The Effects of Moisture Content, Temperature, and Compaction Pressure on the Compressibility of Animal Feed Pellets Produced From Green Pistachio Shell Residues
محورهای موضوعی : Pistachio
Kazem Laei
1
,
Hossein Haji Agha Alizadeh
2
,
Mohammad Hossein Kianmehr
3
1 - Ph.D student, Department of Biosystems Engineering, Faculty of Agriculture, Bu-Ali Sina University, Hamedan, Iran
2 - Associate Professor, Department of Biosystems Engineering, Faculty of Agriculture, Bu-Ali Sina University, Hamedan, Iran
3 - Professor, Department of Agrotechnology, College of Abouraihan, University of Tehran, Tehran, Iran
کلید واژه: Pistachio waste, Animal feed, Pellet quality, Transformational industries,
چکیده مقاله :
Pelleting is a promising, cost-effective method to optimize the use of garden wastes as animal feed production. Shortage of animal feed and increasing costs are the main reasons to produce feed from garden wastes like green pistachio shell residues. In this study, green pistachio shell residues were gathered and stored in the open air to reduce moisture content, then the dried residues were hammered and sieved to make pellets using a hydraulic pellet maker machine. A factorial experiment with three factors was performed at temperatures of 50 and 65℃, moisture content levels of 15 and 20%, and compaction pressure with a single hydraulic pellet machine at 6000, 8000, and 11000 kPa using a 10 mm mold to investigate the possibility of pelleting green pistachio shell residues. Toughness and fracture energy are the important parameters for optimal pellet-making conditions. The produced pellets were investigated in terms of density, fracture energy, and toughness. The results showed that the effect of compaction pressure on the attributes was significant at the 1% level. The highest values of these attributes were obtained at the highest pressure of 11000 kPa. It was observed that the interaction effect of moisture and temperature on pellet density was the most significant level (1308.13 kg m-3) at temperatures of 65 ℃ and 15% moisture content. Also, the highest fracture energy and toughness (0.0228 J and 1.44×10-14 J m-3) were observed at temperatures of 50°C and 20% moisture content. Therefore, pellets made of green pistachio shell residues have sufficient density, fracture energy, and toughness, which makes pelleting a viable option for reducing transportation volume and costs in animal feed production
AACC (1999) 44-15A Method Approved Methods of the American Association of cereal chemists. 9 ed, Volume ll.
Ahmed OH, Husni MHA, Noor, AA, Hanafi MM (2002) The Removal and Burning of Pineapple Residue in Pineapple Cultivation on Tropical Peat: An Economic Viability Comparison. Pertanika Journal of Tropical Agricultural Science. 25(1), 47-52.
Aleyki A (2000) Designing a semi-industrial production line for animal feed from pistachio shells. Master thesis, University of Science and Technology, Tehran.
Amiri H (2018) Design and construction of control release pellet produce system based on compost fertilizer. Ph.D. thesis, College of Abouraihan, University of Tehran.
Amiri H, Kiyanmehr M, Arabhosseini A, Volaei I (2012) Determination of moisture content for production of cow dung pellet using an extruder. The 6th National and 1st International Conference on Waste Management. 23-24 April, Mashhad, Iran.
ASABE A (2007) S269. 4–cubes, pellets, and crumbles–definitions and methods for determining density, durability, and moisture content, American Society of Agricultural and Biological Engineers Standards, St. Joseph, MI, USA. 624–626.
ASAE (2006) S319.3 Method of determining and expressing fineness of feed materials by sieving. pp. 601-605.
Falk D (1985) Pelleting cost center. Feed Manufacturing Technology, 3rd edition, MM McElihiney (ed), American Feed Industry Association, Arlington.
Fallah Tafti N (1999) Production of protozoan protein from pistachio shells. Master thesis, North Tehran Branch of Azad University, Faculty of Basic Sciences.
FAO STAT (2014) Global tomato production in 2012. Rome, FAO. www.fao.org.
Fasina OO (2008) Physical properties of peanut hull pellets. Bioresource Technology. 99(5), 1259-1266.
Filbakk T, Jirjis R, Nurmi J, Hϕibϕ O (2010) The effect of bark content on quality parameters of scot pine (Pinus Sylvestive L.) pellets. Biomass and Bioenergy. 35(8), 3342-3349.
Foroogh Ameri N (1997) Study on the nutritive value and digestibility of dried and silage form of Pistachio Epicarpe. Master of Science Thesis, Isfahan University of Technology.
Garcia-Maraver A, Rodriguez ML, Serrano-Bernardo F, Diaz LF, Zamorano M (2015) Factors affecting the quality of pellets made from residual biomass of olive trees. Fuel Processing Technology. 129, 1-7.
Ghaebi SM (2009) Determination of the physical and mechanical properties of fruit, apricots core and brain of Persia. M.Sc thesis. Collage of Abouraihan, University of Tehran.
Ghasemi A, Chayjan RA (2019) Optimization of pelleting and infrared-convection drying processes of food and agricultural waste using response surface methodology (RSM). Waste and Biomass Valorization. 10(6), 1711-1729.
