RU24263U1 - PIPE HEATER - Google Patents

Abstract

1. A pipe insulation containing a heat-insulating layer and a protective sheath, characterized in that it is made in the form of a semi-cylindrical module, the inner diameter of which is equal to the outer diameter of the insulated pipe, the opposite surfaces of the ends of the half-cylinder are provided with locking elements such as a spike-groove, the insulating layer is made of polyurethane foam with a density of 50-80 kg / m, and the protective shell is made in the form of a metal foil. 2. The pipe insulation according to claim 1, characterized in that at least one insulated conductor is located on the inner surface of the module, the ends of the conductors are led out through the insulator. The pipe insulation according to claim 2, characterized in that the conductors are made in the form of a cable. The pipe insulation according to claim 2, characterized in that the conductors are made in the form of an insulated tape. The pipe heater according to claim 1, or 2, or 3, or 4, characterized in that the length of the module does not exceed two meters.

Description

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Pipe insulation.

The utility model relates to thermal protection devices and can be used in various sectors of the national economy. The primary area of use is the protection of apparatus and equipment operating at cryogenic temperatures from heat influx from the environment, as well as in panels of building structures.

Cellular thermal insulation is known (Heat transfer at low temperatures. Edited by W. Frost, translated from English by M. Mir, 1977, p. 46, Fig. 2.13), consisting of cellular reinforcement made of fiberglass with phenolic resin and filled by; low-density shuretan, an adhesive for tightly pasting foam, cladding and sealing barriers. Instead of polyurethane, honeycombs can be filled with helium.

The disadvantage of this thermal insulation is the low manufacturability due to both the laboriousness of manufacturing the cell panels themselves and the complexity of the process for forming the insulation itself. In addition, honeycomb panels have reduced strength characteristics, since when exposed to a load, their walls work both in compression and in longitudinal stability.

Thermal insulation is known (ed. St. USSR No. 1679129, F 16 L 59/06, 1989), intended for use in cryogenic technology, which consists of honeycomb fittings, a sealing layer and cladding, honeycomb fittings are made in the form of several directly in contact layers whose cells are displaced relative to each other, and, in addition, cells

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reinforcing bars have the shape of a regular hexagon in cross section, and the layers are shifted along one of its diagonals by half the cell.

The disadvantage of this thermal insulation is the low manufacturability, due to both the complexity of the manufacturing process of the honeycomb panels themselves and the difficulty of forming the insulation itself, since it is necessary to maintain the accuracy of the shift layers. In addition, the panels have reduced strength characteristics, since when exposed to loads in their walls, both compression stress and longitudinal stability stress arise.

Known pipe insulation containing a heat-insulating layer and a protective sheath, in which the heat-insulating layer is made of mineral wool piercing mats wound on the pipe, and the protective sheath is made in the form of a cylinder. (Patent of the Russian Federation No. 1536155, IPC: F 16 L 59/06, published. 1990, prototype).

The disadvantage of protrusion, as with the analogue, is its low manufacturability, low strength, high weight of the product, and high labor input when assembling on a heating main.

The main disadvantage of the prototype is the freezing of the pipeline at low temperatures, in the case of seasonal use of the pipeline, as well as local freezing with a large length of the pipeline, when there are sharp temperature changes along the length of the pipeline.

The claimed utility model is aimed at solving the problem of creating thermal insulation with higher manufacturability and improved strength characteristics.

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improving strength characteristics, reducing the weight of the product, reducing labor costs during assembly on the heating main, the ability to maintain a stationary temperature regime of the pipeline and leaking fluid, eliminating freezing and traffic jams, the possibility of applying insulation to the pipeline of any length.

The technical result is achieved by the fact that the pipe insulation containing the heat-insulating layer and the protective sheath is made in the form of a half-module, the inner diameter of which is equal to the outer diameter of the insulated pipe, the opposite surfaces of the ends of the half-cylinder both along the generatrices and along the guides of the half-cylinder are provided with locking joints of the pin type -groove, the insulating layer is made of polyurethane foam with a density of kg / m, and the protective shell is made in the form of a metal foil.

