xbib.bib

@inproceedings{CFD,
	title        = {{CFD Simulation And Measurement Of The Heat Transfer From Building Material Specimens To The Indoor Environment}},
	author       = {Voelker, Conrad and Diewald, Markus},
	year         = 2015,
	booktitle    = {14th Conference of International Building Performance Simulation Association, Hyderabad, India, Dec. 7-9, 2015.},
	pages        = {1---6}
}
@misc{bergman2011fundamentals,
	title        = {{Fundamentals of heat and mass transfer}},
	author       = {Bergman, Theodore L and Lavine, Adrienne S and Incropera, Frank P and Dewitt, David P},
	year         = 2011,
	publisher    = {John Wiley \& Sons Hoboken, NJ}
}


@mastersthesis{almaian2024heat,
  author       = {Almaian, Maryam},
  title        = {{3D} Heat Transfer Analysis in Architectural Modeling: A Case Study with OpenFOAM},
  school       = {Georgia Institute of Technology},
  year         = {2024},
  month        = {May},
  type         = {Master's thesis},
  address      = {Atlanta, GA},
  note         = {School of Architecture, College of Design}
}


@manual{cht,
	title        = {{Tutorial to set up a case for chtMultiRegionFoam in OpenFOAM 2.0.0}},
	author       = {Singhal, Arpit},
	year         = 2014,
	month        = {08},
	url          = {http://www.slideshare.net/ARPITSINGHAL3/cht-multiregionfoam4regiontutorial}
}
@article{COMSOL,
	title        = {{COMSOL Multiphysics validation as simulation software for heat transfer calculation in buildings: Building simulation software validation}},
	author       = {Gerlich, Vladim{\'\i}r and Sulovsk{\'a}, Kate{\v{r}}ina and Z{\'a}le{\v{s}}{\'a}k, Martin},
	year         = 2013,
	journal      = {Measurement},
	publisher    = {Elsevier},
	volume       = 46,
	number       = 6,
	pages        = {2003--2012}
}
@article{EU50,
	title        = {{Review of 50 years of EU energy efficiency policies for buildings}},
	author       = {Economidou, Marina and Todeschi, Valeria and Bertoldi, Paolo and D'Agostino, Delia and Zangheri, Paolo and Castellazzi, Luca},
	year         = 2020,
	journal      = {Energy and Buildings},
	publisher    = {Elsevier},
	volume       = 225,
	pages        = 110322,
	doi          = {10.1016/j.enbuild.2020.110322}
}
@misc{ex1,
	title        = {{THESEUS‑FE model. Adanced Heat Transfer Models \vert{}\ Verification\ \&\ Validation.}},
	author       = {THESEUS‑FE},
	year         = {n.d.},
	publisher    = {https://www.theseus-fe.com/resources/validations/advanced-heat-transfer}
}
@inproceedings{ex2,
	title        = {{3D Dynamic Simulation of Heat Conduction through a Building Corner Using a BEM Model in the Frequency Domain.}},
	author       = {Sim\~{o}es, N. and Prata, J. and Tadeu, A.},
	year         = 2019,
	journal      = {Energies 12},
	publisher    = {Mdpi},
	doi          = {10.3390/en12234595}
}
@inproceedings{heattransfund,
	title        = {{Energy Efficient Buildings: Fundamentals of Building Science and Thermal Systems}},
	author       = {Zhai, Z.},
	year         = 2023,
	booktitle    = {Wiley},
	pages        = {chapter 1}
}
@manual{HTflux,
	title        = {{HTflux Simulation Software}},
	author       = {R\"{u}disser, Daniel},
	year         = 2018,
	month        = {01},
	doi          = {10.13140/RG.2.2.32748.54409}
}
@techreport{ISO,
	title        = {{ISO 10211:2007 thermal bridges in building construction. test case A.3 validation}},
	author       = {{ISO}},
	year         = 2017,
	number       = 65710,
	url          = {https://www.iso.org/standard/65710.html},
	note         = {Available online},
	institution  = {International Organization for Standardization},
	type         = {ISO Standard}
}
@inproceedings{kastner2020solving,
	title        = {{Solving Thermal Bridging Problems for Architectural Applications with OpenFOAM}},
	author       = {Kastner, Patrick and Dogan, Timur},
	year         = 2020,
	booktitle    = {SimAUD 2020 Proceedings},
	pages        = {405---412}
}
@article{RevPCM,
	title        = {{Review on building energy performance improvement using phase change materials}},
	author       = {Song, Mengjie and Niu, Fuxin and Mao, Ning and Hu, Yanxin and Deng, Shiming},
	year         = 2018,
	journal      = {Energy and Buildings},
	publisher    = {Elsevier},
	volume       = 158,
	pages        = {776--793},
	doi          = {10.1016/j.enbuild.2017.10.066}
}
@inproceedings{Heim2005,
	title        = {{Two solution methods of heat transfer with phase change within whole building dynamic simulation}},
	author       = {Heim Dariusz},
	year         = 2005,
	booktitle    = {Ninth International IBPSA Conference},
	pages        = {1--7}
}
@article{Yang,
	title        = {{Volume element model for 3D dynamic building thermal modeling and simulation}},
	author       = {Yang, S and Pilet, TJ and Ordonez, JC},
	year         = 2018,
	journal      = {Energy},
	publisher    = {Elsevier},
	volume       = 148,
	pages        = {642--661}
}
@misc{THERM,
	title        = {{THERM Software Downloads}},
