DTC P0420 Catalyst System Low Efficiency Bank 1 Single Exhaust
Circuit Description
This diagnostic test is designed in order to measure the efficiency
of the three-way catalytic converter (TWC) system. Catalytic convertor efficiency
is a measure of its ability to store oxygen after converting the levels of
hydrocarbon (HC), carbon monoxide (CO), and oxides of nitrogen (NOx) to less
harmful gases. The control module is able to evaluate the catalyst efficiency
once the vehicle has met the enable criteria and the vehicle is at idle instead
of the steady cruise speeds used in the past.
Once the conditions for running this diagnostic trouble code (DTC) are
met, the control module commands either a lean or rich air/fuel ratio depending
on the current state of the exhaust oxygen level. The control module issues
a rich command if the exhaust is currently lean, or a lean command if the
exhaust is currently rich. After completion of the first command, a second
and opposite command is issued.
For example, if the control module were to command a rich mixture, the
upstream heated oxygen sensor (HO2S) voltage would increase immediately. The
rich mixture is delayed in reaching the downstream HO2S due to the conversion
process occurring within the converter. The higher the efficiency, the
more the delay before the rich or lean mixture is detected by the downstream
oxygen (O2) sensor. As a result of the lower conversion efficiency
within a damaged or poisoned catalyst, the delay in the rich or lean mixture
reaching the downstream O2 sensor is significantly shorter. This DTC monitors
the amount of time required for both the upstream and downstream HO2S voltages
to cross a calibrated voltage threshold in response to the rich or lean
command.
Conditions for Running the DTC
• | No active secondary AIR DTCs |
• | No active camshaft position (CMP) sensor DTCs |
• | No active engine coolant temperature (ECT) sensor DTCs |
• | No active exhaust gas recirculation (EGR) DTCs |
• | No active fuel trim DTCs |
• | No active idle air control (IAC) DTCs |
• | No active intake air temperature (IAT) sensor DTCs |
• | No active mass air flow (MAF) sensor DTCs |
• | No active manifold absoluter pressure (MAP) sensor DTCs |
• | No active oxygen (O2) sensor DTCs |
• | No active transmission DTCs |
• | No active evaporative emission (EVAP) system DTCs |
• | No active throttle position (TP) sensor DTCs |
• | No active vehicle speed sensor (VSS) DTCs |
• | No active ignition DTCs |
• | The engine speed is 1,000 RPM or more for more than 32 seconds
for an automatic transmission or 40 seconds for a manual transmission
since last idle period. |
• | The engine has been running for at least 360 seconds and
the long term fuel trim is stable. |
• | The predicted catalyst temperature is more than 390°C (734°F). |
• | The system is in Closed Loop. |
• | The BARO is 72 kPa or more. |
• | The IAT is between -7 and +75°C (19-167°F). |
• | The ECT is between 75-118°C (167-244°F). |
• | The engine has been idling for less than 120 seconds. |
• | The actual engine speed is within 100 RPM of the desired
idle speed. |
Conditions for Setting the DTC
The VCM determines that the oxygen storage capacity of the catalyst
has degraded below a calibrated threshold.
Action Taken When the DTC Sets
• | The control module illuminates the malfunction indicator lamp
(MIL) the first time the diagnostic runs and fails. |
• | The control module will set the DTC and records the operating
conditions at the time the diagnostic fails. The control module stores the
failure information in the scan tools Freeze Frame/Failure Records. |
Conditions for Clearing the MIL or DTC
• | The control module turns OFF the MIL after 3 consecutive
drive trips when the test has run and passed. |
• | A history DTC will clear if no fault conditions have been detected
for 40 warm-up cycles. A warm-up cycle occurs when the coolant temperature
has risen 22°C (40°F) from the startup coolant temperature
and the engine coolant reaches a temperature that is more than 70°C (158°F)
during the same ignition cycle. |
• | Use a scan tool in order to clear the DTCs. |
Diagnostic Aids
The use of fuel with a high sulfur or lead content can degrade the performance
of a marginal converter. Be sure to check fuel quality.
An intermittent may be caused by any of the following conditions:
• | Rubbed through wire insulation |
• | A broken wire inside the insulation |
Thoroughly check any circuitry that is suspected of causing the intermittent
complaint. Refer to
Testing for Intermittent Conditions and Poor Connections
in Wiring Systems.
If a repair is necessary, refer to
Wiring Repairs
or
Connector Repairs
in Wiring Systems.
Test Description
The numbers below refer to the step numbers in the diagnostic table.
-
This step checks for conditions that can cause the three-way catalytic
converter efficiency to appear degraded. Inspect and repair the exhaust
system as necessary.
