Investigation of Combustion Characteristics of a Heavy-Duty Diesel Engine Retrofitted to Natural Gas Spark Ignition Operation

Liu, Jinlong

doi:10.33915/etd.3713

Cited by 5 publications

(19 citation statements)

References 84 publications

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“…In addition, the FL images were showing many high-intensity pixels at MFB95 and significant activity at MFB98. As preliminary 3D CFD simulations of the lean-burn operation in this engine suggested that the burned region contained no unburned fuel, 34 the FL was most probably due to a combination of a late burn of the fuel trapped near the straight corners of the cylindrical bowl and/or of the reflections from the late burn inside the (non-visible) squish region. 34,37 Furthermore, this late burn inside the bowl probably helped maintain the temperature required for late oxidation.…”

Section: Resultsmentioning

confidence: 85%

“…As preliminary 3D CFD simulations of the lean-burn operation in this engine suggested that the burned region contained no unburned fuel, 34 the FL was most probably due to a combination of a late burn of the fuel trapped near the straight corners of the cylindrical bowl and/or of the reflections from the late burn inside the (non-visible) squish region. 34,37 Furthermore, this late burn inside the bowl probably helped maintain the temperature required for late oxidation. Consequently, in addition to the contribution from the combustion phenomena taking place inside the squish region, the combustion of the unburned mass trapped at the bottom of the bowl also contributed to the low slope of the AHRR toward the EOC, as shown in Figure 3(b).…”

Section: Resultsmentioning

confidence: 85%

“…37,38 In detail, when the flame front reached the entrance of the squish region and the bottom corner of the cylindrical bowl, the flame speed reduced due to the smaller local turbulence intensity, lower unburned gas temperature, and more heat transfer to the boundary (due to the high surface-to-volume ratio). 34 Furthermore, Figure 5(b) and (c) suggests a start of combustion (SOC) between −8 and −4 CAD ATDC. Therefore, the cycle-to-cycle variation can be partially explained by the different spark inception period.…”

Section: Resultsmentioning

confidence: 94%

“…However, the 3D CFD simulations predicted no trapped fuel at the bottom of the bowl for the metal engine. 34…”

Section: Resultsmentioning

confidence: 99%

“…The goal of this study was to use flame luminosity (FL) and in-cylinder pressure measurements to investigate flame kernel growth and the subsequent flame propagation inside the bowl region. To ensure that observations of FL such as those in this article will also apply to production engines with similar bowl-in-piston geometry, preliminary 3D CFD simulations 34 of both metal (i.e. production) and optical engine configurations investigated engine operation under similar operating conditions.…”

Section: Introductionmentioning

confidence: 99%

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Optical analysis of flame inception and propagation in a lean-burn natural-gas spark-ignition engine with a bowl-in-piston geometry

Liu

Dumitrescu

2019

International Journal of Engine Research

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Heavy-duty diesel engines can convert to lean-burn natural-gas spark-ignition operation through the addition of a gas injector in the intake manifold and of a spark plug in place of the diesel injector to initiate and control combustion. However, the combustion phenomena in such converted engines usually consist of two distinct stages: a fast-burning stage inside the piston bowl followed by a slow-burning stage inside the squish area. This study used flame luminosity data and in-cylinder pressure measurements to analyze flame propagation inside a bowl-in-piston geometry. The experimental results showed a low coefficient of variation and standard deviation of peak cylinder pressure, moderate rate of pressure rise, and no knocking for the lean-burn (equivalence ratio 0.66), low-speed (900 r/min), and medium-load (6.6 bar IMEP) operating condition. Flame inception had a strong effect on the flame expansion velocity, which increased fast once the flame kernel established, but it reduced near the bowl edge and the entrance of the narrow squish region. However, the burn inside the bowl was very fast. In addition, the long duration of burn inside the squish indicated a much lower flame propagation speed for the outside-the-bowl combustion, which contributed to a long decreasing tail in the apparent heat release rate. Furthermore, cycles with fast flame inception and fast burn inside the bowl had a similar end of combustion with cycles with delayed flame inception and then a retarded burn inside the bowl, which indicated that the combustion inside the squish region determined the combustion duration. Overall, the results suggested that the spark event, the flame development inside the piston bowl, and the start of the second combustion stage affected the phasing and duration of the two combustion stages, which (subsequently) can affect engine efficiency and emissions of diesel engines converted to a lean-burn natural-gas spark-ignition operation.

