5 ways that motor circuit breakers provide optimal protection for motors

It’s estimated that there are more than 300 million electric motors in the world being used in industry, infrastructure, and large buildings, with electric motor-driven systems (EMDS) accounting for between 43-46% of all global electricity consumption. Motors drive everything from processes, to commercial heating, ventilating, cooling, and refrigeration. With business productivity so dependent on them, it’s important that they’re properly protected.

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In most jurisdictions, motor protection is mandatory, so OEM machine builders and electrical contractors will ensure that there is a circuit breaker used on each motor circuit. If the proper type of motor circuit breaker is selected, the motor will be adequately protected.

Unfortunately, there are many examples in which a standard electrical distribution circuit breaker was chosen for this purpose. These breakers are typically selected because they are lower cost. But they are designed to protect standard types of circuits and loads, not motors. If such a breaker is used, there is a very high risk of motor damage, disruption and downtime for the end-customer, and fire.

Here are five critical reasons behind why a dedicated motor circuit breaker should be used to protect a motor, not a distribution circuit breaker. Please note that, in some cases, I am referring to IEC standards and application, which may not be appropriate for use within NEC, CEC, or other standards jurisdictions.

1.    Risk of nuisance tripping during motor startup

When a motor starts up, it draws current up to 10 times its rated value. This can last up to 30 seconds until it reaches its steady speed. Distribution circuit breakers typically have a magnetic threshold set at 8 times the rated current, or less. When current exceeds this threshold, the breaker identifies it as a short-circuit event on the distribution and trips immediately. For a motor, this type of overcurrent can simply represent regular starting up current. So you can see that a distribution circuit breaker used to protect a motor will very likely, and undesirably, trip when the motor starts up.

In contrast, dedicated motor circuit breakers are designed with their short-circuit trip threshold set much higher, usually 13 times the rated current. This avoids the risk of tripping during the motor startup phase.

To save money while avoiding the risk of tripping on motor startup, some contractors may select an overrated distribution circuit breaker, i.e. one with a higher threshold. Let’s use the example of a 7.5 kW motor with 16 A rated current, and startup current likely to reach 160 A. In this case, the contractor may choose a distribution circuit breaker rated at 25 A, with a magnetic threshold of around 200 A, so that motor startup will not immediately trip the circuit breaker. However, there is the serious risk if the motor becomes overloaded during regular operation, reaching a current of up to 24 A, the 25 A rated breaker will not trip and the motor will be in serious risk of being destroyed after only a couple of minutes.

Note that, in the next few years, IE3/IE4 high-efficiency motors will become mandatory in many regions. When using direct starters, these motors will have higher starting current that today’s motor designs. This will make it even more important to choose the correct type of circuit breaker to protect these motors.

2.    Risk of nuisance tripping due to a transient overload

Electrical distribution circuit breakers are designed to protect cables. Their overload tripping times are set according to overcurrent withstand of cables, which is usually shorter than that of motors. So distribution breakers are likely to trip before the situation becomes dangerous for a motor. Keep in mind that motor protection relays, and dedicated motor electronic trip units, offer options to configure even slower overload protection for classes 10A, 10, 20, and 30.

3.    Risk of nuisance tripping due to high ambient temperature

Most distribution circuit breakers are designed to operate under 30 °C, or in some cases under 40 °C. If ambient temperature exceeds this rating, the breaker will trip at a lower current than its rating, unnecessary interrupting a process.

In contrast, motor circuit breakers are set for operation under 60 °C, or optionally 65 °C. So, a 10 A rated motor circuit breaker, protecting a 10 A rated motor will not trip when current is 10 A and ambient temperature is 60 °C. In this way, machines and operations keep running while motors are still properly protected.

4.    Risk of motor damage due to a phase fault

A phase fault can happen for many reasons: wiring errors after maintenance, loose connections, a utility phase loss, or even motor aging. Distribution circuit breakers are not equipped to trip in case of phase unbalance or phase loss, as these common conditions pose no hazard to distribution networks. But a phase fault is a critical event for motors, causing mis-operation (e.g. speed deviations) or the motor to overheat and eventually be damaged.

Motor circuit breakers are designed to trip when sensing a phase fault. This will occur after a couple of seconds when the motor is running at regular speed, or after only a few tenths of seconds when it’s starting up.

5.    Risk of contactor damage and fire due to short-circuit

The international standard for safety of machinery, EN -1, requires at least Type 1 coordination between a circuit breaker and a contactor, in the case of a short circuit. Distribution circuit breakers are usually not tested in coordination with contactors; therefore, there’s no performance guarantee of the combination. This means that if a short circuit occurs, the contactor can be destroyed and, worse, the amount of energy dissipated by the contactor during the interruption process can burn surround materials or ignite a fire.

With motor circuit breakers, short-circuit coordination can easily be selected: Type 1 ensuring no damage around the contactor, or Type 2 ensuring the contactor can still operate after the short-circuit event.

