CN1335901A

CN1335901A - Polypropylene fiber and preparation thereof

Info

Publication number: CN1335901A
Application number: CN00802468.5A
Authority: CN
Inventors: 朴坪烈; 崔源晙
Original assignee: Individual
Current assignee: Cologne Fiber
Priority date: 1999-11-10
Filing date: 2000-11-07
Publication date: 2002-02-13
Anticipated expiration: 2020-11-07
Also published as: CN1174129C; DE10084374B4; ES2237983A1; DK200101392A; MXPA02001814A; BR0010462A; DK175963B1; WO2001034884A3; LU90849B1; GB0121728D0; WO2001034884A2; DE10084374T1; EP1234065B1; CA2372453C; GB2365438A; CA2372453A1; ES2237983B1; EP1234065A4; BR0010462B1; AU1177801A

Abstract

Disclosed is a polypropylene fiber, which is obtained from an isotactic polypropylene homopolymer with an isotactic index of 90 to 99 % through melt-spinning or through drawing after melt-spinning, and shows two differential scanning calorimeter (DSC) endothermic peaks between 155 and 170 DEG C. When being thermally bonded with one another, the fibers are made into non-woven fabrics which have excellent strength in addition to being soft. A high quality of the non-woven fabrics can be produced in high speed carding machines with high yields.

Description

Polypropylene fibre and manufacture method thereof

The background of invention

FIELD OF THE INVENTION

Generally speaking, the present invention relates to polypropylene fibre, or rather, relate to and can be used as the polypropylene fibre that supatex fabric is used, make supatex fabric smooth and have outstanding intensity thus, and in the processing of back, can be supatex fabric machinability and physical property are provided.The present invention also relates to the manufacture method of this fiber.

The description of prior art

In order to prepare staple fibre with polyolefin polymer, they must carry out a series of processing: usually polyolefin polymer is mixed with a certain amount of additive, with common production technology the mixture that forms is melt extruded, make fiber, with fiber crimp and be cut into predetermined length.

When being used to make supatex fabric, the polyolefin staple fibre is generally processed to form nonwoven web on carding machine, then carries out heat bonding.

Usually adopt a pair of calender, sonicated or hot-air to carry out heat bonding.

Especially for polypropylene filament or staple fibre, after shredding and combing, arrange and combine the formation net.These nets carry out heat bonding by means of the calender of band rhombus or triangle pattern, make the supatex fabric that can be applicable to multiple industrial circle.In addition, also can adopt hot-air to replace calender.If the employing hot-air, after combing, it is bonding to utilize the hot-air that circulates in the porous drum to carry out, and forms supatex fabric so.

The polypropylene nonwoven fabric has multiple use, can be used for diaper, sanitary towel, mouth mask and medical textile that disposable diaper, uracratia patients are used.Do not require the intensity so high as woven fabric though be used for the supatex fabric of these purposes, they must be soft, and satisfy the requirement to skin safe, because they directly contact skin.

The intensity of supatex fabric depends on their manufacturing technique, also is decided by the physical property of fibrous material.

In order to boost productivity, speed of production will improve usually in the manufacturer of supatex fabric.But the physical property of the fiber that high production speed requirement supatex fabric is used is more outstanding.

The general introduction of invention

In order to solve the problems referred to above that run in the prior art, the inventor has carried out extensive repetitive research to polypropylene yarn or the staple fibre that is applicable to supatex fabric, caused the present invention, result of study is found, record the isotactic polypropylene homopolymers of two endothermic peaks by differential scanning calorimetry (DSC), can be made into the tencel that prior art is not reported so far, and guarantee that the supatex fabric of being made by this fiber has outstanding intensity and pliability.In addition, by control melt index (MI) and polydispersity index in the per pass operation of whole technology, can obtain the fiber of this structure.

Therefore, an object of the present invention is to provide the polypropylene fibre that supatex fabric is used, this fiber can be used in the high speed carding machine, and guarantees that the supatex fabric after the heat bonding has outstanding intensity and pliability.

Another object of the present invention provides the manufacture method of this polypropylene fibre.

Another purpose of the present invention provides the supatex fabric of being made by this polypropylene fibre.

