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3. Impact of driving style and traffic condition on emissions and fuel consumption during real-world transient operation

Author

G.M. Hasan Shahariar, Timothy A. Bodisco, Ali Zare, Mojibul Sajjad, M.I. Jahirul, Thuy Chu Van, Harry Bartlett, Zoran Ristovski, and Richard J. Brown

Subjects
History, Fuel Technology, Polymers and Plastics, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Business and International Management, Industrial and Manufacturing Engineering
Published
2022

4. Fuel properties and emission characteristics of essential oil blends in a compression ignition engine

Author

Anthony J. Marchese, Md. Nurun Nabi, Farhad M. Hossain, S.M. Ashrafur Rahman, Thomas J. Rainey, Zoran Ristovski, Jessica Tryner, Richard J. C. Brown, Mohammad Jafari, Ashley Dowell, Thuy Chu Van, and Muhammad Aminul Islam

Subjects
020209 energy, General Chemical Engineering, Orange oil, Energy Engineering and Power Technology, 02 engineering and technology, Diesel engine, complex mixtures, law.invention, Diesel fuel, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, medicine, 0204 chemical engineering, Essential oil, Chemistry, Organic Chemistry, technology, industry, and agriculture, Tea tree oil, food and beverages, Pulp and paper industry, Fuel Technology, Eucalyptus oil, Heat of combustion, Cetane number, medicine.drug
Abstract

Essential oils are mostly used in aromatherapy and their popularity has grown rapidly for the last decade. However, the industry has a substantial low-value waste stream, because downstream industries require therapeutic-grade oil. These waste stream oils can be used in the transport and agricultural sectors. This study investigated the influence of various essential oil blends on the emission characteristics of a multi-cylinder diesel engine. Orange, eucalyptus and tea tree oil were blended with diesel at 5% and 10% by volume, neat diesel and a 10% waste cooking biodiesel-diesel blend were also tested for comparison. The major constituents of orange oil and eucalyptus oil are limonene and 1,8-cineole respectively, and the main constituents of tea tree oil are terpinen-4-ol, γ-terpinene and α-terpinene. Orange oil contains negligible amounts of oxygen, whereas eucalyptus oil and tea tree oil contain 8.4% and 5.4% respectively. Compared to neat diesel, all the essential oil blends exhibited similar or slightly higher density, similar heating value, lower viscosity, flash point, and cetane number, and higher surface tension. However, only orange oil and eucalyptus oil blends exhibited oxidation stability above the minimum standards. Interestingly, blending eucalyptus oil increased the oxidation stability of diesel. Tea tree oil blends emitted the most carbon monoxide (CO) while orange oil and eucalyptus oil blends emitted the least CO and nitrogen oxide (NOX). Although eucalyptus oil and tea tree oil blends contain similar levels of oxygen, they exhibited opposite NOX emission trends, which might be attributed to the dissimilar and complex bonding of oxygen molecules into the structures. Particle number emission of essential oils were load dependent, however, all essential oil belnds emitted higher particulate mass at all loads.

Published
2019

5. A comparative investigation into cold-start and hot-start operation of diesel engine performance with oxygenated fuels during transient and steady-state operation

Author

Timothy A. Bodisco, Zoran Ristovski, Farhad M. Hossain, Ali Zare, Richard J. C. Brown, and Nurun Nabi

Subjects
Biodiesel, Cold start (automotive), Materials science, Common rail, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, Diesel engine, 7. Clean energy, Automotive engineering, law.invention, Ignition system, Diesel fuel, Brake specific fuel consumption, Fuel Technology, 13. Climate action, law, 0202 electrical engineering, electronic engineering, information engineering, Turbocharger
Abstract

