textile mills research paper

Advertisement

Energy consumption, environmental impact, and implementation of renewable energy resources in global textile industries: an overview towards circularity and sustainability

• Published: 29 March 2022
• Volume 4 , article number  15 , ( 2022 )

Cite this article

• Kaniz Farhana 1 ,
• Kumaran Kadirgama 2 ,
• Abu Shadate Faisal Mahamude 3 &
• Mushfika Tasnim Mica 4  

3277 Accesses

19 Citations

Explore all metrics

This study aims to review the energy consumption, environmental impact, and implementation of renewable energy in textile industries to enhance circularity and sustainability in the textile industry. Textiles and clothing are the fundamental needs of human beings; this sector consumes an abundant amount of fossil fuels as the main energy supply and has impacts on the environment. However, alternative clean sources of energy can be applied in the textile industry. Moreover, the gradual elimination of fossil fuels and the implementation of renewable energy resources in textile industries is essential. By this paper, fossil energy usage in textile industries and its impact, as well as the application of alternative energy in textiles, can be perceived. In this study, the background of the textile industry, energy consumption, environmental impact, alternative sources, and saving of fossil energy has been narrated tidily. In summary, generally, more than 50% of thermal energy and around 70% of electricity are used in various processes of the textile industry. Along with fossil fuels, it has some adverse effects on the environment. But alternative energy sources and improved energy efficiency can reduce this pollution. Nevertheless, currently, textile industries consume plenty of fossil fuel energy to produce end products; there are huge opportunities to implement renewable energy as well as applying BAT and advanced technology can also increase the existing energy efficiency in the textile industries. Since textile is the eternal demand of human beings, we must give extra effort to this sector and save the immediate vicinity of mankind as well.

This is a preview of subscription content, log in via an institution to check access.

Access this article

Price includes VAT (Russian Federation)

Instant access to the full article PDF.

Rent this article via DeepDyve

Institutional subscriptions

Source: IEA ( 2013 )

Source: Martínez ( 2010 )

Source: Sathaye et al. ( 2005 ). a Standard usage of electricity energy. b Standard usage of thermal energy

Source: Bundesamt. (2014)

Source: authors

Similar content being viewed by others

Bioplastic from Renewable Biomass: A Facile Solution for a Greener Environment

Green building practices to integrate renewable energy in the construction sector: a review

Conversion of biomass to biofuels and life cycle assessment: a review

Data availability.

Data sharing is not applicable to this article as no datasets were generated or analyzed during the current study.

Abdelaziz E, Saidur R, Mekhilef S (2011) A review on energy saving strategies in industrial sector. Renew Sustain Energy Rev 15(1):150–168

Article   Google Scholar  

de Abreu Almeida M, Barragan da Silva M, Paulsen Panato B et al (2015) Clinical indicators to monitor patients with risk for ineffective cerebral tissue perfusion. 33(1), 155–163. Investigación y Educación en Enfermería. http://www.scielo.org.co

Agency IE (2007) Key world energy statistics: international energy agency. https://www.iea.org

Ahlström L-H, Eskilsson CS, Björklund E (2005) Determination of banned azo dyes in consumer goods. TrAC, Trends Anal Chem 24(1):49–56

Akarslan F, Demiralay H (2015) Effects of textile materials harmful to human health. Acta Physica Polonica A, 128(2B). https://doi.org/10.12693/APhysPolA.128.B-407

Allen CD, Macalady AK, Chenchouni H et al (2010) A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. For Ecol Manage 259(4):660–684

Amiro B, Stocks B, Alexander M, Flannigan M, Wotton B (2001) Fire, climate change, carbon and fuel management in the Canadian boreal forest. Int J Wildland Fire 10(4):405–413

Amoco B (2000) BP Amoco statistical review of world energy: BP Amoco. https://www.hydrocarbononline.com

ASA, A. A. L. (2015). A brief report on textile industry in India; ASA & Associates LLP.

Babu BR, Parande A, Raghu S, Kumar TP (2007) Textile technology, cotton textile processing: waste generation and effluent treatment. J Cotton Sci 11:141–153

CAS   Google Scholar  

Barbiroli G, Raggi AJ (2003) A method for evaluating the overall technical and economic performance of environmental innovations in production cycles. J Clean Prod 11(4):365–374

Baydar G, Ciliz N, Mammadov A (2015) Life cycle assessment of cotton textile products in Turkey. Resour Conserv Recycl 104:213–223

Bayramoglu M, Kobya M, Can OT, Sozbir M (2004) Operating cost analysis of electrocoagulation of textile dye wastewater. Sep Purif Technol 37(2):117–125

Article   CAS   Google Scholar  

Bedeloglu A, Demir A, Bozkurt Y, Sariciftci NS (2009) A flexible textile structure based on polymeric photovoltaics using transparent cathode. Synth Met 159(19):2043–2048

