The combined effect of multiwalled carbon nanotubes and exhaust gas recirculation on the performance and emission characteristics of a diesel engine

The present experimental investigation focuses on the combined effects of multiwalled carbon nanotubes (MWCNTs) and exhaust gas recirculation (EGR) of a diesel engine fuelled with Calophyllum inophyllum biodiesel blends. The C. inophyllum biodiesel-diesel blend was prepared in a proportion of 20% biodiesel and 80% diesel (B20) by a volumetric basis with a magnetic stirrer. The MWCNTs (in the mass fraction of 40?ppm) were dispersed into the B20 fuel with the help of an ultrasonicator. The results show that brake thermal efficiency increases by 7.6% with the addition of MWCNTs to the B20 fuel, decreases by 2.42% with the EGR to the B20 fuel, and increases by 2.26% with the addition of MWCNTs and EGR to the B20 fuel compared to the B20 fuel. The maximum cylinder pressure and heat release rate was occurred as 67.35 bar and 74.80?kJ/m³ deg for the B20MWCNT40 fuel at full load condition. The CO and HC emissions for the B20MWCNT40+20%EGR fuel sample were lower compared to the B20 fuel. The Smoke emissions were reduced for B20MWCNT40 fuel compared to the B20 fuel. The NO_x emissions were reduced by 25.6%, 29.7% for B20+20%EGR, B20MWCNT40+20%EGR fuel samples compared to the B20 fuel.     

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 cashew nut shell oil on the CI engine

This article is an effort to address the need for a non-cooking oil-based biodiesel. Here, the experimental work is done on a single cylinder, direct injection CI engine using cashew nut shell oil biodiesel blends under constant speed. The cashew nut shell liquid (CNSL) biodiesel is blended with the diesel fuel and used as biodiesel blend. Blends used for testing are B20, B40 and B60. The effect of the fuels on engine power, brake thermal efficiency (BTE) and exhaust gas temperature was determined by performance tests. The influences of blends on CO, CO₂, HC and NO_x emissions were investigated by emission tests. The BTE values of biodiesel are closer to diesel. Compared to diesel, all the biodiesel blends gave lesser unburnt hydrocarbon (HC), carbon monoxide (CO) and smoke emissions. Slightly higher NO_x emissions were found in CNSL biodiesel blends, which is typical of the other biodiesels.     

Parametric optimisation of exergy destruction in small DI diesel engine fuelled with neem biodiesel using the Taguchi method

ABSTRACT

Large amount of emissions from vehicles have led to the degradation of urban air quality and have resulted in serious health issues. Biodiesel, a substitute fuel for diesel engine, is receiving great attention worldwide. This work investigates the merits of using neem-biodiesel and diesel blends for single cylinder small direct injection diesel engine. The energy (the first law) and exergy (the second law) analyses of direct injection diesel engine using neem-biodiesel blends have been presented. Taguchi’s ‘L’ 16’ orthogonal array has been used for the design of experiments. The engine was tested at different engine speeds, load percentages and blend ratios, using neem biodiesel. The results show that the optimum operating conditions for minimum brake specific fuel consumption are achieved when the engine speed is 1900?rev/min, load percentage is 75 and the engine is fuelled with B40.     

Experimental investigation on regulated and unregulated emissions of a diesel engine fueled with ultra-low sulfur diesel fuel blended with biodiesel from waste cooking oil

Experiments were conducted on a 4-cylinder direct-injection diesel engine using ultra-low sulfur diesel, bi oesel and their blends, to investigate the regulated and unregulated emissions of the engine under five engine loads at an engine speed of 1800 rev/min. Blended fuels containing 19.6%, 39.4%, 59.4% and 79.6% by volume of biodiesel, corresponding to 2%, 4%, 6% and 8% by mass of oxygen in the blended fuel, were used. Biodiesel used in this study was converted from waste cooking oil.The following results are obtained with an increase of biodiesel in the fuel. The brake specific fuel consumption and the brake thermal efficiency increase. The HC and CO emissions decrease while NO_x and NO₂ emissions increase. The smoke opacity and particulate mass concentrations reduce significantly at high engine load. In addition, for submicron particles, the geometry mean diameter of the particles becomes smaller while the total number concentration increases. For the unregulated gaseous emissions, generally, the emissions of formaldehyde, 1,3-butadiene, toluene, xylene decrease, however, acetaldehyde and benzene emissions increase.The results indicate that the combination of ultra-low sulfur diesel and biodiesel from waste cooking oil gives similar results to those in the literature using higher sulfur diesel fuels and biodiesel from other sources.     

