EVAP System: Procedure

CONFIRM DTC
1. Turn the engine switch off and wait for 10 seconds.
2. Turn the engine switch on (IG).
3. Turn the engine switch off and wait for 10 seconds.
4. Connect the Techstream to the DLC3.
5. Turn the engine switch on (IG) and turn the Techstream on.
6. Enter the following menus: Powertrain / Engine / Trouble Codes.
7. Confirm DTCs and freeze frame data.
  If any EVAP system DTCs are stored, the malfunctioning area can be determined using the table below.
  
  Fig 1: Identifying DTC Malfunctioning Area Reference Chart
  Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
  
  NOTE:
  If the reference pressure difference between the first and second checks is greater than the specification, all the DTCs relating to the reference pressure (P043E, P043F, P2401, P2402 and P2419) are stored.
NEXT: Go to next step
PERFORM EVAP SYSTEM CHECK (AUTOMATIC MODE)
NOTE:
- The Evaporative System Check (Automatic Mode) consists of 6 steps performed automatically by the Techstream. It takes a maximum of approximately 18 minutes.
- Do not perform the Evaporative System Check when the fuel tank is more than 90% full because the cut-off valve may be closed, making the fuel tank leak check unavailable.
- Do not run the engine during this operation.
- When the temperature of the fuel is 35°C (95°F) or more, a large amount of vapor forms and any check results become inaccurate. When performing the Evaporative System Check, keep the temperature below 35°C (95°F).
1. Connect the Techstream to the DLC3.
2. Turn the engine switch on (IG).
3. Turn the Techstream on.
4. Clear DTCs. Refer to DTC CHECK / CLEAR .
5. Enter the following menus: Powertrain / Engine / Utility / Evaporative System Check / Automatic Mode.
6. After the Evaporative System Check is completed, check for pending DTCs by entering the following menus: Powertrain / Engine / Trouble Codes.
  HINT:
  
  If no pending DTCs are displayed, perform the Confirmation Driving Pattern. After this confirmation, check for pending DTCs. If no DTCs are displayed, the EVAP system is normal.
NEXT: Go to next step
PERFORM EVAP SYSTEM CHECK (MANUAL MODE)

Fig 2: EVAP System Check Diagram
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
NOTE:
- In the Evaporative System Check (Manual Mode), the series of 6 Evaporative System Check steps are performed manually using the Techstream.
- Do not perform the Evaporative System Check when the fuel tank is more than 90% full because the cut-off valve may be closed, making the fuel tank leak check unavailable.
- Do not run the engine during this operation.
- When the temperature of the fuel is 35°C (95°F) or more, a large amount of vapor forms and any check results become inaccurate. When performing the Evaporative System Check, keep the temperature below 35°C (95°F).
1. Connect the Techstream to the DLC3.
2. Turn the engine switch on (IG).
3. Turn the Techstream on.
4. Clear DTCs. Refer to DTC CHECK / CLEAR .
5. Enter the following menus: Powertrain / Engine / Utility / Evaporative System Check / Manual Mode.
NEXT: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 1/6)

Fig 3: Identifying Evaporative System Check (Step 1/6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in step 1/6.

RESULT

DTC *1	Result	Suspected Trouble Area	Proceed to
-	Virtually no variation in EVAP pressure	Not yet determined	A
P0451	EVAP pressure fluctuates by +/-0.3 kPa(gauge) [2.25 mmHg(gauge)] or more	Canister pressure sensor signal noise	B
(P0452 or P0453) *2	EVAP pressure is below 42.11 kPa(abs) [315.83 mmHg(abs)] or 123.761 kPa(abs) [928.208 mmHg(abs)] or more EVAP pressure deviates +/-10 kPa(gauge) [+/-75 mmHg(gauge)] from actual atmosphere pressure *3	Canister pressure sensor or its circuit has malfunction	C

*1: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.
*2: If the canister pressure sensor circuit has an open or short, DTC P0452 or P0453 is stored 0.5 seconds after the engine switch is turned on (IG).

HINT:

*3: Canister pressure sensor standard output range is 70 to 110 kPa(abs) [525 to 825 mmHg(abs)]. This varies by weather.

B → See step 38

C → See step 12

A: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 1/6 TO 2/6)

Fig 4: Identifying Evaporative System Check (Step 1/6))

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in steps 1/6 and 2/6.

