A reel apparatus comprising a pipe; an outer flange assembly comprising two outer support walls connected to the pipe and wherein each outer support wall comprises an inner wall and an outer wall; an inner flange assembly comprising two inner support walls, wherein the inner flange assembly is rotated relative to the outer flange assembly and the pipe and wherein each inner support wall comprises an inner wall and an outer wall; and a motor assembly connected to the inner flange assembly and outer flange assembly, wherein the motor assembly is physically connect to the outer flange assembly and wherein the motor assembly is rotationally connected to the inner flange assembly.

Disclosed herein is a system and method of controlling a strander by wireless visual monitoring. In certain embodiments, a stranding system includes at least one vision device mounted to a rotating structure of a strander. The at least one vision device is configured to capture a view of at least a portion of a subunit reel of at least one of a set of payoff units of the rotating structure to generate vision data. The stranding system further includes at least one wireless communication module mounted to the rotating structure to receive and wirelessly transmit the vision data over a high-bandwidth data link. The stranding system is configured to proactively identify payout hazards of the subunit package (e.g., cable crossover) to, for example, prevent damage to the strander.

Disclosed herein is a system and method of controlling a strander by wireless visual monitoring. In certain embodiments, a stranding system includes at least one vision device mounted to a rotating structure of a strander. The at least one vision device is configured to capture a view of at least a portion of a subunit reel of at least one of a set of payoff units of the rotating structure to generate vision data. The stranding system further includes at least one wireless communication module mounted to the rotating structure to receive and wirelessly transmit the vision data over a high-bandwidth data link. The stranding system is configured to proactively identify payout hazards of the subunit package (e.g., cable crossover) to, for example, prevent damage to the strander.

Techniques for implementing and/or operating a pipe deployment system that includes pipe deployment equipment, in which a pipe drum having spooled thereon a pipe segment is to be loaded on the pipe deployment equipment, and a pulling device to be secured to an unspooled section of the pipe segment. The pulling device includes a device body having a first body arm and a second body arm, in which the device body is to be disposed around the unspooled section of the pipe segment, the first body arm is to be secured to a first cable branch, and the second body arm is to be secured to a second cable branch. The pulling device includes a first pipe grabber secured to the first body arm and a second pipe grabber secured to the second body arm such that the second pipe grabber and the first pipe grabber open towards one another.

Techniques for implementing and/or operating a pipe deployment system that includes pipe deployment equipment, in which a pipe drum having spooled thereon a pipe segment is to be loaded on the pipe deployment equipment, and a pulling device to be secured to an unspooled section of the pipe segment. The pulling device includes a device body having a first body arm and a second body arm, in which the device body is to be disposed around the unspooled section of the pipe segment, the first body arm is to be secured to a first cable branch, and the second body arm is to be secured to a second cable branch. The pulling device includes a first pipe grabber secured to the first body arm and a second pipe grabber secured to the second body arm such that the second pipe grabber and the first pipe grabber open towards one another.

A speed adjusting cable assembly in accordance with some example embodiments is configured for use with a cable feeder having at least one motor-driven roller configured to pay out cable. The assembly includes a frame, a boom arm pivotally connected thereto by a shaft, a cable guide on the boom arm configured to allow at least one cable to pass therethrough, a sensor in communication with the shaft and configured to measure a rotational position of the boom arm relative to a plane, and a controller in communication with the sensor. The controller is configured to control a speed at which the at least one roller rotates to feed the cable through the cable feeder based upon information received from the sensor. A method of use is also provided.

A speed adjusting cable assembly in accordance with some example embodiments is configured for use with a cable feeder having at least one motor-driven roller configured to pay out cable. The assembly includes a frame, a boom arm pivotally connected thereto by a shaft, a cable guide on the boom arm configured to allow at least one cable to pass therethrough, a sensor in communication with the shaft and configured to measure a rotational position of the boom arm relative to a plane, and a controller in communication with the sensor. The controller is configured to control a speed at which the at least one roller rotates to feed the cable through the cable feeder based upon information received from the sensor. A method of use is also provided.

Disclosed herein is a system and method of controlling a strander by wireless visual monitoring. In certain embodiments, a stranding system includes at least one vision device mounted to a rotating structure of a strander. The at least one vision device is configured to capture a view of at least a portion of a subunit reel of at least one of a set of payoff units of the rotating structure to generate vision data. The stranding system further includes at least one wireless communication module mounted to the rotating structure to receive and wirelessly transmit the vision data over a high-bandwidth data link. The stranding system is configured to proactively identify payout hazards of the subunit package (e.g., cable crossover) to, for example, prevent damage to the strander.

Disclosed herein is a system and method of controlling a strander by wireless visual monitoring. In certain embodiments, a stranding system includes at least one vision device mounted to a rotating structure of a strander. The at least one vision device is configured to capture a view of at least a portion of a subunit reel of at least one of a set of payoff units of the rotating structure to generate vision data. The stranding system further includes at least one wireless communication module mounted to the rotating structure to receive and wirelessly transmit the vision data over a high-bandwidth data link. The stranding system is configured to proactively identify payout hazards of the subunit package (e.g., cable crossover) to, for example, prevent damage to the strander.

A clamp device to clamp to a fishing pole and strip fishing line may include a first clamp member, a second clamp member to pivotably connect to the first clamp member, and a spool member to connect to the first clamp member and the second clamp member to the fishing rod and to rotate and to strip fishing line. The first clamp member may include a first clamp pivoting device. The second clamp member may include a second clamp pivoting device. The first clamp member may include a first clamp arm. The second clamp member may include a second clamp arm. The first clamp arm may include a first clamp slot.