On the impacts of tool geometry and cutting conditions in straight turning of aluminum alloys 6061-T6: an experimentally validated numerical study

Javidikia, Mahshad; Sadeghifar, Morteza; Songmené, Victor; Jahazi, Mohammad

doi:10.1007/s00170-020-04945-3

Cited by 27 publications

(50 citation statements)

References 22 publications

(34 reference statements)

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“…As observed in this figure, the resultant machining forces increased with raising feed rate for both modes. This is because higher feed rates lead to larger tool–chip contact area and pressure, resulting in larger magnitudes of machining forces [ 9 , 11 ].…”

Section: Resultsmentioning

confidence: 99%

“…Orthogonal cutting of aluminum alloys is an important machining operation in the aerospace industry, particularly as initial step for further and more complex operations. According to Javidikia et al [ 9 ], one of the major challenges in othrogonal cutting of aluminum alloys is the occurrence of non-uniform cutting temperatures and machining forces. A previous research study by Hu and Huang [ 10 ] on turing of AISI4340 steel demonstrated that machining forces and temperature are the fundamental factors that determine the extent of residual stresses and tool wear.…”

Section: Introductionmentioning

confidence: 99%

“…Large tensile residual stresses can significantly affect fatigue life and corrosion resistance of machined components, which lead to crack propagation, as mentioned by Javidikia et al [ 1 ] and Sadeghifar et al [ 11 ], who carried out research on surface integrity induced by turning of AA6061-T6 and residual stresses and machining characteristics generated by orthogonal turning of 300M Steel, respectively. Based on the research work by Javidikia et al [ 9 ], the machining with the cutting speed below 900

is considered as LSC, while above 900

is known as HSC. Therefore, different experimental and numerical studies have been carried out to improve tool wear and residual stress induced by machining processes.…”

Section: Introductionmentioning

confidence: 99%

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Low and High Speed Orthogonal Cutting of AA6061-T6 under Dry and Flood-Coolant Modes: Tool Wear and Residual Stress Measurements and Predictions

et al. 2021

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The present research work aimed to study the effects of cutting environments and conditions on tool wear and residual stresses induced by orthogonal cutting of AA6061-T6. Cutting environments included dry- and flood-coolant modes and cutting conditions consisted of cutting speed and feed rate. A 2D finite element (FE) model was developed to predict tool wear and residual stresses and was validated by experimental measurements including machining forces, tool wear, and residual stresses. This was obtained by exploring various magnitudes of the shear friction factor and heat transfer coefficient and choosing proper coefficients using the calibration of the predicted results with the measured ones. The experimental results showed that the effect of cutting environment including dry and flood-coolant modes was negligible on machining forces. The experimental investigation also demonstrated that increasing feed rate raised machining forces, tool wear and residual stresses in both cutting environments. Low Speed Cutting (LSC) led to the highest value of tool wear and High Speed Cutting (HSC) provided the lowest values of resultant machining forces and residual stresses in both modes. Flood-coolant mode reduced tool wear and slightly decreased tensile residual stresses in comparison with dry mode. As a result, low feed rate and high-speed cutting under flood-coolant mode were proposed in order to improve tool wear and residual stress in orthogonal cutting of AA6061-T6.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

is considered as LSC, while above 900

is known as HSC. Therefore, different experimental and numerical studies have been carried out to improve tool wear and residual stress induced by machining processes.…”

Section: Introductionmentioning

confidence: 99%

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Low and High Speed Orthogonal Cutting of AA6061-T6 under Dry and Flood-Coolant Modes: Tool Wear and Residual Stress Measurements and Predictions

et al. 2021

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“…The study also showed that cutting forces increase with an increase in feed rate and depth of cut. A similar study was completed by Javidikia et al [ 10 ]. They studied the impact of tool geometry and cutting conditions in turning the aluminum alloy 6061-T6 under a dry condition with uncoated carbide insert.…”

