Presentation is loading. Please wait.

Presentation is loading. Please wait.

Superconducting Generators for Large Wind Turbines Ozan Keysan Institute for Energy Systems The University of Edinburgh 26/09/2012.

Published byBrittany Parks Modified over 9 years ago

Similar presentations

Presentation on theme: "Superconducting Generators for Large Wind Turbines Ozan Keysan Institute for Energy Systems The University of Edinburgh 26/09/2012."— Presentation transcript:

1 Superconducting Generators for Large Wind Turbines Ozan Keysan o.keysan@ed.ac.uk Institute for Energy Systems The University of Edinburgh 26/09/2012

2 Motivation BARD 5MW Global Offshore Wind Energy Markets and Strategies,2009 In 2020, 85% of offshore wind turbine installations will be larger than 5 MW

3 Wind Turbines: Constantly Growing  How big?  UpWind Project: A 20 MW Wind Turbine is Feasible www.upwind.eu

4 Superconducting Machines Courtesy of Siemens, Converteam (ALSTOM)  Siemens: 400 kW  Converteam (ALSTOM): 5 MW HTS

5 Power Applications : Electrical Machines  36.5 MW, 120 rpm (U.S. Navy, AMSC) Courtesy of AMSC

6 Mass of Direct-Drive Generators Harakosan 1.5MW,18 rpm,47 tonnes (*) D. Bang et.al. “Review of Generator Systems for Direct-Drive Wind Turbines,” 2008, All data available at goo.gl/ZZivv goo.gl/ZZivv Enercon 4.5 MW, 13 rpm 220 tonnes

7 All data available at goo.gl/ZZivv goo.gl/ZZivv Mass of Direct-Drive Generators

8 Reliability of Wind Turbines Hahn, B., & Durstewitz, M. (2007). Wind Energy-Reliability of Wind Turbines. ~1MW, 1500 onshore turbines

9 Reliability?  Cooling System  Cryogenic Couplers  Electric Brushes  Transient torques on SC  Demagnetization for Bulk SC  AC losses on SC wire Issues with Superconducting Generators SeaTitan AMSC, 10 MW, 10 rpm Direct-drive superconducting generator

10 Transverse Flux HTSG

11  Pros  Single Stationary SC Coil  No Brushes  No Cryogenic Coupler  Bidirectional flux  High Torque Density  Cons  Magnetic Attraction Forces  3D Flux (Soft magnetic composites needed) Transverse Flux HTSG

12 Linear Prototype

13 Some Photos & A Short Video

14 Next Stage  A Superconducting Field Winding  Simple Insulation  LN2 bath  Design for Large Wind Turbine  10 MW 10 rpm  Mass/Cost Estimation

15 THANKS

Download ppt "Superconducting Generators for Large Wind Turbines Ozan Keysan Institute for Energy Systems The University of Edinburgh 26/09/2012."

Similar presentations

Approved for public release; distribution is unlimited

Approved for public release; distribution is unlimited
Introduction to Electrical Machines

Introduction to Electrical Machines
High-Temperature Superconducting Generators for Direct Drive Applications OZAN KEYSAN Institute for Energy Systems The University of.

High-Temperature Superconducting Generators for Direct Drive Applications OZAN KEYSAN Institute for Energy Systems The University of.
High-Temperature Superconducting Generators for Direct Drive Applications OZAN KEYSAN Institute for Energy Systems The University of.

High-Temperature Superconducting Generators for Direct Drive Applications OZAN KEYSAN Institute for Energy Systems The University of.
ELECTRICAL POWER AC MOTOR & DC MOTOR.

ELECTRICAL POWER AC MOTOR & DC MOTOR.
The Direct Current (DC) Electric Motor

The Direct Current (DC) Electric Motor
Wind Turbine Session 4.

Wind Turbine Session 4.
Wind Energy Wind power is the conversion of wind energy into a useful form of energy, such as using wind turbines to make electricity, wind mills for mechanical.

Wind Energy Wind power is the conversion of wind energy into a useful form of energy, such as using wind turbines to make electricity, wind mills for mechanical.
Alasdair McDonald & Markus Mueller Edinburgh University

Alasdair McDonald & Markus Mueller Edinburgh University
Superconducting direct drive generators for large offshore wind turbines Asger B. Abrahamsen 1, Bogi Bech Jensen 2 and Henk Polinder 3 1 Department of.

Superconducting direct drive generators for large offshore wind turbines Asger B. Abrahamsen 1, Bogi Bech Jensen 2 and Henk Polinder 3 1 Department of.
1 1 Permanent magnet (PM) DC motors Armature Permanent Magnets Brushes Commutator Coils.

1 1 Permanent magnet (PM) DC motors Armature Permanent Magnets Brushes Commutator Coils.
SYNCHRONOUS MACHINES SUBMITTED BY: Ms. APOORVA KANTHWAL

SYNCHRONOUS MACHINES SUBMITTED BY: Ms. APOORVA KANTHWAL
® A MAGNETICALLY-GEARED COMPACT 3MW DIRECT DRIVE GENERATOR EWEC 2010.

® A MAGNETICALLY-GEARED COMPACT 3MW DIRECT DRIVE GENERATOR EWEC 2010.
Superconducting Generators for Large Wind Turbine: Design Trade-Off and Challenges Philippe J. Masson Advanced Magnet Lab Palm Bay, FL SOWiT, Rome,

Superconducting Generators for Large Wind Turbine: Design Trade-Off and Challenges Philippe J. Masson Advanced Magnet Lab Palm Bay, FL SOWiT, Rome,
Overview of different wind generator systems and their comparisons 2-4~2-7 陳昱希.

Overview of different wind generator systems and their comparisons 2-4~2-7 陳昱希.
Electrical Power Generation. How Does an Electric Generator Work? Rotating turbine attached to an electrical generator, a wire coil. Free electrons moving.

Electrical Power Generation. How Does an Electric Generator Work? Rotating turbine attached to an electrical generator, a wire coil. Free electrons moving.
Generators VS Alternators Tech Topic Presentation Mandi Fournier.

Generators VS Alternators Tech Topic Presentation Mandi Fournier.
Electricity How is it made?.

Electricity How is it made?.
Lesson 33 AC Generators.

Lesson 33 AC Generators.
ECE 4411 Introduction to DC Machines Advantages –Adjustable speed –Develop rated torque at all speeds –Higher torque than an equivalent AC machine Uses.

ECE 4411 Introduction to DC Machines Advantages –Adjustable speed –Develop rated torque at all speeds –Higher torque than an equivalent AC machine Uses.

Similar presentations

Ads by Google