A STUDY ON TREATMENT OF INDUSTRIAL EFFLUENT (DYEING) USING MORINGA OLEIFERA, TAMARINA INDICA AS COAGULANTS
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International Journal of Civil Engineering and Technology (IJCIET) Volume 10, Issue 3, March 2019, pp. 550-565. Article ID: IJCIET_10_03_057 Available online at http://www.iaeme.com/ijciet/issues.asp?JType=IJCIET&VType=10&IType=3 ISSN Print: 0976-6308 and ISSN Online: 0976-6316 © IAEME Publication Scopus Indexed A STUDY ON TREATMENT OF INDUSTRIAL EFFLUENT (DYEING) USING MORINGA OLEIFERA, TAMARINA INDICA AS COAGULANTS Dr. A. Mani Head, Department of Civil Engineering, Bharath Institute of Higher Education and Research T.P. Meikandaan Associate Professor, Department of Civil Engineering, Bharath Institute of Higher Education and Research P.G. Gowrishankar PG Student, Bharath Institute of Higher Education and Research Dr. T. E. Kanchanabhan Professor, Department of Civil Engineering, Bharath Institute of Higher Education and Research. ABSTRACT The doable utilization of common coagulants for the treatment of coloring waste water in SIPCOT industry is abridged in this paper. The distinctive common coagulants like Moringaoleifera, Tamarinaindica, Strychonomouspotatorum of 10, 20, 40, 60 ml doses will be utilized to recognize the appropriate one as essential coagulant. To decide the ideal measurement of regular coagulants flocculation procedure will be considered in lab. The different parameters, for example, pH, turbidity, TSS, TDS, BOD, and COD will be dissected with coloring profluent by including of regular coagulants. Results will be dissected to discover the best characteristic coagulant for evacuation efficiencies concerning turbidity, TSS, TDS, COD and BOD. Keywords: characteristic Strychonomouspotatorum coagulants, http://www.iaeme.com/IJCIET/index.asp 550 Moringaoleifera, Tamarinaindica, editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants Cite this Article: Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan, A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants, International Journal of Civil Engineering and Technology, 10(3), 2019, pp. 550-565. http://www.iaeme.com/IJCIET/issues.asp?JType=IJCIET&VType=10&IType=3 1. INTRODUCTION 1.1. Textile Industry India is the world's second real producer of materials and pieces of clothing after china. The material and article of clothing industry in India is one of the most established assembling areas in the nation and is as of now it's biggest. The material and piece of clothing industry satisfies a critical job in the Indian economy. As of late, it was seen that sipcot enterprises were encountering extreme ecological issues because of material coloring, cowhide tanning, paper and mash handling, ventures, and so forth. Material industry includes wide scope of crude materials, apparatuses and procedures to trap the required shape and properties of the last item. The primary driver of age of this gushing is the utilization of gigantic volume of water either in the real substance handling or amid re-preparing in preliminary, coloring, printing and wrapping up. Material wastewater poisons are commonly burning soft drink, cleansers, starch, wax, urea, smelling salts, shades and colors that expansion its BOD, COD, strong substance and poisonous quality. The treatment strategies for waste-water incorporate enacted carbon adsorption, oxidation, substance coagulation/flocculation, electrochemical strategies, layer methods and natural treatment forms are much of the time used to treat material effluents. These procedures are commonly proficient for Biochemical oxygen request (BOD) and suspended solids (SS) evacuation, however they are to a great extent incapable for expelling shading from the wastewater. Contingent upon the waste-water qualities, COD of a material emanating can be decreased somewhere in the range of 50 and 70 % in the wake of advancing the working conditions, for example, pH, coagulant and flocculants fixation. Coagulation is a basic procedure in the treatment of modern wastewater. Its application incorporates expulsion of broke up compound species and turbidity from water by means of expansion of ordinary synthetic based coagulants, in particular alum, ferric chloride and polyaluminium chloride. The inconveniences related with utilization of these coagulants, for example, inadequate ness in low-temperature water, moderately high acquirement costs, negative impacts on human wellbeing, generation of expansive muck volumes and the way that they fundamentally influence pH of treated water. To neutralize the previously mentioned downsides, it is lucky to reestablish these concoction coagulants with common coagulants. India is rich in