Using a six-cylinder turbocharged common rail compression ignition engine, this study investigated the effect of oxygenated fuels on transient and steady-state performance. This paper considers the effect of oxygenated fuels on both cold- and hot-start operation. A range of fuel oxygen contents between 0% and 13.57% was derived from diesel, waste cooking biodiesel and two other blends, containing triacetin as a fuel additive. A custom test was designed to investigate engine performance parameters using acceleration, load increase and steady-state modes of operation. For each fuel, the cold-start test was conducted after an overnight engine-off time. In this study, different parameters related to engine performance were studied, such as engine coolant and lubricant temperatures and their rise rate, boost pressure, injected fuel, turbocharger lag, engine speed and torque, start of injection, maximum in-cylinder pressure, maximum rate of pressure rise, cyclic variability, FMEP, mechanical and thermal efficiencies, and BSFC. In comparison with hot-start, the cold-start results indicated a higher injected fuel, indicated torque, maximum in-cylinder pressure, maximum rate of pressure rise, FMEP, BSFC and CoV of IMEP, and a lower SOI, ME and BTE. During cold-start, using oxygenated fuels, instead of diesel, resulted in a lower rate of lubricant temperature rise and a higher BSFC, while decreasing the FMEP. Using oxygenated fuels, instead of diesel, during the idle and transient modes resulted in lower indicated torque and maximum in-cylinder pressure under cold-start whilst, under hot-start, it resulted in higher indicated torque and maximum in-cylinder pressure, because during hot-start, the fuel oxygen is significantly influential in torque build-up during turbocharger lag. While, during cold-start there are some other influential factors. In addition, oxygenated fuels—compared to diesel—experienced higher CoV of IMEP during cold-start while, during hot-start, they had lower values.

Published
2018

6. The effect of triacetin as a fuel additive to waste cooking biodiesel on engine performance and exhaust emissions

Author

Zoran Ristovski, Timothy A. Bodisco, Nurun Nabi, Mahmudur Rahman, Farhad M. Hossain, Ali Zare, and Richard J. C. Brown

Subjects
Thermal efficiency, Biodiesel, Common rail, Materials science, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, Diesel engine, Combustion, Pulp and paper industry, 7. Clean energy, Brake specific fuel consumption, Fuel Technology, Mean effective pressure, 13. Climate action, 0202 electrical engineering, electronic engineering, information engineering, human activities, NOx
Abstract

Highlights - Oxygen ratio was used instead of the equivalence ratio. - Oxygen ratio decreases with engine load, but increases with engine speed. - IMEP, BMEP, friction power, CO2, HC, PM and PN decreased with oxygenated fuels. - BSFC, BTE and NOx increased with oxygenated fuels. - Accumulation mode count median diameter decreased with oxygenated fuels. Abstract This study investigates the effect of oxygenated fuels on engine performance and exhaust emission under a custom cycle using a fully instrumented 6-cylinder turbocharged diesel engine with a common rail injection system. A range of oxygenated fuels based on waste cooking biodiesel with triacetin as an oxygenated additive were studied. The oxygen ratio was used instead of the equivalence ratio, or air to fuel ratio, to better explain the phenomena observed during combustion. It was found that the increased oxygen ratio was associated with an increase in the friction mean effective pressure, brake specific fuel consumption, CO, HC and PN. On the other hand, mechanical efficiency, brake thermal efficiency, CO2, NOx and PM decreased with oxygen ratio. Increasing the oxygen content of the fuel was associated with a decrease in indicated power, brake power, indicated mean effective pressure, brake mean effective pressure, friction power, blow-by, CO2, CO (at higher loads), HC, PM and PN. On the other hand, the brake specific fuel consumption, brake thermal efficiency and NOx increased by using the oxygenated fuels. Also, by increasing the oxygen content, the accumulation mode count median diameter moved toward the smaller particle sizes. In addition to the oxygen content of fuel, the other physical and chemical properties of the fuels were used to interpret the behavior of the engine.

