بررسی پارامترهای موثر بر جذب نشاسته از محلولهای آبی با نانوذرات آهن – کیتوزان
محورهای موضوعی :
آلودگی محیط زیست (آب و فاضلاب)
خشایار محمد بیگی
1
,
امیرحسام حسنی
2
,
سیده هدی رحمتی
3
,
امیرحسین جاوید
4
1 - دانشجوی دکتری مهندسی محیط زیست، دانشکده منابع طبیعی و محیط زیست، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران.
2 - استاد گروه مهندسی محیط زیست، دانشکده منابع طبیعی و محیط زیست، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران.
3 - استادیار گروه مهندسی محیط زیست، دانشکده منابع طبیعی و محیط زیست، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران. *(مسوول مکاتبات)
4 - استاد گروه مهندسی محیط زیست، دانشکده منابع طبیعی و محیط زیست، واحد علوم و تحقیقات، دانشگاه آزاد اسلامی، تهران، ایران.
تاریخ دریافت : 1400/09/01
تاریخ پذیرش : 1400/11/03
تاریخ انتشار : 1402/04/01
کلید واژه:
جذب,
نشاسته,
نانو ذرات,
کیتوزان,
ایزوترم,
چکیده مقاله :
زمینه و هدف: نشاسته به طور گسترده ای در صنایع غذایی، دارویی، کاغذسازی و منسوجات استفاده میشود پساب این واحدها دارای میزان اکسیژن بیولوژیکی بالایی است که لازم است تصفیه شود. در این پژوهش، قابلیت جذب نشاسته از محلول آبی با استفاده از نانو ذرات فلزی پوشش داده شده با کیتوزان، مورد بررسی و مطالعه قرار گرفت. با توجه به این که کیتوزان بیوپلیمری، غیر سمی، زیست سازگار و قابل تجزیه بیولوژیکی است و همچنین دارای ظرفیت جذب بالا، تجزیه پذیری، پایداری، سهولت تولید و هزینه کم میباشد، لذا امکان استفاده از این نانو ذرات در سیستمهای تصفیه پساب، میتواند مد نظر قرار گیرد.
روش بررسی: ابتدا نانو ذرات مگنتیتی کیتوزان تهیه گردید و مشخصات ساختار و ریخت شناسی این نانو جاذب بررسی شد. سپس عملکرد نانو جاذب و تاثیر پارامترهای موثر بر میزان جذب نشاسته، نظیر: زمان تماس، میزان جاذب، غلظت اولیه جذب شونده، دما و pH محلول، مطالعه شد.
یافتهها: نتایج نشان داد که امکان جذب نشاسته با نانو ذرات فلزی پوشش داده شده با کیتوزان میسر است و ماکزیمم درصد جذب در شرایط pH معادل 5 و مدت زمان تماس 60 دقیقه برابر 84 درصد بود. مطابق دادههای آزمایشی انطباق بالاتری با ایزوترم لانگمیر نسبت ایزوترم فروندولیچ دارند. همچنین نتایج نشان داد که این دادهها از مدل سینتیکی شبه مرتبه دوم تبعیت میکند.
بحث و نتیجه گیری: با توجه به نتایج اگرچه امکان کاهش میزان نشاسته با استفاده از نانو جاذب مغناطیسی کیتوزان میسر است ولی لازم است مطالعات پایلوتی و بررسی فنی و اقتصادی جهت امکان استفاده هیبریدی با روشهای متداول دیگر در تصفیه پساب واحدهای فرآورش نشاسته نیز انجام شود.
چکیده انگلیسی:
Background and Objective: Starch is widely used in food, pharmaceutical, paper & textile industry in large quantities. The wastewater of these units have high biological oxygen demand (BOD). In this study, the adsorption capacity of starch from aqueous solution was investigated using metal nanoparticles coated with chitosan. Due to the fact that chitosan biopolymer is non-toxic, biocompatible and biodegradable and also high adsorption capacity, degradability, stability, easily production and low cost, so the possibility of this nanoparticle can be considered in starch wastewater treatment.
Material and Methodology: First, magnetic nanoparticles was and the structure characteristics and morphology of this nano particle were investigated. Then, the performance of nano-adsorbent and the effect of effective parameters on starch uptake, such as contact time, adsorbent, initial adsorbent concentration, temperature and pH of the solution, were studied.
Finding: The results showed that it is possible the adsorption of starch with metal nanoparticles coated with chitosan. The maximum adsorption 84 present of starch is obtained at pH 5, contact time: 60 minutes and the dosage 2 mg of adsorbent per liter. According on experimental data are more compatible with the Langmuir isotherm than the Freundlich isotherm. The results also showed that these data follow a pseudo-second order kinetic model.
Discussion and Conclusion: According to the results, although it is possible to reduce the amount of starch by using magnetic chitosan nanosorbent, but it is necessary to pilot and techno- economical study to investigate hybrid use with other conventional methods in treatment system of starch processing units.
