Practical Power System Harmonics, Earthing and Power Quality: Problems and Solutions

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Practical Power System Harmonics, Earthing and

Power Quality Problems and Solutions

Revision 5.1

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Contents

Acknowledgements xi

1 Power Quality Overview 1 1.1 Introduction 2 1.2 Limits on electrical parameters 2 1.3 What is power quality? 3 1.4 Power quality indicators 4 1.5 Need for improving power quality 10 1.6 Summary 11

2 Dealing with Power Interruptions 13 2.1 Introduction 13 2.2 Needs of equipment 14 2.3 Understanding failures 14 2.4 Effect of power interruptions 14 2.5 Planning for reliability 16 2.6 Redundancy and automation 17 2.7 Uninterrupted power supply systems 21 2.8 Rotary UPS systems 22 2.9 Advanced rotary UPS systems 25 2.10 Hybrid UPS system 27 2.11 Static UPS systems 28 2.12 General configuration 28 2.13 Types of static UPS systems 30 2.14 UPS metering, indications, alarms and protection 34 2.15 Other types of UPS systems 34 2.16 Power quality and UPS 36 2.17 UPS applications to computer loads 36 2.18 UPS configurations in computer installations 38 2.19 Rating of UPS systems for computer equipment 39 2.20 Redundant UPS configuration 40 2.21 Summary 41

3 Voltage Variations 43 3.1 Introduction 43 3.2 Variations in voltage amplitude 43 3.3 Reasons for voltage amplitude changes 44 3.4 Voltage sag 46 3.5 Effects of sags 46 3.6 Swell and its effects 47

3.7 Equipment sensitivity 48 3.8 Handling voltage abnormalities 50 3.9 Control measures for mitigation 51 3.10 System changes for voltage improvements 52 3.11 Tackling voltage fluctuations and flicker 55 3.12 Summary 55

4 Surges and Surge Protection 57 4.1 Introduction 57 4.2 Surges, their causes and mitigation 58 4.3 Lightning - the external source of electrical surges 60 4.4 How surges find their way into electrical circuits 63 4.5 Bonding of grounding systems as a means of surge mitigation 65 4.6 Basic principle of surge protection 68 4.7 Surge protection devices 69 4.8 Graded surge protection 72 4.9 Selection criteria of devices for surge protection 77 4.10 Positioning and selection of lightning/surge arrestor 77 4.11 A practical view of surge protection for sensitive equipment 80 4.12 Other ways of mitigation of surges 83 4.13 Codes on surge protection 86 4.14 Surge protection of sensitive circuits 87 4.15 Hybrid SPDs for signal applications 88 4.16 Protection of Instrumentation systems 89 4.17 Surge protection of transmitters (general) 90 4.18 Surge protection of transmitters at the field end 91 4.19 Comprehensive loop protection 92 4.20 SPDs for other types of sensors 93 4.21 Protection of telemetry systems 94 4.22 Protection of data communication systems 95 4.23 SPD for hazardous applications 96 4.24 Grounding of intrinsically safe circuits 97 4.25 Summary 99

5 Voltage Asymmetry 101 5.1 Introduction 101 5.2 Reasons for asymmetry 101 5.3 Analysis of asymmetrical quantities 103 5.4 Effects of asymmetry 105 5.5 Permissible limits of asymmetry 106 5.6 Dealing with asymmetrical loads 106 5.7 Summary 107

6 Harmonics in Power Systems 109 6.1 Introduction 109 6.2 Linear and non-linear loads 110 6.3 Harmonic components 113 6.4 Harmonic currents and voltage distortion 115 6.5 Problems due to harmonics 118 6.6 Limits of harmonic presence in a power system 128 6.7 Measurement of current containing harmonics 129 6.8 Analysis of harmonic components 130 6.9 Methods of harmonic control 131 6.10 Summary 140

7 Electrical Noise and Mitigation 143 7.1 Introduction 143 7.2 Definition of electrical noise 143 7.3 How are sensitive circuits affected by noise? 146 7.4 Time and frequency domain representation of noise 148 7.5 Categories of noise 151 7.6 Noise from nearby electrical equipment 152 7.7 Ground Loop as a source of noise 153 7.8 Control of noise in signal cables 155 7.9 Electrostatic or capacitive coupling 157 7.10 Importance of grounding in noise control 163 7.11 Zero signal reference grid and signal transport ground plane 165 7.12 Summary 168

