Abstract
In this study a new generation of plate-type laboratory air treatment biofilter is applied for the removal of gaseous contaminants
from air. The packing material for the biofilter consists of porous plates arranged vertically one after the other to produce a
capillary humidification effect. The porous plate is made of polymer to secure the stiffness of the plate. Birch fibre granules
thermally treated in a steam explosion reactor are fixed on both sides of the polymer board. The granules are covered with
needle-punched nonwovens. This technology enables to improve the durability of the packing material. During the capillary
effect of humidification of the packing material, moisture (bio-medium) is spontaneously rising together with the humidification
of the wood fibre and needle-punched nonwovens. Therefore, this system of self-humidification does not consume additional
energy, the packing material remains well humidified in case of interruption of technological processes or when power supply is
discontinued for any other reasons.
This paper presents findings of the research into the effectiveness of air treatment and microbiological tests involving air
contaminated with gaseous acetone, xylene and ammonia contaminants passing through the packing material. The results of the
research show high air purification degrees and microbiological activity. The activity of microorganism in the packing material
was 1108 CFU/g on average, while air treatment effectiveness was around 91%. It was established that, with the packing
material of the aforementioned composition, microorganisms are able to use such combinations as acetone, xylene and ammonia
for their metabolism. Bacteria and micromycetes (fungi) were found to be most dominant in the process of destruction of
contaminants. Pseudomonas, Arthrobacter, Acinetobacter, Bacillus were the genera most frequently identified during the
research tests.