Impact of oxygenated cottonseed biodiesel on combustion,performance and emission parameters in a direct injection CI engine

In the present study, biodiesel production from the crude cotton-seed oil (CSO) and its feasibility to be used as fuel in compression ignition engine was analysed. Single-stage transesterification at molar ratio of 8:1 on crude CSO yielded 94% of cottonseed biodiesel (CBD). Gas chromatogram/mass spectrometry analysis revealed the presence of 19.5% unsaturated and 80.5% saturated esters in cotton seed biodiesel. Taguchi approach identified the stable fuel blend with oxygenate concentration. Increased oxygen concentration up to 20% were also analysed to understand the variation. Higher peak in-cylinder pressure was observed in D80CBD20 fuel blend. Diesel–biodiesel blend with oxygenate significantly affected the ignition delay and also resulted in varied exhaust gas temperature. D80CBD20nB10 showed an increase in brake thermal efficiency, whereas D80CBD20 exhibited higher brake specific energy consumption at full load. Carbon monoxide, hydrocarbon and smoke emission was found to be high in diesel with higher oxides of nitrogen in D80CBD20nB10. This experimental investigation finally revealed that, D80CBD20nB10 improved the combustion and performance characteristics with minimal emissions.

Abbreviations ASTM: American Society for Testing and Materials; BP: brake power; BSEC: brake specific energy consumption; BTE: brake thermal efficiency; CBD: cottonseed biodiesel; CI: compression ignition; CO: carbon monoxide; CO₂: carbon dioxide; CSO: cottonseed oil; DEE: diethyl ether; DOE: design of experiments; EGT: exhaust gas temperature; FTIR: Fourier transform infrared spectrometry; GC/MS: gas chromatogram/mass spectrometry; HC: hydrocarbon; HRR: heat release rate; HSDI: high speed direct injection; IDI: indirect injection; KOH: potassium hydroxide; MFB: mass fraction burned; NaOH: sodium hydroxide; NMR: nuclear magnetic resonance; N₂O: nitrous oxide; NO: nitric oxide; NO₂: nitrogen dioxide; NO _x : oxides of nitrogen; ROHR: rate of heat release; ROPR: rate of pressure rise; SOC: start of combustion; aTDC: after top dead centre; bTDC: before top dead centre     

Bio-ethanol additive effect on direct injection diesel engine performance,emission and combustion characteristics – an experimental examination

ABSTRACT

The present investigation explores the effect of dairy scum oil methyl ester (DSOME) blends and ethanol additive on TV1 Kirloskar diesel engine performance, combustion and emission characteristics. From the experimental study, it is concluded that DSOME-B20 (20% dairy scum biodiesel?+?80% diesel) has shown appreciable performance and lower HC and CO emissions among all other blends. Hence DSOME-B20 is optimised as best fuel blend and it is carried for further investigations to study the effect of bio-ethanol additive on diesel engine performance. From the study it apparent that diesel engine operated with ethanol additive and 20% dairy scum biodiesel blended fuels shown the satisfactorily improved emission characteristics when compared to petroleum diesel fuel operation. Finally, from the experimental investigation, it concludes that addition of ethanol shown the slightly higher HC, CO emission and improved BTE, BSFC, NOx and CO₂ than sole B20 biodiesel blend. Among all three (3%, 6% and 9%) ethanol additive ratios, E6% (6%-ethanol with B20) ethanol additive exhibits slightly better BTE, BSFC, cylinder pressure and heat release rate hence 6% ethanol additive with B20 biodiesel blend would furnish beneficial effects in the diesel engine.     

Performance,combustion and emission characteristics of a single-cylinder constant speed compression ignition engine using soybean methyl esters

ABSTRACT

The present study was aimed to produce biodiesel from soybean oil and to investigate its characteristics. Soybean oil-based bio diesel properties are observed and tested in the fuel testing laboratory with standard procedures. It is found that soybean oil-based biodiesel has similar properties as that of diesel fuel. An experimental set-up was used in the study to analyse the performance, combustion and emission of soybean oil biodiesel with respect to normal diesel by using different blends (B20, B40, B60, B80 and B100). It is observed that there is no difficulty found in running the engine, but the performance of the biodiesel blends quite deviated from normal diesel. The combustion characteristics of the tested blends were in agreement with normal diesel. The carbon emissions are much lower for soybean oil biodiesel blends than diesel.     