8 System Planning and Installation Guidelines 169 8.1 Introduction 169 8.2 Power interruptions 170 8.3 Issues of location 170 8.4 Commercial power 171 8.5 Information from equipment vendors 172 8.6 Power requirements and available power conditioning options 175 8.7 Noise suppression sensitive loads by proper grounding 176 8.8 Checking for redundancy requirement 176 8.9 Signal/data cabling susceptibility 177 8.10 Radio Frequency Interference (RFI) protection 177 8.11 Static electricity related problems 177 8.12 Lightning and surge protection 178 8.13 Documentation 178 8.14 Planned maintenance 179 8.15 Summary 180

9 Survey of Power Quality Problems and Solutions 181 9.1 Introduction 181 9.2 Problems commonly experienced 182 9.3 Solutions normally adopted 183 9.4 Summary 185

10 Power quality site study 187 10.1 Introduction 187 10.2 Site study objectives 187 10.3 Defining the problem 189 10.4 Coordination with other agencies 189 10.5 Conducting the study 190 10.6 Level 1 study 190 10.7 Level 2 study 197 10.8 List of instruments 201 10.9 Summary 201

Appendix A Power quality – the utility perspective 207

Appendix B Case studies 223

Appendix C Power recorder system example 269

Appendix D Glossary of terms 295

Appendix E Practical exercises 305

Acknowledgements The authors wish to acknowledge the following as some of the key sources used in the preparation of this text and the various graphs, tables and illustrations therein.

1. IDC technologies manual on Practical power quality problems and solutions

2. IDC Technologies manual on grounding, bonding and shielding

3. IDC Technologies manual on Batteries and UPS systems

4. IEEE Standard 142: 1991 (IEEE Green Book )

5. IEEE Standard 1100: 1992 (IEEE Emerald book)

6. IEEE Standard 519:1992 (Recommended Practices and Requirements for Harmonic Control in Electrical Power Systems)

7. Australian Standard 1768:1991 on Lightning protection

8. Publications by Copper Development Association and European Copper Institute under the series ‘Power Quality Guide’

9. Application notes by MTL Surge Technologies on Lightning and surge protection for electronic equipment published in their web site

10. Article ‘Regulating mains pollution’ by Derek Maule in IEE review, issue March 2001

11. Article ‘Understanding Power System Harmonics’ by W. Mack Grady and Surya Santoso in IEEE Power Engineering Review, November 2001

12. Web resource at http://www.spd.eee.strath.ac.uk/~interact/FFT

Practical Power System Harmonics, Earthing and Power Quality

1

Power Quality Overview

Inadequate power quality is one of the main reasons for unsatisfactory operation and failure of electrical equipment. In this chapter, we will have an introduction to the subject of power quality. We will define the meaning of power quality and the various quality parameters. We will briefly discuss the need for good power quality and the approach for solving problems due to power quality.

Learning objectives • What is power quality? • Parameters related to power quality • Need for quality power • Solving power quality problems

Important note

The terms ‘earth’ as well as ‘ground’ have both been in general use to describe the common signal/power reference point and have been used interchangeably around the world in the Electro-technical terminology. IEEE standard 142: 1991 (Green Book) however, presents a convincing argument for the use of the term ‘ground’ in preference to ‘earth.’ An electrical ground needs not necessarily be anywhere near the earth (meaning soil). For a person working in the top floor of a high-rise building, electrical ground is far above the earth. In deference to this argument, we will adopt the term ground in this manual to denote the common electrical reference point. The term earth where used will refer to the soil mass.

1.1 Introduction Before we start on our discussions on power quality, we will get a few things clear in our mind.

• When we talk about power here and elsewhere in this text, it is AC power that we are discussing.

• AC power is the one which we obtain from the normal electrical mains. • Contrary to expectations, this mains power obtained from the local electrical

supplier (or the utility grid or whatever else this agency is called) is far from perfect. So, we will have to define what perfect power or good quality power is.

• Power quality problems originate often from within an installation.

2 Practical Power System Harmonics, Earthing and Power Quality

In this overview, we will learn what is meant by power quality and the factors that make the power quality less than perfect. We will learn about the various parameters that determine power quality, the impact of these parameters when they go beyond specified limits. We will discuss in detail the different aspects of power quality and measures to be adopted to mitigate the effects of poor power quality in later chapters.

In an ideal power system with perfect power quality, the following should be realized.

