CN110952245B

CN110952245B - Preparation device and method of high-simulation down-like fiber

Info

Publication number: CN110952245B
Application number: CN201911255111.6A
Authority: CN
Inventors: 熊磊; 程安东; 倪丹
Original assignee: Luan Vocational and Technical College
Current assignee: Luan Vocational and Technical College
Priority date: 2019-12-10
Filing date: 2019-12-10
Publication date: 2022-03-04
Anticipated expiration: 2039-12-10
Also published as: CN110952245A

Abstract

The invention discloses a preparation device and a preparation method of high-simulation down-like fibers, and the preparation device comprises a processing table, wherein the processing table is provided with mounting plates, a moving unit is arranged between the mounting plates and comprises a second pull rope, the end part of the second pull rope is connected with an extrusion plate, and the upper surface of the processing table is provided with a dehydration rack; the extrusion plate can compress the down-like fibers on the dewatering plate, so that rapid extrusion can be achieved and a large amount of moisture contained in the down-like fibers can be extruded out; according to the scheme, the limiting clamping plate is shifted through the moving unit, the position of the extrusion plate is moved upwards, and then the pushing frame is pushed to push the pushing block on the limiting clamping plate to be separated from the limiting groove on the limiting plate through pushing the pushing frame, so that the extrusion plate is not restrained to fall freely; when the worker uses the clamp plate for the next time, the worker only needs to clamp the limiting clamp plate in the limiting groove; this scheme is compared with the tradition of stewing, can obviously raise the efficiency, required time when reducing follow-up stoving has improved the practicality.

Description

Preparation device and method of high-simulation down-like fiber

Technical Field

The invention relates to the technical field of down-like fiber processing, in particular to a device and a method for preparing high-simulation down-like fibers.

Background

The natural down feather fiber is a well-known warm-keeping material, is widely applied to the fields of high-grade clothing and cotton wadding, but because the natural down feather fiber is small in quantity and expensive in price, the natural down feather fiber can not meet the increasingly-improved physical living needs of people; the down-like fiber is a novel fiber for wadding developed in the field of synthetic fiber, can keep warm like natural down fiber, has good bulkiness, smooth and soft hand feeling, can be comparable with the natural down fiber in the aspects of bulkiness and compression resilience, and is high in quality and low in price;

the down-like fiber needs to be cleaned in the processing process, and needs to be dehydrated and dried after being cleaned, but the prior art generally dehydrates the down-like fiber in a standing mode, the dehydration mode is long in time consumption, meanwhile, complete dehydration is difficult to guarantee, and the operation needs to be carried out through manual work subsequently, which is very troublesome.

Disclosure of Invention

The purpose of the invention can be realized by the following technical scheme: a preparation device of high-simulation down-like fibers comprises a processing table, wherein mounting plates are arranged on the processing table, a moving unit is arranged between the mounting plates and comprises a second pull rope, the end part of the second pull rope is connected with an extrusion plate, the upper surface of the processing table is provided with a dehydration frame, and the extrusion plate is movably arranged inside the dehydration frame; the inner part of the dehydration frame is provided with a dehydration plate in a sliding manner, the surface of the dehydration plate is provided with a through groove, the inner side of the processing table is provided with a dehydration cavity, and dehydration grooves distributed in an array manner are arranged in the dehydration cavity, so that water can flow into the dehydration cavity from the through groove and flow out along the dehydration groove;

the movable unit comprises a first motor, a lead screw is rotatably arranged at the output end of the first motor, a screw sleeve is sleeved on the surface of the lead screw in a threaded manner, a limiting plate is arranged on the outer side of the screw sleeve, a limiting groove is formed in the limiting plate, a limiting clamping plate is movably clamped in the limiting groove, a clamping block is arranged on the outer side of the limiting clamping plate, the clamping block is clamped on the limiting plate and is located above the limiting groove, a pushing block and a first pull rope are vertically arranged on the surface of the limiting clamping plate, the first pull rope and the pushing block are located on different sides, one end of the first pull rope bypasses the dewatering frame and is provided with a pull plate, and the lower end of the second pull rope is connected with the pull plate;

