Your search keyword '"Ignition timing"' showing total 765 results

1. Effect of ignition timing on the combustion characteristics of liquid ammonia spray in a lean premixed H2/Air

Author

Ge, Ruihan, Yin, Geyuan, Hu, Erjiang, Shen, Shujie, Zhan, Haochen, Tang, Chenglong, and Huang, Zuohua

Published

2025

2. Exploration of Engine Parameters for Emission Reduction in Gasoline-Ethanol Fueled Engines.

Author

Purwanto, Wawan, Maksum, Hasan, Arif, Ahmad, Rochman, Muhammad Latifur, Sujito, and Padrigalan, Kathleen Ebora

Subjects

SPARK ignition engines, SPARK plugs, TAGUCHI methods, ORTHOGONAL arrays, FOSSIL fuels

Abstract

The main objective of this study is to develop spark ignition engine parameters that allow complete combustion while reducing dependence on fossil fuels. To achieve this goal, optimization of compression ratio, gasoline-ethanol mixture, ignition timing, and spark plug type was used. In addition, this study used water injection that continuously injects water before the intake manifold. In this study, the Taguchi method with the L9 orthogonal array was applied. According to the experimental verification results, the best combination to reduce exhaust emission levels is to utilize gasoline-ethanol (E70), a compression ratio (CR) of 15.6:1, an ignition degree of +4°, and a platinum spark plug. Meanwhile, the presence of water injection at 1.45 ml/s helps reduce vehicle exhaust pollutants. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of Ignition Timing and Combustion Duration on the Performance Characteristics of a Diesel Engine Using Vibe 2-Zone Model.

Author

Thong Duc Hong, Hieu Xuan Vo, Truyen Hung Luong, Minh Quang Pham, and Son Hoang Do

Subjects

DIESEL motor combustion, ENERGY consumption, SIMULATION software, POLLUTION, COMBUSTION

Abstract

Copyright of FME Transactions is the property of University of Belgrade, Faculty of Mechanical Engineering and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

4. Exploration of Engine Parameters for Emission Reduction in Gasoline-Ethanol Fueled Engines

Author

Wawan Purwanto, Hasan Maksum, Ahmad Arif, Muji Setiyo, Sujito Sujito, and Kathleen Ebora Padrigalan

Subjects

Engine emissions, Gasoline-ethanol blended, Ignition timing, Engine parameter, Water injection, Mechanical engineering and machinery, TJ1-1570, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

The main objective of this study is to develop spark ignition engine parameters that allow complete combustion while reducing dependence on fossil fuels. To achieve this goal, optimization of compression ratio, gasoline-ethanol mixture, ignition timing, and spark plug type was used. In addition, this study used water injection that continuously injects water before the intake manifold. In this study, the Taguchi method with the L9 orthogonal array was applied. According to the experimental verification results, the best combination to reduce exhaust emission levels is to utilize gasoline-ethanol (E70), a compression ratio (CR) of 15.6:1, an ignition degree of +4°, and a platinum spark plug. Meanwhile, the presence of water injection at 1.45 ml/s helps reduce vehicle exhaust pollutants.

Published

2024

5. Simulation Study on Combustion Performance of Ammonia-Hydrogen Fuel Engines.

Author

Zhao, Duanzheng, Gao, Wenzhi, Li, Yuhuai, Fu, Zhen, Hua, Xinyu, and Zhang, Yuxuan

Subjects

*HYDROGEN as fuel, *ALTERNATIVE fuels, *ENGINES, *THERMAL efficiency

Abstract

Ammonia is a very promising alternative fuel for internal combustion engines, but there are some disadvantages, such as difficulty in ignition and slow combustion rate when ammonia is used alone. Aiming to address the problem of ammonia combustion difficulty, measures are proposed to improve ammonia combustion by blending hydrogen. A one-dimensional turbocharged ammonia-hydrogen engine simulation model was established, and the combustion model was corrected and verified. Using the verified one-dimensional model, the effects of different ratios of hydrogen to ammonia, different rotational speeds and loads on the combustion performance are investigated. The results show that the ignition delay and combustion duration is shortened with the increase of the hydrogen blending ratio. The appropriate amount of hydrogen blending can improve the brake's thermal efficiency. With the increase in engine speed, increasing the proportion of hydrogen blending is necessary to ensure reliable ignition. In conclusion, the ammonia-hydrogen fuel engine has good combustion performance, but it is necessary to choose the appropriate hydrogen blending ratio according to the engine's operating conditions and requirements. [ABSTRACT FROM AUTHOR]

Published

2024

6. Effect of ignition timing and combustion duration on the performance characteristics of a diesel engine using vibe 2-zone model

Author

Hong Duc Thong, Xuan Hieu Vo, Hung Truyen Luong, Quang Minh Pham, and Hoang Son Do

Subjects

ignition timing, combustion duration, diesel engine, performance characteristics, avl boost, vibe 2-zone, Engineering (General). Civil engineering (General), TA1-2040, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

Efficient energy exploitation is a necessary issue because it helps reduce fuel consumption and environmental pollution. Finding the optimal ignition timing (IT) for diesel engines to create high power and efficiency deserves attention. This study utilizes AVL BOOST simulation software with the Vibe 2-Zone combustion model to investigate the effect of IT and combustion duration on engine characteristics such as power, torque, and brake-specific fuel consumption (BSFC) at different engine loads and speeds. Then, the prediction models of the optimal ITs versus combustion durations for maximum power and minimum BSPFC were computed. The results show that ITs strongly affect engine performance characteristics. The optimal ITs that the engine produces maximum power at different combustion durations are unaffected by engine load. In contrast, they are considerably influenced by engine load when considering the engine-generated BSFC. The correlations of optimal IT versus combustion duration are linear functions. The prediction models can be utilized to predict the optimal ignition timings of the engine since the experimental time can be reduced when applied to the actual engine.

Published

2024

7. Impact of Bioethanol Concentration in Gasoline on SI Engine Sustainability.

Author

Rimkus, Alfredas, Pukalskas, Saugirdas, Mejeras, Gabrielius, and Nagurnas, Saulius

Abstract

This study presents an experimental investigation into the impact of blending bioethanol (E100) with conventional gasoline (E0), incrementally increasing biofuel levels up to E10, E50, and E70. The test was carried out in two stages: Stage I assessed the engine's performance under fixed speeds (n = 2000 rpm and n = 2500 rpm) and fixed throttle positions (15%, 20%, and 25%) to measure changes in engine torque, efficiency, and environmental metrics by varying the concentration of bioethanol in the fuel. Stage II aimed to enrich the initial findings by conducting an additional test, running the engine at a fixed speed (n = 2000 rpm) and braking torque (MB = 80 Nm) and varying the ignition timing. Results indicated slight improvements in engine brake torque and thermal efficiency (up to 1.7%) with bioethanol content increased to 70%, and a notable reduction in incomplete combustion byproducts—carbon monoxide and hydrocarbons emissions (up 15% and 43%). Nitrogen oxide emissions were reduced by up to 23%, but carbon dioxide emissions decreased by a mere 1.1%. In order to increase thermal efficiency by adding higher bioethanol blend concentrations, adjusting the ignition timing to counter the longer ignition delay is necessary; however, higher emissions of nitrogen oxides and hydrocarbons are a major drawback of such a strategy. The results of the research are important in determining the optimal concentration of bioethanol in the mixture with gasoline for the energy and environmental sustainability of a spark ignition engine. [ABSTRACT FROM AUTHOR]

Published

2024

8. Exploring the influence of the Keetch–Byram Drought Index and McArthur's Drought Factor on wildfire incidence in Victoria, Australia.

Author

Plucinski, M. P., Tartaglia, E., Huston, C., Stephenson, A. G., Dunstall, S., McCarthy, N. F., and Deutsch, S.

Subjects

WILDFIRES, DROUGHTS, WILDFIRE prevention, FIRE management, DATA recorders & recording

Abstract

Background: Wildfires are thought to become more prevalent during periods of extended dry weather. This issue is examined using two dryness metrics commonly applied in Australian fire management agencies. Aims: This paper investigated links between wildfire incidence and the Keetch–Byram Drought Index (KBDI) and McArthur's Drought Factor (DF) across the state of Victoria, Australia. Methods: Weather records and data from 41 418 wildfires that occurred across the State over a 17-year period were compiled to examine the distributions of KBDI and DF on days with fires smaller and larger than 5 ha in area and all days, using kernel density plots. Key results: Days with fires, particularly days with fires that escaped initial attack, have higher DFs and KBDIs compared with all days. These differences vary between regions and are greatest in areas with moist climates. Conclusions and implications: An appreciation of dryness conditions using tools such as KBDI and DF is useful for understanding fire potential, particularly in areas that experience higher and more regular rainfall. McArthur's Drought Factor and the Keetch–Byram Drought Index are higher than normal on days with fires in Victoria, Australia. These metrics provide a more reliable indication of fire potential in high-rainfall areas than in lower-rainfall areas. This article belongs to the Collection Fire and Climate. [ABSTRACT FROM AUTHOR]

Published

2024

9. Knock combustion characteristics of an opposed‐piston two‐stroke gasoline engine

Author

Fukang Ma, Jianwei Zhang, and Fang Wang

Subjects

compression ratio, ignition timing, knock, opposed piston, two‐stroke gasoline engine, Technology, Science

Abstract

Abstract The spark plug of an opposed‐piston two‐stroke (OP2S) gasoline engine is arranged on the side wall of the cylinder liner, far from the center of the combustion chamber; the ignition core of the mixture is offset, the flame propagation distance is increased, the combustion duration is prolonged, and the knock tendency is severe. In this paper, a quasi‐dimensional two‐zone combustion model is used in GT‐Power software to establish a thermodynamic process simulation model and a knock prediction model is included to analyze the effect and matching of the compression ratio, ignition timing, and other thermodynamic process parameters on the knock intensity and engine performance. The extended coherent flame model combustion model is coupled with the Huh–Gosman spray model in AVL‐Fire software, and the An B knock model is used to establish an in‐cylinder combustion model and analyze the flame propagation and the knock response rate of the flat and pit piston during the combustion process. With an increase of the compression ratio, the temperature and pressure of the mixture in the combustion chamber increase at the time of ignition, which leads to the knocking combustion in the cylinder. With an increase of the ignition advance angle, the in‐cylinder pressure and temperature increase rapidly, which increases the likelihood of knocking combustion. In comparison with the pit piston combustion chamber, the flame propagation speed of the flat piston combustion chamber is relatively slow, which increases the knock tendency. The results show that lowering the compression ratio and delaying the ignition can reduce the in‐cylinder knock tendency by setting a compression ratio of 10.5 and an ignition advance angle of 20°CA. When the pit piston is used to organize the squish and inverse squish before and after the inner dead center, the flame propagation process can be promoted. The knock response rate of pit piston is 24.7% lower than that of flat top piston.

