8 results on '"Watson, N. R."'
Search Results
2. NEW INTERHARMONIC SUBGROUP DEFINITIONS FOR QUANTIFYING AND LIMITING DISTORTION IN DISTRIBUTION NETWORKS
- Author
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Drapela, J., primary, Halpin, M., additional, Langella, R., additional, Meyer, J., additional, Mueller, D., additional, Sharma, H., additional, Testa, A., additional, Watson, N. R., additional, and Zech, D., additional
- Published
- 2021
- Full Text
- View/download PDF
3. New Zealand Guideline for the Connection of PV Solar Power and Determining Hosting Capacity for PV Solar Power.
- Author
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Strahan, R. J., McNab, S. J., Pandey, S., Lemon, S. M., Miller, A. J. V., Watson, N. R., and Wood, A. R.
- Subjects
PHOTOVOLTAIC power generation ,SOLAR energy ,ELECTRIC potential ,ELECTRIC power distribution ,ELECTRICAL engineers - Abstract
Small-scale distributed generation (DG) in New Zealand, particularly photovoltaic (PV) generation, has been growing steadily over the past few years. In the last year alone to 31 March 2016, installed PV generation of all capacities has grown by a factor of about 1.6 to reach 37 MW. Approximately 90% (33 MW) of this installed PV capacity is made up of small-scale, single phase residential grid-tied systems with ratings below 10 kW. This corresponds, on average, to approximately 300-400 new PV systems being installed each month within low voltage (LV) distribution networks. Traditionally, the flow of power in electricity distribution networks has been largely unidirectional. However, distributed generation introduces reverse power flows into the LV network when the power produced by DG systems is greater than what can be consumed locally. This introduction of reverse power flows and the dynamic behavior of DG system inverters can negatively impact the electricity network, causing issues such as over-voltage, phase imbalance, overloading of conductors and transformers, and create unique safety challenges. As such, each DG connection application received by electricity distribution businesses (EDBs) presently needs to be carefully considered for its impact on the electricity network. The resourcing demand imposed by larger numbers of connection applications, and the difficulty of technical assessment including congestion evaluation, are likely to increase substantially as DG uptake intensifies. This has prompted the Electric Power Engineering Centre (EPECentre) via its GREEN Grid programme, with the assistance of the electricity industry based Network Analysis Group (NAG), to develop a small-scale inverter based DG connection guideline for New Zealand EDBs. This has been developed on behalf of the Electricity Engineers' Association (EEA) specifically for the connection of inverter energy systems (IES) of 10 kW or less. This paper summarizes key aspects of this guideline. This includes a streamlined connection application evaluation process that enables EDBs to efficiently categorize DG applications into three groups. These groups vary from those with minimal or moderate network impact that can be autoassessed, to those most likely to cause network congestion that require manual assessment. These categories are determined by looking at the DG hosting capacity specific to the LV network that the DG is connecting to. For two of these categories, mitigation measures for connection, are prescribed. It is also shown how DG hosting capacity can be used to simply evaluate LV network congestion in order to satisfy Electricity Industry Participation Code (EIPC) Part 6 requirements. Key technical requirements for all IES, appropriate for New Zealand conditions, are also summarized. [ABSTRACT FROM AUTHOR]
- Published
- 2016
4. Measurement of phase dependent impedance for 3-phase diode rectifier.
- Author
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JunBum Kwon, Xiongfei Wang, Claus Leth Bak, Blaabjerg, Frede, Hwang, Michael, Wood, Alan R., Watson, N. R., and Esparza, Miguel
- Published
- 2016
- Full Text
- View/download PDF
5. Issues and Challenges Related to Interharmonic Distortion Limits
- Author
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David Mueller, David P. Zech, Jan Meyer, Neville R. Watson, Alfredo Testa, Harish Sharma, Mark Halpin, Roberto Langella, Jiri Drapela, IEEE, Drapela, J., Halpin, M., Langella, R., Meyer, J., Mueller, D., Sharma, H., Testa, A., Watson, N. R., and Zech, D.
- Subjects
Power Quality ,Transmission (telecommunications) ,Computer science ,020209 energy ,Distortion ,Harmonics ,Interharmonic ,0202 electrical engineering, electronic engineering, information engineering ,Electronic engineering ,Power quality ,02 engineering and technology ,Limit ,Standard - Abstract
This paper reports the issues and challenges behind the proposal to include interharmonic limits in the next revision of the IEEE Standard 519 as discussed within the interharmonic distortion sub-group formed in the framework of the Harmonics WG (519) of the IEEE PES Transmission & Distribution Committee.
