Fabrication of isotactic polypropylene casting film and its structural evolution during stretching

doi:10.11949/0438-1157.20230971

Abstract

Abstract:

Polymer films often experience complex temperature fields and tensile fields during processing. Stretching affects the aggregated structure by inducing molecular chain orientation, thereby affecting various properties of the film. Compared to other crystal modifications, βcrystal isotactic polypropylene (iPP) has much better mechanical properties. In this work, we used WBG to improve the βcrystal content of iPP and investigated its structural evolution during casting and post-stretching. With the increase of draw ratio and the decrease of temperature, the crystallinity and tensile strength of iPP casting film increase, however, the βcrystal content decreases. During the post stretching process, increasing the stretch temperature and strain accelerates the transition of iPP from βcrystal to αcrystal. Meanwhile, cavitation occurs at the late stage of post-stretching, which provides the foundation of iPP microporous membrane preparation.

Key words: isotactic polypropylene, βnucleating agent, film, polymer processing, crystallization

摘要：

高分子薄膜在加工过程中往往经历复杂的温度场以及拉伸场，拉伸通过诱导分子链取向而影响聚集态结构，进而影响薄膜各项性能。由于β晶聚丙烯（iPP）具有更好的力学性能，通过加入稀土类β成核剂（WBG）提高了iPP中β晶含量，并且利用流延的方法制备了iPP流延膜，研究了流延以及后拉伸条件对iPP结晶结构的影响。研究结果发现，随着牵伸比的增加以及流延温度的降低，iPP的结晶度增大，β晶含量减少，同时流延膜具有更高的拉伸强度。在后拉伸过程中，增加拉伸温度和应变能够促进β晶向α晶的转变，并且流延膜在拉伸后期出现空洞结构，基于此制备了iPP微孔膜。

关键词: 聚丙烯, β成核剂, 膜, 高分子加工, 结晶

CLC Number:

TQ 325.1

Bo ZHANG, Zhuangzhuang LI, Dan ZHAO, Cuizhu QIAN, Bao WANG, Pengju PAN. Fabrication of isotactic polypropylene casting film and its structural evolution during stretching[J]. CIESC Journal, 2023, 74(12): 4997-5005.

张博, 李壮壮, 赵丹, 钱翠珠, 王宝, 潘鹏举. 聚丙烯流延膜的制备与拉伸过程中的结构演变[J]. 化工学报, 2023, 74(12): 4997-5005.

Figures/Tables 8

Fig.1 Procedure of the preparation of casting film

Fig.2 Properties of iPP/WBG with different stretch ratios [the temperature of casting roller in (a) is 25℃, the stretch direction is indicated as the red arrow]

Fig.3 SAXS patterns (a), SAXS curves (b) and long periods (c) of iPP/WBG casting films with different stretch ratios[the temperature of casting roller in (a) is 25℃, the stretch direction is indicated as the red arrow]

Fig.4 Strain-stress curves of iPP/WBG casting films at 35℃

Fig.5 WAXS patterns and WAXS curves of iPP/WBG-DR20 during post-stretching (the stretch direction is indicated as the red arrow)

Fig.6 β crystal content and orientation of (300) crystal plane of iPP/WBG casting films during post-stretching

Fig.7 SAXS patterns of iPP/WBG-DR20 during post-stretching at 75℃ (the stretch direction is indicated as the red arrow)

Fig.8 SEM images of iPP/WBG-DR120 films (the stretching direction is horizontal)

