An exemplary thermal management system includes, among other things, a valve, a radiator loop configured to be connected to the valve, a power electronics loop configured to be connected to the valve, a heater loop configured to be connected to the valve, and a battery loop configured to be connected to the valve. The valve is configured to connect one or more of the radiator, power electronics, heater, and battery loops together and the valve is configured to isolate at least one of the radiator, power electronics, heater, and battery loops from any remaining loops of the radiator, power electronics, heater, and battery loops.

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.

An under body structure of an automobile enabling batteries to be mounted on an automobile by a simple configuration and efficiently transferring load at the time of a collision, that is, an under body structure 100 of an automobile provided with a body floor 110 forming a floor part of the automobile and batteries 50 (battery cells or battery modules) directly suspended from and fastened to a bottom side of the body floor 110.

An electrical generation system for a vehicle includes a vehicle having a generator for producing electric current. The vehicle has a cavity having a fan and a radiator. The radiator is in fluid communication with the generator to allow a temperature of the generator to be controlled. An air inlet passage extends through a wall of the vehicle and is configured to direct air from outside the vehicle toward an inlet side of the radiator to provide increased static pressure of the air to the inlet side of the radiator compared to an ambient pressure of the air when the vehicle is in motion.

Vehicle battery pack comprising a support structure comprising, in turn, at least two elongated perimeter members facing one another and defining, between them, a box portion; several bulkheads arranged so to divide the box portion delimiting at least two housings, wherein the bulkheads are arranged transversely to the two perimeter elements facing one another; a plurality of planar, electrically connected electrochemical cells parallel both to one another and to the bulkheads and divided into at least two modules, wherein said at least two modules each comprise at least two insertion plates arranged at the ends of each module, parallel to the bulkheads, and configured to facilitate the insertion of each module under compression into the respective housing, so that the compression remains even after the insertion.

Control unit for a vehicle battery pack comprising at least one module provided with a plurality of electrochemical cells carried on board a support structure; the control unit comprising a planar support substrate made of an at least partially insulating material; a plurality of sensor elements; wherein the sensors elements are arranged, on the support substrate, in two rows so as to be each positioned, once the unit is installed on board the vehicle battery pack, in the area of a respective terminal pole of each electrochemical cell; wherein the sensor elements comprise at least one voltage sensing device, which comprises at least two conductor and elastically deformable contact element, which are configured to be elastically compressed between the planar support substrate and the respective terminal pole.

A method for operating a cooling system of a motor vehicle for cooling at least one component, a cooling system of a motor vehicle for cooling at least one component, and a motor vehicle having such a cooling system. The cooling system has a coolant circuit and a refrigerant circuit. The coolant circuit serves for cooling the at least one component and the refrigerant circuit and the coolant circuit are coupled thermally to one another via a heat exchanger. The coolant circuit has a conveying device for conveying a coolant in the coolant circuit. A cooling power of the refrigerant circuit can be regulated. The regulation of the cooling power of the refrigerant circuit is realized in a manner dependent on a return temperature of the coolant and/or on a temporal development of the return temperature of the coolant.

A lubricant supply system for an electric vehicle includes a lubricant supported electric motor and a lubricant supply line extending from a high pressure source to the lubricant supported electric motor for supplying lubricant to the lubricant supported electric motor. In one arrangement, at least one powertrain component is disposed in fluid communication with the lubricant supply line and fluidly connected in parallel with the lubricant supported electric motor for supplying lubricant to the powertrain component. In an alternative arrangement, the powertrain component is fluidly connected in series with and downstream from the lubricant supported electric motor for supplying lubricant from the lubricant supported electric motor to the powertrain component. In either arrangement, the lubricant supported electric motor is incorporated into an existing lubricant supply system of the vehicle to reduce cost and complexity relative to prior designs which required a dedicated lubricant supply for the lubricant supported electric motor.

A cooling system includes a shared path; a first path connected to the shared path and having a first pump and a first heat exchanger exchanging heat with an inverter; a second path connected to the shared path in parallel with the first path and having a second pump and a second heat exchanger exchanging heat with a battery. The first and second paths are configured to be able to switch a flow state between a first state where the heat media flow through the shared path, and a second state where one of the heat media does not flow through the shared path. The control device controls the outputs of the pumps so that when switching the flow state between the first and second states, flow rate of the heat medium flowing through the first path becomes temporarily larger than the target flow rate.

A cooling circuit arrangement includes first and second closed cooling circuits. Each closed cooling circuit has a heat source, a pump and a radiator. By way of the first pump of the first circuit, a coolant can be conveyed to the first radiator and from the first radiator to the first heat source and from the latter to the first pump. By way of the second pump of the second circuit, a coolant can be conveyed to the second radiator and can be conveyed from the second radiator to the second heat source and from the latter to the second pump. Downstream of the first pump and of the second pump, there is provided a first fluidic connection which is controllable by a first valve. Upstream of the first pump and the second pump, there is provided a second fluidic connection which is controllable by a second valve.