A method for detecting and visualizing of a fuel type used in a vehicle is disclosed and may include, determining measurement data of the fuel are determined by at least one sensor during at least one of filling of the vehicle with a fuel and operation of the vehicle with the fuel, evaluating measurement data of the fuel by a control unit of the vehicle, and based on the determined measurement data for the fuel activating, deactivating, and/or changing at least one function in any of the vehicle interior and an outer area of the vehicle.

A fuel-urea injection apparatus including a common inlet for a vehicle may include a filler neck including the common inlet, into which a fuel injection nozzle and a urea injection nozzle, are inserted, a detector detecting whether the injection nozzle inserted into the filler neck is the fuel injection nozzle or the urea injection nozzle, a switchover valve mounted at a common injection pipe connected to the filler neck, a urea injection pipe connected between a urea outlet of the switchover valve and a urea tank, a fuel injection pipe connected between a fuel outlet of the switchover valve and a fuel tank, and a controller controlling an operation of the switchover valve in accordance with the injection nozzle detected by the detector as being inserted into the filler neck to supply either fuel or urea to the corresponding outlet of the fuel and urea outlets.

In a fuel supply device for separating raw fuel into high-octane fuel and low-octane fuel and supplying the fuel, to arrange the structural components compactly and to facilitate sealing against fuel vapor, the fuel supply device (1) includes: a raw fuel tank (2) for storing raw fuel; a separator (6) provided inside the raw fuel tank to separate the raw fuel into high-octane fuel that contains a greater amount of components with high octane numbers than the raw fuel and low-octane fuel that contains a greater amount of components with low octane numbers than the raw fuel; and a high-octane fuel tank (5) provided inside the raw fuel tank to store the high-octane fuel separated from the raw fuel by the separator.

An integrated adsorbed gaseous fuel storage and delivery system comprising an adsorbent in a tank wherein the adsorbent has (a) an initial Working Storage capacity of at least about 140 v/v % at a storage tank pressure of 900 psig, (b) a residual loss of storage capacity that is no more than 10%, and (c) it releases adsorbed gaseous fuel via a pressure differential between the tank pressure the pressure out of the tank without the application of a vacuum to the tank or heat to the adsorbent. The system also comprises a filter capable of passing through the filter at a rate of at least 50 cubic feet of gaseous fuel per minute at 50 psi, a pressure regulator for adjusting the pressure of the filtered gaseous fuel to an operating pressure for a fuel injection system, and an electronic control module capable of operating the fuel injection system.

A fuel tank arrangement for a dual fuel internal combustion engine includes a fuel tank arranged to supply liquid fuel to the dual fuel internal combustion engine, wherein the fuel tank arrangement includes a return conduit connected to the fuel tank and configured to supply leaked fuel from the dual fuel internal combustion engine to the fuel tank, wherein the fuel tank arrangement includes a first fuel separation arrangement positioned in fluid communication between the fuel tank and an outlet to an ambient environment thereof.

A dual-fluid receptacle for a diesel vehicle includes an outer wall disposed on an outer surface of the vehicle. The outer wall defines a diesel receptacle for receiving diesel fuel, a diesel-exhaust receptacle adjacent the diesel receptacle for receiving a diesel-exhaust fluid, and a bridge portion disposed between the diesel and diesel-exhaust receptacles. The receptacles are configured to simultaneously receive the diesel fuel and diesel-exhaust fluid from a single fluid dispensing unit. This allows an operator to fill the vehicle with diesel fuel and diesel-exhaust fluid, simultaneously, from a single fluid dispensing unit. A projection extends from the outer wall proximate to at least one of the two receptacles. The projection is configured to cooperate with an engagement feature of the fluid dispensing unit to selectively enable dispensing of diesel.

A fluid dispensing apparatus is provided and is configured to dispense two fluids to a vehicle. A rigid diesel spout delivers diesel, while a urea spout is slidably disposed on the diesel spout and configured to deliver urea to the vehicle. The urea spout includes a guide that cooperates with a rail on the diesel spout such that insertion of the diesel spout into the vehicle can slide the urea spout relative the diesel spout. A valve in the urea spout includes an area for receiving a projection member on the vehicle to open the urea spout when inserted into the vehicle. The vehicle correspondingly includes a diesel intake and a urea intake. A projection or pin is provided to cooperate with the dispensing apparatus to open the valve and allow urea to flow into the vehicle.

An auxiliary fuel tank for a flexible fuel vehicle is provided. The auxiliary fuel tank is mounted to an auxiliary tank body for storing gasoline fuel and is installed in an engine compartment of a flexible fuel vehicle. The auxiliary fuel tank includes a canister that is coupled to the auxiliary tank body and has activated carbon therein. The canister is configured to collect fuel evaporation gas generated in the auxiliary tank body to supply fuel components to an engine.

The invention relates to a combination tank having a double-walled inner container for temperature-insulated accommodation of a cryogenic fluid, which inner container has an approximately circular cylindrical cross-section and is closed off with end-side caps, wherein an outer container for accommodating at least one operating material is configured around the inner container, which outer container has a jacket having an approximately rectangular cross-section and end walls supported on the inner container, which end walls either sit in the gussets that remain between inner container and jacket, or are touched or penetrated by the caps of the inner container.

An auxiliary fuel tank for a flexible fuel vehicle is provided. The auxiliary fuel tank is mounted to an auxiliary tank body for storing gasoline fuel and is installed in an engine compartment of a flexible fuel vehicle. The auxiliary fuel tank includes a canister that is coupled to the auxiliary tank body and has activated carbon therein. The canister is configured to collect fuel evaporation gas generated in the auxiliary tank body to supply fuel components to an engine.