Verfügbarkeit: Short-Circuit Withstand Capability of Power Transformers.

Short-Circuit Withstand Capability of Power Transformers.:

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Bibliographische Detailangaben
1. Verfasser:	Geißler, Daniel Hermann
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Göttingen : Cuvillier Verlag, 2016.
Schlagworte:	Electric transformers. Transformers. Transformateurs électriques. transformers. Electric transformers Electronic book.
Online-Zugang:	Volltext
Beschreibung:	5.4.1 Testing Method Validation.
Beschreibung:	1 online resource (175 pages)
Bibliographie:	Includes bibliographical references.
ISBN:	3736983328 9783736983328

Internformat

MARC


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100	1		\|a Geißler, Daniel Hermann.
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300			\|a 1 online resource (175 pages)
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505	0		\|a Acknowledgments; Contents; Abstract; 1 Introduction; 1.1 Standardization of Short-Circuit Withstand Capability; 1.2 Thesis Objectives; 1.2.1 Current State of Science; 1.2.2 Buckling Analysis on Transformer Windings; 1.2.3 Characterization of Conductors; 1.2.4 Impact of Insulating Paper Aging; 2 Fundamentals; 2.1 Power Transformer Windings; 2.1.1 Winding Types; 2.1.2 Conductor Types; 2.1.3 Copper for Electric Applications; 2.2 Short-Circuit Considerations; 2.2.1 Short-Circuit Current; 2.2.2 Short-Circuit Forces; 2.2.3 Failures Modes; 2.3 Mechanics of Materials.
505	8		\|a 2.3.1 Elastic Behavior of Materials2.3.2 Theory of Plasticity; 2.3.3 Ramberg-Osgood Equation; 2.3.4 Strain Rate and Temperature Dependency of Copper; 2.4 Method of Finite Element Analysis; 2.4.1 Magnetic Formulation; 2.4.2 Structural Mechanics Formulation; 2.4.3 Coupling of the Magnetic and Mechanical Field; 2.4.4 Eigenvalue Buckling Analysis; 3 Buckling Analysis; 3.1 Analytical Approach; 3.1.1 Bending Stiffness of Conductors; 3.1.2 Antisymmetric Buckling; 3.1.3 Symmetric Buckling; 3.1.4 Transition from Buckling to Pure Bending; 3.1.5 Involving Elastoplastic Properties.
505	8		\|a 3.1.6 Dynamic Buckling Analysis3.1.6.1 Hydrodynamic Damping and Inertial Mass; 3.1.6.2 Governing Equation; 3.1.6.3 Mathieu Equation; 3.1.6.4 Stability Analysis; 3.2 Finite Element-Based Analysis; 3.2.1 Simplified CTC Model; 3.2.2 Strain Rate Estimation; 3.2.2.1 Elastic Vibration; 3.2.2.2 Elastoplastic Buckling; 3.2.3 Buckling of CTC Windings; 3.2.3.1 Geometry and FEA Setup; 3.2.3.2 Linear Analysis; 3.2.3.3 Nonlinear Analysis; 3.2.3.4 Modal Analysis; 4 Static Characterization of Conductors; 4.1 Testing Methods and Standards; 4.1.1 Tensile Test; 4.1.2 Three-Point Bending Test; 4.1.3 T-Peel Test.
505	8		\|a 4.1.4 Overlap Shear Test4.2 Preliminary Investigations; 4.2.1 Copper Characterization; 4.2.2 Validation of Simplified CTC Model; 4.2.3 Oil Impregnation Effects; 4.3 Stiffness Contribution of Insulating Paper; 4.3.1 Measurement Results; 4.3.2 Equivalent Stiffness Evaluation; 4.4 Impact of Insulating Paper Aging; 4.4.1 Accelerated Aging Procedure; 4.4.2 Bending Test Results; 4.4.3 Insulating Paper Characterization; 4.4.4 Tensile and Bending Test Correlation; 4.4.5 FEA-Based Failure Analysis; 4.5 Characterization of Epoxy Bonded CTCs; 4.5.1 Test Results; 4.5.2 Adhesive Layer Parameterization.
