Exhaust gas temperature: Difference between revisions
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This was achieved by enriching the air/fuel |
This was achieved by enriching the air/fuel |
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mixture. |
mixture. |
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= 1 is possible up to high load and engine |
= 1 is possible up to high load and engine |
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speed ranges. |
speed ranges. |
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To facilitate exhaust gas temperature control, |
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the exhaust gas temperature must be recorded |
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to a high degree of accuracy. |
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An accuracy of ± 5 °C is achieved in the |
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measurement range from 950 °C to 1025 °C. |
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The exhaust gas temperature sender is located |
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inside the exhaust manifold upstream of the |
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exhaust gas turbocharger. |
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It comprises a measuring sensor and |
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evaluation electronics. |
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The measuring sensor and the control unit are |
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permanently connected by means of a |
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shielded, heat-resistant wire. |
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The evaluation electronics convert the signal |
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which the measuring sensor generates into a |
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pulse-width-modulated signal (PWM signal). |
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This is a square-wave signal with a fixed |
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frequency and a variable pulse duty factor. |
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The pulse duty factor is expressed as a |
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percentage . The measurement range extends |
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from 10% to 90%. |
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A specific pulse duty factor is assigned to each |
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temperature (refer to diagram). |
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===Substitute function and self-diagnosis=== |
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A pulse duty factor of <1% or >99% is |
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recognised as a fault. |
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A fault is detected as of a certain enrichment |
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quantity. |
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If a sender fails, the charge pressure is reduced |
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to a safe level and an emergency enrichment |
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characteristic (engine speed-dependent) is |
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used. |
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Revision as of 01:28, 2 September 2006
Exhaust gas temperature control
For turbocharged engines, the maximum permissible exhaust gas temperature is a key design criterion.
To protect the exhaust gas turbocharger and the exhaust manifold, the exhaust gas temperature should not exceed 1000 °C for a lengthy period of time.
Since many of the components which influence the exhaust gas temperature have tolerances, thermodynamic adaptation previously took place at 950 °C for safety's sake.
This was achieved by enriching the air/fuel
mixture.
The exhaust gas temperature is recorded in a cylinder-bank-specific manner by the two exhaust gas temperature senders G235 and G236.
The Motronic controls the exhaust gas temperature to 980 °C by enriching the air/fuel mixture .
It is therefore possible to largely dispense with the prophylactic enrichment process that has been standard practice until now.
The mixture is only enriched...
- when necessary and
- to the extent necessary.
This means that engine operation with lambda = 1 is possible up to high load and engine speed ranges.
To facilitate exhaust gas temperature control,
the exhaust gas temperature must be recorded
to a high degree of accuracy.
An accuracy of ± 5 °C is achieved in the measurement range from 950 °C to 1025 °C. The exhaust gas temperature sender is located inside the exhaust manifold upstream of the exhaust gas turbocharger.
It comprises a measuring sensor and evaluation electronics.
The measuring sensor and the control unit are permanently connected by means of a shielded, heat-resistant wire.
The evaluation electronics convert the signal which the measuring sensor generates into a pulse-width-modulated signal (PWM signal). This is a square-wave signal with a fixed frequency and a variable pulse duty factor. The pulse duty factor is expressed as a percentage . The measurement range extends from 10% to 90%. A specific pulse duty factor is assigned to each temperature (refer to diagram).
Substitute function and self-diagnosis
A pulse duty factor of <1% or >99% is recognised as a fault. A fault is detected as of a certain enrichment quantity. If a sender fails, the charge pressure is reduced to a safe level and an emergency enrichment characteristic (engine speed-dependent) is used.