Your search keyword '"shear spinning"' showing total 35 results

1. Shear spinning: numerical modelling and process mechanics.

Author

Uzun, Mustafa Can and Music, Omer

Subjects

*SHEAR (Mechanics), *FRICTION materials, *KINEMATICS, *GEOMETRY, *LITERATURE

Abstract

Shear spinning is a bulk forming technique used to produce hollow, rotationally symmetric parts. Although the shear spinning process has been used for the last six decades in numerous industries, in the literature, the understanding of the mechanics of the process is limited. This study provides insight into process mechanics using physical trials and numerical models. Modelling the process is challenging because of the incremental nature of the process; existing numerical models in the literature suffer from lengthy computational times and simplifications. In this study, two numerical models with different approaches to the kinematics of the spinning process are modelled with input from tests to determine friction coefficient and material properties. Then they are validated against physical trials by comparing both part geometry and strain distribution. Validated numerical models are then employed to investigate the fundamental aspects of shear spinning mechanics; evolution of strains, roller forces and part geometry in a broad range of process conditions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Modelling and Mechanics of Shear Spinning

Author

Uzun, Mustafa Can, Music, Omer, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Mocellin, Katia, editor, Bouchard, Pierre-Olivier, editor, Bigot, Régis, editor, and Balan, Tudor, editor

Published

2024

3. Process design and microstructure-property evolution during shear spinning of Ti2AlNb-based alloy.

Author

Wang, Sibing, Xu, Wenchen, Shao, Bin, Yang, Guoping, Zong, Yingying, Sun, Wanting, Yang, Zhongze, and Shan, Debin

Subjects

ALLOYS, YIELD stress, HYPEREUTECTIC alloys, WORKPIECES

Abstract

• The conical Ti 2 AlNb workpiece was successfully formed by two passes shear spinning with inter-pass heat treatment. • An essential inter-pass heat treatment scheme (960 °C/2 h + 850 °C/12 h) for increasing the spinnability of multi-pass spinning was given out. • An optimal post-spinning heat treatment scheme (960 °C/2 h) was achieved to improve both the room-temperature and high-temperature mechanical properties for service requirement. Rotationally symmetric workpieces of Ti 2 AlNb-based alloys have great potential for high-temperature service condition in aviation industry, while the poor workability limits their application until now. In this study, shear spinning and heat treatment were first conducted to investigate the corresponding microstructure evolution and mechanical properties of Ti 2 AlNb conical workpieces. The microstructure of the 1st and 2nd pass spun workpieces (SP1 and SP2) mainly consisted of B2 + retained α 2 phases. After two passes spinning, the B2 phase texture changed from <111>//ND of as-received alloy to be <001>//ND. The ultimate tensile stress (UTS) of SP1 and SP2 was increased to 1163 MPa and 932 MPa, respectively, compared with 782 MPa of as-received alloy at 650 °C. Also, the yield stress anomaly (YSA) occurred in SP1 and SP2 because {110}<111> and {112}<111> cross slip systems of B2 phase were difficult to slip at or below room temperature (RT), but they became active at 650 °C and above. As an essential step for increasing the spinnability of multi-pass spinning process of the Ti 2 AlNb alloy, the H3 heat treatment scheme, i.e. 960 °C/2 h+ 850 °C/12 h, was carried out between two successive passes to increase the hot workability, by which the ductility of the heat treated as-spun workpieces with the microstructure of B2 + primary O + acicular secondary O + high amount spheroidized α 2 phases reached 72.1% at 900 °C. After being subject to the H1 heat treatment scheme, i.e. 960 °C-2 h, the spun workpieces with the microstructure of B2 + primary O + intergranular primary α 2 phases achieved an optimized comprehensive mechanical properties both at room temperature and 650 °C, which should be chosen as the post-spinning heat treatment process for the service requirement. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

4. Shear Spinning

Author

Chatti, Sami, editor, Laperrière, Luc, editor, Reinhart, Gunther, editor, and Tolio, Tullio, editor

Published

2019

5. Investigation of microstructure and mechanical properties of copper shell produced by shear spinning in different rotation directions

Author

Seyed Mohammad Javad Hoseini, Hamid Ghayour, Ali Salemi Golazani, Masoud Kasiri Asgarani, and Iman Ebrahimzadeh

Subjects

Shear spinning, mechanical properties, EBSD, texture, anisotropy, strain paths, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

In this study, the effect of alteration in the direction of forming during the shear spinning of C11000 copper metal on mechanical properties, microstructure, texture, and anisotropy was investigated. Shear spinning causes the grains stretching along the axial direction besides increasing the grain length in the circumferential direction. Strain-path change in the shear spinning specimens has somewhat resulted in finer grains, more grain refinement, and a higher percentage of high-angle boundaries. More change of strain direction in the shear spinning specimens resulted in approximately 9% to 11% reduction in strength, from 1% to 9% decrease in hardness, and increased elongation from 7% to 37% more than in the specimen without path change. Shear spinning specimens in different paths had different orientations and texture intensities. In the specimen without strain-path change, most of the texture is related to {123}〈412〉 orientation and copper texture with {112}〈111〉 orientation. In the shear spinning specimens in other paths, textures with {001}〈100〉, {011}〈011〉, and {211}〈011〉 orientations and brass texture with {110}〈112〉 orientation were strengthened. Due to the change in texture and mechanical properties, the strain-path change in the shear spinning process reduced the anisotropy in the C11000 copper metal.