Published

2022

10. APLIKASI GAS HHO PADA SEPEDA MOTOR INJEKSI DENGAN MODIFIKASI ECU AFTERMARKET (TIMING PENGAPIAN)

Author

Indah Puspitasari, Noorsakti Wahyudi, Kuntang Winangun, and Fadil Noor Rofiq

Subjects

hho gas, engine performance, ignition timing, dynotest measuring instrument, Mechanical engineering and machinery, TJ1-1570

Abstract

HHO gas is a gas produced from electrolysis, which is the decomposition of an electrolyte using an electric current which produces Hydrogen Gas and Oxygen Gas / Hydrogen Hydrogen Oxygen. The purpose of this study was to determine the application of HHO gas by increasing ignition timing by 3º, 6º, and 9º using an aftermarket ECU on engine performance and injection motor emissions. The method used in this study is an experiment, testing using a dinotest measuring instrument and a gas analyzer. The results obtained are the highest average power value in all tests obtained on the variable use of HHO Gas without variations in ignition timing using an aftermarket ECU of 5.90 HP at 3500 Rpm engine speed, an increase of 0.13% from the conditions of HHO Gas usage and forward time. . ignition of 3º and 6º, an increase of 0.27% from HHO gas usage conditions and a forward ignition time of 9º. Then the highest average torque value from all tests was obtained on the variable using HHO Gas and variations in ignition timing using an aftermarket ECU with an advance of 3º of 14.39 Nm at 3000 rpm engine speed, an increase of 0.29% from conditions using HHO Gas without using Variation ignition timing using aftermarket ECU.

Published

2022

11. Experimental study on the factors influencing performance and emissions of hydrogen internal combustion engines

Author

Wu Taoyang, Liu Jixu, Wu Chunling, Jing Xiaojun, Liu Jiajia, Pang Guomin, Guo Xiangyang, and Guo Yachen

Subjects

hydrogen internal combustion engines, ignition timing, excess air coefficient, near zero emissions of nox, brake thermal efficiency, Environmental sciences, GE1-350

Abstract

Hydrogen internal combustion engines (H2-ICEs) have advantages such as clean combustion and zero carbon emissions, and have become one of the important technical routes for decarbonization in the internal combustion engine industry. In this paper, several key factors affecting the performance and emissions of hydrogen internal combustion engines, such as ignition timing, excess air coefficient, and hydrogen injection timing, were systematically studied on a spark ignition multi-point injection (MPI) hydrogen internal combustion engine bench. The experimental results indicate that the ignition timing controls the combustion phase of hydrogen. Moderate early ignition can improve the brake thermal efficiency (BTE) while having little impact on the NOX emissions. Excess air coefficient(λ) can significantly affect the performance and emissions of H2-ICE. Along with the increase of the λ, the NOX emissions first increases and then continues to decline. When the λ reaching 2.1 or above, near zero emissions of NOX can be achieved. The advance of hydrogen injection timing will slightly increase the peak of cylinder pressure and instantaneous heat release rate. However, overall, the impact of hydrogen injection timing on BTE and NOX emissions is not significant on MPI H2-ICE.

Published

2024

12. Characteristics of SI engine fueled with BE50-Isooctane blends with different ignition timings

Author

Suyatno, Helen Riupassa, Susi Marianingsih, and Hendry Y. Nanlohy

Subjects

Bioethanol, Isooctane, Molecular properties, Ignition timing, Engine characteristic, Spark ignition, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

The effect of various ignition timing on spark ignition (SI) engines with bioethanol-isooctane mixtures has been widely studied. In the present studies, we used three different ignition angle positions, namely 9°, 12°, and 15° BTDC to increase the combustion pressure in the combustion chamber. In addition to macroscopic observations through engine performance, observations are also carried out from a molecular perspective, i.e.; atomic, bond, and bond angle properties of bioethanol-isooctane fuel. The result shows that more atoms of the isooctane carbon chain are non-rotatable (23 atomic bonds) than the 8 bonds of the bioethanol carbon chain. Furthermore, isooctane also has a wider bond angle (around 121.1745°) than the bond angle of ethanol (around 110.0476°). The unique properties of the atoms in the carbon chains of these two fuels have a direct impact on engine performance. The results show that the viscosity of bioethanol is lower when compared to isooctane, which indicates that the bioethanol molecules are more reactive and flammable. The result also found that at an ignition angle of 12° the BE50 engine has the best performance. Moreover, the test results also show that bioethanol produces clean combustion as evidenced by the lowest CO and HC gas emissions.

Published

2023

13. Optimization of Performance and Emission Characteristics of the CI Engine Fueled with Preheated Palm Oil in Blends with Diesel Fuel.

Author

Mohamed, Iqbal Shajahan, Venkatesan, Elumalai Perumal, Parthasarathy, Murugesan, Medapati, Sreenivasa Reddy, Abbas, Mohamed, Cuce, Erdem, and Shaik, Saboor

Abstract

In this analytical investigation, preheated palm oil was used in the direct injection diesel engine with various optimization methods. The main purpose of the optimization was to get better results than the conventional engine. Raw palm oil was heated using the heat exchange process to reduce the density and viscosity. The relationship between the output process and factors response was evaluated in the design of experiment methods. The Taguchi method is an important method for optimization of the output response performance and emission characteristics of a diesel engine. Two important factors—output and input—were calculated. The input factors considered were preheated palm biodiesel blend, torque, injection pressure, compression ratio, and injection timing. The output factors calculated were smoke opacity, carbon monoxide emission, and brake-specific fuel consumption by using the signal-to-noise (S/N) ratio and analysis of variance. Carbon monoxide was most impacted by torque conditions through injection timing and injecting pressure, and opacity of smoke emission. Among them, injection timing had a higher impact. Different biodiesel blends were prepared: B10 (90% diesel + 10% oil), B20 (80% diesel + 20% oil), B30 (70% diesel + 30% oil) and B40 (60% diesel + 40% oil). Silver nanoparticles (50 ppm) were constantly mixed with the various biodiesel blends. The smoke opacity emission for the biodiesel blend B30 + 50 ppm silver nanoparticle showed the lowest S/N ratio and achieved better optimum results compared with the other blends. The blend B30 + 50 ppm silver nanoparticle showed the lowest S/N ratio value of 9.7 compared with the other blends. The smoke opacity, carbon monoxide emission, and brake-specific fuel consumption of all the response optimal factors were found to be 46.77 ppm, 0.32%, and 0.288 kg/kW·h, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

14. Knock combustion characteristics of an opposed‐piston two‐stroke gasoline engine.

Author

Ma, Fukang, Zhang, Jianwei, and Wang, Fang

Subjects

TWO-stroke cycle engines, SPARK ignition engines, COMBUSTION chambers, COMBUSTION, FLAME, SPARK plugs, KNOCK in automobile engines

Abstract

The spark plug of an opposed‐piston two‐stroke (OP2S) gasoline engine is arranged on the side wall of the cylinder liner, far from the center of the combustion chamber; the ignition core of the mixture is offset, the flame propagation distance is increased, the combustion duration is prolonged, and the knock tendency is severe. In this paper, a quasi‐dimensional two‐zone combustion model is used in GT‐Power software to establish a thermodynamic process simulation model and a knock prediction model is included to analyze the effect and matching of the compression ratio, ignition timing, and other thermodynamic process parameters on the knock intensity and engine performance. The extended coherent flame model combustion model is coupled with the Huh–Gosman spray model in AVL‐Fire software, and the An B knock model is used to establish an in‐cylinder combustion model and analyze the flame propagation and the knock response rate of the flat and pit piston during the combustion process. With an increase of the compression ratio, the temperature and pressure of the mixture in the combustion chamber increase at the time of ignition, which leads to the knocking combustion in the cylinder. With an increase of the ignition advance angle, the in‐cylinder pressure and temperature increase rapidly, which increases the likelihood of knocking combustion. In comparison with the pit piston combustion chamber, the flame propagation speed of the flat piston combustion chamber is relatively slow, which increases the knock tendency. The results show that lowering the compression ratio and delaying the ignition can reduce the in‐cylinder knock tendency by setting a compression ratio of 10.5 and an ignition advance angle of 20°CA. When the pit piston is used to organize the squish and inverse squish before and after the inner dead center, the flame propagation process can be promoted. The knock response rate of pit piston is 24.7% lower than that of flat top piston. [ABSTRACT FROM AUTHOR]

