Sage Journals: Discover world-class research

Abstract

Excessive thrust force in micro drilling of difficult to cut materials like Monel alloys poses challenges such as tool breakage, burr formation, and poor hole quality. So optimizing the thrust force is crucial for reducing the tool wear and improving the dimensional accuracy. This work uniquely combines finite element (FE) simulation with experimental validation to evaluate and optimize the effects of spindle speed and feed rate on thrust force, circularity error, and burr formation in micro drilling of Monel 400 alloy. Nine experimental trials and FE simulations with different spindle speeds and feed rates were conducted to evaluate the drilling performance. In addition, three drilling tests were carried out at higher feed rates for assessing its influence on thrust force and drilling quality. Comparison of experimental and simulated thrust forces across varying feed rates and spindle speeds showed strong agreement, with deviations ranging from 1.2% to 5.3%. The influence of cutting parameters on the circularity of holes, burr width, and length at both the entry and exit edges was systematically evaluated. The results demonstrate that higher spindle speeds combined with lower feed rates lead to the lower thrust force (1.703 N), improved hole circularity (entry: 0.6272 mm, exit: 0.6216 mm), and reduced burr formation (entry: 0.27 $μ m$ , exit: 0.16 $μ m$ ). The findings highlight the optimal spindle speed and feed rate to minimize burr and enhance hole quality in micro drilling of Monel 400 alloy.

Keywords

Micro drilling Monel 400 thrust force circularity burr

Get full access to this article

View all access options for this article.

References

Demirbaş

Köklü

Morkavuk

, et al. Machining-Induced damage and corrosion behavior of MONEL-400 alloy under cryogenic cooling conditions: a sustainable initiative. Int J Precision Eng Manuf-Green Technol 2024; 12: 493–508.

Tariq

Shoukat

Hassan

, et al. Thermal management of microelectronic devices using micro-hole cellular structure and nanofluids. J Therm Anal Calorim 2018; 136: 2171–2182.

Abdo

BMA

Almuzaiqer

Noman

, et al. Investigation of heat annealing and parametric optimization for drilling of MONEL-400 alloy. J Manuf Mater Processing 2023; 7: 170.

Romoli

Rashed

CAA

Fiaschi

. Experimental characterization of the inner surface in micro-drilling of spray holes: a comparison between ultrashort pulsed laser and EDM. Opt Laser Technol 2013; 56: 35–42.

Torres-Salcedo

Luis-Pérez

Puertas-Arbizu

, et al. A study on the EDM drilling of reaction-bonded silicon carbide using different electrode materials. Int J Adv Manuf Technol 2023; 126: 5139–5162.

Orbanic

Junkar

. An experimental study of drilling small and deep blind holes with an abrasive water jet. Proc Institut Mech Eng Part B: J Eng Manuf 2004; 218: 503–508.

Mittal

Sehgal

Kumar

. Design and manufacturing of abrasive jet machine for drilling operation. MATEC Web Conf 2016; 57: 03004.

Howitt

Chen

Gierhart

, et al. The electron beam hole drilling of silicon nitride thin films. J Appl Phys 2008; 103: 024101.

Chandar

Nagarajan

Kumar

. Recent research progress in deep hole drilling process: a review. Surf Rev Lett 2021; 28: 2130003.

10.

Attanasio

Ceretti

Outeiro

, et al. Numerical simulation of tool wear in drilling Inconel 718 under flood and cryogenic cooling conditions. Wear 2020; 458–459: 203403.

11.

David

Clara

. Analysis of tool geometry and hole quality effects on drilling carbon-fibre reinforced polymer composites using ANSYS. Ayden J Eng Appl Sci 2024; 12: 1–14.

12.

Di Han

. Finite element simulation of drilling based on third wave systems AdvantEdge. Key Eng Mater 2010; 431–432: 229–232.

13.

Sikulskyi

Maiorova

Garin

, et al. Modeling hole edge and burr formation during drilling using LS-DYNA. In: Lecture notes in networks and systems. Cham: Springer Nature Switzerland, 2023, pp. 123-136.

14.

Geetha

Prasannavenkadesan

Selvaraj

, et al. Analysis of thrust force in micro drilling on Nimonic C-263 alloy using finite element simulation and validated with experiments. J Brazilian Soc Mech Sci Eng 2025; 47: 298.

15.

