CN112777399A - Finished product transfer system for textile fiber production - Google Patents

Abstract

The invention discloses a finished product transferring system for textile fiber production, which relates to the technical field of textile fiber production, wherein two rows of finished product fiber yarn winding units are rotatably connected at the inner bottom end of a height adjusting unit, a plurality of groups of fiber yarn guiding units are symmetrically arranged at the edges of the front side and the rear side of the top of the height adjusting unit, the finished product fiber yarn winding units can wind a plurality of finished product textile fibers discharged from a textile machine at the same time, the method of manually drawing or even winding the finished product textile fibers in the prior art is replaced, the arranged fiber yarn guiding units can excessively guide each textile fiber to prevent the finished product textile fiber from being broken before winding, the process is carried out on a trolley for transferring the finished product textile fiber, and the system structure integrating the winding and the operation of the textile fiber is realized, thereby greatly shortening the production period of the textile fiber and accelerating the production progress.

Description

Finished product transfer system for textile fiber production

Technical Field

The invention relates to the technical field of textile fiber production, in particular to a finished product transferring system for textile fiber production.

Background

Textile fibers are elongated flexible materials with a length that is thousands of times greater than the diameter, mostly organic high molecular compounds, and a few inorganic compounds. The fibers used for weaving must also have the following physical and chemical properties:

(1) has certain strength, extensibility and elasticity, and can withstand various mechanical forces in the process of textile dyeing and finishing and in use;

(2) has certain length, friction force and cohesion force and strong spinnability. The short fiber can only be used for papermaking or used as a regenerated fiber raw material;

(3) has certain hygroscopicity and thermal invariance, and is favorable for dyeing and finishing and comfort in use;

(4) has better chemical invariance and dyeability, and is originally subjected to water and chemical agents (including acid, alkali, oxidant, reducing agent, part of biological enzyme preparation and the like) used in dyeing and finishing processing. The dyeability ensures that the final textile has bright color and is popular with consumers;

(5) has better sunlight resistance, ultraviolet resistance and weather resistance, and ensures that the textile can be used for a long time. The length and fineness of the textile fibers are two important quality indexes, and the quality of textile processing and finished products is influenced. As long as the length is within the required range, the fineness is generally the most important quality index, and when the fineness is the same, the longer the fiber is, the better the spinning quality is, the coarse fiber is not easy to bend, the fabric has hard hand feeling, the fine fiber is easy to bend, the fabric has soft hand feeling and good drapability.

In the production process of the existing textile fiber, the finished textile fiber needs to be taken down from a textile machine, and the finished textile fiber is wound, and only the wound textile fiber can be transferred to a warehouse for storage;

the existing transfer systems for finished textile fibres are usually only plate lathes, i.e. after the finished textile fibres have been removed from the textile machine, because the prior transfer system does not have the function of winding the finished textile fiber, the textile fiber needs to be wound up manually or on other equipment to be placed on the plate trailer, it is not possible to wind the textile fibres coming out of the textile machine directly on the cylinder by means of this transfer system, thereby causing the above-mentioned process to have a vacuum period, which directly results in a reduction in the production efficiency of textile fibers, and therefore, how to immediately realize winding and transfer after winding of textile fibers which are output from a textile machine in real time by a transfer system, therefore, the production cycle of the textile fiber is greatly shortened, the production progress is accelerated, and the problem to be solved at the present stage in the field is solved urgently.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a finished product transferring system for textile fiber production, which solves the problems that the winding and the transfer after winding of the textile fiber which is output from a textile machine in real time are immediately realized by the transferring system, thereby greatly shortening the production period of the textile fiber and accelerating the production progress.

In order to achieve the purpose, the invention is realized by the following technical scheme: a finished product transfer system for textile fiber production comprises a carrying trolley, wherein a through groove with a rectangular structure is formed in the middle area of the top of the carrying trolley, a box body with an open structure at the top is fixedly installed in the through groove, a group of storage batteries are correspondingly and fixedly installed on two sides in the box body, height adjusting units are jointly installed at four corners of the top end face of the carrying trolley and the bottom end in the box body, two rows of finished product fiber yarn winding units are rotatably connected to the bottom end in the height adjusting units, a plurality of groups of fiber yarn guiding units are symmetrically installed at the edges of the front side and the rear side of the top of each height adjusting unit, the power input starting ends of the finished product fiber yarn winding units all extend to the lower side of each height adjusting unit and are fixedly connected with a driving unit together, and two stand columns are symmetrically installed on two sides of the top end face of each height adjusting unit, a ceiling is fixedly mounted at the top ends of the two upright columns together, and a solar cell panel is fixedly mounted at the top end of the ceiling;

