One-Dimensional Simulation Using Port Water Injection for a Spark Ignition Engine

Water injection is a promising solution to reduce fuel consumption while improving the performance of a turbocharged gasoline engine. One-dimensional (1D) engine simulation software, AVL BOOST is rarely used to model water injection. Therefore, this study is aimed to demonstrate the detailed port water injection modelling via AVL BOOST. A four-cylinder turbocharged gasoline engine was developed in AVL BOOST based on the specification of the engine test rig and verified to be used as the baseline model. The port water injection modelling was then added to the baseline model. Water to fuel mass ratios of 0.05, 0.10, 0.15, 0.2 and 0.25 were chosen as the variables to investigate the effect of water injection on the engine performance. The results showed that maximum engine torque and IMEP increased by 10.80% and 8.65%, respectively at 3000 rpm. The water injection also reduced the in-cylinder pressure at the end of the compression stroke, reducing the compression work and improving efficiency. The reduction of combustion temperature also indicates potential for NOx reduction. The lower exhaust temperature can reduce the use of fuel enrichment which consequently reduces the fuel consumption. Conclusively, the water injection model can predict the engine performance parameters accurately.

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Performance Analysis and Improvement Approach of HEV Extended Expansion Gasoline Engine

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.317-319.1999 ◽

2011 ◽

Vol 317-319 ◽

pp. 1999-2006

Author(s):

Yu Wan ◽

Ai Min Du ◽

Da Shao ◽

Guo Qiang Li

Keyword(s):

Mathematical Model ◽

Performance Analysis ◽

Fuel Consumption ◽

Economic Performance ◽

Gasoline Engine ◽

Engine Performance ◽

Valve Train ◽

Gasoline Engines ◽

Simulation Results ◽

Negative Impacts

According to the boost mathematical model verified by experiments, the valve train of traditional gasoline engine is optimized and improved to achieve extended expansion cycle. The simulation results of extended expansion gasoline engine shows that the extended expansion gasoline engine has a better economic performance, compared to traditional gasoline engines. The average brake special fuel consumption (BSFC) can reduce 22.78 g / kW•h by LIVC, but the negative impacts of extended expansion gasoline engine restrict the potential of extended expansion gasoline engine. This paper analyzes the extended expansion gasoline engine performance under the influence of LIVC, discusses the way to further improve extended expansion gasoline engine performance.

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THE STUDY OF THE EFFECT OF INTAKE VALVE TIMING ON ENGINE USING CYLINDER DEACTIVATION TECHNIQUE VIA SIMULATION

Jurnal Teknologi ◽

10.11113/jt.v77.6161 ◽

2015 ◽

Vol 77 (8) ◽

Author(s):

S. F. Zainal Abidin ◽

M. F. Muhamad Said ◽

Z. Abdul Latiff ◽

I. Zahari ◽

M. Said

Keyword(s):

Fuel Consumption ◽

Internal Combustion Engines ◽

Gasoline Engine ◽

Engine Performance ◽

Intake Valve ◽

Cylinder Deactivation ◽

Part Load ◽

Engine Model ◽

Engine Efficiency ◽

Load Conditions

There are many technologies that being developed to increase the efficiency of internal combustion engines as well as reducing their fuel consumption. In this paper, the main area of focus is on cylinder deactivation (CDA) technology. CDA is mostly being applied on multi cylinders engines. CDA has the advantage to improve fuel consumption by reducing pumping losses at part load engine conditions. Here, the application of CDA on 1.6L four cylinders gasoline engine is studied. One-dimensional (1D) engine modeling work is performed to investigate the effect of intake valve strategy on engine performance with CDA. 1D engine model is constructed based on the 1.6L actual engine geometries. The model is simulated at various engine speeds at full load conditions. The simulated results show that the constructed model is well correlated to measured data. This correlated model is then used to investigate the CDA application at part load conditions. Also, the effects on the in-cylinder combustion as well as pumping losses are presented. The study shows that the effect of intake valve strategy is very significant on engine performance. Pumping losses is found to be reduced, thus improve fuel consumption and engine efficiency.

