P. Danca, F. Bode, I. Nastase, and A. Meslem, CFD simulation of a cabin thermal environment with and without human body -thermal comfort evaluation, Advances in Heat and Transfer in Built Environment, Bucharest, E3S Web Conf, vol.32, pp.978-979, 2018.

T. Horobet, P. Danca, I. Nastase, and F. Bode, Preliminary research on virtual thermal comfort of automobile occupants, E3S Web Conf, vol.32, pp.978-979, 2018.

M. Sandu, F. Bode, P. Danca, and I. Voicu, Water flow structure optimization between the screenings and grit removals in a wastewater plant, Proceedings of the 8th International Conference on ENERGY and ENVIRONMENT (CIEM), p.000427610300022, 2017.

F. Bode, I. Nastase, P. Danca, and A. Meslem, The influence of the inlet angle of vehicle air diffuser on the thermal comfort of passengers, Proceedings of the 8th International Conference on ENERGY and ENVIRONMENT (CIEM), p.000427610300094, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01771119

P. Danca, F. Bode, I. Nastase, and A. Meslem, On the possibility of CFD modeling of the indoor environment in a vehicle, Energy Procedia, vol.112, p.000404848300081, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01523119

P. Danca, A. Vartires, and A. Dogeanu, An overview of current methods for thermal comfort assessment in vehicle cabin, Energy Procedia, vol.85, p.000377911100020, 2016.

A. Vartires, A. Dogeanu, and P. Danca, The human thermal comfort evaliation inside the passenger compartment, Proceedings of the 15th International Multidisciplinary Scientific Geoconference (SGEM), p.000371056000143, 2015.

. B+, P. Ouhimi, T. Lechartier, P. Danca, and C. Fabian, Thermal comfort evaluation inside vehicles with classical indices -experimental approach, Romanian Journal of Civil Engineering, vol.7, issue.2, pp.2559-748, 2016.

M. Dan, P. Danca, I. Ursu, and I. Nastase, Advanced thermal manikin with neuro-fuzzy control, Romanian Journal of Civil Engineering, vol.8, issue.4, pp.2559-748, 2017.

P. Danca, F. Bode, I. Nastase, C. Croitoru, and A. Meslem, Experimental and numerical study of the air distribution inside a car cabin, Proceedings of the 1st Conference of the UTCB Doctoral School, pp.1-6, 2018.

I. Ursu, D. Gu??, C. Croitoru, P. Danca, and I. Nastase, Advanced Thermal Manikin Prototype with Neuro-fuzzy Control System, Proceedings of the 4th International Conference On Building Energy & Environment, pp.542-546, 2018.

F. Bode, P. Danca, I. Nastase, A. Meslem, C. Croitoru et al., Developing a realistic CFD model of the air distribution inside a vehicle cockpit, ProceedingsRoomvent & PROCEEDINGS -Roomvent & Ventilation, pp.1109-1114, 2018.

P. Danca and A. Vartires, Thermal comfort assessment using human subjects, Scientific Proceedings of XXIII International Scientific-Technical Concerence "trans & MOTAUTO '15, vol.3, pp.1310-3946, 2015.

P. Danca and V. , A -Thermal comfort assessment using human subjects

. Machines, International Journal for Science, technics and innovations for the industry, issue.9, pp.20-24, 2015.

P. Danca, F. Bode, I. Nastase, C. Croitoru, and A. Meslem, Experimental and numerical study of the air distribution inside a car cabin, 1st Conference of the UTCB Doctoral School, 2018.

F. Bode, P. Danca, I. Nastase, A. Meslem, C. Croitoru et al., Developing a realistic CFD model of the air distribution inside a vehicle cockpit, Roomvent & Ventilation 2018 Conference, ROOM VENTILATION, 2018.

P. Danca, A. Meslem, I. Nastase, and F. Bode, Influence of the driver presence and of velocity profile of ventilation jet over airflow distribution and thermal comfort in a vehicle cabin, Thermique Recherche Internationale Industrie, 2018.

I. Ursu, D. Gu??, C. Croitoru, P. Danca, and I. Nastase, Advanced Thermal Manikin Prototype with Neuro-fuzzy Control System, 4th International Conference On Building Energy & Environment, COBEE, 2018.

P. Danca, F. Bode, I. Nastase, and A. Meslem, On the possibility of CFD modeling of the indoor environment in a vehicle, Advances in Heat and Transfer in Built REFERENCES
URL : https://hal.archives-ouvertes.fr/hal-01523119

J. C. Bertolini, Measuring urban job accessibility with distance decay, competition and diversity, Journal of Transport geography, vol.30, issue.1, pp.100-109, 2013.

C. Cristiana, Thermal comfort models for indoor spaces and vehicles -current capabilities and future perspectives, Renewable & Sustainable Energy Reviews, 2015.

A. Chen and V. W. Chang, Human health and thermal comfort of office workers in Singapore. Building and Environment, vol.58, pp.172-178, 2012.

D. Ormandy and V. Ezratty, Health and thermal comfort: From WHO guidance to housing strategies, Energy Policy, vol.49, pp.116-121, 2012.

H. Tsutsumi, Effect of Car Cabin Environment on Driver's Comfort and Fatigue, 2007.

H. A. Daanen, E. Van-de-vliert, and X. Huang, Driving performance in cold, warm, and thermoneutral environments, Applied Ergonomics, vol.34, issue.6, pp.597-602, 2003.

L. Fang and C. G. , Impact of temperature and humidity on the perception of indoor air quality, Ind. Air, vol.8, pp.80-90, 1998.

J. Rugh and V. Hovland, National and world fuel savings and CO2 emission reductions by increasing vehicle air conditioning COP, Proceedings from the 2003 Alternate Refrigerant Systems Symposium in Phoenix, 2003.

I. Nastase, Analyse des jets lobés en vue de leur intégration dans les Unités Terminales de Diffusion d'air, 2007.

I. Nastase, Lobed grilles for high mixing ventilation -An experimental analysis in a full scale model room. Building and Environment, vol.46, pp.547-555, 2011.

P. O. Fanger, Thermal Comfort-Analysis and Applications in Environmental Engineering, 1970.

M. P. Lee and -. , Sources of broadband noise of an automotive cooling fan. Applied Acoustics, vol.118, pp.66-75, 2017.

. Iso, Ergonomics of the thermal environment -Evaluation of thermal environments in vehicles Part 3: Evaluation of thermal comfort using human subjects, pp.14505-14508, 2006.