-
Before the three-way catalytic converter is replaced,
make sure that the following conditions are not present:
• | High engine oil consumption or coolant consumption |
• | Retarded spark timing or a weak spark |
Step
| Action
| Values
| Yes
| No
|
1
| Did you perform the Powertrain
On-Board Diagnostic (OBD) System Check?
| --
|
Go to Step
2
| Go to
Powertrain On Board Diagnostic (OBD) System Check
|
2
| Are any other DTCs set?
| --
| Go to the applicable DTC table
|
Go to Step 3
|
3
|
- Check the exhaust system for the following:
• | Loose or missing hardware |
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 4
|
4
|
- Verify that the correct original equipment three-way catalytic
converter is installed.
- Check the converter for the following:
- Ensure that the oxygen sensors are properly installed and that
the wiring connections are properly retained and not damaged.
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 6
|
5
|
- Using the scan tool, clear the DTCs.
- Start the engine.
- Allow the engine to idle until the engine reaches normal operating
temperature.
- Select DTC and the Specific DTC function.
- Enter the DTC number which was set.
- Operate the vehicle, with the Conditions for Setting this DTC,
until the scan tool indicates the diagnostic Ran.
Does the scan tool indicate the diagnostic Passed?
| --
| System OK
|
Go to Step 6
|
6
|
Notice: In order to avoid damaging the replacement three-way catalytic converter,
correct the engine misfire or mechanical fault before replacing the three-way
catalytic converter.
Replace the catalytic converter. Refer to
Catalytic Converter Replacement
in Engine
Exhaust.
Is the action complete?
| --
| System OK
| --
|
DTC P0420 Catalyst System Low Efficiency Bank 1 Under 8600 GVW (without C6P)
Circuit Description
This diagnostic test is designed in order to measure the efficiency
of the three-way catalytic converter (TWC) system. Catalytic convertor efficiency
is a measure of its ability to store oxygen after converting the levels of
hydrocarbon (HC), carbon monoxide (CO), and oxides of nitrogen (NOx) to less
harmful gases. The control module is able to evaluate the catalyst efficiency
once the vehicle has met the enable criteria and the vehicle is at idle instead
of the steady cruise speeds used in the past.
Once the conditions for running this diagnostic trouble code (DTC) are
met, the control module commands either a lean or rich air/fuel ratio depending
on the current state of the exhaust oxygen level. The control module issues
a rich command if the exhaust is currently lean, or a lean command if the
exhaust is currently rich. After completion of the first command, a second
and opposite command is issued.
For example, if the control module were to command a rich mixture, the
upstream heated oxygen sensor (HO2S) voltage would increase immediately. The
rich mixture is delayed in reaching the downstream HO2S due to the conversion
process occurring within the converter. The higher the efficiency, the
more the delay before the rich or lean mixture is detected by the downstream
oxygen (O2) sensor. As a result of the lower conversion efficiency
within a damaged or poisoned catalyst, the delay in the rich or lean mixture
reaching the downstream O2 sensor is significantly shorter. This DTC monitors
the amount of time required for both the upstream and downstream HO2S voltages
to cross a calibrated voltage threshold in response to the rich or lean
command.
Conditions for Running the DTC
• | No active secondary AIR DTCs |
• | No active camshaft position (CMP) sensor DTCs |
• | No active engine coolant temperature (ECT) sensor DTCs |
• | No active exhaust gas recirculation (EGR) DTCs |
• | No active fuel trim DTCs |
• | No active idle air control (IAC) DTCs |
• | No active intake air temperature (IAT) sensor DTCs |
• | No active mass air flow (MAF) sensor DTCs |
• | No active manifold absolute pressure (MAP) sensor DTCs |
• | No active oxygen (O2) sensor DTCs |
• | No active transmission DTCs |
• | No active evaporative emission (EVAP) system DTCs |
• | No active throttle position (TP) sensor DTCs |
• | No active vehicle speed sensor (VSS) DTCs |
• | No active ignition DTCs |
• | The engine speed is 1,100 RPM or more for more than 44 seconds
since last idle period. |
• | The engine has been running for at least 360 seconds and
the long term fuel trim is stable. |
• | The predicted catalyst temperature is more than 390°C (734°F). |
• | The system is in Closed Loop. |
• | The BARO is 72 kPa or more. |
• | The IAT is between -7 and +75°C (19-167°F). |
• | The ECT is between 75-118°C (167-244°F). |
• | The engine has been idling for less than 120 seconds. |
• | The actual engine speed is within 100 RPM of the desired
idle speed. |
Conditions for Setting the DTC
The VCM determines that the oxygen storage capacity of the catalyst
has degraded below a calibrated threshold.