505	8		\|a 4.5.3 FEA Model Validation4.5.4 FEA Model for Bonded CTCs; 5 Dynamic Short-Circuit Forces Test Stand; 5.1 Design and Principal Functionality; 5.2 Deformation Measurement Systems; 5.2.1 Acceleration Sensors; 5.2.1.1 Immunity to Magnetic Fields; 5.2.1.2 Mounting to the Windings; 5.2.1.3 Signal Processing; 5.2.2 High-Speed Camera-Based Deformation Tracking; 5.2.2.1 Principal Functionality; 5.2.2.2 Marker Mounting and Image Calibration; 5.2.2.3 Displacement Calculation Algorithm; 5.2.3 Comparison of Both Systems; 5.3 Measurement Data Evaluation; 5.4 Experimental Results.
500			\|a 5.4.1 Testing Method Validation.
504			\|a Includes bibliographical references.
650		0	\|a Electric transformers. \|0 http://id.loc.gov/authorities/subjects/sh85042014
650		0	\|a Transformers.
650		6	\|a Transformateurs électriques.
650		7	\|a transformers. \|2 aat
650		7	\|a Electric transformers \|2 fast
655		4	\|a Electronic book.
758			\|i has work: \|a Short-circuit withstand capability of power transformers (Text) \|1 https://id.oclc.org/worldcat/entity/E39PCGHDtBxtbKYfJvqQVhdQpX \|4 https://id.oclc.org/worldcat/ontology/hasWork
776	0	8	\|i Print version: \|a Geißler, Daniel Hermann. \|t Short-Circuit Withstand Capability of Power Transformers. \|d Göttingen : Cuvillier Verlag, ©2016 \|z 9783736993327
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contents	Acknowledgments; Contents; Abstract; 1 Introduction; 1.1 Standardization of Short-Circuit Withstand Capability; 1.2 Thesis Objectives; 1.2.1 Current State of Science; 1.2.2 Buckling Analysis on Transformer Windings; 1.2.3 Characterization of Conductors; 1.2.4 Impact of Insulating Paper Aging; 2 Fundamentals; 2.1 Power Transformer Windings; 2.1.1 Winding Types; 2.1.2 Conductor Types; 2.1.3 Copper for Electric Applications; 2.2 Short-Circuit Considerations; 2.2.1 Short-Circuit Current; 2.2.2 Short-Circuit Forces; 2.2.3 Failures Modes; 2.3 Mechanics of Materials. 2.3.1 Elastic Behavior of Materials2.3.2 Theory of Plasticity; 2.3.3 Ramberg-Osgood Equation; 2.3.4 Strain Rate and Temperature Dependency of Copper; 2.4 Method of Finite Element Analysis; 2.4.1 Magnetic Formulation; 2.4.2 Structural Mechanics Formulation; 2.4.3 Coupling of the Magnetic and Mechanical Field; 2.4.4 Eigenvalue Buckling Analysis; 3 Buckling Analysis; 3.1 Analytical Approach; 3.1.1 Bending Stiffness of Conductors; 3.1.2 Antisymmetric Buckling; 3.1.3 Symmetric Buckling; 3.1.4 Transition from Buckling to Pure Bending; 3.1.5 Involving Elastoplastic Properties. 3.1.6 Dynamic Buckling Analysis3.1.6.1 Hydrodynamic Damping and Inertial Mass; 3.1.6.2 Governing Equation; 3.1.6.3 Mathieu Equation; 3.1.6.4 Stability Analysis; 3.2 Finite Element-Based Analysis; 3.2.1 Simplified CTC Model; 3.2.2 Strain Rate Estimation; 3.2.2.1 Elastic Vibration; 3.2.2.2 Elastoplastic Buckling; 3.2.3 Buckling of CTC Windings; 3.2.3.1 Geometry and FEA Setup; 3.2.3.2 Linear Analysis; 3.2.3.3 Nonlinear Analysis; 3.2.3.4 Modal Analysis; 4 Static Characterization of Conductors; 4.1 Testing Methods and Standards; 4.1.1 Tensile Test; 4.1.2 Three-Point Bending Test; 4.1.3 T-Peel