CN106702561A - Superhigh water-conducting fiber rod, and production method and application thereof - Google Patents

Superhigh water-conducting fiber rod, and production method and application thereof Download PDF

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Publication number
CN106702561A
CN106702561A CN201710042920.3A CN201710042920A CN106702561A CN 106702561 A CN106702561 A CN 106702561A CN 201710042920 A CN201710042920 A CN 201710042920A CN 106702561 A CN106702561 A CN 106702561A
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China
Prior art keywords
double
fiber
extexine
sandwich layer
inner sandwich
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CN201710042920.3A
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Inventor
邱籼钧
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Guangdong Xin ball new Mstar Technology Ltd
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Baiyun District Guangzhou Xin Ball Fiber Products Factory
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Priority to CN201710042920.3A priority Critical patent/CN106702561A/en
Publication of CN106702561A publication Critical patent/CN106702561A/en
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    • DTEXTILES; PAPER
    • D02YARNS; MECHANICAL FINISHING OF YARNS OR ROPES; WARPING OR BEAMING
    • D02GCRIMPING OR CURLING FIBRES, FILAMENTS, THREADS, OR YARNS; YARNS OR THREADS
    • D02G3/00Yarns or threads, e.g. fancy yarns; Processes or apparatus for the production thereof, not otherwise provided for
    • D02G3/22Yarns or threads characterised by constructional features, e.g. blending, filament/fibre
    • D02G3/40Yarns in which fibres are united by adhesives; Impregnated yarns or threads
    • D02G3/402Yarns in which fibres are united by adhesives; Impregnated yarns or threads the adhesive being one component of the yarn, i.e. thermoplastic yarn
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01DMECHANICAL METHODS OR APPARATUS IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS
    • D01D5/00Formation of filaments, threads, or the like
    • D01D5/24Formation of filaments, threads, or the like with a hollow structure; Spinnerette packs therefor
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01DMECHANICAL METHODS OR APPARATUS IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS
    • D01D5/00Formation of filaments, threads, or the like
    • D01D5/28Formation of filaments, threads, or the like while mixing different spinning solutions or melts during the spinning operation; Spinnerette packs therefor
    • DTEXTILES; PAPER
    • D02YARNS; MECHANICAL FINISHING OF YARNS OR ROPES; WARPING OR BEAMING
    • D02GCRIMPING OR CURLING FIBRES, FILAMENTS, THREADS, OR YARNS; YARNS OR THREADS
    • D02G3/00Yarns or threads, e.g. fancy yarns; Processes or apparatus for the production thereof, not otherwise provided for
    • D02G3/22Yarns or threads characterised by constructional features, e.g. blending, filament/fibre
    • D02G3/26Yarns or threads characterised by constructional features, e.g. blending, filament/fibre with characteristics dependent on the amount or direction of twist
    • D02G3/28Doubled, plied, or cabled threads

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Textile Engineering (AREA)
  • Laminated Bodies (AREA)

Abstract

The invention discloses a superhigh water-conducting fiber rod, and a production method and application thereof. Each double-layer multistrand silk comprises a plurality of single-strand cellosilks only comprising an inner core layer. Each inner core layer is of a hollow tube structure, and is a high-melting-point inner core layer made from PP (polypropylene), PET (polyethylene terephthalate), TPU (thermoplastic polyurethanes) or TPEE (thermoplastic polyester elastomer) materials. The single-strand cellosilks are adhered to one another integrally. Outer surfaces with low melting points are melted through heating, the inner core layers with high melting points do not melt, the cellosilks only with the inner core layers can be adhered to one another by physical effect caused by melting of the outer surfaces, pollution is avoided, and accordingly, the fiber rod becomes an environment-friendly green pollution-free product; impurities do not exist to block pores, swelling and loosening of the cellosilks are not caused, and the superhigh water-conducting fiber rod has good capillary water absorption effect and long service life; the cellosilks are of hollow inner core structures, so that the fiber rod has high porosity and high water conduction, water absorption and filtration performance.

