LEADER 00000cam a2200685Ii 4500
001 on1077778986
003 OCoLC
005 20200717185401.7
006 m o d
007 cr cn|||||||||
008 181205t20182019enka ob 001 0 eng d
019 1083357790
020 9781785612169|q(electronic book)
020 1785612166|q(electronic book)
020 9781523121106|q(electronic book)
020 1523121106|q(electronic book)
020 |z9781785612152|q(hardback)
020 |z1785612158|q(hardback)
035 (OCoLC)1077778986|z(OCoLC)1083357790
040 UIU|beng|erda|epn|cUIU|dCDN|dOCLCF|dYDX|dCUS|dUAB|dEBLCP
|dN$T|dSTF|dCUV|dUKAHL|dOCLCQ|dKNOVL|dAKR|dOCLCQ
049 RIDW
050 4 TA417.55|b.B38 2018eb
072 7 TEC|x009000|2bisacsh
072 7 TEC|x035000|2bisacsh
082 04 620.1127|223
090 TA417.55|b.B38 2018eb
100 1 Brauer, Hartmut,|d1953-|0https://id.loc.gov/authorities/
names/no2019126405|eauthor.
245 10 Motion-induced eddy current techniques for non-destructive
testing and evaluation /|cHartmut Brauer [and five
others].
264 1 Stevenage :|bInstitution of Engineering and Technology,
|c2018.
264 4 |c©2019
300 1 online resource :|billustrations.
336 text|btxt|2rdacontent
337 computer|bc|2rdamedia
338 online resource|bcr|2rdacarrier
340 |gpolychrome|2rdacc
347 text file|2rdaft
490 1 IET Control, robotics and sensors series ;|v06
504 Includes bibliographical references and index.
505 0 Intro; Contents; Author Biographies; Preface; 1:
Introduction (Hartmut Brauer); 1.1 Electromagnetic
testing; 1.1.1 Brief historical review; 1.1.2
Electromagnetic NDT methods; 1.1.3 Capabilities of
electromagnetic techniques; 1.1.4 Present state of eddy
current inspection; 1.2 Eddy current testing; 1.2.1 Eddy
current and ECT; 1.2.2 ECT principles; 1.2.3 Applications;
1.3 Motion-induced ECT; 1.3.1 Introduction; 1.3.2 Lorentz
force eddy current testing; 1.3.3 Theory; 1.3.4
Experiments; 1.3.5 Comparison of ECT and LET
505 8 2: Forward simulation methods (Marek Ziolkowski, Mladen
Zec and Konstantin Weise)2.1 Moving coordinate systems-
transformations; 2.2 Semianalytical methods used in LET
systems; 2.2.1 Calculation of forces in 2D LET systems;
2.2.2 Lorentz forces acting on 3D permanent magnets above
moving conducting plate without defects; 2.2.3 Calculation
of forces in 3D LET systems; 2.2.4 Oscillatory motion of
permanent magnets above a conducting plate; 2.2.5 The
simplest approach to calculate DRS; 2.2.6 A hole in a thin,
large, conductive sheet; 2.2.7 An extended area approach
in the calculation of DRS
505 8 2.3 Surface charge simulation method2.4 Numerical
simulations with FEM; 2.4.1 Introduction and motivation;
2.4.2 Computation of eddy current distributions including
moving parts; 2.4.3 Numerical modeling of conductivity
anomalies; 2.4.4 Comparison of numerical approaches; 3:
Sensors for MIECT (Matthias Carlstedt, Hartmut Brauer and
Konstantin Weise); 3.1 Force measurement systems; 3.1.1
Principles of force transducers; 3.1.2 Differential
Lorentz force eddy current testing sensor; 3.1.3
Characteristics and calibration of force measurement
systems; 3.2 Optimization of PM systems
505 8 3.2.1 Introduction and motivation3.2.2 Methods; 3.2.3
Optimization results and discussion; 3.2.4 Prototypes of
optimized LET magnet systems; 3.2.5 Defect depth study;
3.2.6 Conclusions; 4: Experiments and LET measurements
(Matthias Carlstedt and Konstantin Weise); 4.1 Measurement
procedure; 4.1.1 Measurement principle; 4.1.2 Measurement
method; 4.1.3 Experimental setup; 4.2 Validation
procedure; 4.2.1 DSP and basic statistics; 4.2.2
Autocorrelation on typical force signals; 4.2.3 Program
flowchart for DSP; 4.2.4 Experimental study; 4.2.5
Uncertainty analysis
505 8 5: Lorentz force evaluation (Hartmut Brauer)5.1
Identification of conductivity anomalies; 5.2 Inverse
solution techniques; 5.2.1 Theory; 5.2.2 Classification of
inverse problems; 5.2.3 Regularization; 5.3 Lorentz force
evaluation; 5.4 Summary; 6: Applications (Robert P. Uhlig,
Hartmut Brauer, Konstantin Weise and Marek Ziolkowski);
6.1 Sigmometry; 6.1.1 Introduction and motivation; 6.1.2
Basic principle; 6.1.3 Semianalytical and numerical
calibration; 6.1.4 Experimental validation; 6.1.5
Findings; 6.2 Defectocscopy of multilayered structures;
6.2.1 LET measurements of alucobond specimen
520 The book, consisting of 6 chapters, studies motion-induced
eddy current techniques for non-destructive testing and
evaluation by considering: forward simulation methods;
sensors for MIECT; experiments and LET measurements;
Lorentz force evaluation and non-destructive applications.
588 0 Print version record.
590 eBooks on EBSCOhost|bEBSCO eBook Subscription Academic
Collection - North America
650 0 Nondestructive testing.|0https://id.loc.gov/authorities/
subjects/sh85092221
650 0 Eddy currents (Electric)|0https://id.loc.gov/authorities/
subjects/sh85040943
650 7 Nondestructive testing.|2fast|0https://id.worldcat.org/
fast/1430903
650 7 Eddy currents (Electric)|2fast|0https://id.worldcat.org/
fast/902410
655 4 Electronic books.
776 08 |iPrint version:|aBrauer, Hartmut.|tMotion-induced eddy
current techniques for non-destructive testing and
evaluation.|dStevenage : Institution of Engineering and
Technology, 2018|z9781785612152|w(OCoLC)1063707839
830 0 IET control, robotics and sensors series ;|0https://
id.loc.gov/authorities/names/no2017016106|v06.
856 40 |uhttps://rider.idm.oclc.org/login?url=http://
search.ebscohost.com/login.aspx?direct=true&scope=site&
db=nlebk&AN=2000716|zOnline ebook via EBSCO. Access
restricted to current Rider University students, faculty,
and staff.
856 42 |3Instructions for reading/downloading the EBSCO version
of this ebook|uhttp://guides.rider.edu/ebooks/ebsco
901 MARCIVE 20231220
948 00 |d20200727|cEBSCO|tEBSCOebooksacademic NEW June-July 17
7032|lridw
994 92|bRID