Bennie F, Gazibara I, Murray V (2010) Fashion Futures 2025: global scenarios for a sustainable fashion industry. Forum for the Future, London, UK. http://samuellearning.org

Beton A, Dias D, Farrant L et al (2014) Environmental improvement potential of textiles (IMPRO-textiles). Publications Office of the European Union, European Union, Luxembourg

Google Scholar  

Bhuyar, P., Trejo, M., Dussadee, N., et al. (2021). Microalgae cultivation in wastewater effluent from tilapia culture pond for enhanced bioethanol production. 84 (10-11), 2686-2694

Bilińska L, Gmurek M, Ledakowicz S (2016) Comparison between industrial and simulated textile wastewater treatment by AOPs–biodegradability, toxicity and cost assessment. Chem Eng J 306:550–559

Bobba AG (2002) Numerical modelling of salt-water intrusion due to human activities and sea-level change in the Godavari Delta. India Hydrol Sci J 47(S1):S67–S80

Brenton P, Hoppe M (2007) Clothing and export diversification: still a route to growth for low-income countries? World Bank.  https://openknowledge.worldbank.org

Briga-Sa A, Nascimento D, Teixeira N et al (2013) Textile waste as an alternative thermal insulation building material solution. Constr Build Mater 38:155–160

Bundesamt S (2014) Bruttostromerzeugung 2013. Anteil der erneuerbaren Energien. https://www.smarterworld.de

Carnicer J, Coll M, Ninyerola M et al (2011) Widespread crown condition decline, food web disruption, and amplified tree mortality with increased climate change-type drought. Proc Natl Acad Sci 108(4):1474–1478

Çetin M, Eğrican N (2011) Employment impacts of solar energy in Turkey. Energy Policy 39(11):7184–7190

Chapter 4 GP (n.d.) Green plants as converters of solar energy, solar energy and its utilization. http://www.life.illinois.edu

Chen X, Memon HA, Wang Y, Marriam I, Tebyetekerwa MJ (2021) Circular economy and sustainability of the clothing and textile Industry. Materials Circular Economy 3(1):1–9

Cohen MJJ (2007) Consumer credit, household financial management, and sustainable consumption. Int J Consum Stud 31(1):57–65

Couto SR (2009) Dye removal by immobilised fungi. Biotechnol Adv 27(3):227–235

Dai A (2013) Increasing drought under global warming in observations and models. Nat Clim Chang 3(1):52–58

Dale VH, Joyce LA, McNulty S et al (2001) Climate change and forest disturbances: climate change can affect forests by altering the frequency, intensity, duration, and timing of fire, drought, introduced species, insect and pathogen outbreaks, hurricanes, windstorms, ice storms, or landslides. Bioscience 51(9):723–734

D’amato G, Cecchi L (2008) Effects of climate change on environmental factors in respiratory allergic diseases. Clin Exp Allergy 38(8):1264–1274

de Oliveira Neto GC, Tucci HNP, Correia JMF et al (2021) Stakeholders’ influences on the adoption of cleaner production practices: a survey of the textile industry. Sustain Prod Consum 26:126–145

de Souza AAU, Melo AR, Pessoa FLP, Ulson SM, d. A. G. (2010) The modified water source diagram method applied to reuse of textile industry continuous washing water. Resour Conserv Recycl 54(12):1405–1411

Desantis LR, Bhotika S, Williams K, Putz FE (2007) Sea-level rise and drought interactions accelerate forest decline on the Gulf Coast of Florida, USA. Glob Change Biol 13(11):2349–2360

Devaraja T (2011) Indian textile and garment industry-an overview. Indian Council of Social Science Research, New Delhi. https://www.fibre2fashion.com

Dhainaut J-F, Claessens Y-E, Ginsburg C, Riou B (2003) Unprecedented heat-related deaths during the 2003 heat wave in Paris: consequences on emergency departments. Crit Care 8(1):1

Dissanayake D, Weerasinghe DJ (2021) Fabric waste recycling: a systematic review of methods, applications, and challenges. Mater Circ Econ 3(1):1–20

Dr. Norbert Reintjes DCS, Ismene Jäger (2011) Checklist based on best available techniques in the textile industry. Federal Environment Agency (Umweltbundesamt). http://www.uba.de/uba-info-medien-e/4294.html

Egypt E (2012) Best Available Techniques (BAT) for the textile industry in Egypt; Egyptian Environmental Affairs Agency

European Environmentagency (2007) What Are Greenhouse Gases. http://www.eea.europa.eu/publications/european-union-greenhouse-gas-inventory2010/

Eren HA, Ozturk D (2011) The evaluation of ozonation as an environmentally friendly alternative for cotton preparation. Text Res J 81(5):512–519

Esteves BM, Rodrigues CS, Boaventura RA, Maldonado-Hodar FJ, Madeira LM (2016) Coupling of acrylic dyeing wastewater treatment by heterogeneous Fenton oxidation in a continuous stirred tank reactor with biological degradation in a sequential batch reactor. J Environ Manage 166:193–203. https://doi.org/10.1016/j.jenvman.2015.10.008

Euratex. (2014). European Technology Platform: for the future of textiles and clothing – a vision for 2020; European Apparel and Textile Organization; .

