Embodiments of a multi-diameter foam pig include a first set of radially spaced-apart, longitudinally extending, slots located toward a nose end of the pig and a second set of radially spaced-apart, longitudinally extending, slots located toward a tail end. Each set of slots ends at a band section of the pig so that, together, the two sets of slots do not traverse the entire length of the pig. A standard-length unit version of the foam pig includes only the first set of slots. A set of shorter, intermediate slots, offset in a circumferential direction from the first and second set of slots and partially overlapping those slots, may be included on the band section. Because of the slots, and because of open cell foam, the foam pig decreases or increases in diameter as it enters a different diameter run than the run just traveled.

Embodiments of a multi-diameter foam pig include a first set of radially spaced-apart, longitudinally extending, slots located toward a nose end of the pig and a second set of radially spaced-apart, longitudinally extending, slots located toward a tail end. Each set of slots ends at a band section of the pig so that, together, the two sets of slots do not traverse the entire length of the pig. A standard-length unit version of the foam pig includes only the first set of slots. A set of shorter, intermediate slots, offset in a circumferential direction from the first and second set of slots and partially overlapping those slots, may be included on the band section. Because of the slots, and because of open cell foam, the foam pig decreases or increases in diameter as it enters a different diameter run than the run just traveled.

A pipeline plug includes a plug body. The plug body includes an outer housing. The interior of the outer housing defines a pressure vessel. The pipeline plug includes a pressure head coupled to the plug body, a seal assembly, a gripper assembly, a movable head, and an actuation mechanism. The actuation mechanism includes a leadscrew, the leadscrew coupled to the movable head. The actuation mechanism includes a captive nut, the captive nut positioned within the pressure vessel. The actuation mechanism includes a motor, the motor operatively coupled to the captive nut and adapted to rotate the captive nut.

A mechanical lock unit with a shaft lock assembly and method of achieving a self-lock mode for, e.g., hydraulically activated isolation plug module. The shaft lock assembly includes a teeth-form ring that surrounds a shaft. The teeth-form ring defines a plurality of teeth. A teeth-form split gripper assembly is positioned to surround the teeth-form ring. The teeth-form split gripper assembly has at least a first teeth-form split gripper and a second teeth-form split gripper with a spring therebetween for biasing the first teeth-form split gripper away from said second teeth-form split gripper. The first teeth-form split gripper and the second teeth form split gripper having an inner surface that defines a plurality of teeth for cooperative engagement with the plurality of teeth of the teeth-form ring.

A system and method for measuring an inside diameter of a pipe to determine if it exceeds a predetermined value using a plurality of fingers operatively connected to a spring. When in a fully extended position, the distance between opposite fingers is the predetermined value. The fingers are pivotable between a starting position, through the fully extended position, and to a failing position. In the starting position, an outer end of each finger engages an inside surface of the pipe to compress the spring. If the diameter exceeds the predetermined value as the system moves through the pipe, the pipe inside surface will no longer engage the fingers, which releases the spring causing the fingers to pivot to the failing position, where they remain until the system is removed from the pipe and manually reset.

A system and method for measuring an inside diameter of a pipe to determine if it exceeds a predetermined value using a plurality of fingers operatively connected to a spring. When in a fully extended position, the distance between opposite fingers is the predetermined value. The fingers are pivotable between a starting position, through the fully extended position, and to a failing position. In the starting position, an outer end of each finger engages an inside surface of the pipe to compress the spring. If the diameter exceeds the predetermined value as the system moves through the pipe, the pipe inside surface will no longer engage the fingers, which releases the spring causing the fingers to pivot to the failing position, where they remain until the system is removed from the pipe and manually reset.

The present disclosure relates to a device for assessing the condition of a pipeline containing a liquid, the device comprising an actuatable maneuvering means configured to generate a force sufficient to move the device from one side to another side along a horizontal plane and to move the device from top to bottom along a vertical plane, or any combinations thereof, so as to maneuver the device. The present disclosure relates to a method for maneuvering a device comprising transmitting an electronic signal, receiving the signal, and actuating maneuvering means on the device to generate a force sufficient to alter the path of the device in a direction around the pipeline feature based on information related by the received signal. In aspects, the method comprising identifying a pipeline feature by directing one or more of a camera, sonar sensor, or time of flight sensor disposed on a device towards the intended path.

The present disclosure relates to a device for assessing the condition of a pipeline containing a liquid, the device comprising an actuatable maneuvering means configured to generate a force sufficient to move the device from one side to another side along a horizontal plane and to move the device from top to bottom along a vertical plane, or any combinations thereof, so as to maneuver the device. The present disclosure relates to a method for maneuvering a device comprising transmitting an electronic signal, receiving the signal, and actuating maneuvering means on the device to generate a force sufficient to alter the path of the device in a direction around the pipeline feature based on information related by the received signal. In aspects, the method comprising identifying a pipeline feature by directing one or more of a camera, sonar sensor, or time of flight sensor disposed on a device towards the intended path.

Example aspects of a pipe repair stent, a pipe repair device, and a method for repairing a pipe are disclosed. The pipe repair stent can comprise a sealing layer comprising a flexible and compressible repair material; and a spring, wherein the sealing layer is wrapped around a circumference of the spring; wherein the stent is configurable in an expanded configuration and a compressed configuration, the spring biasing the stent to the expanded configuration.

A modular isolation robot includes a motor configured to drive at least a first wheel, wherein the first wheel is configured to contact an interior surface of a pipe. The robot further includes a first rubber expander configured to selectively expand from a first state to a second state, wherein a diameter of the rubber expander in the second state is equal to an inner diameter of the pipe, and at least a first interchangeable module, wherein the first interchangeable module is configured to house an electronic component. A system for performing maintenance operations within a pipeline includes a first modular isolation robot and a second modular isolation robot.