According to the embodiment of the present invention, provide a kind of like this polypropylene fibre, it is that the isotactic polypropylene homopolymers of 90-99% obtains by stretching after melt spinning or the melt spinning by isotactic index.And between 155-170 ℃, two differential scanning calorimetrics (DSC) endothermic peak appears.

According to another implementation of the invention, provide the method for the described polypropylene fibre of preparation, this method comprises the steps:

(a) the fusion isotactic index is 90-99%, melt index (MI) (MI _a) be 10.0-40.0, preferred 10.0-25.0 and polydispersity index (PI _a) be 2.5-6.0, preferred 2.8-5.0, the more preferably isotactic polypropylene homopolymers of 3.5-4.3, the melt index (MI) of the molten polymer of formation is (MI _b), MI _b/ MI _aRatio be 1.01-1.50, polydispersity index (PI _b) compare PI _aNarrow 10% or below;

(b), make the melt index (MI) (MI of fiber with the molten polymer spinning _c) be 16.5-80.0, polydispersity index (PI _c) compare PI _aNarrow 20% or following, MI _c/ MI _aRatio be 1.65-7.50;

(c) optional with tensile fiber.

Brief description of drawings

Also will more clearly understand above-mentioned and other purposes, feature and other advantages of the present invention in conjunction with the accompanying drawings from following detailed description.

Fig. 1 is a dsc endothermic curve, and polypropylene homo fibres wherein of the present invention has two endothermic peaks that significantly recorded by DSC;

Fig. 2 is a dsc endothermic curve, and two tangible endothermic peaks are wherein arranged, and second peak is the acromion at first peak;

Fig. 3 is a dsc endothermic curve, and wherein conventional polypropylene homo fibres only shows a DSC endothermic peak.

Detailed description of the invention

The present invention relates to by isotactic index be the polypropylene homopolymer of 90-99% by melt spinning or melt spinning and the polypropylene fibre that stretches and make, it shows two means of differential scanning calorimetries (DSC) endothermic peak between 155-170 ℃. Polypropylene fibre of the present invention preferably shows the first endothermic peak at 160 ± 3 ℃, shows the second endothermic peak at 165 ± 3 ℃.

When making supatex fabric by polypropylene fibre of the present invention by heat bonding, above-mentioned physical property is so that supatex fabric is both smooth and have outstanding intensity. This advantage be since between roller because very fast again crystallization when again solidifying, occurs in heat or hot pressing function and the fiber of heat fusing in the high-melting-point district.

Material for the manufacture of fiber of the present invention is that isotactic index is the polypropylene homopolymer of 90-99%.

Melt index (MI) (the MI of polypropylene fibre of the present invention_c) be 16.5-80.0, be preferably the MI of isotactic polypropylene material_a1.65-7.50 doubly.

Polydispersity index (the PI of polypropylene fibre of the present invention_c) being preferably 2.1-5.7, more preferably 3.5-4.3 is than the PI of isotactic polypropylene material_aNarrow by 20%.

The preferred fineness of polypropylene fibre of the present invention is the 1.0-80.0 dawn.

Melt index (MI) (the MI that is used for isotactic polypropylene of the present invention_a) preferred 10-40, polydispersity index (PI_a) preferred 2.5-6.0.

When polypropylene during melting, is preferably allocated stabilizing agent or the antioxidant of the consumption of 0.03-2.0% (weight) in extruder, preferred 0.03-0.7% (weight), more preferably 0.03-0.4% (weight).

Except stabilizing agent or antioxidant, also can prepare fiber of the present invention with carboxylate of the common additives in the industry such as deoxidier, colouring agent, metal etc. Can be used for the nickel salt that metal carboxylate of the present invention is selected from 2 ethyl hexanoic acid, sad, capric acid and dodecylic acid, the iron of 2 ethyl hexanoic acid, cobalt, calcium and barium salt and composition thereof. As deoxidier or colouring agent, can select the common calcium stearate that in petrochemical plant, is used for preparing polypropylene homopolymer. Can be used for multiple additives of the present invention can be with reference to european patent application № 279,511.

