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008			040907s2001 enka 001 0 eng
010			_a 2004351731
015			_aGBA1-Y2239
020			_a9780750650823
040			_aUKM _cUKM _dNTD _dC#P _dTXA _dOCLCQ _dUBA _dDLC _dEG-CaNU
082	0	4	_a696.011 _221
100	1		_aClarke, J. A. _eAuthor
245	1	0	_aEnergy simulation in building design / _cby J.A. Clarke.
250			_a2nd ed.
260			_aOxford : _bButterworth-Heinemann, _c2001.
300			_ax, 362 p. : _bill. ; _c25 cm.
500			_aPrevious ed.: Bristol : Hilger, 1985.
504			_aIncludes bibliographical references and index.
505			_aIntroduction, A brief history of simulation, Simulation overview, Integrative modelling, Energy flowpaths and causal effects, The need for accuracy and flexibility, Energy modelling techniques, References; Integrative modelling methods, Response function methods, Time-domain response functions, Frequency-domain response functions, Numerical methods, Which Method?, References; Building simulation, System discretisation, Finite volume energy equation formulation, Equation structuring, References and further reading; Processing the building energy equations, Establishing the energy matrix equation, Matrix partitioning for fast simultaneous solution, Mixed frequency inversion, References and further reading; Fluid flow, The nodal metwork method, Computational fluid dynamics, Moisture flow within porous media, Linking the building and flow domains, References; HVAC, renewable energy conversion and controls systems, Approaches to systems simulation, HVAC systems, New and renewable energy conversion systems, Control systems, Linking the building, flow and systems models, References; Energy related sub-systems, Weather, Geometrical considerations, Shading and insolation, Shortwave radiation processes, Longwave radiation processes, Surface convection, Casual heat sources, Daylight prediction, Mould growth, References; Use in practice, Validation, Performance assessment method, Uncertainty, Large scale considerations, Support mechanisms, References; Future trends, Design process integration, Virtual construction, Concluding remark, References; Appendix A Thermophysical properties; Appendix B Deficiencies of simplified methods; Appendix C Fourier heat equation; Appendix D Admittance method, worked example; Appendix E Point containment algorithm; Appendix F Nomenclature; Index
520			_aSince the appearance of the first edition of 'Energy Simulation in Building Design', the use of computer-based appraisal tools to solve energy design problems within buildings has grown rapidly. A leading figure in this field, Professor Joseph Clarke has updated his book throughout to reflect these latest developments. The book now includes material on combined thermal/lighting and CFD simulation, advanced glazings, indoor air quality and photovoltaic components. This thorough revision means that the book remains the key text on simulation for architects, building engineering consultants and students of building engineering and environmental design of buildings. The book's purpose is to help architects, mechanical & environmental engineers and energy & facility managers to understand and apply the emerging computer methods for options appraisal at the individual building, estate, city, region and national levels. This is achieved by interspersing theoretical derivations relating to simulation within an evolving description of the built environment as a complex system. The premise is that the effective application of any simulation tool requires a thorough understanding of the domain it addresses.
650		0	_aBuildings _xEnergy conservation _xSimulation methods. _9765
650		4	_aArchitecture and energy conservation _xMathematical models. _9766
650		4	_aArchitecture and energy conservation _xComputer simulation. _9767
650		7	_aCONFORTO TÉRMICO DAS CONSTRUÇÕES _2larpcal _9768
650		7	_aCONSERVAÇÃO DE ENERGIA _2larpcal _9769
690			_aArchitecture
856	4	2	_yhttps://www.routledge.com/Energy-Simulation-in-Building-Design/Clarke/p/book/9780750650823
942			_2ddc _cBK
999			_c9136 _d9136