Abstract: A vehicle lift system includes a vehicle lift operable to lift a vehicle to be serviced by a technician. The vehicle lift includes lifting components for engaging and lifting the vehicle at liftable structures of the vehicle. Electrodes are positioned on the lifting components of the vehicle lift. The electrodes are operable to make electrical contact with the liftable structures of the vehicle when the lifting components engage the liftable structures. A voltage detector system is in electrical communication with the electrodes. The voltage detector system is operable to detect voltages at the electrodes capable of harming the technician. The voltage detector system is also operable to send a warning signal to the technician indicating that a harmful voltage has been detected on the electrodes when the electrodes make electrical contact with the liftable structures of the vehicle.

Abstract: Disclosed is an electronic level control device for a vehicle having an air suspension system, for example a trailer vehicle having an air suspension system, the vehicle comprising a chassis having an axle and at least two wheels arranged on the axle, wherein an air spring is arranged between the axle and the chassis for at least one of the wheels, wherein an electronic control unit can initiate a level controlling procedure by actuating a solenoid valve, and wherein at least one capacitive level sensor is provided for the axle. The distance between the chassis and the at least one axle can be determined by the level sensor.

Abstract: An air spring for a motor vehicle having a rolling bellows filled with gas under pressure, one end of the rolling bellows is connected to a load receiver and the other end is fastened to a roll-off piston?. The load receiver and the roll-off piston are moveable relative to one another depending on a force impinging on the load receiver toward the roll-off piston. A sensor device is arranged inside the rolling bellows by which a distance between the load receiver and the roll-off piston is detected. A pressure piece extending in direction of the roll-off piston is arranged at the load receiver and a sensor body is movably drivable along a sensor track of the sensor device by an end region of the pressure piece facing the roll-off piston. The sensor device generates an electric signal corresponding to the position of the sensor body on the sensor track.

Abstract: A mechanical circuit breaker unit for interrupting a line includes a contact arrangement and an electromagnetic drive. The contact arrangement has first and second fixed contacts and a guided moving contact. The electromagnetic drive moves the moving contact. The separating unit can assume a first state and a second state. No electric connection exists between the first and second fixed contacts in the first state. The moving contact electrically connects the two fixed contacts to each other in the second state. The separating unit can be transferred from the second state into the first state by moving the moving contact. The second fixed contact has a recess for receiving the moving contact, and the moving contact engages at least partly into the recess when the separating unit is in the first state.

Abstract: A vehicle controlling apparatus includes: a vertical acceleration sensor configured to detect a vertical acceleration of a sprung mass; a power-source attitude controller configured to compute a power-source attitude control amount for a driving force outputted from a power source, the control amount making the acceleration detected by the vertical acceleration sensor an appropriate acceleration for attaining a target sprung-mass state, and to control the power source based on the power-source attitude control amount; a stroke sensor configured to detect a stroke speed of a shock absorber; and a friction-brake attitude controller configured to compute a brake attitude control amount for a braking force outputted from a friction brake, the control amount making the stroke speed detected by the stroke sensor an appropriate stroke speed for attaining a target sprung-mass state, and to control the friction brake based on the brake attitude control amount.

Abstract: In a position sensor, two field sensors are placed along a line parallel to the movement to be detected. Two magnets are placed at an angle to each other to generate a magnetic field such that their position is a linear or approximately linear function of the difference between the outputs of the sensors.

Abstract: A method for controlling a pneumatic spring assembly of a motor vehicle includes deriving discrete condition parameters from a condition of the motor vehicle, wherein the discrete condition parameters are combined into parameter sets. Each parameter set is furthermore associated with a defined height control behavior, and wherein a height control behavior that is associated with a specific condition of the vehicle is set by activating at least one valve of the pneumatic spring assembly.

Abstract: A vehicle air suspension system includes at least two spring bellows assigned to pneumatic springs on opposite vehicle sides of a vehicle axle. The springs can be connected via connection lines, each of which is provided with a level-regulating valve, to a main pressure line and can be shut off with respect thereto. The main pressure line can be connected via a main pressure valve alternately to a compressed air source and to a compressed air sink. The connection lines of the spring bellows are connected to each other via a connection line provided with a throttle and can be shut off by a shut-off valve. A mechanically activatable shut-off valve is coupled to one of the level-regulating valves arranged on the offside of the vehicle such that the shut-off valve is open when the level-regulating valve is closed and is closed when the level-regulating valve is open.

