Heat transfer modeling in vacuum insulation panels containing nanoporous silicas

Heat transfer modeling in vacuum insulation panels containing nanoporous silicas—A review

Bouquerel, Mathias / Duforestel, Thierry / Baillis, Dominique / Rusaouen, Gilles

Highlights ► A review is conducted on heat transfer modeling in vacuum insulation panels. ► Models used to determine each heat transfer contribution are discussed in detail. ► Each contribution has a simple semi-empirical expression. ► Most sophisticated approaches failed to reproduce experimental values. ► Humidity and pressure increases should be limited to ensure a good service life.

Abstract A vacuum insulation panel (VIP) is a very efficient thermal insulation system for buildings. A porous core material structure is evacuated and wrapped into a gas barrier envelope. Thanks to the low pressure, the total conductivity measured is as low as 5mW/(mK) for best panels, six to ten times lower than conventional insulation materials. Thin insulation systems with very high thermal performance can thus be designed with VIPs. Heat transfer modeling in these panels is complex, resulting on four contributions of heat fluxes: radiative transfer, solid conduction, gaseous transfer, and envelope thermal bridge. These last years, several approaches have been investigated to estimate the contribution of each heat transfer mode. A complete first review on heat transfer modeling in vacuum insulation panels containing nanoporous silicas is conducted. Monolithic aerogel but also granular aerogels and nanoporous powders (pyrogenic and precipitated) are considered in this review. The parameters that play a key role in the total heat transfer are identified. A special emphasis is put to discuss the influence of pressure and humidity on the total conductivity. The results synthesis can be used to set up a design strategy to minimize the thermal conductivity and to understand the main aging mechanisms.