Your search keyword '"Advanced process"' showing total 13 results

1. Future perspectives and research trends in advanced chemo-mechanical magneto-rheological finishing for enhanced surface quality

Author

Naji, Fadia Ahmed A., Murtaza, Qasim, Khaled, Narjes Ibrahem, and Nasr, Mustafa M.

Published

2025

2. Universal submerged arc welding (USAW): high weaving amplitudes as a new possibilities to SAW process

Author

da Cunha, Tiago Vieira, Rode, Ana Clara, and Voigt, Anna Louise

Published

2024

3. Parameter Identification of the Fractional-Order Mathematical Model for Convective Mass Transfer in a Porous Medium

Author

Ivan Pavlenko, Marek Ochowiak, Sylwia Włodarczak, Andżelika Krupińska, and Magdalena Matuszak

Subjects

advanced process, Riemann–Liouville fractional derivative, Mittag-Leffler function, process innovation, Chemical technology, TP1-1185, Chemical engineering, TP155-156

Abstract

Fractional calculus is an essential tool in studying new phenomena in hydromechanics and heat and mass transfer, particularly anomalous hydromechanical advection–dispersion considering the fractal nature of the porous medium. They are valuable in solving the urgent problem of convective mass transfer in a porous medium (e.g., membranes, filters, nozzles, convective coolers, vibrational prillers, and so on). Its solution allows for improving chemical engineering and technology workflows, refining process models for obtaining porous granular materials, realizing the convective cooling of granular and grain materials, and ensuring the corresponding apparatuses’ environmental safety. The article aims to develop a reliable convective mass transfer model for a porous medium and proposes a practical approach for its parameter identification. As a result, a general scientific and methodological approach to parameter identification of the fractional convective mass transfer model in a porous medium was proposed based on available experimental data. It mainly used Riemann–Liouville fractional time and coordinate derivatives. The comprehensive application of the Laplace obtained the corresponding general solution transform with respect to time and a coordinate, the Mittag-Leffler function, and specialized functions. Different partial solutions in various application case studies proved this solution. Moreover, the algorithm for practically implementing the developed approach was proposed to evaluate parameters for the considered model by evaluation data. It was reduced to the two-parameter model and justified by the available experimental data.

Published

2023

4. Effect of milling process on particle size, morphology and magnetization in non-stoichiometric Fe2O3-MnO2.

Author

P. Vera-Serna, M. A. Martínez-Sánchez, Martin Kusy, A. M. Bolarín-Miró, F. N. Tenorio-González, and J. A. Juanico-Loran

Subjects

advanced process, materials, manganese, milling, crystallite, mechanochemical, Mechanical engineering and machinery, TJ1-1570, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

High-energy milling process on ceramic material was analyzed, it process generate modifications on morphology and particle size, the process showed the last one relation with the crystallite size, about of structural analysis Rietveld refinement let identify anisotropy with the variations on crystalline planes and deformations occasioned by milling process, the particle size decrease with the process, similar tendency was observed on the images obtained by Scanning Electronic Microscopy, an result in this study was the variation on magnetization without chemical reaction under non-stoichiometric conditions and the agglomerates sizes observed on samples it is by process.

Published

2019

5. Using set-based design for developing a 3D metal forming process.

Author

Schjøtt-Pedersen, Nikolai, Welo, Torgeir, Ringen, Geir, and Raknes, Christian A.

Abstract

Industry is continuously searching for solutions to increase flexibility and quality in parallel with cost reductions. This paper presents a case study of using set-based design method to develop a gripping system for an innovative three-dimensional bending and forming technology of extruded aluminium profiles. Traditionally, profiles are formed by mandrel-based stretch-bending to improve cross-sectional stability and spring-back, sometimes combined with subsequent calibration e.g. by hydroforming. However, in the highly competitive automotive industry, where light-weighting is high on the agenda, design and process flexibility, tooling cost and dimensional accuracy are important factors to increase value at a reasonable cost. In this paper, a set-based concurrent engineering approach is used to identify, evaluate and prioritize gripping methods to enable three-dimensional bending meeting automotive requirements for dimensional accuracy. The results demonstrate a multitude of options, providing trade-offs between flexibility and function. Further work will be to build a physical demonstrator to validate output from the set-based method used to systematically narrow down the solution space. [ABSTRACT FROM AUTHOR]

Published

2019

6. Parameter Identification of the Fractional-Order Mathematical Model for Convective Mass Transfer in a Porous Medium.

Author

Pavlenko I, Ochowiak M, Włodarczak S, Krupińska A, and Matuszak M

Abstract

Fractional calculus is an essential tool in studying new phenomena in hydromechanics and heat and mass transfer, particularly anomalous hydromechanical advection-dispersion considering the fractal nature of the porous medium. They are valuable in solving the urgent problem of convective mass transfer in a porous medium (e.g., membranes, filters, nozzles, convective coolers, vibrational prillers, and so on). Its solution allows for improving chemical engineering and technology workflows, refining process models for obtaining porous granular materials, realizing the convective cooling of granular and grain materials, and ensuring the corresponding apparatuses' environmental safety. The article aims to develop a reliable convective mass transfer model for a porous medium and proposes a practical approach for its parameter identification. As a result, a general scientific and methodological approach to parameter identification of the fractional convective mass transfer model in a porous medium was proposed based on available experimental data. It mainly used Riemann-Liouville fractional time and coordinate derivatives. The comprehensive application of the Laplace obtained the corresponding general solution transform with respect to time and a coordinate, the Mittag-Leffler function, and specialized functions. Different partial solutions in various application case studies proved this solution. Moreover, the algorithm for practically implementing the developed approach was proposed to evaluate parameters for the considered model by evaluation data. It was reduced to the two-parameter model and justified by the available experimental data.