Description

A kind of fiber rod of superpower water guide and preparation method and application
Technical field
The present invention relates to the technical field of fiber, especially a kind of composite fibre rod and technique productions method.
Background technology
Existing water-absorption fiber rod is composited by the monofilament of pure PET (terylene) or PP (polypropylene) material, and Filament using real cored structure, these as the filament of water-absorbing core be by glue bonding together, and use certain work Process causes filament inner tight to bond and forms certain elastic club shaped structure, and the dissolving of glue must be used and open oil Water, there are the following problems for it:1st, due to there is impurity inside filament, make the fiber rod purity of last shaping not enough, cause fibre Dimension rod water absorption is not high, and the glue impurity of residual can block pore, influences wicking ability, and the speed of water suction is slow, shadow The volatilization effect of aqua is rung, simultaneously because opening profit, glue equal solvent does not meet environmental requirement so that water-absorbing core is to perfume etc. Related auxiliary products can produce a certain degree of pollution, 2, the glue of residual due to its chemical characteristic, intolerant to sesame oil or essence Corrosion, can cause to be expanded as the filament of water-absorbing core, cause filament loose, and the service life of product is affected;And After fiber rod containing impurity such as residual glue is discarded, it is unfavorable for reclaiming, harmful effect can be produced to surrounding environment;3rd, filament Itself there is certain water imbibition and filterability, but the filament of real cored structure in water imbibition and the filter tip for electronic cigarette Aspect, when as water suction rod use when, because cored structure can be to its water imbibition according into certain influence, when as one kind in fact During the use of Smoke Filter, the fiber rod containing real core fibre silk causes that the penetrability of smog is strong not enough.
The content of the invention
For the technical problem that above-mentioned prior art is present, it is an object of the invention to provide one kind using double-deck difference material Expect the tubular fibre silk structure of composition, do not use the glue also to allow filament to fasten composite joint one, asepsis environment-protecting and have The fiber rod of superpower water guide, capillary water absorption and smog penetrability and the production method of fiber rod.
To achieve the above object, the technical scheme is that:A kind of fiber rod of superpower water guide, fiber rod is by many The fiber rod that double-deck multiple thread strands warping plying, heating are made, described every double-deck multiple thread strands include multiply single-stranded fiber silk, sub-thread Filament is constituted by inner sandwich layer is single, and the inner sandwich layer is hollow tubular construction, the inner sandwich layer be by PP or PET or TPU or The high-melting-point inner sandwich layer that TPEE materials are made, multiply single-stranded fiber silk is bonded to one another one.
The fusing point of PP materials is 150-170 degree, and the fusing point of TPU materials is 170-210 degree, and the material melting point of TPEE is 190- 220 degree, the fusing point of PET material is 240-260 degree.
Described every double-deck multiple thread strands Denier range is 150D-600D, and the D is Denier, every double-deck multiple thread strands bag 48F-192F single-stranded fibers silk is included, wherein F represents stock.
A kind of preparation method of fiber rod, step one:Hollow inner sandwich layer single layer fibre is made, inner sandwich layer is chosen as needed Required materials with high melting point, melt case in reacted, and remove slag, acid-base neutralization, carry out crystallizing and drying, drying temperature 90-100 Degree, drying time 12-14 hours, dried single layer fibre entered inner sandwich layer passage after melt extruded, in inner sandwich layer passage The spray chamber of fibre-bearing pore, inner sandwich layer passage docking spinneret, single layer fibre sprays the individual layer to form hollow core structures from spray chamber Filament;
Step 2:Extexine single layer fibre is made, low melting material needed for extexine is chosen as needed, in case is melted Reaction, removes slag, acid-base neutralization, carries out crystallizing and drying, drying temperature 50-60 degree, drying time 16-18 hours, dried list Layer fiber enters extexine passage after melt extruded, and extexine passage includes spray gun, and extexine passage docks same spinneret;
Step 3:Inner sandwich layer single fiber and extexine single fiber are combined into the fiber with double-decker at spinneret Silk, the extexine is coated on inner sandwich layer outer surface, is drawn by hauling machine after double layer fibre silk cooling, will be fiber Silk moves required length and diameter to, then the sub-thread double layer fibre silk of multiply is carried out being combined the double-deck multiple thread strands needed for obtaining;
Step 4:Double-deck multiple thread strands are carried out by elasticizer again plus bullet forms pore and the more preferable DTY of bulkiness by fiber Filament;
Step 5:Many double-deck multiple thread strands are carried out into warping plying, the radical of plying is determined according to the diameter for making object;
Step 6:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is according to double Depending on the low melting material of the extexine that layer multiple thread strands are chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, through the first segment After heater, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand Silk, this time heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 7:Through the single layer multi-strand silk after first segment heating devices heat, the sizing in secondary heating mechanism is entered back into (reheating is for various diameters to mould shape (mould can according to demand make cylinder, tubular, square, square etc.) With shape shape and heat), the modular system is set to the die form with predetermined shape product, be such as set to it is bar-shaped, justify The various different water absorption products of shape, filament is by after reheating, being solidified into the form of required product bar, reheating Temperature ensure than select the low 10-20 degree of inner sandwich layer materials with high melting point fusing point