the finished product fiber yarn winding unit comprises a chassis fixedly arranged at the bottom end in the height adjusting unit, a driving shaft lever is rotatably connected inside the chassis, a runway groove is fixedly arranged on the edge of the top end of the chassis, a connecting disc with the same size as the driving shaft lever is arranged above the runway groove, a vertically arranged positioning screw rod is fixedly connected with the center of the top end of the connecting disc, a lower rubber disc with the same size as the connecting disc is fixedly sleeved at the position outside the positioning screw rod and above the connecting disc, a wire winding roller is sleeved at the position outside the positioning screw rod and above the lower rubber disc, an upper rubber disc with the same size as the lower rubber disc is sleeved at the position outside the positioning screw rod and above the wire winding roller, a hand disc is rotatably connected to the position, which is outside the positioning screw and above the upper rubber disc, through threads;

the fiber yarn guiding unit comprises a guiding frame which is fixedly installed at the top edge of the height adjusting unit and is of a 'n' -shaped structure, sliding groove holes which are symmetrically arranged are formed in the end faces of two sides of the guiding frame, the two sliding groove holes are internally and correspondingly connected with an 'I' -shaped limiting column in a sliding mode, the two 'I' -shaped limiting columns are fixedly connected with a bearing frame jointly through adjacent end faces of the 'I' -shaped limiting columns, guiding rubber wheels are rotatably connected inside the 'I' -shaped limiting columns through bearings, an electric telescopic rod is fixedly installed at the top end of the guiding frame, and the telescopic end of the electric telescopic rod extends to the inside of the guiding frame and is fixedly connected with the top end of the bearing frame.

Preferably, a hydraulic rod on-off switch is fixedly mounted on the front side of one lateral end face of the height adjusting unit, and a motor telescopic rod on-off switch is fixedly mounted on the rear side of one lateral end face of the height adjusting unit;

the number of the finished product fiber yarn winding units in the two rows is a plurality, and the position of each finished product fiber yarn winding unit corresponds to one fiber yarn guiding unit.

Preferably, the driven end of the driving shaft rod extends to the lower part of the height adjusting unit and is fixedly connected with the driving unit, and the driving shaft rod, the height adjusting unit and the chassis form a rotary connecting structure through shaft sleeves;

a plurality of universal rollers are fixedly arranged between the runway groove and the connecting disc, the top ends of the universal rollers are fixedly connected with the connecting disc, and the bottom ends of the universal rollers are positioned in the runway groove;

and a threaded rotary connecting structure is formed between the positioning screw rod and the hand disc through an inner screw tube, and the inner screw tube is fixedly arranged at the central position of the hand disc in a penetrating manner.

Preferably, two reinforcing plates in an isosceles triangle shape are symmetrically welded on two sides of the bottom of the guide frame;

a textile fiber yarn is arranged between the top end inside the bearing frame and the top of the guide rubber wheel in an inserting mode.

Preferably, the height adjusting unit comprises a base plate which is arranged right above the carrying trolley and matched with the carrying trolley in size, a rectangular-structure expansion groove is formed in the top end face of the base plate, four corners of the base plate are respectively provided with a rod sleeve in a penetrating type fixedly connected mode, the inside of each rod sleeve is correspondingly and slidably connected with a directional shaft rod, a reinforcing framework in an X-shaped structure is fixedly welded at the bottom end of the base plate, and an electric hydraulic rod is fixedly connected to the bottom end of the X-shaped intersection.

Preferably, the bottom end of each directional shaft lever is fixedly connected with the top end of the carrying trolley, a limiting cap with the diameter size larger than that of the rod sleeve is fixedly welded at the top end of each directional shaft lever, and the bottom end of the electric hydraulic rod is fixedly installed at the bottom end of the interior of the box body and located in the middle of the two storage battery packs.

