Design enhancement of an adiabatic LiBr-H2O absorber through a droplet flow optimization
The increase of cooling demands is a widespread phenomenon that poses the problem of identifying new efficient ways to provide the necessary input energy. Waste heat is available in large quantities, and its recovery is a challenging problem. Additionally, small-scale applications are becoming mo...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2019
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/83252 http://hdl.handle.net/10220/47579 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The increase of cooling demands is a widespread phenomenon that poses the
problem of identifying new efficient ways to provide the necessary input energy. Waste
heat is available in large quantities, and its recovery is a challenging problem.
Additionally, small-scale applications are becoming more common in fields such as
electronics and/or automotive. This work aims at providing a solution for the
development of a small-scale waste heat-to-cool conversion system.
To achieve this, a first comparison of the potential conversion systems was
performed. Parameters of efficiency, cost and size were considered both separately and
combined in a comprehensive performance index. From this analysis, the H2O-LiBr
absorption chiller emerged as the most suitable technology for the development of a
small-scale system.
Further investigation of the selected technology identified the absorber as the
most critical component preventing the system downsizing. A critical review of the
current state of the art in the absorber design and operation strategies led to the
proposition of a pin-finned, adiabatic absorber, combined with a droplet flow regime.
In the next phase the proposed design was optimized. Firstly, an analytical
model was developed to accurately describe the geometrical domain of a droplet
forming on a solid surface, a phase which was found to be beneficial to the absorption
process. The model was then validated with experiments and used to optimize the pin
shape.
Secondly, the absorption process was analyzed. An analytical heat and mass
transfer model of the phases of a falling droplet was developed and an experimental
setup, replicating the operation of the absorber, was developed to validate the proposed17
model. The validation process led to the identification of the best pin and distribution
orifice sizes, completing the absorber design optimization.
Finally, the performance improvement of the optimized absorber design was
evaluated with respect to a standard absorption chiller configuration. |
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