RESULT

DTC*	Result	Suspected Trouble Area	Proceed to
-	Virtually no variation in EVAP pressure during step 1/6. Then decreases to reference pressure	Not yet determined	A
P2402	Small difference between EVAP pressures during steps 1/6 and 2/6	Leak detection pump stuck on	B

*: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.

HINT:

The first reference pressure is the value determined in step 2/6.

B → See step 31

A: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 2/6)

Fig 5: Identifying Evaporative System Check (Step 2/6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

HINT:

Make a note of the pressures checked in inspection items (A) and (B) below.

Check the EVAP pressure 4 seconds after the leak detection pump is activated*1 (A).
*1: The leak detection pump begins to operate as step 1/6 finishes and step 2/6 starts.

Check the EVAP pressure again when it has stabilized. This pressure is the reference pressure (B).

RESULT

DTC*2	Result	Suspected Trouble Area	Proceed to
-	EVAP pressure in inspection item (B) is between -4.85 kPa(gauge) and -1.057 kPa(gauge) [-36.375 mmHg(gauge) and -7.9275 mmHg(gauge)]	Not yet determined	A
P043F and P2401	EVAP pressure in inspection item (B) is -1.057 kPa(gauge) [-7.9275 mmHg(gauge)] or more	Reference orifice high-flow Leak detection pump stuck off	B
P043E	EVAP pressure in inspection item (B) is less than -4.85 kPa(gauge) [-36.375 mmHg(gauge)]	Reference orifice clogged	C
P2419	EVAP pressure in inspection item (A) is more than -1 kPa(gauge) [-7.5 mmHg(gauge)]	Vent valve stuck closed Leak detection pump performance deteriorates Leak detection pump circuit malfunctioning (large resistance exists in the circuit)	D

*2: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.

B → See step 11

C → See step 38

D → See step 13

A: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 2/6 TO 3/6)

Fig 6: Identifying Evaporative System Check (Step 2/6 To 3/6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in step 3/6.

RESULT

DTC*	Result	Suspected Trouble Area	Proceed to
-	EVAP pressure increases by 0.3 kPa(gauge) [2.25 mmHg(gauge)] or more within 10 seconds of proceeding from step 2/6 to step 3/6	Not yet determined	A
P2420	No variation in EVAP pressure even after proceeding from step 2/6 to step 3/6	Vent valve stuck open (vent) Canister (charcoal filter inside canister) clogged	B
P0451	No variation in EVAP pressure during steps 1/6 through 3/6	Canister pressure sensor output value stuck Vent valve broken (valve split in two) Leak detection pump performance deteriorates Leak detection pump circuit malfunctioning (large resistance exists in the circuit)	C

*: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.

B → See step 27

C → See step 15

A: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 3/6)

Fig 7: Identifying Evaporative System Check (Step 3/6)
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
1. Wait until the EVAP pressure change is less than 0.12 kPa(gauge) [0.9 mmHg(gauge)] for 40 seconds.
2. Measure the EVAP pressure and record it.
  HINT:
  
  A few minutes are required for the EVAP pressure to become saturated. When there is little fuel in the fuel tank, it takes up to 15 minutes.
NEXT: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 4/6)

Fig 8: Identifying Evaporative System Check (Step 4 of 6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in step 4/6.

RESULT

DTC*1	Result	Suspected Trouble Area	Proceed to
-	EVAP pressure increases by 0.3 kPa(gauge) [2.25 mmHg(gauge)] or more within 10 seconds of proceeding from step 3/6 to step 4/6	Not yet determined	A
P0441 *2	EVAP pressure increases by 0.3 kPa(gauge) [2.25 mmHg(gauge)] or more within 10 seconds of proceeding from step 3/6 to step 4/6	Purge VSV Purge VSV circuit Problems in EVAP hose between purge VSV and intake air surge tank assembly Problems in EVAP hose between canister and purge VSV ECM	B
P0441	Variation in EVAP pressure is less than 0.3 kPa(gauge) [2.25 mmHg(gauge)] for 10 seconds, after proceeding from step 3/6 to step 4/6	Purge VSV stuck closed Purge VSV circuit Canister (charcoal filter inside canister) clogged Problems in EVAP hose between purge VSV and intake air surge tank assembly Problems in EVAP hose between canister and purge VSV ECM	C

*1: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.
*2: This result suggests that due to purge line blockage or purge VSV malfunction, the DTC was stored by the purge flow monitor while the engine was running, or that key-off monitor test result were nearly borderline values.

