阅读说明：本技术 一种超细旦多孔涤纶丝及其制备方法 (Superfine denier porous polyester yarn and preparation method thereof ) 是由 朱冰斌 于 2021-07-15 设计创作，主要内容包括：本申请涉及化纤领域,更具体地说,它涉及一种超细旦多孔涤纶丝及其制备方法,其中超细旦多孔涤纶丝的原料包括聚酯熔体、锦纶熔体、纳米金属氧化物、氧化聚乙烯蜡、聚羟基丁酸酯和其他助剂,其制备方法包括如下步骤：S1、取聚酯切片和锦纶切片,进行结晶干燥处理；S2、混合后熔融挤出；S3、丝线经冷却,上油、网络、绕卷,得到超细旦多孔涤纶丝；所述挤出机中,各段的温度不低于257℃,且不高于280℃,步骤S2中,过滤所用的滤网滤孔孔径不大于15μm。在本申请中,丝线生产过程中出现的断丝现象较少,丝线强度较高,有助于提高生产效率。(The application relates to the field of chemical fibers, in particular to a superfine denier porous polyester yarn and a preparation method thereof, wherein the raw materials of the superfine denier porous polyester yarn comprise a polyester melt, a polyamide melt, a nano metal oxide, oxidized polyethylene wax, polyhydroxybutyrate and other auxiliaries, and the preparation method comprises the following steps: s1, taking polyester chips and nylon chips, and carrying out crystallization drying treatment; s2, mixing, and then melt-extruding; s3, cooling the silk yarn, oiling, networking and winding to obtain the superfine denier porous polyester yarn; in the extruder, the temperature of each section is not lower than 257 ℃ and not higher than 280 ℃, and in the step S2, the aperture of the filtering holes of the filtering screen used for filtering is not more than 15 μm. In this application, the silk thread breakage phenomenon that appears in the silk thread production process is less, and silk thread intensity is higher, helps improving production efficiency.)

1. The superfine porous polyester yarn is characterized in that the raw materials comprise polyester melt, nylon melt, nano metal oxide, oxidized polyethylene wax, polyhydroxybutyrate and other auxiliary agents, wherein,

the mass ratio of the polyester melt to the polyamide melt is 1: 0.2-0.3;

the nano metal oxide is one of nano zirconium oxide, nano aluminum oxide, nano zinc oxide, nano iron oxide, nano titanium oxide and nano chromium oxide, and the particle size of the nano metal oxide is less than 200 nm; the mass of the nano metal oxide is 0.1-0.4% of the total mass of the polyester melt and the polyamide melt;

the adding mass of the oxidized polyethylene wax is 1-5% of the total mass of the polyester melt and the polyamide melt;

the adding mass of the polyhydroxybutyrate is 5-10% of the total mass of the polyester melt and the polyamide melt;

the adding mass of other additives is 0-4% of the total mass of the polyester melt and the polyamide melt.

2. The superfine porous polyester yarn as claimed in claim 1, wherein the polyester melt is ethylene terephthalate.

3. The superfine denier porous polyester yarn as claimed in claim 2, wherein the viscosity of the mixed polyester melt and nylon melt is 0.65-0.67 dL/g.

4. The superfine denier porous polyester yarn as claimed in claim 1, wherein the metal nano-oxide is nano-zirconia.

5. The superfine denier porous polyester yarn as claimed in claim 4, wherein the other additives comprise low density polyethylene, and the mass of the low density polyethylene is 1.5-2% of the total mass of the polyester melt and the nylon melt.

6. The superfine denier porous polyester yarn as claimed in claim 4, wherein the other additives comprise a nonionic surfactant accounting for 1.0-1.2% of the total mass of the polyester melt and the nylon melt, and crown ether accounting for 0.2-0.3% of the total mass of the polyester melt and the nylon melt.

7. The method for preparing the superfine denier porous polyester yarn as claimed in any one of claims 1 to 6, which is characterized by comprising the following steps:

s1, taking polyester chips and nylon chips, and carrying out crystallization drying treatment;

s2, melting the crystallized and dried polyester chips and polyamide chips, adding nano metal oxide, oxidized polyethylene wax, polyhydroxybutyrate and other auxiliaries, mixing uniformly, filtering and extruding into filaments in a screw extruder;

s3, cooling the silk yarn, oiling, networking and winding to obtain the superfine denier porous polyester yarn;

in the extruder, the temperature of each section is not lower than 257 ℃ and not higher than 280 ℃, and in the step S2, the aperture of the filtering holes of the filtering screen used for filtering is not more than 15 μm.

