A first, and second twin AC inverters for a hybrid vehicle, whereby, the first and second inverters having a first, and second twin AC hard wire terminal blocks, a cool-down C-D process, and a conventional Engine Control Unit computerized remote-control drive system, whereby, being capable of activating the twin AC terminal blocks for Freeway speed, hills, faster acceleration, and a hybrid vehicle momentum regenerative braking kinetic energy process for: charging a battery-pack, and multiple batteries. The computer being capable of activating the first terminal block, when the cool-down process is to end, and deactivating the second terminal block, when the cool-down process is to began. The Computer is capable of activating the first, or second terminal blocks, whereby, for operating in conjunction with one another for the Freeway speed for charging the battery-pack, including multiple batteries with respect to the above modification.

An energy storage system for a military vehicle includes a battery housing defining a lower end and an upper end, a battery disposed within the battery housing, a bracket coupled to the battery housing at or proximate the upper end thereof, a lower support supporting the lower end of the battery housing, and an upper connector extending from the bracket. The upper connector is configured to engage a rear wall of a cab of the military vehicle.

Techniques pertaining to an autonomous police vehicle are described. A method may involve a processor associated with an autonomous vehicle obtaining an indication of violation of one or more traffic laws by a first vehicle. The method may also involve the processor maneuvering the autonomous vehicle to pursue the first vehicle. The method may further involve the processor remotely executing one or more actions with respect to the first vehicle.

A military vehicle including an engine coupled to the chassis for providing mechanical power to the military vehicle, a motor/generator coupled to the engine, and an energy storage system including a battery electrically coupled to the motor/generator. The military vehicle is operable in a silent mobility mode with the engine inactive and the energy storage system providing power to the motor/generator to operate the military vehicle. The motor/generator and the battery are sized such that electrical power generation through engine drive of the motor/generator is greater than the power depletion through operation of the military vehicle in the silent mobility mode. The motor/generator can charge the energy storage system while the military vehicle is driving or stationary.

A driveline including a motor/generator configured to receive power from an engine and output power to a tractive element, an accessory drive configured to receive power from the engine and output power to an accessory, and an energy storage system including a battery, the energy storage system electrically coupled to the motor/generator and the accessory drive. The driveline is operable in a charge mode with the motor/generator and the accessory drive providing electrical power to the energy storage system. The driveline is operable in a silent mobility mode with the energy storage system providing electrical power to the motor/generator and the accessory drive to operate the military vehicle.

A military vehicle includes a chassis, a cargo body, and an energy storage system. The chassis includes a passenger capsule having a rear wall. The cargo body is positioned behind the passenger capsule and supported by the chassis. The energy storage system includes a battery housing defining a lower end and an upper end, a battery disposed within the battery housing, a bracket coupled to the battery housing at or proximate the upper end thereof, a lower support supporting the lower end of the battery housing where the lower support is supported by the chassis, and an upper connector extending between the bracket and the rear wall.

The disclosure relates to an autonomously driving vehicle for traveling on an unpaved terrain section, comprising an assessment device and a control device, wherein the assessment device has a soil condition determination device for determining a condition parameter which is representative of the current soil condition of the terrain section, a storage device for storing a drivability dependence of acquired historic slipping data of the vehicle on the condition parameter, and an evaluation device, which determines a discrete drivability prediction of the terrain section by the vehicle based on the drivability dependence and the determined condition parameter. The control device is designed to control the vehicle based on the drivability prediction to drive on the terrain section. Furthermore, the disclosure relates to a computer-implemented control method for controlling the autonomously driving vehicle and a computer program product.

A military vehicle includes a chassis, a front end accessory drive (FEAD), and circuitry. The chassis includes an engine and an integrated motor generator (IMG). The FEAD includes multiple accessories and an electric motor-generator. The circuitry is configured to operate the military vehicle according to different modes. The circuitry is configured to receive a user input indicating a selected mode of the modes, and operate the chassis and the FEAD of the military vehicle according to the selected mode. The modes include an engine mode and an electric mode. In the engine mode, the engine drives the FEAD and the tractive elements of the military vehicle through the IMG for transportation. In the electric mode, the engine is shut off to reduce a sound output of the military vehicle and the IMG drives the tractive elements of the military vehicle for transportation and the electric motor-generator drives the FEAD.

A driveline for a military vehicle includes a driver configured to be positioned between an engine and a transmission. The driver includes a housing, a motor/generator, and a clutch. The housing includes an engine mount configured to couple to the engine and a backing plate configured to couple to the transmission. The motor/generator is disposed within the housing and configured to couple to an input of the transmission. The clutch is disposed within the housing and coupled to the motor/generator. The clutch is configured to selectively couple an output of the engine to the motor/generator.

A military vehicle includes a front axle, a rear axle, and a driveline. The driveline includes an engine, an energy storage system, an accessory drive coupled to the engine, a second motor coupled to at least one of the front axle or the rear axle, and a clutch positioned between the engine and the second motor. The accessory drive includes a first motor and a plurality of accessories. The first motor is electrically coupled to the energy storage system. The plurality of accessories include an air compressor. The second motor electrically is coupled to the energy storage system. The clutch is spring-biased into engagement with the engine and pneumatically disengaged by an air supply selectively provided thereto based on operation of the air compressor. The first motor is configured to drive the air compressor to pneumatically disengage the clutch to decouple the second motor from the engine.