Appraisal of Fine Distribution in a Pilot-scale Silo in Different Filling Conditions

Nourmohamadi-Moghadami, A.; Zare, D.; Kamfiroozi, Sh.; Jafari, A. A.; Nematollahi, M. A.; Kamali, R.

doi:10.22067/jam.v9i1.69749

Document Type : Research Article

Authors

¹ Biosystems Engineering Department, College of Agriculture, Shiraz University, Shiraz, Iran

² Mechanical Engineering College, Shiraz University, Shiraz, Iran

https://doi.org/10.22067/jam.v9i1.69749

Abstract

Introduction
During filling a silo, granular material containing a range of particle sizes, the fine material accumulates under the filling point. The inclined surface of stationary bed particle which is formed in silos during filling process acts similar to a sieve through which the smaller particle fall. This effect is called sifting. As a result of the mentioned effect, much finer particles form a vertical cylindrical zone of high concentration at the silo center. For optimal design in industrial process such as aeration of stored products in silos, filling silos, and wherever granular materials are handled, it is necessary to survey the distribution of the fine materials depending on product and process properties. The objectives of present study were: (a) To study fine change as affected by substantial parameters, (b) To model fine changes at different conditions in silos.
Materials and Methods
In the present study, an experimental setup consist of a main container, elevator, trapezoidal container and experimental silo was designed and built. Fine content was defined by BCFM (broken corn and foreign material). By applying a new approach, sampling was performed in a radial and vertical direction. The position of each sampling point was determined with a scaled distance from center (R) and from bottom (Z). Local BCFM (BCL) was defined as the value of BCFM in each sampling point. Influential parameters namely, initial BCFM (BCI), volume flow rate (Q) and fill pipe diameter (DF) were considered as treatments. Non-linear regression technique was applied on the experimental data to predict the distribution pattern of fines into the pilot-scale silo. The most appropriate model in a try and error procedure was selected based on highest value of R2 and least value of χ2, RMSE and MRDM.
Results and Discussion
According to the results of ANOVA, it was found that the effects of all parameters were significant at 5% probability. BCL decreased nonlinearly with a concave down decreasing trend along radial direction due to sifting effect. As a result, most amount of fines remained in the sections closer to the center of the silo. Fine distribution became more uniform with decreasing Z and increasing BCI and DF. Also, the distribution of fine became more uniform with increasing Q. BCL was a nonlinear function of R and a linear function of Z, BCI, Q and DF. Although including more and complex terms increased the model complexity but in the present study considering BCL as an exponential function of R and as an implicit function of Z and R (ZR) improved the quality of the model significantly. The values of 0.94, 1.14, 1.06, 11.39 for R², χ2, RMSE and MRDM, respectively, gave the best model. The results showed, considerable accumulation of fines occurred at the center of the silo which increased with increase of level of Z. Also, low concentration of fine occurred at the periphery of the silo especially at higher levels of Z. It means that maximum non-uniformity of fine distribution occurred at higher levels of Z.
Conclusion
The present study investigated distribution of fines during filling affected by main parameters namely, initial BCFM, volume flow rate and fill pipe diameter in a pilot scale silo. A new procedure was developed for measuring the fine material along radial and vertical directions. Distribution of fine was modeled using a developed equation considering the effects of main parameters. The results showed that distribution of fine becomes more uniform with decreasing height and increasing initial BCFM, volume flow rate and fill pipe diameter.

Keywords

20.1001.1.22286829.1398.9.1.3.2

References

1. Abbasi, S., S. Minaei, and M. H. Khoshtaghaza. 2014. Investigation of kinetics and energy consumption of thin layer drying of corn. Journal of Agricultural Machinery 4 (1): 98-107. (In Farsi).

2. ASABE. 2008. Moisture measurement- Unground grain and seeds. ASABE S352.2. St. Joseph, Michigan, USA: American Society of Agricultural and Biological Engineers.

