A multi-hole pelletizing device (MPD) was proposed to simulate the granular extrusion process of animal feed due to its cheap, fast, and controllable features. The compression mechanism was analyzed and discussed according to the compression force-time curve. This study applied response surface methodology (RSM) with a central composite design (CCD) to develop predictive models for the compression force Fout and the pellet properties which includes pellet density ρp, pellet moisture content Mcp, and pellet tensile strength Dp based on the MPD. The effects of feedstock moisture content Mcf (10%-18% w.b.), feedstock particle size Sf (8 meshes -24 meshes), die temperature Td (70°C-110°C) and compression speed Vc (5 mm/min to 25 mm/min) were investigated. Response surface models developed for the compression force and pellet properties have adequately described the pelleting process (R2 >0.95). The results showed the significant effects of all factors and most of the squared and interaction terms on the compression force and pellet physical properties. It can be concluded from the present study that moisture content and die temperature, followed by compression speed and feedstock particle size are the interacting process factors influencing compression force and pellet properties.
Keywords: animal feed, pelletization, modeling, compression force, response surface methodology, analysis of variance
DOI: 10.25165/j.ijabe.20191201.3264

Citation: Jiang Q H, Wu K, Sun Y. Modeling and analysis of pelletization process based on a multi-hole pelletizing device. Int J Agric & Biol Eng, 2019; 12(1): 17–23.

animal feed, pelletization, modeling, compression force, response surface methodology, analysis of variance

Abdollahi M R, Ravindran V, Svihus B. Pelleting of broiler diets: An overview with emphasis on pellet quality and nutritional value. Animal Feed Science & Technology, 2013; 179(1-4): 1–23.

Cutlip S E. The effect of steam-conditioning practices on pellet quality and growing broiler nutritional value. Journal of Applied Poultry Research, 2008; 17(2): 249–261.

Thomas M, van der Poel A F B. Physical quality of pelleted animal feed 1. Criteria for pellet quality. Animal Feed Science & Technology, 1996; 61(1): 89–112.

Svihus B, Zimonja O. Chemical alterations with nutritional consequences due to pelleting animal feeds: A review. Animal Production Science, 2011; 51(7): 590–596.

Behnke K C. Feed manufacturing technology: Current issues and challenges. Animal Feed Science & Technology, 1996; 62(1): 49–57.

Johnson P, Cenkowski S, Paliwal J. Compaction and relaxation characteristics of single compacts produced from distiller’s spent grain. Journal of Food Engineering, 2013; 116(2): 260–6.

Lv M, Yan L, Wang Z, An S, Wu M, Lv Z. Effects of feed form and feed particle size on growth performance, carcass characteristics and digestive tract development of broilers. Animal Nutrition, 2015; 1(3): 252–255.

Zimonja O, Svihus B. Effects of processing of wheat or oats starch on physical pellet quality and nutritional value for broilers. Animal Feed Science & Technology, 2009; 149(3-4): 287–297.

Tran Q D, Hendriks W H, van der Poel A F B. Effects of drying temperature and time of a canine diet extruded with a 4 or 8mm die on physical and nutritional quality indicators. Animal Feed Science & Technology, 2011; 165(3-4): 258–264.

Naderinejad S, Zaefarian F, Abdollahi M R, Hassanabadi A, Kermanshahi H, Ravindran V. Influence of feed form and particle size on performance, nutrient utilisation, and gastrointestinal tract development and morphometry in broiler starters fed maize-based diets. Animal Feed Science & Technology, 2016; 215: 92–104.

Abdollahi M R, Ravindran V, Wester T J, Ravindran G, Thomas D V. Effect of improved pellet quality from the addition of a pellet binder and/or moisture to a wheat-based diet conditioned at two different temperatures on performance, apparent metabolisable energy and ileal digestibility of starch and nitrogen in broilers. Animal Feed Science & Technology, 2012; 175(3-4): 150–157.

Holm J K, Henriksen U B, Hustad J E, Sørensen L H. Toward an understanding of controlling parameters in softwood and hardwood pellets production. Energy & Fuels, 2006; 20(6):2686–2694.

Wang Y, Wu K, Sun Y. Pelletizing properties of wheat straw blending with rice straw. Energy & Fuels, 2017; 31(5): 5126–5134.

Amerah A M, Quiles A, Medel P, Sánchez J, Lehtinen M J, Gracia M I. Effect of pelleting temperature and probiotic supplementation on growth performance and immune function of broilers fed maize/soy-based diets. Animal Feed Science & Technology, 2013; 180(1-4): 55–63.

