IEEE 519 1981

$18.42

IEEE Guide for Harmonic Control and Reactive Compensation of Static Power Convertors

Published By	Publication Date	Number of Pages
IEEE	1981	54

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Description

New IEEE Standard – Inactive – Superseded. This guide applies to all types of static power converters used in industrial and commercial power systems. The problems involved in the harmonic control and reactive compensation of such converters are addressed, and an application guide is provided. Limits of disturbances to the AC power distribution system that affect other equipment and communications are recommended. This guide is not intended to cover the effect of radio frequency interference.

PDF Catalog

PDF Pages	PDF Title
9	1 IntroductionandScope 1.1 Introduction 1.2 Scope 2 Definitions and Letter Symbols 2.1 Definitions
11	2.2 Letter Symbols
13	3 References 3.1 Standards References 3.2 References 4 Converter Theory and Harmonic Generation 4.1 Introduction
14	Current and Voltage Wave Forms Delta Six.Phase Y Double Way
16	Relations Among Angles Used in Converter Theory
17	5 Reactive Power Compensation and Harmonic Control Techniques 5.1 Converter Power Factor Theoretical and Typical Values of Harmonic Current For a Six-Pulse Converter Relationship Between Distortion Displacement and Total Power Component
18	Total Power Factor of Six-Pulse and Twelve-Pulse Converters a = (Neglecting Transformer Exciting Current)
19	5.2 Reactive Power Compensation Reactive Power Versus dc Volts of Converter Effect of Reactive Power
20	Capacitors Switched in Binary Values Static VAR Control
21	Three-phase Diagram of One Bank of Capacitors Fig 12 Self Saturating Reactor Scheme
22	Power System Showing Harmonic Current and Voltage Influences
23	Problems and Control of Harmonics
24	6 Calculation Methods Calculation of Harmonic Currents 6.2 System Analysis Static Power Converter in Per-Unit of the Fundamental Current
25	Impedance Diagram of Power System
26	6.3 Telephone Interference Line Notching Calculations (For Low Voltage Systems) Fig 15 Three-phase Full Wave Converter
27	Voltage Notches Fig17 InductanceDiagram
28	6.5 Distortion Factor System Calculation (Low Voltage Below
29	6.7 Power Factor Improvement Calculation Typical Power System and Equivalent Diagram
30	7 Measurements Power-Reactive Triangle for Power Factor Correction
31	7.1 LineNotching Using Potential Transformer and Current Transformer
32	7.2 Harmonics 7.3 Telephone Interference
33	7.4 Flicker Power Factor Correction 8 Recommended Practices 8.1 LineNotching
34	Notch Depth Reduction Simplified Diagram Power Distribution System
35	Converter Connection to Distribution System
36	Power Factor Correction 8.3 Harmonics and Shunt Capacitance Reactances Low Voltage System Classification and Distortion Limits for 460 V Systems
37	Fig 25 Power System with Shunt Filters Fig26 Shuntpower Filter
38	8.4 Telephone Interference Typical Filter Configuration Versus System Size Voltage Distortion Limits for Medium and High Voltage Power Systems
40	for Six- and Twelve-Pulse Rectifiers 1960 Single Frequency TIF Values
41	1960 TIF Weighting Values Typical 1.T Values for 48 V dc Converters Typical 1.T Values for 48 V dc Ferroresonant Converters
42	8.5 Flicker Balanced I*T Guidelines for Converter Installations Tie (Supply) Lines
43	Maximum Permissible Voltage Fluctuations
44	9 Bibliography Books and General Discussion
45	Real and Wattless Power
46	Waveform Analysis and Measurement Techniques 9.4 Standards and Engineering Recommendations
47	Waveform Analysis and Means for Harmonic Suppression/Power Averaging
50	Effects on Components and Systems