A large diameter lay-flat hose spool apparatus has a mobile platform with a chassis and wheels. Side supports extend up from the chassis. An axle bears on the side supports, spanning a gap therebetween. Plural spools are rotatably mounted on the axle. Each spool has at least one rim and a length of lay-flat hose wound thereon. A driver rotates the individual spools about the axle independently of the other spools. The driver has a first actuator that moves a drive wheel into and out of contact with a rim of one of the spools. The driver has a second actuator that moves the drive wheel from one of the spool rims to another of the spool rims. A motor rotates the drive wheel. A controller system operated the motor, the first actuator and the second actuator.

The invention relates to an apparatus for storing cable, comprising a cable carousel (1) rotatable about a vertical axis (2), and rotating means (30) for rotating (4) the carousel (1) about the vertical axis (2), for allowing winding cable (5) on the carousel (1) and unwinding cable (5) from the carousel (1). The carousel (1) is received in a pool (7), a seal (10) is arranged between an outer side (12) of the carousel (1) and a pool outer wall (9). A closed chamber (13) is defined in the pool (7) below the carousel (1), and pressurized liquid in the closed chamber (13) provides a positive pressure for supporting the carousel (1) and allowing rotation (4) of the carousel (1).

The invention relates to an apparatus for storing cable, comprising a cable carousel (1) rotatable about a vertical axis (2), and rotating means (30) for rotating (4) the carousel (1) about the vertical axis (2), for allowing winding cable (5) on the carousel (1) and unwinding cable (5) from the carousel (1). The carousel (1) is received in a pool (7), a seal (10) is arranged between an outer side (12) of the carousel (1) and a pool outer wall (9). A closed chamber (13) is defined in the pool (7) below the carousel (1), and pressurized liquid in the closed chamber (13) provides a positive pressure for supporting the carousel (1) and allowing rotation (4) of the carousel (1).

Techniques for implementing a pipe deployment system that includes a pipe reel, in which the pipe reel includes reel ends and a reel drum and the pipe reel enables a pipe segment to be wrapped on the reel drum. The pipe deployment system includes a brake assembly with a brake wheel having a shaft socket keyed with flat inner surfaces, and a shaft adapter assembly, which includes an adapter head to be coupled between the pipe reel and the brake assembly. The adapter head includes an adapter shaft keyed with flat outer surfaces, in which the adapter shaft matingly interlocks with the shaft socket and is to be partially inserted through a reel end of the pipe reel, and a rotation control pin coupled to the adapter shaft, in which the rotation control pin is to be inserted between adjacent reel spokes in the reel end of the pipe reel.

A creel, such as may be used to supply fiberglass roving to a production process, includes an enclosure and a number of rotatable axles held within the enclosure. Each of the axles is of a shape and size to be inserted into a bobbin of roving. The creel also includes a drive mechanism coupled to each of the plurality of rotatable axles, the drive mechanism synchronizing the rotation of the axles. Bobbins of roving may be stacked on the axles and connected to provide continuous roving. As roving is drawn from the creel, the rate of rotation of the axles may be selected to counteract twisting of the roving that would otherwise result.

A creel, such as may be used to supply fiberglass roving to a production process, includes an enclosure and a number of rotatable axles held within the enclosure. Each of the axles is of a shape and size to be inserted into a bobbin of roving. The creel also includes a drive mechanism coupled to each of the plurality of rotatable axles, the drive mechanism synchronizing the rotation of the axles. Bobbins of roving may be stacked on the axles and connected to provide continuous roving. As roving is drawn from the creel, the rate of rotation of the axles may be selected to counteract twisting of the roving that would otherwise result.

A method and apparatus for engaging a cable from a reel having a reel axle, such as for dispensing the cable from the reel with a motor assembly to figure eight a fiber optic cable sensitive to twisting. An adjustable frame is mounted to a first lifting arm. The adjustable frame is stored in a self-stowed configuration wherein the adjustable frame is vertically stacked parallel to the first lifting arm. The adjustable frame is deployed to align a distal frame end of the adjustable frame near the horizontal center of the reel in a plurality of lifting arm pivot positions.

A method and apparatus for engaging a cable from a reel having a reel axle, such as for dispensing the cable from the reel with a motor assembly to figure eight a fiber optic cable sensitive to twisting. An adjustable frame is mounted to a first lifting arm. The adjustable frame is stored in a self-stowed configuration wherein the adjustable frame is vertically stacked parallel to the first lifting arm. The adjustable frame is deployed to align a distal frame end of the adjustable frame near the horizontal center of the reel in a plurality of lifting arm pivot positions.

A creel, such as may be used to supply fiberglass roving to a production process, includes an enclosure and a number of rotatable axles held within the enclosure. Each of the axles is of a shape and size to be inserted into a bobbin of roving. The creel also includes a drive mechanism coupled to each of the plurality of rotatable axles, the drive mechanism synchronizing the rotation of the axles. Bobbins of roving may be stacked on the axles and connected to provide continuous roving. As roving is drawn from the creel, the rate of rotation of the axles may be selected to counteract twisting of the roving that would otherwise result.

A creel, such as may be used to supply fiberglass roving to a production process, includes an enclosure and a number of rotatable axles held within the enclosure. Each of the axles is of a shape and size to be inserted into a bobbin of roving. The creel also includes a drive mechanism coupled to each of the plurality of rotatable axles, the drive mechanism synchronizing the rotation of the axles. Bobbins of roving may be stacked on the axles and connected to provide continuous roving. As roving is drawn from the creel, the rate of rotation of the axles may be selected to counteract twisting of the roving that would otherwise result.