a pushing frame is arranged on the upper surface of the machining table in a sliding mode, a first connecting rod is welded at one end of the pushing frame, a pushing plate is arranged at the tail end of the first connecting rod, the pushing plate penetrates through the machining table and extends to the lower end of the pushing plate, a spring is arranged on one side of the pushing frame, the tail end of the spring is connected with the surface of the mounting plate, and one side of the pushing frame can be in contact with a pushing block;

the pushing unit comprises a second motor, a winding rod is arranged at the output end of the second motor, a first fixing block is arranged on one side of the processing table, the tail end of the winding rod is rotatably inserted into the first fixing block, so that the winding rod is ensured to be in a horizontal state, a winding tape is wound on the surface of the winding rod, and the end part of the winding tape is connected with the dewatering plate;

the lower surface of processing platform is equipped with the third motor, and the output list of third motor is equipped with the change, is equipped with the kickboard on the change, rotates on the kickboard and is equipped with the keysets, and the kickboard all can contact with the push pedal with the keysets.

Preferably, the welding has the supporting leg around the lower surface of processing platform, is equipped with first backup pad and second backup pad between the adjacent supporting leg respectively, and the second motor is fixed to be set up in first backup pad, and the third motor is fixed to be set up in the second backup pad.

Preferably, the processing table is provided with symmetrically distributed sliding chutes, the sliding chutes are positioned at two sides of the dewatering cavity, the outer side of the dewatering plate is provided with symmetrically distributed sliding blocks, and the sliding blocks are slidably clamped in the sliding chutes.

Preferably, a first through groove and a second through groove are formed in the surface of the processing table in a penetrating mode, the first through groove is located in the dewatering cavity, the lower surface of the dewatering plate is provided with a limiting block, the limiting block penetrates through the first through groove, and the push plate penetrates through the second through groove;

the lower end of the pushing frame is welded with a baffle plate, and the baffle plate is arranged above the second through groove in a sliding manner; the width of the cross section of the baffle is larger than that of the second through groove.

Preferably, the lower surface of the dewatering plate is provided with a connecting block, the cross section of the connecting block is L-shaped, and the tail end of the winding belt is arranged on the connecting block.

Preferably, the mobile unit further comprises a first guide rod, the tail end of the first guide rod is perpendicularly connected with the mounting plate, a second connecting rod is arranged on the outer side of the threaded sleeve, a sliding sleeve is arranged at the end of the second connecting rod, and the sliding sleeve is sleeved on the first guide rod in a sliding mode, so that the threaded sleeve is prevented from rotating, and the limiting plate can only move back and forth along the screw rod.

Preferably, the outer side of the dewatering frame is provided with guide blocks, the upper end of the dewatering frame is provided with a second guide rod and a third guide rod, the third guide rod is positioned in the middle of the upper end of the dewatering frame, the first pull rope bypasses the guide blocks and then is connected with the lower surface of the pulling plate, the two second pull ropes are symmetrically distributed on the pulling plate, and one end of each second pull rope bypasses the second guide rod and then bypasses the third guide rod, and finally is connected with the extrusion plate.

Preferably, the upper end of catch plate is equipped with the switching piece, and the switching piece rotates with the adapter plate to be connected, and the lower extreme welding of adapter plate has the dog, the draw-in groove has been seted up to the tip of catch plate, and the dog card is established in the inside of draw-in groove.

Preferably, the tip welding of slurcam has the cardboard, and cardboard and slurcam keep the slope, and the keysets when clockwise rotation, for avoiding it to rotate to laminating mutually with the slurcam, after clockwise rotation certain angle, the dog is rotatable to laminating mutually with the inboard of cardboard, avoids it to continue to rotate.

