Evaluation of the Physical and Chemical Treatment of Wastewater for the Dairy Industry
محتوى المقالة الرئيسي
الملخص
Dairy wastewater generally contains fats, lactose, whey proteins, and nutrients. Casein precipitation causes the effluent to decompose into a dark, strong-smelling sludge. Fluid waste contains soluble organic matter, suspended solids, and gaseous organic matter, which cause undesirable taste and smell, grant tone and turbidity, and advance eutrophication, which plays an essential role in increasing biological oxygen demand (BOD) in water. It also contains detergents and disinfecting agents from the rinses and washing processes, which increase the need for chemical oxygen (COD). One of the characteristics of dairy effluents is their relatively high temperature, high organic contents, and wide pH range, so the discharge of wastewater into water bodies without treatment leads to deterioration of water quality and ecological imbalance, and therefore treatment is required. To remove or reduce environmental damage. Dairy wastewater treatment includes mechanical, physical, chemical, and biological methods.
Organic treatment techniques are reasonable for treating wastewater from the dairy business because of their high biodegradability. Notwithstanding, the long-chain unsaturated fats framed during lipid hydrolysis show an inhibitory impact during anaerobic treatment. Chain block reactors (SBR) and top stream anaerobic slop cover of sludge (UASB) frameworks are the most encouraging advancements for the organic treatment of dairy wastewater. Many papers have applied high-impact exercise and technical methods to the dairy business's anaerobic wastewater treatment of dairy wastewater. However, the two techniques actually have a few disadvantages. The most vital objective of these studies is to track down savvy and naturally manageable ways to deal with and empower the reuse and management of wastewater and waste. Consequently, elective treatments to organic treatment are physical and substance techniques, for example, coagulation, retention, layer cycles, and electrolysis. This section gives a primary survey zeroing in on physical and compound treatment strategies for dairy wastewater treatment. It is under study and checked for its viability.
تفاصيل المقالة
القسم
كيفية الاقتباس
المراجع
Aghili F., Ghoreyshi A.A., Rahimpour A., and Rahimnejad M., 2016. Enhanced treatment of pretreated
sour whey by PAC adsorption/ membrane process, Chemical Engineering and
Processing, 99:80-85. DOI: 10.1016/j.cep.2015.11.006
Al-Jabari M., 2017. Kinetic mass transfer adsorption model for treating dairy wastewater with
stone cutting solid waste, Environmental Technology and Innovation, 7:21-29. DOI:
1016/j.eti.2016.11.004
Andrade L.H., Mendes F.D.S., Espindola J.C., and Amaral M.C.S., 2014. Nanofiltration as tertiary treatment for the reuse of dairy wastewater treated by membrane bioreactor, Separation and
Purification Technology, 126:21-29. DOI: 10.1016/j.seppur.2014.01.056
Bazrafshan E., Moein H., Mostafapour F.K., and Nakhaie S., 2013. Application of electrocoagulation
process for dairy wastewater treatment, Journal of Chemistry, 8:Article ID 640139.
DOI: 10.1155/2013/640139
Beneois K., Dahmani S., and Berrebah K., 2016. Efficiency and limits of physicochemical treatment of dairy wastewater. (Case Study: Dairy industry in Western Algeria), International Journal
of Chemical, Environmental and Biological Sciences, 4(1):9-11. ISSN: 2320-4087
Blanc F., and Navia R., Treatment of dairy wastewater by chemical coagulation. In: Proceedings
of the 45th Industrial Waste Conference; Pardue University, USA. pp. 681-689
Britz T.J., Van Sckalkwyk C., and Hung Y.T., 2004. Treatment of Dairy Processing Wastewater:
Handbook of Industrial and Hazardous Waste Treatment. 2nd ed. New York: Marcel Dekker, pp. 616-646. DOI: 0-8493-7236-4
Bulletin of the International Dairy Federation, 2016. The World Dairy Report No: 485/216.
Chen J.P., Chang S.Y., and Hung Y.T., 2005. Electrolysis, Phsysicochemical Treatment Processes, In Wang LK, Hung YT, Shammas NK, editors, Totowa, New Jersey: Humana Press Inc., pp. 359-376. DOI: 10.1385/159259820x
Cristian O., 2010. Characteristics of the Untreated Wastewater Produced by Food Industry.
