Alternative Fuels for Particulate Control in CI Engines

Despite a number of efforts to evaluate the utility of water-diesel emulsions (WED) in CI engine to improve its performance and reduce its emissions in search of alternative fuels to combat the higher prices and depleting resources of fossil fuels, no consistent results are available. Additionally, the noise emissions in the case of WED are not thoroughly discussed which motivated this research to analyze the performance and emission characteristics of WED. Brake thermal efficiency (BTE) and brake specific fuel consumption (BSFC) were calculated at 1600 rpm within 15%–75% of the load range. Similarly, the contents of NOx, CO, and HC, and level of noise and smoke were measured varying the percentage of water from 2% to 10% gradually for all values of loads. BTE in the case of water emulsified diesel was decreased gradually as the percentage of water increased accompanied by a gradual increase in BSFC. Thus, WED10 showed a maximum 13.08% lower value of BTE while BSFC was increased by 32.28%. However, NOx emissions (21.8%) and smoke (48%) were also reduced significantly in the case of WED10 along with an increase in the emissions of HC and CO and noise. The comparative analysis showed that the emulsified diesel can significantly reduce the emission of NOx and smoke, but it has a negative impact on the performance characteristics and HC, CO, and noise emissions which can be mitigated by trying more fuels variations such as biodiesel and using different water injection methods to decrease dependency on fossil fuels and improve the environmental impacts of CI engines.

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Experimental investigation on performance, smoke and exhaust gas analysis of four stroke diesel engine using pongomia/neem oil biodiesel

International Journal of Engineering Science and Technology ◽

10.4314/ijest.v12i4.3 ◽

2021 ◽

Vol 12 (4) ◽

pp. 23-40

Author(s):

Naresh Kumar Konada ◽

K.N.S. Suma ◽

B.B. Ashok Kumar

Keyword(s):

Diesel Engine ◽

Energy Demand ◽

Alternative Fuels ◽

Gas Analysis ◽

Load Test ◽

Transport Sector ◽

Exhaust Gas ◽

Neem Oil ◽

Fuel Blends ◽

Ci Engines

Increase in energy demand, stringent emission norms and depletion of oil resources led to the discovery of alternative fuels forinternal combustion engines. Many alternative fuels like alcohols, petroleum gas, and compressed natural gas have been alreadycommercialized in the transport sector. In the present work, Pongomia oil and Neem oil are blended with diesel and used as analternate fuel for CI engines. The Pongomia oil and Neem oil can be converted into bio diesel using a chemical process of trans- esterification.Different proportions of fuel blends have been produced by the process of blending bio diesel consisting of 10%, 15%, 20%, 25%, and 30% (B10, B15, B20, B25, B30). The fuel properties of each blend are determined. The load test along with smoke and exhaust gas analysis of 4- Stroke Diesel engine using the blends of Pongomia oil and Neem oil with diesel are done in this study. The performance parameters of an engine are calculated for different blends. The sustainability of using alternate fuels in Diesel engines, especially the potential use of Pongomia oil and Neem oil as biodiesel have been brought to the fore through this work and suitable blends of bio diesel is suggested from the results. Keywords: 4-Stroke Diesel Engine, Pongomia and Neem oil Bo diesel, Performance, Smoke and exhaust gas analysis.

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A Comprehensive Review on Low-Temperature Combustion Technologies for Emission Reduction in Diesel Engines

International Journal of Automotive and Mechanical Engineering ◽

10.15282/ijame.18.4.2021.07.0710 ◽

2021 ◽

Vol 18 (4) ◽

Author(s):

Amit Jhalani ◽

Dilip Sharma ◽

Pushpendra Kumar Sharma ◽

Digambar Singh ◽

Sumit Jhalani ◽

...

Keyword(s):

Low Temperature ◽

Diesel Engines ◽

Alternative Fuels ◽

Low Temperature Combustion ◽

Compression Ignition ◽

Lean Burn ◽

Performance And Emissions ◽

Temperature Combustion ◽

Hc Emissions ◽

Ci Engines

Diesel engines are lean burn engines; hence CO and HC emissions in the exhaust are less likely to occur in substantial amounts. The emissions of serious concern in compression ignition engines are particulate matter and nitrogen oxides because of elevated temperature conditions of combustion. Hence the researchers have strived continuously to lower down the temperature of combustion in order to bring down the emissions from CI engines. This has been tried through premixed charge compression ignition, homogeneous charge compression ignition (HCCI), gasoline compression ignition and reactivity controlled compression ignition (RCCI). In this study, an attempt has been made to critically review the literature on low-temperature combustion conditions using various conventional and alternative fuels. The problems and challenges augmented with the strategies have also been described. Water-in-diesel emulsion technology has been discussed in detail. Most of the authors agree over the positive outcomes of water-diesel emulsion for both performance and emissions simultaneously.