B → See step 22

C → See step 17

A: Go to next step

PERFORM EVAP SYSTEM CHECK (STEP 5/6)

Fig 9: Identifying Evaportative System Check (Step 5/6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in step 5/6.

Compare the EVAP pressure in step 3/6 and the second reference pressure (step 5/6).

RESULT

DTC*	Result	Suspected Trouble Area	Proceed to
-	EVAP pressure from step 3/6 lower than second reference pressure (step 5/6)	Not yet determined (no leakage from EVAP system)	A
P0441 and P0455	EVAP pressure from step 3/6 higher than [second reference pressure (step 5/6) x 0.32]	Purge VSV stuck open EVAP gross leak	B
P0456	EVAP pressure from step 3/6 higher than second reference pressure (step 5/6)	EVAP small leak	B

*: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.

A → See step 43

B → See step 17

PERFORM EVAP SYSTEM CHECK (STEP 3/6)

Fig 10: Identifying Evaporative System Check (Step 3/6)

Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Check the EVAP pressure in step 3/6.

RESULT

DTC*	Result	Suspected Trouble Area	Proceed to
P043F	EVAP pressure less than [reference pressure] measured in step 2/6	Reference orifice high-flow	A
P2401	EVAP pressure almost same as [reference pressure] measured in step 2/6	Leak detection pump stuck off	B

*: These DTCs are already present in the ECM when the vehicle arrives and are confirmed in the "Confirm DTC" procedure above.

HINT:

The first reference pressure is the value determined in step 2/6.

A → See step 38

B → See step 31

INSPECT CANISTER PUMP MODULE (CANISTER PRESSURE SENSOR CIRCUIT)
1. Check the canister pressure sensor circuit, referring to DTC P0451 canister pressure sensor circuit inspection procedure. Refer to INSPECTION PROCEDURE .
NEXT → See step 48

INSPECT CANISTER PUMP MODULE (VENT VALVE OPERATION)

Turn the engine switch off.
Disconnect the canister pump module connector.

Fig 11: Inspecting Canister Pump Module (Vent Valve Operation)
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Apply the battery voltage to terminals VLVB and VGND of the pump module.

Touch the canister pump module to confirm the vent valve operation.

RESULT

Condition	Tester Result	Suspected Trouble Area	Proceed to
Apply battery voltage to terminals VLVB and VGND	Operating	Wire harness or connector between vent valve and ECM Leak detection pump performance deteriorates Leak detection pump circuit malfunctioning (large resistance exists in the circuit) ECM	A
Apply battery voltage to terminals VLVB and VGND	Not operating	Vent valve	B

B → See step 38

A: Go to next step

CHECK HARNESS AND CONNECTOR (CANISTER PUMP MODULE - ECM)

Turn the engine switch off.
Disconnect the ECM connector.
Disconnect the canister pump module connector.

Measure the resistance according to the value(s) in the table below.

Standard Resistance

Tester Connection	Condition	Specified Condition
Q49-8 (VGND) - E3-16 (VPMP)	Always	Below 1 Ω
Q49-8 (VGND) or E3-16 (VPMP) - Body ground	Always	10 kΩ or higher

RESULT

Result	Suspected Trouble Area	Proceed to
OK	Leak detection pump performance deteriorates Leak detection pump circuit malfunctioning (large resistance exists in the circuit) ECM	A
NG	Wire harness or connector between ECM and canister pump module	B

B → See step 40

A: Go to next step

CHECK HARNESS AND CONNECTOR (CANISTER PUMP MODULE - BODY GROUND)

Disconnect the canister pump module connector.

Measure the resistance according to the value(s) in the table below.

RESULT

Tester Connection	Condition	Specified Condition	Suspected Trouble Area	Proceed to
Q49-6 (MGND) - Body ground	Always	Below 1 Ω	Canister pump module Wire harness or connector between canister pump module and ECM ECM	A
Q49-6 (MGND) - Body ground	Always	10 kΩ or higher	Wire harness or connector between canister pump module and body ground	B

B → See step 40

A: Go to next step

CHECK HARNESS AND CONNECTOR (ECM - CANISTER PUMP MODULE)

Disconnect the canister pump module connector.
Disconnect the ECM connector.

Measure the resistance according to the value(s) in the table below.

