Influence of pre-treatment of straw biomass and additives on the release of nitrogen species during combustion and gasification




Lebendig Florian, Schmid Daniel, Karlström Oskar, Yrjäs Patrik, Müller Michael

PublisherPERGAMON-ELSEVIER SCIENCE LTD

OXFORD

2024

Renewable and Sustainable Energy Reviews

RENEWABLE & SUSTAINABLE ENERGY REVIEWS

RENEW SUST ENERG REV

114033

189

Part B

11

1364-0321

1879-0690

DOIhttps://doi.org/10.1016/j.rser.2023.114033(external)

https://doi.org/10.1016/j.rser.2023.114033(external)



The aim of this study is to investigate how pre-treatment of herbaceous straw biomass for ash control affects the release of nitrogen species during combustion and gasification. To comprehend the formation of NO and its precursors, NH3 and HCN, the release of these species was investigated and compared under both combustion and gasification-like conditions at 950 degrees C. The effects of various upgrading methods, such as torrefaction, water -leaching, a combination of leaching and torrefaction, and CaCO3 addition, were studied. The assessment of ni-trogen release was divided into two consecutive conversion steps - devolatilization/pyrolysis and ash/char re-actions. The release of nitrogen is highly dependent on the reaction conditions. For instance, the emissions of NO from the combustion conditions (3 vol% O2) for all fuel samples were, on average, six times higher than under gasification conditions (14.5 vol% H2O and 5 vol% CO2). The emissions of NO from the combustion and gasi-fication of torrefied biomass were, on average, 20 % higher than those from raw biomass. Water-leaching had a suppressing effect on NO formation during char conversion. Approximately 62 % of the char-N formed NO for raw and torrefied material, whereas only 26 %-35 % was formed for pre-or postwashed samples. The effect of the applied pre-treatment approaches on the release of nitrogen was particularly significant during char con-version. Increasing calcium and decreasing potassium content had catalytic effects, mainly on the conversion of volatile-N to NH3. The Ca-doped biomass feedstock showed approximate 10 % increase in volatile-N to NH3 conversion compared to the source material.



Last updated on 2024-26-11 at 20:45