Experimental analysis of DI diesel engine using dual biofuel blended with diesel

ABSTRACT

In recent years, biodiesel has become more attractive as an alternative fuel for diesel engines because of its environmental benefits and the fact is that it is made from renewable resources. The role of biodiesel is not to replace petroleum diesel, biofuels help to improve the economical growth and positive impacts on the environment. The main purpose of this research is to reduce the emission such as carbon monoxide (CO), nitrogen oxides (NO_X), hydrocarbons (HC) and carbon dioxide (CO₂). And to increase the performance characteristics such as break thermal efficiency (BTE), specific fuel consumption (SFC) of diesel engines. Here we used dual biofuel (lemongrass oil plus mint oil) blended with diesel and cerium oxide is added as an additive and undergone the test of engine performance and emission parameters of diesel. The measuring parameters are BTHE, specific fuel conception, CO₂, CO, NO_x and HC.     

Experimental analysis of the effects of cerium oxide nanoparticles on a single-cylinder diesel engine using biofuel blended with diesel as fuel

Energy demand is the hot topic of all developing and developed countries. Energy demand has been increasing day by day at a high rate. So, it is necessary to find an alternative solution that is eco-friendly. Biodiesel can be the alternative solution for this problem. The main purpose of this paper is to test the engine performance and emission parameters of a diesel engine using pure cinnamon oil blended with diesel and using cerium oxide as a catalyst. The parameters measured are brake power, brake thermal efficiency, specific fuel conception, CO₂, CO, NO_x and HC.     

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.     

Influence of dimethoxymethane addition on performance,emission and combustion characteristics of the diesel engine

This paper assesses the effects of dimethoxymethane (DMM) blends on combustion characteristics, fuel economy, emissions and engine’s power. Experiments were carried out on a single-cylinder, four-stroke compression ignition engine of direct injection with volume fractions of DMM blends of 5%, 10%, 15% and 20% v/v starting from base diesel. Experimental results suggest that 20% DMM blended with diesel achieved better performance in terms of efficiency as well as in exhaust emissions. Carbon monoxide emission levels, hydrocarbon and smoke are reduced considerably with DMM additions, while the oxides of nitrogen emission in exhaust increase due to higher in-cylinder temperature. The oxygen content in the DMM blends plays a greater role in the combustion process compared to neat diesel fuel. The combustion profile was smoother, and no knocking was experienced while operating with DMM blends. Also, it is observed that addition of DMM in diesel shortens the ignition delay and total combustion duration.     

Comparative study of performance of the DI diesel engine using custard apple biodiesel

Rising prices, depletion of fossil fuels and insufficient supply have created great interest on alternative sources of energy and fuels, for example biodiesel. Vegetable oils have been investigated as potential source for biodiesel, but they bring burden on food supply. Biodiesels obtained from non-edible sources are getting much interest now-a-days. This article deals with performance and emission study of biodiesel extracted from custard apple seeds that is non-edible. The custard apple biodiesel is obtained through the tranesterification process and different blends (B10, B20, B30 and B40) are prepared by mixing them with the conventional diesel fuel. The experiments are conducted on a four-stroke DI diesel engine at a compression ratio of 17.5, and performance and emission characteristics are evaluated. The study revealed that custard apple biodiesel has the potential to be used as an alternative source without any modifications in the engine.     

DOE applied to multi-response optimisation study on performance,combustion and emission characteristics of a VCR diesel engine

There are various parameters which may influence the IC engine performance. The trial and error method is a technique used to identify the best parameters. However, this method demands extensive experimental work and results in a great waste of time and resources. Thus, the design of experiments (DOEs) developed by Taguchi is employed. The multi-responses which need to be maximised are brake thermal efficiency, mechanical efficiency, cylinder pressure and cumulative heat release rate, whereas the responses which are to be minimised are specific fuel consumption, oxides of nitrogen and carbon monoxide. In the present study, an optimised DOE(L9) orthogonal array based on the Taguchi statistical method was formulated and a series of experiments were conducted under controlled supervision by considering three different injection operating pressures (IOPs) (200, 220 and 240 bar) and three different compression ratios (CRs) (16.5, 17.5 and 18.5). The main objective of this paper is to find the best suited IOP and CR values which obtain higher performance, better combustion and lower emissions.     