Published

2021

6. Incremental Forming

Author

Emmens, Wilko C. and Emmens, Wilko C.

Published

2011

7. Microstructure and Mechanical Properties of Mg–3Al–Zn Magnesium Alloy Sheet by Hot Shear Spinning

Author

Wang, Fenghua, Su, Peng, Qin, Linxin, Dong, Shuai, Li, Yunliang, and Dong, Jie

Published

2020

8. An investigation into forming internally-spline sleeves by ball spinning.

Author

Abd-Eltwab, Ayman A., El-Abden, S.Z., Ahmed, Khaled I.E., El-Sheikh, M.N., and Abdel-Magied, Ragab K.

Subjects

*SPLINE theory, *POWER transmission, *INDUSTRIAL applications, *DEFORMATIONS (Mechanics), *MECHANICAL loads

Abstract

Internally-spline sleeves have an increased attention since these parts serve as power transmission means in many industrial applications. This research presents using ball spinning process for producing internally-spline sleeves. The process was investigated experimentally and theoretically. The experimentally investigated variables were: the rotational speed of the mandrel 86, 604, 1146 and 1747 rpm; the axial feed, 0.3, 0.6, 0.91 and 1.21 mm/ rev; the cross in-feed 1.5, 2, 2.5, 3 and 3.5 mm. An analytical expression was derived to predict the deformation loads. The theoretically investigated variables were: the mentioned axial feed and cross in-feed at 604 mandrel rotational speed; the initial tube thickness of 3.5 to 8 mm with step 0.5 mm; the ball diameters of 16 to 32 mm with step 4 mm; the number of ribs was 4, 5, 6, 8, and 10. The effects of these variables on the forming load and the quality of formed sleeves were investigated. The results showed that, these variables affecting the forming load and product quality. The optimum values of these variables were determined. The theoretical results have been found to be in close agreement with experiment. [ABSTRACT FROM AUTHOR]

Published

2017

9. Investigation of forming accuracy in mandrel-free hot-spinning.

Author

Imamura, Yoshihide, Ikawa, Ken, Sakane, Yuto, Iwasaki, Hayato, and Hirakawa, Takeo

Subjects

METALWORK, ARBORS & mandrels, STRAINS & stresses (Mechanics), DEFORMATIONS (Mechanics), TEMPERATURE distribution

Abstract

A new mandrel-free hot-spinning was developed as a new near-net-shape forming technology. Hot-spinning provides a high flexibility, because of no mandrel. This paper investigated the material properties and dimensional accuracy of mandrel-free hot-spun Ti-6Al-4V alloy conical product with a wall angle of 30°at 900°C. It was found that the deformation in the process roughly followed the sine law. It is confirmed that shape control is possible by adjusting the roller path. Product thickness tended to be thicker than the thickness predicted by the sine law and the flange part is tilted in the direction of forming progress when the initial thickness was large. It is presumed that a certain amount of bending deformation takes place in the process and strain distribution in the thickness direction was caused during forming. For the purpose of improving forming accuracy in the mandrel-free hot-spinning, reducing the strain distribution in the thickness direction, including optimization of the temperature distribution in the thickness, and optimization of the roller feed ratio, may be most effective factors. [ABSTRACT FROM AUTHOR]

Published

2017

10. A research on thickness distribution of oblique cone in dieless shear spinning.

Author

Han, Z., Fan, Z., Xiao, Y., and Jia, Z.

Subjects

*SPINNING machinery, *THICKNESS measurement, *DISCRETIZATION methods, *HYDRAULIC control systems, *MECHANICAL properties of metals

Abstract

In order to shorten the preparation period, dieless shear spinning is widely used in various industrial fields with advantage of economy of materials and easy control. Controlling roller path is one of the main methods for changing thickness distribution. A new discretization method is proposed by theoretical derivation in dieless shear spinning. It will generate a virtual axis by inclining the flange of the workpiece. And, the roller path is derived for spinning machine combined with the sine law in shear spinning. The derived path should be applied after the range of forming reaches the certain height. The thickness distribution of formed workpiece is basically in agreement with the theoretical value. It also illustrates that roller nose radius and axial feed will influence the surface quality. [ABSTRACT FROM AUTHOR]

Published

2017

11. Some aspects of microstructure and properties of Al-Mg alloys after shear spinning and cold rolling

Author

Radović Ljubica M., Nikačević Milutin Z., and Jordović Branka M.

