RU39673U1 - SHEET HEAT-INSULATING MATERIAL - Google Patents

Abstract

Sheet heat-insulating material is designed to insulate surfaces of complex shape and consists of interconnected insulating elongated rectangular elements, which are a set where sections of elements from deformable and non-deformable under mounting loads of materials with low thermal conductivity alternate. Elements are wrapped.

Description

The inventive utility model relates to sheet heat (cold) insulating materials intended for use as thermal insulation or cold insulation of various non-planar objects, mainly for complex sections of pipelines (turns, branches, etc.), shells, etc.

An analogue of the claimed utility model is a heat-insulating material of finely ground heat-insulating material, compacted in cells of a reinforced honeycomb structure (see application GB No. 2144675, IPC ⁷ F 16 L 59/02, 1985). The essential features of the analogue "thermal insulation material" coincide with the essential features of the claimed utility model.

The disadvantage of the analogue is the inability to use the material to isolate complex-shaped objects without processing on a machine or molding into a shaped product corresponding to the configuration of a complex section.

Another analogue of the claimed utility model is a heat-insulating material in the form of a shell containing flexible removable elements in the form of coated plates made of a material with an insulating packing, and a device for connecting adjacent plates to each other and fixing them on an insulating object (see application FR No. 2597572 IPC ⁷ F 16 L 59/02, 1987). The essential features of the analogue "shell, elements" coincide with the essential features of the claimed utility model.

The disadvantage of the analogue is the complexity, design and installation of the material on objects having a complex shape, the need for special devices for connecting the individual elements of the material and fixing it to an insulated object.

The prototype of the claimed utility model is sheet heat-insulating material having a cellular structure and consisting of interconnected hollow elements of an elongated shape, reinforced with threads (see application JP No. 61-2493, IPC ⁷ V 26 C 63/02, 1986), Essential features of the prototype "Consisting of interconnected elements of an elongated shape" coincide with the essential features of the claimed utility model.

The disadvantage of the prototype is the lack of strength characteristics, the lack of quick access to the damaged area of the insulated object, insufficient maintainability, insufficient heat-insulating properties.

The task to which the claimed utility model is directed is to increase the strength characteristics of the material (up to a value comparable to the weight of an adult), provide quick access to the damaged area of the insulated object, and increase the heat-insulating properties.

To achieve the technical result, a sheet of heat-insulating material, consisting of elongated insulating elements interconnected, contains a shell inside which alternating elongated elements are enclosed along lateral surfaces, each of which consists of successively alternating sections made of elastically deformable material under mounting loads, and sections made of non-deformable material under mounting loads, while the length of the sections is made from elastically deformable of the material is longer than the lengths of sections of non-deformable material, and alternating elements are positioned so that adjacent elements of centers of deformable material are adjacent to centers of sections of non-deformable material, while the shell covers the side surfaces of elongated elements and consists of two sheets, one of which fixed on the side surfaces of elongated elements opposite to the surfaces facing the insulated object, and the other is fixed on the remaining side surfaces on the surfaces of elongated elements.

The essential features of the claimed utility model "containing a shell inside which alternating elements of elongated shape are enclosed on lateral surfaces, each of which consists of successively alternating sections made of elastically deformable material under mounting loads, and sections made of material not deformable during mounting loads, the length of sections of elastically deformable material is greater than the length of sections of non-deformable material, and alternating elements are placed in such a way It is necessary for neighboring elements to have the centers of sections of deformable material opposite the centers of sections of non-deformable material, while the shell covers the lateral surfaces of elongated elements and consists of two sheets, one of which is fixed on the lateral surfaces of elongated elements opposite to the surfaces facing the insulated object and the other is fixed on the remaining lateral surfaces of the elongated elements "are distinctive from the features of the prototype.

Sheet heat-insulating material consists of insulating elements (bars) of an elongated shape of a square, rectangular, trapezoidal or other section close to the indicated ones. The elements forming the sheet material are sequentially alternated between each other, while each of the elements consists of sequentially alternating

sections, some of which are made of elastically deformable material at mounting loads, and others are made of non-deformable material at mounting loads. For example, basalt felt, mineral wool, various non-woven materials, porous rubber, etc. can be used as elastically deformable material during mounting loads. Rigid foams, polyurethane foams, and other solid heat-insulating materials (having low thermal conductivity) can be used as non-deformable material during mounting loads. Elements are enclosed in a fiberglass cladding that covers their side surfaces and does not cover end surfaces; The shell fixes the elements to each other by gluing or flashing the shell and elements with glass fibers and consists of two sheets. As sheets, fiberglass sheets (fiberglass, fiberglass, fiberglass), asbestos fabrics, non-woven sheet materials, etc. can be used. One of the sheets is fixed on the surface of each of the heat-protective elongated elements opposite the insulated surface. Another sheet is fixed on the remaining 3 lateral surfaces of each of the elongated elements. Each elongated element consists of sections of elastically deformable and non-deformable material successively alternating along the length of the element. The length of sections of elastically deformable material is greater than the length of sections of non-deformable material. The elongated elements are placed in the material in such a way that the centers of sections of the deformable material of one of the elements of adjacent elements fall opposite the centers of the sections of the undeformable material of the other element, and the sections of the undeformable material of the element are opposite the sections of the deformable material of the neighboring element. There may be some shift in the mutual arrangement of the centers of the sections of adjacent elements, however, direct contact of non-deformable sections is not allowed (bypassing sections of the deformable material).