Analele Universităţii din Oradea, Fascicula: Protecţia Mediului, p. XV
Dabhi Y.M., 2013. Physicochemical treatment of dairy plant wastewater using ferrous sulphate and ferric chloride coagulants, International Journal of Basic and Applied Chemical Sciences, 3(4):9-14
Demirel B., Yenigün O., and Onay T.T., 2005. Anaerobic treatment of dairy wastewater: A review,
Process Biochemistry, 40:2583-2595. DOI: 10.1016/j.procbio.2004.12.015
Deshmukh D.S., 2017. Wastewater generation and its treatment in dairy industries, International Journal of Application of Engineering and Technology, 2(3):25-35. ISSN: 2321-8134
Hamdani A., Chennaoui M., Assobhei O., and Mountadar M., 2004. Dairy effluent characterization
and treatment by coagulation decantation, Le Lait, 84(3):317-328
Hung Y.T., Lo H.H., Wang L.K., Taricksa J.R., Li K.H., 2005. Granular activated carbon adsorption: Phsysicochemical treatment processes, Phsysicochemical Treatment Processes. Totowa, New Jersey: Humana Press Inc., pp. 573-630. DOI: 10.1016/j.watres.2010.07.001
Jasim, N. A., and Ibrahim, J. A. K., 2020. Stabilization of Al-Rustamiya Waste Water Treatment Plant Sludge Using Lime, Journal of Engineering, 26(9), pp. 165–172. doi: 10.31026/j.eng.2020.09.11.
Karpati A., Bencze L., and Boszeki J., 1989. New phisico-chemical pretreatment of dairy effluents,
In: Proceedings of International Symposium on Waste Management Problems in Agro
Industries; İstanbul, pp. 121-128
Khudair B. H., and Jasim, S. A., 2017. Performance Evaluation of Sequencing Batch Reactor and Conventional Wastewater Treatment Plant based on Reliability assessment, Journal of Engineering, 23(11), pp. 97–112. Available at: https://joe.uobaghdad.edu.iq/index.php/main/article/view/365 (Accessed: 6 March 2022).
Kurzbaum E., and Shalom O.D., 2016. The potential of phosphate removal from dairy wastewater
ad municipal wastewater effluents using a lanthanum modified bentonite, Applied Clay
Science, 123:182-186. DOI: 10.1016/j.clay.2016.01.038
Kushwaha J.P., Srivastana C., and Mall I.D., 2011. An overview of various technologies for the treatment of dairy wastewaters. Critical Reviews in Food Science and Nutrition, 51:442- 452. DOI: 10.1080/10408391003663879
Kuswaha J.P., Srivastava V.C., and Mall I.D., 2010. Organics removal from dairy wastewater by electrochemical treatment and residue disposal, Separation and Purification Technology, 76:198-205. DOI: 10.1016/j.watres.2010.07.001
Lolei M., Alidadi H., Nekonam G., and Kor Y., 2013. Study of the coagulation process in wastewater
treatment of dairy industries, International Journal of Environmental Health
Engineering, 2(5):17-21. DOI: 10.4103/2277-9183.132684
Markou V., Kontogianni M.C., Frontistis Z., Tekerlekopoulou A.G., Katsonous A., and Vayenas
D., 2017. Electrochemical treatment of biologically pre-treated dairy wastewater using dimensionally
stable anodes, Journal of Environmental Management, 202:217-224. DOI:
1016/j.jenvman.2017.07.046
Marshall K.R., and Harper W.J., 1984. Treatment of wastes from the dairy industry. In: Barnes D.,
Forster C.F., Hrudey S.E., editors, Surveys in Industrial Wastewater Treatment, Vol. 1., Boston: Pitman Advanced Publishing Program, pp .296-376
Melchiors M.S., Piovesan M., Becegato V.R., Becegato V.A., Tambourgi E.B., and Paulino A.T., 2016. Treatment of wastewater from the dairy industry using electroflocculation and solid
whey recovery, Journal of Environmental Management, 182:574-580. DOI: 10.1016/j.