Subjects

Al-Mg alloys, shear spinning, cold rolling, mechanical properties, microstructure, dynamic recovery, Chemical technology, TP1-1185

Abstract

Three commercial Al-Mg alloys containing 3 wt.% to 6 wt.% of Mg (AlMg3, AlMg4.5Mn and AlMg6Mn) were subjected to different forming processes: shear spinning and cold rolling. The effect of Mg content and reduction in thickness on the tensile properties and microstructure evolution of Al-Mg alloys were studied. Both optical (OM) and transmission electron microscopy (TEM) were used for the microstructure characterization. The results show that the addition of Mg in these alloys increases the yield strength (YS) and ultimate tensile strength (UTS) in both cold rolled and spun specimens. The strength of all Al-Mg alloys after shear spinning was lower compared to the strength after cold rolling for the same strain. This effect was attributed to the occurrence of dynamic recovery during shear spinning and confirmed by transmission electron microscopy. [Projekat Ministarstva nauke Republike Srbije, br. TR-34018]

Published

2013

12. Mechanism of grain refinement of aluminium alloy in shear spinning under different deviation ratios.

Author

Zhan, Mei, Wang, Xianxian, and Long, Hui

Subjects

*GRAIN refinement, *ALUMINUM alloys, *SHEAR (Mechanics), *MICROSTRUCTURE, *THICKNESS measurement

Abstract

To investigate the grain refinement and its mechanism in shear spinning, microstructures of shear spun parts made by aluminium alloy under different deformation conditions, induced by different shear spinning deviation ratios, are studied. The results show that, after shear spinning, the microstructure is distributed symmetrically about a zone in sheet thickness defined as the neutral zone which is located between the inner surface and the middle plane of spun sheet thickness. Various deviation ratios in shear spinning can lead to grain refinement in different regions along thickness direction of the spun part. The microstructure characteristics indicate that the mechanism of grain refinement is due to the formation of deformation bands (DBs). It is observed that in DBs, parallel geometrically necessary boundaries (GNBs) formed by a zero deviation ratio and crossed GNBs formed by positive and negative deviation ratios are due to the different stress states induced by various deviation ratios in shear spinning. Due to the influence of grain refinement, micro hardness increases with the decreasing of the deviation ratio. The average value is increased by 16.04% under a negative deviation ratio compared to the initial micro hardness of the sheet. [ABSTRACT FROM AUTHOR]

Published

2016

13. Study of shear spinning processing

Author

Coyoy Ixquiac, Pablo Saúl, Universitat Politècnica de Catalunya. Departament de Ciència i Enginyeria de Materials, Elizalde Huitrón, Sergio Alberto, and Cabrera Marrero, José M.

Subjects

shear spinning, correlation hardness and effective strain, Steel, Incremental forming, Acer, forming limits, Enginyeria dels materials [Àrees temàtiques de la UPC]

Abstract

Los procesos de conformado incremental simétricos tales como trefilado, laminación cilíndrica, laminación cónica, repulsado, encolado, forjado rotatorio, conformado por flujo de llantas, etc.,tienen una amplia gama de aplicaciones en industrias tales como: automotriz, aeroespacial, ventilación, iluminación, tuberías de petróleo y gas, proceso de materiales a granel, productos químicos y médicos, etc. La mayoría de estos procesos se rigen por un enfoque de prueba y error y es necesario trabajadores altamente calificados. Como intento de superar esto y tener un mejor conocimiento del proceso introduciendo asimismo criterios científico surge este trabajo. Este proyecto se centra en la “laminación cónica incremental” del acero DC-04, un acero muy utilizado por su alta ductilidad. Para ello se ha utilizado una máquina de laminación incremental a escala de laboratorio. Los objetivos específicos han sido: a) determinar loslímites de conformado basado en el ángulo de ataque del rodillo (RAA por sus siglas en inglés), b) correlacionar la deformación plástica con la dureza de piezas producidas con éxito y c) diseñar e imprimir en 3D un prototipo para medir tensiones residuales de muestras laminadas. Para determinar los límites de conformado se ejecutaron varias pruebas de laminación cónica y se construyeron mapas de procesamiento a partir de ellas. Se han identificado zonas de formación seguras que conducen a una combinación óptima de parámetros: ángulo del mandril y velocidad de avance, que dan como resultado piezas laminadas con éxito. Además, se encontró que las zonas de formación seguras son óptimas cuando se implementa un RAA perpendicular a la superficie de los mandriles. Por otro lado, para correlacionar la deformación plástica con la dureza, se realizaron ensayos de tracción y medición de microdureza y se obtuvo una relación lineal, descrita por: 𝐻���𝑉��� = 63.5 𝜀���𝑒���𝑓���𝑓��� + 135.4. Finalmente, los prototipos para medir tensiones residuales fueron diseñados en SolidWorks e impresos por la impresora “Ender 3”. Después de varias pruebas, se obtuvieron con éxito tres prototipos para las muestras laminadas con mandriles de 15 °, 13 ° y 11 °. Els processos de conformat incremental simètrics com ara trefilat, laminació cilíndrica, laminació cónica, repusatge, retallada, encolat, forjat rotatori, conformat per flux de llantes, etc., tenen una àmplia gamma d'aplicacions en indústries com ara: automotriu, aeroespacial, ventilació, il·luminació, canonades de petroli i gas, procés de materials a granel, productes químics i mediqes, etc. La majoria d'aquests processos es regeixen per un enfocament de prova i error i és necessari treballadors altament qualificats. Com a intent de superar això i tenir un millor coneixement del procés incloent-hi criterir científics es que s’ha plantejat aquest treball. Aquest projecte se centra en la “laminació cònica incremental” de l'acer DC-04, un acer molt utilitzat per la seva alta ductilitat. Per a això s'ha utilitzat una màquina de laminació incremental a escala de laboratori. Els objectius específics han estat: a) determinar els límits de conformat basat en l'angle d'atac de la rulina (RAA per les seves sigles en anglès), b) correlacionar la deformació plàstica amb la duresa de peces produïdes amb èxit i c) dissenyar i imprimir en 3D un prototip per a mesurar tensions residuals de mostres laminades. Per a determinar els límits de conformat es van executar diverses proves de laminació cònica i es van construir mapes de processament a partir d'elles. S'han identificat zones de formació segures que condueixen a una combinació òptima de paràmetres: angle del mandril i velocitat d'avanç, que donen com a resultat peces laminades amb èxit. A més, es va trobar que les zones de formació segures són òptimes quan s'implementa un RAA perpendicular a la superfície dels mandrils. A més, per a correlacionar la deformació plàstica amb la duresa, es van realitzar assajos de tracció i mesurament de microduresa i es va obtenir una relació lineal, descrita per: 𝐻��𝑉�� = 63.5 𝜀��𝑒��𝑓��𝑓�� + 135.4. Finalment, els prototips per a mesurar tensions residuals van ser dissenyats en SolidWorks i impresos per la impressora “Ender 3”. Després de diverses proves, es van obtenir amb èxit tres prototips per a les mostres laminades amb mandrils de 15 °, 13 ° i 11 °. Rotational incremental forming processes such as spinning, flow forming, shear spinning, trimming, necking-in, rotatory forging, wheel rim flow forming, pulley forming, etc, have a wide range of applications in industries such as: Automotive, aerospace, ventilation, light & building, pipe oil & gas, bulk materials process, chemical & medical, etc. Most of these processes are ruled by a trial-and-error approach and by highly skilled workers. This project was designed as an attempt to overcome this and to have a better understanding of the process with a more scientific criteria. This project focuses on “Shear spinning processing” of steel DC 04, a steel widely used due to its high ductility. For this purpose, a spinning flow machine scaled at laboratory has been used. The specific goals have been: To determine the forming limit in shear spinning based on the roller attack angle (RAA), to correlate the plastic deformation with the hardness of successfully produced parts and to design and 3D print a prototype to measure residual stresses on conical laminated samples. To determine the forming limits several shear spinning tests were carried out and processing maps were constructed out of them. Safe forming zones have been identified leading to an optimal combination of parameters: mandrel angle and feed rate, that results in successfully processed parts. Additionally, it was found that the safe forming zones exhibit the best performance when a RAA perpendicular to the mandrels surface is implemented. Furthermore, to correlate the plastic deformation with hardness, tensile test and microhardness measurement were carried out and a linear trend was obtained, described as 𝐻�𝑉� = 63.5 𝜀�𝑒�𝑓�𝑓� + 135.4. Finally, the prototypes to measure residual stresses were designed in SolidWorks and printed by a printer “Ender 3”. After several trials, three prototypes were successfully obtained for the laminated samples of mandrels of 15°, 13° and 11°.

