Disclosed is a urea tank and fuel tank assembly, which belongs to the field of automobile parts. The urea tank and fuel tank assembly includes a shell, wherein the shell includes an upper shell, a middle shell and a lower shell, the upper shell, the middle shell and the lower shell are welded separately to form a cavity including a fuel cavity. The urea tank and fuel tank assembly is welded after injection molding, so that not only is the shell uniform in wall thickness and high in mechanical strength, but also the welding stress is dispersed to the upper and lower ends of the shell by setting that the upper shell, the middle shell and the lower shell are welded separately, on the one hand, the stress concentration of the welded part of the shell is reduced and the cracking of the welded part is avoided.

A motor vehicle tank comprises a main tank that includes at least one main extraction unit that has a main flow line for extracting fuel from the main tank; an auxiliary tank arranged adjacent to and connected with the main tank, the auxiliary tank including: an auxiliary extraction unit having an auxiliary flow line for extraction of fuel from the auxiliary tank, and a filler connection for direct filling of the auxiliary tank; a partition wall which separates the auxiliary tank from the main tank by a partition wall, the partition wall having a lower partition wall region without an opening in an installation position, and an upper partition wall region having at least one opening to form an overflow between the auxiliary tank and the main tank.

A dual-fuel tank houses one or more compressed natural gas (CNG) vessels and one or more diesel fuel vessels. The diesel fuel vessels are generally disposed laterally outwardly from the CNG vessels to provide a buffer that protects the CNG vessels from side impacts. The dual-fuel tank may be retrofit onto a diesel locomotive in place of the locomotive's diesel fuel tank to convert the locomotive into a dual-fuel locomotive. The dual-fuel tank may be provided in a ship.

A fuel supply system for a road vehicle and having: a fuel tank, which is shaped like saddle due to the presence of a central saddle and delimits an inner volume divided into an upper area, which is located above the central saddle, and two lower areas, which are located under the upper area and are separated from one another by the central saddle; two low-pressure fuel pumps, which each suck from the bottom of a corresponding lower area; at least one high-pressure fuel pump, which receives fuel from both low-pressure fuel pumps; a level sensor arranged in the upper area and configured to measure a fuel level only in the upper area; and two level sensors, each arranged in a respective lower area and configured to measure a fuel level only in the respective lower area.

A vehicle tank having a container and a pair of spaced apart baffle plates directly connected to walls of the container to define a swirl pot. The baffle plates have at least one orifice which lies spatially above the swirl pot, and within the swirl pot, the baffle plates have valves to allow an inflow of fuel into the swirl pot.

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.

A tank system for a reducing agent includes: a vessel configured to store the reducing agent, the vessel having: an upper vessel wall, lateral vessel walls, and a lower vessel wall; and a conveying device, the conveying device being configured to provide the reducing agent under pressure by way of an outlet to an exhaust gas. One or more openings are arranged in the lower vessel wall the one or more openings forming a connection to a further volume (V) filled with reducing agent. At least one opening of the one or more openings has radially inwardly directed elements arranged on a circumference of the at least one opening.

A tank arrangement, wherein the fuel tank body comprising a main portion and a secondary portion which comprises an upper portion and an intermediate portion arranged successively along the vertical direction, configured to define a housing to accommodate the urea tank, wherein in an engaged configuration, the urea tank is arranged under the upper portion of the secondary portion along the vertical direction, in abutment on the intermediate portion along the transverse direction, and in abutment on the primary portion along the front-rear direction, wherein the urea tank comprises a urea drain on a lower portion of the urea tank along the vertical direction, the secondary portion of the fuel tank comprises a groove that extends through the fuel tank along the transverse direction, adapted to allow ducts to go through the secondary portion of the fuel tank along the transverse direction to be connected to the urea tank.

The present disclosure relates to a fuel tank having a module pot, which forms a first separate fuel reservoir for a fuel pump arranged inside the fuel tank. To prevent a gap in delivery of fuel to supply the first fuel reservoir in certain operating conditions, in particular when there is persistent lateral acceleration, according to the invention, a second separate fuel reservoir arranged separately from the first fuel reservoir inside the fuel tank is proposed, such that fuel is transferred from the second fuel reservoir into the first fuel reservoir at least when a predetermined acceleration level acting on the fuel tank is exceeded.

Liquid reservoir systems are disclosed. In one embodiment, a liquid reservoir system may capture and retain a fuel reservoir to provide an un-interrupted fuel supply to a fuel pump or pickup line during low fuel conditions such as those that may be experienced during vehicle acceleration, braking or side to side maneuvers. It may also capture and retain a fuel reservoir to provide an un-interrupted fuel supply to a fuel pump or other pickup line during periods of high agitation such as may be experienced during vehicle jumping, cross country/closed course racing and other aggressive driving maneuvers.