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How power quality issues affect the plant and how to get rid of them for good

6 Oct 2020 | Power quality

Poor power quality could be costing you, shortening the life of your equipment, tripping your automated equipment, and producing extraneous heat that must be removed. To make things worse, poor power quality could be originating inside your plant.

The many faces of power quality issues

The electrical power issues that most frequently affect industrial plants include voltage sags (or dips) and swells, harmonics, transients, and voltage and current unbalance. The proper tools to correct these issues include knowledge and electrical test instruments ideally suited for each task.

You also need an accurate one-line diagram of the facility. The one-line diagram identifies the ac power sources, the loads they serve, and their ratings. It's your electrical road map of the facility and nearly impossible to investigate power quality problems without it.

Testing, measuring, troubleshooting, repairs, or any other work performed on any electrical system should be performed only by qualified personnel who have been trained to perform these functions safely, using proper procedures, and using test tools rated for the electrical systems for which they are intended.

Fluke 1750 Power Quality Logger

What is a voltage sag?

A sag is a reduction in voltage magnitude typically between 10 and 90 % of the voltage for more than 8 milliseconds (one half cycle at 60 Hz, or 10ms for 50 Hz systems) and less than 1 minute, according to the Institute of Electrical and Electronics Engineers (IEEE). aIndustrial equipment sensitive to voltage sags includes programmable logic controllers (PLC), robots, and variable frequency drives (VFD).

More than 50 % of voltage sag events originate from within the same building due to increases in current requirements such as starting large inductive loads (typically motors) that create temporary inrush current conditions. However, voltage sags come from external events as well. Most external events that result in voltage sags are nature related such as vegetation affecting power lines. But some are because of careless human behavior.

Detecting sags can be quite challenging because it's difficult to predict when they will occur. You can use the MIN/MAX function of a high-quality digital multimeter to detect single worst-case sags of 100 milliseconds or more while energizing the load. For suspected recurring sags, use the “Sags and Swells” trending feature on a high-performance power quality analyzer.

If you need to "document" power quality events for a longer duration, event recorders are available that can record sags, swells, interruptions, transients, and frequency deviations for several weeks.

Correcting problems that cause sags usually comes down to electrical engineering best practices. For example, wiring should be adequate for the loads they feed. Minimize source impedance by limiting the length of feeder runs to subpanels. Don't cascade subpanels off other subpanels. Reduce the load on the panel if necessary and if possible. Transformers should not be overloaded; this can cause increased energy losses and ultimately premature failure.

Correct wiring and/or loading issues first. When your plant is in order, then you can pursue other sag-mitigating solutions, such as voltage regulators and constant voltage transformers.

What are voltage harmonics?

Harmonics are multiples of a fundamental frequency. These harmonics distort the voltage wave form which should be a pure sine wave.

Devices that conduct current for less than the entire voltage sine wave are non-linear loads, and consequently generate harmonics. This includes any device with a rectifier, and switching electronics such as VFDs, electronic ballasts, electronic test equipment, and switched-mode power supplies.

Since harmonic current flowing through system impedances generates harmonic voltage distortion, it can also create voltage drops. In severe instances, this voltage distortion can cause thermal tripping of relays and protective devices, and logic faults in PLCs and VFDs. As voltage distortion increases, linear loads begin to draw harmonic current. In motors, some of these harmonic currents - most notably the fifth and eleventh harmonics causing counter-torque in the motor, resulting in more current, which decreases motor efficiency, increases heating, and shortens motor life.

Measure harmonics at the point of common coupling using a power quality analyzer or a harmonics analyzer. For simple snapshots you can use a high-quality digital multimeter for harmonic voltage or a high-quality clamp meter for harmonic current. However, the digital multimeter and clamp meter must be True RMS because True RMS test tools are necessary for accurate measurements of distorted waveforms.

Many 6-pulse VFDs generate fifth and seventh harmonics. However, 12- and 18-pulse drives help reduce harmonics because as the number of pulses increase, their amplitudes decrease. Other solutions for mitigating drive-generated harmonics include passive frontend chokes/filters, harmonic trap filters, and active filters.

What are the differences between surges and transients?

Transients are momentary excursions of voltage above the normal sine wave. Their magnitudes can be more than five to 10 times the nominal system voltage. Transients are different from surges. A surge is a high-energy transient, which is usually associated with lightning strikes.

Most transient-causing events happen inside the plant. These include capacitor switching, current interruptions, power electronics operation, arc welding, contact and relay closures, and loads starting up or disconnecting.

Fluke 435-II Power Quality and Energy Analyzer
According to the US Department of Energy, common causes of voltage unbalance include:
  • Unbalanced transformer bank supplying a three-phase load that is too large for the bank
  • Unevenly distributed single-phase loads on the same power system
  • Unidentified single-phase to ground faults
  • An open circuit on the distribution system primary

When transient voltages exceed electrical insulation ratings, the stress can lead to gradual insulation dielectric breakdown or possibly abrupt failure. Transients also deteriorate electronic components. A single high-energy transient can puncture a semi-conductor junction, and sometimes repetitive low-energy transients can have the same effect.

You can detect lower-speed transients using the same tools and techniques you'd use to detect sags. Nearly all electronic equipment manufactured within the last three decades includes some level of transient protection—typically a metal oxide varistor. Transient voltage surge suppression (TVSS) provides additional transient protection. You can apply TVSS protection at several points throughout the facility depending on protection equipment type. Apply category C equipment at the service entrance; apply category B equipment at distribution panels; and apply category A equipment at the individual circuit level.

Voltage unbalance and current unbalance

Voltage unbalance is the measure of voltage differences between the phases of a three-phase system. It degrades the performance and shortens the life of three-phase motors. Voltage unbalance at the motor stator terminals causes high current unbalance leading to negative torque and higher running temperatures, which can be 6 to 10 times as large as the voltage unbalance. Unbalanced currents lead to torque pulsation, increased vibration and mechanical stress, increased losses, and motor overheating.

Voltage and current unbalances could also indicate maintenance issues such as loose connections and worn contacts.

You can make some basic phase-to-phase voltage unbalance measurements using a high-quality digital multimeter and phase-to-phase current unbalance using a high-quality clamp meter. Accurate, real-time unbalance measurements need a three-phase power quality analyzer to enable solving unbalance problems. Open circuits and single-phase to ground faults are easier to correct than load balancing, which typically requires corrective system-level design changes.

Conclusion

Power quality issues are frequently interrelated. Address power quality problems from an entire plant approach without losing focus on how they affect individual loads. Sometimes fixing one power quality problem can make another problem worse. Looking at the big picture by using a three-phase power quality analyzer enables you to correct the causes of power quality issues, and not just doctor the symptoms.

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