. Iso, Ergonomics of the thermal environment -Evaluation of thermal environments in vehiclesPart 2: Determination of equivalent temperature in ISO 14505, 2006.

. Iso, Ergonomics of the thermal environment -Evaluation of thermal environments in vehicles Part 1: Principles and methods for assessment of thermal stress, ISO 14505-1:2007. 2007. 16. Hensel, H., Thermoreception and Temperature Regulation, 1981.

M. Nakamura, Regional differences in temperature sensation and thermal comfort in humans, Journal of Applied Physiology, vol.105, issue.6, pp.1897-1906, 2008.

K. Slater, Human Comfort, vol.1, 1985.

E. Iso, ISO 7730 -Ergonomics of the thermal environment-Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria, 2005.

M. A. Humphreys and J. F. Nicol, Understanding the adaptive approach to thermal comfort, ASHRAE Transactions, vol.104, 1998.

R. J. De-dear and G. S. Brager, Developing an adaptive model of thermal comfort and preference. ASHRAE Transactions, vol.104, pp.145-167, 1998.

A. P. Gagge, J. A. Stolwijk, and Y. Nishi, An effective temperature scale based on a simple model of human physiological regulatory response, ASHRAE Transactions, vol.77, issue.1, pp.247-262, 1970.

J. S. Haldane, The Influence of High Air Temperatures, The Journal of Hygiene, vol.5, pp.494-513, 1905.

F. C. Houghten and C. P. , Determining lines of equal comfort, ASHVE. Transactions, vol.29, pp.163-175, 1923.

A. P. Gagge, A. P. Fobelets, and L. G. Berglund, A standard predictive index of human response to the thermal environment, ASHRAE Transactions, vol.92, issue.2B, pp.709-731, 1986.

&. Ashrae, ANSI/ASHRAE Standard 55-2013, American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2013.

G. Havenith and D. Fiala, Thermal Indices and Thermophysiological Modeling for Heat Stress Comprehensive physiology, vol.6, pp.255-302, 2015.

. Iso, Moderate thermal environments --Determination of the PMV and PPD indices and specification of the conditions for thermal comfort, vol.7730, 1984.

S. Paulke, Thermal simulation of a complete vehicle including manikins, SIMVECSimulation und Erprobung in der Fahrzeugentwicklung, 2014.

A. Psikuta, Thermal manikins controlled by human thermoregulation models for energy efficiency and thermal comfort research -A review. Renewable and Sustainable Energy Reviews, vol.78, pp.1315-1330, 2017.

A. Melikov, Breathing thermal manikins for indoor environment assessment: important characteristics and requirements, European Journal of Applied Physiology, vol.92, issue.6, pp.710-713, 2004.

A. Grundstein, V. Meentemeyer, and J. Dowd, Maximum vehicle cabin temperatures under different meteorological conditions, Int J Biometeorol, vol.53, pp.255-261, 2009.

Y. Shin, Experimental study on the change in driver's physiological signals in automobile HVAC system under Full load condition, International Encyclopedia of Ergonomics and Human Factors, vol.112, pp.1213-1222, 2001.

S. Feher, Thermoelectric Air Conditioned Variable Temperature Seat (VTS) and Effect Upon Vehicle Occupant Comfort, Vehicle Energy Efficiency, and Vehicle Environmental Compatibility, 1993.

C. Walgama, Passenger Thermal Comfort in Vehicles -A Review, Proceedings of the Institution of Mechanical Engineers, vol.220, issue.5, pp.543-562, 2006.

A. Alahmer, Vehicular thermal comfort models; a comprehensive review, pp.995-1002, 2011.

J. L. Hensen, Literature review on thermal comfort in transient conditions, Building and Environment, vol.25, issue.4, pp.309-316, 1990.

N. Djongyang, R. Tchinda, and D. Njomo, Thermal comfort : A review paper. Renewable and Sustainable Energy REviews, vol.14, pp.2626-2640, 2010.

Y. Cheng, J. Niu, and N. Gao, Thermal comfort models: A review and numerical investigation, vol.47, pp.13-22, 2012.

C. Croitoru, Thermal comfort models for indoor spaces and vehicles-Current capabilities and future perspectives. Renewable and Sustainable Energy Reviews, vol.44, pp.304-318, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01165567

C. Walgama, Proc.IMechE Part D: Automobile Engineering, 0220.

P. O. Fanger and C. J. , Discomfort due to air velocities in spaces, Proceedings of the Meeting of Commissions B1, B2, E1 and the IIR, vol.4, 1977.

P. O. Fanger and N. K. Christensen, Perception of draught in ventilated spaces, Ergonomics, vol.29, issue.2, pp.215-235, 1986.

J. Van-hoof, Forty years of Fanger's model of thermal comfort: comfort for all? Indoor Air, vol.18, pp.182-201, 2008.

, ISO 7730 -Ergonomics of the thermal environment-Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria, 2005.

&. Ashrae, Thermal environmental conditions for human occupancy, American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2004.

A. Koestel and G. L. Tuve, Performance and evaluation of room air distribution systems, ASHRAE Transactions, vol.61, p.533, 1955.

I. S. Organisation, ISO 7243 Hot environments -estimation of the heat stress on working man, based on the WBGT-index (wet bulb globe temperature), 1989.

J. Rydberg and P. Norback, Air distribution and draft, ASHVE Transactions, pp.1949-55

H. E. Straub and M. M. Chen, Distribution of air within a room for year-round air conditioningPart II, p.442, 1957.

T. L. Madsen, Thermal comfort measurements, ASHRAE Trans, issue.1, p.82, 1976.

D. Fiala, Ph.D dissertation: Dynamic simulation of human heat transfer and thermal comfort, 1998.

D. Fiala, K. J. Lomas, and M. Stohrer, A computer model of human thermoregulation for a wide range of environmental conditions: The passive system, Journal of Applied Physiology, vol.87, issue.5, pp.1957-1972, 1999.

D. Fiala, K. J. Lomas, and M. Stohrer, Computer prediction of human thermoregulatory and temperature responses to a wide range of environmental conditions, International Journal of Biometeorology, vol.45, issue.3, pp.143-159, 2001.

