000			04114naaaa2200925uu 4500
001			https://directory.doabooks.org/handle/20.500.12854/76723
005			20220714184643.0
020			_abooks978-3-0365-1566-3
020			_a9783036515656
020			_a9783036515663
024	7		_a10.3390/books978-3-0365-1566-3 _cdoi
041	0		_aEnglish
042			_adc
072		7	_aGP _2bicssc
072		7	_aTB _2bicssc
100	1		_aTrianni, Andrea _4edt _91598134
700	1		_aTrianni, Andrea _4oth _91598134
245	1	0	_aEnhancement of Industrial Energy Efficiency and Sustainability
260			_aBasel, Switzerland _bMDPI - Multidisciplinary Digital Publishing Institute _c2021
300			_a1 electronic resource (294 p.)
506	0		_aOpen Access _2star _fUnrestricted online access
520			_aIndustrial energy efficiency has been recognized as a major contributor, in the broader set of industrial resources, to improved sustainability and circular economy. Nevertheless, the uptake of energy efficiency measures and practices is still quite low, due to the existence of several barriers. Research has broadly discussed them, together with their drivers. More recently, many researchers have highlighted the existence of several benefits, beyond mere energy savings, stemming from the adoption of such measures, for several stakeholders involved in the value chain of energy efficiency solutions. Nevertheless, a deep understanding of the relationships between the use of the energy resource and other resources in industry, together with the most important factors for the uptake of such measures-also in light of the implications on the industrial operations-is still lacking. However, such understanding could further stimulate the adoption of solutions for improved industrial energy efficiency and sustainability.
540			_aCreative Commons _fhttps://creativecommons.org/licenses/by/4.0/ _2cc _4https://creativecommons.org/licenses/by/4.0/
546			_aEnglish
650		7	_aResearch & information: general _2bicssc _9928234
650		7	_aTechnology: general issues _2bicssc _9928609
653			_acontaminated soil
653			_apolluted soil
653			_athermal desorption
653			_athermal remediation
653			_aenergy analysis and exergy analysis
653			_aenergy saving
653			_aheat integration
653			_aoperability
653			_aretrofit
653			_aoil refinery
653			_ainterviews
653			_aheat transfer
653			_awaste heat recovery
653			_adusty flue gas
653			_agranular bed
653			_aburied tubes
653			_airon and steel industry
653			_atechno-economic pathways
653			_adecarbonization
653			_aCO2 emissions
653			_acarbon abatement measures
653			_aconstruction
653			_abuilding
653			_asupply chain
653			_aroadmap
653			_aheavy industry
653			_acarbon abatement
653			_aemissions reduction
653			_aclimate transition
653			_amulti-agent cooperation
653			_areduced-dimension Q(λ)
653			_aoptimal carbon-energy combined-flow
653			_aenergy efficiency
653			_acompressed air systems
653			_aenergy efficiency measures
653			_anonenergy benefits
653			_aassessment factors
653			_aindustrial energy efficiency
653			_aenergy efficiency culture
653			_aenergy efficiency practices
653			_aenergy management
653			_acogeneration
653			_atrigeneration
653			_asustainability
653			_atropical climate country
653			_abiomass
653			_aadvanced exergoeconomic analysis
653			_aspray dryer
653			_aexergy destruction cost rate
653			_aenergy management practices
653			_aassessment model
856	4	0	_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/4172 _70 _zDOAB: download the publication
856	4	0	_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/76723 _70 _zDOAB: description of the publication
999			_c3006542 _d3006542