and the transmission assembly, the problem that cotton threads are always in a soft state after being reeled from a bobbin and large winding gaps can be generated among processed yarns in the prior art is solved, the gear plate moves upwards and extrudes the inclined plane block to move upwards in the device, the connecting frame is elastically compressed to be compressed, meanwhile, the inclined plane end of the inclined plane block extrudes the surface of the rotating sleeve, the rotating sleeve and the inclined plane block are in rolling extrusion, the sliding block drives the tree fiber cotton threads and the wool cotton threads to move towards two sides along the guide pillar A respectively, the spring A is elastically compressed, the tension of the cotton threads is increased by increasing the traction force, so that the cotton threads cannot have large gaps during twisting, and the processed yarns are more compact and attached;

2. through the cooperation of sending line subassembly and spiral subassembly, realization that can be fine is to the rolling function of yarn, combines pneumatic cylinder continuous operation in this device, and the flexible end of pneumatic cylinder drives the intermittent type and send the line piece to reciprocate along guide arm C, forms effectual reciprocating motion to through wire guide B's limiting displacement, make yarn even winding about the surface at the spool.

Drawings

FIG. 1 is a schematic front view of the overall structure of the present invention;

FIG. 2 is a schematic view of a driving assembly according to the present invention;

FIG. 3 is a schematic view of the pay-off assembly of the present invention;

FIG. 4 is a schematic view of the extrusion assembly of the present invention;

FIG. 5 is a schematic view of a doubling assembly according to the present invention;

FIG. 6 is a schematic view of the wire feeding assembly of the present invention;

fig. 7 is a schematic structural view of the wire winding assembly of the present invention.

The reference numbers in the figures illustrate: 1. a base; 101. a bracket A; 102. a bracket B; 103. a support C; 104. a support D; 105. a lead block A; 2. a drive assembly; 201. a rotating shaft; 202. a gear A; 203. a motor; 204. a gear B; 3. a pay-off assembly; 301. a bobbin A; 302. a bobbin B; 303. mounting a bar; 304. a reversing wheel; 4. an extrusion assembly; 401. a connecting frame; 402. a guide pillar A; 403. a slider; 404. a spring A; 405. rotating the sleeve; 406. a guide pillar B; 407. a spring B; 408. a bevel block; 5. a transmission assembly; 501. a rotating rod A; 502. a toothed plate; 503. a half-tooth block; 504. a pulley set A; 6. a doubling component; 601. a rotating rod B; 602. a lead block B; 603. a wire guide hole A; 604. a pulley set B; 605. a wire guide hole B; 7. a wire feeding assembly; 701. a guide bar C; 702. a wire feeding block; 703. a wire guide C; 704. a hydraulic cylinder; 705. a fixed block; 8. a wire winding assembly; 801. turning the column; 802. a bevel gear A; 803. a bevel gear B; 804. a winding reel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides an embodiment: a processing device for blending wool and tree fibers into yarns comprises a base 1, a support A101, a support B102, a support C103, a support D104 and a lead block A105, wherein the support A101 is fixedly installed on one side of the upper surface of the base 1, the support B102 is fixedly installed on one side of the upper surface of the base 1 corresponding to the support A101, the support C103 is fixedly installed between the support A101 and the support B102 on the upper surface of the base 1, the support D104 is fixedly installed between the support C103 and the support A101 on the upper surface of the base 1, the lead block A105 is fixedly installed on the upper surface of the support D104, a driving component 2 is transversely arranged above the base 1, a pay-off component 3 is arranged on the inner side surface of the support A101 close to the end of the support A101, an extrusion component 4 is arranged on the side surface of the support A101 and below the pay-off component 3, a transmission component 5 is arranged below the extrusion component 4, and the transmission component 5 is structurally matched with the extrusion component 4, the wire doubling component 6 is arranged at one side of the end of the support C103, the wire feeding component 7 is arranged at one side, away from the wire doubling component 6, of the support C103, and the wire winding component 8 is arranged at one side, close to the wire feeding component 7, of the support B102.