D. Fiala, UTCI-Fiala multi-node model of human heat transfer and temperature regulation, International Journal of Biometeorology, vol.56, issue.3, pp.429-441, 2012.

K. Nagano and T. Horikoshi, New index indicating the universal and separate effects on human comfort under outdoor and non-uniform thermal conditions. Energy and Buildings, vol.43, pp.1694-1701, 2011.

G. Jendritzky, R. De-dear, and G. Havenith, UTCI-Why another thermal index?, International Journal of Biometeorology, vol.56, issue.3, pp.421-428, 2012.

I. O. Standards, Ergonomics of the thermal environment --Analytical determination and interpretation of heat stress using calculation of the predicted heat strain, vol.7933, 2004.

I. O. Standards, Ergonomics of the thermal environment --Methods for the assessment of human responses to contact with surfaces --Part 3: Cold surfaces, p.21, 2005.

I. O. Standards, Ergonomics of the thermal environment --Determination and interpretation of cold stress when using required clothing insulation (IREQ) and local cooling effects, ISO 11079, p.34, 2007.

G. M. Budd, Wet-bulb globe temperature (WBGT)-its history and its limitations, J Sci Med Sport, vol.11, issue.1, pp.20-32, 2008.

F. R. Alfano, Ann Occup Hyg, vol.58, issue.8, pp.955-970, 2014.

. Iso, Ergonomics of the thermal environment -Evaluation of thermal environments in vehicles Part 2: Determination of Equivalent Temperature, pp.14505-14508, 2006.

I. Holmer, Evaluation of vehicle climate in Environmental Ergonomics, 2005.

H. Nilsson, Comfort Climate Evaluation with Thermal Manikin Methods and Computer Simulation Models, 0264.

H. Nilsson, Equivalent temperature and thermal sensation -Comparison with subjective responses. in Comfort in the automotive industry-Recent development and achievements, 1997.

H. Nilsson, Thermal climate assessment in office environment -CFD calculations and thermal manikin measurements. in ROOMVENT, 2000.

H. O. Nilsson, Thermal comfort evaluation with virtual manikin methods, vol.42, pp.4000-4005, 2007.

H. O. Nilsson and I. Holmér, Definitions and Measurements of Equivalent Temperature, European commission cost contract no smt4-ct95-2017 Development of standard test methods for evaluation of thermal climate in vehicles, 2002.

. Iso, Ergonomics of the thermal environment -Assessment of the influence of the thermal environment using subjective judgement scales, ISO 10551, 1995.

B. Givoni and G. R. , Predicting rectal temperature response to work, environment, and clothing, J. Appl. Physiol, vol.32, pp.812-821, 1972.

C. Huizenga, Z. Hui, and E. Arens, A model of human physiology and comfort for assessing complex thermal environments, Building and Environment, vol.36, pp.691-699, 2001.

N. P. Gao, H. Zhang, and J. L. Niu, Investigating indoor air quality and thermal comfort using a numerical thermal manikin. Indoor and Built Environment, 2007.

J. Schminder, Development of a Cockpit-Pilot Model for Thermal Comfort Optimization During Long-Mission Flight, AIAA Modeling and Simulation Technologies Conference, 2016.

N. Z. Azer and S. Hsu, The prediction of Thermal Sensation from Simple model of Human Physiological Regulatory Response, ASHRAE Trans, issue.1, p.83, 1977.

J. A. Stolwijk, A mathematical model of physiological temperature regulation in man. NASA CR-1855, 1971.

S. Tanabe, Evaluation of thermal comfort using combined multi-node thermoregulation (65MN) and radiation models and computational fluid dynamics (CFD), vol.34, pp.637-646, 2002.

A. Alahmer, M. Abdelhamid, and M. Omar, Design for thermal sensation and comfort states in vehicles cabins, Applied Thermal Engineering, vol.36, issue.0, pp.126-140, 2012.

L. Yi, An integrated model for simulating interactive thermal processes in human-clothing system, Journal of Thermal Biology, vol.29, pp.567-575, 2004.

N. P. Gao and J. L. Niu, Indoor and Built Environment. CFD study of thermal environment around a human body: A review, vol.14, pp.5-16, 2005.

C. Huizenga, Z. Hui, and E. Arens, A model of human physiology and comfort for assessing complex thermal environments. Building and Environment, vol.36, pp.691-699, 2001.

J. Gwak, M. Shino, and M. Kamata, Interaction between Thermal Comfort and Arousal Level of Drivers in Relation to the Changes in Indoor Temperature, International Journal of Automotive Engineering, vol.9, issue.2, pp.86-91, 2018.

B. Lv, Effects of stimulus mode and ambient temperature on cerebral responses to local thermal stimulation: An EEG study, International Journal of Psychophysiology, vol.113, pp.17-22, 2017.

M. J. Farrell, Brain activation associated with ratings of the hedonic component of thermal sensation during whole-body warming and cooling, Journal of Thermal Biology, vol.36, issue.1, pp.57-63, 2011.

Y. Yao, Experimental study on physiological responses and thermal comfort under various ambient temperatures, Physiology & Behavior, vol.93, issue.1, pp.310-321, 2008.

C. F. Bulcao, Relative contribution of core and skin temperatures to thermal comfort in humans, Journal of Thermal Biology, vol.25, issue.1, pp.147-150, 2000.

R. Dowman, D. Rissacher, and S. Schuckers, EEG indices of tonic pain-related activity in the somatosensory cortices, Clinical Neurophysiology, vol.119, issue.5, pp.1201-1212, 2008.

P. F. Chang, L. Arendt-nielsen, and A. C. Chen, Comparative cerebral responses to non-painful warm vs. cold stimuli in man: EEG power spectra and coherence, International Journal of Psychophysiology, vol.55, issue.1, pp.73-83, 2005.

S. Burch, V. Hassani, and T. Penney, Use of infra-red thermography for automotive climate control analysis, Proceedings of the SAE World Congress, p.921136, 1993.

M. Ö. Korukçu and M. Kilic, The usage of IR thermography for the temperature measurements inside an automobile cabin. International Communications in Heat and Mass Transfer, vol.36, pp.872-877, 2009.

J. H. Kang and S. J. Lee, Investigation on the flow characteristics inside an automotive HVAC system with varying ventilation mode, Journal of Visualization, vol.12, issue.4, pp.375-382, 2009.

