A fleet-prediction oriented catalyst model for highly transient driving in cold and hot mode conditions

Various models for simulating catalytic converters are given in the literature. They deal with a wide range of different aspects. In addition to the type of catalytic converter (three-way catalytic converter, diesel oxidation catalytic converter, etc.), the aspect of complexity versus accuracy and speed can be tackled using different approaches. Moreover, the desired use has an influence on the model structure: optimization of catalyst design or prediction of emissions from real-world traffic situations or optimization of air–fuel ratio control? The model described here has been developed to predict emissions in arbitrary real-world driving patterns, both for hot driving as well as for cold-start situations. As these tests mainly last over 30 minutes (real time), the calculation effort should be small. The model should be easy to parameterize, as it should be applicable to vehicles from traffic. A model with a reduced set of chemical reactions has been developed with a particular focus on the thermal balance for cold-start cycles. Its outputs are the pollutant emissions at the tailpipe if the emissions, exhaust mass flow and temperature from the engine are given. It is applied to three-way catalytic converters. It models the chemical phenomena almost entirely based on oxygen storage and release reactions, which dominate highly transient situations. The model has been validated against a large database of measured driving cycles, carried out using different types of cars. It presents an acceptable degree of correlation between simulated and experimental results.

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A Catalyst Surface Control Automation System for Emission Reduction During Cold Start

ASME 2004 Internal Combustion Engine Division Fall Technical Conference ◽

10.1115/icef2004-0865 ◽

2004 ◽

Author(s):

Anastasios N. Karkanis ◽

Pantelis N. Botsaris ◽

Panagiotis D. Sparis

Keyword(s):

Catalyst Surface ◽

Catalytic Converter ◽

Ceramic Body ◽

Cold Start ◽

Active Surface ◽

Pollutant Emissions ◽

Automation System ◽

Initial Surface ◽

Simple Method ◽

Exhaust Gases

This paper presents and discusses experimental data obtained during test simulating the test cycle ECE-15 for a relatively simple method for the reduction of pollutant emissions during a cold start. During a cold start the volume of the exhaust gases is considerably smaller than the ones under full load. Therefore, only a small portion of the catalyst active surface is used to process the gases at the cold start phase. After the light-off at the initial surface the exhaust gases pass from the total catalytic surface which is already pre-heated from the first phase. The experimental results presented here indicate that there is a reduction of the pollutant emissions during the cold start of an engine. The developed system uses the 20% of the catalyst active surface during start-up and the rest of the catalyst surface after this phase, controlled by a proper automation system. At the cold start phase the system focusing the gas flow towards the center core of the monolith, so there is a quicker warm-up of the catalyst and a faster initiation of catalysis in this area. So when the remaining ceramic body of the catalytic converter is used, it is already warmed and the catalysis starts almost immediately.

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Development of a Cost Effective Catalytic Converter for Diesel Automobiles

International Journal of Recent Technology and Engineering - 2 ◽

10.35940/ijrte.c4823.098319 ◽

2019 ◽

Vol 8 (3) ◽

pp. 2989-2994

Keyword(s):

Negative Impact ◽

Catalytic Converter ◽

Cost Effective ◽

Developed Countries ◽

Fuel Oil ◽

Oxygen Storage ◽

Catalytic Converters ◽

Coating Materials ◽

Exhaust Gases ◽

The Developed Countries

The purpose of the work presented in this paper is to find and suggest a suitable solution to the exhaust pollution coming from the Diesel Automobiles particularly in the metro cities. Due to incomplete combustion of fuel oil pollutants like CO, HC, NOx are released into atmosphere causing negative impact on air quality, environment and human health. Researchers all over the world concentrated on how to reduce the pollutants. Euro norms specify the allowable percentages of CO, HC and NOx in the exhaust gases. Euro norms being implemented in the developed countries have given stringent values which has led to the development of catalytic converter which is an added equipment in automobile. Hitherto in the catalytic converters supplied in modern cars, Platinum and Rhodium metals are used for coating monoliths. These metals are rare and hence expensive. In the research carried out by the authors, suitable monolith substrates are tested and used in the catalytic converters with coating materials like CeO2 , ZrO2 over clay marbles, Copper Monolith and SS Discs which help NOx¬ abatement and oxygen storage. These were designed, fabricated and tested on automobiles. The results are encouraging showing marked fall of pollutants in exhaust gases.

