High speed machining of the thin-walled aircraft constructions

Machining operations of thin-walled elements generate a lot of production process issues related to deformations and elastic and plastic displacements of the workpiece. Due to displacements of the milled workpiece, vibrations can occur, and thus, geometric errors may occur on surface in the structure of the workpiece. Furthermore, plastic deformation can also cause shape problems and be a source of internal stresses in the surface layer, which are highly difficult to remove and lead to deformation of the workpiece after machining. Consequently, this leads to an increase in the manufacturing costs of machining operations, especially of thin-walled elements, due to shortages and increased manufacturing time. It is recommended that multiple methods for minimizing machining errors be utilized to improve the quality of thin walled elements, such as: optimization of the machining strategy, increase of the cutting speed vc, optimization of cutting parameters, especially feed per blade fz, the radial depth of cut ae due to the minimization of the cutting force component perpendicular to the surface of the milled wall.

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Cutting Forces in High Speed Milling of Hardened Steel by Coated Tool

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.69-70.418 ◽

2009 ◽

Vol 69-70 ◽

pp. 418-422

Author(s):

L.D. Wu ◽

Cheng Yong Wang ◽

D.H. Yu ◽

Yue Xian Song

Keyword(s):

Cutting Forces ◽

High Speed ◽

Cutting Speed ◽

Cutting Parameters ◽

Hardened Steel ◽

Depth Of Cut ◽

Coated Tool ◽

Radial Depth ◽

Solid Carbide ◽

End Mills

Hardened steel P20 at 50 HRC is milled at high speed by TiN coated and TiAlN coated solid carbide straight end mills, and the cutting forces and tool wear are measured. The result shows that TiAlN coated tool is more suitable for cutting hardened steel at high speed. Then the hardened steel is milled under different cutting parameters. It is indicated that the effect of cutting speed on cutting forces is small, but the effect of cutting speed on machine vibration should be considered. Increase feed per tooth or radial depth of cut will increase the cutting forces.

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Effect of cutting parameters on tool life during end milling of AISI 4340 under MQL condition

Industrial Lubrication and Tribology ◽

10.1108/ilt-08-2021-0295 ◽

2022 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Ahsana Aqilah Ahmad ◽

Jaharah A. Ghani ◽

Che Hassan Che Haron

Keyword(s):

Tool Wear ◽

Tool Life ◽

Wear Mechanism ◽

High Speed ◽

End Milling ◽

Cutting Speed ◽

Cutting Parameters ◽

Depth Of Cut ◽

Content Type ◽

Radial Depth

Purpose The purpose of this paper is to study the cutting performance of high-speed regime end milling of AISI 4340 by investigating the tool life and wear mechanism of steel using the minimum quantity lubrication (MQL) technique to deliver the cutting fluid. Design/methodology/approach The experiments were designed using Taguchi L9 orthogonal array with the parameters chosen: cutting speed (between 300 and 400 m/min), feed rate (between 0.15 and 0.3 mm/tooth), axial depth of cut (between 0.5 and 0.7 mm) and radial depth of cut (between 0.3 and 0.7 mm). Toolmaker microscope, optical microscope and Hitachi SU3500 Variable Pressure Scanning Electron Microscope used to measure tool wear progression and wear mechanism. Findings Cutting speed 65.36%, radial depth of cut 24.06% and feed rate 6.28% are the cutting parameters that contribute the most to the rate of tool life. The study of the tool wear mechanism revealed that the oxide layer was observed during lower and high cutting speeds. The former provides a cushion of the protective layer while later reduce the surface hardness of the coated tool Originality/value A high-speed regime is usually carried out in dry conditions which can shorten the tool life and accelerate the tool wear. Thus, this research is important as it investigates how the use of MQL and cutting parameters can prolong the usage of tool life and at the same time to achieve a sustainable manufacturing process.

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Effect of Various Cooling Strategies on Surface Roughness of High Speed Milling Ti-6Al-4V

Materials Science Forum ◽

10.4028/www.scientific.net/msf.697-698.49 ◽

2011 ◽

Vol 697-698 ◽

pp. 49-52 ◽

Cited By ~ 2

Author(s):

Xiao Yong Yang ◽

Cheng Zu Ren ◽

Guang Chen ◽

Bing Han ◽

Y. Wang

Keyword(s):

Surface Roughness ◽

High Speed ◽

Cutting Speed ◽

Cutting Parameters ◽

Cutting Fluid ◽

Depth Of Cut ◽

Side Milling ◽

High Speed Milling ◽

Cooling Strategies ◽

Radial Depth

This study focused on the side milling surface roughness of titanium alloy under various cooling strategies and cutting parameters. The experimental results show that the cooling strategies significantly affect the surface roughness in milling Ti-6Al-4V. Surface roughness (Ra) alterations are investigated. Cutting fluid strategy made nearly all the smallest and most stable roughness values. The surface roughness values produced by all cooling strategies are obviously affected by feed, radial depth-of-cut and cutting speed. However, axial depth-of-cut has little influence.