	author       = {THERM},
	year         = {2022},
	url          = {https://windows.lbl.gov/therm-software-downloads}
}
@article{glaser1959graphisches,
	title        = {{Graphisches Verfahren zur Untersuchung von Diffusionsvorgängen}},
	author       = {Glaser, H},
	year         = 1959,
	journal      = {K{\"a}ltetechnik},
	volume       = 11,
	number       = 10,
	pages        = {345--349}
}
@misc{OpenFOAMFoundation,
	title        = {{ChtMultiRegionFoam}},
	author       = {OpenFOAM},
	year         = 2019,
	url          = {https://openfoamwiki.net/index.php/ChtMultiRegionFoam}
}
@misc{OFD,
	title        = {{chtMultiRegionFoam Solver Documentation}},
	author       = {OpenFOAM},
	year         = 2018,
	url          = {https://www.openfoam.com/documentation/guides/latest/doc/guide-applications-solvers-heat-transfer-chtMultiRegionFoam.html}
}
@article{hce,
	title        = {CFD Analysis of Convective Heat Transfer Coefficient on External Surfaces of Buildings},
	author       = {Vollaro, Andrea De Lieto and Galli, Giorgio and Vallati, Andrea},
	year         = 2015,
	journal      = {Sustainability},
	volume       = 7,
	number       = 7,
	pages        = {9088--9099},
	doi          = {10.3390/su7079088},
	issn         = {2071-1050},
	url          = {https://www.mdpi.com/2071-1050/7/7/9088},
	abstract     = {Convective heat transfer coefficients for external building surfaces are essential in building energy simulation (BES) to calculate convective heat gains and losses from building facades and roofs to the environment. These coefficients are complex functions of: building geometry, building surroundings, local air flow patterns and temperature differences. A microclimatic analysis in a typical urban configuration, has been carried out using Ansys Fluent Version 14.0, an urban street canyon, with a given H/W ratio, has been considered to simulate a three-dimensional flow field and to calculate the thermal fluid dynamics parameters that characterize the street canyon. In this paper, the convective heat transfer coefficient values on the windward external façade of the canyon and on the windward and leeward inner walls are analyzed and a comparison with values from experimental and numerical correlations is carried out.}
}
@misc{greenteg,
	title        = {{GreenTeg. (n.d.). U-value - GreenTeg}},
	url          = {https://shop.greenteg.com/u-value/}
}
@article{litrev2,
	title        = {CFD Simulation of Convective Heat Transfer on Vernacular Sustainable Architecture: Validation and Application of Methodology},
	author       = {Zhong, Wenzhou and Zhang, Tong and Tamura, Tetsuro},
	year         = 2019,
	journal      = {Sustainability},
	volume       = 11,
	number       = 15,
	doi          = {10.3390/su11154231},
	issn         = {2071-1050},
	url          = {https://www.mdpi.com/2071-1050/11/15/4231},
	article-number = 4231,
	abstract     = {The global background of energy shortages and climate deterioration demands bioclimatic sustainable buildings. Vernacular architecture can provide a useful resource of passive strategies and techniques for creating inner comfort conditions with minimum heating, ventilation, and air conditioning (HVAC) assistance. The identification and verification of such knowledge are essential for climate responsive or energy passive building design. Among the methods, computational fluid dynamics (CFD) is a useful tool for simulating convective heat transfer of vernacular architecture and predicting the convective heat transfer coefficient (CHTC) and flow field. Geometric complexity and diversity of building samples are crucial in the development of an effective simulation methodology in terms of computational cost and accuracy. Therefore, this paper presents high-resolution 3D steady Reynolds-averaged Navier–Stokes (RANS) CFD simulations of convective heat transfer on Japanese vernacular architecture, namely, “machiya.” A CFD validation study on the CHTC is performed based on wind-tunnel experiments on a cube heated by constant heat flux and placed in a turbulent channel flow with a Reynolds number of 3.3 × 104. Three steady RANS models and two boundary layer modeling approaches are compared and discussed. Results show that the SST k-ω model applied with low Reynolds number modeling approach is suitable for CHTC simulations on a simplified building model. The RNG k-ε model applied with wall functions is an appropriate choice for simulating flow field of a complicated building model. Overall, this study develops a methodology involving RANS model selection, boundary layer modeling, and target model fitting to predict the convective heat transfer on vernacular architecture.}
}


@misc{kendeda,
	title        = {{Microgrant}},
	author       = {{Kendeda Building Advisory Board}},
	year         = 2023,
	url          = {https://research.gatech.edu/micro-research-grants-awarded},
	howpublished = {https://research.gatech.edu/micro-research-grants-awarded},
}




