Machining characteristics of biodegradable Zn-2Mg-0.1Cu alloy under varying cutting conditions

Abstract

Biodegradable implant materials hold significant potential by degrading within the body after fulfilling their intended function. The advantages of such materials emphasize the need for increased diversity in functional biomaterials and further research in this area. This experimental study aims to develop and investigate Zn-2Mg-0.1Cu alloys and evaluate their machinability. To develop Zn-2Mg-0.1Cu alloys, high-purity elements were melted at 565°C under an argon atmosphere and cast into preheated steel molds. Homogenization at 350°C for 16 hours followed by quenching with iced water was applied to ensure uniform microstructure. The samples were examined using microstructural analysis, and mechanical tests were conducted to assess the effects of Cu addition. In the drilling process, the feed rate was initially kept constant at 200 mm/min, while the spindle speed was varied (2000, 4000, and 6000 rpm) to study the effects of spindle speed on the drilling results. Then, when the spindle speed was fixed at 5000 rpm, the feed rate was adjusted (150, 250, and 350 mm/min) and the effect of feed rate was studied. Drilling characteristics—including thrust force, chip formation, burr formation, surface morphology, and roughness—were analyzed to evaluate machinability. The addition of Cu led to secondary phase formation within the structure, increasing the hardness of the samples. The thrust force decreased by 4.5% at 2000 rpm, 6.3% at 4000 rpm and 1.4% at 6000 rpm in Cu added samples. At lower spindle speeds, the increased hardness from Cu addition resulted in shorter chip lengths. Additionally, Cu addition provided a more consistent and reduced surface roughness along the hole surface. The lowest average surface roughness was 0.446 µm for Zn-2Mg and 0.267 µm for Zn-2Mg-0.1Cu at 200 mm/min feed rate and 6000 rpm spindle speed, 0.385 µm for Zn-2Mg and 0.271 µm for Zn-2Mg-0.1Cu at 5000 rpm spindle speed and 150 mm/min feed rate. In summary, the analysis of these data indicates that Cu addition improved the machinability of the alloy.

Keywords

Cu addition biodegradable Zn-2Mg-0.1Cu drilling

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References

Manne

Thiruvayapati

Bontha

, et al. Surface design of Mg-Zn alloy temporary orthopaedic implants: tailoring wettability and biodegradability using laser surface melting. Surf Coat Technol 2018; 347: 337–349.

Jiao

Liu

, et al. Microstructures, mechanical properties and in vitro corrosion behavior of biodegradable Zn alloys microalloyed with Al, Mn, Cu, Ag and Li elements. J Mater Sci Technol 2022; 103: 244–260.

Yue

Zhang

, et al. Effects of extrusion temperature on microstructure, mechanical properties and in vitro degradation behavior of biodegradable Zn-3Cu-0.5 Fe alloy. Mater Sci Eng C 2019; 105: 110106.

Yang

Jia

, et al. Biodegradable Zn–Cu alloys show antibacterial activity against MRSA bone infection by inhibiting pathogen adhesion and biofilm formation. Acta Biomater 2020; 117: 400–417.

Roche

Koga

Matias

, et al. Degradation of biodegradable implants: the influence of microstructure and composition of Mg-Zn-Ca alloys. J Alloys Compd 2019; 774: 168–181.

Young

Reddy

. Synthesis, mechanical properties, and in vitro corrosion behavior of biodegradable Zn–Li–Cu alloys. J Alloys Compd 2020; 844: 156257.

Cho

Avey

Nam

, et al. In vitro and in vivo assessment of squeeze-cast Mg-Zn-Ca-Mn alloys for biomedical applications. Acta Biomater 2022; 150: 442–455.

Qian

Zhang

, et al. Improved biodegradability of zinc and its alloys by sandblasting treatment. Surf Coat Technol 2021; 405: 126678.

Hagihara

, Shakudo S, Fujii K, et al. Degradation behavior of Ca–Mg–Zn intermetallic compounds for use as biodegradable implant materials. Mater Sci Eng C 2014; 44: 285–292.

10.

Kubásek

Dvorský

Šedý

, et al. The fundamental comparison of Zn–2Mg and Mg–4Y–3RE alloys as a perspective biodegradable materials. Materials (Basel). (2019); 12: 3745.

11.

Wang

Liu

Zhang

, et al. Additively manufactured Zn-2Mg alloy porous scaffolds with customizable biodegradable performance and enhanced osteogenic ability. Adv Sci 2024; 11: 2307329.

12.

