A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Simplified modeling of displacement ventilation systems with chilled ceilings
https://orcid.org/0000-0002-9332-4009
Graphical abstract
Highlights Simplified three-node model for CC/DV. The model is validated using twelve different experimental studies. Model average temperature error of 0.2K. Can predict disruption of the thermal stratification and condensation in the CC surface.
Abstract Displacement ventilation (DV) flows are more complex than conventional overhead mixing systems since the stratified room environment cannot be modeled using the traditional fully mixed room air approach. A successful DV designer must be able to control the vertical room temperature profile and manage the position of the lower boundary of the upper air layer that contains heat and pollutants. The inclusion of a chilled ceiling (CC) in the DV system increases the complexity by adding the need to manage the CC cooling power so that it does not disrupt the DV stratification. This paper presents the extension of an existing DV nodal model so that the effects of the CC in room airflow and air temperatures can be predicted. The model uses three air nodes and focuses on the thermal plumes as the drivers of the airflow and room air heat exchange. The proposed model is validated using twelve different test chamber configurations from three independent experimental studies. When compared with existing models the proposed model achieves improved precision and model flexibility while using less air nodes. The last section of the paper presents a set of CC/DV design charts that can assist system designers in early design phases.
Simplified modeling of displacement ventilation systems with chilled ceilings
https://orcid.org/0000-0002-9332-4009
Graphical abstract
Highlights Simplified three-node model for CC/DV. The model is validated using twelve different experimental studies. Model average temperature error of 0.2K. Can predict disruption of the thermal stratification and condensation in the CC surface.
Abstract Displacement ventilation (DV) flows are more complex than conventional overhead mixing systems since the stratified room environment cannot be modeled using the traditional fully mixed room air approach. A successful DV designer must be able to control the vertical room temperature profile and manage the position of the lower boundary of the upper air layer that contains heat and pollutants. The inclusion of a chilled ceiling (CC) in the DV system increases the complexity by adding the need to manage the CC cooling power so that it does not disrupt the DV stratification. This paper presents the extension of an existing DV nodal model so that the effects of the CC in room airflow and air temperatures can be predicted. The model uses three air nodes and focuses on the thermal plumes as the drivers of the airflow and room air heat exchange. The proposed model is validated using twelve different test chamber configurations from three independent experimental studies. When compared with existing models the proposed model achieves improved precision and model flexibility while using less air nodes. The last section of the paper presents a set of CC/DV design charts that can assist system designers in early design phases.
Simplified modeling of displacement ventilation systems with chilled ceilings
https://orcid.org/0000-0002-9332-4009
Graphical abstract
Highlights Simplified three-node model for CC/DV. The model is validated using twelve different experimental studies. Model average temperature error of 0.2K. Can predict disruption of the thermal stratification and condensation in the CC surface.
Abstract Displacement ventilation (DV) flows are more complex than conventional overhead mixing systems since the stratified room environment cannot be modeled using the traditional fully mixed room air approach. A successful DV designer must be able to control the vertical room temperature profile and manage the position of the lower boundary of the upper air layer that contains heat and pollutants. The inclusion of a chilled ceiling (CC) in the DV system increases the complexity by adding the need to manage the CC cooling power so that it does not disrupt the DV stratification. This paper presents the extension of an existing DV nodal model so that the effects of the CC in room airflow and air temperatures can be predicted. The model uses three air nodes and focuses on the thermal plumes as the drivers of the airflow and room air heat exchange. The proposed model is validated using twelve different test chamber configurations from three independent experimental studies. When compared with existing models the proposed model achieves improved precision and model flexibility while using less air nodes. The last section of the paper presents a set of CC/DV design charts that can assist system designers in early design phases.
Simplified modeling of displacement ventilation systems with chilled ceilings
Mateus, Nuno M. (author) / Graça, Guilherme Carrilho da (author)
Energy and Buildings ; 108 ; 44-54
2015-08-30
11 pages
Article (Journal)
Electronic Resource
English
Simplified modeling of displacement ventilation systems with chilled ceilings
| Online Contents | 2015
Chilled ceilings and displacement ventilation - do they work?
| British Library Conference Proceedings | 1998
| Online Contents | 1994
Online Contents | 1995
| British Library Online Contents | 1995