The inner sandwich layer is the high-melting-point inner sandwich layer being made up of PP or PET or TPU or TPEE materials, and the extexine is served as reasons The low melting point extexine that PE or PP or POE or TPU or TPEE materials are made;The fusing point of the POE materials is 50-90 degree, PE materials The fusing point of material is 120-140 degree, and the fusing point of PP materials is 150-170 degree, and the fusing point of TPU materials is 170-210 degree, the material of TPEE Material fusing point is 190-220 degree, and the fusing point of PET material is 240-260 degree.
The appearance layer component accounts for the 40%-60% of total amount, and the inner core layer component accounts for the 60%-40% of total amount.
A kind of application of fiber rod in fiber nib, water suction rod, filter stick is made.
A kind of fiber rod makes fiber nib, water suction rod, the preparation method of filter stick, step one:By many double-deck multiplies Silk carries out warping plying, and the radical of plying is determined according to the diameter for making object;
Step 2:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is according to double Depending on the low melting material of the extexine that layer multiple thread strands are chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, through the first segment After heater, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand Silk, this time heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 3:Through the single layer multi-strand silk after first segment heating devices heat, the sizing in secondary heating mechanism is entered back into (reheating is for various diameters to mould shape (mould can according to demand make cylinder, tubular, square, square etc.) With shape shape and heat), the modular system is set to the die form with predetermined shape product, be such as set to it is bar-shaped, justify The various different water absorption products of shape, filament is by after reheating, being solidified into the form of required product bar, reheating Temperature ensure than select the low 10-20 degree of inner sandwich layer materials with high melting point fusing point.
Compared with prior art, the beneficial effects of the invention are as follows:By what is be made of double-deck inside and outside low melting material high Filament, by mode of heating, the extexine of low melting point is melted, and dystectic inner sandwich layer is insoluble, and extexine dissolving is produced The filament that many multiplies can be only left raw physical effect inner sandwich layer is bonded to each other, and this production method is shut out completely Glue and the use of profit is opened absolutely, unnecessary impurity will not be produced so that chemical substance will not be produced in fiber rod, no matter During use or in the removal process in later stage, all without any pollution of generation so that it is green that fiber rod turns into a kind of environmental protection The free of contamination product of color, simultaneously because no impurity blocks pore, does not also result in filametntary expansion loosely, therefore relatively Using the traditional fibre rod of glue, fiber rod of the invention has more stronger wicking ability and service life, and fine Dimension silk uses the core arrangement of hollow so that fiber rod has stronger porosity, has more preferable water guide, water suction, strainability, When for being fabricated to fiber nib, it is more smooth that its internal structure can allow ink to absorb water, and in terms of for cigarette filter, also can So that smog penetrability is stronger.
Brief description of the drawings
Fig. 1 is single-stranded fiber of the present invention silk structure enlarged diagram;
Fig. 2 is every double-deck multiple thread strands structure enlarged diagram;
Fig. 3 is the close-up schematic view of Fig. 2;
Fig. 4 is fiber rod structural representation of the present invention.
Specific embodiment
Present disclosure is described in further details with reference to the accompanying drawings and detailed description.
Embodiment:
Refer to shown in Fig. 1 to Fig. 4, a kind of fiber rod of superpower water guide, fiber rod is by many double-deck warpings of multiple thread strands 1 The fiber rod that plying, heating are made, every double-deck multiple thread strands 1 include multiply single-stranded fiber silk 2, and single-stranded fiber silk 2 is by inner sandwich layer 22 single compositions, inner sandwich layer 22 is hollow tubular construction, and inner sandwich layer 22 is by PP (polypropylene) or PET (terylene) or TPU (thermoplasticity Polyurethane elastomer) or the high-melting-point inner sandwich layer that is made of TPEE (thermoplastic polyester elastomer) material, multiply single-stranded fiber silk 2 that This bonds one.
The fusing point of PP materials is 150-170 degree in the present embodiment, and the fusing point of TPU materials is 170-210 degree, the material of TPEE Fusing point is 190-220 degree, and the fusing point of PET material is 240-260 degree.
The every double-deck Denier range of multiple thread strands 1 is 150D-600D, and the D is Denier, and every double-deck multiple thread strands 1 include 48F-192F single-stranded fibers silk 2, wherein F represents stock, and according to demand, a fiber rod can generally include up to a hundred with extremely thousands of The double-deck multiple thread strands of root, so as to form the fiber rod of different-diameter size, are adapted to make various sizes of fiber nib, water suction Rod, filter stick etc..
