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Автор: Grafiati
Опубліковано: 6 вересня 2023

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Статті в журналах з теми "Energy intensive industries- India"

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Soni, Archana, Arwind Mittal, and Manmohan Kapshe. "Energy Intensity analysis of Indian manufacturing industries." Resource-Efficient Technologies, no. 3 (September 1, 2017): 353–57. http://dx.doi.org/10.18799/24056529/2017/3/146.

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Анотація:
Energy has been recognized as one of the key inputs for the economic growth and social development of a country. India being one of the largest and rapidly growing developing countries, there is an impending energy crisis which requires immediate measures to be adopted. In this situation the concept of Energy Intensity comes under special focus to ensure energy security in an environmentally sustainable way. Energy Intensity of Indian manufacturing industries is among the highest in the world and stands for enormous energy consumption. Hence, reducing the Energy Intensity of Indian manufacturing industries is one of the challenges. This study attempts to analyse the factors which influence the Energy Intensity of Indian manufacturing industries and how they can be improved to reduce the Energy Intensity. The paper considers five of the largest energy consuming manufacturing industrial sectors in India viz. Aluminium, Cement, Iron & Steel Industries, Textile Industries and Fertilizer Industries and conducts a detailed Energy Intensity analysis using the data from PROWESS database of the Centre for Monitoring Indian Economy (CMIE) for the period 2005–2014.
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Oak, Hena. "ANALYSING FACTORS INFLUENCING ENERGY INTENSITY OF INDIAN CEMENT INDUSTRY." International Journal of Engineering Technologies and Management Research 5, no. 2 (February 10, 2020): 213–20. http://dx.doi.org/10.29121/ijetmr.v5.i2.2018.165.

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Анотація:
India is a fast growing economy, with a considerable dependence on energy resources. Energy resources mainly comprise of fossil fuels that are highly emission intensive. In order to move towards sustainable development, it is important to reduce emissions. Since a sizable amount of emissions gets generated from the use of energy resources, it is essential to use energy more efficiently and reduce energy intensity. In India the industrial sector is the biggest consumer of energy and hence energy intensity of this sector has to be improved. To achieve this, Bureau of Energy Efficiency and Ministry of Power launched the Perform-Achieve-Trade scheme for 8 most energy intensive industries in India. This study was conducted to analyse the impact of the Perform-Achieve-Trade scheme on the energy intensity of the Indian Cement Industry, which was one of the eight energy intensive industries. Effect of other determinants like FDI, Domestic R&D, Imports and Exports were also estimated. The paper does a panel data study for the years 1997-2015. Results suggest that BEE’S PAT scheme has been successful for the Cement industry as the designated consumers have lower energy intensity on an average during the periods this scheme was announced and implemented
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3

Verma, Piyush, Alka Verma, and Anupam Agnihotri. "India’s initiatives on Improving Energy Efficiency in Aluminium Industries." Asia Pacific Journal of Energy and Environment 2, no. 2 (December 31, 2015): 53–60. http://dx.doi.org/10.18034/apjee.v2i2.224.

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Анотація:
India is an important player in the aluminium, especially because of its abundant bauxite reserves and low-cost skilled manpower. The sector has a significant importance in the growth of Indian economy since the aluminium consumption follows GDP growth curve. Indian aluminium sector is observed as one of the energy intensive sectors with ample scope for improvements in energy efficiency as compared to world standards. The aluminium industries are upgrading themselves by adapting state-of-art technologies, which are more energy-efficient and sustainable in a highly competitive market. These initiatives are further accelerated and motivated by an innovative incentivization scheme (called Perform, Achieve and Trade) of Govt. of India. Currently, the first phase (2012-15) is under implementation, and an unexpected movement towards energy efficiency is envisaged as a result that will ultimately lead towards production of low carbon aluminium for the society.
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Golder, Bishwanath. "Energy Intensity of Indian Manufacturing Firms." Science, Technology and Society 16, no. 3 (November 2011): 351–72. http://dx.doi.org/10.1177/097172181101600306.

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Анотація:
The energy intensity of Indian manufacturing has declined signifi cantly since 1992. Between 1992–93 and 2007–08, it fell by about 50 per cent. However, it seems, there is scope for further substantial decline in energy intensity, since industrial energy consumption data across states indicate signifi cant inter-plant variation in the energy intensity of energy-intensive industries. The paper examines the factors that infl uence energy intensity in Indian industries. The results of the analysis indicate that the post-1992 decline in energy intensity of Indian manufacturing is attributable mostly to an improvement in energy use efficiency of energy-intensive industries, which in turn may be traced in part to hikes in the real price of energy paid by manufacturing fi rms. The results also show a signifi cant impact of technological change on energy intensity and presence of energy efficiency spillover effects from foreign fi rms to local firms.
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Bagchi, Prantik, and Santosh Kumar Sahu. "Energy Intensity, Productivity and Pollution Loads: Empirical Evidence from Manufacturing Sector of India." Studies in Microeconomics 8, no. 2 (July 16, 2020): 194–211. http://dx.doi.org/10.1177/2321022220930968.

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Анотація:
We explain the relationship between energy intensity and productivity for the organized manufacturing sector of India. Using data from the secondary sources, we explain the relationships at aggregate, state and industry levels. The novelty of this paper lies in bringing in pollution loads in explaining inter-industry variations in energy intensity. Results of this study indicate that the organized manufacturing sector of India has gained energy efficiency and productivity. We found heterogeneity among Indian states in productivity growth and energy intensity. The results indicate that small states performed well whereas large states fall in the productivity paradox. The productivity dilemma hypothesis is validated at industry level analysis however, results are inconsistent to validate the decoupling growth hypothesis. Pollution loads as classified by Government of India, plays a vital role in explaining energy intensity variations across industries, which calls for better policies aiming at pollutive industries specifically to achieve sustainable growth for the manufacturing sector of the Indian economy.
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Anjana Das, Tara Chandra Kandpal. "A Modeling Framework for Estimating Energy Demand and CO2 Emissions from Energy Intensive Industries in India." Energy Sources 21, no. 7 (June 1999): 649–61. http://dx.doi.org/10.1080/00908319950014597.

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Mukherjee, Arijit, Soumendra Nath Basu, and Sayan Paul. "A REVIEW ON ENERGY EFFICIENCY OF STEEL PLANTS IN INDIA." International Journal of Engineering Technologies and Management Research 5, no. 4 (February 24, 2020): 7–16. http://dx.doi.org/10.29121/ijetmr.v5.i4.2018.203.