منابع و مأخذ:
Weibiao Ye. (2008). Research progress on starch wastewater treatment methods. Food and oil. 10 (4-7).
Xia Chen, Cuiju Zhang, Shaoyan Luan. (2013). Experimental study on treatment of starch wastewater by activated carbon adsorption. Journal of anhui agricultural sciences. 41(5524-5525).
Jianbo Mu, Hui Ren, Yigang Ding, et al. (2002). Application research of starch wastewater treatment by air-flotation integrated device. Henan chemical industry. 8(14-15).
Yong Tong, Gang Yan. (2016). Preparation of polyferric zinc silicate flocculant from Zn-containing sulfuric acid wastewater and its treatment of potato starch wastewater. Science and technology bulletin, 32(194-198).
Youle Wang, Baorong Zhang, Zhiming Fan. (2009). Study on compound microbial flocculant treatment of potato starch wastewater. Water treatment technology. 35(79-82).
Chaoping Cen. (2001). Flocculation treatment of cassava starch wastewater. Shanghai environmental science. 20 (31-32).
Deng S, et al. (2003). Characteristics of a bioflocculant produced by bacillus mucilagihosus and its use in starch wastewater treatment. Applied Microbiology and Biotechnology. 60(588- 5930).
E.M.P,Mai.S.T.Vlyssides. A.G. (2005). The dynamic modeling of the ratio volatile fatty acids/ bicarbonate alkalinity in a UASB reactor for potato processing waste water treatment, Water Treatment. 110 (121-128).
Hui Liu, Kangqun Zhou, Jieping Liu, Yiping Zhou. (2005). Journal of zhongkai Treatment of starch wastewater with microbial flocculant. Institute of agricultural technology. 17(45-50).
Tianhua Xu, Haiqing Cao. (2012)Treatment of high concentration industrial wastewater in corn starch plant by UASB anaerobic reactor. Science and technology information development and economics. 22 (144-146).
B. K. Annachhatre. A. P. (2004). Anaerobic ponds treatment of starch wastewater. case study in Thailand. Bioresource Technology. 95(135–143).
P. Annachhatre, Prasanna. L. Amatya. (2000). UASB Treatment of Tapioca Starch Wastewater Journal of Environmental Engineering. 40(1149-1159).
Xinkai Liao, Qingbiao Li, Wenmou Chen. (2004). Research on technological conditions of SRB method for treating simulated starch wastewater. Journal of xiamen university (natural science edition). 43(376-380).
Rajasimman M, Karthikeyan C. (2007). Aerobic digestion of starch wastewater in a fluidized bed bioreactor with low density biomass support. J. of Hazardous materials. 143(82-86).
Miao Wu. (2009) Design of wastewater treatment process of huaibei guwang starch plant. Heilongjiang environmental bulletin. 33(60-62).
Rajasimman M, Karthikeyan C (2007). Aerobic digestion of starch wastewater in a fluidized bed bioreactor with low density biomass support. J. of Hazardous materials. 143(82-86).
Villaverde S, García Encina P.A. Lacalle M.L. and Fdz-Polanco F (2000). New operational strategy for SBR technology for total nitrogen removal from industrial wastewaters highly loaded with nitrogen, Water Science and Technology.41 (85-93).
Fakai Xu. (2012).Application of expanded granular sludge bed (EGSB) reactor in corn starch wastewater treatment, Innovation technology. 28 (55-57).
Genyuan Zhang. (2013). Application of EGSB anaerobic reactor to treat wheat starch wastewater and biogas by-product. Environmental engineering. 12 (80-81).
Yunzhi Deng. (2009). Design of starch wastewater treatment project in a starch factory in Yunnan Province. Guangxi light industry. 12(93-94).
Yong Chen, Gang Li, Yinping Xin. (2015) Modification and operation effect of amylase plant wastewater treatment project, China water & wastewater. 31(101-103).
Ping Li, Wenying Xu. (2009). Anaerobic (IC reactor) / aerobic combined treatment of starch production wastewater. China water & wastewater. 25(52-54).
Tongbo Cai, Hua Lin, Zhaojun Liu, Kaiwei Chen, Yi Lin, Yuan Xi, Kong Chhuond. (2019). Starch wastewater treatment technology. IOP Conf. Series. Earth and Environmental Science 358 (022054).
V. Nesterov, A. S. Lisyanskii, E. I. Makaroval. Ya. Bal, P. Yu. Prikhod. (2011). The thermal process diagram and equipment of the secondary coolant circuit of a nuclear power station unit based on the BREST-OD-300 reactor installation for subcritical steam conditions. Therm. Eng. 58 (478-482).
Palanikumar S. Kannammal L. Meenarathi B. Anbarasan R. (2014). Effect of folic acid decorated magnetic fluorescent nanoparticles on the sedimentation of starch molecules. Int Nano Lett. 4(104-108).
