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Space produce other sugar industry products and its waste

Space produce other sugar industry products and its waste

Biovalorisation of Wastes to Renewable Chemicals and Biofuels addresses advanced technologies for converting waste to biofuels and value-added products. Biovalorisation has several advantages over conventional bioremediation processes as it helps reduce the costs of bioprocesses. Examples are provided of several successfully commercialized technologies, giving insight into developing, potential processes for biovalorisation of different wastes. Different bioprocess strategies are discussed for valorising the wastes coming from the leather industry, olive oil industry, pulp and paper, winery, textile, and food industries, as well as aquaculture.

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Sugarcane biorefineries wastewater: bioremediation technologies for environmental sustainability

VIDEO ON THE TOPIC: How is Sugar Made White? - Earth Lab

Subscribe to our Newsletter and get informed about new publication regulary and special discounts for subscribers! Full Text PDF. This work is licensed under a Creative Commons Attribution 4. Rao, Comparative performance of cane sugar industry in seven countries. Bhat, J. Singh, A. Vig, Genotoxic assessment and optimization of pressmud with the help of exotic earthworm Eisenia fetida.

Vig, Potential utilization of bagasse as feed material for earthworm Eisenia fetida and production of vermicompost. Vig, Vermistabilization of sugar beet Beta vulgaris L waste produced from sugar factory using earthworm Eisenia fetida: Genotoxic assessment by Allium cepa test. Balakrishnan, V. Batra, Valorization of solid waste in sugar factories with possible application in India: A review. J Environ. Yadav, S. Solomon, Potential of developing sugarcane by-products based industries in India.

Sugar Tech. Sen, T. Chandra, Chemolytic and solid-state spectroscopic evaluation of organic matter transformation during vermicomposting of sugar industry wastes.

Ezhumalai, V. Thangavelu, Kinetic and optimization studies on the bioconversion of lignocellulosic material into ethanol. Pessoa, I. Sato, Evaluation of sugar cane hemicellulose hydrolyzate for cultivation of yeasts and filamentous fungi. Dronnet, C. Renard, M. Axelos, J. Thibault, Binding of divalent metal cations by sugar-beet pulp. Gerente, P. Couespel du Mesnil, Y. Andres, J.

Thibault, P. Le Cloirec, Removal of metal ions from aqueous solution on low cost natural polysaccharides-sorption mechanism approach. Khwairakpam, R. Bhargava, Bioconversion of filter mud using vermicomposting employing two exotic and one local earthworm species. Lim, T. Wu, P. Lim, K. Shak, The use of vermicompost in organic farming: overview, effects on soil and economics. Food Agric. Wu, C. Clarke, N. Nik Daud, A potential bioconversion of empty fruit bunches into organic fertilizer using Eudrilus eugeniae.

Reddy, M. Shantaram, Potentiality of earthworms in composting of sugarcane by products. Asian J. Sangwan, C. Kaushik, V. Garg, Feasibility of utilization of horse dung spiked filter cake in vermicomposters using exotic earthworm Eisenia foetida. Garg, Vermiconversion of industrial sludge for recycling the nutrients. Prakash, N. Karmegam, Vermistabilization of pressmud using Perionyx ceylanensis Mich. Kumar, D. Verma, B. Singh, U. Kumar, Shweta, Composting of sugar-cane waste by-products through treatment with microorganisms and subsequent vermicomposting.

Garg, Vermicomposting of sugar industry waste pressmud mixed with cow dung employing an epigeic earthworm Eisenia foetida. Waste Manage. Honarvar, S. Samavat, M. Davoodi, K. Karimi, Possibility of producing compost and vermicompost from sugar beet waste in the sugar factory. Food Technol. Cynthia, K. Rajeshkumar, A study on sustainable utility of sugar mill effulent to vermicompost.

Pandit, S. Maheshwaria, Optimization of vermicomposting technique for sugarcane waste management by using Eisenia fetida. Niyazi, S. Chaurasia, Vermistabilization of fly ash amended with pressmud by employing eisenia foetida.

Maheshwaria, Vermiremediation of sugarcane by-products into nutrient rich vermicompost through enhancing the bioconversion efficiency of Eisenia fetida by developing vermireactors. Bioprocess Technol. Shah, M. Abid, M. Qayyum, R. Waste Agricult.

