Performance evaluation of micro/nano-silica filled silicone rubbers aged under multiple environmental stresses and bipolar DC voltage

IF 1.2 4区化学 Q4 POLYMER SCIENCE

Journal of Rubber Research Pub Date : 2023-02-25 DOI:10.1007/s42464-023-00192-9

Atif Mahmood, Shahid Alam

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Abstract

For the outdoor insulation of high voltage transmission lines, insulating materials made of high-temperature vulcanized silicone rubber (HTV-SiR) are used all over the world. To enhance the performance of these base polymers, fillers of various sizes, concentrations and dimensions are added. In this study, four different types of HTV-SiR materials, one unfilled and three reinforced with silica of micro/nano size were used. Followed by preparation of the samples, aging was performed by placing them in a specially designed weathering chamber with various stresses and bipolar DC voltage for 5000 h. To diagnose integrity of the aged materials, different types of measurements based on hydrophobicity classification, leakage current, mechanical analysis, thermal tests, Fourier transform infrared (FTIR) spectroscopy and scanning electron microscopy (SEM) were conducted. Results of the hydrophobicity classification revealed S₃ to be most hydrophobic having HC2 class under the influence of bipolar DC voltage, whereas, sample S₁ was the most hydrophilic resulting in HC4 and HC5 under negative and positive DC voltages, respectively. Similarly, the lowest leakage currents of 5.56 μA and 5.81 μA were recorded for sample S₃ after being aged under negative DC and positive DC voltages, respectively. The %age decrease in tensile strength recorded for samples S₁, S₂, S₃ and S₄ was 32.3, 25.32, 23.56 and 27.12, respectively, under the positive DC voltage. Thermogravimetric analysis exhibited the least decrease of %yield from 49.3% to 48.9% and 48.4% for sample S₃ under negative and positive DC voltages, respectively. Additionally, according to FTIR spectroscopic investigation, hybrid composite S₃ kept the highest intactness in siloxane backbone (Si–O–Si) linkages, with a drop in its peak of 37% for positive DC and 11.2% for negative DC. In contrast to the co-filled composites S₂ and S₃ with improved surface morphology, samples S₁ and S₄ indicated voids, cracks, increased roughness and structural damages.

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微/纳米二氧化硅填充硅橡胶在多重环境应力和双极直流电压老化下的性能评价

在高压输电线路的室外绝缘中，高温硫化硅橡胶(hhtv - sir)制成的绝缘材料在世界范围内得到广泛应用。为了提高这些基础聚合物的性能，添加了各种尺寸、浓度和尺寸的填料。在这项研究中，使用了四种不同类型的HTV-SiR材料，一种是未填充的，三种是微纳米尺寸的二氧化硅增强的。然后对样品进行制备，将其放置在专门设计的具有不同应力和双极直流电压的老化室中进行5000 h的老化。为了诊断老化材料的完整性，进行了基于疏水性分类、泄漏电流、力学分析、热测试、傅里叶变换红外(FTIR)光谱和扫描电子显微镜(SEM)的不同类型的测量。疏水分类结果显示，在双极直流电压影响下，S3最疏水，为HC2类，而S1最亲水，在直流负电压和正电压影响下，分别为HC4和HC5。同样，S3样品在直流负电压和直流正电压老化后，漏电流最低，分别为5.56 μA和5.81 μA。在直流正电压下，试样S1、S2、S3和S4的抗拉强度随时间的下降百分比分别为32.3、25.32、23.56和27.12。热重分析表明，样品S3在直流负电压和正电压下的产率分别从49.3%下降到48.9%和48.4%，降幅最小。此外，根据FTIR光谱调查，杂化复合材料S3在硅氧烷主链(Si-O-Si)键上保持了最高的完整性，其正直流电峰值下降了37%，负直流电峰值下降了11.2%。与表面形貌改善的共填充复合材料S2和S3相比，样品S1和S4存在空洞、裂纹、粗糙度增加和结构损伤。

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来源期刊

Journal of Rubber Research 化学-高分子科学

自引率

15.40%

发文量

审稿时长

3 months

期刊介绍： The Journal of Rubber Research is devoted to both natural and synthetic rubbers, as well as to related disciplines. The scope of the journal encompasses all aspects of rubber from the core disciplines of biology, physics and chemistry, as well as economics. As a specialised field, rubber science includes within its niche a vast potential of innovative and value-added research areas yet to be explored. This peer reviewed publication focuses on the results of active experimental research and authoritative reviews on all aspects of rubber science. The Journal of Rubber Research welcomes research on: the upstream, including crop management, crop improvement and protection, and biotechnology; the midstream, including processing and effluent management; the downstream, including rubber engineering and product design, advanced rubber technology, latex science and technology, and chemistry and materials exploratory; economics, including the economics of rubber production, consumption, and market analysis. The Journal of Rubber Research serves to build a collective knowledge base while communicating information and validating the quality of research within the discipline, and bringing together work from experts in rubber science and related disciplines. Scientists in both academia and industry involved in researching and working with all aspects of rubber will find this journal to be both source of information and a gateway for their own publications.