A dual reservoir fuel tank, wherein the fuel tank comprises a main fuel reservoir having an inner wall and an outer wall that define a main reservoir chamber, and an auxiliary fuel reservoir connected to a bottom of the main fuel reservoir. The dual reservoir fuel tank additionally includes a fuel retention lip structured and operable to retain fuel within the auxiliary reservoir chamber when the dual reservoir fuel tank is disposed at an angle.

An apparatus and a method are provided for an alternative fuel system, comprising a plurality of fuel tank assemblies interconnected with fuel lines; the plurality of fuel tank assemblies comprising a CNG fuel tank and a fuel tank shield; wherein a first and second fuel tank assembly is disposed immediately in front of a rear wheel assembly, and a third fuel tank assembly is disposed immediately behind the rear wheel assembly.

A midfloor module (10, 11) for a motor vehicle has a frame structure (10) with a battery frame (10). The battery frame (10) has multiple battery modules (11), and multiple tank volumes (1, 2, 2+) that can be used optionally for fuel. A motor vehicle that is equipped with such a midfloor module (10, 11) also is provided as well as a method for manufacturing the midfloor module (10,11).

An apparatus and a method are provided for a compressed natural gas fuel system configured to replace a motor vehicle's fuel system comprising a storage assembly comprising an enclosure, wherein the enclosure contains a plurality of tanks configured to contain compressed natural gas; and a chassis disposed within the enclosure and configured to retain the plurality of tanks, wherein the storage assembly is configured to be mounted to the roof of a motor vehicle.

A high-pressure container unit includes: a box-shaped case mounted on a vehicle and configured to include a bottom portion, a ceiling portion, and a peripheral wall portion; a plurality of container main bodies arranged in an interior of the case and each having a cylindrical body portion; and a reinforcing member extending along an axial direction of the container main body, the reinforcing member being provided in at least one of a space surrounded by the container main bodies adjacent to each other and the bottom portion and, a space surrounded by the container main bodies adjacent to each other and the ceiling portion.

Presented are battery assemblies with integrated fuel tanks, methods for making/using such battery assemblies, and fuel cell electric vehicles having rechargeable traction battery packs with integrated fiber-composite hydrogen fuel tanks. A rechargeable energy storage system (RESS) assembly includes a battery pack housing with an internal battery module compartment located between two tank mounting cavities. Each mounting cavity is recessed into a respective lateral side of the battery pack housing. Multiple rechargeable battery modules are electrically interconnected with one another and mounted inside the battery module compartment. Each battery module contains multiple battery cells, such as a stack of series-connected lithium-ion pouch cells. A fuel tank is mounted in each of the tank mounting cavities on the lateral sides of the battery pack housing. Each fuel tank, which may be fabricated from a carbon fiber reinforced polymer, stores and selectively dispenses a fuel, such as a hydrogen-rich, compressed gas fuel.

A fuel delivery unit for use within a vehicle fuel tank includes: a surge tank arranged on a wall of the fuel tank, a feed line extending from a region of the surge tank to a connector stub on the flange, and a wiring harness extending from the fuel pump to the flange. A flange-side holder forms a first force application point for fixing the wiring harness on a flange side, and a surge tank-side holder forms a second force application point for fixing the wiring harness on the surge tank side. The wiring harness, the flange-side holder and the surge tank-side holder together form a force absorber configured to protect the feed line and the connector stub during a vehicle impact by absorbing kinetic energy from the impact acting on the fuel delivery unit, thereby dissipating the kinetic energy.

A low-profile liquid storage tank and vehicles incorporating same. An exemplary low-profile liquid storage tank may define an interior volume having an upper surface that defines an access port, and a lower surface that includes a fluid impingement portion positioned below the access port. The impingement portion may include two or more undulations formed in or on the lower surface of the tank, the undulations adapted to assist with reducing splash-back of fluid added to the tank through the access port.

Systems and methods for operating a fuel system that includes two separate fuel tanks are disclosed. In one example, fuel may be purged from a fuel rail in response to Reid vapor pressure of a fuel so that engine starting may be improved. A fuel with a higher Reid vapor pressure may be pumped into the fuel rail when the engine is expected to be cold started.

A container holding mechanism is applied to a fuel cell vehicle including a driving mechanism capable of driving rear wheels and disposed on a side of the rear wheels. The container holding mechanism includes a first hydrogen gas, a second hydrogen gas, a third hydrogen gas container, and a moving unit. The first hydrogen gas container is disposed behind a rear drive shaft. The second hydrogen gas container is disposed in front of the rear drive shaft. The third hydrogen gas container disposed in parallel with the second hydrogen gas container in front of the rear drive shaft. The moving unit is configured to move the driving mechanism pushed out by the first hydrogen gas container in collision in such a manner that the driving mechanism avoids the second hydrogen gas container and the third hydrogen gas container.