Mughal Khurram Hameed, Qureshi Muhammad Asif Mahmood, Jamil Muhammad Fawad, Ahmad Shehzad, Ahmad Khalid Fazal, Qaiser Asif Ali, Maqbool Adnan, Raza Syed Farhan, Zhang Jianfu
Mechanical Engineering Department, University of Engineering and Technology, Lahore 54890, Pakistan; Mechanical Engineering Department, The University of Lahore, Lahore 54000, Pakistan.
Mechanical Engineering Department, University of Engineering and Technology, Lahore 54890, Pakistan.
Ultrasonics. 2024 Jul;141:107343. doi: 10.1016/j.ultras.2024.107343. Epub 2024 May 11.
Nomex honeycomb composite (NHC) has been increasingly used in the automotive, aerospace and defence applications due to its excellent thermal and mechanical properties. Its complex cellular hexagonal thin-walled configuration along with heterogeneous, soft and brittle nature pose substantial processing defects such as burr formation, tearing of walls, surface roughness, dimensional inaccuracy and low machining quality during conventional machining (CM). These surface defects have a substantial influence on the operating life and functional performance of its sandwiched structural members. Hybrid ultrasonic vibration assisted machining (HUSVAM) technology has been introduced to overcome such limitations. For an in depth research on HUSVAM of NHC using ultrasonic toothed disc cutter (UTDC), three dimensional finite element model was developed and experimental validation was carried out. The numerical simulation and experimental results were found to be in good agreement with one another. The influence of various machining parameters including the ultrasonic tool vibration amplitude (UTVA), feed rate (FR), depth of cut (DoC) and spindle angular speed (SAS) on NHC cutting forces, chip formation and surface quality was investigated using both HUSVAM and CM techniques. Furthermore, stresses, deformation and forces near tool-workpiece interaction along with the surface topography and morphologies were also analysed and compared for various operating conditions. A reduction in the cutting forces was found with the increase of SAS and UTVA (up to 65.47 % and 65.74 %, respectively). Although, the cutting forces were observed to increase by increasing the DoC and FR (up to 159.45 % and 126.33 %, respectively). DoC has a greater impact on the cutting forces among all machining parameters according to 4 levels, 4 factors (L) orthogonal experiments based on Taguchi method. The results show that the chip formation and machining quality of NHC core can be improved with HUSVAM technique using UTDC. HUSVAM also reduced the cutting forces (up to 73 %) compared to CM. The ultrasonic toothed disc cutter generated large number of burr with very short length, no tearing defects and no uncut fibers as observed from scanning electron microscopy of NHC hexagonal cell structure, walls and triple points. A burr formation of less than 10 % was realized during HUSVAM of NHC cores for F≤3N, while it was found up to 20 % if F>3N, compared to at least 40 % during CM. The finite element model developed can be used to investigate the influence of HUSVAM on modern difficult to machine materials for enhanced surface quality.
诺梅克斯蜂窝复合材料(NHC)因其优异的热性能和机械性能,在汽车、航空航天和国防应用中得到了越来越广泛的应用。其复杂的蜂窝状六边形薄壁结构,以及材料的不均匀、柔软和脆性特性,在传统加工(CM)过程中会产生大量加工缺陷,如毛刺形成、壁面撕裂、表面粗糙度、尺寸不准确和加工质量低等问题。这些表面缺陷对其夹层结构部件的使用寿命和功能性能有重大影响。为了克服这些限制,引入了混合超声振动辅助加工(HUSVAM)技术。为了深入研究使用超声齿盘铣刀(UTDC)对NHC进行HUSVAM加工,建立了三维有限元模型并进行了实验验证。数值模拟和实验结果相互吻合良好。使用HUSVAM和CM技术研究了各种加工参数,包括超声刀具振动幅度(UTVA)、进给速度(FR)、切削深度(DoC)和主轴角速度(SAS)对NHC切削力、切屑形成和表面质量 的影响。此外,还分析和比较了不同工况下刀具与工件相互作用附近的应力、变形和力,以及表面形貌和形态。发现随着SAS和UTVA 的增加,切削力会降低(分别高达65.47%和65.74%)。然而,切削力会随着DoC和FR的增加而增加(分别高达159.45%和126.33%)。根据基于田口方法的4水平、4因素(L)正交试验,DoC在所有加工参数中对切削力的影响更大。结果表明,使用UTDC的HUSVAM技术可以提高NHC芯材的切屑形成和加工质量。与CM相比,HUSVAM还降低了切削力(高达73%)。从NHC六边形孔结构、壁面和三相点的扫描电子显微镜观察到,超声齿盘铣刀产生的毛刺数量多但长度很短,没有撕裂缺陷,也没有未切割的纤维。在F≤3N时,NHC芯材的HUSVAM加工过程中毛刺形成率低于10%,而当F>3N时,毛刺形成率高达20%,相比之下,CM过程中的毛刺形成率至少为40%。所建立的有限元模型可用于研究HUSVAM对现代难加工材料的影响,以提高表面质量。