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The Effects of Port Water Injection on Spark Ignition Engine Performance and Emissions Fueled by Pure Gasoline, E5 and E10

Processes ◽

10.3390/pr8101214 ◽

2020 ◽

Vol 8 (10) ◽

pp. 1214

Author(s):

Farhad Salek ◽

Meisam Babaie ◽

Maria Dolores Redel-Macias ◽

Ali Ghodsi ◽

Seyed Vahid Hosseini ◽

...

Keyword(s):

Water Injection ◽

Engine Performance ◽

Spark Ignition ◽

Injection Rate ◽

Spark Ignition Engine ◽

Oxides Of Nitrogen ◽

Human Beings ◽

Performance And Emissions ◽

Engine Performance And Emissions ◽

Engine Power

It has been proven that vehicle emissions such as oxides of nitrogen (NOx) are negatively affecting the health of human beings as well as the environment. In addition, it was recently highlighted that air pollution may result in people being more vulnerable to the deadly COVID-19 virus. The use of biofuels such as E5 and E10 as alternatives of gasoline fuel have been recommended by different researchers. In this paper, the impacts of port injection of water to a spark ignition engine fueled by gasoline, E5 and E10 on its performance and NOx production have been investigated. The experimental work was undertaken using a KIA Cerato engine and the results were used to validate an AVL BOOST model. To develop the numerical analysis, design of experiment (DOE) method was employed. The results showed that by increasing the ethanol fraction in gasoline/ethanol blend, the brake specific fuel consumption (BSFC) improved between 2.3% and 4.5%. However, the level of NOx increased between 22% to 48%. With port injection of water up to 8%, there was up to 1% increase in engine power whereas NOx and BSFC were reduced by 8% and 1%, respectively. The impacts of simultaneous changing of the start of combustion (SOC) and water injection rate on engine power and NOx production was also investigated. It was found that the NOx concentration is very sensitive to SOC variation.

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Effect of Spark Timing on Performance of a Hydrogen Gasoline Engine

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.713-715.239 ◽

2015 ◽

Vol 713-715 ◽

pp. 239-242 ◽

Cited By ~ 1

Author(s):

Wei Bo Shi ◽

Xiu Min Yu ◽

Ping Sun

Keyword(s):

Gasoline Engine ◽

Direct Injection ◽

Engine Performance ◽

Spark Ignition Engine ◽

Gasoline Direct Injection ◽

Hydrogen Energy ◽

Energy Fraction ◽

Direct Injection Engine ◽

Excess Air ◽

Spark Timing

Hydrogen-gasoline blends is an effective way to improving the performance of spark ignition engine at stoichiometric and lean conditions. Spark timing is one of the important parameters affect the engine performance. This paper investigated the effect of spark timing on performance of a hydrogen-gasoline engine. A four cylinder, gasoline direct injection engine was modified to be a gasoline port injection, hydrogen direct injection engine. The hydrogen energy fraction was set as 0% and 30%. For a specified hydrogen addition, the engine was operated at four excess air ratios of 0.8, 1.0, 1.2 and 1.5. Under the specified excess air ratio condition, the spark timing was varied from 4 to 19°CA before top dead center (BTDC) with an interval of 3°CA. The test result showed that the indicated mean effective pressure (IMEP) climb up and then decline with the increase of spark advance. For hydrogen-gasoline engine, the optimum spark timing for the max IMEP was retarded at a specified excess air ratio. The max thermal efficiency appeared at the optimum spark timing.