Ghorbani M (2021) Effect of ozonation on delignification and physical, mechanical and nutritional properties of wheat straw. Ph.D thesis, College of Abouraihan, University of Tehran.
Golmohammadi F (2012) Study on the solutions and benefits of producing animal feed from fresh pistachio skin, The first national conference on agriculture in difficult environmental conditions, Ramhormoz.
Homayoonfar F, Kiyanmehr M, Arab Mohammad Hoseini A, Raei M, Rezapour K (2016) Effect of extruder parameters on some mechanical properties of pelleted compost, Iranian Journal of Biosystems Engineering. 47(3), 551-559.
Jiang L, Yuan X, Xiao Z, Liang J, Li H, Cao L, Zeng G (2016) A comparative study of biomass pellet and biomass-sludge mixed pellet: Energy input and pellet properties. Energy Conversion and Management. 126, 509-515.
Kaliyan N, Morey RV (2009) Factors affecting strength and durability of densified biomass products. Biomass Bioenerg. 33, 337-359.
Kaliyan N, Morey RV (2010) Natural binders and solid bridge type binding mechanisms in briquettes and pellets made from corn Stover and switch grass. Bioresource Technology. 101, 1082- 1090.
Laei G (2021) Pistachio processing industrial plan report. Research project of Islamic Azad University, Damghan branch, Iran.
Larsson SH, Thyrel M, Geladi P, Lestander TA (2008) High quality biofuel pellet production from pre-compacted low density raw materials. Bioresource Technology. 99(15), 7176-7182.
McMullen J, Fasina OO, Wood CW, Feng Y (2005) Storage and handling characteristics of pellets from poultry litter. Applied Engineering in Agriculture. 21(4), 645-651.
Nielsen N (2009) Important of raw material properties in wood production – Effects of differences in wood properties for the energy requirements of pelletizing and pellet quality. Industrial PhD thesis. Copenhagen. University of Copenhagen.
Pickard GE, Roll WM, Ramser JH (1961) Fundamentals of hay wafering. Transactions of the ASAE 4. p. 65–68.
Rezaiefar J, Hassan-Beygi SR, Kianmehr MH, Azadegan B (2008) Physical properties of pelleted cattle manure. Journal of Agriculture. 10 (2), 53-68.
Rhen C, Gref R, Sjöström M, Wästerlund I (2005) Effects of raw material moisture content, densification pressure and temperature on some properties of Norway spruce pellets. Fuel Processing Technology. 87(1), 11-16.
Rouissi T, Mahmoudi A, Tyagi RD, Brar SK, Prèvost D, Surampalli RY (2013) Optimisation of spray drying by response surface methodology for the production of Sinorhizobium meliloti powder formulation by using starch industry wastewater. Biosystems Engineering. 114(3), 334-343.
Sahoo A, Sarkar S, Lal B, Kumawat P, Sharma S, De K (2021) Utilization of fruit and vegetable waste as an alternative feed resource for sustainable and eco-friendly sheep farming. Waste Management. 128, 232-242.
Salihoglu G, Salihoglu NK, Ucaroglu S, Banar M (2018) Food loss and waste management in Turkey. Bioresource Technology. 248, 88-99.
Shakeri P, Fazaeli H, Forough Ameri N (2004) The use of pistachio shelling residues in fattening diet of Kermani male lambs. The First National Congress of the Animal Science and Aquatic, P. 243.
Siddiqu Z, Hagare D, Jayasena V, Swick R, Rahman M, Boyle N, Ghodrat M (2021) Recycling of food waste to produce chicken feed and liquid fertilizer. Waste Management. 131, 386–393.
Tabatabaei kolor R, Motevali A, Hdipour R, Mavaddati S (2020) Effect of Temperature, Compression Force and Mixing Ratio of Materials on the Mechanical Properties of Pellets Made from Rice Bran and Sugarcane Molasses. Iranian Journal of Biosystems Engineering. 51(3), 551-561.
Thomas M, Van Vliet T, Van Der Poel AFB (1998) Physical quality of pelleted animal feed. 3. Contribution of feedstuff components. Animal Feed Science and Technology. 70(1-2), 59–78.
Tumuluru JS (2020) Biomass Densification: Systems, Particle Binding, Process Conditions, Quality Attributes, Conversion Performance, and International Standards. Springer Nature Switzerland AG, Biological Processing Department Idaho National Laboratory Idaho Falls, ID, USA.
Tumuluru JS, Wright CT, Hess JR, Kenney KL (2011) A review of biomass densification systems to develop uniform feedstock commodities for bioenergy application. Biofuels. Bioproducts and Biorefining. 5(6), 683-707.
Zafari A, Kianmehr MH (2014) Factors affecting mechanical properties of biomass pellet from compost. Environmental technology, 35(4), 478-486.
Zainuddin MF, Rosnah S, Noriznan MM, Dahlan I (2014) Effect of moisture content on physical properties of animal feed pellets from pineapple plant waste. Agriculture and Agricultural Science Procedia. 2, 224-230