As mentioned above, the melt index (MI) MI that is used for isotactic polypropylene of the present invention _aPreferred 10-40.For example, work as MI _aBe lower than at 10 o'clock, spinning head pressure can increase during spinning, causes productivity ratio to descend.The heat that this polyacrylic melt spinning needs is just big, and energy consumption is increased.In addition, the fibre strength that obtains under this high heat condition increases, and makes them not be suitable for the supatex fabric of requirement smoothness.On the other hand, as the MI of isotactic polypropylene _aBe higher than at 40 o'clock, the intensity of the fiber of formation is not suitable for supatex fabric.In addition, spinning causes the fusion between the adjacent fiber after regular meeting's cooling is not thorough.

Should be noted that fiber of the present invention comprises the fiber that makes through fusion, spinning, curing and coiling operation, also comprise through the stretching process after the melt spinning, and the fiber that must make through curling operation, HEAT SETTING and cutting short-forming fiber.Through MI, the PI of the fiber of melt spinning and DSC endothermic peak and further stretched fiber much at one.

Prepare in the embodiment of polypropylene filament or staple fibre in the present invention, polymeric material is fusion in extruder, and the molten polymer of formation has MI _b/ MI _aFor the melt index (MI) of 1.01-1.50 is MI _b, polydispersity index PI _bCompare PI _aNarrow by 10%, more preferably narrow 5%.PI _bBe preferably 2.4-5.0.

For example, if MI _bSurpass MI _a1.5 times, polyacrylic strand will rupture, and makes it can not keep its original intensity.In addition, this fracture can cause strand to be orientated required viscosity deficiency at spinneret orifice, can not keep being suitable for the pressure of spinning.In addition, the fibre strength that obtains like this is poor, uses the feel of the supatex fabric that this fiber makes coarse, causes force of labor to descend.When extruding, polyacrylic MI increases 1% or greater than 1% naturally.Work as MI _bFade to and be lower than MI _a1.01 times the time, can the preparation fiber technology in run into very big difficulty.Especially the pressure that high viscosity can increase spinning head occurs at the spinneret orifice place, make spinning process very unstable.Therefore, productive rate can reduce, and fiber quality can seriously descend.

By the cooling condition after the control spinning, changed the second time of the polymer generation MI that experience MI changes in extruding operation.The temperature that postpones the cooling zone, atmosphere, temperature, speed and the cold gas flux of refrigerating gas are depended in MI variation in the cooling step.United States Patent (USP) № 4,193,961 has described and use to have postponed cooling and cooling air, also can be with reference to other documents, and Society of Plastics Engineers for example, " polypropylene fibre-science and technology " of the M.Ahmed that Inc. supports.

Preparation in accordance with the present invention, preferred control is through the melt index (MI) (MI of the fiber of refrigerating work procedure _c) be polymeric material melt index (MI) (MI _a) 1.65-7.50 doubly, polydispersity index PI _cPI than polymeric material _aNarrow 20% or following (that is 0.80PI, _aOr it is wideer).The PI of fiber _cPreferred 2.1-5.7, more preferably 2.3-4.5, most preferably 3.0-4.0.

Work as MI.When exceeding above-mentioned scope, the intensity decreases of raw yarn.The machinability of making supatex fabric with raw yarn is just poor, because supatex fabric pollutes card clothing easily, and partial melting is on calender.In detail, if MI _cDepart from higher limit, the molecular weight and molecular weight of yarn is too big, and the cooling effect that spins behind the silk from spinneret orifice also descends, and can produce between the yarn and merge.Even make yarn, and be used for making supatex fabric, in shredding and combing operation, also need more energy, influence manufacturing technique.In addition, the hot-short weak part of poor quality's yarn can melt when calendering, stains the calender surface of working in the last heat bonding of supatex fabric.

On the other hand, if MI _cExceed lower limit, the intensity of raw yarn can improve so, but is difficult to the heat bonding index of this raw yarn (below be called " TBI ") is brought up to desired degree.That is, the TBI of the supatex fabric that obtains is low, and feel is coarse.Though can improve the intensity or the TBI of supatex fabric by the temperature that increases calender or heat bonding district, supatex fabric is still very coarse.

