Lightweight, liquid-cooled, direct-drive generator for highpower wind turbines: motivation, concept, and performance
Semken, R Scott (2015-03-06)
Väitöskirja
Semken, R Scott
06.03.2015
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-752-7
https://urn.fi/URN:ISBN:978-952-265-752-7
Tiivistelmä
Thesis: A liquid-cooled, direct-drive, permanent-magnet, synchronous generator with
helical, double-layer, non-overlapping windings formed from a copper conductor with a
coaxial internal coolant conduit offers an excellent combination of attributes to reliably
provide economic wind power for the coming generation of wind turbines with power
ratings between 5 and 20MW. A generator based on the liquid-cooled architecture
proposed here will be reliable and cost effective. Its smaller size and mass will reduce
build, transport, and installation costs.
Summary: Converting wind energy into electricity and transmitting it to an electrical
power grid to supply consumers is a relatively new and rapidly developing method of
electricity generation. In the most recent decade, the increase in wind energy’s share of
overall energy production has been remarkable. Thousands of land-based and offshore
wind turbines have been commissioned around the globe, and thousands more are being
planned. The technologies have evolved rapidly and are continuing to evolve, and wind
turbine sizes and power ratings are continually increasing.
Many of the newer wind turbine designs feature drivetrains based on Direct-Drive,
Permanent-Magnet, Synchronous Generators (DD-PMSGs). Being low-speed high-torque
machines, the diameters of air-cooled DD-PMSGs become very large to generate higher
levels of power. The largest direct-drive wind turbine generator in operation today, rated
just below 8MW, is 12m in diameter and approximately 220 tonne. To generate higher
powers, traditional DD-PMSGs would need to become extraordinarily large. A 15MW air-cooled direct-drive generator would be of colossal size and tremendous mass and no
longer economically viable.
One alternative to increasing diameter is instead to increase torque density. In a permanent
magnet machine, this is best done by increasing the linear current density of the stator
windings. However, greater linear current density results in more Joule heating, and the
additional heat cannot be removed practically using a traditional air-cooling approach.
Direct liquid cooling is more effective, and when applied directly to the stator windings,
higher linear current densities can be sustained leading to substantial increases in torque
density. The higher torque density, in turn, makes possible significant reductions in
DD-PMSG size.
Over the past five years, a multidisciplinary team of researchers has applied a holistic
approach to explore the application of liquid cooling to permanent-magnet wind turbine
generator design. The approach has considered wind energy markets and the economics
of wind power, system reliability, electromagnetic behaviors and design, thermal design
and performance, mechanical architecture and behaviors, and the performance modeling
of installed wind turbines.
This dissertation is based on seven publications that chronicle the work. The primary
outcomes are the proposal of a novel generator architecture, a multidisciplinary set of
analyses to predict the behaviors, and experimentation to demonstrate some of the key
principles and validate the analyses. The proposed generator concept is a direct-drive,
surface-magnet, synchronous generator with fractional-slot, duplex-helical, double-layer,
non-overlapping windings formed from a copper conductor with a coaxial internal coolant
conduit to accommodate liquid coolant flow. The novel liquid-cooling architecture is
referred to as LC DD-PMSG.
The first of the seven publications summarized in this dissertation discusses the technological
and economic benefits and limitations of DD-PMSGs as applied to wind energy. The
second publication addresses the long-term reliability of the proposed LC DD-PMSG
design. Publication 3 examines the machine’s electromagnetic design, and Publication 4
introduces an optimization tool developed to quickly define basic machine parameters.
The static and harmonic behaviors of the stator and rotor wheel structures are the subject
of Publication 5. And finally, Publications 6 and 7 examine steady-state and transient
thermal behaviors. There have been a number of ancillary concrete outcomes associated with the work
including the following.
X Intellectual Property (IP) for direct liquid cooling of stator windings via an embedded
coaxial coolant conduit, IP for a lightweight wheel structure for lowspeed,
high-torque electrical machinery, and IP for numerous other details of the
LC DD-PMSG design
X Analytical demonstrations of the equivalent reliability of the LC DD-PMSG;
validated electromagnetic, thermal, structural, and dynamic prediction models;
and an analytical demonstration of the superior partial load efficiency and annual
energy output of an LC DD-PMSG design
X A set of LC DD-PMSG design guidelines and an analytical tool to establish optimal
geometries quickly and early on
X Proposed 8 MW LC DD-PMSG concepts for both inner and outer rotor configurations
Furthermore, three technologies introduced could be relevant across a broader spectrum
of applications. 1) The cost optimization methodology developed as part of this work
could be further improved to produce a simple tool to establish base geometries for
various electromagnetic machine types. 2) The layered sheet-steel element construction
technology used for the LC DD-PMSG stator and rotor wheel structures has potential for
a wide range of applications. And finally, 3) the direct liquid-cooling technology could
be beneficial in higher speed electromotive applications such as vehicular electric drives.
helical, double-layer, non-overlapping windings formed from a copper conductor with a
coaxial internal coolant conduit offers an excellent combination of attributes to reliably
provide economic wind power for the coming generation of wind turbines with power
ratings between 5 and 20MW. A generator based on the liquid-cooled architecture
proposed here will be reliable and cost effective. Its smaller size and mass will reduce
build, transport, and installation costs.
