RU167150U1 - PIPE HEAT INSULATION DEVICE - Google Patents

Abstract

1. The pipe insulation device, characterized in that it contains a thermal insulation layer, a protective shell, between which there is a layer of polyurethane foam, while the thermal insulation layer has a thermal conductivity coefficient similar to the thermal conductivity coefficient of the polyurethane foam layer, and centering supports made of material with a thermal conductivity coefficient similar to the coefficient thermal conductivity of a layer of polyurethane foam. 2. The device according to claim 1, characterized in that the thermal insulation layer is based on extruded polystyrene foam, foam glass, stone wool and is located on the outer surface of the pipe with an anti-corrosion coating based on epoxy, polyurethane, polyethylene, polypropylene coatings, consisting of one or several layers. 3. The device according to claim 1, characterized in that the protective shell is made spiral-wound with a lock seam connection from galvanized sheet steel. 4. The device according to claim 1, characterized in that the protective shell is made spiral-wound with an internal lock seam connection from cold-rolled sheet steel with an outer three-layer polyethylene coating. The device according to claim 1, characterized in that the protective sheath is made of extruded polyethylene. The device according to claim 1, characterized in that the coefficient of thermal conductivity is located in the range of 0.03-0.035 W / (m · K). 7. The device according to claim 1, characterized in that the centering supports are located on the upper hemisphere of the thermal insulation layer. The device according to claim 1, characterized in that the centering bearings are located on the inner surface of the protective sheath.

Description

The invention relates to the field of thermal insulation of tubular products, in particular to pipe thermal insulation devices (heat-insulating product), and can be used in the construction of a pipe / pipeline thermal insulation coating.

The prior art construction of pipe insulation, which is fixed on the outer surface of the pipe and between each other layers of elastic heat-insulating material, in which refractory adhesive is used as fixing material (RU 51703, 02.27.2006).

The disadvantage is the low thermal insulation properties and short life.

Known thermal insulation of the pipeline, including the pipeline, the protective sheath and sandwiched between them multilayer insulation. Thermal insulation contains closed air cavities formed between screens of reflective heat-conducting material and support rings, while support rings are placed on the pipeline, screens of reflective heat-conducting material are placed between them, one above the other with an air gap (RU 30919, 07/10/2003).

This design also does not provide sufficient thermal insulation, in addition, it has a low life and complexity in manufacturing.

Known heat-insulating product for pipelines for various purposes, including shells, grooves and ridges, a waterproofing layer, fasteners, and containing two shells of a semicylindrical shape made of heat-insulating material, an upper shell with a groove and a crest front and rear for connection with neighboring upper shells to form transverse connecting seams with a groove inside and a crest on the outside along the horizontal edges and a lower shell with a groove and a crest in the front and back for connecting to adjacent lower shells with the formation of transverse connecting seams with a groove on the outside and a crest from the inside along horizontal edges, as well as openings from one to several per linear meter of the length of the lower shell in its lowermost part to remove moisture condensate from the product to the outside, fixed as a whole, by grooves and ridges of the upper and lower shells, which together form longitudinal butt joints around the pipeline with a waterproofing layer with holes matching localization with the holes of the lower shell, and fasteners Does not coincide with the same holes (RU 85977, 20.08.2009).

However, the aforementioned disadvantages are not eliminated in this product design.

The closest analogue of the proposed utility model is a device for thermal insulation of a pipeline containing heat-insulating material from ultralight monolithic foam concrete and an external protective coating. The protective coating is mounted on centralizers made of heat-insulating and heat-resistant material, while the protective coating has ventilation openings closed with a water-repellent and vapor-permeable material (RU 68092, 10.11.2007).

Due to the presence of centralizers and ventilation holes, a cold bridge is formed, which reduces the thermal insulation of the device, and also the specified device has a low lifetime.

The problem to which the proposed utility model is directed is to create a pipe insulation device that would eliminate the above disadvantages.

The technical result achieved by the implementation of this utility model is to increase the operational and physicomechanical qualities / characteristics, which leads to an increase in body insulation properties and an increase in the life of a thermally insulated structure.

The specified technical result is achieved in a pipe insulation device containing a thermal insulation layer and a protective shell, between which a layer of polyurethane foam is located, while the thermal insulation layer has a thermal conductivity coefficient similar to the thermal conductivity coefficient of a polyurethane foam layer.

The thermal insulation layer is made on the basis of extruded polystyrene foam, stone wool, foam glass and is located on the outer surface of the pipe with an anti-corrosion coating based on epoxy, polyurethane, polyethylene, polypropylene coatings, consisting of one or several layers.

The protective shell is made spiral-wound with a lock seam connection from galvanized sheet steel, or spiral-wound with an internal lock seam connection from cold-rolled sheet steel with an outer three-layer polyethylene coating, or from extruded polyethylene

The thermal conductivity coefficient is in the range of 0.03-0.035 W / mK.

The pipe insulation device further comprises centering supports located on the upper hemisphere of the insulation layer and made of a material with a thermal conductivity coefficient similar to that of the polyurethane foam layer.