Test. 4.1.4 Overlap Shear Test4.2 Preliminary Investigations; 4.2.1 Copper Characterization; 4.2.2 Validation of Simplified CTC Model; 4.2.3 Oil Impregnation Effects; 4.3 Stiffness Contribution of Insulating Paper; 4.3.1 Measurement Results; 4.3.2 Equivalent Stiffness Evaluation; 4.4 Impact of Insulating Paper Aging; 4.4.1 Accelerated Aging Procedure; 4.4.2 Bending Test Results; 4.4.3 Insulating Paper Characterization; 4.4.4 Tensile and Bending Test Correlation; 4.4.5 FEA-Based Failure Analysis; 4.5 Characterization of Epoxy Bonded CTCs; 4.5.1 Test Results; 4.5.2 Adhesive Layer Parameterization. 4.5.3 FEA Model Validation4.5.4 FEA Model for Bonded CTCs; 5 Dynamic Short-Circuit Forces Test Stand; 5.1 Design and Principal Functionality; 5.2 Deformation Measurement Systems; 5.2.1 Acceleration Sensors; 5.2.1.1 Immunity to Magnetic Fields; 5.2.1.2 Mounting to the Windings; 5.2.1.3 Signal Processing; 5.2.2 High-Speed Camera-Based Deformation Tracking; 5.2.2.1 Principal Functionality; 5.2.2.2 Marker Mounting and Image Calibration; 5.2.2.3 Displacement Calculation Algorithm; 5.2.3 Comparison of Both Systems; 5.3 Measurement Data Evaluation; 5.4 Experimental Results.
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record_format	marc
spelling	Geißler, Daniel Hermann. Short-Circuit Withstand Capability of Power Transformers. Göttingen : Cuvillier Verlag, 2016. 1 online resource (175 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Print version record. Acknowledgments; Contents; Abstract; 1 Introduction; 1.1 Standardization of Short-Circuit Withstand Capability; 1.2 Thesis Objectives; 1.2.1 Current State of Science; 1.2.2 Buckling Analysis on Transformer Windings; 1.2.3 Characterization of Conductors; 1.2.4 Impact of Insulating Paper Aging; 2 Fundamentals; 2.1 Power Transformer Windings; 2.1.1 Winding Types; 2.1.2 Conductor Types; 2.1.3 Copper for Electric Applications; 2.2 Short-Circuit Considerations; 2.2.1 Short-Circuit Current; 2.2.2 Short-Circuit Forces; 2.2.3 Failures Modes; 2.3 Mechanics of Materials. 2.3.1 Elastic Behavior of Materials2.3.2 Theory of Plasticity; 2.3.3 Ramberg-Osgood Equation; 2.3.4 Strain Rate and Temperature Dependency of Copper; 2.4 Method of Finite Element Analysis; 2.4.1 Magnetic Formulation; 2.4.2 Structural Mechanics Formulation; 2.4.3 Coupling of the Magnetic and Mechanical Field; 2.4.4 Eigenvalue Buckling Analysis; 3 Buckling Analysis; 3.1 Analytical Approach; 3.1.1 Bending Stiffness of Conductors; 3.1.2 Antisymmetric Buckling; 3.1.3 Symmetric Buckling; 3.1.4 Transition from Buckling to Pure Bending; 3.1.5 Involving Elastoplastic Properties. 3.1.6 Dynamic Buckling Analysis3.1.6.1 Hydrodynamic Damping and Inertial Mass; 3.1.6.2 Governing Equation; 3.1.6.3 Mathieu Equation; 3.1.6.4 Stability Analysis; 3.2 Finite Element-Based Analysis; 3.2.1 Simplified CTC Model; 3.2.2 Strain Rate Estimation; 3.2.2.1 Elastic Vibration; 3.2.2.2 Elastoplastic Buckling; 3.2.3 Buckling of CTC Windings; 3.2.3.1 Geometry and FEA Setup; 3.2.3.2 Linear Analysis; 3.2.3.3 Nonlinear Analysis; 3.2.3.4 Modal Analysis; 4 Static Characterization of Conductors; 4.1 