Further, drive assembly 2 includes axis of rotation 201, gear A202, motor 203 and gear B204, rotate between support A101 and the support C103 and run through and establish axis of rotation 201, axis of rotation 201 tip is located the coaxial fixed mounting gear A202 in support A101 one side, base 1 upper surface is located gear A202 one side fixed mounting motor 203, motor 203 output end portion fixed mounting gear B204, and gear B204 is connected with the meshing of motor 203, and motor 203 work drives gear B204 and rotates, can drive axis of rotation 201 through the meshing transmission effect of gear B204 and gear A202 and rotate, provides stable power for whole device.

Further, the paying-off assembly 3 comprises a bobbin A301, a bobbin B302, a mounting bar 303 and a reversing wheel 304, the inner side of the support A101 is close to the end portions and is respectively and fixedly mounted with the bobbin A301 and the bobbin B302, the side surface of the support A101 is located below the bobbin A301 and is fixedly mounted with the mounting bar 303, the two ends of the side surface of the mounting bar 303 are symmetrically and fixedly mounted with the reversing wheel 304, the surface of the bobbin B302 is wound with wool cotton threads, the surface of the bobbin A301 is wound with tree fiber cotton threads, and in the twisting processing of the tree fiber cotton threads and the wool cotton threads, the wool cotton threads and the tree fiber cotton threads are respectively reversed by being wound on the surface of the reversing wheel 304, so that the cotton threads are conveniently guided into the next processing step.

Further, the extrusion assembly 4 comprises a connecting frame 401, a guide post a402, a sliding block 403, a spring a404, a rotating sleeve 405, a guide post B406, a spring B407 and a bevel block 408, the connecting frame 401 is fixedly installed on the side surface of the support a101 below the pay-off assembly 3, the guide post a402 is symmetrically and fixedly installed on the side wall of the connecting frame 401, the sliding block 403 is slidably sleeved on the outer surface of the guide post a402, the spring a404 is sleeved on the outer surface of the guide post a402 between the sliding block 403 and the side wall of the connecting frame 401, the sliding block 403 is elastically connected with the side wall of the connecting frame 401 through the spring a404, the rotating sleeve 405 is rotatably installed on the inner side surface of the sliding block 403, the guide post B406 is vertically fixed between the rotating sleeves 405 on the side surface of the support a101, the bevel block 408 is slidably sleeved on the outer surface of the guide post B406, the bevel block 408 is slidably and is in press fit with the rotating sleeve 405, the spring B407 is sleeved on the outer surface of the guide post B406 between the bevel block 408 and the end of the guide post B406, and the inclined plane piece 408 passes through spring B407 and guide pillar B406 tip elastic connection, inclined plane piece 408 upwards moves, link 401 elastic pressure compresses, inclined plane piece 408 inclined plane end will extrude the rotating sleeve 405 surface simultaneously, the rotating sleeve 405 rolls with inclined plane piece 408 and extrudes, sliding block 403 drives respectively tree fiber cotton thread and wool cotton thread and moves to both sides along guide pillar A402, and spring A404 elastic compression, through increase traction force, make cotton tension increase, cause the cotton thread can not have great space when twisting, make the laminating that tightens more of the yarn that processes out.

Further, the transmission assembly 5 includes a rotating rod a501, a toothed plate 502, a half toothed block 503 and a belt pulley set a504, the side surface of the support a101 is located below the inclined block 408 and rotatably mounts the rotating rod a501, the outer surface of the guide post B406 is located below the inclined block 408 and slidably sleeves the toothed plate 502, the upper surface of the toothed plate 502 is fixedly connected with the inclined block 408, the half toothed block 503 is fixedly mounted at the end of the rotating rod a501 and is engaged with the toothed plate 502, the rotating shaft 201 can drive the rotating rod a501 to rotate under the transmission action of the belt pulley set a504, the half toothed block 503 rotates along with the rotating rod, and through the engagement action of the half toothed block 503 and the toothed plate 502, the toothed plate 502 can be driven to move upwards along the surface of the guide post B406 in a clearance manner, and the toothed plate 502 can well realize a clearance extrusion action.

