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  • Produktbild: An Introduction to High-Voltage Experimental Technique
  • Produktbild: An Introduction to High-Voltage Experimental Technique

An Introduction to High-Voltage Experimental Technique Textbook for Electrical Engineers

54,99 €

inkl. gesetzl. MwSt., Versandkostenfrei

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

01.01.1978

Abbildungen

mit 26 Abbildungen

Verlag

Vieweg & Teubner

Seitenzahl

212

Maße (L/B/H)

24,4/17/1,3 cm

Gewicht

401 g

Auflage

1978

Sprache

Deutsch

ISBN

978-3-528-08383-0

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

01.01.1978

Abbildungen

mit 26 Abbildungen

Verlag

Vieweg & Teubner

Seitenzahl

212

Maße (L/B/H)

24,4/17/1,3 cm

Gewicht

401 g

Auflage

1978

Sprache

Deutsch

ISBN

978-3-528-08383-0

Herstelleradresse

Vieweg+Teubner Verlag
Abraham-Lincoln-Straße 46
65189 Wiesbaden
DE

Email: ProductSafety@springernature.com

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  • Produktbild: An Introduction to High-Voltage Experimental Technique
  • Produktbild: An Introduction to High-Voltage Experimental Technique
  • 1 Fundamental Principles of High-Voltage Experimental Techniques.- 1.1 Generation and Measurement of High Alternating Voltages.- 1.1.1 Characteristic Parameters of High Alternating Voltages.- 1.1.2 Test Transformer Circuits.- 1.1.3 Construction of Test Transformers.- 1.1.4 Performance of Test Transformers.- 1.1.5 High Voltage Generation with Resonant Circuits.- 1.1.6 Peak Voltage Measurement with Sphere Gaps.- 1.1.7 Peak Voltage Measurement Using Measuring Capacitors.- 1.1.8 Peak Value Measurement with Capacitive Voltage Dividers.- 1.1.9 Measurement of r.m.s. Values by Means of Electrostatic Voltmeters.- 1.1.10 Measurements with Voltage Transformers.- 1.2 Generation and Measurement of High Direct Voltages.- 1.2.1 Characteristic Parameters of High Direct Voltages.- 1.2.2 Properties of High-Voltage Rectifiers.- 1.2.3 The Half-Period Rectifier Circuit.- 1.2.4 Voltage Multiplier Circuits.- 1.2.5 Electrostatic Generators.- 1.2.6 Measurements with High-Voltage Resistors.- 1.2.7 Measurement of r.m.s. Values by Means of Electrostatic Voltmeters.- 1.2.8 Voltmeter and Field Strength Meter Based upon the Generator Principle.- 1.2.9 Other Methods for the Measurement of High Direct Voltages.- 1.2.10 Measurement of Ripple Voltages.- 1.3 Generation and Measurement of Impulse Voltages.- 1.3.1 Characteristic Parameters of Impulse Voltages.- 1.3.2 Capacitive Circuits for Impulse Voltage Generation.- 1.3.3 Calculation of Single-Stage Impulse Voltage Circuits.- 1.3.4 Further Means of Generating Impulse Voltages.- 1.3.5 Peak Value Measurement Using a Sphere Gap.- 1.3.6 Circuit and Transient Response of Impulse Voltage Dividers.- 1.3.7 Experimental Determination of the Response Characteristics of Impulse Voltage Measuring Circuits.- 1.4 Generation and Measurement of Impulse Currents.- 1.4.1 Characteristic Parameters of Impulse Currents.- 1.4.2 Energy Storage Systems.- 1.4.3 Discharge Circuits for the Generation of Impulse Currents.- 1.4.4 Current Measurement with Measuring Resistors.- 1.4.5 Current Measurement Using Induction Effects.- 1.4.6 Other Methods of Measuring Rapidly Varying Transient Currents.- 1.5 Non-Destructive High-Voltage Tests.- 1.5.1 Loss in a Dielectric.- 1.5.2 Measurement of the Conduction Current for Direct Voltage.- 1.5.3 Measurement of the Dissipation Factor for Alternating Voltage.- 1.5.4 Measurement of Partial Discharges at Alternating Voltages.- 2 Layout and Operation of High-Voltage Laboratories.- 2.1 Dimensions and Technical Equipment of the Laboratories.