water resources, having a network of as many as 113 rivers and vast alluvial basins to hold plenty of groundwater. India is also blessed with snow capped peaks in the Himalayan ranges, which can meet a variety of water requirement of the country. However, with the rapid increase in the population of the country and to meet the increasing demands of irrigation, domestic and industrial consumption, the available water resources in many parts of the country are getting depleted and the water quality has deteriorated. The most significant environment problem and threat to public health in both rural and urban India is inadequate access to clean drinking water and sanitation facilities. Almost all the surface water sources are contaminated to some extent by organic pollution and bacterial http://www.iaeme.com/IJCIET/index.asp 551 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan contamination and make them unfit for human consumption unless disinfected. The diseases commonly caused by contaminated water are typhoid, cholera, gastroenteritis, bacterial dysentery, hepatitis, poliomycitis, amoebic dysentery etc. In India, water pollution comes from three main sources: domestic sewage, industrial effluents and run off from agriculture. Rapid industrialization is adversely impacting the environment globally. Pollution by in appropriate management of industrial wastewater is one of the major environment problems in India as well, especially with burgeoning small-scale industrial sector in the country. It is estimated that 22,900 Million Liters per Day (MLD) of domestic wastewater is generated from urban centers and about 13,500 MLD from industrial sector. The treatment capacity available for domestic wastewater is only for 5,900 MLD where as 8,000 MLD in case of industrial wastewater. To address the pollution coming out from industries, adoption of cleaner production technologies and waste minimization initiatives are being encouraged. Presently, 6.2 billion liters of untreated industrial wastewater is generated every day that causes pollution and reduces available freshwater reserves. This necessitates that government should take initiatives and encourage large industries to set up their own treatment plants to reduce the wastewater by reusing the treated water for industrial purposes. Thermal power and steel plants are the highest generators of industrial wastewater followed by textile and food processing industry. Common Effluent Treatment Plants (CETPs) are considered as one of the viable solution for small to medium enterprises for effective wastewater treatment. Wastewater generated by small and medium industries need to be transported to the Common Effluent Treatment Plant (CETP) by pumping of effluent from these industries. The effluent through pumping stations initially reaches a stilling/inlet chamber, after which it flows into the oil and grease (O&G) chamber for removing these from the wastewater, using a skimming mechanism. During this process, air and chlorine are injected into the chamber and the separated oil and grease is then disposed. Wastewater moves from the O&G chamber to be collected in the screen chamber for removal of floating materials in the effluent. Apart from floating materials and O&G, the effluent also contains solid particles like grit and sand. The treatment process is a multifaceted task that needs to be planned and controlled in a sequential manner in order to meet the required discharge standards. Plant is designed to meet the specific demands of wastewater to be treated. The treatment processes for various effluents originating from different industrial sources are different. However, in India many of the operating CETPs are not performing optimally due to various technical and managerial reasons. Physic-chemical treatment of wastewater was widely practiced until the late 19th century, until the advent of the trickling filter for biological treatment. The early 1970s saw a partial revival of interest that has continued to the present day, particularly for treatment plants that are overloaded during peak flow events. The addition of coagulant chemicals to primary clarifiers, or to other dedicated physical separation process, is a effective way of reducing the load to downstream biological process, or in some cases for direct discharge. This practice is generally referred to as chemically enhanced primary treatment, or CEPT. Principle disadvantages that might preclude a wholly physic-chemical solution to wastewater treatment are the problems associated with the sludge produced, and the high operating costs of chemical addition. However, much of the current interests in physic-chemical treatment stem from its suitability for