Published

2022

15. Control methods for variations in natural gas composition in air–fuel controlled natural gas engines

Author

Cheolwoong Park, Sechul Oh, Changgi Kim, and Young Choi

Subjects

Natural gas, Fuel composition, Internal combustion engine, Ignition timing, Countermeasures, Torque compensation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In the present study, the countermeasures are proposed to minimize the problem on torque and power output performance and exhaust gas emissions of natural gas engine with use of lower calorific gas. An experiment was conducted to identify thermal efficiency and harmful exhaust gas emission characteristics under partial load conditions in order to improve efficient fuel use in engines affected by the introduction of low calorific gases. A countermeasure for coping with emission gas regulations and preventing thermal efficiency deterioration under rated power operating conditions was then presented. An 11 L six-cylinder turbo-charged engine for city buses compliant with the EURO 6 regulation was used in the experiment, and the results obtained using the reference natural gas fuel were compared with those obtained using simulated low calorific gases. Pure methane (CH 4) was also used to investigate the effects of gas composition changes on thermal efficiency and exhaust gas emissions.When N2is added or pure CH 4 is used under partial load operating conditions, the combustion rate decreases; consequently, the optimum ignition timing is additionally advanced relative to that obtained when the reference natural gas fuel is used. If the N2mixing ratio is increased to a minimum of 4.7% under rated power operating conditions, combustion becomes unstable. Stable operation can be secured by increasing the set base fuel amount, 2.35% and 9.41% for pure CH 4 and 8% N2, respectively; however, torque decreases in proportion to the combustion speed of the gas fuel. The strategy of boost pressure control for the torque compensation can minimize the decrease in thermal efficiency.

Published

2021

16. Performance and emission study of low HCNG fuel blend in SI engine with fixed ignition timing

Author

Vivek Pandey, Suresh Guluwadi, and Gezahegn Habtamu Tafesse

Subjects

alternative fuels, hcng, emissions, hydrocarbons, nitrogen oxides, ignition timing, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Natural gas (NG) has many advantages of clean fuels and can replace gasoline in spark ignition (SI) engines. However, it comes with disadvantages such as low energy density. Hydrogen blended NG can improve the fuel characteristics. Ignition timing also plays an important role in engine performance, especially at lean limits. Experiments were conducted for performance and emissions with hydrogen-compressed natural gas (HCNG) blends in a spark ignition (SI) engine with fixed ignition timing. HCNG blends with 0–15% hydrogen were tested with maximum brake torque (MBT) spark timing 30° before top dead center (BTDC) ignition. Significant reduction of carbon monoxide (CO), carbon dioxide (CO2) and hydrocarbons (HC) along with improved break thermal efficiency was observed with higher hydrogen fraction. There was no significant benefit in indicated thermal efficiency or NOx reduction by using MBT ignition. Hence, the expensive retrofitting of using variable spark timing apparatus can be avoided for on-road vehicles.

Published

2022

17. Multi-objective optimization analysis of hydrogen internal combustion engine performance based on game theory.

Author

Yang, Zhenzhong, Guo, Ping, Wang, Lijun, and Hao, Qingyang

Subjects

*PARTICLE swarm optimization, *NASH equilibrium, *UTILITY functions, *GAME theory, *INTERNAL combustion engines, INTERNAL combustion engine exhaust gas

Abstract

An innovative analytical approach combining game theory and particle swarm algorithms is used for the performance optimisation problem of hydrogen engines.An innovative analysis method combining game theory and particle swarm optimization algorithm was adopted to optimize the performance of hydrogen engines. Firstly, the power performance, fuel economy and emission of hydrogen internal combustion engines are studied in detail, and a three-way game model is constructed with the three as the main players, with strategic attribution for ignition timing, hydrogen injection timing and compression ratio.The simulation process of the model is then transformed into numerical optimisation by integrating the game utility function. Finally, the particle swarm algorithm is used to determine the initial set of strategies to obtain the Nash equilibrium solution.The results of the study showed that the optimized hydrogen internal combustion engine improved its power performance by 3.6%; economic efficiency increased by 5.7%; and emissions were reduced by 2% compared to the original engine. • Transforming the optimisation problem of the H2-ICE into a game theoretic problem. • A multi-objective optimization strategy based on game theory is proposed. • Determine the initial set of strategies and find the Nash equilibrium solution using particle swarm algorithm. • The operating parameters of the H2-ICE at variable compression ratios were optimally designed. [ABSTRACT FROM AUTHOR]

Published

2024

18. The Effect of Ignition Timing on the Emission and Combustion Characteristics for a Hydrogen-Fuelled ORP Engine at Lean-Burn Conditions.

Author

Huang, Junfeng, Gao, Jianbing, Yang, Ce, Tian, Guohong, and Ma, Chaochen

Subjects

EXHAUST gas recirculation, COMBUSTION chambers, COMBUSTION, FLAME, HEAT release rates, THERMAL efficiency, HYDROGEN as fuel, DIESEL motor combustion

Abstract

The application of hydrogen fuel in ORP engines makes the engine power density much higher than that of a reciprocating engine. This paper investigated the impacts of combustion characteristics, energy loss, and NOx emissions of a hydrogen-fuelled ORP engine by ignition timing over various equivalence ratios using a simulation approach based on FLUENT code without considering experiments. The simulations were conducted under the equivalence ratio of 0.5~0.9 and ignition timing of −20.8~8.3° CA before top dead centre (TDC). The engine was operated under 1000 RPM and wide-open throttle condition which was around the maximum engine torque. The results indicated that significant early ignition of the ORP engine restrained the flame development in combustion chambers due to the special relative positions of ignition systems to combustion chambers. In-cylinder pressure evolutions were insensitive to early ignition. The start of combustion was the earliest over the ignition timing of −17.3° CA for individual equivalence ratios; the correlations of the combustion durations and equivalence ratios were dependent on the ignition timing. Combustion durations were less sensitive to equivalence ratios in the ignition timing range of −14.2~−11.1° CA before TDC. The minimum and maximum heat release rates were 15 J·(°CA)−1 and 22 J·(°CA)−1 over the equivalence ratios of 0.5 and 0.9, respectively. Indicated thermal efficiency was higher than 41% for early ignition scenarios, and it was significantly affected by late ignition. Energy loss by cylinder walls and exhaust was in the range of 10~16% and 42~58% of the total fuel energy, respectively. The impacts of equivalence ratios on NOx emission factors were affected by ignition timing. [ABSTRACT FROM AUTHOR]

Published

2022

19. Model Investigation of Natural Gas Engine Performance to Achieve Variable Heat/Electricity Ratios for a CCHP System by Varying Spark Ignition Timings.

Author

Wei, Yanju, Du, Ruiheng, Zhang, Yajie, Jamil, Huzaifa, Zhu, Zengqiang, and Liu, Shenghua

Subjects

INTERNAL combustion engines, SPARK ignition engine ignition, SPARK ignition engines, NATURAL gas, HEAT recovery, DISTRIBUTED power generation

Abstract

For electric reliability and to save energy, the distributed power generation combining cooling and heating supply called a CCHP system for architectures has many potential advantages and is widely adopted to provide electric power and to satisfy local heating and cooling loads by waste heat recovery with low carbon intensity. However, the current CCHP system usually has a fixed ratio of the power and heat due to the features of its power unit, which leads to difficulties in the load management. In this paper, based on the operation of an internal combustion engine fueled with natural gas, a novel method is proposed and studied to achieve a controllable rate of heat/power to meet different load requirements of the electricity and heat (cooling or heating loads). By varying the ignition timing of the spark ignition engine, the combustion process within the cylinder can be adjusted to occur at different crank angles so that the engine crank shaft output power (related to the generated electricity) and the heat from the exhaust gas are changed accordingly. To study the effects of ignition timing on engine power and exhaust heat energy, a two-zone model was established with a predictive combustion model. The changes in the combustion process, output power, exhaust gas temperature, and heat energy were mostly our concern. The results show that the heat/electricity ratio can be adjusted from normally 1.0 to 1.6, and they can be controlled independently under partial load operating conditions. To solve the potential thermal failure of the turbine, the extraordinarily high exhaust temperature will be adjusted by compressed air. [ABSTRACT FROM AUTHOR]

Published

2022

20. Engine performance and combustion characteristics of a direct injection compression ignition engine fueled waste cooking oil synthetic diesel

Author

Thanh Viet Nguyen, Khanh Duc Nguyen, Nang Xuan Ho, and Vinh Duy Nguyen

Subjects

Feedstock, Waste cooking oil, Engine characteristics, Exhaust missions, Ignition timing, Fuel consumption, Mining engineering. Metallurgy, TN1-997

Abstract

Abstract Biodiesels produced from various feedstocks have been considered as alternative fuels used in internal combustion engines without major modifications. This research focuses on producing biodiesel from waste cooking oil (WCOSD) by the catalytic cracking method using MgO as the catalyst and comparing the engine operating characteristics of the test engine when using WCOSD and traditional diesel (CD) as test fuels. As a result, the brake power of the test engine fueled WCOSD, and traditional diesel is similar. However, the engine fuel consumption in the case of using WCOSD is slight increases in some operating conditions. Also, the nitrogen oxides emissions of the test engine fueled WCOSD are higher than those of CD at all tested conditions. The trend is opposite for hydrocarbon emission as the HC emission of the engine fueled by WCOSD reduces 26.3% on average. The smoke emission of the test engine in case of using WCOSD is lower 17% on average than that of CD. However, the carbon monoxide emissions are lower at the low and medium loads and higher at the full loads. These results show that the new biodiesel has the same characteristics as those of commercial biodiesel and can be used as fuel for diesel engines.