Action Taken When the DTC Sets
• | The control module illuminates the malfunction indicator lamp
(MIL) the first time the diagnostic runs and fails. |
• | The control module will set the DTC and records the operating
conditions at the time the diagnostic fails. The control module stores the
failure information in the scan tools Freeze Frame/Failure Records. |
Conditions for Clearing the MIL or DTC
• | The control module turns OFF the MIL after 3 consecutive
drive trips when the test has run and passed. |
• | A history DTC will clear if no fault conditions have been detected
for 40 warm-up cycles. A warm-up cycle occurs when the coolant temperature
has risen 22°C (40°F) from the startup coolant temperature
and the engine coolant reaches a temperature that is more than 70°C (158°F)
during the same ignition cycle. |
• | Use a scan tool in order to clear the DTCs. |
Diagnostic Aids
The use of fuel with a high sulfur or lead content can degrade the performance
of a marginal converter. Be sure to check fuel quality.
An intermittent may be caused by any of the following conditions:
• | Rubbed through wire insulation |
• | A broken wire inside the insulation |
Thoroughly check any circuitry that is suspected of causing the intermittent
complaint. Refer to
Testing for Intermittent Conditions and Poor Connections
in Wiring Systems.
If a repair is necessary, refer to
Wiring Repairs
or
Connector Repairs
in Wiring Systems.
Test Description
The numbers below refer to the step numbers in the diagnostic table.
-
This step checks for conditions that can cause the three-way catalytic
converter efficiency to appear degraded. Inspect and repair the exhaust
system as necessary.
-
Before the three-way catalytic converter is replaced,
make sure that the following conditions are not present:
• | High engine oil consumption or coolant consumption |
• | Retarded spark timing or a weak spark |
Step
| Action
| Values
| Yes
| No
|
1
| Did you perform the Powertrain
On-Board Diagnostic (OBD) System Check?
| --
|
Go to Step
2
| Go to
Powertrain On Board Diagnostic (OBD) System Check
|
2
| Are any other DTCs set?
| --
| Go to the applicable DTC table
|
Go to Step 3
|
3
|
- Check the exhaust system for the following:
• | Loose or missing hardware |
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 4
|
4
|
- Verify that the correct original equipment three-way catalytic
converter is installed.
- Check the converter for the following:
- Ensure that the oxygen sensors are properly installed and that
the wiring connections are properly retained and not damaged.
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 6
|
5
|
- Using the scan tool, clear the DTCs.
- Start the engine.
- Allow the engine to idle until the engine reaches normal operating
temperature.
- Select DTC and the Specific DTC function.
- Enter the DTC number which was set.
- Operate the vehicle, with the Conditions for Setting this DTC,
until the scan tool indicates the diagnostic Ran.
Does the scan tool indicate the diagnostic Passed?
| --
| System OK
|
Go to Step 6
|
6
|
Notice: In order to avoid damaging the replacement three-way catalytic converter,
correct the engine misfire or mechanical fault before replacing the three-way
catalytic converter.
Replace the catalytic converter. Refer to
Catalytic Converter Replacement
in Engine
Exhaust.
Is the action complete?
| --
| System OK
| --
|
DTC P0420 Catalyst System Low Efficiency Bank 1 Over 8600 GVW (C6P)
Circuit Description
This diagnostic test is designed in order to measure the efficiency
of the three-way catalytic converter (TWC) system. Catalytic convertor efficiency
is a measure of its ability to store oxygen after converting the levels of
hydrocarbon (HC), carbon monoxide (CO), and oxides of nitrogen (NOx) to less
harmful gases. The control module is able to evaluate the catalyst efficiency
once the vehicle has met the enable criteria and the vehicle is at idle instead
of the steady cruise speeds used in the past.
Once the conditions for running this diagnostic trouble code (DTC) are
met, the control module commands either a lean or rich air/fuel ratio depending
on the current state of the exhaust oxygen level. The control module issues
a rich command if the exhaust is currently lean, or a lean command if the
exhaust is currently rich. After completion of the first command, a second
and opposite command is issued.
For example, if the control module were to command a rich mixture, the
upstream heated oxygen sensor (HO2S) voltage would increase immediately. The
rich mixture is delayed in reaching the downstream HO2S due to the conversion
process occurring within the converter. The higher the efficiency, the
more the delay before the rich or lean mixture is detected by the downstream
oxygen (O2) sensor. As a result of the lower conversion efficiency
within a damaged or poisoned catalyst, the delay in the rich or lean mixture
reaching the downstream O2 sensor is significantly shorter. This DTC monitors
the amount of time required for both the upstream and downstream HO2S voltages
to cross a calibrated voltage threshold in response to the rich or lean
command.
