Showing total 34 results

1. Feasibility of net zero energy high rise apartment buildings in Australia.

Author

Alawode, Adisa and Rajagopalan, Priyadarsini

Subjects

*HIGH-rise apartment buildings, *TALL buildings, *APARTMENT buildings, *TEMPERATE climate, *DWELLINGS, *ENERGY consumption

Abstract

• Investigated strategies that can deliver NZE performance for high-rise residential buildings in Australia. • It was challenging for tropical, subtropical and cold temperate climates to meet the NZE targets. • Design and optimisation of the envelope was effective in overcoming the challenges imposed by the more demanding climates. • The impacts of shading from neighbouring buildings presented the largest obstacle to energy production through the façade. • Study demonstrated a need to include density factors in the design consideration for NZE high-rise residential designs. Net-Zero Energy (NZE) buildings are gaining popularity globally as a solution to reduce operational energy usage and limit greenhouse gas emissions in the building industry. Their deployment is occurring rapidly as many countries are planning to make it mandatory for new developments. Despite the advancements in research in the various aspects of NZE, significant barriers do exist to its successful adoption and implementation, particularly with respect to high-rise residential buildings which are becoming a major portion of the housing supply in Australia. One of the challenges attributed to the achievement of NZEB performance is the uncertainty involved in selecting appropriate solution strategies that could deliver quality performances. This paper investigated strategies that can deliver NZE performance for high-rise residential buildings in Australia. A calibrated model of 26 storey high-rise apartment building with 396 units was prepared for detailed analysis of NZE strategies using building simulation. The impact of various interventions was evaluated across cities in five climate zones in Australia and a guideline for solution sets that can deliver the goal for each climate zone is presented. The findings show that NZE performance for high-rise residential buildings can be realised in Australia, albeit with some limitations. While the tropical, subtropical and cold temperate climates appear to be more challenging, proper design and optimisation of the envelope proved to be effective in overcoming the challenges imposed by the more demanding climates. The impacts of shading from neighbouring buildings and objects presented the largest impediment to energy production through the façade. [ABSTRACT FROM AUTHOR]

Published

2022

2. Solar industrial process heating systems in operation – Current SHIP plants and future prospects in Australia.

Author

Farjana, Shahjadi Hisan, Huda, Nazmul, Mahmud, M.A. Parvez, and Saidur, R.

Subjects

*SOLAR power plants, *SOLAR heating, *FOSSIL fuels, *SOLAR thermal energy, *ENERGY consumption

Abstract

Solar thermal technology to supply process heat in different industrial sectors has become very promising in recent years. Industries can reduce their consumption of fossil fuels by replacing them with solar process heat with non-conventional system integration and using clean energy. In this paper, a systematic review of 10 countries is presented which demonstrated extensive use of solar industrial process heating systems in their manufacturing sectors. This country-wise analysis is then used to compare with current Australian scenario and identify future prospects of integrating solar process heating in Australian industrial sectors. The choice of countries is based on a database where promising industrial sectors and solar process heating applications are currently using incident solar energy. These are analyzed for their potential of integration to developing solar heat in industrial processes (SHIP) and a number of potential industrial sectors that have the highest potential like Motor vehicles, Textiles, Printing, Wood, Paper, Fabricated metal, Rubber and plastics, chemicals, Food, beverages, electrical equipment, machinery, and equipment are being identified. An overview of available studies is discussed in this paper focused on specific countries and the industrial heat demand of existing operational plants. Future trends due to solar energy potential are also outlined. [ABSTRACT FROM AUTHOR]

Published

2018

3. The impact of various carbon reduction policies on green flowshop scheduling.

Author

Foumani, Mehdi and Smith-Miles, Kate

Subjects

*BASELINE emissions, *LINEAR programming, *SCHEDULING, *CARBON, *SET theory, *MAINTENANCE

Abstract

• Presenting a set of mathematical models for green flowshop scheduling problems. • Considering common carbon reduction policies and their corresponding scenarios. • Providing analysis of models and insights to design a framework for green flowshops. • Industries can use our cost-effective strategies to meet limits mandated by government. • Government can explore our integrated framework to gauge impacts of carbon policies. In this paper we consider, from an environmental policy-maker perspective, how carbon reduction policies impact the economic competitiveness of the manufacturing sector. Specifically, we focus on flowshop scheduling – which typically aims to minimize makespan for purely economic objectives – and consider how three common carbon reduction policies – namely, taxes on emissions, baselines on emissions, and emissions trading schemes – can create competitive green flowshops that balance minimization of makespan and carbon emissions. The goal is to enable policy-makers to understand how to set policies and control parameters to achieve environmental objectives while ensuring global economic competitiveness of industry. We initially present a set of mixed-integer linear programming (MILP) models for flowshop scheduling problems operating in a regulated environment in which each carbon reduction policy is adopted. We then introduce a bi-objective scheduling framework for the corresponding problem to obtain alternative solutions under each policy. These models and their computational results however, are not the main focus of the study, but are presented as a means to demonstrate how green policies co-exist with economic objectives, with policy-makers in control of the balance. To this end, based on financial data from Australia's carbon emissions profile, we provide a policy-oriented analysis of the models, and some managerial insights into the effect of scheduling strategies on carbon emissions under different reduction policies. These insights offer support to both environmental policy-makers and corporate production and sustainability managers to determine whether it is technically feasible and profitable to replace traditional scheduling strategies with environmentally friendly scheduling strategies. [ABSTRACT FROM AUTHOR]

Published

2019

4. Assessing net energy consumption of Australian economy from 2004–05 to 2014–15: Environmentally-extended input-output analysis, structural decomposition analysis, and linkage analysis.