Evaluation of performance and emission behaviour of DI diesel engine powered by biofuel

In this experiment, the performance, emission, and combustion characteristics of a diesel engine were tested using bio-fuel (Anise oil) at different loads. The main focus of this study was to compare the existing biodiesel blends with the proposed mixture (anise?+?cerium oxide) of biodiesel blends in terms of engine parameters, cost, efficiency, and pollution control. The blends used in this experiment are B10 (Biodiesel-10%), B20 (Biodiesel-20%), and B30 (Biodiesel-30%). The emission and performance parameters considered for the test are SFC (specific fuel consumption), CO (carbon monoxide), NO_X (nitrogen oxide), and HC (hydrocarbon). These parameters were tested for different load conditions such as 0%, 25%, 50%, 75%, and 100%. From the results, it shows that SFC is lower for B20 blend compared to that of pure diesel fuel, while B10, B30, B40, and B50 blends have slightly higher values. From the experiment, it is found that emissions of the HC and NO_x were reduced and CO emission is slightly higher than the pure diesel.     

The influence of bio additive on the compression ignition engine with diesel and Jatropha methyl ester biodiesel

The present experimental investigation evaluates the effects of using blends of diesel fuel with 20% concentration of Methyl Ester of Jatropha biodiesel blended with bio additive. Both the diesel and biodiesel fuel blend was injected at 23° Before Top Dead Centre to the combustion chamber. The experiment was carried out with three different ratios of bio additive. Biodiesel was extracted from Jatropha oil; 20% (B20) concentration is found to be best blend ratio from the earlier experimental study. The bio additive was added to B20MEOJ at various concentrations of 1?ml, 2?ml and 3?ml, respectively. The main objective is to obtain minimum specific fuel consumption, better efficiency and lesser Emission using bio additive blends. The results concluded that full load shows an increase in efficiency when compared with diesel, and highest efficiency is obtained with B20MEOJBA 3?ml bio additive blend. It is noted that there is an increase in thermal efficiency as the blend ratio increases. Biodiesel blend has a performance closer to that of diesel, but emission is reduced in all blends of B20MEOJBA 3?ml compared to that in diesel. Thus the work marks for the suitability of biodiesel blends as an alternate fuel in diesel engines.     

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.     

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.     

Experimental analysis of Deccan hemp oil as a new energy feedstock for compression ignition engine

This study investigates the biodiesel from Deccan hemp oil and its blends for the purpose of fuelling diesel engine. The performance and emission characteristics of Deccan hemp biodiesel are estimated and compared with diesel fuel. The experimental investigations are carried out with different blends of Deccan hemp biodiesel. Results show that brake thermal efficiency is improved significantly by 4.15% with 50 BDH when compared with diesel fuel. The Deccan hemp biodiesel reduces NO_x, HC and CO emission along with a marginal increase in CO₂ and smoke emissions with an increase in the biodiesel proportion in the diesel fuel. The improvement in heat release rates shows an increase in the combustion rate with different percentage blends of Deccan hemp biodiesel. From the engine test results, it has been established that 30–50 BDH of Deccan hemp biodiesel can be substituted for diesel.     

Effect of biodiesel fuel properties and formation of NOx emissions: a review

Biodiesel is revealed as an environmentally friendly alternative fuel for a CI engine and it can palliate regulated and unregulated emissions. Biodiesel is substantially found to reduce the emissions of hydrocarbons, carbon monoxide, and particulate matter, but increasing (10–15%) oxides of nitrogen (NO_x) emissions compared with conventional diesel fuel. The accurate cause for NO_x emission is still vague. This paper reviews the effect of biodiesel properties and formation of NO_x emissions and it is classified in three sections. The first section bestows the NO_x formation mechanisms. The second edition deals with the influence of formation and biodiesel properties on NO_x emissions. Finally, a few prevailing conclusions are epitomised, and more researches are pointed out.     

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.     

Experimental investigation on the performance and emission characteristics of CI engine using waste cotton seed biodiesel with ZNO as a fuel additive

ABSTRACT

The energy crisis created by depletion of fossil fuels and the toxic emissions from the fossil fuel demands for eco-friendly potential alternative sources of energy. Even though unclean, biodiesel is found to be a potential alternative for the fossil fuels. In the present work, the emission characteristics and performance of biodiesel blend with and without ZNO additive was studied. There are four biodiesel blends studied in the first part of the research and found that the B25 combination gives a better result compared to others; therefore, this blend is tested with three proportion of ZNO additive in the second part of the research. The addition of 125?PPM of ZNO to the selected B25 blends gives a better performance, the efficiency improvement is found to be 4.2% and the emission of NO_x is by 10.3% under full load condition.     

Effect of Al2O3 nano-additives on the performance and emission characteristics of jatropha and pongamia methyl esters in compression ignition engine

Nano-additives can be added to biodiesel blends to improve its performance through better fuel properties. The present study investigated the effects of Al₂O₃ nano-additives on B20 blends of pongamia and jatropha biodiesel in a vertical single cylinder direct injection compression ignition engine. The fuel properties have been determined for all fuel samples with and without additives addition. The engine study was conducted to analyse the performance and emission characteristics of the blends with and without the additives at varying loads. The emissions from the biodiesel blends were comparatively lesser than that of normal diesel. B20 blend of pongamia biodiesel with additive has shown better performance. Additive-added biodiesel blends show a significant reduction in NO_x emission.     