Published

2023

7. Identification and Analysis of Advanced Manufacturing Processes Susceptible of Generating New and Emerging Occupational Risks.

Author

Brocal, F. and Sebastián, M.A.

Subjects

ADVANCED planning & scheduling, MANUFACTURING processes, EMERGING occupations, MATHEMATICAL variables, POTENTIAL theory (Physics)

Abstract

Advanced manufacturing processes (AMP) are characterized by innovative variables of a technological and organizational nature which tend to change with workplaces, processes and conventional work practices, and can generate, as well as traditional occupational risks, other so-called new and emerging risks (NER). The main innovative aspect of this paper is that such risks have been analyzed applying recent specific models in the field, with the overall aim of identifying susceptible AMP of generating NER. From the results the main apparent conclusion is that there is NER of a general nature susceptible in AMP but it is not possible, in most cases, to establish direct links with specific AMP. However, it has been possible to identify among those NER a set of technological aspects with which can be established a starting point to facilitate the identification of AMP that are potential generators of NER. [ABSTRACT FROM AUTHOR]

Published

2015

8. A membrane-integrated advanced scheme for treatment of industrial wastewater: Dynamic modeling towards scale up.

Author

Kumar, Ramesh and Pal, Parimal

Subjects

*SEWAGE purification, *MATHEMATICAL models, *ARTIFICIAL membranes, *WATER treatment plants, *WASTE products & the environment, *WASTE recycling, *PREDICTION theory

Abstract

Highlights: [•] Mathematical model developed for an advanced integrated water treatment plant. [•] Highly integrated scheme is novel in ensuring by-product recovery and water reuse. [•] Model successfully predicted plant performance. [•] Study will facilitate industrial scale up of this new and advanced scheme. [Copyright &y& Elsevier]

Published

2013

9. Discoloration and detoxicification of a Congo red dye solution by means of ozone treatment for a possible water reuse

Author

Khadhraoui, M., Trabelsi, H., Ksibi, M., Bouguerra, S., and Elleuch, B.

Subjects

*COLOR removal in water purification, *CONGO red (Staining dye), *WATER reuse, *PHYTOTOXICITY, *BIOMINERALIZATION, *CHEMICAL oxygen demand, *ENVIRONMENTAL protection, *OZONE

Abstract

Abstract: The objective of this study was to investigate the degradation and mineralization of an azo-dye, the Congo red, in aqueous solutions using ozone. Phytotoxicity and the inhibitory effects on the microbial activity of the raw and the ozonated solutions were also carried out with the aim of water reuse and environment protection. Decolorization of the aqueous solutions, disappearance of the parent compound, chemical oxygen demand (COD) and total organic carbon (TOC) removal were the main parameters monitored in this study. To control the mineralization of the Congo red, pH of the ozonated solution and heteroatoms released from the mother molecule such NH4 +, NO3 − and SO4 2− were determined. It was concluded that ozone by itself is strong enough to decolorize these aqueous solutions in the early stage of the oxidation process. Nonetheless, efficient mineralization had not been achieved. Significant drops in COD (54%) were registered. The extent of TOC removal was about 32%. Sulfur heteroatom was totally oxidized to SO4 2− ions while the central –N azo ring was partially converted to NH4 + and NO3 −. Results of the kinetic studies showed that ozonation of the selected molecule was a pseudo-first-order reaction with respect to dye concentration. The obtained results also demonstrate that ozone process reduced the phytotoxicity of the raw solution and enhanced the biodegradability of the treated azo-dyes-wastewater. Hence, this show that ozone remains one of the effective technologies for the discoloration and the detoxification of organic dyes in wastewater. [Copyright &y& Elsevier]

Published

2009

10. Advanced process design for re-contouring using a time-domain dynamic material removal simulation

Author

O. Pape, Berend Denkena, A. Mücke, and Thilo Grove

Subjects

0209 industrial biotechnology, Ternary alloys, Topography, Welds, Material removal, Process parameters, Computer science, Dewey Decimal Classification::600 | Technik::670 | Industrielle und handwerkliche Fertigung, Process design, 02 engineering and technology, Welding, 010501 environmental sciences, 01 natural sciences, law.invention, Surface topography, Process strategies, Ball milling, Time-domain dynamics, 020901 industrial engineering & automation, law, ddc:670, Titanium alloys, Time domain, Process engineering, Vanadium alloys, Milling, Konferenzschrift, 0105 earth and related environmental sciences, General Environmental Science, Titanium, Contouring, business.industry, End milling, Process stability, Dewey Decimal Classification::600 | Technik, Aluminum alloys, High surface, Machined surface, Machined surface topography, General Earth and Planetary Sciences, Advanced process, business, ddc:600, Milling (machining), Simulation

