A method for renovating the interior of a hollow structure such as a sewerage pit (1) is described. The method provides an access opening (16) to the hollow structure (1); provides a plurality of material sheets (3) comprising reinforcing fibers and a curable resin composition through the access opening (16) and against a wall (11a, 11b) of the hollow structure (1); and provides an inflatable pressure means (4a, 4b) within the hollow structure (1). The pressure means (4a, 4b) are inflated against the wall (11a, 11b). A curing means (6) is then provided within the hollow structure (1) for curing the resin composition; and the resin composition is cured to harden the material sheets and provide a renovated interior of the hollow structure (1).

A device (100) for providing a tube arranged or arrangeable in a circumferentially closed manner around a prolate object (102), preferably around a conductor, as a marking (101) of the object (102) is described. The device (100) comprises a printer (200) for outputting a printed tube (214) in longitudinal direction (210) or a material interface (156) for receiving a printed tube (214) output from a printer (200) in longitudinal direction (210). Further, the device (100) comprises a cutting unit (120) configured to cut through the printed tube (214) at a cutting position of the tube (214) in a transverse direction (121) transverse, preferably perpendicular, to the longitudinal direction (210) of the tube. At least at the intersection, an upper half of the tube and a lower half of the tube, terminally or insidely, abut on each other or are connected to each other. Further, the device (100) comprises an opening unit (122) for opening the upper and lower halves of the tube. The opening unit comprises at least two opening rollers (123), each rotatable about a rotational axis (123A). The respective rotational axis (123A) is perpendicular or substantially perpendicular to the longitudinal direction (210) and the transverse direction (121). The at least two opening rollers (123) abut against the cut and printed tube on opposite sides in the transverse direction (121).

The invention relates to a system (10) for curing and/or inspecting a pipeline lining (30) positioned in a pipeline (20), the pipeline lining (30) comprising an outer plastics material layer and an inner fiber composite layer, the fiber composite layer comprising a plastics material which is to be cured and/or which is at least partially cured. In accordance with the invention, the system (10) comprises at least one high-frequency unit (40) which comprises at least one microwave-generator unit (41) and at least one microwave-transmitting antenna (42) for curing a plastics material which is to be cured, at least the at least one microwave-transmitting antenna (42) being movable in the pipeline (20) by means of a transporting device (60).

A bioinert piping (1) that has a flow path (2) provided inside and a main body portion (10) between end portions (8, 8) includes a resin tube (4) that forms an inner wall of the flow path (2) over an entire length of the flow path (2), and a metal tube (6) that accommodates the resin tube (4) inside so as to cover the outer peripheral surface of the resin tube (4) over at least an entire length of the main body portion (10). The metal tube (6) is plastically deformed toward an inner side so that the outer peripheral surface of the resin tube (4) and an inner peripheral surface of the metal tube (6) are in liquid-tight contact with each other.

A device for applying a film to a three-dimensional article includes an inflatable shape having at least one opening connected or connectable to a source of heated gas. The inflatable shape is configurable in a deflated configuration and in an inflated configuration when the heated gas is introduced into the inflatable shape through the opening. The inflatable shape is configured and sized to allow an article to be placed thereon, at least when the inflatable shape is in the deflated configuration. In the inflated configuration, the inflatable shape is configured for pressing against the article and for adhering, to the article, a film interposed between the inflatable shape and the article. The inflatable shape is impermeable to the heated gas and has a thermal transmittance greater than 600 W/m.sup.2K.

A method of installing a liner assembly for pipeline repair or reinforcement includes: pulling a prepared liner assembly into position in the pipeline, the liner assembly including a tubular liner wetted with a curable compound; introducing fluid into the inflatable bladder to bring the tubular liner into firm contact with an interior surface of the pipeline; flowing the fluid continuously through the bladder and discharging the fluid into the pipeline, while maintaining the liner assembly in an inflated condition; measuring a flow rate and a temperature of the fluid entering the bladder; calculating a time period sufficient for the tubular liner to cure based on: an amount of heat required for curing, based on dimensional information of the liner, and the measured flow rate and temperature of the fluid; and maintaining the liner assembly in an inflated condition for the time period sufficient for the tubular liner to cure.

A liner assembly and method for lining a damaged pipe junction between a main and lateral pipe is provided. The liner assembly includes a main liner member and a lateral liner tube. A collar disposed near the juncture between the main liner member and lateral liner tube is impregnated with a liquid hydrophobic or hydrophilic material capable of curing in a flexible or rigid state with the material expanding in the presence of water. The hydrophobic or hydrophilic material can also be applied without the use of the collar. When the liner assembly is pressed against the main and lateral pipes, a portion of the hydrophilic or hydrophobic material is forced into the damaged pipe junction.

A steam generator for use with a liner assembly for pipeline repair or reinforcement, includes: a water heater configured to heat water to generate steam; a water feed conduit configured to convey water to the water heater; an air heater configured to generate heated air; an air supply conduit configured to convey pressurized air to the air heater; a heated air supply conduit configured to convey heated air from the air heater to the water heater to yield a steam-air mixture; and an output conduit configured to convey the steam-air mixture from the water heater. An automated steam generator system including the steam generator is also described.

A pipe, the inner surface of which is lined with a thermoplastic layer, is produced by a process comprising the following steps: a) a metal pipe is provided, b) a tubular inliner composed of a thermoplastic material is provided, c) a tape is cohesively helically bonded to the inliner, wherein the region of the contact surface of the tape consists of a moulding composition or an adhesive which adhere firmly to the surface of the inliner, and wherein the region of the opposing surface of the tape consists of a moulding composition or an adhesive which adhere firmly to the metal of the pipe, wherein the tape contains unidirectional reinforcing fibers; d) the cross section of the inliner is optionally reduced by exposure to an external force, e) the inliner is inserted into the metal pipe, f) by means of contact pressure and optionally heat, the inliner and metal pipe are firmly bonded to each other. Relative movements between the metal pipe and inliner are thereby prevented; the inliner also has high safety against collapse. The pipe is used to produce a routed pipeline.

An expander of a tubular assembly having a tubular covering element inserted into a tubular element includes a tip for pushing a first internal wall of the tubular covering element towards a second internal wall of the tubular element so as to enable the adhesion of a first external wall of the tubular covering element to the second internal wall. The expander includes a rotary joint sliding along a first longitudinal axis, to which the tip is coupled so as to arrange the tip radially and enable it to rotate around the first axis. The expander further includes a sensor operatively connected to the tip to detect a radial displacement of the tip owing to a current thrust exerted by the tip, and a logic control unit operatively connected to the sensor and the tip to adjust a future thrust as a function of the radial displacement.