000			04449naaaa2200997uu 4500
001			https://directory.doabooks.org/handle/20.500.12854/69397
005			20220220073317.0
020			_abooks978-3-03943-528-9
020			_a9783039435272
020			_a9783039435289
024	7		_a10.3390/books978-3-03943-528-9 _cdoi
041	0		_aEnglish
042			_adc
072		7	_aTBX _2bicssc
100	1		_aD'Ambrosio, Francesca Romana _4edt
700	1		_aPalella, Boris Igor _4edt
700	1		_aD'Ambrosio, Francesca Romana _4oth
700	1		_aPalella, Boris Igor _4oth
245	1	0	_aIndoor Thermal Comfort
260			_aBasel, Switzerland _bMDPI - Multidisciplinary Digital Publishing Institute _c2020
300			_a1 electronic resource (230 p.)
506	0		_aOpen Access _2star _fUnrestricted online access
520			_aAs the century begins, natural resources are under increasing pressure, threatening public health and development. As a result, the balance between man and nature has been disrupted, with climatic changes whose effects are starting to be irreversible. Due to the relationship between the quality of the indoor built environment and its energy demand, thermal comfort issues are still relevant in the disciplinary debate. This is also because the indoor environment has a potential impact on occupants' health and productivity, affecting their physical and psychological conditions. To achieve a sustainable compromise in terms of comfort and energy requirements, several challenging questions must be answered with regard to design, technical, engineering, psychological, and physiological issues and, finally, potential interactions with other IEQ issues that require a holistic way to conceive the building envelope design. This Special Issue collected original research and review articles on innovative designs, systems, and/or control domains that can enhance thermal comfort, work productivity, and wellbeing in a built environment, along with works considering the integration of human factors in buildings’ energy performance.
540			_aCreative Commons _fhttps://creativecommons.org/licenses/by/4.0/ _2cc _4https://creativecommons.org/licenses/by/4.0/
546			_aEnglish
650		7	_aHistory of engineering & technology _2bicssc
653			_asmart broiler chamber
653			_aventilation system
653			_awind velocity
653			_aage of air
653			_acomputational fluid dynamics
653			_asimulation analysis
653			_auser awareness
653			_aenergy consumption
653			_aindividual metering
653			_afeedback strategies
653			_aN-ZEB
653			_aIoT
653			_aTrombe wall
653			_athermal comfort
653			_apassive heating systems
653			_aheat accumulation
653			_athermal comfort models
653			_athermal comfort assessment
653			_aFanger’s models
653			_amoderate environments
653			_asport facilities
653			_adesert cooler
653			_aevaporative cooling
653			_aindoor air quality
653			_aliquid desiccant
653			_aeffectiveness model
653			_amoisture removal
653			_aPMV
653			_acomfort indices
653			_asoftware
653			_aapp
653			_abuilding simulation
653			_ahealth and comfort
653			_aevaluation indicators
653			_awork environments
653			_aindoor environmental quality
653			_aindoor comfort
653			_ahuman health
653			_aclothing thermal insulation
653			_athermoregulation model
653			_aTanabe model
653			_ainfrared camera
653			_aindoor air quality (IAQ)
653			_ahybrid ventilation
653			_ademand controlled ventilation (DCV)
653			_ainternet of things (IoT)
653			_asoft-sensor
653			_aconvolution neural networks
653			_adraught
653			_acooling period
653			_aopen office
653			_athermal sensation
653			_abiological structure and composition
653			_atissue temperature
653			_abioheat model
653			_aMRI analysis
653			_asensitivity analysis
856	4	0	_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/3190 _70 _zDOAB: download the publication
856	4	0	_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/69397 _70 _zDOAB: description of the publication
999			_c73522 _d73522