RESULT

Tester Connection	Condition	Specified Condition	Suspected Trouble Area	Proceed to
E3-15 (MPMP) - Q49-1 (MTRB)	Always	Below 1 Ω	Canister pump module ECM	A
E3-15 (MPMP) - Q49-1 (MTRB)	Always	10 kΩ or higher	Wire harness or connector between ECM and canister pump module	B

A → See step 45

B → See step 40

PERFORM ACTIVE TEST USING TECHSTREAM (PURGE VSV)

Enter the following menus: Powertrain / Engine / Active Test / Activate the VSV for EVAP Control.
Disconnect the hose (connected to the canister) from the purge VSV.

Fig 12: Identifying Purge VSV & Hose To Canister
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Start the engine.
Using the Techstream, turn off the purge VSV (Activate the VSV for EVAP Control: OFF).
Use your finger to confirm that the purge VSV has no suction.
Using the Techstream, turn on the purge VSV (Activate the VSV for EVAP Control: ON).

Use your finger to confirm that the purge VSV has suction.

RESULT

Test Result	Suspected Trouble Area	Proceed to
No suction when purge VSV turned off, and suction applied when turned on	Blockage in the purge line is considered (based on result of step 9): Problems with EVAP hose between canister and purge VSV Canister (charcoal filter inside canister) clogged ECM	A
	Leakage is considered (based on result of step 10): Fuel cap Leakage from EVAP line, fuel tank, or canister	B
Suction applied when purge VSV turned off	Purge VSV stuck open	C
No suction when purge VSV turned on	Purge VSV stuck closed Problems with EVAP hose between purge VSV and intake air surge tank assembly	D

B → See step 20

C → See step 21

D → See step 23

A: Go to next step

INSPECT EVAP HOSE (PURGE VSV - CANISTER)
1. Check for blockages in the EVAP purge line between the purge VSV and canister.
  OK
  
  No blockages in the EVAP purge line between the purge VSV and canister.
NG → See step 44

OK: Go to next step
INSPECT CANISTER (CHARCOAL FILTER INSIDE CANISTER)
1. Check for filter blockage in the canister. Refer to INSPECTION .
  OK
  
  No blockages in the canister.
OK → See step 47

NG → See step 38

CHECK FUEL CAP

Check that the fuel cap is correctly installed and confirm that the fuel cap meets OEM specifications.

Tighten the fuel cap firmly (only one click sound could be heard).

HINT:

If an EVAP tester is available, check the fuel cap using the Techstream.

Remove the fuel cap and install it onto a fuel cap adapter.
Connect an EVAP tester pump hose to the adapter, and pressurize the cap to 3.2 to 3.7 kPa(gauge) [24 to 28 mmHg(gauge)] using an EVAP tester pump.
Seal the adapter and wait for 2 minutes.

Check the pressure. If the pressure is 2 kPa(gauge) [15 mmHg(gauge)] or more, the fuel cap is normal.

RESULT

Test Result	Suspected Trouble Area	Proceed to
Fuel cap correctly installed	-	A
Fuel cap loose	Fuel cap improperly installed Defective fuel cap Fuel cap does not meet OEM specifications	B
Defective fuel cap	-	B
No fuel cap	-	C

A → See step 37

B → See step 35

C → See step 36

INSPECT PURGE VSV

Turn the engine switch off.
Disconnect the purge VSV connector.

Fig 13: Identifying Purge VSV & Hose To Canister
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Disconnect the hose (connected to the canister) from the purge VSV.
Start the engine.

Use your finger to confirm that the purge VSV has no suction.

RESULT

Test Result	Suspected Trouble Area	Proceed to
No suction	Wire harness or connector between purge VSV and ECM (short to ground) ECM	A
Suction applied	Purge VSV	B

A → See step 26

B → See step 39

INSPECT EVAP HOSE (PURGE VSV - CANISTER)
1. Check for blockages in the EVAP purge line between the purge VSV and canister.
  OK
  
  No blockages in the EVAP purge line between the purge VSV and canister.
NG → See step 44

OK: Go to next step

CHECK EVAP HOSE (PURGE VSV - INTAKE AIR SURGE TANK ASSEMBLY)

Disconnect the hose (connected to the intake air surge tank assembly) from the purge VSV.

Fig 14: Identifying Intake Air Surge Tank Assembly
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Start the engine.

Use your finger to confirm that the hose has suction.