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One-Dimensional Model to Quantify NOx Reduction in Gas Turbines Using EGR

Volume 3: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/98-gt-270 ◽

1998 ◽

Author(s):

K. K. Botros ◽

M. J. de Boer ◽

G. Kibrya

Keyword(s):

Gas Turbine ◽

Thermal Efficiency ◽

Gas Turbines ◽

Nox Reduction ◽

Simulation Software ◽

Specific Work ◽

Dimensional Model ◽

Nox Formation ◽

One Dimensional ◽

Thermal Nox

A one dimensional model based on fundamental principles of gas turbine thermodynamics and combustion processes was constructed to quantify the principle of exhaust gas recirculation (EGR) for NOx reduction. The model utilizes the commercial process simulation software ASPEN PLUS®. Employing a set of 8 reactions including the Zeldovich mechanism, the model predicted thermal NOx formation as function of amount of recirculation and the degree of recirculate cooling. Results show that addition of sufficient quantities of uncooled recirculate to the inlet air (i.e. EGR>∼4%) could significantly decrease NOx emissions but at a cost of lower thermal efficiency and specific work. Cooling the recirculate also reduced NOx at lower quantities of recirculation. This has also the benefit of decreasing losses in the thermal efficiency and in the specific work output. Comparison of a ‘rubber’ and ‘non-rubber’ gas turbine confirmed that residence time is one important factor in NOx formation.

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Experimental and Theoretical Study of Injection Timing on Performance and Exhaust Emissions in a Port-Injected Gasoline Engine

ASME 2006 Internal Combustion Engine Division Spring Technical Conference (ICES2006) ◽

10.1115/ices2006-1405 ◽

2006 ◽

Author(s):

E. Movahednejad ◽

F. Ommi ◽

M. Hosseinalipour ◽

O. Samimi

Keyword(s):

Gasoline Engine ◽

Fuel Injection ◽

Engine Performance ◽

Fuel Mixture ◽

Exhaust Emissions ◽

Operating Conditions ◽

Exhaust Emission ◽

Injection Timing ◽

Intake Port ◽

One Dimensional

For spark ignition engines, the fuel-air mixture preparation process is known to have a significant influence on engine performance and exhaust emissions. In this paper, an experimental study is made to characterize the spray characteristics of an injector with multi-disc nozzle used in the engine. The distributions of the droplet size and velocity and volume flux were characterized by a PDA system. Also a model of a 4 cylinder multi-point fuel injection engine was prepared using a fluid dynamics code. By this code one-dimensional, unsteady, multiphase flow in the intake port has been modeled to study the mixture formation process in the intake port. Also, one-dimensional air flow and wall fuel film flow and a two-dimensional fuel droplet flow have been modeled, including the effects of in-cylinder mixture back flows into the port. The accuracy of model was verified using experimental results of the engine testing showing good agreement between the model and the real engine. As a result, predictions are obtained that provide a detailed picture of the air-fuel mixture properties along the intake port. A comparison was made on engine performance and exhaust emission in different fuel injection timing for 2600 rpm and different loads. According to the present investigation, optimum injection timing for different engine operating conditions was found.

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Investigation of the Gasoline Engine Performance and Emissions Working on Methanol-Gasoline Blends Using Engine Simulation

Numerical and Experimental Studies on Combustion Engines and Vehicles ◽

10.5772/intechopen.92858 ◽

2020 ◽

Author(s):

Simeon Iliev

Keyword(s):

Fuel Consumption ◽

Gasoline Engine ◽

Engine Performance ◽

Specific Fuel Consumption ◽

Injection System ◽

Si Engine ◽

Engine Simulation ◽

Fuel Blends ◽

Performance And Emissions ◽

The One

The aim of this study is to develop the one-dimensional model of a four-cylinder, four-stroke, multi-point injection system SI engine and a direct injection system SI engine for predicting the effect of various fuel types on engine performances, specific fuel consumption, and emissions. Commercial software AVL BOOST was used to examine the engine characteristics for different blends of methanol and gasoline (by volume: 5% methanol [M5], 10% methanol [M10], 20% methanol [M20], 30% methanol [M30], and 50% methanol [M50]). The methanol-gasoline fuel blend results were compared to those of net gasoline fuel. The obtained results show that when methanol-gasoline fuel blends were used, engine performance such as power and torque increases and the brake-specific fuel consumption increases with increasing methanol percentage in the blended fuel.

