Power Quality Monitoring Part 1: The Importance of ...

Author: Ruby

Aug. 26, 2024

Measurement & Analysis Instruments

Power Quality Monitoring Part 1: The Importance of ...

Abstract

This article discusses the importance of power quality (PQ) measurements in today&#;s electric infrastructure and reviews areas of application for PQ monitoring. It will cover the IEC standard for power quality and its parameters. Finally, it summarizes the key differences between Class A and Class S power quality meters. A subsequent article will illustrate recommended solutions on &#;How to Design a Standards Compliant Power Quality Meter.&#;

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The Need for Power Quality Measurement in Today&#;s Electric Infrastructure

Power quality has found a renewed interest due to changing power generation modes and consumption dynamics. The unprecedented growth in renewable sources at different voltage levels has increased the amount of PQ related issues. Consumption patterns have also seen a wide transformation due to unsynchronized loads added at multiple entry points of the grid and voltage levels. Some examples are electric vehicle (EV) chargers that can require hundreds of kilowatts and a great number of data centers and their related equipment such as heating, ventilation, and air conditioning. In industrial applications, arc furnaces that run by variable frequency drives, switching transformers, etc. not only add a lot of unwanted harmonics to the grid, but are also responsible for voltage dips, swells, transient brownouts, and flicker.

Figure 1. Power quality issues.

Power quality in the utility space refers to the quality of the voltage delivered to the consumer; a series of prescribed regulations for the magnitude, phase, and frequency determine this quality of service. However, by definition, it denotes both voltage and current. While the voltage is easily controlled by the generation side, the current is governed largely by consumer usage. The concept and implications of PQ issues are rather widespread depending on the end users.

The economic impact of bad PQ has been studied and surveyed extensively in the last few years; its effects are estimated to be in the region of billions of dollars worldwide.1 All these studies conclude that monitoring the quality of power has a direct impact on the economic results of many business sectors. Even though it is clear how bad PQ negatively affects the economics of business, monitoring it efficiently and effectively at scale is not an easy task. Monitoring PQ in a facility involves having highly trained personnel and expensive equipment installed on multiple points along the electric system for long or indefinite periods of time.

Power Quality Monitoring Areas of Application

Power quality monitoring is often seen as a cost saving strategy for some business sectors and a critical activity for others. Power quality issues can arise in a broad range of electric infrastructure, as illustrated in Figure 2. As we&#;ll discuss later, power quality monitoring is becoming increasingly critical in business sectors such as electric generation and distribution, EV charging, factories, and data centers.

Figure 2. The dynamics of generation and consumption can lead to power quality issues across electric infrastructure.

Electricity Utility Companies, Electricity Transmission, and Distribution

Utility companies serve the consumers with distribution systems that include generating stations, which are power substations that supply electricity via transmission lines. The voltage supplied via these transmission lines is stepped down to lower levels by substation transformers, which inject certain harmonics or interharmonics to the system. Harmonic currents in distribution systems can cause harmonic distortion, low power factor, and additional losses as well as overheating in the electrical equipment2, leading to a reduction in the lifetime of equipment and increases in cooling costs. Nonlinear single-phase loads served by these substation transformers deform the current&#;s waveform. The unbalance of nonlinear loads leads to additional losses on power transformers, additional load of neutrals, unexpected operation of low power circuit breakers, and incorrect measurement of electricity consumed.3 Figure 3 illustrates the effect of these linear loads.

Electricity generation by wind and photovoltaic (PV) solar systems injected into the grid cause several power quality problems as well. On the wind generation side, wind intermittency creates harmonics and short-duration voltage variations.4 The inverters in PV solar systems create noise that can produce voltage transients, distorted harmonics, and radio frequency noise because of the high speed switching commonly used to increase the efficiency of the energy harvested.

Figure 3. The impact of current harmonics generated by a nonlinear load.

EV Chargers

EV chargers can face multiple power quality challenges, both in power sent to and from the grid (see Figure 4). From a power distribution company perspective, power electronics-based converters used in EV chargers inject harmonics and interharmonics. Chargers with improperly designed power converters can inject direct currents (DC). Additionally, fast EV chargers introduce rapid voltage changes and voltage flicker into the grid. From the EV charger side, faults in transmission or distribution systems lead to voltage dips or interruption of supply voltage to the charger. Reduction of voltage from the EV charger tolerance limits will lead to activation of undervoltage protection and disconnection from the grid (which leads to a very bad user experience).5

Figure 4. Power quality issues for EV chargers.

Factories

Power quality problems caused by power supply variations and voltage disturbances, cost approximately $119 billion (U.S.) per year for industrial facilities in the United States, as per an Electric Power Research Institute (EPRI) report.6 Additionally, 25 EU states suffer an equivalent of $160 billion (U.S.) in financial losses per year due to different PQ issues, according to the European Copper Institute.7 These figures are linked to subsequent downtime and production losses as well as the equivalent of intellectual productivity losses.8

Degradation of power quality is usually caused by intermittent loads and load variations from arc furnaces and industrial motors. Such disturbances give rise to surges, dips, harmonic distortions, interruptions, flicker, and signaling voltages.9 To detect and record these disturbances inside a factory installation, it is necessary to have power quality monitoring equipment in several points throughout the electric installation or, even better, have it at the load level. With the arrival of new Industry 4.0 technologies, power quality monitoring at the load can be addressed by industrial panel meters or submeters to have a comprehensive view of the quality of the power delivered to each load.

