多重熔融法制备超高分子量聚乙烯带

IF 0.3 4区工程技术 Q4 MATERIALS SCIENCE, TEXTILES

Journal of Fiber Science and Technology Pub Date : 2021-01-15 DOI:10.2115/FIBERST.2021-0001

Masaki Kakiage, K. Komatsu

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引用次数: 0

摘要

：超高分子量聚乙烯（UHMW-PE）带是通过刮除UHMW-PE粉末的压实块而在商业上制备的。然而，刮膜的机械性能较差，并且薄膜的生产是困难的。在本研究中，我们成功地以UHMW-PE反应器粉末为原料，通过熔体挤出、熔体轧制和熔体拉伸等多种熔体工艺制备了UHMW-PE胶带。将UHMW-PE反应器粉末连续熔融挤出成没有熔融断裂的股线。将获得的熔融挤出的股线在155和150˚C下依次重复熔融轧制，并逐步减小辊之间的间隙以形成带。将获得的胶带（作为轧制胶带）在155˚C下进行熔融拉伸，以实现高拉伸强度和薄厚度。最大拉伸比（DR）在5/min的应变速率下最高。通过宽角度X射线衍射测量和差示扫描量热法测量，研究了熔体拉伸带材晶体结构的发展。延伸链晶体（ECCs）是通过轧制带的熔融拉伸形成的，并随着DR的增加而发展，从而获得高拉伸强度。在5分钟的应变速率下，通过DR为15的熔体拉伸制备的熔体拉伸带表现出最大程度的ECC形成和最高程度的结晶取向，导致0.56GPa的拉伸强度和70µm的厚度。因此，由UHMW-PE反应器粉末通过多次熔体处理制备了具有优异拉伸强度的薄UHMW-PE带。

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Preparation of Ultrahigh-Molecular-Weight Polyethylene Tapes by Multiple Melt Processing

: Ultrahigh-molecular-weight polyethylene (UHMW-PE) tapes are commercially prepared by skiving a compacted block of UHMW-PE powder. However, the mechanical properties of a skived film are poor, and the production of a thin film is difficult. In this study, we succeeded in preparing UHMW-PE tapes from UHMW-PE reactor powder by multiple melt processing, i.e., melt-extrusion, melt-rolling, and melt-drawing. UHMW-PE reactor powder was continuously melt-extruded into a strand without melt fracture. The obtained melt-extruded strand was repeatedly melt-rolled at 155 and 150 ˚C in order and with stepwise reduction of the gap between the rolls to form a tape. The obtained tape (as-rolled tape) was melt-drawn at 155 ˚C to achieve high tensile strength and thin thickness. The maximum draw ratio ( DR ) was the highest under a strain rate of 5/min. The development of the crystalline structure of the melt-drawn tapes was investigated by wide-angle X -ray diffraction measurements and differential scanning calorimetry measurements. Extended-chain crystals (ECCs) were formed by melt-drawing of the as-rolled tape and developed with increasing DR , resulting in high tensile strength. The melt-drawn tape prepared by melt-drawing with DR of 15 under a strain rate of 5/min exhibited the most enhanced ECC formation and the highest degree of crystalline orientation, resulting in a tensile strength of 0.56 GPa and a thickness of 70 µ m. Consequently, a thin UHMW-PE tape with superior tensile strength was prepared from UHMW-PE reactor powder by multiple melt processing.

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来源期刊

Journal of Fiber Science and Technology Materials Science-Materials Science (miscellaneous)

CiteScore

0.50

自引率

0.00%

发文量