A preparation method of high-simulation down-like fiber comprises the following steps:

step one, preparing polyester chips; carrying out crystallization drying and melt extrusion on a high-viscosity polyester chip with the intrinsic viscosity of 0.8-1.4 dL/g and a low-viscosity polyester chip with the intrinsic viscosity of 0.25-0.5 dL/g to obtain two spinning melts;

secondly, compounding polyester chips, feeding the spinning melt into a composite spinning manifold, using a triethanolamine titanium complex as a tackifier, providing high-temperature heat preservation for the spinning melt by using the composite spinning manifold, and then extruding at 250-350 ℃ in a screw extrusion mode;

step three, ejecting the compounded melt from spinneret orifices in the double-channel composite spinning assembly to form parallel composite spinning tows, and arranging the parallel composite spinning tows through a composite spinning spinneret plate to finally obtain composite melt spinning;

and step four, preparing the down-like fiber product through the procedures of air-blowing cooling, oiling, winding, barrel falling, balancing, bundling, drafting, surface oiling, tension heat setting, curling, drying, cutting and packaging.

The invention has the beneficial effects that:

1. compared with the prior art, the scheme has the advantages that the extrusion plate is designed, and the down-like fibers on the dewatering plate can be compressed by the extrusion plate, so that rapid extrusion can be realized, and a large amount of moisture contained in the down-like fibers can be extruded;

2. according to the scheme, the limiting clamping plate is shifted through the moving unit, so that the position of the extrusion plate is moved upwards, and meanwhile, the pushing frame pushes the pushing block on the limiting clamping plate to be separated from the limiting groove on the limiting plate through pushing the pushing frame, so that the extrusion plate is not restrained to fall freely; the whole process is convenient and practical, and when the worker uses the device next time, the worker only needs to clamp the limiting clamping plate in the limiting groove;

3. this scheme is compared with the tradition of stewing, can obviously raise the efficiency, required time when reducing follow-up stoving has improved the practicality.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of a mobile unit of the present invention;

FIG. 3 is a schematic view of the construction of the insert of the present invention;

FIG. 4 is a schematic view of a processing station of the present invention;

FIG. 5 is a schematic view of the push frame of the present invention;

FIG. 6 is a schematic view of a dewatering plate according to the present invention;

FIG. 7 is a schematic view of a dewatering stand according to the present invention;

FIG. 8 is a schematic view of a second motor of the present invention;

fig. 9 is a schematic view of a pusher plate of the present invention.

In the figure: 1 processing table, 11 supporting legs, 12 sliding grooves, 13 first fixing blocks, 14 mounting plates, 15 first penetrating grooves, 16 second penetrating grooves, 17 first supporting plates, 18 second supporting plates, 2 pushing frames, 21 first connecting rods, 22 pushing plates, 23 springs, 24 baffle plates, 3 moving units, 31 first motors, 311 screw rods, 32 screw sleeves, 321 second connecting rods, 33 sliding sleeves, 34 first guide rods, 35 limiting plates, 351 limiting grooves, 36 limiting clamping plates, 361 pushing blocks, 362 clamping blocks, 363 first pull ropes, 364 pull plates, 365 second pull ropes, 4 dewatering frames, 41 guide blocks, 42 second guide rods, 43 third guide rods, 44 conveying grooves, 5 extrusion plates, 6 second motors, 61 winding rods, 62 winding plates, 7 dewatering plates, 71 limiting blocks, 72 sliding blocks, 73 connecting blocks, 8 third motors, 81 swivel rings, 82 pushing plates, 821 transfer blocks, clamping grooves 822, clamping plates, 83 transfer plates and 823.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all 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. 1-9, the present invention provides a technical solution: a preparation device of high-simulation down-like fibers comprises a processing table 1, wherein mounting plates 14 are arranged on the processing table 1, a moving unit 3 is arranged between the mounting plates 14, the moving unit 3 comprises a second pull rope 365, the end part of the second pull rope 365 is connected with a squeezing plate 5, a dewatering frame 4 is arranged on the upper surface of the processing table 1, and the squeezing plate 5 is movably arranged inside the dewatering frame 4; a dewatering plate 7 is arranged in the dewatering frame 4 in a sliding mode, a through groove is formed in the surface of the dewatering plate 7, a dewatering cavity is formed in the inner side of the processing table 1, dewatering grooves distributed in an array mode are formed in the dewatering cavity, therefore, water can flow into the dewatering cavity from the through groove and flow out along the dewatering groove, a conveying groove 44 is formed in one side of the lower end of the dewatering frame 4, the dewatering plate 7 can move out of the conveying groove 44, a pushing unit is arranged at one end of the dewatering plate 7, and the pushing unit is arranged on the lower side of the processing table 1;