@misc{issst,
	title        = {{issst}},
	author       = {issst},
	year         = 2023,
	url          = {https://issst.net/issst-2024/},
	howpublished = {https://issst.net/issst-2024/},
}


@misc{ibpc,
	title        = {{International Building Physics Conference 2024}},
	author       = {{IBPC}},
	year         = 2024,
	url          = {https://www.ibpc2024.org/},
	howpublished = {https://www.ibpc2024.org/},
}



@article{Zhao2007,
  author = {Zhao, Fu-Yun and Liu, Di and Tang, Guang-Fa},
  title = {Conjugate heat transfer in square enclosures},
  journal = {Heat and Mass Transfer},
  volume = {43},
  number = {9},
  pages = {907--922},
  year = {2007},
  doi = {10.1007/s00231-006-0136-4},
  url = {https://doi.org/10.1007/s00231-006-0136-4},
  abstract = {Building elements represented by square vertical enclosures encircled with finite walls or with centered solid body, could maintain the equivalent fluid volumes through the volume ratio scale. Present work aims to investigate the fluid flow and heat transfer in these two building elements. Complete two-dimensional numerical simulation of the conjugate heat conduction}
}






@misc{sigfpe,
	title        = {{IPC}},
	author       = {Sigfpe},
	year         = 2023,
	url          = {https://en.wikipedia.org/wiki/Signal_(IPC)#SIGFPE}
}

@misc{energy2d,
    title        = {{ENERGY2D}},
    author       = {{Concord Consortium}},
    year         = 2017,
    url          = {https://energy.concord.org/energy2d},
    howpublished = {https://energy.concord.org/energy2d},
}

@misc{heat2,
    title        = {{heat2}},
    author       = {{BuildingPhysics.com}},
    year         = 2021,
    url          = {https://buildingphysics.com/heat2-3/},
    howpublished = {https://buildingphysics.com/heat2-3/},
}

@misc{kelvin,
    title        = {{Kelvin}},
    author       = {{Integrated Engineering Software}},
    year         = 2021,
    url          = {https://www.integratedsoft.com/products/Kelvin},
    howpublished = {https://www.integratedsoft.com/products/Kelvin},
}

@misc{theusus,
    title        = {{Theusus - Heat Transfer Analysis}},
    author       = {{Theseus}},
    year         = 2021,
    url          = {https://www.theseus-fe.com/simulation-software/heat-transfer-analysis},
    howpublished = {https://www.theseus-fe.com/simulation-software/heat-transfer-analysis},
}

@misc{quickfield,
    title        = {{QuickField}},
    author       = {{Tera Analysis Ltd.}},
    year         = 2021,
    url          = {https://quickfield.com/transfer.htm},
    howpublished = {https://quickfield.com/transfer.htm},
}

@misc{simscale,
    title        = {{SimScale}},
    author       = {{SimScale GmbH}},
    year         = 2021,
    url          = {https://www.simscale.com/},
    howpublished = {https://www.simscale.com/},
}

@misc{physibel,
    title        = {{Physibel}},
    author       = {{Physibel}},
    year         = 2021,
    url          = {https://www.physibel.be/en},
    howpublished = {https://www.physibel.be/en},
}

@misc{taitherm,
    title        = {{Taitherm}},
    author       = {{ThermoAnalytics Inc.}},
    year         = 2021,
    url          = {https://thermoanalytics.com/taitherm},
    howpublished = {https://thermoanalytics.com/taitherm},
}



@inproceedings{MPIbpc,
  author       = {Maryam Almaian and Patrick Kastner},
  title        = {3D Heat Transfer Analysis in Architectural Modeling: A Case Study with OpenFOAM},
  booktitle    = {Proceedings of the 2024 International Building Physics Conference},
  address      = {Toronto, Canada},
  month        = {07},
  days         = {25--27},
  year         = {2024}
}


@misc{glb,
  author = {{Berkeley Earth}},
  title = {{Berkeley Earth Global Land Temperature}},
  url = {https://berkeleyearth.org/temperature-region/global-land},
  year = {2024}
}



@misc{ipcc,
  author = {{Masson-Delmotte, V. and Zhai, P. and Pirani, A. and Connors, S.L. and Péan, C. and Berger, S. and Caud, N. and Chen, Y. and Goldfarb, L. and Gomis, M.I. and Huang, M. and Leitzell, K. and Lonnoy, E. and Matthews, J.B.R. and Maycock, T.K. and Waterfield, T. and Yelekçi, O. and Yu, R. and Zhou, B.}},
  title = {{Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change}},
  year = {2021},
  publisher = {Cambridge University Press},
  address = {Cambridge, UK and New York, NY, USA},
  pages = {3--32},
  doi = {10.1017/9781009157896.001},
  url = {https://www.ipcc.ch/report/ar6/wg1/}
}


@misc{ofvoptions,
  title        = {OpenFOAM Guide: fvOptions},
  howpublished = {Online},
  year         = 2024,
  url          = {https://www.openfoam.com/documentation/guides/latest/doc/guide-fvoptions.html}
}