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Анотація:
The steel industry being highly energy intensive in nature is one the major consumers of energy. The iron and steel industry is the largest energy consuming manufacturing sector in the world. It is therefore that the question of fuel or energy has been of the highest importance in steel making, and one can boldly claim that all other conditions remaining constant, saving or wasting of fuel can make the difference between a profit or a loss of a steel plant. Energy conservation in steel plants is very crucial to ensure the competitiveness of the steel producing industries and to minimise environmental impacts. India's leading iron and steel companies, scored averages at best in Centre for Science and environment green rating test. The Indian iron and steel sector's energy consumption of 6.6 GCal per tonne, is 50 per cent higher than the global best practice. The integrated steel plants in India have the opportunities to strengthen their operations and minimise energy losses and wastages to reduce specific energy consumption by 5-6%. To reduce the gaps between India and developed countries we have to follow the technological advancement and implementation of innovative strategies at every stage of the operation of steel plants. The specific energy consumption in the Indian steel industry is high compared to that in advanced countries. Data for four integrated steel plants in India have been analysed. World crude steel production reached 1.621 million tones (Mt) in 2015. To meet the needs of our growing population, steel use is projected to increase by 1.5 times that of present level by 2050.
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Tripathy, Upendra Prasad, and Sunil Kumar Bishoyi. "Reduction of Colour from effluents of Pulp and Paper Industry by Ozonation: A Review." Research Journal of Chemistry and Environment 25, no. 12 (November 25, 2021): 170–74. http://dx.doi.org/10.25303/2512rjce170174.

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Анотація:
Pulp and paper making is the major old process industry in India which is water intensive and generates heavy water pollution. Pulp and paper industries are the fifth largest contributor to industrial water pollution. Waste water is generated from each and every section of paper making process and depends upon the type of pulping and bleaching process. Presently, primary and secondary (Biological) treatment systems based on activated sludge process are widely used by paper industry for effluent treatment. The process requires high energy and chemical inputs and involves high operational costs. One of the novel processes for treating effluent is its oxidation through ozonation which is a greener way of degrading pollutants. Ozonation of intermediate stage effluents having high colour load is more effective for industrial application and re-utilization.
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Nabernegg, Stefan, Birgit Bednar-Friedl, Fabian Wagner, Thomas Schinko, Janusz Cofala, and Yadira Mori Clement. "The Deployment of Low Carbon Technologies in Energy Intensive Industries: A Macroeconomic Analysis for Europe, China and India." Energies 10, no. 3 (March 14, 2017): 360. http://dx.doi.org/10.3390/en10030360.

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Athira, G., A. Bahurudeen, and Srinivas Appari. "Sustainable alternatives to carbon intensive paddy field burning in India: A framework for cleaner production in agriculture, energy, and construction industries." Journal of Cleaner Production 236 (November 2019): 117598. http://dx.doi.org/10.1016/j.jclepro.2019.07.073.

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Більше джерел

Дисертації з теми "Energy intensive industries- India"

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Jasonarson, Ivar Kristinn. "Digitalization for Energy Efficiency in Energy Intensive Industries." Thesis, KTH, Energiteknik, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-276987.

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Анотація:
A fourth industrial revolution (Industry 4.0) is on the horizon. It is enabled by advancements in information and communication technologies (i.e. digitalization) and concepts such as the Internet of Things and cyber-physical systems. Industry 4.0 is expected to have great impact on the manufacturing and process industries, changing how products are developed, produced and sold. However, Industry 4.0 is a novel concept and its impacts are still uncertain. An increasingly strict climate and energy agenda in Sweden is putting pressure on the industrial sector and it is, therefore, important that the sector exploits the full potential Industry 4.0 can provide for increased sustainability. This thesis examines the status of digitalization in the Swedish energy intensive industries (i.e. pulp and paper, steel, and chemical industries) and how it could impact energy efficiency in the sector. Qualitative research methods were used to carry out the study. A literature review and in-depth interviews with employees within the industries were conducted. The results show that, while digitalization is considered important for the future competitiveness of the Swedish energy intensive industries, the digital maturity of the sector is not considered high. Digital technologies can increase energy efficiency in a number of different ways (e.g. through better optimization tools, increased availability of processes and more efficient maintenance management). However, there is not a clear link between digital strategies and energy efficiency measures in the energy intensive industries in Sweden. Moreover, energy efficiency is not considered the main driver for implementing digital technologies, it is rather considered a positive side effect. To accelerate the implementation of digital technologies it is important to support further research in this area and encourage a closer cooperation between stakeholders as well as mitigating challenges such as uncertainty regarding return on investment and issues related to data security and ownership.
Industrin är på väg in i en fjärde industriell revolution (Industri 4.0). Revolutionen möjliggörs av framsteg inom informations- och kommunikationsteknologier (digitalisering) och koncept som internet av saker och cyberfysiska system. Industri 4.0 förväntas ha en stor påverkan på tillverknings- och processindustrin, vilket kommer att förändra hur produkter utvecklas, produceras och säljs. Industri 4.0 är dock ett nytt koncept och dess effekter är fortfarande osäkra. I samband med att en allt strängare klimat- och energiagenda i Sverige sätter press på industrisektorn, är det viktigt att sektorn utnyttjar den fulla potentialen som Industri 4.0 kan bidrag med för en ökad hållbarhet. Det här examensarbetet analyserar det nuvarande läget för digitalisering inom de svenska energiintensiva industrierna (dvs. massa och pappers-, stål- och kemisk industrin) och hur det kan påverka energieffektiviteten i sektorn. Studien genomfördes med hjälp av kvalitativa forksningsmetoder. En litteraturstudie och fördjupade intervjuer med anställda inom branscherna genomfördes. Resultaten visar att trots att digitalisering anses vara viktig för de svenska energiintensiva industriernas framtida konkurrenskraft, anses sektorns digitala mognad inte vara hög. Digital teknik kan öka energieffektiviteten på ett antal olika sätt (t.ex. genom bättre optimeringsverktyg, ökad tillgänglighet av processer och effektivare underhållshantering). Det finns dock ingen tydlig koppling mellan digitala strategier och energieffektivitetsåtgärder i de energiintensiva industrierna i Sverige. Dessutom anses energieffektivitet inte vara den främsta drivkraften för att implementera digitala teknologier, utan anses snarare vara en positiv bieffekt. För att påskynda implementeringen av digital teknik är det viktigt att fortsätta stötta forskningen inom området och uppmuntra till ett närmare samarbete mellan olika aktörer samt bemöta utmaningar som osäkerheten kring framtida avkastningar på investeringar och frågor relaterade till datasäkerhet och ägande.
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2

Teng, Sin Yong. "Intelligent Energy-Savings and Process Improvement Strategies in Energy-Intensive Industries." Doctoral thesis, Vysoké učení technické v Brně. Fakulta strojního inženýrství, 2020. http://www.nusl.cz/ntk/nusl-433427.