treatment under emergency measures; for seasonal applications, to avoid excess wastewater discharges during storm events; and for primary treatment before biological treatment, where the above disadvantages become lesser impact. http://www.iaeme.com/IJCIET/index.asp 552 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants CEPT can also be an effective first step for pollution control in developing countries particularly in large urban area that has evolved with sewerage system but without centralized waste water treatment, that have limited financial resources for complete, but capitalintensive biological treatments options such as activated sludge systems. Such urban development’s also may not have the areas available for appropriate technology options such as stabilization pond processes. The efficiency of CEPT, in terms of BOD or COD removal, depends on waste water characteristics. With CEPT, one can expect to remove particulate components, together with some portion of the colloidal components. Therefore, with such a waste water, it is feasible to achieve removals of more than: 95% TSS: 65% COD: 50% BOD: 20% Nitrogen and 90% phosphorus. In practice, removals may be lower or higher, for example: in warmer climates, with larger collection systems, and relatively flat sewers, one would expect a higher soluble fraction, and lower overall removals with CEPT. On the other hand, if the collection system is relatively small, the climate is cold, and waste water is relatively fresh, there may be a higher proportion of particulate material and CEPT removals could be higher. Staged coagulation- flocculation can enhance CEPT performance. 1.2. Textile and Dye Industry Dyes and textile industry are one of the most important and continuously developing industrial sector especially in India. The textile is classified into three main categories: cellulose fibres (cotton, rayon, linen, ramie, hemp and lyocell), protein fibres (wool, angora, mohair, cashmere and silk) and synthetic fibres (polyester, nylon, spandex, acetate, acrylic, ingeo and polypropylene). The type of dyes and chemicals used in the textile industry are found to differ depending on the fabrics manufactured. Reactive dyes (remazol, procion MX and cibacron F), direct dyes (congo red, direct yellow 50 and direct brown 116), naphthol dyes (fast yellow GC, fast scarlet R and fast blue B) and indigo dyes (indigo white, tyrian purple and indigo carmine) are some of the dyes used to dye cellulose fibres. Protein fibres are dyed using acid dyes (azo dyes, triarylmethane dyes and anthraquinone dyes) and lanaset dyes (Blue 5G and Bordeaux B). Other dyes, like dispersed dyes (Dispersed yellow 218 and disperse navy 35), basic dyes (basic orange 37 and basic red 1) and direct dyes are used to dye synthetic fibres.During the dying process, the dye is dissolved into the process water and it is still there when the process water later is released as effluent. The effluent contains high content of dyestuffs, surfactants and other additives that are generally made up of organic compounds with a complex structure. The dissolved dye compounds of the effluent or resistant to light, acids, bases and oxygen, as these are the desired properties of the dyed clothes. It’s therefore difficult to treat textile wastewater with conventional methods as these organic compounds have poor bio-degradability. The colour wastewaters of these industries are harmful to the aquatic life in the rivers and lakes due to reduced light penetration and the presence of highly toxic metal complex dyes. The main environmental concern of textile wastewater lies in the dissolved organic dye compounds as some of them are aromatics and considered carcinogenic, also it consumes huge volumes of processed water and produces highly polluted colour wastewater. Removal of these pollutants require strategies for selecting most appropriate method/methods from physic-chemical treatment, bio oxidation, biological treatment, activate sludge treatment, micro filtration, coagulation, flocculation process, Fenton oxidation, adsorption, electrochemical oxidation and electro coagulation, cavitations etc. Among these, coagulation flocculation has historically attracted considerable attention for its high removal efficiency. For the treatment of dyes/textile industry http://www.iaeme.com/IJCIET/index.asp 553 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan wastewater, biological treatment, chemical treatment and combinations of these are used. In wastewater treatment plants utilising biological treatment rather than chemical processes is largely ineffective. It is therefore imperative that process intensification be explored by enhancing existing treatment processes using new materials methods/ processes. 