Design of a Controlled-ventilation Open-top Chamber for Climate Change Research.

Lancaster Environment Centre

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https://doi.org/10.1006/jaer.1996.0069
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Design of a Controlled-ventilation Open-top Chamber for Climate Change Research. / Norris, T. S.; Bailey, B. J.; Lees, M. et al.
In: Journal of Agricultural Engineering Research, Vol. 64, No. 4, 08.1996, p. 279-288.

Research output: Contribution to Journal/Magazine › Journal article

Harvard

Norris, TS, Bailey, BJ, Lees, M & Young, PC 1996, 'Design of a Controlled-ventilation Open-top Chamber for Climate Change Research.', Journal of Agricultural Engineering Research, vol. 64, no. 4, pp. 279-288. https://doi.org/10.1006/jaer.1996.0069

APA

Norris, T. S., Bailey, B. J., Lees, M., & Young, P. C. (1996). Design of a Controlled-ventilation Open-top Chamber for Climate Change Research. Journal of Agricultural Engineering Research, 64(4), 279-288. https://doi.org/10.1006/jaer.1996.0069

Vancouver

Norris TS, Bailey BJ, Lees M, Young PC. Design of a Controlled-ventilation Open-top Chamber for Climate Change Research. Journal of Agricultural Engineering Research. 1996 Aug;64(4):279-288. doi: 10.1006/jaer.1996.0069

Author

Norris, T. S. ; Bailey, B. J. ; Lees, M. et al. / Design of a Controlled-ventilation Open-top Chamber for Climate Change Research. In: Journal of Agricultural Engineering Research. 1996 ; Vol. 64, No. 4. pp. 279-288.

Bibtex

@article{5268d30d6d6c4db59634a8b01269c904,

title = "Design of a Controlled-ventilation Open-top Chamber for Climate Change Research.",

abstract = "An advanced controlled-ventilation, open-top chamber (CVOTC) has been designed which offers considerable advantages over the current continuously-ventilated open-top chambers (OTC), used in climate change impact studies on plants. The CVOTC gives a five-fold reduction in carbon dioxide consumption by recirculating the air when ventilation is not required to control temperature. Full ventilation at six air changes per minute limited the chamber temperature to 2°C above ambient during periods of high solar flux. The average temperature excess was 1·6°C. The air distribution system within the CVOTC provides uniform air speeds above 1 m s-1which produces leaf boundary layer resistances comparable with those of plants in the open. A mean chamber light transmission of 90% in direct sunlight was attained using inexpensive film cladding and by employing a simple chamber frame. These performance improvements derive from the efficient design of the chamber and control of ventilation/recirculation using a novel, scheduled-gain, adaptive control system.",

author = "Norris, {T. S.} and Bailey, {B. J.} and M. Lees and Young, {P. C.}",

year = "1996",

month = aug,

doi = "10.1006/jaer.1996.0069",

language = "English",

volume = "64",

pages = "279--288",

journal = "Journal of Agricultural Engineering Research",

publisher = "Academic Press Inc.",

number = "4",

}

RIS

TY - JOUR

T1 - Design of a Controlled-ventilation Open-top Chamber for Climate Change Research.

AU - Norris, T. S.

AU - Bailey, B. J.

AU - Lees, M.

AU - Young, P. C.

PY - 1996/8

Y1 - 1996/8

N2 - An advanced controlled-ventilation, open-top chamber (CVOTC) has been designed which offers considerable advantages over the current continuously-ventilated open-top chambers (OTC), used in climate change impact studies on plants. The CVOTC gives a five-fold reduction in carbon dioxide consumption by recirculating the air when ventilation is not required to control temperature. Full ventilation at six air changes per minute limited the chamber temperature to 2°C above ambient during periods of high solar flux. The average temperature excess was 1·6°C. The air distribution system within the CVOTC provides uniform air speeds above 1 m s-1which produces leaf boundary layer resistances comparable with those of plants in the open. A mean chamber light transmission of 90% in direct sunlight was attained using inexpensive film cladding and by employing a simple chamber frame. These performance improvements derive from the efficient design of the chamber and control of ventilation/recirculation using a novel, scheduled-gain, adaptive control system.

AB - An advanced controlled-ventilation, open-top chamber (CVOTC) has been designed which offers considerable advantages over the current continuously-ventilated open-top chambers (OTC), used in climate change impact studies on plants. The CVOTC gives a five-fold reduction in carbon dioxide consumption by recirculating the air when ventilation is not required to control temperature. Full ventilation at six air changes per minute limited the chamber temperature to 2°C above ambient during periods of high solar flux. The average temperature excess was 1·6°C. The air distribution system within the CVOTC provides uniform air speeds above 1 m s-1which produces leaf boundary layer resistances comparable with those of plants in the open. A mean chamber light transmission of 90% in direct sunlight was attained using inexpensive film cladding and by employing a simple chamber frame. These performance improvements derive from the efficient design of the chamber and control of ventilation/recirculation using a novel, scheduled-gain, adaptive control system.

U2 - 10.1006/jaer.1996.0069

DO - 10.1006/jaer.1996.0069

M3 - Journal article

VL - 64

SP - 279

EP - 288

JO - Journal of Agricultural Engineering Research

JF - Journal of Agricultural Engineering Research

IS - 4

ER -

Research

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