Influence of machining parameters on part geometrical error in abrasive waterjet offset-mode turning

Zohoor, Mehdi; Zohourkari, Iman; Cacciatore, Francesco; Annoni, Massimiliano

doi:10.1177/0954405414548462

Cited by 14 publications

(16 citation statements)

References 17 publications

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“…Indeed, numerous examples of such applications can be found in the literature. [16][17][18][19][20][21][22][23] Zohoor et al 22 used waterjet technology in turning process and analysed geometrical error in turned parts. Karakurt et al 23 studied the effects of the AWJ operating variables on the kerf angle and the material properties in machining of rocks.…”

Section: Introductionmentioning

confidence: 99%

The use of high-frequency acoustic emission analysis for in-process assessment of the surface quality of aluminium alloy 5251 in abrasive waterjet machining

Sutowski

Sutowska

Kapłonek

2017

Proceedings of the Institution of Mechanical Engineers, Part B:

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In this article, the use of acoustic emission signal analysis for in-process assessment of the surface quality in abrasive waterjet machining is presented. The authors carried out an analysis of the influence of the cutting head traverse speed (considered in this case as the performance measurement) on the flatness, waviness and roughness of surfaces made of aluminium alloy 5251 after cutting process, as well as the influence of changing the quality factor on values of selected descriptors of the emitted high-frequency acoustic emission signal processed in the frequency domain. This was a new approach, different from the norm, in which an acoustic emission signal is usually studied for low frequencies. The obtained results confirmed the clear influence of machining conditions on the geometric structure of the obtained cuts and the registered values of the emitted stress waves. This influence can be accurately determined by the use of the high-frequency acoustic emission signal analysis being proposed. Additionally, statistical dependence models developed between the given process quality indicator and the registered selected acoustic emission signal parameters in the frequency domain allowed for the prediction of the surface texture of the obtained cuts on the basis of the acoustic emission signal emitted during the machining process.

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Section: Introductionmentioning

confidence: 99%

The use of high-frequency acoustic emission analysis for in-process assessment of the surface quality of aluminium alloy 5251 in abrasive waterjet machining

Sutowski

Sutowska

Kapłonek

2017

Proceedings of the Institution of Mechanical Engineers, Part B:

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“…30 The inlet velocity directly affects the distribution of the turbulent flow energy, velocity, and dynamic pressure of the abrasive flow on the workpiece surface, which would affect the machining effect. 31 Compared with the conventional abrasive flow machining, the soft abrasive flow has a lower viscosity, and the tendency of the abrasive particles to roll back in the flow channel is greater. Therefore, the processing temperature and inlet velocity could be further studied and expanded to improve the applicability of the prediction model.…”

Section: Resultsmentioning

confidence: 99%

Experimental study of coverage constraint abrasive flow machining of titanium alloy artificial joint surface

Zhang

Huang

Chen

et al. 2019

Proceedings of the Institution of Mechanical Engineers, Part B:

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In order to study the machining mechanism and process of abrasive flow machining for the titanium alloy artificial joint surface, the abrasive flow machining experimental platform and the curved surface profiling flow channel were established for the machining. The influence of various process parameters (abrasive particle size, abrasive particle concentration, and processing time) and interaction factors on surface roughness and surface micro-topography of the workpiece was quantitatively evaluated through response surface analysis, and a surface roughness prediction model was established. The experimental results show that coverage constraint abrasive flow machining can significantly improve the surface quality of the titanium alloy artificial joint surface, thereby improving the wear resistance and service life of the artificial joint. Using abrasive flow machining with a smaller abrasive particle size and a larger concentration can obtain smaller surface roughness. Under the experimental conditions, the influence of process parameters on the surface roughness is in descending order of processing time, abrasive particle concentration, and abrasive particle size. And the interaction of processing time and abrasive particle size is more effective during processing. The research results can provide the basis for optimizing the flow channel structure for the abrasive flow machining of the titanium alloy artificial joint surface and have a certain guiding significance on the process optimization.

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“…Using a suitable abrasive during disintegration can be advantageous when processing a specific material, from a technological and economic point of view. Selecting a 13 Olivine Glass Surface roughness, Surface waviness p, v, z", Ra, Wa # n, m a ", Ra, Wa# Kartal et al 14 Barton Garnet Aluminium 6082 T6 Surface roughness n, m a ", Ra# v, z", Ra" Cárach et al 15 Barton Garnet Monel K500 Surface roughness, MRR v", Ra" n, m a ", Ra# v ", MRR %# m a ", MRR %" Kartal et al 16 Barton Garnet Low-density polyethene Optimisation of surface roughness and waviness n, m a ", Ra # v", Ra" n, m a ", MRR" v", MRR# Srivastava et al 17 Australian 18 Barton Garnet AlSi17Cu4Mg Comparison of AWJT with conventional turning n", Ra# Zohoor et al 19 Australian Garnet Aluminium alloy AA2011-T4 Geometrical accuracy a p , p", GE% # v, m a #, GE% # a p , m a #, GE% # p, m a ", GE% # a p #, v", GE% # suitable abrasive type for a targeted material (particularly in the case of special materials) would bring economic advantages, as well as quantitative and qualitative benefits. 21 Moreover, the workpiece rotation direction influences the material removal process.…”

Section: Introductionmentioning

confidence: 99%

Effect of rotation direction, traverse speed, and abrasive type during the hydroabrasive disintegration of a rotating Ti6Al4V workpiece

Hlaváček

Hloch

Nag

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part B:

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In this study, a new methodology is considered for determining the rotational senses (clockwise or anti-clockwise) of a workpiece during the hydroabrasive disintegration of rotating samples. The rotational directions are taken with respect to the position of the abrasive jet, that is, keeping it on the right side of the rotating workpiece when viewed from the free end in the cartesian coordinate system. Measurements were carried out for diameter deviation, material removal rate and surface roughness as a response to machining parameters such as traverse speed, workpiece rotation direction and abrasive grain. Final diameter of the workpiece (10.28–14.12 mm), material removal rate (1154–3936 mm3/min) and surface roughness (6.65–25.43 µm) values increase with increasing value of traverse speed (5–25 mm/min) using anti-clockwise rotation with Australian garnet abrasive grains. ANOVA analysis of the responses shows that traverse speed ( p = 0.000) is a statistically significant parameter for predicting all the machining responses. Abrasive type and rotational direction were statistically significant for determining diameter deviation ( p = 0.017, 0.006) and material removal rate ( p = 0.000, 0.000) but insignificant for surface roughness ( p = 0.373, 0.367). Scanning electron microscopy provided information on the surface morphology, depicting the characteristics of the disintegrated surface. Disintegrated features, like peak and valley formations, craters, holes, cutting traces and embedded abrasive particles on the surface were observed.

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Influence of machining parameters on part geometrical error in abrasive waterjet offset-mode turning

Cited by 14 publications

References 17 publications

The use of high-frequency acoustic emission analysis for in-process assessment of the surface quality of aluminium alloy 5251 in abrasive waterjet machining

The use of high-frequency acoustic emission analysis for in-process assessment of the surface quality of aluminium alloy 5251 in abrasive waterjet machining

Experimental study of coverage constraint abrasive flow machining of titanium alloy artificial joint surface

Effect of rotation direction, traverse speed, and abrasive type during the hydroabrasive disintegration of a rotating Ti6Al4V workpiece

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