Author

He, He, Reynolds, Christian John, Li, Linyang, and Boland, John

Subjects

*INPUT-output analysis, *INDUSTRIAL energy consumption, *ENERGY consumption, *ENVIRONMENTAL policy, *REDUCTION potential

Abstract

• Direct and indirect effects of sectors on net energy consumption are analysed. • Level effect is identified as the major driver for increasing energy consumption. • Manufacturing has the largest energy consumption reduction potential. • How to decrease net energy consumption has been offered to policy-makers. This paper provides a comprehensive analysis of Australian net energy consumption between 2004–05 and 2014–15. Results from environmentally-extended input-output (EEIO) analysis show that the Transport sector has the largest direct effect on net energy consumption in industrial sectors, which decreased by about 35% for net energy consumption per million $AUD in the period. The Export sector has the largest direct net energy consumption while Households consumption results in the largest net energy consumption embodied in different categories of Final demand. The structural decomposition analysis (SDA) decomposes the change of net energy consumption into five drivers, in which net energy intensity mainly reduces Australian net energy consumption by about 8000 Petajoules, while the level effect of Final demand increases it by about 10,000 Petajoules. Analysis of forward and backward linkages highlights the Manufacturing sector as the key industrial sector with the largest energy consumption reduction potential via minor changes in its input and Final demand. This indicates that more attention should be given to the reduction of energy demand from the consumption patterns of Households consumption, the improvement of energy intensity, and the application of cleaner technologies in the Transport and Manufacturing sectors. The Australian Environmental-Economic Accounts is combined with Australian input-output tables to construct the EEIO tables for net energy consumption. The combination of economic and environmental data sets provides a depth of understanding their potential to inform environmental policy decisions. The novelty of the research is the combination of economic and energy data sets, the application of EEIO model, the implementation of the additive SDA method, and the use of forward and backward linkages for the Australian energy system. [ABSTRACT FROM AUTHOR]

Published

2019

5. Achieving high renewable energy penetration in Western Australia using data digitisation and machine learning.

Author

Tayal, Dev

Subjects

*RENEWABLE energy sources, *MACHINE learning, *DIGITIZATION, *ENERGY consumption, *RENEWABLE energy source management

Abstract

The energy industry is undergoing significant disruption. This research outlines that, whilst challenging, this disruption is also an emerging opportunity for electricity utilities. One such opportunity is leveraging the developments in data analytics and machine learning. As the uptake of renewable energy technologies and complimentary control systems increases, electricity grids will likely transform towards dense microgrids with high penetration of renewable generation sources, rich in network and customer data, and linked through intelligent, wireless communications. Data digitisation and analytics has already impacted numerous industries, and its influence on the energy sector is growing, as computational capabilities increase to manage big data, and as machines develop algorithms to solve the energy challenges of the future. The objective of this paper is to address how far the uptake of renewable technologies can go given the constraints of existing grid infrastructure, and provides a qualitative assessment of how higher levels of renewable energy penetration can be facilitated by incorporating even broader technological advances in the fields of data analytics and machine learning. Western Australia is used as a contextualised case-study, given its abundance and diverse renewable resources (solar, wind, biomass, and wave) and isolated networks, making a high penetration of renewables a feasible target for policy makers over coming decades. [ABSTRACT FROM AUTHOR]

Published

2017

6. Carbon neutral mine site villages: Myth or reality?

Author

Goodfield, David, Anda, Martin, and Ho, Goen

Subjects

*VILLAGES, *MINES & mineral resources, *ECOLOGICAL impact, *MINERAL industries & the environment, *RENEWABLE energy sources, *ENERGY consumption

Abstract

This paper focuses on the calculation of the carbon footprint of a typical West Australian mine site village and the ways by which it can be reduced to a point where the village can be legitimately described as ‘carbon neutral’. The study contributes to a broader ARC joint research program by Murdoch and Curtin Universities entitled ‘Decarbonising Cities and Regions’. The term carbon neutral has a far from uniform definition. For the purpose of the carbon accounting that follows carbon neutrality is achieved when there is a net zero carbon footprint across the full life cycle or when total emissions are balanced by total offsets. As much of the full life cycle of the village as is practical is included in the process and acknowledges any omissions made. The paper will show how the carbon footprint of a mine site village in Western Australia's mid-west has been measured, calculated and reduced effectively to a point where carbon neutrality can be claimed. This will commence with calculation of the embodied and operational energy in constructing and operating the village, followed by methods towards achieving carbon neutrality. The latter includes energy efficiency opportunities; an environmental and economic sustainability assessment of renewable energy and construction materials; design modification of the infrastructure; and assessment of accredited biomass offset mechanisms. The whole process has been termed LEVI©, Low Energy Village Infrastructure. An economic assessment of the carbon neutral strategy is the key to implementation. Mining companies are particularly drawn to the ‘bottom line’ when making investment decisions and only sound financial analysis will facilitate substantial carbon neutral expenditure. LEVI© significantly includes a net present cost (NPC) analysis of all such investment and belies the myth that carbon neutral mine site accommodation cannot be achieved. The paper then presents a carbon accounting methodology of the case study mine site village and set out the results and overall carbon emissions the village is responsible for. This life cycle analysis (LCA) is done from cradle to gate in terms of LCA terminology and represents the manufacture, construction, installation and operation. Energy efficiencies and behavioural changes are then applied and estimated as to their carbon reductive effect on the total carbon, followed by verifiable renewable energy offsets. These offsets are substantiated by a vigorous renewable energy analysis and selection supported by an NPC analysis. An optimum renewable energy system (RE) is then selected (best value for money) and its carbon reducing effect over the current power system calculated. This amount, together with that produced by energy efficiencies and behavioural changes, makes a total carbon reduction and is annualised. The paper clearly shows that the projected life of the mine, and therefore the village, is a critical factor in the overall carbon analysis and that the optimum time period within which carbon neutrality of such a mine site village can be claimed lays somewhere between 7 and 10 years. Another key finding was that the capital expenditure (CAPEX) savings by developing such a village as a standalone facility produces clear advantages over connection to a mine power generation system as is the case study example. The optimum standalone RE system for introduction from 2014 was found to be 110 kW fixed amorphous photovoltaic array and two 100 kW wind turbines with one 150 kW and one 100 kW low-cycle diesel generators as a backup. The projected cost was approximately $2 million. It is contended that the metrics produced from the results can provide a pro-rata basis with which to model future carbon neutral villages of similar construction. The model accommodates dependencies such as life of mine, size of village, number of workers and location. The paper will describe some innovative solutions and outcomes from this research that may be applied to the built environment on a broader scale. [ABSTRACT FROM AUTHOR]

Published

2014

7. Key concepts for Integrated Urban Water Management infrastructure planning: Lessons from Melbourne.

Author

Furlong, Casey, Brotchie, Ryan, Considine, Robert, Finlayson, Greg, and Guthrie, Lachlan