When making supatex fabric, their machine-direction oriented and transverse strength is put with row with the carding machine kind and different.If these machines are made by different manufacturers, so, the vertical and horizontal intensity difference of the supatex fabric of process carding machine.Even on the carding machine that same manufacturer makes, supatex fabric also along with the shape of card clothing and material and arbitrarily roller existence and show different physical properties.In addition, according to the needs of back processing, the design weight difference of supatex fabric.The supatex fabric intensity level that records is only represented toughness, and each company characterizes all different to volume unit.Therefore, because situation good and bad between them can take place to distinguish, so only can not determine with intensity whether the physical property of supatex fabric is improved.Yet, though put may be different for the kind of carding machine or row, can be with reference to the bondability index of the supatex fabric of making, come the influence of the structure of comparison yarns or staple fibre and inherent physical property to supatex fabric.

Therefore, determining that accurately it is very suitable that the notion of TBI is considered in the influence of physical property to supatex fabric of yarn or staple fibre.Describe TBI in detail in " polypropylene fibre and textiles " article of in the 4th international conference that plastics and rubber association hold, reporting.Really, the present invention has quoted TBI and has come to determine relatively the influence of the physical property of yarn or staple fibre to supatex fabric as the most useful parameter.

Available TBI be 2.0 or higher fiber of the present invention make the good supatex fabric of pliability.

The present invention may be better understood by following embodiment, and they are to be used for illustrating of the present invention, can not be interpreted as restriction the present invention.

In the following embodiments, the fiber of the present invention's proposition and the physical property of supatex fabric have been analyzed.

The DSC endothermic peak: fully the washing the fibre sample is to remove finish.After air drying 30 minutes, the 2-4 millimeters long is cut in sample vacuumize in vacuum plant (decicater) after 1 hour.5 milligrams of samples that are cut into are put into the measurement dish, then use Perkin Elmer 7 series of heat analyzers to carry out heat and analyze, be warming up to 190 ℃ with 5 ℃ of/minute clock rate from 30 ℃, to obtain endothermic curve.Other conditions of this test are according to ASTM 3418-82 method.Conventional polypropylene homo fibres shows single endothermic peak, and fiber of the present invention has two endothermic peaks, as shown in drawings.Fig. 1 has shown the obvious DSC endothermic peak of two of fiber of the present invention, and second DSC endothermic peak appears in Fig. 2 on the acromion of first endothermic peak.Fig. 3 is the conventional fibre endothermic curve, only demonstrates a DSC endothermic peak.

The dawn number of yarn and staple fibre: the Vibroskop that uses Lenzing to make measures.

The intensity of yarn and staple fibre and percentage elongation: the Vibrodyn that uses Lenzing to make, press ASTM D638 and measure.

Melt index (MI) (MI): use the MP993 type instrument of Tinius Olsen, press ASTM D1238 and measure.Measure MI and must wash fiber sample with massive laundering, centrifugal dehydration, 105 ℃ of dryings are 15 minutes in baking oven, and are cut into 1 centimeter length.

Polydispersity index (PI): use RMS-800 (dish, the parallel-plate) type of U.S. Rheometrics, under 10% strained condition, measure Gc in 200 ℃ with the shear rate of 0.1-100, and the substitution following formula:

PI = \frac{10^{6}}{G_{c}}

Wherein Gc is storage modulu (G ') and the loss modulus (modulus of the point that intersect at 2-6 the frequency place of G ") in 5-250 hertz frequency scope.When joining not occurring, Gc is determined by extrapolation.

Isotactic index (I.I.): the polypropylene homo matter sample is cut into 5 millimeters long, wash with water, and in baking oven 105 ℃ of dryings 1 hour.Take out about 5 grams, accurately weigh then, a part of drying sample boiled in heptane about 5 hours, extracted.After extraction finishes, the abundant washing sample of water, 105 ℃ of dryings are 1 hour in baking oven, then weigh.With before the extraction and after the weight substitution following formula that records, obtain isotactic index. The heat bonding index (TBI) of supatex fabric: calculate according to following formula:

Wherein MD is longitudinal strength (kilogram/50 millimeters), and CD is transverse strength (kilogram/50 millimeters), and design weight is the weight of supatex fabric unit are.

The intensity of supatex fabric: use Instron to test the sample of 50 mm wides and 140 millimeters long with the draw speed of 100 mm/min.