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Анотація:
S tím, jak se neustále vyvíjejí nové technologie pro energeticky náročná průmyslová odvětví, stávající zařízení postupně zaostávají v efektivitě a produktivitě. Tvrdá konkurence na trhu a legislativa v oblasti životního prostředí nutí tato tradiční zařízení k ukončení provozu a k odstavení. Zlepšování procesu a projekty modernizace jsou zásadní v udržování provozních výkonů těchto zařízení. Současné přístupy pro zlepšování procesů jsou hlavně: integrace procesů, optimalizace procesů a intenzifikace procesů. Obecně se v těchto oblastech využívá matematické optimalizace, zkušeností řešitele a provozní heuristiky. Tyto přístupy slouží jako základ pro zlepšování procesů. Avšak, jejich výkon lze dále zlepšit pomocí moderní výpočtové inteligence. Účelem této práce je tudíž aplikace pokročilých technik umělé inteligence a strojového učení za účelem zlepšování procesů v energeticky náročných průmyslových procesech. V této práci je využit přístup, který řeší tento problém simulací průmyslových systémů a přispívá následujícím: (i)Aplikace techniky strojového učení, která zahrnuje jednorázové učení a neuro-evoluci pro modelování a optimalizaci jednotlivých jednotek na základě dat. (ii) Aplikace redukce dimenze (např. Analýza hlavních komponent, autoendkodér) pro vícekriteriální optimalizaci procesu s více jednotkami. (iii) Návrh nového nástroje pro analýzu problematických částí systému za účelem jejich odstranění (bottleneck tree analysis – BOTA). Bylo také navrženo rozšíření nástroje, které umožňuje řešit vícerozměrné problémy pomocí přístupu založeného na datech. (iv) Prokázání účinnosti simulací Monte-Carlo, neuronové sítě a rozhodovacích stromů pro rozhodování při integraci nové technologie procesu do stávajících procesů. (v) Porovnání techniky HTM (Hierarchical Temporal Memory) a duální optimalizace s několika prediktivními nástroji pro podporu managementu provozu v reálném čase. (vi) Implementace umělé neuronové sítě v rámci rozhraní pro konvenční procesní graf (P-graf). (vii) Zdůraznění budoucnosti umělé inteligence a procesního inženýrství v biosystémech prostřednictvím komerčně založeného paradigmatu multi-omics.
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Waldemarsson, Martin. "Planning production and supply chain in energy intensive process industries." Doctoral thesis, Linköpings universitet, Produktionsekonomi, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-112289.

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Анотація:
To make a difference among the energy intensive process industries, this dissertation addresses production planning and supply chain planning problems related to industrial energy management issues. The energy issue is turning more and more important from different angles, involving price as well as environmental problems due to climate change leading to political pressure on all energy users. The process industry sector is one of the largest users of energy, and thus important to analyse. Process industries are also capital intensive and operate on large and expensive process equipment, making it imperative to plan their production well in order to reach preferable capacity utilisation. Therefore this dissertation strives to locate the most important energy management issues for the long term profitability of process industries, and investigates the  symbiotic effects of including energy issues in production and supply chain planning. Three different studies at three case companies are carried out, analysed, and presented in five papers. The cases represent the process industry sectors: chemicals, pulp, and steel. Both qualitative case study methodologies as well as quantitative mathematical modelling and optimisation approaches have been practiced. The research questions are analysed from both an energy system and from a production process point of view, separately as well as combined. Energy is somewhat considered to be the main workforce for process industries and this dissertation exemplifies some of its most important dimensions in this context. Several prerequisites for putting energy management on the strategic agenda are located in a specialty chemical industry where the importance of introducing a strategic perspective on energy, the way energy is used, and the possibilities of increasing alternative revenue from utilising by- and/or co-products differently are pinpointed. Approaches for including energy issues in planning processes are also suggested in terms of a MILP model for the entire supply chain of a pulp company, including decisions on purchase and transportation of raw maerials, production allocation, energy mix, and distribution. Another example is presented based on the perspectives of economics of scale and lot sizing through economic order quantity principles in a steel company. By using real company data, energy smart approaches in planning and scheduling are developed with respect to the most important intersections between the production processes and their supporting energy system. The accumulated resource intensity and embedded energy could, and probably should, hence be more fairly  reflected in the product price. The research finally shows some possible impact with including energy issues in a production and supply chain planning model. By planning differently, production prioritisations can be done, and it is not only possible without any large investments, but also prosperous with savings on both energy and money within reach. To conclude, planning of production and supply chain has either a direct or an indirect impact on the energy cost-effectiveness of a company. This dissertation argues that such impact also exists in its mutual form, and is very important when the energy issues are large enough, as they often are in the energy intensive process industry sector. Decision makers should thus beware of the short end of the stick that might be  devastating in the long run, but also aware of all the possibilities that can bring success and prosperity when the future begins.
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4

Mukhopadhyay, Boidurjo. "Solar energy based entrepreneurship and rural development : analysing institutional arrangements that support solar energy entrepreneurs in India." Thesis, University of Sussex, 2017. http://sro.sussex.ac.uk/id/eprint/68229/.

