전자선 조사 폴리프로필렌과 블랜드의 결정화 거동은 고분자 가공시 중요한 변수중 하나이다. 저밀도폴리에틸렌(linear low density polyethylene, LDPE) 함량에 따라 폴리프로필렌(polypropylene, PP)/LDPE 블렌드를 이축압출기를 이용하여 제조하였다. 조사에 의한 가교반응을 용이하게 하기위해 가교조제로 trimethylolpropane-trimetacrylate (TMPTMA)를 PP/LDPE 블렌드 제조시 첨가하였다. PP/LDPE 블랜드의 조사가교 효율에 대한 LDPE 함량의 영향을 평가하였다. 조사시료의 비등온 결정화과정과 결정구조를 DSC, X-선회절분석(X-ray diffraction, XRD), 그리고 편광현미경(polarized optical microscope, POM)을 이용하여 분석하였다. 조사 후 시료의 용융온도가 감소하는 것은 조사에 의한 PP 사슬의 절단에 의한 것으로 판단된다. Ozawa 지수, n이 4일 때 구형, 3일 때 디스크형, 2일 때 로드형의 결정구조를 나타낸다. Ozawa 분석 결과, 순수 PP의 n 값은 3.8, 30 wt%의 LDPE를 포함하는 시료의 n은 2.3을 나타내었다. LDPE 첨가와 조사에 의해 PP의 결정구조가 구형에서 disk나 rod형으로 변화하는 것을 Ozawa 분석과 POM을 통해 확인하였다. XRD 스펙트럼의 $16.1^{\circ}$에서 나타나는 ${\beta}$ 형 결정구조가 조사 후 시편에서 사라지는데, 이는 가교결합에 의한 것으로 해석할 수 있다.
전자선 조사 폴리프로필렌과 블랜드의 결정화 거동은 고분자 가공시 중요한 변수중 하나이다. 저밀도폴리에틸렌(linear low density polyethylene, LDPE) 함량에 따라 폴리프로필렌(polypropylene, PP)/LDPE 블렌드를 이축압출기를 이용하여 제조하였다. 조사에 의한 가교반응을 용이하게 하기위해 가교조제로 trimethylolpropane-trimetacrylate (TMPTMA)를 PP/LDPE 블렌드 제조시 첨가하였다. PP/LDPE 블랜드의 조사가교 효율에 대한 LDPE 함량의 영향을 평가하였다. 조사시료의 비등온 결정화과정과 결정구조를 DSC, X-선회절분석(X-ray diffraction, XRD), 그리고 편광현미경(polarized optical microscope, POM)을 이용하여 분석하였다. 조사 후 시료의 용융온도가 감소하는 것은 조사에 의한 PP 사슬의 절단에 의한 것으로 판단된다. Ozawa 지수, n이 4일 때 구형, 3일 때 디스크형, 2일 때 로드형의 결정구조를 나타낸다. Ozawa 분석 결과, 순수 PP의 n 값은 3.8, 30 wt%의 LDPE를 포함하는 시료의 n은 2.3을 나타내었다. LDPE 첨가와 조사에 의해 PP의 결정구조가 구형에서 disk나 rod형으로 변화하는 것을 Ozawa 분석과 POM을 통해 확인하였다. XRD 스펙트럼의 $16.1^{\circ}$에서 나타나는 ${\beta}$ 형 결정구조가 조사 후 시편에서 사라지는데, 이는 가교결합에 의한 것으로 해석할 수 있다.
The crystallization behavior of irradiated polypropylene (PP) and the blend is an important parameter for polymer processing. Blends of PP/low density polyethylene (LDPE) with different LDPE contents were prepared by melt mixing in a twin screw extruder. The effect of the LDPE content on the irradia...
The crystallization behavior of irradiated polypropylene (PP) and the blend is an important parameter for polymer processing. Blends of PP/low density polyethylene (LDPE) with different LDPE contents were prepared by melt mixing in a twin screw extruder. The effect of the LDPE content on the irradiation effectiveness of the PP/LDPE blend with trimethylolpropane-trimetacrylate (TMPTMA) as a crosslinking co-agent was investigated in conjunction with the LDPE loading in the blend. The non-isothermal crystallization and crystal structure were measured by DSC, X-ray diffraction (XRD), and polarized optical microscopy (POM). A decrease in the melting temperature of PP was observed due to irradiation, which may be due to the PP chain scissioning effect of irradiation. The Ozawa component n represents a rod shaped, disc shaped and sphere-shaped geometry of the crystal if the value corresponds to 2, 3 and 4, respectively. Based on Ozawa analysis, the values of n were 3.8 and 2.3 for the pure PP and PP blends with 30 wt% LDPE, respectively. The fact that the crystal geometry of PP changed from spherical to disc and rod shaped was confirmed by Ozawa analysis and POM. The ${\beta}$ form XRD peak of the PP/LDPE blend at $16.1^{\circ}$ disappeared after irradiation due to the crosslinking reaction.
The crystallization behavior of irradiated polypropylene (PP) and the blend is an important parameter for polymer processing. Blends of PP/low density polyethylene (LDPE) with different LDPE contents were prepared by melt mixing in a twin screw extruder. The effect of the LDPE content on the irradiation effectiveness of the PP/LDPE blend with trimethylolpropane-trimetacrylate (TMPTMA) as a crosslinking co-agent was investigated in conjunction with the LDPE loading in the blend. The non-isothermal crystallization and crystal structure were measured by DSC, X-ray diffraction (XRD), and polarized optical microscopy (POM). A decrease in the melting temperature of PP was observed due to irradiation, which may be due to the PP chain scissioning effect of irradiation. The Ozawa component n represents a rod shaped, disc shaped and sphere-shaped geometry of the crystal if the value corresponds to 2, 3 and 4, respectively. Based on Ozawa analysis, the values of n were 3.8 and 2.3 for the pure PP and PP blends with 30 wt% LDPE, respectively. The fact that the crystal geometry of PP changed from spherical to disc and rod shaped was confirmed by Ozawa analysis and POM. The ${\beta}$ form XRD peak of the PP/LDPE blend at $16.1^{\circ}$ disappeared after irradiation due to the crosslinking reaction.
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제안 방법
Trimethylolpropane-trimetacrylate (TMPTMA, Sigma Aldrich) was used as a co-agent for crosslinking. The PP/LDPE blend was prepared and tested in order to check the effect of LDPE on the crosslinking and crystallization kinetic of PP by electron beam irradiation. Table 1 summarizes the constituents of the samples.
The goal of this study is to characterize a modified PP/PE blend subjected to an irradiation process, and then analyze the effects LDPE content on the non-isothermal kinetics and crystal structure of modified PP. DSC, XRD, and POM are used for characterization and analysis of the crystallization properties of the PP/LDPE blend.
2. The samples were heated twice to investigate the change in their enthalpy and melting points. Thermal properties of the PP/LDPE blend achieved after both scans are listed in [Table 2].
Irradiated sample left gel after extraction while non-irradiated samples dissolved. These extracted gels were then hot pressed into thin films and FT-IR tests were conducted. The TMPTMA crosslinking reaction was confirmed from the intensity of 1700 cm-1 for the -C=O group in the FT-IR spectrum.
대상 데이터
Polypropylene used in this experiment was Block PP (MI 30), supplied by SK Energy. Polyethylene was supplied by LG Chemicals and the type of polyethylene used was low density polyethylene (LDPE).
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