Review on Surface Form Accuracy Evaluation Technologies of Honeycomb Core Components

doi:10.3901/JME.2024.14.001

Abstract

Abstract: Honeycomb sandwich structure is made of honeycomb core with specific geometry bonded to upper and lower skin. The accuracy of honeycomb core surface form also determines the strength and performance of the whole sandwich structure. The measurement and evaluation of the surface form accuracy of the machined honeycomb core is the important foundation to ensure the machining accuracy, but there is still short of ideal measurement and evaluation method. Honeycomb core is a kind of discontinuous and thin-walled structure, and it is difficult to locate on the thin walls when measuring the surface form accuracy by contact method. In non-contact measurement, the scale of wall thickness makes it difficult for conventional measurement methods to meet the accuracy requirements. In view of the research needs of honeycomb core surface form accuracy evaluation technologies, the current research statuses of contact and non-contact surface form measurement technologies of honeycomb core are reviewed. The measurement principle, key technologies and current progress of each method are introduced in detail. The development trend of surface form measurement technologies of honeycomb core in the future is forecasted.

Key words: honeycomb materials, measurement of honeycombs, machining accuracy evaluation, honeycomb surface form accuracy, measurement of discontinuous surface form

CLC Number:

TH161

QIN Yan, KANG Renke, WANG Yidan, SUN Jiansong, DONG Zhigang. Review on Surface Form Accuracy Evaluation Technologies of Honeycomb Core Components[J]. Journal of Mechanical Engineering, 2024, 60(14): 1-10.