Abstract

The repair of components often requires the removal of excess weld material. This removal is considered as re-contouring. Re-contouring processes have to be designed individually for each case of damage to fulfil the high quality requirements. Therefore, a prognosis of the machined surface topography is crucial. The material removal simulation introduced in this paper allows the prediction of process stability and surface topography for 5-axis ball end milling including dynamic effects. Different process strategies for re-contouring of Ti-6Al-4V welds are examined. It is shown, that selecting suitable process parameters can lead to high surface quality while maintaining productivity. © 2019 The Author(s).

Published

2019

11. Optimization of complex cutting tools using a multi-dexel based material removal simulation

Author

O. Pape, Thilo Grove, and Berend Denkena

Subjects

Optimization, 0209 industrial biotechnology, Turning, Discretization, Material removal, Computer science, Dewey Decimal Classification::600 | Technik::670 | Industrielle und handwerkliche Fertigung, Mechanical engineering, Geometry, 02 engineering and technology, Serrated end mills, 010501 environmental sciences, 01 natural sciences, Dexel, Indexable inserts, 020901 industrial engineering & automation, Position (vector), ddc:670, Machining centers, Representation (mathematics), Turning operations, Konferenzschrift, 0105 earth and related environmental sciences, General Environmental Science, Milling cutters, Rake, Process (computing), Cutting tools, Dewey Decimal Classification::600 | Technik, Discretizations, Face (geometry), General Earth and Planetary Sciences, Geometric modeling, Advanced process, Simulaton, ddc:600, Milling (machining)

Abstract

Multi-dexel based material removal simulations provide a fast and flexible way to compute process forces and tool deflections for milling and turning operations. This allows an advanced process planning including detection of collisions for complex toolpaths. However, using dexel simulations for designing cutting tools has rarely been investigated. Especially the position of individual cutting edges is not considered, because current approaches only subtract the sweep volume of the tool envelop instead of the rake face. This paper presents a new method to design cutting tools using material removal simulations and a detailed tool geometry representation. The discretization of the tool allows an efficient calculation of the engagement conditions of individual cutting edges. The method is used to optimize novel porcupine milling cutters with round indexeble inserts, which produces a geometry analogous to serrated end mills. Based on the calculated forces, the positions of individual indexable inserts are adjusted to minimize the maximum radial force. An optimum has been found that reduces radial force by 12% compared to conventional porcupine milling cutters with squared inserts. © 2019 The Authors. Published by Elsevier B.V. Peer-review under responsibility of the scientific committee of The 17th CIRP Conference on Modelling of Machining Operations

Published

2019

12. Approaches for improving cutting processes and machine too in re-contouring

Author

Denkena, Berend, Boess, V., Nespor, D., Rust, F., and Floeter, F.

Subjects

Machine tool, Aircraft engine blades, Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, Cutting tools, Geometrical accuracy, Dewey Decimal Classification::600 | Technik, Machined surface, Re-contouring, Process simulation, Aircraft engines, Fighter aircraft, Advanced process, ddc:620, Machine tool technology, ddc:600, Repair, Konferenzschrift, Experimental investigations

Abstract

Re-contouring in the repair process of aircraft engine blades and vanes is a crucial task. Highest demands are made on the geometrical accuracy as well as on the machined surface of the part. Complexity rises even more due to the unique part characteristic originating from the operation and repair history. This requires well-designed processes and machine tool technologies. In this paper, approaches for coping with these challenges and improving the re-contouring process are described and discussed. This includes an advanced process simulation with its capabilities to accurately depict different material areas and predict process forces. Beyond, experimental investigations on workpiece-tooldeflection are presented. Finally, a machine tool prototype with a novel electromagnetic guiding system is introduced and the benefits of this technology in the field of repair are outlined. DFG/CRC/871

Published

2014

13. Identification and Analysis of Advanced Manufacturing Processes Susceptible of Generating New and Emerging Occupational Risks

Author

Francisco Brocal and Miguel A. Sebastián

Subjects

Engineering, Occupational risk, business.industry, advanced process, risk model, General Medicine, Risk model, Identification (information), manufacturing, Risk analysis (engineering), Forensic engineering, occupational risk, Advanced manufacturing, Set (psychology), business, Engineering(all), new and emerging risk

Abstract

Advanced manufacturing processes (AMP) are characterized by innovative variables of a technological and organizational nature which tend to change with workplaces, processes and conventional work practices, and can generate, as well as traditional occupational risks, other so-called new and emerging risks (NER). The main innovative aspect of this paper is that such risks have been analyzed applying recent specific models in the field, with the overall aim of identifying susceptible AMP of generating NER. From the results the main apparent conclusion is that there is NER of a general nature susceptible in AMP but it is not possible, in most cases, to establish direct links with specific AMP. However, it has been possible to identify among those NER a set of technological aspects with which can be established a starting point to facilitate the identification of AMP that are potential generators of NER.