CN111809422A - Production and processing technology of cone yarn based on graphene - Google Patents

Abstract

The invention belongs to the technical field of yarn production, and particularly relates to a production and processing technology of a graphene-based cone yarn, which comprises the following steps: (1) laying the degreased cotton in a dyeing frame, and stacking the dyeing frame on a dyeing positioning mechanism in sequence; (2) sending the dyeing positioning mechanism filled with the degreased cotton into a drying room for drying; (3) preparing graphene slurry, and pouring the prepared graphene slurry into a dyeing box; pouring the dye to be dyed into a dyeing box, and then mixing and stirring uniformly; (4) placing the dried dyeing positioning mechanism into a dyeing box, soaking and dyeing; (5) after dyeing, taking out the dyeing positioning mechanism, and then sending the dyeing positioning mechanism into a drying room for drying; (6) the degreased cotton which is dried and dyed is spun, the degreased cotton is treated in a mode of drying firstly, dyeing and then drying, and the stability of the pigment after dyeing can be effectively improved, and the effect after dyeing is improved.

Description

Production and processing technology of cone yarn based on graphene

Technical Field

The invention belongs to the technical field of yarn production, and particularly relates to a production and processing technology of a cheese based on graphene.

Background

The cheese is technically a knitted fabric knitted by a circular loom, needles are distributed on a machine body in a circular cylinder shape, and a gray fabric is a large cylinder and can be used for further use after being opened and shaped.

In the production and processing of the cone yarn, different yarns are needed, so the color dyeing of the cone yarn is needed, but the stability of the dyed yarn is poor in the prior cone yarn production.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a production and processing technology of a graphene-based cone yarn.

In order to achieve the purpose, the invention adopts the following technical scheme:

a production and processing technology of a graphene-based cone yarn comprises the following steps:

(1) preparing raw materials: laying the degreased cotton in a dyeing frame, and stacking the dyeing frame on a dyeing positioning mechanism in sequence;

(2) drying: sending the dyeing positioning mechanism filled with the degreased cotton into a drying room for drying;

(3) preparing a dyeing liquid: preparing graphene slurry, and pouring the prepared graphene slurry into a dyeing box; pouring the dye to be dyed into a dyeing box, and then mixing and stirring uniformly;

(4) soaking: placing the dried dyeing positioning mechanism into a dyeing box, soaking and dyeing;

(5) drying: after dyeing, taking out the dyeing positioning mechanism, and then sending the dyeing positioning mechanism into a drying room for drying;

(6) preparing a finished product: and spinning the dried and dyed degreased cotton.

Preferably, the temperature of the graphene slurry in the dyeing box is controlled between 50 and 80 degrees.

Preferably, the soaking time in the step (4) is 8 to 12 hours.

Preferably, the dyeing frame is a square frame body, and the bottom of the dyeing frame is provided with a dyeing net which is matched in size and can move up and down.

Further, sliding connection between dyeing net and the dyeing frame inner wall, each limit of dyeing net all is equipped with fixed connection's connecting network, all be equipped with first adjustment tank in the dyeing frame lateral wall, be equipped with sliding connection's slide in the first adjustment tank, the slide upper end all is equipped with a plurality of fixed connection's first reset spring, first reset spring upper end is fixed with corresponding first adjustment tank upper wall connection respectively, is located the slide bottom all be equipped with the spread groove that communicates with first adjustment tank on each inner wall of dyeing frame, the connecting network extends the end and passes the spread groove and be connected fixedly bottom the slide.

Furthermore, a plurality of flow guide holes for flow guide are formed in the side wall of the dyeing frame.