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Renewable energy (RE hereafter) has been observed as a potentially significant new source of jobs and rural growth in both OECD and BRICs countries, and a means of addressing environmental and energy security concerns. The global deployment of RE has been expanding rapidly. For instance, the RE electricity sector grew by 26% between 2005 and 2010 globally and currently provides about 20% of the world's total power (including hydro-power) (OECD, 2012). Rural areas attract a large part of investment related to renewable energy deployment, rending to be sparsely populated but with abundant sources of RE. Several case studies have found that RE deployment can provide hosting communities with some benefits including new revenue sources, new job and business opportunities, innovation in products/practices/policies in rural areas, capacity building and community empowerment, and affordable energy. There is a growing body of evidence on the instrumental role that entrepreneurs and small businesses play in driving local and national economies. The structure of rural economies is essentially composed of small enterprises, which are responsible for most of the job growth and the innovation. Rural development is a key element of strategies to reduce poverty and create income and employment opportunities (UNIDO, 2003). It is important to unleash and harness the creativity of grassroots entrepreneurs but they are posed with many challenges, the biggest being these grassroots inventions don't scale up. To overcome these challenges and promote rural entrepreneurship, support roles are required; this is also where the importance and role of institutions and their planned arrangements (for example, partnerships) are much debated in both domestic and international forums. This research investigates the current institutional arrangements that support solar entrepreneurship which creates solar energy based income-generating micro enterprises in rural India. In addition to that, it explores the wider implications on rural development that these entrepreneurships have while using these solar RETs. Institutions and individuals promoting rural development see entrepreneurship as a strategic development intervention that could accelerate the rural development process (Ezeibe, 2013). India, being the only country with a national ministry dedicated to RE initiatives (the MNRE, Government of India) and also ranking third on the renewable energy country attractiveness index (E&Y, 2013; 2016) makes an interesting country choice for investigation. The thesis applies a qualitative research method with an exploratory design to understand the interaction process between institutions and how different institutions support rural development to generate an in-depth analysis of existing institutions using a conceptual framework.
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5

Kobori, Satoru. "Development of energy conservation technology in Japan, 1920–1970: specific examination of energy intensive industries and energy conservation policy." 名古屋大学大学院経済学研究科附属国際経済政策研究センター, 2014. http://hdl.handle.net/2237/20961.

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6

Bosnjak, Vjekoslav. "Waste Heat Recovery in Intensive Small and Medium Sized Industries : Case Study - Gästrike Härdverkstad." Thesis, Högskolan i Gävle, Avdelningen för bygg- energi- och miljöteknik, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:hig:diva-13816.

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Анотація:
In order to keep a high level and to stay competitive in the world market in the future, it is important for the Swedish steel industry to improve their efficiencies continuously and to reduce the energy consumption. In order to realize these goals, the Swedish steel association Jernkotoret was found and by their initiative Triple Steelix was found in 2006 in Berglanden, a significant area for the steel industry. In 2009, the Clean Production Centre was found in Hofors in order to build a cluster of local steel manufacturers, factories and companies. One of those companies is Gästrike Härdverkstad, a small steal heat treatment industry with six employees and about 700.000 tons treated materials every year. The aim for this thesis is to suggest solutions for recovering waste heat and lowering the total energy consumption in furnaces for heat treatment in the case of Gästrike Härdverkstad. Some limitations were necessary to complete the analysis and to come to conclusions. The yearly treated material and energy prices were assumed to be constant and the yearly power consumption was estimated by an extrapolation of a one to five days measurement. Gästrike Härdverkstad is located in Uhrfors, the southern part of Åshammar, a village with 727 inhabitants. There are not any buildings with a possibility to supply heat and there is no district heating in the surroundings. The company has a power consumption of 1.40 GWh/year, of which 65.7% is consumed by the 12 main furnaces. The rest is used by eight seldom used furnaces, devices and auxiliary machines of the support process like fans, pumps, compressor, office heating, and some other. The efficiencies of the main furnaces are between 10% and 20%.The estimated energy consumption of the space heating is about 27 MWh/year, which completely can be covered by the material coolant and the combustion heat of the exhaust gases from the hardening furnaces. Since there are 10 different types of furnaces with different duties and efficiencies, the preheating furnace was taken as an example and compared with a new furnace. According to the needs of Gästrike Härdverkstad, the furnace VAW 60/100-650°C from the company Vötsch was chosen at the cost of 248,827 SEK. The payback time depends on the efficiency. With an efficiency of 40% the payback time would be about 13 years, see Figure 20. After the annealing and ageing, the finished products are cooled down in the building hall by the ambient air. In future, the possibility of preheating the material with the heat of the finished products should be considered. With an efficiency of 30.87%, one preheating furnace could bereplaced, and taken a payback time of 5 years into account; the price of the construction would be allowed to be up to 253,200 SEK.
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Radke, William Henry. "The interrelationships of electric utilities and energy intensive industries : the case of the primary aluminum industry." Thesis, Georgia Institute of Technology, 1991. http://hdl.handle.net/1853/28778.

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Chantramonklasri, N. "Technological responses to rising energy prices : A study of technological capability and technical change efforts in energy-intensive manufacturing industries in Thailand." Thesis, University of Sussex, 1985. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.372063.

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Bagayev, Igor. "The energy-intensive legacy in Eastern Europe and Central Asia." Thesis, Paris Est, 2015. http://www.theses.fr/2015PESC0051.