The influence of different parameters on the performance of the compression ignition engine

The purpose of this work was to provide a flexible thermodynamic model based on the filling-and-emptying approach for the performance prediction of a four-stroke turbocharged compression ignition engine. To validate the model, comparisons were made between results from a computer program developed using FORTRAN language and the commercial GT-Power software operating under different conditions. The comparisons showed that there was a good concurrence between the developed program and the commercial GT-Power software. The range of variation of the rotational speed of the diesel engine chosen extends from 800 to 2100 RPM. By analysing these parameters with regard to two optimal points in the engine, one relative to maximum power and another to maximum efficiency, it was found that if the injection timing is advanced, the maximum levels of pressure and temperature in the cylinder are high.     

Experimental investigation of performance,combustion and emission characteristics of CI engine fuelled with chicha oil biodiesel

As the decreasing availability of the fossil fuel is rising day by day, the search of alternate fuel that can be used as a substitute to the conventional fuels is rising rapidly. A new type of biofuel, chicha oil biodiesel, is introduced in this work for the purpose of fuelling diesel engine. Chicha oil was transesterified with methanol using potassium hydroxide as catalyst to obtain chicha oil methyl ester (COME). The calorific value of this biodiesel is lower, when compared to that of diesel. The COME and their blends of 20%, 40%, 60% and 80% with diesel were tested in a single cylinder, four stroke, direct injection diesel engine and the performance, combustion and emission results were compared with diesel. The test result indicates that there is a slight increase in brake thermal efficiency and decrease in brake-specific fuel consumption for all blended fuels when compared to that of diesel fuel. The use of biodiesel resulted in lower emissions of CO and HC and increased emissions of CO₂ and NO_x. The experimental results proved that the use of biodiesel (produced from chicha oil) in compression ignition engine is a viable alternative to diesel.     

Effects of waste chicken fat derived biodiesel on the performance and emission characteristics of a compression ignition engine

ABSTRACT

In this investigation, chicken fat methyl ester (CFME) was produced from the waste chicken fat obtained from meat processing industries. Blends were prepared with diesel-CFME, such as DCFME10, DCFME20, DCFME30, and DCFME40. The blends were tested in a direct injection diesel engine to examine the performance and emission characteristics. The results showed that the diesel substitution was attainable with CFME. DCFME30 had excellent performance and emission than other blends, but it was marginally lower than diesel. For the DCFME operation, brake-specific fuel consumption was higher and brake thermal efficiency was lower in comparison with diesel throughout the load spectrum. The CO (carbon monoxide), HC (hydrocarbon), and smoke emissions were reported to be lower for DCFME blends than that of diesel, but the NO (nitric oxide) emission was marginally higher throughout the load spectrum. A maximum of 30% diesel saving was obtained by using CFME, energy from animal residue.     

Behaviour of CI engine performance,combustion and exhaust emission with neem biodiesel at varied fuel injection rates

Motorisation and fast depletion of fossil fuel reserves and issues like global warming have led the researchers all over to look for substitute fuels. Biodiesel resulting from vegetable oil is being used around the globe to lessen air pollution and reduce the necessity of diesel fuel. The current study covers the various aspects of N20 neem biodiesel with increased fuel injection pressure. The blends of N20 were tested with increased fuel injection pressure to examine the characteristics such as brake thermal efficiency, fuel consumption, emission and combustion parameters. Experimental results indicated that N20 with 240?bar has a closer performance to diesel, reduced exhaust emission and improved combustion parameters.     