Farhana K, Kadirgama K, Rahman M et al (2019) Improvement in the performance of solar collectors with nanofluids—a state-of-the-art review. Nano-Struct Nano-Objects 18:100276

Farhana K, Kadirgama K, Mohammed HA et al (2021) Analysis of efficiency enhancement of flat plate solar collector using crystal nano-cellulose (CNC) nanofluids. Sustain Energy Technol Assess 45:101049

Farhana K, Syduzzaman M, Munir MS (2015) Present status of workers in ready-made garments industries in Bangladesh. European Scientific Journal 11(7)

Farooq MS, Salam MJ (2021) Cleaner production practices at company level enhance the desire of employees to have a significant positive impact on society through work. J Clean Prod 283:124605

Fernandes PRB, Contin B, Siqueira MU, Ruschel-Soares R, Baruque-Ramos JJ (2021) Biocomposites from cotton denim waste for footwear components. Mater Circ Econ 3(1):1–10

Flannigan M, Stocks B, Turetsky M, Wotton M (2009) Impacts of climate change on fire activity and fire management in the circumboreal forest. Glob Change Biol 15(3):549–560

Fouillet A, Rey G, Laurent F et al (2006) Excess mortality related to the August 2003 heat wave in France. Int Arch Occup Environ Health 80(1):16–24

Fridley D (2010) Nine challenges of alternative energy. The Post Carbon Reader Series: Energy; Post Carbon Institute. https://qibebt.cas.cn

Frihy OE (2003) The Nile delta-Alexandria coast: vulnerability to sea-level rise, consequences and adaptation. Mitig Adapt Strat Glob Change 8(2):115–138

Gereffi G, Frederick S (2010) The global apparel value chain, trade and the crisis: challenges and opportunities for developing countries. The World Bank Development Research Group Trade and Integration Team April 2010. https://citeseerx.ist.psu.edu

Gislason AG (2010) Proceedings of the: Joint ICES/CIESM Workshop to Compare Zooplankton Ecology and Methodologies between the Mediterranean and the North Atlantic (WKZEM): International Council for the Exploration of the Sea (ICES). http://hdl.handle.net/20.500.11822/2637

Grave K, Hazrat M, Boeve S et al (2015) Electricity costs of energy intensive industries an international comparison. German Ministry of Economic Affairs and Energy. https://doi.org/10.13140/RG.2.1.2442.9286

Group C (2008) Technology roadmap for the Canadian textile industry. Quebec. https://slidelegend.com

Gulrajani M, Deepti G (2011) Emerging techniques for functional finishing of textiles. Indian Journal of Fibre & Textile Research 36:388–397

Haque SI, Thaku I (2015) Development of textile industry of India and China: flying geese model revisited. Pac Bus Rev Int 8(2):68–75

Hasan AM, Tuhin RA, Ullah M et al (2021) A comprehensive investigation of energy management practices within energy intensive industries in Bangladesh. Energy 232:120932

Hasanbeigi A, Price L (2012) A review of energy use and energy efficiency technologies for the textile industry. Renew Sustain Energy Rev 16(6):3648–3665

Hasanbeigi A, Price L (2015) A technical review of emerging technologies for energy and water efficiency and pollution reduction in the textile industry. J Clean Prod 95:30–44

Hasanbeigi A, Hasanabadi A, Abdorrazaghi M (2012) Comparison analysis of energy intensity for five major sub-sectors of the textile industry in Iran. J Clean Prod 23(1):186–194

Hasanbeigi A (2010) Energy-efficiency improvement opportunities for the textile industry. Lawrence Berkeley National Laboratory. https://www.energystar.gov

Hasanuzzaman M, Rahim N, Saidur R, Kazi S (2011) Energy savings and emissions reductions for rewinding and replacement of industrial motor. Energy 36(1):233–240

Hepbasli A, Erbay Z, Icier F, Colak N, Hancioglu E (2009) A review of gas engine driven heat pumps (GEHPs) for residential and industrial applications. Renew Sustain Energy Rev 13(1):85–99

Ho YC, KYS, Guo XX, Norli I, Alkarkhi Abbas FM, Morad N (2012) Industrial discharge and their effect to the environment, industrial waste, Prof. Kuan-Yeow Show (Ed.). https://doi.org/10.5772/38830 ; https://www.intechopen.com