Tang

Niu

Huang

, et al. Potential biodegradable Zn-Cu binary alloys developed for cardiovascular implant applications. J Mech Behav Biomed Mater 2017; 72: 182–191.

13.

Niu

Tang

Huang

, et al. Research on a Zn-Cu alloy as a biodegradable material for potential vascular stents application. Mater Sci Eng C 2016; 69: 407–413.

14.

García-Mintegui

,Córdoba LC, Buxadera-Palomero J, et al. Zn-Mg and Zn-Cu alloys for stenting applications: from nanoscale mechanical characterization to in vitro degradation and biocompatibility. Bioactive Mater 2021; 6: 4430–4446.

15.

Liu

Qiu

Wang

, et al. Crystallography of grain refinement in cast zinc–copper alloys. App Crystallogr 2015; 48: 890–900.

16.

Luqman

Ali

Zaghloul

MMY

, et al. Grain refinement mechanism and its effect on mechanical properties and biodegradation behaviors of Zn alloys–A review. J Mater Res Technol 2023; 24: 7338–7365.

17.

Osório

, Brito C, Peixoto LC, et al. Electrochemical behavior of Zn-rich Zn–Cu peritectic alloys affected by macrosegregation and microstructural array. Electrochim Acta 2012; 76: 218–228.

18.

Trumbo

Yates

Schlicker

, et al. Dietary reference intakes. J Am Diet Assoc 2001; 101: 294–294.

19.

Tang

Huang

Niu

, et al. Design and characterizations of novel biodegradable Zn-Cu-Mg alloys for potential biodegradable implants. Mater Des 2017; 117: 84–94.

20.

Tong

Cai

Lin

, et al. Biodegradable Zn− 3Mg− 0.7 Mg2Si composite fabricated by high-pressure solidification for bone implant applications. Acta Biomater 2021; 123: 407–417.

21.

Tong

Zhang

, et al. Microstructure, mechanical properties, biocompatibility, and in vitro corrosion and degradation behavior of a new Zn–5Ge alloy for biodegradable implant materials. Acta Biomater 2018; 82: 197–204.

22.

Yao

, Zhao Y, Han S, et al. Microstructure, mechanical properties, in vitro degradation behavior and in vivo osteogenic activities of Zn-1Mg-β-TCP composites for bone defect repair. Mater Des 2023; 225: 111494.

23.

Deepak

Arunkumar

Ravipati

SVS

, et al. XRD Investigation of biodegradable magnesium rare earth alloy. Mater Today Proc 2021; 47: 4676–4681.

24.

Tong

Wang

Zhu

, et al. A biodegradable in situ Zn–Mg2Ge composite for bone-implant applications. Acta Biomater 2022; 146: 478–494.

25.

Dehghanpour

Emadi

Salimijazi

. Influence of mechanochemically fabricated nano-hardystonite reinforcement in polycaprolactone scaffold for potential use in bone tissue engineering: synthesis and characterization. J Mech Behav Biomed Mater 2023; 146: 106100.

26.

Yue

Niu

, et al. In vitro cytocompatibility, hemocompatibility and antibacterial properties of biodegradable Zn-Cu-Fe alloys for cardiovascular stents applications. Mater Sci Eng C 2020; 113: 111007.

27.

Yang

Zheng

, et al. Design and characterizations of novel biodegradable ternary Zn-based alloys with IIA nutrient alloying elements Mg, Ca and Sr. Mater Des 2015; 83: 95–102.

28.

Hassan

Abdullah

Franz

. Multi-objective optimization in single-shot drilling of CFRP/Al stacks using customized twist drill. Materials (Basel) 2022; 15: 1981.

29.

Zhuo

, Wu Y, Ju J, et al. Recent progress of novel biodegradable zinc alloys: from the perspective of strengthening and toughening. J Mater Res Technol 2022; 17: 244–269.

30.

Liu

. A new approach toward designing and synthesizing the microalloying Zn biodegradable alloys with improved mechanical properties. Metallurg Mater Trans A 2019; 50: 311–325.

31.

El-Hossainy

El-Zoghby

Badr

, et al. Cutting parameter optimization when machining different materials. Mater Manuf Processes 2010; 25: 1101–1114.

32.

Karpat

, Bahtiyar O, Değer B, et al. A mechanistic approach to investigate drilling of UD-CFRP laminates with PCD drills. CIRP Ann 2014; 63: 81–84.

33.

Ghasemi

Khorasani

Gibson

. Investigation on the effect of a pre-center drill hole and tool material on thrust force, surface roughness, and cylindricity in the drilling of Al7075. Materials (Basel) 2018; 11: 140.

34.

