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Nitrocellulose

Nitrocellulose, also called cellulose nitrate, a mixture of nitric esters of cellulose, and a highly flammable compound that is the main ingredient of modern gunpowder and is also employed in certain lacquers and paints. In the late 19th and early 20th centuries it was the basis of the earliest man-made fibres and plastic materials. A nitrocellulose solution in ether and alcohol. Collodion has a wide range of uses in industry including applications in the manufacture of photographic film, in fibers, in lacquers, and in engraving and lithography. In medicine it is used as a drug solvent and a wound sealant. Nitrocellulose is a highly inflammable compound produced by nitrating cellulose by exposure to nitric acid or other powerful nitrating agent. Nitrocellulose when utilized as a low-order explosive or propellant it is known as guncotton. Nitrocellulose is a highly inflammable compound produced by nitrating cellulose by exposure to nitric acid or other powerful nitrating agent. Nitrocellulose when utilized as a low-order explosive or propellant it is known as guncotton. Globally, Technological Advancement, Rising Technology and manufacturing process cleaner are the prime growth drivers of Nitrocellulose market.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Sulphur Black Dye

Sulfur dyes are the most commonly used dyes manufactured for cotton in terms of volume. They are cheap, generally have good wash-fastness, and are easy to apply. Sulfur dyes are predominantly black, brown, and dark blue. Red sulfur dyes are unknown, although a pink or lighter scarlet color is available. Sulfur dye is generally heated sulfur or sodium sulfide together with certain aromatic amines, amino phenols and other organic compounds, namely vulcanization. In dyeing, sulfur dye needs to be dissolved in a sodium sulfide solution or alkaline hydrosulfite solution to reduce to its hidden color, and then absorbed and oxidized by fiber to show color. • Sulfur dyes are commonly used for black, blue, brown, khaki and green colors. • Sulfur dyes are applied to cellulosic fibers and blends of cellulosics with polyester, nylon and acrylics. • Sulfur dyes can be applied with little difficulty and with excellent results at a relatively low cost. Sulfur dyes are high molecular weight compounds that are obtained from the reaction of sulfur or sulfides with phenols and amines. There are many colorants available in the market that contain sulfur however, only those dyes that are soluble in water after reacting with sodium sulphide in alkaline conditions are known to be sulfur dyes. Sulphur Black dye is available in powder, granules and liquid form, having high degree of properties than other cotton dyes available in market. Good color fastness properties such as light fastness, wash fastness and cost effectiveness makes Sulphur black an important class of dye. This dye can be applied on garment, fabric by exhaust, semi continuous or continuous dyeing methods.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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PVC Stabilizer (Lead Stearate & Calcium Stearate)

Stabilizers are a class of chemical additives commonly added to polymeric materials, such as plastics, to inhibit or retard their degradation. Polymers can be subject to various degradation processes, including oxidation, UV-damage, thermal degradation, ozonolysis, or combinations thereof like photo-oxidation. These processes all degrade the polymer on a chemical level, leading to chain scission that can adversely affect its mechanical properties such as strength and malleability, as well as its appearance and colour. PVC Stabilisers are added either directly into PVC or in combination to prevent oxidation, chain scission, uncontrolled recombination, and cross-linking reactions caused by photo oxidation. Essentially, they protect PVC from the harmful effects of extreme temperature and ultraviolet radiations. PVC Stabilisers are of different types like Heat Stabilisers which are mainly used in Construction projects. The global PVC stabilizers market is estimated to register a CAGR of 5.90% during the forecast period, 2018-2023. Asia-Pacific is expected to dominate the market among other regions, supported by the growing automotive & electronics industry in countries, like China and India. Building & construction is expected to dominate the consumption of PVC stabilizers through the forecast period. Polyvinyl chloride (PVC) is one of the most important commercial plastic materials, but it is thermally unstable at processing temperature and hence, the processing of PVC at elevated temperatures requires the use of stabilizers. PVC stabilizers are used in various PVC applications such as pipes & fittings, window profiles, rigid & semi-rigid films, wire & cables, coatings & flooring, and others. PVC pipes & fittings application is the largest market for PVC stabilizers globally.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Antimony Trioxide

Antimony (III) oxide is the inorganic compound with the formula Sb2O3. It is the most important commercial compound of antimony. It is found in nature as the minerals valentinite and senarmontite. Like most polymeric oxides, Sb2O3 dissolves in aqueous solutions with hydrolysis. Antimony trioxide, also known as antimony(III) oxide, is a chemical compound. Its chemical formula is Sb2O3. It has antimony and oxide ions in it. It has antimony in its +3 oxidation state. Antimony oxide is mainly produced by two ways either by oxidation of antimony or by the process of re-volatilizing of crude antimony trioxide. The method of production is mainly dependent on the composition of ores. The antimony market size is projected to reach USD 2.37 billion by 2023, at a CAGR of 6.0% between 2018 and 2023. The growth of the antimony market can be attributed to the increasing use of antimony in the chemical industry. In the chemical industry, antimony is prominently used in flame synergist, catalyst, and stabilizer. The automotive industry is the second-largest end-use industry of antimony. Antimony is used in lead acid batteries in the automotive sector.
