Time to ignition for wood covered with ZnO : A laboratory and theoretical study if ZnO can enhance time to ignition for wood exposed to radiation in the cone calorimeter

Sammanfattning: In recent years, interest in sustainability and being environmentally friendly has increased. Wood is a durable and renewable building material, which is becoming more common in the constructions industry. In 2002, the government in Sweden adopted a national strategy to promote an increased use of wood in buildings. However, the usage of wood in construction has a potential risk – wood is ignitable and has fire-spreading properties.  The aim of this project was to investigate whether a ZnO coating can reduce the risk of ignition on wooden surfaces exposed to a radiative heat source, focusing on the time to ignition of the wood. ZnO possess a wide combination of physical properties, such as ability to reflect infrared radiation and being thermally stable at extremely high temperatures. The study has been carried out through a literature review and laboratory experiments. In the laboratory experiments, a cone calorimeter was used and the tests were performed according to ISO 5660-1. In the cone calorimeter, two different amounts of ZnO applied to the wood surface were tested, 0.5 and 1 g ZnO per dm2 and an untreated piece of wood as a reference. The test was carried out in three different heat fluxes: 20, 35 and 50 kWm-2. After completed tests, the change in the wood’s morphology was examined in a scanning electron microscopy (SEM). The result shows that an application of ZnO on a wooden surface significantly increases the time to ignition for the wood. An application of 0.5 g ZnO per dm2increased the time to ignition by 26-33 % for the three different heat fluxes. On the other hand, 1 g of ZnO per dm2 created an increase of 37-40 %. The trend of the increase of time to ignition was similar for all heat fluxes. The result showed no clear tendency that the smoke production rate was reduced with the application of ZnO. The heat release rate was not affected by the addition of ZnO, which was expected because ZnO delays the time to ignition, but once it catches fire, the wood burns. The SEM images before and after combustion showed that there is no change in the morphology of ZnO, although some ZnO has agglomerated but remains intact after combustion. The conclusion of this study is that ZnO has the potential to protect wood from fireby increasing the time to ignition. But when the wood has ignited, there is no clear tendency for ZnO to affect the growth of the fire. The study has shown that in the future ZnO could be applied to a wooden surface to reduce the risk of fire ignition. Further studies are required to find effective methods to implement the usage of ZnO, as applying ZnO on vertical wooden surfaces.