Data Centers

Presently, most business activities depend on data centers in one way or another to provide , data storage, cloud services, etc. Data centers demand a high level of clean, reliable, and uninterrupted electricity supply. PQ monitoring excellence helps managers prevent costly outages and helps manage equipment maintenance, or replacement, required due to issues on the power supply units (PSU). The integration of uninterruptable power supply (UPS) systems into rack power distribution units (PDUs) represents another reason to add PQ monitoring to IT racks inside the data center. This integration can provide visibility to power issues at a power socket level.

UPS system failure, including UPS and batteries, is the primary cause of unplanned data center outages according to a report made by Emerson Network Power.10 Around a third of all reported outages cost companies nearly $250,000.11 UPS systems are used on every data center to ensure clean and uninterrupted power. These systems isolate and mitigate most of the power problems from the utility side, but they do not protect against issues generated by the PSU of IT equipment itself. IT equipment PSUs are nonlinear loads that can introduce harmonic distortion in addition to other problems caused by equipment such as those that can result in high density cooling systems with variable frequency speed-controlled fans. Apart from these issues, PSUs also face interferences that come in multiple forms such as voltage transients and surges, voltage swells, sags, and spikes, imbalance or fluctuations, frequency variation, and poor facility grounding.

Power Quality Standards Defined

Power quality standards specify measurable limits to the electricity magnitudes as to how far they can deviate from a nominal specified value. Different standards apply to different components of the electricity system. Specifically, the International Electrotechnical Commission (IEC) defines the methods for measurement and the interpretation of results of PQ parameters of alternating current (AC) power systems in the IEC -4-30 standard. The PQ parameters are declared for fundamental frequencies of 50 Hz and 60 Hz. This standard also establishes two classes for measurement devices: Class A and Class S.

  • Class A defines the highest level of accuracy and precision for the measurements of PQ parameters and is used for instruments requiring very precise measurements for contractual matters and dispute resolution. It is also applicable to the devices that need to verify compliance of the standard.
  • Class S is used for power quality assessment, statistical analysis applications, and diagnostics of power quality problems with low uncertainty. The instrument in this class can report a limited subset of the parameters defined by the standard. The measurements made with Class S instruments can be done on several sites on a network, on complete locations or even on single pieces of equipment.

Figure 5. IEC power quality standards.

It is important to note that the standard defines the measurement methods, establishes a guide for the interpretation of the results, and specifies the performance of the power quality meter. It does not give guidelines on the design for the instrument itself.

The IEC -4-30 standard defines the following PQ parameters for Class A and Class S measurement devices.12

  • Power frequency
  • Magnitude of the supply voltage and current
  • Flicker
  • Supply voltage dips and swells
  • Voltage interruptions
  • Supply voltage unbalance
  • Voltage and current harmonics and interharmonics
  • Rapid voltage change
  • Underdeviation and overdeviation
  • Mains signaling voltage on the supply voltage

Contact us to discuss your requirements of Single-Phase Power Quality Analyzer Manufacturers. Our experienced sales team can help you identify the options that best suit your needs.

Figure 6. Classification of power quality parameters in a timescale.

Key Differences Between Class A and Class S Defined by the IEC -4-30 Standard

Although Class A defines higher levels of accuracy and precision than Class S, the differences are beyond just levels of accuracy. Instruments must comply with requirements such as time synchronization, quality of probes, calibration period, temperature ranges, etc. Table 1 presents a list of requirements that instruments shall meet to be certified in one or the other class.

Table 1. IEC -4-30 Class A and Class S Key Differences Class A Class S Voltage Measurement Accuracy ±0.1% ±0.5% Current Measurement Accuracy ±1% ±2% Voltage and Current rms Calculation Half-cycle steps One-cycle steps Frequency Measurement Accuracy ±10 mHz ±50 mHz 150/180-Cycle Aggregation No gaps permitted, synchronized with UTC 10 min tick Gaps between aggregations allowed Measurements of Harmonics up to Order 50th 40th Time-Clock Uncertainty per 24 Hours ±1 second ±5 seconds Time Synchronization GPS receiver, radio timing signals or network timing signals Not required Operation Temperature Range 0°C to 45°C Specified by manufacturer

Conclusion

Power quality issues are present across the whole electric infrastructure. Having equipment that monitors these PQ issues helps to improve performance, quality of service, and equipment lifetime while reducing economic losses. In the subsequent article &#;How to Design a Standards Compliant Power Quality Meter,&#; we will introduce an integrated solution and a ready to use platform that can significantly accelerate development and reduce costs for developing PQ monitoring products.

