An electric vehicle is configured to be able to perform running by an MT mode that controls an electric motor with a torque characteristic like an MT vehicle having a manual transmission and an internal combustion engine, and running by an EV mode that controls the electric motor with a normal torque characteristic. The electric vehicle includes a mode changeover switch for switching to the running by the MT mode.

The controller of the electric vehicle is configured to control the torque of the electric motor using the MT vehicle model based on the operation amount of the accelerator pedal, the operation amount of the pseudo-clutch pedal, and the shift position of the pseudo-shifter. The electric vehicle also includes a pedal reaction force generator that generates a pedal reaction force in response to the operation of the pseudo-clutch pedal using by the operating of the reaction force actuator. The controller is configured to store the pedal reaction force characteristic simulating the characteristic of the pedal reaction force according to the operation of the clutch pedal. Then, the controller is configured to control the pedal reaction force output by the pedal reaction force generator in response to the operation of the pseudo-clutch pedal using the stored pedal reaction force characteristic.

The electric vehicle according to the present disclosure is configured to be able to select a traveling mode between an MT mode in which an electric motor is controlled with torque characteristics like an MT vehicle having a manual transmission and an internal combustion engine, and an EV mode in which the electric motor is controlled with normal torque characteristics. The controller of the electric vehicle controls the electric motor in the MT mode such that responsiveness of the motor torque with respect to a change in the operation amount of the accelerator pedal is lower than in the EV mode.

A movable machine including a chassis, a tool coupled to the chassis, an operator control carried by the chassis and a controller. The controller is communicatively coupled to the operator control. The controller being configured to send a force feedback and/or a vibration feedback to the operator control thereby conveying information to the operator. The information is not related to a load encountered by the tool.

An operation device includes a support for pivotally supporting a shift lever, a first movable member configured to be pivotally operated from home position in a direction in conjunction with the shift lever, a pair of permanent magnets supported, at an operation reference position, by the support so as to be opposite the first magnetic body, and first plate springs for biasing the first movable member in a direction in which the first magnetic body moves toward the permanent magnets.

A standing pedal is provided for a vehicle, comprising a support, a pedal arm, a rocker, a return spring for forcing the pedal arm into a direction of an idle position of the pedal arm, and a power transmission element. The return spring is linked to the support and the rocker in a power transmitting manner. The power transmission element is linked to the pedal arm and the rocker in a power transmitting manner. In order to provide a standing pedal for a vehicle, which is robust and shows an enhanced durability, the pivot axis of the pedal arm and the power transmission element are located on a common first side of the rocker with respect to a basic part of the rocker.

In order to provide a pedal for a motor vehicle in which restoration of the pedal arm to its rest position is improved, it is proposed that a friction system has a rocker and the first return spring is disposed between the separate friction element and the rocker such that when the pedal arm moves in the direction of its maximum actuation position, the rocker is pressed against a friction surface of the separate friction elements in a friction force-generating manner, wherein the separate friction element is connected to the pedal arm in a compressive force-transmitting manner by means of the at least one first return spring, a bearing part for a second return spring, and a connecting element, and wherein the second return spring is disposed between the bearing part and the base part or the bearing part and the rocker.

An electronic pedal assembly may include a pedal platform and at least one force sensor configured to sense a force applied to the pedal platform. One or more control devices may be communicatively coupled to the force sensor(s) and configured to determine a throttle output for controlling the throttle condition of the vehicle based at least in part on the force applied to the pedal platform and based at least in part on an operating condition associated with operating the vehicle. In some embodiments, the force sensor(s) may be configured to measure a force distribution on the pedal platform. The control device(s) may monitor the force distribution and adjust an operation of the vehicle based on the force distribution. The operation of the vehicle can include controlling the throttle condition of the vehicle or an operation that is different from controlling the throttle condition of the vehicle.

Disclosed is a vehicle accelerator pedal that may include a cylindrical hinge unit, a lever unit having one side configured to operate in a first direction and another side formed to correspond to an inner circumferential edge of the hinge unit and configured to operate in a second direction opposite the first direction. An outer circumferential edge may be configured to come into close contact with an upper inner circumferential edge of the hinge unit such that a moment of force is applied in a first rotation direction by the hinge unit. An elastic unit having one side may be configured to elastically support one side of the lever unit, the other side formed to correspond to the inner circumferential edge of the hinge unit. An outer circumferential edge may be configured to come into close contact with a lower inner circumferential edge of the hinge unit.

A pedal assembly, including an upper housing and a lower housing with an upper surface positioned below the upper housing. A receiving cavity is positioned in the lower housing, with at least a portion positioned below the upper surface in the pedal assembly vertical direction. A pedal arm having a pivot end and an opposite pedal pad, pivotally coupled to the upper housing at the pivot end. The pedal arm is movable between a stowed position and a use position, wherein in the stowed position, the pedal pad is positioned in the receiving cavity and below the upper surface in the pedal assembly vertical direction such that access to the pedal pad is prohibited. In the use position, the pedal pad is positioned above the receiving cavity and the upper surface in the pedal assembly vertical direction such that access to the pedal pad is permitted.