Abstract
In biomass and waste combustion, the release of KCl into the gas phase
results in its deposition on heat exchanger surfaces, enhancing their
stickiness and accelerating deposit buildup from incoming ash particles.
Despite this, the mechanisms governing KCl deposition remain
inadequately explored. KCl has been observed to form either a fine,
powdery layer through thermophoresis of nucleated KCl particles or a
crystal-like, coarse layer through heterogeneous condensation of KCl
vapor. However, the quantitative assessment of coarse and fine layer
formation has never been performed. In this study, an entrained flow
reactor and mechanistic model were employed to analyze KCl deposition
behavior, examining the effect of probe temperature and exposure time.
Quantification of both the coarse and fine deposit layers was
accomplished. Probe temperature was found to have no influence on the
deposition in the range from 300 °C – 595 °C. For coarse layer
formation, the critical factor was the development of a fine layer upon
which the crystal-like structure of the coarse layer grows. Lower probe
temperatures accelerate initial layer formation, initiating the coarse
section sooner. Additionally, it slightly increases nucleation and
condensation, however, nucleation is increased stronger resulting in a
lower ratio of coarse to fine deposit. The quantification of the coarse
mass, in conjunction with the simulation, provides a first estimation of
the critical mass required to initiate heterogeneous condensation on a
steel tube. In this study, a critical mass of 1.26e-3 g/cm2 was determined.
Original language | English |
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Article number | 105604 |
Journal | Proceedings of the Combustion Institute |
Volume | 40 |
Issue number | 1-4 |
Number of pages | 7 |
ISSN | 1540-7489 |
DOIs | |
Publication status | Published - 2024 |
Keywords
- Condensation
- Deposition
- KCl
- Nucleation
- Thermophoresis