• slidebg1
    A State of the Art Trainning Solutions.
  • slidebg1
    Internationally recognized health and safety qualifications.
  • slidebg1
    Covering a wide range of disciplines and industries.


Electrical Engineering

Modern Electrical Power Systems

Introduction

The course starts by reviewing current practice to establish a sound understanding of the underlying principles of power system transmission, distribution, operation, and control. Next are considered the developments that are taking place as a result of new forms of generation, load interconnection, fault level limitation and numerous advances in system innovation.

The manner in which the new technologies are implemented is related to geographical location, sites requiring additional power, government strategy and technical motivation for change. Not all power systems will advance at the same rate, but all will take advantage of the benefits of technology to a greater or lesser extent, thus improving the overall electrical efficiency.

The course aims to make candidates aware of improvements that technological advances makes possible and to consider implementing these on their system, whether it be a utility, a large end-user, or an industrial islanded system. Asset management, DSM, non-linear loads, harmonics and on line diagnostics of the plant are also considered, as are ways of improving the utilization and efficiency of system plant.


Objectives

Delegates will gain a detailed appreciation of the following:

  • The operation and power flow characteristics of small large networks and how the network can be arranged to deliver more ‘real power’ over the transmission system to the load centers
  • The form and use of a range of FACTS devices to improve system operation
  • Fault level limiting devices
  • New CT and VT optical transducers and protection relaying system using microprocessor configured relays
  • To deal with non-linear loads and the problem of Harmonics, at the PCC (point of common coupling)
  • Protection systems for thermal monitoring of cable networks
  • Alternative forms of generation and embedded generation. Carbon emission limiting, etc.
  • Diagnostic monitoring of plant and in particular GIS substations
  • Advances in power electronics and the application of back to back HV-DC links on stability
  • High-speed fault limiters and real-time stability monitors
  • Demand-side management

Target Audience

This course is Participants those involved with the planning, operation, and maintenance of small to large scale power networks. Designers, Engineers, and Technicians from Distribution Companies, Power Utilities, Engineering Professionals in the Electricity Supply Industry and Petrochemical Companies who have to deal with aspects of generation, transmission and distribution should be interested in learning how to handle the increased demand.


Electrical Engineering Outline

The course covers the following topics:

Introduction

  • Overview of a typical systems covering generation, transmission and distribution
  • Determination of flow of real and reactive power
  • Determination and control of fault level
  • Control of reactive power and voltage
  • Control of active power and system frequency
  • The requirements for reactive compensation voltage profiles
  • Quality of supply

Current Operational Problems

  • Coping with rising demand for power transmission and distribution
  • The costs associated with increasing fault level
  • Catering for increasing load on the existing system ratings of plant
  • Monitoring of plant conditioning. temperature
  • A review of analytical methods and demonstration of software for optimizing system operation
  • Increasing problems of heavily loaded systems, stability, voltage dips

Introduction to System Operation

  • Active Power and Frequency Control - automated
  • Voltage Control and Reactive Power Requirements automated
  • Generation, including combined cycle and small embedded generators
  • Transmission voltage levels - line and cable design, power loading and de-rating for temperature effects

Emerging technologies

  • Energy and the Environment - solar power, geothermal power, etc. CO2 and its impact on the world
  • ‘Green’ generation? Is it possible on a large scale or are there stability problems?
  • Demand Side Management remote load control minimizing demand optimizing transmission coping with dips and swells
  • Optical Current Transducers for Protection
  • High Voltage Applications - Surge protection, current limiters network switching, etc

Advances in control and monitoring

  • Power Electronics Applied to Power Systems
  • Flexibility in AC Systems
  • Static Var Compensation
  • Series Controlled Capacitors
  • Changing maintenance schedules, remote surveillance of plant and the introduction of unmanned substations
  • Data logging

Making the system work harder

  • Power Dynamics Management the low frequency oscillation
  • Advanced protection and Control Techniques
  • Is - Fault Current Limiter how to apply
  • Diagnostics partial discharge techniques
  • Optical cable temperature monitoring
  • SCADA and artificial intelligence systems for fault diagnostics

System protection

  • Digital and Micro Processor Protection
  • Electrical Insulation
  • Condition Monitoring of Plant
  • Appendix - Characteristics of a Power Network - Review for the Future

  
  

Ref Location From To Cost
EE01 Kuwait 5-1-2020 9-1-2020