8. The method for preparing the superfine denier porous polyester yarn as claimed in claim 7, wherein a first section, a second section and a third section are sequentially arranged from a feeding end to a discharging end in the extruder, the temperature of the first section is 259-261 ℃, the temperature of the second section is 275-277 ℃, the temperature of the third section is 263-265 ℃, the length ratio of the first section to the second section to the third section is 1: 1.3-1.5: 0.9-1, and the screw rotation speed is 30-40 r/min.

9. The method for preparing the superfine denier porous polyester yarn as claimed in claim 8, wherein the temperature of the extrusion head is 230-233 ℃, the extrusion head is stretched by hot air flow with the pressure of 0.1-0.12 mPa, and the temperature of the hot air flow is 202-210 ℃.

10. The method for preparing the superfine denier porous polyester yarn as claimed in claim 6, wherein in the step S3, the air pressure of the circular blowing air is controlled to be 16-20 Pa, the temperature of the circular blowing air is divided into two sections, the temperature of the first section is 60-70 ℃, and the temperature of the second section is 15-20 ℃; the ratio of the time of the silk thread passing through the two sections of circular air blowing is (0.2-0.3) to 1, and the humidity of the two sections is controlled below 60 percent.

Technical Field

The application relates to the field of chemical fibers, in particular to superfine denier porous polyester yarns and a preparation method thereof.

Background

The super fine denier fiber is generally a fiber having a fineness of 1.5D or less, and has a more bulky and soft touch because the super fine denier fiber is finer than conventional fibers. The porous fiber has good warm-keeping and heat-insulating effects due to the porous structure in the porous fiber, and meanwhile, the density of the fiber is low, the hand feeling is soft, and the fiber is breathable and comfortable. The superfine denier porous polyester fiber is widely applied to the fields of clothes, furniture fabrics or other special fabrics.

In the production process of the superfine denier porous polyester yarn, the yarn is thin originally, so that the phenomena of breakage, yarn floating and the like are easy to generate, and the production efficiency of enterprises is seriously influenced.

Disclosure of Invention

In order to reduce the phenomena of end breakage and filament floating of the superfine denier porous polyester filament in the production process, the application provides the superfine denier porous polyester filament and the preparation method thereof.

Firstly, the application provides a superfine denier porous polyester yarn, which comprises polyester melt, nylon melt, nano metal oxide, oxidized polyethylene wax, polyhydroxybutyrate and other auxiliary agents,

the mass ratio of the polyester melt to the polyamide melt is 1: 0.2-0.3;

the nano metal oxide is one of nano zirconium oxide, nano aluminum oxide, nano zinc oxide, nano iron oxide, nano titanium oxide and nano chromium oxide, and the particle size of the nano metal oxide is less than 200 nm; the mass of the nano metal oxide is 0.1-0.4% of the total mass of the polyester melt and the polyamide melt;

the adding mass of the oxidized polyethylene wax is 1-5% of the total mass of the polyester melt and the polyamide melt;

the adding mass of the polyhydroxybutyrate is 5-10% of the total mass of the polyester melt and the polyamide melt;

the adding mass of other additives is 0-4% of the total mass of the polyester melt and the polyamide melt.

In the technical scheme, the polyester is used as a main body, the polyester melt and the nylon melt are selected, the polyester melt and the nylon melt have good compatibility, and meanwhile, the nano metal oxide has good coating performance, so that the silk thread has good strength integrally. The nylon has certain polarity, the overall viscosity is stronger than that of the polyester, the improvement of the strength of the silk thread is facilitated, and the compatibility of the polyester and the nano metal oxide is improved.

The nanometer metal oxide plays a role in improving the wear resistance of the silk thread, and meanwhile, the nanometer powder is adopted, so that the problem that the polyester silk is hard in hand feeling can be solved, in addition, the polyhydroxybutyrate is added, the integral softness is improved, the integral strength is good, and the occurrence of breakage is further reduced. Polyethylene wax is used for improving the flatness and smoothness of the surface of the silk thread, so that the surface of the silk thread is smoother, static electricity is reduced to a certain extent, and the possibility of breakage of the silk thread is further reduced.

In conclusion, by adopting the technical scheme, the possibility of breakage of the polyester yarns during preparation of the superfine-denier porous polyester yarns can be reduced, and the production efficiency is greatly improved.

Optionally, the polyester melt is ethylene terephthalate.