Castrillo C, Mota M, van Laar H, Martín-Tereso J, Gimeno A, Fondevila M et al. Effect of compound feed pelleting and die diameter on rumen fermentation in beef cattle fed high concentrate diets. Animal Feed Science & Technology, 2013; 180(1-4): 34–43.

Thomas M, van Vliet T, van der Poel A F B. Physical quality of pelleted animal feed 3: Contribution of feedstuff components. Animal Feed Science & Technology, 1998; 70(1): 59–78.

Kaliyan N, Vance Morey R. Factors affecting strength and durability of densified biomass products. Biomass & Bioenergy, 2009; 33(3):337–359.

Draganovic V, van der Goot A J, Boom R, Jon J. Assessment of the effects of fish meal, wheat gluten, soy protein concentrate and feed moisture on extruder system parameters and the technical quality of fish feed. Animal Feed Science & Technology, 2011; 165(3): 238–250.

Segerström M, Larsson S H. Clarifying sub-processes in continuous ring die pelletizing through die temperature control. Fuel Processing Technology, 2014; 123(7): 122–126.

Nielsen N P K, Gardner D J, Poulsen T, Felby C. Importance of temperature, moisture content, and species for the conversion process of wood residues into fuel pellets. Wood and Fiber Science, 2009; 41(4): 414–425

Gilbert P, Ryu C, Sharifi V, Swithenbank J. Effect of process parameters on pelletisation of herbaceous crops. Fuel, 2009; 88(8): 1491–1497.

Wongsiriamnuay T, Tippayawong N. Effect of densification parameters on the properties of maize residue pellets. Biosystems Engineering, 2015; 139 (November): 111–120.

Holm J K, Henriksen U B, Wand K, Hustad J E, Posselt D. Experimental verification of novel pellet model using a single pelleter unit. Energy & Fuels, 2007; 21(4): 2446–2449.

Holm J K, Stelte W, Posselt D, Ahrenfeldt J, Henriksen U B. Optimization of a Multiparameter Model for Biomass Pelletization to Investigate Temperature Dependence and to Facilitate Fast Testing of Pelletization Behavior. Energy & Fuels, 2011; 25(8): 3706–3711.

Mišljenović N, Čolović R, Vukmirović Đ, Brlek T, Bringas C S. The effects of sugar beet molasses on wheat straw pelleting and pellet quality. A comparative study of pelleting by using a single pellet press and a pilot-scale pellet press. Fuel Processing Technology, 2016; 144: 220–229.

Tumuluru J S. Specific energy consumption and quality of wood pellets produced using high-moisture lodgepole pine grind in a flat die pellet mill. Chemical Engineering Research & Design, 2016; 110: 82–97.

Song X, Zhang M, Pei Z J, Wang D. Ultrasonic vibration-assisted pelleting of wheat straw: A predictive model for energy consumption using response surface methodology. Ultrasonics, 2014; 54(1): 305–311.

Jha S K, Singh A, Kumar A. Physical characteristics of compressed cotton stalks. Biosystems Engineering, 2008; 99(2): 205–10.

Zimonja O, Stevneb A, Svihus B. Nutritional value of diets for broiler chickens as affected by fat source, amylose level and diet processing. Canadian Journal of Animal Science, 2007; 87(4): 553–562.

Stelte W, Nielsen N P K, Hansen H O, Dahl J, Shang L, Sanadi A R. Pelletizing properties of torrefied wheat straw. Biomass & Bioenergy, 2013; 53(49): 105–112.

Tumuluru J S. Effect of process variables on the density and durability of the pellets made from high moisture corn stover. Biosystems Engineering, 2014; 119(4): 44–57.

Bazargan A, Rough S L, McKay G. Compaction of palm kernel shell biochars for application as solid fuel. Biomass & Bioenergy, 2014; 70: 489–497.

Song B, Rough S L, Wilson D I. Effects of drying technique on extrusion–spheronisation granules and tablet properties. International Journal of Pharmaceutics, 2007; 332(1-2): 38–44.

Berthold J, Rinaudo M, Salmeń L. Association of water to polar groups; estimations by an adsorption model for ligno-cellulosic materials. Colloids and surfaces A: Physicochemical and engineering aspects, 1996; 112(2): 117–129.

Lai Z Y, Chua H B, Goh S M. Influence of process parameters on the strength of oil palm kernel shell pellets. Journal of Materials Science, 2013; 48(4): 1448–1456.