Huang B, Zhao J, Geng Y, Tian Y, Jiang P (2016) Energy-related GHG emissions of the textile industry in China. Resour Conserv Recycl. https://doi.org/10.1016/j.resconrec.2016.06.013

Hussain M (1987) Bangladesh energy resources and renewable energy prospects. Energy 12(5):369–374

ICAC F (2011) A summary of the world apparel fiber consumption survey 2005–2008; Food and Agriculture Organization of the United Nation. http://www.fao.org

ICAC F (2013) A Summary of the world apparel fiber consumption survey 2013. Food and Agricultural Organisation of the United Nations and International Cotton Advisory Committee. https://sewitagain.com

IEA (2008) World Energy Outlook 2008. OECD/ IEA, Paris, France. https://www.iea.org

IEA (2013) Key world energy statistics. International Energy Agency. https://www.iea.org

Institute WW (2009) State of the World 2009: Into a Warming World: World Watch Institute Washington, DC. https://www.environmentandsociety.org

ISO (2011) ISO Launches ISO 50001 energy management standard, Document Ref: 1434, p 1. 2011. https://www.iso.org

Jacobson MZ, Delucchi MA (2011) Providing all global energy with wind, water, and solar power, part I: technologies, energy resources, quantities and areas of infrastructure, and materials. Energy Policy 39(3):1154–1169

Jarek Gontek IM, Nadolski A, Wojcik K, Seoánez C. Öztürk AE, Yılmaz K, Aktaş I, Demir M, Tok E, Savaş S, Gülay O, Gürpınar Ö (2012) BAT Guide for textile industry; Eşleştirme Projesi TR 08 IB EN 03; IPPC – Entegre Kirlilik Önleme ve Kontrol; T.C. Çevre ve Şehircilik Bakanlığı. http://webdosya.csb.gov.tr

Jucevičius, R., & Rybakovas, E. Competitiveness of Lithuanian textile and clothing industry.

Kalogirou S (2003) The potential of solar industrial process heat applications. Appl Energy 76(4):337–361

Kant R (2012) Textile dyeing industry an environmental hazard. Nat Sci 4(1):22

Kasu SR (2015) Renewable energy in industrial applications. https://digitalcommons.kennesaw.edu

Keane J, te Velde DW (2008) The role of textile and clothing industries in growth and development strategies. Overseas Development Institute. Dostupno na: www.odi.org.uk/resources/docs/3361.pdf [28.6. 2013.]. https://cdn.odi.org

Khan MA, Khan MZ, Zaman K, Naz L (2014) Global estimates of energy consumption and greenhouse gas emissions. Renew Sustain Energy Rev 29:336–344

Khandaker S, Bashar MM, Islam A et al (2022) Sustainable energy generation from textile biowaste and its challenges: a comprehensive review. Renew Sustain Energy Rev 157:112051

Khondoker M, Kalirajan K (2012) Determinants of labor-intensive exports by the developing countries: a cross country analysis. ASARC WP 2012/09.  https://crawford.anu.edu.au

Kim J-O, Traore M, Warfield C (2006) The textile and apparel industry in developing countries. Text Prog 38(3):1–64

Klinenberg E (2008) Are you ready for the next disaster? New York Times Magazine. https://www.nytimes.com

Koç E, Çinçik E (2010) Analysis of energy consumption in woven fabric production. Fibres Text East Europe 18(2):79

Koç E, Kaplan E (2007) An investigation on energy consumption in yarn production with special reference to ring spinning. Fibres Text East Europe 4(63):18–24

Kocabas AM, Yukseler H, Dilek FB, Yetis U (2009) Adoption of European Union’s IPPC Directive to a textile mill: analysis of water and energy consumption. J Environ Manage 91(1):102–113

Kocabas AM (2008) Improvements in energy and water consumption performances of a textile mill after BAT applications. Citeseer. https://etd.lib.metu.edu.tr

Lanham G (2007) 4 factors to lower energy costs. Met Prod Process 45(5):8–8

Lassi S (2009) Energy Visions 2050. VTT Technical Research of Finland, Finland. https://cris.vtt.fi

Liserre M, Sauter T, Hung JY (2010) Future energy systems: integrating renewable energy sources into the smart power grid through industrial electronics. IEEE Ind Electron Mag 4(1):18–37

LTD GC (2006) A study to examine the benefits of the End of Life Vehicles Directive and the costs and benefits of a revision of the 2015 targets for recycling, re-use and recovery under the ELV Directive. https://ec.europa.eu

M&S. (2013) Cutting cotton carbon emission findings from Warangal. WWF Report, India

Maia LC, Alves AC, Leão CP (2013) Definition of a protocol for implementing Lean Production Methodology in Textile and Clothing case studies. Paper presented at the ASME 2013 International Mechanical Engineering Congress and Exposition. IMECE2013-64739, V02BT02A027; 7. https://doi.org/10.1115/IMECE2013-64739