Subjects

*MUNICIPAL water supply, *INFRASTRUCTURE (Economics), *ENERGY consumption, *CLIMATE change, *MANAGEMENT

Abstract

“Integrated Urban Water Management plans” consider all water services simultaneously to determine optimal infrastructure solutions. They create many benefits, including unlocking opportunities for water reuse. This paper conducts preliminary assessment of nine IUWM plan case studies from Melbourne. It finds inconsistencies between plans in relation to environmental and liveability objectives, and option identification methods, and also that many IUWM options perform worse than conventional water supplies in regards to energy. The most consequential finding is that the plans do not include scenario planning and therefore fail to consider infrastructure performance regarding resilience to future uncertainties around population and climate change. [ABSTRACT FROM AUTHOR]

Published

2017

8. Economic modelling of the potential of wave energy

Author

Hayward, Jennifer, Behrens, Sam, McGarry, Scott, and Osman, Peter

Subjects

*WAVE energy, *ECONOMIC models, *EMISSIONS (Air pollution), *ELECTRIC power production, *ENERGY consumption, *ESTIMATES, *POWER resources

Abstract

Abstract: Wave energy is increasingly being seen as an alternative source of low-emissions power particularly for Australia, as Australia has abundant wave resources. This paper, using the performance characteristics of wave energy converters (WEC), resource measurements along Australia''s southern coastline and global resource estimates, models projections of the future uptake of wave energy globally and in Australia. Globally, wave farms are projected to be installed up to a presumed maximum limit of 500 GW. In Australia there is more variability in the amount of wave farms installed, with differences across the different WEC. The outcome globally and in Australia depends on variations in the average power generated by the WEC and the carbon price path. In Australia, the majority of projected WEC installations are in the state of Victoria, which has relatively high demand and currently highly-emissions intensive sources of generation compared to states with better wave resources. When a dispatchable, or continuous power ability is added to wave energy''s output the uptake of wave energy increases in Australia, in those states with the best resources. When the amount of wave energy extractable in any region is increased or decreased it has a large effect on output in Victoria in particular, which generates power from wave energy up to 30% of the total extractable resource under the dispatchable power scenario. Wave energy has the potential to make a significant contribution to electricity generation globally and in Australia. This paper is part two of a series of papers, the first being . [Copyright &y& Elsevier]

Published

2012

9. Energy and time modelling of kerbside waste collection: Changes incurred when adding source separated food waste.

Author

Edwards, Joel, Othman, Maazuza, Burn, Stewart, and Crossin, Enda

Subjects

*FOOD industrial waste, *ENERGY consumption, *WASTE minimization, *MATHEMATICAL models, *MANAGEMENT

Abstract

The collection of source separated kerbside municipal FW (SSFW) is being incentivised in Australia, however such a collection is likely to increase the fuel and time a collection truck fleet requires. Therefore, waste managers need to determine whether the incentives outweigh the cost. With literature scarcely describing the magnitude of increase, and local parameters playing a crucial role in accurately modelling kerbside collection; this paper develops a new general mathematical model that predicts the energy and time requirements of a collection regime whilst incorporating the unique variables of different jurisdictions. The model, Municipal solid waste collect (MSW-Collect) , is validated and shown to be more accurate at predicting fuel consumption and trucks required than other common collection models. When predicting changes incurred for five different SSFW collection scenarios, results show that SSFW scenarios require an increase in fuel ranging from 1.38% to 57.59%. There is also a need for additional trucks across most SSFW scenarios tested. All SSFW scenarios are ranked and analysed in regards to fuel consumption; sensitivity analysis is conducted to test key assumptions. [ABSTRACT FROM AUTHOR]

Published

2016

10. A review of drivers, benefits, and challenges in integrating renewable energy sources into electricity grid

Author

Zahedi, A.

Subjects

*RENEWABLE energy sources, *ELECTRIC power plants, *GLOBAL warming, *CLIMATE change, *ENERGY policy, *ELECTRIC power production, *ENERGY consumption

Abstract

Abstract: Since the global warming and climate change are recognized as real concerns, attention of power system planners and operators, energy policy makers and regulators as well as developers around the world including Australia is focused on using alternative and low emission energy technologies for electric power production. Renewable energy and energy efficient technologies have many advantages including reducing climate change, increasing sustainability in power sector, and increasing security of power supply. This paper presents an overview on both current electricity grid and future grid. Experts believe that in future more distributed generation (DG) will be integrated into the low to medium electricity grid. This paper will also review the key drivers in relation to integration of increased DG technologies in general and the renewable energy-distributed generation (RE-DG) technologies in particular, into the electric power system and the opportunities and challenges linked to these technologies. This paper also reviews possible connection location of RE-DG into the grid and its impact on system voltage. [Copyright &y& Elsevier]

Published

2011

11. Surveying the state of higher education in energy efficiency, in Australian engineering curriculum

Author

Desha, Cheryl J. and Hargroves, Karlson (Charlie)

Subjects

*ENGINEERING education, *ENERGY consumption, *COLLEGE curriculum, *ENERGY management, *EDUCATORS, *SUSTAINABLE development

Abstract

Abstract: This paper presents the method and results of a survey of 27 of the 33 Australian universities teaching engineering education in late 2007, undertaken by The Natural Edge Project (hosted by Griffith University and the Australian National University) and supported by the National Framework for Energy Efficiency. This survey aimed to ascertain the extent of energy efficiency (EE) education, and to identify preferred methods to assist in increasing the extent to which EE education is embedded in engineering curriculum. In this paper the context for the survey is supported by a summary of the key results from a variety of surveys undertaken over the last decade internationally. The paper concludes that EE education across universities and engineering disciplines in Australia is currently highly variable and ad hoc. Based on the results of the survey; this paper highlights a number of preferred options to support educators to embed sustainability within engineering programs, and future opportunities for monitoring EE, within the context of engineering education for sustainable development (EESD). [Copyright &y& Elsevier]

Published

2010

12. An Australian climate-based characterization of hygrothermal risks for buildings.

Author

Javed, Haniya, Brambilla, Arianna, and Strang, Marcus

Subjects

*METEOROLOGICAL charts, *THERMAL efficiency, *ECONOMIC impact, *ENERGY consumption, *CONSTRUCTION materials