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Effect by Guide Vane Swirl and Tumble Device to Improve the Air-Fuel Mixing of Diesel Engine Running With Higher Viscous Fuels

Volume 7B: Fluids Engineering Systems and Technologies ◽

10.1115/imece2013-62297 ◽

2013 ◽

Author(s):

Idris Saad ◽

Saiful Bari

Keyword(s):

Alternative Fuels ◽

Parametric Optimization ◽

Reference Data ◽

Guide Vane ◽

Optimization Technique ◽

Optimum Number ◽

Ansys Software ◽

Mixing Processes ◽

Ci Engine ◽

Ci Engines

The purpose of this study was to investigate the effect guide vane swirl and tumble device (GVSTD) on the in-cylinder airflow particularly to generate turbulent kinetic energy (TKE) and velocity inside the combustion chamber and around fuel injected region. High velocity and TKE would accelerate the evaporation, diffusion and mixing processes of CI engines, particularly when alternative fuels of higher viscosity and density (known as HVF — higher viscous fuel) are used. A verified simulation base model was prepared by the SolidWorks software and analysed using ANSYS software to study the reference data of the resulting in-cylinder airflow characteristics. Then GVSTD models were developed and imposed on the intake runner of the base model. The parametric optimization technique was used to find the optimum number of vanes for the GVSTD model. This was done by preparing 10 GVSTD models with the vane number varied from 3 to 12. The models were then tested on the base model individually. Generally, GVSTD improve in-cylinder TKE and velocity. Additionally, this research found that GVSTD with 3 vanes resulted in an improved TKE and velocity of about 6.3% and 10.4% respectively when compared to the base model. Therefore, it may be said that the use of GVSTD can increase the chances to improve the performance of a CI engine and reduce the emission when run on HVF.

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The effect of alternative fuels injection timing on toxic substances formation in CI engines

Combustion Engines ◽

10.19206/ce-2017-112 ◽

2017 ◽

Vol 168 (1) ◽

pp. 73-76

Author(s):

Marcin WOJS ◽

Piotr ORLIŃSKI ◽

Jakub LASOCKI

Keyword(s):

Diesel Fuel ◽

Alternative Fuels ◽

Fuel Injection ◽

Combustion Process ◽

Acid Methyl Ester ◽

Operating Conditions ◽

Injection Timing ◽

Toxic Substances ◽

Important Conclusion ◽

Ci Engines

The present study describes selected issues associated with the emission level in toxic exhaust gases and fuel injection timing. The study was focused on the following types of fuels: Diesel oil (the base fuel) and the other fuels were the mixture of fatty acid methyl ester with Camelina (L10 – diesel fuel with 10% V/V FAME of Camelina and L20 – diesel fuel with 10% V/V FAME of Camelina) was used. Fuel injection advanced angle was set for three different values – the factory setting – 12° before TDC, later injection – 7° and earlier injection – 17°. The most important conclusion is that in most measurement points registered in the same engine operating conditions, the concentration of fuel NOx in L10 and L20 increased but PM emissions decreased which is caused by active oxygen located in the internal structure of the fuel. This fact contributes to the rise in temperature during the combustion process. At the same time factory settings of the angle makes NOx emissions lower and close to reference fuel.

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Experimental Investigations on the Effect of Long Term Biodiesel Usage on Thermal Decomposition of CI Engine Crankcase Oil

ASME 2009 Internal Combustion Engine Division Fall Technical Conference ◽

10.1115/icef2009-14047 ◽

2009 ◽

Author(s):

Purnanand V. Bhale ◽

Nishikant V. Deshpande ◽

Piyush N. Deshpande

Keyword(s):