At least one insulated conductor is located on the inner surface of the module, the ends of the conductors are brought out. Conductors are made in the form of a cable, or in the form of an insulated tape. The length of the module does not exceed two meters. The wall thickness of the half cylinder varies depending on the diameter of the pipe. For pipelines of housing and industrial water supply not less than 1.0.-1.5 cm, and for extended pipelines of the intake type or for oil pipelines not less than 3.0 cm. In practice, module thickness deficiencies can be compensated for by heating.

The essence of the utility model is illustrated in figL, figa, fig. 26, and FIG. 3.

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Figure 1 presents a three-dimensional image of the module, where 1 zashchgny coating in the form of a metal foil; 2 - sealant body made of polyurethane foam; 3 - insulated conductors.

In FIG. 1 shows the grooves and protrusions of the lock connection of the module for articulating the module into a pipe, the size of a module and for articulating the modules in length, and the length of the insulation can be set to any size.

In Fig. 2a, a view of the module from the upper end is shown, where 1 is a protective coating in the form of a metal foil, 2 is the body of the module insulation made of polyurethane foam, 3 are insulated conductors (in this case, in the form of a cable), 4 are the ends of the conductors brought out through the goolator.

In FIG. 26, a module view from the bottom is presented. The designations are the same as in FIG. 2a.

In FIG. Figure 3 shows an end view of the connection of two modules to illustrate a closed insulation.

The body of module 2 is made of polyurethane foam with a density of

50 to 80 kg / m. At a lower density, the product becomes brittle, i.e. the module may crumble, especially during transport. Even in the manufacture of the module, through holes are possible, which does not ultimately provide thermal insulation.

At a density of the body of module 2 above 80 kg / m, its strength and solidity increase, but its thermal insulation properties decrease.

The length of the module can be any, but from the point of view of the manufacturability of the process and the strength of the product, it is not practical to increase the length of more than two meters.

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The optimal longitudinal size of the module is 1.2-g1.5 meters. At the same time, high manufacturability, high strength of the module, size and weight, convenient for transportation and assembly, are achieved.

The device operates as follows. The pipeline pipe on both sides as shown in FIG. 3 surround with two modules. It should be noted that all modules are identical, which leads to universality. Production of the required number of modules in one matrix allows you to insulate the pipeline of any length, because they are also well connected without gaps at the ends of the cylinder. The protective coating 1 protects the body of the seal 2 from mechanical damage, being at the same time a reflector. Therefore, the body temperature of the seal 2 is stable

In conditions of low temperature, conductors 3 are included in the work. The insulation of conductors 3 is necessary, because they, as a rule, lie on the surface of an insulated pipe.

The external ends brought out through the insulator, the ends of u) of the ovodnikov 4 are connected to an external current source. The current passing through the conductors 3 heats them and transfers heat to the pipe and into the pipeline, heating up the liquid flowing in it.

It is not necessary to connect all conductors 3 to a current source. The connection of the current source to the conductors 3 is selected from the local climatic conditions in each region, since the length of the pipeline can reach hundreds of kilometers. By choosing the number of conductors 3 for connection to a current source, both in a single module and along the entire length, they support any temperature set in advance in the current environment. It is especially important to maintain the temperature for viscous fluids, as at low temperatures, their fluidity decreases.

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Claims (5)

1. A pipe insulation containing a heat-insulating layer and a protective sheath, characterized in that it is made in the form of a semi-cylindrical module, the inner diameter of which is equal to the outer diameter of the insulated pipe, the opposite surfaces of the ends of the half-cylinder are equipped with spike-groove locking elements, the heat-insulating layer is made of polyurethane foam density of 50-80 kg / m ³ and the protective shell is made in the form of a metal foil.  2. The pipe heater according to claim 1, characterized in that at least one insulated conductor is located on the inner surface of the module, the ends of the conductors are brought out through the insulator.  3. The pipe heater according to claim 2, characterized in that the conductors are made in the form of a cable.  4. The pipe insulation according to claim 2, characterized in that the conductors are made in the form of an insulated tape. 5. The pipe heater according to claim 1, or 2, or 3, or 4, characterized in that the length of the module does not exceed two meters.