Martínez CIP (2010) Energy use and energy efficiency development in the German and Colombian textile industries. Energy Sustain Dev 14(2):94–103

Mekhilef S, Saidur R, Safari A (2011) A review on solar energy use in industries. Renew Sustain Energy Rev 15(4):1777–1790

Mendoza J-MF, Capitano C, Peri G et al (2014) Environmental management of granite slab production from an industrial ecology standpoint. J Clean Prod 84:619–628

Moorhead KK, Brinson MM (1995) Response of wetlands to rising sea level in the lower coastal plain of North Carolina. Ecol Appl 5(1):261–271

Muneer T, Maubleu S, Asif M (2006) Prospects of solar water heating for textile industry in Pakistan. Renew Sustain Energy Rev 10(1):1–23

Muneer T, Asif M, Cizmecioglu Z, Ozturk H (2008) Prospects for solar water heating within Turkish textile industry. Renew Sustain Energy Rev 12(3):807–823

Muthu SS (2014) Assessing the environmental impact of textiles and the clothing supply chain. Elsevier. https://www.sciencedirect.com

Nicholls RJ, Hoozemans FM, Marchand M (1999) Increasing flood risk and wetland losses due to global sea-level rise: regional and global analyses. Glob Environ Chang 9:S69–S87

Noor-E-Hasnin, & Ahsan, M. (2016). Employee training and operational risks: the case of RMG sector in Bangladesh. World Journal of Social Sciences, 6 (2), 71-81

Nordås HK (2004) The global textile and clothing industry post the agreement on textiles and clothing. World, 7(1,000). WTO, https://www.wto.org

Nunes L, Matias J, Catalão J (2015) Analysis of the use of biomass as an energy alternative for the Portuguese textile dyeing industry. Energy 84:503–508

Nunes L, Matias J, Catalão J (2013) Economic evaluation and experimental setup of biomass energy as sustainable alternative for textile industry. UPEC, IEEE, 978-1-4799-3254-2. https://doi.org/10.1109/UPEC.2013.6714907

Ogugbue CJ, Sawidis T (2011) Bioremediation and detoxification of synthetic wastewater containing triarylmethane dyes by Aeromonas hydrophila isolated from industrial effluent. SAGE-Hindawi Access to Research Biotechnology Research International 2011:11. https://doi.org/10.4061/2011/967925

Organization WT (2015a) International Trade Statistics.  https://www.wto.org

Organization WT (2015b) W. T. International Trade Statistics 2015b, International Trade Statistics 2015 - WTO. https://www.wto.org

Ottmar Edenhofer (2014) Climate change 2014 mitigation of climate change. In: Contribution of working group III to the fifth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, UK and New York, NY. https://www.ipcc.ch

Ozdil NFT, Tantekin A, Erbay Z (2016) Energy and exergy analyses of a fluidized bed coal combustor steam plant in textile industry. Fuel 183:441–448

Ozsoz E (2014) Exploitation or empowerment? The impact of textile and apparel manufacturing on the education of women in developing countries, MPRA Paper No. 58125. https://mpra.ub.uni-muenchen.de/58125/

Ozturk HK (2005) Energy usage and cost in textile industry: a case study for Turkey. Energy 30(13):2424–2446

Ozturk E, Karaboyacı M, Yetis U, Yigit NO, Kitis M (2015) Evaluation of integrated pollution prevention control in a textile fiber production and dyeing mill. J Clean Prod 88:116–124

Palamutcu S (2010) Electric energy consumption in the cotton textile processing stages. Energy 35(7):2945–2952

Parry ML, Rosenzweig C, Iglesias A, Livermore M, Fischer G (2004) Effects of climate change on global food production under SRES emissions and socio-economic scenarios. Glob Environ Chang 14(1):53–67

Parry M, Rosenzweig C, Livermore M (2005) Climate change, global food supply and risk of hunger. Philos Trans R Soc London b: Biol Sci 360(1463):2125–2138

Pieprzyk B, Kortlüke N, Hilje PR (2009) The impact of fossil fuels, greenhouse gas emissions, environmental, consequences and socio-economic effects. Era–Energy Research Architecture Report. BEE’s comment on JRC’s report “Assessing GHG default emissions from biofuels in EU legislation

Poumadere M, Mays C, Le Mer S, Blong R (2005) The 2003 heat wave in France: dangerous climate change here and now. Risk Anal 25(6):1483–1494

Prevention IP (2003) Control (IPPC) Reference document on best available techniques for the textiles industry. European Comission. https://eippcb.jrc.ec.europa.eu

Rakib MI, Saidur R, Mohamad EN, Afifi AM (2017) Waste-heat utilization–the sustainable technologies to minimize energy consumption in Bangladesh textile sector. J Clean Prod 142:1867–1876

