RU200563U1 - HEAT INSULATING PRODUCT - Google Patents

Abstract

The utility model relates to sheet heat (cold) insulating products intended for insulating various non-planar objects, mainly pipelines and shells. The heat-insulating product contains banding elements and heat-insulating elements enclosed in a shell that covers the side surfaces of the heat-insulating elements and consists of two flexible sheets. One of the sheets is placed on the side surfaces of the heat-insulating elongated elements opposite to the surfaces facing the insulated object. Another sheet is placed on the remaining side surfaces of the heat-insulating elongated elements. Flexible sheets are connected in the spaces between the heat-insulating elements with a metal wire. To ensure the tightness of the product, the elongated heat-insulating elements are made of fibrous material, the fibers of which are arbitrarily oriented relative to the side surfaces of the heat-insulating elements, and the flexible sheet placed on the side surfaces of the heat-insulating elements opposite to the surfaces facing the insulated object is made sealed.

Description

The claimed utility model relates to heat-insulating structures designed to insulate various types of pipelines and other objects.

An analogue of the claimed utility model is a heat-insulating product (heat-insulating structure), which includes fibrous heat-insulating elements enclosed in a shell that covers their lateral surfaces and consists of two sheets of fiberglass, while the fibrous heat-insulating elements are made with variable porosity, which increases with distance from the insulated surface , and the sheets of the casing are connected in the intervals between the fibrous heat-insulating elements (see RF patent No. 160072, IPC F16L 59/02, 2016). The essential features of the analogue are “fibrous heat-insulating elements; a shell covering the side surfaces; a shell consisting of two sheets; the sheets of the shell are connected in the intervals between the heat-insulating elements "coincide with the essential features of the claimed utility model.

The disadvantage of the analogue is the insufficient deformation stability of the shell sheets made of fiberglass, which, during the installation and operation of the insulation, bend significantly and undergo significant stretching and compression in some areas. Another disadvantage is the high dust-permeability of the shell sheets, which causes the loss of a part of the heat-insulating elements made of brittle mineral fibers during operational influences on the thermal insulation.

The closest analogue of the claimed utility model is a heat-insulating product containing insulating elements made of elastically deformable fibrous material, enclosed in a shell that covers the side surfaces of the insulating elements and consists of two flexible sheets of fiberglass, one of which is placed on the side surfaces of the insulating elements opposite to the surfaces facing to the insulated object, and the other is placed on the remaining side surfaces of the insulating elements, while the flexible sheets of the shell are interconnected in the spaces between the insulating elements, and the insulating elements are made with the possibility of adopting a trapezoidal shape in their cross-section when mounted on the insulated object with an increase in their density as we approach the insulated object (see RF patent No. 159044, IPC F16L 59/02, 2016). The essential features of the analogue are “insulating elements made of deformable material; a shell covering the side surfaces of the insulating elements; a shell consisting of two flexible sheets; one sheet is placed on the side surfaces of the insulating elements opposite to the surfaces facing the object to be insulated, the other sheet is placed on the remaining side surfaces of the insulating elements; flexible sheets are interconnected in the spaces between the insulating elements; insulating elements are made with the possibility of adopting a trapezoidal shape in cross-section when mounted on an insulated object with an increase in their density as they approach the insulated object "coincide with the essential features of the claimed utility model.

The disadvantage of the closest analogue is also the low deformation resistance of fiberglass sheets, especially when it comes to a sheet placed on three side surfaces of each of the insulating elements at once. As a result, this sheet has various bends and bends, undergoes significant stretching and compression both during installation and during operation of the insulation, which can lead to a violation of the integrity of the shell due to the low deformability of the glass fabric and poor form stability.

The task to be solved by the claimed utility model is to improve the performance of thermal insulation by increasing the deformation resistance of the most deformable sheet of the product shell by increasing its elasticity, structure uniformity and dimensional stability.

To achieve the specified technical result in a heat-insulating product containing insulating elements made of deformable fibrous material, enclosed in a shell that covers the side surfaces of the insulating elements, and consists of two flexible sheets, one of which is placed on the side surfaces of the insulating elements opposite to the surfaces facing the insulated object, and the other is placed on the remaining lateral surfaces of the insulating elements, while the flexible sheets of the shell are interconnected in the intervals between the insulating elements, and the insulating elements are made with the possibility of adopting a trapezoidal shape in their cross-section when mounted on the insulated object with an increase in their density along As it approaches the object to be insulated, the sheet placed on the remaining side surfaces of the insulating elements is made of non-woven polypropylene thermally bonded fabric.

The essential features of the claimed utility model "the sheet placed on the remaining side surfaces of the insulating elements is made of non-woven polypropylene thermally bonded fabric" are distinctive from the features of the closest analogue.

The heat-insulating product includes insulating elements (bars) of an elongated shape made of a material that is elastically deformable under assembly loads (basalt felt, mineral slabs, etc.). The elongated insulating elements have four side and two end surfaces, while the insulating elements are enclosed in a shell that covers their side surfaces. The shell keeps the insulating elements at a certain distance from each other and consists of two flexible sheets. One of the flexible sheets is placed on the surface of each of the insulating elements that is opposite the insulating surface. This sheet can be additionally waterproofed, reinforced with foil, foil tape or another method. Moreover, this sheet is made of fiberglass, fiberglass, basalt fabric, non-woven fabric, etc. The second flexible sheet is placed on the other three side surfaces of each of the insulating elements. This sheet is made of non-woven polypropylene thermally bonded fabric. In the intervals between the insulating elements, the shell sheets are fixed to each other in any way (gluing, stitching, etc.). Due to this fixation, the insulating elements can change their shape in cross-section when mounted on the insulated object, which leads to a change (increase) in the density of the insulating elements as they approach the insulated object.

The use of non-woven polypropylene thermally bonded fabric, which has dimensional stability, elasticity, rigidity, high elasticity, good deformability and uniformity of the structure, eliminates the likelihood of destructive deformation under excessive tension and bending of the shell sheet, and reduces the likelihood of breaking the integrity of the sheet. As a result, the performance of the thermal insulation is improved.

Claims (2)

A heat-insulating product, including insulating elements made of deformable fibrous material, enclosed in a shell that covers the side surfaces of the insulating elements and consists of two flexible sheets, one of which is placed on the side surfaces of the insulating elements opposite to the surfaces facing the insulated object, and the other is placed on the rest of the side surfaces of the insulating elements, while the flexible sheets of the shell are interconnected in the intervals between the insulating elements, and the insulating elements are made with the possibility of adopting a trapezoidal shape in their cross-section when mounted on the insulated object with an increase in their density as they approach the insulated object, characterized in that the sheet placed on the remaining side surfaces of the insulating elements is made of non-woven polypropylene thermally bonded fabric.