The present embodiment additionally provides a kind of preparation method of fiber rod, comprises the following steps:
Step one:Hollow inner sandwich layer single layer fibre is made, materials with high melting point needed for inner sandwich layer is chosen as needed, in melting Reacted in case, and remove slag, acid-base neutralization, carry out crystallizing and drying, drying temperature 90-100 degree, drying time 12-14 hours, Dried single layer fibre enters inner sandwich layer passage after melt extruded, and the spray chamber of inner sandwich layer passage including fiber pore is interior Sandwich layer passage docks spinneret, and single layer fibre sprays the single layer fibre silk to form hollow core structures from spray chamber;
Step 2:Extexine single layer fibre is made, low melting material needed for extexine is chosen as needed, in case is melted Reaction, removes slag, acid-base neutralization, carries out crystallizing and drying, drying temperature 50-60 degree, drying time 16-18 hours, dried list Layer fiber enters extexine passage after melt extruded, and extexine passage includes spray gun, and extexine passage docks same spinneret;
Step 3:Inner sandwich layer single fiber and extexine single fiber are combined into the fiber with double-decker at spinneret Silk, extexine is coated on inner sandwich layer outer surface, is drawn by hauling machine after double layer fibre silk cooling, filament will be drawn To required length and diameter, then the sub-thread double layer fibre silk of multiply is carried out being combined the double-deck multiple thread strands needed for obtaining;
Step 4:Double-deck multiple thread strands are carried out by elasticizer again plus bullet forms pore and the more preferable DTY of bulkiness by fiber Filament;
Step 5:Many double-deck multiple thread strands are carried out into warping plying, the radical of plying is determined according to the diameter for making object;
Step 6:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is according to double Depending on the low melting material of the extexine that layer multiple thread strands are chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, through the first segment After heater, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand Silk, this time heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 7:Through the single layer multi-strand silk after first segment heating devices heat, the sizing in secondary heating mechanism is entered back into (reheating is for various diameters to mould shape (mould can according to demand make cylinder, tubular, square, square etc.) Shape and heat with shape), the modular system is set to the die form with predetermined shape product, and filament is added by secondary After heat, the form of required product bar is solidified into, the temperature of reheating ensures the inner sandwich layer materials with high melting point fusing point than selecting Low 10-20 degree.
Inner sandwich layer is the high-melting-point inner sandwich layer being made up of PP or PET or TPU or TPEE materials, extexine be by PE or PP or The low melting point extexine that POE (rubber and plastic composite elastic material) or TPU or TPEE materials are made;The fusing point of POE materials is 50-90 Degree, the fusing point of PE materials is 120-140 degree, and the fusing point of PP materials is 150-170 degree, and the fusing point of TPU materials is 170-210 degree, The material melting point of TPEE is 190-220 degree, and the fusing point of PET material is 240-260 degree.Chosen inner sandwich layer and extexine is given respectively During material, chosen according to its fusing point height correspondence, as long as the fusing point for ensureing inner sandwich layer is higher than outer sandwich layer fusing point, such as work as inner core When layer choosing takes the TPU that fusing point is 170 degree, then extexine does not choose TPEE of the fusing point higher than TUP, and need to choose PE or 150 degree , to ensure extexine fusing point less than inner sandwich layer, other are by that analogy for PP or POE.
A progressive step, first segment heater can select Far-infrared Heating mode.
The component of extexine 21 accounts for the 40%-60% of total amount, and the component of inner sandwich layer 22 accounts for the 60%-40% of total amount.
This kind of fiber rod can be applied and make fiber nib, water suction rod, filter stick.
A kind of use fiber rod makes fiber nib, water suction rod, the preparation method of filter stick, comprises the following steps:
Step one:Many double-deck multiple thread strands are carried out into warping plying, the radical of plying is determined according to the diameter for making object;
Step 2:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is according to double Depending on the low melting material of the extexine that layer multiple thread strands are chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, through the first segment After heater, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand Silk, this time heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 3:Through the single layer multi-strand silk after first segment heating devices heat, the sizing in secondary heating mechanism is entered back into (reheating is for various diameters to mould shape (mould can according to demand make cylinder, tubular, square, square etc.) With shape shape and heat), the modular system is set to the die form with predetermined shape product, be such as set to it is bar-shaped, justify The various different water absorption products of shape, filament is by after reheating, being solidified into the form of required product bar, reheating Temperature ensure than select the low 10-20 degree of inner sandwich layer materials with high melting point fusing point.
Above-listed detailed description is directed to illustrating for possible embodiments of the present invention, and the embodiment simultaneously is not used to limit this hair Bright protection domain, all equivalence enforcements or change without departing from carried out by the present invention are intended to be limited solely by the protection domain of this case.

