Experimental Study of Thermal Buoyancy in the Cavity of Ventilated Roofs
Journal article, 2020

Pitched wooden roofs are ventilated through an air cavity beneath the roofing in order to remove heat and moisture from the roof construction. The ventilation is driven by wind pressure and thermal buoyancy.
This paper studies ventilation driven by thermal buoyancy in the air cavity of inclined roofs. The influence of air cavity design and roof inclination on the airflow is investigated. Laboratory measurements were carried out on an inclined full-scale roof model with an air cavity heated on one side in order to simulate solar radiation on a roof surface. Equipment to measure temperature was installed in the roof model, while air velocity in the cavity was
determined by smoke tests. Combinations of different roof inclinations, air cavity heights and applied heating power on the air cavity top surface were examined.
The study showed that increased air cavity height led to increased airflow and decreased surface temperatures in the air cavity. Increased roof inclination and heating power applied to the roofing also increased the airflow. The investigations imply that thermal buoyancy in the air cavity of pitched roofs could be a relevant driving force for cavity ventilation and important to consider when evaluating the heat and moisture performance of such a construction.

wood construction

air cavity

natural ventilation

pitched roof

thermal buoyancy

Author

[Person be0bd5fd-89c6-4b2e-a3f1-84ad0cbc010b not found]

SINTEF

[Person 41b96634-909e-4cb3-bb20-9900bb672c95 not found]

Chalmers, Architecture and Civil Engineering, Building Technology

[Person 68e17019-ad2d-4761-badc-373af00c5de5 not found]

Chalmers, Architecture and Civil Engineering, Building Technology

[Person 65026aac-8740-42f8-9a7e-8bcc1cf69fd5 not found]

Norwegian University of Science and Technology (NTNU)

[Person 436d3d15-5297-462c-9d8f-67d11685b779 not found]

SINTEF

[Person cd5976a4-c70b-4f7f-9fdb-b9bd0978b9d6 not found]

Chalmers, Architecture and Civil Engineering, Building Technology

[Person 391a36a7-18e8-4a10-aa8d-9ac62a016048 not found]

Norwegian University of Science and Technology (NTNU)

Buildings

20755309 (eISSN)

Vol. 10 1 8

Driving Forces

Sustainable development

Areas of Advance

Building Futures (2010-2018)

Subject Categories

Energy Engineering

Other Civil Engineering

Building Technologies

DOI

10.3390/buildings10010008

More information

Latest update

8/4/2020 1