Power quality and electromagnetic compatibility: special report, session 2

The scope of Session 2 (S2) has been defined as follows by the Session Advisory Group and the Technical Committee: Power Quality (PQ), with the more general concept of electromagnetic compatibility (EMC) and with some related safety problems in electricity distribution systems. Special focus is put on voltage continuity (supply reliability, problem of outages) and voltage quality (voltage level, flicker, unbalance, harmonics). This session will also look at electromagnetic compatibility (mains frequency to 150 kHz), electromagnetic interferences and electric and magnetic fields issues. Also addressed in this session are electrical safety and immunity concerns (lightning issues, step, touch and transferred voltages). The aim of this special report is to present a synthesis of the present concerns in PQ&EMC, based on all selected papers of session 2 and related papers from other sessions, (152 papers in total). The report is divided in the following 4 blocks: Block 1: Electric and Magnetic Fields, EMC, Earthing systems Block 2: Harmonics Block 3: Voltage Variation Block 4: Power Quality Monitoring Two Round Tables will be organised: - Power quality and EMC in the Future Grid (CIGRE/CIRED WG C4.24, RT 13) - Reliability Benchmarking - why we should do it? What should be done in future? (RT 15

Assessing micro-generation’s and non-linear loads’ impact in the power quality of low voltage distribution networks

Distribution networks face an increasing penetration of solar PV (photovoltaic) and small WTG (wind turbine generator) as well as other forms of micro-generation. To this scenario, one must add the dissemination of non-linear loads such as EV (electric vehicles). There is something in common between those loads and sources: the extensive use of power electronic converters with commutated switches. These devices may be a source of medium-to-high frequency harmonic distortion and their impact on the local distribution grid must be carefully assessed in order to evaluate their negative impacts on the network, on the existing conventional loads and also on other active devices. In this paper, methodologies to characterize effects such as: harmonics, network unbalances, damaging power line resonance conditions, and over/under voltages are described and applied to a real local grid configuration

Power Quality

Electrical power is becoming one of the most dominant factors in our society. Power generation, transmission, distribution and usage are undergoing signifi cant changes that will aff ect the electrical quality and performance needs of our 21st century industry. One major aspect of electrical power is its quality and stability – or so called Power Quality. The view on Power Quality did change over the past few years. It seems that Power Quality is becoming a more important term in the academic world dealing with electrical power, and it is becoming more visible in all areas of commerce and industry, because of the ever increasing industry automation using sensitive electrical equipment on one hand and due to the dramatic change of our global electrical infrastructure on the other. For the past century, grid stability was maintained with a limited amount of major generators that have a large amount of rotational inertia. And the rate of change of phase angle is slow. Unfortunately, this does not work anymore with renewable energy sources adding their share to the grid like wind turbines or PV modules. Although the basic idea to use renewable energies is great and will be our path into the next century, it comes with a curse for the power grid as power fl ow stability will suff er. It is not only the source side that is about to change. We have also seen signifi cant changes on the load side as well. Industry is using machines and electrical products such as AC drives or PLCs that are sensitive to the slightest change of power quality, and we at home use more and more electrical products with switching power supplies or starting to plug in our electric cars to charge batt eries. In addition, many of us have begun installing our own distributed generation systems on our rooft ops using the latest solar panels. So we did look for a way to address this severe impact on our distribution network. To match supply and demand, we are about to create a new, intelligent and self-healing electric power infrastructure. The Smart Grid. The basic idea is to maintain the necessary balance between generators and loads on a grid. In other words, to make sure we have a good grid balance at all times. But the key question that you should ask yourself is: Does it also improve Power Quality? Probably not! Further on, the way how Power Quality is measured is going to be changed. Traditionally, each country had its own Power Quality standards and defi ned its own power quality instrument requirements. But more and more international harmonization efforts can be seen. Such as IEC 61000-4-30, which is an excellent standard that ensures that all compliant power quality instruments, regardless of manufacturer, will produce of measurement instruments so that they can also be used in volume applications and even directly embedded into sensitive loads. But work still has to be done. We still use Power Quality standards that have been writt en decades ago and don’t match today’s technology any more, such as fl icker standards that use parameters that have been defi ned by the behavior of 60-watt incandescent light bulbs, which are becoming extinct. Almost all experts are in agreement - although we will see an improvement in metering and control of the power fl ow, Power Quality will suff er. This book will give an overview of how power quality might impact our lives today and tomorrow, introduce new ways to monitor power quality and inform us about interesting possibilities to mitigate power quality problems. Regardless of any enhancements of the power grid, “Power Quality is just compatibility” like my good old friend and teacher Alex McEachern used to say. Power Quality will always remain an economic compromise between supply and load. The power available on the grid must be suffi ciently clean for the loads to operate correctly, and the loads must be suffi ciently strong to tolerate normal disturbances on the grid

Assessment of Power System Equipment Insulation Based on Distorted Excitation Voltage