1.3. Coagulates and Coagulation Mechanisms Conventional chemical coagulants, namely alum, ferric chloride and Poly Aluminium Chloride (PAC) etc are used for the treatment of wastewater from various industries like tannery, textile, meat processing and so on. But the disadvantages associated with chemical coagulants include high operation costs, ineffectiveness in low temperature water, large sludge volume, significant effect on pH of the waste water and studies have reported that. Inorganic coagulants have several ecotoxicological impacts and when released into the aquatic systems may continue to cycle between the sediments. However, some studies have reported that aluminium that remains in the water after coagulation may induce Alzheimer’s disease. In view of the limitations of chemical coagulants and the possibility of serious threat to public health arising due to biological amplification, it is instructive to design and develop alternative coagulants that are environment friendly, inexpensive and practically implementable. 1.4. Natural Coagulants Polymer coagulants can be cationic, anionic or non-ionic, in which the former two are collectively termed as polyelectrolytes. Many studies concerning natural coagulants referred to them as polyelectrolyte’ even through many of these studies did not actually conduct indepth chemical characterization to determine their ionic activity. As such, this term should be used carefully and be applies only after ionic activity is determined to be present in the coagulant. Natural coagulants are mostly either polysaccharides or proteins. In many cases, even though polymer labeled as non- ionic are not necessarily absent of charged interactions, as there may be interactions between the polymer and a solvent within a solution environment as the polymer may contain partially charged groups including OHalong its chain. It is imperative to fully grasp the underlying coagulation mechanism associated with these natural coagulants so that complete underlying of their usage can be realized. Aggregation of particles in a solution can occur via four classic coagulation mechanisms: a) double layer compression b) sweep flocculation c) adsorption and charge neutralization and d) adsorption and inter particle bridging. The presence of salts (or suitable coagulants) can cause compression of the double layer which destabilizes the particulates. Sweep flocculation occurs when a coagulant encapsulates suspended particulates with oppositely charged ions while inter particle bridging occurs when a coagulant provides polymeric chain which sorbs particles. In this present study, three types of natural material were selected from which the coagulant is to be prepared. They are Moringaoleifera, Tamarinaindica and Strychonomouspotatorum. http://www.iaeme.com/IJCIET/index.asp 554 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants 1.5. Merits of Natural Coagulants The main advantage of using natural coagulants as waste treatment material are mentioned in the Table 1.1 the advantages are especially augmented if the plant from which the coagulation is extracted in indigenous to rural community. Usage of natural coagulant for treatment of textile waste water being new and prominent way in removal of dye from the effluent wastewater. Table 1.5 ADVANTAGES OF USING NATURAL COAGULANT Parameters Cost Toxicity Corrosiveness Sludge characteristics pH Fragrance Conventional Chemical Coagulants Sustainable and economical Complex and expensive Nontoxic to environment Highly toxic Noncorrosive to the materials Highly corrosive due to alkalinity Small amount of Large amount of hazardous &nonnonhazardous& biodegradable biodegradable sludge sludge Do not alter the pH of water More changes in pH due to under treatment metallic salts Acts as a deodorant agent Offensive odour due to forming insoluble complexes decomposed chemicals in the with organic species sludge Natural Coagulants 1.6. Dye Processing Modern dyeing technology consists of several step selected according to the nature of the fibre and properties of the dyes and pigments for use in fabrics, such as chemical structure, classification, commercial availability, fixing properties compatible with the target material to be dyed, economic considerations and many others. Dyeing methods have not changed much with time. Basically water is used to clean, dye and apply auxiliary chemicals to the fabrics, and also to rinse the treated fibres or fabrics. The dyeing process involves three steps: preparation, dyeing and finishing, as follows. 