Two separate injectors were used to simultaneously inject ethanol and gasoline in the intake port of a single cylinder SI engine. The relative amounts of the two fuels on mass basis and the spark timing were changed using a real time controller. Neat gasoline could be used till 35% throttle beyond which higher thermal efficiency and torque could be obtained by switching to 30% ethanol. This system can be used to provide sufficient margin for knock free operation. Efficiency and torque were better at a mass ratio of 1:1 (50% of ethanol and 50% of gasoline) due to faster combustion as a result of better mixture preparation as compared to conventional pre-blended injection of gasoline and ethanol. However, NO and HC were slightly elevated. This dual injection system can allow the use of ethanol only when needed while permitting stoichiometric operation even under high torque conditions by adjusting the proportion of ethanol. Ethanol-gasoline and n-butanol-gasoline were compared in terms of performance and emission with dual injection strategy. The amount of n-butanol has to be increased with increase in torque conditions for better performance and low emission. The benefit of using ethanol with gasoline is significant at high torque conditions. © 2016 Elsevier Ltd.

Venugopal T

Mechanical

School of Mechanical Engineering

Chennai Campus

Sai Yashwanth Momula

Ramesh Asvathanarayanan

Momula S.Y

Gosala D.B

Asvathanarayanan R.

efficiency

Engine cylinders

Engines

Ethanol

Torque

DUAL INJECTORS

FUEL RATIO

KNOCK MARGIN

n-Butanol

SIMULTANEOUS INJECTIONS

Gasoline

alcohol

combustion

diesel engine

Energy efficiency

equipment

experimental study

fuel

operations technology

Petroleum

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

&nbsp;

&nbsp;

VIT University

Renewable Energy

This study discusses the effects of addition of small amount of ethanol on performance and emission behaviour of a gasoline fuelled lean burn SI engine. Experiments were carried out in a single cylinder diesel engine which is made to operate as SI engine on lean condition with gasoline as a fuel. The engine was operated at wide open throttle at a compression ratio of 10.5:1 and 1500 rpm at diverse equivalent ratios by injecting the fuel into manifold. The test outcomes stipulated that use of ethanol-gasoline blend (10% by volume) was better compared with pure gasoline. The test results also revealed that there was an accountable increase in brake power output, brake thermal efficiency and an apparent extension in the lean limit of operation with ethanol-gasoline blend. In emission front, reduction in hydrocarbon and carbon monoxide emissions were observed. There was an increase in carbon dioxide and NO emissions due to better combustion and high in-cylinder temperature. On the whole it is concluded that small ethanol addition to gasoline improves performance and reduces emission for lean operating SI engine. © 2019 Published under licence by IOP Publishing Ltd.

Fulltext

IOP Conference Series: Earth and Environmental Science

Investigations on effects of ethanol blending on performance and combustion characteristics of gasoline fuelled lean burn SI engine

Who's Who

Levin, David Saul, (born 28 Jan. 1962), Chief Executive, McGraw-Hill Education, New York, since 2014

SUMMARY: Simultaneous injection of n-butanol and gasoline through a new system of two injectors directing the sprays towards the back of the intake valve in a spark-ignition engine was tried in lieu of injecting a blend of these fuels through a single injector. This system avoids the problem of phase separation, which is generally faced during the use of alcohol-gasoline blends. Experiments were conducted on a spark-ignition engine with this dual injection system using a fuel ratio of 1:1 (B50S) on the mass basis. High-speed photographs indicated that the sprays from the injectors did not interfere till they reached the intake valve. Comparisons were made with pre-blended butanol-gasoline (B50) and neat (100%) gasoline at the best spark timing. All injection and spark parameters were controlled using a real time engine controller.Neat n-butanol (B100) was superior only near full throttle with improved efficiency of the engine of about 1.2% (absolute). Heat release rates were observed to be higher and more advanced with B100 at wide open throttle. However, a reverse of this trend was observed at the throttle position of 15%. NO emission was also lower by 30% with B100 at wide open throttle as compared with gasoline. However, a small increase in carbon monoxide (CO) levels was observed because of lower post combustion temperatures as compared with gasoline and B50S. Simultaneous injection reduced hydrocarbon (HC) emissions by 13% to 50% as compared with B50 (blended fuel). HC emissions with gasoline and B50S were similar. Nitric oxide (NO) emission was lower with B50S as compared with gasoline; however it was higher than B50 because of better combustion. On the whole, the developed dual injection system was superior to the conventional method of blending in terms of performance, emissions and ability to change the fuel ratio as needed. B50S is suitable at all throttle positions, whereas B100 shows benefits at full throttle conditions. © 2013 John Wiley & Sons, Ltd.

International Journal of Energy Research

Performance, combustion and emission characteristics of a spark-ignition engine with simultaneous injection of n-butanol and gasoline in comparison to blended butanol and gasoline

SAE Technical Paper Series

Investigation to Leveraging Effect of Ethanol Direct Injection (EDI) in a Gasoline Port Injection (GPI) Engine

Impact of alcohol–gasoline fuel blends on the exhaust emission of an SI engine

In spark ignition engines fuelled by alcohol gasoline blends, the proportion of the two fuels has to be varied according to the operating condition. Further high amounts of alcohol cannot be blended with gasoline because the two phases can separate under certain conditions. In this work a dual injection system, wherein n-butanol and gasoline can be injected separately in any ratio has been employed in a spark ignition engine. The objective is to determine the most suitable amounts of n-butanol and gasoline to be used at different operating conditions of a four stroke spark ignition engine when these fuels are simultaneously injected into the intake manifold using this dual injection system. Experiments are conducted at different fuel ratios and throttle positions at an equivalence ratio of 1. The system results in good vaporization of the fuels even at low load conditions because the fuel jets are aligned to hit different portions of the intake valve. Results indicate that with proper selection of the fuel ratio significant reduction in HC emissions can be achieved as compared to operation on neat gasoline. Up to 60% of n-butanol could be used at 15% throttle while up to 80% could be used at 25% throttle. These proportions are higher than what have been achieved by pre-blending these fuels. The possibility of using high amounts of n-butanol reduced the tendency to knock. Hence, with the dual injection system n-butanol can be effectively used along with gasoline. © 2013 Elsevier Ltd. All rights reserved.

Applied Thermal Engineering

Effective utilisation of butanol along with gasoline in a spark ignition engine through a dual injection system

Experimental studies on simultaneous injection of ethanol-gasoline and n-butanol-gasoline in the intake port of a four stroke SI engine

Journal	Data powered by TypesetRenewable Energy
Publisher	Data powered by TypesetElsevier Ltd
ISSN	09601481
Open Access	No