An aerosol generation device includes a main housing, a cover, and a heat insulating air gap formed between the main housing and the cover. A main body is defined by the main housing, and a cover element is detachably attached or connected to the main housing and covers a portion of the main housing to form part of the exterior surface of the main housing. The main housing and the cover element are shaped such that an air gap is formed between the main housing and the cover element.

A method includes forming fluid conduit inside a heat shield in an additive manufacturing process, removing powder from an interior passage of the fluid conduit and from an insulation gap defined between the fluid conduit and the heat shield, separating the heat shield and fluid conduit from the build platform, and shifting the fluid conduit to a shifted position relative to the heat shield. The method includes securing the fluid conduit to the heat shield in the shifted position.

A thermal insulating sleeve liner for fluid flow devices such as valves and piping used in severe industrial applications is preferably additively manufactured (e.g., by 3D printing) to fit into the bore of a protected fluid flow device. Internal interstices and/or external ribs provide added thermal insulation. An integrally formed end-lip or a separate end-cap secures and/or locates the sleeve liner within the protected fluid flow device between different diameter distal and proximal portions of the bore. If internal interstices are sealed they can be vacuumed or pressurized to enhance thermal insulating properties. Fitted dimensions are sufficiently small to prevent ingress of thermally conductive particles circulating in use within the flow path of the protected flow device. A pressure equalizing aperture can be provided on or through the sleeve if needed in some applications.

A heat insulation sheet includes a fiber sheet having spaces therein and a silica xerogel held in the spaces of the fiber sheet. The heat insulation sheet includes a thick region and a low compressible region thinner than the thick region. A compressibility of the low compressible region is equal to smaller than 5% upon having a pressure of 0.7 MPa applied to the low compressible region. This heat insulation sheet is superior in electrical insulation properties and thermal insulation properties, and secures a predetermined distance even in a case that the heat insulation sheet receives pressures from the both sides thereof, thus providing equipment with reliability.

A method for producing a composite glue composed of a hydrophobic aerogel according to the present invention includes: (S1) mixing step; (S2) hydrolysis step; (S3) condensation step; (S4) aging step; (S5) high-temperature pulse washing step; (S6) drying step; and (S7) composition step. The obtained composite glue composed of a hydrophobic aerogel is high-viscosity glue made by blending the hydrophobic aerogel with an inorganic fiber, and the related product not only has good properties of cold resisting and heat insulating, but also is light and has appropriate strength, excellent flame retardancy, and excellent water repellency.

The present invention relates to a method for producing an aerogel blanket exhibiting excellent hydrophobicity at high temperatures and an aerogel blanket produced thereby. The present invention uses a mixture of silica sol and a hydrophobic aerogel powder as an aerogel precursor and thus can achieve hydrophobicity in the internal structure as well as on the surface of the aerogel included in the aerogel blanket. Accordingly, the aerogel blanket can attain high hydrophobicity and thus can exhibit excellent hydrophobicity retention ability even in high-temperature applications.

The present invention relates to a method for producing an aerogel blanket exhibiting excellent hydrophobicity at high temperatures and an aerogel blanket produced thereby. The present invention uses a mixture of silica sol and a hydrophobic aerogel powder as an aerogel precursor and thus can achieve hydrophobicity in the internal structure as well as on the surface of the aerogel included in the aerogel blanket. Accordingly, the aerogel blanket can attain high hydrophobicity and thus can exhibit excellent hydrophobicity retention ability even in high-temperature applications.

Heat-insulation materials that can be placed along the lines of heat sources, heat-insulation structures using the same, and processes for producing the same. A heat-insulation material, that includes: fiber sheets that each have fibers and an aerogel and that have different sizes; and at least one covering material that covers the fiber sheets, or at least one elastic material that includes the fiber sheets. The at least one covering material may include a first covering material and a second covering material.

Heat-insulation materials that can be placed along the lines of heat sources, heat-insulation structures using the same, and processes for producing the same. A heat-insulation material, that includes: fiber sheets that each have fibers and an aerogel and that have different sizes; and at least one covering material that covers the fiber sheets, or at least one elastic material that includes the fiber sheets. The at least one covering material may include a first covering material and a second covering material.

A refrigerator includes a housing and a first partition portion. The housing includes a first storage chamber. The first partition portion is disposed in the first storage chamber and partitions the inside of the first storage chamber into at least a first storage portion and a second storage portion which is cooled to a temperature zone lower than that of the first storage portion. At least a part of the first partition portion is formed of a heat-insulating material containing an aerogel, a xerogel, or a cryogel.