The potential health risk of diesel particulate (DP) has
stimulated research into its physical and chemical composition.
Its interaction with unburnt hydrocarbons (UHC) at exhaust
temperatures was studied (i.e. composition and microstructure), at
varying engine conditions. A hot whole exhaust filtration system
was developed to collect DP on Pallflex TX-40 PTFE coated filters
(for minimal artefact formation) down the exhaust of a Ricardo E6/T
IDI diesel engine.
Electron microscopy (SEM and TEM) and a gravimetric BET method
determined particle size, specific surface area (SSA) and pore
character. An in vacuo gravimetric thermal degassing (TD)
apparatus was constructed to extract adsorbed volatiles (filter
extractable sample - FES). The volatile FES was trapped and
analysed by gas chromatography and identified as fuel and oil
derived UHC's. Ultrasonic and soxhlet extraction techniques were
employed for comparison studies.
DP are graphitic carbonaceous aggregates of 30-40nm mean
particle diameter. Structural analysis indicated that slit-shaped
pores (Type II isotherm) were formed between crystallite layers.
Highly adsorbed pore-bound FES fractions were identified (fuel i n
ultramicropores, 0.355-lnm; fuel/oil in supermicropores, 1-2nm),
trapped by overlapping crystallite van der Waal's fields. Engine
load influenced micropore adsorption and DP SSA. High loads with
high combustion temperatures, efficiently pyrolysed fuel, producing
DP with little adsorbed FES and SSA's of 100m² /g. Low loads with
lower in-cylinder temperatures, formed less DP and more fuel
survived, producing soots of low SSA(<20m² /g). Between aggregated
particles, 'ink-bottle' mesopores (2-50nm) were evident (Type IV
isotherm) where fuel FES was weakly adsorbed by temperature
dependent chemical scavenging as exhaust temperature declined ,
reducing SSA and increasing particle size.
Thermal degassing was more efficient than soxhlet or ultrasonic
extraction methods, because the solvent methods failed to penetrate
the smallest pores. TD increased soot SSA, greatest for low load
samples (by 200m²/g) compared to high load samples (by 50m² /g).
TD was highly advantageous for DP extraction and allowed progressive
removal of volatiles.
A modern DI engine showed structurally similar soots, but the
lower DP emissions produced high relative %FES for all engine
conditions giving low SSA's.
The research findings are related to cylinder and environmental
processes for engineers and environmental scientists to improve
control strategies.
Date of Award | 1989 |
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Original language | English |
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Awarding Institution | |
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THE INTERACTION BETWEEN UNBURNT HYDROCARBONS AND SOOT IN DIESEL EXHAUSTS
SEEBOLD, C. R. (Author). 1989
Student thesis: PhD