• Title/Summary/Keyword: KAVF

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A UBET Analysis on the Lateral Extrusion Process of a Spider (스파이더의 측방 압출 공정에 대학 UBET해석)

  • Lee, Hee-In;Bae, Won-Byong
    • Journal of the Korean Society for Precision Engineering
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    • v.18 no.6
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    • pp.174-181
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    • 2001
  • An upper bound elemental technique(UBET) has been carried out to predict the forming load, the deformation pattern and the extrude length of the lateral extrusion of a spider for the automotive universal joint. For the upper bound analysis, a kinematically admissible velocity field(KAVF) is proposed. From the proposed velocity field, the upper bound load, the deformation pattern and the average length of the extruded billets are determined by minimizing the total energy consumption rate which is a function of unknown velocities at each element. Experiments are carried out with antimony-lead billets at room temperature using the rectangular shape punch. The theoretical prediction of the forming load, the deformation pattern and the extruded length are good in agreement with the experimental results.

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A UBET Analysis on the Lateral Extrusion Process of a Spider (스파이더의 측방 압출 공정에 대한 UBET 해석)

  • 황범철;이희인;배원병
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2001.04a
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    • pp.1129-1133
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    • 2001
  • An upper bound elemental technique(UBET) has been carried out to predict the forming load, the deformation pattern and the extruded length of the lateral extrusion of a spider for the automotive universal joint. For the upper bound analysis, a kinematically admissible velocity field(KAVF) is proposed. From the proposed velocity field, the upper bound load, the deformation pattern and the average length of the extruded billets are determined by minimizing the total energy consumption rate which is a function of unknown velocities at each element. Experiments are carried out with antimony-lead billets at room temperature using the rectangular shaped punch. The theoretical prediction of the forming load, the deformation pattern and the extruded length are good in agreement with the experimental results.

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A UBET Analysis of the Extrusion/Forging Process of Polygonal Headed Bars (다각형의 머리를 가진 봉의 압출/단조 공정에 관한 UBET 해석)

  • Kim, Myung-Hun;Hwang, Bum-Chul;Kim, Ho-Yoon;Bae, Won-Byong
    • Journal of the Korean Society for Precision Engineering
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    • v.16 no.9
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    • pp.110-116
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    • 1999
  • A new KAVF(kinematically-admissible velocity field) is proposed to determine the forming load, the average extruded length and the flow pattern is the extrusion/forging process of polygonal headed bars. Experiments are carried out with lead billets at room temperature using regular polygonal shaped punches. The theoretical predictions of the forming load and the average extruded length are in good agreement with the experimental results.

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UBET Analysis of Combined Forging of Non-Axisymmetric Shapes With Inclined Protrusion (경사진 돌출부가 있는 비축대칭 복합단조의 상계요소해석)

  • 윤정호;양동열
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.14 no.1
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    • pp.1-12
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    • 1990
  • The study is concerned with the analysis of combined forging of non-axisymmetric shapes with inclined protrusions by UBET technique. Work hardening is considered for the given range of strain rate during the forging process. A complex shape with inclined cavities is analyzed by subdividing the workpiece into finite UBET elements for which simple velocity fields are applicable. An experimental set-up was designed and manufactured for the experiment, and experiments are carried out with lead billets. The devised set-up can be used for closed-die forging of complex shapes with protrusions in which the dies can be separated automatically for easy removal of the forged products. Based on the derived kinematically admissible velocity fields for corresponding UBET elements, general computer programs have been developed. Since the energy dissipation rate for each elemental region is provided by subprograms (Subroutine or Function), the developed program can be applied to the forging problems of various shapes. The present study has shown that the method developed can be effectively applied to forging of non-axisymmetric shapes with complicated protrusions.