Abstract:The use of non-edible, second-generation feedstocks for the production of biodiesel has been an active area of research, due to its potential in replacing fossil diesel as well as its environmentally friendly qualities. Despite this, more needs to be done to remove the technical barriers associated with biodiesel production and usage, to increase its quality as well as to widen the choice of available feedstocks; so as to avoid over-dependence on limited sources. This paper assesses the feasibility of using a local plant, Reutealis trisperma, whose seeds contain a high percentage of oil of up to 51%, as one of the possible feedstocks. The techno-economic and sensitivity analysis of biodiesel production from Reutealis trisperma oil as well as implementation aspects and environmental effects of the biodiesel plant are discussed. Analysis indicates that the 50 kt Reutealis trisperma biodiesel production plant has a life cycle cost of approximately $710 million, yielding a payback period of 4.34 years. The unit cost of the biodiesel is calculated to be $0.69/L with the feedstock cost accounting for the bulk of the cost. The most important finding from this study is that the biodiesel from Reutealis trisperma oil can compete with fossil diesel, provided that appropriate policies of tax exemptions and subsidies can be put in place. To conclude, further studies on biodiesel production and its limitations are necessary before the use of biodiesel from Reutealis trisperma oil may be used as a fuel source to replace fossil diesel.
Some methods of generating power such as power generation through coal, natural gas, oil result in inevitable emissions of greenhouse gases. While power generation is necessary due to its increasing demand, it is important for power companies to generate their power in an efficient manner to reduce its effect on the environment. One of the most effective ways of tackling inefficiency issues is through the implementation of efficiency standard. While there exist a lot of studies addressing the topic of energy efficiency standards, there are very few papers that deal specifically with efficiency standard for power generation plant. This paper presents methodology for the implementation of power plant efficiency standard; as mandatory or voluntary regulatory instrument, that may be implemented by the government to control greenhouse emissions from power plants. It is hoped that through its implementation, power companies shall become more conscious of their efficiency and emission quality, hereby encouraging the adoption of more efficient energy sources and latest available technologies. In this paper, methods of calculating greenhouse intensity value and its corresponding allowable ranges have been demonstrated. Case study on a 10-year-old base-load multi-fuel-fired power plant in Malaysia has shown that the power plant is in conformance to the power plant efficiency standard, with an actual greenhouse intensity of 859.4461 kgCO 2 /MWh sent-out, well within the allowable range of greenhouse intensities for that power plant which is between 760 and 890 kgCO 2 /MWh sent-out. It has also been demonstrated that older power plants are allowed to have higher values of greenhouse intensity. Benefits of utilising natural gas and operating the power plant at full load have also been shown. Keywords Techno-economic · Energy efficiency standard · Power generation · Life cycle cost List of symbols 3EF j Total emission of greenhouse gas j produced (kg) by the power plant ER Overall emission reduction efficiency of the power plant EM CO 2 ,equiv. Total emission for carbon dioxide equivalence, from the power plant in kgCO 2 equiv over time period T F j Emission factors for greenhouse gas j by the power plant (kg CO 2 /kg fuel)Emission factors for greenhouse gas CO 2 by the power plant (kg CO 2 /kg fuel) F CO 2 equiv,iCollective emission factor, in carbon dioxide equivalence by the power plant from fuel i (kg CO 2 /kg fuel)Emission factors for CO 2 by the power plant from fuel i (kg CO 2 /kg fuel)Emission factors for CH 4 by the power plant from fuel i (kg CO 2 /kg fuel)Emission factors for N 2 O by the power plant from fuel i (kg CO 2 /kg fuel) GHR Generated heat rate of the power plant GI
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