Variation of Exhaust Gas Temperature with the Change of Spark Timing and Exhaust Valve Timing During Cold Start Operation of an SI Engine

Low Temperature Combustion (LTC) strategies such as Reactivity Controlled Compression Ignition (RCCI) can result in significant improvements of fuel economy and emissions reduction. However, they can produce significant carbon monoxide and unburnt hydrocarbon emissions at low load operating conditions due to poor combustion efficiencies at these operating points, which is a consequence of the low combustion temperatures that cause the oxidation rates of these species to slow down. The exhaust gas temperature is also not high enough at low loads for effective performance of turbocharger systems and diesel oxidation catalysts (DOC). The DOC is extremely sensitive to exhaust gas temperature changes and lights off only when a certain temperature is reached, depending on the catalyst specifications. Uncooled EGR can increase combustion temperatures, thereby improving combustion efficiency, but high EGR concentrations of 50% or more are required, thereby increasing pumping work and reducing volumetric efficiency. However, with early exhaust valve opening, the exhaust gas temperature can be much higher, allowing lower EGR flow rates, and enabling activation of the DOC for more effective oxidization of unburnt hydrocarbons and CO in the exhaust. In this paper, a multi-cylinder engine system simulation of RCCI at low load operation with early exhaust valve opening is presented, along with consideration of the exhaust aftertreatment system. The combustion process is modeled using the 3D CFD code, KIVA, and the heat release rates obtained from this combustion are used in a GT-Power model of a turbocharged, multi-cylinder light-duty RCCI engine for a full system simulation. The post-turbine exhaust gas is fed into GT-Power’s aftertreatment model of the engine’s DOC to determine the catalyst response. It is confirmed that opening the exhaust valve earlier increases the exhaust gas temperature, and hence lower EGR flow rates are needed to improve combustion efficiency. It was also found that exhaust temperatures of around 457 K are required to light off the catalyst and oxidize the unburnt hydrocarbons and CO effectively. Performance of the DOC was drastically improved and higher amounts of unburnt hydrocarbons were oxidized by increasing the exhaust gas temperature.

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Emissions Level Approximation at Cold Start for Spark Ignition Engine Vehicles

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.555.375 ◽

2014 ◽

Vol 555 ◽

pp. 375-384 ◽

Cited By ~ 3

Author(s):

Stelian Tarulescu ◽

Adrian Soica

Keyword(s):

Cold Start ◽

Spark Ignition ◽

Spark Ignition Engine ◽

Estimation Methods ◽

Exhaust Gas ◽

Gas Temperature ◽

Mathematical Approximation ◽

Exhaust Gas Temperature ◽

The Mathematical Model ◽

Polynomial Regressions

This paper present a study regarding the emissions produced at the engine cold start. Also, the paper presents a brief survey of current extra emissions estimation methods. The main goal of this work is to describe the relative cold start extra emissions as a function of exhaust gas temperature. Experimental research has been done for a light vehicle, Dacia Sandero, equipped with a 1390 cm3 Renault spark ignition engine (Power = 55 kW at 5500 rpm). There were been made several tests, in different temperature conditions, in the could season, using a portable analyzer, GA-21 plus (produced by Madur Austria). The parameters measured with the analyzer and used in the analysis are: CO, NO, NOx and SO2. It was concluded that the highest pollutants values are recorded until the point when the catalyst comes into operation (when the gas temperature entering the catalyst is approx. 200 oC) and exhaust gas temperature is 40-50 oC. In order to accomplish a mathematical approximation of CO, NO and SO2 in function of exhaust gas temperature, logarithmic approximations and polynomial regressions were used. The curves resulted from the mathematical model can be used to approximate the level of CO, NO and SO2, for similar vehicles.

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Exhaust gas treatment for reducing cold start emissions of a motorcycle engine fuelled with gasoline-ethanol blends

Journal of Energy in Southern Africa ◽

10.17159/2413-3051/2015/v26i2a2199 ◽

2017 ◽

Vol 26 (2) ◽

pp. 84 ◽

Cited By ~ 1

Author(s):

A. Samuel Raja ◽

A. Valan Arasu

Keyword(s):

Traffic Congestion ◽

Catalytic Converter ◽

Cold Start ◽

Exhaust Gas ◽

Gas Temperature ◽

Gas Treatment ◽

Single Cylinder ◽

Hc Emissions ◽

Ethanol Blends ◽

Exhaust Gas Temperature

In countries like India, transportation by a two wheeled motorcycle is very common owing to affordable cost, easy handling and traffic congestion. Most of these bikes use single cylinder air cooled four-stroke spark ignition (SI) engines of displacement volume ranging from 100 cm3 to 250 cm3. CO and HC emissions from such engines when started after a minimum stop-time of 12 hours or more (cold-start emissions) are higher than warmed-up emissions. In the present study, a 150 cm3 single cylinder air cooled SI engine was tested for cold start emissions and exhaust gas temperature. Different gasoline-ethanol blends (E0 to E20) were used as fuel expecting better oxidation of HC and CO emissions with additional oxygen present in ethanol. The effect of glow plug assisted exhaust gas ignition (EGI) and use of catalytic converter on cold start emissions were studied separately using the same blends. Results show that with gasoline-ethanol blends, cold start CO and HC emissions were less than that with neat gasoline. And at an ambient temperature of 30±1°C, highest emission reductions were observed with E10. EGI without a catalytic converter had no significant effect on emissions except increasing the exhaust gas temperature. The catalytic converter was found to be active only after 120 seconds in converting cold start CO, HC and NOx. Use of a catalytic converter proves to be a better option than EGI in controlling cold start emissions with neat gasoline or gasoline-ethanol blends.

