• Title/Summary/Keyword: Limit Drawing Ratio

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Investigation of Deep Drawability and Product Qualities of Ultra Thin Beryllium Copper Sheet Metal (베릴륨동 극박판의 드로잉 성형성과 품질특성 연구)

  • Park, S.S.;Hwang, K.B.;Kim, J.B.;Kim, J.H.
    • Transactions of Materials Processing
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    • v.19 no.3
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    • pp.179-184
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    • 2010
  • The present study is focused on the deep drawability and product qualities of ultra thin beryllium copper sheet metal. The goal of this research is to investigate the limit drawing ratio in deep drawing of ultra thin beryllium copper metal. For the experiment, beryllium copper(C1720, $50{\mu}m$ in thickness) is used. Tensile test are also carried out to find out the material properties. Deep drawing experiments are carried out in Universal Testing Machine(UTM) to obtain limit drawing ratio. Deep drawing tests are carried out for various specimen sizes. Teflon film is used as a lubricant and constant blank holding force is imposed. Sheet thickness and surface hardness are measured along radial direction after deep drawing. Thickness is measured using optical microscope. For beryllium copper(C1720), the maximum LDR of 2.4 is obtained when the die shoulder radius is 20 or 30 times of sheet thickness.

The Applicatiion of Finite Element Method to Process Design Considering Forming Limit in Deep Drawing (성형한계를 고려한 디프 드로잉 공정설계에 대한 유한 요소 해석)

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    • Proceedings of the Korean Society for Technology of Plasticity Conference
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    • 1998.06a
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    • pp.74-82
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    • 1998
  • The limit drawing ratio (LDR) is a major process parameter in the process design of deep drawing. If the actual drawing ratio is greater than the LDR for a particular stage, then an intermediate stage has to be added to the process sequence to avoid failure during the ratio. In this study, the optimal process design considering forming limit is performed for the first-drawing and redrawing by using finite element method combined with ductile fracture criterion. The LDR and the site of fracture initiation are predicted by means of the fracture criterion. From the results of finite element analysis, the optimal value of drawing ratio is obtained, which contributes to the more uniform distribution of thickness and the smaller values of the ductile fracture in final cup.

Thickness Distribution of Hemispherical Cup in Meso-Scale Deep Drawing Process (반구형 극소 드로인 제품의 두께분포 비교)

  • Lee, K.S.;Jung, H.K.;Kim, J.B.;Kim, J.H.
    • Transactions of Materials Processing
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    • v.20 no.1
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    • pp.36-41
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    • 2011
  • Meso-scale or micro-scale forming of sheet metal parts has been recently considered as one of the important forming technologies with growing demand on meso/micro products for electric or medical devices. Experimental investigation on the cylindrical meso-cup drawing with hemispherical punch is carried out to examine the limit drawing ratio and thickness distribution of drawn cups. The working parameters chosen in this study are blank diameter, die-corner radius and blankholding force. It is found from the experiments that the limit drawing ratio of 2.4 can be achieved in the case of hemispherical cup drawing and uniform thickness distribution in wider region can be obtained compared with the results of conventional cup drawing.

Deep Drawing With Internal Air-Pressing to Increase The Limit Drawing Ratio of Aluminum Sheet

  • Moon, Young-Hoon;Kang, Yong-Kee;Park, Jin-Wook;Gong, Sung-Rak
    • Journal of Mechanical Science and Technology
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    • v.15 no.4
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    • pp.459-464
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    • 2001
  • The effects of internal air-pressing on deep drawability are investigated in this study to increase the deep drawability of aluminum sheet. The conventional deep drawing process is limited to a certain limit drawing ratio(LDR) beyond which failure will occur. The intention of this work is to examine the possibilities of relaxing the above limitation through the deep drawing with internal air-pressing, aiming towards a process with an increased drawing ratio. The idea which may lead to this goal is the use of special punch that can exert high pressure on the internal surface of deforming sheet during the deep drawing process. Over the ranges of conditions investigated for Al-1050, the local strain concentration at punch nose radius area was decreased by internal air-pressing of punch, and the deep drawing with internal air-pressing was proved to be very effective process for obtaining higher LDR.

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The Application of Finite Element Method to Process Design Considering Forming Limit in Deep Drawing (성형한계를 고려한 디프 드로잉 공정설계에 대한 유한 요소 해석)

  • Choe, Yeong;Lee, Gyu-Ho;Go, Dae-Cheol;Kim, Byeong-Min;Choe, Jae-Chan
    • Transactions of Materials Processing
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    • v.7 no.6
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    • pp.562-569
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    • 1998
  • The limit drawing ratio (LDR) is a major process parameter in the process design of deep drawing. If the actual drawing ratio is greater than the LDR for a particular stage then an intermediate stage has to b added the process sequence to avoid failure during the drawing operation and the optimal process design considering for the first-drawing and redrawing by using finite element method combined with ductile fracture criterion. From the results of finrte element analysis the optimal value of drawing ratio is obtained which contributes to the more uniform distribution of thickess and the smaller values of the ductile fracture infinal cup.