Preferably, the dyeing positioning mechanism comprises a bottom plate and positioning rods, wherein four positioning rods which are uniformly distributed and fixedly connected are arranged on the bottom plate, each positioning rod consists of a plurality of positioning plates with the same size, an adjusting hole is formed in the middle of each positioning plate, the positioning plate positioned at the bottommost part is fixedly connected with the corresponding bottom plate, a transmission rod capable of moving up and down is arranged in the adjusting hole in each positioning rod, a top plate fixedly connected is arranged at the end part of the adjusting hole in the positioning plate positioned at the topmost part, communication holes communicated with the adjusting holes are formed in the side walls of the positioning plates, top blocks in sliding connection are arranged in the communication holes, annular third adjusting grooves are arranged in the communication holes positioned outside the top blocks, second reset springs are arranged in the third adjusting grooves positioned outside the top blocks, and positioning rings fixedly connected are arranged outside the top blocks positioned on one sides of the second reset springs, the adjusting rod is located on one side of the connecting hole, a second adjusting groove is formed in the middle of the adjusting rod, an adjusting line is arranged in the second adjusting groove, one end of the adjusting line is fixedly connected with the corresponding adjusting hole side wall, the other end of the adjusting line is fixedly connected with the corresponding end portion of the ejecting block, and transmission lines connected with the positioning plates are arranged between the upper positioning plate and the lower positioning plate and are adjacent to each other.

Further, be located the locating lever bottom all be equipped with assorted transmission groove on the bottom plate, transmission groove middle part is equipped with threaded connection's connecting axle, swing joint between connecting axle upper end and the regulation pole, the connecting axle bottom is equipped with the transmission shaft, the transmission shaft upper end is equipped with fixed connection's kelly, the connecting axle bottom is equipped with the draw-in groove with kelly phase-match and sliding connection, be equipped with the intercommunication groove that is linked together between the transmission groove bottom, the bottom plate middle part is equipped with adjusting motor, the adjusting motor output is equipped with the output shaft, the output shaft is located the intercommunication inslot, and the output shaft passes through the chain and is connected with corresponding transmission shaft respectively.

Furthermore, the locating lever is L shape, and the locating lever parcel is in four corners of dyeing frame.

Furthermore, a plurality of rollers fixedly connected are arranged at the bottom of the bottom plate.

Furthermore, a plurality of backflow holes for backflow are formed in the bottom plate.

Further, compared with the prior art, the invention has the following technical effects:

according to the method, the degreased cotton is treated in a manner of drying, dyeing and then drying, so that the stability of the pigment after dyeing and the effect after dyeing can be effectively improved, and a protective layer can be formed on the surface of the degreased cotton after dyeing by utilizing the characteristic of graphene, so that the stability after dyeing is ensured, the graphene has aromaticity, and the degreased cotton also has the property of aromatic hydrocarbon after dyeing.

Drawings

FIG. 1 is a block flow diagram provided by the present invention;

FIG. 2 is a schematic view of a front view of a dyeing positioning mechanism according to the present invention;

FIG. 3 is a schematic view of the front view of the internal structure of the dyeing positioning mechanism provided by the present invention;

FIG. 4 is an enlarged schematic view of the invention at A of FIG. 3;

FIG. 5 is an enlarged schematic view of the invention at B of FIG. 3;

FIG. 6 is a schematic view of a front view of a dyeing frame according to the present invention;

FIG. 7 is a schematic structural view of the dyeing frame and the dyeing net provided by the present invention when they are separated;

FIG. 8 is a schematic view of a connection structure of a dyeing frame and a dyeing net provided by the present invention;

FIG. 9 is a schematic view of a superimposed front view structure of the dyeing frames provided by the present invention;

FIG. 10 is a schematic structural view of a dyeing frame stacked on a dyeing positioning mechanism according to the present invention;

fig. 11 is a schematic structural view of a dyeing frame separated vertically by the dyeing positioning mechanism according to the present invention;

FIG. 12 is a schematic view of a top-down connection structure of the dyeing frame and the dyeing positioning mechanism according to the present invention;

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further clarified by combining the specific drawings.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example 1

Referring to fig. 1-12, a graphene-based cone yarn production process includes the following steps:

(1) preparing raw materials: laying the degreased cotton in a dyeing frame, and stacking the dyeing frame on a dyeing positioning mechanism in sequence;

(2) drying: sending the dyeing positioning mechanism filled with the degreased cotton into a drying room for drying;

(3) preparing a dyeing liquid: preparing graphene slurry, and pouring the prepared graphene slurry into a dyeing box; pouring the dye to be dyed into a dyeing box, and then mixing and stirring uniformly;

(4) soaking: placing the dried dyeing positioning mechanism into a dyeing box, soaking and dyeing;

(5) drying: after dyeing, taking out the dyeing positioning mechanism, and then sending the dyeing positioning mechanism into a drying room for drying;

(6) preparing a finished product: and spinning the dried and dyed degreased cotton.

