26-29 Nov. 2003 - Superconducting magnetic levitated bearings for rotary machines Superconducting magnetic levitated bearings for rotary machines 5 th.

Slides:



Advertisements
Similar presentations
WHAT IS SUPERCONDUCTIVITY?? For some materials, the resistivity vanishes at some low temperature: they become superconducting. Superconductivity is the.
Advertisements

Superconductivity Michael Spreitzer. Overview „Superconductivity“ ? Who discovered it ? Meissner & Ochsenknecht effect? BCS – Theory Different types of.
Magnetic Properties. Introduction Magnetism arises from the Magnetic Moment or Magnetic dipole of Magnetic Materials. When the electrons revolves around.
Chapter 7 Electrical Properties Hong-Wen Wang. Basic of electrical properties What is characteristics of metallic conductivity ? What is characteristics.
“… at each new level of complexity, entirely new properties appear, and the understanding of this behavior requires research which I think is as fundamental.
High Temperature Superconducting Solenoid Punch. Our Mission Make an actuator using BSSCO 2223 HTS tape from American Superconductor.
Current, Ohm’s Law, Etc. where R is resistance Resistance does not vary with the applied voltage resistor.
The Three Hallmarks of Superconductivity
Superconductor Ceramics
Superconductivity Practical Days at CERN
Advanced Higher Chemistry
Current, Ohm’s Law, Etc. where R is resistance Resistance does not vary with the applied voltage resistor.
High Temperature Copper Oxide Superconductors: Properties, Theory and Applications in Society Presented by Thomas Hines in partial fulfillment of Physics.
Constructing and Studying a Levitating Frictionless Bearing Ruth Toner Senior Project Speech
Superconductors: Basic Concepts Daniel Shantsev AMCS group Department of Physics University of Oslo History Superconducting materials Properties Understanding.
High Temperature Superconductivity Allen Moussa
Superconductivity Narratives The Players: The Applications: And the Future:
By: Shruti Sheladia, Garrett M Leavitt, Stephanie Schroeder, Christopher Dunn, Kathleen Brackney Levitation of a magnet above a high temperature superconductor.
Resistance R - _____________________________________ ____________________________________________________ _____________________________________________________.
Exciting New Insights into Strongly Correlated Oxides with Advanced Computing: Solving a Microscopic Model for High Temperature Superconductivity T. Maier,
1 Superconductivity  pure metal metal with impurities 0.1 K Electrical resistance  is a material constant (isotopic shift of the critical temperature)
Feb. 18, 2012 Brian Utter Saturday Morning Physics.
Who was the first person to observe superconductivity? 1.Leon Cooper 2.Walther Meissner 3.Sir James Dewar 4.Heike Kamerlingh- Onnes.
How does Superconductivity Work? Thomas A. Maier.
Superconductors Jason Weimer Honors physics Mr. Pagani Period 3 Project A.
Cultural Project 1- Superconductors Molly Risko Xinyu Zhu Evonne Britton Shu Chen.
Prof. Harvinder Kaur Govt College for Girls. Outline  Introduction  Mechanism of Superconductors  Meissner Effect  Type I and Type II superconductors.
Superconductivity Practical Days at CERN
Superconductors J Pemberton Dutch Physicist Fredrick Onnes was measuring the resistivity of Mercury and found it went to zero at 4K.
Michael Browne 11/26/2007.
Studies of the Cryogenic Part with Load Lock System T. Eisel, F. Haug CERN TE-CRG-CI October 19 th, 2011, Page 1 Superconductivity years Heike Kamerlingh.
START. What’s “SUPER” about SUPERCONDUCTORS? Clarina R. dela Cruz High Pressure and Low Temperature Laboratory Texas Center for Superconductivity University.
O n t h e T r a c k o f M o d e r n P h y s i c s and Leonardo da Vinci, EU “Supercomet2” network If you want a Super Prize you should think of SUPERconductivity.
Electro-Mechanical Applications of High Temperature Superconductors A. Cansiz, E.A. Oral and O. Gundogdu Electric-Electronic Engineering Department Atatürk.
Current Density Consider current flowing in a homogeneous wire with cross sectional area A.
Superconductivity and Superfluidity PHYS3430 Professor Bob Cywinski “Superconductivity is perhaps the most remarkable physical property in the Universe”
c18cof01 Magnetic Properties Iron single crystal photomicrographs
1 Superconducting Materials Group 9: Kyle Koliba Jeremy Katusak.
Superconductivity. Work on Worksheets. Superconductivity Lecture
Superconducting Cobaltites Nick Vence. Definition A material which looses its electrical resistivity below a certain temperature (Tc)is said to be superconducting.
SUPERCONDUCTORS mobile electrons in conducting material move through lattice of atoms or ions that vibrate (thermal motion) when conductor is cooled down.
Why Make Holes in Superconductors? Saturday Morning Physics December 6, 2003 Dr. Sa-Lin Cheng Bernstein.
Presented by Fermion Glue in the Hubbard Model: New Insights into the Cuprate Pairing Mechanism with Advanced Computing Thomas C. Schulthess Computer Science.
Resistance R - _____________________________________ ____________________________________________________ _____________________________________________________.
SUPERCONDUCTIVITY INSTRUCTOR-DR. MARIA MERCY A. NAME Sparsh Sharma Anurag Patil Sai Prakash ID NO. 2015A1PS795H 2015A3PS311H 2015A1PS749H.
Chapter 7 in the textbook Introduction and Survey Current density:
HIGH TEMPERATURE SUPERCONDUCTORS. INTRODUCTION Superconducitivity Beginning of HTS.
Presented by Fermion Glue in the Hubbard Model: New Insights into the Cuprate Pairing Mechanism with Advanced Computing Thomas C. Schulthess Computational.
Superconductivity Eton College Physics WJEC AS Level.
HIGH TEMPERATURE SUPERCONDUCTOR Prepared By Dutt Thakar.
WHAT IS SUPERCONDUCTIVITY?? For some materials, the resistivity vanishes at some low temperature: they become superconducting. Superconductivity is the.
Superconductor Ceramics
Dipole magnets A dipole magnet gives a constant B-field.
Super Conductivity/ Quantum Locking
BCS THEORY BCS theory is the first microscopic theory of superconductivity since its discovery in It explains, The interaction of phonons and electrons.
COCKCROFT INSTITUTE, DARESBURY
Electrical resistance
Nathan Finney Michael Gammon Newell Jensen
PHY 752 Solid State Physics
Graduate Lecture Series
Out line of lecture What is superconductivity?
What Puts the Super in Superconductors?
Superconductivity investigated low temperature resistance of mercury Superconductivity occurs in certain materials at very low temperatures. Kelvin.
O n t h e T r a c k o f M o d e r n P h y s i c s
Magnetic Properties and Superconductivity
High Temperature Superconductivity
Special Topics in Electrodynamics:
Special Topics in Electrodynamics:
Special Topics in Electrodynamics:
Ginzburg-Landau theory
Presentation transcript:

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Superconducting magnetic levitated bearings for rotary machines 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 1 A Leão Rodrigues Layout  Brief description of superconductor materials  Calculation of magnetic levitation forces  Journal magnetic bearings design  Thrust magnetic bearings design  Levitation experiment  Conclusions

Discovery of Superconductivity Heike Kammerling Onnes in his Cryogenic Laboratory at Leiden University, Holland, th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 2 Hg 0,025 0,00 0,05 0,075 0,10 0,125 0,15  4 o 00 4 o 10 4 o 20 4 o 30 4 o 40 T ( K )  Onnes results Resistence Nov Superconducting magnetic levitated bearings for rotary machines A i u T V Mercury Thermometer Liquid Helium Onnes Experiment

Magnetic Field Effect Superconductor State Normal State 0 T c T HcHc H(T)H(T) Magnetic Field H c (kA/m) Leather (Pb) Mercury (Hg) Selenium(Sn) Indium(In) Thallium (Tl) T(K) Low Temperature Superconductors (LTS), or 1 st generation discovered until th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech Nov Superconducting magnetic levitated bearings for rotary machines Onnes Experiment A i u T V Material Thermometer Liquid Helium H

26-29 Nov Superconducting magnetic levitated bearings for rotary machines JcJc TcTc HcHc Current density, J Magnetic field, H Temperature, T 0 Superconductivity region Critical Surface Region of normal state The superconductivity state of a material is destroyed if one of the following parameters are out of the critical surface: Critical superconductivity (T C ) Critical magnetic field (H C ) Critical current density (J C ) Lost of Superconductivity Superconductor I S T c T Superconductor state Normal state 0 JcJc J(T)J(T) Current density 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 4

