RU2608717C1 - Method for repeated heat insulation of pipes - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to heating of residential and other buildings, more specifically to methods for heat insulation of various pipelines to provide energy saving and can be used for heat insulation of pipelines in all industries and agriculture. Method for repeated heat insulation of pipes comprises placing and attaching on a pipe a new heat-insulating layer, made of insulating elements enclosed in a shell. New heat-insulating layer is placed on insulated pipe with possibility of insulating elements enclosing said insulated pipe and fixing through it said shell enclosing insulated pipe along its whole circumference.

EFFECT: technical result is simplification of repeated heat insulation of pipes and reducing time and labour intensity of performing restorative heat-insulating works.

1 cl, 2 dwg

Description

The invention relates to the field of heating of residential and other buildings, more specifically to methods of thermal insulation of various kinds of pipelines to ensure energy saving, and can be used for thermal insulation of pipelines in all industries and agriculture.

As you know, heat-insulating products mounted on pipelines experience a variety of external loads, leading to uneven wear of these heat-insulating products and a significant deterioration in thermal insulation, especially in the upper part of the pipes, that is, in the part that is the most remote from the supporting surface. The most obvious negative factor is the force of gravity, as a result of which, over time, the thermal insulation layer collapses in the upper part of the pipe and the thermal insulation layer sags in the lower part of the pipe. Moreover, if the heat-insulating layer (basalt felt, mineral wool, various fibrous non-woven materials, etc.) significantly loses its heat-insulating properties in the upper part of the pipe, then on the sides and in the lower part of the pipe these properties remain almost unchanged. Therefore, in order to restore full thermal insulation of the pipe, it is enough to insulate only its upper part (that part of the pipe on which the heat-insulating layer has worn out or significantly lost its heat-insulating properties).

In addition to the economic benefits of reducing the number of materials needed to restore effective thermal insulation, this solves the technical problem of simplifying the production of heat-insulating products, reducing time and simplifying installation, as well as an environmental problem caused by the exclusion of operations on the disposal, processing or burial of a dismantled heat-insulating layer.

Methods for thermal insulation of pipes with heat-insulating products are widely known from the prior art, for example, in application GB No. 213124, published 1984, or RU 34688, published 2003, or RU 53751, published 2006, etc. These same well-known products can be used for repeated thermal insulation of pipelines, but only after dismantling the previously installed thermal insulation.

The disadvantages of the known technical solutions include the lack of the possibility of reconditioning without dismantling the old insulation and, as a result, the high complexity and cost of using a heat-insulating structure to repair insulation in pipelines in operation, since such repairs require complete dismantling of the old insulation, so and disposal or disposal of dismantled insulation.

The task to be solved by the claimed method is aimed at providing the possibility of restorative thermal insulation of pipelines without dismantling the previously installed thermal insulation.

The technical result achieved by the implementation of the task is to simplify the repeated thermal insulation of pipes and reduce the time and laboriousness of conducting thermal insulation works.

The technical result is achieved due to the fact that the method of repeated thermal insulation of pipes consists in placing and securing a new thermal insulation layer on the pipe made of insulating elements enclosed in a shell. New operations according to the proposed method are that a new heat-insulating layer is placed on the insulated pipe with the possibility of insulating elements to cover part of the circumference of the insulated pipe and fasten it by means of a shell covering the insulated pipe around its entire circumference.

The proposed new operations to cover with insulating elements only part of the circumference of the insulated pipe, and the sheath of the entire pipe with previously installed insulation, can significantly simplify the repeated thermal insulation of pipes and reduce the time and laboriousness of reconstructive thermal insulation works by eliminating the operations of dismantling the previously installed insulation and facilitating the installation of a new thermal insulation layer.

In the future, the invention will be described in detail in the description section of the "Implementation of the invention" and in the figures, which depict:

- FIG. 1 is a schematic cross-sectional view of a re-insulated pipe,

- FIG. 2 is a schematic cross-sectional view of a thermal insulation product intended for repeated thermal insulation of pipes.

It should be noted that one of the preferred embodiments of the proposed method is disclosed below.