1.6.1. Dye Wastewater Textile dyeing industry is one of the most water consuming industries after thermal, engineering pulp and paper industries. In India water consumed by textile industries in the year of 2010 was around 1900 mm3(Million cubic meters) and effluent water generated was around 75 per cent of its intake. As the textile industry is one of the most water consuming industries in the country. The dye stuff lost in the textile industry poses a major problem to wastewater sources and indeed, textile industry produces high levels of dye and floating solid materials. It is estimated that 5000 tons of dyeing materials are discharged into the environment every year. These poisonous materials absorb the oxygen of the water and his risen much as it threatens human life and the environment. Industrial wastewaters contain various kinds of toxic substances such as cyanides, alkaline cleaning agents, degreasing solvents, oil, fat, and metals. A chain of operations involving receiving and storing of raw materials, processing of raw materials into finished products, packed and storing of finished products, and a group of other operations will produce wastewater. In the textile industry, some amount of wastewater gets http://www.iaeme.com/IJCIET/index.asp 555 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan produced during starting, equilibrating, dyeing and rinsing of the processing units. Dyeing processing effluents are generated in an intermittent way and the flow rates of these effluents change significantly. The quantity of the product content in the dyeing wastewater at a given time changes with the application of another technological cycle in the processing line. 1.6.2. Treatment of Dyeing Effluent The highly variable nature of dyeing wastewaters in terms of volumes and flow rates and in terms of pH and total dissolved solids content makes the choice of an effective wastewater treatment regime difficult. Because dyeing wastewaters are highly biodegradable, they can be effectively treated with biological wastewater treatment systems, but can pose a potential environmental hazard if not treated properly. 1.7. Objective of the Study The main aim of this present study is, 1. To characterize the dyeing wastewater. 2. To characterize the natural coagulant using analytical techniques. 3. To determine the optimum coagulant dosage using analytical techniques. 4. To determine dye removal efficiency in terms of BOD &COD removal. 5. To perform optimization by varying parameters such as pH, settling time. 1.8. Scope of the Study Dyeing wastewater has been associated with the increased incidence and severity of aquatic life. Textile dyes contamination in surface and ground water is becoming a growing issue due to excessive usage. The dyes contaminated wastewater leads to various range of environmental and health effects. So, this study scopes to find out an efficient solution for the treatment of textile dyes contaminated water using coagulants which is locally available and found to be economical. 2. LITERATURE REVIEW 2.1. Introduction The importances of treatment of the textile wastewater along with their effects were discussed in the previous chapter. The current chapter revels the various research work carried out so far nationally and internationally on application of natural coagulants to remove the dye. The conclusions about using natural coagulant and its efficiencies are also discussed in this chapter. 2.2. MoringaOleifera Seed Extract-Among Other Natural Coagulants Jesu’sbeltra’n-Heredia et al (2008) and ArunkantiGubaandAshraful Islam (2013) and TasneembanuKazi, ArjunVirupakshi, (2013) researched the ability of Moringaoleifera seed extract-among other natural coagulants-to remove several different types of dyes has been researched. Moringaoleifera has been demonstrated to have high removal ability for anionic dyes. This study was particularly focused on testing the removal of an azo dye such as Chicago Sky Blue 6B (CSB). http://www.iaeme.com/IJCIET/index.asp 556 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants 2.3. Coagulants/Flocculation in Order to Remove TheColour and Turbidity of Raw Water GrasieleScaramalMadrona (2010) andAboulhassan M.A, Souabi S, Yaacoubi A and Bauda (2006) SyedaAzeemUnnisa, PunamDeepthi and Khaggamukkanti, (2012) investigated by using several coagulants/flocculation in order to remove the colour and turbidity of raw water, employing natural ones demonstrated advantages in relation to chemicals. Moringaoleifera Lam was a natural polymer that has been gaining prominence in water treatment. It acts as a clarifying agent, providing a cationic protein that destabilizes the particles contained in a liquid medium. 