Methods and systems for cleaning, coating and sealing leaks in existing pipes, in a single operation. A piping system can be cleaned in one pass by dry particulates forced and pulled by air throughout the piping system by a generator and a vacuum. Pipes can be protected from water corrosion, erosion and electrolysis, extending the life of pipes such as copper, steel, lead, brass, cast iron piping and composite materials. Coatings can be applied to pipes having diameters up to approximately 6″. Leak sealants of at least approximately 4 mils thick can cover insides of pipes, and can include novel mixtures of fillers and epoxy materials, and viscosity levels. A positive pressure can be maintained within the pipes during applications. Piping systems can be returned to service within approximately 96 hours.

The proposed technology relates to a system (8) for preventing microbiological growth in a conduit conveying a liquid. The system (8) comprises a multi-layered pipe (10) constituting said conduit and having an inner layer (12) that covers the complete inside (16) of the pipe (10) and is formed of an electrically conductive polymer material. A liquid in the pipe (10) is in direct contact with the inner layer (12). The system further has a first electrical connector (18) and a second electrical connector (19) connecting to the inner layer (12) from outside the pipe (10), wherein the first electric connector (18) and the second electric connector (19) are spaced apart along the pipe (10). The system further has an electric power source (20) operationally connected to the first electrical connector (18) and the second electrical connector (19) and configured for supplying an electric current to the inner layer (12).

The proposed technology relates to a system (8) for preventing microbiological growth in a conduit conveying a liquid. The system (8) comprises a multi-layered pipe (10) constituting said conduit and having an inner layer (12) that covers the complete inside (16) of the pipe (10) and is formed of an electrically conductive polymer material. A liquid in the pipe (10) is in direct contact with the inner layer (12). The system further has a first electrical connector (18) and a second electrical connector (19) connecting to the inner layer (12) from outside the pipe (10), wherein the first electric connector (18) and the second electric connector (19) are spaced apart along the pipe (10). The system further has an electric power source (20) operationally connected to the first electrical connector (18) and the second electrical connector (19) and configured for supplying an electric current to the inner layer (12).

A pipe support assembly for use in the pipeline transmission industry. More particularly, an adjustable pipe support assembly for use in bracing and securing a section of pipe, while being able to removably detach a strap of said support assembly from said pipe, and thus, monitor and inspect an outer coating of said pipe for corrosion and/or any other possible damage to said pipe. More particularly still, a pipe support assembly having a plurality of pipe chocks with vibration regulators for use in preventing and controlling any vibratory movements of said pipe.

An embedded Alternating Current (AC) mitigation system reduces or eliminates induced AC currents on pipelines. When a pipeline runs parallel to power lines, the AC current in the power lines induces AC current in the pipeline. Known coatings applied to the pipelines provides electrical insulation and result in a dangerous or destructive buildup of AC voltage in the pipeline. A combination of the pipeline, a dielectric, and a plate, forms a capacitor. The dielectric may be a coating on the pipe, or a dielectric material deposited on the pipeline and under the plate. The capacitor acts as a decoupler by transmitting AC current to the ground while preserving DC current on the pipeline. The embedded AC mitigation system will further act as grounding system and eliminate the need of adding a grounding system.

A method and apparatus is described that uses a device that presents a surface of a dielectric material to a flowing or circulating fluid that results in charge being created at a boundary layer of the dielectric where it contacts the fluid by ion exchange and charging of compounds, for example insoluble dielectric particles such as colloids, and using at least one control impedance to control an impressed current in the fluid caused by the fluid flowing through the device and to cause suspended particles in the fluid to be charged, whereby the charge of the suspended particles is then neutralised causing coagulation of the particles as suspended insoluble particles.

A method of improving the life expectancy of piping has steps of determining a circumferential position in the piping having a highest expected rate of wall thickness reduction; determining a circumferential section of a pipe length having a greatest wall thickness; and installing the pipe length in the piping by rotating the pipe length to align the circumferential section of the pipe length having the greatest wall thickness with the circumferential position of the piping having the highest expected rate of wall thickness reduction.

A method of improving the life expectancy of piping has steps of determining a circumferential position in the piping having a highest expected rate of wall thickness reduction; determining a circumferential section of a pipe length having a greatest wall thickness; and installing the pipe length in the piping by rotating the pipe length to align the circumferential section of the pipe length having the greatest wall thickness with the circumferential position of the piping having the highest expected rate of wall thickness reduction.

The present invention relates to an unbonded flexible pipe including a bore for transport of a fluid wherein the unbonded flexible pipe includes an internal pressure structure including a fluid-tight polymer sheath and a barrier layer on the inside of the fluid-tight polymer sheath and bonded thereto, wherein the internal pressure sheath further includes a permeable protection sheath inside the fluid-tight polymer sheath and, wherein the barrier layer is located between the fluid-tight polymer sheath and the permeable protection sheath.

The present invention relates to an unbonded flexible pipe including a bore for transport of a fluid wherein the unbonded flexible pipe includes an internal pressure structure including a fluid-tight polymer sheath and a barrier layer on the inside of the fluid-tight polymer sheath and bonded thereto, wherein the internal pressure sheath further includes a permeable protection sheath inside the fluid-tight polymer sheath and, wherein the barrier layer is located between the fluid-tight polymer sheath and the permeable protection sheath.