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Meissner Effect 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 5 Ferromagnetic Magnet picoseconds Metal t 0 A superconductor is a diamagnetic material Negative magnetic susceptibility Supercondutor Magnet In 1933, Walter Meissner and Robert Ochsenfeld observed that the magnetic flux was expelled from the interior of the superconductor. Supercondutor Persistent current Walter Meissner

26-29 Nov Superconducting magnetic levitated bearings for rotary machines 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 6 Bardeen Cooper Schiffer BCS Theory. In 1957 the scientists John Bardeen, Leon Cooper e John Schiffer, from Illinois University, presented a mathematical model that described the superconductivity phenomenon in the low temperature superconductors, called BCS theory. F F Cooper pair Electron 1 Electron 2 T < T c. Two free electrons when cooled down at temperature T<T c are attracted forming a Cooper pair. Then, the pair travels through the crystalline structure without touching it and therefore finding no resistance.

5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 7 H Supercondutor increasing - M H HcHc 0 Type I superconductor  Type I superconductors attain abruptly the normal state for a given critical magnetic field H c - M H H c1 0 H c2 increasing Vortexes H Type II superconductor  Type II superconductors start attaining transition for a given critical magnetic field H c1. Vortexes are formed and for H c2 > H c1 the superconductivity is totally lost.

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Bednorz e Alex Muller, in IBM laboratories, near Zurique, in Crystalline structure of La 2 CuO 4 Transition curves of La 2 CuO 4 Tc = 20 K High Temperature Superconductors (HTS) 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 8 In 1986, George Bednorz e Alex M ü ller, from IBM laboratories in R ü schliko (Switzerland), discovered a ceramic composite based in lanthanum, which was superconductor around the transition temperature of 20 K.

26-29 Nov Superconducting magnetic levitated bearings for rotary machines YBCO Superconductor (Yttrium, barium and copper oxide) YBCO ceramic blocks YBCO ceramic rings YBCO ceramic disc Paul Chu discovered YBCO in 1987 at the University of Huston. Tc = 86 K 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 2 YBa 2 Cu 3 O 7 Crystalline structure of YBCO O O O Ba Y Cu

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Superconductors evolution versus time 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 10 Liquid nitrogen 77 K

26-29 Nov Superconducting magnetic levitated bearings for rotary machines 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 11 Superconducting Levitation Force Superconductor NdFeB Permanent Magnet Superconductor

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Superconductor materials applications Evolution of the superconductors materials application Source: ISIS – International Superconductivity Industry Summit Electronics Energy - bearings Transportation Industry Instrumentation 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 12 Year

26-29 Nov Superconducting magnetic levitated bearings for rotary machines LEVITATION FORCE CALCULATION x z (mm) HTS REM z YBCO BSCCO Levitation force (mN) Computed Experimental t Measured levitation force between a HTS and a REM versus vertical distance z 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 13 HTS material B magnet J induced Permanent magnet z y z t Levitation force F Liquid nitrogen t (mm) BSCCO Levitation force (mN) HTS t YBCO REM Thickness of bulk YBCO dependence on levitation force z = 5 mm x Maxwell stress method

26-29 Nov Superconducting magnetic levitated bearings for rotary machines 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 14

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Journal magnetic bearing design 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 15 Shaft HTS cylinder NdFeB permanent magnet f = 9.7 N/cm 2 Force density distribution surface alongside the magnetic bearing Journal magnetic bearing layout Shaft Permanent magnet Superconducting ring Copper ring g Permanent magnet Superconducting ring Copper ring Commercial journal magnetic bearing

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Thrust magnetic bearing design a) Lower part (HTS) b)Upper part (PM) Layout of the thrust magnetic bearing HTS blocks Stabilization NdFeB blocks Air gaps 300 Thrust magnetic bearing flux plot NdFeB YBCO Liquid nitrogen Levitator Thrust magnetic bearing 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 16 Liquid nitrogen

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Magnetic Levitation 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 17

26-29 Nov Superconducting magnetic levitated bearings for rotary machines Conclusions 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 18 Maxwell stress method to evaluate levitation forces between a permanent magnet and a YBCO superconductor under zero field cooling was presented.  Results for magnetic pressures are of the order of 10 N/cm 2.  The method was applied to the design of journal and thrust bearings.  These devices are now commercially produced and the market expectation shows a broad and innovative potential of industrial application. 

26-29 Nov Superconducting magnetic levitated bearings for rotary machines 5 th International Symposium on Advanced Nova University of Lisbon Electromechanical Motion Systems Marrakech 20

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.