3. Bartosik, R. E., and D. E. Maier. 2006. Effect of airflow distribution on the performance of NA/LT in-bin drying of corn. Transactions of the ASABE 49 (4): 1095-1104.

4. Combarros, M. G., H. J. Feise, S. Strege, and A. Kwade. 2016. Segregation in heaps and silos: Comparison between experiment, simulation and continuum model. Powder Technology 293: 26-36.

5. Engblom, N., H. Saxen, R. Zevenhoven, H. Nylander, and G. G. Enstad. 2012. Segregation of powder mixtures at filling and complete discharge of silos. Powder Technology 215-216: 104-116.

6. Fan, Y., K. V. Jacob, B. Freireich, and R. M. Lueptow. 2017. Segregation of granular materials in bounded heap flow: A review. Powder Technology 312: 67-88.

7. Fan, Y., P. B. Umbanhowar, J. M. Ottino, and R. M. Lueptow. 2013. Kinematics of monodisperse and bidisperse granular flows in quasi-two-dimensional bounded heaps. Proceedings of the Royal Society A, 469, 20130235.

8. Fan, Y., Y. Boukerkour, T. Blanc, P. B. Umbanhowar, J. M. Ottino, and R. M. Lueptow. 2012. Stratification, segregation, and mixing granular materials in quasi-two-dimensional bounded heaps. Physical Review E 86, 051305.

9. Jain, A., M. J. Metzger, and B. J. Glasser. 2013. Effect of particle size distribution on segregation in vibrated systems. Powder Technology 237: 543-553.

10. Jayas, D. S., S. Sokhansanj, E. B. Moyseyand, and E. M. Barber.1987. Distribution of foreign material in canola bins using a spreader or spout. Canadian Agricultural Engineering 29: 183-188.

11. Koeppe, J. P., M. Enz, and J. Kakalios. 1998. Phase diagram for avalanche stratification of granular media. Physical Review E 58, R4104-R4107.

12. Mohsenin, N. N. 1986. Physical Properties of Plant and Animal Materials. New York. Gordon and Breach Science Publisher.

13. Noyes, R., S. Navarro, and D. Armitage. 2002. Supplemental aeration systems. PP 413-488 in S. Navarro, & R. Noyes eds. The mechanics and physics of modern grain aeration management. Boca Raton: CRC Press.

14. Schulze, D. 2008. Powders and Bulk Solids - Behaviour, Characterization, Storage and Flow (chapter 13). Springer. Verlag Berlin Heidelberg.

15. Shinohara, K., B. Golman, and T. Nakata. 2001. Size segregation of multicomponent particles during the filling of a hopper, Advanced Powder Technology 10 (1): 333-343.

16. SPSS. 2012. SPSS/PC for IBM PC/XT, Version 1.10. SPSS Inc., Chicago, IL, USA,

17. Stephens, L. E., and G. H. Foster. 1976. Grain bulk properties as affected by mechanical grain spreaders, Transactions of ASAE 19 (2): 354-358.

18. Stroshine, R. 2004. Physical properties of agricultural materials and food products (Chapter 2). West Lafayette, Indiana.

19. USDA. 2013. Grain inspection handbook. Book II. Chapter 4. Corn. U.S. Department of Agriculture, Grain inspection, Packers and Stockyards Administration, Federal Grain Inspection Service.

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Journal of Agricultural Machinery

Appraisal of Fine Distribution in a Pilot-scale Silo in Different Filling Conditions

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Volume 9, Issue 1 - Serial Number 17
Spring and Summer
2019
Pages 31-48

Appraisal of Fine Distribution in a Pilot-scale Silo in Different Filling Conditions

References

References

Send comment about this article

Volume 9, Issue 1 - Serial Number 17Spring and Summer 2019Pages 31-48

Volume 9, Issue 1 - Serial Number 17
Spring and Summer
2019
Pages 31-48