A laminate structure having a metal foil having a lower and an upper surface area, a first layer of a thermoplastic polymer laid onto and covering the lower surface of the layer of metal foil except for a longitudinal uncovered surface area of the layer of metal foil, and a second layer of thermoplastic polymer laid onto and covering the upper surface of the layer of metal foil except for a longitudinal uncovered surface area of the layer of metal foil, and wherein the laminate structure is wrapped around the cable core such that the first uncovered surface area of the metal foil faces the cable core and the second uncovered surface area of the metal foil faces away from the laminate structure, and the laminate structure is thermally joined by a heat treatment.

A Galley container (1) for use in an aircraft, includes at least two container sidewalls (6), a container floor element (7) and a container ceiling element (8), forming a hollow inner shell casing (2) with a circumferential first rim (12) and a circumferential second rim (12). The composite tape (11) is spun around the inner shell casing and along the circumference of the rims, forming at least part of a construction layer (5) of the galley container. The composite tape includes at least one fiber and a matrix material.

A Galley container (1) for use in an aircraft, includes at least two container sidewalls (6), a container floor element (7) and a container ceiling element (8), forming a hollow inner shell casing (2) with a circumferential first rim (12) and a circumferential second rim (12). The composite tape (11) is spun around the inner shell casing and along the circumference of the rims, forming at least part of a construction layer (5) of the galley container. The composite tape includes at least one fiber and a matrix material.

The present disclosure relates to the technical field of electrochemistry, and in particular, to a threadlike sensor, a wearable device and a method for fabricating the threadlike sensor. The threadlike sensor includes a thread core, an inner insulating layer, an outside electrode layer and an outer insulating layer. The inner insulating layer covers the thread core with two ends of the thread core being exposed by the inner insulating layer. The outside electrode layer is disposed outside the inner insulating layer. The outer insulating layer covers the outside electrode layer with two ends of the outside electrode layer being exposed by the outer insulating layer. One end of the threadlike sensor is a detection end configured for placement in a human body. The other end of the threadlike sensor is an interface end configured for external connection. The thread core and the outside electrode layer are configured for sensitivity testing.

The present disclosure relates to the technical field of electrochemistry, and in particular, to a threadlike sensor, a wearable device and a method for fabricating the threadlike sensor. The threadlike sensor includes a thread core, an inner insulating layer, an outside electrode layer and an outer insulating layer. The inner insulating layer covers the thread core with two ends of the thread core being exposed by the inner insulating layer. The outside electrode layer is disposed outside the inner insulating layer. The outer insulating layer covers the outside electrode layer with two ends of the outside electrode layer being exposed by the outer insulating layer. One end of the threadlike sensor is a detection end configured for placement in a human body. The other end of the threadlike sensor is an interface end configured for external connection. The thread core and the outside electrode layer are configured for sensitivity testing.

Duct segments that define a channel for conveying a fluid, where the duct wall includes a sheath of reinforcing fabric incorporating multiple reinforcing fibers, and a thermoplastic fused with the sheath of reinforcing fabric. The duct segments may be prepared by wrapping a mandrel configured to define the inner mold line of a desired duct segment with a thermoplastic film, enveloping the wrapped mandrel with a reinforcing sheath incorporating reinforcing fibers; wrapping the enveloped mandrel with another thermoplastic film to form a multilayer duct segment precursor; enclosing the mandrel and multilayer duct segment precursor within an outer mold defining the outer mold line for the desired duct segment; heating the duct segment precursor at a temperature and for a time sufficient to fuse the layers of the multilayer duct segment precursor; and then cooling the resulting duct segment.

A method for producing endless abrasive articles (100) includes providing a mandrel coil (200), which comprises a first complete turn (B0.sub.A) formed of an endless mandrel belt (B0), feeding the endless mandrel belt (B0) to an input end (IN0) of the mandrel coil (200) and unwinding the mandrel belt (B0) from an output end (OUT0) of the mandrel coil (200) so as to move the surface of the first complete turn (B0.sub.A) of the mandrel coil (200), forming a laminated sleeve (SLEEVE1) by feeding a first strip (S1) on the moving surface of the first complete turn (B0.sub.A) of the mandrel coil (200), and forming an endless abrasive article (100) by cutting the laminated sleeve (SLEEVE1).