Detailed analysis on emission and performance characteristics of neat biofuel-fuelled diesel engine

ABSTRACT

There is an entanglement over the rapid exhaust of fossil fuel and soreness of environmental changes. Biofuels are acting as an alternative resource for petroleum products and also salve of emissions control and engine performance improvement. Scholars have seen the supreme use of bio-fuel apparent, as it will influence greenhouse effect. Investigation results show the diminished heating value in congruence with conventional pabulum, so it had depleted more in brake mean effective-fuel power ratio and proliferated NO_x compared with diesel fuel. The article mainly focuses on the selection – process of biofuel and analysis of performance (BSFC, EGT and brake thermal efficiency), emissions (CO, NO_x, CO₂, PM and HC) and combustion (NHR and CP) of the engine are exclusively discussed and summarised. Finally, stability, opportunity, and restraint of a selection of alternative fuel and investigation and study on the engine were asserted to guide further future exploration and evolution in that domain.     

The use of rapeseed methyl ester biodiesel in diesel engines

Biodiesel fuel is made from vegetable oil and can be used in existing diesel engines without requiring any modifications. The product is produced by transesterification of vegetable oil which uses alcohol (methanol or ethanol) and is known as methyl ester or ethyl ester. Biodiesel fuel is more environmentally friendly because it is biodegradable. The fuel does not contain sulphur and hence does not produce any sulphurous oxides which are, to a large extent, responsible for acid rain. The fuel does emit CO₂ but since this is absorbed by the plants during growth, it offers a net reduction in overall greenhouse gases relative to fossil fuels. The test results on biodiesel fuels showed high friction power with a net reduction in hydrocarbon emissions. The carbon deposits on the injector were similar to those observed when running on diesel while maximum power output was slightly lower due to low heating value of plant fuels.     

Performance and emission analysis of diesel engine with design modifications on piston crown

The present work aims to enhance the performance of the existing diesel engine by modifying the piston design. Swirl piston is used to induce turbulence as an active enhancement technique. The engine is run at 250 bar injection pressure and 17.5 compression ratio by varying the injection timings. A stirrer is introduced at the top of the piston so as to inculcate more turbulence to incoming charge that improves the fuel vaporisation rate. Whirling motion is created in the combustion chamber by rotating the blades on the cavity/bowl of the reciprocating piston head. A simple link mechanism is provided to convert the oscillatory motion of connecting rod into the rotary motion of the vane. The experimental result clears that the brake-specific fuel consumption is reduced by 8.7%, brake thermal efficiency is enhanced by 9.4%, 11.8% of CO emissions are controlled and NO _x emissions are controlled by 27% is observed with the modified piston compared to the normal piston at retarded injection timing.     

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.     

Performance and emission characteristics analysis of thermal barrier coated LHR engine fuelled with Eucalyptus-water emulsion

ABSTRACT

Experiments were conducted to analyse the efficiency of Diesel, E20 biodiesel and Eucalyptus-Water emulsions (Eucalyptus Water Mixture1, Eucalyptus Water Mixture2, Eucalyptus Water Mixture3) in a Low Heat Rejection Engine (LHR). The parameters considered were brake thermal efficiency, specific energy consumption, hydrocarbon emission, carbon monoxide emission, smoke opacity emission, oxides of nitrogen (NO _X ) emission, exhaust gas temperature, heat release rate and cylinder pressure. For this experiment, the piston’s top surface and cylinder head’s bottom surface, of the LHR engine were covered with Partially Stabilised Zirconia (PSZ). The Process of trans-esterification was made use of to process the raw eucalyptus. The experiment was found fruitful with the use of EWM3 (Eucalyptus Water Mixture3) in the LHR engine. From the analyses, the brake thermal efficiency substantially increased and the NO _X emission was found to be decreased when EWM3 (Eucalyptus Water Mixture3) was used in the LHR engine.     

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.     

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.     

Evaluation of the effects of engine parameters on performance and emissions of diesel engine operating with biodiesel blend

Diminishing resources, alarming pollution levels and escalating price associated with the application of diesel in compression ignition engine have forced scientific community throughout the world to conduct several experiments for the evaluation of biodiesel (BD) as a substitute for diesel. Due to difference in the physical and chemical properties of BD and diesel, the engine parameters such as compression ratio (CR), injection pressure (IP) and injection timing (IT) may not be optimum for BD, especially for higher blends. The present study is carried out with the aim to investigate the combined effect of CR, IP and IT on the performance and emission of a diesel engine widely used in agriculture sector in India, fuelled with B40 (40% BD and 60% diesel on a volume basis). Furthermore, this paper also aims to find the optimum engine parameters. A total of 27 sets of experiments were conducted for different combination of engine parameters and 162 sets of performance and emission data were recorded with varying load conditions. Adjustment of operating parameters was helpful to overcome the shortcoming of higher blend of BD (B40). The results demonstrated that higher CR (18:1) and IP (240 bar) along with advance IT (26° bTDC) is the best combination for a constant speed engine with brake power of 3.5 kW.     