Preferably, the temperature of the graphene slurry in the dyeing box is controlled to be 65 ℃.

Preferably, the soaking time in the step (4) is 9 hours.

Preferably, the dyeing frame 3 is a square frame body, and the bottom of the dyeing frame 3 is provided with a dyeing net 33 which is matched in size and can move up and down.

Further, a sealing cover 32 for sealing is arranged on the dyeing frame 3 positioned at the uppermost end, and a fixed connecting handle 31 is arranged on the sealing cover 32.

Further, sliding connection between dyeing net 33 and the 3 inner walls of dyeing frame, each limit of dyeing net 33 all is equipped with soft flexible and fixed connection's connecting net 34, all be equipped with first adjustment tank 36 in the 3 lateral walls of dyeing frame, be equipped with sliding connection's slide 38 in the first adjustment tank 36, slide 38 upper end all is equipped with a plurality of fixed connection's first reset spring 39, first reset spring 39 upper end is fixed with corresponding first adjustment tank 36 upper wall connection respectively, is located slide 38 bottom all be equipped with the spread groove 35 that is linked together with first adjustment tank 36 on each inner wall of dyeing frame 3, connecting net 34 extends the end and passes spread groove 35 and slide 38 bottom connection is fixed.

The design of dyeing net 33 makes the cotton wool after soaking, when separating with the soak solution, presses the dyeing net 33 of top through sealed lid 32, makes dyeing net 33 can synchronous downstream, realizes the compression step by step to carry out preliminary extrusion separation to the soak in the cotton wool after soaking, improve the drying efficiency in later stage, thereby improved holistic process flow's efficiency.

Further, the dyeing net 33 is a metal net.

Furthermore, a plurality of guide holes (not shown) for guiding flow are formed in the side wall of the dyeing frame 3.

Due to the design of the flow guide holes, when the dyeing net 33 is extruded, redundant liquid can be directly and quickly discharged through the flow guide holes, and the overall separation efficiency is improved.

Preferably, the dyeing positioning mechanism comprises a bottom plate 1 and positioning rods, four positioning rods which are uniformly distributed and fixedly connected are arranged on the bottom plate 1, each positioning rod is composed of a plurality of positioning plates 2 with the same size, an adjusting hole 26 is arranged in the middle of each positioning plate 2, the positioning plate 2 positioned at the bottommost part is fixedly connected with the corresponding bottom plate 1, a transmission rod 25 capable of moving up and down is arranged in the adjusting hole 26 in each positioning rod, a top plate 27 fixedly connected is arranged at the end part of the adjusting hole 26 positioned in the positioning plate 2 at the topmost part, communication holes 29 communicated with the adjusting holes 26 are arranged on the side walls of the positioning plates 2, top blocks 21 in sliding connection are arranged in the communication holes 29, annular third adjusting grooves 24 are arranged in the communication holes 29 positioned at the outer sides of the top blocks 21, and second reset springs 23 are arranged in the third adjusting grooves 24 positioned at the outer sides of the top blocks 21, the outer side of the ejector block 21, which is positioned on one side of the second reset spring 23, is provided with a positioning ring 22 fixedly connected with the ejector block, the middle of the adjusting rod 25, which is positioned on one side of the connecting hole 29, is provided with a second adjusting groove 252, an adjusting line 211 is arranged in the second adjusting groove 252, one end of the adjusting line 211 is fixedly connected with the corresponding side wall of the adjusting hole 26, the other end of the adjusting line 211 is fixedly connected with the corresponding end part of the ejector block 21, and the upper end and the lower end of the adjusting line are adjacent to each other, and a transmission line.

