锻压技术

聚碳酸酯板多点热成形起皱的影响因素

英文标题：Influence factors on wrinkle of polycarbonate sheet in multi-point thermoforming

作者：彭赫力昝林李明哲李中权

分类号：TG320

出版年,卷(期):页码：2017,42(11):79-83

摘要：

为了研究聚碳酸酯（PC）板多点热成形起皱的影响因素，介绍了PC板多点热成形的原理，测试了PC板的玻璃态转变温度，获得了不同温度下PC板的应力松弛曲线，建立了球面件多点热成形有限元模型，并得到了球形面多点热成形起皱的模拟结果。同时，研究了板厚、半径和成形温度对起皱的影响。数值模拟结果表明：板料越厚、半径越大、成形温度越低，均导致球面件起皱越轻微。此外，获得了不同板厚、半径和成形温度条件下PC板的无皱曲成形极限，并开展了PC板多点热成形试验，结果验证了数值模拟的准确性和无皱曲成形极限图的实用性。

In order to investigate the influence factors on wrinkle of polycarbonate (PC) sheet in multi-point thermoforming（MPTF）, the principle of multi-point thermoforming for sheet was introduced, and the glass transition temperature of PC sheet was tested. Then, the stress relaxation curves of PC sheet under different temperatures were obtained, and the finite element model of multi-point thermoforming for spherical part was built. At last, the numerical simulation of wrinkle for spherical part in multi-point thermoforming was got, and the influences of thickness, radius and forming temperature on the wrinkle were researched. The numerical simulation results show that a thicker sheet, or a larger radius, or a lower forming temperature can bring a smaller wrinkles. In addition, the non-wrinkle FLD of PC sheet under different sheet thicknesses, radius and deformation temperatures was obtained respectively, and the experiments of multi-point thermoforming for PC sheet were carried out. Finally, the validity of simulated results and practicability of non-wrinkle forming limited diagram were verified by experimental results.

基金项目：

国家自然科学基金资助项目 (51505278)

作者简介：彭赫力（1986-），男，博士，高级工程师 E-mail：phl12616040811@126.com 通讯作者：李中权（1964-），男，学士，博士生导师 E-mail：lizhongquan401@163.com

参考文献：

[1]Li M Z, Cai Z Y, Sui Z, et al. Multi-point forming technology for sheet metal[J]. Journal of Materials Processing Technology, 2002,129(1-3):333-338.

[2]汪华，周贤宾.飞机蒙皮多点成形用复合柔性垫层的结构参数优化[J].航空学报，2007，28(6)：1482-1486.

Wang H, Zhou X B. Structure parameters optimization on composite flexible pad for aircraft skin stretch forming with reconfigurable tool [J]. Acta Aeronautica ET Astronautica Sinica，2007，28(6)：1482-1486.

[3]Tan F X, Li M Z, Cai Z Y. Research on the process of multi-point forming for the customized titanium alloy cranial prosthesis [J]. Journal of Material Processing Technology, 2007, 187-188 (4):453-457.

[4]韩奇钢，付文智，冯朋晓，等.多点成形技术的研究进展及应用现状[J].航空制造技术，2011, (10):87-89.

Han Q G, Fu W Z, Feng P X, et al. Research development and application of multi-point forming technology [J].Aeronautical Manufacturing Technology, 2011, (10):87-89.

[5]Su S Z, Li M Z, Liu C G, et al. Flexible tooling system using reconfigurable multi-point thermoforming technology for manufacturing freeform panels [J]. Key Engineering Materials, 2012, 504-506: 839-844.

[6]Peng H L, Li M F, Liu C G, et al. Numerical simulation of multi-point forming accuracy for polycarbonate sheet [J]. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 2013, 228(2): 87-96.

[7]Al-Qureshi H A. Analysis of simultaneous sheet metal forming operations using elastomer technique [J]. Journal of Materials Processing Technology, 2002, 125-126 (1) :751-755.

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