Natural Ventilation as a Design Strategy for Energy Saving
Ventilation is a fundamental requirement for
occupant health and indoor air quality in buildings. Natural
ventilation can be used as a design strategy in free-running
buildings to:
• Renew indoor air with fresh outside air and lower room
temperatures at times when the outdoor air is cooler.
• Promote air flow to cool down the building structure
(structural cooling).
• Promote occupant physiological cooling processes
(comfort cooling).
This paper focuses on ways in which ventilation can
provide the mechanism for heat dissipation and cooling of the
building structure..It also discusses use of ventilation as a
means of increasing air movement to improve comfort when
indoor air temperatures are too high. The main influencing
factors and design considerations and quantitative guidelines
to help meet the design objectives are also discussed.
[1] Warren, P. R., and Parkins, L. M. 1984. Single Sided Ventilation
Through Open Windows. In Proc. Windows in Building Design and
Maintenance. Jitterbug, Sweden. p.487.
[2] Evans, B. H. 1979. Energy Conservation with Natural Airflow Through
Windows. ASHRAE Transactions, 852:641 650.
[3] Reed, R. H. 1953. Design for Natural Ventilation in Hot Humid
Weather--Reprint from Housing and Building in Hot Humid and Hot
Dry Climates. Washington, D.C.: Building Research Institute, National
Academy of Sciences, National Research Council.
[4] Bowen, A. 1981. Classification of Air Motion Systems and Patterns.
Proceeding of the International Passive and Hybrid Cooling Conference.
American Section of the International Solar Energy Society. Miami
Beach. p. 743-763.
[5] Bahadori, M. 1988. A Passive Cooling System for Hot Arid Regions.
13th National Passive Solar Conference. Cambridge, USA, pp 364-367.
[6] Fleury, B. 1990. Ventilative Cooling: State of the Art. Workshop on
Passive Cooling. Ispra, 2-4 April.
[7] Holleman, T. R. 1951. Air Flow through Conventional Window
Openings. RR-33, College Station, TX: Texas A&M University, Texas
Engineering Experiment Station.
[8] Givoni, B. 1976. Man, Climate and Architecture, 2nd Edition, London:
Applied Science.
[9] Givoni, B. 1968. Ventilation Problems in Hot Countries. Research
Report to Ford Foundation, Haifa, Israel: Building Research Station,
Israel Institute of Technology.
[10] Chandra, S. 1980. Passive Cooling by Natural Ventilation Principles
and Design Implications. Passive Cooling Applications Handbook,
Prepared for the Passive Cooling Workshop Amherst, Massachusetts.
[11] Sobin, H. J. 1981. Window Design for Passive Ventilating Cooling an
Experiment Model Scale Study. In Proc. International Passive and
Hybrid Cooling Conference. Miami Beach, FL. Boulder, CO: AS/ISES,
pp. 191-195.
[12] Aynsley, R. M., Melbourne, W. and Vickery, B. J. 1977. Architectural
Aerodynamics. London: Applied Science Publishers.
[13] Van Straaten, J. F., 1967. Thermal Performance Of Buildings.
Amsterdam: Elsevier.
[14] Nielsen, 1974. Ph.D. Thesis, Technical University of Denmark.
[15] Ishizu, Y. and Kaneki, K. 1984. Evaluation of Ventilation Systems
Through Numerical Computation and Presentation of a New Ventilation
Model. Trans. SHASE 24:47 57.
[16] White, R. F. 1954. Effects of Landscape Development on the Natural
Ventilation on Buildings and Their Adjacent Areas. RR-45, College
Station, TX: Texas A&M University, Texas Engineering Experiment
Station.
[17] Evans, B. H. 1979. Energy Conservation with Natural Airflow Through
Windows. ASHRAE Transactions, 852:641 650.
[18] Sobin, H. J. 1980. Window Design for Passive Ventilative Cooling: An
Experimental Study. Passive Cooling Applications Handbook, Prepared
for the Passive Cooling Workshop Amherst, Massachusetts.
[19] Givoni, B. 1962. Basic Study of Ventilation Problems in Housing in Hot
Countries, Final Report, Building Research Station, Technion - Israel
Institute of Technology, Haifa.
[20] Sobin, H. J. 1980. Window Design for Passive Ventilative Cooling: An
Experimental Study. Passive Cooling Applications Handbook, Prepared
for the Passive Cooling Workshop Amherst, Massachusetts.
[1] Warren, P. R., and Parkins, L. M. 1984. Single Sided Ventilation
Through Open Windows. In Proc. Windows in Building Design and
Maintenance. Jitterbug, Sweden. p.487.
