The reinforced removable thermal insulation (PARTS) contains the heat-insulating blocks joined among themselves placed on an external surface of the heat-isolated equipment. The Asti block is filled with heat-insulating material and consists of a reinforcing frame lattice sheathed on all sides with facing stainless sheets. For mutual detachable connection of heat-insulating blocks between themselves the lock latch is used. When using the proposed lock-latch, a guaranteed tightness is provided, the disclosure of thermal gaps between the side faces of thermal insulation blocks from the inaccessible internal bases of thermal insulation at temperature fluctuations is excluded, fitting works and welding of tension locks on the surface of their blocks in place during installation and Assembly work on the equipment are excluded. Asti blocks are able to save the weight of stainless steel, increase the strength of thermal insulation blocks by 2.56 times, significantly reduce the cost of their manufacture.

The reinforced removable thermal insulation (PARTS) contains the heat-insulating blocks joined among themselves placed on an external surface of the heat-isolated equipment. The Asti block is filled with heat-insulating material and consists of a reinforcing frame lattice sheathed on all sides with facing stainless sheets. For mutual detachable connection of heat-insulating blocks between themselves the lock latch is used. When using the proposed lock-latch, a guaranteed tightness is provided, the disclosure of thermal gaps between the side faces of thermal insulation blocks from the inaccessible internal bases of thermal insulation at temperature fluctuations is excluded, fitting works and welding of tension locks on the surface of their blocks in place during installation and Assembly work on the equipment are excluded. Asti blocks are able to save the weight of stainless steel, increase the strength of thermal insulation blocks by 2.56 times, significantly reduce the cost of their manufacture.

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 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.

An insulation product is disclosed comprising a plurality of glass fibers; and a cross-linked formaldehyde-free binder composition at least partially coating the glass fibers. The glass fibers have an average fiber diameter in the range of 8 HT (2.03 μm) to 15 HT (3.81 μm). At a density (x) between 0.3 pcf and 1.6 pcf, the insulation product may achieve a thermal conductivity (y) less than or equal to that which satisfies Formula (III):

y=0.116x.sup.2−0.3002x+0.4219.  Formula (III):

An insulation product is disclosed comprising a plurality of glass fibers; and a cross-linked formaldehyde-free binder composition at least partially coating the glass fibers. The glass fibers have an average fiber diameter in the range of 8 HT (2.03 μm) to 15 HT (3.81 μm). At a density (x) between 0.3 pcf and 1.6 pcf, the insulation product may achieve a thermal conductivity (y) less than or equal to that which satisfies Formula (III):

y=0.116x.sup.2−0.3002x+0.4219.  Formula (III):

A mineral wool product comprises mineral fibers bound by a binder resulting from the curing of a binder composition comprising a phenol-formaldehyde-based resin, and/or a carbohydrate containing component; a hydrophobic agent comprising (i) at least one silicone compound, such as silicone resin; (ii) at least one hardener, such as silane; (iii) optionally, at least one emulsifier; as insulation of a metallic structure, said structure having an operating temperature between 0-650° C.

A mineral wool product comprises mineral fibers bound by a binder resulting from the curing of a binder composition comprising a phenol-formaldehyde-based resin, and/or a carbohydrate containing component; a hydrophobic agent comprising (i) at least one silicone compound, such as silicone resin; (ii) at least one hardener, such as silane; (iii) optionally, at least one emulsifier; as insulation of a metallic structure, said structure having an operating temperature between 0-650° C.

A mineral wool product comprises mineral fibers bound by a binder resulting from the curing of a binder composition comprising a phenol-formaldehyde-based resin, and/or a carbohydrate containing component; a hydrophobic agent comprising (i) at least one silicone compound, such as silicone resin; (ii) at least one hardener, such as silane; (iii) optionally, at least one emulsifier; as insulation of a metallic structure, said structure having an operating temperature between 0-650° C.

The invention relates to a method for maintaining the temperature of fluid media in pipes even in the event of an interruption of the fluid media flow. In a first step, a heat reservoir layer (1) is produced comprising a latent heat reservoir material (2) and a matrix material (3). In a second step, the heat reservoir layer (1) is either arranged around a pipe (4) and subsequently encased with a heat damping material (5) or the heat reservoir layer (1) is brought into contact with heat damping material (5), whereby a heat reservoir damper composite (51) is obtained, and the pipe (4) is then encased with the heat reservoir damper composite (51) such that the heat reservoir layer (1) of the heat reservoir damper composite (51) lies between the pipe (4) and the heat damping material (5) of the heat reservoir damping composite (51).