Three-dimensional modeling of biomass fuel flow in a circulating fluidized bed furnace
Nikku, Markku (2015-06-25)
Väitöskirja
Nikku, Markku
25.06.2015
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-810-4
https://urn.fi/URN:ISBN:978-952-265-810-4
Tiivistelmä
The reduction of greenhouse gas emissions in the European Union promotes the
combustion of biomass rather than fossil fuels in energy production. Circulating fluidized
bed (CFB) combustion offers a simple, flexible and efficient way to utilize untreated
biomass in a large scale. CFB furnaces are modeled in order to understand their operation
better and to help in the design of new furnaces. Therefore, physically accurate models
are needed to describe the heavily coupled multiphase flow, reactions and heat transfer
inside the furnace.
This thesis presents a new model for the fuel flow inside the CFB furnace, which
acknowledges the physical properties of the fuel and the multiphase flow phenomena
inside the furnace. This model is applied with special interest in the firing of untreated
biomass. An experimental method is utilized to characterize gas-fuel drag force relations.
This characteristic drag force approach is developed into a gas-fuel drag force model
suitable for irregular, non-spherical biomass particles and applied together with the new
fuel flow model in the modeling of a large-scale CFB furnace. The model results are
physically valid and achieve very good correspondence with the measurement results
from large-scale CFB furnace firing biomass.
With the methods and models presented in this work, the fuel flow field inside a
circulating fluidized bed furnace can be modeled with better accuracy and more
efficiently than in previous studies with a three-dimensional holistic model frame.
combustion of biomass rather than fossil fuels in energy production. Circulating fluidized
bed (CFB) combustion offers a simple, flexible and efficient way to utilize untreated
biomass in a large scale. CFB furnaces are modeled in order to understand their operation
better and to help in the design of new furnaces. Therefore, physically accurate models
are needed to describe the heavily coupled multiphase flow, reactions and heat transfer
inside the furnace.
This thesis presents a new model for the fuel flow inside the CFB furnace, which
acknowledges the physical properties of the fuel and the multiphase flow phenomena
inside the furnace. This model is applied with special interest in the firing of untreated
biomass. An experimental method is utilized to characterize gas-fuel drag force relations.
This characteristic drag force approach is developed into a gas-fuel drag force model
suitable for irregular, non-spherical biomass particles and applied together with the new
fuel flow model in the modeling of a large-scale CFB furnace. The model results are
physically valid and achieve very good correspondence with the measurement results
from large-scale CFB furnace firing biomass.
With the methods and models presented in this work, the fuel flow field inside a
circulating fluidized bed furnace can be modeled with better accuracy and more
efficiently than in previous studies with a three-dimensional holistic model frame.
Kokoelmat
- Väitöskirjat [1070]