Finite Element Numerical Simulation Computation of Kitchen Units under the Condition of Stacking and Horizontal Controlled Impact

Si Lian Sheng; Han Yang; Zhan Sheng Gong; De Zhi Zheng; Fei Wang

doi:10.4028/www.scientific.net/AMM.300-301.907

Paper Titles

Size Effect on Pull-In Behaviors of Electrostatically Actuated Cantilever Micro-Beams
p.889

Numerical Analysis of Bubble Motion Characteristics within Vertical Rectangular Micro Channels
p.893

The Noise Source Localization of Industrial Sewing Machine by NAH Method
p.898

Structural Design of Primary Mirror Subassembly for Space Telescope
p.903

Finite Element Numerical Simulation Computation of Kitchen Units under the Condition of Stacking and Horizontal Controlled Impact
p.907

PZT Acoustic Energy Harvester Arrays with Dual Top Electrodes
p.912

Real-Time Monitoring for Vehicle Brake Temperature Rise in Continuous Long Downhill
p.916

Multi-Physical Analysis of Eddy Current Damper (ECD) for Reaction Force Compensation Device
p.920

Mobility Deposition Effect of Aerosol Particles in the Boundary Layer
p.924

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 300-301Finite Element Numerical Simulation Computation of...

Finite Element Numerical Simulation Computation of Kitchen Units under the Condition of Stacking and Horizontal Controlled Impact

Abstract:

The box-type field kitchen units is used to guarantee the diet in field operations for troops, a set of box-type field kitchen units includes 3 boxes and 1 tent (a kind of rotationally-molding material is applicable to box-type military kitchen equipments), cooking staple and non-staple food for 150 people in one hour. Meanwhile, it can supply 75 or 300 people by modularization. The unit weight of box-type field kitchen units is not exceeding 112KG, which can be loaded on the vehicle by 2-people moving laterally or 3-people lifting. Stacking is done frequently in transit, and always suffered from bump and impact; therefore, the structural strength is the key point of design. ANSYS is applied in this paper to make analysis on finite element structural strength, assist to make design, simulate the load-carrying condition of box under the condition of stacking and horizontal impact, guiding the design and production in the end.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 300-301)

Pages:

907-911

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.300-301.907

Citation:

Cite this paper

Online since:

February 2013

Authors:

Si Lian Sheng, Han Yang, Zhan Sheng Gong, De Zhi Zheng, Fei Wang

Keywords:

Box-Type, Kitchen Units, Rotationally-Molding Material, Workbench Software

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Wang Yilin, Chen Chongshi and ect. GJB2711 Test methods for military transport packages, (1996).

Google Scholar

[2] Fengxiang mei. About D'Alembert's Principle – Reading note 6 of theoretical mechanics, Mechanics in Engineering, May (2009).

Google Scholar

[3] Dingning yang; Jingxiang zou; Dengyu gai; Computer-aided Engineering (CAE) and its development, Mechanics in Engineering, 2005. 03.

Google Scholar

[4] Zhengshun ni; Zhiping ding. Finite element analysis software ANSYS and its application in packing machinery element design, China Packaging Industry, 200206.

Google Scholar

[5] Xuetao huang. Study on AWE-based collaborative design and optimization technology, Journal of Shandong University of Science and Technology, May (2007).

Google Scholar

[6] D. V. Steward. The Design Structure System: A Method for Managing the Design of Complex . System. IEEE Trans, on Engineering Management . (1981).

Google Scholar

[7] Eppinger S D, Whitney D E, Smith R P, etal. A model-based method for organizing tasks in product development. Research in Engineering Design . (1994).

Google Scholar

[8] K. Suzuki,N. Kikuchi. A Homogenization Method for Shape and Topology Optimization. Computer Methods in Applied Mechanics and Engineering . (2001).

Google Scholar