Plant capacity: -Plant & machinery: -
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Return: 1.00%Break even: N/A
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Bleaching Powder

Bleaching Powder is an oxidizing agent and the activity is measured in terms of available chlorine, which is the same weight as that of gaseous or liquid chlorine that would exert the same action as the chlorine compound. Bleaching powder is used to whiting or removing the natural color of textile fibers, yarns, wood pulp, paper and other products by chemical reaction and also is an additive in the scouring powder preparation as germicide. The global bleaching powder market was valued at around US$ 5 Bn in 2016 and is anticipated to expand at a CAGR of more than 3% from 2018 to 2026. Expansion in the global bleaching powder market is driven by the rise in demand for fresh water and increase in demand for bleaching powder in pulp & paper applications. This facilitates the development of new technologies and ensures a high quality product. Few Indian major players are as under • Aditya Birla Chemicals (India) Ltd. • Bengal Chemicals & Pharmaceuticals Ltd. • Daikaffil Chemicals India Ltd. • Gacl-Nalco Alkalies & Chemicals Pvt. Ltd. • Lords Chemicals Ltd. • Lords Chloro Alkali Ltd.
Plant capacity: 5 MT/DayPlant & machinery: Rs 83 lakhs
Working capital: -T.C.I: Cost of Project: Rs 249 lakhs
Return: 27.00%Break even: 44.00%
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Potassium Permanganate Manufacturing Business

Potassium Permanganate Manufacturing Business. Production of Potassium Permanganate Solution Potassium permanganate is an inorganic compound of potassium, manganese, and oxygen. It has strong oxidizing property and solubility in water. It is used in waste treatment, metal processing, chemical manufacturing and air and gas purification. Potassium permanganate is used as a bleaching and coloring agent in tanning & textile industries. Potassium permanganate is used extensively in the water treatment industry. It is used as a regeneration chemical to remove iron and hydrogen sulfide (rotten egg smell) from well water via a "Manganese Greensand" Filter. "Pot-Perm" is also obtainable at pool supply stores and is used additionally to treat waste water. Potassium permanganate is used by the owners of fisheries and large aquariums as a way to prevent fish from developing bacterial, fungal and parasitic diseases. This same disinfectant quality makes the compound useful to florists, who add the crystallized powder to the water of cut flowers to prevent algae growth and extend the life of the flowers. Potassium permanganate finds varied and widespread use in the global market. In the medical sector, potassium permanganate finds application as a fungicide and antiseptic. People with pus-formation, blisters or suffering from oozing wounds are recommended a diluted potassium permanganate bath. It is also used to treat skin infections like dermatitis, eczema, and fungal infections like athlete’s foot. Potassium permanganate is used industrially as a precursor in the production of compounds, such as ascorbic acid and saccharine. Additionally, the Paint Pro website reports that designers often use a potassium permanganate solution to alter the appearance of wood surfaces significantly. Market Outlook The global potassium permanganate market is estimated to exhibit a CAGR of 3.0% from 2015 to 2023, reaching a valuation of US$368.1 mn by 2023. Global potassium permanganate market is expected to grow at a significant pace over the next seven years. It is an inorganic chemical compound which has strong oxidizing property and easily dissolves in water. Potassium permanganate is added in water to remove the iron content and bacteria. This technique is highly used in water treatment plants. Growing health awareness and government initiatives to develop innovative water treatment methods is anticipated to be beneficial for the overall market growth. Growing population and increasing disposable income in consumers led to increase in demand for food. Potassium permanganate is used in the food preservation process. Once added, it reduces the moisture content of that food product, further reducing the chance of damage and improves shelf life. Based on application, the global potassium permanganate market is divided into industrial, water and water treatment, and others. The waste and water treatment segment commands the dominant share in the market. Potassium permanganate is a widely used oxidant for removing hardness of water and also manganese and iron from water due to their high effectiveness and efficiency. The others (includes chemical and food processing) segment is expected to register a considerable CAGR during the forecast period, owing to the surging demand from the chemical industry in Europe and Asia Pacific. Potassium permanganate is segmented by grade as free flowing, technical and pharmaceutical. Free flowing grade has the largest market share. Pharmaceutical grade is expected to grow during the forecast period. Potassium permanganate market is classified by application as water & waste treatment, industrial and others (including chemical processing, etc.). Water and waste treatment has the largest market share. Chemical processing is expected to be the fastest growing segment during the forecast period. Increasing need for water treatment is estimated to propel the demand for potassium permanganate in the near future. Large number of substitute products compete with potassium permanganate for usage in its primary applications. These substitute products are relatively economical and easily available. For instance, sodium permanganate offers higher solubility and can be used readily in the liquid form vis-à-vis potassium permanganate. This helps avoid handling problems such as dusting. Thus, presence of substitutes is expected to hamper the demand for potassium permanganate in the near future. Nonetheless, increasing demand for aquaculture is anticipated to open new avenues for the potassium permanganate market. Potassium permanganate when mixed with anti-freeze agent from car radiators or glycerin reacts to create fire. This chemical is used