A comprehensive techno-economic and power quality analysis of a remote PV-diesel system in Australia

Presently, the world is considering the integration of small, medium and large-scale PV systems into both urban and remote rural electricity networks. This sees a transition towards a 100% renewable energy based electricity supply from the current conventional fossil fuel based electricity supply. Australia has a significant electricity generation potential from solar PV resources which also encourages the uptake of PV-battery hybrid systems. Australian utilities operating in the isolated and remote areas are now seriously considering the integration of solar PV systems as a long-term solution to reduce costs and facilitate sustainable electricity generation. This would also defer expensive grid extension to supply electricity to these dispersed remote communities. This study aims to model and optimise a remote Australian PV-diesel system incorporated with high levels of PV penetration and battery storage and investigate the system power quality issues. The study includes system component optimisation and techno-economic analysis which considers the outcomes regarding the cost of energy (AUD$/kWh), fuel savings potential and environmental impacts. Power quality issues have been explored by analysing the response of fast frequency-responsive (FFR) battery storage. The overall study has found that higher levels of PV penetration integrated with the current diesel operated system provides a comprehensive and efficient electricity supply and FFR Li-ion batteries can mitigate transient power quality issues and maintain system frequency within acceptable limits

The renewable energy household lighting for Chibayish inhabitant’s in Iraq

Affordable and clean energy is one of the major goals for global sustainable development. Lighting is a major aspect of human energy consumption and access to quality lighting is one of the most important indicators of human development. Like other countries around the world, the Iraqi government has realized the importance of climate change and the necessity for clean energy which has led them to officially ratifying the Kyoto Protocol in January 2008. However, it is challenging to implement a clean and renewable energy lighting system for a small community like Chibayish in the Iraqi marshes. The Chibayish unique house building technique of man-made islands (floating baskets), results that these floating houses are not connected to the Iraqi national grid. The villagers in Chibayish require artificial light for their indoor living areas after dark and also for night fishing, which is a common practice. In this research study, various renewable energy resources have been examined in order to identify the most locally practical renewable energy technology for household lighting needs. The solar irradiance profile in the area showed the viability of solar energy in comparison to other renewable energy sources considered within these specific environmental conditions. An analysis carried out using HOMER Pro simulator shows that the solar photovoltaic is an affordable and reliable option for this community

Life cycle assessment of domestic heat pump hot water systems in Australia

Water heating accounts for 23% of residential energy consumption in Australia, and, as over half is provided by electric water heaters, is a significant source of greenhouse gas emissions. Due to inclusion in rebate schemes heat pump water heating systems are becoming increasingly popular, but do they result in lower greenhouse gas emissions? This study follows on from a previous life cycle assessment study of domestic hot water systems to include heat pump systems. The streamlined life cycle assessment approach used focused on the use phase of the life cycle, which was found in the previous study to be where the majority of global warming potential (GWP) impacts occurred. Data was collected from an Australian heat pump manufacturer and was modelled assuming installation within Australian climate zone 3 (AS/NZS 4234:2011). Several scenarios were investigated for the heat pumps including different sources of electricity (grid, photovoltaic solar modules, and batteries) and the use of solar thermal panels. It was found that due to their higher efficiency heat pump hot water systems can result in significantly lower GWP than electric storage hot water systems. Further, solar thermal heat pump systems can have lower GWP than solar electric hot water systems that use conventional electric boosting. Additionally, the contributions of HFC refrigerants to GWP can be significant so the use of alternative refrigerants is recommended. Heat pumps combined with PV and battery technology can achieve the lowest GWP of all domestic hot water systems

Reviewing the scope and thematic focus of 100,000 publications on energy consumption, services and social aspects of climate change: a big data approach to demand-side mitigation