Jayakumar

Koundinya

Jayakumar

, et al. Experimental studies on the effect of drilling parameters on monel alloy. Mater Sci Forum 2020; 979: 137–141.

16.

Sanjay

Alsamhan

Abidi

. Multi response optimization of machining parameters for an annealed Monel K 500 alloy in drilling using machine learning techniques and ANN. J Intell Fuzzy Syst 2021; 42: 5605–5625.

17.

Panigrahi

Bartarya

Chetan

. Drilling performance of nickel-based Hastelloy C276 under mono and hybrid nanofluids environments. J Manuf Process 2024; 120: 1213–1230.

18.

Stalin

Khan

Jappes

JTW

. Studies on machining performance and surface quality of nickel based super alloy using micro drilling process. Conf Proc 2024; 245. DOI: https://doi.org/10.1007/s10751-024-01945-7

19.

Kothapalli

Meena

Raju

CRB

. Investigating micro drilling with electrical discharge machining on nickel-based superalloy: effects of electrode material and diameter. Cogent Eng 2024; 11: 2383971.

20.

Guan

Deng

, et al. An analytical and numerical modeling method for predicting drilling force and hole expansion of a BTA drill processing Inconel 625 and FeCr alloy laminated materials. J Manuf Process 2023; 108: 653–670.

21.

Prasannavenkadesan

Pandithevan

. Bone drilling simulation using Johnson-Cook model combined with Cowper-Symonds model validated with in-vitro experiments. Mech Adv Mater Struct 2022; 29: 4546–4556.

22.

Prasannavenkadesan

Pandithevan

. Johnson–Cook model combined with Cowper–Symonds model for bone cutting simulation with experimental validation. J Mech Med Biol 2021; 21: 2150010.

23.

Prasannavenkadesan

Pandithevan

. An in-silico bone drilling protocol to control thrust forces using finite element analysis coupled with the constitutive models. Proc Instit Mech Engineers, Part C: J Mech Eng Sci 2022; 236: 8201–8210.

24.

Aydin

. Investigation of optimal machining Monel 400 superalloy considering carbon emissions using FEM, regression and ANN methods. J Cleaner Prod 2024; 447: 141616.

25.

Sun

Geng

Guo

, et al. Introducing transversal vibration in twist drilling: material removal mechanisms and surface integrity. J Mater Process Technol 2024; 325: 118296.

26.

Özbek

Saruhan

. The effect of vibration and cutting zone temperature on surface roughness and tool wear in eco-friendly MQL turning of AISI D2. J Mater Res Technol 2020; 9: 2762–2772.

27.

Chen

Shi

Zhu

, et al. Chip removal mechanism and hole plugging in back-drilling of high-speed printed circuit board. Int J Adv Manuf Technol 2025; 137: 2919–2934.

28.

Bahçe

Özdemir

. Determination of tool deflection in drilling by image processing. IET Image Proc 2019; 13: 2487–2494.

29.

Aamir

Giasin

Tolouei-Rad

, et al. Effect of cutting parameters and tool geometry on the performance analysis of one-shot drilling process of AA2024-T3. Metals 2021; 11: 854.

30.

Venkateshwarlu

Singaravel

Shekar

, et al. Analysis and optimization of circularity error in drilling process using statistical technique. IOP Conf Ser Mater Sci Eng 2021; 1057: 012063.

31.

Ahmad

Ibrahim

Zainoridin

, et al. An analysis of chip formation and hole circularity in drilling applications: an aircraft components perspective. J Adv Res Appl Mech 2024; 118: 28–39.

32.

Zhou

, et al. Study on cutting force and surface quality in drilling 2.5D-Cf/SiC composites. Diamond Relat Mater 2025; 157: 112573.

33.

Morkavuk

. Improving machinability of Ni-based Monel 400 superalloy: a novel thermal-assisted drilling method based induction heating. Int J Adv Manuf Technol 2025. DOI: https://doi.org/10.1007/s00170-025-15783-6.

34.

Yazman

Köklü

Urtekin

, et al. Experimental study on the effects of cold chamber die casting parameters on high-speed drilling machinability of casted AZ91 alloy. J Manuf Process 2020; 57: 136–152.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

2.56 MB

Experimental investigation and finite element analysis of the effects of spindle speed and feed rate on hole quality in micro drilling of Monel 400 alloy

Abstract

Keywords

Get full access to this article

References

Supplementary Material