1 / 10

Power System Analysis/ Power System 1 EEE 4113/ EEE 3131

Power System Analysis/ Power System 1 EEE 4113/ EEE 3131. Protective Relay Lecture taken By Kazi Md. Shahiduzzaman Lecturer, EEE, NUB. Outline of this chapter. To Define the protective relay The working principle of protective relay The fundamental requirements of protective relay

zuri
Télécharger la présentation

Power System Analysis/ Power System 1 EEE 4113/ EEE 3131

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Power System Analysis/ Power System 1EEE 4113/ EEE 3131 Protective Relay Lecture taken By Kazi Md. Shahiduzzaman Lecturer, EEE, NUB

  2. Outline of this chapter • To Define the protective relay • The working principle of protective relay • The fundamental requirements of protective relay • Get a Brief knowledge about different types of protective relay

  3. Protective Relay Definition: A protective relay is a device that detects the fault and initiates the operation of the circuit breaker to isolate the defective element from the rest of the system.

  4. Working Principle: A typical relay circuit is shown in the diagram. This diagram shows one phase of 3-phase system for simplicity. The relay circuit connections can be divided into three parts viz. (i) First part is the primary winding of a current transformer(C.T.) (ii) Second part consists of secondary winding of C.T. and (iii) Third part is the tripping circuit which may be either a.c.

  5. Fundamental requirements • Selectivity: It is the ability of the protective system to select correctly that part of the system in trouble and disconnect the faulty part without disturbing the rest of the system. • Speed • Sensitivity: It is the ability of the relay system to operate with low value of actuating quantity. • Reliability: It is the ability of the relay system to operate under the pre-determined conditions. • Simplicity: The relaying system should be simple so that it can be easily maintained. • Economy: The most important factor in the choice of a particular protection scheme is the economic aspect.

  6. Induction type overcurrent relay To trip circuit Construction : • It consists of a metallic (aluminum) disc • The upper electromagnet has a primary and a secondary winding. • The tappings are connected to a plug-setting bridge. • The secondary winding is energized by induction from primary and is connected in series with the winding on the lower magnet. • The controlling torque is provided by a spiral spring. • The spindle of the disc carries a moving contact which bridges two fixed contacts (connected to trip circuit) when the disc rotates through a pre-set angle. From C.T.

  7. To trip circuit Operation: • The driving torque is set up due to the induction principle . • This torque is opposed by the restraining torque provided by the spring. • Under normal operating conditions, the aluminum disc remains stationary. • If the current in the protected circuit exceeds the pre-set value, the driving torque becomes greater than the restraining torque. • The disc rotates and the moving contact bridges the fixed contacts when the disc has rotated through a pre-set angle. • The trip circuit operates the circuit breaker which isolates the faulty section. From C.T.

  8. Distance or Impedance Relay This type of relay in which the operation is governed by the ratio of applied voltage to current in the protected circuit. • The relay will operate when the ratio V/I is less than a predetermined value. • The basic principle of operation of an impedance relay is illustrated by the figure. • The voltage element of the relay is excited through a potential transformer (P.T.) from the line to be protected. • The current element of the relay is excited from a current transformer (C.T.) in series with the line. • The portion AB of the line is the protected zone. • Under normal operating conditions, the impedance of the protected zone is ZL. • The relay is so designed that it closes its contacts whenever impedance of the protected section falls below the pre-determined value i.e. ZL in this case. • Now suppose a fault occurs at point F1 in the protected zone. The impedance Z (= *V/I) between the point where the relay is installed and the point of fault will be less than ZL and hence the relay operates. Type: There are two types of distance relays in use for the protection of power supply, namely ; (i) Definite-distance relay (ii) Time-distance relay

  9. Differential relay A differential relay is one that operates when the phasor difference of two or more similar electrical quantities exceeds a predetermined value. • Under normal operating conditions, the two currents are equal. • But as soon as a fault occurs, this condition no longer applies. • If this differential current is equal to or greater than the pickup value, the relay will operate and open the circuit breaker to isolate the faulty section. There are two fundamental systems of differential or balanced protection: Current balance protection Voltage balance protection

  10. Thank you

More Related