• A constant voltage at a constant frequency • Perfectly sinusoidal voltage waveform • Perfectly balanced voltages in case of a three-phase supply system • No transient sub-cycle voltage variations • No interruptions of power

It is also important that these conditions are maintained regardless of the variations of connected load or its nature. In a practical system however, all the above cannot be realized. Normally, power received from the supplier at the point of supply to the consumer is expected to have the following attributes:

• Voltage within specified limits • Frequency within specified limits

Often, these are the only two parameters that a supplier commits to, but the other attributes too are equally important, whether specified or not. These are:

• Sinusoidal waveform without appreciable distortion • In the case of a three phase supply, symmetry of line/phase voltages (equal in

magnitude and shifted in phase by 120 electrical degrees) to be maintained within limits

• Control of transients or surges in the supply voltage (sub-cycle disturbances) • Control of repeated voltage changes giving rise to flicker in lamps • Power interruptions

1.2 Limits on electrical parameters From the above introduction it will be clear that power quality (or lack of it) is mainly concerned with maintaining specific parameters of the electric supply within a given set of limits. But why are such limits necessary? Why not fix a specific value to each parameter? The answer to this lies in the physical laws governing the flow of electricity and the practical considerations of design. For example, consider a system with a ring main distribution feeder having a single source. The voltage will be highest at a point close to the source but will gradually decrease as we move away from the source due to the voltage drop. A larger conductor size may reduce (but not eliminate) the voltage drop but will make the design expensive. Thus, it is clear that any system will have to evolve a range of acceptable values for each parameter. The acceptable range will depend on the capabilities of the equipment connected to this electrical system. In a distribution system, which is not usually provided with any facility for controlling the voltage, the voltage parameters will require closer control, say + 5% to – 5%. But in a transmission network, where voltage can be corrected using on-load tap-changers on the step down transformers, a larger variation can be allowed. Usually, limits of + 10% to –15% are considered acceptable. Even during normal operations, the voltage at a given point in the system hardly remains constant. The loads of a system constantly keep changing and as a result the voltage drop keeps changing too. A load with a highly fluctuating current profile (such as an electrical arc

Power Quality Overview 3

furnace) can produce very heavy voltage fluctuations during certain phases of its operating cycle. Also, it is impossible to totally prevent interruption of supply. Even in the best-maintained systems, equipment failures and short circuit faults can occur and if the process or parts of it cannot tolerate a supply interruption, then a mechanism for ensuring power to those loads where interruptions can have catastrophic results has to be worked out. Similarly, the dynamic nature of a power system operation causes constant frequency swings representing the shifting of system equilibrium point between generation and loads. The presence of non-linear equipment in a system gives rise to harmonics and so on. What are the limits that need to be applied to each parameter primarily depends on the behavior of the loads which are connected to the system and how much of a variation can normally be tolerated by these loads. The national regulatory authorities of each country therefore try to define these limits through the applicable standards and codes of practices (examples being the National Electrical Code of USA and British Wiring regulations, as well as other specific standards governing the relevant equipment). The supplier (of electrical power) has thus an obligation to maintain the stipulated limits at the point of power supply to each consumer. It may also happen that a bulk purchaser of electricity may lay down more stringent requirements if there is such a need in his specific case. These may be spelt out in the power supply agreement between the supplier and the consumer. On their part, the suppliers can also impose operational limits on the consumers by asking them to restrict demand, avoid load fluctuations, limit the injection of high frequency currents into the system (we will discuss about how this can happen as we proceed) and maintain certain minimum power factor. These limits are necessary so that an individual consumer does not pollute the power supply system or cause large variations in the supply parameters, thus affecting the quality of power supply to the other consumers. It also follows that the designers of power consuming/switching equipment such as motors or switchgear will have to design their equipment to operate satisfactorily within the accepted supply limits and deliver rated output. Conversely, when the supply parameters do not remain within the specified limits, the above equipment may not perform satisfactorily. Therefore, power quality needs to be strictly maintained in any electrical system within agreed set of operational limits to ensure that the electrical equipment fed from the system can operate without problems over their entire design life.

1.3 What is power quality? Before we go any further into the details of power quality aspects, let us first try to define what we mean by the term power quality. A reasonable definition of quality power can be:

Power made available at stipulated voltage and frequency without distortion of waveform or loss of symmetry and with minimum instances/duration of variations beyond the specified limits or unscheduled interruptions.