As current action remains insufficient to meet the goals of the Paris agreement let alone to stabilize the climate, there is increasing hope that solutions related to demand, services and social aspects of climate change mitigation can close the gap. However, given these topics are not investigated by a single epistemic community, the literature base underpinning the associated research continues to be undefined. Here, we aim to delineate a plausible body of literature capturing a comprehensive spectrum of demand, services and social aspects of climate change mitigation. As method we use a novel double-stacked expert—machine learning research architecture and expert evaluation to develop a typology and map key messages relevant for climate change mitigation within this body of literature. First, relying on the official key words provided to the Intergovernmental Panel on Climate Change by governments (across 17 queries), and on specific investigations of domain experts (27 queries), we identify 121 165 non-unique and 99 065 unique academic publications covering issues relevant for demand-side mitigation. Second, we identify a literature typology with four key clusters: policy, housing, mobility, and food/consumption. Third, we systematically extract key content-based insights finding that the housing literature emphasizes social and collective action, whereas the food/consumption literatures highlight behavioral change, but insights also demonstrate the dynamic relationship between behavioral change and social norms. All clusters point to the possibility of improved public health as a result of demand-side solutions. The centrality of the policy cluster suggests that political actions are what bring the different specific approaches together. Fourth, by mapping the underlying epistemic communities we find that researchers are already highly interconnected, glued together by common interests in sustainability and energy demand. We conclude by outlining avenues for interdisciplinary collaboration, synthetic analysis, community building, and by suggesting next steps for evaluating this body of literature

Solar PV Electrification Programs in Developing Countries: Towards an Holistic Approach

Rural renewable electrification programs are increasingly being used as a means of providing the rural poor in developing countries with access to electricity. Those programs have varied significantly in design and implementation, as well as in their degrees of success. The explanations for the lack of success and the non-sustainability of the earliest programs are widely accepted as these tended to be technical demonstration projects that relied totally on funding from donor organisations or governments. These projects ignored or overlooked the vital question of how ongoing operational, maintenance and replacement costs would be met. Many genuine programs, however, also met with limited success and much effort has been invested in attempting to understand the reasons for this lack of success. To increase the rates of success of these programs, best practice guidelines were developed. Despite these efforts, many programs have continued to meet with limited success. These points required better explanations of the reasons for program success and failure, which requires a greater understanding of these programs. This thesis looks more closely at solar PV electrification programs being undertaken in the Asia-Pacific region to understand why some programs continue to be more successful than others. It aims to understand the decisions behind the planning and implementation of the programs and the reasons that are being implemented in the way that they are, the selection of program objectives, the actual benefits of the programs the and causes of any factors that contribute to their apparent success or lack of success. This understanding is obtained by undertaking in-depth comprehensive field surveys to obtain the views of all program stakeholders. The outcomes of these field surveys are then used to develop a comprehensive set of success criteria and a set of indicators that can be used to measure the success of rural renewable electrification programs. A roadmap that could be followed by the program planners and implementers to ensure program success is also provided

The renewable energy household lighting for Chibayish inhabitant’s in Iraq

Affordable and clean energy is one of the major goals for global sustainable development. Lighting is a major aspect of human energy consumption and access to quality lighting is one of the most important indicators of human development. Like other countries around the world, the Iraqi government has realized the importance of climate change and the necessity for clean energy which has led them to officially ratifying the Kyoto Protocol in January 2008. However, it is challenging to implement a clean and renewable energy lighting system for a small community like Chibayish in the Iraqi marshes. The Chibayish unique house building technique of man-made islands (floating baskets), results that these floating houses are not connected to the Iraqi national grid. The villagers in Chibayish require artificial light for their indoor living areas after dark and also for night fishing, which is a common practice. In this research study, various renewable energy resources have been examined in order to identify the most locally practical renewable energy technology for household lighting needs. The solar irradiance profile in the area showed the viability of solar energy in comparison to other renewable energy sources considered within these specific environmental conditions. An analysis carried out using HOMER Pro simulator shows that the solar photovoltaic is an affordable and reliable option for this community

Empowering Low-Income Communities with Sustainable Decentralized Renewable Energy-Based Mini-Grids