Further, the doubling component 6 comprises a rotating rod B601, a wire guide block B602, a wire guide hole a603, a pulley set B604 and a wire guide hole B605, wherein the wire guide hole B605 is formed in the position, close to the end, of the side surface of the support C103, the rotating rod B601 is rotatably installed at the position, below the wire guide hole B605, of the side surface of the support C103, the wire guide block B602 is fixedly installed at the end of the rotating rod B601, the wire guide hole a603 is symmetrically formed in the side surface of the wire guide block B602, the pulley set B604 is arranged between the rotating rod B601 and the rotating shaft 201, the rotating rod B601 is in transmission connection with the rotating shaft 201 through the pulley set B604, the rotating shaft 201 can drive the rotating rod B601 to rotate through the transmission effect of the pulley set B604, the rotating rod B601 can drive the wire guide block B602 to rotate, under the separation and limiting effects of the wire guide block B602, two cotton threads can be rotatably wound and led out through the wire guide hole B605, and the twisting and the doubling function of the cotton threads can be well realized.

Further, the thread feeding assembly 7 comprises a guide rod C701, a thread feeding block 702, a thread guide hole C703 and a hydraulic cylinder 704, a fixed block 705 is fixedly mounted on the surface of one side, close to the support B102, of the support C103, the guide rod C701 is fixedly mounted on the upper surface of the fixed block 705, the thread feeding block 702 is slidably sleeved on the outer surface of the guide rod C701, the thread guide hole C703 is formed in the position, close to the end portion, of the outer surface of the thread feeding block 702, the hydraulic cylinder 704 is fixedly mounted on the side surface of the fixed block 705, the telescopic end portion of the hydraulic cylinder 704 is fixedly connected with the end portion of the thread feeding block 702, the hydraulic cylinder 704 continuously works, the telescopic end of the hydraulic cylinder 704 intermittently drives the thread feeding block 702 to move up and down along the guide rod C701 to form effective reciprocating movement, and accordingly, threads are uniformly wound on the surface of the winding drum 804 up and down through the limiting effect of the thread guide hole C.

Further, the winding assembly 8 includes a rotary column 801, a bevel tooth a802, a bevel tooth B803 and a winding reel 804, the rotary column 801 is rotatably installed between the end of the support B102 and the base 1, the winding reel 804 is fixedly sleeved on the outer surface of the rotary column 801 near the end of the support B102, the bevel tooth a802 is fixedly installed on the end of the rotary shaft 201, the bevel tooth B803 is fixedly sleeved on the outer surface of the rotary column 801 corresponding to the bevel tooth a802, the bevel tooth B803 is meshed with the bevel tooth a802, the twisted cotton thread passes through the thread guide hole C703 and then is wound on the surface of the winding reel 804, the rotary shaft 201 can drive the rotary column 801 to rotate through the meshing transmission action of the bevel tooth a802 and the bevel tooth B803, and the winding reel 804 can conveniently rotate and wind the yarn.