Sangeetha

Prakash

. Experimental investigation of process parameters in drilling LM25 composites coated with multi wall carbon nano tubes using sonication process. Arch Metall Mater 2017; 62: 1761–1770.

35.

Gecgel

Altıntaş

Arslan

, et al. Effect of silicon on machinability in AlSi6, AlSi12 and AlSi18 alloys. Silicon 2024; 16: 1467–1479.

36.

Adhikari

Bolar

Shanmugam

, et al. Machinability and surface integrity investigation during helical hole milling in AZ31 magnesium alloy. Int J Lightweight Mat Manuf 2023; 6: 149–164.

37.

Lughmani

Bouazza-Marouf

Ashcroft

. Drilling in cortical bone: a finite element model and experimental investigations. J Mech Behav Biomed Mater 2015; 42: 32–42.

38.

Güldibi

Köklü

Koçar

, et al. The effects of aging process after solution heat treatment on drilling machinability of corrax steel. Exp Tech 2024; 48: 239–257.

39.

Koklu

Morkavuk

Urtekin

. Effects of the drill flute number on drilling of a casted AZ91 magnesium alloy. Mater Test 2019; 61: 260–266.

40.

Palanikumar

Muniaraj

. Experimental investigation and analysis of thrust force in drilling cast hybrid metal matrix (Al–15% SiC–4% graphite) composites. Measurement (Mahwah NJ) 2014; 53: 240–250.

41.

Dou

, Fu H, Li Z, et al. Prediction model, simulation, and experimental validation on thrust force and torque in drilling SiCp/Al6063. Int J Adv Manuf Technol 2019; 103: 165–175.

42.

Koklu

Coban

. Effect of dipped cryogenic approach on thrust force, temperature, tool wear and chip formation in drilling of AZ31 magnesium alloy. J Mater Res Technol 2020; 9: 2870–2880.

43.

Ekici

Motorcu

Uzun

. An investigation of the effects of cutting parameters and graphite reinforcement on quality characteristics during the drilling of Al/10B4C composites. Measurement (Mahwah N J) 2017; 95: 395–404.

44.

Koklu

Basmaci

. Evaluation of tool path strategy and cooling condition effects on the cutting force and surface quality in micromilling operations. Metals (Basel) 2017; 7: 426.

45.

Amran

Salmah

Sanusi

, et al. Surface roughness optimization in drilling process using response surface method (RSM). Jurnal Teknologi 2014; 66: 29–35.

46.

Zhang

Chen

. Surface roughness optimization in a drilling operation using the Taguchi design method. Mater Manuf Processes 2009; 24: 459–467.

47.

Amran

, Salmah S, Hussein NIS, et al. Effects of machine parameters on surface roughness using response surface method in drilling process. Procedia Eng 2013; 68: 24–29.

48.

Sadiq

Hameed

Idris

, et al. Effect of different machining parameters on surface roughness of aluminium alloys based on Si and Mg content. J Brazil Soc Mech Sci Eng 2019; 41: 1–11.

49.

Motorcu

Kuş

Durgun

. The evaluation of the effects of control factors on surface roughness in the drilling of Waspaloy superalloy. Measurement (Mahwah NJ) 2014; 58: 394–408.

50.

Batzer

Haan

Rao

, et al. Chip morphology and hole surface texture in the drilling of cast aluminum alloys. J Mater Process Technol 1998; 79: 72–78.

51.

Demirbaş

Köklü

Morkavuk

, et al. Machining-induced damage and corrosion behavior of Monel-400 alloy under cryogenic cooling conditions: a sustainable initiative. Int J Prec Eng Manuf–Green Technol 2025; 12: 493–508.

52.

, Li Y, Chen J, et al. Experimental study on chip formation and surface quality in milling of TiB2/Al alloy composites. Mater Manuf Processes 2020; 35: 1671–1679.

53.

Gökçe

. Modelling and optimization for thrust force, temperature and burr height in drilling of custom 450. Exp Tech 2022; 46: 707–721.

54.

Kim

Dornfeld

. Development of an analytical model for drilling burr formation in ductile materials. J Eng Mater Technol 2002; 124: 192–198.

55.

Kim

Min

Dornfeld

. Optimization and control of drilling burr formation of AISI 304L and AISI 4118 based on drilling burr control charts. Int J Mach Tools Manuf 2001; 41: 923–936.

56.

Adineh

Doostmohammadi

, Microstructure, mechanical properties and machinability of Cu–Zn–Mg and Cu–Zn–Sb brass alloys. Mater Sci Technol 2019; 35: 1504–1514.

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