An aerial work platform having an electric rotary actuator for electrically rotating the aerial work platform. The aerial work platform includes a housing support to which an electric motor is mounted, the electric motor having output shaft that meshes with a compound planetary gearset disposed within a main gear housing. The planetary gearset is used to actuate a rotary shaft to which is attached a rotary bracket that supports an aerial work platform. An electric brake is disposed adjacent one of the rotary shaft or the motor output shaft to prevent rotation of a shaft when the motor is not energized or when loss of power occurs. The electric rotary actuator can be energized to rotate the aerial work platform in a lateral plane.

An aerial work platform having an electric rotary actuator for electrically rotating the aerial work platform. The aerial work platform includes a housing support to which an electric motor is mounted, the electric motor having output shaft that meshes with a compound planetary gearset disposed within a main gear housing. The planetary gearset is used to actuate a rotary shaft to which is attached a rotary bracket that supports an aerial work platform. An electric brake is disposed adjacent one of the rotary shaft or the motor output shaft to prevent rotation of a shaft when the motor is not energized or when loss of power occurs. The electric rotary actuator can be energized to rotate the aerial work platform in a lateral plane.

A towable crash-attenuating vehicle is shown having a frame; at least two axles coupled to the frame, each of the axles having wheels attached thereto; a T-shaped ballast coupled to the frame, and oriented such that the weight of the ballast is biased toward the front end of the frame; deflection shields coupled to the right and left sides of the frame, wherein the deflection shields cover the frame and a majority of the wheels on each side of the vehicle; a tow connection coupled to the front of the frame, pivotable from a deployed state to an undeployed state; an impact attenuator coupled to the rear of the frame; wherein the vehicle is provided with a brake system, and wherein said brake system may be locked and unlocked and wherein the vehicle is provided with an on-board mechanism for locking and unlocking the brake system.

An arrangement and method for mounting a brake disc to an axle hub of a vehicle is provided. The arrangement includes wedge-shaped holes at an radially inner region of the brake disc, corresponding wedge-shaped key inserts, a retaining device such as a retaining ring, and mounting devices such as bolts or studs and nuts that pass through the retaining ring and keys to bias the keys against the axle hub. The circumferential sides of the wedge shapes are aligned with radial lines extending from the rotation axis of the axle hub. This arrangement and method provides a simple, robust and easily installed brake disc mounting that minimizes heat transfer between the brake disc and the axle hub and accommodates thermal expansion of the brake disc and the axle hub to minimize thermal expansion-induced stresses to the brake disc.

An arrangement and method for mounting a brake disc to an axle hub of a vehicle is provided. The arrangement includes wedge-shaped holes at an radially inner region of the brake disc, corresponding wedge-shaped key inserts, a retaining device such as a retaining ring, and mounting devices such as bolts or studs and nuts that pass through the retaining ring and keys to bias the keys against the axle hub. The circumferential sides of the wedge shapes are aligned with radial lines extending from the rotation axis of the axle hub. This arrangement and method provides a simple, robust and easily installed brake disc mounting that minimizes heat transfer between the brake disc and the axle hub and accommodates thermal expansion of the brake disc and the axle hub to minimize thermal expansion-induced stresses to the brake disc.

A system and method having a magnetic brake apparatus configured to be operable for slowing or stopping motion with magnetic or electromagnetic force. An electromagnetic coil appliance generates the magnetic or electromagnetic force when power is applied to the electromagnetic coil appliance. A brake control module is configured to be operable for controlling the magnetic brake apparatus. A controller implement of the brake control module is configured to be operable for processing a program instruction to control an operation of the magnetic brake apparatus where a full-bridge driver coupled to the controller implement, applies power the electromagnetic coil appliance. A receiver device is configured to supply a control signal to the controller implement.

A system and method having a magnetic brake apparatus configured to be operable for slowing or stopping motion with magnetic or electromagnetic force. An electromagnetic coil appliance generates the magnetic or electromagnetic force when power is applied to the electromagnetic coil appliance. A brake control module is configured to be operable for controlling the magnetic brake apparatus. A controller implement of the brake control module is configured to be operable for processing a program instruction to control an operation of the magnetic brake apparatus where a full-bridge driver coupled to the controller implement, applies power the electromagnetic coil appliance. A receiver device is configured to supply a control signal to the controller implement.

A power takeoff mechanism utilizes intermeshing gears as a PTO power transfer mechanism to transfer rotational power from a power takeoff input shaft to an offset power takeoff output shaft. The PTO power transfer mechanism is supported in a fluid-tight housing mounted on the rearward side of the transfer case of a four wheel drive vehicle. A braking apparatus is operably connected to the drive gear and includes a piston, a biasing spring coupled with the piston and a pressure apparatus that keeps the spring from moving the piston until the drive has been disengaged from the power takeoff input shaft. The speed of operation of the PTO output shaft can be selectively varied by changing the ratio of the respective diameters of the drive gear and driven gear within the PTO power transfer mechanism.

A power takeoff mechanism utilizes intermeshing gears as a PTO power transfer mechanism to transfer rotational power from a power takeoff input shaft to an offset power takeoff output shaft. The PTO power transfer mechanism is supported in a fluid-tight housing mounted on the rearward side of the transfer case of a four wheel drive vehicle. A braking apparatus is operably connected to the drive gear and includes a piston, a biasing spring coupled with the piston and a pressure apparatus that keeps the spring from moving the piston until the drive has been disengaged from the power takeoff input shaft. The speed of operation of the PTO output shaft can be selectively varied by changing the ratio of the respective diameters of the drive gear and driven gear within the PTO power transfer mechanism.

A lift device comprises a base, a retractable lift mechanism, a work platform, a linear actuator, and a descent control mechanism. The base has a plurality of wheels. The retractable lift mechanism has a first end coupled to the base and is moveable between an extended position and a retracted position. The work platform is configured to support a load. The work platform is coupled to and supported by a second end of the retractable lift mechanism. The linear actuator is configured to selectively move the retractable lift mechanism between the extended position and the retracted position. The linear actuator has an electric motor. The descent control mechanism is configured to reduce a speed at which the retractable lift mechanism is moved from the extended position to the retracted position.