Analytical prediction of springback based on residual differential strain during sheet metal bending

Yi, Hui-Jun; Kim, D W; Tyne, C. J. Van; Moon, Young Hoon

doi:10.1243/09544062jmes682

Cited by 46 publications

(24 citation statements)

References 7 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…due to elastic relief with applied bending moment in a forming process, may cause this error. Springback occurs in many manufacturing processes where material deformations happen [4]. Cold working processes are more prone to springback.…”

Section: Springback In Metal Formingmentioning

confidence: 99%

Springback optimization in automotive Shock Absorber Cup with Genetic Algorithm

Kakandikar¹,

Nandedkar

2018

Manufacturing Rev.

View full text Add to dashboard Cite

Abstract. Drawing or forming is a process normally used to achieve a required component form from a metal blank by applying a punch which radially draws the blank into the die by a mechanical or hydraulic action or combining both. When the component is drawn for more depth than the diameter, it is usually seen as deep drawing, which involves complicated states of material deformation. Due to the radial drawing of the material as it enters the die, radial drawing stress occurs in the flange with existence of the tangential compressive stress. This compression generates wrinkles in the flange. Wrinkling is unwanted phenomenon and can be controlled by application of a blank-holding force. Tensile stresses cause thinning in the wall region of the cup. Three main types of the errors occur in such a process are wrinkling, fracturing and springback. This paper reports a work focused on the springback and control. Due to complexity of the process, tool try-outs and experimentation may be costly, bulky and time consuming. Numerical simulation proves to be a good option for studying the process and developing a control strategy for reducing the springback. Finite-element based simulations have been used popularly for such purposes. In this study, the springback in deep drawing of an automotive Shock Absorber Cup is simulated with finite element method. Taguchi design of experiments and analysis of variance are used to analyze the influencing process parameters on the springback. Mathematical relations are developed to relate the process parameters and the resulting springback. The optimization problem is formulated for the springback, referring to the displacement magnitude in the selected sections. Genetic Algorithm is then applied for process optimization with an objective to minimize the springback. The results indicate that a better prediction of the springback and process optimization could be achieved with a combined use of these methods and tools.

show abstract

Section: Springback In Metal Formingmentioning

confidence: 99%

Springback optimization in automotive Shock Absorber Cup with Genetic Algorithm

Kakandikar¹,

Nandedkar

2018

Manufacturing Rev.

View full text Add to dashboard Cite

show abstract

“…SLM can be used to build full-density, high-performance, and complex metal parts without the need for dies or tools [5][6][7][8]. When compared with other traditional techniques, laser processing typically does not require mechanical tooling and, therefore, exhibits high flexibility [9][10][11][12][13][14][15]. A laser beam scans each layer to melt powder particles locally and form a melting pool, which is instantaneously solidified as the laser beam moves away.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Mesh Patterns Using a Selective Laser-Melting Process

et al. 2019

View full text Add to dashboard Cite

The selective laser-melting (SLM) process can be applied to the additive building of complex metal parts using melting metal powder with laser scanning. A metal mesh is a common type of metal screen consisting of parallel rows and intersecting columns. It is widely used in the agricultural, industrial, transportation, and machine protection sectors. This study investigated the fabrication of parts containing a mesh pattern from the SLM of AISI 304 stainless steel powder. The formation of a mesh pattern has a strong potential to increase the functionality and cost-effectiveness of the SLM process. To fabricate a single-layered thin mesh pattern, laser layering has been conducted on a copper base plate. The high thermal conductivity of copper allows heat to pass through it quickly, and prevents the adhesion of a thin laser-melted layer. The effects of the process conditions such as the laser scan speed and scanning path on the size and dimensional accuracy of the fabricated mesh patterns were characterized. As the analysis results indicate, a part with a mesh pattern was successfully obtained, and the application of the proposed method was shown to be feasible with a high degree of reliability.

show abstract

“…The technology enables a wide spectrum of possibilities for constructing 3D parts for various applications such as automobiles, medical supplies, and mechanical parts. When compared with other traditional techniques, laser processing typically does not require mechanical toolings, and, therefore, exhibits high flexibility [1][2][3][4][5]. Porous metal parts have also been applied to filters, fluid-permeable components, electronic products, and biomaterials.…”

Section: Introductionmentioning

confidence: 99%

Control of Porosity in Parts Produced by a Direct Laser Melting Process

Jeon¹,

Hwang

Yun

et al. 2018

Applied Sciences

View full text Add to dashboard Cite

Recent advances in direct laser melting (DLM) have demonstrated its great potential for manufacturing three-dimensional porous metal parts. Various combinations of powder layering and processing parameters can be set to adjust the porous properties of the final parts. This study presents the effects of powder morphologies and process parameters on porosity formation during DLM. Four types of Fe-powders composed of spherical or non-spherical particles with different sizes were experimentally investigated. Furthermore, the laser processing parameters, such as laser energy density, laser focus, and line spacing, which have a significant effect on the results, were characterized. In the case of a mixed powder composed of spherical and non-spherical powders, the packing density decreases as the non-spherical powder size increases. The porosity of the laser-melted layer increases with the degree of size misfit between the non-spherical and spherical powders. Decreased laser absorption and enlargement of the powder-depleted zone as a result of decreased packing density increases the porosity during DLM. The overall results show that the porosity of DLM parts could be actively controlled by adjusting the process parameters and powder morphologies.

show abstract

Analytical prediction of springback based on residual differential strain during sheet metal bending

Cited by 46 publications

References 7 publications

Springback optimization in automotive Shock Absorber Cup with Genetic Algorithm

Springback optimization in automotive Shock Absorber Cup with Genetic Algorithm

Fabrication of Mesh Patterns Using a Selective Laser-Melting Process

Control of Porosity in Parts Produced by a Direct Laser Melting Process

Contact Info

Product

Resources

About