2.4. Textile Wet Processing OnetCrisian (2010) and Hemapriya G et al (2015) andGeethaPriya P, and Sharpudhin J (2016) Choy S.Y (2015) AsrafuzzamanMd, Fakhruddin A.N.M, and AlamgirHossainMd, (2011) investigated that the textile industry occupies a unique place in our country. During textile wet processing, a large volume of wastewater is released. Though various physicochemical and biological treatment methods are employed for the removal of organic contaminants present in the textile wastewater. 3. METHODOLOGY 3.1. Description of Study Area The study area selected is SIPCOT industries located in Perungudi. The effect of contact time, pH is tob e studied. (T E Kanchanabhan et al, 2011) 3.2. Methodology of Experiments http://www.iaeme.com/IJCIET/index.asp 557 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan 4. MATERIALS 4.1. Collection of Natural Coagulants Moringaoleifera seeds were gathered from Erode showcase. The seeds are permitted to dry in the research facility broiler at a temperature of 50 °C for 24 h. A rice husk evacuating machine was utilized to expel the structures and wings from the pieces. The pieces were ground in to medium fine powder with residential sustenance blender. Tamarinaindica seeds utilized in this examination was collectedfrom the kitchen as a waste material. It was absorbed water for 1 h to expel the following mash, washed well with faucet water and after that with twofold refined water, dried in an air broiler at 110 °C for 1 h, micronized in a four mill15. Strychonospotatorum seeds were gathered from thelocal showcase in Erode city. Strychonos seeds, because of their hard structure, couldn't be powdered in a processor. The seeds were kept inundated in 50 mL water containing 2mL conc. HCl. Following seven days, the blend was squashed to a soup-like arrangement, which was washed through a nylon fabric and the material held on the material was broiler dried for 24 h at 103 to 105 °C and gauged. 4.2. Preparation of Coagulant Stock Solution Develop seeds hinting at no staining, relaxing or extraordinary drying up were utilized. The seed pieces of M.oleifera, T. indicaand S. Potaturumwere ground to fine powderof estimated size 600 µm to accomplish solubilization of dynamic fixings in the seed. Faucet water was added to the powder to make 2 % suspension (2 g of M. oleifera, T. indica and S. Potaturumpowder in 100 mL water).The suspension wasvigorously shaken for 0.5 h utilizing an attractive stirrer to advance water extraction of the coagulant proteins and this was then gone through Whatman no. 1 channel paper. Crisp arrangements were arranged every day and kept refrigerated to keep any age-ing impacts. Arrangements were shaken vigorously before use. 4.3. Physico-Chemical Parameters pH, COD, Total Solids, Total Suspended Solids, Dissolved Solids, were analyzed as per norms. 4.4. Optimization of Natural Coagulants Dosage using Jar Test The improvement for M.oleifera, T.indica, S. Potatorumand alum measurement were performed utilizing the container test mechanical assembly. The mechanical assembly allowed four measuring utencils to be upset all together. 0.5 L of material wastewater were dosed with 10, 20, 40, 60 and 80 mL of common coagulants were blended quickly for 10 min at 180 rpm, trailed by 10 min moderate mixing for flocculation. The coagulant dose can be chosen relying upon the turbidity of wastewater. Floc forma-tion can be watched all through this time. Flocs were allowed to make due with one hour before acquired for tests investigation. These techniques are performed for a few times so the ideal pH and dose of coagulant can be determined. In the wake of settling, 30 mL of the example was taken from the center of every measuring utencil utilizing a pipette and set in little container for further investigation. http://www.iaeme.com/IJCIET/index.asp 558 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants 5. RESULT 5.1. Treatment of Dyeing Effluent by Natural Coagulants An underlying test was done to decide the fundamental qualities of material profluent for the viability of the Moringaoleifera, Tamarandusindica, Strychnouspotatorum as a coagulant. The qualities of crude material profluent was organized beneath Table 5.1 Characteristics of Raw Textile Effluent Parameters pH TURBIDITY, NTU TSS(mg/l) TDS(mg/l) BOD(mg/l) COD (mg/l) Value 9.73 5700 5450 3235 765 2100 5.2. Effect of Floc Formation on Dosage of Natural Coagulants Coagulants actions onto colloidal particles take place through charge neutralization of negatively charged particles. If the charge neutralization is the predominant mechanisms a stochiometric relation can be established between the particle’s concentration and coagulant optimal dose. 5.2.1. Determination of Optimal Dosage by Moringaoleifera The Moringaoleifera powder is added as natural coagulant to find the optimal dosage level by