in fire starter kits in automobiles. Growing automotive industry is thus expected to drive the global market demand. Medicine industry has immense use for potassium permanganate, is expected to witness significant growth over the forecast period. It is used in various medicines for the treatment of canker sores, dermatitis and mild pompholyx. It is also used in hand sanitizers because of high oxidizing and antiseptic characteristics. Growing awareness for cleanliness and knowledge about the benefits of using hand sanitizers regularly is anticipated to be beneficial for the overall market growth. It is also used in histology for bleaching melanin to obscure the tissue detail. Potassium permanganate comes in handy for a wide range of applications across a multitude of industries. Potassium permanganate is extensively used for the treatment for waste water across towns and cities. Since the government has initiated several operations for the treatment of sewage and canal water, the demand within the global market for potassium permanganate has reached unprecedented levels. Furthermore, the growth of aquaculture across several regions has also aided the growth of the market and has created lucrative opportunities for market players. The chemical industry is virtually the largest consumer of potassium permanganate for several processes, reactions, and experiments. Metal processing has emerged as an important industry that has driven economic growth of regions. Since potassium permanganate is widely used across the metal processing industry, the demand within the global market has grown by leaps and bounds. In the textiles industry, potassium permanganate is extensively used as a bleaching agent. It is used in the bleaching process of polyester fabrics, cotton fabrics, and jeans. It is used to provide denim effects in the fabric. Also, due to its powerful oxidation property, it is preferred in the textiles industry. When compared to conventional bleaching agents, potassium permanganate is considered economical. Also, potassium permanganate does not affect the dye uptake values adversely like other conventional bleaching agents. Due to the increase in the demand for fabrics, changing fashion trends, affordability of buying clothes due to the rise in the disposable income, and the rise in the standard of living the global textiles market is anticipated to grow significantly. One trend in the market is growth in the pharmaceutical industry. Potassium permanganate is used in pharmaceuticals extensively, due to its oxidation and antiseptic properties. It is used in treating diseases such as skin diseases, fungal infection, healing wounds, and hair dye allergies. The growing demand of potassium permanganate in food processing and automotive industries is also expected to boost the market demand. The key constraints hampering the growth of this market are availability of cheaper substitutes such as sodium permanganate and health hazards associated with production of potassium permanganate. Geographically, this market has been segmented into regions such as North America, Europe, Latin America, Asia Pacific and the Middle East & Africa. The key players operating in Potassium Permanganate market are Carus Corporation, Chongqing Chagyuan Group Limited, Groupstars Chemical L.L.C., Zunyi Shuangyuan Chemical Group Co., Ltd., Organic Industries Pvt. Ltd, Libox Chem Pvt. Ltd., Guangdong Meixian Hanghai Manganese Chemical Plant, and Universal Chemicals & Industries Pvt. Ltd. Tags #Potassium_Permanganate, #Potassium_Permanganate_Formula, #How_to_Make_a_Potassium_Permanganate Solution, #Manufacture_of_Potassium_Permanganate, Process for Producing Potassium Manganite, Preparation of Potassium Permanganate, #Production_of_Potassium_Permanganate, Process for Production of Potassium Manganite, #Potassium_Permanganate_Manufacturing_Plant, Potassium Permanganate Manufacture in India, #Potassium_Permanganate_Production, Potassium Permanganate Plant, Potassium Permanganate Manufacture, #Potassium_Permanganate_Industry, Manufacturing Process of Potassium Permanganate, Potassium Permanganate Manufacturing, Inorganic Compound, Chemical Manufacturing, Chemical Industry, Chemical Manufacturing Industry, Highly Profitable Chemical Business Ideas, How to Start a Small Chemical Industry, Chemical Business Ideas & Opportunities, #Project_Report_on_Potassium_Permanganate_Manufacturing_Industry, Detailed Project Report on Potassium Permanganate Industry, Project Report on Potassium Permanganate Manufacturing Industry, Pre-Investment Feasibility Study on Potassium Permanganate Industry, Techno-Economic feasibility study on Potassium Permanganate Manufacturing Industry, #Feasibility_report_on_Potassium_Permanganate_Industry, Free Project Profile on Potassium Permanganate Manufacturing, Project profile on Potassium Permanganate Manufacturing Industry, Download free project profile on Potassium Permanganate Manufacturing
Plant capacity: -Plant & machinery: -
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Return: 1.00%Break even: N/A
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Polylactic Acid (PLA) from Lactic Acid

Poly-lactic acid (PLA) is a rigid thermoplastic polymer that can be semi-crystalline or totally amorphous, depending on the stereo-purity of the polymer backbone. PLA is a unique polymer that in many ways behaves like PET, but also performs a lot like polypropylene (PP), a polyolefin. PLA is used broadly in textile applications for several reasons. Polyesters currently used for apparel and related fiber applications. The global polylactic acid (PLA) market was valued around US$ 2.23 Bn in 2017 and is anticipated to expand at a stable CAGR above 20.5% during the forecast period 2018 to 2026. The polylactic acid market is projected to reach USD 5.16 Billion by 2020, growing at a CAGR of 20.9% during the forecast period. This facilitates the development of new technologies and ensures a high quality product. Few Indian major players are as under • Astra Specialty Compounds India Pvt. Ltd. • Crest Composites & Plastics Pvt. Ltd. • Malladi Specialities Ltd. • Neelam Aqua & Speciality Chem Pvt. Ltd. • Network Polymers Pvt. Ltd. • Reichhold India Pvt. Ltd.