Abstract

Moisture-related issues in buildings can accelerate the decay of building materials and increase occurrence of mould, resulting in significant economic and health implications. Transient hygrothermal risks assessment proved to be the most reliable approach, yet its application at early design stages is impeded by the high number of assumptions, input and skills required to be robustly applied. Climate-based indicators can assist in determining effective prevention design strategies based on the magnitude of the potential hygrothermal risks. However, in Australia, the National Construction Code relies on a climate zoning originally developed for thermal and energy efficiency provisions, clustering locations that present different moisture profiles. This paper investigates the suitability of the existing climate zones for hygrothermal risk indications by calculating the moisture index for several representative cites across Australia. Results reveal the current climate mapping to be unsuitable and too coarse to reliably provide robust indications for moisture management. Further, a new characterization of Australian climates for hygrothermal assessment purposes is proposed as a first step towards a better representation of moisture risks within the building code. [ABSTRACT FROM AUTHOR]

Published

2022

13. Quantification of atmospheric lead emissions from 70 years of leaded petrol consumption in Australia.

Author

Kristensen, Louise Jane

Subjects

*ENERGY consumption, *ATMOSPHERIC lead, *ENVIRONMENTAL impact analysis, *PERSISTENT pollutants, *AIR quality

Abstract

Lead is a persistent pollutant and the subject of many environmental studies, yet, in Australia, the extent of atmospheric lead emissions from the use of leaded petrol is unquantified. This paper details the first comprehensive account of leaded petrol sales and its lead concentrations over the 70 years of use in Australia. The resulting atmospheric lead emissions are calculated to provide the most complete understanding of the volume of lead released to the Australian continent from the consumption of leaded petrol. Atmospheric emissions of lead to the entire Australian continent from leaded petrol are calculated to total 240,510 tonnes over seven decades of use, peaking at 7869 tonnes in 1974. Total emissions for individual states and territories range from 1745 to 67,893 tonnes, with New South Wales responsible for the largest emissions. The effect of regulations on allowable concentrations of tetraethyl-lead additives are observed in the reduction of lead emissions in New South Wales and Victoria. The consequences to human health and the environment of leaded petrol consumption in Australia's populous cities are examined against historical air quality data and blood lead levels. [ABSTRACT FROM AUTHOR]

Published

2015

14. Prospect of biofuels as an alternative transport fuel in Australia.

Author

Azad, A.K., Rasul, M.G., Khan, M.M.K., Sharma, Subhash C., and Hazrat, M.A.

Subjects

*BIOMASS energy, *ALTERNATIVE fuels, *ENERGY consumption, *SUPPLY chains

Abstract

The prospect of biofuels as a transport alternative fuel in Australia is reviewed and discussed in this paper. The Australian transport sector is the second largest energy consuming sector which consumes about 24% of total energy consumption. A part of this energy demand can be met by ecofriendly biofuels. A wide array of different biofuels feedstocks including Australian native species, their distributions, oil content, traditional uses are reviewed and listed in the descending order of their oil content. The world biofuel scenario as well as the 20 largest biofuel production countries and their mandates on biofuels blending with petroleum diesel are presented. Australia’s biofuel production, consumption, production facilities and future investment projects are also reviewed and discussed. The study developed a biofuel supply chain for Australia and found that the second generation biofuels have better prospects as a future alternative transport fuel in Australia. These biofuel feedstocks are readily available and can overcome the shortcomings of the first generation biofuels, such as socio-economic, environmental and food versus land use challenges. Although some research is in progress, further study is needed on the process development of second generation biofuel production at commercial scale in Australia and abroad. [ABSTRACT FROM AUTHOR]

Published

2015

15. Statistical modeling of Electric Vehicle electricity consumption in the Victorian EV Trial, Australia.

Author

Khoo, Yong Bing, Wang, Chi-Hsiang, Paevere, Phillip, and Higgins, Andrew

Subjects

*ELECTRIC vehicles, *ENERGY consumption, *POTENTIAL energy, *COMPUTER simulation

Abstract

The market share of Electric Vehicles (EVs), an attractive alternative to conventional vehicles, is expected to exceed 30% of all vehicles by 2033 in Australia. Although the expected EV uptake may place greater burdens on electricity networks, the potential impacts contributed by different EV user categories and vehicle models to peak loads at different times during the day are not well understood. This paper addresses the issue through statistical analysis of the charge events in the Victorian EV Trial in Australia as well as modeling the charging behaviors according to participant categories and vehicle models. The analysis was performed on 4933 charge events that were recorded by both private and public Electric Vehicle Supply Equipment. In total, these events consumed over 33 MW h of energy over 12,170 h by the 178 trial participants, out of which about 70% were household participants while the others were fleet participants. Based on a range of EV uptake scenarios and modeled charging behaviors from the trial, the power demand in the summer of 2032/33 was estimated for all of Victoria. The results of the simulations show that the broad scale uptake of EVs produces a relatively small increase in overall power demand (estimated to be between 5.72% and 9.79% in 2032/33). [ABSTRACT FROM AUTHOR]

Published

2014

16. Impacts of electrifying public transit on the electricity grid, from regional to state level analysis.

Author

Purnell, K., Bruce, A.G., and MacGill, I.

Subjects

*PUBLIC transit, *EMISSIONS (Air pollution), *ELECTRIC power consumption, *ENERGY consumption, *BUS terminals, *ELECTRICITY

Abstract

• Bottom-up estimation tool to develop electric public transport (EPT) charging loads. • Uses GTFS public data and can be scaled to hundreds of cities/states globally. • EPT could add 17% to critical peak demand on some distribution zone substations. Battery electrified public transit (BEPT), including buses and passenger ferries, is a promising solution to transport-related climate emissions and urban air pollution, but introduces potentially challenging large, coincident demand in the low-voltage distribution network. This paper presents a tool for estimating the energy and charging demand of electrified public transit using public data that is available in over 150 cities/states globally and demonstrates it in two case studies. The tool applies heuristic vehicle scheduling to existing public General Transit Feed Specification data to model the charging profiles and electricity consumption of BEPT for various charging regimes across different geographical scales. For the case study of New South Wales, Australia, the impacts of BEPT are most significant at the low-voltage network, where adding a battery-electric bus depot was found to increase the annual critical peak demand at the local zone substation in Summer by up to 17% while exacerbating demand during the daily evening peak period by 20–30%. Across the entire state of NSW, a full transition to BEPT increases annual electricity consumption by 1.28–1.34% and peak daily demand by 1–3%. [ABSTRACT FROM AUTHOR]

Published

2022

17. Concentrating solar power/alternative fuel hybrid plants: Annual electricity potential and ideal areas in Australia.

Author

Peterseim, Juergen H., Herr, Alexander, Miller, Sarah, White, Stuart, and O'Connell, Deborah A.