varying the coagulant dosage range from 10 mg/l to 80mg/l. Table 5.2 Optimum Dosage of M.oleifera Coagulant Dosage(mg/l) 10 20 40 60 80 Floc Formation in % 43.02 52.15 63.21 54.76 36.09 5.2.2. Determination OfOptimal Dosage by TamarindusIndica The Tamarindusindica powder is added as natural coagulant to find the optimal dosage level by varying the coagulant dosage range from 10 mg/l to 80mg/l. Table 5.3 Optimum Dosage of T.indica Coagulant Dosage(mg/l) 10 20 40 60 80 http://www.iaeme.com/IJCIET/index.asp Floc Formation in % 28.03 36.23 49.21 57.36 25.89 559 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan 5.2.3. Determination of Optimal Dosage by Strychnouspotatrum The Strychnouspotatrum powder is added as natural coagulant to find the optimal dosage level by varying the coagulant dosage range from 10 mg/l to 80mg/l. Table 5.4 Optimum Dosage of S.potatrum Coagulant Dosage(mg/l) Floc Formation in % 10 21.34 20 36.37 40 42.89 60 53.54 80 37.25 Figure 5.1 Optimal Dosages by Natural Coagulants The Fig 5.1 illustrates the optimum dosage 40ml solution of M.oleifera produces 63.21% of flocs when it agitated with the textile effluent. Subsequently 10,20,60,80 ml dosages of M.oleifera generates 43.02%, 52.15%, 54.76%, 36.09% offlocs with respect to their corresponding dosages. It was evidently understood that T.indica solution produces 57.36% of flocformation at 60 ml of solution and has been designated as the optimum coagulant dosage. 28.03%, 36.23%, 49.21%, 25.89% of floc was achieved by 10,20,40 and 80 ml dosages of T.indica solutions. The jar test apparatus data articulate that on all dosage of S.potatorum produces 53.54% of the floc is optimum for 60 ml dosage. 21.34%, 36.37%, 42.89% and 37.25% of floc were produced with respect to 1,20,40 and 80 ml dosages. 5.3. Effect of Ph on the Removal of Turbidity using Natural Coagulants To determine the pH of each coagulant added solution in order to take the optimal dosage level of each coagulant added solution and varying the pH range to find the optimal level of pH. 5.3.1. Determination of pH by Moringaoleifera The Moringaoleifera powder is added as natural coagulant to find the optimal pH level by varying the pH range from 3 to 10. Table 5.5 Optimum pH of M.oleifera Coagulant pH 3 6 7 8 10 http://www.iaeme.com/IJCIET/index.asp Turbidity Removal % 61.20 72.15 82.10 74.26 66.69 560 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants 5.3.2. Determination of pH by Tamarindusindica The Tamarindusindica powder is added as natural coagulant to find the optimal pH level by varying the pH range from 3 to 10. Table 5.6 Optimum pH of T.indicaCoagulant pH 3 6 7 8 10 Turbidity Removal % 52.70 65.58 80.80 68.73 62.61 5.3.3. Determination of pH by S.potatarum The Strychnouspotatorum powder is added as natural coagulant to find the optimal pH level by varying the pH range from 3 to 10. Table 5.7 Optimum pH of S. potatorumCoagulant pH Turbidity Removal % 3 54.31 6 69.73 7 81.45 8 66.15 10 56.39 Figure 5.2 Optimal pH by Natural Coagulants The impact of pH esteem on the expulsion of turbidity utilizing M.oleifera, T.indica, and S.Potatorum as a coagulant is appeared in figure 5.2. The volume of material emanating that has been utilized was 500ml, while the ideal dose of M.oleifera was taken as 40ml and 60ml for T.indica and S.Potatorum. It tends to be clearly observed that the ideal scope of pH in term of rate evacuation of turbidity is 7. In the present work it is prescribed that the pH estimation of 7 is the best regarding turbidity which are observed to be around 82.10%, 80.80% and 81.40% individually when M.oleifera , T.indica and S.Potatorum is utilized as a coagulant in coagulation process. 5.4. Effect of Natural Coagulants on the Removal of TDS Analysis carried out on textile effluent before treatment showed that the values of total dissolved solids (TDS) on the raw sample were 3235 mg/l. http://www.iaeme.com/IJCIET/index.asp 561 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan The Moringaoleifera powder is added as natural coagulant on the removal of TDS. In order to find out the removal efficiency of TDS by adding M.oleifera as a coagulant to take the optimal dosage level as 40 mg/l of waste water. The reduction on TDS in case of 40ml dosage of M.oleifera is 70.51 %. The Tamarindusindica powder is added as natural coagulant on the removal of TDS. In order to find out the removal efficiency of TDS by adding T.indica as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on TDS in case of 60ml dosage of T.indica is 41.85 %. The Strychonospotatorum powder is added as natural coagulant on the removal of TDS. In order to find out the removal efficiency of TDS by adding S.Potatorum as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on TDS in case of 60ml dosage of S.Potatorum is 52.30 %. 