论文:2018,Vol:36,Issue(4):693-700
引用本文:
赵盼, 史耀耀, 康超, 俞涛, 邓博, 张宏基, 陈振. 复合材料机器人纤维铺放工艺参数优化[J]. 西北工业大学学报
Zhao Pan, Shi Yaoyao, Kang Chao, Yu Tao, Deng Bo, Zhang Hongji, Chen Zhen. Optimization of Process Parameters for Robotic Fibre Placement[J]. Northwestern polytechnical university

复合材料机器人纤维铺放工艺参数优化
赵盼, 史耀耀, 康超, 俞涛, 邓博, 张宏基, 陈振
西北工业大学 机电学院, 陕西 西安 710072
摘要:
相较于复合材料结构件传统加工方法的劳动密集型和耗时性,机器人纤维铺放技术大大的提高了复合材料成型过程的灵活性,允许制造更为复杂的结构。基于热塑性复合材料机器人纤维铺放成型工艺过程研究,分别对成型过程中紧密接触过程与融合过程进行理论分析,提出影响铺放制品质量的关键工艺参数:热气炬温度、铺放压力和铺放速度;针对圆柱形零件轴向0°铺放成型过程,以层间粘结强度为优化目标,根据响应面法设计实验,建立工艺参数耦合对层间粘结强度影响模型,通过方差分析验证了模型可靠性及有效性,进而获得纤维铺放成型最优工艺参数;实验研究表明,在最优工艺参数作用下,层间剥离力最高为24.1 N,铺放制品粘结强度最高。
关键词:    预浸丝束    纤维铺放    工艺参数优化    响应面法    层间粘结强度    方差分析    实验设计   
Optimization of Process Parameters for Robotic Fibre Placement
Zhao Pan, Shi Yaoyao, Kang Chao, Yu Tao, Deng Bo, Zhang Hongji, Chen Zhen
School of Mechanical Engineering, Northwestern Polytechnical University, Xi'an 710072, China
Abstract:
Compared with labour-intensive and time-consuming processing of conventional fabrication methods, the robotic fiber placement process greatly improves the flexibility of the fiber placement process and allows for the construction of more complex structures. Based on the study of the placement process, the intimate contact process and healing process were analysed theoretically. The key process parameters for affecting the quality of the composite component were put forward:hot gas torch temperature, compaction force and laying velocity. In order to analyse the fabrication process for laying the cylindrical parts with 0-degree tow direction, the model of the process parameters coupling affected the interlaminar bond strength was established, according to the design of the response surface method. The reliability and validity of the model were verified by the analysis of variance. The optimal process parameters of fiber placement were obtained. The results show that the model is effective and the optimum peeling force of the laying products is 24.1 N under the optimum process parameters.
Key words:    prepreg tow    fibre placement    parameter optimization    response surface methodology    interlaminar bonding strength    analysis of variance(ANOVA)    design of experiments   
收稿日期: 2017-05-20     修回日期:
DOI:
基金项目: 国家自然科学基金(51375394)资助
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作者简介: 赵盼(1986-),西北工业大学博士研究生,主要从事智能制造装备与机器人纤维铺放技术研究。
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参考文献:
[1] 李斌太, 邢丽英, 包建文, 等. 先进复合材料国防科技重点实验室的航空树脂基复合材料研发进展[J]. 航空材料学报, 2016, 36(3):92-100 Li Bintai, Xing Liying, Bao Jianwen, et al. Research and Development Progress of National Key Laboratory of Advanced Composites on Advanced Aeronautical Resin Matrix Composites[J]. Journal of Aeronautical Materials, 2016, 36(3):92-100(in Chinese)
[2] 张鹏, 孙容磊, 连海涛,等. 自动铺带铺层贴合形成机制[J]. 复合材料学报, 2014, 31(1):40-48 Zhang Peng, Sun Ronglei, Lian Haitao, et al. Bonding Mechanism of Ply During Automated Tape Laying Process[J]. Acta Materiae Compositae Sinica, 2014, 31(1):40-48(in Chinese)
[3] He X, Shi Y, Kang C, et al. Analysis and Control of the Compaction Force in the Composite Prepreg Tape Winding Process for Rocket Motor Nozzles[J]. Chinese Journal of Aeronautics, 2016, 36(2):836-845
[4] Zhao P, Shirinzadeh B, Shi Y, et al. Improved Uniform Degree of Multi-layer Interlaminar Bonding Strength for Composite Laminate[J]. Journal of Reinforced Plastics & Composites, 2017, 36(17):1211-1224
[5] 韩振宇, 李玥华, 富宏亚,等. 热塑性复合材料纤维铺放工艺的研究进展[J]. 材料工程, 2012(2):91-96 Han Zhenyu, Li Yuehua, Fu Hongya, et al. Thermoplastic Composites Fiber Placement Process Research[J]. Journal of Materials Engineering, 2012(2):91-96(in Chinese)
[6] Shirinzadeh B, Cassidy G, Oetomo D, et al. Trajectory Generation for Open-Contoured Structures in Robotic Fiber Placement[J]. Robotics and Computer-Integrated Manufacturing, 2007, 23(4):380-394
[7] Ma Xuqiang, Gu Yizhuo, Li Yanxia, et al. Interlaminar Properties of Carbon Fiber Composite Laminates with Resin Transfer Molding/Prepreg Co-Curing Process[J]. Journal of Reinforced Plastics and Composites, 2014, 33(24):2228-2241
[8] Khan M A, Mitschang P, Schledjewski R. Identification of Some Optimal Parameters to Achieve Higher Laminate Quality through Tape Placement Process[J]. Advances in Polymer Technology, 2010. 29(2):98-111
[9] Bendemra H, Vincent M J, Compston P. Optimisation of Compaction Force for Automated Fibre Placement[C]//Australasian Congress on Applied Mechanics, 2014:957-965
[10] Grouve W J B, Warnet L L, Rietman B, et al. Optimization of the Tape Placement Parameters for Carbon-PPS Composites[J]. Composites Part A:Applied Science and Manufacturing, 2013, 50:44-53
[11] 文琼华, 王显峰, 何思敏, 等. 温度对预浸料铺放效果的影响[J]. 航空学报, 2011, 32(9):1740-1745 Wen Qionghua, Wang Xianfeng, He Simin, et al. Influence of Temperature on Placement Effect of Prepreg[J]. Acta Aeronautica et Astronautica Sinica, 2011, 32(9):1740-1745(in Chinese)
[12] 段玉岗, 刘芬芬, 陈耀, 等. 纤维铺放压紧力及预浸带加热温度对复合材料力学性能的影响[J]. 复合材料学报, 2012(4):148-156 Duan Yugang, Liu Fenfen, Chen Yao, et al. Effects of Compaction Force and Heating Temperature of Prepreg on Composite Mechanical Properties during Fiber Placement Process[J]. Acta Materiae Compositae Sinica, 2012(4):148-156(in Chinese)
[13] Zhao P, Shirinzadeh B, Shi Y, et al. Multi-Pass Layup Process for Thermoplastic Composites Using Robotic Fiber Placement[J]. Robotics and Computer-Integrated Manufacturing, 2018, 49:277-284
[14] Tierney J, Gillespie J. W. Modeling of Insitu Strength Development for the Thermoplastic Composite Tow Placement Process[J]. Journal of Composite Materials, 2006, 40(16):1487-1506
[15] Schell J S U, Guilleminot J, Binetruy C, et al. Computational and Experimental Analysis of Fusion Bonding in Thermoplastic Composites:Influence of Process Parameters[J]. Journal of Materials Processing Technology, 2009, 209(11):5211-5219