Subjects

*SOLAR energy, *ALTERNATIVE fuels, *ELECTRICITY, *ENERGY consumption, *RENEWABLE energy sources, *INFRASTRUCTURE (Economics), *ENERGY economics

Abstract

Abstract: Australia's extensive solar resource is underexploited especially in the CSP (concentrating solar power) arena because of the high investment and lack of stable investment incentives. CSP hybrid plants provide an option to improve returns from CSP installations because of lower specific investment. This paper investigates the generation potential and most prospective regions for 5–60 MWe CSP hybrids using forestry residues, bagasse, stubble, wood waste and refuse derived fuels in locations with a direct normal irradiance >18 MJ/m2/day. Different plant efficiencies are used to identify the overall electricity potential for single and multiple feedstocks systems. The EfB (energy from biomass) or EfW (energy from waste) components of the hybrid plants considered are assumed to allow base load operation with the CSP components providing additional capacity during the day. The total CSP-EfB & EfW hybrid potential in Australia, within 50 km of existing transmission and distribution infrastructure, is 7000 MWe which would require an investment of AU$ 39.5b to annually generate 33.5 TWh. This is equivalent to 12.8% of all electricity generated in 2008–2009 or 74% of Australia's 2020 renewable energy target. The CO2 abatement potential of CSP-EfB & EfW hybrids is up to 27 Mt or 4.8% of all 2009–10 CO2 emissions. [Copyright &y& Elsevier]

Published

2014

18. Australian renewable energy policy: Barriers and challenges.

Author

Byrnes, Liam, Brown, Colin, Foster, John, and Wagner, Liam D.

Subjects

*RENEWABLE energy industry, *ENERGY policy, *ENERGY consumption, *CARBON dioxide mitigation, *EMISSIONS (Air pollution), *DEPLOYMENT (Military strategy)

Abstract

Abstract: Effective policy and regulatory frameworks are paramount to incentivising the deployment of renewable energy to achieve long term reductions in carbon emissions. Australia's renewable energy policy has taken significant steps towards encouraging the deployment of lower-emission energy generation. Significant policy barriers still exist at the federal and state levels, however, which have reduced the effectiveness of a concerted national effort to deploy renewables. The current policy landscape has favoured mature technologies which present the lowest investment risk at the expense of emerging options which may present greater efficiency and emissions reduction gains. The lack of support for emerging technologies delays their effective deployment and the accumulation of highly skilled human capital, until the medium to long term. This paper outlines the key policy frameworks, incentives and regulatory environment which encompasses the renewable energy sector, and presents a critical analysis of the barriers faced by the industry. [Copyright &y& Elsevier]

Published

2013

19. An overview of solar assisted air conditioning in Queensland's subtropical regions, Australia.

Author

Baniyounes, Ali M., Ghadi, Yazeed Yasin, Rasul, M.G., and Khan, M.M.K.

Subjects

*SOLAR air conditioning, *CLIMATE change, *ENERGY consumption, *POWER resources, *ENVIRONMENTAL impact analysis

Abstract

Abstract: Australia has a very sunny climate, with a very high demand for air conditioning. Relying on electricity to drive, buildings' HVAC systems will cause a significant negative impact on the environment. In this paper, recent developments in solar assisted air conditioning technologies are reviewed and presented. The conceptual basis of the technologies including open and closed cycles cooling technologies, capabilities and limitation are discussed. Energy demand, energy consumption by Australian buildings sector and economic and environmental problems associated with the usage of fossil fuel resources are reported. Second the issue of mould growth and indoor thermal comfort and indoor air quality is highlighted. Finally the technology fundamentals and theories involved with solar energy and solar collector's technologies are summarised and discussed. [Copyright &y& Elsevier]

Published

2013

20. Comparison study of solar cooling technologies for an institutional building in subtropical Queensland, Australia.

Author

Baniyounes, Ali M., Liu, Gang, Rasul, M.G., and Khan, M.M.K.

Subjects

*SOLAR air conditioning, *PETROLEUM product sales & prices, *EMISSIONS (Air pollution), *ENERGY consumption

Abstract

Abstract: In the last few years, due to soaring fuel prices and gas emissions, buildings designers have suggested new cooling technologies that can compete with conventional cooling technologies. The interest in solar assisted cooling technologies stems from the fact that they are sustainable and environmentally friendly compared to conventional cooling systems. The present paper investigates and compares the performance of two types of solar cooling: solar absorption cooling system and solar desiccant cooling system, for an institutional building located in the state of Queensland, Australia. A simulation model of the building has been developed for the evaluation of cooling load and primary energy usage with the application of the solar cooling systems. The evaluation of these systems has been conducted taking into account the solar fraction, the coefficient of performance and the primary energy savings. The building cooling load profile and the technologies component were modelled using TRNSYS16 in Subtropical Central Queensland typical meteorological year. Results showed that by installing a 50m2 of solar collectors, the desiccant system will achieve a maximum of 0.89 and 0.82 of solar fraction in the month of December and January in Gladstone and Rockhampton sites respectively, while the absorption system will achieve a 0.81 and 0.75 of solar fraction for the same time period in Gladstone and Rockhampton sites respectively. [Copyright &y& Elsevier]

Published

2013

21. An overview of renewable energy potential and utilisation inAustralia

Author

Bahadori, Alireza, Nwaoha, Chikezie, Zendehboudi, Sohrab, and Zahedi, Gholamreza

Subjects

*RENEWABLE energy sources, *ENERGY consumption, *CLIMATE change, *PETROLEUM product sales & prices, *ENERGY security, *ENERGY economics

Abstract

Abstract: As concerns about rising fossil fuel prices, energy security, and climate change increase, renewable energy can play a key role in producing local, clean, and inexhaustible energy to supply Australia’s growing demand for electricity, heat, and transportation fuel. Renewable energy is an essential part of Australia’s low emissions energy mix and this energy is important to its energy security. Australia has some of the best renewable energy resources in the world. This paper will focus on the impact of these renewable energies in Australia. This study shows that Australia has the potential to secure its long term energy future through focus and encouragement on increasing utilisation of renewable energy. [Copyright &y& Elsevier]