Claims (8)

1. a kind of fiber rod of superpower water guide, it is characterised in that:The fiber rod is to be closed by many double-deck multiple thread strands (1) warpings The fiber rod that stock, heating are made, described every double-deck multiple thread strands (1) includes multiply single-stranded fiber silk (2), single-stranded fiber silk (2) Constituted by inner sandwich layer (22) is single, the inner sandwich layer (22) is hollow tubular construction, the inner sandwich layer (22) be by PP or PET or The high-melting-point inner sandwich layer that TPU or TPEE materials are made, multiply single-stranded fiber silk (2) is bonded to one another one.
2. a kind of fiber rod of superpower water guide as claimed in claim 1, it is characterised in that:The fusing point of PP materials is 150-170 Degree, the fusing point of TPU materials is 170-210 degree, and the material melting point of TPEE is 190-220 degree, and the fusing point of PET material is 240-260 Degree.
3. a kind of fiber rod of superpower water guide as claimed in claim 1, it is characterised in that:Described every double-deck multiple thread strands (1) Denier range is 150D-600D, and the D is Denier, and every double-deck multiple thread strands (1) includes 48F-192F single-stranded fibers silk (2).
4. a kind of preparation method of fiber rod as claimed in claim 1, it is characterised in that comprise the following steps:
Step one:Hollow inner sandwich layer single layer fibre is made, materials with high melting point needed for inner sandwich layer is chosen as needed, in case is melted Reacted, and remove slag, acid-base neutralization, carry out crystallizing and drying, drying temperature 90-100 degree drying time 12-14 hours, is dried Single layer fibre afterwards enters inner sandwich layer passage, the spray chamber of inner sandwich layer passage including fiber pore, inner sandwich layer after melt extruded Passage docks spinneret, and single layer fibre sprays the single layer fibre silk to form hollow core structures from spray chamber;
Step 2:Extexine single layer fibre is made, low melting material needed for extexine is chosen as needed, it is anti-in case is melted Should, remove slag, acid-base neutralization, carry out crystallizing and drying, drying temperature 50-60 degree, drying time 16-18 hours, dried individual layer Fiber enters extexine passage after melt extruded, and extexine passage includes spray gun, and extexine passage docks same spinneret;
Step 3:Inner sandwich layer single fiber and extexine single fiber are combined into the filament with double-decker, institute at spinneret State extexine and be coated on inner sandwich layer outer surface, drawn by hauling machine after double layer fibre silk cooling, filament will be drawn To required length and diameter, then the sub-thread double layer fibre silk of multiply is carried out being combined the double-deck multiple thread strands needed for obtaining;
Step 4:Double-deck multiple thread strands are carried out by elasticizer again plus bullet forms pore and the more preferable DTY fiber of bulkiness by fiber Silk;
Step 5:Many double-deck multiple thread strands are carried out into warping plying, the radical of plying is determined according to the diameter for making object;
Step 6:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is more according to bilayer Depending on the low melting material of the extexine that stock silk is chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, is heated through the first segment After device, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand silk, this Secondary heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 7:Through the single layer multi-strand silk after first segment heating devices heat, the shaper in secondary heating mechanism is entered back into Sizing, the modular system is set to the die form with predetermined shape product, and filament is by after reheating, being solidified into institute Needing the form of product bar, the temperature of reheating ensures the low 10-20 degree of inner sandwich layer materials with high melting point fusing point than selecting.
