Artificial neural networks applied to prediction of surface roughness in dry drilling of some polymers

Tabacaru, V.

doi:10.1088/1757-899x/916/1/012117

Cited by 5 publications

(4 citation statements)

References 16 publications

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“…The authors of Tabacaru et al (2020) proposed a neural model that is able to predict surface roughness not only with regard to cutting parameters, but also to the type of material when drilling polymeric materials in dry conditions -high-density polyethylene (class HDPE 1000), polyamide (class PA6) and polyacetal (class POM -C). The final conclusion from this study can be stated that POM-C has the best machinability of all materials studied, the second-best being HDPE 1000 and PA6 [18].…”

Section: Machining Of Ertacetal C (Pom-c)mentioning

confidence: 99%

Evaluation of the Effect of Machining Technologies on the Surface Texture Analysis of Ertacetal C Polymer

Hrbáčková¹,

Sedlák²,

Chromjaková³

et al. 2023

Manufacturing Technology

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The surface created by machining significantly affects the service life and functional reliability of the component. As part of this study, four different chip machining technologies were evaluated on the surface texture of the polymer material Ertacetal C. The samples were processed by turning, milling, grinding and polishing technologies, 5 samples for each technology. Within the given technology, different cutting conditions were chosen to compare the effect of cutting conditions on the resulting surface roughness. The machined surfaces were comprehensively evaluated on the basis of 16 profile and surface roughness parameters due to the practical use of the tested material. Surface texture measurements were performed on a Talysurf CCI Lite device. A non-contact method using a coherence correlation interferometer was used for the measurement. The obtained data were evaluated using TalyMap Platinum software. Graphical documentation of the machined surfaces was made using an Olympus DSX500 opto-digital metallographic microscope. Machining

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Section: Machining Of Ertacetal C (Pom-c)mentioning

confidence: 99%

Evaluation of the Effect of Machining Technologies on the Surface Texture Analysis of Ertacetal C Polymer

Hrbáčková¹,

Sedlák²,

Chromjaková³

et al. 2023

Manufacturing Technology

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“…On the other hand, the increase in f and apse translates into an increase in the section of the chip; consequently, the volume of the chip increases, which contributes directly to the rise in temperature in the cutting zone. As polymer materials in general and our two materials studied in particular have very low thermal diffusion coefficients, the heat released by the cutting process is concentrated in the cutting zone and in turn contributes to the degradation of the surface condition obtained [6]. The graph of the main effects is presented in figure 2.…”

Section: Anova For Ramentioning

confidence: 99%

“…However, for the evolution of the specific cutting effort (Ks), (Vc) is more dominant. Tabacaru et al [6] conducted a study on predicting roughness during dry drilling of polymeric materials such as high-density polyethylene (HDPE 1000 grade), polyamide (PA-6 grade), and polyacetal (POM-C grade). Alateyah et al [7] performed an experimental and analytical study investigation on the influence of cutting parameters on the turning of two different polymers types: high-density polyethylene (HDPE) and un-reinforced polyamide (PA-6).…”

Section: Introductionmentioning

confidence: 99%

Comparative study of turning two engineering plastics (POM-C and PA-6) and optimisation using GA, SA, GRA and COPRAS with and without weighting (Entropie, critic, Swara, ROC)

Kaddeche

Boucherit²,

Belhadi³

et al. 2023

Preprint

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This paper focuses on a comparative study of the machinability of two semi-crystalline polymers (POM-C) and (PA-6), during dry turning operations. The aim is to experimentally examine the impact of cutting parameters, namely cutting speed, feed, and depth of cut on surface roughness, cutting force, cutting power, and material removal rate. A series of experiments according to a Taguchi L18 plan was implemented. The ANOVA analysis revealed that the type of material a substantial effect on surface roughness, followed by feed, whereas cutting force and cutting power are more affected by depth of cut. Linear regression models with interactions proved effective in predicting the studied responses, and single-objective optimization using SA and GA methods were applied to optimize each response. The GRA and COPRAS methods coupled with weighting methods CRITIC, ROC, SWARA, and Entropy are used for multi-objective optimization of the considered responses. The results showed that the combination of the COPRAS method with the SWARA method provides a better compromise, which is of crucial interest for researchers in the field of optimization in polymer material machining.

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“…Pre-draining coal seam gas with long boreholes is one of the effective measures to control coal seam gas in China [1][2][3][4]. At present, wet drilling and dry drilling are two of the methods mainly adopted for long boreholes in coal seams [5][6][7]. Wet drilling generates less dust powder but has problems with drilling jams, hole collapse, and sewage disposal [8,9].…”

Section: Introductionmentioning

confidence: 99%

Dust Control Technology in Dry Directional Drilling in Soft and Broken Coal Seams

Gao

2022

Energies

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High rate of dust generation and serious dust diffusion in dry directional drilling in soft and broken coal seams (SBCS) have long been critical problems in the mining process. To solve these problems, in this study, a dust hood was designed and applied to realize non-contact dust control in drilling holes. The optimal performance of the dust hood was achieved when different technical parameters, including the gap width between the dust hood and the drill pipe, the air-slot width of the sealing device, the slag discharge pressure, and the air curtain pressure were controlled at 2 mm, 0.2 mm, 0.3 MPa, and 0.5 MPa, respectively. As a result, the dust concentration was reduced from 540 mg/m³ to 15 mg/m³, with dust control efficiency reaching 97.2%. The in situ test results confirmed good dust control effects, as the dust control efficiency reached 98.3% after using the dust hood.

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Artificial neural networks applied to prediction of surface roughness in dry drilling of some polymers

Cited by 5 publications

References 16 publications

Evaluation of the Effect of Machining Technologies on the Surface Texture Analysis of Ertacetal C Polymer

Evaluation of the Effect of Machining Technologies on the Surface Texture Analysis of Ertacetal C Polymer

Comparative study of turning two engineering plastics (POM-C and PA-6) and optimisation using GA, SA, GRA and COPRAS with and without weighting (Entropie, critic, Swara, ROC)

Dust Control Technology in Dry Directional Drilling in Soft and Broken Coal Seams

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