Published

2013

22. A review of geothermal energy resources in Australia: Current status and prospects

Author

Bahadori, Alireza, Zendehboudi, Sohrab, and Zahedi, Gholamreza

Subjects

*GEOTHERMAL resources, *POTENTIAL energy, *RADIOACTIVE decay, *ENERGY consumption, *PARAMETER estimation, *ELECTRICITY

Abstract

Abstract: Australia has considerable hot rock geothermal energy potential. This results from the widespread occurrence of basement rocks (granites in particular) in which heat is generated by natural radioactive decay. There are extensive areas where temperatures are estimated to reach at least 200°C at around 5km depth. In Australia, there is also potential for lower temperature geothermal resources associated with naturally-circulating waters in aquifers deep in a number of sedimentary basins (Hot Sedimentary Aquifer Geothermal). These are potentially suitable for electricity generation and direct use. This paper will focus on the need to improve geothermal energy utilization in Australia, challenges facing it and the future benefits. This study shows, there is a significant potential for energy savings through greater use of geothermal energy in some regions of Australia. [Copyright &y& Elsevier]

Published

2013

23. Designing liners for performance not life

Author

Toor, Paul, Franke, Jochen, Powell, Malcolm, Bird, Matthew, and Waters, Thomas

Subjects

*STUDY skills, *MILLING machinery, *ENERGY consumption, *PERFORMANCE evaluation, *MECHANICAL wear

Abstract

Abstract: Scanalyse in collaboration with JKMRC and Newcrest Mining Limited conducted an extensive study of the effect of liner wear on mill performance of a 32 foot SAG mill at Newcrest’s Cadia Valley Operations in Australia. The methodology of determining the optimum liner shape was previously presented at Metplant 2011, and expanded on at the SAG11. The results presented indicated that liners with a reduced mass and shorter life outperform their longer life counter parts in all key production parameters of throughput, energy consumption and product size. This paper quantifies the benefit of having shorter liner life cycles for improved performance by calculating the increase in throughput and reduction in power based on historical data for an operational 32 foot mill. It also presents the total overall gain by accounting for the increase in required reline effort. This provides a holistic view of the net achievements when designing liners for performance and not life. [Copyright &y& Elsevier]

Published

2013

24. Assessment of solar assisted air conditioning in Central Queensland's subtropical climate, Australia

Author

Baniyounes, Ali M., Rasul, M.G., and Khan, M.M.K.

Subjects

*SOLAR air conditioning, *GREENHOUSE gas mitigation, *CHLOROFLUOROCARBONS, *RENEWABLE energy sources, *ENERGY consumption, *SOLAR energy, TROPICAL climate

Abstract

Abstract: Australia has a very sunny climate, with a very high demand for air conditioning. Implementing solar assisted air conditioning is an ideal option to achieve a high solar fraction which leads to a significant amount of energy and greenhouse gas emission savings. Solar assisted air conditioning systems are environmentally friendly by being constructed in a way that minimises the need for chlorofluorocarbons CFC, Hydro chlorofluorocarbons HCFC or Chlorofluorocarbons HFC refrigerants and by using a low grade thermal renewable energy, therefore, making them energy efficient and environmentally safe. They can be used either as stand-alone systems or with conventional AC, to improve the indoor air quality. Solar cooling is a new and a fast growing technology compared to other fields of solar energy applications. On the other hand most of the current solar cooling applications are demonstration projects in nature; the technologies are advancing yet still need a lot of additional design, planning, development, and research efforts. T now solar assisted air conditioning''s main obstacles are the high installation costs, and the lack of knowledge and familiarity with this technology between designers, developers and architects. In this paper a feasibility study is carried out to assess a solar assisted air conditioning system for an office building under three of Queensland''s subtropical climates; Rockhampton, Gladstone, and Emerald. The technical aspects of a proposed solar cooling system are investigated. Cooling load profile for a proposed reference building was obtained using TRNSYS software under the influence of these different climates. An electric vapour compression pump, with 2.5 coefficient of performance (COP) for cooling is used as a reference system to assess the primary energy consumption, assuming 80% of primary energy consumed by the reference conventional system is replaced by solar energy. The results of analysing the proposed system indicated that an 80% of the primary energy savings can be achieved by installing 50 m2 of solar collectors and 1.8 m3of hot water''s storage tank under the three selected climates. [Copyright &y& Elsevier]

Published

2013

25. Energy efficiency status of the community housing in Australia

Author

Urmee, Tania, Thoo, Sid, and Killick, Winnie

Subjects

*ENERGY consumption, *COMMUNITY housing, *INCOME, *ENERGY economics, *CARBON dioxide mitigation

Abstract

Abstract: Community housing in Australia provides a range of rental options to low-to-moderate income tenants ranging from short-term crisis accommodation to long-term housing. Most community housing providers rely on rental income as their major source of recurrent funding and the rents are often set to a low percentage of the tenants’ income. Therefore, these not-for-profit organizations have to operate within very stringent budgets. Tenants in community housing may also have special needs. Their energy consumption are relatively high, as they spend long hours in their homes. They are therefore particularly vulnerable to increasing energy prices, and in need of the most assistance in reducing these living costs. This paper researches the status of energy use and the needs of the community housing to reduce the energy and water consumption. There appear to be ample opportunities for water and energy efficiency improvement in community housing, e.g. insulation, more energy efficient hot water systems, etc. However, the organizations lack of time, knowledge, fund and expertise to improve energy efficiency makes it hard and thus create a room for the Government to take initiates to reduce carbon from this sector. [Copyright &y& Elsevier]

Published

2012

26. Road transport and climate change: Stepping off the greenhouse gas

Author

Stanley, John K., Hensher, David A., and Loader, Chris

Subjects

*AUTOMOTIVE transportation, *CLIMATE change, *PUBLIC transit, *ENERGY consumption, *GREENHOUSE gas mitigation, *TECHNOLOGICAL innovations, *BEHAVIOR modification

Abstract

Abstract: Transport is Australia’s third largest and second fastest growing source of greenhouse gas (GHG) emissions. The road transport sector makes up 88% of total transport emissions and the projected emissions increase from 1990 to 2020 is 64%. Achieving prospective emission reduction targets will pose major challenges for the road transport sector. This paper investigates two targets for reducing Australian road transport greenhouse gas emissions, and what they might mean for the sector: emissions in 2020 being 20% below 2000 levels; and emissions in 2050 being 80% below 2000 levels. Six ways in which emissions might be reduced to achieve these targets are considered. The analysis suggests that major behavioural and technological changes will be required to deliver significant emission reductions, with very substantial reductions in vehicle emission intensity being absolutely vital to making major inroads in road transport GHG emissions. [Copyright &y& Elsevier]

Published

2011

27. Tests on ducted and bare helical and straight blade Darrieus hydrokinetic turbines

Author

Kirke, B.K.