Abstract: A vehicle has a frame, at least one front wheel connected to the frame, at least one front suspension assembly connecting the at least one front wheel to the frame, at least one rear wheel connected to the frame, and at least one rear suspension assembly connecting the at least one rear wheel to the frame. At least one of the at least one front and at least one rear suspension assemblies includes an air spring. A seat is connected to the frame. An engine is connected to the frame and is operatively connected to at least one of the wheels. An air compressor is connected to the frame and fluidly communicates with the at least one air spring for supplying air to the at least one air spring. A control unit is electrically connected to the air compressor for controlling an operation of the air compressor.

Abstract: A device for springing a mass including a fluid spring and a frame, in which the fluid spring is arranged between the mass and the frame in such a way that the mass is mounted on the frame in a sprung and/or damped manner. An add-on-fluid volume device for providing an additional fluid volume for the fluid spring includes at least two fluid volume chambers that can be fluidically connected to one another and which have a common, displaceable chamber wall.

Abstract: A gas spring assembly includes a gas spring and a height control module. The gas spring includes a first end member, a second end member and a flexible wall secured therebetween. The height control module includes a height control system that is operatively associated with the gas spring. The height control system includes a sensor, a valve arrangement and a fixed-logic control circuit. A suspension system and a method are also included.

Abstract: A vehicle fluid suspension control system includes a fluid supply adapted to fluidly communicate with a lift mechanism in the vehicle. A circuit board is connected to the fluid supply and exhausts fluid from the lift mechanism when the kneel switch is activated. The circuit board may also open a flowpath from the fluid supply to the lift mechanism when a kneel switch is deactivated and the brake pedal is depressed. A manifold may be in fluid communication with the fluid supply and the lift mechanism and may include a supply flowpath and an exhaust flowpath. The control system may be programmed with a height averaging adjustment delay, which determines whether the average height of the vehicle during a period of time is outside of a predetermined range. The control system may make corresponding adjustments to bring the height of the vehicle within the predetermined range.

Abstract: An adjustment device for suspension means in wheel suspensions of motor vehicles, with the suspension means having a first spring, for example a bearing spring that is arranged between the assembly of the motor vehicle and wheel guide elements, and/or a second spring, for example a preloaded spring that is connected in parallel or in series, as well as an electrically-actuated actuator, by means of which a force adjustment between the motor vehicle assembly and the wheel guide elements is made possible. According to the invention, the electric actuator is provided with an integrated brake or lock that acts in a bistable manner in such a way that in the unpowered state, it can occupy an open or closed position, and can be switched by means of electric actuation from the open to the closed position and vice versa.

Abstract: A height controlling apparatus for controlling at least one actual height as a relative position of (a) a body of a vehicle and (b) at least one wheel of the vehicle relative to each other, the apparatus including at least one height controlling actuator which changes the at least one actual height; and an actuator control device which controls the at least one height controlling actuator so that the at least one actual height approaches at least one target height.

Abstract: A suspension system adaptable for cross-flow operation includes a plurality of gas springs, a transfer passage in communication between the gas springs, and a transfer valve for selectively permitting gas flow along the transfer passage. A control system selectively actuates the transfer valve. A method of operation is also described.

Abstract: An air-bag suspension system for a motorcycle having a motorcycle main frame, fender struts extending outwardly from the main frame, and a swing arm pivotally mounted to the main frame about a pivot axis. The air-bag suspension system includes shock absorber assemblies each having an air-bag. The air in the air-bags is generated by an on-board compressor and released through a solenoid valve. The air-bag suspension system replaces the standard coil spring hydraulic suspension commonly found on motorcycles and provides a greater range of adjustment, remotely controlled, while the motorcycle is in use. The air-bag suspension system accommodates heavier loads than the stock suspension systems when the air-bags are fully inflated; and when deflated completely, provide an aesthetically pleasing stance. The range of wheel travel provided allows the rider to adjust the suspension to provide the smoothest ride coupled with an increased load capacity or adverse road conditions.

Abstract: The present invention is intended for use with a motor vehicle having at least one fluid-pressurized height adjusting member having first and second separable components. Apparatus constructed in accordance with the invention includes an integrated vehicle ride height system control system. The control system includes an electronic output drive signal circuit and input signal interpretation circuit to electronically interface with at least one position sensor. The position sensor provides output signals related to extent of separation of said first and second separable components of the fluid pressurized height adjusting member.