Manufacturing at double the speed

Allwood, Julian M.; Childs, T.H.C.; Clare, Adam T.; Silva, A.K.M. De; Dhokia, Vimal; Hutchings, I.M.; Leach, Richard; Leal-Ayala, David R.; Lowth, Stewart; Majewski, Candice; Marzano, Adelaide; Mehnen, Jörn; Nassehi, Aydin; Öztürk, Erdem; Raffles, Mark; Roy, Rajkumar; Shyha, Islam; Turner, Sam

doi:10.1016/j.jmatprotec.2015.10.028

Cited by 45 publications

(16 citation statements)

References 114 publications

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“…This behavior can be explained by the effect of a heating rate and holding time on the nucleation and growth of austenite and the dissolution of Fe 3 C carbides. Several studies [12][13][14] have indicated that during rapid reheating the classical view of phase transformations will deviate markedly from those observed during equilibrium conditions. That is, the kinetics of transformation will have a different behavior.…”

Section: Effect Of Heating Rate On Transformation Temperatures (A C1 mentioning

confidence: 99%

The Effect of Rapid Heating and Fast Cooling on the Transformation Behavior and Mechanical Properties of an Advanced High Strength Steel (AHSS)

Pedraza¹,

Landa-Mejia

García-Rincón³

et al. 2019

Metals

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The major goal of this work was to study the effect of rapid heating and fast cooling on the transformation behavior of 22MnB5 steel. The effect of the initial microstructure (ferrite + pearlite or fully spheroidized) on the transformation behavior of austenite (during intercritical and supercritical annealing) in terms of heating rates (2.5, 30 & 200 °C/s) and fast cooling, i.e., 300 °C/s rate, were studied. As expected, the kinetics of austenite nucleation and growth were strongly related to the heating rates. Similarly, the carbon content of the austenite was higher at lower intercritical annealing temperatures, particularly when slower heating rates were used. The supercritical temperatures used in this study were similar to those used during commercial hot stamping operations, i.e., 845 and 895 °C, respectively, followed by a fast cooling rate. The prior austenite grain size (PAGS) was not strongly influenced by the nature of the initial microstructure, heating rate, reheating temperatures (845 or 895 °C), at 30 s holding time. The decomposition of austenite using fast cooling rates was examined. The results showed that 100% martensite was not obtained. The observed low temperature transformation products consisted of mixtures of martensite-bainite plus undissolved Fe3C carbides and small amounts of martensite-austenite (M-A). At higher supercritical temperatures, i.e., 1000 °C and 1050 °C, the final microstructure showed an increase in the volume fraction of martensite and a decrease in the volume fraction of bainite. The Fe3C and the M-A microconstituent were not observed. The best combination of tensile properties was obtained on samples reheated in the lower temperature range (845 to 895 °C). Interestingly, when the samples where reheated at the higher temperature range (1000 to 1050 °C) and fast cooled, the results of the mechanical properties did not exhibit significantly higher strength levels independent of heating rate or initial microstructural condition. This can be attributed to the change in the microstructural balance %martensite+%bainite as the reheating temperature increases. The results of this study are presented and discussed.

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Section: Effect Of Heating Rate On Transformation Temperatures (A C1 mentioning

confidence: 99%

The Effect of Rapid Heating and Fast Cooling on the Transformation Behavior and Mechanical Properties of an Advanced High Strength Steel (AHSS)

Pedraza¹,

Landa-Mejia

García-Rincón³

et al. 2019

Metals

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“…However, pushing cutting conditions boundaries in machining titanium is required for faster manufacturing [4]. Owing to low thermal conductivity such as 7.3 W/m·K for annealed Ti-6Al-4V, cutting titanium generates a large amount of heat close to the machining zone.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of a Novel Controlled Cutting Fluid Impinging Supply System When Machining Titanium Alloys

2017

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Abstract:Following a comprehensive review on titanium machining and methods of cutting fluid application, this paper presents a new Controlled cutting fluid impinging supply system (Cut-list) developed to deliver an accurate amount of cutting fluid into the machining zone via well-positioned coherent nozzles based on the calculation of the heat generated. The performance of the new system was evaluated against a conventional flood cutting fluid supply system during step shoulder milling of Ti-6Al-4V using vegetable oil-based cutting fluid. The comparison was performed at different cutting speeds and feed rates. Comparison measures/indicators were cutting force, workpiece temperature, tool flank wear, burr formation and average surface roughness (Ra). The new system provided significant reductions in cutting fluid consumption of up to 42%. Additionally, reductions in cutting force, tool flank wear and burr height of 16.41%, 46.77%, and 31.70% were recorded, respectively. Smaller Ra values were also found with the use of the new system.

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“…Mechatronics components are often substituted in case of damage. A potential future technology for spare part production is Additive Layer Manufacturing that allows producing directly from 3D scan data [3,47,103]. The mechanism involves cleaning the damaged area, depositing new material ( Fig.…”

Section: Repair Mechanismsmentioning

confidence: 99%

Continuous maintenance and the future – Foundations and technological challenges

et al. 2016

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Manufacturing at double the speed

Cited by 45 publications

References 114 publications

The Effect of Rapid Heating and Fast Cooling on the Transformation Behavior and Mechanical Properties of an Advanced High Strength Steel (AHSS)

The Effect of Rapid Heating and Fast Cooling on the Transformation Behavior and Mechanical Properties of an Advanced High Strength Steel (AHSS)

Evaluation of a Novel Controlled Cutting Fluid Impinging Supply System When Machining Titanium Alloys

Continuous maintenance and the future – Foundations and technological challenges

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