References 34

1	Demeuse M T. Biaxial Stretching of Film: Principles and Applications[M]. Oxford: Woodhead Publishing Ltd., 2011.
2	Deimede V, Elmasides C. Separators for lithium-ion batteries: a review on the production processes and recent developments[J]. Energy Technology, 2015, 3(5): 453-468.
3	Tan D, Zhang L L, Chen Q, et al. High-temperature capacitor polymer films[J]. Journal of Electronic Materials, 2014, 43(12): 4569-4575.
4	Tabatabaei S H, Carreau P J, Ajji A. Structure and properties of MDO stretched polypropylene[J]. Polymer, 2009, 50(16): 3981-3989.
5	Tabatabaei S H, Carreau P J, Ajji A. Effect of processing on the crystalline orientation, morphology, and mechanical properties of polypropylene cast films and microporous membrane formation[J]. Polymer, 2009, 50(17): 4228-4240.
6	Arora P, Zhang Z J. Battery separators[J]. Chemical Reviews, 2004, 104(10): 4419-4462.
7	Brückner S, Meille S V, Petraccone V, et al. Polymorphism in isotactic polypropylene[J]. Progress in Polymer Science, 1991, 16(2/3): 361-404.
8	Luo F, Geng C Z, Wang K, et al. New understanding in tuning toughness of β-polypropylene: the role of β-nucleated crystalline morphology[J]. Macromolecules, 2009, 42(23): 9325-9331.
9	Wang B, Cavallo D, Zhang X L, et al. Evolution of chain entanglements under large amplitude oscillatory shear flow and its effect on crystallization of isotactic polypropylene[J]. Polymer, 2020, 186: 121899.
10	Wu T, Xiang M, Cao Y, et al. Influence of lamellar structure on the stress-strain behavior of β nucleated polypropylene under tensile loading at elevated temperatures[J]. RSC Advances, 2015, 5(54): 43496-43507.
11	Zhang D X, Ding L, Yang F, et al. Effect of annealing on the microvoid formation and evolution during biaxial stretching of β nucleated isotactic polypropylene[J]. Polymer-Plastics Technology and Materials, 2020, 59(14): 1595-1607.
12	Tordjeman P, Robert C, Marin G, et al. The effect of α, β crystalline structure on the mechanical properties of polypropylene[J]. The European Physical Journal E, 2001, 4(4): 459-465.
13	Pukánszky B, Mudra I, Staniek P. Relation of crystalline structure and mechanical properties of nucleated polypropylene[J]. Journal of Vinyl and Additive Technology, 1997, 3(1): 53-57.
14	Bai H W, Deng H A, Zhang Q, et al. Effect of annealing on the microstructure and mechanical properties of polypropylene with oriented Shish-Kebab structure[J]. Polymer International, 2012, 61(2): 252-258.
15	Wang B, Cavallo D, Chen J B. Delay of re-entanglement kinetics by shear-induced nucleation precursors in isotactic polypropylene melt[J]. Polymer, 2020, 210: 123000.
16	Mi D S, Xia C, Jin M, et al. Quantification of the effect of shish-kebab structure on the mechanical properties of polypropylene samples by controlling shear layer thickness[J]. Macromolecules, 2016, 49(12): 4571-4578.
17	Balzano L, Ma Z, Cavallo D, et al. Molecular aspects of the formation of Shish-Kebab in isotactic polypropylene[J]. Macromolecules, 2016, 49(10): 3799-3809.
18	Qin Y J, Xu Y H, Zhang L Y, et al. Interfacial interaction enhancement by shear-induced β-cylindrite in isotactic polypropylene/glass fiber composites[J]. Polymer, 2016, 100: 111-118.
19	Li Z M, Yang W, Li L B, et al. Morphology and nonisothermal crystallization of in situ microfibrillar poly(ethylene terephthalate)/polypropylene blend fabricated through slit-extrusion, hot-stretch quenching[J]. Journal of Polymer Science Part B: Polymer Physics, 2004, 42(3): 374-385.
20	Varga J. β-modification of polypropylene and its two-component systems[J]. Journal of Thermal Analysis, 1989, 35(6): 1891-1912.
21	Cowking A, Rider J G. On molecular and textural reorientations in polyethylene caused by applied stress[J]. Journal of Materials Science, 1969, 4(12): 1051-1058.
22	Young R J, Bowden P B, Ritchie J M, et al. Deformation mechanisms in oriented high-density polyethylene[J]. Journal of Materials Science, 1973, 8(1): 23-36.
23	Peterlin A. Drawing and extrusion of semi-crystalline polymers[J]. Colloid and Polymer Science, 1987, 265(5): 357-382.
24	Lu Y, Chen R, Zhao J Y, et al. Stretching temperature dependency of fibrillation process in isotactic polypropylene[J]. The Journal of Physical Chemistry B, 2017, 121(28): 6969-6978.
25	Luo F, Wang K, Ning N Y, et al. Dependence of mechanical properties on β-form content and crystalline morphology for β-nucleated isotactic polypropylene[J]. Polymers for Advanced Technologies, 2011, 22(12): 2044-2054.
26	Pi L, Nie M, Wang Q. Crystalline composition and morphology in isotactic polypropylene pipe under combining effects of rotation extrusion and fibril β-nucleating agent[J]. Journal of Vinyl and Additive Technology, 2019, 25(S1): E195-E202.
27	Wen X, Li Y, Nie M, et al. Formation mechanism of hybrid shish kebab and its reinforcing effects on polypropylene[J]. Polymer-Plastics Technology and Engineering, 2016, 55(8): 775-783.
28	Wang Z F, Yang W H, Liu G M, et al. Probing into the epitaxial crystallization of β form isotactic polypropylene: from experimental observations to molecular mechanics computation[J]. Journal of Polymer Science Part B: Polymer Physics, 2017, 55(5): 418-424.
29	Wang B, Utzeri R, Castellano M, et al. Heterogeneous nucleation and self-nucleation of isotactic polypropylene microdroplets in immiscible blends: from nucleation to growth-dominated crystallization[J]. Macromolecules, 2020, 53(14): 5980-5991.
30	Li S W, Zheng G Q, Jia Z H, et al. Effect of stretching on β-phase content of isotactic polypropylene melt containing β-nucleating agent[J]. Journal of Macromolecular Science, Part B, 2012, 51(5): 828-838.
31	Flory P J. Thermodynamics of crystallization in high polymers(Ⅰ): Crystallization induced by stretching[J]. Journal of Chemical Physics, 1947, 15(6): 397-408.
32	Ji H J, Zhou X L, Chen X, et al. Deformation-induced crystallization behavior of isotactic polypropylene sheets containing a β-nucleating agent under solid-state stretching[J]. Polymers, 2020, 12(6): 1258.
33	Mollova A, Androsch R, Mileva D, et al. Crystallization of isotactic polypropylene containing beta-phase nucleating agent at rapid cooling[J]. European Polymer Journal, 2013, 49(5): 1057-1065.
34	Rhoades A M, Wonderling N, Gohn A, et al. Effect of cooling rate on crystal polymorphism in beta-nucleated isotactic polypropylene as revealed by a combined WAXS/FSC analysis[J]. Polymer, 2016, 90: 67-75.

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