C. Chien, 3-D numerical and experimental analysis for airflow within a passenger compartment, International Journal of Automotive Technology, vol.9, issue.4, pp.437-445, 2008.

T. Le?ovi?, HVAC automotive vents evaluation and their performance, HVAC&R Research, vol.19, issue.8, pp.1073-1082, 2013.

M. Fojtlín, 114: p. 02023. 96. jonsson, J., Including Solar Load in CFD Analysis of Temperature Distribution in a Car Passenger Compartment, 2007.

A. Alahmer, Effect of relative humidity and temperature control on in-cabin thermal comfort state: Thermodynamic and psychometric analyses, pp.2636-2644, 2011.

A. Alahmer, Analysis of vehicular cabins' thermal sensation and comfort state, under relative humidity and temperature control, using Berkeley and Fanger models, vol.48, pp.146-163, 2012.

M. E. Fountain, Laboratory studies of the effect of air movement on thermal comfort: A comparison and discussion of methods, ASHRAE Transactions, vol.97, issue.1, pp.863-873, 1991.

A. Alahmer, Effect of relative humidity and temperature control on in-cabin thermal comfort state: Thermodynamic and psychometric analyses, pp.2636-2644, 2011.

L. Holmer, Equivalent temperature in vehicles-conclusions and recommendations for standard, 6th ATA International Conference, 1999.

M. Bohm, Comparison of methods to determine the equivalent temperature in a cab in a climatic chamber, 6th ATA International Conference, pp.17-19, 1999.

N. A. Martinho, M. C. Silva, and J. A. Ramos, Evaluation of thermal comfort in a vehicle cabin in Proceedings of the Institution of Mechanical Engineers, Journal of Automobile Engineering

. London, , vol.218, pp.159-166, 2004.

P. Lange, A. W. , D. Schmeling, and J. Bosbach, Cost-effective human comfort manikin with realistic thermal load for convection-driven ventilation systems. in Roomvent, 2018.

H. J. Chun, Effect of indoor air temperature on the occupants' attention ability based on the electroencephalogram analysis, J. Archi. Inst. Korea Plan. Des, vol.28, issue.3, pp.217-225, 2012.

J. S. Kim, A study of physiology signal change by air conditioner temperature change, J. Fish. Mar. Sci. Edu, vol.19, issue.3, pp.502-509, 2007.

D. Kim and K. Kang, Design and Implementation of Integrated Information System for Monitoring Resources in Grid Computing, 10th International Conference on Computer Supported Cooperative Work in Design, 2006.

D. J. Kim, Comfortableness evaluation method using EEGs of the frontopolar and the parietal lobes, Trans. KIEE, vol.53, issue.5, pp.374-379, 2004.

K. N. Kang and S. D. Song, Study on the evaluation of amenity and physical characteristic of airconditioning systems applying fluctuation characteristic on natural wind, J. Archit. Inst. Korea Plan. Des, vol.29, issue.12, pp.267-275, 2013.

L. Lan, Experimental study on thermal comfort of sleeping people at different air temperatures. Building and Environment, vol.73, pp.24-31, 2014.

Y. Liu, A study of human skin and surface temperatures in stable and unstable thermal environments, Journal of Thermal Biology, vol.38, issue.7, pp.440-448, 2013.

A. T. Nguyen, M. K. Singh, and S. Reiter, An adaptive thermal comfort model for hot humid SouthEast Asia. Building and Environment, vol.56, pp.291-300, 2012.

Y. Yao, Experimental study on physiological responses and thermal comfort under various ambient temperatures, Physiology and Behavior, vol.93, issue.1-2, pp.310-321, 2008.

J. W. Seo, J. H. Park, and Y. H. Choi, Evaluation of thermal comfort and cooldown performance inside automotive cabin according to air-conditioning vent location, KSAE, vol.20, issue.5, pp.120-129, 2012.

Y. T. Kobayashi, Thermal comfort in car cabin with cooling individual body parts, 10th International Conference on Healthy Buildings, vol.2, 2012.

S. Murakami, S. Kato, and J. Zeng, CFD analysis of thermal environment around human body, vol.2, pp.479-484, 1996.

S. J. Dunnett, A numerical study of the factors affecting worker exposure to contaminant, Aerosol Science and Technology, vol.25, issue.1, pp.481-482, 1994.

K. Niwa, Numerical analysis of flow and temperature field with local air conditioning by supply jets from the seats in hall. in ROOMVENT, 1996.

R. J. Heinsohn, Industrial ventilation: engineering principle, 1991.

P. O. Tjelflaat and R. Knott, A simulation model for thermal comfort of a person in a large enclosure, INDOOR AIR, 1996.

S. Iwamoto, A study on numerical perdiction methods of thermal environmnent around occupants. in Indoor Air, 1996.

P. M. Bluyssen and T. Lemaire, The distribution of percieved air quality in an office spacecomputer simulations and sensory evaluations. in ROOMVENT, 1992.

G. Gan, Numerical method for full assessment of indoor thermal comfort, Indoor Air, vol.4, pp.154-168, 1994.

H. Brohus and P. V. Nielsen, Personal exposure to contaminant sources in uniform velocity field in Healthy Buildings, 1995.

H. Brohus and P. V. Nielsen, CFD models of persons evaluated by full-scale wind channel experiments. in ROOMVENT, 1996.

M. Kiliç and G. Sevilgen, The effects of using different type of inlet vents on the thermal characteristics of the automobile cabin and the human body during cooling period, The International Journal of Advanced Manufacturing Technology, vol.60, issue.5, pp.799-809, 2012.

V. M. Limaye, Design of Dynamic Airvents and Airflow Analysis in a Passenger Car Cabin. SASTECH, vol.11, pp.41-48, 2012.

M. Konstantinov and C. Wagner-;-a.-dillmann, Numerical Simulation of the Thermal Comfort in a Model of a Passenger Car Cabin, New Results in Numerical and Experimental Fluid Mechanics X: Contributions to the 19th STAB/DGLR Symposium, pp.383-393, 2014.

A. K. Ahirrao, Effect of Vent Shape on Thermal Comfort of Passengers in a Car, vol.10, pp.21-28, 2011.

S. G. Hodder and K. Parsons, The effects of solar radiation on thermal comfort, International Journal of Biometeorology, vol.51, issue.3, pp.233-250, 2007.