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Cette thèse vise à analyser les enjeux et les conséquences la consommation énergétique dans les pays anciennement communistes d’Europe et d’Asie Centrale (EAC). Plus particulièrement, nous soulevons la question des politiques économiques à mettre en place afin d’améliorer l’efficacité énergétique dans cette région et analysons les conséquences en termes de pollution et de croissance de la spécialisation intensive en énergie de leurs économies.Le système d’économie planifié a profondément altéré les structures économiques et la trajectoire de consommation énergétique de ces pays. En effet, une des empreintes restantes de l’économie de type soviétique réside dans l’importante intensité énergétique et la forte spécialisation des pays EAC dans les industries intensives en énergie. Les récentes crises géopolitiques vis-à-vis de la Russie, l’épuisement des ressources énergétiques fossiles ainsi que la problématique environnementale mettent en exergue l’importance de la question énergétique dans ces pays.La présente thèse s’intéresse plus spécifiquement à deux problèmes fondamentaux. Comment améliorer les performances énergétiques des pays Est-Européens ? Et quel est l’impact de la spécialisation dans les industries structurellement intensives en énergie sur la croissance des pays EAC ?Dans le premier chapitre, nous analysons les fondations microéconomiques de la demande énergétique en se focalisant sur les déficiences de marché qui peuvent contraindre l’efficacité énergétique des firmes. Nous nous intéressons en particulier à l’effet relié au développement financier. L’inefficience des marchés financiers est une des principales explications du « paradoxe d’efficience énergétique », mais n’a pour l’instant pas été empiriquement démontré. Les résultats empiriques de ce chapitre montrent que les marchés financiers locaux jouent un rôle important dans la consommation énergétique des firmes.Le chapitre 2 examine dans quelle mesure la réglementation environnementale de l’Union Européenne (UE) impacte la spécialisation des pays est-européens dans les industries polluantes. En ce sens, ce chapitre traite de la question centrale du développement de havres de pollution en Europe de l’Est. Nos résultats indiquent que les exportations des pays EAC vers un pays de l’UE sont relativement plus importantes dans des secteurs polluants lorsque ce pays a dû mettre en place des mesures environnementales. Cet effet est rendu robuste au biais de variables omises grâce à l’inclusion d’un ensemble d’effets fixes. De plus, le problème potentiel de causalité inverse est traité grâce à l’utilisation d’un instrument exogène de politique environnementale basé sur les conditions climatiques des pays.Au-delà des problèmes liés à l’environnement, le chapitre 3 analyse les conséquences économiques de la spécialisation dans des industries énergivores dans la région EAC. En effet, cette spécialisation est un héritage direct de l’ancien système d’économie planifiée. L’économie planifiée de type soviétique a façonné une spécialisation dans des secteurs industriels très énergivores, et ce indépendamment des caractéristiques structurelles spécifiques des différents pays de l’ancien bloc de l’Est. La volonté idéologique et les distorsions de marché dans ces économies ont été les principaux moteurs d’un surdéveloppement des industries extrêmement énergivores. L’effet de la sur-spécialisation dans les industries intensives en énergie est strictement négatif et significatif dans toutes nos estimations. Ce résultat est robuste et met en exergue des symptômes de « maladie soviétique ». Les pays anciennement communistes qui maintiennent des distorsions de spécialisation dans les secteurs industriels développés sous le système d’économie planifiée font face à de moins bonnes performances économiques. Ainsi, maintenir une spécialisation industrielle intensive en énergie est inefficace aussi bien d’un point de vue environnemental que d’un point de vue économique
The current thesis raises important issues about the drivers able to improve energy intensity of the Eastern Europe and Central Asia (ECA) region from both an efficiency point of view and in terms of structural specialization in energy-intensive sectors. In particular, we question about the rationale of keeping a high degree of specialization in energy-intensive sectors, given that this specialization was primarily based on the mechanisms of the former planned economy system. This dissertation consists of three empirical essays studying these issues.We focus on two main questions. How to improve energy and pollution performances of the ECA countries? And how the over-specialization in energy-intensive sectors affects their economic growth? The first question is examined in Chapters 1 and 2, whereas the second question is discussed in Chapter 3.To address these issues there is a need to analyze the two components of the energy intensity, namely the energy efficiency and the structural specialization in energy intensive sectors, with the adequate levels of investigation. To cover the scope of the different problems raised by the legacy of high energy intensity in the ECA countries, I thus rely on micro-, sector- and macro-level analysis. Chapter 1 considers the market constraints to firm-level energy efficiency and examines whether the financial development explains the firm-level energy efficiency. Then, using bilateral export flows at the industry-level, Chapter 2 studies how environmental policy inside the EU influences the energy- and pollution- intensive specialization in ECA countries that are not EU members. More specifically, this chapter aims to exhibit to what extent the EU environmental stringency fosters the pollution havens in the ECA region by stimulating exports in energy-intensive sectors. And finally, Chapter 3 seeks to provide macroeconomic evidence about the growth consequences of the maintaining of a specialization highly oriented towards energy-intensive sectors. This ultimate chapter tries to identify whether over-specialization in energy-intensive sectors is negative for growth performances in this region
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10

Xylia, Maria. "Is energy efficiency the forgotten key to successful energy policy? : Investigating the Swedish case." Licentiate thesis, KTH, Energi och klimatstudier, ECS, 2016. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-192291.

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Sweden aims to become one of the first fossil-free welfare countries in the world. In 2009, specific energy and climate policy targets were announced for 2020, which exceed the ambition of respective EU targets in some areas. The overarching objective of the thesis is to understand the role of energy efficiency in Swedish energy and climate policy frameworks, and identify the gaps that need to be addressed. In this context, energy efficiency is recognized as a challenge to address. Yet, there are reasons to believe that it is not being pursued with the same dedication as other energy and climate-related targets. This hypothesis is tested using Mixed Methods research, with cases on different sectors of the Swedish economy, namely energy intensive industry and public bus transport, as well as comparisons with energy efficiency within the EU-28. With the help of abductive reasoning, the observations are inferred to an explanation, and common themes for Swedish energy efficiency policies emerge. The evidence indicates that energy efficiency has received lower priority than other energy and climate policies. This is demonstrated by the conflict between energy efficiency, emission reduction and renewable energy targets, for example in the case of public transport. There is generally a mismatch between targets and the instruments in place. Thus more attention should be given to energy efficiency and its potential benefits for the Swedish energy system. Opportunities for energy efficiency improvements are not being fully realized, but new policy initiatives could provide the necessary support to harness the potential. In-depth evaluation of new policy instruments should be integrated in the policy-making process, in order to provide a clear picture of costs versus benefits. An example is given with a Cost-Benefit Analysis for energy efficiency obligations targeting the Swedish energy intensive industry. Simplicity and transparency in the introduction and monitoring of new instruments need to be sought for. Energy efficiency should be given first priority in relation to other energy and climate targets. The basis for future policies should be grounded now in order for energy efficiency to become the key for successful Swedish energy policy.

QC 20160914

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Книги з теми "Energy intensive industries- India"

1

Gaba, Kwawu Mensan. Energy intensive sectors of the Indian economy: Path to low carbon development. Washington: International Bank for Reconstruction and Development, World Bank, 2011.

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2

Federation of Indian Chambers of Commerce and Industry. Energy: Who's who in India. Ahmedabad: Saket Projects, 2003.

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3

Naseem, Mohammad. Energy law in India. Alphen aan den Rijn, The Netherlands: Kluwer Law International, 2014.

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4

Energy law in India. Alphen aan den Rijn, The Netherlands: Kluwer Law International, 2011.

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5

Sengupta, M. Energy and power policies in India. New Delhi: S. Chand, 1985.

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6

Barkakati, Dipankar. Energy scene in India: Problems and prospects. New Delhi: Associated Chambers of Commerce & Industry of India, 1990.

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7

Kothari, Virendra S. Industrial energy policies of India. New Delhi: Tata Energy Research Institute, 1987.

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8

Institute, Tata Energy Research, Commission of the European Communities., Chiʻng hua ta hsüeh (Beijing, China). Institute of Nuclear Energy Technology., and Chiʻng hua ta hsüeh (Beijing, China). Institute for Techno-Economics and Energy System Analysis., eds. Energy developments in China and India: A comparative study of energy supply, energy consumption, and energy policies. New Delhi, India: Tata Energy Research Institute and Institute of Nuclear Energy Technology and Institute for Techno-Economics and Energy System Analysis, Tsinghua University, Beijing, China, 1990.