RESULT

Test Result	Suspected Trouble Area	Proceed to
Suction applied	EVAP hose between purge VSV and intake air surge tank assembly normal Purge VSV Purge VSV power source Wire harness or connector between purge VSV and ECM	A
No suction	Intake air surge tank assembly port EVAP hose between purge VSV and intake air surge tank assembly	B

B → See step 34

A: Go to next step

INSPECT PURGE VSV

Remove the purge VSV.
Apply battery voltage to the terminals of the purge VSV.

Fig 15: Testing Purge VSV
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Confirm that air flows from port E to port F.

RESULT

Test Result	Condition	Suspected Trouble Area	Proceed to
Air flows	Battery voltage is applied to purge VSV terminals	Purge VSV normal Purge VSV power source Wire harness or connector between purge VSV and ECM	A
No air flow	Battery voltage is applied to purge VSV terminals	Purge VSV	B

B → See step 39

A: Go to next step

CHECK TERMINAL VOLTAGE (POWER SOURCE OF PURGE VSV)

Disconnect the purge VSV connector.
Turn the engine switch on (IG).

Fig 16: Purge VSV Connector Terminal Identification
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002

Measure the voltage according to the value(s) in the table below.

RESULT

Tester Connection	Switch Condition	Specified Condition	Suspected Trouble Area	Proceed to
E77-2 - Body ground	Engine switch on (IG)	11 to 14 V	Purge VSV power source normal Wire harness or connector between purge VSV and ECM	A
E77-2 - Body ground	Engine switch on (IG)	Other than result above	Wire harness or connectors between purge VSV and battery	B

B → See step 40

A: Go to next step

CHECK HARNESS AND CONNECTOR (PURGE VSV - ECM)

Disconnect the ECM connector.
Disconnect the purge VSV connector.

Measure the resistance according to the value(s) in the table below.

Standard Resistance

Tester Connection	Condition	Specified Condition
E77-1 - E3-17 (PRG)	Always	Below 1 Ω
E77-1 or E3-17 (PRG) - Body ground	Always	10 kΩ or higher

OK → See step 47

NG → See step 40

INSPECT CANISTER PUMP MODULE (POWER SOURCE FOR VENT VALVE)

Turn the engine switch off.

Fig 17: Identifying Canister Pump Module Connector
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Disconnect the canister pump module connector.
Turn the engine switch on (IG).

Measure the voltage according to the value(s) in the table below.

RESULT

Tester Connection	Switch Condition	Specified Condition	Suspected Trouble Area	Proceed to
Q49-9 (VLVB) - Body ground	Engine switch on (IG)	11 to 14 V	Wire harness or connector between vent valve and ECM Vent valve Canister (charcoal filter inside canister) clogged ECM	A
Q49-9 (VLVB) - Body ground	Engine switch on (IG)	Below 3 V	Power source wire harness of vent valve	B

B → See step 40

A: Go to next step

INSPECT CANISTER PUMP MODULE (VENT VALVE OPERATION)

Turn the engine switch off.
Disconnect the canister pump module connector.

Fig 18: Inspecting Canister Pump Module (Vent Valve Operation)
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Apply the battery voltage to terminals VLVB and VGND of the pump module.

Touch the canister pump module to confirm the vent valve operation.

RESULT

Condition	Tester Result	Suspected Trouble Area	Proceed to
Apply battery voltage to terminals VLVB and VGND	Operating	Wire harness or connector between vent valve and ECM Canister (charcoal filter inside canister) clogged ECM	A
Apply battery voltage to terminals VLVB and VGND	Not operating	Vent valve	B

B → See step 38

A: Go to next step

CHECK HARNESS AND CONNECTOR (CANISTER PUMP MODULE - ECM)

Turn the engine switch off.
Disconnect the canister pump module connector.
Disconnect the ECM connector.

Measure the resistance according to the value(s) in the table below.

RESULT

Tester Connection	Condition	Test Result	Suspected Trouble Area	Proceed to
Q49-8 (VGND) - E3-16 (VPMP)	Always	Below 1 Ω	Canister (charcoal filter inside canister) clogged ECM	A
Q49-8 (VGND) - E3-16 (VPMP)	Always	10 kΩ or higher	Wire harness or connector between ECM and canister pump module	B

B → See step 40

A: Go to next step

INSPECT CANISTER (CHARCOAL FILTER INSIDE CANISTER)
1. Check for filter blockage in the canister. Refer to INSPECTION .
  OK
  
  No blockages in the canister.
OK → See step 47

NG → See step 38

PERFORM ACTIVE TEST USING TECHSTREAM (ACTIVATE THE VACUUM PUMP)

Turn the engine switch off.
Disconnect the canister pump module connector.