With less than seven years before the UN’s Sustainable Development Goals deadline, the race is on to achieve universal access to affordable, reliable and modern energy services in low-income communities in developing countries. These communities are mostly distant from central grids and economically suitable for off-grid mini-grid systems. Data suggest that these mini-grids are not sustained and often fail after a few years of operation. The authors investigated the challenges of an existing mini-grid system in Ghana and proposed measures to overcome them. Field surveys with expert stakeholders and users of the system were conducted to examine the challenges. The results showed that 98% of the residents use power for domestic purposes. The inability to pay for the power consumed was the highest-ranked challenge the users faced followed by power quality issues. From the expert stakeholders’ perspectives, economic challenges were the most significant barriers with a mean score range of 3.92 to 4.73 on a 1–5 Likert scale, followed by political challenges. The researchers propose that implementers must optimize non-hardware costs and promote local component manufacturing to address these economic challenges. In addition, we suggest that the government review the government-driven policy and involve the private sector

A comprehensive techno-economic and power quality analysis of a remote PV-diesel system in Australia

Presently, the world is considering the integration of small, medium and large-scale PV systems into both urban and remote rural electricity networks. This sees a transition towards a 100% renewable energy based electricity supply from the current conventional fossil fuel based electricity supply. Australia has a significant electricity generation potential from solar PV resources which also encourages the uptake of PV-battery hybrid systems. Australian utilities operating in the isolated and remote areas are now seriously considering the integration of solar PV systems as a long-term solution to reduce costs and facilitate sustainable electricity generation. This would also defer expensive grid extension to supply electricity to these dispersed remote communities. This study aims to model and optimise a remote Australian PV-diesel system incorporated with high levels of PV penetration and battery storage and investigate the system power quality issues. The study includes system component optimisation and techno-economic analysis which considers the outcomes regarding the cost of energy (AUD$/kWh), fuel savings potential and environmental impacts. Power quality issues have been explored by analysing the response of fast frequency-responsive (FFR) battery storage. The overall study has found that higher levels of PV penetration integrated with the current diesel operated system provides a comprehensive and efficient electricity supply and FFR Li-ion batteries can mitigate transient power quality issues and maintain system frequency within acceptable limits

Influence of occupancy on building energy performance: a case study from social housing dwellings in Perth, Western Australia

Worldwide, the residential sector is a substantial energy consumer mainly due to the requirements of space heating and cooling, lighting and electronic appliances in the building. In Australia, the residential sector accounts for a significant proportion of final energy consumption, with a significant proportion of this energy attributed to space conditioning. Appliances including lighting, refrigeration, water heating, cooking and standby power also factoring into the energy used in Australian households. In response to sharp rises in energy prices in recent years, many households are taking steps to reduce their energy consumption. Many are investing in energy efficient appliances, home upgrades, installing rooftop solar panels, etc. However, low income can become a barrier, preventing many people from investing in energy efficiency as a way of reducing costs. This paper is a part of a broader study aiming to identify the areas of energy inefficiency in social housing dwellings, and improve the overall efficiency through modifying occupants’ energy use culture. The firsthand information on where and how energy is used in the dwellings was collected through conducting walk-through energy audits in the sample dwellings. This information was then combined with the information provided by the households’ representatives on the time of use of their appliances as well as direct observations to calculate energy consumption in these households. Practical guidelines were then proposed, taking into account their energy use behaviour to minimize their energy consumption at a minimum cost

Dust Effect and its Economic Analysis on PV Modules Deployed in a Temperate Climate Zone

AbstractThe aim of this study is to investigate the effect of dust on the degradation of PV modules deployed in a temperate climate region, Perth, Western Australia. Results revealed that PV performance, quantified by normalised maximum power output, varied with season. For a one-year period of study, over which the only cleaning activities were due to wind and rain, the performance of PV modules deployed in Perth, decreased at the end of summer and spring, tended to increase at the end of autumn and reached their peaks at the end of the winter season. Assuming the effect of dust on Pmax output is similar among the PV modules and is linear among the consecutive seasons, economic analysis indicated that the total cost of production losses of 13 polycristalline silicone PV modules caused by dust (A$5.47) is lower than total cleaning cost (A$ 78). Therefore, no cleaning procedure is recommended for the grid-connected PV system simulated in the case study