A yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.

A yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.

A yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.

A yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.

A system for handling, storing and transportation of an elongated element, the system includes a basket suitable for rotation about a central vertical axis. The basket includes an interior upright wall surrounding the central vertical axis, an exterior upright wall spaced from and exterior to the interior upright wall. The interior and exterior upright walls are connected to a floor, thereby defining an open-topped chamber for receiving the elongated element. The system further includes a plurality of pedestals and a transportable drive unit. The basket, on a surface of the floor facing the plurality of pedestals and the transportable drive unit, is provided with interfaces which cooperate with corresponding interfaces provided in the plurality of pedestals and the transportable drive unit.

A system for handling, storing and transportation of an elongated element, the system includes a basket suitable for rotation about a central vertical axis. The basket includes an interior upright wall surrounding the central vertical axis, an exterior upright wall spaced from and exterior to the interior upright wall. The interior and exterior upright walls are connected to a floor, thereby defining an open-topped chamber for receiving the elongated element. The system further includes a plurality of pedestals and a transportable drive unit. The basket, on a surface of the floor facing the plurality of pedestals and the transportable drive unit, is provided with interfaces which cooperate with corresponding interfaces provided in the plurality of pedestals and the transportable drive unit.

A strander apparatus includes a disk and a plurality of cradles, each of the cradles includes a reel and a cradle shaft, the cradle shaft extending in an axial direction from the disk. Each reel dispenses cable. The strander includes a main shaft, wherein the cradles are disposed on the cradle shafts radially about the main shaft. Planetary gears are disposed between the main shaft and the plurality of cradle shafts. The strander operates in one of a planetary mode and a rigid mode. In the planetary mode, while the main shaft rotates, the planetary gears are engaged to rotate each of the plurality of cradles on the respective cradle shafts. In the rigid mode, the planetary gears are disengaged.

A strander apparatus includes a disk and a plurality of cradles, each of the cradles includes a reel and a cradle shaft, the cradle shaft extending in an axial direction from the disk. Each reel dispenses cable. The strander includes a main shaft, wherein the cradles are disposed on the cradle shafts radially about the main shaft. Planetary gears are disposed between the main shaft and the plurality of cradle shafts. The strander operates in one of a planetary mode and a rigid mode. In the planetary mode, while the main shaft rotates, the planetary gears are engaged to rotate each of the plurality of cradles on the respective cradle shafts. In the rigid mode, the planetary gears are disengaged.

A seismic cable deployment system is equipped with a cable puller comprising a windlass. A seismic cable follows a cable path extending from a storage unit to the cable puller, where the cable path extends in a circumferential direction deflected around a cylindrical drum surface and confined between the cylindrical drum surface and a drum-side surface of a tension belt which is pressed against the cylindrical drum surface by two pulley rollers being disposed on either side of the cylindrical drum surface. A belt tensioner is configured to impart elastic tension to the tension belt and a motor is configured to impart rotational motion to the cylindrical drum surface and translational motion to the tension belt.

A seismic cable deployment system is equipped with a cable puller comprising a windlass. A seismic cable follows a cable path extending from a storage unit to the cable puller, where the cable path extends in a circumferential direction deflected around a cylindrical drum surface and confined between the cylindrical drum surface and a drum-side surface of a tension belt which is pressed against the cylindrical drum surface by two pulley rollers being disposed on either side of the cylindrical drum surface. A belt tensioner is configured to impart elastic tension to the tension belt and a motor is configured to impart rotational motion to the cylindrical drum surface and translational motion to the tension belt.