GF14.00-P-3000OGG Exhaust Treatment Function

GF14.00-P-3000OGG Exhaust Treatment Function
ENGINES 642.8 in MODEL 164.1 as of model year 2009
- except CODE (U42) BlueTEC (SCR) diesel exhaust treatment / YoM 08 model refinement package
ENGINES 642.8 in MODEL 164.8, 251.1 as of model year 2009
- except CODE (U42) BlueTEC (SCR) diesel exhaust treatment / YoM 08
ENGINES 642.8 in MODEL 251.0 /1 as of model year 2011
- except CODE (U42) BlueTEC (SCR) diesel exhaust treatment / YoM 10 model refinement package

Function requirements for exhaust treatment, general points
^ Circuit 87 ON (engine control ON)
^ Engine running

Exhaust treatment, general
The task of exhaust treatment is to reduce the exhaust emissions:

- Nitrogen oxides (NOX)
- Hydrocarbons (HC)
- Carbon monoxide (CO)
- Soot particles

Pollutant reduction is supported by the following subfunctions:

- Intake port shutoff (EKAS)
- Diesel particulate filter (DPF) preheating (with code (474) Particulate filter)
- Exhaust gas recirculation (AGR) (EGR)

The CDI control unit (N3/9) reads in the following sensors for purging:

- O2 sensor upstream of catalytic converter (G3/2)
- Temperature sensor upstream of diesel particulate filter (B19/9), on vehicles with code (474) Particulate filter
- Temperature sensor upstream of turbocharger (B19/11)
- Pressure differential sensor (DPF) (B28/8), on vehicles with code (474) Particulate filter
- AAC [KLA] control and operating unit (N22) (except code (581) Comfort automatic air conditioning) or comfort AAC control and operating unit (N22/7) (with code (581) Comfort automatic air conditioning), outside temperature via the interior CAN (CAN B), central gateway control unit (N93) and engine compartment CAN (CAN C)

Function sequence for exhaust treatment
The following subsystems are involved in exhaust treatment:

^ Function sequence for oxidation catalytic converter
^ Function sequence for diesel particulate filter (DPF)
^ Function sequence for intake port shutoff

Function sequence for oxidation catalytic converter
The oxidation catalytic converter reduces the amount of hydrocarbon (HC), carbon monoxide (CO) and nitrogen oxides (NOX, and, on vehicles with code (474) Particulate filter, generates the required thermal energy for the DPF regeneration phase by afterburning.

Function sequence for diesel particulate filter (DPF)
The diesel particulate filter consists of a ceramic honeycomb filter body made out of silicon carbide, which is coated with platinum.
The passages of the diesel particulate filter are opened alternately at the front and rear and are separated from each other through the porous filter walls of the honeycomb filter body.
The precleaned exhaust which has passed though the oxidation catalytic converter flows into the ducts of the DPF which are open to the front and passes through the porous filter walls of the honeycomb filter body into the ducts which are open to the rear.
After this, the cleaned and filtered exhaust is dissipated through the exhaust system. The soot particles are retained in the honeycomb filter body of the DPF.
If the soot particle content exceeds a map-based value, the CDI control unit will start the regeneration phase provided the prerequisites for regeneration are given. The CDI control unit receives the soot particle content in the DPF via the DPF differential pressure sensor.

Regeneration takes place by means of a periodical increase of the exhaust temperature. For this purpose, the following functions are initiated by the CDI control unit:
- One further post injection via the fuel injectors (Y76)
- DPF glow function via the drive train LIN (LIN C1) over the glow time output stage (N14/3) to the glow plugs (R9)
- Switching line shift over the engine compartment CAN by the electric controller unit (VGS) (Y3/8)

Soot content is reduced by approx. 99%.

The soot particles retained in the DPF are mostly burnt off to produce carbon dioxide (CO2) by increasing the exhaust temperature. The ash produced remains in the DPF. The exhaust temperature is monitored during regeneration by the temperature sensor upstream of turbocharger and from the temperature sensor upstream of diesel particulate filter, for vehicles with code (474) Particulate filter.

The pressure differential sensor determines the pressure difference between the exhaust gas pressure upstream and downstream of DPF via the exhaust gas pressure lines upstream of DPF and downstream of DPF.
The soot particle content in the DPF is determined using a characteristic map on the basis of the pressure differential and the exhaust mass calculated by the CDI control unit.
Necessary maintenance of the DPF is signalized via the CHECK ENGINE indicator lamp (A1e26) (for code (494) USA version) or engine diagnosis indicator lamp (A1e58) (except code (494) USA version) in the instrument cluster (A1).

On short trips, regeneration is interrupted and distributed over several driving cycles. Until the specified regeneration temperature is reached several heating-up phases are required. Regeneration occurs unnoticeably by the customer.

Function sequence for intake port shutoff
The intake port shutoff (EKAS) achieves the best possible relation between air swirl and air mass in all load conditions of the engine.

The CDI control unit additionally reads the following sensors for intake port shutoff:
- Oil temperature sensor (B1)
- Atmospheric pressure sensor, for the atmospheric pressure
- Accelerator pedal sensor (B37), for load recognition
- Crankshaft Hall sensor (B70), for the engine speed
- AAC [KLA] control and operating unit (except code (581) Comfort automatic air conditioning) or from the comfort AAC control and operating unit (with code (581) Comfort automatic air conditioning), outside temperature via the interior CAN (CAN B), central gateway control unit and engine compartment CAN

After evaluating the input signals, the CDI control unit actuates the motor for the inlet port shutoff switchover valve (M55) by means of a pulse width modulated (PWM) signal. Half of the intake ports (2 intake port per cylinder) are closed over flaps for intake port shutoff in the lower motor speed and engine load range.
In the open intake ports, the flow rate is thus increased. This leads to a higher swirl which creates a better vortex. This improves combustion and also contributes to reducing the soot particles in the exhaust gas. As the engine speed and engine load increase, the closed intake ports are continuously opened so that the best possible relationship between air swirl and air mass is available for every operating phase of the engine. In this way, the exhaust characteristics and the engine performance are optimized.

If there is a fault or discontinuity in the supply voltage, the flaps are opened by spring force.