Pliability: the classification of feel: 1: very coarse; 2: coarse; 3: general; 4: softness; 5: very soft.

Embodiment 1-7 and Comparative Examples 1-7

Isotactic index be 97 and MI be the isotactic polypropylene homopolymers that contains 0.09% (weight) antioxidant and stabilizing agent shown in the table 1, melt spinning in temperature is 250-290 ℃ extruder, utilize heat medium the heating to the spinning head scope to be controlled in the 285-310 ℃ of scope simultaneously, make melt have the MIb shown in the table 1 from extruder.MI for the melt before raw material relatively and the spinning head just in the gear pump front that is used for the constant melt is fed spinning head, is provided with a branch road, with at pressure hour sample thief.

Then, melt is extruded from spinnerets with 1500 meters/minute spinning speed, and through protecting the hot-zone to postpone cooling, cooling forms the spun yarn at 2.4 dawn again, and its MIc, PIc and DSC endothermic peak are as shown in table 1.

The spun yarn that obtains is like this collected bunchy, and stretch, in crimping machine, curl, be cut into the staple fibre of 40 millimeters long then with 1.5 times draw ratio.

Table 2 has provided MI, PI, fibre strength, crispation number and the DSC endothermic peak of gained staple fibre.

In order to make supatex fabric, require staple fibre is administered on the carding machine according to manufacturer.The top roll that is used for making supatex fabric is an argyle design, and the sealing area reaches 22%, and calender is 147 ℃, 95 kg/cm ²Pressure operation calendering down.

The design weight of the supatex fabric that obtains, longitudinal strength and transverse strength, TBI and pliability are as shown in table 3.

Table 1

The embodiment numbering	Material		Melt		Fiber		?MI _b/MI _a	?MI _c/MI _a
	Material		Melt		Fiber				????MI _a	????PI _a	????MI _b	????PI _b	????MI _c	????PI _c
	??1	????17.2	????4.1	????18.2	????3.9	????52.0			????MI _a	????PI _a	????MI _b	????PI _b	????MI _c	????PI _c	????3.8	????1.1	????3.0
??2	??1	????17.2	????4.1	????18.2	????3.9	????52.0	????22	????3.2	????23.0	????3.1	????56.0	????2.9	????1.0	????2.5	????3.8	????1.1	????3.0
??2	??3	????12.2	????5.5	????18.0	????5.1	????57.0	????22	????3.2	????23.0	????3.1	????56.0	????2.9	????1.0	????2.5	????4.5	????1.5	????4.7
??4	??3	????12.2	????5.5	????18.0	????5.1	????57.0	????12.2	????6.0	????17.0	????5.5	????36.5	????4.9	????1.4	????3.0	????4.5	????1.5	????4.7
??4	??5	????13.2	????4.3	????15.0	????3.9	????45.0	????12.2	????6.0	????17.0	????5.5	????36.5	????4.9	????1.4	????3.0	????3.6	????1.1	????3.4
??6	??5	????13.2	????4.3	????15.0	????3.9	????45.0	????11.0	????3.8	????14.6	????3.6	????46.0	????3.5	????1.3	????4.2	????3.6	????1.1	????3.4
??6	??7	????11.0	????5.8	????13.6	????5.6	????31.2	????11.0	????3.8	????14.6	????3.6	????46.0	????3.5	????1.3	????4.2	????4.9	????1.2	????2.8
??C1	??7	????11.0	????5.8	????13.6	????5.6	????31.2	????12.2	????2.4	????17.0	????2.3	????24.3	????2.2	????1.4	????2.0	????4.9	????1.2	????2.8
??C1	??C2	????17.1	????10.8	????29.2	????9.5	????106.5	????12.2	????2.4	????17.0	????2.3	????24.3	????2.2	????1.4	????2.0	????6.5	????1.7	????6.2
??C3	??C2	????17.1	????10.8	????29.2	????9.5	????106.5	????3.9	????6.5	????5.6	????6.4	????32.5	????5.1	????1.4	????8.3	????6.5	????1.7	????6.2
??C3	??C4	????12.2	????5.5	????15.4	????4.9	????80.2	????3.9	????6.5	????5.6	????6.4	????32.5	????5.1	????1.4	????8.3	????4.7	????1.3	????6.6
??C5	??C4	????12.2	????5.5	????15.4	????4.9	????80.2	????8.1	????5.6	????11.6	????5.1	????28.0	????4.2	????1.4	????3.5	????4.7	????1.3	????6.6
??C5	??C6	????10.8	????12.0	????19.1	????11.0	????39.5	????8.1	????5.6	????11.6	????5.1	????28.0	????4.2	????1.4	????3.5	????10.2	????1.8	????3.7
??C7	??C6	????10.8	????12.0	????19.1	????11.0	????39.5	????42.5	????5.9	????62.4	????5.7	????698.0	????5.1	????1.5	????4.7	????10.2	????1.8	????3.7