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9

Sutherland, Ronald J. The impact of high energy price scenarios on energy-intensive sectors: Perspectives from industry workshops. Argonne, Ill: Argonne National Laboratory, 1997.

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10

1955-, Taylor Robert P., and World Bank, eds. Financing energy efficiency: Lessons from Brazil, China, India, and beyond. Washington, DC: World Bank, 2008.

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Частини книг з теми "Energy intensive industries- India"

1

Sahu, Santosh Kumar, and K. Narayanan. "Labour and Energy Intensity: A Study of the Pulp and Paper Industries in India." In Human Capital and Development, 55–76. India: Springer India, 2012. http://dx.doi.org/10.1007/978-81-322-0857-0_5.

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2

Chakraborty, Debrupa. "Recycled Paper from Wastes: Calculation of Ecological Footprint of an Energy-Intensive Industrial Unit in Orissa, India." In Environmental Implications of Recycling and Recycled Products, 259–82. Singapore: Springer Singapore, 2015. http://dx.doi.org/10.1007/978-981-287-643-0_10.

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3

Kristjánsdóttir, Helga. "The Importance of Renewable Energy for the Power Intensive Industry, from an Economic Perspective." In Economics and Power-intensive Industries, 41–49. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-12940-2_6.

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4

Blesl, Markus, and Alois Kessler. "Industries with Their Highly Specialized or Energy-Intensive Processes." In Energy Efficiency in Industry, 283–442. Berlin, Heidelberg: Springer Berlin Heidelberg, 2021. http://dx.doi.org/10.1007/978-3-662-63923-8_8.

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5

Merkert, Lennart, and Iiro Harjunkoski. "Integrating Energy Optimization and Production Scheduling in Energy-Intensive Industries." In Advances in Energy Systems Engineering, 601–20. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-42803-1_20.

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Sahu, Santosh Kumar, and K. Narayanan. "Exports and Participation in CDM in Technology Intensive Industries in India." In India Studies in Business and Economics, 121–40. Singapore: Springer Singapore, 2015. http://dx.doi.org/10.1007/978-981-10-0083-6_6.

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7

Foersund, Finn R. "Choice of Technology and Long-Run Technical Change in Energy Intensive Industries." In International Association of Energy Economists, 615–29. New York: Routledge, 2020. http://dx.doi.org/10.4324/9780429268175-43.

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8

Johansson, Mans. "LCC-based Guidelines on Procurement of Energy Intensive Equipment in Industries." In Energy Efficiency Improvements in Electronic Motors and Drives, 546–49. Berlin, Heidelberg: Springer Berlin Heidelberg, 2000. http://dx.doi.org/10.1007/978-3-642-59785-5_53.

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Nandan, Abhishek, S. M. Tauseef, and N. A. Siddiqui. "Assessment of Ambient Air Quality Parameters in Various Industries of Uttarakhand, India." In Materials, Energy and Environment Engineering, 279–90. Singapore: Springer Singapore, 2017. http://dx.doi.org/10.1007/978-981-10-2675-1_33.

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10

Hulme, Charlotte. "The Train Has Left the Station: Automotive and Energy-Intensive Industries." In Environmental Politics and Theory, 83–121. Cham: Springer Nature Switzerland, 2023. http://dx.doi.org/10.1007/978-3-031-34115-1_3.

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Тези доповідей конференцій з теми "Energy intensive industries- India"

1

Soni, Nimish, Venkoparao Vijendran Gopalan, and R. Varadharajan. "Electrical and operational anomaly detection in energy intensive manufacturing industries." In 2016 IEEE Annual India Conference (INDICON). IEEE, 2016. http://dx.doi.org/10.1109/indicon.2016.7839161.

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2

Sathish, Sharath, Pramod Kumar, Logesh Nagarathinam, Lokesh Swami, Adi Narayana Namburi, Venkata Subbarao Bandarupalli, and Pramod Chandra Gopi. "Brayton Cycle Supercritical CO2 Power Block for Industrial Waste Heat Recovery." In ASME 2019 Gas Turbine India Conference. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/gtindia2019-2347.

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Abstract The Brayton cycle based supercritical CO2 (sCO2) power plant is an emerging technology with benefits such as; higher cycle efficiency, smaller component sizes, reduced plant footprint, lower water usage, etc. There exists a high potential for its applicability in waste heat recovery cycles, either as bottoming cycles for gas turbines in a combined cycle or for industrial waste heat recovery in process industries such as iron & steel, cement, paper, glass, textile, fertilizer and food manufacturing. Conventionally steam Rankine cycle is employed for the gas turbine and industrial waste heat recovery applications. The waste heat recovery from a coke oven plant in an iron & steel industry is considered in this paper due to the high temperature of the waste heat and the technological expertise that exists in the author’s company, which has supplied over 50 steam turbines/ power blocks across India for various steel plants. An effective comparison between steam Rankine cycle and sCO2 Brayton cycle is attempted with the vast experience of steam power block technology and extending the high pressure-high temperature steam turbine design practices to the sCO2 turbine while also introducing the design of sCO2 compressor. The paper begins with an analysis of sCO2 cycles, their configurations for waste heat recovery and its comparison to a working steam cycle producing 15 MW net power in a coke oven plant. The sCO2 turbomachinery design follows from the boundary conditions imposed by the cycle and iterated with the cycle analysis for design point convergence. The design of waste heat recovery heat exchanger and other heat exchangers of the sCO2 cycle are not in the scope of this analysis. The design emphasis is on the sCO2 compressor and turbine that make up the power block. This paper highlights the design of a sCO2 compressor and turbine beginning from the specific speed-specific diameter (Ns-Ds) charts, followed by the meanline design. Subsequently, a detailed performance map is generated. The relevance of this paper is underscored by the first of a kind design and comparative analysis of a Brayton sCO2 power block with a working Steam Power block for the waste heat recovery in the energy intensive iron and steel industry.
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3

Locatelli, Giorgio, Mauro Mancini, and Pietro Belloni. "Assessing the Attractiveness of SMR: An Application of INCAS Model to India." In 2013 21st International Conference on Nuclear Engineering. American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/icone21-15932.