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Weibiao Ye. (2008). Research progress on starch wastewater treatment methods. Food and oil. 10 (4-7).
Xia Chen, Cuiju Zhang, Shaoyan Luan. (2013). Experimental study on treatment of starch wastewater by activated carbon adsorption. Journal of anhui agricultural sciences. 41(5524-5525).
Jianbo Mu, Hui Ren, Yigang Ding, et al. (2002). Application research of starch wastewater treatment by air-flotation integrated device. Henan chemical industry. 8(14-15).
Yong Tong, Gang Yan. (2016). Preparation of polyferric zinc silicate flocculant from Zn-containing sulfuric acid wastewater and its treatment of potato starch wastewater. Science and technology bulletin, 32(194-198).
Youle Wang, Baorong Zhang, Zhiming Fan. (2009). Study on compound microbial flocculant treatment of potato starch wastewater. Water treatment technology. 35(79-82).
Chaoping Cen. (2001). Flocculation treatment of cassava starch wastewater. Shanghai environmental science. 20 (31-32).
Deng S, et al. (2003). Characteristics of a bioflocculant produced by bacillus mucilagihosus and its use in starch wastewater treatment. Applied Microbiology and Biotechnology. 60(588- 5930).
E.M.P,Mai.S.T.Vlyssides. A.G. (2005). The dynamic modeling of the ratio volatile fatty acids/ bicarbonate alkalinity in a UASB reactor for potato processing waste water treatment, Water Treatment. 110 (121-128).
Hui Liu, Kangqun Zhou, Jieping Liu, Yiping Zhou. (2005). Journal of zhongkai Treatment of starch wastewater with microbial flocculant. Institute of agricultural technology. 17(45-50).
Tianhua Xu, Haiqing Cao. (2012)Treatment of high concentration industrial wastewater in corn starch plant by UASB anaerobic reactor. Science and technology information development and economics. 22 (144-146).
B. K. Annachhatre. A. P. (2004). Anaerobic ponds treatment of starch wastewater. case study in Thailand. Bioresource Technology. 95(135–143).
P. Annachhatre, Prasanna. L. Amatya. (2000). UASB Treatment of Tapioca Starch Wastewater Journal of Environmental Engineering. 40(1149-1159).
Xinkai Liao, Qingbiao Li, Wenmou Chen. (2004). Research on technological conditions of SRB method for treating simulated starch wastewater. Journal of xiamen university (natural science edition). 43(376-380).
Rajasimman M, Karthikeyan C. (2007). Aerobic digestion of starch wastewater in a fluidized bed bioreactor with low density biomass support. J. of Hazardous materials. 143(82-86).
Miao Wu. (2009) Design of wastewater treatment process of huaibei guwang starch plant. Heilongjiang environmental bulletin. 33(60-62).
Rajasimman M, Karthikeyan C (2007). Aerobic digestion of starch wastewater in a fluidized bed bioreactor with low density biomass support. J. of Hazardous materials. 143(82-86).
Villaverde S, García Encina P.A. Lacalle M.L. and Fdz-Polanco F (2000). New operational strategy for SBR technology for total nitrogen removal from industrial wastewaters highly loaded with nitrogen, Water Science and Technology.41 (85-93).
Fakai Xu. (2012).Application of expanded granular sludge bed (EGSB) reactor in corn starch wastewater treatment, Innovation technology. 28 (55-57).
Genyuan Zhang. (2013). Application of EGSB anaerobic reactor to treat wheat starch wastewater and biogas by-product. Environmental engineering. 12 (80-81).
Yunzhi Deng. (2009). Design of starch wastewater treatment project in a starch factory in Yunnan Province. Guangxi light industry. 12(93-94).
Yong Chen, Gang Li, Yinping Xin. (2015) Modification and operation effect of amylase plant wastewater treatment project, China water & wastewater. 31(101-103).
Ping Li, Wenying Xu. (2009). Anaerobic (IC reactor) / aerobic combined treatment of starch production wastewater. China water & wastewater. 25(52-54).
Tongbo Cai, Hua Lin, Zhaojun Liu, Kaiwei Chen, Yi Lin, Yuan Xi, Kong Chhuond. (2019). Starch wastewater treatment technology. IOP Conf. Series. Earth and Environmental Science 358 (022054).
V. Nesterov, A. S. Lisyanskii, E. I. Makaroval. Ya. Bal, P. Yu. Prikhod. (2011). The thermal process diagram and equipment of the secondary coolant circuit of a nuclear power station unit based on the BREST-OD-300 reactor installation for subcritical steam conditions. Therm. Eng. 58 (478-482).
Palanikumar S. Kannammal L. Meenarathi B. Anbarasan R. (2014). Effect of folic acid decorated magnetic fluorescent nanoparticles on the sedimentation of starch molecules. Int Nano Lett. 4(104-108).