Preferably, the driving unit comprises a motor mounting bracket fixedly mounted on one side of the bottom end of the height adjusting unit, a three-phase asynchronous motor is fixedly mounted at the bottom of the motor mounting bracket, and the plurality of component fiber yarn winding units are connected with each other and the driving ends of the component fiber yarn winding units and the three-phase asynchronous motor through transmission structures.

Preferably, the transmission structure comprises a driving synchronous wheel with a small size, a driven synchronous wheel with a large size and a synchronous belt sleeved outside the driving synchronous wheel and the driven synchronous wheel.

Advantageous effects

The invention provides a finished product transfer system for textile fiber production. Compared with the prior art, the method has the following beneficial effects:

1. a finished product transfer system for textile fiber production is characterized in that two rows of finished product fiber yarn winding units are rotatably connected to the bottom end inside a height adjusting unit, a plurality of groups of fiber yarn guiding units are symmetrically arranged on the edges of the front side and the rear side of the top of the height adjusting unit, and the finished product fiber yarn winding units can wind a plurality of finished product textile fibers discharged from a textile machine simultaneously, so that the mode that the finished product textile fibers need to be pulled or even wound manually in the prior art is replaced, the arranged fiber yarn guiding units can excessively carry out on each textile fiber, the problem that the finished product textile fibers are broken before being wound is solved, the process is carried out on a trolley for transferring the finished product textile fibers, namely, the system structure that the textile fibers are wound and operated into a whole is realized, and the production period of the textile fibers is greatly shortened, and the production schedule is accelerated.

2. A finished product transfer system for textile fiber production is characterized in that height adjusting units are jointly installed at four corners of the top end face of a carrying trolley and the inner bottom end of a box body, each height adjusting unit comprises a base plate which is arranged right above the carrying trolley and matched with the carrying trolley in size, a position expanding groove with a rectangular structure is formed in the top end face of the base plate, a rod sleeve is fixedly connected to the four corners of the base plate in a penetrating mode, a directional shaft rod is correspondingly and slidably connected to the inner portion of each rod sleeve, a reinforcing framework in an X-shaped structure is fixedly welded to the bottom end of the base plate, an electric hydraulic rod is fixedly connected to the bottom end of the X-shaped intersection, and the finished product fiber winding unit and the fiber leading-in unit can be adjusted in height during actual use so as to correspond to fiber discharge ports of textile machines with different heights, the practicability of the whole system is improved.

3. A finished product transfer system for textile fiber production, the power input starting end of a finished product fiber yarn winding unit extends to the lower part of a height adjusting unit and is fixedly connected with a driving unit together, the driving unit comprises a motor mounting bracket fixedly mounted on one side of the bottom end of the height adjusting unit, a three-phase asynchronous motor is fixedly mounted at the bottom of the motor mounting bracket, two parts of the plurality of finished product fiber yarn winding units and the driving end of the finished product fiber yarn winding unit and the driving end of the three-phase asynchronous motor are connected through a transmission structure, the transmission structure comprises a driving synchronous wheel with small size, a driven synchronous wheel with large size and a synchronous belt sleeved outside the driving synchronous wheel and the driven synchronous wheel, the structure realizes that the plurality of finished product fiber yarn winding units are driven by one three-phase asynchronous motor when in actual use, and a plurality of finished product fiber yarn winding units can synchronously wind the textile fibers, and the same speed and the same amount are achieved.

4. The utility model provides a finished product transportation system for textile fiber production, through the logical groove of seting up the rectangle structure in the top middle zone at the carrying trolley, there is the box that the top is open structure at the inside fixed mounting who leads to the groove, there is a set of storage battery in the inside both sides of box all corresponding fixed mounting, two stands are installed to bilateral symmetry at height adjusting unit top terminal surface, the common fixed mounting in top of two stands has the ceiling, top fixed mounting at the ceiling has solar cell panel, the structure mentioned above, when the in-service use, solar cell panel can change solar energy into the electric energy, and real-time storage is in storage battery, supply with whole consumer's use, thereby let entire system realize energy-concerving and environment-protective purpose.