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Pollutant emissions from vehicles with regenerating after-treatment systems in regulatory and real-world driving cycles

The Science of The Total Environment ◽

10.1016/j.scitotenv.2008.02.022 ◽

2008 ◽

Vol 398 (1-3) ◽

pp. 87-95 ◽

Cited By ~ 7

Author(s):

Robert Alvarez ◽

Martin Weilenmann ◽

Philippe Novak

Keyword(s):

Real World ◽

Pollutant Emissions ◽

Driving Cycles

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Optimum Use of Noble Metal Catalysts in Catalytic Converters

Design, Application, Performance and Emissions of Modern Internal Combustion Engine Systems and Components ◽

10.1115/icef2002-534 ◽

2002 ◽

Author(s):

F. Lacin ◽

M. Zhuang

Keyword(s):

Noble Metal ◽

Catalytic Converter ◽

Cold Start ◽

Metal Catalysts ◽

Vapor Condensation ◽

Metal Distribution ◽

Catalytic Converters ◽

Model Calculations ◽

Noble Metal Catalysts ◽

Off Time

The catalytic converter is an important device for the emission control from spark-ignition engines. Several concurrent physical/chemical processes such as convective heat transfer, gas phase chemical reactions, surface reactions, flow oscillations, water vapor condensation and diffusion mechanisms add complexity to modeling of flows inside catalytic converters. Under cold-start conditions, the fact that catalytic converters do not become operational during the initial operation allows a significant fraction of the overall pollutants to be emitted. In the present study, these complex transient phenomena have been examined using a previously validated numerical model.1 The numerical results suggest new material-dependent designs to improve both the transient conversion characteristics and the steady state conversion efficiency of catalytic converters. Moreover, from our model calculations, we have observed that for a given amount of the noble metal catalysts the light-off time and the monolith temperature are greatly affected by the noble-metal distribution along the honeycomb walls of a monolith. The results of the numerical simulations indicate that the light-off time is shortened by approximately 35% for CO, H2 and C3H6 when replacing a traditional homogeneous noble metal distribution by a simple, step-function distribution.2 The emissions of CO, H2 and C3H6 from the exhaust gas are, therefore, reduced without increasing the cost of noble metal catalysts used in converters. In order to avoid further deterioration of catalysts due to the thermal effects, an optimum noble metal distribution needs to be investigated with the understanding that the optimum noble metal distribution proposed has to be practical for the manufacturing. Since the main source of the exhaust emissions is generated during the cold-start period of the converter operation, the reduction of emissions shown in our model calculations is quite substantial.

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Effects of biodiesel on passenger car fuel consumption, regulated and non-regulated pollutant emissions over legislated and real-world driving cycles

Fuel ◽

10.1016/j.fuel.2009.02.011 ◽

2009 ◽

Vol 88 (9) ◽

pp. 1608-1617 ◽

Cited By ~ 172

Author(s):

Georgios Fontaras ◽

Georgios Karavalakis ◽

Marina Kousoulidou ◽

Theodoros Tzamkiozis ◽

Leonidas Ntziachristos ◽

...

Keyword(s):

Fuel Consumption ◽

Real World ◽

Pollutant Emissions ◽

Passenger Car ◽

Driving Cycles

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Reduction of Cold-Start Emissions for a Micro Combined Heat and Power Plant

Energies ◽

10.3390/en13081862 ◽

2020 ◽

Vol 13 (8) ◽

pp. 1862

Author(s):

Tammo Zobel ◽

Christian Schürch ◽

Konstantinos Boulouchos ◽

Christopher Onder

Keyword(s):

Power Plant ◽

Power Plants ◽

Combustion Engine ◽

Catalytic Converter ◽

Energy Transition ◽

Cold Start ◽

Combined Heat And Power ◽

Operating Conditions ◽

Pollutant Emissions ◽

Full Load Operation

Decentralized power generation by combined heat and power plants becomes increasingly popular as a measure to advance the energy transition. In this context, a substantial advantage of small combined heat and power plants is based on the relatively low pollutant emissions. However, a large proportion of the pollutant emissions is produced during a cold-start. This fact is not reflected in governmental and institutional emission guidelines, as these strongly focus on the emission levels under steady-state conditions. This study analyzes the spark advance, the reference air/fuel ratio and an electrically heated catalyst in terms of their potential to reduce the cold-start emissions of a micro combined heat and power plant which uses a natural gas fueled reciprocating internal combustion engine as prime mover and a three-way catalytic converter as aftertreatment system. Based on these measures, control approaches were developed that account for the specific operating conditions of the class of small combined heat and power plants, e.g., full-load operation and flexible, demand-driven runtimes. The experimental data demonstrates that even solutions with marginal adaptation/integration effort can reduce cold-start emissions to a great extent.

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