References

[1] BITZER T. Honeycomb technology:Materials，design，manufacturing，applications and testing[M]. Heidelberg： Springer-Science+Business Media，B.V.，1997.
[2] 张建明，党晓娟. 芳纶纸蜂窝芯材的制备技术及其应用研究进展[J]. 新材料产业，2019(12)：52-56. ZHANG Jianming，DANG Xiaojuan. Research progress on preparation technology and application of aramid paper honeycomb core materials[J]. Advanced Materials Industry，2019(12)：52-56.
[3] AHMAD S，ZHANG J，FENG P，et al. Experimental study on rotary ultrasonic machining (RUM) characteristics of Nomex honeycomb composites (NHCs) by circular knife cutting tools[J]. Journal of Manufacturing Processes. 2020，58：524-535.
[4] 程文礼，袁超，邱启艳，等. 航空用蜂窝夹层结构及制造工艺[J]. 航空制造技术，2015(7)：94-98. CHENG Wenli，YUAN Chao，QIU Qiyan，et al. Honeycomb sandwich structure and manufacturing process in aviation industry[J]. Aeronautical Manufacturing Technology，2015(7)：94-98.
[5] 徐龙，梅颖，刘元，等. NOMEX薄壁蜂窝芯型面加工技术[J]. 工具技术，2018，52(12)：116-119. XU Long， MEI Ying， LIU Yuan，et al. Processing technology for shaped profile of Nomex thin-walled honeycomb core[J]. Tool Engineering，2018，52(12)：116-119.
[6] 马义新. 高密度芳纶纸蜂窝磨削加工试验研究[D]. 大连：大连理工大学，2019. MA Yixin. Experimental study on grinding performance of high-density Nomex honeycomb[D]. Dalian：Dalian University of Technology，2019.
[7] 王毅丹，康仁科，白杜娟，等. 高密度芳纶纸蜂窝的磨削试验[J]. 金刚石与磨料磨具工程，2018，38(6)：48-53. WANG Yidan， KANG Renke，BAI Dujuan，et al. Experiment on grinding performance of high-density aramid honeycombs[J]. Diamond & Abrasive Engineering，2018，38(6)：48-53.
[8] QIU K，MING W，SHEN L，et al. Study on the cutting force in machining of aluminum honeycomb core material[J]. Composite Structures，2017，164：58-67.
[9] VAKILINEJAD M，OLABI A，GIBARU O，et al. Geometrical error improvement of Aramid honeycomb workpieces in robot-based triangular knife ultrasonic cutting process[J]. The International Journal of Advanced Manufacturing Technology，2020，110(1-2)：523-541.
[10] XIANG D，WU B，YAO Y，et al. Ultrasonic longitudinal-torsional vibration-assisted cutting of Nomex® honeycomb-core composites[J]. The International Journal of Advanced Manufacturing Technology，2019，100(5)：1521-1530.
[11] 牛景露. 芳纶蜂窝芯的超声切削系统开发及其切削性能研究[D]. 大连：大连理工大学，2017. NIU Jinglu. Study on design and cutting performance of ultrasonic cutting system for cutting Nomex honeycomb core[D]. Dalian：Dalian University of Technology，2017.
[12] 朱文秀. Nomex蜂窝材料直刃尖刀超声切割切削力分析[D]. 大连：大连理工大学，2016. ZHU Wenxiu. Study on cutting force in Nomex honeycomb composites’ ultrasonic cutting by straight blade knife[D]. Dalian：Dalian University of Technology,2016.
[13] 李秀渊. 芳纶蜂窝材料超声切削过程仿真和实验研究[D]. 杭州：杭州电子科技大学，2019. LI Xiuyuan. Research on ultrasonic cutting process simulation and experiment for aramid honeycomb material[D]. Hangzhou：Hangzhou Dianzi University，2019.
[14] 马成，刘方军. 蜂窝材料加工工艺研究进展[J]. 航空制造技术，2016(3)：48-54. MA Cheng，LIU Fangjun. Research progress in processing technology of honeycomb materials[J]. Aeronautical Manufacturing Technology，2016(3)：48-54.
[15] 张生芳，王际帆，马付建，等. 刀具参数对超声切削蜂窝芯切削力及温度影响仿真分析[J]. 大连交通大学学报，2017，38(1)：57-61. ZHANG Shengfang，WANG Jifan，MA Fujian，et al. Simulation analysis of tool parameters influence on feeding force and cutting temperature of ultrasonic cutting for honeycomb[J]. Journal of Dalian Jiaotong University，2017，38(1)：57-61.
[16] 孙健淞，董志刚，王毅丹，等. 超声切割铝蜂窝试验研究[J]. 机械工程学报，2017，53(19)：128-135. SUN Jiansong，DONG Zhigang，WANG Yidan，et al. Experimental study on ultrasonic cutting of aluminum honeycombs[J]. Journal of Mechanical Engineering，2017，53(19)：128-135.
[17] WANG Y，KANG R，DONG Z，et al. A Novel method of blade-inclined ultrasonic cutting Nomex honeycomb core with straight blade[J]. Journal of Manufacturing Science and Engineering，2021，143(4)：1-34.
[18] 王毅丹，王宣平，康仁科，等. 直刃尖刀超声辅助切割Nomex蜂窝芯切削力分析[J]. 机械工程学报，2017，53(19)：73-82. WANG Yidan，WANG Xuanping，KANG Renke，et al. Analysis of influence on ultrasonic-assisted cutting force of Nomex honeycomb core material with straight knife[J]. Journal of Mechanical Engineering，2017，53(19)：73-82.
[19] HU X，YU B，LI X，et al. Research on cutting force model of triangular blade for ultrasonic assisted cutting honeycomb composites[J]. Procedia CIRP，2017，66：159-163.
