Your search keyword '"Negnevitsky, Michael"' showing total 6 results

1. Investigating Using Stochastic Methods to Generate Training Data for Windpower Prediction

Author

Potter, Cameron and Negnevitsky, Michael

Published

2007

2. Solar Hot Water Systems Using Latent Heat Thermal Energy Storage: Perspectives and Challenges.

Author

Modi, Nishant, Wang, Xiaolin, and Negnevitsky, Michael

Subjects

HOT water, LATENT heat, WATER use, HYDRONICS, ENERGY consumption, ENERGY consumption of buildings

Abstract

Domestic water heating accounts for 15% to 27% of the total energy consumption in buildings in Australia. Over the past two decades, the latent heat thermal energy storage (LHTES) system has been widely investigated as a way to reduce fossil fuel consumption and increase the share of renewable energy in solar water heating. However, the research has concentrated on the geometric optimisation of the LHTES heat exchanger for the past few years, and this might not be sufficient for commercialisation. Moreover, recent review papers mainly discussed the development of a particular heat-transfer improvement technique. This paper presents perspectives on various solar hot water systems using LHTES to shift focus to on-demand performance studies, as well as structure optimisation studies for faster commercialisation. Future challenges are also discussed. Since the topic is an active area of research, this paper focuses on references that showcase the overall performance of LHTES-assisted solar hot water systems and cannot include all published work in the discussion. This perspective paper provides directional insights to researchers for developing an energy-efficient solar hot water system using LHTES. [ABSTRACT FROM AUTHOR]

Published

2023

3. Grid-Scale Battery Energy Storage Operation in Australian Electricity Spot and Contingency Reserve Markets.

Author

Bayborodina, Ekaterina, Negnevitsky, Michael, Franklin, Evan, and Washusen, Alison

Subjects

*ENERGY storage, *GRID energy storage, *BATTERY storage plants, *SOLAR power plants, *ELECTRIC batteries, *ELECTRICITY markets

Abstract

Conventional fossil-fuel-based power systems are undergoing rapid transformation via the replacement of coal-fired generation with wind and solar farms. The stochastic and intermittent nature of such renewable sources demands alternative dispatchable technology capable of meeting system stability and reliability needs. Battery energy storage can play a crucial role in enabling the high uptake of wind and solar generation. However, battery life is very sensitive to the way battery energy storage systems (BESS) are operated. In this paper, we propose a framework to analyse battery operation in the Australian National Electricity Market (NEM) electricity spot and contingency reserve markets. We investigate battery operation in different states of Australia under various operating strategies. By considering battery degradation costs within the operating strategy, BESS can generate revenue from the energy market without significantly compromising battery life. Participating in contingency markets, batteries can substantially increase their revenue with almost no impact on battery health. Finally, when battery systems are introduced into highly volatile markets (such as South Australia) more aggressive cycling of batteries leads to accelerated battery aging, which may be justified by increased revenue. The findings also suggest that with falling replacement costs, the operation of battery energy systems can be adjusted, increasing immediate revenues and moving the battery end-of-life conditions closer. [ABSTRACT FROM AUTHOR]

Published

2021

4. Very Short-Term Wind Forecasting for Tasmanian Power Generation.

Author

Potter, Cameron W. and Negnevitsky, Michael

Subjects

*WIND power, *ELECTRIC power production, *ELECTRIC power systems, *ELECTRIC power transmission, *ELECTRIC utilities

Abstract

This paper describes very short-term wind prediction for power generation, utilizing a case study from Tasmania, Australia. Windpower presently is the fastest growing power generation sector in the world. However, windpower is intermittent. To be able to trade efficiently, make the best use of transmission line capability, and address concerns with system frequency in a re-regulated system, accurate very short-term forecasts are essential. The research introduces a novel approach—the application of an adaptive neuro-fuzzy inference system to forecasting a wind time series. Over the very short-term forecast interval, both windspeed and wind direction are important parameters. To be able to be gain the most from a forecast on this time scale, the turbines must be directed toward on oncoming wind. For this reason, this paper forecasts wind vectors, rather than windspeed or power output. [ABSTRACT FROM AUTHOR]

Published

2006

5. The Role of Low-Load Diesel in Improved Renewable Hosting Capacity within Isolated Power Systems.

Author

Hamilton, James, Negnevitsky, Michael, Wang, Xiaolin, and Semshchikov, Evgenii

Subjects

*GREEN diesel fuels, *HYBRID power systems, *DIESEL electric power-plants

Abstract

Isolated communities are progressively integrating renewable generation to reduce the societal, economic and ecological cost of diesel generation. Unfortunately, as renewable penetration and load variability increase, systems require greater diesel generation reserves, constraining renewable utilisation. Improved diesel generator flexibility can reduce the requirement for diesel reserves, allowing increased renewable hosting. Regrettably, it is uncommon for utilities to modify diesel generator control during the integration of renewable source generation. Identifying diesel generator flexibility and co-ordination as an essential component to optimising system hosting capacity, this paper investigates improved diesel generator flexibility and coordination via low-load diesel application. Case study comparisons for both high- and low-penetration hybrid diesel power systems are presented in King Island, Australia, and Moloka'i, Hawai'i, respectively. For King Island, the approach details a 50% reduction in storage requirement, while for Moloka'i the application supports a 27% increase in renewable hosting capacity. [ABSTRACT FROM AUTHOR]

Published

2020

6. Assessment of wind and wave power characteristic and potential for hybrid exploration in Australia.

Author

Gao, Qiang, Khan, Salman Saeed, Sergiienko, Nataliia, Ertugrul, Nesimi, Hemer, Mark, Negnevitsky, Michael, and Ding, Boyin

Subjects

*WIND waves, *OCEAN wave power, *WIND power, *WAVE energy, *ENERGY crops, *POWER resources, *WIND forecasting, *SEISMIC prospecting

Abstract

Offshore wind and wave power are abundant energy sources and could provide long term contributions to our future energy supply. The combined exploration of wind and wave power has been proposed as an effective way to mitigate the non-negligible power intermittency and variability of offshore renewables. However, the assessments of wind and wave resources have been developed separately in Australia, and the potential of diversified wind and wave power has not been studied systematically. This study investigates offshore wind and wave energy sources in multiple locations around the Australian coastline and their potentials for integration in terms of energy availability, power variability, coherence and correlation, and annual and seasonal variability over the last seven years. In addition, wind and wave mixed energy farms are studied using commercial wind turbine models and various wave energy converter prototype models. The energy availability, power smoothing effect, capacity factor and downtime of these mixed energy farms are also discussed. Moreover, this paper proposes an effective matrix for assessing the potential of hybrid energy farms in multiple sites in terms of power availability, power variability and combination performance and the sensitivity of selecting various wave energy converter (WEC) models is also investigated to provide a general guideline for future work. The regional comparative results indicate that the swell wave dominated sites in Western and Southern Australia present merits for combining wind and wave power, while wind–wave dominated regions, such as Eastern Australia, are not preferable for this diversified system. It can be found that power variability and downtime can be significantly reduced for the specific wind–wave capacity mix if a lower correlation or longer lag time exists between the two renewables. The results also illustrate that the combinations with different WEC systems present varying benefits in the different locations in Australia. • Wind and wave energy resources are assessed in Australian region. • A wave identification system is designed for hybrid exploration. • A matrix to assess the potential of combined energy farm is proposed. • Sensitivity of WEC selection to the combined energy farm is investigated. [ABSTRACT FROM AUTHOR]

Published

2022