Study on the outcome of a cetane improver on the emission characteristics of a diesel engine

ABSTRACT

Dimethyl carbonate (DMC), a cetane improver, is used as a fuel additive to investigate the exhaust emission in diesel engine. Neem oil biodiesel (B100), neem oil biodiesel + dimethyl carbonate (B100+DMC) and diesel were used as test fuels. DMC is added 0.5% by volume to biodiesel. This research work was executed in a four-stroke, single-cylinder diesel engine. Owing to the percentage of DMC in biodiesel, carbon monoxide (CO) and hydrocarbon (HC) emissions were dropped corresponding to diesel. A considerable amount of nitrogen oxide (NO_x) is decreased when diesel is used, and by the addition of B100+DMC, NO_x were slightly reduced compared to B100.     

Experimental investigation of performance and emissions characteristics on single-cylinder direct-injection diesel engine with PSZ coating using radish biodiesel

ABSTRACT

It has been determined that world oil production is likely to level off very shortly and that alternative fuels will have to meet the demands of an increasing energy crisis. The crude oil price is continuing to increase; at the same time the need of energy is also increasing rapidly. So there is an urgent need to switch to some other fuels which could replace petrol and diesel in order to produce energy. An eco-friendly alternative is required to fulfil the growing demand. This project highlights our work on alternate fuels and the importance of choosing radish seed as one such alternative. The aim of this study is the experimental investigation of performance and emissions on a single-cylinder direct-injection diesel engine with a coating. Diesel, B25, B50, B75 and B100 are used as fuels. The engine cylinder head, valves and piston crown are coated with 100 micron of nickel-chrome-aluminium bond coat and 450 micron of partially stabilised zirconia by the atmospheric plasma spray method [Ravikumar and Senthilkumar (2013). “Reduction of NOx Emission on NiCrAl-Titanium Oxide Coated Direct Injection Diesel Engine Fuelled with Radish (Raphanus sativus) Biodiesel.” Journal of Renewable and Sustainable Energy 5 (6): 063121]. Further, by using radish biodiesel and its blends, the emission and performance characteristics are checked and a suitable blend is selected.     

Effects of hydrocarbon fuel extracted from waste transformer oil on a DI diesel engine

In this study, hydrocarbon fuel (HCF) was derived from waste transformer oil through a traditional base-catalysed trans-esterification process. The experimental investigations using its blends of 25%, 50%, 75%, 100% and diesel fuel were carried out separately. The HCF obtained from waste transformer oil is used in a direct injection (DI) diesel engine without any engine modification to evaluate its performance, emission and combustion characteristics. The results indicate that the engine operating on test fuel blends shows a marginal increase in brake thermal efficiency (BTE) with a significant reduction in smoke. Nitrous oxides (NO_x) emission was slightly higher for test fuel blends than for diesel. The results show that at maximum load conditions, 25% HCF reduces carbon monoxide, smoke and hydrocarbon emission by 50%, 31% and 10%, respectively, whereas 50% HCF shows a greater BTE than other blends and is 12% higher than that of the diesel fuel. The combustion characteristics of fuel blends closely followed those of standard diesel.     

Investigation on the combustion,performance and emissions of a diesel engine fuelled by biodiesel and its blends with different oxygenated organic compounds

An experimental investigation is carried out to evaluate the effects of biodiesel–ethanol (BE) blends, biodiesel–dimethyl carbonate (BC) blends and biodiesel–diglyme (BG) blends on the combustion, performance and emission characteristics of a diesel engine operated at different loads and constant engine speed. Compared with biodiesel, for a specific engine load, the BE and BC blends have lower peak cylinder pressure at full load, while the BG blends show a slight variation in the peak cylinder pressure. In comparison with biodiesel, the BE, BC and BG blends have slightly higher brake thermal efficiency. Drastic reduction in smoke is observed with BE, BC and BG blends at higher engine loads. The BSNO_x emissions are found slightly lower for BE, BC and BG blends almost at all loads. The BE and BC blends have a slight variation in the BSCO and BSHC emissions, while the BG blends have lower BSCO and BSHC emissions.     

Evaporation rate and engine performance analysis of coated diesel engine using Raphanus sativus biodiesel and its diesel blends

An experimental investigation to measure the evaporation rates, PSZ-coated engine performance and emissions of radish biodiesel (Methyl Ester of radish oil) and its blends in different volumetric proportions with diesel is presented. The thermo-physical properties of all the fuel blends have been measured and presented. Evaporation rates of neat radish biodiesel, neat diesel and their bends have been measured under slow convective environment of air velocity of 0.2?m/s with a constant temperature of 200°C. Evaporation constants have been determined by using the droplet regression rate data. The neat fuels and fuel blends have been utilised in a test engine with different load conditions to evaluate the performance and emission characteristics of the fuels. From the observed evaporation, performance and emissions characteristics, it can be suggested that a blend of B25–B75 could be optimally used in coated diesel engine settings without any modifications on it.     

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.