Ramakrishna S, Jose RJ (2022) Addressing sustainability gaps. Sci Total Environ 806:151208

Reddy BS, Ray BK (2011) Understanding industrial energy use: physical energy intensity changes in Indian manufacturing sector. Energy Policy 39(11):7234–7243

Reddy CC, Khilji IA, Gupta A et al (2021) Valorization of keratin waste biomass and its potential applications. J Water Process Eng 40:101707

Roos S, Peters GM (2015) Three methods for strategic product toxicity assessment—the case of the cotton T-shirt. Int J Life Cycle Assess 20(7):903–912

Roos S, Posner S, Jönsson C, Peters GM (2015) Is unbleached cotton better than bleached? Exploring the limits of life-cycle assessment in the textile sector. Cloth Text Res J 33(4):231–247

Rosen M (2007) Creating sustainable communities. A Guide for Developers and Communities: New Jersey: New Jersey Department and Environmental Protectin. https://www.nj.gov

Ryu C, Phan AN, Sharifi VN, Swithenbank J (2007) Co-combustion of textile residues with cardboard and waste wood in a packed bed. Exp Thermal Fluid Sci 32(2):450–458

SahebKoussa D, Koussa M (2016) GHGs (greenhouse gases) emission and economic analysis of a GCRES (grid-connected renewable energy system) in the arid region, Algeria. Energy 102:216–230

Saidur R (2009) Energy consumption, energy savings, and emission analysis in Malaysian office buildings. Energy Policy 37(10):4104–4113

Saidur R, Masjuki H, Jamaluddin M (2007) An application of energy and exergy analysis in residential sector of Malaysia. Energy Policy 35(2):1050–1063

Saidur R, Rahim N, Ping H et al (2009) Energy and emission analysis for industrial motors in Malaysia. Energy Policy 37(9):3650–3658

Saidur R, Islam M, Rahim N, Solangi K (2010a) A review on global wind energy policy. Renew Sustain Energy Rev 14(7):1744–1762

Saidur R, Rahim N, Hasanuzzaman M (2010b) A review on compressed-air energy use and energy savings. Renew Sustain Energy Rev 14(4):1135–1153

Sathaye J, Price L, Fridley D (2005) Assessment of energy use and energy savings potential in selected industrial sectors in India. Bull Energy Efficiency 6(2):25–28

Saxena S, Raja A, Arputharaj A (2017) Challenges in sustainable wet processing of textiles Textiles and Clothing Sustainability. Springer, pp. 43–79. https://link.springer.com/chapter/10.1007/978-981-10-2185-5_2

Schmidhuber J, Tubiello FN (2007) Global food security under climate change. Proc Natl Acad Sci 104(50):19703–19708

Schnitzer H, Brunner C, Gwehenberger G (2007) Minimizing greenhouse gas emissions through the application of solar thermal energy in industrial processes. J Clean Prod 15(13):1271–1286

Scurities F (2014) Textile & apparel Industry Report. 1–45. http://fpts.com.vn

Shah DS, Shah J (2013) Unconventional techniques for energy conservation in textile wet Processing: Formatex. https://www.semanticscholar.org

Shah SAS, Syed AASG, Shaikh FM (2013) Effects of wto on the textile industry on developing countries. Revista Română de Statistică nr 61:60–77

Shaikh MA (2009) Water conservation in textile industry. Pakistan Textile J 2009:48–51

Shakti SEF (2013) Technology compendium on energy saving opportunities-textile sector. Confederation of indian Industry. https://shaktifoundation.in

Sharma AK, Sharma C, Mullick SC, Kandpal TC (2016) GHG mitigation potential of solar industrial process heating in producing cotton based textiles in India. J Clean Prod. https://doi.org/10.1016/J.JCLEPRO.2016.12.161

da Silva, P. C., de Oliveira Neto, G. C., Correia, J. M. F., Tucci, H. N. P. J. J. o. C. P. (2021). Evaluation of economic, environmental and operational performance of the adoption of cleaner production: Survey in large textile industries. 278, 123855

Son MY (2012) The impact of climate change on the fashion industry in Korea. Ritsumeikan J Asia Pacific Stud 31:56–65

Sovacool BK, Sidortsov RV, Jones BR (2013) Energy security, equality and justice. Taylor & Francis. https://doi.org/10.4324/9780203066348

Stocker TF, Qin D, Plattner G-K et al (2014) Climate change 2013: the physical science basis. Cambridge University Press Cambridge, UK. https://www.ipcc.ch

Su B, Goh T, Ang B, Ng TSJ (2022) Energy consumption and energy efficiency trends in Singapore: the case of a meticulously planned city. Energy Policy 161:112732

Szirmai A (2012) Industrialisation as an engine of growth in developing countries, 1950–2005. Struct Chang Econ Dyn 23(4):406–420

