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The rating of a circuit breaker are given by

• the MAXIMUM VOLTAGE in kV,
• the maximum continuous current CARRYING CAPACITY in amperes,
• the maximum interrupting capacity in MVA and kilo amperes (kA),
• the supply frequency 
• the MAKING capacity in amperes.

The rating of a circuit breaker are given by

• Low voltage circuit breakers are used in indoor CONTROL gears for controlling power consuming devices of circuits below rated voltage 1000 VOLT a.c. or 1200 volts d.c. whereas high voltage circuit breakers are used in both indoor and outdoor controllers in high voltage supply system.
• Low voltage circuit breakers operate frequently than the high voltage circuit breaker.
• Low voltage circuit breakers are more COMPACT than high voltage circuit breakers because of less PHASE to phase and phase to ground clearances.
• Testing REQUIREMENTS of a high voltage circuit breaker are quite different from those of low voltage circuit breakers.

(a) It is possible only when the breaker is TYPE tested at 60 HZ frequency, otherwise not.

(b) A 12 kV circuit breaker can use for any voltage up to its rated voltage under the CONDITION that the breaking current is within its breaking capacity.

(a) It is possible only when the breaker is type tested at 60 Hz frequency, otherwise not.

(b) A 12 kV circuit breaker can use for any voltage up to its rated voltage under the condition that the breaking current is within its breaking capacity.

Generally a.c. the circuit BREAKER is not suitable for d.c. SUPPLY LINE because of a.c. circuit breaker quenches arc easily at CURRENT zero of an alternating wave which is not possible in d.c. due to nonexistence of current zero.

Generally a.c. the circuit breaker is not suitable for d.c. supply line because of a.c. circuit breaker quenches arc easily at current zero of an alternating wave which is not possible in d.c. due to nonexistence of current zero.

DUE to NATURAL current zeros in ALTERNATING current WAVES interruption of an a.c. CIRCUIT becomes more easier.

Due to natural current zeros in alternating current waves interruption of an a.c. circuit becomes more easier.

The rate of RISING of RESTRIKING VOLTAGE DEPENDS upon the inductance and capacitance of the system.

The rate of rising of restriking voltage depends upon the inductance and capacitance of the system.

As the voltage RATING of circuit BREAKER corresponds to highest SYSTEM voltage so the circuit breaker to be used on 6.6 kV LINE should be of RATED voltage 7.2 kV and so on.

As the voltage rating of circuit breaker corresponds to highest system voltage so the circuit breaker to be used on 6.6 kV line should be of rated voltage 7.2 kV and so on.

The restriking VOLTAGE or the TRANSIENT recovery voltage is the voltage between the CONTACTS of a pole of the circuit BREAKER after the extinction of the ARCS while the transient state persists.

The restriking voltage or the transient recovery voltage is the voltage between the contacts of a pole of the circuit breaker after the extinction of the arcs while the transient state persists.

The recovery VOLTAGE is defined to be the r.m.s. the VALUE of the LINE voltage of SERVICE frequency that reappears across the poles of the CIRCUIT breaker short after arc extinction in all the poles and after damping of the transient phenomena.

The recovery voltage is defined to be the r.m.s. the value of the line voltage of service frequency that reappears across the poles of the circuit breaker short after arc extinction in all the poles and after damping of the transient phenomena.

No. Whatever MAY be the VALUE of base KVA the value of SHORT circuit CURRENT remains unchanged.

No. Whatever may be the value of base KVA the value of short circuit current remains unchanged.

As the VARIOUS equipment used in the POWER SYSTEM have different KVA rating with different PERCENTAGE reactances so for easy calculation it is necessary to find the percentage reactances of all equipment on a common KVA rating. This common KVA rating is known as base KVA.

As the various equipment used in the power system have different KVA rating with different percentage reactances so for easy calculation it is necessary to find the percentage reactances of all equipment on a common KVA rating. This common KVA rating is known as base KVA.

In a SYMMETRICAL fault since all the three conductors are SHORT circuit together causing equal fault currents to flow through the LINE then the symmetrical fault because more SEVERE.

In a symmetrical fault since all the three conductors are short circuit together causing equal fault currents to flow through the line then the symmetrical fault because more severe.

As the symmetrical fault is most severe in a three PHASE line and imposes the heavy duty on the control gear, THEREFORE, the CIRCUIT breaker is rated on the basis of symmetrical short circuit currents.

As the symmetrical fault is most severe in a three phase line and imposes the heavy duty on the control gear, therefore, the circuit breaker is rated on the basis of symmetrical short circuit currents.