Section: Literature Reviewmentioning

confidence: 75%

Experimental Investigation and Statistical Evaluation of Optimized Cutting Process Parameters and Cutting Conditions to Minimize Cutting Forces and Shape Deviations in Al6026-T9

et al. 2020

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Precise, economical and sustainable cutting operations are highly desirable in the advanced manufacturing environment. For this aim, the present study investigated the influence of cutting parameters (i.e., the cutting speed (c), feed rate (f), depth of cut (d) and positive rake angle (p)) and sustainable cutting conditions (dry and minimum quantity lubricant (MQL)) on cutting forces (i.e., feed force (Ff), tangential forces (Ft), radial force (Fr) and resultant cutting forces (Fc) and shape deviations (i.e., circularity and cylindricity) of a 6026-T9 aluminum alloy. The type of lubricant and insert used are virgin olive oil and uncoated tungsten carbide tool. Turning experiments were performed on a TAKISAWA TC-1 CNC lathe machine and cutting forces were measured with the help of a Kistler 9257B dynamometer. Shape deviations were evaluated by means of a Tesa Micro-Hite 3D DCC 474 coordinate measuring machine (CMM). Experimental runs were planned based on Taguchi mixture orthogonal array design L16. Analysis of variance (ANOVA) was performed to study the statistical significance of cutting parameters. Taguchi based signal to noise (S/N) ratios are applied for optimization of single response, while for optimization of multiple responses Taguchi based signal to noise (S/N) ratios coupled with multi-objective optimization on the basis of ratio analysis (MOORA) and criteria importance through inter-criteria correlation (CRITIC) are employed. ANOVA results revealed that feed rate, followed by a depth of cut, are the most influencing and contributing factors for all components of cutting forces (Ff, Ft, Fr, and Fc) and shape deviations (circularity and cylindricity). The optimized cutting parameters obtained for multi responses are c = 600 m/min, f = 0.1 mm/rev, d = 1 mm and p = 25°, while for cutting conditions, MQL is optimal.

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“…According to Pattnaik et al [2], excessive crater wear was noticed while machining non-ferrous materials because of continuous chip flow over the outside of the tool. Javidikia et al [3] revealed that a larger contact region of the toolchip builds the chip thickness proportion that prompts to have higher cutting temperatures. Likewise, it induces a higher cutting force that prompts an effective utilization of the machine.…”

Section: Introductionmentioning

confidence: 99%

Studies on the effects of deep cryogenic treated WC–Co insert on turning of Al6063 using multi-objective optimization

Arunkarthikeyan¹,

Balamurugan²

2020

SN Appl. Sci.

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To improve the machining performance manufacturers adopt various methods to improve the tool life which influences production cost and the degree of the surface finish. Recently cryogenic treatment is used to improve the machining performances. In the present work, the tungsten carbide-cobalt (WC-Co) cutting tool is cryogenically treated at − 196 °C for a soaking time of 24 h and tempered to 200 °C for 2 h. The machinability attributes such as Tool Wear Rate, Surface profile roughness (Ra), of the Cryo Treated (CT) cutting tool, are measured on turning operation with different parametric conditions on the Al6063 alloy and compared with an Untreated Tool (UT). The results show that the CT tool improves the tool life with an acceptable surface finish. Taguchi's coupled multi-objective optimization methods such as Grey Relational Analysis (TC-GRA) and Technique for Order Preference by Similarity to Ideal Solution (TC-TOPSIS) were actualized to enhance the turning performance of CT tool. The outcomes revealed that TC-TOPSIS acquired ideal condition is improving the exhibition than the TC-GRA. Furthermore, the interaction impact of cutting parameters is analyzed through 3D surface plots.

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On the impacts of tool geometry and cutting conditions in straight turning of aluminum alloys 6061-T6: an experimentally validated numerical study

Cited by 27 publications

References 22 publications

Low and High Speed Orthogonal Cutting of AA6061-T6 under Dry and Flood-Coolant Modes: Tool Wear and Residual Stress Measurements and Predictions

Low and High Speed Orthogonal Cutting of AA6061-T6 under Dry and Flood-Coolant Modes: Tool Wear and Residual Stress Measurements and Predictions

Experimental Investigation and Statistical Evaluation of Optimized Cutting Process Parameters and Cutting Conditions to Minimize Cutting Forces and Shape Deviations in Al6026-T9

Studies on the effects of deep cryogenic treated WC–Co insert on turning of Al6063 using multi-objective optimization

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