Published

2020

21. Performance and emission study of low HCNG fuel blend in SI engine with fixed ignition timing.

Author

Pandey, Vivek, Guluwadi, Suresh, and Tafesse, Gezahegn Habtamu

Subjects

SPARK ignition engines, NATURAL gas, THERMAL efficiency, CARBON monoxide, CARBON dioxide, ENERGY density, DIESEL fuels, HYDROGEN as fuel

Abstract

Natural gas (NG) has many advantages of clean fuels and can replace gasoline in spark ignition (SI) engines. However, it comes with disadvantages such as low energy density. Hydrogen blended NG can improve the fuel characteristics. Ignition timing also plays an important role in engine performance, especially at lean limits. Experiments were conducted for performance and emissions with hydrogen-compressed natural gas (HCNG) blends in a spark ignition (SI) engine with fixed ignition timing. HCNG blends with 0–15% hydrogen were tested with maximum brake torque (MBT) spark timing 30° before top dead center (BTDC) ignition. Significant reduction of carbon monoxide (CO), carbon dioxide (CO2) and hydrocarbons (HC) along with improved break thermal efficiency was observed with higher hydrogen fraction. There was no significant benefit in indicated thermal efficiency or NOx reduction by using MBT ignition. Hence, the expensive retrofitting of using variable spark timing apparatus can be avoided for on-road vehicles. [ABSTRACT FROM AUTHOR]

Published

2022

22. Model Investigation of Natural Gas Engine Performance to Achieve Variable Heat/Electricity Ratios for a CCHP System by Varying Spark Ignition Timings

Author

Yanju Wei, Ruiheng Du, Yajie Zhang, Huzaifa Jamil, Zengqiang Zhu, and Shenghua Liu

Subjects

CCHP, heat/electricity ratio, natural gas engine, ignition timing, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

For electric reliability and to save energy, the distributed power generation combining cooling and heating supply called a CCHP system for architectures has many potential advantages and is widely adopted to provide electric power and to satisfy local heating and cooling loads by waste heat recovery with low carbon intensity. However, the current CCHP system usually has a fixed ratio of the power and heat due to the features of its power unit, which leads to difficulties in the load management. In this paper, based on the operation of an internal combustion engine fueled with natural gas, a novel method is proposed and studied to achieve a controllable rate of heat/power to meet different load requirements of the electricity and heat (cooling or heating loads). By varying the ignition timing of the spark ignition engine, the combustion process within the cylinder can be adjusted to occur at different crank angles so that the engine crank shaft output power (related to the generated electricity) and the heat from the exhaust gas are changed accordingly. To study the effects of ignition timing on engine power and exhaust heat energy, a two-zone model was established with a predictive combustion model. The changes in the combustion process, output power, exhaust gas temperature, and heat energy were mostly our concern. The results show that the heat/electricity ratio can be adjusted from normally 1.0 to 1.6, and they can be controlled independently under partial load operating conditions. To solve the potential thermal failure of the turbine, the extraordinarily high exhaust temperature will be adjusted by compressed air.

Published

2022

23. Analisis Perubahan Output Sensor Terhadap Kerja Aktuator pada Sistem EFI (Electronic Fuel Injection)

Author

Toto Sugiarto, Dwi Sudarno Putra, Wawan Purwanto, and Wagino Wagino

Subjects

sensor and actator efi system, injection time, ignition timing, idle speed control valve, intake camshaft timing, Technology (General), T1-995, Education (General), L7-991

Abstract

Penelitian ini bertujuan untuk: (1) Mendeskripsikan bagaimana sensor-sensor dalam sistem EFI bekerja pada putaran idle, mesin rotasi tingkat menengah dan tinggi, dengan melihat sensor output. (2) Mengetahui pekerjaan aktuator pada Sistem EFI pada putaran idle, mesin rotasi tingkat menengah dan tinggi. Metode eksperimen digunakan untuk penelitian ini. Mesin EFI dengan tipe D EFI yang digunakan telah dianalisis. Alat pindai digunakan untuk mengamati untuk mengukur output yang dihasilkan oleh sensor dan mengukur kerja aktuator sistem EFI menggunakan alat Pindai. Dari percobaan ditemukan bahwa peningkatan putaran mesin akan menghasilkan peningkatan kerja aktuator pada Sistem EFI, yang terdiri dari Injeksi Waktu dan Pengisi Waktu Pengapian, tetapi untuk Idle Speed ​​Control Valve (ISCV) dan Intake Camshaft Timing perubahan relatif stabil.

Published

2018

24. Engine performance and combustion characteristics of a direct injection compression ignition engine fueled waste cooking oil synthetic diesel.

Author

Nguyen, Thanh Viet, Nguyen, Khanh Duc, Ho, Nang Xuan, and Nguyen, Vinh Duy

Subjects

DIESEL motors, WASTE products as fuel, BIODIESEL fuels, DIESEL fuels, SYNTHETIC lubricants, ENERGY consumption, ALTERNATIVE fuels

Abstract

Biodiesels produced from various feedstocks have been considered as alternative fuels used in internal combustion engines without major modifications. This research focuses on producing biodiesel from waste cooking oil (WCOSD) by the catalytic cracking method using MgO as the catalyst and comparing the engine operating characteristics of the test engine when using WCOSD and traditional diesel (CD) as test fuels. As a result, the brake power of the test engine fueled WCOSD, and traditional diesel is similar. However, the engine fuel consumption in the case of using WCOSD is slight increases in some operating conditions. Also, the nitrogen oxides emissions of the test engine fueled WCOSD are higher than those of CD at all tested conditions. The trend is opposite for hydrocarbon emission as the HC emission of the engine fueled by WCOSD reduces 26.3% on average. The smoke emission of the test engine in case of using WCOSD is lower 17% on average than that of CD. However, the carbon monoxide emissions are lower at the low and medium loads and higher at the full loads. These results show that the new biodiesel has the same characteristics as those of commercial biodiesel and can be used as fuel for diesel engines. [ABSTRACT FROM AUTHOR]

Published

2020

25. Torque and Power Characteristics of Single Piston LPG-Fueled Engines on Variations of Ignition Timing

Author

Bagiyo Condro Purnomo and Noto Widodo

Subjects

Single piston engine, LPG, Ignition timing, Torque, Power, Mechanical engineering and machinery, TJ1-1570, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

Liquefied Petroleum Gas (LPG) is an alternative fuel that has all key properties for the Spark Ignition (SI) engine. However, because of its properties, ignition timing on an LPG SI engine needs to be advanced from the reference angle to get the optimum performance. Therefore, this article presents the torque and power characteristics of a single piston LPG engine on variations of ignition timing. Evaluation of engine performance is carried out at the ignition timing of 15O, 17O, and 19O BTDC. The results showed the highest torque for LPG fuel was 10.64 Nm which was achieved at 3500 rpm with ignition timing of 19O BTDC, while the highest power for LPG fuel was 6.9 hp which was achieved at 5936 rpm with ignition timing of 19O BTDC.

Published

2019

26. A Study on the Effect of Ignition Timing on Residual Gas, Effective Release Energy, and Engine Emissions of a V-Twin Engine

Author

Quach-Nhu Yhcmute, Nguyen-Xuan Khoa, and Ocktaeck Lim

Subjects

ignition timing, emissions, effective release energy, residual gas, engine, Technology

Abstract

The ignition timing of an SI engine is a critical parameter. The influence on residual gas, effective release energy, and emissions characteristics of ignition timing for the V-twin engine is investigated in this research. For this purpose, an experiment system was built with a dynamometer, and a model of the simulation was created. In this research, the ignition timing was varied from 10 to 45 degrees BTDC under full load operating conditions, with engine speeds ranging from 3000 to 10,000 rpm. Based on the output data, ignition timing has a major impact on the proportion of residual gas, efficient release energy, performance of the engine, and the emission characteristics. The smallest proportion of residual gas was 0.07% at 8000 rpm and ignition timing of 10 °CA. At 15 °CA of ignition timing, the highest efficient release energy was 0.817 kJ at 4000 rpm, while at 8000 rpm and 25 °CA of ignition timing, it was 0.8305 kJ. At 6000 rpm, the greatest braking torque of the engine was 21.57 Nm, while the minimal BSFC was 343.821 g/kWh. The nitrogen oxide emission and HC emission increase with the advanced ignition timing, but CO emission decreases.

