A removable spoiler or vehicle stabilizing apparatus for a pickup truck having a truck bed is provided. The spoiler comprises a spoiler shell constructed and arranged to fit securely on the truck bed, an interior spoiler frame, at least one mounting support configured to securely support the spoiler on the truck bed, and a plurality of spoiler securement and lifting elements. The spoiler may easily be installed or removed from the truck even while the truck is hitched to a travel trailer, camper trailer or the like. The spoiler may be installed or removed with any suitable device, such as a crane, jack, jack stands, cherry picker, auto cherry picker, travel trailer tongue-mounted lift/crane, lifts, roll on/off platform or the like. The spoiler may also be used as a multipurpose device, and may provide a golf cart enclosure, and may further comprise at least one utility shelf.

A removable spoiler or vehicle stabilizing apparatus for a pickup truck having a truck bed is provided. The spoiler comprises a spoiler shell constructed and arranged to fit securely on the truck bed, an interior spoiler frame, at least one mounting support configured to securely support the spoiler on the truck bed, and a plurality of spoiler securement and lifting elements. The spoiler may easily be installed or removed from the truck even while the truck is hitched to a travel trailer, camper trailer or the like. The spoiler may be installed or removed with any suitable device, such as a crane, jack, jack stands, cherry picker, auto cherry picker, travel trailer tongue-mounted lift/crane, lifts, roll on/off platform or the like. The spoiler may also be used as a multipurpose device, and may provide a golf cart enclosure, and may further comprise at least one utility shelf.

A system is used for lifting a heavy oversized structural element. At least two opposing lifts are placement adjacent opposing sides of the element. Each lift includes a base, a tower, an elevator, and an actuator. The tower extending vertically from the base, and the elevator is disposed on the tower. A support extends from the elevator outward from the tower to engage a point on the element. A guide of the elevator is configured to ride along a rail of the tower. The actuator is connected to the elevator and is configured to move with the elevator vertically along the tower. The actuator can include a strand jack disposed on the elevator. Hydraulic operation of the stand jack moves the jack and elevator along a strand extending along the tower. The arrangements of the lifts leave space below the raised element free for access to other operations.

A system is used for lifting a heavy oversized structural element. At least two opposing lifts are placement adjacent opposing sides of the element. Each lift includes a base, a tower, an elevator, and an actuator. The tower extending vertically from the base, and the elevator is disposed on the tower. A support extends from the elevator outward from the tower to engage a point on the element. A guide of the elevator is configured to ride along a rail of the tower. The actuator is connected to the elevator and is configured to move with the elevator vertically along the tower. The actuator can include a strand jack disposed on the elevator. Hydraulic operation of the stand jack moves the jack and elevator along a strand extending along the tower. The arrangements of the lifts leave space below the raised element free for access to other operations.

A vehicle leveling device for ensuring that a vehicle is level for calibration of sensors that are installed on the vehicle is presented. A lifting jack is placed under each of the vehicle's wheels and a mounting clamp is mounted to each wheel. Each mounting clamp has a sizing frame having two ends, a clamping member slidably mounted upon each end of the sizing frame and a pair of pivotally mounted engagement hooks. A support member mounted central to the sizing frame that supports an indicator that allows a level reading to be taken. The lifting jacks may be actuated under each of the vehicle's wheels as needed the ever level indicator reads the same indicating that each wheel is coplanar and the vehicle is level.

A vehicle leveling device for ensuring that a vehicle is level for calibration of sensors that are installed on the vehicle is presented. A lifting jack is placed under each of the vehicle's wheels and a mounting clamp is mounted to each wheel. Each mounting clamp has a sizing frame having two ends, a clamping member slidably mounted upon each end of the sizing frame and a pair of pivotally mounted engagement hooks. A support member mounted central to the sizing frame that supports an indicator that allows a level reading to be taken. The lifting jacks may be actuated under each of the vehicle's wheels as needed the ever level indicator reads the same indicating that each wheel is coplanar and the vehicle is level.

According to embodiments of the present invention, an apparatus for adjusting a wind turbine system is provided. The apparatus includes a structure including a top surface opening and a bottom surface opening opposite to the top surface opening, the structure configured to receive a mast of the wind turbine system through the top surface opening and the bottom surface opening; a jacking mechanism operable to raise or lower the structure with respect to the mast; and a locking mechanism configured to releasably secure the structure to the wind turbine system. According to further embodiments, a mast of a wind turbine system, a system including the apparatus and the mast, and a method for adjusting a wind turbine system are also provided.

According to embodiments of the present invention, an apparatus for adjusting a wind turbine system is provided. The apparatus includes a structure including a top surface opening and a bottom surface opening opposite to the top surface opening, the structure configured to receive a mast of the wind turbine system through the top surface opening and the bottom surface opening; a jacking mechanism operable to raise or lower the structure with respect to the mast; and a locking mechanism configured to releasably secure the structure to the wind turbine system. According to further embodiments, a mast of a wind turbine system, a system including the apparatus and the mast, and a method for adjusting a wind turbine system are also provided.

A vehicle lift system configured for wireless charging is disclosed. The vehicle lift system includes a vehicle lift and a light transmitter. The vehicle lift includes a base, a carriage, a lift actuator, a battery, and a photovoltaic receiver. The carriage is configured for receiving a wheel of a vehicle. The lift actuator is configured to vertically raise and lower the carriage relative to the base. The battery is configured to provide electrical energy to the vehicle lift. The photovoltaic receiver is electrically coupled with the battery. The light transmitter is configured for transmitting electrical energy to said photovoltaic receiver. Thus, the battery of the vehicle lift can be recharged wirelessly, such that the vehicle lift need not have a wired power connection.

A vehicle lift system configured for wireless charging is disclosed. The vehicle lift system includes a vehicle lift and a light transmitter. The vehicle lift includes a base, a carriage, a lift actuator, a battery, and a photovoltaic receiver. The carriage is configured for receiving a wheel of a vehicle. The lift actuator is configured to vertically raise and lower the carriage relative to the base. The battery is configured to provide electrical energy to the vehicle lift. The photovoltaic receiver is electrically coupled with the battery. The light transmitter is configured for transmitting electrical energy to said photovoltaic receiver. Thus, the battery of the vehicle lift can be recharged wirelessly, such that the vehicle lift need not have a wired power connection.