Published
2016

7. Cold-start NOx emissions: Diesel and waste lubricating oil as a fuel additive

Author

Timothy A. Bodisco, Andrew P.W. Banks, Svetlana Stevanovic, Richard J. C. Brown, Liping Yang, Mohammad Jafari, Puneet Verma, Ali Zare, Zoran Ristovski, M.M. Rahman, and Meisam Babaie

Subjects
Cold start (automotive), 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Exhaust gas, 02 engineering and technology, respiratory system, Combustion, Diesel engine, Pulp and paper industry, Diesel fuel, Fuel Technology, 020401 chemical engineering, Volume (thermodynamics), 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, NOx, Turbocharger
Abstract

NOx emissions from diesel engines are a concern from both environmental and health perspectives. Recently this attention has targeted cold-start emissions highlighting that emission after-treatment systems are not effective in this period. Using a 6-cylinder, turbocharged, common-rail diesel engine, the current research investigates NOx emissions during cold-start using different engine performance parameters. In addition, it studies the influence of waste lubricating oil on NOx emissions introducing it as a fuel additive (1 and 5% by volume). To interpret the NOx formation, this study evaluates different parameters: exhaust gas temperature, engine oil temperature, engine coolant temperature, start of injection/combustion, in-cylinder pressure, heat release rate, maximum in-cylinder pressure and maximum rate of pressure rise. This study clarified how cold-start NOx increases as the engine is warming up while in general cold-start NOx is higher than hot-start. Results showed that in comparison with warmed up condition, during cold-start NOx, maximum in-cylinder pressure and maximum rate of pressure rise were higher; while start of injection, start of combustion and ignition delay were lower. During cold-start increased engine temperature was associated with decreasing maximum rate of pressure rise and peak apparent heat release rate. During cold-start NOx increased with temperature and it dropped sharply due to the delayed start of injection. This study also showed that using waste lubricating oil decreased NOx and maximum rate of pressure rise; and increased maximum in-cylinder pressure. NOx had a direct correlation with the maximum rate of pressure rise; and an inverse correlation with the maximum in-cylinder pressure.

Published
2021

8. Influence of doping Mg cation in Fe3O4 lattice on its oxygen storage capacity to use as a catalyst for reducing emissions of a compression ignition engine

Author

Nasrin Sabet Sarvestani, Hassan Karimi-Maleh, Zoran Ristovski, Mohammad Tabasizadeh, Richard J. C. Brown, Mohammad Hossein Abbaspour-Fard, Hamed Nayebzadeh, Thuy Chu Van, and Mohammad Jafari

Subjects
Materials science, 020209 energy, General Chemical Engineering, Organic Chemistry, Spinel, Oxide, Energy Engineering and Power Technology, 02 engineering and technology, engineering.material, Diesel engine, Combustion, medicine.disease_cause, Nanomaterial-based catalyst, Soot, Catalysis, chemistry.chemical_compound, Fuel Technology, 020401 chemical engineering, chemistry, Chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, engineering, medicine, 0204 chemical engineering, Carbon monoxide
Abstract

Improving oxygen storage capacity (OSC) of metal oxides by doping with metal cations can produce a catalyst with superior properties to improve engine performance and reduce emissions. In this study, Mg cations were incorporated into a ferric oxide lattice to form Mg0.25Fe2.75O4 via the solution combustion method. The structure, texture, morphology, and oxygen storage capacity of the samples were deeply investigated. The catalytic activity of Mg0.25Fe2.75O4 was finally compared with Fe3O4 as a reference nanocatalyst in terms of its combustion emissions using a six-cylinder Cummins diesel engine. It was found that the doped catalyst presented high crystallinity containing a mixture of the spinel-type crystal lattice and α-Fe2O3 structure, which confirms the ability of the solution combustion method for the fabrication of well-crystalline catalysts. The crystalline structure, surface area, and porosities and vacancy of spinel structure of Mg doped catalyst compared to the inverse spinel structure of Fe3O4 affect OSC of the samples, such that a significant increase in OSC of Fe3O4 (7941 µmol/g) occurred by loading of Mg cations (8661 µmol/g). Based on the engine emissions results, synthesized nanocatalysts are beneficial for decreasing the hydrocarbon (HC), carbon monoxide (CO), and particle mass (PM1.0) emissions. More specifically, the effect of nanocatalysts OSC would be dominated by the impact of increased soot oxidation, leading to PM1.0 reduction.

