Provided are a material feeding mechanism, a multi-material unit and a 3D printing system. The material feeding mechanism includes a main body, an unloading clutch assembly connected to the main body, and a driver assembly configured to drive the unloading clutch assembly to be switchable between a first position relative to the main body and a second position relative to the main body. In the first position, the unloading clutch assembly is drivingly coupled to a reel to rotate the reel under driving of the driver assembly to wind a wire around the reel. In the second position, the unloading clutch assembly is drivingly separated from the reel.

A reel system that includes a drum that receives a coil of flexible pipe. A first flange that removably couples to a first side of the drum. A second flange that removably couples to a second side of the drum. The first flange and the second flange secure the coil of flexible pipe to the drum.

A reel support apparatus (100) for supporting a pipeline storage reel (102) on a vessel (104) is disclosed. A method for supporting a pipeline storage reel (102) on a vessel (104) using the reel support apparatus (100) is also disclosed. The reel support apparatus (100) comprises a hub body (112) for locating within a hollow central bore (140) of a pipeline storage reel (102) and a plurality of discrete roller elements (114), spaced apart at locations on an outer surface of the hub body (112). In use, a pipeline storage reel (102) is supported by the plurality of discrete and spaced apart roller elements (114).

A reel support apparatus (100) for supporting a pipeline storage reel (102) on a vessel (104) is disclosed. A method for supporting a pipeline storage reel (102) on a vessel (104) using the reel support apparatus (100) is also disclosed. The reel support apparatus (100) comprises a hub body (112) for locating within a hollow central bore (140) of a pipeline storage reel (102) and a plurality of discrete roller elements (114), spaced apart at locations on an outer surface of the hub body (112). In use, a pipeline storage reel (102) is supported by the plurality of discrete and spaced apart roller elements (114).

A pipe puller system and methods of pipe extraction are shown. In one example a pipe to be replaced is pulled by attaching a pulling force to multiple locations along a length of the pipe. In one example pulling forces can be varied between different attachment locations to better control or eliminate tearing of the pipe. In one example, a pipe loosening device may be used prior to pulling the pipe from the ground.

A pipe puller system and methods of pipe extraction are shown. In one example a pipe to be replaced is pulled by attaching a pulling force to multiple locations along a length of the pipe. In one example pulling forces can be varied between different attachment locations to better control or eliminate tearing of the pipe. In one example, a pipe loosening device may be used prior to pulling the pipe from the ground.

Disclosed herein are stackable cable payout devices and systems for converting cable payout systems to stackable systems. Methods of stacking cable payout devices, such as cable reel rollers are also disclosed herein. Stacking systems disclosed herein may be adjustable, and may accommodate materials commonly available at storage facilities. Devices, systems, and methods disclosed herein allow increased efficiency in storage of cable payout machinery.

Disclosed herein are stackable cable payout devices and systems for converting cable payout systems to stackable systems. Methods of stacking cable payout devices, such as cable reel rollers are also disclosed herein. Stacking systems disclosed herein may be adjustable, and may accommodate materials commonly available at storage facilities. Devices, systems, and methods disclosed herein allow increased efficiency in storage of cable payout machinery.

A filament container for housing a spool of filament comprising a base and a lid that define an inner volume. The lid rotatably attached to the base and moveable between a closed position, wherein the inner volume is substantially sealed, and an open position, wherein the inner volume is accessible. First and second horizontal shafts are supported rotatably within the inner volume, parallel to and spaced from one another a distance, and rotatable about a respective longitudinal axis. The first and second horizontal shafts are adapted to support a spool of filament vertically within the inner volume and to allow the spool of filament to freely rotate about a horizontal axis that is parallel to and spaced from the longitudinal axis of each of the first and second horizontal shafts as filament is pulled from the spool and out of the filament container.

A filament container for housing a spool of filament comprising a base and a lid that define an inner volume. The lid rotatably attached to the base and moveable between a closed position, wherein the inner volume is substantially sealed, and an open position, wherein the inner volume is accessible. First and second horizontal shafts are supported rotatably within the inner volume, parallel to and spaced from one another a distance, and rotatable about a respective longitudinal axis. The first and second horizontal shafts are adapted to support a spool of filament vertically within the inner volume and to allow the spool of filament to freely rotate about a horizontal axis that is parallel to and spaced from the longitudinal axis of each of the first and second horizontal shafts as filament is pulled from the spool and out of the filament container.