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Small Modular Reactors (SMRs) have the potential to be an important component of the worldwide nuclear renaissance. Whilst requiring more diluted investment than Large Reactors (LRs), SMRs are simpler build and operate as well as being suitable for deployment in harsh environmental conditions. In addition, useful by-products such as desalinated water and process heat are generated. The economic competitiveness of SMRs with respect to LRs must be carefully evaluated since the economies of scale label these reactors as not economically competitive. As such, a variety of financial and economic models have been developed by the scientific community in order to assess the competitiveness of SMRs. One of these, the INCAS model (Integrated model for the Competitiveness Assessment of SMRs), performs an investment project simulation and assessment of SMR and LR deployment scenarios, providing monetary indicators (e.g. IRR, LUEC, total equity invested) and not-monetary indicators (e.g. design robustness, required spinning reserve). The work in this paper investigates the attractiveness of SMRs for a given scenario, the Indian state, through application of the INCAS model. India is the second most populated country in the world with rapid economic growth and a huge requirement for energy. There is also both good public acceptance and political support for nuclear power in India, important factors favoring the deployment SMRs in particular. India seems particularly suitable for SMR deployment because (i) its energy intensive industrial sites are located far from existing grids, (ii) rapid growth in the region and (iii) the requirement for plants to provide fresh water for the population, as well as for agriculture and industry. The results show that SMRs have roughly the same financial performance of LRs, however they have a competitive advantage as a result of non-financial factors such as co-generation application, higher local content and better management of the spinning reserves in a country with an electricity deficit.
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4

Su, Ziyi, Kazuaki Inaba, Amit Karmakar, and Apurba Das. "Characterization of Mechanical Property of PLA-ABS Functionally Graded Material Fabricated by Fused Deposition Modeling." In ASME 2021 Gas Turbine India Conference. American Society of Mechanical Engineers, 2021. http://dx.doi.org/10.1115/gtindia2021-76025.

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Abstract Application of functionally graded materials (FGMs) in energy, aviation and nuclear industries has increased since the last decade due to potential reduction of in-plane and transverse through-the-thickness stresses, enhanced residual stress distribution, superior thermal properties, free from delamination, and reduced stress intensity factors. FGMs are categorized as an advanced class of composite materials where the two constituent materials are graded along the thickness direction. Absence of sharp change in material property in the interface layer eliminates the problem of delamination and debonding, which is a major concern for traditional composite material. In this work, PLA-ABS functionally graded material is manufactured using additive manufacturing techniques through fused deposition modeling (FDM) using Y-type extruder. X-ray computed tomography test is conducted to see the air void (generated during printing) distribution in the printed FGM. Tensile test (as per ISO-527standrad) is conducted to evaluate the Young’s Modulus of additive manufactured FGMs. Three different measuring positions are considered in the FGM specimens to check the effect of property change along the grading direction. Tensile test results of PLA-ABS FGM are compared with their individual constituents (ABS and PLA). Further, flexural vibration test is conducted to evaluate the natural frequency of printed FGM beam. Experimentally determined mechanical and dynamic characteristics in terms effective Young’s Modulus and natural frequency are analyzed and discussed.
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5

Ahuja, Anil K., Sanjay Pande, Vivek Gangwar, Yogesh Sharma, and Anubhav Dahiya. "A Study of Indian Power Plant MRO (Maintenance Repair Overhaul) Industry." In ASME 2008 Power Conference. ASMEDC, 2008. http://dx.doi.org/10.1115/power2008-60023.

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Indian power sector has made significant progress despite legacy industry constraints. The current installed capacity is 140,000 MW and is growing at about 10% annually. The capacity utilization is beyond known benchmarks i.e. national average is over 78% and while NTPC over 92%. Traditional Indian MRO strategy is based on strategic improvisations to obtain the best out of prevailing industry and restricted maintenance windows. Power plant MRO in India faces issues of service and quality response. It presents an area which has scope for systemic improvements. The subject is also important due to linkage to energy efficiency improvement potentials which are central to global climate initiatives. “MRO Study Project” was undertaken by NTPC (along with Frost & Sullivan) with participation of other Indian generating companies to create a holistic industry view to accurately directionalize the improvement efforts. Power plant MRO is a weakly documented subject in India whereas for industrial countries it’s an almost settled issue. The project — which targeted creation of insights into power station and vendor side — therefore called for significant primary research. Teams visited most of the 36 participating Indian power stations and interviewed 40 MRO vendors (out of 200 participants). For best practice reference creation, visits were made to 7 power stations in Germany while information was also gathered from USA, South Africa and China. The project deliverables include a project report and certain data base considered useful to the industry. Indian power plant MRO has evolved around capacity utilization as the centre. The processes are man power intensive characterized by 1000 very small vendors who work for some 140 thermal stations. Survey indicated service and quality issues as well as inadequate technical back up of vendors which is compensated by plant personnel supervision. New objectives of efficiency improvement and costs reduction call for fundamental changes in areas of tooling, craft skill sets and procedures. MRO Destination envisions emergence of new industry components other than workforce providers — maintenance companies, maintenance schools, certification companies etc. The road map for change recommends three key focus areas: tariff structure which incentivizes efficiency improvement through MRO, best practice infusion to the MRO business and contracting processes improvements of power stations. Involvement of international vendors is expected to provide the best practice exposure as well as catalyze changes in the internal systems. Industry level initiative is recommended by creating a platform for accelerating change and cost effectiveness. The paper presents the project process, key data/analysis, salient findings and business opportunities. For India and many developing countries with similar focus, the work could be useful as it provides a structured platform for internal diagnostics on MRO as well as provides the prospective partners (international utilities and MRO service providers) with Indian MRO business nuances and opportunities to better plan possible business tie ups.
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6

Wang, Anbo. "Optical fiber sensors for energy-production and energy-intensive industries." In Photonics Asia 2002, edited by Yun-Jiang Rao, Julian D. C. Jones, Hiroshi Naruse, and Robert I. Chen. SPIE, 2002. http://dx.doi.org/10.1117/12.481999.

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7

Hansen, Mogens Weel, and Jan Sandvig Nielsen. "Optimal Integration of Humid Air Cycle in Energy Intensive Industries." In ASME 1996 Turbo Asia Conference. American Society of Mechanical Engineers, 1996. http://dx.doi.org/10.1115/96-ta-049.