Published

2021

27. Experimental Investigation of Combustion Characteristics on Opposed Piston Two-Stroke Gasoline Direct Injection Engine

Author

Fukang Ma, Wei Yang, Junfeng Xu, Yufeng Li, Zhenfeng Zhao, Zhenyu Zhang, and Yifang Wang

Subjects

opposed piston two stroke gasoline engine, combustion characteristics, phase difference, scavenging pressure, injection timing, ignition timing, Technology

Abstract

The combustion characteristics of an opposed-piston two-stroke gasoline engine are investigated with experiment. The energy conversion and exergy destruction are analyzed and the organization method of the combustion process is summarized. The effects of phase difference, scavenging pressure, injection timing, ignition timing, and dual spark plug ignition scheme on the combustion process and engine performance are discussed, respectively. The heat release rate of the opposed-piston two-stroke gasoline engine is consistent with the conventional gasoline engine. With the increase of opposed-piston motion phase difference, the scavenging efficiency decreases and overmuch residual exhaust gas is not beneficial to the combustion process. Meanwhile, the faster relative velocity of the opposed-piston near the inner dead center enhances the cylinder working volume change rate, which leads to the rapid decline of in-cylinder pressure and temperature. The 15 °CA of opposed-piston motion phase difference improves the scavenging and combustion process effectively. When scavenging pressure is 0.12 MPa, the scavenging efficiency and heat release rate are improved at medium-high speed conditions. With the delay of injection timing, the flame developing period decreases gradually, and the rapid burning period decreases and then increases. The rapid burning period may reach the minimum value when the injection advance angle is 100 °CA. With the delay of ignition timing, the flame developing period increases gradually, and the rapid combustion period decreases and then increases. The rapid combustion period may reach the minimum value when the ignition advance angle is 20 °CA. Notably, the flat-top piston structure should be matched with the dual spark plug, which the ignition advance angle is 20 °CA at medium-high load conditions.

Published

2021

28. CI engine performance and emissions with waste cooking oil biodiesel boosted with hydrogen supplement under different load and engine parameters

Author

Mohamed Y. E. Selim, Emad Elnajjar, S.T.P. Purayil, and S. A. B. Al-Omari

Subjects

Thermal efficiency, Biodiesel, Waste management, Dual engine performance, General Engineering, Four-stroke engine, Hydrogen supplement, Engineering (General). Civil engineering (General), Cylinder (engine), law.invention, Ignition system, Fuel gas, law, Solid and gaseous emissions, Environmental science, Used cooking oil biodiesel, Ignition timing, TA1-2040, NOx

Abstract

This research article deals with the variable parametric study on dual fuel compression ignition engine fueled with waste cooking oil biodiesel with hydrogen supplement at atmospheric condition. The parametric study include variation in engine speed (18–30 rev/sec), gaseous fuel flow rate (0–18.4LPM), pilot fuel flow rate (9.92–15.79Mlpm) and ignition timing (20–45° BTDC). The experiment was conducted on a four stroke, 0.5-liter single cylinder E6 Ricardo engine. From the experimentation, overall parametric variation of 4.15%, 64.7%, 76.61% and 57% in thermal efficiency, CO, N O X and opacity respectively was observed. However, with increase of hydrogen content resulted in increased engine performance, increased in NOx emission and reduction in CO emission with same WCO biodiesel flow rate.

Published

2022

29. Cylinder Deactivation

Author

Schaeffler Technologies GmbH and Schaeffler Technologies GmbH & Co. KG, editor

Published

2014

30. Dynamic performance of engine timing transmission system with RU type synchronous belt

Author

Hu Qingming, Guo Jianhua, Dandan Sun, and Junpeng Hou

Subjects

Crankshaft, Vibration, Physics, Amplitude, law, Acoustics, Camshaft, Angular velocity, Transmission system, Ignition timing, Interference (wave propagation), law.invention

Abstract

The dynamic characteristic of the timing system has a significant impact on the performance of the engine's NVH. With low contact stress and strong anti-interference ability, the arc tooth synchronous belt was adopted by engine timing transmission system. The multi-body dynamics model of the in-line four cylinder engine timing system was established. We explored the influence of crankshaft speed and initial tension on the dynamic performance of the engine timing system. The result shows when the crankshaft speed V= 2000 r/min and the initial tension of the synchronous belt F= 300 N, the load distribution of the RU type synchronous belt teeth root is more uniform. The stress is 0.2474 N/mm2 lower than the average value, and the transverse vibration amplitude decreases by 0.3067 mm. Under this circumstance, the fluctuation amplitude of camshaft angular velocity is 6.5312 rad/s lower than the maximum average amplitude, so the transmission error is reduced by 37.95 %. The fluctuation amplitude of interference value decreases by 0.3413 mm, and the fluctuation amplitude of interference velocity decreases by 263.8908 mm/s. The synchronous belt based engine timing transmission is more stable and the dynamic performance is better. It laid a solid foundation for the optimization of the tooth profile and load conditions of the engine timing system.

Published

2021

31. MATHEMATICAL MODELING OF THE ENGINE PARAMETERS INFLUENCE ON VEHICLE ACCELERATION DYNAMICS

Author

B. S. Chuchumenko and О.О. Osetrov

Subjects

Engine power, Acceleration, Cylinder head, Mathematical model, Control theory, law, Computer science, Compression ratio, Ignition timing, Throttle, Cylinder (engine), law.invention

Abstract

The throttle response of a vehicle determines its dynamic properties and is characterized by an acceleration time from 0 to 100 km/h. An experimental study of the influence of vehicle parameters on its throttle response is associated with significant material and labor costs. At the stage of sketching the design of the vehicle, preliminary determination of design parameters and settings, it is rational to use mathematical models. In the existing models of the vehicles movement dynamics, the engine power, as a rule, is set by empirical dependencies and does not take into account the possibility of changing its parameters and characteristics. The paper proposes a mathematical model that combines models of the engine workflow and the dynamics of vehicle acceleration. The mathematical model of the engine workflow is a quasi-stationary thermodynamic model, in which combustion is described by the Vibe equation, and heat transfer with the walls is described by the Woschni equation. To check its adequacy, an experimental study of the VAZ-2108 engine was carried out to obtain external speed, load and control characteristics. Good agreement between the calculated and experimental data is shown. Vehicle acceleration simulation was carried out according to the method of E.A. Chudakov. The parameters of the VAZ-2108 car and the resistance forces during acceleration from 0 to 100 km / h have been determined. It is shown that the car accelerates from 0 to 100 km / h in 18.3 s, which corresponds to the experimental data and indicates the adequacy of the chosen techniques. The influence of changing the parameters and settings of the engine on the dynamics of vehicle acceleration has been investigated. It is shown that in order to achieve better dynamics of motion, the cylinder diameter and compression ratio must be maximized. The ignition timing, intake valve closing angle and excess air ratio have extremes. The efficiency of using a 16-valve cylinder head instead of an 8-valve one is shown. Based on the results of the studies, it was proposed to apply a set of engine parameters, which made it possible to reduce the acceleration time of the VAZ-2108 from 18.3 s to 13.2 s. Thus, the developed mathematical model makes it possible to quantitatively evaluate the influence of engine parameters on the dynamics of vehicle acceleration, to optimize the parameters and settings of the power plant and the vehicle as a whole.

Published

2021

32. Experimental Research on Controllability and Emissions of Jet-Controlled Compression Ignition Engine

Author

Hua Tian, Jingchen Cui, Tianhao Yang, Yao Fu, Jiangping Tian, and Wuqiang Long

Subjects

jet controlled compression ignition (JCCI), emissions, ignition timing, robust control, Technology

Abstract

Low-temperature combustions (LTCs), such as homogeneous charge compression ignition (HCCI), could achieve high thermal efficiency and low engine emissions by combining the advantages of spark-ignited (SI) engines and compression-ignited (CI) engines. Robust control of the ignition timing, however, still remains a hurdle to practical use. A novel technology of jet-controlled compression ignition (JCCI) was proposed to solve the issue. JCCI combustion phasing was controlled by hot jet formed from pre-chamber spark-ignited combustion. Experiments were done on a modified high-speed marine engine for JCCI characteristics research. The JCCI principle was verified by operating the engine individually in the mode of JCCI and in the mode of no pre-chamber jet under low- and medium-load working conditions. Effects of pre-chamber spark timing and intake charge temperature on JCCI process were tested. It was proven that the combustion phasing of the JCCI engine was closely related to the pre-chamber spark timing. A 20 °C temperature change of intake charge only caused a 2° crank angle change of the start of combustion. Extremely low nitrogen oxides (NOx) emission was achieved by JCCI combustion while keeping high thermal efficiency. The JCCI could be a promising technology for dual-fuel marine engines.

Published

2019

33. Fuzzy Logic Control System for Fuel Mixture Quality in Spark Ignition Engines.(Dept.M)

Author

Saber Abd Rabbo and Hassan A. Soliman

Subjects

Needle valve, business.industry, General Engineering, Fuzzy control system, Fuzzy logic, Automotive engineering, law.invention, Ignition system, law, Spark-ignition engine, Control system, General Earth and Planetary Sciences, Environmental science, Exhaust gas recirculation, Ignition timing, business, General Environmental Science

Abstract

Spark ignition engine performance and exhaust emissions are strongly affected by the fuel/air ratio used. A considerable amount of investigations have been carried out by engine manufacturers to control engine performance and meet exhaust emission standards of governmental agencies by developing control systems for some operating variables such as ignition timing(IT), Fuel Air Ratio(FAR), and Exhaust Gas Recirculation (EGR) This paper presents a fuzzy control system that measures exhaust temperature and operates a needle valve on the engine earburetor jet that enables the fuel to air ratio lo oscillate about a desired value. A group of experiments have been carried out to obtain the relationship between fuel to air ratio or (ɸ), Exhaust temperature and exhaust emissions. A group of fuzzy logic rules which relate exhaust temperature, to the desired speed with the position of a needle valve actuated by a stepping motor are prop osed. A beneficial of fuzzy control method was that the rules determined the characteristics of control system are interpreted by the operator. Experimental and simulated results show that the prop osed fuzzy system improves the fuel/air mixture quality.