Venkatesh, T. Eevera, Mass reduction and recovery of nutrients through vermicomposting of fly ash. Appl Ecol Environ Res 6 Garg, R. Gupta, A. Yadav, Potential of Vermicomposting technology in solid waste management. In: Pandey A et al ed Current developments in solid state fermentation. Publishers Inc. Lim, J. Jung, W. Choi, H. Ro HM, Substrate quality effects on decomposition of three livestock manure composts with similar stability degree in an acid loamy soil. Korean J. Soil Sci. Senesi, Composted materials as organic fertilizers.

Total Env. Kaur, A. Vig, P. Rup PJ, Role of Eisenia fetida in rapid recycling of nutrients from bio sludge of beverage industry. Health Sci. Suthar, Pilot-scale vermireactors for sewage sludge stabilization and metal remediation process: comparison with small-scale vermireactors.

Loh, Y. Lee, J. Liang, D. Tan, Vermicomposting of cattle and goat manures by Eisenia foetida and their growth and reproduction preference. Suthar, Potential utilization of Guar gum industrial waste in vermicompost production. Vig, "Instrumental characterization of organic wastes for evaluation of vermicompost maturity", Journal of Analytical Science and Technology, Vol.

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An action-oriented set of methods, mindsets and thought starters to help innovators design circular solutions that are fit for the future. The New Plastics Economy is an ambitious, three-year initiative to build momentum towards a plastics system that works. There are plenty of hot startups with a new technology that can accelerate the transition to a circular economy. Yet some of the best examples don't rely on new tech, but instead on the gradual evolution of processes and a precise understanding of energy and resource flows. Continual improvement, collaboration and systems thinking are the name of the game.

Future Applications of Biotechnology to the Energy Industry

Metrics details. Sugarcane is known to be one of the oldest cultivated plants in tropical and subtropical countries. Sugar industries are increasing exponentially to satisfy the growing demand for sugar; whereas, the ethanol distilleries have been rapidly expanding, since bioethanol emerged as an affordable, low carbon footprint and renewable bioenergy. However, inadequately treated and indiscriminate disposal of the effluent from sugarcane industries resulted in extensive soil and water pollutions. Hence, this study aimed at reviewing the sugarcane industrial process with its water consumption rates, and effluent characteristics and its adverse effects on the environment. Finally, the study has gone through the most common wastewater treatment efforts made to minimize the effluent environmental burden. In addition to the large volumes of sugar and ethanol industrial effluents, the presence of the different varieties of the pollutants in the effluent is challenging for conventional treatment methods.

Use of sugarcane industrial by-products for improving sugarcane productivity and soil health

This paper presents an overview of alternative uses for products of sugar beet processing, especially sucrose, as chemical raw materials for the production of biodegradable polymers. Traditionally, sucrose has not been considered as a chemical raw material, because of its use in the food industry and high sugar prices. Beet pulp and beetroot leaves have also not been considered as raw materials for chemical production processes until recently. However, current changes in the European sugar market could lead to falling demand and overproduction of sucrose. Increases in the production of white sugar will also increase the production of waste biomass, as a result of the processing of larger quantities of sugar beet. This creates an opportunity for the development of new chemical technologies based on the use of products of sugar beet processing as raw materials. Promising methods for producing functionalized materials include the acidic hydrolysis of sugars sucrose, biomass polysaccharides , the catalytic dehydration of monosaccharides to HMF followed by catalytic oxidation of HMF to FDCA and polymerization to biodegradable polymers.

Alternative energy news, and information about renewable energy technologies. The enormous increase in the quantum and diversity of waste materials generated by human activity and their potentially harmful effects on the general environment and public health, have led to an increasing awareness about an urgent need to adopt scientific methods for safe disposal of wastes.

There are few images more identifiably Australian than the lush green sugarcane fields of northern Queensland as trucks wait to gather their sweet harvest. While 30 percent of the crop yields sugar products, accounting for 95 percent of the revenue, the other two thirds left after harvest has little economic value and is largely treated as waste. His project seeks to convert trash into biofuels, which can then be used in transportation. In a neat twist, the trash left over from the sugar refining process could soon be fuelling the trucks and machines that help carry the process out. While the industry is already diversifying, producing enough renewable energy to supply surplus electricity to the grid, it is also a significant consumer of fossil fuels which produce greenhouse gas emissions in the growing, harvesting and transport of cane. The QUT project aims to reduce, if not eliminate entirely the use of fossil fuels in cane production by turning the trash into biomethane. I n this project, the focus is on converting the residues into biomethane or biodiesel. Rojo says that one advantage the cane industry has is the short transport distances from field to mill, which make it possible to replace diesel with biogas.