Drawings

FIG. 1 is a schematic view of an assembly structure of the present invention;

FIG. 2 is a front view of the present invention in an assembled state;

FIG. 3 is a left side view of the present invention in an assembled state;

FIG. 4 is an exploded view of the present invention;

FIG. 5 is a schematic view showing an assembled structure of the height adjusting unit according to the present invention;

FIG. 6 is an exploded view of the height adjustment unit of the present invention;

FIG. 7 is a schematic structural diagram of a driving unit according to the present invention;

FIG. 8 is an exploded view of the final filament winding unit of the present invention;

FIG. 9 is a schematic view of the assembled structure of the finished filament winding unit of the present invention;

FIG. 10 is a schematic view showing an assembled structure of a fiber introduction unit according to the present invention;

FIG. 11 is a right side view of the fiber introduction unit of the present invention in an assembled state;

FIG. 12 is a top view of the filament introducing unit of the present invention in an assembled state;

FIG. 13 is a cross-sectional view of section A-A of FIG. 12;

fig. 14 is an enlarged view of a portion a of fig. 13.

In the figure: 1. carrying the trolley; 2. a through groove; 3. a box body; 4. a battery pack; 5. a height adjustment unit; 51. a base plate; 52. a position expanding groove; 53. a rod sleeve; 54. an orienting shaft; 55. a limiting cap; 56. reinforcing the framework; 57. an electro-hydraulic lever; 6. a drive unit; 61. a motor mounting bracket; 62. a three-phase asynchronous motor; 63. a driving synchronizing wheel; 64. a driven synchronizing wheel; 65. a synchronous belt; 7. a finished fiber yarn winding unit; 71. a chassis; 72. a drive shaft; 73. a shaft sleeve; 74. a runway groove; 75. a universal roller; 76. a splice tray; 77. positioning a lead screw; 78. a lower rubber disc; 79. a winding roll; 710. an upper rubber disc; 711. a handwheel; 712. an inner wire barrel; 8. a fiber yarn introduction unit; 81. a guide frame; 82. a reinforcing plate; 83. a sliding slot hole; 84. an I-shaped limiting column; 85. a load-bearing frame; 86. a guide rubber wheel; 87. spinning the fiber yarns; 88. an electric telescopic rod; 9. a column; 10. a ceiling; 11. a solar panel; 12. a hydraulic rod on-off switch; 13. the motor telescopic link opens and closes the switch.

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. 1-4, the present invention provides a technical solution: a finished product transfer system for textile fiber production comprises a carrying trolley 1, a through groove 2 with a rectangular structure is formed in the middle area of the top of the carrying trolley 1, a box body 3 with an open top structure is fixedly installed inside the through groove 2, a group of storage batteries 4 are correspondingly and fixedly installed on two sides inside the box body 3, height adjusting units 5 are jointly installed on four corners of the top end face of the carrying trolley 1 and the bottom inside the box body 3, two rows of finished fiber yarn winding units 7 are rotatably connected to the bottom inside the height adjusting units 5, a plurality of groups of fiber yarn guiding-in units 8 are symmetrically installed on the edges of the front side and the rear side of the top of each height adjusting unit 5, the power input starting ends of the finished fiber yarn winding units 7 all extend to the lower side of the height adjusting units 5 and are fixedly connected with a driving unit 6, two upright posts 9 are symmetrically installed on two sides of the top end face of each height adjusting unit 5, the top ends of the two upright posts 9 are fixedly provided with a ceiling 10 together, the top end of the ceiling 10 is fixedly provided with a solar cell panel 11, the front side of one lateral end face of the height adjusting unit 5 is fixedly provided with a hydraulic rod opening and closing switch 12, the rear side of one lateral end face of the height adjusting unit 5 is fixedly provided with a motor telescopic rod opening and closing switch 13, the number of the finished fiber yarn winding units 7 in the two rows is a plurality, and the position of each finished fiber yarn winding unit 7 corresponds to one fiber yarn guiding-in unit 8.

