A hybrid vehicle powertrain assembly includes a combustion engine, an electric machine, an input shaft, a ratchet mechanism, and a controller. The input shaft selectively couples the engine and electric machine. The ratchet mechanism includes a base integrated with a transmission housing, a camwheel fixedly coupled to the input shaft, a pawl, and an actuator to move the pawl. The controller is programmed to, in response to receipt of an engine brake command, output an engagement command to the actuator to move the pawl toward the camwheel for engagement to prevent the input shaft from spinning. A method for controlling a hybrid vehicle powertrain is also provided herein. The method includes, responsive to receipt of an engine brake command, outputting via a controller a command for a ratchet mechanism to engage an input shaft coupled to an engine to prevent the input shaft from spinning.

Systems and apparatuses include a cab floor defining a center plane, a seat slide actuator coupled to the cab floor and selectively moveable in a direction transverse to the center plane relative to the cab floor, and a seat supported by the seat slide actuator and moveable therewith.

An apparatus for determining a failure of an engine clutch is provided. The apparatus includes an engine clutch that is disposed between an engine generating power and a motor and a driving information detector that senses driving information including a shift speed stage, an engine speed, a motor speed, a SOC of a battery, and a vehicle speed. A controller then determines a driving mode of the engine from the detected driving information and determines whether oil leakage of the engine clutch is generated from the driving information and the driving mode.

Methods and systems are provided for a park lock system for an automatic transmission. In one example, a park lock system may include a slideable element coupled to a park rod, a lock slot formed by the slideable element, a cam coupled to an end of a shaft, the shaft positioned within a solenoid and moveable by energization of the solenoid, and a pivotable pawl adapted to couple with the lock slot. In one example, the pivotable pawl is coupled to the lock slot by energization of the solenoid, and a position of the slideable element is locked.

A control system for a hybrid vehicle to start an engine without causing a torque drop is provided. A combined planetary gear unit is configured in such a manner that an input element connected to the engine and an output element are situated between a reaction element connected to a first motor and a fixed element connected to a brake in a nomographic diagram. The first motor is selectively connected to the engine by a clutch. A controller is configured to start the engine by the first motor while engaging the brake to restrict rotation of the fixed element and engaging the clutch.

A thermal management system has a cooling medium circuit for cooling a brake of the vehicle, a heating medium circuit for cooling and/or heating one more of a battery, power electronics, a charging device, a component of an electric drive motor, or an interior of the vehicle. Also included is a heat transfer device for exchanging heat between the cooling medium circuit and the heating medium circuit, a coupling/decoupling unit, which couples a rotation of a rotor of the electric drive motor and a rotation of a drive wheel of the vehicle in a coupling position and decouples the rotor and the drive wheel in a decoupling position, and a control unit, which, when the vehicle is stationary, causes the coupling/decoupling unit to be in the decoupling position, such that the electric drive motor rotates the rotor and causes the brake to brake the rotation of the rotor.

An overheat prevention method includes an rpm comparison step of comparing an engine revolution per minute (rpm) speed with a preset rpm speed by a controller when requiring an engagement of an engine clutch, a temperature comparison step of comparing a temperature of a transmission clutch with a preset temperature by the controller when it is determined that the engine rpm speed is less than the preset rpm speed at the rpm comparison step, and a serial drive mode control step of releasing the engine clutch and engaging the transmission clutch, and controlling a hybrid starter generator (HSG) to charge a battery using engine power to provide driving power to a motor by the controller when it is determined that the temperature of the transmission clutch is higher than the preset temperature at the temperature comparison step.

A method for learning a contact point of an engine clutch configured to control connection of power between an engine and a motor of a hybrid vehicle is provided. The method includes performing a first learning of the contact point of the engine clutch by increasing a contact speed of the engine clutch and storing information of a first contact point learned by the first learning. A second learning of the contact point of the engine clutch is then performed by decreasing the contact speed of the engine clutch.

A hybrid system includes an engine, a speed change device, a differential device, a rotary machine, a first engagement device, a case, and a cover wall. The first engagement device is configured to shift the speed change device, and be actuated by hydraulic pressure. The first engagement device includes a first oil chamber. The rotary machine is arranged between the first engagement device and the engine. The case houses the rotary machine, the speed change device, the differential device, and the first engagement device, and is connected to the engine and has an opening on the engine side. The cover wall covers the opening, and operating oil is supplied to the first oil chamber via the cover wall.

An ECU executes control processing including the step of extracting amplitudes f1, f2 of a resonant zone when a traveling mode is in a hybrid traveling mode, the step of executing count processing, the step of starting a first resonance avoidance control when a first count value Nf1 is greater than a threshold value n(1), the step of starting a second resonance avoidance control when a second count value Nf2 is greater than a threshold value n(2), the step of releasing a clutch K2 when resonance continues even after elapse of a predetermined time period Tb from starting of the second resonance avoidance control, and the step of terminating the resonance avoidance control when predetermined time period Ta has elapsed from determination of occurrence of resonance.