Published

2021

14. Visual Servoing of a Conventional CNC Machine Using an External Axis Controller

Author

Daniel Hanafi, Guy Rodnay, Michal Tordon, and Jayantha Katupitiya

Subjects

visual profile tracking, active control, shear spinning, Information technology, T58.5-58.64, Communication. Mass media, P87-96

Abstract

This paper presents the implementation of an external axis control system on a conventional CNC machine so that the machine can be actively controlled in response to sensors such as vision and force. The controller that runs on an external computer has direct access to the CNC controller for machine position sensing. The control signals to the machine are sent through purpose built circuitry via the machine's manual pulse generator (MPG) inputs. To demonstrate the accuracy and performance of the control system, it was used to visually track the profile of a mandrel used for shear spinning. The implemented system eliminates the parallax error and the need to use an accurate pixel resolution. The raw tracking data is processed by a curvature detection algorithm that detects linear and circular segments and segment transitions. The results show that the visual tracking system provides accurate tracking results that are well within the tolerances used in the industry.

Published

2003

15. Shear Spinning

Author

The International Academy for Production Engineering, Laperrière, Luc, editor, and Reinhart, Gunther, editor

Published

2014

16. Evolution of texture distribution in thickness direction of aluminum sheet in metal spinning.

Author

Gondo, Shiori, Arai, Hirohiko, Kajino, Satoshi, and Hanada, Kotaro

Subjects

*METAL-spinning, *ALUMINUM sheets, *SHEET metal, *CRYSTAL orientation, *CRYSTAL texture

Abstract

We evaluated the texture distribution in the thickness direction of the spun workpieces and clarified the mechanism of the change in the crystal orientation of the texture during metal spinning. Blank aluminum disks with a thickness of 1.44 mm were deformed into circular truncated cone cups by under-, true shear, and over-spinning and into cylindrical cups by 13 passes of conventional spinning. Crystal orientation analysis using electron backscatter diffraction revealed that the calculations of the orientation densities for small Miller indices could lead to a systematic evaluation of high intensity texture. The orientation density of Cu {121}< 1 1 ¯ 1 > decreased or that of B {110}< 1 1 ¯ 2 > increased on the roller side of the shear-spun part, of the workpieces formed by shear spinning, and on the roller side of the wall part and on the mandrel side of the open-edge part, of the workpieces formed by conventional spinning. The cosine similarity and Euclidean distance showed that the texture distributions obtained by shear spinning and that of the wall part obtained by conventional spinning were similar. Based on the stress state and preferred crystal orientation in deep drawing, the mechanism of the change in crystal orientation during spinning were described. The density of the texture with {110} (corresponding to B in this study) parallel to a disk plane increased when tensile stress was applied in the circumferential direction, contrarily, when compressive stress was applied in a similar fashion the density of the texture with {112} (corresponding to Cu) parallel to the disk plane increased. [Display omitted] • Clarified the mechanism of change in crystal orientation during metal spinning. • Deriving orientation density of small Miller index systematically founds high intensity texture. • Cu density decreased or B density increased on roller side at wall and on mandrel side at open edge. • Quantitative technique evaluated similarity of textures between shear and conventional spinning. • Tensile stress in a circumferential direction decreased Cu density and increased B density. [ABSTRACT FROM AUTHOR]