Published
2020

9. Engine performance and emissions of high nitrogen-containing fuels

Author

Puneet Verma, Farah Obeid, Thuy Chu Van, Branka Miljevic, Yi Guo, Thomas J. Rainey, Eva Johanna Horchler, Timothy A. Bodisco, Richard J. C. Brown, and Zoran Ristovski

Subjects
Biodiesel, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, Diesel engine, Combustion, Hydrothermal liquefaction, Diesel fuel, Fuel Technology, 020401 chemical engineering, Biofuel, Environmental chemistry, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Heat of combustion, 0204 chemical engineering, NOx
Abstract

Nitrogen (N) content in algae hydrothermal liquefaction (HTL) biocrude is high (5–8 wt%) and generally presumed to result in high NOx emissions during combustion. However, to our knowledge a very limited previous work on diesel engine performance and emissions of N-containing fuels. In order to investigate this issue, pyridine, an N-heterocyclic compound commonly found in algae biocrude, was blended with diesel fuel. This study investigated the influence of N in fuels, using a surrogate fuel to simulate algal biocrude, to determine the combustion behavior and emissions profile of an industrial multi-cylinder diesel engine. The presence of N in the fuel affected its physical properties. Density was slightly higher than neat diesel, while the viscosity, the flash point and the higher heating value (HHV) of the N-containing fuels reduced with increasing N content. The flash point of N-containing fuels were reduced, which affects the storage and transportation of the fuel. The engine load between 25 and 75% was observed to have an effect on engine performance parameters. Compared to diesel, N-containing fuels emitted both lower carbon monoxide (CO) and unburned hydrocarbons (HC). Increasing nitrogen oxides (NOx) emissions were observed with increasing N content in the fuels. At 50% and 75% loads, NOx emissions from N0.1 (0.1 wt% N), N0.5 (0.5 wt% N) and N2 (2 wt% N) were lower than for EUROIII. Particulate matter (PM) was lower for N-containing fuels compared to diesel fuel except for N0.1.

Published
2020

10. The effect of diesel fuel sulphur and vanadium on engine performance and emissions

Author

Nicholas C. Surawski, Farhad M. Hossain, Chung-Shin Yuan, Thomas J. Rainey, Yi Guo, Zoran Ristovski, Svetlana Stevanovic, Thuy Chu-Van, Richard J. C. Brown, and S.M. Ashrafur Rahman

Subjects
Biodiesel, Elemental composition, Diesel exhaust, Particle number, 020209 energy, General Chemical Engineering, Organic Chemistry, Metallurgy, Energy Engineering and Power Technology, Vanadium, chemistry.chemical_element, Bonding in solids, 02 engineering and technology, Sulfur, Diesel fuel, Fuel Technology, 020401 chemical engineering, chemistry, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering
Abstract

Metallic composition of diesel particulate matter, even though a relatively small proportion of total mass, can reveal important information regarding engine conditions, fuel/lubricating oil characteristics and for health impacts. In this study, a detailed investigation into the metallic elemental composition at different particle diameter sizes has been undertaken. A bivariate statistical analysis was performed in order to investigate the correlation between the metallic element, measured engine performance and engine emission variables. Major sources of metallic elements in the emitted particles are considered in this study, including the fuel and lubricating oil compositions, engine wear emissions and metal-containing dust in the ambient air. Metallic solid ultrafine-particles (Dp 100 nm). Calculated correlation matrices show a clear effect of engine load conditions and fuel S contents on particle number and mass emissions.

Published
2020

11. The impact of chemical composition of oxygenated fuels on morphology and nanostructure of soot particles

Author

Puneet Verma, Ashley Dowell, Zoran Ristovski, S.M. Ashrafur Rahman, Edmund Pickering, Svetlana Stevanovic, Richard J. C. Brown, and Mohammad Jafari

Subjects
Materials science, Nanostructure, 020209 energy, General Chemical Engineering, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, medicine.disease_cause, complex mixtures, 7. Clean energy, Oxygen, Diesel fuel, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, medicine, 0204 chemical engineering, Biodiesel, Diesel particulate filter, Organic Chemistry, Particulates, Soot, Fuel Technology, Chemical engineering, chemistry, 13. Climate action, Carbon
Abstract