Thermal Stability ◽

Thermal Decomposition ◽

Alternative Fuels ◽

Lubricating Oil ◽

Experimental Investigations ◽

Biodiesel Fuel ◽

Endurance Tests ◽

Ci Engines ◽

Thermal Stability Of

The gradual depletion of world petroleum reserves, increases in prices of petroleum based fuels and environmental pollution due to exhaust emissions have encouraged studies to search for alternative fuels. Biodiesel is an alternative diesel fuel consisting of alkyl monoesters of fatty acids derived from vegetable oils. It has been the focus of considerable amount of recent research because it is renewable and reduces the emission of some pollutants. The desirability of developing biodiesel from different tree borne oil seeds and decreasing the dependency on petroleum based fuels has been discussed by many over the last few decades. However some of the important issues like compatibility of biodiesel with the crankcase lubricating oil, thermal stability of lubricating oil with biodiesel usage, changes in physical and chemical properties of lubricating oil with biodiesel etc. have not been sufficiently investigated. This needs to be addressed in order to ensure the long term acceptability of biodiesel in an existing family of diesel engines. In the present work these issues have been addressed. For this purpose engine endurance tests were conducted on CI engines. Two new single cylinder four stroke CI engines were operated for 512 hours each for diesel and 100% biodiesel fuel. The endurance tests were conducted as per BIS 10000 part IX norms. Biodiesel from Jatropha oil was prepared in-house using transesterification process. The sample of lubricating oil was collected through a one way valve connected to the crankcase sump after every 128 hours intervals. Thermograviometric analysis (TGA) was used to evaluate the thermal stability of lubricating oil samples obtained from both the engines. The thermal decomposition of lubricating oil samples were measured as a function of various reaction parameters such as temperature, time and heating rates. This TGA test involves a weight change as the oil was heated. The weight loss data of the sample was logged using the in situ computer. Early decomposition of biodiesel fueled engine lubricating oil was observed as compared to diesel fueled engine lubricating oil. The changes in viscosity of lubricating oil were also monitored during the endurance test and discussed in detail. A higher level of crank case dilution was observed in case of biodiesel as compared to diesel.

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Experimental Investigation of Four Stroke Diesel Engine Performance Using Neem Oil and Neem Oil with Hydrogen as a Fuel

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.592-594.1559 ◽

2014 ◽

Vol 592-594 ◽

pp. 1559-1563

Author(s):

Thangaraju Rajasekaran ◽

K. Duraisamy ◽

K.R. Arvindd ◽

D. Thamilarasu ◽

Venkatachalam Chandraprabu ◽

...

Keyword(s):

Energy Demand ◽

Alternative Fuels ◽

Fossil Fuels ◽

Driving Forces ◽

Environmental Concern ◽

Engine Performance ◽

Calorific Value ◽

Neem Oil ◽

Combustion Properties ◽

Ci Engines

Depletion of fossil fuels, unaffordability of conventional fuels (petrol, diesel) and atmospheric pollution lead researchers to develop alternative fuels. Fuels derived from renewable biological resources used in diesel engines are known as biodiesel. Biodiesel is environmental friendly liquid fuel similar to petrol and diesel in combustion properties. Increasing environmental concern, diminishing petroleum reserves and agriculture based economy of our country are the driving forces to promote biodiesel as an alternate fuel. Hydrogen seems to be viable fuel to meet sustainable energy demand with minimum environmental impact. Hydrogen has high calorific value and clean burning characteristics which makes it effective fuel for future. It was found that hydrogen usage reduce emissions such as CO2and HC. India is one of the largest producers of neem oil and its seed contains 30% oil content. It is an untapped source in India, so the neem oil usage will be a best option. The investigation made on pure neem oil and neem oil with hydrogen addition at different flow rate (2 lpm & 4 lpm) in CI engines. The result shows that, brake thermal efficiency of neem oil with 4 lpm hydrogen was increased to 7.98% compare to pure neem oil at 4 Nm torque and fuel consumption of neem oil with 4 lpm hydrogen was decreased to 13.49% compared to pure neem oil at 4 Nm torque.

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Experimental Investigations on DI Diesel Engine With Low Heat Rejection Combustion Chamber With Waste Fried Vegetable Oil and its Biodiesel

Volume 8B: Heat Transfer and Thermal Engineering ◽

10.1115/imece2015-53202 ◽

2015 ◽

Cited By ~ 1

Author(s):

Raavi Peraiah Chowdary ◽

Maddali V. S. Murali Krishna ◽

T. Kishen Kumar Reddy ◽

D. Srikanth ◽

P. V. Krishna Murthy ◽

...

Keyword(s):