Plant capacity: 100 MT/DayPlant & machinery: Rs 260 Crore
Working capital: -T.C.I: Cost of Project: Rs 452 Crore
Return: 27.00%Break even: 29.00%
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Bromelain Enzyme Production from Pineapple Stems

Bromelain Enzyme Production from Pineapple Stems. Bromelain Extraction from Pineapple Fruit Bromelain is a mixture of enzymes derived from pineapple. Its effects are mainly a product of its proteolytic activity, which stimulates fibrinolysis by increasing plasmin, but bromelain also has been shown to prevent kinin production and to inhibit platelet aggregation. Because its mechanism of action is generally antiinflammatory, rather than specific to a particular disease process, bromelain is used to treat a variety of pain and inflammatory conditions. Derived from the pineapple plant, the bromelain enzyme finds various applications across different end-use industries. At the industrial level, bromelain is used to digest proteins. The proteolytic nature of bromelain finds application in the F&B industry where bromelain is largely used as a meat tenderizer. With added benefits such as anti-inflammation and immunity boosting properties, bromelain is being increasingly used in dietary supplements. Bromelain also finds application as a viable solution to several energy and resource consuming processes in industries such as leather and paper processing. This digestive enzyme is extracted from pineapple fruit & stem and is used in numerous industries including healthcare, meat & seafood, dietary supplements, cosmetics, bakery and beverage. Globally, meat & seafood industry is found to be the largest end user industry for this market where its main application is to improve tenderness of meat & seafood. Market Outlook The global bromelain market is anticipated to reach USD 1,055.1 million by 2025, at a 4.60% CAGR over the forecast period (2018-2025), as per Market Research Future (MRFR). The market can accumulate a demand of 579,958.3 kg by 2025, at a CAGR of 6.54% during the forecast period. The Food & Beverages and Pharmaceuticals industries have the largest applications of bromelain for several processes. Both these segments are collectively expected to hold more than 85% of the global bromelain market share throughout the forecast period 2017 – 2025. Increasing application of bromelain in the bakery, meat, and brewing industry is likely to boost revenue growth of the F&B segment during the period of assessment. The Food & Beverages segment is estimated to represent an absolute $ opportunity of US$ 11.6 Mn in 2017 over 2016, and an incremental $ opportunity of US$ 129.6 Mn between 2017 and 2025. The Pharmaceuticals segment is estimated to represent an absolute $ opportunity of US$ 10.0 Mn in 2017 over 2016, and an incremental $ opportunity of US$ 102.9 Mn between 2017 and 2025. Bromelain finds increasing application across the following end-use industries: • Food & Beverages: Meat processing, dough relaxer, anti-browning agent, dairy processing, brewing process, etc. • Pharmaceuticals: Anti-inflammatory drugs, burn recovery ointments, blood thinning, post-surgery medication, dermatological solutions, etc. • Industrial: Detergent agent, paper processing, leather processing, silk extraction, animal feed and pet food preparations, etc. • Cosmetics: Skin conditioner, anti-tan products, anti-infection agent, anti- aging solution, etc. Growing demand from various end-use industries such as household care, animal feed, textile industry, etc., due to its properties is key factor expected to drive growth of the global bromelain market. Moreover, bromelain can be used for production of dietary supplement, as tenderizing meat agent, which is expected to boost demand for bromelain and thereby drive growth of the global market. Increasing demand of the bromelain and usage of natural products for production in various industries is also spurring demand for bromelain. The Bromelain has its inherent properties to tenderize meat helps to reduce post process preparation time and reduces production costs considerably. This is expected to boost market demand for the enzyme in the forecast period. Geographically, North America is expected to dominate the global bromelain market during the forecast period. This is mainly because of the rising awareness among the people regarding several health benefits of bromelain. Apart from this, increasing investments on research and development of healthcare sector in the region is another strong factor expected to drive the bromelain market in the region. Some of the key players operating in the bromelain market are Enzybel International SA Hong Mao Biochemicals Co., Ltd, Nanning Pangbo Biological Engineering Co., Ltd, Great Food Group of Companies Enzyme Technology (PTY) Ltd, Guangxi Nanning Javely Biological Products Co., Ltd and Nanning Doing-Higher Bio-Tech Co., Ltd. Tags #Bromelain_Enzyme_from_Pineapple_Stems, #Extraction_of_Bromelain_from_Pineapple, #Bromelain, #Bromelain_Enzyme_from_Pineapple, #Stem_Bromelain_Enzyme, Bromelain from Pineapple Stem, #Bromelain_Enzyme_Extraction_from_Pineapple, Bromelain Production in India, Bromelain Production, Bromelain Enzyme Pdf, Application of Bromelain, #Bromelain_Production_Process, How to Get Bromelain from a Pineapple, #Bromelain_Production_Business, Bromelain Content of Extract from Stem of Pineapple, Bromelain Production in India, Bromelain Pineapple Enzymes, Bromelain Manufacture, Bromelain Enzyme, Pineapple Enzyme Bromelain Manufacture, India Bromelain, India Bromelain Manufacture, Bromelain Extraction from Pineapple, Extraction of Bromelain from Fruit Waste, Extraction of Enzymes from Fruits, #Detailed_Project_Report_on_Bromelain_Production, Project Report on Bromelain Production, Pre-Investment Feasibility Study on Bromelain Production, Techno-Economic feasibility study on Bromelain Production, #Feasibility_report_on_Bromelain_Production, Free Project Profile on Bromelain Production, Project profile on Bromelain Production, Download free project profile on Bromelain Production
