基于应变硬化模量的聚乙烯耐慢速裂纹增长性能与热分级表征关系探讨OA
Relationship Between Slow Crack Growth Resistance Performance and Thermal Fractionation Characterization of Polyethylene Based on Strain Hardening Modulus
通过应变硬化模量、连续自成核退火热分级(SSA)和升温淋洗分级(TREF)表征了 4种聚乙烯管材专用料的耐慢速裂纹增长性能,探讨应变硬化模量与热分级的相关性.结果表明,聚乙烯应变硬化模量可以有效地反映原料的耐慢速裂纹增长性能,PE100-RC级的应变硬化模量最高,PE80级的应变硬化模量最低;SSA和TREF结果呈现了一致性,连续自成核退火热分级在135 ℃、升温淋洗分级在90~105 ℃区间内,级分含量与聚乙烯管材专用料应变硬化模量呈正相关性;通过2个方法的高温结晶区级分含量均可以定性判断出聚乙烯管材专用料的耐慢速裂纹增长性能;SSA方法在设备、4 h实验周期、样品用量以及环保方面均更具有优势.
The slow crack growth resistance of four polyethylene pipe materials was characterized by strain hardening modulus,successive self-nucleation and annealing fractionation(SSA),and temperature rising elution fractionation(TREF).The correlation between strain hardening modulus and thermal fractionation was investigated.The strain hardening modulus of polyethylene can effectively reflect the performance of the raw material in resisting slow crack growth.The strain hardening modulus of PE100-RC grade is the highest,while that of PE80 grade is the lowest.The results of SSA and TREF show consistency.SSA is within 135℃,and TREF is within the range of 90~105℃,the grade content is positively correlated with the strain hardening modulus of the polyethylene pipe material special grade.The slow crack growth resistance of the polyethylene pipe materials can be qualitatively assessed by the content of high-temperature crystalline fractions obtained from both methods.The SSA method offers advantages in terms of equipment,test cycle of 4 hours,sample consumption,and environmental friendliness.
李玉娥;徐渝;郭若海;张伟
中石化(北京)化工研究院有限公司标准研究所,北京 100013中石化(北京)化工研究院有限公司标准研究所,北京 100013中石化(北京)化工研究院有限公司标准研究所,北京 100013中石化(北京)化工研究院有限公司标准研究所,北京 100013
化学化工
聚乙烯管材专用料耐慢速裂纹扩展应变硬化模量热分级
PolyethyleneResin material for pipeSlow crack growth resistanceStrain hardening modulusThermal fractionation
《应用化学》 2026 (4)
614-616,中插11-中插14,7
中国石化项目(No.722014)资助 Supported by China Petroleum & Chemical Corporation Project(No.722014)
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