Published

2022

17. Control of wall thickness distribution by oblique shear spinning methods

Author

Sekiguchi, Akio and Arai, Hirohiko

Subjects

*THICKNESS measurement, *SHEAR (Mechanics), *METAL-spinning, *DEFORMATIONS (Mechanics), *ALUMINUM, *STRESS concentration, *SHEET metal

Abstract

Abstract: A flexible method of forming circumferentially variant wall thickness distributions on the same shape is attempted using two oblique sheet spinning processes. The fundamental strategy entails the inclination of the flange plane of the workpiece during forming. In one type of synchronous dieless spinning, edge-hemmed aluminum blanks are formed for truncated cone shells, by synchronizing the motion of the spherical head roller in the axial and radial directions with the angle of the general purpose mandrel fixed on a bidirectionally rotating spindle. On the other hand, in the other type of force-controlled shear spinning, flat aluminum discs are formed by feeding perpendicularly to the flange plane of the workpiece and maintaining the thrust force along the plane via the roller tool, exerted onto the rotating truncated-cone-shaped die. The estimated wall-thickness distribution based on a simple shear deformation model nearly conformed to the measured thickness distributions of the products formed at several inclination angles of up to 15 degrees in the forming and both spinning methods. The low-cost value-added forming method seems to be practicable not only for metal spinning but also for other incremental sheet forming processes. [Copyright &y& Elsevier]

Published

2012

18. Effects of feeding ratio on flange bending in shear spinning.

Author

Zhang, Shi-Hong, Lu, Xin-Yu, Liu, Hai, Hou, Hong-Liang, Li, Zhi-Qiang, and Zeng, Yuan-Song

Abstract

The effects of feeding ratio on flange bending of shear spinning are investigated with analytical method. Firstly, influence of feeding ratio on total energy is analyzed utilizing the formula of shear spinning force and power derived by energy method. Subsequently, the connection between the deviation ratio and the thinning ratio, and the influence of feeding ratio on the thinning ratio are researched. Finally, the conclusions about the deviation ratio and flange bending are adopted to reveal the influential tendency of feeding ratio on flange bending. The results show that the flange bending towards headstock weakens with the increase of feeding ratio, which is verified by the experimental results very well. It indicates that the calculation method in this paper is reasonable. [ABSTRACT FROM AUTHOR]

Published

2011

19. A review of the mechanics of metal spinning

Author

Music, O., Allwood, J.M., and Kawai, K.

Subjects

*METAL-spinning, *MECHANICAL behavior of materials, *LITERATURE reviews, *GERMAN language, *SHEAR (Mechanics), *NUMERICAL analysis, *RESIDUAL stresses, *FRACTURE mechanics

Abstract

Abstract: This review presents a thorough survey of academic work on the analysis and application of the mechanics of spinning. It surveys most literature published in English and the most important publications in German and Japanese languages. The review aims to provide insight into the mechanics of the process and act as a guide for researchers working on both metal spinning and other modern flexible forming processes. The review of existing work has revealed several gaps in current knowledge of spinning mechanics: the evolution of the stress state and the strain history of the workpiece in both conventional and shear spinning is not well understood, mainly due to the very long solution times that would occur in modelling the process throughout its duration with a sufficiently fine mesh to capture detailed behaviour through the workpiece thickness; the evolution of microstructure, residual stress and hence springback, has not been examined—either numerically or by experiment; the failure mechanisms of spinning – fracture and wrinkling – are only partially understood, through analogy with other processes, and as yet models of the process have not made use of contemporary damage mechanics; the design of toolpaths required to make particular parts without failure remains an art, and cannot currently be performed automatically with confidence. Studies on novel process configurations in spinning have shown that great potential for innovation in spinning exists. The process has the potential to be more flexible, to produce a wider range of shapes, and to form more challenging materials. [Copyright &y& Elsevier]

Published

2010

20. The mechanics of incremental sheet forming

Author

Jackson, Kathryn and Allwood, Julian

Subjects

*DEFORMATIONS (Mechanics), *SHEET metal, *SHEAR (Mechanics), *ISOSTATIC pressing, *STRAINS & stresses (Mechanics), *MECHANICAL engineering

Abstract

Abstract: The deformation mechanism of incremental sheet forming (ISF) is examined experimentally through forming specially prepared copper sheets. Strain distributions through the thickness of the sheets are measured for two configurations of ISF: two-point incremental forming (TPIF) and single-point incremental forming (SPIF), and a comparison is made to pressing. The measurements show that the deformation mechanisms of both SPIF and TPIF are stretching and shear in the plane perpendicular to the tool direction, with shear in the plane parallel to the tool direction. Strain components increase on successive laps, and the most significant component of strain is shear parallel to the tool direction. Increasing stretching and shear perpendicular to the tool direction account for differences between the sine law prediction and measured wall thickness for both SPIF and TPIF. The observed mechanisms of SPIF and TPIF differ from a mechanism of pure shear that has previously been assumed. [Copyright &y& Elsevier]

Published

2009

21. Evolution of plastic strain during a flow forming process

Author

Roy, M.J., Klassen, R.J., and Wood, J.T.