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Humid Air Turbine cycle (HAT) is characterised by its high single cycle efficiency. The HAT cycle is typically constrained by a pinch point at low temperature. This indicates that additional heat in the range 100 °C to 200 °C can be utilised with high marginal efficiency. At the same time energy intensive industries (for example refineries, Cement production plants and Steel works) typically have a surplus of heat from around 250 °C to 300 °C and down. This study is aimed at the integration of HAT Cycle into the industrial process plant where the complementary features can be exploited. The present paper has two main objectives. The first objective is to present a general approach for integration analysis. The approach is based on conceptual design using targeting procedures (e.g. Pinch Analysis). The second objective is to find an optimum integration scheme for specific heat sources available from industrial sites. To illustrate both objectives a case study based on real refinery data is discussed.
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8

Oliver, J., R. Malet, R. Aragones, R. Voces, and C. Ferrer. "Waste Heat Recovery Unit for Energy Intensive Industries Thermoelectricity Harvesting." In 2020 IEEE 29th International Symposium on Industrial Electronics (ISIE). IEEE, 2020. http://dx.doi.org/10.1109/isie45063.2020.9152289.

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Makridou, Georgia, Kostas Andriosopoulos, Michael Doumpos, and Constantin Zopounidis. "MEASURING THE EFFICIENCY OF ENERGY-INTENSIVE INDUSTRIES ACROSS 23 EU COUNTRIES." In Bridging Asia and the World: Globalization of Marketing & Management Theory and Practice. Global Alliance of Marketing & Management Associations, 2014. http://dx.doi.org/10.15444/gmc2014.06.02.03.

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Locmelis, Kristaps, and Dagnija Blumberga. "Energy taxation exemptions for energy intensive industries and its impact on energy efficiency in Latvia." In 2019 IEEE 60th International Scientific Conference on Power and Electrical Engineering of Riga Technical University (RTUCON). IEEE, 2019. http://dx.doi.org/10.1109/rtucon48111.2019.8982313.

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Звіти організацій з теми "Energy intensive industries- India"

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Cooper, Kristie L., Anbo Wang, and Gary R. Pickrell. Optical Fiber High Temperature Sensor Instrumentation for Energy Intensive Industries. Office of Scientific and Technical Information (OSTI), November 2006. http://dx.doi.org/10.2172/895010.

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2

Chapas, Richard B., and Jeffery A. Colwell. Industrial Technologies Program Research Plan for Energy-Intensive Process Industries. Office of Scientific and Technical Information (OSTI), October 2007. http://dx.doi.org/10.2172/1218715.

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3

Yépez, Ariel, Luis San Vicente Portes, and Santiago Guerrero. Productivity and Energy Intensity in Latin America. Inter-American Development Bank, April 2021. http://dx.doi.org/10.18235/0003219.

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Within an industrial setting, what would ones conjecture be about the relation between Energy Intensity (EI) and productivity? Could higher Energy use be associated to more capital intensive processes, and thus higher output (per worker)? Or Ceteris paribus, are productivity indicators inversely associated with energy intensity? So that more productive firms or industries tend also to be more energy efficient. The nature of this question is multifold as there are historical, geographical, institutional, developmental, and policy variables that jointly affect industrial development as well as a nations energy supply. This study seeks to assess the relationship between these variables in the industrial sector of four Latin American countries. Under alternative measures of productivity, namely, average labor productivity and total factor productivity (TFP), we find a statistically negative relationship between productivity and Energy intensity.
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4

Hinojosa, Jorge Luis, Saúl Villamizar, and Nathalia Gama. Green Hydrogen Opportunities for the Caribbean. Inter-American Development Bank, January 2023. http://dx.doi.org/10.18235/0004621.

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The decarbonization of the energy, transport, and industrial sectors is an essential part of achieving net-zero CO2 emissions, to limit global warming to 1.5C above pre-industrial levels. Green hydrogen is emerging as one of the most versatile climate change mitigation tools, since it poses a unique potential to decarbonize hard-to-abate sectors, such as freight transport, energy-intensive industries, and power systems highly dominated by fossil fuels. It also holds an alternative to produce fuels and chemical feedstock locally, using renewable energy without dependency on imported fuel, energy, or commodities. The Caribbean has defined as a priority its aim to enhance its energy security with resilient and low-carbon technologies while improving reliability, affordability, and sustainability of energy services. This report aims to contribute to the ongoing discussion on the role that green hydrogen can play to support the achievement of these goals and to provide an overview and guide for decision-makers in this area. Even though hydrogen is currently expensive for most applications at a global level, the exponential decrease in renewable energy costs in the last decade and the expected accelerated cost reduction of hydrogen technologies in the upcoming years are projected to drive an increase in the attractiveness of green hydrogen worldwide. As Caribbean countries are in the early stages of developing their renewable energy potential, there are opportunities to keep the cost decline of renewable energy production, enabling green hydrogen to get closer to achieving cost-competitiveness and could eventually become economically viable and a more broadly adopted solution.
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Tao, Yang, Victor Alchanatis, and Yud-Ren Chen. X-ray and stereo imaging method for sensitive detection of bone fragments and hazardous materials in de-boned poultry fillets. United States Department of Agriculture, January 2006. http://dx.doi.org/10.32747/2006.7695872.bard.

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As Americans become increasingly health conscious, they have increased their consumptionof boneless white and skinless poultry meat. To the poultry industry, accurate detection of bonefragments and other hazards in de-boned poultry meat is important to ensure food quality andsafety for consumers. X-ray imaging is widely used for internal material inspection. However,traditional x-ray technology has limited success with high false-detection errors mainly becauseof its inability to consistently recognize bone fragments in meat of uneven thickness. Today’srapid grow-out practices yield chicken bones that are less calcified. Bone fragments under x-rayshave low contrast from meat. In addition, the x-ray energy reaching the image detector varieswith the uneven meat thickness. Differences in x-ray absorption due to the unevenness inevitablyproduce false patterns in x-ray images and make it hard to distinguish between hazardousinclusions and normal meat patterns even by human visual inspection from the images.Consequently, the false patterns become camouflage under x-ray absorptions of variant meatthickness in physics, which remains a major limitation to detecting hazardous materials byprocessing x-ray images alone.Under the support of BARD, USDA, and US Poultry industries, we have aimed todeveloping a new technology that uses combined x-ray and laser imaging to detect bonefragments in de-boned poultry. The technique employs the synergism of sensors of differentprinciples and has overcome the deficiency of x-rays in physics of letting x-rays work alone inbone fragment detection. X-rays in conjunction of laser-based imaging was used to eliminatefalse patterns and provide higher sensitivity and accuracy to detect hazardous objects in the meatfor poultry processing lines.Through intensive research, we have met all the objectives we proposed during the researchperiod. Comprehensive experiments have proved the concept and demonstrated that the methodhas been capable of detecting frequent hard-to-detect bone fragments including fan bones andfractured rib and pulley bone pieces (but not cartilage yet) regardless of their locations anduneven meat thickness without being affected by skin, fat, and blood clots or blood vines.
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