It should also be noted that the phrase “repeated thermal insulation” should be interpreted in a broad sense, that is, the sign “repeated” means being performed again, repeatedly, not for the first time.

The essence of the proposed method is as follows. There is a previously heat-insulated pipe 1, the heat-insulating layer 2 of which cannot effectively perform the function of thermal insulation due to partial wear, consisting, as mentioned above, of thinning the part that covers the top of the pipe and sagging in the lower part of the pipe. To restore complete thermal insulation of the pipe along its entire circumference, it is proposed without dismantling the damaged thermal insulation layer to place and fix on this pipe a new thermal insulation layer made of insulating elements enclosed in a shell. A new heat-insulating layer is placed on the pipe so that the heat-insulating elements overlap the upper part of the pipe with a layer of worn-out previous heat insulation, and the shell in which the new heat-insulating layer is enclosed covers the entire pipe in a circle, compressing, if possible, due to the interference, the sagging layer of the previous thermal insulation to the pipe. After tight compression by the pipe shell, the shell is reliably lapped, providing a tight pressing of the insulation to the pipe.

For the implementation of the proposed method, for example, the heat-insulating product shown in FIG. 2.

Such a product contains a heat-insulating layer consisting of insulating elements 3, in particular elongated bars made of a material that is elastically deformable under mounting loads. As such material, basalt felt, mineral wool, various fibrous nonwoven materials, etc. can be used. The insulating elements 3 are enclosed in a shell 4, which covers their side surfaces. The shell 4 holds the insulating elements 3 at a small distance from each other and consists of two flexible sheets, for example, fiberglass, fiberglass, basalt fabric, fiberglass, fiberglass, foil plastic, etc. One of the flexible sheets is placed on the surfaces of each of the insulating elements 3, opposite insulated surface, and can be additionally waterproofed, reinforced with metal foil or protected by any other suitable method. Another sheet is placed on the remaining three side surfaces of each of the insulating elements 3. In the spaces between the insulating elements, the flexible sheets are fixed to each other in any accessible and reliable way, for example, with glue and / or firmware, etc. In areas free of insulating elements, it is also advisable to fix flexible sheets to each other in any accessible and reliable way, for example, with glue.

By fixing the initially specified distance between the insulating elements 3, the flexible sheets interconnected in the spaces between the insulating elements leave a sufficient degree of freedom for the insulating elements, allowing them to take the necessary shape in their cross section when mounted on an insulated object.

The number of insulating elements 3 is selected from the calculation of the coverage of part of the circumference of the insulated pipe. Since heat-insulating products are manufactured under standardized pipe sizes, it is preferable to perform a heat-insulating layer with the ability to cover no more than 2/3 of the pipe circumference (i.e., the heat-insulating layer occupies no more than 2/3 of the inner shell area 4). The decrease in the number of insulating elements 3 (in comparison with the known analogues) provides a simplification of the design of the insulating product and significantly reduces the time and complexity of its production.

The heat-insulating product may contain bandage elements 5 made, for example, of wire or glass bandage.

The heat-insulating product may contain an element 6 (for example, a board) designed to improve the fixation of the overlap of the sheath 4 at the end of the installation of the heat-insulating product on the pipe 1. The overlap can be fixed by any available method, for example, brackets, screws, glue, etc.

Thus, the proposed method provides the placement of a heat-insulating layer with the possibility of insulating elements to cover part of the circumference of the insulated pipe, which allows for the use of a heat-insulating structure when repairing thermal insulation of pipelines without dismantling the previously installed thermal insulation, which reduces the cost, simplifies and speeds up the process of restoring thermal insulation of pipelines and eliminates the need for disposal earlier used thermal insulation.

Claims (1)

A method of re-insulating pipes, which consists in placing and securing on a pipe with installed insulation a new heat-insulating layer made of insulating elements enclosed in a shell, characterized in that the new heat-insulating layer is placed on the insulated pipe with the possibility of insulating elements covering part of the circumference of the insulated pipe and securing it by means of a sheath covering the insulated pipe along its entire circumference.

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