the moving unit 3 comprises a first motor 31, the output end of the first motor 31 is rotatably provided with a screw rod 311, the surface of the screw rod 311 is in threaded sleeve fit with a threaded sleeve 32, the outer side of the threaded sleeve 32 is provided with a limiting plate 35, the limiting plate 35 is provided with a limiting groove 351, the limiting groove 351 is movably clamped inside the limiting groove 351, the outer side of the limiting plate 36 is provided with a clamping block 362, the clamping block 362 is clamped on the limiting plate 35, the clamping block 362 is positioned above the limiting groove 351, the surface of the limiting plate 36 is vertically provided with a push block 361 and a first pull rope 363, the first pull rope 363 and the push block 361 are positioned on different sides, one end of the first pull rope 363 bypasses the dewatering frame 4 and is provided with a pull plate 364, and the lower end of the second pull rope 365 is connected with the pull plate 364;

the upper surface of the processing table 1 is provided with a push frame 2 in a sliding manner, one end of the push frame 2 is welded with a first connecting rod 21, the tail end of the first connecting rod 21 is provided with a push plate 22, the push plate 22 penetrates through the processing table 1 and extends to the lower end of the processing table, one side of the push frame 2 is provided with a spring 23, the tail end of the spring 23 is connected with the surface of the mounting plate 14, and one side of the push frame 2 can be contacted with a push block 361;

the pushing unit comprises a second motor 6, a winding rod 61 is arranged at the output end of the second motor 6, a first fixing block 13 is arranged on one side of the processing table 1, the tail end of the winding rod 61 is rotatably inserted into the first fixing block 13, so that the winding rod 61 is ensured to be in a horizontal state, a winding belt 62 is wound on the surface of the winding rod 61, and the end part of the winding belt 62 is connected with the dewatering plate 7;

the lower surface of the processing table 1 is provided with a third motor 8, the output of the third motor 8 is provided with a rotating ring 81, the rotating ring 81 is provided with a pushing plate 82, the pushing plate 82 is provided with an adapter plate 83 in a rotating manner, and both the pushing plate 82 and the adapter plate 83 can be contacted with the push plate 22.

The lower surface of processing platform 1 has the supporting leg 11 all around the welding, is equipped with first backup pad 17 and second backup pad 18 between the adjacent supporting leg 11 respectively, and third motor 8 is fixed to be set up on first backup pad 17, and second motor 6 is fixed to be set up in second backup pad 18.

The processing table 1 is provided with symmetrically distributed chutes 12, the chutes 12 are positioned at two sides of the dewatering cavity, symmetrically distributed sliding blocks 72 are arranged at the outer side of the dewatering plate 7, and the sliding blocks 72 are slidably clamped in the chutes 12.

A first through groove 15 and a second through groove 16 are formed in the surface of the processing table 1 in a penetrating manner, the first through groove 15 is positioned in the dewatering cavity, a limiting block 71 is arranged on the lower surface of the dewatering plate 7, the limiting block 71 penetrates through the first through groove 15, and the push plate 22 penetrates through the second through groove 16;

the lower end of the pushing frame 2 is welded with a baffle plate 24, and the baffle plate 24 is arranged above the second through groove 16 in a sliding manner; the cross-sectional width of the baffle 24 is greater than the width of the second through groove 16.

The lower surface of the dewatering plate 7 is provided with a connecting block 73, the cross section of the connecting block 73 is L-shaped, and the tail end of the winding belt 62 is arranged on the connecting block 73.

The moving unit 3 further comprises a first guide rod 34, the tail end of the first guide rod 34 is vertically connected with the mounting plate 14, a second connecting rod 321 is arranged outside the threaded sleeve 32, a sliding sleeve 33 is arranged at the end of the second connecting rod 321, and the sliding sleeve 33 is slidably sleeved on the first guide rod 34, so that the threaded sleeve 32 is prevented from rotating, and the limiting plate 35 can only move back and forth along the screw rod 311.