Diesel Engine ◽

Combustion Chamber ◽

Vegetable Oil ◽

Alternative Fuels ◽

Air Gap ◽

Operating Conditions ◽

Injection Timing ◽

Heat Rejection ◽

Improved Performance ◽

Ci Engines

Biodiesels derived from vegetable oils present a very promising alternative fuels for diesel fuel, since they have numerous advantages compared to fossil fuels. However crude vegetable oil and biodiesel have high viscosity and low volatility causing combustion problems in CI engines, call for engine with hot combustion chamber. Investigations were carried out on single–cylinder, four–stroke, water cooled, 3.68 kW direct injection diesel engine at a speed of 1500 rpm to evaluate the performance of a engine with low heat rejection (LHR) combustion chamber. It consisted of an air gap (3 mm) insulated piston with superni (an alloy of nickel) crown and an air gap (3 mm) insulated liner with superni insert and ceramic coated cylinder head fuelled with different operating conditions (normal temperature and preheated temperature) of waste fried vegetable oil and its biodiesel with varied injection timing and injector opening pressure. Engine with LHR combustion chamber with biodiesel showed improved performance over conventional engine (CE) at 27° bTDC and at optimum injection timing. Biodiesel showed improved performance over crude vegetable oil with engine with both versions of the combustion chamber. Preheated test fuels and increase of injection pressure showed reduction of pollution levels and marginally improved performance over normal test fuels.

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THE INFLUENCE OF THE CHEMICAL STRUCTURE OF SYNTHETIC HYDROCARBONS AND ALCOHOLS ON THE LUBRICITY OF CI ENGINE FUELS AND AVIATION FUELS

Tribologia ◽

10.5604/01.3001.0010.6140 ◽

2017 ◽

Vol 273 (3) ◽

pp. 91-100 ◽

Cited By ~ 3

Author(s):

Andrzej KULCZYCKI ◽

Wojciech DZIĘGIELEWSKI ◽

Dariusz OZIMINA

Keyword(s):

Alternative Fuels ◽

Test Results ◽

Saturated Hydrocarbons ◽

Synthetic Hydrocarbons ◽

Lubricating Film ◽

Lubrication Layer ◽

Ci Engine ◽

Acid Test ◽

Ci Engines ◽

Fuel Lubricity

The paper covers the mechanism of lubrication layer formation by fuels containing synthetic hydrocarbons and alcohols. Development of alternative fuels containing FAME, alcohols, and synthetic hydrocarbons has increased the interest in the mechanism of lubrication of fuelling systems parts. Fuel lubricity tests have been conducted using the HFRR and BOCLE testing rigs. Fuels under testing, both for CI engines and for aviation turbine ones, contained synthetic components: saturated hydrocarbons both of even and odd number of carbon atoms, and butanol, isomers. These components have been added to conventional fuels, such as diesel fuel and Jet A-1 fuel at the concentration of 0–20% (V/V). All fuels under testing contained commercially available lubricity improvers (carboxylic acid). Test results were analysed using model αi described in [L. 6, 7]. As a result of the analysis, it has been found that the liquid phase, which is a lubricating film, should contain agglomerates or molecular clusters responsible for the transport of energy introduced into lubricating film by electrons emitted from metal surface. The mechanism enabling a description of the effect of base fuel without lubricity improvers on efficiency of such additives has been suggested.

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Potential Improvement in PM-NOX Trade-Off in a Compression Ignition Engine by n-Octanol Addition and Injection Pressure

Processes ◽

10.3390/pr9020310 ◽

2021 ◽

Vol 9 (2) ◽

pp. 310

Author(s):

Qiwei Wang ◽

Rong Huang ◽

Jimin Ni ◽

Qinqing Chen

Keyword(s):

Oxygen Content ◽

Alternative Fuels ◽

Energy Content ◽

Cetane Number ◽

High Energy ◽

Compression Ignition ◽

Compression Ignition Engine ◽

Promising Alternative ◽

Trade Off ◽

Ci Engines

n-Octanol, as an oxygenated fuel, is considered as one of the most promising alternative fuels, owing to advantages such as its low hygroscopic nature, high cetane number, and high energy content. However, the introduction of n-octanol leads to a higher viscosity and latent heat of evaporation (LHOE), affecting the combustion and emission performances of compression ignition (CI) engines. This study sheds light on the effect of injection pressures (IPs, ranging from 60 to 160 MPa) on the combustion and emission performances of a turbocharged CI engine, in conjunction with n-octanol/diesel blends. According to the proportion of oxygen content, the test fuels contain pure diesel (N0), N2.5 (2.5% oxygen content in the blending fuels), and N5 (5% oxygen content in the blending fuels). The results indicate that the blending fuels have little influence on the in-cylinder pressure, ignition delay (ID), and CA50, but they improve the brake thermal efficiency (BTE). In terms of emissions, with the use of blending fuels, the levels of carbon monoxide (CO), soot, and nitrogen oxides (NOX) decrease, whereas emissions of hydrocarbons (HC) slightly increase. With increasing IP, the ID, brake specific fuel consumption (BSFC), HC, CO, and soot decrease significantly, and the BTE and NOX increase. In addition, the combination of n-octanol and IP improves the trade-off between NOX and soot and reduces the CO emissions.

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