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Section: Resultsmentioning

confidence: 85%

Section: Resultsmentioning

confidence: 85%

Section: Resultsmentioning

confidence: 94%

“…However, the 3D CFD simulations predicted no trapped fuel at the bottom of the bowl for the metal engine. 34…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Optical analysis of flame inception and propagation in a lean-burn natural-gas spark-ignition engine with a bowl-in-piston geometry

Liu

Dumitrescu

2019

International Journal of Engine Research

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Numerical Investigation of Methane Number and Wobbe Index Effects in Lean-Burn Natural Gas Spark-Ignition Combustion

Liu

Dumitrescu

2019

Energy Fuels

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A larger use of natural gas in internal combustion engines will reduce the dependence upon petroleum imports. However, large variations in gas composition as a result of the gas origin and/or gas treatments applied can affect engine performance and emissions. This study used a three-dimensional computational fluid dynamics internal combustion engine model (validated with experimental data) to investigate the effect of adding heavier hydrocarbons (ethane and propane) to the gas mix. The simulation investigated the effects of spark timing, intake pressure, equivalence ratio, and engine speed when the engine operated with six different natural gas blends (methane number from 50 to 100 and Wobbe index from 48 to 58) that had a nonlinear relationship between the methane number and the Wobbe index. The results showed that a lower methane number and a higher Wobbe index increased and advanced in-cylinder pressure, advanced the combustion phasing, decreased the ignition lag, and shortened the combustion duration, regardless of the operating condition as a result of the higher laminar flame speed and energy density. In addition, it increased nitrogen oxides emissions but lowered unburned hydrocarbon emissions. A higher sensitivity to gas composition was found when the methane number was lower than 70. Moreover, the results suggest that gas composition will not affect lean-burn operation if the methane number is above 70. This suggests that the engine control system of a diesel engine converted to lean-burn natural gas spark-ignition operation will adjust to changes in natural gas composition as long as the methane number of the gas is at least 70.

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Numerical Investigation of the Effects of Engine Speed on Performance and Combustion Characteristics on a Converted Spark-Ignition Natural Gas Engine

Aktas

2022

Gazi Üniversitesi Fen Bilimleri Dergisi Part C: Tasarım Ve Teknoloji

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In this study, the effects of different engine speed values on performance and combustion characteristics were investigated by converting a diesel engine to a spark-ignition engine using natural gas. In numerical analysis, G-equation combustion model, reduced methane chemical kinetic mechanism that represent natural gas consisting of 29 types and 171 equations, and RANS k-e turbulence model were used. Analyzes were performed at full load, 17.5:1 compression ratio, constant ignition timing, and 6 different engine speeds. In order to examine only the effect of speed, the initial value, boundary conditions and spark plug ignition time were considered constant. While engine power and fuel consumption increased with increasing engine speed, engine efficiency decreased. In addition, increasing engine speed also increased the ignition delay time and combustion duration, and the flame front reached the squish zone later.

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Investigation of Combustion Characteristics of a Heavy-Duty Diesel Engine Retrofitted to Natural Gas Spark Ignition Operation

Cited by 5 publications

References 84 publications

Optical analysis of flame inception and propagation in a lean-burn natural-gas spark-ignition engine with a bowl-in-piston geometry

Optical analysis of flame inception and propagation in a lean-burn natural-gas spark-ignition engine with a bowl-in-piston geometry

Numerical Investigation of Methane Number and Wobbe Index Effects in Lean-Burn Natural Gas Spark-Ignition Combustion

Numerical Investigation of the Effects of Engine Speed on Performance and Combustion Characteristics on a Converted Spark-Ignition Natural Gas Engine

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