Testing Methods and Standards; 4.1.1 Tensile Test; 4.1.2 Three-Point Bending Test; 4.1.3 T-Peel Test. 4.1.4 Overlap Shear Test4.2 Preliminary Investigations; 4.2.1 Copper Characterization; 4.2.2 Validation of Simplified CTC Model; 4.2.3 Oil Impregnation Effects; 4.3 Stiffness Contribution of Insulating Paper; 4.3.1 Measurement Results; 4.3.2 Equivalent Stiffness Evaluation; 4.4 Impact of Insulating Paper Aging; 4.4.1 Accelerated Aging Procedure; 4.4.2 Bending Test Results; 4.4.3 Insulating Paper Characterization; 4.4.4 Tensile and Bending Test Correlation; 4.4.5 FEA-Based Failure Analysis; 4.5 Characterization of Epoxy Bonded CTCs; 4.5.1 Test Results; 4.5.2 Adhesive Layer Parameterization. 4.5.3 FEA Model Validation4.5.4 FEA Model for Bonded CTCs; 5 Dynamic Short-Circuit Forces Test Stand; 5.1 Design and Principal Functionality; 5.2 Deformation Measurement Systems; 5.2.1 Acceleration Sensors; 5.2.1.1 Immunity to Magnetic Fields; 5.2.1.2 Mounting to the Windings; 5.2.1.3 Signal Processing; 5.2.2 High-Speed Camera-Based Deformation Tracking; 5.2.2.1 Principal Functionality; 5.2.2.2 Marker Mounting and Image Calibration; 5.2.2.3 Displacement Calculation Algorithm; 5.2.3 Comparison of Both Systems; 5.3 Measurement Data Evaluation; 5.4 Experimental Results. 5.4.1 Testing Method Validation. Includes bibliographical references. Electric transformers. http://id.loc.gov/authorities/subjects/sh85042014 Transformers. Transformateurs électriques. transformers. aat Electric transformers fast Electronic book. has work: Short-circuit withstand capability of power transformers (Text) https://id.oclc.org/worldcat/entity/E39PCGHDtBxtbKYfJvqQVhdQpX https://id.oclc.org/worldcat/ontology/hasWork Print version: Geißler, Daniel Hermann. Short-Circuit Withstand Capability of Power Transformers. Göttingen : Cuvillier Verlag, ©2016 9783736993327 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2130593 Volltext
spellingShingle	Geißler, Daniel Hermann Short-Circuit Withstand Capability of Power Transformers. Acknowledgments; Contents; Abstract; 1 Introduction; 1.1 Standardization of Short-Circuit Withstand Capability; 1.2 Thesis Objectives; 1.2.1 Current State of Science; 1.2.2 Buckling Analysis on Transformer Windings; 1.2.3 Characterization of Conductors; 1.2.4 Impact of Insulating Paper Aging; 2 Fundamentals; 2.1 Power Transformer Windings; 2.1.1 Winding Types; 2.1.2 Conductor Types; 2.1.3 Copper for Electric Applications; 2.2 Short-Circuit Considerations; 2.2.1 Short-Circuit Current; 2.2.2 Short-Circuit Forces; 2.2.3 Failures Modes; 2.3 Mechanics of Materials. 2.3.1 Elastic Behavior of Materials2.3.2 Theory of Plasticity; 2.3.3 Ramberg-Osgood Equation; 2.3.4 Strain Rate and Temperature Dependency of Copper; 2.4 Method of Finite Element Analysis; 2.4.1 Magnetic Formulation; 2.4.2 Structural Mechanics Formulation; 2.4.3 Coupling of the Magnetic and Mechanical Field; 2.4.4 Eigenvalue Buckling Analysis; 3 Buckling Analysis; 3.1 Analytical Approach; 3.1.1 Bending Stiffness of Conductors; 3.1.2 Antisymmetric Buckling; 3.1.3 Symmetric Buckling; 3.1.4 Transition from Buckling to Pure Bending; 3.1.5 Involving Elastoplastic Properties. 