Effect of diethyl ether and ethanol on performance,combustion, and emission of single-cylinder compression ignition engine

The effect of diesel, ethanol, and diethyl ether (DEE) blends on performance, combustion, and emission of a 3.6?kW single-cylinder compression ignition engine is investigated in this paper. The experiments were conducted using different percentages of ethanol and DEE in diesel. The fuel samples selected for experimentation included neat diesel fuel, 5% DEE (D95DEE5), 10% DEE (D90DEE10), 5% DEE with 5% ethanol (D90DEE5E5), 5% DEE with 10% ethanol (D85DEE5E10), 10% DEE with 5% ethanol (D85DEE10E5), and 10% DEE with 10% ethanol (D80DEE10E10). It was found that 5% DEE can improve the brake thermal efficiency (η_bth), but the same decreased with 10% DEE in the blend. However, ethanol addition to both the blends produced an appreciable increase in η_bth of the engine. The diesel–DEE–ethanol blends were also more efficient in reducing emissions of carbon monoxide (CO), oxides of nitrogen (NO_x), hydrocarbon (HC), and particulate matter (PM). Among all the blends tested in this study, it was found that the D80DEE10E10 blend can produce optimum performance-emission characteristics with improved thermal efficiency and reduced emission of NO_x, CO, HC, and PM.     

Experimental investigation of the influence of isobutanol addition on engine performance and emissions of a direct ignition diesel engine fuelled by biodiesel blends derived from waste vegetable oil

Biodiesel has become one of the potential alternative sources to replace diesel. Some of the limitations of biodiesel include high NO _x , poor atomization, poor oxidation stability, cold-flow problems, long-term storage problems, etc. Various strategies were discussed to overcome the limitations of biodiesels. Recent research is on effects of fuel additives or fuel composition modification to reformulate the fuel properties. This article is aimed at presenting the experimental investigation of the effects of isobutanol additive on the engine performance and emission characteristics of biodiesel blends derived from waste vegetable oils. The experimental investigation was conducted on a direct injection four-stroke diesel engine with different blends, B10, B20, B30, B10 (10% ISB), B20 (10% ISB), B30 (10% ISB), B10 (20% ISB), B20 (20% ISB) and B30 (20% ISB), and engine performance and emission characteristics are evaluated and discussed.     

Influence of injection timing on the performance,combustion and emission characteristics of diesel engine powered with tamarind seed biodiesel blend

ABSTRACT

The limitations and ramifications of petroleum fuel on the present environmental society raised the necessity of alternative fuel. The physicochemical properties of biodiesel and its ability to reduce emissions have engaged the attention of researchers to prefer biodiesel as a better alternative fuel. A modification in engine parameters is proven to be one of the best techniques to obtain comparable results with diesel. The following study emphasises TSME 20 (20% Tamarind Seed Methyl Ester with 80% diesel) as an alternative fuel and its performance and emission characteristics are deciphered at different injection timings (19°, 23° and 27° bTDC) at different loads. Focusing on the results obtained at full-load condition, considerable improvement in brake thermal efficiency by 3.18% was noticed with the significant reduction in carbon monoxide, hydrocarbon, oxides of nitrogen and smoke by 17.3%, 57.3%, 31.34% and 8.1%, respectively, at retarded injection timing compared to standard injection timing.     

Influence of an aqueous cerium oxide nanofluid fuel additive on performance and emission characteristics of a compression ignition engine

Aqueous cerium oxide at the rate of 50cc per liter was dispersed into diesel and diesel–biodiesel using mechanical agitator and an ultrasonicator for preparing the test fuels. Cerium oxide nanomaterials present in the aqueous cerium oxide exhibit higher catalytic activity because of their large contact surface area per unit volume and can react with water at high temperature to generate hydrogen and improve fuel combustion. Also, cerium oxide nanomaterials act as oxygen buffers causing simultaneous oxidation of hydrocarbons (HCs) as well as the reduction of oxides of nitrogen. The neat diesel and test fuels were tested in an engine without changing the engine system at 0%, 25%, 50%, 75% and 100% load condition and resulted in a considerable enhancement in the brake thermal efficiency, improved brake-specific fuel consumption and decreased concentration of HC, NO_x and smoke in the exhaust emitted from the diesel engine due to incorporation of aqueous cerium oxide in the test fuels.     