From this definition, a few aspects would be clear to the reader. The first is that it is generally accepted that any electrical parameter cannot remain absolutely constant and some variations will occur. So also, an unscheduled interruption is a possibility that has to be anticipated. What is important is that:

a) The variations should be within acceptable limits. b) The number of instances of variations should be as few as possible. c) Unscheduled interruptions should be as few as possible d) Duration of off-limit variations as well as interruptions should be as short as possible.

It is clear that to improve power quality in a system, the stress should be on preventing the variations from going beyond specified limits, on preventing interruptions and on reducing

4 Practical Power System Harmonics, Earthing and Power Quality

the number and duration of such variations and interruptions. We will learn in this chapter as to how all these can be achieved in practical systems. As an example, given below in Figure 1.1 the results of a study made in a typical system indicating various deviations during the course of a specific period.

Figure 1.1 Typical power quality problems

It is evident from this figure that transient disturbances and voltage spikes together form the bulk of the deviations followed by low voltage conditions. Total blackout period is less than 11 minutes on an average per month. We will discuss in detail in the next section about the indicators of power quality in any system and their effects.

1.4 Power quality indicators Inadequate power quality is indicated if one or more of the following occur frequently in a system. • Changes in amplitude of the AC voltage. This can be either for short periods or for

long periods. Such changes can take the form of: o Voltage variations such as sag and swell and repeated voltage fluctuations o Surges or transient sub-cycle disturbances o Interruption (an extreme form of amplitude change) o Noise

• Frequency disturbances produced from the generating source, which can be a utility grid, or a stand-alone power source such as an emergency engine generator.

• Waveform asymmetry, which may cause the voltage vectors of the three phases to be different in values and the phase angle shift to vary from the normal value of 120 electrical degrees.

• Changes in the AC voltage waveform appearing as harmonics We will discuss these problems briefly in this section.

Power Quality Overview 5

1.4.1 Sag Sag is a temporary reduction in the normal AC voltage. Momentary sag is a variation, which lasts for a period of 0.5 cycles to about 2 seconds, usually the result of a short circuit somewhere in the power system. Instances of longer duration of low voltage are called Sustained sags (see Figure 1.2).

LIN

E to

NEU

TRAL

AC V

OLT

AG

E

Time (Seconds)

Figure 1.2 Sag-momentary and sustained

1.4.2 Swell Swell is the opposite of sag and refers to the increase of power frequency voltage. A momentary swell lasts from 0.5 cycles to 2 seconds. A sustained swell lasts for longer periods (see Figure 1.3).

6 Practical Power System Harmonics, Earthing and Power Quality

LIN

E to

NE

UTR

AL A

C V

OLT

AG

E

Time (Seconds)

Figure 1.3 Swell-momentary and sustained

1.4.3 Surges or transients Surge is a sub cycle disturbance lasting for durations of less than half a cycle and mostly less than a millisecond. The earlier terminology for such disturbances was transient or spikes. Surges generally occur due to atmospheric disturbances such as lightning or due to switching of large transformers, inductors or capacitors. Figures 1.4 and 1.5 show the waveforms of such surges.

Figure 1.4 Surge voltage with oscillatory decay

Power Quality Overview 7

Figure 1.5 Surge caused by lightning

A surge with oscillatory decay is generally a result of switching. A lightning surge on the other hand occurs as train of steep pulses of decreasing with definite time delay between them and all in one direction only.

1.4.4 Interruption Interruption means the complete loss of voltage. A momentary interruption lasts from half cycle period to less than 2 seconds. Longer interruptions are called Sustained interruptions. Momentary interruption is usually the result of a line outage with the supply being restored automatically from another source or by auto-reclosing operation. Refer to Figure 1.6 for illustration. An interruption can be instantaneous or of slowly decaying type.

Figure 1.6 Examples of supply interruption

In the figures above, the one at the top shows the RMS voltage value during a momentary interruption. The figure on the lower left depicts the waveform of a sustained interruption where the voltage drops to zero almost instantaneously. The waveform on the lower right shows an interruption where the voltage decays slowly.

8 Practical Power System Harmonics, Earthing and Power Quality 1.4.5 Frequency disturbance

Frequency disturbances originate from a power system and arise out of an unbalance between generation and loads. A system operating normally with the generation being equal to the loads stays near the rated frequency. Any disturbance of this equilibrium by reduction of generation or a sudden change in loading can produce changes in system frequency till the generation and load attain a new point of equilibrium. Such normal changes however do not produce very abrupt or large frequency changes but the frequency remains well within the defined range. But more severe system changes such as the outage of a generator or tripping of a heavily loaded transmission line can produce very high rates of change of frequency and can result in the frequency going beyond normal limits.