5. the preparation method of fiber rod as claimed in claim 4, it is characterised in that:The inner sandwich layer is by PP or PET or TPU Or the high-melting-point inner sandwich layer that TPEE materials are made, the extexine be by PE or PP or POE or TPU or TPEE materials be made it is low Fusing point extexine;The fusing point of the POE materials is 50-90 degree, and the fusing point of PE materials is 120-140 degree, and the fusing point of PP materials is 150-170 degree, the fusing point of TPU materials is 170-210 degree, and the material melting point of TPEE is 190-220 degree, and the fusing point of PET material is 240-260 degree.
6. a kind of fiber rod of superpower water guide as claimed in claim 4, it is characterised in that:Extexine (21) component is accounted for always The 40%-60% of amount, inner sandwich layer (22) component accounts for the 60%-40% of total amount.
7. application of a kind of fiber rod as claimed in claim 1 in fiber nib, water suction rod, filter stick is made.
8. it is a kind of that fiber nib, water suction rod, the preparation method of filter stick, its feature are made using fiber rod as claimed in claim 1 It is:
Step one:Many double-deck multiple thread strands are carried out into warping plying, the radical of plying is determined according to the diameter for making object;
Step 2:Double-deck multiple thread strands after warping plying are heated into first heater, and heating-up temperature is more according to bilayer Depending on the low melting material of the extexine that stock silk is chosen, it is ensured that extexine dissolves, and inner sandwich layer is insoluble, is heated through the first segment After device, the single-stranded fiber silk in double-deck multiple thread strands is changed into sub-thread single layer fibre silk, and double-deck multiple thread strands are changed into single layer multi-strand silk, this Secondary heating is to allow extexine to dissolve so that the filametntary inner sandwich layer of multiply can mutually be bonded together;
Step 3:Through the single layer multi-strand silk after first segment heating devices heat, the shaper in secondary heating mechanism is entered back into (reheating is for various diameters and shape for sizing (mould can according to demand make cylinder, tubular, square, square etc.) Shape is shaped and is heated), the modular system is set to the die form with predetermined shape product, is such as set to bar-shaped, toroidal Various different water absorption products, filament is by after reheating, being solidified into the form of required product bar, the temperature of reheating Degree ensures the low 10-20 degree of inner sandwich layer materials with high melting point fusing point than selecting.
CN201710042920.3A 2017-01-20 2017-01-20 Superhigh water-conducting fiber rod, and production method and application thereof Pending CN106702561A (en)

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Cited By (2)

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Publication number Priority date Publication date Assignee Title
CN109483914A (en) * 2018-09-30 2019-03-19 无锡盛烨特邦新材料科技有限公司 One kind exempting from glue fiber bar heat setting machine and its heat setting method
CN109591331A (en) * 2019-01-18 2019-04-09 无锡盛烨特邦新材料科技有限公司 One kind exempting from glue fiber bar production line

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