GF49.10-P-2010V Three-Way Catalytic Converter, Component Description

GF49.10-P-2010V Three-way Catalytic Converter, Component Description
ENGINE 272.920 in MODEL 203 up to Model Year 8
ENGINE 272.922 in MODEL 211
ENGINE 272.940 in MODEL 203 up to Model Year 8
ENGINE 272.941 in MODEL 203 up to Model Year 8
ENGINE 272.942 in MODEL 171 up to Model Year 8
ENGINE 272.943 in MODEL 211, 219
ENGINE 272.944 in MODEL 211
ENGINE 272.945 in MODEL 251 up to Model Year 8
ENGINE 272.946 in MODEL 221 up to Model Year 8
ENGINE 272.960 in MODEL 203 up to Model Year 8
ENGINE 272.963 in MODEL 171 up to Model Year 8
ENGINE 272.964 in MODEL 211, 219
ENGINE 272.965 in MODEL 221 up to Model Year 8
ENGINE 272.966 in MODEL 230 up to Model Year 8
ENGINE 272.967 in MODEL 164, 251 up to Model Year 8
ENGINE 272.970 in MODEL 203 up to Model Year 8
ENGINE 272.972 in MODEL 211
ENGINE 272.975 in MODEL 221 up to Model Year 8
ENGINE 272.985 in MODEL 211, 219
ENGINE 273.922 in MODEL 221 up to Model Year 8
ENGINE 273.923 in MODEL 164 up to Model Year 8
ENGINE 273.924 in MODEL 221 up to Model Year 8
ENGINE 273.960 in MODEL 211, 219
ENGINE 273.961 in MODEL 216, 221 up to Model Year 8
ENGINE 273.962 in MODEL 211
ENGINE 273.963 in MODEL 164, 251 up to Model Year 8
ENGINE 273.965 in MODEL 230 up to Model Year 8
ENGINE 273.967 in MODEL 209
ENGINE 273.968 in MODEL 221 up to Model Year 8
ENGINE 272.940 in MODEL 209
ENGINE 272.960 in MODEL 209





Shown on engine 272.963, right cylinder bank

158 Catalytic converter
G3/4 Right O2 sensor upstream TWC
G3/6 Right O2 sensor downstream of TWC

Location
Near the engine in the front section of the exhaust system.

Task
Reduction of the following pollutants in the exhaust:
^ Carbon monoxide (CO)
^ Hydrocarbon (HC)
^ Nitrogen oxide (NOx).





Catalytic converter design (schematic)
1 ceramic monolith
2 Wire mesh (embedded)
3 Double-walled housing (insulation)
4 Substrate (washcoat) with a coating of platinum and rhodium

In each catalytic converter, there are two ceramic monoliths with each approx. 600 cells. The exhaust gas flows through these passages. The ceramic consists of high temperature-resistant magnesium aluminum silicate.
The monoliths are extremely sensitive to warping and are embedded in an elastic wire mesh of high-carbon steel wire and mounted inside a double-wall housing of stainless steel.

Ceramic monoliths require a support layer of alumina (Al2O3) (the "washcoat"), which increases the effective surface of the catalytic converter by a factor of 7000.

The active catalytic layer coated on the substrate is available in three-way catalysts primarily out of platinum and rhodium.
Platinum promotes the oxidation of hydrocarbons (HC) and carbon monoxide (CO) and rhodium the reduction of nitrogen oxides (NOX).

Owing to its property of simultaneously reducing three pollutant components, it is called a "three-way catalyst".





A Unpurified exhaust
B Purified exhaust
F Rich mixture
M Lean mixture
Lambda (air/fuel ratio)

Exhaust gas components:
CO Carbon monoxide
CO2 Carbon dioxide
H2O Water
HC Hydrocarbon
N2 nitrogen
NOX Nitrogen oxides

Function
The exhaust gases flow through the three way catalytic converter and hence come into contact with the rare metals, platinum and rhodium.
^ The carbon monoxide (CO) is converted to carbon dioxide (CO2) and hydrocarbons (HC) converted to water (H2O) + carbon dioxide (CO2) by oxidation.
^ Due to reduction, nitrogen oxides (NOx) are converted into nitrogen (N2) + carbon dioxide (CO2).

The critical factors for the conversion of the pollutants is the residual oxygen content in the exhaust. It is determined through lambda control and maintained at lambda equals 1 in normal operation.

Operating conditions
As is the case for the O2 sensor, the operating temperature also plays a very important role in the case of the catalytic converter.
Appreciable conversion of the pollutants does not commence until an operating temperature of approx. 250°C. This temperature is reached quickly after the engine is started, due to the near-engine location, the air-gap insulation on the exhaust manifold and mixture enrichment.

Ideal operating conditions for high conversion rates and a long life prevail at temperatures between around 400 to 800°C.

The temperature of the three way catalytic converter can increase beyond 1400 °C due to a malfunctioning of the engine such as misfiring etc. These high temperatures can lead to destruction of the catalytic converter, by melting the ceramic monoliths.

Another requirement for reliable long-term operation is that only unleaded fuel be used. Lead compounds form a deposit on the active surface and as a result prevent the exhaust gases from coming into contact with the catalytic layer.

If the vehicle is driven during direct injection in stratified charge operation with excess air, the catalytic converter cannot convert the nitrogen oxide sufficiently. Additional NOX storage catalytic converters are necessary.