Over the years, oxygenated fuels such as biodiesel and alcohol fuels have been useful in reducing particulate matter (PM) emissions of diesel engines. The presence of oxygen in the fuel impacts the soot oxidation process and thus the morphology and nanostructural characteristics of soot particles change. The nanostructure characteristics of soot particles hold an importance for their oxidation reactivity and toxicity. Higher reactivity and exposure of soot particles to oxygen will affect the regeneration and filtration efficiency of diesel particulate filters. In this study, we investigate the impact of oxygen functional groups on morphology and nanostructure of soot particles by blending different types of essential oil in diesel. The test fuels were prepared by mixing orange oil, tea tree oil, eucalyptus oil and coconut biodiesel to keep an overall oxygen content of 0 and 2.2%. Transmission electron microscopy was used to investigate the physical changes in the nanostructure of soot particles. The primary particle diameter decreases, and fractal dimension of soot aggregates increases for oxygenated fuels. Microscopy reveals that the arrangement of carbon lamellae within the soot particles changes significantly with use of oxygenated as observed by the changes in fringe length, fringe tortuosity and fringe separation distance. Lower fringe length, higher fringe tortuosity and fringe separation distance shows disordered arrangement of carbon layers with more possibility of oxygen attack. The different structural characteristics for oils having same oxygen content shows that formation and structure of soot particles strongly depend upon chemical structure and composition of the fuel.

Published
2020

12. Combustion analysis of microalgae methyl ester in a common rail direct injection diesel engine

Author

Muhammad Aminul Islam, Richard J. C. Brown, Md. Nurun Nabi, George Thomas, Kirsten Heimann, Mostafizur Rahman, Ashley Dowell, Zoran Ristovski, Nicolas von Alvensleben, and Bo Feng

Subjects
Biodiesel, Thermal efficiency, Common rail, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Diesel engine, Pulp and paper industry, Diesel fuel, Brake specific fuel consumption, Fuel Technology, Mean effective pressure, Environmental science, NOx
Abstract

In this study, the biodiesel properties and effects of blends of oil methyl ester petroleum diesel on a CI direct injection diesel engine is investigated. Blends were obtained from the marine dinoflagellate Crypthecodinium cohnii and waste cooking oil. The experiment was conducted using a four-cylinder, turbo-charged common rail direct injection diesel engine at four loads (25%, 50%, 75% and 100%). Three blends (10%, 20% and 50%) of microalgae oil methyl ester and a 20% blend of waste cooking oil methyl ester were compared to petroleum diesel. To establish suitability of the fuels for a CI engine, the effects of the three microalgae fuel blends at different engine loads were assessed by measuring engine performance, i.e. mean effective pressure (IMEP), brake mean effective pressure (BMEP), in cylinder pressure, maximum pressure rise rate, brake-specific fuel consumption (BSFC), brake thermal efficiency (BTE), heat release rate and gaseous emissions (NO, NOx,and unburned hydrocarbons (UHC)). Results were then compared to engine performance characteristics for operation with a 20% waste cooking oil/petroleum diesel blend and petroleum diesel. In addition, physical and chemical properties of the fuels were measured. Use of microalgae methyl ester reduced the instantaneous cylinder pressure and engine output torque, when compared to that of petroleum diesel, by a maximum of 4.5% at 50% blend at full throttle. The lower calorific value of the microalgae oil methyl ester blends increased the BSFC, which ultimately reduced the BTE by up to 4% at higher loads. Minor reductions of IMEP and BMEP were recorded for both the microalgae and the waste cooking oil methyl ester blends at low loads, with a maximum of 7% reduction at 75% load compared to petroleum diesel. Furthermore, compared to petroleum diesel, gaseous emissions of NO and NOx, increased for operations with biodiesel blends. At full load, NO and NOx emissions increased by 22% when 50% microalgae blends were used. Petroleum diesel and a 20% blend of waste cooking oil methyl ester had emissions of UHC that were similar, but those of microalgae oil methyl ester/petroleum diesel blends were reduced by at least 50% for all blends and engine conditions. The tested microalgae methyl esters contain some long-chain, polyunsaturated fatty acid methyl esters (FAMEs) (C22:5 and C22:6) not commonly found in terrestrial-crop-derived biodiesels yet all fuel properties were satisfied or were very close to the ASTM 6751-12 and EN14214 standards. Therefore, Crypthecodinium cohnii- derived microalgae biodiesel/petroleum blends of up to 50% are projected to meet all fuel property standards and, engine performance and emission results from this study clearly show its suitability for regular use in diesel engines.