Turning human waste into plastic, nutrients could aid long-distance space travel (video)

Sugarcane is a water-intensive crop that remains in the soil all year long. Historic planting of sugarcane around the world has led to significant impacts on biodiversity. A vast global market for sugarcane derivatives keeps the industry booming.

Frontiers E-books Amazon. Petroleum hydrocarbons are both a product of, and rich substrate for, microorganisms from across all Domains of life. Rooted deeply in the history of microbiology, hydrocarbons have been studied as sources of carbon and energy for microorganisms for over a century.

Sugarcane industries are age-old industrial practices in India which contribute a significant amount of by-products as waste. Handling and management of these by-products are huge task, because those require lot of space for storage. However, it provides opportunity to utilize these by-products in agricultural crop production as organic nutrient source. Therefore, it is attempted to review the potential of sugar industries by-products, their availability, and use in agricultural production. A large number of research experiments and literatures have been surveyed and critically analyzed for the effect of sugarcane by-products on crop productivity and soil properties. Application of sugar industries by-products, such as press mud and bagasse, to soil improves the soil chemical, physical, and biological properties and enhanced the crop quality and yield. A huge possibility of sugarcane industries by-products can be used in agriculture to cut down the chemical fertilizer requirement. If all the press mud is recycled through agriculture about 32,, 28,, 14,, , , , and tonnes t of N, P, K, Fe, Zn, Mn, and Cu, respectively, can be available and that helps in saving of costly chemical fertilizers. Application of sugarcane industries by-products reduces the recommended dose of fertilizers and improves organic matter of soil during the crop production. It can also be used in combination with inorganic chemical fertilizers and can be packed and marketed along with commercial fertilizer for a particular cropping system. That helps in reduce the storage problem of sugarcane industries by-products across the India.

Sep 22, - The enormous increase in the quantum and diversity of waste materials turbines for electricity generation or to provide direct space and water heating. by the transformation of the waste into product gas as energy carrier for later . The sugar cane industry produces large volumes of bagasse each year.

How a waste product from the sugar industry could soon power the trucks that carry it

An award-winning team of journalists, designers, and videographers who tell brand stories through Fast Company's distinctive lens. Leaders who are shaping the future of business in creative ways. New workplaces, new food sources, new medicine--even an entirely new economic system. But the problem was the inspiration for the company, which launched six years ago. When the founders learned that hundreds of millions of pounds of watermelon stayed in fields to rot because the fruit was judged too unattractive for sale in supermarkets, they decided to create a product that could help avoid that waste. ReFed, an organization that tracks the food waste industry, counts at least 70 businesses and nonprofits that now transform food that otherwise would have been wasted into new products. The majority of these companies launched within the last five years.

Management of Sugar Industrial Wastes through Vermitechnology

Subscribe to our Newsletter and get informed about new publication regulary and special discounts for subscribers! Full Text PDF. This work is licensed under a Creative Commons Attribution 4. Rao, Comparative performance of cane sugar industry in seven countries. Bhat, J. Singh, A. Vig, Genotoxic assessment and optimization of pressmud with the help of exotic earthworm Eisenia fetida. Vig, Potential utilization of bagasse as feed material for earthworm Eisenia fetida and production of vermicompost.

All rights reserved. The Swedish city of Kristianstad uses biogas to generate electricity and heat and to fuel cars and municipal garbage trucks and buses. Its two refineries produce enough biofuel to replace 1. Biofuels have been around longer than cars have, but cheap gasoline and diesel have long kept them on the fringe.

Profile In rural areas in northern Laos -around Luang Prabhang province -there are still plenty of villagers producing cane sugar using traditional methods. Fresh cane juice is first obtained using a simple pressing tool.

There has been a dramatic growth in the production of biofuels in recent times. Global biofuel production tripled between and , and biofuels accounted for about 1.

Focusing of our actions on the circular economy and the regions, developing new ways of recovering non-food waste in our plants and preserving natural resources to the greatest extent possible. Recovering cellulose waste The Futurol project was intended to develop and demonstrate a process to produce ethanol biologically, known as second-generation ethanol, using ligno-cellulose material deriving from agricultural and forestry by-products, waste and dedicated crops.

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