Working fluid selection and design of small-scale waste heat recovery systems based on organic Rankine cycles
Uusitalo, Antti (2014-12-10)
Väitöskirja
Uusitalo, Antti
10.12.2014
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-711-4
https://urn.fi/URN:ISBN:978-952-265-711-4
Tiivistelmä
Demand for the use of energy systems, entailing high efficiency as well as availability to
harness renewable energy sources, is a key issue in order to tackling the threat of global
warming and saving natural resources. Organic Rankine cycle (ORC) technology has
been identified as one of the most promising technologies in recovering low-grade heat
sources and in harnessing renewable energy sources that cannot be efficiently utilized by
means of more conventional power systems. The ORC is based on the working principle
of Rankine process, but an organic working fluid is adopted in the cycle instead of steam.
This thesis presents numerical and experimental results of the study on the design of
small-scale ORCs. Two main applications were selected for the thesis: waste heat re-
covery from small-scale diesel engines concentrating on the utilization of the exhaust gas
heat and waste heat recovery in large industrial-scale engine power plants considering
the utilization of both the high and low temperature heat sources. The main objective
of this work was to identify suitable working fluid candidates and to study the process
and turbine design methods that can be applied when power plants based on the use of
non-conventional working fluids are considered. The computational work included the
use of thermodynamic analysis methods and turbine design methods that were based on
the use of highly accurate fluid properties. In addition, the design and loss mechanisms in
supersonic ORC turbines were studied by means of computational fluid dynamics.
The results indicated that the design of ORC is highly influenced by the selection of the
working fluid and cycle operational conditions. The results for the turbine designs in-
dicated that the working fluid selection should not be based only on the thermodynamic
analysis, but requires also considerations on the turbine design. The turbines tend to be
fast rotating, entailing small blade heights at the turbine rotor inlet and highly supersonic
flow in the turbine flow passages, especially when power systems with low power outputs
are designed. The results indicated that the ORC is a potential solution in utilizing waste
heat streams both at high and low temperatures and both in micro and larger scale appli-
cations.
harness renewable energy sources, is a key issue in order to tackling the threat of global
warming and saving natural resources. Organic Rankine cycle (ORC) technology has
been identified as one of the most promising technologies in recovering low-grade heat
sources and in harnessing renewable energy sources that cannot be efficiently utilized by
means of more conventional power systems. The ORC is based on the working principle
of Rankine process, but an organic working fluid is adopted in the cycle instead of steam.
This thesis presents numerical and experimental results of the study on the design of
small-scale ORCs. Two main applications were selected for the thesis: waste heat re-
covery from small-scale diesel engines concentrating on the utilization of the exhaust gas
heat and waste heat recovery in large industrial-scale engine power plants considering
the utilization of both the high and low temperature heat sources. The main objective
of this work was to identify suitable working fluid candidates and to study the process
and turbine design methods that can be applied when power plants based on the use of
non-conventional working fluids are considered. The computational work included the
use of thermodynamic analysis methods and turbine design methods that were based on
the use of highly accurate fluid properties. In addition, the design and loss mechanisms in
supersonic ORC turbines were studied by means of computational fluid dynamics.
The results indicated that the design of ORC is highly influenced by the selection of the
working fluid and cycle operational conditions. The results for the turbine designs in-
dicated that the working fluid selection should not be based only on the thermodynamic
analysis, but requires also considerations on the turbine design. The turbines tend to be
fast rotating, entailing small blade heights at the turbine rotor inlet and highly supersonic
flow in the turbine flow passages, especially when power systems with low power outputs
are designed. The results indicated that the ORC is a potential solution in utilizing waste
heat streams both at high and low temperatures and both in micro and larger scale appli-
cations.
Kokoelmat
- Väitöskirjat [1091]