A fuel vapor treatment apparatus is provided with an air-fuel-ratio obtaining portion and a clogging determining portion. The air-fuel-ratio obtaining portion obtains the air-fuel ratio. The clogging determining portion determines whether a purge line is clogged based on a maximum variation amount of air-fuel ratio. In a case where no clogging is occurred in the purge line, the air-fuel ratio significantly fluctuates temporarily. In a case where at least a part of the purge line is fully clogged, even when a purge valve receives a valve opening command to be opened, fuel vapor cannot be introduced into the engine, so that the air-fuel ratio is not varied. In view of an air-fuel ratio variation, it is determined whether the purge line is clogged.

Methods and systems are provided for conducting an evaporative emissions test diagnostic on a vehicle fuel system and evaporative emissions control system during engine-on conditions. In one example, a first fuel vapor storage device is separated from a second fuel vapor storage device by a one-way check valve, thus preventing loading of the first fuel vapor storage device during conditions such as refueling operations, diurnal temperature fluctuations, or from running-loss vapors from a vehicle fuel tank. In this way, the evaporative emissions test diagnostic may be conducted during a cold-start event where an exhaust catalyst is below a predetermined threshold temperature required for catalytic oxidation of hydrocarbons in the engine exhaust, without increasing undesired exhaust emissions.

Methods and systems are provided for conducting an engine-off-natural-vacuum (EONV) test diagnostic on a vehicle fuel system and evaporative emissions system. In one example, a method may include setting an initial vent duration for the EONV test as a function of a likelihood that the vehicle will pass the EONV test during a pressure phase portion, or during a vacuum phase portion, and commencing the EONV test with the vacuum phase portion responsive to the likelihood that the vehicle will pass during the vacuum phase portion. In this way, battery power may be conserved and fuel economy improved, by avoiding a pressure phase portion of the EONV test if it is indicated that the vehicle is not expected to pass the EONV test during the pressure phase portion.

Methods and systems are provided for diagnostics of an intake air system hydrocarbon (AIS HC) trap during vehicle-off conditions. In one example, a method may include generating fuel vapor in a fuel tank, directing the generated vapor to the AIS HC trap, and then actively purging the AIS HC trap. Degradation of the AIS HC trap may be indicated based on an exhaust air fuel ratio during the active purging of the AIS HC trap.

A method for diagnosing a purge valve of a canister purge system includes (a) determining whether a purge valve, which is installed on a purge pipe connecting a canister with an intake system of an engine, is open and whether a purge pump is running, wherein the purge pump is configured to pump evaporative emission captured in the canister toward the intake system, and (b) determining whether the purge valve is in a close stuck state, based on upstream pressure and downstream pressure of the purge pump, when the purge valve is open while the purge pump is running.

The invention provides a method for monitoring a vehicle that features the steps of: 1) generating a data packet including vehicle data retrieved from the vehicle using a wireless appliance; 2) transmitting the data packet over an airlink with the wireless appliance so that the data packet passes through a network and to a host computer system; 3) processing the data packet with the host computer system to generate a set of data; and 4) displaying the set of data on a web page hosted on the internet.

A device may determine whether there is a communicated point with open air between a pump and a control valve or on an opposite side to the control valve of the pump, by at least two of pressures: between the pump and the control valve in case the control valve is in a cutoff state, the switching valve is in a communication state, and the pump sends in forward direction, on an opposite side to the control valve of to the pump in case the control valve is in a communication state, the switching valve is in the cutoff state, and the pump sends in reverse direction; and between the pump and the control valve or on the opposite side to the control valve of the pump in case the valves are in the cutoff states and the pump is stopped after one of these cases.

A system for testing an evaporative emissions (EVAP) canister of a vehicle according to the present disclosure includes an evaporator configured to contain liquid fuel, a fuel vapor supply line configured to deliver a mixture of fuel vapor and carrier gas from the evaporator to the EVAP canister, and a fuel vapor supply valve disposed in the fuel vapor supply line. The test system further includes a gas density meter configured to measure a density of the fuel vapor mixture flowing through the fuel vapor supply line, and a valve control module configured to control a position of the fuel vapor supply valve to adjust a flow of fuel vapor from the evaporator to the EVAP canister based on the fuel vapor mixture density.

A method for diagnosing operation of a valve to purge a canister of an internal combustion engine, the method, carried out during a purge, including: a) detecting, at an instant to, that the purge valve is open; b) executing a forced closing of the valve at an instant t2; c) measuring a pressure P1m of the intake manifold and calculating a corresponding modelled pressure P1c, at an instant t1 between the instant t0 and the instant t2; d) measuring a pressure of the manifold P2m and calculating a corresponding modelled pressure P2c, at an instant t3 after the instant t2; e) calculating a deviation E1 between P1m and P1c and calculating a deviation E2 between P2m and P2c; f) calculating a criterion C=E1?E2; and g) diagnosing malfunction of the purge valve if the criterion C is lower than a predetermined threshold value Cs.

Methods and systems are provided for conducting an engine-off-natural-vacuum (EONV) test diagnostic on a vehicle fuel system and evaporative emissions system. In one example, a method may include setting an initial vent duration for the EONV test as a function of a likelihood that the vehicle will pass the EONV test during a pressure phase portion, or during a vacuum phase portion, and commencing the EONV test with the vacuum phase portion responsive to the likelihood that the vehicle will pass during the vacuum phase portion. In this way, battery power may be conserved and fuel economy improved, by avoiding a pressure phase portion of the EONV test if it is indicated that the vehicle is not expected to pass the EONV test during the pressure phase portion.