Subjects

*METALWORK, *METAL-spinning, *DEFORMATIONS (Mechanics), *STRUCTURAL plates, *STEEL, *HARDNESS, *STRAINS & stresses (Mechanics)

Abstract

Abstract: The distribution of equivalent plastic strain through the thickness of several AISI 1020 steel plates formed under different conditions over a smooth cylindrical mandrel using a single-roller forward flow forming operation was studied by measuring the local micro-indentation hardness of the deformed material. The equivalent plastic strain was higher at the inner and outer surfaces and lowest at the center of the workpiece. Empirical expressions are presented which describe the contribution of the roller and mandrel to the total local equivalent plastic strain within the flow formed part. The dependence of these expressions upon the thickness reduction during flow forming is discussed. [Copyright &y& Elsevier]

Published

2009

22. A flexible shear spinning of axi-symmetrical shells with a general-purpose mandrel

Author

Kawai, K., Yang, L.-N., and Kudo, H.

Subjects

*MOLLUSKS, *SHELLFISH, *CEPHALOPODA, *CHITONS

Abstract

Abstract: An experimental study is conducted to survey the technological possibility of the shear spinning of truncated hemispherical shells with a cylindrical mandrel for general purposes using A1050-H and A1050-O commercially pure aluminum sheets of 1mm thickness. It is found that there exist forming limits to prevent the occurrence of wall fractures and flange wrinkles during the spinning process of truncated hemispherical shells. It is also found that the sine law is not realized exactly in shear spinning of truncated hemispherical shells with a cylindrical mandrel for general purposes due to the spring back of the workpiece. [Copyright &y& Elsevier]

Published

2007

23. A Study on the mechanics of shear spinning of cones.

Author

Kim, Jae, Park, Jun, and Kim, Chul

Abstract

The shear spinning process, where the plastic deformation zone is localized in a very small portion of the workpiece, shows a promise for increasingly broader application to the production of axially symmetric parts. In this paper, the three components of working force are calculated by the newly proposed deformation model in which the spinning process is understood as shearing deformation after uniaxial yielding by bending, and shear stress, τ rz becomes k, yield limit in pure shear, in the deformation zone. The tangential forces are first calculated and the feed forces and the normal forces are obtained by the assumption of uniform distribution of roller pressure on the contact surface. The optimum contact area is obtained by minimizing the bending energy required to get the assumed deformation of the blank. The calculated forces are compared with experimental results. A comparison shows that theoretical prediction is reasonably in good agreement with experimental results. [ABSTRACT FROM AUTHOR]

Published

2006

24. An analysis of force distribution in shear spinning of cone

Author

Chen, Ming-Der, Hsu, Ray-Quan, and Fuh, Kuang-Hua

Subjects

*FORCING (Model theory), *SURFACE roughness, *SURFACES (Technology), *FRICTION

Abstract

Abstract: An analytic model for calculation of shear spinning force incorporate factor of over-roll (press down) of the blank is derived. The effects of blank thickness, roller nose radius, mandrel revolution and roller feed on the spinning force are discussed. Results obtained from calculation were compared with the experiment and other theoretical predictions. It is found that the present findings yield optimum results. [Copyright &y& Elsevier]

Published

2005

25. Effects of over-roll thickness on cone surface roughness in shear spinning

Author

Chen, Ming-Der, Hsu, Ray-Quan, and Fuh, Kuang-Hua

Subjects

*SURFACE roughness, *SURFACES (Technology), *SHEAR (Mechanics), *MECHANICS (Physics)

Abstract

A high quality of cone surface finish was achieved by carefully controlled over-roll thickness in the shear spinning process. In this study, blank thickness, roller nose radius, mandrel revolution, roller feed and over-roll thickness were taken as major process variables to investigate the effects of the above parameters on the surface roughness of cone shape products. From the experiment, several sets of experimental data were obtained, which in turn were used to construct regression equations for applied forces and product surface roughness. The results were verified by four extra spinning experiments. It is found that deeper over-roll combines with the thinner blank sheet, larger roller nose radius and slower roller feed, and are advantageous for obtaining smoother surface roughness. Over-roll of the blank in shear spinning is an effective way to improve the surface roughness of the product. [Copyright &y& Elsevier]

Published

2005

26. A lower upper-bound solution for shear spinning of cones

Author

Kim, Chul, Jung, S.Y., and Choi, J.C.