The ethylene terephthalate has high strength and good forming performance, and is not easy to break as a whole.

Optionally, the viscosity range of the mixed polyester melt and polyamide melt is 0.65-0.67 dL/g.

The mixture of the polyester melt and the polyamide melt within the viscosity range is not easy to break and adhere when being extruded and spun, has better spinning performance as a whole, and is beneficial to improving the spinning production efficiency.

Optionally, the metal nano-oxide is nano-zirconia.

In the technical scheme, on one hand, the nano zirconia has better wear resistance, and meanwhile, the overall property of the nano zirconia is stable, and metal ions are not easy to release, so that the stability of the silk thread can be kept without additionally adding a metal complexing agent.

Optionally, the other additives comprise low-density polyethylene, and the adding mass of the low-density polyethylene is 1.5-2% of the total mass of the polyester melt and the nylon melt.

In the technical scheme, the low-density polyethylene contributes to further improving the overall compatibility, and meanwhile, the melting temperature of the system can be reduced, so that the processing is easier, and meanwhile, when the processing is carried out, because the low-density polyethylene is melted, a tighter winding state can be formed through flexible molecular chains, the whole spinning machine is less prone to breakage, and the spinning production efficiency is further improved.

Optionally, the other auxiliary agents comprise a nonionic surfactant accounting for 1.0-1.2% of the total mass of the polyester melt and the nylon melt and crown ether accounting for 0.2-0.3% of the total mass of the polyester melt and the nylon melt.

The nonionic surfactant mainly plays a role in lubrication, reduces the agglomeration of nano metal oxides, and crown ether also has a similar effect. The combination of the two contributes to further improving the uniformity of the mixed system, making the yarn more difficult to break.

In addition, the application provides a preparation method of the superfine denier porous polyester yarn, which comprises the following steps:

s1, taking polyester chips and nylon chips, and carrying out crystallization drying treatment;

s2, melting the crystallized and dried polyester chips and polyamide chips, adding nano metal oxide, oxidized polyethylene wax, polyhydroxybutyrate and other auxiliaries, mixing uniformly, filtering and extruding into filaments in a screw extruder;

s3, cooling the silk yarn, oiling, networking and winding to obtain the superfine denier porous polyester yarn;

in the extruder, the temperature of each section is not lower than 257 ℃ and not higher than 280 ℃, and in the step S2, the aperture of the filtering holes of the filtering screen used for filtering is not more than 15 μm.

The superfine denier porous polyester yarn is prepared by the preparation method, and the whole low temperature is adopted, so that the strength of the yarn is improved. Due to the fact that oxidized polyethylene wax and polyhydroxybutyrate are added into the system, the extrusion can be smoothly carried out at a low temperature, the whole filament is smooth in discharging, the filament is not prone to breaking, and therefore production efficiency is improved.

Optionally, in the extruder, a first section, a second section and a third section are sequentially arranged from a feeding end to a discharging end, the temperature of the first section is 259-261 ℃, the temperature of the second section is 275-277 ℃, the temperature of the third section is 263-265 ℃, the length ratio of the first section, the second section and the third section is 1: 1.3-1.5: 0.9-1, and the rotating speed of a screw is 30-40 r/min.

In the technical scheme, the production is carried out by adopting the parameters, and the fracture rate is lower while the components are uniformly mixed.

Optionally, the temperature of the extrusion head is 230-233 ℃, the extrusion head is drafted by hot air flow with the pressure of 0.1-0.12 mPa, and the temperature of the hot air flow is 202-210 ℃.

The temperature of the extrusion head is slightly lower than that of the screw, and the extruded silk threads are fully extended by hot air with higher temperature, the lower pressure of the hot air is beneficial to further reducing the breakage of the silk threads caused by uneven stress, meanwhile, the hot air is also beneficial to slowing down the cooling speed of the silk threads, so that the silk threads are uniformly cooled, and the breakage probability of the silk threads in the processing process is further reduced.

Optionally, in step S3, in the cooling process, the air pressure of the circular blowing air is controlled to be 16 to 20Pa, the temperature of the circular blowing air is divided into two sections, the temperature of the first section is 60 to 70 ℃, and the temperature of the second section is 15 to 20 ℃; the ratio of the time of the silk thread passing through the two sections of circular air blowing is (0.2-0.3) to 1, and the humidity of the two sections is controlled below 60 percent.