Table 1 is continuous

The embodiment numbering	??{1-(PI _b/PI _a)} ????×100(％)	??{1-(PI _c/PI _a)} ????×100(％)	The DSC endothermic peak of spun yarn (℃)
			The DSC endothermic peak of spun yarn (℃)		????1′	????2′
			???1	????4.9	????1′	????2′	????7.3	????159.6	????164.2
???2	????3.1	????9.4	???1	????4.9	????160.2	????164.5	????7.3	????159.6	????164.2
???2	????3.1	????9.4	???3	????7.3	????160.2	????164.5	????18.2	????159.8	????165.2
???4	????8.3	????18.3	???3	????7.3	????158.9	????164.8	????18.2	????159.8	????165.2
???4	????8.3	????18.3	???5	????9.3	????158.9	????164.8	????16.3	????160.1	????163.9
???6	????5.3	????7.9	???5	????9.3	????160.0	????166.2	????16.3	????160.1	????163.9
???6	????5.3	????7.9	???7	????3.4	????160.0	????166.2	????15.5	????159.5	????164.2
???C1	????4.2	????8.3	???7	????3.4	????159.8	????-	????15.5	????159.5	????164.2
???C1	????4.2	????8.3	???C2	????12.0	????159.8	????-	????39.8	????160.2	????-
???C3	????1.5	????21.5	???C2	????12.0	????160.2	????-	????39.8	????160.2	????-
???C3	????1.5	????21.5	???C4	????10.9	????160.2	????-	????14.5	????159.2	????-
???C5	????8.9	????25.0	???C4	????10.9	????160.0	????-	????14.5	????159.2	????-
???C5	????8.9	????25.0	???C6	????8.3	????160.0	????-	????15.0	????159.9	????-
???C7	????8.4	????13.6	???C6	????8.3	????159.8	????-	????15.0	????159.9	????-