The design of the second reset spring 24 and the positioning ring 22 enables the top block 21 to be always kept in an ejecting state due to the elasticity of the second reset spring 24, and the design of the second adjusting groove 252 and the adjusting rod 25 moving up and down enables the upper inner wall of the second adjusting groove 252 to press down the adjusting line 211 when the adjusting rod 25 moves down, so that the top block 21 is driven to shrink, the dyeing frame 3 can be quickly placed between the positioning rods for clamping and fixing, and the top block 21 cannot influence the placement of the dyeing frame 3; after the dyeing frame 3 is placed, the adjusting line 211 is loosened and the top block 21 is ejected out through the upward movement of the adjusting rod 25, so that the dyeing frame 3 is clamped and fixed; when the adjusting rod 25 continuously ascends, the top plate 27 is moved upwards by the upper end of the adjusting rod 25, the upper and lower adjacent dyeing frames 3 are driven to be separated up and down through the transmission of the connecting wire 28, and when raw materials in the dyeing frames 3 are dried, the drying efficiency of the dyeing frames 3 can be effectively improved.

Further, be located the locating lever bottom all be equipped with assorted transmission groove 16 on the bottom plate 1, transmission groove 16 middle part is equipped with threaded connection's connecting axle 15, swing joint between connecting axle 15 upper end and the regulation pole 25, connecting axle 15 bottom is equipped with transmission shaft 14, transmission shaft 14 upper end is equipped with fixed connection's kelly 141, connecting axle 15 bottom is equipped with the draw-in groove 151 with kelly 141 phase-match and sliding connection, be equipped with the intercommunication groove 12 that is linked together between transmission groove 16 bottom, bottom plate 1 middle part is equipped with adjusting motor 15, adjusting motor 15 output is equipped with output shaft 17, output shaft 17 is located intercommunication groove 12, and output shaft 17 passes through chain 13 and is connected with corresponding transmission shaft 14 respectively.

The adjusting motor 15 is used for driving the transmission shafts 14 to synchronously rotate in the same direction through the chain 13, the sliding connection mode of the clamping groove 151 and the clamping rod 141 is used, the connecting shaft 15 is in threaded connection with the transmission groove 16, the transmission shafts 14 can be driven to rotate, the connecting shaft 15 can be driven to move up and down in the transmission groove 16 in a rotating mode, meanwhile, the adjusting rods 25 are movably connected with the connecting shaft 15, and therefore the connecting shaft 15 can drive the adjusting rods 25 to synchronously move up and down.

Furthermore, the locating rods are L-shaped and wrapped at four corners of the dyeing frame 3.

Further, a plurality of rollers 11 fixedly connected are arranged at the bottom of the bottom plate 1.

Further, the outer side wall of the dyeing frame 3 is provided with a top groove 30 which is clamped with the top block 21.

The design of the top groove 30 enables the top block 21 to be engaged with the top groove 30 when being ejected, thereby improving the firmness of fixing the dyeing frame 3 by the top block 21.

Furthermore, the bottom plate 1 is provided with a plurality of reflow holes (not shown) for reflow.

Due to the design of the backflow hole, when the dyeing frame 3 is extruded, extruded liquid can be discharged in a backflow mode in time, and the overall efficiency is improved.

Further, a chuck 152 fixedly connected and having a T-shaped section is disposed at the upper end of the connecting shaft 15, and a chuck groove 251 movably engaged with and rotatably connected to the chuck 152 is disposed at the bottom of the adjusting rod 25.

A drying method after dyeing of degreased cotton comprises the following steps:

(1) after the soaking and dyeing are finished, emptying the liquid in the dyeing box, covering the top dyeing frame 3 with a sealing cover 32, pressing down to enable the dyeing net 33 to synchronously move downwards to realize step-by-step compression, so that the soaking liquid in the soaked degreased cotton is subjected to preliminary extrusion separation, and the raw material moisture in the dyeing frame 3 is extruded;

(2) after extrusion is finished, the dyeing positioning mechanism is sent into a drying room, meanwhile, the adjusting motor 18 is started to drive the adjusting rod 25 to move upwards synchronously, the adjusting line 211 is loosened, the jacking block 21 is ejected out, and the dyeing frame 3 is clamped and fixed; when the adjusting rod 25 continuously ascends, the bottom of the adjusting groove 252 and the adjusting line 211 are at a certain distance, so that the top plate 27 is moved upwards by the upper end of the adjusting rod 25, the upper and lower adjacent dyeing frames 3 are driven to be separated up and down through the transmission of the connecting line 28, and when raw materials in the dyeing frames 3 are dried, the dried air flow can be uniformly distributed at the upper and lower ends of the dyeing frames 3, and the drying efficiency of the dyeing frames 3 can be effectively improved.