Experimental study on performance,combustion and emission characteristics of a four-stroke diesel engine using blended fuel

In day today's applications, it is obligatory to devise the usage of diesel in an economic and environmentally benign way. The present work was aimed at studying the performance, emission and combustion characteristics of a four-stroke diesel engine by adding n-pentane at different proportions such as 2%, 4%, 6%, 8% and 10% by volume with diesel. The performance, combustion and emission characteristics obtained from the experiment revealed that the addition of n-pentane augments the brake thermal efficiency of the engine. At full load, the brake thermal efficiency increased by 3.17% for an addition of 6% n-pentane, 4.31% for an addition of 8% n-pentane and 6.36% for an addition of 10% n-pentane. From the emission test, it was concluded that at full load, the NO_x emission decreased by 8.67% for an addition of 6% n-pentane, 17.43% for an addition of 8% n-pentane and 18.09% for an addition of 10% n-pentane.     

Experimental investigation of compression ratio on performance and emissions characteristics of pumpkin seed oil blends in a diesel engine

This aim of the current study is to evaluate the performance and emission characteristics of pumpkin seed oil with diesel at different blended ratios (B10-CR15, B20-CR15, B10-CR18 and B20-CR18) in a constant speed (1500?rpm) engine. The tests were conducted at various loads of the engine and with specific compression ratios of 15 and 18. The performance and emissions were compared with the different blend ratios and compression ratios. As a result of which the higher compression ratios shows better performance and emission than the lower compression ratio; among them B20-CR18 shows better results such that CO₂, HC and CO emissions were reduced and there is a slight increase in NO_X value compared to diesel and other blend ratios and also there is an increased brake thermal efficiency for the blend B20-CR18. This shows that the optimum blend is chosen from the results is identified as B20-CR18, which has better performance and emission than other blends and compression ratios.     

Effect of compression ratio on the performance of CI engine fuelled with freshwater algae biodiesel

ABSTRACT

Biodiesel is proved to be a better substitute of conventional diesel. Economically good biosource is a needed one. In this study, freshwater algae (micro algae) are used for producing the biodiesel. The fuel properties of the biodiesel sample were tested and found within the limits. The B10 and B20 biodiesel blends with diesel are tested in a single cylinder CI engine. The blends show a better performance in CI engine and the values are closer to the conventional diesel. The important engine parameter compression ratio is also made to vary. At the three compression ratios, the biodiesel’s performance trend is quite comparable with diesel.     

Performance and emission characteristics of direct injection diesel engine using linseed oil as biodiesel by varying injection timing

The depletion of fossil fuels and increasing demand leads to research in alternate fuels. The alternate fuels are bio-degradable, renewable and non-toxic. Many types of oils are re-used in biodiesel production, considering their availability, among which linseed oil is the most significant one. Injection timing plays a major role among various injection parameters which affects its performance and emission characteristics. This paper focuses on experimental investigation on a single cylinder, four-stroke direct injection diesel engine with output of 5.2?kW at 1500?rpm at various injection timings, 20, 23, 26 degree BTDC for observing the performance and emission characteristics of direct injection diesel engine using methyl esters of linseed oil and its blends. The blends are B10, B20, and fuel characteristics are observed. The results show that when compared with diesel it gives an increase in BTHE and reduction in SFC. Both the biodiesel blends give lesser NOx. Slightly higher CO and HC emission were found. The performance and emissions were increased in when injection increased.     