Referring to fig. 8-9, the finished fiber winding unit 7 includes a bottom plate 71 fixedly installed at the bottom end inside the height adjusting unit 5, a driving shaft 72 is rotatably connected inside the bottom plate 71, a runway groove 74 is fixedly installed at the top end edge of the bottom plate 71, a connecting plate 76 having the same size as the driving shaft 72 is installed above the runway groove 74, a vertically installed positioning screw 77 is fixedly connected at the center of the top end of the connecting plate 76, a lower rubber plate 78 having the same size as the connecting plate 76 is fixedly sleeved outside the positioning screw 77 and above the connecting plate 76, a winding roller 79 is sleeved outside the positioning screw 77 and above the lower rubber plate 78, an upper rubber plate 710 having the same size as the lower rubber plate 78 is sleeved outside the positioning screw 77 and above the winding roller 79, a hand plate 711 is rotatably connected outside the positioning screw 77 and above the upper rubber plate 710 by a thread, the driven end of drive shaft pole 72 extends to the below of height control unit 5, and be in the same place with drive unit 6 fixed connection, all form through axle sleeve 73 and rotate connection structure between drive shaft pole 72 and height control unit 5 and the chassis 71, fixed mounting has a plurality of universal gyro wheel 75 between runway groove 74 and the linking dish 76, the top and the linking dish 76 fixed connection of universal gyro wheel 75, and the bottom of universal gyro wheel 75 is located the inside of runway groove 74, form the rotation connection structure of screw thread formula through interior silk section of thick bamboo 712 between positioning screw 77 and the hand dish 711, interior silk section of thick bamboo 712 run through fixed the setting in the central point of hand dish 711.

Referring to fig. 10-14, the fiber guiding unit 8 includes a guiding frame 81 fixedly installed on the top edge of the height adjusting unit 5 and having a zigzag structure, sliding slot holes 83 symmetrically disposed with respect to each other are formed on both side end surfaces of the guiding frame 81, an i-shaped limiting post 84 is correspondingly slidably connected inside each of the two sliding slot holes 83, a carrying frame 85 is fixedly connected to the adjacent end surfaces of the two i-shaped limiting posts 84, a guiding rubber wheel 86 is rotatably connected inside each of the i-shaped limiting posts 84 through a bearing, an electric telescopic rod 88 is fixedly installed on the top end of the guiding frame 81, the telescopic end of the electric telescopic rod 88 extends into the guiding frame 81 and is fixedly connected with the top end of the carrying frame 85, two isosceles triangle-shaped reinforcing plates 82 are symmetrically welded on both sides of the bottom of the guiding frame 81, a textile fiber 87 is inserted between the top end of the inside of the bearing frame 85 and the top of the guide rubber wheel 86.

Referring to fig. 5-6, the height adjustment unit 5 includes a base plate 51 disposed over the carrying trolley 1 and adapted to the carrying trolley 1 in size, a rectangular expansion slot 52 is disposed on a top end surface of the base plate 51, a rod sleeve 53 is fixedly connected to four corners of the base plate 51 in a penetrating manner, a directional shaft rod 54 is correspondingly and slidably connected to the inside of each rod sleeve 53, a reinforcing frame 56 having an "X" shape is fixedly welded to a bottom end of the base plate 51, an electric hydraulic rod 57 is fixedly connected to a bottom end of the "X" shape, a bottom end of each directional shaft rod 54 is fixedly connected to a top end of the carrying trolley 1, a stop cap 55 having a diameter larger than that of the rod sleeve 53 is fixedly welded to a top end of each directional shaft rod 54, a bottom end of the electric hydraulic rod 57 is fixedly mounted to an inside bottom end of the box 3, and is located at a position intermediate between the two battery packs 4.

Referring to fig. 7, the driving unit 6 includes a motor mounting bracket 61 fixedly mounted at one side of the bottom end of the height adjusting unit 5, a three-phase asynchronous motor 62 is fixedly mounted at the bottom of the motor mounting bracket 61, and two of the plurality of component filament winding units 7 and the driving ends of the component filament winding units 7 and the three-phase asynchronous motor 62 are connected through a transmission structure, which includes a driving synchronous wheel 63 with a small size, a driven synchronous wheel 64 with a large size, and a synchronous belt 65 sleeved outside the driving synchronous wheel 63 and the driven synchronous wheel 64.