Tandon N, Reddy EE (2003) A study on emerging trends in textile industry in India. Issues 169(226):395

Timmons D, Harris JM, Roach B (2014) The economics of renewable energy. Tufts University, Medford, MA, Global Development And Environment Institute, p 52

Ubeda S, Arcelus F, Faulin J (2011) Green logistics at Eroski: a case study. Int J Prod Econ 131(1):44–51

Uddin F (2014) Energy management and energy crisis in textile finishing. American J Energy Res 2(3):53–59

Venkatesharaju K, Ravikumar P, Somashekar R, Prakash K (2010) Physico-chemical and bacteriological investigation on the river Cauvery of Kollegal stretch in Karnataka. Kathmandu Univ J Sci Eng Technol 6(1):50–59

Verma AK, Dash RR, Bhunia P (2012) A review on chemical coagulation/flocculation technologies for removal of colour from textile wastewaters. J Environ Manage 93(1):154–168

Vine E (2012) Adaptation of California’s electricity sector to climate change. Clim Change 111(1):75–99

Yuan Z-W, Zhu Y-N, Shi J-K, Liu X, Huang L (2013) Life-cycle assessment of continuous pad-dyeing technology for cotton fabrics. Int J Life Cycle Assess 18(3):659–672

Zabaniotou A, Andreou K (2010) Development of alternative energy sources for GHG emissions reduction in the textile industry by energy recovery from cotton ginning waste. J Clean Prod 18(8):784–790

Zaffalon V (2010) Carbon mitigation and textiles. Textile World, 35. The sub-council of textile industry. http://www.ccpittex.com

Zhang Y, Liu X, Xiao R, Yuan Z (2015) Life cycle assessment of cotton T-shirts in China. Int J Life Cycle Assess 20(7):994–1004

Download references

This study received financial support from the University Malaysia Pahang (UMP), Grant RDU191801-3.

Author information

Authors and affiliations.

Department of Apparel Engineering, Bangladesh University of Textiles, Dhaka-1208, Dhaka, Bangladesh

Kaniz Farhana

Faculty of Mechanical and Automotive Engineering Technology, Universiti Malaysia Pahang, 26600, Pekan, Pahang, Malaysia

Kumaran Kadirgama

College of Engineering, Universiti Malaysia Pahang, 26300, Gambang, Pahang, Malaysia

Abu Shadate Faisal Mahamude

Wilson College of Textiles, North Carolina State University, Raleigh, NC, 27695, USA

Mushfika Tasnim Mica

You can also search for this author in PubMed   Google Scholar

Contributions

K. F. designed the concept, writing—original draft; K. K. overall supervision and funding resources; A. S. F. M. data checking and writing; M. T. M. writing and checking. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Kaniz Farhana .

Ethics declarations

Conflict of interest.

The authors declare no competing interests.

Additional information

Publisher's note.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Rights and permissions

Reprints and permissions

About this article

Farhana, K., Kadirgama, K., Mahamude, A.S.F. et al. Energy consumption, environmental impact, and implementation of renewable energy resources in global textile industries: an overview towards circularity and sustainability. Mater Circ Econ 4 , 15 (2022). https://doi.org/10.1007/s42824-022-00059-1

Download citation

Received : 20 January 2022

Revised : 11 February 2022

Accepted : 21 February 2022

Published : 29 March 2022

DOI : https://doi.org/10.1007/s42824-022-00059-1

Share this article

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

• Textile industry
• Energy consumption
• Environment
• Renewable energy
• Find a journal
• Publish with us
• Track your research

Academia.edu no longer supports Internet Explorer.

To browse Academia.edu and the wider internet faster and more securely, please take a few seconds to  upgrade your browser .

Enter the email address you signed up with and we'll email you a reset link.

• We're Hiring!
• Help Center

SUSTAINING INDIAN TRADITIONAL TEXTILES

2019, indian journal of applied research

Related Papers

Journal of Textile Engineering & Fashion Technology

pervin ANİŞ

International Journal for Research in Applied Science & Engineering Technology (IJRASET)

IJRASET Publication

The textile industry is one of the biggest and most complex businesses in the world, confronting numerous environmental and social challenges. Feasible textile generation is getting to be progressively imperative to decrease the negative environmental and social impacts of textile generation. The scale and productivity of economical textile generation is key to guaranteeing that textile generation meets natural guidelines and social responsibility.

Non-Metallic Material Science

SANOWAR HOSSEN

The purpose of this study was to offer a general concept and overview of the textile industry’s environmental sustainability assessment. The textile and garment industries cause environmental damage at every stage of manufacturing, from the cultivation of raw materials through the disposal of finished goods. Chemical loading, high water consumption, high energy consumption, air pollution, solid waste, and odour creation are all key environmental concerns in the textile industry. To achieve sustainable production, it is necessary to examine the performance of the textile sector while considering the three elements of sustainability. To study and locate recent and related works, five keywords were used: environmental; sustainability; eco-design; manufacturer; supply chain management. All through the life cycle of textile products, the textile sector has a substantial environmental impact. This paper illustrates how the textile industry may use strategic ways to improve ecologically su...