Among the above-mentioned technical scheme, adopt two sections refrigerated modes, the silk thread receives the cold inhomogeneous phenomenon that breaks that receives in the further reduction cooling process takes place, because silk thread itself is comparatively smooth, the wearing and tearing that the silk thread received in the operation process are less, has reduced the phenomenon that water infiltration produced the destruction to the molecular structure of silk thread in the silk thread simultaneously for the broken phenomenon further reduces.

In summary, the present application includes at least one of the following advantages:

1. in the application, the polyester melt and the polyamide melt are used as raw materials, and the nano metal oxide, the oxidized polyethylene wax, the polyhydroxybutyrate and other auxiliaries are added, so that the yarn breakage phenomenon of the superfine denier porous polyester yarn in the production process is reduced, and the production efficiency is improved.

2. In this application further sets up, through adding low density polyethylene, when reducing whole operating temperature, help further reducing the broken silk rate, improve the production efficiency and the quality of silk thread.

3. The application provides a preparation method of the superfine denier porous polyester yarn, which optimizes preparation parameters and process, adopts lower temperature for production and further reduces the occurrence of yarn breakage.

Detailed Description

The present application will be described in further detail with reference to examples.

In the following examples and comparative examples, the sources and specifications of the materials used are given in Table 1.

TABLE 1 partial Components Source Table

Examples 1 to 6 show that the raw material components of the superfine denier porous polyester yarn are shown in table 2 in terms of specific gravity.

Table 2, examples 1 to 6 Material mass fraction (%)

Taking example 1 as an example, the preparation method of the superfine denier porous polyester yarn in the above example comprises the following steps: s1, weighing the polyester chips, the nylon chips and the polyhydroxybutyrate master batches, and respectively carrying out crystallization drying in different crystallization beds, wherein the temperature in the crystallization drying process of the polyester chips and the nylon chips is controlled to be 175-180 ℃, and the crystallization temperature of the polyhydroxybutyrate master batches is controlled to be 140-145 ℃.

S2, melting the polyester chips and the nylon chips to obtain a polyester melt and a nylon melt, mixing the polyester melt and the nylon melt, adding the nano metal oxide, the polyhydroxybutyrate and the oxidized polyethylene wax, fully stirring and uniformly mixing, filtering by a 15-micrometer filter screen, adding into a single-screw extruder, and extruding into filaments, wherein the single-screw extruder is divided into three sections, from a feeding end to a discharging end, the single-screw extruder is sequentially divided into a first section, a second section and a third section, the temperature of the first section is 259 ℃, the temperature of the second section is 277 ℃, and the temperature of the third section is 265 ℃. The length ratio of the first section, the second section and the third section is 1: 1.5: 0.9, and the screw rotation speed is 30 rpm. The temperature of the extrusion head is controlled at 233 ℃, and the extrusion head is stretched by hot air flow with the pressure of 0.1mPa, and the temperature of the hot air flow is 209 +/-1 ℃.

S3, cooling the extruded silk yarn by two sections of circular blowing, controlling the wind pressure of the two sections of circular blowing to be 16Pa, wherein the temperature of the first section of circular blowing is 65 +/-2 ℃, the temperature of the second section of circular blowing is 18 +/-2 ℃, the silk yarn is blown circularly from top to bottom through the two sections of circular blowing, the time of the first section of circular blowing is 0.6S, the time of the second section of circular blowing is 3S, and after cooling by the two sections of circular blowing, oiling, networking and winding are carried out to obtain the superfine denier porous polyester yarn.

In examples 1 to 7, the nano metal oxide is nano zirconia having a particle size range of less than 200 μm, and the main particle size distribution is 100 to 200 μm and the small amount is 50 to 100 μm.

The polyester chip is polyethylene terephthalate, and the viscosity of the mixed polyester melt and polyamide melt is 0.65 dL/g.

The chemical fiber oil used for oiling is shown in table 1.

The monofilament fiber of the superfine denier porous polyester yarn obtained by the production is 0.83 dtex.

Examples 7 to 11, a difference between the super fine denier porous polyester yarn and example 1 is that different nano metal oxides are selected, and the specific details are shown in table 3.

Table 3, selection of 7-11 nano metal oxides

Example 7	Nano alumina
		Example 8	Nano zinc oxide
Example 9	Nano iron oxide
		Example 10	Nano titanium oxide
Example 11	Nano chromium oxide

Example 12, an ultra fine denier porous polyester yarn, different from example 1, was obtained in that the viscosity of the mixed polyester melt and nylon melt was 0.67dL/g, which was obtained by blending polyester melt and nylon melt having different weight average molecular weights.