References

1Panuwat Teansri, Worapong Pairindra, Narongkorn Uthathip Pornrapeepat Bhasaputra, and Woraratana Pattaraprakorn. &#;The Costs of Power Quality Disturbances for Industries Related Fabricated Metal, Machines and Equipment in Thailand.&#; GMSARN International Journal, Vol. 6, .

2Sai Kiran Kumar Sivakoti, Y. Naveen Kumar, and D. Archana. &#;Power Quality Improvement In Distribution System Using D-Statcom in Transmission Lines.&#; International Journal of Engineering Research and Applications (IJERA), Vol. 1, Issue 3.

3Gabriel N. Popa, Angela Lagar, and Corina M. Diniş. &#;Some Power Quality Issues in Power Substation from Residential and Educational Buildings.&#; 10th International Symposium on Advanced Topics in Electrical Engineering (ATEE), IEEE, .

4Sulaiman A. Almohaimeed and Mamdouh Abdel-Akher. &#;Power Quality Issues and Mitigation for Electric Grids with Wind Power Penetration.&#; Applied Sciences, December .

5George G. Karady, Shahin H. Berisha, Tracy Blake, and Ray Hobbs. &#;Power Quality Problems at Electric Vehicle&#;s Charging Station.&#; SAE Transactions, .

6David Lineweber and Shawn McNulty. &#;The Cost of Power Disturbances to Industrial and Digital Economy Companies.&#; Electric Power Research Institute, Inc., June .

7Roman Targosz and Jonathan Manson. &#;Pan-European Power Quality Survey.&#; 9th International Conference on Electrical Power Quality and Utilisation, IEEE, .

8Subrat Sahoo. &#;Recent Trends and Advances in Power Quality.&#; Power Quality in Modern Power Systems, .

9A. El Mofty and K. Youssef. &#;Industrial Power Quality Problems.&#; 16th International Conference and Exhibition on Electricity Distribution, . Part 1: Contributions. CIRED (IEE Conf. Publ No. 482), IEEE, June .

10&#;Cost of Data Center Outages.&#; Ponemon Institute, January .

11&#;Data Center Outages Are Common, Costly, and Preventable.&#; Uptime Institute.

12&#;IEC -4-30:: Electromagnetic Compatibility (EMC)-Part 4-30: Testing and Measurement Techniques-Power Quality Measurement Methods.&#; International Electrotechnical Commission, February .

Power Analyzers and Power Meters

±(0.8% rdg + 0.2% rng) when using clamps , , , , ±(1.1% rdg + 0.2% rng) when using clamp , ±(1.3% rdg + 0.2% rng) when using clamp ,

Peak voltage of 2 kV or RMS of 1.1 kV, whichever is lower

Peak voltage of 1.5 kV or RMS of 1.0 kV, whichever is lower

Peak voltage of 1.5 kV or RMS of 1.0 kV, whichever is lower

Peak voltage of 1.5 kV or RMS of 1.0 kV, whichever is lower

The peak is 1.5 kV, or the RMS of 1kV, whichever is less.

The peak is 1.6 kV, or the RMS of 1.1kV, whichever is less.

Peak voltage of 2 kV or RMS of 1.1 kV, whichever is lower

Peak voltage of 1.6 kV or RMS of 1.5 kV, whichever is lower

Continuous Allowable Max. Input Current

Direct input (5 A element): Peak current of 10 A or RMS of 7 A (whichever is lower.), Direct input (30 A element): Peak current of 90 A or RMS of 33 A (whichever is lower.) External Current Sensor Input - Peak not to exceed 5 times range-value or 25 V (whichever is lower)

Direct input (5 A element): Peak current of 10 A or RMS of 7 A (whichever is lower.), Direct input (50 A element): Peak current of 150 A or RMS of 55 A (whichever is lower.) External Current Sensor Input - Peak not to exceed 5 times range-value

30A direct input: The peak is 90 A, or RMS is 33 A, whichever is less. 2A direct input: The peak is 6 A, or RMS is 2.2 A, whichever is less. Current sensor input: The peak is not to exceed 5 times the range

Direct input: The peak is 100 A, or RMS is 45 A, whichever is less. External input: The peak is 5 times the range or less.

Direct input: 5-200 mA Peak current of 30 A or RMS of 20 A (whichever is less.), 0.5-20 A Peak current of 100 A or RMS of 30 A (whichever is less.) External input: Peak value of 5 times range or less.

Direct input: 1-20 A Peak current of 100 A or RMS of 44 A (whichever is less.) External input: Peak value of 5 times range or less.

Direct input: 0.5-20 A Peak current of 100 A or RMS of 30 A (whichever is less.) External input: Peak value of 5 times range or less.

Direct input: 8.5 A Peak or RMS of 6 A (whichever is less.) External input: Peak value of 4 times range or less.

(2A) 60Arms (50A) 130Arms (100A) 100Arms (200A) 250Arms (500A) 500Arms (A) A (A) A

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