The foregoing shows and describes the general principles, essential features, and inventive features of this invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. A production and processing technology of cone yarn based on graphene is characterized in that: the method comprises the following steps:

(1) preparing raw materials: laying the degreased cotton in a dyeing frame, and stacking the dyeing frame on a dyeing positioning mechanism in sequence;

(2) drying: sending the dyeing positioning mechanism filled with the degreased cotton into a drying room for drying;

(3) preparing a dyeing liquid: preparing graphene slurry, and pouring the prepared graphene slurry into a dyeing box; pouring the dye to be dyed into a dyeing box, and then mixing and stirring uniformly;

(4) soaking: placing the dried dyeing positioning mechanism into a dyeing box, soaking and dyeing;

(5) drying: after dyeing, taking out the dyeing positioning mechanism, and then sending the dyeing positioning mechanism into a drying room for drying;

(6) preparing a finished product: and spinning the dried and dyed degreased cotton.

2. The graphene-based cone yarn production and processing process according to claim 1, characterized in that: the temperature of the graphene slurry in the dyeing box is controlled between 50 and 8 ℃.

3. The graphene-based cone yarn production and processing process according to claim 1, characterized in that: the soaking time in the step (4) is 8-12 hours.

4. The graphene-based cone yarn production and processing process according to claim 1, characterized in that: the dyeing frame is a square frame body, and a dyeing net which is matched in size and can move up and down is arranged at the bottom of the dyeing frame.

5. The graphene-based cone yarn production and processing process according to claim 1, characterized in that: the dyeing positioning mechanism comprises a bottom plate and positioning rods, wherein four positioning rods which are uniformly distributed and fixedly connected are arranged on the bottom plate, each positioning rod consists of a plurality of positioning plates with the same size, an adjusting hole is formed in the middle of each positioning plate, the positioning plate positioned at the bottommost part is fixedly connected with the corresponding bottom plate, a transmission rod capable of moving up and down is arranged in the adjusting hole in each positioning rod, a fixedly connected top plate is arranged at the end part of the adjusting hole in the positioning plate positioned at the topmost part, communication holes communicated with the adjusting holes are formed in the side walls of the positioning plates, top blocks in sliding connection are arranged in the communication holes, annular third adjusting grooves are arranged in the communication holes positioned at the outer sides of the top blocks, second reset springs are arranged in the third adjusting grooves positioned at the outer sides of the top blocks, and positioning rings fixedly connected are arranged at the outer sides of the top blocks positioned at one, the adjusting rod is located on one side of the connecting hole, a second adjusting groove is formed in the middle of the adjusting rod, an adjusting line is arranged in the second adjusting groove, one end of the adjusting line is fixedly connected with the corresponding adjusting hole side wall, the other end of the adjusting line is fixedly connected with the corresponding end portion of the ejecting block, and transmission lines connected with the positioning plates are arranged between the upper positioning plate and the lower positioning plate and are adjacent to each other.

6. The graphene-based cone yarn production and processing process according to claim 5, wherein the processing process comprises the following steps: be located the locating lever bottom all be equipped with assorted transmission groove on the bottom plate, transmission groove middle part is equipped with threaded connection's connecting axle, swing joint between connecting axle upper end and the regulation pole, the connecting axle bottom is equipped with the transmission shaft, the transmission shaft upper end is equipped with fixed connection's kelly, the connecting axle bottom is equipped with the draw-in groove with kelly phase-match and sliding connection, be equipped with the intercommunication groove that is linked together between the transmission groove bottom, the bottom plate middle part is equipped with adjusting motor, the adjusting motor output is equipped with the output shaft, the output shaft is located the intercommunication inslot, and the output shaft passes through the chain and is connected with corresponding transmission shaft respectively.

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