The working principle is as follows: when the device is used, wool cotton threads are wound on the surface of a thread cylinder B302, tree fiber cotton threads are wound on the surface of a thread cylinder A301, the wool cotton threads and the tree fiber cotton threads are respectively wound on the surface of a reversing wheel 304 and reversed in direction in the twisting process of the tree fiber cotton threads and the wool cotton threads, then the wool cotton threads and the tree fiber cotton threads are led into thread holes of a sliding block 403, then the wool cotton threads and the tree fiber cotton threads are respectively led into a wire guide block A105 and then pass through a wire guide hole A603, the wool cotton threads and the tree fiber cotton threads are twisted together and then led out through a wire guide hole B605, then the doubling thread is led out from a wire guide hole C703, then the end part of the doubling thread is wound on the surface of a thread winding cylinder 804, after the preparation is finished, a motor 203 works to drive a gear B204 to rotate, a rotating shaft 201 can be driven to rotate through the meshing transmission action of a gear B204 and a gear A202, the rotating shaft 201 can drive a rotating rod A501 to rotate under the transmission action of a wheel set A504, and a half-tooth block 503 can rotate along with the twisting thread block, through the meshing action of the half-tooth block 503 and the tooth plate 502, the tooth plate 502 can be driven to move upwards along the surface of the guide pillar B406 at a clearance, the extrusion inclined plane block 408 moves upwards in the upward movement process of the tooth plate 502, the connecting frame 401 is elastically pressed to be compressed, meanwhile, the inclined plane end of the inclined plane block 408 extrudes the surface of the rotating sleeve 405, the rotating sleeve 405 and the inclined plane block 408 are extruded in a rolling mode, the sliding block 403 respectively drives the tree fiber cotton threads and the wool cotton threads to move towards two sides along the guide pillar A402, the spring A404 is elastically compressed, the tension of the cotton threads is increased through increasing the traction force, so that no larger gap exists when the cotton threads are twisted, the processed yarns are more tightly attached, when the half-tooth block 503 is separated from the tooth plate 502, the extrusion inclined plane block 408 slides downwards along the guide pillar B406 to reset under the elastic action of the spring B407, the inclined plane of the inclined plane block 408 is separated from the rotating sleeve 405, and simultaneously under the elastic action of the spring A404, the rotating shaft 201 can drive the rotating rod B601 to rotate through the transmission action of the belt pulley set B604, the rotating rod B601 can drive the wire guide block B602 to rotate, under the separation limiting action of the wire guide block B602, two cotton threads can be wound in a rotating mode and guided out through the wire guide hole B605, the twisting and doubling functions of the cotton threads can be well realized, the twisted cotton threads penetrate through the wire guide hole C703 and then are wound on the surface of the winding reel 804, the rotating shaft 201 can drive the rotating column 801 to rotate through the meshing transmission action of the bevel teeth A802 and the bevel teeth B803, the winding reel 804 is driven to rotate and wind the yarns, meanwhile, the hydraulic cylinder 704 continuously works, the telescopic end of the hydraulic cylinder 704 intermittently drives the wire feeding block 702 to move up and down along the guide rod C701 to form effective reciprocating movement, and the yarns can be uniformly wound on the surface of the winding reel 804 up and down through the limiting action of the wire guide hole C703, by the above processing, a yarn having a small twist gap can be obtained.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (8)

1. The utility model provides a processingequipment of yarn is blended with tree fiber to wool, includes base (1), support A (101), support B (102), support C (103), support D (104) and wire piece A (105), its characterized in that: the device is characterized in that a support A (101) is fixedly installed on one side of the upper surface of a base (1), a support B (102) is fixedly installed on one side of the upper surface of the base (1) and corresponds to the support A (101), a support C (103) is fixedly installed on the upper surface of the base (1) and is positioned between the support A (101) and the support B (102), a support D (104) is fixedly installed on the upper surface of the base (1) and is positioned between the support C (103) and the support A (101), a lead block A (105) is fixedly installed on the upper surface of the support D (104), a driving assembly (2) is transversely arranged above the base (1), a pay-off assembly (3) is arranged on the inner side surface of the support A (101) close to the end of the support A (101), an extruding assembly (4) is arranged on the side surface of the support A (101) and is positioned below the pay-off assembly (3), and a transmission assembly (5) is arranged below the extruding assembly (4), and transmission assembly (5) and extrusion component (4) structure cooperation, support C (103) tip one side department is equipped with doubling subassembly (6), one side that doubling subassembly (6) were kept away from in support C (103) is equipped with and send line subassembly (7), one side that support B (102) are close to and send line subassembly (7) is equipped with spiral subassembly (8).

2. A processing apparatus for blending wool with tree fibers to form a yarn according to claim 1, wherein: drive assembly (2) include axis of rotation (201), gear A (202), motor (203) and gear B (204), rotate between support A (101) and support C (103) and run through and establish axis of rotation (201), axis of rotation (201) tip is located support A (101) one side coaxial fixed mounting gear A (202), base (1) upper surface is located gear A (202) one side fixed mounting motor (203), motor (203) output end fixed mounting gear B (204), and gear B (204) and motor (203) meshing are connected.

3. A processing apparatus for blending wool with tree fibers to form a yarn according to claim 1, wherein: unwrapping wire subassembly (3) are including a line section of thick bamboo A (301), a line section of thick bamboo B (302), mounting bar (303) and reverse wheel (304), support A (101) inboard is close to tip position fixed mounting line section of thick bamboo A (301) and a line section of thick bamboo B (302) of symmetry respectively, support A (101) side surface is located a line section of thick bamboo A (301) below position fixed mounting bar (303), mounting bar (303) side surface both ends department symmetry fixed mounting reverse wheel (304).

