A spreader (10) for lifting an intermodal transport container (22) comprises a main beam (24) extending in a longitudinal direction (L), the main beam formed of a first, upper C-beam of a relatively thicker material thickness and a second, lower C-beam of a relatively thinner material thickness; and an indicator configured to provide an indication if a distance in a transversal direction (T) between a pair of twist-locks (18) is set in a wide-body position when lowered onto respective lifting castings (20) provided with top openings (50) separated by a transversal distance corresponding to a standard position.

A side lift spreader main beam (22) comprises a vertical carrier plate (58) having a first vertical height (H1) and being made of steel plate having a first thickness (T1); a C-beam (60) comprising a first horizontal flange (64) and a second horizontal flange (66) interconnected by a vertical web portion (68), the C-beam (60) having a second vertical height (H2) lower than the first vertical height (H1) and being made of steel plate having a second thickness (T2) thinner than the first thickness (T1), wherein the C-beam (60) defines, together with the carrier plate (58), a closed channel beam with a first flange (74) of the carrier plate (58) extending vertically from the closed channel beam; and an inclined support plate (62) welded to the carrier plate, and to an outer face of the first flange (64) of the C-beam (60) at a distance from the carrier plate (58).

A device for installing and handling a module of a subsea processing station, comprises a frame, and a hydraulic system comprising hydraulic cylinders each comprising a cylinder body, and a piston intended to be put into contact with a foot and movable inside the cylinder body between a first mechanical abutment corresponding to a deployed position of the piston and a second mechanical abutment corresponding to a retracted position of the piston. The piston divides the internal volume of the cylinder body into a first chamber and a second chamber. The first chamber is supplied with hydraulic fluid by two independent hydraulic circuits comprising a shock-absorbing circuit able to move the piston between the deployed and intermediate positions located between the deployed position and the retracted position defined by a hydraulic abutment, and a controlled-lowering circuit able to move the piston between the intermediate position and its retracted position.

An apparatus for handling bulk material, the apparatus comprising a spreader configured for attachment to a crane, the spreader having a spreader body having a first engagement formation. The apparatus includes a bulk material storage cradle having a first side member and a second side member, the first and second side members defining two opposing longitudinal side walls which are spaced relative to each other to define an internal bulk material storage receptacle. The bulk material storage cradle has a second engagement formation, and at least one gate member having a proximal end hingedly connected to a lower portion of the first side member and a distal end having a third engagement formation configured to selectively engage with a fourth engagement formation located at a lower portion of the second side member. The first engagement formation is selectively engageable with the second engagement formation to secure the spreader to the bulk material storage cradle. The third engagement formation is selectively disengageable from the fourth engagement formation to release the gate member from the second side member.

A spreader for lifting an intermodal transport container includes a main beam extending in a longitudinal direction, the main beam formed of a first, upper C-beam of a relatively thicker material thickness and a second, lower C-beam of a relatively thinner material thickness; and an indicator configured to provide an indication if a distance in a transversal direction between a pair of twist-locks is set in a wide-body position when lowered onto respective lifting castings provided with top openings separated by a transversal distance corresponding to a standard position.

An apparatus and method for lifting and collapsing a collapsible cargo container includes a frame, and vertical guides for aligning the actuator with the cargo container. First and second pusher assemblies engage the end walls of the container to pivot the end walls against the ceiling of the container, where uplocks retain the end walls in a stowed away position. Foldable side walls are then buckled by the weight of the ceiling with assistance from the actuator, until the side walls occupy a predominantly horizontal position between the ceiling/end wall combination and a floor of the cargo container, resulting in a compact configuration. The actuator unfolds the container using steps discussed above in a reverse order.

An automated storage and retrieval system comprises a rail system comprising a first set of parallel tracks arranged in a horizontal plane and extending in a first direction, and a second set of parallel tracks arranged in the horizontal plane and extending in a second direction which is orthogonal to the first direction, which first and second sets of tracks form a grid pattern in the horizontal plane comprising a plurality of adjacent grid cells, each comprising a grid opening defined by a pair of neighboring tracks of the first set of tracks and a pair of neighboring tracks of the second set of tracks; and a plurality of stacks of storage containers arranged in storage columns located beneath the rail system. Each storage column is located vertically below a grid opening. A container handling vehicle comprises a transport mechanism for transport of the vehicle on the rail system, a lifting assembly for picking up storage containers from the storage columns to a position above the lowest level of the transport mechanism. The lifting assembly comprises a lifting frame connectable to a storage container, a first lifting shaft and a second lifting shaft, the first and second lifting shafts being mainly parallel, and each of the first and second lifting shafts being supported in an upper portion of the vehicle, two lifting elements extending from each of the first and second lifting shafts to the lifting frame, a motor drive assembly comprising at least a first motor, wherein the at least first motor encircles one of the lifting shafts, and a force transferring assembly rotatably connecting the first and second lifting shafts via a force transferring element.

Embodiments of this document provides improved safety logic for a mobile container handler of the reach stacker or top pick type. The improved logic involves limitations surrounding the hoist function of the machine subsequent to attaching to a shipping container. This improvement addresses damage to the container spreader caused by abrupt joystick hoist inputs by the operator immediately subsequent to attaching onto a shipping container. Due to space between the spreader arms and spreader body, which is so designed to facilitate movement of the arms inside the spreader body, sudden vertical movement of the spreader results in impact forces being exerted on various parts of the spreader body and spreader arms. These impacts accelerate fatigue leading to premature catastrophic failure of the spreader body and/or spreader arms' structural steel.

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 lid assembly for a portable biochar kiln and system is disclosed. An example of a lid assembly includes a cylindrical sidewall, a rim around the cylindrical sidewall, and a top portion having an opening formed therein. A removable stack is configured to fit over the opening formed in the top portion to direct exhaust from the portable biochar kiln. A gasket cover is interchangeable with the removable stack to fit over the opening formed in the top portion to form a substantially airtight seal over the opening formed in the top portion when a burn is complete in the portable biochar kiln to self-extinguish embers in the portable biochar kiln.