Published
2015

13. Performance and gaseous and particle emissions from a liquefied petroleum gas (LPG) fumigated compression ignition engine

Author

Branka Miljevic, Nicholas C. Surawski, Rong Situ, Timothy A. Bodisco, Zoran Ristovski, and Richard J. C. Brown

Subjects
Energy, Particle number, Chemistry, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Particulates, Fuel injection, Pulp and paper industry, Combustion, Liquefied petroleum gas, law.invention, Ignition system, Ultra-low-sulfur diesel, Fuel Technology, law, Turbocharger
Abstract

In this study, an LPG fumigation system was fitted to a Euro III compression ignition (CI) engine to explore its impact on performance, and gaseous and particulate emissions. LPG was introduced to the intake air stream (as a secondary fuel) by using a low pressure fuel injector situated upstream of the turbocharger. LPG substitutions were test mode dependent, but varied in the range of 14-29% by energy. The engine was tested over a 5 point test cycle using ultra low sulphur diesel (ULSD), and a low and high LPG substitution at each test mode. The results show that LPG fumigation coerces the combustion into pre-mixed mode, as increases in the peak combustion pressure (and the rate of pressure rise) were observed in most tests. The emissions results show decreases in nitric oxide (NO) and particulate matter (PM2.5) emissions; however, very significant increases in carbon monoxide (CO) and hydrocarbon (HC) emissions were observed. A more detailed investigation of the particulate emissions showed that the number of particles emitted was reduced with LPG fumigation at all test settings - apart from mode 6 of the ECE R49 test cycle. Furthermore, the particles emitted generally had a slightly larger median diameter with LPG fumigation, and had a smaller semi-volatile fraction relative to ULSD. Overall, the results show that with some modifications, LPG fumigation systems could be used to extend ULSD supplies without adversely impacting on engine performance and emissions. © 2014 Elsevier Ltd. All rights reserved.

Published
2014

14. Particle emissions from biodiesels with different physical properties and chemical composition

Author

Hao Wang, Mostafizur Rahman, Ali Mohammad Pourkhesalian, Richard J. C. Brown, Assaad R. Masri, M.I. Jahirul, Svetlana Stevanovic, Zoran Ristovski, and Phuong Pham

Subjects
Degree of unsaturation, Biodiesel, Materials science, Particle number, General Chemical Engineering, Organic Chemistry, food and beverages, Energy Engineering and Power Technology, Diesel engine, complex mixtures, Diesel fuel, Fuel Technology, Chemical engineering, Particle, Organic chemistry, Particle size, Chemical composition
Abstract

Biodiesels produced from different feedstocks usually have wide variations in their fatty acid methyl ester (FAME) so that their physical properties and chemical composition are also different. The aim of this study is to investigate the effect of the physical properties and chemical composition of biodiesels on engine exhaust particle emissions. Alongside with neat diesel, four biodiesels with variations in carbon chain length and degree of unsaturation have been used at three blending ratios (B100, B50, B20) in a common rail engine. It is found that particle emission increased with the increase of carbon chain length. However, for similar carbon chain length, particle emissions from biodiesel having relatively high average unsaturation are found to be slightly less than that of low average unsaturation. Particle size is also found to be dependent on fuel type. The fuel or fuel mix responsible for higher particle mass (PM) and particle number (PN) emissions is also found responsible for larger particle median size. Particle emissions reduced consistently with fuel oxygen content regardless of the proportion of biodiesel in the blends, whereas it increased with fuel viscosity and surface tension only for higher diesel–biodiesel blend percentages (B100, B50). However, since fuel oxygen content increases with the decreasing carbon chain length, it is not clear which of these factors drives the lower particle emission. Overall, it is evident from the results presented here that chemical composition of biodiesel is more important than its physical properties in controlling exhaust particle emissions.