Conditions for Running the DTC
• | No active secondary AIR DTCs |
• | No active camshaft position (CMP) sensor DTCs |
• | No active engine coolant temperature (ECT) sensor DTCs |
• | No active exhaust gas recirculation (EGR) DTCs |
• | No active fuel trim DTCs |
• | No active idle air control (IAC) DTCs |
• | No active intake air temperature (IAT) sensor DTCs |
• | No active mass air flow (MAF) sensor DTCs |
• | No active manifold absolute pressure (MAP) sensor DTCs |
• | No active oxygen (O2) sensor DTCs |
• | No active transmission DTCs |
• | No active evaporative emission (EVAP) system DTCs |
• | No active throttle position (TP) sensor DTCs |
• | No active vehicle speed sensor (VSS) DTCs |
• | The engine speed is 900 RPM or more for more than 42 seconds
since last idle period. |
• | The engine has been running for at least 360 seconds and
the long term fuel trim is stable. |
• | The predicted catalyst temperature is 385°C (725°F)
or more. |
• | The system is in Closed Loop. |
• | The BARO is 72 kPa or more. |
• | The IAT is between -7 and +75°C (19-167°F). |
• | The ECT is between 75-118°C (167-244°
F). |
• | The engine has been idling between 0-120 seconds. |
• | The actual engine speed is within 125 RPM of the desired
idle speed. |
Conditions for Setting the DTC
The VCM determines that the oxygen storage capacity of the catalyst
has degraded below a calibrated threshold.
Action Taken When the DTC Sets
• | The control module illuminates the malfunction indicator lamp
(MIL) the first time the diagnostic runs and fails. |
• | The control module will set the DTC and records the operating
conditions at the time the diagnostic fails. The control module stores the
failure information in the scan tools Freeze Frame/Failure Records. |
Conditions for Clearing the MIL or DTC
• | The control module turns OFF the MIL after 3 consecutive
drive trips when the test has run and passed. |
• | A history DTC will clear if no fault conditions have been detected
for 40 warm-up cycles. A warm-up cycle occurs when the coolant temperature
has risen 22°C (40°F) from the startup coolant temperature
and the engine coolant reaches a temperature that is more than 70°C (158°F)
during the same ignition cycle. |
• | Use a scan tool in order to clear the DTCs. |
Diagnostic Aids
The use of fuel with a high sulfur or lead content can degrade the performance
of a marginal converter. Be sure to check fuel quality.
An intermittent may be caused by any of the following conditions:
• | Rubbed through wire insulation |
• | A broken wire inside the insulation |
Thoroughly check any circuitry that is suspected of causing the intermittent
complaint. Refer to
Testing for Intermittent Conditions and Poor Connections
in Wiring Systems.
If a repair is necessary, refer to
Wiring Repairs
or
Connector Repairs
in Wiring Systems.
Test Description
The numbers below refer to the step numbers on the diagnostic table.
-
This step checks for conditions that can cause the three-way catalytic
converter efficiency to appear degraded. Inspect and repair the exhaust system
as necessary.
-
Before the three-way catalytic converter is replaced,
make sure that the following conditions are not present:
• | High engine oil consumption or coolant consumption |
• | Retarded spark timing or a weak spark |
Step
| Action
| Values
| Yes
| No
|
1
| Did you perform the Powertrain
On-Board Diagnostic (OBD) System Check?
| --
|
Go to Step
2
| Go to
Powertrain On Board Diagnostic (OBD) System Check
|
2
| Are any other DTCs set?
| --
| Go to the applicable DTC table
|
Go to Step 3
|
3
|
- Check the exhaust system for the following conditions:
• | Loose or missing hardware |
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 4
|
4
|
- Verify that the correct original equipment three-way catalytic
converter is installed.
- Check the converter for the following:
- Ensure that the oxygen sensors are properly installed and that
the wiring connections are properly retained and not damaged.
- Repair as necessary. Refer to
Exhaust System Inspection
in Engine Exhaust.
Did you find a problem?
| --
|
Go to Step
5
|
Go to Step 6
|
5
|
- Using the scan tool, clear the DTCs.
- Start the engine.
- Allow the engine to idle until the engine reaches normal operating
temperature.
- Select DTC and the Specific DTC function.
- Enter the DTC number which was set.
- Operate the vehicle, with the Conditions for Setting this DTC,
until the scan tool indicates the diagnostic Ran.
Does the scan tool indicate the diagnostic Passed?
| --
| System OK
|
Go to Step 6
|
6
|
Notice: In order to avoid damaging the replacement three-way catalytic converter,
correct the engine misfire or mechanical fault before replacing the three-way
catalytic converter.
Replace the catalytic converter. Refer to
Catalytic Converter Replacement
in Engine
Exhaust.
Is the action complete?
| --
| System OK
| --
|