Published

2021

34. Measurement of fuel consumption and harmful emissions of cars when using different types of fuel

Author

S. Gutarevyc, I. Manko, J. Ragulskiene, A. Pauliukas, A. Korpach, and Y. Shuba

Subjects

Pollutant, Variator, Waste management, Mechanical Engineering, Materials Science (miscellaneous), measurement of fuel consumption, ignition timing variator, Liquefied petroleum gas, chemistry.chemical_compound, chemistry, harmful emissions, lcsh:Technology (General), Carbon dioxide, Fuel efficiency, lcsh:T1-995, Environmental science, Ignition timing, Gasoline, Instrumentation, liquefied petroleum gas, Carbon monoxide

Abstract

The article presents the results of studies of energy, environmental and fuel efficiency indicators of a passenger car with a gasoline injection system. The engine is equipped with a device additionally supplying liquefied petroleum gas (LPG) and it has an ignition timing variator (ITV). As a result of research, an improvement in the fuel efficiency of a car in thermal equivalent was found when the engine was running on LPG and a slight increase in energy performance was observed. Emissions of pollutants with exhaust gases change in different ways: emissions of carbon monoxide practically do not change, emissions of hydrocarbons and nitrogen oxides are growing, carbon dioxide emissions from LPG operation are reduced, socio-economic damage when the engine is running on LPG is also reduced.

Published

2020

35. Emission Characteristics from Vehicles at Idling Condition.(Dept.M)

Author

A. H. Bawady, A. A. El-Zahaby, S. A. Wilson, A. S. El Dabaa, and A. E. Kabeel

Subjects

Ignition system, law, Range (aeronautics), Combustion products, General Engineering, General Earth and Planetary Sciences, Environmental science, Ignition timing, Spark gap, Automotive engineering, General Environmental Science, Flammability limit, law.invention

Abstract

The present study aims to evaluate the emission characteristics for gasoline-fueled vehicles at idling condition. Factors influencing the formation of emissions at different operating conditions are examined. The study is focused on the ignition parameters as well as the mixture quality which are the most important factors affecting the engine performance and emission. A wide range of spark plug gap(0.3- 1.9) mm and ignition timing (10- 1900 BTDC)were employed in the present study. The mixture quality at idling is varied along the flammability limit to clarify its effect on the combustion products concentration. The measurements were carried out on a specified vehicle. Both the engine speed and combustion products concentration were recorded simultaneously. The results indicate the importance of adjusting the idling condition to optimize the exhaust products.

Published

2020

36. The Optimization of The Relationship between Octane Number of Gasoline-Ethanol Blend Fuels in Various Settings of The Engine Control Module

Author

Fransiskus Adian, CahyoSWibowo, Bambang Sugiarto, and YuliantoSNugroho

Subjects

Ethanol, ignition timing, engine control module, injection duration, Management, Monitoring, Policy and Law, Automotive engineering, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, chemistry, Biofuel, Ceramics and Composites, Octane rating, Environmental science, Ignition timing, Gasoline, Engine control unit, octane number, bioethanol

Abstract

This study present the performance optimization of a spark ignition (SI) engine using gasoline fuels with variations of research octane number (88, 92, and 98) with 40 volume % of bioethanol. The optimization is done by setting the spark ignition time (2° CA advanced) and fuel injection duration (10% reduction) of the engine control module. The engine was tested using an engine dynamometer test to obtain the performance data at the shaft speed of 1000, 1500, 2000, and 2500 RPM and wide-open throttle conditions. From the results of this study, we conclude that optimizing the engine control strategy can lead to the improvement of engine power, torque, and specific fuel consumption which are more significant with the usage of fuels with higher octane number.

Published

2020

37. Research on ethanol and toluene's synergistic effects on auto-ignition and pressure dependences of flame speed for gasoline surrogates

Author

Xingyu Sun, Zhi Wang, Qi Yunliang, Qinhao Fan, and Liu Shang

Subjects

Materials science, 020209 energy, General Chemical Engineering, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, 02 engineering and technology, General Chemistry, Flame speed, Combustion, Toluene, chemistry.chemical_compound, Fuel Technology, 020401 chemical engineering, chemistry, 0202 electrical engineering, electronic engineering, information engineering, Octane rating, Ignition timing, 0204 chemical engineering, Gasoline, Lean burn, Octane

Abstract

Spark-assisted compression ignition (SACI) has a promising potential to substantially improve engine's fuel efficiency. To this end, two exothermic stages in SACI combustion, flame propagation and auto-ignition, need to be well organized to increase control authority of bulk ignition timing especially in lean burn. In this study, three gasoline surrogates, namely EPRF, ETPRF and TPRF, formulated through blending ethanol/toluene with primary reference fuel (PRF) and having the same research octane number (RON) and octane sensitivity (S), were used to conduct experiments in a rapid compression machine (RCM) under lean engine-relevant conditions (10–30 bar and 722–862 K). Under different ethanol blending ratios, both ethanol's synergistic effect during auto-ignition and its stronger pressure dependence of flame speed (S_(Flame)) than toluene were observed. The ethanol's synergistic effect is mainly attributed to its more HO₂ production and then faster consumption by benzyl which results in more OH radical production. As for the stronger pressure dependence of S_(Flame) of ethanol, at 722 K, it is primarily determined by the stronger pressure dependence of H radical in EPRF's flame structure rather than the promotion effect from critical reactions on S_(Flame); while at 862 K, these two factors influence the pressure dependence of S_(Flame) simultaneously. Whatever the temperature is, third-body reactions have larger impacts on ethanol's S_(Flame) than on toluene's. In this study, the relative magnitude of S_(Flame)’s pressure dependence between ethanol and toluene shows rationality at lower φ and higher T, which is in line with the pressure exponents extracted from the existing high-p laminar burning velocities of ethanol and toluene. Further verification was made in a spark-ignition engine, which showed that low-carbon alcohols, exhibited stronger pressure dependence of S_(Flame) than monophenyl aromatics in commercial gasoline, represented by toluene. The aforementioned characteristics of ethanol can be utilized under different engine loads and provide a reference in fuel design for lean SACI combustion.

Published

2020

38. Successive Convexification for Real-Time Six-Degree-of-Freedom Powered Descent Guidance with State-Triggered Constraints

Author

Taylor P. Reynolds, Michael Szmuk, and Behcet Acikmese

Subjects

020301 aerospace & aeronautics, 0209 industrial biotechnology, Computer science, Angle of attack, Applied Mathematics, Aerospace Engineering, 02 engineering and technology, 020901 industrial engineering & automation, 0203 mechanical engineering, Space and Planetary Science, Control and Systems Engineering, Control theory, Ignition timing, State (computer science), Electrical and Electronic Engineering, Descent (aeronautics), Quaternion, Center of pressure (fluid mechanics), Sequential quadratic programming

Abstract

This paper presents a real-time implementable successive convexification algorithm for a generalized free-final-time six-degree-of-freedom powered descent guidance problem. Building on our previous...

Published

2020

39. Aqueous solution of ammonia as marine fuel

Author

Alessandro Schönborn

Subjects

Materials science, Hydrogen, 020209 energy, chemistry.chemical_element, Ocean Engineering, 02 engineering and technology, Combustion, law.invention, chemistry.chemical_compound, Ammonia, Physics::Plasma Physics, law, 0202 electrical engineering, electronic engineering, information engineering, Physics::Chemical Physics, Ammonium nitrite, Astrophysics::Galaxy Astrophysics, Physics::Atmospheric and Oceanic Physics, Aqueous solution, Water transport, Mechanical Engineering, 021001 nanoscience & nanotechnology, Ignition system, chemistry, Chemical engineering, Ignition timing, 0210 nano-technology

Abstract

The ignition of ammonia in aqueous solution was simulated in a two-stroke compression ignition engine model. Zero-dimensional chemical kinetic calculations were used to estimate the ignition timing of fuel air mixtures in homogeneous charge compression ignition and diesel combustion modes. The fuel consisted of a 25% m/m aqueous solution of ammonia and pure ammonia for comparison. Ignition was studied by varying the geometric compression ratio of the engine. To ignite ammonia in aqueous solution a minimum compression ratio of 25 was necessary under homogeneous charge compression ignition combustion conditions, whereas under diesel combustion conditions a minimum compression ratio of 27 was required. Ammonia containing ammonium nitrite or hydrogen were two potential ammonia derivatives that were shown to enhance aqueous ammonia ignition in the simulations, and allowed ignition to take place at a compression ratio of 24 for diesel combustion. When comparing the ignition of aqueous ammonia solution to pure ammonia, the minimum compression ratio necessary to ignite pure ammonia was approximately 24.8 and that for aqueous ammonia 26.7 in diesel combustion. This led to the conclusion that aqueous ammonia is not prohibitively more difficult to ignite than pure ammonia. Ammonia containing ammonium nitrite or hydrogen were found to be potential pilot fuels.