Table 2

The embodiment numbering	??????????MIc		??????????PIc		Fibre strength (gram/dawn)	Crispation number	The DSC endothermic peak of staple fibre (℃)
	??????????MIc		??????????PIc				The DSC endothermic peak of staple fibre (℃)		The fiber that spinning forms	The staple fibre of spinning after-drawing	The fiber that spinning forms	The staple fibre of spinning after-drawing	????1′	????2′
	??1	???52.0	??51.0	???3.8			???3.7	???1.9	The fiber that spinning forms	The staple fibre of spinning after-drawing	The fiber that spinning forms	The staple fibre of spinning after-drawing	????1′	????2′	??7.7	????159.4	???164.2
??2	??1	???52.0	??51.0	???3.8	???56.0	??55.0	???3.7	???1.9	???2.9	???2.8	???2.2	??6.2	????160.1	???164.5	??7.7	????159.4	???164.2
??2	??3	???57.0	??57.6	???4.5	???56.0	??55.0	???4.5	???2.3	???2.9	???2.8	???2.2	??6.2	????160.1	???164.5	??6.4	????159.7	???165.8
??4	??3	???57.0	??57.6	???4.5	???36.5	??36.9	???4.5	???2.3	???4.9	???5.0	???1.9	??6.4	????158.9	???165.1	??6.4	????159.7	???165.8
??4	??5	???45.0	??44.0	???3.6	???36.5	??36.9	???3.8	???2.4	???4.9	???5.0	???1.9	??6.4	????158.9	???165.1	??7.2	????160.2	???164.1
??6	??5	???45.0	??44.0	???3.6	???46.0	??47.3	???3.8	???2.4	???3.5	???3.4	???2.2	??6.2	????159.8	???165.8	??7.2	????160.2	???164.1
??6	??7	???31.2	??33.0	???4.9	???46.0	??47.3	???4.8	???2.6	???3.5	???3.4	???2.2	??6.2	????159.8	???165.8	??55.9	????159.9	???163.7
??C1	??7	???31.2	??33.0	???4.9	???24.3	??24.3	???4.8	???2.6	???2.2	???2.3	???2.2	??7.5	????160.1	???-	??55.9	????159.9	???163.7
??C1	??C2	???106.5	??104.2	???6.5	???24.3	??24.3	???6.5	???1.7	???2.2	???2.3	???2.2	??7.5	????160.1	???-	??7.6	????160.2	???-
??C3	??C2	???106.5	??104.2	???6.5	???32.3	??33.6	???6.5	???1.7	???5.1	???5.2	???2.2	??6.5	????160.3	???-	??7.6	????160.2	???-
??C3	??C4	???80.2	??81.2	???4.7	???32.3	??33.6	???4.9	???1.9	???5.1	???5.2	???2.2	??6.5	????160.3	???-	??8.1	????160.4	???-
??C5	??C4	???80.2	??81.2	???4.7	???28.0	??29.3	???4.9	???1.9	???4.2	???4.3	???2.1	??6.9	????160.1	???-	??8.1	????160.4	???-
??C5	??C6	???39.6	??41.2	???10.2	???28.0	??29.3	???10.3	???1.6	???4.2	???4.3	???2.1	??6.9	????160.1	???-	??7.2	????160.2	???-
??C7	??C6	???39.6	??41.2	???10.2	???201.0	??197.0	???10.3	???1.6	???5.1	???5.2	???1.7	??6.5	????160.1	???-	??7.2	????160.2	???-

Table 3

The embodiment numbering	Combing			Intensity (kilogram/5 centimetres)		????TBI	Pliability	Note
	Combing			Intensity (kilogram/5 centimetres)					Machine	Speed (rice/minute)	Design weight (gram/rice ²)	???MD	????CD
	??1	??THIBEAU	????180	????21.0	???5.3				Machine	Speed (rice/minute)	Design weight (gram/rice ²)	???MD	????CD	????1.4	????2.6	??5	????-
??2	??1	??THIBEAU	????180	????21.0	???5.3	??SPINNBAU	????175	????19.0	???5.2	????1.2	????2.6	??4	????-	????1.4	????2.6	??5	????-
??2	??3	??SPINNBAU	????100	????19.5	???7.2	??SPINNBAU	????175	????19.0	???5.2	????1.2	????2.6	??4	????-	????2.6	????4.4	??5	????-
??4	??3	??SPINNBAU	????100	????19.5	???7.2	??SPINNBAU	????210	????17.8	???6.2	????1.5	????3.4	??4	????-	????2.6	????4.4	??5	????-
??4	??5	??HERGETH	????95	????20.1	???4.9	??SPINNBAU	????210	????17.8	???6.2	????1.5	????3.4	??4	????-	????1.8	????3.0	??5	????-
??6	??5	??HERGETH	????95	????20.1	???4.9	??HERGETH	????95	????22.1	???6.8	????1.8	????3.2	??4	????-	????1.8	????3.0	??5	????-
??6	??7	??HERGETH	????180	????20.3	???3.9	??HERGETH	????95	????22.1	???6.8	????1.8	????3.2	??4	????-	????1.4	????2.3	??4	????-
??C1	??7	??HERGETH	????180	????20.3	???3.9	??SPINNBAU	????100	????20.2	???3.2	????0.9	????1.7	??1	Coarse	????1.4	????2.3	??4	????-
??C1	??C2	??HERGETH	????150	????21.0	???3.5	??SPINNBAU	????100	????20.2	???3.2	????0.9	????1.7	??1	Coarse	????0.8	????1.6	??3	TBI descends
??C3	??C2	??HERGETH	????150	????21.0	???3.5	??SPINNBAU	????150	????20.3	???3.4	????0.9	????1.7	??1	TBI descends	????0.8	????1.6	??3	TBI descends
??C3	??C4	??SPINNBAU	????160	????20.4	???3.5	??SPINNBAU	????150	????20.3	???3.4	????0.9	????1.7	??1	TBI descends	????1.0	????1.8	??2	TBI descends
??C5	??C4	??SPINNBAU	????160	????20.4	???3.5	??SPINNBAU	????100	????19.8	???3.8	????0.9	????1.9	??2	Coarse	????1.0	????1.8	??2	TBI descends
??C5	??C6	??SPINNBAU	????105	????18.9	???3.9	??SPINNBAU	????100	????19.8	???3.8	????0.9	????1.9	??2	Coarse	????0.8	????1.9	??2	Coarse
??C7	??C6	??SPINNBAU	????105	????18.9	???3.9	??SPINNBAU	????90	????19.5	???3.8	????0.9	????1.9	??3	Difficulty, NEP is many	????0.8	????1.9	??2	Coarse

