An insulation system comprises a first insulation blanket and a second insulation blanket. The first insulation blanket extends circumferentially within a curved body. The second insulation blanket extends circumferentially within the curved body and covers a zero position of the curved body. A portion of the second insulation blanket covers a portion of the first insulation blanket so that the portion of the second insulation blanket is between the portion of the first insulation blanket and the curved body to form an overlap. The overlap is positioned within a range having an absolute value of 5 to 40 degrees from the zero position of the curved body.

A blanket assembly for use in at least one bay and with at least one frame member of an aircraft, the assembly including an insulation blanket. The insulation blanket includes a bay section sized and shaped to fit within the bay and of sufficient thickness to provide insulation to the bay, a return section disposed on a first side of the bay section; and a cap section disposed on a second side of the bay section, opposite the first side. The cap section is sized and shaped to at least partially cover the frame member when the cap section is wrapped around the frame member, the cap section being of sufficient thickness to provide insulation to the frame member. The bay section, the return section, and the cap section are of unitary construction.

Systems and methods are provided for insulation and moisture drainage. One exemplary embodiment is an apparatus comprising a bay blanket configured to insulate an aircraft. The bay blanket includes insulation, and a first waterproof lip that protrudes from the insulation in an outboard direction towards a frame of the aircraft and extends along a length of a leftward side of the bay blanket. The bay blanket also includes a second waterproof lip that protrudes from the insulation in an outboard direction towards the frame of the aircraft along a length of a rightward side of the bay blanket.

Systems and methods are provided for insulation and moisture drainage. One exemplary system comprises a liner. The liner covers a frame element of an aircraft. The liner includes a first waterproof lip that is attached to a first insulator and protrudes towards the frame element. The first waterproof lip and the first insulator form a first drainage channel for the frame element. A second waterproof lip is attached to a second insulator and protrudes towards the frame element. The second waterproof lip and the second insulator form a second drainage channel for the frame element. The first waterproof lip and the second waterproof lip each include a lengthwise fixation element that attaches the first waterproof lip to the second waterproof lip, sealing at least a portion of the lengthwise gap.

A system for controlling moisture ingress in aircraft skin mounted electronics, comprising: a moisture diverter comprising a substantially planar base flange, configured to sealingly engage an underlying surface of an interior structure of an aircraft, and, a shroud having a moisture impermeable wall extending inboard from the base flange and defining an enclosure therein for enclosing an electrical connector.

A moisture diversion system of an aircraft for capturing moisture from at least one internal aircraft structure or at least one gap, the moisture diversion system comprising: a drip shield with an upper surface having a concave shape, at least one moisture channel disposed in the upper surface of the drip shield, the drip shield being in a moisture capturing orientation under the at least one internal aircraft structure or the at least one gap.

A moisture control apparatus for use with a structure within an aircraft fuselage, the structure including an upper surface, the apparatus comprising: a moisture absorbing layer including a moisture absorbing material, the layer including a leading edge, a trailing edge, side edges, an upper surface, and, a lower surface; and, a wicking layer disposed in fluid communication with the lower surface of the moisture absorbing layer, the wicking layer including a wicking layer leading edge, a wicking layer trailing edge and a wicking layer upper surface configured for capillary action of moisture from the wicking layer trailing edge towards the wicking layer leading edge, wherein the wicking layer leading edge is offset from the leading edge of the moisture absorbing layer such that an offset portion of the wicking layer is exposed to air to facilitate evaporation of the moisture.

A moisture control apparatus for use with a structure within an aircraft, the structure including an upper surface, the moisture control apparatus comprising: a moisture absorbing layer including a moisture absorbing material, the layer including a leading edge, a trailing edge, side edges, an upper surface, and, a lower surface; and, a reverse-bevel defined along the leading edge of the layer, wherein the reverse-bevel and the upper surface of the structure define a gutter configured to retain moisture flowing along the upper surface of the structure.

A moisture control assembly for use with a support beam extending through an insulation layer is provided. The insulation layer is positioned between an outer wall and an inner wall. The assembly includes: a moisture path close-out structure coupled to the insulation layer at an aperture defined through the insulation layer, the moisture path close-out structure including an opening substantially aligned with the aperture and configured to receive the support beam therethrough; and a coupling mechanism configured to secure the moisture path close-out structure to the support beam such that the moisture path close-out structure is partially pulled away from the insulation layer, the coupling mechanism and the moisture path close-out structure configured to direct liquid flow down and away from the support beam and along the insulation layer.

A moisture control assembly for use with a support beam extending through an insulation layer is provided. The insulation layer is positioned between an outer wall and an inner wall. The assembly includes: a moisture path close-out structure coupled to the insulation layer at an aperture defined through the insulation layer, the moisture path close-out structure including an opening substantially aligned with the aperture and configured to receive the support beam therethrough; and a coupling mechanism configured to secure the moisture path close-out structure to the support beam such that the moisture path close-out structure is partially pulled away from the insulation layer, the coupling mechanism and the moisture path close-out structure configured to direct liquid flow down and away from the support beam and along the insulation layer.