The claimed material can be manufactured as follows. The elongated elements prefabricated (using a set of blanks of the deformable and non-deformable material) are sequentially placed on the fiberglass sheet and fixed to the sheet by gluing, piercing, etc. Then, on the other lateral surfaces of the elements, a second fiberglass sheet is fixed (by gluing, stitching, etc.). To do this, the elements are successively aligned in pairs in pairs with surfaces where the first sheet is already fixed (by bending this sheet in the joint area of the elements), and the sheet is fixed on the side surfaces of the elements facing each other, then the second sheet is fixed on the surface of the element facing the insulated surface, fixation is repeated on the side surfaces of the elements facing each other, and again on the surface facing the insulated surface, etc.

Figure 1 presents a specific example of the inventive sheet material (side view). Figure 2 presents a top view of the material (from the side of the insulated object). In FIG. 3 shows a top view of the material (part of the shell removed).

A specific example of the proposed sheet material is a heat-insulating system, which is a carpet 15 m long, 1 m wide and 0.06 m thick. The system consists of bars 1 with a cross-section close to a square shape, sections 2 of which are made of rigid foam, the hardness and strength of which provides its non-deformability under mounting loads, as well as under the weight of an adult, and sections 3 made of mineral wool P-75 or P-125, elastically deformable during mounting loads. The length of sections 2 is ~ 0.06 m, the length of sections 3 ~ 0.08 m. Shell 4 of the system consists of two fiberglass sheets 5 and 6 of the PSXT grade, the first of which is fixed on the surfaces of 7 bars opposite the insulated surface, and the second is fixed on the surfaces 8 and 9 bars facing each other, and surfaces 10 facing the insulated surface. The width 11 and height 12 of each bar is ~ 0.06 m. The bars are fixed to the casing by fiberglass parallel seams 13.

The sheet material of the claimed structure can be bent in the direction opposite to the insulated surface, without deformation of the elongated elements. This makes it easy to roll material for transportation, for example in cardboard boxes, and during storage. This property of the material simplifies the solution of issues of storage and transportation of material. During installation, bending of the sheet towards the insulated surface requires deformation of the deformable elements. Depending on the curvature of the insulated surface, this deformation can be larger or smaller, which simplifies the installation of insulation on various pipe sizes and beyond. due to elastic deformation provides the possibility of reusable use of deformable elements. The presence in the elements of alternating sections of rigid foam, the strength of which is sufficient to support the weight of an adult, and the gap between the hard sections is 0.06-0.08 m (which is much less than the foot of a person), makes it possible to walk on insulation without deforming it. One or more elements can be removed from the finished insulation, for example on a pipeline, as a result of which access to the pipe damage (fistula) will be provided, and then the removed elements can be installed again with glue, cement or gypsum binder, firmware, using staples, etc. as a result, quick access to the damaged section of the pipe and high maintainability are provided. In the case of a complex configuration of an insulated surface, for example, turning or branching a pipeline, a curved surface, etc., within the same sheet, the deformation of various deformable elements may be different. At

This sheet material, due to the deformation of sections of the deformable material, can bend in almost any direction, and not only along or across. The possibility of "diagonal" bending is provided due to the fact that the sections of the deformable material have a greater length than the sections of the undeformable material, and, as a result, there is no direct contact of the undeformable sections. All this allows the sheet material to take the form that is most appropriate for the shape of the insulated surface, which ensures the isolation of surfaces of complex curvature.

Claims (1)

Sheet heat-insulating material, consisting of interconnected insulating elements of an elongated shape, characterized in that the material contains a shell inside which alternating elements of an elongated shape are enclosed on the side surfaces, each of which consists of successively alternating sections made of elastically deformable material under mounting loads and sections made of non-deformable material under mounting loads, while the length of sections of elastically deformable material is greater lengths of sections of non-deformable material, and alternating elements are placed so that adjacent elements of centers of sections of deformable material fall opposite centers of sections of non-deformable material, while the shell covers the side surfaces of elongated elements and consists of two sheets, one of which is fixed on the side surfaces of elongated elements opposite to surfaces facing the insulated object, and the other is fixed on the remaining side surfaces elongated x elements.