The asymmetrical breaking current is the r.m.s. the value of the total current at the INITIAL instant of contact separation and is equal to the square root of the SUM of the squares of the symmetrical breaking current and of the DIRECT COMPONENT of the current at the same instant. The symmetrical breaking current is the r.m.s. the value of the symmetrical current (a.c. component of current) at the initial instant of contact separation. ACTUALLY, the rating of the breaker is specified in terms of symmetrical breaking current & voltage.

The asymmetrical breaking current is the r.m.s. the value of the total current at the initial instant of contact separation and is equal to the square root of the sum of the squares of the symmetrical breaking current and of the direct component of the current at the same instant. The symmetrical breaking current is the r.m.s. the value of the symmetrical current (a.c. component of current) at the initial instant of contact separation. Actually, the rating of the breaker is specified in terms of symmetrical breaking current & voltage.

the making current is normally SPECIFIED in PEAK VALUE.

Breaking current = 3000/(√3×33) KA = 52.48 KA

Making current = 2.55 × 52.48 = 133.82 KA.

the making current is normally specified in peak value.

Breaking current = 3000/(√3×33) KA = 52.48 KA

Making current = 2.55 × 52.48 = 133.82 KA.

To SELECT the MVA rating of the CIRCUIT breaker of a high voltage installation the fault level at the INCOMING point of supply must be known. POWER supply authority furnishes the fault level.

To select the MVA rating of the circuit breaker of a high voltage installation the fault level at the incoming point of supply must be known. Power supply authority furnishes the fault level.

“Short CIRCUIT MVA” is the rupturing capacity or breaking capacity of a circuit BREAKER in case of a three PHASE symmetrical fault which determines the size of the circuit breaker. The breaking capacity of a circuit breaker is specified EITHER in terms of symmetrical breaking current/MVA or ASYMMETRICAL breaking current/MVA.

“Short Circuit MVA” is the rupturing capacity or breaking capacity of a circuit breaker in case of a three phase symmetrical fault which determines the size of the circuit breaker. The breaking capacity of a circuit breaker is specified either in terms of symmetrical breaking current/MVA or asymmetrical breaking current/MVA.

1. The ‘Making CURRENT’ of a circuit breaker is the TOTAL MAXIMUM current peak which occurs during the first cycle immediately after the circuit is closed on a short circuit.
2. The ‘Breaking Current’ of a circuit breaker is the total maximum current peak that can be safely broken by the circuit breaker at the TIME of separation of the contacts at its rated VOLTAGE.

Rupturing capacity of a circuit breaker means the maximum power a circuit breaker can interrupt under a fault. It is usually expressed in Mega VOLT AMPERE (MVA) and it is then the product of the rated breaking CURRENT in kilo amperes and rated voltage expressed in kilo volts.

Rupturing capacity of a circuit breaker means the maximum power a circuit breaker can interrupt under a fault. It is usually expressed in Mega volt Ampere (MVA) and it is then the product of the rated breaking current in kilo amperes and rated voltage expressed in kilo volts.

Some of the duties of the circuit breakers are listed below:

• Interruption of small INDUCTIVE currents
• Switching of unloaded transmission lines and unloaded cables
• Switching of capacitor banks and REACTORS
• Interruption of terminal FAULTS
• Interruption of SHORT line faults
• Asynchronous switching

Some of the duties of the circuit breakers are listed below:

Answer :For Exta HIGH VOLTAGE (EHV) applications SF6 gas INSULATED switchgear is preferred.

ANSWER :The current CHOPPING is considered as SERIOUS drawback because it sets up high voltage transient across the BREAKER contacts.

ANSWER :Copper-Bismuth, Copper-lead, Copper-tellurium, Silver-bismuth, Silver-lead and Silver-tellurium are some of the alloys employed as CONTACT MATERIALS in the vacuum CIRCUIT breakers.

Answer :Current chopping is not COMMON in oil CIRCUIT BREAKERS because in most of the oil circuit breakers the ARC extinguishing power is proportional to the MAGNITUDE of current to be interrupted.

Answer :The making capacity of the circuit breaker when closed on a SHORT circuit is the peak value of the maximum current wave (INCLUDING DC COMPONENT) in the FIRST cycle of the current after the circuit is closed by the circuit breaker.

Answer :Switch is just a device when can be able to open and close the CIRCUIT during normal operation. Whereas on the other HAND circuit breaker has the ability to open and close the contacts during abnormal or fault CONDITIONS. Thus circuit breaker has the potential to break and make heavy short circuit currents. Auto-reclosures in the circuit beaker has the ability to re-close after certain designed duration to VERIFY whether the short circuit was cleared.

Answer :Circuit BREAKER is a MECHANICAL device designed to close or open contact members, thus closing or OPENING an ELECTRICAL circuit under the normal or abnormal conditions.