Subjects

*CONES, *SHEAR (Mechanics), *HYPOTHESIS, *FORECASTING

Abstract

The shear spinning process, where the plastic deformation zone is localized in a very small portion of the work piece, is introduced for the manufacturing of large conical shapes. This process seemingly shows a promise for increasingly broader application to the production of axially symmetric parts. This study is to gain a better understanding of the process of shear spinning and to propose a lower upper-bound solution for shear spinning cones. Velocity fields and strain rates are derived from considering the adequate deformation mode and the contact factor is introduced to obtain the lower upper-bound power. The theoretical values are compared with the experimental results of various materials. Al-1100-0, Al-1100-H14, and Al-6061-0. A comparison shows that theoretical prediction is reasonably in good agreement with experimental results. [Copyright &y& Elsevier]

Published

2003

27. Three-dimensional cancer cell culture in high-yield multiscale scaffolds by shear spinning

Author

Connor R. Browse, Stoyan K. Smoukov, Ivan Gout, Ahmed A. Ahmed, C. J. Luo, Christopher Thrasivoulou, Sandra Perez‐Garrido, and Simeon D. Stoyanov

Subjects

0106 biological sciences, business.product_category, Yield (engineering), Materials science, Cell Survival, Nanotechnology, fibrous scaffold, 3D mammalian cell culture, 01 natural sciences, Multiphoton Fluorescence Microscopy, Tissue engineering, microfiber, 010608 biotechnology, Microfiber, Tumor Cells, Cultured, Humans, nanofiber, Spinning, Cell Proliferation, VLAG, shear spinning, Tissue Engineering, Tissue Scaffolds, 010401 analytical chemistry, Electrospinning, 0104 chemical sciences, Microscopy, Fluorescence, Nanofiber, Cancer cell, Shear Strength, business, Physical Chemistry and Soft Matter, Biotechnology

Abstract

Polymeric scaffolds comprising two size scales of microfibers and submicron fibers can better support three-dimensional (3D) cell growth in tissue engineering, making them an important class of healthcare material. However, a major manufacturing barrier hampers their translation into wider practical use: scalability. Traditional production of two-scale scaffolds by electrospinning is slow and costly. For day-to-day cell cultures, the scaffolds need to be affordable, made in high yield to drive down cost. Combining expertise from academia and industry from the United Kingdom and United States, this study uses a new series of high-yield, low-cost scaffolds made by shear spinning for tissue engineering. The scaffolds comprise interwoven submicron fibers and microfibers throughout as observed under scanning electron microscopy and demonstrate good capability to support cell culturing for tumor modeling. Three model human cancer cell lines (HEK293, A549 and MCF-7) with stable expression of GFP were cultured in the scaffolds and found to exhibit efficient cell attachment and sustained 3D growth and proliferation for 30 days. Cryosection and multiphoton fluorescence microscopy confirmed the formation of compact 3D cell clusters throughout the scaffolds. In addition, comparative growth curves of 2D and 3D cultures show significant cell-type-dependent differences. This work applies high-yield shear-spun scaffolds in mammalian tissue engineering and brings practical, affordable applications of multiscale scaffolds closer to reality. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2750, 2019.

Published

2019

28. Three‐dimensional cancer cell culture in high‐yield multiscale scaffolds by shear spinning.

Author

Ahmed, Ahmed A., Perez‐Garrido, Sandra, Browse, Connor R., Gout, Ivan, Luo, CJ, Smoukov, Stoyan K., Thrasivoulou, Christopher, and Stoyanov, Simeon D.

Subjects

CANCER cells, SHEAR (Mechanics), MICROFIBERS, TISSUE engineering, MEDICAL care

Abstract

Polymeric scaffolds comprising two size scales of microfibers and submicron fibers can better support three‐dimensional (3D) cell growth in tissue engineering, making them an important class of healthcare material. However, a major manufacturing barrier hampers their translation into wider practical use: scalability. Traditional production of two‐scale scaffolds by electrospinning is slow and costly. For day‐to‐day cell cultures, the scaffolds need to be affordable, made in high yield to drive down cost. Combining expertise from academia and industry from the United Kingdom and United States, this study uses a new series of high‐yield, low‐cost scaffolds made by shear spinning for tissue engineering. The scaffolds comprise interwoven submicron fibers and microfibers throughout as observed under scanning electron microscopy and demonstrate good capability to support cell culturing for tumor modeling. Three model human cancer cell lines (HEK293, A549 and MCF‐7) with stable expression of GFP were cultured in the scaffolds and found to exhibit efficient cell attachment and sustained 3D growth and proliferation for 30 days. Cryosection and multiphoton fluorescence microscopy confirmed the formation of compact 3D cell clusters throughout the scaffolds. In addition, comparative growth curves of 2D and 3D cultures show significant cell‐type‐dependent differences. This work applies high‐yield shear‐spun scaffolds in mammalian tissue engineering and brings practical, affordable applications of multiscale scaffolds closer to reality. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2750, 2019. [ABSTRACT FROM AUTHOR]

Published

2019

29. Some aspects of microstructure and properties of Al-Mg alloys after shear spinning and cold rolling

Author

Milutin Nikacevic, Ljubica Radović, and Branka Jordovic

Subjects

shear spinning, 0209 industrial biotechnology, Materials science, dynamic recovery, Mg alloys, General Chemical Engineering, Metallurgy, microstructure, Al-Mg alloys, Forming processes, 02 engineering and technology, General Chemistry, mechanical properties, Microstructure, lcsh:Chemical technology, Shear (sheet metal), 020303 mechanical engineering & transports, 020901 industrial engineering & automation, cold rolling, 0203 mechanical engineering, Transmission electron microscopy, Ultimate tensile strength, lcsh:TP1-1185, Spinning

