Research on breakage characteristics in side milling of titanium alloy with cemented carbide end mill

Du, Yanjie; Yue, Caixu; Li, Xiaochen; Liu, Xianli; Liang, Steven Y.

doi:10.1007/s00170-021-07938-y

Cited by 7 publications

(3 citation statements)

References 39 publications

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“…Generally, it can be claimed that the temperature generated in the cutting zone is inextricably linked to chip formation time, because at a later stage of the milling process the chip temperature does not increase. The problem of short-term ignition during milling and its infrared measurement [3,4] has also been investigated in studies devoted to the machinability of other construction materials such as titanium or nickel alloys [5][6][7][8].…”

Section: Introductionmentioning

confidence: 99%

“…Similar studies (on chip temperature in the cutting zone) have also been conducted for other grades of construction materials used in industry. For example, chip ignition may occur during milling titanium alloys [5][6][7][8] and nickel alloys. Although the machining conditions and machining parameter ranges are considerably different from those used for light alloys, the risk of chip ignition and resulting machining problems are very similar.…”

Section: Introductionmentioning

confidence: 99%

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Safety in Rough Milling of Magnesium Alloys Using Tools with Variable Cutting Edge Geometry

Zagórski¹

2023

Adv. Sci. Technol. Res. J.

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This paper presents the results of a study investigating the problem of safety in dry milling magnesium alloy AZ91D. Selected indicators of safe machining were analyzed, including time to ignition, ignition temperature, chip mass and morphology. Experiments were performed using carbide end mills with a variable edge helix angle. It was observed that magnesium alloys could be dry milled without the risk of chip ignition. The milling process conducted with the axial depth of cut a p set to 6 mm was found to be optimum (a great amount of leading fraction A was produced). Unfortunately, however, some machining conditions proved to be inductive to the formation of chip powder known as magnesium dust. For most cases, chips obtained using the tool with λ s 50° had higher unit mass than those obtained with λ s 20°. Metallographic images of chips confirmed the safe range of the machining parameters employed (no partial melting or burn marks were observed). Determined on a specially designed test stand outside of the machine tool, time to ignition can be an effective parameter for performing simplified chip ignition simulations.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Safety in Rough Milling of Magnesium Alloys Using Tools with Variable Cutting Edge Geometry

Zagórski¹

2023

Adv. Sci. Technol. Res. J.

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“…For structural components of Ti-6Al-4V, the material removal by machining can be up to 95% of the total workpiece mass [6]. The machining of workpieces made of titanium alloys inevitably involves corner machining and slot machining, which requires the uniform removal of material in the slot bottom, while at the same time requiring the quality of the machining in the slot sidewalls [7]. However, it is di cult to guarantee the quality of both the slot bottom and the slot sidewall with conventional machining methods [6,8].…”

Section: Introductionmentioning

confidence: 99%

Surface feature and material removal in ultrasonic vibration-assisted slot-milling of Ti–6Al–4 V titanium alloy

Chang

Duan

2022

Int J Adv Manuf Technol

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The continuous optimization of processing technology and evaluation methods is an important way to achieve high processing quality and processing e ciency for di cult-to-process materials. To solve the problem of frequent defects on the slot, the ultrasonic vibration assisted slot-milling (UVASM) technology was developed for processing titanium alloy. Simultaneously, comparative experiments were carried out between UVASM and conventional slot-milling (CSM), in terms of surface features of slot bottom and slot sidewall, cutting force, tool trajectory, chip morphology, and micro-hardness. The results show that uniform vibration micro-texture could signi cantly improve surface topography of slot bottom in UVASM, while numerous tool feed trajectories and observable machining defects detract from the surface quality in CSM. The UVASM can greatly reduce material spalling and edge breakage, thereby maintaining a smooth and regular edge pro le of slot sidewall. The tool tips trajectories of two machining methods are highly corresponding to the machining textures of the slot sidewall surface. There is a high-frequency and small-amplitude force uctuation signal on the axial force waveform in UVASM, which can reduce the instantaneous maximum milling force and milling force in the stable stage by 8.7% and 12.2%, respectively. The UVASM has a better chip breaking effect and surface anti-scratch effect and the UVASM can obtain higher surface micro-hardness and deeper plastic deformation layer than those of CSM. In summary, the multi-dimensional evaluation of slot processing status has been completed and the processing quality of the slot has been improved.

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Wear Behavior of Ceramic Tools in Longitudinal‐Torsional Ultrasonic Vibration‐Assisted Milling

Gu,

Niu,

Wei

et al. 2024

Adv Eng Mater

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Austenitic heat‐resistant cast steel is widely used in the manufacture of automotive exhaust manifolds and other occasions for its superior performance. Longitudinal‐torsional ultrasonic vibration‐assisted milling (LTUM) technology can effectively slow down tool wear and improve surface quality. In presented work, a longitudinal‐torsion ultrasonic milling method of heat‐resistant cast steel ceramic milling cutter is proposed, and the effects of the cutting performance and tool wear mechanisms of ordinary milling (OM) and ultrasonic longitudinal‐torsional milling of austenitic heat‐resistant cast steel with ceramic tools are investigated. The relationship between the milling force and the process parameters used are investigated, and the cutting surface quality and wear characteristics of ceramic tools are studied. The results show that compared to OM, LTUM has a lower cutting force, with an average milling force reduction of 34.65%; the surface quality of LTUM‐machined workpieces is higher, with a reduction in surface roughness of 68.98%. Ceramic tools in LTUM machining conditions than OM tool life increased by 140%. The main forms of wear of ceramic tools are spalling wear, abrasive wear, and adhesive wear.

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Research on breakage characteristics in side milling of titanium alloy with cemented carbide end mill

Cited by 7 publications

References 39 publications

Safety in Rough Milling of Magnesium Alloys Using Tools with Variable Cutting Edge Geometry

Safety in Rough Milling of Magnesium Alloys Using Tools with Variable Cutting Edge Geometry

Surface feature and material removal in ultrasonic vibration-assisted slot-milling of Ti–6Al–4 V titanium alloy

Wear Behavior of Ceramic Tools in Longitudinal‐Torsional Ultrasonic Vibration‐Assisted Milling

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