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Return: 1.00%Break even: N/A
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Recovery of Ferric oxide (Fe2O3) & Titanium Dioxide (TiO2) from Bauxite Processing Waste

Recovery of Ferric oxide (Fe2O3) & Titanium Dioxide (TiO2) from Bauxite Processing Waste. Wealth from Waste Ferric oxide (Fe? O?) is an inorganic compound also known as hematite. Ferric oxide is used in the iron industry in the manufacturing of alloys and steel. The Food and Drug Administration (FDA) has approved ferric oxide pigment for use in cosmetics. Moreover, ferric oxide granules are used in the form of filtration media for removing phosphates in saltwater aquariums. The global titanium dioxide market size was valued at USD 15.76 billion in 2018 and is expected to witness a CAGR of 8.7% from 2019 to 2025 In addition, high demand for anti-corrosive architectural coatings in the pigments has increased the demand for titanium dioxide. FOR Fe2O3 ? In iron industries for producing steel and alloys ? Ferric oxide powder, also called jeweler’s rouge, is used for polishing lenses and metallic jewelry ? Its granular form is used as a filtration media for pulling out phosphates in saltwater aquariums ? As FDA-approved Pigment Brown 6 and Pigment Red 101, for use in cosmetics. ? In biomedical applications, because its nanoparticles are non-toxic and biocompatible Recovery of Fe2O3 Fe2O3 is another material in red mud that has attracted a number of researchers. Until now, there are three means to recover iron from red mud: smelting, solid-state reduction and magnetic separation. In smelting process, red mud is charged into blast furnace or rotary furnace with a reducing agent. Then, iron oxide in red mud is reduced to generate pig iron that can be used in steel production. However, smelting process has some demerits. High energy and capital costs are associated with blast furnace (BF) operation because scale of operation is high. Red mud must be mixed with some good-grade iron ore to maintain the minimum grade of the charge to BF. In addition, titanium reacts with other constituents of the slag to form multiple oxides that are difficult to leach. In the solid-state reduction process, the mud is mixed with a reducing agent or contacted with a reducing gas to produce metallic iron. The product can be an input either in a steel-making furnace or a conventional blast furnace. Compared to smelting process, solid-state reduction process consumes less energy. But, it also has some disadvantages. First, the metallic iron produced is quite difficult to separate from the rest of product. So, it is easily polluted by gangue materials. Second, the product is in a very fine form. The recovery rate of Fe2O3 was 45% (weight percent). Another means is to convert hematite or goethite in red mud to magnetite firstly, which is followed with magnetic separation. Obviously, this process is more complex than magnetic separation. Advantages. Goethite is easier to separate magnetically and needs less energy to reduce compared to hematite. So, the extra cost of reducing hematite to magnetite can be compensated by the energy difference between reducing hematite and magnetite to metallic iron. Titanium Dioxide, also known as titanium (IV) oxide or titanic, is a white crystalline powder, made up of limonite and rutile, which are used as the main raw materials. It is created using either the chloride process or sulfuric acid, referred to as the sulfate process. Titanium dioxide is extensively used as a white pigment in paints and coatings application. Also, it has a wide range of applications, ranging from paints and sunscreens to food coloring FOR TiO2 Uses for white pigment Four million tons of pigmentary TiO2 are consumed annually. Apart from producing a white color in liquids, paste or as coating on solids, TiO2 is also an effective pacifier, making substances more opaque. Here are some examples of the extensive range of applications: ? Paints ? Plastics ? Papers ? Inks ? Medicines ? Most toothpastes ? Skimmed milk; adding TiO2 to skimmed milk makes it appear brighter, more opaque and more palatable Recovery of TiO2 Generally, there have been two main methods developed by which the titanium can be recovered from red mud: pyro metallurgical recovery and hydro-metallurgical recovery. The pyro- metallurgical method generally comprises the separation of pig iron. The red mud is claimed at a range of temperatures, from 800 to 1350°C, and is smelted through a reducing agent using an electric-furnace to obtain melted iron as well as slag that includes titanium dioxide, silica and alumina. The metallic iron is removed from the slag and the slag is digested to recover the titanium and aluminium from the solution. The pyro-metallurgical process is not an energy-friendly method and, hence, the hydrometallurgical technique usually attracts more attention from the research community. A number of the acids’ extractability have been analyzed to recover titanium from red mud, such