The outer side of the dewatering frame 4 is provided with a guide block 41, the upper end of the dewatering frame 4 is provided with a second guide rod 42 and a third guide rod 43, the third guide rod 43 is positioned in the middle of the upper end of the dewatering frame 4, the first pull rope 363 bypasses the guide block 41 and then is connected with the lower surface of the pull plate 364, the two second pull ropes 365 are symmetrically distributed on the pull plate 364, one end of each second pull rope 365 firstly bypasses the second guide rod 42 and then bypasses the third guide rod 43, and finally is connected with the extrusion plate 5.

The upper end of the pushing plate 82 is provided with a switching block 821, the switching block 821 is rotatably connected with the switching plate 83, a stop 831 is welded at the lower end of the switching plate 83, the end portion of the pushing plate 82 is provided with a clamping groove 822, and the stop 831 is clamped inside the clamping groove 822.

The tip welding of slurcam 82 has cardboard 823, and cardboard 823 keeps the slope with slurcam 82, and adapter plate 83 is when clockwise rotation, for avoiding it to rotate to laminating mutually with slurcam 82, after clockwise rotation certain angle, dog 831 can rotate to laminating mutually with the inboard of cardboard 823, avoids it to continue to rotate.

When the down-like fiber dewatering device is used, firstly, the first motor 31 is started, the first motor 31 drives the screw rod 311 to rotate, so that the screw sleeve 32 moves, the limiting plate 35 is driven to be close to the first motor 31 until the limiting plate is positioned between the push plate 22 and the push frame 2, the first pull rope 363 arranged on one side of the limiting plate 35 pulls the second pull rope 365, so that the height of the extrusion plate 5 positioned in the dewatering frame 4 rises, then the second motor 6 is started, the second motor 6 drives the winding rod 61 to rotate, the dewatering plate 7 is driven to move out of the dewatering frame 4, the down-like fiber is firstly paved on the dewatering plate 7, and then the dewatering plate 7 is moved into the dewatering frame 4; the third motor 8 is started, the third motor 8 drives the rotating ring 81 to rotate, the rotating ring 81 drives the pushing plate 82 on the surface of the rotating ring to rotate periodically, when the pushing plate 82 moves to the vertical state, the adapter plate 83 on the pushing plate 82 is attached to the lower end of the pushing plate 22, the pushing plate 22 is driven to move forwards, the limiting clamping plate 36 is separated from the limiting plate 35, the extruding plate 5 moves downwards at the moment and finally presses on the down-like fibers, the steps are repeated for several times, and most of moisture on the down-like fibers is extruded out.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Claims

1. A preparation device of high-simulation down-like fibers comprises a processing table (1) and is characterized in that mounting plates (14) are arranged on the processing table (1), moving units (3) are arranged between the mounting plates (14), each moving unit (3) comprises a second pull rope (365), the end parts of the second pull ropes (365) are connected with extrusion plates (5), a dewatering frame (4) is arranged on the upper surface of the processing table (1), and the extrusion plates (5) are movably arranged inside the dewatering frame (4); a dewatering plate (7) is arranged in the dewatering frame (4) in a sliding mode, one end of the dewatering plate (7) is provided with a pushing unit, and the pushing unit is arranged on the lower side of the processing table (1);

the moving unit (3) comprises a first motor (31), the output end of the first motor (31) is rotatably provided with a lead screw (311), a threaded sleeve (32) is sleeved on the surface of the lead screw (311) in a threaded manner, a limiting plate (35) is arranged on the outer side of the threaded sleeve (32), a limiting groove (351) is formed in the limiting plate (35), a limiting clamping plate (36) is movably clamped in the limiting groove (351), a clamping block (362) is arranged on the outer side of the limiting clamping plate (36), the clamping block (362) is clamped on the limiting plate (35), the clamping block (362) is located above the limiting groove (351), a push block (361) and a first pull rope (363) are vertically arranged on the surface of the limiting clamping plate (36), one end of the first pull rope (363) bypasses the dewatering frame (4) and is provided with a pull plate (364), and the lower end of a second pull rope (365) is connected with the pull plate (364);