A. Mezrhab and M. Bouzidi, Computation of thermal comfort inside a passenger car compartment, vol.26, pp.1697-1704, 2006.

G. Sevilgen and M. Kilic, Investigation of transient cooling of an automobile cabin with a virtual manikin under solar radiation, Thermal Science, vol.17, pp.397-406, 2013.

H. Zhang, Studies of air-flow and temperature fields inside a passenger compartment for improving thermal comfort and saving energy. Part II: Simulation results and discussion, Applied Thermal Engineering, vol.29, issue.10, pp.2028-2036, 2009.

H. Zhang, Studies of air-flow and temperature fields inside a passenger compartment for improving thermal comfort and saving energy. Part I: Test/numerical model and validation, Applied Thermal Engineering, vol.29, issue.10, pp.2022-2027, 2009.

T. Srisilpsophon, J. Tiansuwan, and T. Kiatsiriroat, Effect of anti-solar glass film on heat transfer and mean radiant temperature inside cabin of air-conditioned vehicle, International Journal of Ambient Energy, vol.28, issue.1, pp.39-50, 2007.

W. F. Stoecker and J. W. Jones, Refrigeration & Air Conditioning, 1987.

J. H. Moon, Thermal comfort analysis in a passenger compartment considering the solar radiation effect, International Journal of Thermal Sciences, vol.107, pp.77-88, 2016.

F. Bode, The influence of the Inlet angle of vehicle air diffuser on the thermal comfort of passengers, 2017 International Conference on ENERGY and ENVIRONMENT (CIEM), 2017.
URL : https://hal.archives-ouvertes.fr/hal-01771119

T. Han, Virtual thermal comfort engineering, 2001.

J. and T. , Coupling of Human Thermoregulation and URANS Computation for Investigation of Local Heat Transfer and Flow Structures in a Generic Car Cabin. Flow, Turbulence and Combustion, vol.97, pp.1281-1296, 2016.

H. Zhang, Thermal sensation and comfort models for non-uniform and transient environments, part II: Local comfort of individual body parts. Building and Environment, vol.45, pp.389-398, 2010.

H. Zhang, Thermal sensation and comfort models for non-uniform and transient environments: Part I: Local sensation of individual body parts. Building and Environment, vol.45, pp.380-388, 2010.

A. Society, R. Heating, and A. Engineers, ASHRAE Handbook: Fundamentals, 2001.

M. F. Kader, M. A. Jinnah, and K. Lee, The effect of solar radiation on automobile environment through natural convection and mixed convection, Journal of Engineering Science and Technology, vol.7, pp.589-600, 2012.

H. O. Nilsson, Comfort Climate Evaluation with Thermal Manikin Methods and Computer Simulation Models. National Institut for Working Life, 2004.

M. S. Oh, Thermal comfort and energy saving in a vehicle compartment using a localized air-conditioning system, Applied Energy, vol.133, pp.14-21, 2014.

C. A. Neacsu and M. Ivanescu, The Development of a New Thermal Comfort Indexes, Proceedings of the European Automotive Congress EAEC-ESFA 2015, C. Andreescu and A. Clenci, pp.703-714, 2016.

I. Nastase and A. Meslem, Vortex dynamics and entrainment mechanisms in lobed jets, Bulletin of the American Physical Society, issue.12, p.52, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00312272

I. Nastase and A. Meslem, Passive control of jet flows using lobed nozzle geometries. Mécanique & Industries, vol.8, pp.101-109, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00312271

I. Nastase and A. Meslem, Lobed jets for improving air diffusion performance in buildings, The 29th AIVC Conference, 2008.
URL : https://hal.archives-ouvertes.fr/hal-00315325

I. Nastase and A. Meslem, Vortex dynamics and entrainment mechanisms in low Reynolds orifice jets, Journal of Visualization, vol.11, issue.4, 2008.
URL : https://hal.archives-ouvertes.fr/hal-00315324

I. Nastase and A. Meslem, Vortex Dynamics and mass entrainement in turbulent lobed jets with and without lobe deflection angles, Experiments in Fluids, vol.48, issue.4, pp.693-714, 2010.

I. Nastase, A. Meslem, and T. Bowmans, Vortical structures analysis in jet flows using a classical 2D-PIV system and time resolved visualization image processing, Journal of Flow Visualization and Image Processing, vol.15, pp.275-300, 2008.
URL : https://hal.archives-ouvertes.fr/hal-00312274

I. Nastase, A. Meslem, and I. Colda, Innovative passive mixing devices for better air diffusion performance in buildings, 43-th National Conference, 2008.

A. Meslem and I. Nastase, Analysis of free or twin-jets for innovative air diffusion terminal units, 2009.
URL : https://hal.archives-ouvertes.fr/hal-00536057

A. Meslem, I. Nastase, and K. Abed-meraim, Experimental investigation of a lobed jet flow mixing performance, Journal of Engineering Physics and Thermophysics, vol.81, issue.1, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00315322

A. Meslem, I. Nastase, and F. Allard, Passive mixing control for innovative air diffusion terminal devices for buildings. Building and Environment, vol.45, pp.2679-2688, 2010.

I. Nastase, A. Meslem, and P. Gervais, Primary and secondary vortical structures contribution in the entrainement of low Reynolds number jet flows, Experiments in Fluids, vol.44, issue.6, pp.1027-1033, 2008.

I. Nastase and A. Meslem, Vortex Dynamics and Entrainment Mechanisms in Low Reynolds Orifice Jets, Journal of Visualisation, vol.11, issue.4, pp.309-318, 2008.
URL : https://hal.archives-ouvertes.fr/hal-00315324

I. Nastase and A. Meslem, Vortex dynamics and mass entrainment in turbulent lobed jets with and without lobe deflection angles, Experiments in Fluids, vol.48, issue.4, pp.693-714, 2010.

I. Nastase, Lobed grilles for high mixing ventilation -An experimental analysis in a full scale model room, Building and Environment, 2010.

A. Meslem, M. El-hassan, and I. Nastase, Analysis of jet entrainment mechanism in the transitional regime by time-resolved PIV, Journal of Visualization, pp.1-12, 2010.

M. El-hassan and A. Meslem, Time-resolved stereoscopic PIV investigation of the entrainement in the near-field of circular and daisy-shaped orifice jets, Physics of Fluids, issue.3, p.22, 2010.