as dilute and concentrated H2SO4 and hydrochloric acid. The solvent extraction technique has been applied to extract titanium from red mud using HCl, which comprised di- and mono-. Red mud can also be considered a secondary source of the most important modification of titanium compound, titanium dioxide. Market Outlook The Global Ferric Oxide Market is expected to register a CAGR of 4.99% to reach a value of USD 2,414,382.9 Million by 2030. The primary driver of the global ferric oxide market is its growing adoption in steel production. The increasing application of steel in the major end-use industries such as transportation, construction, and energy, packaging, and consumer appliances is also a prime factor driving market growth. Steel finds application in the manufacturing of automobile structures, panels, doors, engine blocks, gears, suspension, wheels, fuel tanks, steering, and braking systems. The use of iron oxide pigments to impart colors to construction materials, paints, inks, plastics, papers, cosmetics, rubbers, concrete blocks, and tiles is another key driver of the market. Global Ferric oxide Market Revenue, by Application, 2030 (USD Million) The growing construction industry output is expected to be one of the most significant drivers for the iron oxide market on a global scale. The growing adoption of iron oxide nanoparticles in wastewater treatment is an excellent opportunity for the players in the market. With the steady growth of the construction industry, stemming from increasing urban and civil infrastructure projects, the demand for iron oxides is expected to increase significantly. The ferric oxide market is witnessing consolidation, driven by the pursuit for sustainability among market participants, owing to the imposition of stringent regulations on the production of ferric oxide, which are increasing the overhead costs for ferric oxide manufacturers. This has prompted ferric oxide manufacturers to consolidate production and business operations through acquisition of external enterprises having a sufficient infrastructure and resources. Mining and metallurgy industry dominated the market in 2018, and it is likely to grow during the forecast period with the continuous growth in mining activities. The increasing demand for titanium dioxide downstream products and natural dyes in the textile industry are likely to provide opportunities for the studied market during the forecast period. Asia-Pacific dominated the market across the world, due to the growing mining activities in the region, and robust demand fueling the growth of polymer synthesis and chemicals industry. The global titanium dioxide market size was valued at USD 15.76 billion in 2018 and is expected to witness a CAGR of 8.7% from 2019 to 2025. The major factors driving the growth of the market studied are the increasing demand from the mining industry and increasing use in polymer synthesis. On the flipside, the toxicity of titanium dioxide hampers the growth of the market. Escalating demand for lightweight vehicles owing to strict emission policies is expected to fuel the market growth over the coming years. Thus, rising usage of lightweight materials for enhanced safety and fuel-efficiency is expected to have a positive impact on the industry over the forecast period. These lightweight materials, when coated with titanium dioxide, increase durability, stability, persistence, and scratch resistance. The product has an increasing application scope in printing inks, rubber, and chemical fibers. In printing inks, it is used in flexographic, lamination, screen printing, UV-cured, and metal decorative inks. The Top Players Including: ? Cathay Industries ? Huntsman ? Lanxess ? Bayferrox ? Toda Kogyo ? Quality Magnetite ? Prochem ? BariteWorld • Bengal Chemicals & Pharmaceuticals Ltd. • Bharat Chemicals & Fertilizers Ltd. • Kerala Minerals & Metals Ltd. • Kolmak Chemicals Ltd. • Tata Pigments Ltd. • Travancore Titanium Products Ltd. • V V Titanium Pigments Pvt. Ltd. • Kerala Minerals & Metals Ltd. Tags Recovery_of_Fe2O3_from_Bauxite_Processing, #Iron_Oxide_Recovery, #Recovery_of_Ferric_Oxide, #Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Ferric Oxide, Manufacturing Applications for Iron (III) Oxide, Manufacture of ferric oxide, Production of Iron (II) Oxide (Fe2O3), Process for the Manufacture of Iron Oxide, Process for Producing Iron Oxide, Iron Oxide Formula, Ferric Oxide Production, How to Make Iron Oxide, Preparation of iron oxide, Titanium Dioxide (TiO2) Production and Manufacturing, #Titanium_Dioxide, Manufacture of Titanium Dioxide, #Titanium_Dioxide_(TiO2) Production, Manufacturing Process of Titanium Dioxide, Titanium Dioxide Properties, Titanium Dioxide Uses, Titanium Dioxide Process Flow Diagram, Titanium Dioxide Manufacture, How to Make Titanium Dioxide, Manufacturing Process of Titanium Dioxide, Production of Titanium Dioxide, Titanium Dioxide Production, #Recovery_of_Titanium_Dioxide, Process for Recovery of Titanium Dioxide, Recovering Titanium Dioxide (Tio2), Recovery of Titanium Dioxide from Bauxite Processing Waste, #Project_Report_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Detailed Project Report on Recovery of Ferric oxide from Bauxite Processing Waste, Project Report on Recovery of Titanium Dioxide, Pre-Investment Feasibility Study on Recovery of Ferric oxide from Bauxite Processing Waste, Techno-Economic feasibility study on Recovery of Titanium Dioxide, #Feasibility_report_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, #Free_Project_Profile_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Project profile on Recovery of Ferric oxide from Bauxite Processing Waste, Download free project profile on Recovery of Titanium Dioxide