Subjects

*WATER power, *DIFFUSERS (Fluid dynamics), *TURBINE blades, *HYDRAULIC turbines, *HYDRODYNAMICS, *WEBSITES, *ENERGY consumption, *TORQUE, *DYNAMICS

Abstract

Abstract: Despite much optimistic language on commercial websites, little data is available on actual performance of hydrokinetic turbines. This paper summarises the findings of a series of tests on several Darrieus type cross flow hydrokinetic turbines (HKTs). Although this type of hydrokinetic turbine (HKT) has some advantages over axial flow turbines, fixed pitch Darrieus HKTs also have some drawbacks, including inability to self-start under load, low efficiency and shaking. Variable pitch has been suggested to increase starting torque and efficiency, ducts to increase power output and helical blades to produce smooth torque. To assess each of these modifications, tests were conducted in Australia and Canada on HKTs with fixed and variable pitch straight blades, fixed helical blades, with and without a slatted diffuser, by mounting each turbine in front of a barge and motoring through still water at speeds ranging from less than 1 m/s up to 5 m/s. The diffuser increased the power output by a factor of 3 in one configuration but considerably less in others. A reason for this finding is suggested. The maximum coefficient of performance Cp of the fixed pitch straight blade and helical turbines without a diffuser ranged from about 0.25 at 1.5 m/s down to less than 0.1 at 5 m/s, while Cp for those with a diffuser ranged from about 0.45 down to about 0.3. Fixed blade turbines, both straight and helical, exhibited low starting torque, while variable pitch turbines started easily. Considerable differences in Cp were observed for the same turbine configuration at different speeds. The turbine with fixed pitch, straight blades was found to shake violently due to cyclical hydrodynamic forces on blades, while the helical and variable pitch turbines did not shake excessively. These findings suggest that variable pitch cross flow HKTs should be further investigated. [Copyright &y& Elsevier]

Published

2011

28. Potential of renewable energy alternatives in Australia

Author

Yusaf, Talal, Goh, Steven, and Borserio, J.A.

Subjects

*RENEWABLE energy sources, *BIOMASS energy, *WIND power, *SOLAR energy, *FOSSIL fuels, *NONRENEWABLE natural resources, *WAVE energy, *ENERGY consumption

Abstract

Abstract: Australia is one of those countries that are considered rich and abundant in fossil fuel energy resources. It is important for Australia to regulate the use of conventional energy and attempt replacing these conventional energies with renewable energy (RE) resources. Renewable energy resources in Australia are widely categorised as solar energy, biomass, wave energy and wind energy. By increasing the utilisation of renewable energy resources the national contribution to world wide green house gases (GHG) emissions would be reduced, at the moment approximately 50% of Australia''s GHG emissions are contributed from electricity generation [Dicks, AL, Diniz da Costa, JC, Simpson A, McLellan B. Fuel cells, hydrogen and energy supply in Australia. Journal of Power Sources 2004;1:1–12] with a large proportion of the remaining emissions coming from transport and vehicular sectors. As Australia''s population, as well as that of the world, continues to grow and live increasingly energy dependant lives, the future of energy supply will grow. This paper investigates the potential of renewable resources in Australia at present and the magnitude of their present and future contributions to the national energy consumption. Conclusions will be drawn from the results of this investigative scan and recommendations will be proposed. [Copyright &y& Elsevier]

Published

2011

29. Energy consumption at the state level: The unit root null hypothesis from Australia

Author

Kumar Narayan, Paresh, Narayan, Seema, and Popp, Stephan

Subjects

*ENERGY consumption, *TIME series analysis, *ENERGY management, *ENERGY policy, *POWER resources

Abstract

Abstract: In this paper, our goal is to examine the unit root null hypothesis in energy consumption for Australian states and territory. We consider sectoral energy consumption for Australia and its six states and one territory using time series data for the period 1973–2007. This is the first study that does this. Generally, except for some cases in South Australia, we find strong support that shocks to energy consumption have a temporary effect on energy consumption in Australia. [Copyright &y& Elsevier]

Published

2010

30. High efficiency pool filtering systems utilising variable frequency drives

Author

Hameiri, Z., Spooner, T., and Sproul, A.B.

Subjects

*SWIMMING pools, *ENERGY consumption, *POWER resources

Abstract

Abstract: Over 1 year, private swimming pools in Australia will typically consume 1680GWh of electricity, producing 2130kt of CO2. Redesigning a pool''s filtration system and using it more efficiently can reduce the energy use, and hence the CO2 production, by a significant amount. This paper describes experimental measurements carried out on a new design of pool pump system. Initial experiments using a variable frequency drive (VFD) with a standard, single phase pump/motor system have achieved energy savings of 40%. Utilising a VFD and a three phase pump/motor energy savings of 61% have been achieved, without degrading the system performance. [Copyright &y& Elsevier]

Published

2009

31. Energy use and thermal comfort in a rammed earth office building

Author

Taylor, P., Fuller, R.J., and Luther, M.B.

