Comparison of Different Manufacturing Processes of AISI 4140 Steel with Regard to Surface Modification and Its Influencing Depth

Borchers, Florian; Clausen, B.; Eckert, Sandro; Ehle, Lisa; Épp, Jérémy; Harst, Simon; Hettig, Matthias; Klink, Andreas; Kohls, Ewald; Meyer, Heiner; Meurer, Markus; Rommes, Bob; Schneider, Sebastian; Strunk, Rebecca

doi:10.3390/met10070895

Cited by 27 publications

(25 citation statements)

References 35 publications

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“…Volumetric wear rate R v was 1.22 ± 0.04 mm 3 •s −1 at roughing and 0.52 ± 0.002 mm 3 •s −1 at finishing; mass wear rate R m -9.6 × 10 −3 ± 0.01 g•s −1 and 4.0 × 10 −3 ± 0.008 g•s −1 , respectively. 41 ÷ 62% of the tool subjected wear under discharge impulses at roughing during electrical discharge machining of anti-corrosion steel when summarized lateral wear exceed front wear by 29.17%.…”

Section: Wire Tool Topology and Wear Ratementioning

confidence: 92%

“…where ∆V is volumetric wear, mm 3 , ∆m is a worn mass, g, and t is the wire length wear time; for a thickness of 20 mm, t = 0.343 ± 0.005 s. The discharge gap is calculated by the following equation:…”

Section: Characterization Of the Samples Wear Rate And Discharge Gapmentioning

confidence: 99%

“…The subject of electrical discharge machining (EDM) and wear of a wire tool electrode is not new, but the physical processes that occur during processing are still not sufficiently studied [1][2][3][4]. It is related to the absence of the possibility of visual control over the processes occurring in the discharge gap during EDM especially for large workpieces [5,6].…”

Section: Introductionmentioning

confidence: 99%

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Wire Tool Electrode Behavior and Wear under Discharge Pulses

et al. 2020

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This work is devoted to researching the tool electrode behavior and wear under discharge pulses at electrical discharge machining. The experiments were conducted on the workpieces of 12Kh18N10T (AISI 321) chrome-nickel anti-corrosion steel and D16 (AA 2024) duralumin by a 0.25-mm-diameter CuZn35 brass tool in a deionized water medium. The developed diagnostic and monitoring mean based on acoustic emission registered the oscillations accompanying machining at 4–8 kHz. The obtained workpiece and non-profiled tool surfaces were investigated by optical and scanning electron microscopy. Calculated volumetric and mass removal rates showed the difference in the character of wear at roughing and finishing. It was shown that interaction between material components in anti-corrosion steel machining had an explosive character between Zn of brass and Ni of steel at a micron level and formed multiple craters of 30–100 µm. The secondary structure and topology of worn tool surfaces were caused by material sublimation, chemical interaction between material components at high heat (10,000 °C), explosive deposition of the secondary structure. Acoustic diagnostics adequately registered the character of interaction. The observed phenomena at the submicron level and microstructure of the obtained surfaces provide grounding on the nature of material interactions and electrical erosion wear fundamentals.

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Section: Wire Tool Topology and Wear Ratementioning

confidence: 92%

Section: Characterization Of the Samples Wear Rate And Discharge Gapmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Wire Tool Electrode Behavior and Wear under Discharge Pulses

et al. 2020

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“…According to the detailed literature review by Jawahir et al [5] and the recent research of Borchers et al [6] about Surface Integrity in machining, the functionality and fatigue life of a machined part is strongly related to its topographical, metallurgical and mechanical properties in the rim zone. Hard turning is known for the induced thermo-mechanical loads that lead to altered microstructures, hardness, residual stresses, dislocation densities and grain sizes at the surface layers.…”

Section: Introductionmentioning

confidence: 99%

Modelling of Grain Size Evolution with Different Approaches via FEM When Hard Machining of AISI 4140

Tekkaya

Meurer

Münstermann

2020

Metals

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Thermo-mechanical loads during hard turning lead to the formation of so-called White Layers on the machined surface. Characterized by a very fine microstructure and high hardness, White Layers have a negative effect on the fatigue life of a component. The fundamental mechanism for the White Layer formation is the dynamic recrystallization (DRX). Therefore, in the current work, two different DRX models, Helmholtz free energy and Zener-Hollomon, are implemented into Abaqus/Explicit to predict the thickness of the White Layer when hard turning quenched/tempered AISI 4140 and the results are compared with each other. For the simulation of the machining process a Finite Element Method (FEM) model based on the Coupled-Eulerian-Lagrangian (CEL) method is built up. Although both DRX models achieved a very good match between predicted and measured White Layer thickness and grain size evolution on the workpiece rim zone, the Zener-Hollomon model produced more closer agreement.

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“…High thermo-mechanical loads that are generated during the hard turning process have a great influence on the functionality of a machined part [1,2]. These loads are responsible for microstructural alterations, modification of hardness, residual stress state, mechanical properties, chemical composition and corrosion resistance in the workpiece rim zone [3].…”

Section: Introductionmentioning

confidence: 99%

Cutting force based surface integrity soft-sensor when hard machining AISI 4140

Meurer

Tekkaya

Augspurger

et al. 2020

Tm - Technisches Messen

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Workpiece rim zone modifications during hard machining can be explained with the high thermo-mechanical loads induced by the cutting process. The formation of White Layers with a fine-grained microstructure by dynamic recrystallization (DRX) is one of those surface modifications that can negatively affect the functionality of a machined part by changing the residual stress state and facilitating crack initiation. As a consequence, the fatigue life of the machined parts is reduced. It is therefore of great interest to understand the thermo-mechanical conditions which induce White Layers formation in order to be able to control them by in-situ measurements if necessary. For this purpose, a cutting force based Soft-Sensor is developed in this study which enables the in-process estimation of White Layer thickness. Therefore, a cutting force based analytical model is used to estimate the resulting temperature fields and correlated with validated numerical chip formation simulations. In addition, the predictions of the White Layer thickness of the analytical model are then compared using light microscopy and the results of the numerical finite element model, in which a DRX model is additionally implemented.

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Comparison of Different Manufacturing Processes of AISI 4140 Steel with Regard to Surface Modification and Its Influencing Depth

Cited by 27 publications

References 35 publications

Wire Tool Electrode Behavior and Wear under Discharge Pulses

Wire Tool Electrode Behavior and Wear under Discharge Pulses

Modelling of Grain Size Evolution with Different Approaches via FEM When Hard Machining of AISI 4140

Cutting force based surface integrity soft-sensor when hard machining AISI 4140

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