Fig 19: Identifying Cansiter Pump Module Connector
Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
Turn the engine switch on (IG).
Enter the following menus: Powertrain / Engine / Active Test / Activate the Vacuum Pump.

Measure the voltage according to the value(s) in the table below.

RESULT

Tester Connection	Condition	Test Result	Suspected Trouble Area	Proceed to
Q49-1 (MTRB) - Body ground	Leak detection pump on and off (Active Test ON and OFF)	Below 3 V when OFF 9 to 14 V when ON	Wire harness or connector between leak detection pump and body ground Leak detection pump	A
		Below 3 V when OFF and ON	Wire harness or connector between leak detection pump and ECM ECM	B
		9 to 14 V when OFF and ON	ECM	C

B → See step 33

C → See step 47

A: Go to next step

CHECK HARNESS AND CONNECTOR (CANISTER PUMP MODULE - BODY GROUND)

Turn the engine switch off.
Disconnect the canister pump module connector.

Measure the resistance according to the value(s) in the table below.

RESULT

Tester Connection	Condition	Specified Condition	Suspected Trouble Area	Proceed to
Q49-6 (MGND) - Body ground	Always	Below 1 Ω	Leak detection pump	A
Q49-6 (MGND) - Body ground	Always	10 kΩ or higher	Wire harness or connector between canister pump module and body ground	B

A → See step 38

B → See step 40

CHECK HARNESS AND CONNECTOR (ECM - CANISTER PUMP MODULE)

Turn the engine switch off.
Disconnect the canister pump module connector.
Disconnect the ECM connector.

Measure the resistance according to the value(s) in the table below.

Standard Resistance

Tester Connection	Condition	Specified Condition
E3-15 (MPMP) - Q49-1 (MTRB)	Always	Below 1 Ω
E3-15 (MPMP) or Q49-1 (MTRB) - Body ground	Always	10 kΩ or higher

RESULT

Result	Suspected Trouble Area	Proceed to
OK	ECM	A
NG	Wire harness or connector between ECM and canister pump module	B

A → See step 47

B → See step 40

INSPECT INTAKE AIR SURGE TANK ASSEMBLY (EVAP PURGE PORT)

Stop the engine.
Disconnect the EVAP hose from the intake air surge tank assembly.
Start the engine.

Use your finger to confirm that the port of the intake air surge tank assembly has suction.

RESULT

Tester Connection	Suspected Trouble Area	Proceed to
Suction applied	EVAP hose between intake air surge tank assembly and purge VSV	A
No suction	Intake air surge tank assembly	B

A → See step 41

B → See step 42

CORRECTLY REINSTALL OR REPLACE FUEL CAP
HINT:
- When reinstalling the fuel cap, tighten it firmly (only one click sound could be head).
- When replacing the fuel cap, use a fuel cap that meets OEM specifications, and install it firmly.
NEXT → See step 48
REPLACE FUEL CAP
HINT:

When installing the fuel cap, tighten it firmly (only one click sound could be head).

NEXT → See step 48
LOCATE EVAP LEAK PART
1. Disconnect the vent hose.
  
  Fig 20: Identifying Vent Hose Disconnect Point
  Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
2. Connect the EVAP pressure tester tool to the canister pump module with the adapter.
  
  Fig 21: View Of Pressure Gauge, Canister And Adapter
  Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
3. Pressurize the EVAP system to 3.2 to 3.7 kPa(gauge) [24 to 28 mmHg(gauge)].
4. Apply soapy water to the piping and connecting parts of the EVAP system.
5. Look for areas where bubbles appear. This indicates the leak point.
6. Repair or replace the leak point.
  HINT:
  