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Return: 1.00%Break even: N/A
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Recovery of Ferric oxide (Fe2O3) & Titanium Dioxide (TiO2) from Bauxite Processing Waste

Recovery of Ferric oxide (Fe2O3) & Titanium Dioxide (TiO2) from Bauxite Processing Waste. Wealth from Waste Ferric oxide (Fe? O?) is an inorganic compound also known as hematite. Ferric oxide is used in the iron industry in the manufacturing of alloys and steel. The Food and Drug Administration (FDA) has approved ferric oxide pigment for use in cosmetics. Moreover, ferric oxide granules are used in the form of filtration media for removing phosphates in saltwater aquariums. The global titanium dioxide market size was valued at USD 15.76 billion in 2018 and is expected to witness a CAGR of 8.7% from 2019 to 2025 In addition, high demand for anti-corrosive architectural coatings in the pigments has increased the demand for titanium dioxide. FOR Fe2O3 ? In iron industries for producing steel and alloys ? Ferric oxide powder, also called jeweler’s rouge, is used for polishing lenses and metallic jewelry ? Its granular form is used as a filtration media for pulling out phosphates in saltwater aquariums ? As FDA-approved Pigment Brown 6 and Pigment Red 101, for use in cosmetics. ? In biomedical applications, because its nanoparticles are non-toxic and biocompatible Recovery of Fe2O3 Fe2O3 is another material in red mud that has attracted a number of researchers. Until now, there are three means to recover iron from red mud: smelting, solid-state reduction and magnetic separation. In smelting process, red mud is charged into blast furnace or rotary furnace with a reducing agent. Then, iron oxide in red mud is reduced to generate pig iron that can be used in steel production. However, smelting process has some demerits. High energy and capital costs are associated with blast furnace (BF) operation because scale of operation is high. Red mud must be mixed with some good-grade iron ore to maintain the minimum grade of the charge to BF. In addition, titanium reacts with other constituents of the slag to form multiple oxides that are difficult to leach. In the solid-state reduction process, the mud is mixed with a reducing agent or contacted with a reducing gas to produce metallic iron. The product can be an input either in a steel-making furnace or a conventional blast furnace. Compared to smelting process, solid-state reduction process consumes less energy. But, it also has some disadvantages. First, the metallic iron produced is quite difficult to separate from the rest of product. So, it is easily polluted by gangue materials. Second, the product is in a very fine form. The recovery rate of Fe2O3 was 45% (weight percent). Another means is to convert hematite or goethite in red mud to magnetite firstly, which is followed with magnetic separation. Obviously, this process is more complex than magnetic separation. Advantages. Goethite is easier to separate magnetically and needs less energy to reduce compared to hematite. So, the extra cost of reducing hematite to magnetite can be compensated by the energy difference between reducing hematite and magnetite to metallic iron. Titanium Dioxide, also known as titanium (IV) oxide or titanic, is a white crystalline powder, made up of limonite and rutile, which are used as the main raw materials. It is created using either the chloride process or sulfuric acid, referred to as the sulfate process. Titanium dioxide is extensively used as a white pigment in paints and coatings application. Also, it has a wide range of applications, ranging from paints and sunscreens to food coloring FOR TiO2 Uses for white pigment Four million tons of pigmentary TiO2 are consumed annually. Apart from producing a white color in liquids, paste or as coating on solids, TiO2 is also an effective pacifier, making substances more opaque. Here are some examples of the extensive range of applications: ? Paints ? Plastics ? Papers ? Inks ? Medicines ? Most toothpastes ? Skimmed milk; adding TiO2 to skimmed milk makes it appear brighter, more opaque and more palatable Recovery of TiO2 Generally, there have been two main methods developed by which the titanium can be recovered from red mud: pyro metallurgical recovery and hydro-metallurgical recovery. The pyro- metallurgical method generally comprises the separation of pig iron. The red mud is claimed at a range of temperatures, from 800 to 1350°C, and is smelted through a reducing agent using an electric-furnace to obtain melted iron as well as slag that includes titanium dioxide, silica and alumina. The metallic iron is removed from the slag and the slag is digested to recover the titanium and aluminium from the solution. The pyro-metallurgical process is not an energy-friendly method and, hence, the hydrometallurgical technique usually attracts more attention from the research community. A number of the acids’ extractability have been analyzed to recover titanium from red mud, such as dilute and concentrated H2SO4 and hydrochloric acid. The solvent extraction technique has been applied to extract titanium from red mud using HCl, which comprised di- and mono-. Red mud can also be considered a secondary source of the most important modification of titanium compound, titanium dioxide. Market Outlook The Global