A packer ring and activation system for use in a pipeline pressure isolation system utilizing a packer, a packer support ring, a primary wedge, and a plurality of secondary wedges for use with a pipe engagement, sealing and testing system.

An in-line inspection tool for a pipeline comprises a body defining an axis, a sensor module coupled to the body, and a drive cup coupled to the body. The drive cup includes an outer surface with a plurality of axial channels, each of the axial channels including at least one bridge positioned therein that extends circumferentially across the channel.

A device is produced as a small sphere with neutral buoyancy, within which there is, at least, one hydrophone that is connected to a signal processor, which stores the information on a memory card and that is powered by at least one battery. This signal processor has a clock module, through which the sailing time elapsed for each audio signal received by the hydrophone is recorded in the memory. Therefore, based on the sailing time, the exact position of the detected anomalies or leaks can be ascertained. The device is complemented by a series of external synchronisation systems, laid out every certain distance, by which the position error that could be accumulated by the device is neutralised. Thus, a simple device is attained, which is cheap, solid, durable and highly effective.

Semi-automated testing devices for a plumbing stack are disclosed. A semi-automated testing device in accordance with the present disclosure may comprise a transfer pump configured to automatically fill the plumbing stack; at least one automated gripping element configured to grip a supplemental pipe coupled to a pipe of the plumbing stack via a connection; at least one automated sealing element configured to seal the connection; and at least one sensor configured to measure a water level of the supplemental piping. A method of testing the plumbing stack with the semi-automated testing device is also disclosed.

In-pipe leak detection systems and related methods are disclosed for detecting in-pipe leaks while fluid is actively flowing through the pipe. The system can include a sensing element coupled to a membrane that are disposed parallel to or in-line with an axial direction of a fluid flow. The membrane is configured to be drawn into contact with the inner wall in response to a suction force caused by a leak. The leak is detected based on a transient output from the sensing element indicative of a stretch or strain on the membrane. The sensing element and the membrane is coupled to a support structure configured to position the membrane adjacent to an inner wall of a pipe. The support structure can include a mechanism that couples the membrane and the sensing element to the support structure and is configured to help in discriminating between leaks and false detections.

A device is produced as a small sphere with neutral buoyancy, within which there is, at least, one hydrophone that is connected to a signal processor, which stores the information on a memory card and that is powered by at least one battery. This signal processor has a clock module, through which the sailing time elapsed for each audio signal received by the hydrophone is recorded in the memory. Therefore, based on the sailing time, the exact position of the detected anomalies or leaks can be ascertained. The device is complemented by a series of external synchronisation systems, laid out every certain distance, by which the position error that could be accumulated by the device is neutralised. Thus, a simple device is attained, which is cheap, solid, durable and highly effective.

The system utilizes conductivity equipment as well as a camera, pressure sensor, and acoustic hydrophone within a probe deployed via cable into a pipe to be inspected. The probe completes an electric circuit back to ground when the probe is adjacent a defect through which electric currents can pass, thus producing varying electric current. The camera, incorporated into the electric probe, is utilized for both inspection and navigation through the pipe by providing a close-circuit video data feed. The pressure sensor detects alterations in the pressure and flow field of the fluidic region in the area of a leak. The acoustic hydrophone listens for the sound leaks in a pressurized pipeline. The inspection device is tethered to a cable and inserted a measured distance into the pipeline, typically with the pipeline under pressure, via a launch tube. Multi-sensor data versus pipeline position is thus obtained.

A packer ring and activation system for use in a pipeline pressure isolation system utilizing a packer, a packer support ring, a primary wedge, and a plurality of secondary wedges for use with a pipe engagement, sealing and testing system.

In-pipe leak detection systems and related methods are disclosed for detecting in-pipe leaks while fluid is actively flowing through the pipe. The system can include a sensing element coupled to a membrane that are disposed parallel to or in-line with an axial direction of a fluid flow. The membrane is configured to be drawn into contact with the inner wall in response to a suction force caused by a leak. The leak is detected based on a transient output from the sensing element indicative of a stretch or strain on the membrane. The sensing element and the membrane is coupled to a support structure configured to position the membrane adjacent to an inner wall of a pipe. The support structure can include a mechanism that couples the membrane and the sensing element to the support structure and is configured to help in discriminating between leaks and false detections.

Provided is a device, method, and inspection system for collecting data in a fluid conduit. The inspection system includes a pig, wherein the pig is defined by at least a front end and a read end, the rear end being distally opposed to the front end along a longitudinal axis, a mount assembly secured to the rear end of the pig; and at least one sensor device removably coupled to the mount assembly.