Introduction to Protective Device Coordination Analysis
In Introduction to Protective Device Coordination Analysis, you'll learn ...
- Basic theory behind protective device coordination studies
- How overcurrent and earth fault protection device coordination is achieved
- Commercial software modeling techniques, simulation performance and interpretation of the results
The objective of a protection scheme in a power system is to minimize hazards to personnel and equipment while allowing the least disruption of power service. Coordination studies are required to select or verify the clearing characteristics of devices such as fuses, circuit breakers, and relays used in the protection scheme. These studies are also needed to determine the protective device settings that will provide selective fault isolation. In a properly coordinated system, a fault results in interruption of only the minimum amount of equipment necessary to isolate the faulted portion of the system. The power supply to loads in the remainder of the system is maintained. The goal is to achieve an optimum balance between equipment protection and selective fault isolation that is consistent with the operating requirements of the overall power system.
Short-circuit calculations are a prerequisite for a coordination study. Short-circuit results establish minimum and maximum current levels at which coordination must be achieved and which aid in setting or selecting the devices for adequate protection. Traditionally, the coordination study has been performed graphically by manually plotting time-current operating characteristics of fuses, circuit breaker trip devices, and relays, along with conductor and transformer damage curves—all in series from the fault location to the source.
This course reviews the subject of protective device coordination in a very structured fashion. First, modelling technique is shown for a generic power system, protective relays are modelled in, details and relay settings are determined based on short circuit current calculations. A detailed explanation of modelling and calculation procedure is offered. Explained techniques can be implemented in any commercial power system software package.
Specific Knowledge or Skill Obtained
This course teaches the following specific knowledge and skills:
- Basics of coordination
- Computer programs for coordination
- Common structure for computer programs
- How to make use of coordination software
- Verifying the results
- Equipment needs
- Practical example
Certificate of Completion
You will be able to immediately print a certificate of completion after passing a multiple-choice quiz consisting of 28 questions. PDH credits are not awarded until the course is completed and quiz is passed.
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