Maintaining the frequency of a supply system is important for two reasons:

• Speed of motors connected to the system changes with frequency and affects the throughput of equipment driven by them.

• Any co-generation units working in parallel with the utility will be forced to follow the system frequency. Extreme cases of under/over frequency can prove harmful for the prime movers, particularly steam turbines and may lead to premature failures.

Generally, in well-regulated systems with adequate spinning reserve capacity, frequency is not a problem. We will not therefore discuss this issue in detail in this text. However, in systems where frequency is a problem, the following measures may be useful for avoiding difficulties due to frequency-sensitive loads:

• Providing variable speed drives for control of motor speeds independent of supply frequency

• Planning for a separate generator operated from a prime-mover or some form of uninterrupted power system (UPS) whose frequency can be regulated independent of the system frequency

Co-generation units may have to be provided with means of isolation from the utility source in the case of large variations of supply frequency and continue to supply specified plant loads independently.

1.4.6 Waveform asymmetry A generator in any practical 3-phase electrical system is designed to produce a perfectly symmetrical output. The line/phase voltages of each phase will be equal in magnitude with a phase displacement of 120 electrical degrees. However, the voltage experienced by a consumer or specific parts of the consumer’s internal distribution system or sometimes a specific load may experience an asymmetrical voltage. Asymmetrical voltage is usually a result of an unbalanced load and less often unbalanced system impedance. An unbalanced load or a balanced load with an unbalanced system impedance produce different voltage drops in each line and as a result, the voltage available at the consumer point can become asymmetrical even though the source may generate a perfectly symmetrical output. An extreme case of asymmetry happens when one line gets broken (a condition which is commonly known as single-phasing). Apart from these, large single-phase loads can be found in traction systems and in industries deploying induction furnaces. These loads can introduce large unbalances in the system require specific corrective measures. Asymmetry poses a problem to three phase motors and converters but does not affect single-phase loads except by way of a change of voltage. To know how an asymmetry will affect the connected loads, it is necessary to mathematically resolve the voltages using a technique called symmetrical components. We will discuss this in detail in a later chapter.

Power Quality Overview 9

1.4.7 Waveform distortion (Harmonics) Distortion of the sine waveform of an AC voltage or current can happen as a result of two conditions.

• Magnetic saturation of transformer cores • Presence of large non-linear loads

Magnetic saturation causes sudden change in the inductive reactance of a coil and results both in distortion of the magnetizing input current in a transformer as well as the output waveform. Loads that draw distorted currents when supplied with sinusoidal voltage are called non-linear. Loads that are resistances, capacitances or inductances (operating in the linear, unsaturated zone) or a combination of these circuit elements have the same wave shapes for voltage and current. Both are normally pure sinusoids and such loads are said to be linear. Most induction motors fed directly from AC mains also behave as a combination of resistance and inductive reactance and therefore can be considered as linear loads. However, the current waveform gets distorted when power electronic devices are introduced in the system to control the speed of AC (or DC) motors. These devices chop off part of the AC waveform using thyristors or power transistors, which are used as static switches. These are called non-linear loads. Such altered waveforms may be mathematically analyzed using Fourier transforms as a combination of vectors of the power frequency (50/60 Hz) and others whose frequency is a multiple of the power frequency. The power frequency component is called the Fundamental frequency component and higher multiples are called Harmonic frequency components or simply as harmonics. It should be remembered that all electrical generators produce only voltage at fundamental frequency. But there has to be a source of harmonic frequency voltage if a harmonic current has to flow. It is therefore construed theoretically that all harmonic producing loads are current sources of harmonics. These sources drive harmonic currents through the rest of the system consisting of the fundamental frequency source as well as other loads connected to it. The current flowing through the different impedance of the system appears as harmonic voltages. It is usual for the voltage waveform of such a system to appear distorted. Also, the harmonic currents flowing through the other loads of the system give rise to several abnormalities (refer to Table 1.1 for the effects harmonics have on different system components).

