NUMERICAL ANALYSIS OF SPRAY-DIC MODELING FOR FRUIT CONCENTRATION DRYING PROCESS INTO POWDER BASED ON COMPUTATIONAL FLUID DYNAMIC

Authors

  • Norma Alias CSNano, Ibnu Sina Institute for Scientific and Industrial Research, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Johor
  • Nadia Nofri Yeni Suhari CSNano, Ibnu Sina Institute for Scientific and Industrial Research, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Johor
  • Che Rahim Che Teh Department of Mathematical of Science, Faculty of Science, Universiti Teknologi Malaysia, 81310 UTM Johor Bahru, Johor

DOI:

https://doi.org/10.11113/jt.v78.8274

Keywords:

Computational fluid dynamic, partial difference equation, numerical analysis, finite difference method

Abstract

The drying process is most popular preservation methods. It is important in producing the powder and natural dye by concentration fruit drying. Spray-DIC is one of the concentration techniques for drying process using the nozzle flow application in computational fluid dynamic. The mathematical modeling for drying process in this paper includes mass conservation and energy conservation of fruit concentration based on partial differential equation. The discretization of mathematical model will use the finite difference method with the initial and boundary conditions of nozzle flow application. The mathematical modeling computes numerical in sequential algorithm. Jacobi and Gauss-Seidel scheme will use to solve the linear system of mathematical modeling. The execution time, no of iteration, accuracy, root mean square error and maximum error are measured for investigating the numerical analysis. The results show the Gauss Seidel method is the alternative method compared to Jacobi method for solving the Spray-DIC modeling.

References

Haddad, M. A., S. Mounir, V. Sobolik, and K. Allaf. 2008. Fruits & Vegetables Drying Combining Hot Air, DIC Technology And Microwaves. International Journal of Food Engineering. 4(6): 9

Chen, X.D. and A.S. Mujumdar. 2009. Drying Technologies In Food Processing. John Wiley & Sons.

Jayaraman, K. and D. D. Gupta. 1992. Dehydration Of Fruits And Vegetables-Recent Developments In Principles And Techniques. Drying Technology. 10(1): 1-50.

George, S., S. Cenkowski, and W. Muir. 2004. A Review Of Drying Technologies For The Preservation Of Nutritional Compounds In Waxy Skinned Fruit. in North Central ASAE/CSAE Conf, Winnipeg, Manitoba, Canada.

Mounir, S., P. Schuck, and K. Allaf. 2010. Structure And Attribute Modifications Of Spray-Dried Skim Milk Powder Treated By DIC (Instant Controlled Pressure Drop) Technology. Dairy Science & Technology. 90(2-3): 301-320.

Haddad, J. and K. Allaf. 2007. A Study Of The Impact Of Instantaneous Controlled Pressure Drop On The Trypsin Inhibitors Of Soybean. Journal Of Food Engineering. 79(1): 53-357.

Mounir, S. and K. Allaf. 2008. Three-Stage Spray Drying: New Process Involving Instant Controlled Pressure Drop. Drying Technology. 26(4): 452-463.

Setyopratomo, P., A. Fatmawati, and K. Allaf. 2009. Texturing By Instant Controlled Pressure Drop DIC In The Production Of Cassava Flour: Impact On Dehydration Kinetics, Product Physical Properties And Microbial Decontamination. Proceedings of the World Congress on Engineering and Computer Science. San Francisco, USA2009.

Murtaza, Q. 2006. A Critical Investigation Into The Spray-Drying Of Hydroxyapatite Powder For Thermal Spray Applications. Dublin City University.

Mezhericher, M., A. Levy, and I. Borde. 2010. Spray Drying Modelling Based On Advanced Droplet Drying Kinetics. Chemical Engineering and Processing: Process Intensification. 49(11): 1205-1213.

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Published

2016-04-18

How to Cite

NUMERICAL ANALYSIS OF SPRAY-DIC MODELING FOR FRUIT CONCENTRATION DRYING PROCESS INTO POWDER BASED ON COMPUTATIONAL FLUID DYNAMIC. (2016). Jurnal Teknologi (Sciences & Engineering), 78(4-4). https://doi.org/10.11113/jt.v78.8274