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Influence on Cutting Forces and Vibration in High Speed Machining Pocket Corner

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.189-193.3084 ◽

2011 ◽

Vol 189-193 ◽

pp. 3084-3088

Author(s):

De Wen Tang ◽

Ru Shu Peng ◽

Rui Lan Zhao

Keyword(s):

Cutting Force ◽

Cutting Forces ◽

High Speed ◽

Sudden Change ◽

Cutting Speed ◽

Cutting Parameters ◽

Poor Quality ◽

Depth Of Cut ◽

Processing Efficiency ◽

Radial Depth

High speed milling hardened mould steel (above HRC50) at pocket corner generates the cutting forces increase and vibration gets fiercely because of the sudden change of cutting direction. It will cause serious wear and possible breakage of cutting tool, and poor quality of parts. Hence, the need to select reasonable cutting parameters and adopt appropriate cutting strategies will help them to achieve their goal. In this paper, the effects cutting parameters including cutting speed, pocket corner angle, feed rate per tooth and radial depth of cut on cutting force and vibration are studied. The results show that sharper pocket corner results in the increase of cutting force and makes vibration strong. Cutting force increase with the increase of cutting speeding, feed per tooth and radial depth of cut. The optimum of cutting speed leads to the decrease of vibration. It is proposed that cutting parameters should be optimized to improve tool life and processing efficiency.

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Optimization of Cutting Parameters using Cryogenically Treated High Speed Steel Tool by Taguchi Application

International Journal of Manufacturing Materials and Mechanical Engineering ◽

10.4018/ijmmme.2013010102 ◽

2013 ◽

Vol 3 (1) ◽

pp. 26-38 ◽

Cited By ~ 4

Author(s):

Lakhwinder Pal Singh ◽

Jagtar Singh

Keyword(s):

Feed Rate ◽

High Speed ◽

Cryogenic Treatment ◽

Cutting Speed ◽

High Speed Steel ◽

Cutting Parameters ◽

Small Scale ◽

Depth Of Cut ◽

Machining Parameters ◽

Optimization Of Cutting Parameters

In the field of mechanical engineering, engineers are always looking for ways to improve the properties of materials. Cryogenic treatment of tooling steels is a proven technology to increase wear resistance and extend intervals between component replacements. The main idea of this paper is to apply Taguchi method to optimize cutting parameters in turning operation using cryogenic treated (CT) and untreated (UT) high speed steel (HSS) tools, so that the scope of cryogenic treatment on HSS tool material may be presented for the benefit of medium and small scale industry using HSS tools for cutting operation. Taguchi L25 orthogonal array is employed to study the performance characteristics in turning operations of AISI 1020 steel bars using CT and UT HSS tools. The microstructure has been found more refined and uniformly distributed after cryogenic treatment of HSS tool. It has been observed that optimum machining parameters in both the cases (CT HSS and UT HSS tools) are higher cutting speed (49.9 to 75.7 m/min.), lower feed rate (0.15 mm/rev.), medium depth of cut (0.40 mm). Analysis of variance (ANOVA) indicates that the cutting speed is most significant parameter followed by feed rate in case of CT HSS tool and depth of cut in case of UT HSS tool.

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Experimental Studies on Cutting Temperature of Nickel-Based Supper Alloy Inconel 718

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.584.20 ◽

2013 ◽

Vol 584 ◽

pp. 20-23

Author(s):

Mao Hua Xiao ◽

Ning He ◽

Liang Li ◽

Xiu Qing Fu

Keyword(s):

Inconel 718 ◽

High Speed ◽

Experimental Studies ◽

Cutting Temperature ◽

Cutting Speed ◽

Cutting Parameters ◽

Depth Of Cut ◽

High Speed Milling ◽

Radial Depth ◽

The Impact

The method to measure the cutting speed when high speed milling nickel alloy Inconel 718 based on semi-artificial thermocouple. The cutting parameters, tool wear and so on the cutting temperature were analyzed. The tests showed that the temperature was gradually increased with the increase of cutting speed. The cutting speed must be more than 600m/min, when the ceramic tools would perform better cutting performance in the high-speed milling nickel-based superalloy. In order to achieve more efficient machining, milling speed can be increased to more than 1000m/min. The impact amount of Radial depth of cut and feed per tooth were relatively small.