So you can clearly see, choosing a motor circuit breaker is critical to properly protecting motors and the installation. If you’re an OEM, you may not always know in what kind of environment your machines will be installed. To maintain your customer’s perception of quality, you need to ensure that your motors and machines are operating reliably under all conditions. During warranty periods and beyond, you need to make sure motors are protected while delivering the performance you promised. Having the right type of circuit breaker can be the difference between normal motor maintenance or costly substitution, and between continuous operation or costly disruption to your customer’s productivity, or even a catastrophic fire.

Industrial circuit breakers are critical components in electrical systems, providing protection against faults such as overloads, short circuits, and electrical surges. Ensuring the safety and reliability of these breakers is paramount, as they safeguard both personnel and equipment in industrial environments. This article highlights the essential safety features that are needed for industrial circuit breakers.

1. Overload Protection

Functionality: Overload protection ensures that the circuit breaker trips when the electrical load exceeds the safe operating limits, preventing overheating and potential fires.

Key Features:

• Thermal Trip Mechanism: Uses a bimetallic strip that bends when heated by excessive current, triggering the trip.
• Adjustable Settings: Allows customization of the trip threshold to match specific operational requirements.

2. Short Circuit Protection

Functionality: Short circuit protection provides immediate interruption of electrical flow in the event of a short circuit, preventing damage to the electrical system and associated equipment.

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Key Features:

• Magnetic Trip Mechanism: Utilizes an electromagnet to trigger the trip when a high current surge is detected.
• High Interrupting Capacity: Ensures the circuit breaker can safely interrupt large fault currents without damage.

3. Ground Fault Protection

Functionality: Ground fault protection detects unintentional paths to ground, which can cause electrical shock and equipment damage, and trips the breaker to interrupt the fault.

Key Features:

• Residual Current Device (RCD): Monitors the difference between the live and neutral currents, tripping the breaker if an imbalance is detected.
• Sensitive Detection: Capable of detecting low-level ground faults to ensure maximum safety.

4. Arc Fault Protection

Functionality: Arc fault protection identifies and mitigates the dangerous conditions caused by arcing faults, which can lead to electrical fires.

Key Features:

• Arc Fault Circuit Interrupter (AFCI): Detects arcing conditions and trips the circuit breaker to prevent fires.
• Advanced Sensing Technology: Uses pattern recognition to differentiate between harmless arcs (like those from a switch or motor) and dangerous ones.

5. Under Voltage Protection

Functionality: Under voltage protection ensures that the circuit breaker trips when the voltage drops below a predefined threshold, preventing damage to sensitive equipment.

Key Features

• Voltage Sensing Mechanism: Continuously monitors voltage levels and trips the breaker if the voltage falls below a safe limit.
• Adjustable Thresholds: Allows customization to accommodate different equipment requirements.

6. Overvoltage Protection

Functionality: Overvoltage protection trips the circuit breaker when the voltage exceeds a safe level, protecting equipment from damage caused by voltage spikes.

Key Features:

• Surge Protection Devices (SPDs): Absorb and dissipate excess voltage, preventing it from reaching sensitive components.
• Transient Voltage Suppression: Quickly responds to voltage spikes to protect connected equipment.

7. Remote Monitoring and Control

Functionality: Remote monitoring and control features allow operators to monitor the status of circuit breakers and control them from a central location, enhancing safety and operational efficiency.

Key Features

• Digital Communication Interfaces: Enable integration with supervisory control and data acquisition (SCADA) systems.
• Remote Trip and Reset Capabilities: Allow operators to trip or reset circuit breakers remotely, reducing the need for physical intervention.

8. Mechanical Interlocks

Functionality: Mechanical interlocks prevent simultaneous closing of breakers in certain configurations, ensuring safe operation and preventing equipment damage.

Key Features:

• Key Interlocks: Ensure that certain operations can only be performed in a specific sequence, enhancing operational safety.
• Locking Mechanisms: Physically prevent the breaker from closing if certain conditions are not met.

9. Dual Rating

Functionality: Dual rating allows circuit breakers to operate effectively under different conditions, ensuring safety across various operational scenarios.

Key Features:

• AC and DC Ratings: Ensure the breaker can safely handle both alternating current (AC) and direct current (DC) applications.
• Temperature Compensation: Adjusts the trip settings based on ambient temperature, ensuring consistent protection.

10. Diagnostic and Testing Features

Functionality: Diagnostic and testing features allow for regular inspection and testing of circuit breakers to ensure they function correctly and safely.

Key Features:

• Self-Diagnostic Capabilities: Continuously monitor the health and performance of the breaker, alerting operators to potential issues.
• Built-In Test Functions: Enable routine testing of the breaker’s functionality without removing it from service.

Conclusion

Industrial circuit breakers must incorporate a comprehensive array of safety features to ensure the protection of both personnel and equipment. Overload and short circuit protection, ground fault and arc fault detection, voltage protection, remote monitoring, mechanical interlocks, dual rating capabilities, and diagnostic features are all essential components that contribute to the safe and reliable operation of industrial electrical systems.

By integrating these safety features, industrial circuit breakers can effectively prevent electrical hazards, reduce the risk of equipment damage, and ensure compliance with safety standards, ultimately fostering a safer and more efficient working environment.

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