Optimizing drilling parameters for unidirectional glass fiber/nanoclay-epoxy matrix composites using gray relational analysis and response surface methodology

IF 2.4 3区 化学 Q3 POLYMER SCIENCE
Sakine Kiratli, Hüseyin Gökçe
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Abstract

In this innovative study, the drilling performances of laminated composites containing different ratios (0, 1, 3, and 5 wt% ) of nanoclay were examined and optimized using the Multi-Criteria Decision-Making method. Control factors included material (NC), feed rate (f), cutting speed (Vc), drill bit (D), were considered and an appropriate experimental design was made. Thrust force (Fc), cutting tool temperature (T), and delamination factor (Df) were determined as quality characteristics. Delamination in the holes was measured using imaging analysis, and a two-dimensional (2D) delamination factor based on the nominal diameter was calculated. As the nanoclay ratio increased, the Fc increased by over 50% due to the increase in friction and material strength. Conversely, as the drill tip angle decreased, a relative decrease was observed in the Fc and T values. According to the quality characteristics, NC was found to be the most effective control factor, with 65.53% and 70.74% for Fz and T, respectively, while D was found to be the most effective control factor with 41.23% for Df. Using Gray Relational Analysis, the optimum drilling parameters were found to be a pure composite material, a drill bit with a 90° tip angle, 140 m/min cutting speed, and a 0.04 mm/rev feed rate. The results calculated with the mathematical models obtained using the Response Surface Method were tested with a series of verification experiments. The relative error values of the results obtained from these experiments and the results measured from the models were calculated as approximately 1% for Fz, nearly 0.54% for T, and almost 1.48% for Df. The results calculated with the mathematical models obtained using the Response Surface Method were tested with a series of verification experiments. The relative error values of the results obtained from these experiments and the results calculated from the models were calculated as approximately 1% for Fz, approximately 0.54% for T, and approximately 1.48% for Df.

Graphical abstract

Abstract Image

利用灰色关系分析和响应面方法优化单向玻璃纤维/纳米粘土-环氧基复合材料的钻孔参数
在这项创新性研究中,采用多标准决策法对含有不同比例(0、1、3 和 5 wt%)纳米土的层状复合材料的钻孔性能进行了检验和优化。考虑的控制因素包括材料(NC)、进给量(f)、切削速度(Vc)和钻头(D),并进行了适当的实验设计。推力 (Fc)、切削刀具温度 (T) 和分层系数 (Df) 被确定为质量特性。通过成像分析测量了孔中的分层情况,并计算出了基于公称直径的二维(2D)分层系数。随着纳米粘土比率的增加,由于摩擦力和材料强度的增加,Fc 增加了 50%以上。相反,随着钻尖角度的减小,Fc 和 T 值也相对减小。根据质量特性,NC 是最有效的控制因素,其 Fz 和 T 值分别为 65.53% 和 70.74%,而 D 是最有效的控制因素,其 Df 值为 41.23%。通过灰色关系分析,发现最佳钻孔参数为:纯复合材料、90° 尖端角的钻头、140 米/分钟的切削速度和 0.04 毫米/转的进给速度。利用响应面法获得的数学模型计算出的结果经过了一系列验证实验的检验。根据计算,这些实验得出的结果与模型测得的结果之间的相对误差值分别为:Fz 约为 1%,T 接近 0.54%,Df 接近 1.48%。利用响应面法获得的数学模型计算出的结果通过一系列验证实验进行了检验。实验结果与模型计算结果的相对误差值分别为:Fz 约为 1%,T 约为 0.54%,Df 约为 1.48%。
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来源期刊
Iranian Polymer Journal
Iranian Polymer Journal 化学-高分子科学
CiteScore
4.90
自引率
9.70%
发文量
107
审稿时长
2.8 months
期刊介绍: Iranian Polymer Journal, a monthly peer-reviewed international journal, provides a continuous forum for the dissemination of the original research and latest advances made in science and technology of polymers, covering diverse areas of polymer synthesis, characterization, polymer physics, rubber, plastics and composites, processing and engineering, biopolymers, drug delivery systems and natural polymers to meet specific applications. Also contributions from nano-related fields are regarded especially important for its versatility in modern scientific development.
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