3.1.6 Dynamic Buckling Analysis3.1.6.1 Hydrodynamic Damping and Inertial Mass; 3.1.6.2 Governing Equation; 3.1.6.3 Mathieu Equation; 3.1.6.4 Stability Analysis; 3.2 Finite Element-Based Analysis; 3.2.1 Simplified CTC Model; 3.2.2 Strain Rate Estimation; 3.2.2.1 Elastic Vibration; 3.2.2.2 Elastoplastic Buckling; 3.2.3 Buckling of CTC Windings; 3.2.3.1 Geometry and FEA Setup; 3.2.3.2 Linear Analysis; 3.2.3.3 Nonlinear Analysis; 3.2.3.4 Modal Analysis; 4 Static Characterization of Conductors; 4.1 Testing Methods and Standards; 4.1.1 Tensile Test; 4.1.2 Three-Point Bending Test; 4.1.3 T-Peel Test. 4.1.4 Overlap Shear Test4.2 Preliminary Investigations; 4.2.1 Copper Characterization; 4.2.2 Validation of Simplified CTC Model; 4.2.3 Oil Impregnation Effects; 4.3 Stiffness Contribution of Insulating Paper; 4.3.1 Measurement Results; 4.3.2 Equivalent Stiffness Evaluation; 4.4 Impact of Insulating Paper Aging; 4.4.1 Accelerated Aging Procedure; 4.4.2 Bending Test Results; 4.4.3 Insulating Paper Characterization; 4.4.4 Tensile and Bending Test Correlation; 4.4.5 FEA-Based Failure Analysis; 4.5 Characterization of Epoxy Bonded CTCs; 4.5.1 Test Results; 4.5.2 Adhesive Layer Parameterization. 4.5.3 FEA Model Validation4.5.4 FEA Model for Bonded CTCs; 5 Dynamic Short-Circuit Forces Test Stand; 5.1 Design and Principal Functionality; 5.2 Deformation Measurement Systems; 5.2.1 Acceleration Sensors; 5.2.1.1 Immunity to Magnetic Fields; 5.2.1.2 Mounting to the Windings; 5.2.1.3 Signal Processing; 5.2.2 High-Speed Camera-Based Deformation Tracking; 5.2.2.1 Principal Functionality; 5.2.2.2 Marker Mounting and Image Calibration; 5.2.2.3 Displacement Calculation Algorithm; 5.2.3 Comparison of Both Systems; 5.3 Measurement Data Evaluation; 5.4 Experimental Results. Electric transformers. http://id.loc.gov/authorities/subjects/sh85042014 Transformers. Transformateurs électriques. transformers. aat Electric transformers fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85042014
title	Short-Circuit Withstand Capability of Power Transformers.
title_auth	Short-Circuit Withstand Capability of Power Transformers.
title_exact_search	Short-Circuit Withstand Capability of Power Transformers.
title_full	Short-Circuit Withstand Capability of Power Transformers.
title_fullStr	Short-Circuit Withstand Capability of Power Transformers.
title_full_unstemmed	Short-Circuit Withstand Capability of Power Transformers.
title_short	Short-Circuit Withstand Capability of Power Transformers.
title_sort	short circuit withstand capability of power transformers
topic	Electric transformers. http://id.loc.gov/authorities/subjects/sh85042014 Transformers. Transformateurs électriques. transformers. aat Electric transformers fast
topic_facet	Electric transformers. Transformers. Transformateurs électriques. transformers. Electric transformers Electronic book.
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2130593
work_keys_str_mv	AT geißlerdanielhermann shortcircuitwithstandcapabilityofpowertransformers

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