Published
2014

15. The influence of fatty acid methyl ester profiles on inter-cycle variability in a heavy duty compression ignition engine

Author

Assaad R. Masri, Phuong Pham, Zoran Ristovski, Timothy A. Bodisco, and Richard J. C. Brown

Subjects
Particle number, Chemistry, General Chemical Engineering, Coefficient of variation, Organic Chemistry, Diffusion flame, Analytical chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Compression (physics), Combustion, Oxygen, law.invention, Ignition system, Fuel Technology, Mean effective pressure, law, Organic chemistry
Abstract

With the advent of alternative fuels, such as biodiesels and related blends, it is important to develop an understanding of their effects on inter-cycle variability which, in turn, influences engine performance as well as its emission. Using four methanol trans-esterified biomass fuels of differing carbon chain length and degree of unsaturation, this paper provides insight into the effect that alternative fuels have on inter-cycle variability. The experiments were conducted with a heavy-duty Cummins, turbo-charged, common-rail compression ignition engine. Combustion performance is reported in terms of the following key in-cylinder parameters: indicated mean effective pressure (IMEP), net heat release rate (NHRR), standard deviation of variability (StDev), coefficient of variation (CoV), peak pressure, peak pressure timing and maximum rate of pressure rise. A link is also established between the cyclic variability and oxygen ratio, which is a good indicator of stoichiometry. The results show that the fatty acid structures did not have a significant effect on injection timing, injection duration, injection pressure, StDev of IMEP, or the timing of peak motoring and combustion pressures. However, a significant effect was noted on the premixed and diffusion combustion proportions, combustion peak pressure and maximum rate of pressure rise. Additionally, the boost pressure, IMEP and combustion peak pressure were found to be directly correlated to the oxygen ratio. The emission of particles positively correlates with oxygen content in the fuel as well as in the air-fuel mixture resulting in a higher total number of particles per unit of mass.

Published
2014

16. The effects of fuel characteristics and engine operating conditions on the elemental composition of emissions from heavy duty diesel buses

Author

McKenzie Lim, Godwin A. Ayoko, Zoran Ristovski, Lidia Morawska, and E.R. Jayaratne

Subjects
Particle number, General Chemical Engineering, Organic Chemistry, Analytical chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Cetane index, Diesel engine, Sulfur, Diesel fuel, chemistry.chemical_compound, Ultra-low-sulfur diesel, Fuel Technology, chemistry, Nitrogen oxide, NOx
Abstract

The effects of fuel characteristics and engine operating conditions on elemental composition of emissions from twelve heavy duty diesel buses have been investigated. Two types of diesel fuels – low sulfur diesel (LSD) and ultra low sulfur diesel (ULSD) fuels with 500 ppm and 50 ppm sulfur contents respectively and 3 driving modes corresponding to 25%, 50% and 100% power were used. Elements present in the tailpipe emissions were quantified by inductively coupled plasma mass spectrometry (ICPMS) and those found in measurable quantities included Mg, Ca, Cr, Fe, Cu, Zn, Ti, Ni, Pb, Be, P, Se, Ti and Ge. Multivariate analyses using multi-criteria decision making methods (MCDM), principal component analysis (PCA) and partial least squares (PLS) facilitated the extraction of information about the structure of the data. MCDM showed that the emissions of the elements were strongly influenced by the engine driving conditions while the PCA loadings plots showed that the emissions factors of the elements were correlated with those of other pollutants such as particle number, total suspended particles, CO, CO2 and NOx. Partial least square analysis revealed that the emission factors of the elements were strongly dependent on the fuel parameters such as the fuel sulfur content, fuel density, distillation point and cetane index. Strong correlations were also observed between these pollutants and the engine power or exhaust temperature. The study provides insights into the possible role of fuel sulfur content in the emission of inorganic elements from heavy duty diesel vehicles.

Published
2007

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