Table 1.1 Effects harmonics have on different system components

Capacitors: Amplify harmonics on electrical distribution system Electrical wiring: Phase and neutral conductors undersized Engine generators: Transferring capability and operation disrupted Induction motors: May fail prematurely due to fifth harmonic Metering: Inaccurate measurement of power Over-current protection: Breaker and fuse nuisance tripping Sensitive electronic loads: Voltage drop between neutral and earth Transformers: Decreased efficiency and overheating Uninterruptible power systems: Line and load interaction

Higher frequency harmonics can be propagated by the power conductors acting as antennae and appear as induced noise voltages in nearby signal circuits.

1.4.8 Noise Noise, or interference, can be defined as an undesirable electrical voltage, which distorts or interferes with a desired signal. Noise could be transient (temporary) or constant.

10 Practical Power System Harmonics, Earthing and Power Quality

Unpredictable transient noise can be caused, for example, by lightning. Constant noise can be due to the 50 or 60 Hz AC ‘hum’ from power circuits or its harmonic multiples of power frequency close to the data communications cable. This unpredictability makes the design of a data communications system quite challenging. Noise can be generated from within the sensitive equipment itself (internal noise) or from an outside source (external noise). Generation and propagation of electrical noise requires a source of noise, a mechanism coupling the source to the ‘victim’ circuit and a circuit conveying sensitive communication signals. Typical sources of noise are devices, which produce quick changes (spikes) in voltage or current or harmonics. Noise generally manifests itself in two forms. In one form, the noise may be a result of an external disturbance such as a high-energy electromagnetic pulse from a lightning. In this case, noise appears on all the conductors (including the neutral) of a power system as identical pulses. This type of noise is called as Common mode noise. The other form of noise is the result of a disturbance from the power system itself. This kind of noise called as Transverse mode or differential mode noise. Noise is not in the strict sense a power quality issue but it is an effect of other power quality problems. Noise can get transmitted into communication and signal circuits and cause problems such as component failures, malfunction of controls etc. A good design should therefore ensure that noise is not generated and when generated by equipment or originating from an external source, is not propagated into a system containing noise-sensitive equipment.

1.5 Need for improving power quality Power quality problems can either originate from the power supply system (which may include problems caused by neighboring consumers) or from the concerned installation itself. Many of the problems of power quality may manifest themselves as equipment failures such as burn-out of motors, failure of electronic cards, nuisance tripping of circuit-breakers and so on. It is up to the engineers in charge of the installation to recognize these as symptoms of power quality, especially when the problems become frequent or repetitive, and take appropriate action. Many of the possible issues of power quality need to be taken into consideration while planning and installation. In the case of large facilities, observations at the supplier’s installation from where power supply will be obtained as well as a study of available records and system parameters at the point of common coupling will be necessary to detect any inherent deficiency in the system. Making suitable provisions in the initial design of the electrical systems of a facility and equipment specifications and adopting correct installation practices will go a long way in avoiding a lot of downtime, loss of production and expensive retrofits at a later stage. In spite of the best of precautions, problems can still happen during the operation of a facility. This may happen due to addition of new equipment within a facility, changes in the supplier’s installation such as addition of new consumers as well as temporary configuration changes in the system. It is then necessary to correctly pinpoint the source of the problem and introduce appropriate remedies. Identifying a power quality problem requires proper instruments, with measurements being done at different points in the system and even at different times of the day. The readings thus obtained should be correctly interpreted to understand the real reasons, which may call for adequate theoretical knowledge of the principles involved and familiarity with the system under study. We will discuss these aspects in detail in further chapters in this text.

Power Quality Overview 11

1.6 Summary Quality power can be defined as power made available at stipulated voltage and frequency without distortion of waveform and with minimum instances/duration of variations going beyond the specified limits or unscheduled interruptions. In other words, power quality is mainly concerned with controlling critical electrical parameters from straying beyond specified limits, avoiding interruptions of electrical supply and minimizing the duration of power interruptions and abnormal variations, should they happen. The most common instances of power quality problems are surges and voltage sags. Other problems are voltage swells, voltage fluctuations, supply interruptions, frequency variations, harmonics and noise. All these problems have wide-ranging effects on power system equipment. It is possible to control the occurrence of these problems by appropriate system design. Mitigating the effects of these problems is also possible by adopting appropriate protective measures and by the addition of power conditioning equipment. Also, adequate care during the design of a system and proper installation practices will go a long way in preventing serious problems from arising. In case problems do happen in an installation, a proper site analysis must be conducted to study the problems in depth, analyze the probable reasons and institute necessary corrective measures. We will discuss these aspects in detail in the ensuing chapters.

12 Practical Power System Harmonics, Earthing and Power Quality