One aspect of the invention provides a composite refrigeration line set including at least one selected from the group consisting of: a suction line and a return line, characterized in that one or more of the suction line and the return line are a composite refrigeration line set tube include: an inner plastic tube; a first adhesive layer positioned about the inner plastic tube; an aluminum layer positioned about the first adhesive layer and coupled to the inner plastic tube via the first adhesive layer; a second adhesive layer positioned about the aluminum layer; and an outer plastic layer positioned about the aluminum layer coupled to the aluminum layer via the second adhesive layer. The inner plastic tube is polyethylene of raised temperature. The outer plastic tube is polyethylene of raised temperature. The aluminum layer comprises AL 3005-O.

Methods and systems are provided for a flexible support for a vehicle. In one example, the flexible support is formed of a composite material and configured to surround a vehicle component and absorb oscillations generated by the vehicle. The composite material may be a mixture of aluminum particles dispersed in an elastomer matrix.

A ventilation duct for a fire rated ventilation duct wall penetration has one or more metal sheets forming said duct, wherein said metal sheet duct is covered on the outside by a heat insulating material, and said duct includes elongated stiffening members located on the outside of the duct and attached to said metal sheets. The stiffening members each comprises a metal profile and at least one non-combustible bar of inorganic material. The metal profile is fixed to the metal sheet of the duct and retains the non-combustible bar by at least partly encircling the bar.

A device for securing at least one thermal protection mat to an internal fixed structure of a nacelle includes at least one removable fastening element for securing the at least one thermal protection mat to the internal fixed structure designed to be arranged between the mat and the internal fixed structure. The device includes at least one gripping element connected to the removable fastening element to project relative to the mat on the opposite side to the internal fixed structure, the removable fastening element being intended to be detached from the internal fixed structure by a pulling force exerted on the gripping element.

A ventilation system for insulated pipe or pipeline to prevent corrosion thereof is discussed. The ventilation system can include an outer skin wrapped around the insulated pipe or pipeline, the outer skin separated from the insulation pipe by stand-off supports to form an annular chamber within the system. The system has a vent screen along a bottom side of the outer skin and a gable running along the top side of the outer skin, the gable having a number of openings therethrough to allow air to flow in through the vent screen, through the annular chamber and out through the gable openings, drawing moisture from the insulation thereby preventing corrosion of the pipe or pipeline.

Self-regulating thermal insulation includes one or more thermal actuators that expand and contract in response to changes in temperature adjacent the thermal insulation, thereby automatically changing the thermal resistance of the thermal insulation. In this manner, a self-regulating thermal insulation may be configured to locally adjust in response to local changes in temperature of a part being insulated, for example, during curing or some other manufacturing process. Such self-regulating thermal insulation may be configured to respond to temperature changes without feedback control systems, power, or human intervention. Methods of making self-regulating thermal insulation include coupling a first plate with respect to a second plate using a support structure, thereby defining an insulation thickness therebetween, positioning an internal partition positioned between the first plate and the second plate, and positioning at least one thermal actuator positioned between the second plate and the internal partition.

Self-regulating thermal insulation includes one or more thermal actuators that expand and contract in response to changes in temperature adjacent the thermal insulation, thereby automatically changing the thermal resistance of the thermal insulation. In this manner, a self-regulating thermal insulation may be configured to locally adjust in response to local changes in temperature of a part being insulated, for example, during curing or some other manufacturing process. Such self-regulating thermal insulation may be configured to respond to temperature changes without feedback control systems, power, or human intervention. Methods of making self-regulating thermal insulation include coupling a first plate with respect to a second plate using a support structure, thereby defining an insulation thickness therebetween, positioning an internal partition positioned between the first plate and the second plate, and positioning at least one thermal actuator positioned between the second plate and the internal partition.

A pipe insulation spacer system has a first spacer ring and a second spacer ring. Each of the first spacer ring and the second spacer ring have a flexible band. The flexible band has a bottom with a plurality of feet. The plurality of feet engage an outer surface of the process pipe such that the flexible band is spaced from the outer surface of the process pipe. An inner cladding has a body with a first end, a second end, and a pair of peripheral side edges. The first end of the inner cladding is supported by the first end spacer ring and the second end of the inner cladding is supported by the second end spacer ring. The inner cladding wraps around the process pipe such that the pair of peripheral side edges are adjacent each other and the inner cladding is spaced from the process pipe.

A pipe insulation spacer system has a first spacer ring and a second spacer ring. Each of the first spacer ring and the second spacer ring have a flexible band. The flexible band has a bottom with a plurality of feet. The plurality of feet engage an outer surface of the process pipe such that the flexible band is spaced from the outer surface of the process pipe. An inner cladding has a body with a first end, a second end, and a pair of peripheral side edges. The first end of the inner cladding is supported by the first end spacer ring and the second end of the inner cladding is supported by the second end spacer ring. The inner cladding wraps around the process pipe such that the pair of peripheral side edges are adjacent each other and the inner cladding is spaced from the process pipe.

An assembly including a support panel of an internal fixed structure, a thermal protection element and a plurality of fastening systems. Each fastening system includes a female part secured to the support panel and which has, in its interior, a circular shoulder, and a male part including a sleeve pierced with a main bore, a slide movable in translation in the main bore and a plurality of balls. For each ball, the sleeve has a secondary bore, and each ball is movable along the secondary bore between a locking position and an unlocking position. The slide is movable in translation between a blocking position and an unlocking position. Such an assembly makes it possible to fasten the thermal protection element to the support panel in a simple and rapid manner, also permitting easy removal if necessary.