- 2.1.1 Stands for High-Voltage Practicals.- 2.1.2 High-Voltage Testing Bays.- 2.1.3 High-Voltage Research Laboratories.- 2.1.4 Auxiliary Facilities for Large Laboratories.- 2.2 Fencing, Earthing and Shielding of Experimental Setups.- 2.2.1 Fencing.- 2.2.2 Earthing Equipment.- 2.2.3 Shielding.- 2.3 Circuits for High-Voltage Experiments.- 2.3.1 Power Supply and Safety Circuits.- 2.3.2 Setting up High-Voltage Circuits.- 2.4 Construction Elements for High-Voltage Circuits.- 2.4.1 High-Voltage Resistors.- 2.4.2 High-Voltage Capacitors.- 2.4.3 Gaps.- 2.4.4 High-Voltage Construction Kit.- 3 High-Voltage Practicals.- 3.1 Experiment “Alternating Voltages”.- 3.1.1 Fundamentals: Safety Arrangements — Testing Transformers — Peak Value Measurement — r.m.s. Value Measurement — Sphere Gaps.- 3.1.2 Experiment.- 3.1.3 Evaluation.- 3.2 Experiment “Direct Voltages”.- 3.2.1 Fundamentals: Rectifier Characteristics — Ripple Factor — Greinacher Doubler-Circuit — Polarity Effect — Insulating Barriers.- 3.2.2 Experiment.- 3.2.3 Evaluation.- 3.3 Experiment “Impulse Voltages”.- 3.3.1 Fundamentals: Lightning Impulse Voltages — Single Stage Impulse Voltage Circuits — Peak Value Measurement with Sphere Gaps — Breakdown Probability.- 3.3.2 Experiment.- 3.3.3 Evaluation.- 3.4 Experiment “Electric Field”.- 3.4.1 Fundamentals: Graphical Field Determination — Model Measurements in Electric Fields — Field Measurements at High Voltages.- 3.4.2 Experiment.- 3.4.3 Evaluation.- 3.5 Experiment “Liquid and Solid Insulating Materials”.- 3.5.1 Fundamentals: Insulating Oil and Solid Insulating Material — Conductivity Measurement — Dissipation Factor Measurement — Fibre-Bridge Breakdown — Thermal Breakdown — Breakdown Test.- 3.5.2 Experiment.- 3.5.3 Evaluation.- 3.6 Experiment “Partial Discharges”.- 3.6.1 Fundamentals: External Partial Discharges (Corona) — Internal Partial Discharges — Gliding Discharges.- 3.6.2 Experiment.- 3.6.3 Evaluation.- 3.7 Experiment “Breakdown of Gases”.- 3.7.1 Fundamentals: Townsend Mechanism — Streamer Mechanism — Insulating Gases.- 3.7.2 Experiment.- 3.7.3 Evaluation.- 3.8 Experiment “Impulse Voltage Measuring Technique”.- 3.8.1 Fundamentals: Multiplier Circuit after Marx — Impulse Voltage Divider — Impulse Voltage-Time Curves.- 3.8.2 Experiment.- 3.8.3 Evaluation.- 3.9 Experiment “Transformer Test”.- 3.9.1 Fundamentals: Specifications for High-Voltage Tests — Insulation Coordination — Breakdown Test of Insulating Oil — Transformer Test with Alternating Voltage — Transformer Test with Lightning Impulse Voltage.- 3.9.2 Experiment.- 3.9.3 Evaluation.- 3.10 Experiment “Internal Overvoltages”.- 3.10.1 Fundamentals: Neutral Shift — Earthing Coefficient — Magnetization Characteristic — Jump Resonance — Subharmonic Oscillations.- 3.10.2 Experiment.- 3.10.3 Evaluation.- 3.11 Experiment “Travelling Waves”.- 3.11.1 Fundamentals: Lightning Overvoltages — Switching Overvoltages — Surge Diverter — Protective Range — Waves in Windings — Impulse Voltage Distribution.- 3.11.2 Experiment.- 3.11.3 Evaluation.- 3.12 Experiment “Impulse Currents and Arcs”.- 3.12.1 Fundamentals: Discharge Circuit with Capacitive Energy Storage — Impulse Current Measurement — Forces in a Magnetic Field — Alternating Current Arc — Arc Quenching.- 3.12.2 Experiment.- 3.12.3 Evaluation.- Appendix 1 Safety Regulations for High-Voltage Experiments.- Appendix 2 Calculation of the Short-Circuit Impedance of Transformers in Cascade Connection.- Appendix 3 Calculation of Single-Stage Impulse Voltage Circuits.- Appendix 4 Calculation of the Impedance of Plane Conductors.- Appendix 5 Statistical Evaluation of Measured Results.- References.