Coursecode:
wb4304
Coursename: Thermodynamics 3
DUT creditpoints: 2
ECTS creditpoints: 4 |
| Faculty
of Mechanical Engineering and Marine Technology |
| Lecturer(s):
Verkooijen, prof.dr.ir. A.H.M., Infante
Ferreira, dr. ir. C. A. (coordinator) and Buijtenen, prof. ir. J. P. van |
Tel.: 015-2784894 |
Catalog data:
Types of thermodynamic cycles. Processes in thermodynamic cycles. The zeroth, first and
second law of thermodynamics. Energy and energy systems. Evaluation criteria,
efficiencies. Work. Sources of non-adiabatic process pathes. Heat pump. Carnot cycle
versus actual cycle for refrigerating machine or heat pump. Heat sources and heat sinks
with a temperature glide. The reciprocating compressor. Entropy production in the cycle
components and their effect on performance (COP). Application example: a practically
implemented heat pump. Work transfer in rotodynamic machines. The axial-flow turbine. The
axial flow compressor. Radial machines. Performance and performance presentation of
rotodynamic machines. Sizing of rotodynamic machines. |
Course year: 3
Period: 0/4/0/0/0
Hours p/w: 4
Other hours:
Assessment: written
Assessm.period(s): 2,3
(see academic calendar) |
| Prerequisites:
wb1123, wb1224 |
| Follow
up: wb4301A, wb4407, wb4410A
e.a. |
Detailed description of topics:
- Types of thermodynamic
cycles.
- Processes in thermodynamic
cycles. The zeroth and first law of thermodynamics. System boundaries. Types of energy
systems. Energy classification. Energy balance of steady-flow open system. Closed cycles.
Evaluation criteria and efficiencies.
- Second law of thermodynamics.
Work transfer in reversible adiabatic processes. Work transfer in non-adiabatic processes
without mechanical friction. Work transfer in adiabatic expansion processes with
mechanical friction in steady-flow heat engines. Work transfer in compression processes.
Several sources of non-adiabatic process pathes.
- Heat pump as an example of heat
engine. Refrigerating machine versus heat pump. The Carnot cycle as a reference cycle for
the refrigerating machine and the heat pump. Heat sources and heat sinks with a
temperature glide. Thermodynamic averaged heat source and heat sink temperatures. Actual
cycle for refrigerating machine or heat pump. The reciprocating compressor as example of
non-ideal compressor. Entropy production in the cycle components and their effect on
performance (COP). Application example: a practically implemented heat pump.
- Rotodynamic machines. Energy
conversion in rotodynamic machines. The axial-flow turbine: working principle; calculation
of a turbine stage; degree of reaction, impulse and reaction turbines. The axial flow
compressor: working principle; calculation of a compressor stage. Radial machines: pumps
and compressors. Performance and performance presentation of rotodynamic machines.
Dimensionless coefficients for rotodynamic machines working with incompressible and
compressible fluids. Performance characteristics. Fixed guide vanes and pre-whirl.
Cavitation phenomena in pumps. Sizing of rotodynamic machines.
|
Course material:
- Van
Paassen, C.A.A., "Processen in thermische machines", collegedictaat, Faculteit
WbMT, TUD, 1994.
- Touber,
S., "Thermische machines -een compressie warmtepomp", collegedictaat, Faculteit
WbMT, TUD, 1996.
- Van
Buijtenen, J.P., "Thermische machines -roterende stromingsmachines",
collegedictaat, Faculteit WbMT, TUD, 1994.
|
| References
from literature: Baehr, H. D., "Thermodynamik", 5e ed., Springer-Verlag, Berlin, 1984.
Brodowicz, K. en T. Dyakowski, "Heat pumps", Butterworth-Heinemann Ltd,
Oxford, 1993.
Dixon, S.L., "Fluid mechanics of turbomachinery", Pergamon Press, Oxford,
1978.
Moran, M.J. en H.N. Shapiro, "Fundamentals of Engineering Thermodynamics",
Wiley, Chichester, 1992.
Traupel, W., "Thermische Turbomaschinen", Springer Verlag, 1977.
|
| Remarks
(specific information about assesment, entry requirements, etc.): |
Goals:
The purpose of this course is to illustrate the practical application to implemented
machines (as a turbine or heat pump) of a part of the theory provided to the students in
the courses "basic heat transfer and fluid mechanics" (wb1123) and
"thermodynamics" (wb1224). The use of the entropy-production concept for the
quantification of the contribution of the different heat pump components to the
irreversibility of the complete system is illustrated. |
| Computer
use: |
| Laboratory
project(s): |
Design
content:
The proposed method for the identification of the components with a large contribution
to the total irreversibility of the system gives a deeper understanding of the
consequences of design choices. Further on dimensional aspects and speed of turbomachines
are related to performance. |
| Percentage
of design: 30% |