When in use, firstly, the whole transfer system is parked at a position between two textile machines, and when the finished cellosilk winding unit 7 and the cellosilk guide-in unit 8 are both higher or lower than the height of the discharge port of the textile machines, the whole height of the whole transfer system can be adjusted by the height adjusting unit 5;

during adjustment, the hydraulic rod on-off switch 12 is pressed down to enable the electric hydraulic rod 57 to work normally, the electric hydraulic rod 57 jacks up upwards or carries the X-shaped reinforcing framework 56 downwards to lift, and due to the fact that the reinforcing framework 56 and the base plate 51 are of an integrated structure, the whole base plate 51 and the parts above the base plate 51 are effectively lifted under the action of the four directional shaft rods 54 until a feed port of the fiber yarn guide-in unit 8 is flush with a discharge port of a textile machine, and then subsequent work can be carried out;

subsequently, the finished textile yarn 87 drawn out by the textile machine is introduced into the yarn introducing unit 8, and at the time of introduction, it is necessary to let the drawn-out end of the finished textile yarn 87 pass through between the bearing frame 85 and the guide rubber 86, and then be tied on the top end of the winding roller 79;

then, the motor telescopic rod start-stop switch 13 is pressed down, the electric telescopic rod 88 and the three-phase asynchronous motor 62 are controlled to work simultaneously, the three-phase asynchronous motor 62 drives a transmission structure consisting of the driving synchronous wheels 63, the driven synchronous wheels and the synchronous belts 65 to synchronously rotate, and then each finished product fiber yarn winding unit 7 is driven to rotate at a high speed, so that winding processing of finished product textile fibers is realized, in the winding process, the electric telescopic rod 88 can slowly extend, under the action of the sliding groove hole 83 and the I-shaped limiting column 84, the bearing frame 85 and the guide rubber wheel 86 are driven to synchronously move downwards, and the textile fibers 87 are sequentially wound downwards when being wound, so that the phenomenon that the textile fibers are stacked on one place to be wound is avoided;

when the winding amount of each winding roller 79 reaches the specification, similarly operating, stopping the electric telescopic rod 88 and the three-phase asynchronous motor 62 to continue working, cutting off the textile fiber yarns 87, and transferring the whole transfer system to a warehouse;

at this moment, the staff rotates the hand disc 711, because the hand disc 711 is connected with the positioning screw 77 through the screw thread, in the process of rotating the hand disc 711, the hand disc 711 can move towards the top end of the positioning screw 77, and after completely falling off, the upper rubber disc 710 is taken down, and then the winding roll 79 which has finished winding can be taken down.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The finished product transfer system for textile fiber production comprises a carrying trolley (1) and is characterized in that a through groove (2) with a rectangular structure is formed in the middle area of the top of the carrying trolley (1), a box body (3) with an open structure at the top is fixedly mounted inside the through groove (2), a group of storage battery sets (4) are correspondingly and fixedly mounted on two sides inside the box body (3), height adjusting units (5) are jointly mounted on four corners of the top end surface of the carrying trolley (1) and the bottom inside the box body (3), two rows of finished product fiber yarn winding units (7) are rotatably connected to the bottom inside the height adjusting units (5), a plurality of groups of fiber yarn guiding units (8) are symmetrically mounted on the edges of the front side and the rear side of the top of each height adjusting unit (5), and the power input starting ends of the finished product fiber yarn winding units (7) all extend to the lower side of each height adjusting unit (5), the driving unit (6) is fixedly connected with the height adjusting unit (5), two upright posts (9) are symmetrically arranged on two sides of the top end face of the height adjusting unit (5), a ceiling (10) is fixedly arranged at the top ends of the two upright posts (9) together, and a solar cell panel (11) is fixedly arranged at the top end of the ceiling (10);

finished product cellosilk winding unit (7) is including chassis (71) of fixed mounting in the inside bottom of height adjusting unit (5) the inside rotation of chassis (71) is connected with a drive axostylus axostyle (72) the top edge fixed mounting of chassis (71) has runway groove (74) the top of runway groove (74) is provided with the same with drive axostylus axostyle (72) size links up dish (76) the center fixedly connected with a vertical setting's of linking up dish (76) top location lead screw (77) the outside of location lead screw (77) and the top position that is located linking up dish (76) are fixed to be cup jointed the size and are linked up the same lower rubber dish (78) of linking up dish (76), the outside of location lead screw (77) and the top position that is located lower rubber dish (78) are overlapped and are equipped with lower rubber dish (78), the outside of location lead screw (77) and the top position that is located winding roll (79) are overlapped and are equipped with lower rubber dish (78) The upper rubber discs (710) are the same in size, and hand discs (711) are rotatably connected to the positions, located above the upper rubber discs (710), outside the positioning screw rods (77) through threads;