the upper surface of the machining table (1) is provided with a pushing frame (2) in a sliding mode, one end of the pushing frame (2) is welded with a first connecting rod (21), the tail end of the first connecting rod (21) is provided with a pushing plate (22), the pushing plate (22) penetrates through the machining table (1) and extends to the lower end of the machining table, one side of the pushing frame (2) is provided with a spring (23), the tail end of the spring (23) is connected with the surface of the mounting plate (14), and one side of the pushing frame (2) can be in contact with a pushing block (361);

the pushing unit comprises a second motor (6), a winding rod (61) is arranged at the output end of the second motor (6), a winding belt (62) is wound on the surface of the winding rod (61), and the end part of the winding belt (62) is connected with the dewatering plate (7);

the lower surface of processing platform (1) is equipped with third motor (8), and the output list of third motor (8) is equipped with change (81), is equipped with kickboard (82) on change (81), rotates on kickboard (82) and is equipped with adapter plate (83), and kickboard (82) and adapter plate (83) all can contact with push pedal (22).

2. The device for preparing the high-simulation down-like fiber according to claim 1, wherein the support legs (11) are welded around the lower surface of the processing table (1), a first support plate (17) and a second support plate (18) are respectively arranged between the adjacent support legs (11), the third motor (8) is fixedly arranged on the first support plate (17), and the second motor (6) is fixedly arranged on the second support plate (18).

3. The device for preparing the high-simulation down-like fiber according to claim 1, wherein the processing table (1) is provided with symmetrically distributed sliding chutes (12), the sliding chutes (12) are positioned at two sides of the dewatering chamber, symmetrically distributed sliding blocks (72) are arranged at the outer side of the dewatering plate (7), and the sliding blocks (72) are slidably clamped in the sliding chutes (12).

4. The device for preparing the highly-simulated down-like fiber according to claim 1, wherein a first through groove (15) and a second through groove (16) are formed in the surface of the processing table (1) in a penetrating manner, the first through groove (15) is positioned in the dewatering cavity, a limiting block (71) is arranged on the lower surface of the dewatering plate (7), the limiting block (71) penetrates through the first through groove (15), and the pushing plate (22) penetrates through the second through groove (16);

the lower end of the pushing frame (2) is welded with a baffle (24), and the baffle (24) is arranged above the second through groove (16) in a sliding mode.

5. The device for preparing the highly artificial down-like fiber according to claim 1, wherein the lower surface of the dewatering plate (7) is provided with a connecting block (73), the cross-sectional shape of the connecting block (73) is L-shaped, and the tail end of the winding belt (62) is arranged on the connecting block (73).

6. The device for preparing the high-simulation down-like fiber according to claim 1, wherein the moving unit (3) further comprises a first guide rod (34), the end of the first guide rod (34) is vertically connected with the mounting plate (14), a second connecting rod (321) is arranged outside the screw sleeve (32), a sliding sleeve (33) is arranged at the end of the second connecting rod (321), and the sliding sleeve (33) is slidably sleeved on the first guide rod (34).

7. The device for preparing the highly artificial down-like fiber according to claim 1, wherein the outer side of the dewatering frame (4) is provided with a guide block (41), the upper end of the dewatering frame is provided with a second guide rod (42) and a third guide rod (43), the first pull rope (363) bypasses the guide block (41), and one end of the second pull rope (365) bypasses the second guide rod (42) and then bypasses the third guide rod (43).

8. The device for preparing the high-simulation down-like fiber according to claim 1, wherein a transfer block (821) is arranged at the upper end of the pushing plate (82), the transfer block (821) is rotatably connected with the transfer plate (83), a stopper (831) is welded at the lower end of the transfer plate (83), a clamping groove (822) is formed in the end portion of the pushing plate (82), and the stopper (831) is clamped in the clamping groove (822).

9. The device for preparing the high-simulation down-like fiber according to claim 1, wherein a clamping plate (823) is welded at the end of the pushing plate (82), and the stopper (831) can rotate to be attached to the inner side of the clamping plate (823).