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SIMULATION ANALYSIS OF SPARK IGNITION ENGINE INTAKE MANIFOLD FOR BETTER PERFORMANCE

Jurnal Teknologi ◽

10.11113/jt.v79.12260 ◽

2017 ◽

Vol 79 (7-4) ◽

Author(s):

Muhammad Hariz Khairuddin ◽

Muhammad Fitri Shamsul Bahri ◽

Afiq Aiman Dahlan ◽

Mahadhir Mohammad ◽

Mohd Farid Muhamad Said

Keyword(s):

Engine Speed ◽

Simulation Analysis ◽

Engine Performance ◽

Simulation Software ◽

Spark Ignition Engine ◽

Intake Manifold ◽

Engine Simulation ◽

Engine Model ◽

Air Intake ◽

Manifold System

Intake manifold system is one of the important component in the engine system which functions to evenly distribute the air flows into every cylinder of the engine. With the restricted air intake rule regulation, the intake air system for a car must be properly design in order to minimize the performance dropped caused by the restrictor. The paper presents the study on the effects of intake design parameter towards the performance of the engine and then improves the performance of previous intake manifold system. This study starts with the development of Honda CBR 600RR engine model and intake manifold system model using GT-Power engine simulation software to be used for the simulation purposes. After developing the reference engine model, the parametric study was carried out to study the effect of the intake manifold parameter design on the engine performance. The optimization process was then performed to achieve the target of improvement which has already been set prior to performing the optimization. The final results show an increase up to 4.83% and 4.45% of torque and air flow rate respectively at the desired operating range of engine speed.

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Diesel Engine NOx Reduction Using Charge Air Water Injection

ASME 2005 Internal Combustion Engine Division Fall Technical Conference (ICEF2005) ◽

10.1115/icef2005-1235 ◽

2005 ◽

Cited By ~ 4

Author(s):

Ernst Radloff ◽

Charles Gautier

Keyword(s):

Fuel Consumption ◽

Nox Reduction ◽

Water Injection ◽

Fuel Oil ◽

Emissions Reduction ◽

Nox Emissions ◽

Test Results ◽

Marine Diesel ◽

Marine Vessels ◽

The Impact

The Transportation Development Centre of Transport Canada, in collaboration with Environment Canada’s Emissions Research and Measurement Division, conducted a series of emissions tests onboard the Oceanex RoRo vessel MV Cabot operating between Montre´al, Quebec, and St. John’s, Newfoundland. The primary objectives were to verify emissions inventories and demonstrate the feasibility of installing affordable emissions reduction technology on marine vessels as well as compliance with future regulatory emissions limits. The tests also provided an opportunity for Canada to share information on emissions program and technology developments with U.S. regulatory authorities. This may lead to developing joint emissions reduction initiatives for existing marine vessels. This paper describes the field-testing of a water injection system (WIS) to reduce oxides of nitrogen (NOx) emissions from ocean-going vessels. Tests were conducted on a semi-dedicated basis during voyage and under steady-state conditions. The emissions measurements were taken in accordance with ISO 8178-4-E3 protocol and using both marine diesel oil and intermediate fuel oil, which enabled the evaluation of the impact of different fuel type and quality on emissions. An initial series of tests was carried out on the MV Cabot in March 2004, followed by a second series of tests on the same vessel in March 2005. These tests demonstrated the effectiveness of a low-cost WIS for reducing NOx emissions in marine diesel engines. They also showed that water injection reduces NOx at the expense of an increase in both particulate matter and carbon monoxide when using intermediate fuel oil. NOx reductions varied between 10 and 35 percent, and were most effective at high water injection ratios above 50 percent engine load. The test results showed no negative impact of the WIS on fuel consumption or engine operation and performance. This paper compares the results obtained from the consecutive series of tests in terms of the effectiveness of NOx reduction, and analyses the results in the context of other full-scale test results obtained from emissions control system vendors and engine suppliers. It also investigates the theoretical process and technology of water injection through charge air fumigation, and both direct water and fuel/water emulsion injection. In addition, the effects of water injection on engine emissions, operation and maintenance, and the optimization of water injection from a knowledge-based perspective are discussed. Further testing and development of the WIS are required to realize optimal emissions reduction potential and to determine the impact of water injection on fuel consumption, and engine operational performance as well as the impact of fuel quality on emissions.

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