International Symposium "Technical Textiles - Present and Future"

Melinda Pruneanu

Palgrave studies in business, arts and humanities

Claire Lerpiniere

GOPALAKRISHNAN DURAISAMY

Sustainability is the major concern in the age of modern world. For textile and apparel sector, this has been a burning issue for many related concerned bodies. Over the past few years, increasing awareness of the environmental and social concerns surrounding the fashion industry have led to a rise in the implementation of sustainability initiatives. Sustainability is the major concern in the age of modern world. For textile and apparel sector, this has been a burning issue for many related concerned bodies. Over the past few years, increasing awareness of the environmental and social concerns surrounding the fashion industry have led to a rise in the implementation of sustainability initiatives. Environmental sustainability in business refers to longevity, but in terms of which natural resources the production process might draw upon, how resources are used and replenished, the overall impact of the final production on the environment, and where the product ends up following its disposal. The textile and apparel products impact the environment at every point along the product’s lifecycle. Keywords: Sustainability, Environmental sustainability, Product lifecycle

Globalization is inevitable and unavoidable under the present world economic situation. Many industries are affected positively or negatively with the globalization trend. Sustainability has become an essential attribute of today's textile and clothing industry, the process of transforming textile industry into more sustainable one is very sensitive, needs a lot of knowledge, skills and commitment. The global textile and clothing trade has increased by around 60 times from $ 6 billion in 1962 to $395 in the year 2003. Over the past few years, increasing awareness of the environmental and economic concerns surrounding the fashion industry have led to a rise in the implementation of sustainability initiatives. Sustainable apparel products can be defined as a part of the growing design philosophy and trend of sustainability, the goal of which is to create a system which can be supported indefinitely in terms of environmentalism and economic responsibility. Conventional textile production is one of the most polluting industries on the planet. The World Bank estimates that the textile industry is responsible for as much as 20 percent of industrial pollution in our rivers and land. Environmental impacts occur throughout the production chain and most attention is paid to water consumption, chemical use, and waste and green house gas emissions. The textile industry has taken several initiatives to reduce its environmental impact and improve economic conditions. Global awareness of the real price of clothing is growing and there are increasing numbers of cases of people experiencing health problems such as rashes, allergies, respiratory and concentration problems due to chemical sensitivities. There has been a growing concern over apparel brands in improving their environmental impact and the economic responsibility throughout their supply chains. Environmental sustainability refers to the ability of something to continue without upsetting earth's ecological balance. Sustainable apparel products can be defined as a part of the growing design philosophy and trend of sustainability, the goal of which is to create a system which can be supported indefinitely in terms of environmentalism and economic responsibility.

Victoria Danila

Goksel Demirer , Emrah Alkaya

avinash raipally

RELATED PAPERS

出售澳洲斯威本科技大学毕业证 sut学位证书本科学位证书雅思证书原版一模一样

Maxime Corron

Research Square (Research Square)

Carlos Arriaga Jordan

The Journal of Urology

Joseph Pariser

Paul D.Y Higgins,Jr II

Cahiers d’études africaines

Thibault Tranchant

Shifu Careaga

Analytica Chimica Acta

Sibilla Orsini

Arquivo Brasileiro de Medicina Veterinária e Zootecnia

Elias Jorge Facury Filho

Jean Hertzman

Journal of Food Products Marketing

Mark Ratchford

原版定做达尔豪斯大学毕业证 dalhousie毕业证本科文凭证书录取通知原版一模一样

Microbiology Research Journal International

Lobna S El-Hosseiny

SSRN Electronic Journal

NATHAN CHILDS

Journal of Education and Learning (EduLearn)

Anesthesiology

Contemporary Clinical Dentistry

TAPAS GUPTA

Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit

Anna Lina Ruscelli

RELATED TOPICS

•   We're Hiring!
•   Help Center
• Find new research papers in:
• Health Sciences
• Earth Sciences
• Cognitive Science
• Mathematics
• Computer Science
• Academia ©2024

Category : Gorodok factory

Subcategories.

This category has only the following subcategory.

• Gorodok pipe bridge ‎ (7 F)

Media in category "Gorodok factory"

The following 41 files are in this category, out of 41 total.

• Factories in Pavlovsky Posad
• Gorodok (Pavlovsky Posad)
• 1900s architecture in Russia
• Weaving mills in Russia
• Brick architecture in Pavlovsky Posad
• Uses of Wikidata Infobox
• Uses of Wikidata Infobox with maps
• Pages with maps

Navigation menu