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Design of Porcess Parameters in Axisymmetric Multi-step Deep Drawing by a Finite Element Inverse Method (유한요소 역 해석을 이용한 축대칭 다단계 박판성형에서의 공정변수 설계에 관한 연구)

  • Cho, Cheon-Soo;Lee, Choong-Ho;Huh, Hoon
    • Transactions of Materials Processing
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    • v.6 no.4
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    • pp.300-310
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    • 1997
  • A finite element inverse method is introduced for direct prediction of blank shapes, strain distributions, and reliable intermediate shapes from desired final shapes in axisymmetric multi-step deep drawing processes. This mothod enables the determination of process disign. The approach deals with the Hencky's deformation theory. Hill's second order yield criterion, simplified boundary conditions, and minimization of plastic work with constraints. The algorithm developed is applied to motor case forming, and cylindrical cup drawing with the large limit drawing ratio so that it confirms its validity by demonstrating resonably accurate numerical results of each problem. Numerical examples reveal the reason of difficulties in motor case forming with corresponding limit diagrams.

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A Study on the Prediction of Limit Drawing Ratio And Forming Load in Redrawing of Sheet Metal (박판의 재인발 가공 에서의 한계인발비 및 성형하중 의 예측 에 관한 연구)

  • 박장호;양동열
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.7 no.3
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    • pp.249-256
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    • 1983
  • The study is concerned with the analysis of sheet metal for the prediction of limit drawing ratio and forming load. The direct redrawing process is analyzed by using an equilibrium approach and strain increment theory both for non-workhardening material and for workhardening material. Computations are carried out numerically for the workhardening case. Limit drawing ratios are predicted for some chosen variables. The forming loads are also computed with respect to punch travel. Then the predicted loads are compared with the experimental results. For ordinary lubricated conditions, the comparison shows reasonable agreement between the theory and experimental observation. It is also shown that limit drawing ration can be increased by using a greater die angle and proper lubrication significantly reduces the punch load. Finally numerical results show that material of greater R-value and strain-hardening exponent(n)is better for direst redrawing of sheet metal.

Finite Element Analysis and Experimental Investigation of Non-isothermal Foming Processes for Aluminum-Alloy Sheet Metals(Part 1. Experiment) (알루미늄 합금박판 비등온 성형공정의 유한요소해석 및 실험적 연구 (제1부. 실험))

  • 류호연;김영은;김종호;구본영;금영탁
    • Transactions of Materials Processing
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    • v.8 no.2
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    • pp.152-159
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    • 1999
  • This study is to investigate the effects of warm deep drawing with aluminum sheets of A1050-H16 and A5020-H32 for improving deep drawability. Experiments for producing circular cups and square cups were carried out for various working conditions, such as forming temperature and blank shapes. The limit drawing ratio(LDR) of 2.63 in warm deep drawing of circular cups in case of A5020-H32 sheet, whereas LDR of 2.25 in case of A1050-H16, could be obtained and the former was 1.4 times higher than the value at room temperature. The maximum relative drawing depth for square cups of A5020-H32 material was also about 1.92 times deeper than the depth drawn at room temperature. The effects of blank shape and forming temperature on drawability as well as thickness distribution of drawn cups were examined and discussed.

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A Study on the Deep Drawing of AZ31B Magnesium Sheet at Warm and Hot Temperature (AZ31B 마그네슘 판재의 온.열간 ?K드로잉에 관한 연구)

  • Kim, H.G.;Bae, J.W.;Choo, D.K.;Kang, C.G.
    • Transactions of Materials Processing
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    • v.15 no.7 s.88
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    • pp.504-511
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    • 2006
  • The drawability of AZ31B magnesium sheet is estimated at various temperatures($200,\;250,\;300,\;350\;and\;400^{\circ}C$), and forming speed(20, 50, 100mm/min), thickness(0.5, 0.8, 1.0, 1.4mm). The deep drawing process of circular cup and square cup were used in forming experiments. Experimental and FEM analysis are performed to investigate drawability and affection of controlled blank holding force. Through the controlled blank holding force, drawability was improved. Limit drawing ratio is increased from 2.1 to 3.0 in circular cup drawing and change of thickness is decreased from 16.3 to 6.9%. This result is verified by FEM analysis. Through the observation of microstructure, the main cause is investigated as a quantity of the dynamic recrystallization.

A Study on the Warm Deep Drawability of Mg- Alloy Sheet Metal (마그네슘합금 판재의 온간 디프 드로잉성에 관한 연구)

  • 이용길;김종호;이종섭
    • Proceedings of the Korean Society for Technology of Plasticity Conference
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    • 2003.10a
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    • pp.117-120
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    • 2003
  • Warm deep drawing which is one of the new forming technologies to improve formability of sheet metal is applied to the cylindrical cup drawing of Mg-alloy sheet metal. In experiments the temperature of die and blank holder is varied from room temperature to $300^{\circ}C$, while the punch is cooled by circulation of coolant to increase the fracture strength of workpiece on the punch corner area. Test material chosen for experiments is AZ31 magnesium sheet metal. Teflon film as a lubricant is used on both sides of a workpiece. The limit drawing ratio as well as thickness distributions of drawn cups are investigated and validity of warm deep drawing process is also discussed.

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