4. A processing apparatus for blending wool with tree fibers to form a yarn according to claim 1, wherein: the extrusion assembly (4) comprises a connecting frame (401), guide pillars A (402), sliding blocks (403), springs A (404), rotating sleeves (405), guide pillars B (406), springs B (407) and inclined blocks (408), the connecting frame (401) is fixedly installed at the position below the pay-off assembly (3) on the side surface of the support A (101), the guide pillars A (402) are symmetrically and fixedly installed on the side wall of the connecting frame (401), the sliding blocks (403) are slidably sleeved on the outer surfaces of the guide pillars A (402), the springs A (404) are sleeved on the outer surfaces of the guide pillars A (402) between the sliding blocks (403) and the side wall of the connecting frame (401), the sliding blocks (403) are elastically connected with the side wall of the connecting frame (401) through the springs A (404), the rotating sleeves (405) are rotatably installed on the inner side surfaces of the sliding blocks (403), and the guide pillars B (406) are vertically fixed on the side surface of the support A (101) between the rotating sleeves (405), the outer surface of the guide post B (406) is sleeved with an inclined block (408) in a sliding mode, the inclined block (408) is matched with the rotating sleeve (405) in a sliding and extruding mode, the outer surface of the guide post B (406) is located between the inclined block (408) and the end portion of the guide post B (406) and sleeved with a spring B (407), and the inclined block (408) is elastically connected with the end portion of the guide post B (406) through the spring B (407).

5. A processing apparatus for blending wool with tree fibers to form a yarn as claimed in claim 4, wherein: the transmission assembly (5) comprises a rotating rod A (501), a toothed plate (502), a half toothed block (503) and a belt pulley group A (504), the side surface of the support A (101) is located below the inclined surface block (408) and rotatably mounted with the rotating rod A (501), the outer surface of the guide column B (406) is located below the inclined surface block (408) and slidably sleeved with the toothed plate (502), the upper surface of the toothed plate (502) is fixedly connected with the inclined surface block (408), the end part of the rotating rod A (501) is fixedly mounted with the half toothed block (503), and the half toothed block (503) is meshed with the toothed plate (502).

6. A processing apparatus for blending wool with tree fibers to form a yarn as claimed in claim 2, wherein: doubling subassembly (6) are including bull stick B (601), wire guide block B (602), wire guide A (603), pulley group B (604) and wire guide B (605), wire guide B (605) is opened near tip department to support C (103) side surface, support C (103) side surface is located wire guide B (605) below position rotation installation bull stick B (601), bull stick B (601) tip fixed mounting wire guide block B (602), wire guide A (603) are opened to wire guide B (602) side surface symmetry, be equipped with pulley group B (604) between bull stick B (601) and axis of rotation (201), and bull stick B (601) are connected with axis of rotation (201) transmission through pulley group B (604).

7. A processing apparatus for blending wool with tree fibers to form a yarn according to claim 1, wherein: send line subassembly (7) including guide arm C (701), send line piece (702), wire guide C (703) and pneumatic cylinder (704), support C (103) are close to support B (102) one side fixed surface installation fixed block (705), fixed surface fixed mounting guide arm C (701) on fixed block (705), send line piece (702) is established to guide arm C (701) surface slip cover, send line piece (702) surface to be close to tip position and open wire guide C (703), fixed block (705) side fixed surface installs pneumatic cylinder (704), and pneumatic cylinder (704) flexible tip and send line piece (702) tip fixed connection.

8. A processing apparatus for blending wool with tree fibers to form a yarn as claimed in claim 2, wherein: spiral subassembly (8) are including changeing post (801), awl tooth A (802), awl tooth B (803) and winding reel (804), rotate between support B (102) tip and base (1) and install commentaries on classics post (801), commentaries on classics post (801) surface is close to support B (102) tip fixed position and is established winding reel (804), axis of rotation (201) tip fixed mounting awl tooth A (802), it establishes awl tooth B (803) to change post (801) surface and the fixed cover of awl tooth A (802) department of correspondence, and awl tooth B (803) and awl tooth A (802) meshing are connected.

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