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Recent Development of Parameter Optimization for Metal Cutting and Grinding Processes

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.652-654.2218 ◽

2013 ◽

Vol 652-654 ◽

pp. 2218-2221 ◽

Cited By ~ 1

Author(s):

Li Bao An ◽

Chun Guang Lu

Keyword(s):

Parameter Optimization ◽

High Speed ◽

Metal Cutting ◽

Cutting Tools ◽

Cutting Speed ◽

Cutting Parameters ◽

Optimization Techniques ◽

Depth Of Cut ◽

Dry Cutting ◽

Optimization Of Cutting Parameters

Metal cutting indicates a specific category of processes in which unwanted material is removed from workpeice by single- or multi-point cutting tools for making products meeting prescribed specifications. Parameter optimization in metal cutting plays an important role in satisfying quality requirements of machined parts at low production cost or time. It requires optimal selection of cutting speed, feed rate, depth of cut, and the number of passes. A brief review of recent progress on the optimization of cutting parameters is introduced in the present work. Some new machining practices expending in recent years are involved including hard turning, dry cutting, high speed machining, machining of difficult-to-machine materials and composites. Modeling skills for creating optimization models and optimization techniques for solving optimal or near-optimal solutions are summarized and analyzed.

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Optimization of Cutting Parameters in Milling Process Using Genetic Algorithm and ANOVA (March 2020)

Engineering and Technology Journal ◽

10.30684/etj.v38i10a.1124 ◽

2020 ◽

Vol 38 (10A) ◽

pp. 1489-1503

Author(s):

Marwa Q. Ibraheem

Keyword(s):

Genetic Algorithm ◽

Tool Wear ◽

Material Removal Rate ◽

Material Removal ◽

Removal Rate ◽

Cutting Speed ◽

Cutting Parameters ◽

Depth Of Cut ◽

Optimal Value ◽

Optimization Of Cutting Parameters

In this present work use a genetic algorithm for the selection of cutting conditions in milling operation such as cutting speed, feed and depth of cut to investigate the optimal value and the effects of it on the material removal rate and tool wear. The material selected for this work was Ti-6Al-4V Alloy using H13A carbide as a cutting tool. Two objective functions have been adopted gives minimum tool wear and maximum material removal rate that is simultaneously optimized. Finally, it does conclude from the results that the optimal value of cutting speed is (1992.601m/min), depth of cut is (1.55mm) and feed is (148.203mm/rev) for the present work.

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Cutting Temperature and Cutting Forces Investigation Based on the Taguchi Design Method when High-Speed Milling of Titanium Matrix Composites with PCD Tool

Materials Science Forum ◽

10.4028/www.scientific.net/msf.836-837.168 ◽

2016 ◽

Vol 836-837 ◽

pp. 168-174 ◽

Cited By ~ 2

Author(s):

Ying Fei Ge ◽

Hai Xiang Huan ◽

Jiu Hua Xu

Keyword(s):

Cutting Force ◽

Feed Rate ◽

Cutting Forces ◽

High Speed ◽

Volume Fraction ◽

Cutting Temperature ◽

Cutting Speed ◽

Depth Of Cut ◽

High Speed Milling ◽

Radial Depth

High-speed milling tests were performed on vol. (5%-8%) TiCp/TC4 composite in the speed range of 50-250 m/min using PCD tools to nvestigate the cutting temperature and the cutting forces. The results showed that radial depth of cut and cutting speed were the two significant influences that affected the cutting forces based on the Taguchi prediction. Increasing radial depth of cut and feed rate will increase the cutting force while increasing cutting speed will decrease the cutting force. Cutting force increased less than 5% when the reinforcement volume fraction in the composites increased from 0% to 8%. Radial depth of cut was the only significant influence factor on the cutting temperature. Cutting temperature increased with the increasing radial depth of cut, feed rate or cutting speed. The cutting temperature for the titanium composites was 40-90 °C higher than that for the TC4 matrix. However, the cutting temperature decreased by 4% when the reinforcement's volume fraction increased from 5% to 8%.

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A Comprehensive Study on Surface Roughness in Machining of AISI D2 Hardened Steel

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.576.60 ◽

2012 ◽

Vol 576 ◽

pp. 60-63 ◽

Cited By ~ 7

Author(s):

N.A.H. Jasni ◽

Mohd Amri Lajis

Keyword(s):

Surface Roughness ◽

High Speed ◽

End Milling ◽

Cutting Speed ◽

Hardened Steel ◽

Depth Of Cut ◽

Feed Speed ◽

Radial Depth ◽

Aisi D2 ◽

Coated Carbide

Hard milling of hardened steel has wide application in mould and die industries. However, milling induced surface finish has received little attention. An experimental investigation is conducted to comprehensively characterize the surface roughness of AISI D2 hardened steel (58-62 HRC) in end milling operation using TiAlN/AlCrN multilayer coated carbide. Surface roughness (Ra) was examined at different cutting speed (v) and radial depth of cut (dr) while the measurement was taken in feed speed, Vf and cutting speed, Vc directions. The experimental results show that the milled surface is anisotropic in nature. Surface roughness values in feed speed direction do not appear to correspond to any definite pattern in relation to cutting speed, while it increases with radial depth-of-cut within the range 0.13-0.24 µm. In cutting speed direction, surface roughness value decreases in the high speed range, while it increases in the high radial depth of cut. Radial depth of cut is the most influencing parameter in surface roughness followed by cutting speed.

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