高電壓技術專業英語閱讀教程

《高電壓技術專業英語閱讀教程》以專業辭彙學習和專業知識探索為主線條，編撰了高壓技術基礎知識和技術的專業英語文集，其中包括氣、液、固態及複合電介質放電機理，高電壓試驗技術，高電壓設備知識，極端條件下電介質放電現象研究，以及氣體放電過程的非線性動力學現象等。

　　《高電壓技術專業英語閱讀教程》力爭涵蓋本專業的英語辭彙並儘可能為增強專業知識提供專業前沿信息，可作為高等院校電氣工程類高電壓技術專業的高年級學生及研究生的專業英語閱讀教材，也可供從事高電壓電介質放電現象研究的科技人員與高壓電氣絕緣配合及結構設計的工程技術人員參考。

Unit 1 Gas Discharge Phenomena

1.1 Classification of Discharges

1.2 Current-voltage Characteristics of DC Discharge

1.2.l Non-self-sustaining Discharge

1.2.2 Townsend Discharge

1.2.3 Glow Discharge

1.2.4 Transition to Arc Discharge

1.3 Townsend Breakdown

1.4 Production and Loss of Charges in a Gas

Unit 2 Non-Destructive High-voltage Tests

2.1 Loss in a Dielectric

2.2 Measurement of the Conduction Current for Direct Voltage

2.3 Measurement of the Dissipation Factor for Alternating Voltage

2.3.1 Dielectric Loss and Equivalent Circuits

2.3.2 Measurement with the Sobering Bridge

2.4 Measurement of Partial Discharges at Alternating Volfages

2.4.1 External Partial Discharges

2.4.2 Internal Partial Discharges

Unit 3 Liquid and Composite Dielectrics

3.1 Liquid Characteristics

3.2 Solid Dielectrics

3.3 Composites

3.4 Estimation ancl Control of Electrical

3.5 Electric Fields

3.6 Uniformanci Non-Uniform Electric Fielcis

3.7 Estimation of Electric Field in Some Geometric Boundaries

3.7.1 Parallel Plates

3.7.2 Concentric Cylinders

3.7.3 Parallel Cylinders of Equal Diameter

3.8 Surge Voltages, Their Distribution Anti Control

Unit 4 Breakdown in Air Gaps with Solid Insulating Barrier under Impulse Voltage Stress

4.1 Introduction

4.2 The First Approach for the Understanding of the Barrier Effect

4.3 Barriers with Opening

4.4 In Depth Investigation of the Breakdown Process

4.5 Quantitative Analysis of Spaces Charges

4.6 Flashover Around the Barrier without Penetration

4.7 Barrier Effect in Symmetric Fields

4.8 Investigations with Other Types of Voltages

4.9 Conclusions

Unit 5 Specialized Knowledge of Cables

5.1 Material Technology

5.2 Conductor and Insulation Screens

5.3 Cable Design

5.4 Manufacturing

5.5 Installation Design

5.6 Joints/Terminations

5.7 Minute Step Voltage Test

Unit 6 Treeing Phenomena of XLPE Cable

6.1 Introcluction

6.2 Failures ofXLPE Cable

6.3 Treeing Phenomena in XLPE Cables

6.4 Electrical Trees and Mechanisms

6.5 Water Treesand Mechanisms

Unit 7 Specialized Knowledge of Power Transformers

7.1 Features

7.2 Core

7.3 Winding

7.3.1 Hisercap Disk Winding (Interleaved Disk Winding)

7.3.2 Continuous Disk Winding

7.3.3 Helical Coil

7.4 Insulation Structure

7.5 Prevention of Internal Partial Discharge and Insulation

7.5.1 Treatment

7.5.2 Drying/Oil Filling Treatment

7.5.3 Removing Voids

7.5.4 Electric Field Control

7.5.5 Dust Control

7.6 Measures against Leakage Flux

7.7 Tank

7.8 Cooling System

7.8.l Self-cooled Type

7.8.2 Air-cooled-air-cooled

7.8.3 Forced-oil, Forced-air-cooled Type

7.8.4 Forced-oil, Water-cooled Type

7.9 Accessories

7.9.1 Oil Preservation System

7.9.2 Diaphragm-type Oil Preservation System (Type OH-D)

7.9.3 Dehydrating Breather (Types FG, FP, FS)

7.9.4 Dial Oil Level Indicator

7.9.5 Protective Relays

7.9.6 Buchholtz Relay

7.9.7 Liquid Temperature Indicator

7.9.8 Winding Temperature Indicator Relay

7.9.9 Pressure Relief Device

7.10 Low-noise Transformer

7.11 Construction of Cable Connection and GIS

7.11.1 Connection Cable Connection

7.11.2 GIS (Gas Insulated Switchgear) Connection

7.11.3 Transportation

Unit 8 Investigation of Sub-Nanosecond Breakdown through Computational Methods,

8.1 Introduction

8.2 Background Theory and Prior Research

8.2.1 Background Discharge Regimes in Pulsed Breakdown

8.2.2 Townsend Regime

8.2.3 Streamer Regime

8.2.4 Post Streamer Regime

8.3 Physical Processes in Picosecond Breakdown

8.3.1 Field Emission

8.3.2 Electron-Neutral Collisions

8.3.3 Runaway Electrons

8.3.4 Explosive Electron Emission

8.4 Recent Research Efforts

Unit 9 Numerical Simulation of Gas Discharge

9.1 Governing Equations

9.1.1 Two-Fluid Theory

9.1.2 Coefficients

9.1.3 Boundary Conditions

9.2 Model Eauations in Dimensionless Form

9.2.1 Numerical Approach and Results

9.2.2 Grid and Discretization

9.2.3 8-Method

9.2.4 Time Step and Iteration

9.2.5 Boundary Conditions and Error

9.3 One Dimensional Model

9.3.1 Thomas Algorithm and Results

9.3.2 Two Dimensional Model

9.3.3 Successive Over Relaxation Method

9.3.4 Results

9.3.5 Convergence

9.4 Dynamic Characteristics of SF6-N2-CO2 Gas Mixtures in DC Discharge Process

9.4.1 The Hybrid Computing Model

9.4.2 Development of the Avalanche and Streamer

9.4.3 Spatial Electric Field and Electron Velocity

9.4.4 Influence of Photoionization

Unit 10 Pattern Dynamics in a Two-dimensional Gas Discharge System

10.1 Introduction

10.2 Experiment

10.3 Model

10.3.1 Assumption

10.3.2 Specific Model

10.3.3 Constraint for the Constant Total Charge

10.3.4 Flowing Charge Density

10.3.5 Parameter Setting

10.4 Phenomena

10.4.1 Preparation: Behavior of Each Element Under the Global Constraint

10.4.2 Global Phase Diagram

10.4.3 DS Phase

10.4.4 LS Phase

10.4.5 Moving Spot Phase

10.5 Summary and Discussion

10.5.1 Summary

10.5.2 Comparison with the Experiment by Nasuno

10.5.3 Discussion

附錄1 高電壓技術常用辭彙中英文對照

附錄2 絕緣介質電特性中英文對照

附錄3 美國工程索引(EI)對文摘的要求

參考文獻