Example 13, a superfine denier porous polyester yarn, based on example 12, obtained by increasing the average molecular weight of polyester and nylon of polyester chip and nylon chip, finally measured the viscosity of the polyester melt and nylon melt is 0.70 dL/g.

Example 14, a super fine denier porous polyester yarn, differs from example 1 in that other additives in the total mass of the polyester melt and the nylon melt are further added as shown in table 4.

Table 4, in examples 14 to 22, the ratio (%) of the mass of the other additives to the mass of the polyester melt and the polyamide melt

Numbering	Low density polyethylene	Nonionic surfactant	Crown ethers
				Example 14	1.5	0	0
Example 15	2.0	0	0
				Example 16	3.0	0	0
Example 17	1.5	1.0	0.2
				Example 18	1.5	1.2	0.3
Example 19	1.5	1.2	0.6
				Example 20	1.5	1.2	0
Example 21	1.5	0	0.3
				Example 22	1.5	4.0	0.3

In examples 14 to 22, the low density polyethylene was first subjected to crystallization and drying treatment in a crystallization bed at a temperature range of 120 to 123 ℃ when being added to a mixed system of a polyester melt and a nylon melt.

The nonionic surfactant is Tween-20, and the crown ether is 18 crown-6.

Example 23, a super fine denier porous polyester yarn, which is different from example 17 in that a cationic surfactant with the same mass is used instead of a nonionic surfactant, and the cationic surfactant is octadecyl dimethyl hydroxyethyl quaternary ammonium salt, and the counter ion is nitrate.

Example 24, a superfine denier porous polyester yarn, which is different from example 17 in that an anionic surfactant with equal mass is used to replace a nonionic surfactant, and the anionic surfactant is sodium dodecyl benzene sulfonate.

In examples 14 to 24, other additives were added in amounts after mixing the polyester melt and the nylon melt in step S2.

Example 25, a micro-denier porous polyester yarn, different from example 17, is prepared by adjusting the production steps, wherein the step S2 is specifically as follows:

s2, melting the polyester chips and the nylon chips to obtain a polyester melt and a nylon melt, mixing the polyester melt and the nylon melt, adding the nano metal oxide, the polyhydroxybutyrate and the oxidized polyethylene wax, fully stirring and uniformly mixing, filtering by a 15-micrometer filter screen, adding into a single-screw extruder, and extruding into filaments, wherein the single-screw extruder is divided into three sections, from a feeding end to a discharging end, the single-screw extruder is sequentially divided into a first section, a second section and a third section, the temperature of the first section is 261 ℃, the temperature of the second section is 275 ℃, and the temperature of the third section is 263 ℃. The length ratio of the first section, the second section and the third section is 1: 1.3: 1, and the screw rotation speed is 40 rpm. The temperature of the extrusion head is controlled at 230 ℃, hot air with the pressure of 0.12mPa is drafted at the extrusion head, and the temperature of the hot air is 203 +/-1 ℃.

Step S3 is specifically as follows:

s3, cooling the extruded silk yarn by two sections of circular blowing, controlling the wind pressure of the two sections of circular blowing to be 20Pa, wherein the temperature of the first section of circular blowing is 65 +/-2 ℃, the temperature of the second section of circular blowing is 18 +/-2 ℃, the silk yarn is blown circularly from top to bottom through the two sections of circular blowing, the time of the first section of circular blowing is 0.6S, the time of the second section of circular blowing is 3S, and after cooling by the two sections of circular blowing, oiling, networking and winding are carried out to obtain the superfine denier porous polyester yarn.

Example 26, an ultra fine denier porous polyester yarn, differs from example 25 in that the temperature of the first stage is 257 c and the remaining parameters are maintained constant at step S2.

Example 27, a micro denier porous polyester yarn, different from example 25, in step S2, the temperature of the second stage is 280 ℃.

Example 28, an ultra fine denier porous polyester yarn, differs from example 25 in that the temperature of the hot air stream is 170 ± 2 ℃ in step S2.

Example 29, a micro denier porous polyester yarn, different from example 25, wherein the temperature of the first stage circular blow and the second stage circular blow are both 18 ± 2 ℃ in step S3.

For the above examples, comparative examples were set as follows.

Comparative examples 1 to 4, a super fine denier porous polyester yarn, which is different from example 2 in that the raw material components thereof are shown in table 5 in terms of specific gravity.

Table 5, comparative examples 1 to 4 Material weight fractions (%)

The above examples and comparative examples were measured as follows.