the fiber yarn guide unit (8) comprises a guide frame (81) which is fixedly arranged on the top edge of the height adjusting unit (5) and is in a structure like a Chinese character 'ji', the end surfaces of two sides of the guide frame (81) are respectively provided with sliding slot holes (83) which are symmetrically arranged, the insides of the two sliding slot holes (83) are respectively and correspondingly connected with an I-shaped limiting post (84) in a sliding way, the adjacent end surfaces of the two I-shaped limiting posts (84) are jointly and fixedly connected with a bearing frame (85), a guide rubber wheel (86) is rotatably connected inside the I-shaped limiting column (84) through a bearing, an electric telescopic rod (88) is fixedly arranged at the top end of the guide frame (81), the telescopic end of the electric telescopic rod (88) extends to the inside of the guide frame (81) and is fixedly connected with the top end of the bearing frame (85).

2. A finished product transfer system for textile fiber production according to claim 1, wherein a hydraulic rod on-off switch (12) is fixedly installed on the front side of one of the lateral end faces of the height adjusting unit (5), and a motor telescopic rod on-off switch (13) is fixedly installed on the rear side of one of the lateral end faces of the height adjusting unit (5);

the number of the finished product fiber yarn winding units (7) in the two rows is a plurality, and the position of each finished product fiber yarn winding unit (7) corresponds to one fiber yarn guiding unit (8).

3. A finished product transfer system for textile fibre production according to claim 1, characterised in that the driven end of the drive shaft (72) extends below the height adjustment unit (5) and is fixedly connected with the drive unit (6), and the drive shaft (72) and the height adjustment unit (5) and the chassis (71) form a rotary connection therebetween by means of a shaft sleeve (73);

a plurality of universal rollers (75) are fixedly arranged between the runway groove (74) and the joining disc (76), the top ends of the universal rollers (75) are fixedly connected with the joining disc (76), and the bottom ends of the universal rollers (75) are positioned inside the runway groove (74);

a threaded rotary connecting structure is formed between the positioning screw rod (77) and the hand disc (711) through an inner wire tube (712), and the inner wire tube (712) is fixedly arranged at the center of the hand disc (711) in a penetrating manner.

4. A finished product transfer system for textile fibre production, according to claim 1, characterised in that two stiffening plates (82) in the shape of an isosceles triangle are symmetrically welded on both sides of the bottom of the guide frame (81);

a textile fiber (87) is arranged between the top end inside the bearing frame (85) and the top of the guide rubber wheel (86) in an inserting mode.

5. The finished product transferring system for textile fiber production according to claim 1, wherein the height adjusting unit (5) comprises a base plate (51) which is arranged right above the carrying trolley (1) and is matched with the carrying trolley (1) in size, a position expanding groove (52) with a rectangular structure is formed in the top end face of the base plate (51), four corners of the base plate (51) are fixedly connected with a rod sleeve (53) in a penetrating manner, an oriented shaft rod (54) is correspondingly and slidably connected inside each rod sleeve (53), a reinforcing framework (56) with an X-shaped structure is fixedly welded at the bottom end of the base plate (51), and an electric hydraulic rod (57) is fixedly connected at the bottom end of the X-shaped intersection.

6. A finished product transfer system for textile fiber production according to claim 5, wherein the bottom end of each orientation shaft lever (54) is fixedly connected with the top end of the carrying trolley (1), a limiting cap (55) with the diameter size larger than that of the lever sleeve (53) is fixedly welded on the top end of each orientation shaft lever (54), and the bottom end of the electric hydraulic lever (57) is fixedly installed at the inner bottom end of the box body (3) and is located in the middle of the two storage battery packs (4).

7. A finished product transfer system for textile fibre production according to claim 1, wherein the drive unit (6) comprises a motor mounting bracket (61) fixedly mounted on one side of the bottom end of the height adjustment unit (5), a three-phase asynchronous motor (62) is fixedly mounted on the bottom of the motor mounting bracket (61), and the plurality of finished product filament winding units (7) are connected with each other and the drive ends of the finished product filament winding units (7) and the three-phase asynchronous motor (62) through transmission structures.

8. A finished product transfer system for textile fibre production according to claim 7, characterised in that the transmission structure comprises a smaller sized driving synchronizing wheel (63), a larger sized driven synchronizing wheel (64) and a timing belt (65) which is sleeved outside the driving synchronizing wheel (63) and the driven synchronizing wheel (64).

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