Molded Case Circuit Breaker

MOLDED CASE CIRCUIT BREAKER

Circuit breakers are electrical devices that offer protection against fault current. They use different medium to safely extinguish the arc such as air, oil, SF6 or vacuum etc. MCCB or Molded Case Circuit Breaker uses air as the dielectric medium to break a circuit. Air has a low dielectric strength as opposed to other mediums that is why it is used for protection in low voltage circuits.

Molded Case Circuit Breaker or MCCB is an automatic electrical device. It is a type of circuit breaker that protects the circuit from overloading, short circuit and current surges. It is an advanced version of miniature circuit breaker MCB since it operates like one. However, it offers extra features that make it a superior circuit breaker such as remote closing and adjustable trip settings i.e. its current settings and time settings can be adjusted according to our needs.

MCCB is used to protect the low voltage distribution system. It is available in rating up to 2500 Amps and 1.1 kV.

Construction of Molded Case Circuit Breaker

An MCCB is made from the following main parts each one explained in detail

1. Arc chute

2. Contacts

3. Operating mechanism

4. Terminal Connector

5. Thermal Trip Unit

6. Magnetic Trip Unit

7. Handle / Trip-free Mechanism

8. Trip Button

Below are the brief details of each mechanism used in a typical MCCB.

1. Arc Chute

Arc chute is a set of parallel metal plates that are mutually insulated from each other. it helps in extinguishing the arc by splitting the arc and lengthening it. it is also known as an arc divider or arc splitter. These plates are made of ferromagnetic material.

2. Contacts

Contacts are the metallic conductors that are responsible for carrying the current to the load. There are two types of contacts i.e. fixed and moving contact. The contacts are made of arc resistance material having low resistivity and corrosion. The quality of the material decides the lifetime of the circuit breaker.

3. Operating Mechanism

It is the mechanism of MCCB responsible for opening and closing the current-carrying contacts. it is connected with trip unit that triggers the operating mechanism. The trip unit operates on a thermal and magnetic mechanism.

4. Terminal Connector

The terminal connectors are used to connect the MCCB to the external circuit. The to a upper terminals are connected to the output/load while the bottom terminals are connected to the input/supply. Although they are bidirectional, the input and output designation is due to their physical installation

5. Trip Unit

It is the unit responsible to trigger the operating mechanism. The trip unit includes a thermal mechanism for overload, magnetic tripping for short circuits and a test button for testing.

6. Thermal Trip Unit

The thermal trip unit uses a thermal mechanism that is a bimetallic strip that bends (and opens the contacts) when the temperature rises due to the overloading.

7. Magnetic Trip Unit

The magnetic trip unit has a relay that generates a magnetic field when higher currents flow through its solenoid due to the short circuit. it trips the circuit breaker. While the test button is used to simulate the above-said mechanisms and test the response of the circuit breaker.

8. Handle / Trip-free Mechanism

It is a handle used to open or close the breaker manually. It is also known as a trip- free mechanism because it will trip even if the handle is held in ON position.

The handle could be in either three positions i.e. upward, middle or downward. If the abo handle is in upward position, it is ON position. If it is in the middle position, the breaker has been tripped while the downward position shows OFF status.

9. Trip Button

The trip button is used for testing the breaker. It is a red-colored button that trips the operating mechanism when pushed.

Function of MCCB

MCCB as it is an electrical protection device has the following functions

1. Protection against Overloading

Overloading is the condition when the current exceeds a predetermined limit for a specific duration of time. The overloading current can damage the equipment, wirings and can create fire hazards. MCCB offers protection against overloading using a bimetallic strip.

2. Protection against Short Circuit

A short circuit is a condition when the live wire comes into contact with each other 976 or with a neutral wire. It can occur due to downed lines or broken or exposed wires or deteriorated insulation of wires. The current flow due to the short circuit is very large and very destructive.

Short circuit current must be interrupted in the shortest period of time. MCCB can trip short circuit current up 200k amps in the duration of 0.04 seconds.

3. Manual Switching

The MCCB can also perform manual switching to switch ON/OFF the power supply to the circuit connected. It can de-energize the circuit in case of maintenance.

Working Principle of MCCB

An MCCB protects a circuit from fault current. It uses thermal and magnetic mechanisms to break those fault currents. The thermal mechanism is used for overload protection while the magnetic mechanism is used for short circuit protection

1. Overload Protection

Overload occurs when the current exceeds a limit for a prolonged duration. MCCB has a thermal mechanism that contains a bimetallic contact to protect from overload. A bimetallic strip is made from two different types of metal having different rates of thermal expansion. Upon temperature change, the strip bends or contracts.

The main current passes through the bimetallic strip. If the current exceeds a certain limit, the contacts heat up and expand. Due to different expansion rates, the strip bends and trips the circuit.

In electrical devices, the current can overload for short durations of time, it is normal and should not be considered as fault current. Therefore, MCCB has a time delay that allows the overload current for a short duration of time before tripping the circuit.

2. Short Circuit Protection

MCCB protects against a short circuits using a solenoid that produces electromagnetic force. The main current flows through the solenoid that attracts and repels a plunger responsible for tripping the breaker. If the current remains below the threshold, the solenoid produces a weak magnetic force that cannot attract the plunger. In short circuit conditions, a very high current flows through the solenoid that generates a very strong magnetic force. It attracts the plunger that trips the circuit.

Types of MCCB

As MCCB are advanced versions of MCB, they are also classified like them based on the tripping curves.

Type B MCCB:

These MCCB trips at current 3 to 5 times its rated current with tripping time of 0.04 to 13 seconds. These are the 2nd most sensitive types of MCCB after type Z as they can tolerate very small surges. It must not be used in places having normal low surges. It will frequently trip even in normal conditions. They are used for resistive loads and other resistive elements.

Type C MCCB:

Such MCCB trips at current surges 5 to 10 times its rated current with tripping time of 0.04 to 5 seconds. As they can tolerate higher surges than type B, they are used for small inductive loads such as small motors, transformers and electromagnets used in industries.

Type D MCCB:

Type D MCCB trips at current 10 to 20 times its rated current with a tripping time of 0.04 to 3 seconds. They can tolerate the highest surges; therefore, they are used for highly inductive loads having very high inrush current such as large electrical motors in industries.

Type K MCCB:

Type K MCCB trips at 10 to 12 times its rated current with a tripping time of 0.04 to svile 5 seconds. They are used for inductive loads such as motors with high inrush current.

Type Z MCCB:

Type Z MCCB is the most sensitive MCCB as they trip at 2 to 3 times its rated smil current. They are used for sensitive semiconductor-based medical or other expensive Har equipment that is vulnerable to low current surges.