Melt spinning of polyvinyl chloride (PVC) fibers and their structure and properties

Abstract

Abstract: Polyvinyl chloride is a non-toxic, odorless, and widely used thermoplastic material. It has advantages such as good flame retardancy, acid and alkali resistance, low price, good physical properties, and electrical insulation. It is currently one of the most widely used plastics. However, due to its poor stability to light and heat, it can decompose and produce hydrogen chloride when exposed to sunlight above 100 ℃ or for a long time, causing discoloration and rapid decline in physical and mechanical properties. When applying, it is necessary to add plasticizers, heat stabilizers, and other additives to improve the stability of PVC materials to light and heat. The traditional methods for PVC spinning and forming are wet spinning and dry spinning, but both methods require PVC resin to swell in acetone. However, acetone itself is toxic, and solvent recovery is harmful to the environment. The melt spinning method lags behind other technologies due to the poor heat resistance of PVC and its thermal decomposition and carbonization at high temperatures.
This article used heat stabilizers and plasticizers to modify PVC resin to make it resistant to high temperatures and enable smooth melt spinning. The melt spinning process of PVC fibers was studied. The melt flow index instrument was used to test the melting temperature of PVC granules to preliminarily determine the optimal spinning temperature. The effects of different spinning temperatures and drafting ratios on the structure and properties of PVC fibers were studied. And research on the breaking strength, elongation at break, crystallinity, surface and cross-sectional morphology, as well as acid and alkali corrosion resistance and flame retardancy of the fibers were conducted. Through comparative experiments, it is found that the optimal comprehensive mechanical properties of PVC fibers are obtained when the screw temperature is 160 ℃ and the spinneret temperature is 190 ℃. When the drawing ratio is 4, the breaking strength and orientation of PVC fibers are the highest. The best spinning parameters obtained from the experiment are as follows: the spinneret is 1 cm away from the water bath, the screw temperature is 160 ℃, the spinneret temperature is 190 ℃, the hot water bath temperature is 60 ℃, the metering pump pressure is 2 MPa, and the drafting ratio is 4. Under such conditions, the PVC fibers prepared have the best performance, and their breaking strength, breaking elongation, and Linear density are 1.16 cN/dtex, 32.1%, and 12 tex, respectively; PVC fibers have excellent mechanical properties, good flame retardancy, and excellent resistance to acid and alkali corrosion. They have minimal loss of quality and strength in acid and alkali solutions, especially in acidic solutions.
The use of melt spinning technology to prepare PVC fibers has the advantages of simple process and low price. And the PVC fibers obtained through melt spinning have excellent properties and can be used to prepare corrosion-resistant and flame-retardant fabrics.

Key words: PVC fiber, melt spinning, mechanical properties, corrosion resistance, drafting process

摘要： 为了通过熔融纺丝方法制备出性能优良的聚氯乙烯（PVC）纤维，在将聚氯乙烯粉体共混改性造粒的基础上，调整熔融纺丝的工艺参数，研究纺丝温度和牵伸倍数等工艺条件对纤维结构与性能的影响，并对纤维的断裂强度、断裂伸长率、取向度、表面形貌、截面形貌以及耐酸、碱腐蚀性能、阻燃性能进行测试分析。结果表明：当喷丝板距离水浴1 cm距离、螺杆温度为160 ℃、喷丝板温度为190 ℃、热水浴温度为60 ℃、计量泵压力为2 MPa、牵伸倍数为4倍时，制得的PVC纤维性能较好，其断裂强度、断裂伸长率、线密度分别为1.16 cN/dtex、32.1%、12 tex，并且具有优异的耐酸、碱腐蚀性能和阻燃性能。研究结果为制备高性能的PVC纤维提供了一种新的方法。

关键词: 聚氯乙烯纤维, 熔融纺丝, 力学性能, 耐腐蚀性能, 牵伸工艺

CLC Number:

Q342+.51

FAN Yangrui, QIAN Jianhua, YU Deyou, GUO Yuhai, DAI Hongxiang, LI Chengcai. Melt spinning of polyvinyl chloride (PVC) fibers and their structure and properties[J]. Advanced Textile Technology, 2024, 32(7): 42-47.

范洋瑞, 钱建华, 余德游, 郭玉海, 戴宏翔, 李成才. 聚氯乙烯纤维熔融纺丝及其结构与性能[J]. 现代纺织技术, 2024, 32(7): 42-47.

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