A Study on Dynamic Simulation of Litchi Pitting Process Based on ANSYS / LS-DYNA

Zhen Chen; Chang You Li; Feng Ying Xu

doi:10.4028/www.scientific.net/AMR.479-481.2557

Paper Titles

Effect of Assembly Error on the Meshing Characteristic of Spacial Beveloid Gears
p.2533

A Mechanical Calculation of the Flexible & Floating Anti-Ship Collision Device for Bridge Piers
p.2540

Study on the Thermal Characteristics of a Motorized Spindle Unit
p.2546

A Numerical Study of the Effect of Bubble Layer on Propulsion Performance of Deep-Vee Hull Form Ship
p.2551

A Study on Dynamic Simulation of Litchi Pitting Process Based on ANSYS / LS-DYNA
p.2557

Effects of Material Properties and Thickness of Die Attach on Package Delamination of IC Packages
p.2564

Study on Design Method of Non-Uniform Beam of Mechanical Structure
p.2568

New Fault Isolation Method during Functional Test in Manufacturing
p.2572

The Implement of Optimization Design of a Car Body Based on VCD-ICAE System
p.2577

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 479-481A Study on Dynamic Simulation of Litchi Pitting...

A Study on Dynamic Simulation of Litchi Pitting Process Based on ANSYS / LS-DYNA

Abstract:

To study the dynamic mechanical changes in litchi pitting process and improve the accuracy of litchi pitting, this paper established a 3-D solid assembly model of litchi, fixture and tool and conducted the finite element discrete of the model by using ANSYS / LS-DYNA software. In addition, the deformations and stress states of litchi’s multi-layer structure under the effects of tool and fixture were simulated and calculated by the LS-DYNA971 solver. The results showed that the deformations and stresses of litchi’s multi-layer structure changed with the increase of cutting depth, and appeared the maximum amplitude out of sync. When the litchi was gonna cut through, the stress amplitude of fruit pulp was the maximum among litchi’s multi-layer structure and the stress amplitude of fruit pulp was the minimum. Pulp would reach its maximum stress when cutting through the litchi, and because of its low strength, the breakage was prone to occur. The stress of fruit stone was large in the initial stage, and big fruit stone was easily led to the breakage for its overlarge stress. In pitting process, the deformation and slippage of litchi would take place with fixture clamping and tool pitting, so this is a complex dynamic deformation process. This study is urgent to make more comprehensive and systematic researches.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 479-481)

Pages:

2557-2563

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.479-481.2557

Citation:

Cite this paper

Online since:

February 2012

Authors:

Zhen Chen, Chang You Li, Feng Ying Xu

Keywords:

Dynamic, Litchi, LS-DYNA, Pitting Process, Simulation

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Huibai Huang, Jiankai Xu: Seientia Hortieulturae, Vol. 9 (1983), p.335

Google Scholar

[2] Hetong Lin, Shaojun Chen, Yufang Xi: Transactions of the CSAE, Vol. 19 (2003), p.126 (In Chinese)

Google Scholar

[3] Zhen Chen, Fengying Xu, Changyou Li, Shuncheng Lu: Journal of Agricultural Mechanization Research, issue 9 (2008), p.128 (In Chinese)

Google Scholar

[4] Zhen Chen, Changyou Li, Ying Hong: Proceedings of the Chinese Society of Agricultural Engineering Annual Conference, Guangzhou, China, 19-21 December, 2005, p.453 (In Chinese)

Google Scholar

[5] Yan Chen, Weiliang Cai, Xiangjun Zou, Heping Xiang, Tianhu Liu, Fengying Xu: Transactions of the CSAE, Vol. 27 (2011), p.358 (In Chinese)

Google Scholar

[6] Junxiong Huang, Guanyu Peng, Jintian Yang: Study on Litchi Peeling and Pitting Automatic Machine (Food Industry Development Institute Press, Taiwan, 1985).

Google Scholar

[7] Xiaohong Dai: Packaging and Food Machinery,Vol. 15 (1997), p.18 (In Chinese)

Google Scholar

[8] Ming Li, Ganran Deng, Wenwei Lian, Shihua Lian: Transactions of the CSAE, Vol. 15 (1999), p.213 (In Chinese)

Google Scholar

[9] Linquan Zhang: Packaging and Food Machinery, Vol. 22 (2004), p.4 (In Chinese)

Google Scholar

[10] Xudong Wang, Changyou Li, Shaohui Zhang, Maozhu Huang: Transactions of The CSAM, Vol. 36 (2005), p.167 (In Chinese)

Google Scholar

[11] Hongsheng Cheng, Changyou Li, Yanhua Bao, Ye Zhang, Xiaowen Li: Transactions of the CSAE, Vol. 26 (2010), p.123 (In Chinese)

Google Scholar

[12] Bajema, R. W., Baritelle, A. L., Hyde, G. M., Pitts, M. J.: Transactions of the ASAE, Vol. 43 (2000), p.1725

Google Scholar

[13] Stoneham T.R., Lund D.B., Tong C.H.: Journal of Food Science, Vol. 65 (2000), p.968

Google Scholar

[14] JamaLNourain, Yibin Ying, Jianping Wang, Xiuqin Rao: Transactions of the CSAE, Vol. 21 (2005), p.17

Google Scholar

[15] Ezawa Y, Okamoto N: Computers & Structures, Vol. 57 (1995), p.691

Google Scholar

[16] Gongbing Su, Jianying Liu, Shucai Wang: Transactions of the CSAM, Vol. 38 (2007), p.62 (In Chinese)

Google Scholar