A joining structure includes a first member, a second member of a material different from that of the first member, and a separation mechanism provided between the first member and the second member and that separates the first member and the second member from each other, wherein a resin is filled into the space between the edge of at least one member among the first member and the second member, and the other member.

A machine is disclosed for coating field joints of pipeline with a coating material. The machine includes an extruder, at least one accumulator, a mold, and pipework. The extruder is configured to melt the coating material into a molten coating material, and the at least one accumulator is configured to store the molten coating material. The mold is configured to fit around the field joints and is configured to mold the molten coating material to harden about the field joints. The pipework connects the extruder to the at least one accumulator and connects the at least one accumulator to the mold. The pipework is configured to conduct the molten coating material along the pipework. At least one heater has a fluid medium and is configured to heat the fluid medium to at least one temperature setpoint. Conduit work connects the at least one heater to the pipework and is configured to conduct the heated fluid medium with the pipework to keep the coating material molten in the pipework.

A structural reinforcement and biocompatible pump head for a pump includes a reinforcement structure having a plurality of ports and fluid pathways therein. The fluid pathways in the reinforcement may be coated or lined with a biocompatible material to form a biocompatible pump head useful for liquid chromatography and other analytical instrument systems. The biocompatible material may be injection molded into the fluid pathways of the reinforcement structure and may be machined after core pins are removed to obtain a desired surface finish and/or size of the biocompatible fluid pathways of the pump head.

A padding device (10a; 10b; 10c; 10d; 10e), for a carrying belt system (100) for a respirator (1000), has a closed pad core shell (20) and a pad core (30) configured in the pad core shell. The padding device is formed by injection molding a hollow profiled section, inserting of a pad core material into the hollow profiled section for forming the pad core in the hollow profiled section, and closing the hollow profiled section (21) for creating the closed pad core shell (20). The padding device (10a; 10b; 10c; 10d; 10e) has a closed pad core shell (20) and a pad core (30) arranged in the pad core shell. The pad core shell is seamless as an injection-molded component in at least some sections. A carrying belt system and a respirator with the carrying belt system are provided with the belt system having the padding device.

A canister for storing and launching a self-propelled projectile comprises: a) an inner layer comprising an aluminum foil; b) a top layer consisting of an injected thermoplastic polymer; and c) optionally, a primer and/or a topcoat.

Apparatuses and methods for on-line internal siliconing of glass bottles including a baking station for baking the siliconed bottles; wherein a siliconing station includes a support designed to selectively receive one bottle at a time, an injection device facing towards an inlet opening of the bottle, a mobile device for selectively blocking the injector against the inlet opening, a selective feeding device for feeding filtered compressed air and liquid silicone to the injector, the injector provided at the front, towards the support, with a drainage channel communicating with the inlet opening; an emitter to send towards a sensor and through the bottle on the support a beam of electromagnetic radiation; and a control unit to selectively inject into the bottle a mixture of silicone and compressed air and to process a signal emitted by the sensor to control the feeding device and/or a manipulator to discard defective bottles.

A molding system for applying moldable material to a pipe. An elongate mold has at least one elongate mold member movable relative another elongate mold member between open and closed positions. The mold includes a pipe support that extends generally radially into a mold cavity along a support axis. An inner end of the support is configured to support the pipe in a molding position in which an annular portion of the mold cavity extends circumferentially around the pipe. After moldable material in the annular portion of the mold cavity can support the pipe, the support is withdrawn from the mold cavity by moving outwardly along the support axis. An injector selectively dispenses additional moldable material into a space formed by the support in the existing moldable material.

A molding system for applying moldable material to a pipe. An elongate mold has at least one elongate mold member movable relative another elongate mold member between open and closed positions. In the closed position, the mold may define an elongate vent between the mold members that extends along the longitudinal axis of the mold. Air in the mold cavity displaced by moldable material received into the mold cavity vents through the elongate vent along the longitudinal axis of the mold. The mold can include a positioner that positions the mold members in the closed position while the mold is filled with the moldable material. The positioner also allows movement of the first mold member toward the open position to partially open the mold as the moldable material cures to reduce forces imparted upon the mold due to expansion of the moldable material during curing.

A method of protecting a layered coating on a length of pipe for subsea use includes applying an edge finisher to the coating to encase an edge of the coating by fusing the edge finisher with the coating or by molding the edge finisher at an edge of the coating. Where the coating and the edge finisher are of thermoplastics such as PP, fusing can be achieved by injection molding the edge finisher or by welding a discrete edge finisher component to the edge of the coating. Mirror welding may be employed for this purpose, with a hot plate being interposed between the edge of the coating and the edge finisher.

A process manufactures a padding device (10a; 10b; 10c; 10d; 10e), for a carrying belt system (100) for a respirator (1000), having a closed pad core shell (20) and a pad core (30) configured in the pad core shell. The process includes injection molding a hollow profiled section, inserting of a pad core material into the hollow profiled section for forming the pad core in the hollow profiled section, and closing the hollow profiled section (21) for creating the closed pad core shell (20). The padding device (10a; 10b; 10c; 10d; 10e) has a closed pad core shell (20) and a pad core (30) arranged in the pad core shell. The pad core shell is seamless as an injection-molded component in at least some sections. A carrying belt system as well as a respirator with the carrying belt system are provided with the belt system having the padding device.