A mounting and dismounting system for a battery assembly is disclosed. The system may be located onboard of an electric vehicle powered by a battery pack disposed in the battery assembly. The system includes a pair of four-bar linkages that can be used to raise and lower the battery assembly. Each four-bar linkage includes a pair of hooks with different vertical positions. The hooks are positioned to grasp horizontal mounting bars that are disposed on the battery assembly. Using vertically displaced hooks ensures the battery can be raised and lowered without rocking.

The invention provides a new design of an intelligent pooling vehicle and trailer system equipped with an intelligent pooling vehicle and an intelligent electric powered trailer capable to improve the efficiency of the system, avoid off-tracking and make the system more user friendly. The rear powered tires train is capable to turn around a pivot, taking different positions with respect to the trailer. The independent electric motors on each tire of the trailer rear tires train provide additional power to the vehicle and steering capability of the trailer rear tires train. This allows better control of the rear of the trailer and instead to be only pull by the truck, the trailer may be driven by it self, by using different speeds on each of the two tires, avoiding accidents and helping back parking and driving. The system may work in automatic or manual mode.

The invention provides a new design of an intelligent pooling vehicle and trailer system equipped with an intelligent pooling vehicle and an intelligent electric powered trailer capable to improve the efficiency of the system, avoid off-tracking and make the system more user friendly. The rear powered tires train is capable to turn around a pivot, taking different positions with respect to the trailer. The independent electric motors on each tire of the trailer rear tires train provide additional power to the vehicle and steering capability of the trailer rear tires train. This allows better control of the rear of the trailer and instead to be only pull by the truck, the trailer may be driven by it self, by using different speeds on each of the two tires, avoiding accidents and helping back parking and driving. The system may work in automatic or manual mode.

The present invention relates to a gas tank arrangement (100) for an internal combustion engine (102), said gas tank arrangement (100) comprising a gas tank (104) for containing a combustible gas, a first fuel pump (106) arranged downstream said gas tank (104) and arranged to increase the pressure level of the combustible gas to a first pressure level, wherein the gas tank arrangement (100) further comprises a second fuel pump (108) arranged downstream the first fuel pump (106) and arranged to increase the pressure level of the combustible gas to a second pressure level, wherein said second pressure level is higher than said first pressure level.

Provided is a compressed natural gas (CNG) fuel system that can include a frame and at least one container. The frame can include a first side and a second side, with each side being configured to partly define a portion of an interior space. The at least one container can be configured to house or contain CNG and can be engaged to and partly encased by the frame. The at least one container can be partly located within the interior space of at least one of the first side or the second side. The frame assembly can be engaged to a chassis of a vehicle such that the at least one container is located either at least partially underneath a cab of the vehicle or at least partially behind a cab of the vehicle.

The invention relates to a method for operating a vehicle/trailer unit, an appropriately designed vehicle/trailer unit, as well as a towing vehicle and an implement for such a vehicle/trailer unit, with the vehicle/trailer unit having a towing vehicle and an implement. The towing vehicle has a combustion engine and a first machine that can be operated as a prime mover, as well as a first axle that can be driven by means of the combustion engine, with it being possible for the combustion engine to be driven by means of the first machine. The implement has a second machine that can be operated as a work machine and a second axle that is mechanically coupled with the second machine. When the vehicle/trailer unit is in overrun mode and/or braking mode, the vehicle/trailer unit can be operated in a first operating mode in which the second machine is operated as a work machine and driven by means of the mechanical kinetic energy of the second axle, while the first machine is operated as a prime mover and drives the combustion engine, with it being possible for at least a portion of the energy generated by the second machine to be utilized to drive the first machine.

A through the road (TTR) hybridization strategy is proposed to facilitate introduction of hybrid electric vehicle technology in a significant portion of current and expected trucking fleets. In some cases, the technologies can be retrofitted onto an existing vehicle (e.g., a truck, a tractor unit, a trailer, a tractor-trailer configuration, at a tandem, etc.). In some cases, the technologies can be built into new vehicles. In some cases, one vehicle may be built or retrofitted to operate in tandem with another and provide the hybridization benefits contemplated herein. By supplementing motive forces delivered through a primary drivetrain and fuel-fed engine with supplemental torque delivered at one or more electrically-powered drive axles, improvements in overall fuel efficiency and performance may be delivered, typically without significant redesign of existing components and systems that have been proven in the trucking industry.

A heavy haul vehicle has a chassis capable of supporting a load to be transported by the vehicle. A first group of one or more first drive axles and a second group of one or more second drive axles are coupled to the chassis. The vehicle also has a first engine and a second engine. The first engine drives each axle in the first group of drive axles. The second engine drives each axle in the second group drive axles.

A method is provided for predicting a risk for rollover of a working machine for load transportation. The method includes: obtaining ground topographic data of a geographical area located close to the working machine from a ground topographic detection system; extracting a ground gradient from the ground topographic data; obtaining weight information of the load being currently transported by means of an on-board load weighting system or by receiving load information originating from the device that loaded the load being currently transported; determining a current maximal allowed ground gradient for the working machine based on the weight information; and predicting a risk for working machine rollover if the working machine approaches a geographical area including a ground gradient exceeding or being close to the current maximal allowed ground gradient for the working machine.

An integrated fill system is provided for a vehicle. The integrated fill system can include a receptacle, a cap that mates with the receptacle, and a fill line that is in fluid communication between the receptacle and a container. The integrated fill system can further include a valve between an opening on an end of the container and an end of the fill line to allow one-way fluid communication for entry of compressed material into the container. The integrated fill system can further include a draw line on an opposite end of the container to maintain separate lines for filling and drawing compressed material into/from the container.