80 Removal Efficiency % 60 40 20 0 M.oleifera T.indica S.potatorum Figure 5.3 Effect of Natural coagulant on the removal of TDS 5.5. Effect of Natural Coagulant on the Removal of Tss The Moringaoleifera powder is added as natural coagulant on the removal of TSS was determined. In order to find out the removal efficiency of TSS by adding M.oleifera as a coagulant to take the optimal dosage level as 40 mg/l of waste water. The reduction on TSS in case of 40ml dosage of M.oleifera is 80.56%. The Tamarindusindica powder is added as natural coagulant on the removal of TSS was determined. In order to find out the removal efficiency of TSS by adding T.indica as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on TSS in case of 60ml dosage of T.indica is 77.28%. The Strychonospotatorum powder is added as natural coagulant on the removal of TSS was determined. In order to find out the removal efficiency of TSS by adding S.Potatorum as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on TSS in case of 60ml dosage of S.Potatorum is 75.72 %. Removal Efficien cy % 82 80 78 76 74 72 M.oleifera T.indica S.potatorum Figure 5.4 Effect of Natural coagulant on the removal of TDS http://www.iaeme.com/IJCIET/index.asp 562 editor@iaeme.com A Study on Treatment of Industrial Effluent (Dyeing) using Moringa Oleifera, Tamarina Indica as Coagulants 5.6. Effect of Natural Coagulant on the Removal of Bod The Moringaoleifera powder is added as natural coagulant on the removal of BOD was determined. In order to find out the removal efficiency of BOD by adding M.oleifera as a coagulant to take the optimal dosage level as 40 mg/l of waste water. The reduction on BOD in case of 40ml dosage of M.oleifera is 72.29%. The Tamarindusindica powder is added as natural coagulant on the removal of BOD was determined. In order to find out the removal efficiency of BOD by adding T.indica as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on BOD in case of 60ml dosage of T.indica is 57.52%. The Strychonospotatorum powder is added as natural coagulant on the removal of BOD was determined. In order to find out the removal efficiency of BOD by adding S.potatorum as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on BOD in case of 60ml dosage of S.Potatorum is 65.36 %. 80 Remov al Efficien cy % 60 40 20 0 M.oleifera T.indica S.potatorum Figure 5.5 Effect of Natural coagulant on the removal of BOD 5.7. Effect of Natural Coagulant on the Removal of Cod The Moringaoleifera powder is added as natural coagulant on the removal of COD was determined. In order to find out the removal efficiency of COD by adding M.oleifera as a coagulant to take the optimal dosage level as 40 mg/l of waste water. The reduction on COD in case of 40ml dosage of M.oleifera is 79.34%. The Tamarindusindica powder is added as natural coagulant on the removal of COD was determined. In order to find out the removal efficiency of COD by adding T.indica as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on COD in case of 60ml dosage of T.indica is 68.90%. The Strychnouspotatorum powder is added as natural coagulant on the removal of COD was determined. In order to find out the removal efficiency of COD by adding S.potatorum as a coagulant to take the optimal dosage level as 60 mg/l of waste water. The reduction on COD in case of 60ml dosage of S.potatorum is 72.71 %. http://www.iaeme.com/IJCIET/index.asp 563 editor@iaeme.com Dr. A. Mani, T.P. Meikandaan, P.G. Gowrishankar and Dr. T. E. Kanchanabhan 85 80 Remov al Efficien cy % 75 70 65 60 M.oleifera T.indica S.potatorum Figure 5.6 Effect of Natural coagulant on the removal of COD 6. CONCLUSION 6.1. General Conclusion The coloring emanating gathered from passing on industry was broke down for the different parameters, where in turbidity, TSS, BOD and COD were in predominant points of confinement and sought after of end. The practicality in the treatment of coloring profluent utilizing characteristic coagulants like Moringaoliefera, Tamarinaindica and Strychonouspotatorum had been taken for examination. 6.2. Experimental Conclusion Ideal measurement for most astounding rate decrease in TSS,TDS,BOD and COD utilizing M.oliefera, T.indica, S.Potatorum was observed to be 40 and 60ml.When M.oliefera, T.indica and S.potatorum was utilized as a coagulant regarding rate evacuation of turbidity, pH estimation of 7 was the most suitable and were observed to be around 82.1% ,80.8% and 81.4% respectively.AS contrasted with T.indica and S.potatorum it was seen from acquired information that M.oliefera has greater capacity for the expulsion of TDS and TSS. 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