Subjects

*ENERGY shortages, *ENERGY consumption, *ENERGY policy

Abstract

Abstract: A two-storey rammed earth building was built on the Thurgoona Campus of Charles Sturt University in Albury-Wodonga, Australia, in 1999. The building is novel both in the use of materials and equipment for heating and cooling. The climate at Wodonga can be characterised as hot and dry, so the challenge of providing comfortable working conditions with minimal energy consumption is considerable. This paper describes an evaluation of the building in terms of measured thermal comfort and energy use. Measurements, confirmed by a staff questionnaire, found the building was too hot in summer and too cold in winter. Comparison with another office building in the same location found that the rammed earth building used more energy for heating. The thermal performance of three offices in the rammed earth building was investigated further using simulation to predict office temperatures. Comparisons were made with measurements made over typical weeks in summer and winter. The validated model has been used to investigate key building parameters and strategies to improve the thermal comfort and reduce energy consumption in the building. Simulations showed that improvements could be made by design and control strategy changes. [Copyright &y& Elsevier]

Published

2008

32. Has COVID-19 lockdown impacted on aged care energy use and demand?

Author

Liu, Aaron, Miller, Wendy, Crompton, Glenn, and Zedan, Sherif

Subjects

*ENERGY consumption, *ELDER care, *STAY-at-home orders, *COVID-19, *ELECTRIC power consumption

Abstract

• The impacts of COVID lockdown on six aged care communities' energy and peak demand are studied. • The lockdown period was compared with the same period of similar temperature in previous years. • The impacts of COVID lockdown varied enormously in different climate regions. • Effectiveness and limitations of existing energy KPIs are discussed. In late March to April 2020 residential aged care facilities (RAC) in Australia were under COVID-19 lockdown. This paper explores whether the resultant restrictions on entry and exit and elimination of site group activities within RACs impacted on the total electricity use, peak demand and electrical load profiles. Six RACs in four different climate zones are analysed, comparing historical electricity load and demand profiles with the lockdown period. The facilities in warm regions showed largest reductions in energy use and peak demands. There was a peak demand timing shift in temperate regions and hot regions' changes were negligible for energy use or peak demands. This study revealed the limitations of using aggregate data as the key performance indicator (KPI) – energy use per bed. Also, KPIs in relation to cooling degree days (or total cooling and heating degree days) have been examined and are not recommended for temperate regions or temperate seasons. The potential CO 2 emission reduction from onsite renewable generation is quantified. Further research is to investigate energy use changes at circuit levels under lockdowns, and develop more nuanced KPIs that include the rate of energy use and the timing of that use. [ABSTRACT FROM AUTHOR]

Published

2021

33. A review on renewable energy transition in Australia: An updated depiction.

Author

Li, Hong Xian, Edwards, David J., Hosseini, M. Reza, and Costin, Glenn P.

Subjects

*RENEWABLE energy transition (Government policy), *RENEWABLE energy sources, *GEOTHERMAL resources, *ENERGY consumption, *FOSSIL fuels, *ENERGY policy

Abstract

Despite the global context, only 6% of Australia's total energy consumption was derived from renewables, while 86.3% of electricity was generated from fossil fuels. However, this trend has been disrupted by the recent decommissioning and closure of a fleet of ageing coal power plants, along with the country's international commitments to reduce fossil fuel emissions. Currently, Australia is at a crucial stage of its transition to renewable energy adoption. With the purpose of providing an updated depiction of renewable energy, related policy and the way ahead in the Australian context, this research paper presents a systematic review of contemporary literature from the perspectives of energy potential, utilisation and policy incentives. The research analysed a total of 118 documents using an interpretivist epistemological lens; emergent findings offer an evidence-based, lucid account of advancements in the renewable energy market. Polynomial regression analysis is also conducted on secondary data obtained from the literature to predict trends in the electricity generated by different sources of renewable energy. The work also identifies several areas that require attention, including: (1) the most recent time-varying feed-in tariffs (TV FiTs) which offer the innate potential to alter consumer attitudes toward power usage at peak times, thereby improving grid security; (2) the increasingly popular integration of waste-to-energy with other sources of renewable energy emerges as a viable complementary solution to meet energy demands; (3) the increasing utilisation of subsidised geothermal energy installations which are set to rise exponentially in the future; and (4) the use of Public Private Partnerships (PPP) for developing renewable energy generation infrastructure and how this investment may facilitate the national transition to renewable energy adoption. This research contributes to the existing body of knowledge by raising awareness of the current state of renewable energy in Australia, along with proposing pragmatic recommendations for overcoming any challenges posed. As a comprehensive reference, this study provides practitioners and policymakers with thorough, reliable and collated information on Australia's current renewable energy position. [ABSTRACT FROM AUTHOR]

Published

2020

34. Development of an enthalpy-based index to assess climatic potential for ventilative cooling of buildings: An Australian example.

Author

Fiorentini, Massimo, Tartarini, Federico, Ledo Gomis, Laia, Daly, Daniel, and Cooper, Paul

Subjects

*COOLING, *METEOROLOGICAL stations, *LATENT heat, *ENERGY consumption, *ENTHALPY, *EFFECT of earthquakes on buildings

Abstract

• Development of a new enthalpy-based Climatic Cooling Potential index. • Critical evaluation of using enthalpy to evaluate Climatic Cooling Potential. • Practical significance of the enthalpy-based Climatic Cooling Potential. • Critical discussion of climatic effects on applicability of Ventilative Cooling. • Spatiotemporal analysis of the Climatic Cooling Potential in Australia. Ventilative Cooling is a promising technique to improve the energy efficiency of buildings through reduced need for mechanical cooling to maintain thermal comfort. To assess the feasibility of Ventilative Cooling in a specific location, it is useful for designers to be able to evaluate the climate potential for cooling. This paper describes a new and enhanced version of the Climatic Cooling Potential (CCP) method, which is a simplified method to evaluate the climate potential for passive cooling that does not require detailed knowledge of the building characteristics. The proposed Enthalpy Climatic Cooling Potential (CCP h) integrates humidity into the climate evaluation, using the enthalpy difference between indoors and outdoors, instead of the temperature difference. It accounts for latent heat, providing a better estimate of locations where the use of outside air will be beneficial from an energy perspective. The methods were compared by mapping the Ventilative Cooling potential for the Australian climate, using weather data from 391 weather stations across Australia. Results showed that most of the highly populated cities in the south of Australia have a climate suitable for Ventilative Cooling. This is true even in the summer period, although the area where the climate is beneficial is significantly larger during the shoulder seasons and winter. The analysis showed that using the CCP index, rather than the new CCP h index, can lead to an under-estimation of the cooling potential during dry winters and an over-estimation during humid summers, due to the contribution of the latent heat. [ABSTRACT FROM AUTHOR]

Published

2019