- Published
- 2020
6. Analysis of approaches for modeling the low frequency emission of LED lamps
- Author
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Jiri Drapela, Neville R. Watson, Roberto Langella, Adam J. Collin, Z. Guo, Alfredo Testa, Sasa Z. Djokic, Collin, A. J., Djokic, S. Z., Drapela, J., Guo, Z., Langella, R., Testa, A., and Watson, N. R.
- Subjects
Control and Optimization ,Computer science ,020209 energy ,Frequency-domain model ,Energy Engineering and Power Technology ,02 engineering and technology ,Low frequency ,lcsh:Technology ,law.invention ,Time-domain analysis ,law ,Component-based model ,component-based model ,frequency-domain model ,LED lamps ,power system harmonics ,time-domain analysis ,0202 electrical engineering, electronic engineering, information engineering ,Electronic engineering ,Power-flow study ,Time domain ,Electrical and Electronic Engineering ,Power system harmonic ,Engineering (miscellaneous) ,LED lamp ,Renewable Energy, Sustainability and the Environment ,lcsh:T ,020208 electrical & electronic engineering ,Frequency domain ,Harmonic ,Low voltage ,Energy (miscellaneous) ,Voltage ,Light-emitting diode - Abstract
Light emitting diode (LED) lamps are now an established lighting technology, which is becoming prevalent in all load sectors. However, LED lamps are non-linear electrical loads, and their impact on distribution system voltage quality must be evaluated. This paper provides a detailed analysis of time domain and frequency domain approaches for developing and evaluating models suitable for use in large scale steady-state harmonic power flow analysis of the low frequency (LF) emission of LED lamps. The considered approaches are illustrated using four general categories of LED lamps, which have been shown to cover the vast majority of LED lamps currently available on the market. The aim is an in-depth assessment of the ability of commonly applied models to represent the specific design characteristics of different categories of LED lamps. The accuracy of the models is quantitatively evaluated by means of laboratory tests, numerical simulations, and statistical analyses. This provides an example, for each LED lamp category, of comprehensive information about the overall accuracy that can be achieved in the general framework of large scale LF harmonic penetration studies, particularly in the assessment of voltage quality in low voltage networks and their future evolution.
- Published
- 2020
7. Transient State Estimation for Transmission Systems
- Author
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Neville R. Watson, A. Castellanos-Escamilla, Roberto Langella, IEEE, Castellanos-Escamilla, A., Watson, N. R., and Langella, R.
- Subjects
Transient state ,electromagnetic transient ,Computer science ,Transmission system ,power quality ,Transient state estimation ,travelling wave transmission line ,Electric power transmission ,Control theory ,Transmission line ,Integrator ,Waveform ,Node (circuits) ,Transient (oscillation) - Abstract
As measurement and communication technology improves algorithms are being developed to get more useful information from the recorded data. One such technique is transient state estimation (TSE) which estimates the node voltages at unmonitored location from current and voltage waveforms measurements recorded during a transient event. This is useful for determining the sources of disturbances. One of the previous limitations was the lumped representation of transmission lines which limited its application to distribution systems. This paper presents a new distributed parameter transmission line model using numerical integrator substitution approach for modelling the travelling wave transmission line model. The accuracy of the model is investigated for different scenarios. To do so, the proposed algorithm is applied to two test transmission systems. The results show that a good estimation is obtained with the proposed algorithm when long transmission lines are present in the system being estimated.
- Published
- 2020
8. Harmonic Modelling of LED lamps by Means of Admittance Frequency Coupling Matrices
- Author
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Adam J. Collin, Sasa Z. Djokic, Roberto Langella, Neville R. Watson, Alfredo Testa, Jiri Drapela, IEEE, Collin, A. J., Drapela, J., Langella, R., Testa, A., Djokic, S. Z., and Watson, N. R.
- Subjects
Physics ,LED lamp ,Admittance ,Frequency coupling matrice ,020209 energy ,Acoustics ,Non-linear equipment ,020208 electrical & electronic engineering ,Fingerprint (computing) ,Harmonic ,02 engineering and technology ,law.invention ,Power quality ,law ,Harmonics ,0202 electrical engineering, electronic engineering, information engineering ,Tensor representation ,Frequency coupling - Abstract
The paper reports an experimental evaluation of LED lamps in terms of admittance Frequency Coupling Matrices (FCM) for harmonic modelling needs. After recalling the FCM approach, a description of the experimental setup used and an LED lamp classification previously proposed by the authors is presented. For each of the four lamp types identified, some harmonic fingerprint plots are shown to introduce the admittance characteristics. More detailed analysis of the characteristics is performed using the tensor representation of the FCM, which compares characteristics between the different lamp types and also between different lamps of the same type. It is shown that this approach can identify characteristics of different types of lamps for modelling purposes.
- Published
- 2019
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