  Disconnect the hose between the canister and fuel tank from the canister. Block the canister side and conduct an inspection. In this way, the fuel tank can be excluded as an area suspected of causing fuel leaks.
NEXT → See step 48
REPLACE CANISTER
1. Replace the canister. Refer to REMOVAL .
  NOTE:
  - When replacing the canister, check the canister pump module interior and related pipes for water, fuel and other liquids. If liquids are present, check for disconnections and/or cracks in the following: 1) the pipe from the air inlet port to the canister pump module; 2) the canister filter; and 3) the fuel tank vent hose.
  - Check for filter blockage in the canister filter. If the canister filter has blockages, replace the canister filter.
  Fig 22: Identifying EVAP Inspection Areas
  Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
NEXT → See step 48
REPLACE PURGE VSV
1. Replace the purge VSV. Refer to REMOVAL .
NEXT → See step 48
REPAIR OR REPLACE HARNESS OR CONNECTOR
NEXT → See step 48
REPAIR OR REPLACE EVAP PURGE LINE (INTAKE AIR SURGE TANK ASSEMBLY - PURGE VSV)
NEXT → See step 48
INSPECT INTAKE AIR SURGE TANK ASSEMBLY (EVAP PURGE PORT)
1. Check that the EVAP purge port of the intake air surge tank assembly is not clogged. If necessary, replace the intake air surge tank assembly. Refer to REMOVAL .
NEXT → See step 48
REPAIR OR REPLACE PARTS AND COMPONENTS INDICATED BY OUTPUT DTCS
1. Repair the malfunctioning areas indicated by the DTCs that had been confirmed when the vehicle was brought in.
NEXT → See step 48
REPAIR OR REPLACE EVAP PURGE LINE (PURGE VSV - CANISTER)
NEXT → See step 48
REPLACE CANISTER
1. Replace the canister. Refer to REMOVAL .
  NOTE:
  - When replacing the canister, check the canister pump module interior and related pipes for water, fuel and other liquids. If liquids are present, check for disconnections and/or cracks in the following: 1) the pipe from the air inlet port to the canister pump module; 2) the canister filter; and 3) the fuel tank vent hose.
  - Check for filter blockage in the canister filter. If the canister filter has blockages, replace the canister filter.
  Fig 23: Identifying EVAP Inspection Areas
  Courtesy of © TOYOTA, LICENSE AGREEMENT TMS1002
NEXT: Go to next step

PERFORM EVAP SYSTEM CHECK (AUTOMATIC MODE)

NOTE:

The Evaporative System Check (Automatic Mode) consists of 6 steps performed automatically by the Techstream. It takes a maximum of approximately 18 minutes.
Do not perform the Evaporative System Check when the fuel tank is more than 90% full because the cut-off valve may be closed, making the fuel tank leak check unavailable.
Do not run the engine in this step.
When the temperature of the fuel is 35°C (95°F) or more, a large amount of vapor forms and any check results become inaccurate. When performing an Evaporative System Check, keep the fuel temperature below 35°C (95°F).

Connect the Techstream to the DLC3.
Turn the engine switch on (IG).
Turn the Techstream on.
Clear the DTCs. Refer to DTC CHECK / CLEAR .
Enter the following menus: Powertrain / Engine / Utility / Evaporative System Check / Automatic Mode.

After the Evaporative System Check is completed, check for pending DTCs by entering the following menus: Powertrain / Engine / Trouble Codes.

Result

Result	Proceed to
EVAP system DTCs are output	A
DTCs is not output (Pending DTCs is not output)	B

B → END

A: Go to next step

REPLACE ECM
1. Replace the ECM. Refer to REMOVAL .
NEXT: Go to next step
PERFORM EVAP SYSTEM CHECK (AUTOMATIC MODE)
NOTE:
- The Evaporative System Check (Automatic Mode) consists of 6 steps performed automatically by the Techstream. It takes a maximum of approximately 18 minutes.
- Do not perform the Evaporative System Check when the fuel tank is more than 90% full because the cut-off valve may be closed, making the fuel tank leak check unavailable.
- Do not run the engine in this step.
- When the temperature of the fuel is 35°C (95°F) or more, a large amount of vapor forms and any check results become inaccurate. When performing an Evaporative System Check, keep the fuel temperature below 35°C (95°F).
1. Connect the Techstream to the DLC3.
2. Turn the engine switch on (IG).
3. Turn the Techstream on.
4. Clear the DTCs. Refer to DTC CHECK / CLEAR .
5. Enter the following menus: Powertrain / Engine / Utility / Evaporative System Check / Automatic Mode.
6. After the Evaporative System Check is completed, check for pending DTCs by entering the following menus: Powertrain / Engine / Trouble Codes.
  HINT:
  
  If no pending DTCs are found, the repair has been successfully completed.
NEXT → END