The pipe insulation device further comprises centering supports located on the inner surface of the containment and made of a material with a thermal conductivity coefficient similar to that of the polyurethane foam layer.

The centering supports are made of segments of rigid polyurethane foam or expanded polystyrene in terms of their physical and mechanical properties that meet the requirements of the main layer of polyurethane foam.

The pipe insulation device is placed on a steel pipe, the inner surface of which is coated with an internal anticorrosion coating based on epoxy, silicate enamel, polyurethane materials, consisting of one or several layers, and the outer surface of which is coated with an external anticorrosion coating based on epoxy, polyurethane, polyethylene, polypropylene coatings, consisting of one or more layers.

On the outer surface of the pipe there is a heating element, which is made either in the form of a cable or in the form of an element of an induction-resistive skin of the system, which is a satellite tube made of ferromagnetic material with a conductor made of non-magnetic material placed in it.

The pipe insulation device consists of:

- a thermal insulation layer based on extruded polystyrene foam, stone wool, foam glass, located on the outer surface of the pipe with an anti-corrosion coating. The insulation layer occupies the annular volume in the range from 25 to 90% and can be made in the form of rectangular segments or shells;

- a protective sheath spiral-wound with a lock seam connection made of galvanized sheet steel, spiral wound with an internal lock seam connection made of cold-rolled sheet steel with an outer three-layer polyethylene coating, an extruded polyethylene sheath;

- a layer of polyurethane foam located between the thermal insulation layer based on extruded polystyrene foam, stone wool, foam glass and the inner surface of the protective sheath. A layer of polyurethane foam (after curing) occupies the entire remaining free volume of the annulus with a density of at least 60 kg / m3.

The pipe thermal insulation device further comprises centering supports, which are made of a material having the same thermal conductivity coefficient with a thermal conductivity coefficient of the polyurethane foam layer and the thermal insulation layer, which is in the range of 0.03-0.035 W / mK.

Centering supports are located on the inner surface of the containment or on top of the thermal insulation layer.

The centering bearings are made of segments of rigid polyurethane foam in terms of their physical and mechanical properties that meet the requirements of the main layer of polyurethane foam.

The manufacturing process of a pipe insulation device consists of the steps:

- applying a corrosion-resistant internal or external coating to the pipe (if necessary),

- installation on the outer surface of the pipe of a layer of thermal insulation (polymer heat-insulating materials - extruded polystyrene foam, stone wool, foam glass made in the form of rectangular segments or shells) using a polymer tie band,

- installation on the outer surface of the pipe, on the upper hemisphere of the insulation layer of the centering supports (centering supports are made of rigid polyurethane foam),

- assembly of the structure of the pipe in the pipe,

- pouring the free annular space with polyurethane foam using high-pressure filling machines. As a result of the foaming process, polyurethane foam fills the entire free annular space with the formation of adhesive bonds between it and the insulation layer (polymer insulation of extruded polystyrene foam, stone wool, foam glass) forming a single monolithic layer.

Since inside the polyurethane foam layer there are no centering supports that are cold bridges, or the centering supports are made of material with a thermal conductivity coefficient similar to that of the polyurethane foam layer and thermal insulation layer, as a result of which there are no cold bridges, an increase in body insulation properties occurs. That is, the use of polyurethane foam and other cured polymeric materials with thermal conductivity in the range of 0.03-0.035 W / mK and compressive strength at 10% deformation of at least 0.3 MPa allows to increase thermal insulation properties.

In addition, due to the claimed design of the pipe insulation device, the water absorption of the heat-insulating layer is reduced from 10% to 1%, thereby increasing the life of the insulated structure

Claims (9)

1. The pipe insulation device, characterized in that it contains a thermal insulation layer, a protective shell, between which there is a layer of polyurethane foam, while the thermal insulation layer has a thermal conductivity coefficient similar to the thermal conductivity coefficient of the polyurethane foam layer, and centering supports made of material with a thermal conductivity coefficient similar to the coefficient thermal conductivity of a layer of polyurethane foam. 2. The device according to claim 1, characterized in that the thermal insulation layer is made on the basis of extruded polystyrene foam, foam glass, stone wool and is located on the outer surface of the pipe with an anti-corrosion coating based on epoxy, polyurethane, polyethylene, polypropylene coatings, consisting of one or more layers. 3. The device according to p. 1, characterized in that the protective shell is made spiral-wound with a lock seam connection of sheet steel galvanized steel. 4. The device according to p. 1, characterized in that the protective shell is made spiral-wound with an internal locking seam connection from cold-rolled sheet steel with an outer three-layer polyethylene coating. 5. The device according to claim 1, characterized in that the protective shell is made of extruded polyethylene. 6. The device according to p. 1, characterized in that the coefficient of thermal conductivity is in the range of 0.03-0.035 W / (m · K). 7. The device according to claim 1, characterized in that the centering supports are located on the upper hemisphere of the insulation layer. 8. The device according to claim 1, characterized in that the centering bearings are located on the inner surface of the protective sheath. 9. The device according to p. 7 or p. 8, characterized in that the centering supports are made of segments of rigid polyurethane foam or expanded polystyrene.