Wind Turbine Direct-Drive Permanent-Magnet Generator with Direct Liquid Cooling for Mass Reduction
Alexandrova, Yulia (2014-06-25)
Väitöskirja
Alexandrova, Yulia
25.06.2014
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-608-7
https://urn.fi/URN:ISBN:978-952-265-608-7
Tiivistelmä
Today’s electrical machine technology allows increasing the wind turbine output power
by an order of magnitude from the technology that existed only ten years ago. However,
it is sometimes argued that high-power direct-drive wind turbine generators will prove
to be of limited practical importance because of their relatively large size and weight.
The limited space for the generator in a wind turbine application together with the
growing use of wind energy pose a challenge for the design engineers who are trying to
increase torque without making the generator larger.
When it comes to high torque density, the limiting factor in every electrical machine is
heat, and if the electrical machine parts exceed their maximum allowable continuous
operating temperature, even for a short time, they can suffer permanent damage.
Therefore, highly efficient thermal design or cooling methods is needed. One of the
promising solutions to enhance heat transfer performances of high-power, low-speed
electrical machines is the direct cooling of the windings. This doctoral dissertation
proposes a rotor-surface-magnet synchronous generator with a fractional slot nonoverlapping
stator winding made of hollow conductors, through which liquid coolant
can be passed directly during the application of current in order to increase the
convective heat transfer capabilities and reduce the generator mass.
This doctoral dissertation focuses on the electromagnetic design of a liquid-cooled
direct-drive permanent-magnet synchronous generator (LC DD-PMSG) for a directdrive
wind turbine application. The analytical calculation of the magnetic field
distribution is carried out with the ambition of fast and accurate predicting of the main
dimensions of the machine and especially the thickness of the permanent magnets; the
generator electromagnetic parameters as well as the design optimization. The focus is
on the generator design with a fractional slot non-overlapping winding placed into open
stator slots. This is an a priori selection to guarantee easy manufacturing of the LC
winding. A thermal analysis of the LC DD-PMSG based on a lumped parameter thermal model takes place with the ambition of evaluating the generator thermal performance.
The thermal model was adapted to take into account the uneven copper loss distribution
resulting from the skin effect as well as the effect of temperature on the copper winding
resistance and the thermophysical properties of the coolant. The developed lumpedparameter
thermal model and the analytical calculation of the magnetic field distribution
can both be integrated with the presented algorithm to optimize an LC DD-PMSG
design.
Based on an instrumented small prototype with liquid-cooled tooth-coils, the following
targets have been achieved: experimental determination of the performance of the direct
liquid cooling of the stator winding and validating the temperatures predicted by an
analytical thermal model; proving the feasibility of manufacturing the liquid-cooled
tooth-coil winding; moreover, demonstration of the objectives of the project to potential
customers.
by an order of magnitude from the technology that existed only ten years ago. However,
it is sometimes argued that high-power direct-drive wind turbine generators will prove
to be of limited practical importance because of their relatively large size and weight.
The limited space for the generator in a wind turbine application together with the
growing use of wind energy pose a challenge for the design engineers who are trying to
increase torque without making the generator larger.
When it comes to high torque density, the limiting factor in every electrical machine is
heat, and if the electrical machine parts exceed their maximum allowable continuous
operating temperature, even for a short time, they can suffer permanent damage.
Therefore, highly efficient thermal design or cooling methods is needed. One of the
promising solutions to enhance heat transfer performances of high-power, low-speed
electrical machines is the direct cooling of the windings. This doctoral dissertation
proposes a rotor-surface-magnet synchronous generator with a fractional slot nonoverlapping
stator winding made of hollow conductors, through which liquid coolant
can be passed directly during the application of current in order to increase the
convective heat transfer capabilities and reduce the generator mass.
This doctoral dissertation focuses on the electromagnetic design of a liquid-cooled
direct-drive permanent-magnet synchronous generator (LC DD-PMSG) for a directdrive
wind turbine application. The analytical calculation of the magnetic field
distribution is carried out with the ambition of fast and accurate predicting of the main
dimensions of the machine and especially the thickness of the permanent magnets; the
generator electromagnetic parameters as well as the design optimization. The focus is
on the generator design with a fractional slot non-overlapping winding placed into open
stator slots. This is an a priori selection to guarantee easy manufacturing of the LC
winding. A thermal analysis of the LC DD-PMSG based on a lumped parameter thermal model takes place with the ambition of evaluating the generator thermal performance.
The thermal model was adapted to take into account the uneven copper loss distribution
resulting from the skin effect as well as the effect of temperature on the copper winding
resistance and the thermophysical properties of the coolant. The developed lumpedparameter
thermal model and the analytical calculation of the magnetic field distribution
can both be integrated with the presented algorithm to optimize an LC DD-PMSG
design.
Based on an instrumented small prototype with liquid-cooled tooth-coils, the following
targets have been achieved: experimental determination of the performance of the direct
liquid cooling of the stator winding and validating the temperatures predicted by an
analytical thermal model; proving the feasibility of manufacturing the liquid-cooled
tooth-coil winding; moreover, demonstration of the objectives of the project to potential
customers.
Kokoelmat
- Väitöskirjat [1099]