Electrical insulation plays a critical role in high voltage power system equipment. The presence of electrical, thermal, and mechanical stresses imposed when they are in operation for a long time cause gradual degradation of the insulation. Therefore, regular condition monitoring and diagnostic testing of power system equipment are of paramount importance for the reliable operation of electricity supply networks and systems. The dielectric dissipation factor (DDF) measurement is one of the most common techniques for insulation assessment. From a traditional perspective, a pure sinusoidal voltage is used for excitation in the testing. However, the grid voltage nowadays in reality is often distorted with a waveform having multiple harmonic components. Generally, there are distorted voltages and currents generated due to the presence of non-linear equipment or components in the system. Thus, testing under distorted voltage with harmonics provides a more realistic diagnostic measurement as compared to traditional AC sinusoidal high voltage testing. This dissertation investigates the impact of harmonically distorted excitation on the dielectric dissipation factor of high voltage power equipment. A practical measurement method based on distorted excitation is proposed and tested on a reference capacitor-resistor test object. A theoretical and mathematical model is developed to quantify the impact of distortion on the DDF measured in contrast to the case of non-distorted excitation. It is established that for the same total RMS magnitude of the applied excitation, the DDF decreases with the increasing harmonic proportion in the applied voltage waveform. For validation, laboratory experiments and computer simulations were carried out, and data obtained were compared with the analytical results. The proposed technique is then tested on some real high voltage components (33kV dry-type current transformers). The results confirm the monotonically decreasing trend, but the pattern is more complex. The dielectric dissipation factor mathematical and electrical circuit model is implemented based on the polarisation loss. The theoretical formulation is implemented in a computer simulation using MATLAB Simulink to validate the results. In summary, the thesis provides useful diagnostic insights on the characteristics of the dielectric dissipation factor measurement under distorted excitation

Power quality requirements and responsibilities at the point of connection

In the present power delivery environment, electricity as a product has become more competitive than before. Modern electrical devices are complex in terms of their functionalities and are more sensitive to the quality of the supplied electricity. A disturbance in supply voltage can cause significant financial losses for an industrial customer. Moreover, there are increasing number of disputes in different countries of the world among the network operators, the customers and the device manufacturers regarding their individual responsibility concerning 'Power Quality' (PQ) problems and solutions. In addition, the existing standards on PQ give very limited information about responsibility sharing among the involved parties. PQ disturbances can be originated in the network as well as at the customer's premises and can propagate to other parts of the network. The PQ level in the network is also highly influenced by PQ emission behaviors of customer's devices and the network characteristics. During the last decades, PQ related complaints have increased largely. Inadequate PQ can lead to various technical and financial inconveniences to the customers and the network operators. This research aims to find out a socio-economically optimum solution to PQ problems. The main objectives of this thesis are defined as: "Analyze main PO problems and their consequences to various involved parties in the network. Next, define optimal PQ criteria at the customer's point of connection (POC) and finally specify responsibilities of the involved parties". The thesis is based on practical field measurements of PQ parameters in the network, on analyzing the developed network models by using computer simulations and laboratory experiments. The most important part of the work is the verification of simulation results with thepractical measurements. Further, the obtained results are compared with the values given in the available standards. Lastly optimal PQ parameters at a poc are defined for flicker, harmonics and voltage dips. A summary of the research work reported in this thesis is as follows: • Obtained a deeper insight in PQ problems around the world • Developed typical network models for computer simulations on different PQ phenomena (such as flicker, harmonics and voltage dips) and verified the results with field measured data • Gathered practical information on various technical and financial consequences of inadequate PQ for different parties namely: the network operators, the customers and the equipment manufacturers • Made an inventory on various existing (and developing) standards and technical documents on PQ around the world. Then, compared the limits given on various PQ parameters in those standards/documents and discussed their relevance and applicability in the future • A proposal is given about optimal PQ limits (for flicker, harmonics) at the low voltage (LV) customer's POC Also, the average and maximum values of voltage dips in the networks are estimated • Suitable planning level limit values for flicker, harmonics and voltage dips are proposed • PQ related responsibilities of the customers, network operators and device manufacturer at the customer's POC are defined The main conclusions and thesis contributions are: • It is found that a harmonization among the presently available PQ standards is required and a dedicated set of global standards is needed to get optimal PQ at the customer's POC Various limiting values on different PQ parameters (e.g. flicker emission and harmonic current emission limits for a customer) at a POC are proposed in this thesis. Also, the average and maximum numbers of voltage dips in the Dutch high voltage (HV) and medium voltage (MV) networks are estimated. • A new set of planning level values for flicker severities at different voltage levels of a network is proposed. For harmonics, a proposal is given to change the planning level values for 'triple n' harmonic voltages and new values are suggested for the MV and LV networks. Moreover, it was proposed that the 3rd harmonic summation coefficient value of the standard can be modified to a higher value as sufficient diversity is found in the system. Regarding voltage dips, the numbers of planning and compatibility levels are proposed for a MV network in the Netherlands. In this thesis, PQ responsibility sharing procedures are defined for a network operator, customer and a device manufacturer. Network impedance is identified as an important parameter in deciding flicker and harmonics at a POC The network operator should provide information on the approximate number of occurrence of voltage dips in a year at a customer's POC To maintain sufficient PQ level in the network, all the involved parties should follow certain rules and duties. It was concluded that PQ regulation can be successfully implemented in the electricity business when all the involved parties are aware of their respective responsibilities in the network

Power quality analysis and automatic intelligent control strategy for solar PV microgrid

My thesis focuses on quantification of the power quality issues in a solar photovoltaic based microgrid network through the simulation and experimental approach. PSO based optimization control strategy was also implemented to further improve the power quality factors in the Microgrid network<br /