Published

2020

40. Експериментальне дослідження віброакустичним методом клапанного механізму двигуна внутрішнього згоряння

Subjects

lcsh:Military Science, Computer science, lcsh:U, Motor transport, USB, Signal, Automotive engineering, law.invention, Internal combustion engine, law, Calibration, Ignition timing, Oscilloscope, Sensitivity (electronics), віброакустична діагностика, амплітуда, фаза грм, діагностування, клапанний механізм

Abstract

The article indicates the methodology of using vibroacoustic nosting on the example of the gas distribution mechanism (GDM). Until the beginning of 2000 this method was not widely used due to the significant cost diagnostic systems, the complexity of used sensors calibration, the complexity processing and analysis of diagnostic information. Nowadays its’ using is simplified due to the advent of low-cost USB oscilloscopes and high sensitivity real vibration sensors. Moreover, the possibilities for processing diagnostics of statistical data and their presentation have significantly increased. Besides, the car in the field of electronic systems and elements that allow synchronously receiving the necessary diagnostic signal, and then, analyze the received data was significantly improved. Failures of engine timing elements and, in particular, burnout valves, violation of their tightness, phase displacement, the growth of gaps or their absence occur in most vehicles with runs much lower than normal matte or marginal. This is explained by a number of operational factors, such as - untimely maintenance, the use of recommended oils and fuel materials, violation of thermal and load re- bench presses and others. In 30–50% of cases, these factors cause an increase in valve clearances of GDM. In the presented material the studies allowed establish: when tolerance for clearance in the exhaust valve 0.35 ± 0.05 mm set –150–182 mV. The control of gaps in gas distribution mechanism valves revealed 14 deviations of 20 controlled cylinders of the internal combustion engine. Any excess of the amplitude of the signal impulses above 182 mV require adjustment of gaps or replacement of hydraulic pushers. This method and the used set of technological methods allow quickly determine the technical condition of engine systems without disassembly at any intermediate exact conditions of diagnosed objects. This set of diagnostic tools, technological methods and regulatory data allows to recommend their use at modern motor transport enterprises engaged in operation, repair and maintenance of vehicles.

Published

2020

41. Formation of combustion wave in lean propane-air mixture with a non-uniform chemical reactivity initiated by nanosecond streamer discharges in the HCCI engine

Author

George V. Naidis, E. A. Filimonova, Valentin Bityurin, Anastasia S. Dobrovolskaya, and A N Bocharov

Subjects

Materials science, 010304 chemical physics, General Chemical Engineering, Homogeneous charge compression ignition, General Physics and Astronomy, Energy Engineering and Power Technology, 02 engineering and technology, General Chemistry, Mechanics, Combustion, Compression (physics), Kinetic energy, 01 natural sciences, Cylinder (engine), law.invention, Fuel Technology, 020401 chemical engineering, Physics::Plasma Physics, law, 0103 physical sciences, Specific energy, Ignition timing, 0204 chemical engineering, Corona discharge

Abstract

The propagation of combustion wave, which is formed as a result of impact of a filamentary pulsed periodic non-equilibrium discharge on a mixture that is not ignited by only compression in the HCCI engine, has been simulated. The discharge for a short time locally activated the mixture in the engine cylinder at a certain crankshaft rotation angle at the compression stage. The approach to evaluation of the temperature and composition in the region activated by high-frequency corona discharge has been proposed. Multi-pulse and multi-channel nature of discharge was accounted for in our model. The densities of chemically active species produced during streamer propagation were found using two-dimensional axially symmetric fluid model. The obtained composition and temperature in the activated zone were the initial conditions for modeling the propagation of combustion wave along the cylinder radius in 1D approximation. Special terms were included in equations responsible for the compression along the axis of cylinder to mimic the real change in pressure in cylinder. The calculations were performed for a lean C3H8-air mixture, which is characterized by the presence of low-temperature heat release (LTHR) stage, and intermediate and high temperatures heat release (ITHR and HTHR) stages. It was shown that the ignition timing in activated zone depends on the specific energy input into the streamer channel, the radius of activated region coupled with the volume fraction of activated region treated by discharge, and the moment of discharge initiation relative to the top dead center (TDC). The speed of combustion wave, the occurrence of auto-ignition in the end gas and transition to combustion, accompanied by “knocking” or strong pressure fluctuations are largely determined by the moment of discharge initiation and the specific energy input. The significant effect of discharge is explained by the stimulation of oxidation kinetic mechanisms at LTHR and ITHR stages.

Published

2020

42. Engine performance and combustion characteristics of a direct injection compression ignition engine fueled waste cooking oil synthetic diesel

Author

Khanh Duc Nguyen, Vinh Duy Nguyen, Nang Xuan Ho, and Thanh Viet Nguyen

Subjects

020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, Fluid catalytic cracking, Combustion, law.invention, chemistry.chemical_compound, Diesel fuel, 020401 chemical engineering, law, Exhaust missions, Brake, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Ignition timing, Biodiesel, Mining engineering. Metallurgy, Waste management, Engine characteristics, TN1-997, Feedstock, Waste cooking oil, Geotechnical Engineering and Engineering Geology, Ignition system, chemistry, Fuel consumption, Fuel efficiency, Environmental science, Carbon monoxide

Abstract

Biodiesels produced from various feedstocks have been considered as alternative fuels used in internal combustion engines without major modifications. This research focuses on producing biodiesel from waste cooking oil (WCOSD) by the catalytic cracking method using MgO as the catalyst and comparing the engine operating characteristics of the test engine when using WCOSD and traditional diesel (CD) as test fuels. As a result, the brake power of the test engine fueled WCOSD, and traditional diesel is similar. However, the engine fuel consumption in the case of using WCOSD is slight increases in some operating conditions. Also, the nitrogen oxides emissions of the test engine fueled WCOSD are higher than those of CD at all tested conditions. The trend is opposite for hydrocarbon emission as the HC emission of the engine fueled by WCOSD reduces 26.3% on average. The smoke emission of the test engine in case of using WCOSD is lower 17% on average than that of CD. However, the carbon monoxide emissions are lower at the low and medium loads and higher at the full loads. These results show that the new biodiesel has the same characteristics as those of commercial biodiesel and can be used as fuel for diesel engines.

Published

2020

43. Optimization of performance and emission characteristics of the CI engine fueled with preheated palm oil in blends with diesel fuel

Author

Iqbal Shajahan Mohamed, Elumalai Perumal Venkatesan, Murugesan Parthasarathy, Sreenivasa Reddy Medapati, Mohamed Abbas, Erdem Cuce, Saboor Shaik, RTEÜ, Mühendislik ve Mimarlık Fakültesi, Makine Mühendisliği Bölümü, and Cüce, Erdem

Subjects

Diesel engine, Energy, Renewable Energy, Sustainability and the Environment, Performance, Geography, Planning and Development, Building and Construction, Injection pressure, Management, Monitoring, Policy and Law, Internal combustion engine, diesel engine, internal combustion engine, performance, diesel, energy, Taguchi method, compression ratio, ignition timing, injection pressure, Compression ratio, Diesel, Ignition timing

Abstract

In this analytical investigation, preheated palm oil was used in the direct injection diesel engine with various optimization methods. The main purpose of the optimization was to get better results than the conventional engine. Raw palm oil was heated using the heat exchange process to reduce the density and viscosity. The relationship between the output process and factors response was evaluated in the design of experiment methods. The Taguchi method is an important method for optimization of the output response performance and emission characteristics of a diesel engine. Two important factors—output and input—were calculated. The input factors considered were preheated palm biodiesel blend, torque, injection pressure, compression ratio, and injection timing. The output factors calculated were smoke opacity, carbon monoxide emission, and brake-specific fuel consumption by using the signal-to-noise (S/N) ratio and analysis of variance. Carbon monoxide was most impacted by torque conditions through injection timing and injecting pressure, and opacity of smoke emission. Among them, injection timing had a higher impact. Different biodiesel blends were prepared: B10 (90% diesel + 10% oil), B20 (80% diesel + 20% oil), B30 (70% diesel + 30% oil) and B40 (60% diesel + 40% oil). Silver nanoparticles (50 ppm) were constantly mixed with the various biodiesel blends. The smoke opacity emission for the biodiesel blend B30 + 50 ppm silver nanoparticle showed the lowest S/N ratio and achieved better optimum results compared with the other blends. The blend B30 + 50 ppm silver nanoparticle showed the lowest S/N ratio value of 9.7 compared with the other blends. The smoke opacity, carbon monoxide emission, and brake-specific fuel consumption of all the response optimal factors were found to be 46.77 ppm, 0.32%, and 0.288 kg/kW·h, respectively.

Published

2022

44. Effect of Ignition Timing on the Emission of Internal Combustion Engine with Syngas Containing Hydrogen using a Spark Plug Reformer System.

Author

Huang, Dao-Yi, Jang, Jer-Huan, Lin, Po-Han, and Chen, Bo-Han

Abstract

In our previous studies, a plasma reformer system has been developed to produce syngas containing hydrogen to an electronic fuel injection motorcycle engine. In present investigation, the effect of ignition timing of the engine was considered with an improved spark plug reformer system. The spark plug reformer system included two spark plugs, three supersonic atomizers, a controlling device, and a storage tank. In the experiment, the vehicle under testing was a 1988 c.c. 4 cylinder Nissan Sentra with spark timing 16 BTDC (before top deadcenter). The emission test were tested with HAMA LPS 3000 dynamometer and MTG-5. The ignition timing are 12°, 14°, 16°, 18°, and 20° BTDC. Europe Emission standard cycle was run for the emission test. Results show that the emission of HC decreases and both NO x and CO increase with using the spark plug reforming system without changing the spark timing. The best spark timing of the engine was 14° BTDC, especially for the vehicle operated in high speed. In this operating condition, the HC and NO x decreased and CO 2 increased, however, CO also increased. [ABSTRACT FROM AUTHOR]

Published

2016

45. 90. Ignition timing control strategy based on openECU design.

