Variability and performance analysis of the PV plant at The University of Queensland

Raygani, Saeid Veysi; Sharma, Rahul; Saha, Tapan Kumar

doi:10.1109/aupec.2013.6725342

Cited by 4 publications

(2 citation statements)

References 12 publications

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“…For example, in Australia, coal plants work at near 85%, while wind power plants at around 35% and peak power hydro plant at around 17.4% capacity factor. Capacity factors for gas power station vary from 85% as base power to less than 10% while they are used for peak power [11].…”

Section: Total Energy Produced (Kwh) Cf=mentioning

confidence: 99%

Analysing the PV output variability and its mitigation through aggregation in Queensland, Australia

Raygani

Sharma

Saha

2014

2014 IEEE PES General Meeting | Conference &Amp; Exposition

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Aggregation of photovoltaic (PV) plants has a potential to reduce the variability in power output to enhance large-scale integration of PV plants with power systems. Nevertheless, effectiveness of aggregation has to be evaluated on a case-by-case basis for various PV plants. This paper performs a quantitative analysis to investigate the reduction in PV output variability in Queensland, Australia by considering two utility scale PV plants. Based on some existing results, a PV output prediction model is developed, which explicitly takes into account the module temperature. This model is then used to predict the PV output of a modeled PV plant and aggregates it with the existing PV plant at The University of Queensland. Substantial reductions in ramp rate variability are observed through the aggregation for all the four seasons with most reductions obtained for the summer season. Index Terms-Aggregation of PV plants, PV output prediction, temperature, variability I.

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Section: Total Energy Produced (Kwh) Cf=mentioning

confidence: 99%

Analysing the PV output variability and its mitigation through aggregation in Queensland, Australia

Raygani

Sharma

Saha

2014

2014 IEEE PES General Meeting | Conference &Amp; Exposition

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“…It is also more beneficial to look at the uncertainty in a larger time-frame. If the uncertainty set of solar generations is created on the daily bases using metrics such as DEI and DUI [44][45][46], the RO becomes more accurate and realistic. In this approach, the bound of uncertainty applies to the forecast of the daily-based metrics rather than the instantaneous forecast.…”

Section: Introductionmentioning

confidence: 99%

Robust unit commitment with characterised solar PV systems

Raygani

2018

IET Renewable Power Generation

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This article addresses a critical issue on the robust unit commitment (RUC), which is the construction of an accurate and reliable uncertainty set for solar photovoltaic (PV) systems. The classic robust unit commitment (CRUC) provides an inaccurate and unreliable model for the highly intermittent solar generations. However, the authors' proposed uncertainty set utilises the forecast models that rely on the clear-sky and overcast solar forecasts, which are more accurate and reliable. The uncertainty set for solar generations is constructed based on the type of day, levels of daily uncertainty index (DUI) and daily energy index (DEI), and the uncertainty level of solar ramps. The test results on the IEEE 118-bus test system demonstrate that (i) using DEI and DUI reliably and efficiently manages and reduces the cost for highly uncertain and overcast day compared to the CRUC and (ii) the RUC cost is much sensitive to the selected level of DUI and DEI than the uncertainty level of the solar ramps.

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