Ferric Oxide Market is expected to register a CAGR of 4.99% to reach a value of USD 2,414,382.9 Million by 2030. The primary driver of the global ferric oxide market is its growing adoption in steel production. The increasing application of steel in the major end-use industries such as transportation, construction, and energy, packaging, and consumer appliances is also a prime factor driving market growth. Steel finds application in the manufacturing of automobile structures, panels, doors, engine blocks, gears, suspension, wheels, fuel tanks, steering, and braking systems. The use of iron oxide pigments to impart colors to construction materials, paints, inks, plastics, papers, cosmetics, rubbers, concrete blocks, and tiles is another key driver of the market. Global Ferric oxide Market Revenue, by Application, 2030 (USD Million) The growing construction industry output is expected to be one of the most significant drivers for the iron oxide market on a global scale. The growing adoption of iron oxide nanoparticles in wastewater treatment is an excellent opportunity for the players in the market. With the steady growth of the construction industry, stemming from increasing urban and civil infrastructure projects, the demand for iron oxides is expected to increase significantly. The ferric oxide market is witnessing consolidation, driven by the pursuit for sustainability among market participants, owing to the imposition of stringent regulations on the production of ferric oxide, which are increasing the overhead costs for ferric oxide manufacturers. This has prompted ferric oxide manufacturers to consolidate production and business operations through acquisition of external enterprises having a sufficient infrastructure and resources. Mining and metallurgy industry dominated the market in 2018, and it is likely to grow during the forecast period with the continuous growth in mining activities. The increasing demand for titanium dioxide downstream products and natural dyes in the textile industry are likely to provide opportunities for the studied market during the forecast period. Asia-Pacific dominated the market across the world, due to the growing mining activities in the region, and robust demand fueling the growth of polymer synthesis and chemicals industry. The global titanium dioxide market size was valued at USD 15.76 billion in 2018 and is expected to witness a CAGR of 8.7% from 2019 to 2025. The major factors driving the growth of the market studied are the increasing demand from the mining industry and increasing use in polymer synthesis. On the flipside, the toxicity of titanium dioxide hampers the growth of the market. Escalating demand for lightweight vehicles owing to strict emission policies is expected to fuel the market growth over the coming years. Thus, rising usage of lightweight materials for enhanced safety and fuel-efficiency is expected to have a positive impact on the industry over the forecast period. These lightweight materials, when coated with titanium dioxide, increase durability, stability, persistence, and scratch resistance. The product has an increasing application scope in printing inks, rubber, and chemical fibers. In printing inks, it is used in flexographic, lamination, screen printing, UV-cured, and metal decorative inks. The Top Players Including: ? Cathay Industries ? Huntsman ? Lanxess ? Bayferrox ? Toda Kogyo ? Quality Magnetite ? Prochem ? BariteWorld • Bengal Chemicals & Pharmaceuticals Ltd. • Bharat Chemicals & Fertilizers Ltd. • Kerala Minerals & Metals Ltd. • Kolmak Chemicals Ltd. • Tata Pigments Ltd. • Travancore Titanium Products Ltd. • V V Titanium Pigments Pvt. Ltd. • Kerala Minerals & Metals Ltd. Tags Recovery_of_Fe2O3_from_Bauxite_Processing, #Iron_Oxide_Recovery, #Recovery_of_Ferric_Oxide, #Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Ferric Oxide, Manufacturing Applications for Iron (III) Oxide, Manufacture of ferric oxide, Production of Iron (II) Oxide (Fe2O3), Process for the Manufacture of Iron Oxide, Process for Producing Iron Oxide, Iron Oxide Formula, Ferric Oxide Production, How to Make Iron Oxide, Preparation of iron oxide, Titanium Dioxide (TiO2) Production and Manufacturing, #Titanium_Dioxide, Manufacture of Titanium Dioxide, #Titanium_Dioxide_(TiO2) Production, Manufacturing Process of Titanium Dioxide, Titanium Dioxide Properties, Titanium Dioxide Uses, Titanium Dioxide Process Flow Diagram, Titanium Dioxide Manufacture, How to Make Titanium Dioxide, Manufacturing Process of Titanium Dioxide, Production of Titanium Dioxide, Titanium Dioxide Production, #Recovery_of_Titanium_Dioxide, Process for Recovery of Titanium Dioxide, Recovering Titanium Dioxide (Tio2), Recovery of Titanium Dioxide from Bauxite Processing Waste, #Project_Report_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Detailed Project Report on Recovery of Ferric oxide from Bauxite Processing Waste, Project Report on Recovery of Titanium Dioxide, Pre-Investment Feasibility Study on Recovery of Ferric oxide from Bauxite Processing Waste, Techno-Economic feasibility study on Recovery of Titanium Dioxide, #Feasibility_report_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, #Free_Project_Profile_on_Recovery_of_Ferric_oxide_from_Bauxite_Processing_Waste, Project profile on Recovery of Ferric oxide from Bauxite Processing Waste, Download free project profile on Recovery of Titanium Dioxide
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Return: 1.00%Break even: N/A
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