I. Nastase, Terminal inovative devices for HVAC air diffusion-research project PNII, RP cod CNCSIS, vol.6, 2008.

I. Nastase and A. Meslem, Passive control of jet flows using lobed nozzle geometries. Mécanique et Industries, vol.8, pp.101-109, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00312271

Z. Bolashikov, Improved inhaled air quality at reduced ventilation rate by control of airflow interaction at the breathing zone with lobed jets, Hvac&R Research, vol.20, issue.2, pp.238-250, 2014.

A. Meslem, M. El-hassan, and I. Nastase, Analysis of jet entrainment mechanism in the transitional regime by time-resolved PIV, Journal of Visualization, vol.14, issue.1, pp.41-52, 2011.

A. Meslem, Optimization of a Lobed Perforated Panel Diffuser -A Numerical Study of Orifice Arrangement, International Journal of Ventilation, vol.11, issue.3, pp.255-270, 2012.

I. Nastase, INADEVA: INtelligent Air Diffusion for healthy environments: advanced strategies and EVAluation methods -research project PN-II-ID, 2011.

J. F. Nicol and M. A. Humphreys, Adaptive thermal comfort and sustainable thermal standards for buildings. Energy and Buildings, vol.34, pp.563-572, 2002.

A. Leaman, L. Thomas, and M. Vandenberg, Green buildings: what Australian users are saying? EcoLibrium, vol.6, pp.22-30, 2007.

F. Nicol and M. Humphreys, Maximum temperatures in European office buildings to avoid heat discomfort. Solar Energy, vol.81, pp.295-304, 2007.

J. Baron, Thinking and deciding, 2008.

J. Baron, Against bioethics, 2006.

J. Baron, Norm-endorsement utilitarianism and the nature of utility, Economics and Philosophy, vol.12, issue.1, pp.165-182, 1996.

R. Burke, J. Rugh, and R. Farrington, ADAM -The Advanced Automotive Manikin. in International meeting on thermal manikins and modelling, 2003.

P. Lebbin, M. Hosni, and T. Gielda, Design and manufacturing of two thermal observation manikins for automobile applications. in International meeting on thermal manikins and modelling, 2003.

A. Dogeanu, Conception of a real human shaped thermal manikin for comfort assesment, PhD & DLA Symposium Pesc, 2012.

A. Dogeanu, Conception of a simplified seated thermal manikin for CFD validation purposes, Revista Romana de Inginerie Civila, issue.5, 2013.

Y. Y. Lee, Surrogate human sensor for human skin surface temperature measurement in evaluating the impacts of thermal behaviour at outdoor environment. Measurement, vol.118, pp.61-72, 2018.

S. Shi, Y. Li, and B. Zhao, Deposition velocity of fine and ultrafine particles onto manikin surfaces in indoor environment of different facial air speeds. Building and Environment, vol.81, pp.388-395, 2014.

I. Holmér, Thermal manikin history and applications, European Journal of Applied Physiology, pp.614-618, 2004.

R. Nayak and S. Houshyar, 7 -Comparison of manikin tests with wearer trials, in Manikins for Textile Evaluation, pp.159-171, 2017.

K. Jambunathan, A review of heat transfer data for single circular jet impingement, International Journal of Heat and Fluid Flow, vol.13, pp.106-115, 1992.

I. Ursu, D. G. , C. Croitoru, P. Danca, and I. Nastase, Advanced Thermal Manikin Prototype with Neurofuzzy Control System, COBEE 2018, 2018.

T. Sakoi, Thermal comfort, skin temperature distribution, and sensible heat loss distribution in the sitting posture in various asymmetric radiant fields. Building and Environment, vol.42, pp.3984-3999, 2007.

E. Bjorn and P. V. Nielsen, Dispersal of exhaled air and personal exposure in displacement ventilated rooms. Indoor Air, vol.12, pp.147-164, 2002.

A. K. Melikov, Impact of airflow interaction on inhaled air quality and transport of contaminants in rooms with personalized and total volume ventilation, Healthy Buildings, 2003.

J. Fan, New Functions and Applications of "Walter"-Sweating Fabric Manikin, International meeting on thermal manikins and modelling, 2003.

C. Topp, Influence of geometry of Thermal Manikins on concentration distribution and personal exposure. in Healthy Buildings, 2003.

C. Topp, Influence of geometry of Thermal Manikins on room airflow, Healthy Buildings, 2003.

T. Tamura, Development of a two-layer movable sweating thermal manikin, Industrial Health, vol.44, issue.3, pp.441-444, 2006.

C. Damjana, M. Harriet, and G. Jelka, A study of the influence of different clothing materials on heat and moisture transmission through clothing materials, evaluated using a sweating cylinder, International Journal of Clothing Science and Technology, vol.20, issue.2, pp.119-130, 2008.

E. A. Mccullough, The use of thermal manikins to evaluate clothing and environmental factors, Elsevier Ergonomics Book Series, Y. Tochihara and T. Ohnaka, pp.403-407, 2005.

S. Tanabe, Evaluating thermal environments by using a thermal manikin with controlled skin surface temperature, ASHRAE Transactions, vol.100, pp.39-48, 1994.

C. Croitoru, Studii teoretice ?i experimentale referitoare la influen?a turbulen?ei aerului din înc?perile climatizate asupra confortului termic, in UTCB, 2011.

T. Lund-madsen, Thermal effects of ventilated car seats, International Journal of Industrial Ergonomics, vol.13, issue.3, pp.253-258, 1994.

G. Karimi, Thermal Comfort Analysis of an Automobile Driver with Heated and Ventilated Seat, 2002.

L. Preusser, Development of a thermal model for a heated steering wheel to compensate defective feedback variables, 2017.

Y. Mao, J. Wang, and J. Li, Experimental and numerical study of air flow and temperature variations in an electric vehicle cabin during cooling and heating, Applied Thermal Engineering, vol.137, pp.356-367, 2018.

D. G. Baur and N. Todorova, Automobile Manufacturers, Electric Vehicles and the Price of Oil, Energy Economics

R. J. De-dear and J. W. Ring, Human subjective experience of ambient temperature step-changes: experimental results compared to the predictions of a numerical model, Indoor Air, 1990.