Author

Xianzheng Ling, Changshui Wu, Yangbo Liu, and Sheng Lu

Subjects

*INTERNAL combustion engine ignition, *DIESEL motors, *AUTOMOTIVE fuel consumption, *ELECTRONIC control, *NATURAL gas vehicles

Abstract

Ignition system is the main important part of the engine, and has absolute influence on engine performance. OpenECU for ignition timing strategy on the basis of the design and calibration work, greatly shorten the development difficulty and cycle; machine of a LNG gas ignition timing strategy has carried on the design and optimization, and combining the calculation model for the engine (air intake, compression, power, and exhaust) feedback and verification. It can save a lot of time and resources for experiment if experiments use openECU. It also can monitor the influence of the different inputs conditions on the ignition advance angle. It has realized the map of calibration, greatly shorten the development work and has certain actual application value. [ABSTRACT FROM AUTHOR]

Published

2016

46. Investigation into pressure dependence of flame speed for fuels with low and high octane sensitivity through blending ethanol

Author

Zhi Wang, Yunliang Qi, Yingdi Wang, and Qinhao Fan

Subjects

Materials science, 020209 energy, General Chemical Engineering, Homogeneous charge compression ignition, Flame structure, General Physics and Astronomy, Energy Engineering and Power Technology, Thermodynamics, 02 engineering and technology, General Chemistry, Flame speed, chemistry.chemical_compound, Fuel Technology, 020401 chemical engineering, chemistry, 0202 electrical engineering, electronic engineering, information engineering, Octane rating, Ignition timing, 0204 chemical engineering, Gasoline, Octane, Flammability limit

Abstract

Spark assistance for homogeneous charge compression ignition (HCCI) can control combustion phasing, improve thermal efficiency, and reduce emissions in gasoline engines. As the characteristics of flame propagation determine the control authority of ignition timing, it is important and necessary to investigate pressure dependence of flame speed in the lean-premixed mixture relative to engine operating conditions. Experimental study in an optical rapid compression machine (RCM) and simulation work were carried out using two fuels comprising n-heptane/iso-octane/ethanol with varied octane sensitivity (S). The effective pressure ranged from 10 to 35 bar, temperature from 715 to 860 K, and equivalence ratios between 0.3 and 0.7 to cover the region of lean flammability limits of low and high S fuels with ethanol blended. Based on pressure profiles, flame speed extracted from images, and sensitivity analysis of flame speed, the dependence of flame speed on the effective pressure in low and high S fuels was discovered and the fundamental mechanism behind this phenomena became to be understood in the negative temperature coefficient (NTC) and non-NTC regions, respectively. In the studied temperature conditions, the flame speed of high S fuel has stronger dependence on the pressure than that of low S fuel does. In the NTC region, this phenomenon is attributed to the dependence of H radical concentration on pressure in the unburned mixture and flame structure. In the non-NTC region, promoting effect of dominant reactions varied with pressure can significantly influence pressure dependence of flame speed. Although quite limited data of laminar burning velocity for studied fuels were obtained in high pressures (>15 bar), the trend of flame speed's dependence on pressure was well predicted by two models with different but well-accepted core mechanisms, showing consistent results with the experimental ones in the RCM.

Published

2020

47. Effect of Early and Late Ignition on Combustion and Formation of Emissions in a Natural-Gas Fuelled Spark-Ignited Direct-Injection Engine

Author

Müjdat Firat

Subjects

Natural gas, business.industry, Spark-ignition engine, Spark (mathematics), Environmental science, General Medicine, Ignition timing, Combustion, business, Cylinder pressure, Throttle, Automotive engineering

Abstract

Bu çalışmada doğalgazla çalışan direkt enjeksiyonlu benzinli bir motorda ateşleme zamanının yanma ve emisyonlar üzerine etkileri incelenmiştir. Farklı ateşleme zamanları için motorun 3000 devir şartlarında simülasyonlar gerçekleştirilmiştir. Yanma karakteristikleri ve emisyon oluşumlarını incelemek için üç boyutlu hesaplamalı akışkanlar mekaniği kodu olan ANSYS-Forte 19.0 kullanılmıştır. Tüm simülasyonlar farklı ateşleme zamanları için gaz kelebeğinin tam açık konumunda tekrarlanmıştır. Erken ateşleme zamanlamasında silindir içi basıncın yükseldiği görülürken, HC ve CO emisyonlarında düşüş gözlenmiştir. Ayrıca, erken ateşleme şartlarında düşen HC ve CO emisyonlarına rağmen NOx emisyonlarında artış görülmüştür. Sonuç olarak doğalgazlı motorlarda erken ateşleme zamanında daha yüksek yanma verimi elde edilmiştir.

Published

2020

48. Pengaruh Derajat Pengapian terhadap Kinerja Motor Bakar 6 Langkah Berbahan Bakar Etanol

Author

Misru Razi, Eko Siswanto, and Widya Wijayanti

Subjects

Thermal efficiency, lcsh:Mechanical engineering and machinery, Combustion, Automotive engineering, law.invention, Ignition system, Physics::Plasma Physics, law, Spark-ignition engine, Fuel efficiency, ignition degree, Motor fuel, Environmental science, lcsh:TJ1-1570, 6-stroke engine, ethanol, Thrust specific fuel consumption, Ignition timing, Physics::Chemical Physics, Physics::Atmospheric and Oceanic Physics, performance

Abstract

The six-stroke spark ignition engine has the potential to be developed as a new alternative to future motor fuel technology. The development of motor vehicles will be directly proportional to the use of rising fossil fuels. It is, therefore, necessary to have renewable alternative fuel, in which one of them is using ethanol fuel. Characteristics of the ethanol fuel are different from fossil fuels so the ignition timing is needed to be modified. The purpose of this study was to determine the effect of the ignition degree on the performance of a 6-stroke spark-ignition engine fuel using ethanol. This research is worked out directly by experimental and testing on the intended object. The test was carried out on an ethanol-fueled 6-step spark ignition engine with variations in the ignition angle at 24 0 ,26 0 and 28 0 . Each variation was tested for a rotation interval of 600 rpm from 2400 rpm to 7200 rpm. The results show that ignition degree greatly affects performance. The ignition angle of 28 0 produced better torque, effective power, effective specific fuel consumption and effective thermal efficiency than those of the ignition degrees at 24 0 and 26 0 (standard angle ). This is due to the use of ethanol fuel which has a slower combustion speed. Based on this fact, it is necessary to advance the ignition angle so that the explosive power of the air-fuel mixture is increasing. Low fuel consumption and better effective thermal efficiency were observed for 28 0 ignition degrees compared to 24 0 and 26 0 ignition degrees.

Published

2019

49. Numerical Investigation of Combustion in HCCI Diesel Engine Fuelled with Biodiesel Blends

Author

Hagar Alm ElDin Mohamad, Medhat Elkelawy, Abd Elnaby Kabeel, E. A. ElShenawy, and Mahmoud M. Elshanshoury

Subjects

Diesel fuel, Biodiesel, business.industry, Homogeneous charge compression ignition, Ignition timing, Particulates, Diesel engine, Process engineering, business, Combustion, NOx

Abstract

Homogeneous Charge Compression Ignition (HCCI) is an advanced combustion technology being considered for internal combustion engines due to the potential for high fuel conversion efficiency and extremely low particulate matter (PM) and Nitrogen Oxides (NOx) emissions. In HCCI engines, there is no direct control method for auto ignition time. A common method to indirectly control the ignition timing in HCCI combustion engines is altering engine’s parameters which can affect the combustion. Previous research has indicated that fuel chemistry has a strong impact on HCCI combustion. This work introduces a new predictive multi-zone model for the description of combustion in HCCI engines. A multi zone model with reduced fuel chemistry was developed to simulate the combustion process in HCCI engines and predict engine performance. In this work, a parametric study on Diesel/Biodiesel blends(D80B20) HCCI combustion is conducted in order to identify the effect of equivalence ratio values (0.1786, 0.27, 0.37, and 0.4762) on combustion and engine performance parameters. Two kinds of parameters will be discussed. First, in-cylinder pressure, temperature and net heat release rate diagrams at altering Diesel/Biodiesel dose (0%, 20%, 40%, 60%), then the second category, the variation of start of combustion and combustion duration which are performance parameters of HCCI Diesel Engine.

Published

2019

50. Ignition control in a gasoline compression ignition engine with ozone addition combined with a two-stage direct-injection strategy

Author

Hideyuki Ogawa, Yoshimitsu Kobashi, K. Naganuma, Gen Shibata, and Y. Wang

Subjects

020209 energy, General Chemical Engineering, Nuclear engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, Combustion, Fuel injection, Ignition, Cylinder (engine), law.invention, Ignition system, Ozone, Fuel Technology, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Octane rating, Stroke (engine), Ignition timing, 0204 chemical engineering, Gasoline, Gasoline compression ignition engine

Abstract

To control the ignition timing in a gasoline compression ignition (GCI) engine, ozone (O-3) was introduced into the intake air. The O-radicals are decomposed from the O-3 above 550 K during the compression stroke, and combine into oxygen (O-2) in a very short time. The authors adopted two-stage direct injection to mix the fuel injected into the cylinder at very early timings with the O-radicals, before a reduction of the O-radicals would take place. The ignition timing of the second fuel injection for the main combustion is controlled by the heat release from the first fuel injection. In this paper, engine experiments were performed to examine the feasibility of the ignition control with a primary reference fuel, octane number 90 (PRF90). The O-3 concentration, the quantity, and the timing of the first injection were changed as experimental parameters. The results showed that a very small quantity of O-3, tens of ppm, is sufficient to promote the heat release of the first injected fuel. The heat release increases with the O-3 concentration and the quantity of fuel in the first injection. The addition of O-3 has no other impact on the ignition when the first injection timing is retarded to around - 40 degrees CA ATDC. In this manner, it is possible to control the ignition delays and to alter the combustion state from typical diesel combustion to premixed compression ignition combustion.

Published

2019