Abstract

Three commercial Al-Mg alloys containing 3 wt.% to 6 wt.% of Mg (AlMg3, AlMg4.5Mn and AlMg6Mn) were subjected to different forming processes: shear spinning and cold rolling. The effect of Mg content and reduction in thickness on the tensile properties and microstructure evolution of Al-Mg alloys were studied. Both optical (OM) and transmission electron microscopy (TEM) were used for the microstructure characterization. The results show that the addition of Mg in these alloys increases the yield strength (YS) and ultimate tensile strength (UTS) in both cold rolled and spun specimens. The strength of all Al-Mg alloys after shear spinning was lower compared to the strength after cold rolling for the same strain. This effect was attributed to the occurrence of dynamic recovery during shear spinning and confirmed by transmission electron microscopy. [Projekat Ministarstva nauke Republike Srbije, br. TR-34018]

Published

2013

30. A COMPARATIVE EVALUATION OF THE FORMABILITY OF TUNGSTEN PLATE AND SHEET BY SPINNING TECHNIQUES.

Author

SUPER-TEMP CORP SANTA FE SPRINGS CALIF, Armstrong,J. R., Bauer,D. W., Oberley,G. L., SUPER-TEMP CORP SANTA FE SPRINGS CALIF, Armstrong,J. R., Bauer,D. W., and Oberley,G. L.

Abstract

This program endeavors to establish the relationship between the fabrication history, physical properties, and spinning characteristic of tungsten sheet and plate. Three sources for the tungsten material have been established as: Fansteel Metallurgical Company, General Electric Company, and Metallwerk Plansee. Fansteel tungsten sheet and plate have been received; sample preparations from the sheet stock have begun. Tooling design and manufacture for spinning tests and workability tests are in process. (Author)

Published

1963

31. Technologie smykového tlačení

Author

Peterková, Eva, Dohnal, Ivo, Povalač, Tomáš, Peterková, Eva, Dohnal, Ivo, and Povalač, Tomáš

Abstract

Předložená práce vypracovaná v rámci bakalářského studia B-STI Strojní inženýrství je zaměřena na technologii smykového tlačení. Na základě studie a vlastních zkušeností je v práci představena problematika tlačení, technologie využívající procesu tlačení, stroje a nástroje pro smykové tlačení., Submitted work fully fashioned within the frame of bachelor study B-STI Mechanical engineering, is specialized for shear spinning technology. On the basis of study and own experiences are presented problems spinning, technologies exploited the process of spinning, machines and tools for shear spinning.

32. Technologie smykového tlačení

Author

Peterková, Eva, Dohnal, Ivo, Povalač, Tomáš, Peterková, Eva, Dohnal, Ivo, and Povalač, Tomáš

Abstract

Předložená práce vypracovaná v rámci bakalářského studia B-STI Strojní inženýrství je zaměřena na technologii smykového tlačení. Na základě studie a vlastních zkušeností je v práci představena problematika tlačení, technologie využívající procesu tlačení, stroje a nástroje pro smykové tlačení., Submitted work fully fashioned within the frame of bachelor study B-STI Mechanical engineering, is specialized for shear spinning technology. On the basis of study and own experiences are presented problems spinning, technologies exploited the process of spinning, machines and tools for shear spinning.

33. Technologie smykového tlačení

Author

Peterková, Eva, Dohnal, Ivo, Peterková, Eva, and Dohnal, Ivo

Abstract

Předložená práce vypracovaná v rámci bakalářského studia B-STI Strojní inženýrství je zaměřena na technologii smykového tlačení. Na základě studie a vlastních zkušeností je v práci představena problematika tlačení, technologie využívající procesu tlačení, stroje a nástroje pro smykové tlačení., Submitted work fully fashioned within the frame of bachelor study B-STI Mechanical engineering, is specialized for shear spinning technology. On the basis of study and own experiences are presented problems spinning, technologies exploited the process of spinning, machines and tools for shear spinning.

34. Technologie smykového tlačení

Author

Peterková, Eva, Dohnal, Ivo, Peterková, Eva, and Dohnal, Ivo

Abstract

Předložená práce vypracovaná v rámci bakalářského studia B-STI Strojní inženýrství je zaměřena na technologii smykového tlačení. Na základě studie a vlastních zkušeností je v práci představena problematika tlačení, technologie využívající procesu tlačení, stroje a nástroje pro smykové tlačení., Submitted work fully fashioned within the frame of bachelor study B-STI Mechanical engineering, is specialized for shear spinning technology. On the basis of study and own experiences are presented problems spinning, technologies exploited the process of spinning, machines and tools for shear spinning.

35. Technologie smykového tlačení

Author

Peterková, Eva, Dohnal, Ivo, Povalač, Tomáš, Peterková, Eva, Dohnal, Ivo, and Povalač, Tomáš

Abstract

Předložená práce vypracovaná v rámci bakalářského studia B-STI Strojní inženýrství je zaměřena na technologii smykového tlačení. Na základě studie a vlastních zkušeností je v práci představena problematika tlačení, technologie využívající procesu tlačení, stroje a nástroje pro smykové tlačení., Submitted work fully fashioned within the frame of bachelor study B-STI Mechanical engineering, is specialized for shear spinning technology. On the basis of study and own experiences are presented problems spinning, technologies exploited the process of spinning, machines and tools for shear spinning.