Summary: Converting wind energy into electricity and transmitting it to an electrical
power grid to supply consumers is a relatively new and rapidly developing method of
electricity generation. In the most recent decade, the increase in wind energy’s share of
overall energy production has been remarkable. Thousands of land-based and offshore
wind turbines have been commissioned around the globe, and thousands more are being
planned. The technologies have evolved rapidly and are continuing to evolve, and wind
turbine sizes and power ratings are continually increasing.
Many of the newer wind turbine designs feature drivetrains based on Direct-Drive,
Permanent-Magnet, Synchronous Generators (DD-PMSGs). Being low-speed high-torque
machines, the diameters of air-cooled DD-PMSGs become very large to generate higher
levels of power. The largest direct-drive wind turbine generator in operation today, rated
just below 8MW, is 12m in diameter and approximately 220 tonne. To generate higher
powers, traditional DD-PMSGs would need to become extraordinarily large. A 15MW air-cooled direct-drive generator would be of colossal size and tremendous mass and no
longer economically viable.
One alternative to increasing diameter is instead to increase torque density. In a permanent
magnet machine, this is best done by increasing the linear current density of the stator
windings. However, greater linear current density results in more Joule heating, and the
additional heat cannot be removed practically using a traditional air-cooling approach.
Direct liquid cooling is more effective, and when applied directly to the stator windings,
higher linear current densities can be sustained leading to substantial increases in torque
density. The higher torque density, in turn, makes possible significant reductions in
DD-PMSG size.
Over the past five years, a multidisciplinary team of researchers has applied a holistic
approach to explore the application of liquid cooling to permanent-magnet wind turbine
generator design. The approach has considered wind energy markets and the economics
of wind power, system reliability, electromagnetic behaviors and design, thermal design
and performance, mechanical architecture and behaviors, and the performance modeling
of installed wind turbines.
This dissertation is based on seven publications that chronicle the work. The primary
outcomes are the proposal of a novel generator architecture, a multidisciplinary set of
analyses to predict the behaviors, and experimentation to demonstrate some of the key
principles and validate the analyses. The proposed generator concept is a direct-drive,
surface-magnet, synchronous generator with fractional-slot, duplex-helical, double-layer,
non-overlapping windings formed from a copper conductor with a coaxial internal coolant
conduit to accommodate liquid coolant flow. The novel liquid-cooling architecture is
referred to as LC DD-PMSG.
The first of the seven publications summarized in this dissertation discusses the technological
and economic benefits and limitations of DD-PMSGs as applied to wind energy. The
second publication addresses the long-term reliability of the proposed LC DD-PMSG
design. Publication 3 examines the machine’s electromagnetic design, and Publication 4
introduces an optimization tool developed to quickly define basic machine parameters.
The static and harmonic behaviors of the stator and rotor wheel structures are the subject
of Publication 5. And finally, Publications 6 and 7 examine steady-state and transient
thermal behaviors. There have been a number of ancillary concrete outcomes associated with the work
including the following.
X Intellectual Property (IP) for direct liquid cooling of stator windings via an embedded
coaxial coolant conduit, IP for a lightweight wheel structure for lowspeed,
high-torque electrical machinery, and IP for numerous other details of the
LC DD-PMSG design
X Analytical demonstrations of the equivalent reliability of the LC DD-PMSG;
validated electromagnetic, thermal, structural, and dynamic prediction models;
and an analytical demonstration of the superior partial load efficiency and annual
energy output of an LC DD-PMSG design
X A set of LC DD-PMSG design guidelines and an analytical tool to establish optimal
geometries quickly and early on
X Proposed 8 MW LC DD-PMSG concepts for both inner and outer rotor configurations
Furthermore, three technologies introduced could be relevant across a broader spectrum
of applications. 1) The cost optimization methodology developed as part of this work
could be further improved to produce a simple tool to establish base geometries for
various electromagnetic machine types. 2) The layered sheet-steel element construction
technology used for the LC DD-PMSG stator and rotor wheel structures has potential for
a wide range of applications. And finally, 3) the direct liquid-cooling technology could
be beneficial in higher speed electromotive applications such as vehicular electric drives.
Kokoelmat
- Väitöskirjat [1099]