[2] Evans, B. H. 1979. Energy Conservation with Natural Airflow Through
Windows. ASHRAE Transactions, 852:641 650.
[3] Reed, R. H. 1953. Design for Natural Ventilation in Hot Humid
Weather--Reprint from Housing and Building in Hot Humid and Hot
Dry Climates. Washington, D.C.: Building Research Institute, National
Academy of Sciences, National Research Council.
[4] Bowen, A. 1981. Classification of Air Motion Systems and Patterns.
Proceeding of the International Passive and Hybrid Cooling Conference.
American Section of the International Solar Energy Society. Miami
Beach. p. 743-763.
[5] Bahadori, M. 1988. A Passive Cooling System for Hot Arid Regions.
13th National Passive Solar Conference. Cambridge, USA, pp 364-367.
[6] Fleury, B. 1990. Ventilative Cooling: State of the Art. Workshop on
Passive Cooling. Ispra, 2-4 April.
[7] Holleman, T. R. 1951. Air Flow through Conventional Window
Openings. RR-33, College Station, TX: Texas A&M University, Texas
Engineering Experiment Station.
[8] Givoni, B. 1976. Man, Climate and Architecture, 2nd Edition, London:
Applied Science.
[9] Givoni, B. 1968. Ventilation Problems in Hot Countries. Research
Report to Ford Foundation, Haifa, Israel: Building Research Station,
Israel Institute of Technology.
[10] Chandra, S. 1980. Passive Cooling by Natural Ventilation Principles
and Design Implications. Passive Cooling Applications Handbook,
Prepared for the Passive Cooling Workshop Amherst, Massachusetts.
[11] Sobin, H. J. 1981. Window Design for Passive Ventilating Cooling an
Experiment Model Scale Study. In Proc. International Passive and
Hybrid Cooling Conference. Miami Beach, FL. Boulder, CO: AS/ISES,
pp. 191-195.
[12] Aynsley, R. M., Melbourne, W. and Vickery, B. J. 1977. Architectural
Aerodynamics. London: Applied Science Publishers.
[13] Van Straaten, J. F., 1967. Thermal Performance Of Buildings.
Amsterdam: Elsevier.
[14] Nielsen, 1974. Ph.D. Thesis, Technical University of Denmark.
[15] Ishizu, Y. and Kaneki, K. 1984. Evaluation of Ventilation Systems
Through Numerical Computation and Presentation of a New Ventilation
Model. Trans. SHASE 24:47 57.
[16] White, R. F. 1954. Effects of Landscape Development on the Natural
Ventilation on Buildings and Their Adjacent Areas. RR-45, College
Station, TX: Texas A&M University, Texas Engineering Experiment
Station.
[17] Evans, B. H. 1979. Energy Conservation with Natural Airflow Through
Windows. ASHRAE Transactions, 852:641 650.
[18] Sobin, H. J. 1980. Window Design for Passive Ventilative Cooling: An
Experimental Study. Passive Cooling Applications Handbook, Prepared
for the Passive Cooling Workshop Amherst, Massachusetts.
[19] Givoni, B. 1962. Basic Study of Ventilation Problems in Housing in Hot
Countries, Final Report, Building Research Station, Technion - Israel
Institute of Technology, Haifa.
[20] Sobin, H. J. 1980. Window Design for Passive Ventilative Cooling: An
Experimental Study. Passive Cooling Applications Handbook, Prepared
for the Passive Cooling Workshop Amherst, Massachusetts.
@article{"International Journal of Architectural, Civil and Construction Sciences:58857", author = "Zahra Ghiabaklou", title = "Natural Ventilation as a Design Strategy for Energy Saving", abstract = "Ventilation is a fundamental requirement for
occupant health and indoor air quality in buildings. Natural
ventilation can be used as a design strategy in free-running
buildings to:
• Renew indoor air with fresh outside air and lower room
temperatures at times when the outdoor air is cooler.
• Promote air flow to cool down the building structure
(structural cooling).
• Promote occupant physiological cooling processes
(comfort cooling).
This paper focuses on ways in which ventilation can
provide the mechanism for heat dissipation and cooling of the
building structure..It also discusses use of ventilation as a
means of increasing air movement to improve comfort when
indoor air temperatures are too high. The main influencing
factors and design considerations and quantitative guidelines
to help meet the design objectives are also discussed.", keywords = "Natural Ventilation, Sustainable Building,
Passive Cooling, Energy Saving", volume = "4", number = "11", pages = "363-6", }