[20] 黄秀秀，胡小平，于保华. 蜂窝复合材料超声切割力建模及工艺参数选择研究[J]. 机电工程，2015，32(1)：32-36. HUANG Xiuxiu，HU Xiaoping，YU Baohua. Ultrasonic cutting force model of honeycomb composites and selection of the processing parameters[J]. Journal of Mechanical & Electrical Engineering，2015，32(1)：32-36.
[21] CAO W，ZHA J，CHEN Y. Cutting force prediction and experiment verification of paper honeycomb materials by ultrasonic vibration-assisted machining[J]. Applied Sciences，2020，10(13)：4676.
[22] 袁信满，郑华林，忻龙飞，等. 基于响应曲面法的NOMEX蜂窝芯超声复合铣削力预测模型构建[J]. 制造技术与机床，2017(1)：103-108. YUAN Xinman，ZHENG Hualin，XIN Longfei，et al. Prediction model of Nomex honeycomb composite material force by response surface methodology[J]. Manufacturing Technology & Machine Tool，2017(1)：103-108.
[23] 张迅，董志刚，王毅丹，等. Nomex蜂窝芯直刃尖刀超声切割表面微观形貌特征[J]. 机械工程学报，2017，53(19)：90-99. ZHANG Xun，DONG Zhigang，WANG Yidan，et al. Characterization of surface microscopic of Nomex honeycomb after ultrasonic assisted cutting[J]. Journal of Mechanical Engineering，2017，53(19)：90-99.
[24] AN Q，DANG J，MING W，et al. Experimental and numerical studies on defect characteristics during milling of aluminum honeycomb core[J]. Journal of Manufacturing Science and Engineering，2019，141(3)：31006.
[25] JIANG J，LIU Z. Formation mechanism of tearing defects in machining Nomex honeycomb core[J]. The International Journal of Advanced Manufacturing Technology，2021，112(11-12)：3167-3176.
[26] JAAFAR M，MAKICH H，NOUARI M. A new criterion to evaluate the machined surface quality of the Nomex® honeycomb materials[J]. Journal of Manufacturing Processes，2021，69：567-582.
[27] SEEMANN R，KRAUSE D. Numerical modelling of Nomex honeycomb sandwich cores at meso-scale level[J]. Composite Structures，2017，159：702-718.
[28] XU Q，BAO Y，WANG Y，et al. Investigation on damage reduction method by varying cutting angles in the cutting process of rectangular Nomex honeycomb core[J]. Journal of Manufacturing Processes，2021，68：1803-1813.
[29] 刘望子，管海新，惠稳棉，等. 复合材料双曲面NOMEX蜂窝加工技术研究及应用[J]. 航空制造技术，2019，62(10)：88-92. LIU Wangzi，GUAN Haixin，HUI Wenmian，et al. Research progress and application of hyperboloid Nomex honeycomb of composite materials[J]. Aeronautical Manufacturing Technology，2019，62(10)：88-92.
[30] 杨波，郭守玉，李洪哲，等. 双曲率U型蜂窝夹芯金属胶接件校验膜制造和胶接工艺研究[J]. 科技创新与应用，2017(12)：49-50. YANG Bo，GUO Shouyu，LI Hongzhe，et al. Manufacturing and bonding technology of verification film of double curvature U-shaped honeycomb sandwich metal bonding part[J]. Technology Innovation and Application，2017(12)：49-50.
[31] 张嘉礼，李特，谭朝元，等. 面向蜂窝结构件的机器人视觉定位方法[J]. 航天制造技术，2019(2)：13-18. ZHANG Jiali，LI Te，TAN Chaoyuan，et al. Robot vision location method for honeycomb structures[J]. Aerospace Manufacturing Technology，2019(2)：13-18.
[32] JIANG H，ZHAO H，LI X，et al. Hyper thin 3D edge measurement of honeycomb core structures based on the triangular camera-projector layout & phase-based stereo matching[J]. Optics Express，2016，24(5)：5502.
[33] Twin Coast Metrology. Honeycomb composite core measurement [EB/OL].(2020-03-01)[2022-03-02]. https://twincoastmetrology.com/products/metrology/honeycomb-core-measurement-cellgage/
[34] 聂天智. 基于摄影测量的大型空间结构参数辨识与实验[D]. 大连：大连理工大学，2019. NIE Tianzhi. Parameter identification and experimental of large space structure based on photogrammetry[D]. Dalian：Dalian University of Technology，2019.
[35] 刘蕾，陈雪梅，易元，等. 一种针对蜂窝芯外形曲面特征的测量方法[J]. 中国测试，2019，45(7)：56-60. LIU Lei，CHEN Xuemei，YI Yuan，et al. A method for measuring the shape and surface characteristics of honeycomb core[J]. China Measurement & Testing Technology，2019，45(7)：56-60.
[36] 董志刚，康仁科，朱祥龙，等. 一种蜂窝芯面形的测量方法[P]. 中国，201610585321.1，2016-10-12. DONG Zhigang，KANG Renke，ZHU Xianglong，et al. A method for measuring the surface shape of a honeycomb core[P]. China，201610585321.1，2016-10-12.
[37] DONG Z，QIN Y，KANG R，et al. Robust cell wall recognition of laser measured honeycomb cores based on corner type identification[J]. Optics and Lasers in Engineering，2021，136：106321.
[38] QIN Y，KANG R，DONG Z，et al. Burr removal from measurement data of honeycomb core surface based on dimensionality reduction and regression analysis[J]. Measurement Science and Technology，2018，29(11)：115010.
[39] QIN Y，KANG R，WANG Y，et al. A form error evaluation method of honeycomb core surface[J]. Measurement，2022，201：111667.