From the foregoing description as seen, the supatex fabric with the isotactic polypropylene homopolymer fibre heat bonding that two DSC endothermic peaks are arranged of the present invention is made except softness, also shows outstanding intensity.Also can on the high speed carding machine, make supatex fabric.Thus, the present invention can high yield make the high-quality supatex fabric.

More than in illustrative mode the present invention has been described, should be understood that the technology words and phrases of use are illustrative, rather than the restriction the present invention.According to above-mentioned technology, can carry out multiple modification and variation.Therefore, should be understood that within the scope of the appended claims, also can implement the present invention in the mode different with described concrete mode.

Claims

1. polypropylene fibre, it is that the isotactic polypropylene homopolymers of 90-99% obtains by stretching after melt spinning or the melt spinning by isotactic index, and it shows two endothermic peaks that recorded by differential scanning calorimetry (DSC) between 155-170 ℃.

2. second endothermic peak when polypropylene fibre as claimed in claim 1, the endothermic peak that wherein said two differential scanning calorimetries (DSC) record comprise first endothermic peak when appearing at 160 ± 3 ℃ and appear at 165 ± 3 ℃.

3. polypropylene fibre as claimed in claim 1, the melt index (MI) (MI of wherein said fiber _c) be 16.5-80.0.

4. polypropylene fibre as claimed in claim 1, the polydispersity index (PI of wherein said fiber _c) be 2.1-5.7.

5. polypropylene fibre as claimed in claim 1, the fineness of wherein said fiber are 1.0-80.0 dawn/monofilament.

6. polypropylene fibre as claimed in claim 4, the PI of wherein said fiber _cBe 2.3-4.5.

7. polypropylene fibre as claimed in claim 1, it also contains stabilizing agent and/or the antioxidant of 0.03-2.0% (weight).

8. polypropylene fibre as claimed in claim 7, the content of wherein said stabilizing agent and/or antioxidant are 0.03-0.7% (weight).

9. polypropylene fibre as claimed in claim 8, the content of wherein said stabilizing agent and/or antioxidant are 0.03-0.4% (weight).

10. method for preparing polypropylene fibre, it comprises the steps:

(a) the fusion isotactic index is 90-99%, melt index (MI) (MI _a) be 10.0-40.0 and polydispersity index (PI _a) be the isotactic polypropylene homopolymers of 2.5-6.0, form molten polymer, this molten polymer melt index (MI) is MI _b, MI _b/ MI _aRatio be 1.01-1.50, polydispersity index (PI _b) compare PI _aNarrow 10% or below;

(c) randomly with tensile fiber.

11. method as claimed in claim 10, wherein in described step (a), described polypropylene homopolymer contains 0.03-2.0% (weight) stabilizing agent and/or antioxidant.

12. method as claimed in claim 10, wherein said MI _aBe 10-30.

13. method as claimed in claim 10, wherein said PI _aBe 2.8-5.0.

14. method as claimed in claim 13, wherein said PI _aBe 3.5-4.3.

15. method as claimed in claim 10, the fineness of wherein said fiber are 1.0-80.0 dawn/monofilament.

16. method as claimed in claim 10, wherein said MI _bBe 10.1-41.0.

17. method as claimed in claim 10, the PI of wherein said fiber _cBe 2.1-5.7.

18. method as claimed in claim 17, the PI of wherein said fiber _cBe 2.3-4.5.