Assessment of waste plastic oil blends on performance,combustion and emission parameters in direct injection compression ignition engine

The present experimental investigation deals with the transformation of waste plastic into oil in a pyrolysis reactor. A single feed at a rate of 8?kg yielded 675?ml of pyrolytic oil. The physiochemical properties of plastic oil (PO) were found to be within American Society for Testing and Material standards with higher kinematic viscosity and carbon residue. The GC-MS and Fourier Transform Infrared Analysis studies revealed the presence of 14 different compounds in PO. Straight diesel–PO blending was carried out at 15% and 30% in volume ratio. At full-load condition, in-cylinder pressure, rate of pressure rise, rate of heat release and peak pressure were higher for PO30% than straight diesel. The brake thermal efficiency for PO blends was found to be slightly higher than straight diesel with a significant increase in brake-specific fuel consumption. Unburned hydrocarbon (UBHC), CO NO _x and smoke emission showed significant variation with PO blends. The physiochemical properties of PO blends significantly affect the engine performance.     

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.     

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.     

Experimental investigation of engine emissions with marine gas oil-oxygenate blends

This paper investigates the diesel engine performance and exhaust emissions with marine gas oil-alternative fuel additive. Marine gas oil (MGO) was selected as base fuel for the engine experiments. An oxygenate, diethylene glycol dimethyl ether (DGM), and a biodiesel (BD) jatropha oil methyl ester (JOME) with a volume of 10% were blended with the MGO fuel. JOME was derived from inedible jatropha oil. Lower emissions with diesel-BD blends (soybean methyl ester, rapeseed methyl ester etc.) have been established so far, but the effect of MGO-BD (JOME) blends on engine performance and emissions has been a growing interest as JOME (BD) is derived from inedible oil and MGO is frequently used in maritime transports. No phase separation between MGO-DGM and MGO-JOME blends was found. The neat MGO, MGO-DGM and MGO-JOME blends are termed as MGO, Ox10 and B10 respectively. The experiments were conducted with a six-cylinder, four-stroke, turbocharged, direct-injection Scania DC 1102 (DI) diesel engine. The experimental results showed significant reductions in fine particle number and mass emissions, PM and smoke emissions with Ox10 and B10 fuels compared to the MGO fuel. Other emissions including total unburned hydrocarbon (THC), carbon monoxide (CO) and engine noise were also reduced with the Ox10 and B10 fuels, while maintaining similar brake specific fuel consumption (BSFC) and thermal efficiency with MGO fuel. Oxides of nitrogen (NOx) emissions, on the other hand, were slightly higher with the Ox10 and B10 fuels at high engine load conditions.     

CI engine performance during cold weather condition using preheated air and engine by waste energy

ABSTRACT

The aim of the current research is to experimentally investigate the performance, combustion and emission parameters of a compression ignition engine in the discharging and air preheating mode during the cold weather condition. For preheating the engine, a thermal energy storage device using phase-change material (PCM) and for preheating the inlet air an air preheater is used. From the results, it is observed that the engine temperature increases with time from 15°C to 27°C in 840?s. PCM temperature rises from 15°C to 60°C in 3000?s. during charging and while in discharging it decreases from 45°C to 30°C within the same time period. Brake thermal efficiency increases and brake-specific fuel consumption decreases with increase in load. Air-preheated diesel gives maximum cylinder pressure as compared to normal diesel. Carbon monoxide and hydrocarbon emissions are reduced during discharging and air preheating as compared to cold weather emission.     

Numerical and experimental investigations on a dual fuel HCCI engine by using ethanol as primary fuel and diesel as secondary fuel for NOX reduction and better performance

ABSTRACT

Achieving the new emission norms is a difficult task to today’s compression ignition (CI) engine without any exhaust gas after-treatment technologies. It is necessary to find the practical method which reduces the unsafe emission, with minor modifications of the CI engine. Dual fuel homogeneous charge compression ignition (HCCI) engine has been recognised as one of the solutions to minimise the emissions and achieve higher performance. In the present study the dual fuel HCCI engine mode of operation carried out by supply of ethanol fuel-air mixture to the engine cylinder through the carburetor and diesel fuel is directly injected at the end of compression for the initiation of ignition. Dual fuel HCCI engine is one of the most promising engines suitable for alternative fuels and lower NO_X emissions. An experimental investigation is carried out on dual fuel HCCI engine. Fuel consumption and exhaust emissions such as NO_X, CO₂, CO, HC are measured and compared with conventional CI engine. The results show that NO_X emission tends to decrease at low and moderate loads of the engine, but at full load condition it is slightly higher. Further, thermal efficiency is calculated and compared in CI engine; it is observed that there is a slight improvement in thermal efficiency at high load operation. In the dual fuel HCCI engine mode, there is a provision to use of ethanol or any other alternate fuel for better energy efficiencies and low NO_X emission.