A handle-type integrated control device includes: a steering lever disposed to be movable in a width direction of a vehicle by a driver's operation; a handle housing disposed at an upper end of the steering lever and configured to rotate, in a front-to-rear direction of the vehicle, about one end of the steering lever by the driver's operation; a speed value receiver disposed at one end of the handle housing to receive an acceleration or deceleration change value; and a speed controller connected to the speed value receiver to receive the acceleration or deceleration change value from the speed value receiver.

A control method for moving an electromechanical parking brake, according to which method an actuator of the parking brake is moved by actuation by means of an actuator-control unit, wherein a writable, non-volatile memory unit is provided in which position data concerning the current actuator position of the actuator is stored so as to be readable and writable, and according to which method, when a write error occurs while writing the position data to the memory unit, the actuation of the actuator for moving said actuator is continued, and, when the write error is detected, a synchronization process is carried out independently of the actuation of the actuator so that, upon completion of this synchronization process, the position data stored in the memory unit correctly represents the actuator position of the actuator.

A passenger side driving instructor brake controller can include a telescoping shaft including a first end and a second end, and a brake lever connector disposed at the first end of a telescoping shaft and adapted to be secured to a brake lever of a motor vehicle disposed within a driver-side front floorboard area of the motor vehicle. A tubular main body bent near its mid-section, the tubular main body configured to adjustably accept the second end of the telescoping shaft therein and secure the telescoping shaft with locking hardware at a fixed position within the tubular main body to enable the main body to traverse over a main console of the motor vehicle where the tubular main body is bent at its mid-section and also to extend into a passenger compartment area of the motor vehicle wherein the tubular main body can terminate at a handle area.

Various examples of park brake interface modules which are utilized as human machine interfaces (HMI) in vehicles are provided. In one example, a park brake interface module for a vehicle includes an actuation member mounted to an electromechanical switch to actuate the park brake. The actuation member includes a finger pad opposite the front surface and the actuation member is movable between a brake apply position and a brake release position to actuate the vehicle park brake. In another example, the actuation member is pivotally mounted to the electromechanical switch device and the actuation member is pivotable between the brake apply position and the brake release positions to actuate the park brake.

A hydraulic control valve for an ATV or motorcycle takes hydraulic input from a hand brake lever as an input to a first cavity of the control valve with a movable piston therein, and from a foot brake lever as an input to a second cavity of the control valve with a movable piston therein, with the two pistons being linked. A bypass channel extends around the piston in the first cavity, which is closed off when the first piston moves longitudinally. The output of the first cavity hydraulically controls braking of the front wheel(s). The foot brake lever also pressurizes a direct line to brake the rear wheel(s) that doesn't go through the control valve.

A hydraulic control valve for an ATV or motorcycle takes hydraulic input from a hand brake lever as an input to a first cavity of the control valve with a movable piston therein, and from a foot brake lever as an input to a second cavity of the control valve with a movable piston therein, with the two pistons being linked. A bypass channel extends around the piston in the first cavity, which is closed off when the first piston moves longitudinally. The output of the first cavity hydraulically controls braking of the front wheel(s). The foot brake lever also pressurizes a direct line to brake the rear wheel(s) that doesn't go through the control valve.

A driver assistance system enables brake and accelerator operation by an operation bar in a manner close to a sense of a driver of a vehicle, regardless of the degree of operation of the operation bar. Embodiments include an operation bar extending downward toward a vehicle floor panel from a manual operation area where a seated driver manually operates the operation bar, and whose lower portion is supported in a slidingly displaceable manner along an axial direction in a front-down, rear-up tilted state. The operation bar includes a brake actuation section, below the manual operation area, that actuates a brake mechanism by sliding displacement of the operation bar in a front-down direction; and an accelerator actuation section that actuates an acceleration mechanism by sliding displacement of the operation bar in a rear-up direction that is a reverse direction on the same axis from the sliding displacement in the front-down direction.

A driver assistance system enables brake and accelerator operation by an operation bar in a manner close to a sense of a driver of a vehicle, regardless of the degree of operation of the operation bar. Embodiments include an operation bar extending downward toward a vehicle floor panel from a manual operation area where a seated driver manually operates the operation bar, and whose lower portion is supported in a slidingly displaceable manner along an axial direction in a front-down, rear-up tilted state. The operation bar includes a brake actuation section, below the manual operation area, that actuates a brake mechanism by sliding displacement of the operation bar in a front-down direction; and an accelerator actuation section that actuates an acceleration mechanism by sliding displacement of the operation bar in a rear-up direction that is a reverse direction on the same axis from the sliding displacement in the front-down direction.

A commercial vehicle includes at least one driven axle, a service brake, at least one propulsion engine, and wheels. A parking brake function of the vehicle is achieved by a bistable locking means that acts on both wheels. A first and second multi-speed gearbox having respective first and second gear stages are each activated by an actuator and coupled to the wheels. The parking brake function is achieved at least in-part by concurrently activating the first and second gear stages. A computing device is configured to activate the bistable locking means when the commercial vehicle is at a standstill and configured to send a brake request via an electronic signal to an electronic brake control unit to activate the service brake.

A hydraulic/mechanical braking system for a vehicle comprises a cam (128) keyed onto a transmission shaft or a trailing wheel and at least two hydraulic cylinder assemblies (126,129) including a cam follower (127). A hydraulic circuit (C) connects the hydraulic cylinder assemblies together. A master brake valve (113) controls the flow of fluid in the circuit. Actuation of the master brake valve (113) obstructs the flow of fluid and hence the reciprocation of the hydraulic cylinder assemblies, forcing the cam following against the cam to resist rotation. The system further comprises an energy recovery system configured to transfer energy from the hydraulic fluid flowing in the hydraulic circuit to generate electricity and/or to recover heat from the hydraulic fluid flowing in the hydraulic circuit.