Experiment 1, a single yarn strength tester (purchased from a medium fiber instrument) was used,

experiment 2, a yarn break experiment, with the formulation in the above partial example, on a single set of equipment, a 24h continuous run was performed, recording the number of yarn breaks during the operation of the equipment.

The experimental results of examples 1 to 6 and comparative examples 1 to 4 in experiment 1 and experiment 2 are shown in table 6.

Table 6, examples 1 to 6 and comparative examples 1 to 4

According to the experimental data, the scheme as in the embodiments 1 to 6 is adopted, the polyester melt and the polyamide melt are used as the base materials, and the nano metal oxide, the oxidized polyethylene wax and the polyhydroxybutyrate are added, so that the overall strength can be effectively improved, and the filament breakage rate is reduced. The applicant believes that the principles therein may be as follows:

during the production of the yarn, there are two main causes of breakage, one is wear and the other is uneven texture of the yarn. The metal oxide has good wear resistance, so that the wear resistance of the silk thread can be improved in the production process of the silk thread, and the breakage of the silk thread caused by wear is reduced. Meanwhile, as polyhydroxybutyrate is added into the system, polyhydroxybutyrate has good compatibility with metal oxides on the whole, so that the whole system is uniform and effective. Meanwhile, compared with a pure terylene system, the system has lower integral treatment temperature, so that the generated silk threads are not easy to soften and break due to overhigh temperature, and the probability of silk thread breakage is further reduced.

In fact, in the present application, in experiment 2, the winding rate of the silk thread is 2565m/min, and if the winding rate is slowed down, the broken rate of the silk thread can be further reduced.

Further, examples 7 to 13 were subjected to experiment 1 and experiment 2, and the experimental results are shown in table 7.

Table 7 and Experimental results of examples 7 to 11

In the above technical solution, different nano metal oxides all have a certain improvement on strength, wherein the improvement on strength by zirconia and chromia is the largest, which may be related to the hardness of the nano metal oxide. However, since chromium is a heavy metal, zirconium oxide is selected for subsequent experiments.

In examples 12 to 13, by adjusting the mixing viscosity of the polyester melt and the nylon melt, when the viscosity of the elastomer is too high, the processing temperature itself is low in the present application, so that the yarns are easily adhered to the spinneret holes, and the breakage rate is increased.

Further, examples 15 to 24 were subjected to experiments 1 and 2, and the results are shown in Table 8.

Table 8 and Experimental results of examples 15 to 24

According to the experimental data, the low-density polyethylene is added into the system, so that the effects of improving the strength of the silk threads and reducing the broken rate of the silk threads are achieved. The low-density polyethylene can reduce the melting point, so that the overall processing temperature is lower, and the low-density polyethylene is easy to form, and the low-density polyethylene has flexible molecular chains, so that the nano metal oxide and other components in the low-density polyethylene can be coated after forming, thereby being beneficial to further improving the overall dispersion uniformity, enabling the stress of each part of the silk thread to be more uniform during extrusion, and further reducing the silk breakage rate.

The experimental data of examples 17-24 show that the addition of a nonionic surfactant and a crown ether contributes to further improvement of the strength of the yarn. The nonionic surfactant can further coat the nano metal oxide to reduce the agglomeration of the nano metal oxide, and the crown ether has certain coordination capacity and can further cooperate with the nonionic surfactant to realize the dispersion effect. While the simple crown ether has a poor dispersing effect, but has a bad influence on the properties of the silk threads. In addition, the cationic surfactant and the anionic surfactant do not exert similar effects at this point, probably because the charged surfactant cannot be ionized in the above system, the emulsifying effect thereof is poor, and self-dispersion is not uniform enough.

Further, experiments 1 and 2 were performed on examples 25 to 29, and the results are shown in table 9.

Table 9 and Experimental results of examples 25 to 29

Numbering	Breaking strength (cN/dtex)	Number of filament breakage
			Example 25	4.5	0
Example 26	4.3	4
			Example 27	4.3	6
Example 28	4.0	5
			Example 29	4.2	4

In the above technical solutions, the processing parameters are further adjusted, wherein the temperature of each section in the screw is adjusted in examples 26 and 27, the technical solutions in the present application can be performed at a lower temperature, but when the temperature is too low, the fluidity of the molten system in the extruder is poor, and when the temperature is too high, the overall adhesion performance is reduced, and the filament breakage rate of the filament is increased.

In example 29, the cooling was not performed by two-stage circular blowing, which resulted in uneven cooling of the yarn and also caused yarn breakage.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.