jenvman.2016.08.022
Qazi J.I., Nadeem M., Baig S.S., Baig S., and Syed Q., 2011. Anaerobic fixed film biotreatment of
dairy wastewater, Middle-East Journal of Scientific Research, 8(3):590-593. ISSN:
-9233
Sarkar B., Chakrabarti P.P., Vijaykumar A., and Kale V., 2005. Wastewater treatment in dairy industries: Possibility of reuse. Desalination, 195:141-152. DOI: 10.1016/j.desal.2005.11.015
Sarkar B., Chakrabari P.P., Viyajkumar A., Kale V., 2006. Wastewater treatment in dairy industries-possibility of reuse. Desalination, 195:141-152. DOI: 10.1016/j.desal.2005.11.015
Sharma D., 2014. Treatment of dairy wastewater by electrocoagulation using aluminum
electrodes and settling, filtration studies, International Journal of ChemTech Research, 6(1):591-599. ISSN: 0974-4290
Shete B.S., and Shinkar N.P., 2013. Dairy industry wastewater sources, characteristics and its effects on environment. International Journal of Current Engineering and Technology, 3(5):
-1615. ISSN: 2277-4106
Shivsharan V.S., Kulkarni S.W., and Wani M., 2013. Physicochemical characterization of dairy effluents, International Journal of Life science and Pharma Research, 2(2):182-191. ISSN: 2250-3137
Shivsharan V.S., Kulkarni S.W., and Wani M., 2014. Physicochemical characterization of dairy effluents, International Journal of Life science and Pharma Research, 2(2):182-191. ISSN: 2250-3137
Sivrioğlu Ö., and Yonar T., 2015. Determination of the acute toxicities of physicochemical pretreatment and advanced oxidation processes applied to dairy effluents on activated sludge, Journal of Dairy Science, 98(4):2337-2344. DOI: 10.3168/jds.2014-8278
SKKY: Su Kirliligi Kontrol Yonetmeligi (Water Pollution and Control Regulation), T.C.
Basbakanlik Mevzuati Gelistirme ve Yayin Genel Mudurlugu, 2004. p. 54. Available
from: http://mevzuat.basbakanlik.gov.tr
Suarez A., Fidalgo T., and Riera F.A., 2014. Recovery of dairy wastewaters by reverse osmosis, Production of boiler water, Separation and Purification Technology, 133:204-211. DOI: 10.1016/j.seppur.2014.06.041
Rao M., and Bhole A.G., 2002. Removal of organic matter from dairy industry wastewater using
low-cost adsorbents, Journal of Indian Chemical Engineer, Section A, 44(1):25-28
Rusten B., Eikebrokk B., and Thorvaldsen G., 1990. Coagulation as pretreatment of food industry
Wastewater, Water Science and Technology, 22:1-8
Tawfika A., Sobheyb M., Badawya M., 2008. Treatment of a combined dairy and domestic wastewater in an up-flow anaerobic sludge blanket (UASB) reactor followed by activated
sludge (AS system), Desalination, 227(1-3):167-177. DOI: 10.1016/j.desal.2007.06.023
Tchamango S., Njiki C.P.N., Ngameni E., Hadjiev D., and Darchen A., 2010. Treatment of dairy effluents by electrocoagulation using aluminum electrodes, Science of the Total Environment, 408:947-952. DOI: 10.1016/j.scitotenv.2009.10.026
Tikariha A, Omprakash S., 2014 Study of characteristics and treatments of dairy industry
wastewater. Journal of Applied & Environmental Microbiology, 2(1):16-22. DOI:
12691/jaem-2-1-4
Tzoupanas N.D., and Zouboulis A.I., 2008. Coagulation-Flocculation processes in water/wastewater
treatment: The application of new generation of chemical reagents, In: Proceedings of the
th International Conference on Heat Transfer, Thermal Engineering and Envıronment
(HTE'08); 20-22 Aug., Greece
Vaccari D.A., Li Y., and Shammas N.K., 2005. Chemical precipitation, Phsysicochemical Treatment Processes, Totowa, New Jersey: In Wang LK, Hung YT, Shammas N.K., editors, Humana Press Inc., pp. 141-174. DOI: 10.1016/j.watres.2010.07.001
Vignesvaran S., Ngo H.H., Chaudry D.S., and Hung Y.T., 2005. Physicochemical treatment processes
for water reuse, Phsysicochemical Treatment Processes, , In: Wang LK, Hung YT, Shammas NK, editors, Totowa, New Jersey: Humana Press Inc., pp. 359-376. DOI:
1385/159259820x
Vourch M., Balannec B., Chaufer B., and Dorange G., 2008. Treatment of dairy industry wastewater
by reverse osmosis for water reuse, Desalination, 219:190-202. DOI: 10.1016/j.
desal.2007.05.013
Yavuz Y., Öcal E., Koparal A.S., and Öğütveren Ü.B., 2011. Treatment of dairy industry wastewater
by EC and EF processes using hybrid Fe-Al plate electrodes, Journal of Chemical
Technology and Biotechnology, 86(7):964-969. DOI: 10.1002/jctb.2607
Yonar T., and Sivrioğlu Ö., 2017. Electrochemical degradation of dairy effluent using novel Sn/Sb/
Ni-Ti anodes, Journal of Physical Chemistry and Biophysics, 7:2. In: 3rd International
Conference on Electrochemistry, 10-11 July, Berlin, Germany