A pedal device includes a base disposed on an inner wall surface of a vehicle body, a pedal pad movable relative to the base, and a pad fixation portion configured to fix the pedal pad to be immovable relative to the base.

A pedal device includes a base disposed on an inner wall surface of a vehicle body, a pedal pad movable relative to the base, and a pad fixation portion configured to fix the pedal pad to be immovable relative to the base.

A potentiometer device has a tubular body, an actuation shaft, splines, spline-receiving cavities, a potentiometer, a tubular housing, first and second annular cavities and retention balls. The splines are externally positioned about the actuation shaft. The spline-receiving cavities are internally positioned around the tubular body. The potentiometer has a housing body and a wiper pin. The tubular body is connected to the housing body. The tubular housing and the wiper pin are positioned within the housing body. The tubular housing is connected to the housing body. The wiper pin is mechanically coupled to the actuation shaft. The actuation shaft is removably positioned within the tubular body and the housing body. The first annular cavity internally and radially traverses into the tubular housing. The second annular cavity externally and radially traverses into an output coupling end of the actuation shaft. The retention balls are engaged within the first annular cavity.

A potentiometer device has a tubular body, an actuation shaft, splines, spline-receiving cavities, a potentiometer, a tubular housing, first and second annular cavities and retention balls. The splines are externally positioned about the actuation shaft. The spline-receiving cavities are internally positioned around the tubular body. The potentiometer has a housing body and a wiper pin. The tubular body is connected to the housing body. The tubular housing and the wiper pin are positioned within the housing body. The tubular housing is connected to the housing body. The wiper pin is mechanically coupled to the actuation shaft. The actuation shaft is removably positioned within the tubular body and the housing body. The first annular cavity internally and radially traverses into the tubular housing. The second annular cavity externally and radially traverses into an output coupling end of the actuation shaft. The retention balls are engaged within the first annular cavity.

A lighting control operating unit generating digital adjusting commands which are transmitted to a processing unit via a data link includes several control elements, including key buttons, slide controls and/or rotary controls, which are disposed at the upper side of a housing. At least one dual encoder is provided in a control panel of the lighting control operating unit allowing users to enter input values. The dual encoder presents a first shaft rotatably mounted in a housing, and a second shaft mounted in the housing so as to be coaxially rotatable, and corresponding first and second rotation signal generators Both shafts include actuating elements transmitting adjusting movements. The actuating elements are a rotary disk and/or a rotary swivel configured to be coaxially turned in opposite directions.

A lighting control console for controlling a lighting system includes at least one digital processor, at least one digital memory, and at least one display device configured to graphically depict graphic elements for users. At least one dual encoder is provided in the control panel, which allows users to enter input values. The dual encoder presents a first shaft rotatably mounted in a housing with a first rotation signal generator and a second shaft mounted in the housing so as to be coaxially rotatable at the dual encoder. Both shafts include actuating elements transmitting adjusting movements onto the shafts. The actuating elements are embodied in a rotary disk and/or of a rotary swivel disposed in the control panel of the lighting control console and configured to be coaxially turned in opposite directions.

A locking mechanism for releasably locking a lock bolt against axial movement, the mechanism comprising an axially moveable member, arranged to move axially with the lock bolt biasing means, arranged to bias the piston towards the lock bolt; rotation means in threaded engagement with the piston such that rotation of the rotation means causes axial movement of the piston, and a solenoid assembly arranged to prevent rotation of said rotation means in a locked state, the solenoid assembly comprising: a solenoid plunger having a solenoid tip and a solenoid arranged to cause movement of the solenoid plunger relative to the rotation means, the solenoid assembly arranged such that in a locked state the solenoid causes the solenoid tip to engage with the rotation means such as to prevent rotation thereof, thus preventing axial movement of the piston.

A locking mechanism for releasably locking a lock bolt against axial movement, the mechanism comprising an axially moveable member, arranged to move axially with the lock bolt biasing means, arranged to bias the piston towards the lock bolt; rotation means in threaded engagement with the piston such that rotation of the rotation means causes axial movement of the piston, and a solenoid assembly arranged to prevent rotation of said rotation means in a locked state, the solenoid assembly comprising: a solenoid plunger having a solenoid tip and a solenoid arranged to cause movement of the solenoid plunger relative to the rotation means, the solenoid assembly arranged such that in a locked state the solenoid causes the solenoid tip to engage with the rotation means such as to prevent rotation thereof, thus preventing axial movement of the piston.

A method for operating an input device. An input element of the input device is manually operated to perform an input into a computer device operatively connected to the input device. Mobility of the input element can be selectively delayed, blocked, and enabled by a controllable magneto-rheological braking device. The mobility of the input element is selectively adjusted by the computer device at least as a function of at least one input condition stored in the computer device. The input device may be a computer mouse.

A method for operating an input device. An input element of the input device is manually operated to perform an input into a computer device operatively connected to the input device. Mobility of the input element can be selectively delayed, blocked, and enabled by a controllable magneto-rheological braking device. The mobility of the input element is selectively adjusted by the computer device at least as a function of at least one input condition stored in the computer device. The input device may be a computer mouse.