Experimental investigation on the effect of alkanes blending on performance,combustion and emission characteristics of four-stroke diesel engine

In this experimental investigation, an attempt was made to increase the performance and reduce the emission by adding alkanes such as n-pentane and n-hexane separately at different proportions, such as 4%, 6% and 8% by volume, with diesel. The performance analysis reported that, at full load, the brake thermal efficiency was increased by 3.605%, 3.170%, 4.305%, 4.394%, 5.336% and 6.173% for the blending of 4% n-pentane, 6% n-pentane, 8% n-pentane, 4% n-hexane, 6% n-hexane and 8% n-hexane with diesel, respectively. The emission test concluded that the smoke density was increased by 9.915%, 9.905%, 6.325%, 9.573%, 6.154% and 5.983% for the blending of 4% n-pentane, 6% n-pentane, 8% n-pentane, 4% n-hexane, 6% n-hexane and 8% n-hexane with diesel, respectively. The NO_x emission was decreased by 8.265%, 8.674%, 17.430%, 5.401%, 5.810% and 7.529% for the blending of 4% n-pentane, 6% n-pentane, 8% n-pentane, 4% n-hexane, 6% n-hexane and 8% n-hexane with diesel, respectively.     

Effect of injection timing on the combustion characteristics of rice bran and algae biodiesel blends in a compression-ignition engine

Fuel injection timing is a very important factor among various injection parameters which influences the combustion characteristics of a compression-ignition (CI) engine. This work used a single cylinder CI engine to test the two biodiesel samples rice bran oil methyl esters (ROME) and alga extracted oil methyl esters (AME) for their combustion characteristics influenced by injection timings. The tests were conducted at constant speed (1500?rpm) single cylinder CI engine with three different injection timings (20° before top dead centre [BTDC], 23°?BTDC and 26°?BTDC). The results show increased cylinder pressure and heat release rate when advancing the injection timing at earlier combustion stages. When retarding the injection timing the cylinder pressure and the heat release rate lowers. Compare to AME, the combustion characteristics for ROME shown improved results. The variations in exhaust gas temperature are also depicted.     

Effect of injection pressure on the performance and emission characteristics of the CI engine using Vateria indica biodiesel

Vateria indica Linn seeds were found to contain nearly 19% of oil/fat content. This fat is converted into biodiesel by a novel method by the authors at the biodiesel preparation facility at NITK, Surathkal, India. As biodiesel is a promising alternative fuel for petro diesel in compression ignition (CI) engines, this biofuel is tested in a single-cylinder diesel engine. The objective of this work is to find combustion, performance and emission characteristics of a CI engine with diesel and blends of V. indica biodiesel at 180, 200 and 220?bar injection pressures. Blending is done in volumetric ratios of 10%, 15%, 20% and 25% of biodiesel with diesel which are called as B10, B15, B20 and B25. The idea of increasing fuel injection pressure is to promote atomisation and full penetration into the combustion chamber leading to better combustion. Blend B25 showed best thermal efficiency of the order of 33.03% and the least NO_X emission of 1047?ppm at 220?bar injection pressure at 75% load.     

Performance and emission characteristics of diesel engine operated on plastic pyrolysis oil with exhaust gas recirculation

The objective of this research was to study the performance and emission characteristics of using waste plastic pyrolysis oil in diesel engine without any engine modification. The engine used in this study is a four-stroke single-cylinder naturally aspirated diesel engine (compression ignition). In the present work, the engine fuelled with blends of diesel fuel (DF) with plastic oil in the ratio of 90:10 (blend10%), 80:20 (blend20%), 70:30 (blend30%), and 50:50 (blend50%) are experimentally measured the efficiencies and emissions, analysed the performance, and compared results with that of DF.     

Energy and exergy analysis of a CI engine using tyre pyrolysis oil blends with diesel

Tyre pyrolysis oil (TPO) blend with diesel can be used as an alternate fuel. Tests have been carried out to analyse the energy and exergy characteristics of diesel engine fuelled by B10, B20 and B30 blend of TPO with diesel fuel. TPO was derived from waste automobile tyres through vacuum pyrolysis process (batch type). In this paper, the brake thermal efficiencies of TPO of different blends (10%, 20% and 30%) are compared with the pure diesel and discussed. Further, exergy and energy values of TPO–diesel with different blends are analysed.