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Exhaust Gas Condensation during Engine Cold Start and Application of the Dry-Wet Correction Factor

Applied Sciences ◽

10.3390/app9112263 ◽

2019 ◽

Vol 9 (11) ◽

pp. 2263 ◽

Cited By ~ 7

Author(s):

Barouch Giechaskiel ◽

Alessandro A. Zardini ◽

Michael Clairotte

Keyword(s):

Internal Combustion Engines ◽

Cold Start ◽

Combustion Products ◽

Dew Point ◽

Exhaust Gas ◽

Gas Temperature ◽

Compressed Natural Gas ◽

Ambient Temperatures ◽

Instrument Measuring ◽

Exhaust Gas Temperature

Gas components, like carbon monoxide (CO) and dioxide (CO2), can be measured on a wet- or dry-basis depending on whether the water is left or removed from the sample before analysis. The dry concentrations of gaseous components in the exhaust from internal combustion engines are converted to wet concentrations with conversion factors based on the combustion products and the fuel properties. Recent CO2 measurements with portable emissions measurement systems (PEMS) compared to laboratory grade equipment showed differences during the first minutes after engine start. In this study we compared instruments measuring on a dry- and wet-basis using different measuring principles (non-dispersive infrared detection (NDIR) and Fourier-transform infrared spectroscopy (FTIR)) at the exhaust of gasoline, compressed natural gas (CNG), and diesel light-duty and L-category vehicles. The results showed an underestimation of the CO2 and CO mass emissions up to 13% at cold start when the conversion factor is applied and not direct “wet” measurements are taken, raising concerns about reported CO2 and CO cold start emissions in some cases. The underestimation was negligible (<1%) for CO2 when the whole test (20–30 min) was considered, but not for CO (1%–10% underestimation) because the majority of emissions takes place at cold start. Exhaust gas temperature, H2O measurements and different expressions of the dry-wet corrections confirmed that the differences are due to condensation at the exhaust pipes and aftertreatment devices when the surface temperatures are lower than the dew point of the exhaust gases. The results of this study help to interpret differences when comparing instruments with different principles of operation at the same location, instruments sampling at different locations, or the same instrument measuring different driving test cycles or at different ambient temperatures (e.g., −7 °C).

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The Simulation Calculation of Temperatures on Valve Seats of Combustion Engine and its Verification

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1016.577 ◽

2014 ◽

Vol 1016 ◽

pp. 577-581 ◽

Cited By ~ 1

Author(s):

Pavel Brabec ◽

Aleš Dittrich

Keyword(s):

Cylinder Head ◽

Combustion Engine ◽

Combustion Process ◽

Exhaust Valve ◽

Gas Temperature ◽

Si Engine ◽

Simulation Calculation ◽

Exhaust Gas Temperature ◽

Cooling And Lubrication ◽

Complex Parts

The paper deals with the load of the head of the engine. Head of SI engine, which has molded seat of intake and exhaust valve, is one of the most complex parts of the engine. It contains intake and exhaust ports, spark plugs, timing of the mechanism and channels for cooling and lubrication. Much of the final form of this component also contributes its load, which is both heat and mechanical. The biggest influence on the deformation of embedded saddles exhaust valve has a temperature distribution in the cylinder head. These temperatures are influenced by many factors, especially temperature and coolant flow, load and engine speed, which affect the combustion process and exhaust gas temperature (the engine mode is constantly changing, therefore the thermal load on the valve seats is different). In our paper we will only deal with the heat load of the cylinder head of the engine. Currently, the most common use of appropriate software tools for determining the distribution as voltage or temperature. The simulation results may not always be identical to the actual situation, so it is necessary to perform by verification. The paper described measurements of temperature on the inserted valve seats cylinder head of the engine.

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Effects of application of variable valve timing on the exhaust gas temperature improvement in a low-loaded diesel engine

Applied Thermal Engineering ◽

10.1016/j.applthermaleng.2017.04.098 ◽

2017 ◽

Vol 122 ◽

pp. 758-767 ◽

Cited By ~ 14

Author(s):

Hasan Ustun Basaran ◽

Osman Azmi Ozsoysal

Keyword(s):

Diesel Engine ◽

Exhaust Gas ◽

Variable Valve Timing ◽

Gas Temperature ◽

Valve Timing ◽

Variable Valve ◽

Exhaust Gas Temperature

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Lime kiln conversion from coke to natural gas operation – an option in direction of sustainable energy

Sugar Industry ◽

10.36961/si24555 ◽

2020 ◽

pp. 431-434

Author(s):

Oliver Arndt

Keyword(s):

Natural Gas ◽

New Technology ◽

Exhaust Gas ◽

Gas Temperature ◽

Gaseous Fuels ◽

Lime Kiln ◽

Lime Kilns ◽

Co2 Balance ◽

Exhaust Gas Temperature

This paper deals with the conversion of coke fired lime kilns to gas and the conclusions drawn from the completed projects. The paper presents (1) the decision process associated with the adoption of the new technology, (2) the necessary steps of the conversion, (3) the experiences and issues which occurred during the first campaign, (4) the impacts on the beet sugar factory (i.e. on the CO2 balance and exhaust gas temperature), (5) the long term impressions and capabilities of several campaigns of operation, (6) the details of available technologies and (7) additional benefits that would justify a conversion from coke to natural gas operation on existing lime kilns. (8) Forecast view to develop systems usable for alternative gaseous fuels (e.g. biogas).

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