K. Jeong, Z. Zhai, and M. Krarti, Experimental and Numerical Investigation on Cooling Characteristics of Partition Air Supply System, ASHRAE Transactions, vol.112, p.6, 2006.

M. Kilic and S. M. , Experimental investigation of termal confrot and air qualitu in an automobile cabin during cooling period, pp.1375-1384, 2012.

C. Chen, Effects of temperature steps on human skin physiology and thermal sensation response. Building and Environment, vol.46, pp.2387-2397, 2011.

H. Oi, Effects of heated seats in vehicles on thermal comfort during the initial warm-up period, Applied Ergonomics, vol.43, issue.2, pp.360-367, 2012.

M. Hepokoski, Simulating Physiological Response with a Passive Sensor Manikin and an Adaptive Thermal Manikin to Predict Thermal Sensation and Comfort, 2015.

M. Kraj?ík, A. Simone, and B. W. Olesen, Air distribution and ventilation effectiveness in an occupied room heated by warm air. Energy and Buildings, vol.55, pp.94-101, 2012.

H. Xing, A. Hatton, and H. B. Awbi, A study of the air quality in the breathing zone in a room with displacement ventilation. Building and Environment, vol.36, pp.809-820, 2001.

W. Wu and Z. Lin, Experimental study of the influence of a moving manikin on temperature profile and carbon dioxide distribution under three air distribution methods. Building and Environment, vol.87, pp.142-153, 2015.

A. Dogeanu, Cercetari privind realizarea unor proceduri performante de evaluare si clasificare a microclimatului interior, 2015.

R. Gardon and J. C. Akfirat, The role of turbulence in determining the heat-transfer characteristics of impinging jets, International Journal of Heat and Mass Transfer, vol.8, pp.1261-1272, 1965.

D. G. Ursu, P. Croitoru, . Danca, and . Nastase, Advanced Thermal Manikin Prototype with Neurofuzzy Control System in COBEE, 2018.

I. Ursu, Switching neuro-fuzzy control with antisaturating logic. Experimental results for hydrostatic servoactuators, Proceedings of the Romanian Academy, Series A, Mathematics, Physics, Technical Sciences, Information Science, vol.12, pp.231-238, 2011.

U. Ioan, U. Felicia, and I. Lucian, Neuro-fuzzy synthesis of flight control electrohydraulic servo. Aircraft Engineering and Aerospace Technology, vol.73, pp.465-472, 2001.

W. Li-xin, Combining mathematical model and heuristics into controllers: an adaptive fuzzy control approach, Proceedings of 1994 33rd IEEE Conference on Decision and Control, 1994.

I. Ursu and F. Ursu, Airplane ABS control synthesis using fuzzy logic, Journal of Intelligent & Fuzzy Systems, vol.16, issue.1, pp.23-32, 2005.

I. Ursu, F. Ursu, and L. Iorga, Neuro-fuzzy synthesis of flight controls electrohydraulic servo, Aircraft Engineering and Aerospace Technology, issue.73, pp.465-471, 2001.

R. J. Adrian, Laser Velocimetry, in Fluid Mechanics Measurements, pp.155-240, 1983.

A. Boutier, L'ensemencement en vélocimétrie laser. AFVL Ecole d'automne: Vélocimétrie et granulométrie laser, 2003.

C. Kähler, B. Sammler, and J. Kompenhans, Generation and control of tracer particles for optical flow investigations in air, Experiments in Fluids, vol.33, issue.6, pp.736-742, 2002.

W. H. Echols and J. A. Young, Studies of portable air-operated aerosol generators, 1963.

A. S. Dantec-dynamics and . Comfortsense, , 2017.

L. Wang, Combining mathematical model and heuristics into controllers: An adaptive fuzzy control approach. Fuzzy Sets and Systems, vol.89, pp.151-156, 1997.

I. Nastase, C. Croitoru, and C. Lungu, A Questioning of the Thermal Sensation Vote Index Based on Questionnaire Survey for Real Working Environments, vol.85, pp.366-374, 2016.

. Iso, Assessment of the influence of the thermal environment using subjective judgement scales in EN ISO 10551, 2001.

C. M. Garcia, P. R. Jackson, and M. H. Garcia, Confidence Intervals in the Determination of Turbulence Parameters, Experiments in Fluids, vol.40, issue.4, pp.514-522, 2006.

H. L. Petrie, M. Samimy, and A. L. Addy, Laser Doppler velocity biais in separated flows, Experiments in Fluids, vol.6, issue.1, pp.80-88, 1988.

D. O. Barnett and H. T. Bentley, Statistical bias of individual realization laser velocimeters, Proceedings of the Second International Workshop on Laser Velocimetry, 1974.

J. S. Bendat and A. G. Piersol, Analysis and Measurement Procedures, vol.566, 1986.

J. Haertig, Traitement de données en Vélocimétrie Laser Doppler. AFVL Ecole d'automne: Vélocimétrie et granulométrie laser, 2003.

S. Danaila, C. Berbente-;-tenekes, H. , and J. Lumley, Metode numerice în dinamica fluidelor, vol.233, 1975.

B. E. Launder, W. C. Reynolds, and W. Rodi, La simulation des modeles de turbulence et leurs applications, 1984.

A. Meslem, A comparison of three turbulence models for the prediction of parallel lobed jets in perforated panel optimization. Building and Environment, vol.46, pp.2203-2219, 2011.

P. V. Nielsen, Berechnung der Luftbewegung in einem zwangsbelüfteten Raum, GesundheitsIngenieur, vol.94, pp.299-302, 1973.

P. V. Nielsen, Benchmarks test for a computer simulated person Indoor Air, vol.14, pp.144-156, 2003.

S. Murakami, S. Kato, and J. Zeng, Numerical simulation of contaminant distribution around a modeled human body: CFD study on computational thermal manikin Part II, ASHRAE Transactions, vol.104, pp.226-233, 1998.

T. Hayashi, CFD analysis on rising stream araound a human body and its effect on inhalation air quality, ASHRAE Transactions, vol.108, issue.2, pp.1173-1178, 2002.

D. N. Sorensen, Radiation between segments of the seated human body in ROOMVENT, pp.317-320, 2002.

S. Murakami, S. Kato, and J. Zeng, Combined simulation of airflow, radiation and moisture transport for heat release from a human body, Building and Environment, vol.35, issue.6, pp.489-500, 2000.

