A lifting apparatus (10) for a pulley (12), the apparatus (10) including: a first beam section (14) adapted to couple to the pulley (12) in a fitted condition; and a second beam section (16) connected to the first beam section (14) in a spaced apart relationship extending parallel to the first beam section (14). The second beam section (16) includes a lifting arrangement (20) including a pair of lift couplings (22) and a plurality of notches (24), the pair of lift couplings (22) being moveable between a first condition in which each one of the pair of lift couplings (22) are able to be moved between the plurality of notches (24), and a second condition in which each one of the pair of lift couplings (22) is substantially retained in a respective one of the plurality of notches (24). A related method of use is also disclosed.

A method for lifting a tank car is provided. The method can include positioning a lifting apparatus above a tank car, pulling at least one of the first arm and the second arm outward to place the lifting apparatus in an open configuration, lowering the lifting apparatus in the open configuration to surround a tank of the tank car, connecting the second end of the first arm to a first tank car support, connecting the second and of the second arm to a second tank car support, and raising the lifting apparatus to lift the tank car.

The lifting apparatus is a mechanical structure. The lifting apparatus is configured for use in manually lifting a load. The lifting apparatus attaches to the load such that a plurality of individuals are able to simultaneously lift the load. The lifting apparatus comprises a master beam, a grasping structure, and a rigging chain. The grasping structure and the rigging chain attach to the master beam. The plurality of individuals manipulate the lifting apparatus using the master beam. The grasping structure attaches the load to the master beam. The grasping structure adjusts to accommodate the form factor of the load. The rigging chain is a secondary attachment structure that attaches the load to the master beam such that the loading distribution of the load is balanced relative to the master beam such that the lifting apparatus is more easily manipulated by the plurality of individuals.

An example system includes an aerial vehicle, a sensor, and a winch system. The winch system includes a tether disposed on a spool, a motor operable to apply a torque to the tether, and a payload coupling apparatus coupled to the tether and configured to mechanically couple to a payload. The system also includes a repositioning apparatus configured to reposition the payload coupling apparatus in at least a horizontal direction. A control system is configured to control the aerial vehicle to deploy the payload coupling apparatus by unwinding the tether from the spool; receive, while the aerial vehicle hovers above the payload and from the sensor, data indicative of a position of the payload coupling apparatus in relation to the payload; and reposition, using the repositioning apparatus and based on the data, the payload coupling apparatus in the horizontal direction to mechanically couple to the payload.

A gripper assembly for a portable biochar kiln and system is disclosed. An example of a gripper includes an attachment for connecting to a loader, the attachment having a mating surface configured for engagement with the biochar kiln. The example gripper assembly also includes a substantially C-shaped claw having a first arm and a second arm. The example gripper assembly also includes a motor on the attachment. The motor operates to open and close the first and second arms in a pinch-and-release motion to grasp and release the biochar kiln. The motor further operates to rotate the first and second arms to tilt the biochar kiln for dumping operations. The motor further operates to raise and lower the first and second arms to raise and lower the biochar kiln relative to the ground for moving operations.

A boom mountable breaker system and a method of using same for interrupting electrical transmission through a portion of an energized conductor downstream of a desired break location. The method includes: mounting the jumper onto the energized conductor across the desired break location so as to form an electrically conductive first parallel electrical path; installing an in-line opener in the energized conductor at the desired break location on the energized conductor; positioning the breaker at the desired break location on the energized conductor, and electrically connecting the breaker, while open, across the desired break location and across the opposite ends of the jumper so as to form a second parallel electrical path when the breaker is closed; closing the breaker to thereby complete the second parallel electrical path; removing the jumper from across the desired break location; and, opening and then removing the breaker.

A medical device includes (a) a capsule including a lumen extending therethrough, a proximal end of the capsule including at least one window extending therethrough; (b) a bushing including a channel extending therethrough, a distal end including at least one arm extending distally therefrom such that a corresponding one of the arms is releasably engagable with a corresponding one of the windows; and (c) a core member including a locking portion and at least one engaging element. The locking portion is sized and shaped to be received within the channel of the bushing to apply a pressure to the arm such that the arm engages the windows. The engaging element extends laterally outward from a portion of the core member such that the engaging element engages a corresponding one of the arms to deform the arms radially inward and out of engagement with the windows.

A medical device includes (a) a capsule including a lumen extending therethrough, a proximal end of the capsule including at least one window extending therethrough; (b) a bushing including a channel extending therethrough, a distal end including at least one arm extending distally therefrom such that a corresponding one of the arms is releasably engagable with a corresponding one of the windows; and (c) a core member including a locking portion and at least one engaging element. The locking portion is sized and shaped to be received within the channel of the bushing to apply a pressure to the arm such that the arm engages the windows. The engaging element extends laterally outward from a portion of the core member such that the engaging element engages a corresponding one of the arms to deform the arms radially inward and out of engagement with the windows.

An apparatus for lifting and manipulating a heavy load by way of at least one pair of tongs and at least one hydraulic cylinder is disclosed. The load lifting apparatus may be configured such that it includes a first linkage, consisting of two pivotal linkage members, and a second linkage, having two pivotal linkage members. The load lifting apparatus may further have a set of tongs which includes two tong arms, and a hydraulic cylinder capable of actuating about one of the pivot points of the linkages. This configuration allows for the distance between the two tong arms to be adjusted according to the relative size of the load being engaged by the load lifting apparatus. A controller may actuate the hydraulic cylinder to adjust the distance between the tong arms.

An example system includes an aerial vehicle, a sensor, and a winch system. The winch system includes a tether disposed on a spool, a motor operable to apply a torque to the tether, and a payload coupling apparatus coupled to the tether and configured to mechanically couple to a payload. The system also includes a repositioning apparatus configured to reposition the payload coupling apparatus in at least a horizontal direction. A control system is configured to control the aerial vehicle to deploy the payload coupling apparatus by unwinding the tether from the spool; receive, while the aerial vehicle hovers above the payload and from the sensor, data indicative of a position of the payload coupling apparatus in relation to the payload; and reposition, using the repositioning apparatus and based on the data, the payload coupling apparatus in the horizontal direction to mechanically couple to the payload.