D. N. Sorensen and L. K. Voigt, Modeling airflow and heat transfer around a seated human body by computational dynamics. Building and Environment, vol.38, pp.753-762, 2003.

C. Topp, P. V. Nielsen, and D. N. Sorensen, Application of computer simulated persons in indoor environmental modeling, ASHRAE Transactions, vol.108, issue.2, pp.1084-1089, 2002.

T. Yang, A new simulation system to predict human-environment thermal interactions in naturally ventilated buildings. in Building Simulation, 2007.

Y. Zhang and T. Yang, Simulation of human thermal responses in a confined space. in Indoor Air, 2008.

L. K. Voigt, Navier-Stokes simulations of airflow in rooms and around a human body, 2001.

Q. Chen and W. Xu, A zero-equation turbulence model for indoor airflow simulation. Energy and Buildings, vol.28, pp.137-144, 1998.

J. Torano, R. Rodríguez, and I. Diego, Computational Fluid Dynamics (CFD) use in the simulation of the death end ventilation in tunnels and galleries, WIT Transactions on Engineering Sciences, p.52, 2006.

A. J. Gadgil, Indoor pollutant mixing time in an isothermal closed room: an investigation using CFD, Atmospheric Environment, vol.37, pp.5577-5586, 2003.
URL : https://hal.archives-ouvertes.fr/hal-00312122

Z. Zhang and Q. Chen, Experimental measurements and numerical simulations of particle transport and distribution in ventilated rooms, Atmospheric Environment, vol.40, issue.18, pp.3396-3408, 2006.

J. Bosbacha, Experimental and numerical simulations of turbulent ventilation in aircraft cabins. in The Second ASME-ZSIS International Thermal Science Seminar (ITSS II), 2006.

J. D. Posner, C. R. Buchanan, and D. Dunn-rankin, Measurement and prediction of indoor air flow in a model room, Energy and Buildings, vol.35, issue.5, pp.515-526, 2003.

D. C. Wilcox, Reassessment of the scale-determining equation for advanced turbulence models, AIAA Journal, vol.26, pp.1299-1310, 1988.

A. Stamou and I. Katsiris, Verification of a CFD model for indoor airflow and heat transfer, vol.41, pp.2171-1181, 2006.

F. Kuznik, G. Rusaouën, and J. Brau, Experimental and numerical study of a full scale ventilated enclosure: Comparison of four two equations closure turbulence models Building and Environment, vol.42, pp.1043-1053, 2007.

A. Musser and K. Mcgrattan, Evaluation of a fast Large-Eddy-Simulation model for indoor airflows, J. Arch. Engrg, vol.8, issue.1, pp.10-18, 2002.

G. Sevilgen and M. Kilic, Numerical analysis of airflow, heat transfer, moisture transport and thermal comfort in a room heated by two-panel radiators, Energy and Buildings, vol.43, issue.1, pp.137-146, 2011.

F. Bode, Cercetari privind procesele termo-fluidodonamice din arzatoare si focare la arderea turbionara, in Facultatea de Mecanica, 2010.

H. Homma and M. Yakiama, Examination of free convection around occupant's body caused by metabolic heat, ASHRAE Transactions, vol.94, issue.1, pp.104-124, 1988.

M. E. Fountain, Laboratory studies of the effect of air movement on thermal comfort: A comparison and discussion of methods, ASHRAE Transactions, vol.97, issue.1, pp.863-873, 1991.

M. A. Humphreys, Field studies and climate chamber experiments in thermal comfort research, Thermal Comfort : Past Present and Future, pp.52-72, 1994.

N. A. Oseland and M. A. Humphreys, Trends in Thermal Comfort Research, 1994.

M. A. Humphreys and J. F. Nicol, The validity of ISO-PMV for predicting comfort votes in everyday thermal environments. Energy and Buildings, vol.34, pp.667-684, 2002.

A. Al-mogbel, A coupled model for predicting heat and mass transfer from a human body to its surroundings, 36th AIAA Thermophysics Conference, 2003.

T. Omori, Coupled simulation of convection and radiation on thermal environment around an accurately shaped human body. in ROOMVENT, 2004.

J. Srebric, CFD boundary conditions for contaminant dispersion, heat transfer and airflow simulations around human occupants in indoor environments, Building and Environment, p.43, 2008.

M. Kilic and G. Sevilgen, Modelling airflow, heat transfer and moisture transport around a standing human body by computationla fluid dynamics, Int. Journal Heat Mass Transfer, vol.33, pp.1159-1164, 2008.

Q. Y. Chen, Z. Zhang, and W. Zuo, Computational fluid dynamics for indoor environment modeling: past, present and future, XXV UIT National Heat Transfer Conference, 2007.

Z. Zhang, J. Z. Zhai, and Q. Chen, Evaluation of various CFD models in predicting room airflow and turbulence. in ROOMVENT, 2007.

J. E. Jaramillo, Numerical Study of Plane and Round Impinging Jets using RANS Models, Numerical Heat Transfer, vol.54, issue.3, pp.213-237, 2008.

P. Danca, On the Possibility of CFD Modeling of the Indoor Environment in a Vehicle. Energy Procedia, vol.112, pp.656-663, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01523119

P. O. Fanger, Air turbulence and sensation of draught. Energy and Buildings, vol.12, pp.21-39, 1988.

P. O. Fanger, The new comfort equation for indoor air quality, Ashrae Journal, vol.31, issue.10, pp.33-38, 1989.

H. B. Awbi, Ventilation of Buildings, 2003.

W. M. Yan, Measurement of detailed heat transfer on a surface under arrays of impinging elliptic jets by a transient liquid crystal technique, International Journal of Heat and Mass Transfer, vol.47, pp.5235-5245, 2004.

C. Buratti and R. P. , Adaptive analysis of thermal comfort in university classrooms: correlation between experimental data and mathematical models, Build Environ, vol.44, pp.674-87, 2009.

J. Lee, J. K. , and J. Park, Effect of the air-conditioning system on the fuel economy in a gasoline engine vehicle. Institution of mechanical enginners, vol.227, pp.66-77, 2012.

C. Croitoru, Numerical and experimental modeling of airflow and heat transfer of a human body, 2011.

C. Croitoru, Inlet turbulence intensity influence on the thermal comfort in the case of a mixing ventilation system submitted to Building and Environment, 2011.