RU187349U1 - Self-locking split thermal lock for heat insulating elements - Google Patents

Abstract

The technical solution relates to the field of power engineering, and in particular to devices used for thermal insulation of pipelines formed by segments joined together (cylindrical heat-insulating shells), preferably from foamed polymeric materials or mineral wool materials. The technical result is to increase the installation speed without additional devices providing the mounting position by fixing the prefabricated elements, which is achieved due to the friction forces arising in the lock providing a more tight and durable connection, allowing its dismantling if necessary.

A self-locking detachable thermal lock for heat-insulating elements, characterized in that it includes a longitudinal groove and, intended to enter into it, a reciprocal longitudinal protrusion, the longitudinal protrusion made of an elastic material, while the size of the longitudinal protrusion exceeds the size of the groove. 7 c.p. f-ly, 8 ill.

Description

The technical solution relates to the field of power engineering, and in particular to devices used for thermal insulation of pipelines formed by segments joined together (cylindrical heat-insulating shells), preferably from foamed polymeric materials or mineral wool materials.

State of the art

When thermal insulation of pipelines and equipment often a technical problem arises, which is due to the fact that due to many factors it is impossible to produce a single product, therefore, in the manufacture of thermal insulation products use a multi-segmented shape of the product. At joints, it is optimal to make special thermal locks in order to reduce heat loss (to exclude the formation of "thermal bridges", cold bridges).

At the same time, during the installation process there are problems associated with the fact that detachable connections (see the list below) require a preliminary installation connection (wire, bandage tape), which cannot be achieved during work by one person.

From the development of technology, the following technical solutions are currently known to prevent excessive heat loss at the junctions of individual segments:

“Overlap”, Z-shaped section (for flat products the so-called “quarter”)

"Semicircular castle"

Thorn groove

"Simple bevel"

"triangular"

one-piece dovetail connection is closest to the described model, but is characterized by its one-piece nature: the segments are connected by sliding one into another during the assembly process. A significant drawback of this solution is the impossibility of rapid dismantling without complete or partial destruction of the insulating structure (shell).

The following sources of information are known from the patent literature.

Known locking element of the insulating element, made stepped along the longitudinal side of the cylindrical closable shells (SU 811051 A1, F16L 59/05, 03/07/1981).

A known locking element of a heat-insulating element, including a protrusion and a groove, between which a heat-insulating liner is located (SU 341918 A1, F16L 59/05, 06/14/1972).

Known labyrinth locks on the surface of the connection between the half-cylinders of non-combustible material for insulating the pipe (RU 2570538 C1, F16L 59/14, 12/10/2015).

Known lock thermal insulation of the pipe, made in the body of the tubular shell with a hollow cylindrical body, and the body of the pipe body contains two halves of the shell; a groove is formed on the outer lateral end of each end surface of the first half-shell; the convex step is located on the outer lateral end of the other end surface of the second half-shell (CN104100804 A, F16L 59/02, 10/15/2014).

Known heat pipe lock based on a longitudinal adhesive connection (US 4748060 A, F16L 59/02, 1988-05-31).

Known lock heat-retaining structure in the form of two interconnected cylindrical parts, which when connected due to the selected configuration of the protrusions and grooves and troughs prevent condensation of dew (JP 2002139194 A, F16L 59/147, 05.17.2002).

Known locking elements, including those in which the groove is made along the long side of the half cylinder, and the protrusion is made on the opposite side also along the long side of the half cylinder (JPS 51130969 U, F16L 59/05, 10/22/1976).

A castle is known that combines segments of heat-insulating shells made of expanded polystyrene foam, and the segments are combined into a structure forming a heat-insulating shell around the pipeline and consisting of N sectors, diametrically joined together in a lock, and the bandages are made in the form of tightening tapes secured with a lanyard equipped with stopper (RU 40433 U8, F16L 59/00, 09/10/2004).

Known locking element at the end of the connected heat-insulating blocks made having beveled protrusions and their corresponding troughs (RU 204781, F16L 59/12, 10.11.1995).

Known locking elements of the thorn-groove type, made on opposite surfaces of the ends of the half-cylinder, the heat-insulating layer is made of polyurethane foam with a density of 50-80 kg / m ³ and the protective shell is made in the form of a metal foil (RU 24263 U1, F16L 59/06, 27.07 .2002).

Known thermal locking joints of the protrusion-trough type, made with an additional inner layer of more heat-resistant material, offset along the perimeter and along the length of the shell relative to the outer layer (RU 70958 U1, F16L 59/12, 02.20.2008).

The closest analogue to the claimed technical solution is a thermal lock for pipe insulation made on two inextricably connected open-ended curved cylindrical heat-insulating shells, one of the shells having a longitudinal protrusion on one side and a longitudinal hollow on the other (RU 172059 U1, F16L 59 / June 28, 2017).

The disadvantages of the closest analogue are the relative complexity of the installation, lack of tightness and one-piece locking connection, which does not allow re-dismantling and installation of the shell. The proposed technical solution is aimed at eliminating these shortcomings.

The technical result is to increase the installation speed without additional devices providing the mounting position due to the fixation of prefabricated elements, which is achieved due to the friction forces arising in the lock, providing a more tight and durable connection, allowing its dismantling if necessary.

The technical result is achieved due to the fact that the self-locking detachable thermal lock for heat-insulating elements includes a longitudinal groove and a reciprocal longitudinal protrusion intended to enter into it, the protrusion being made of elastic material, and the protrusion is larger than the size of the groove.

The width of the cross section of the longitudinal protrusion is 1-10%, preferably 4-6%, greater than the width of the cross section of the longitudinal groove.

The walls of the longitudinal groove are also made elastic.

The cross section of the longitudinal protrusion has a rectangular shape.

The cross section of the longitudinal protrusion has a rounded or rounded shape.

The end parts of the longitudinal protrusion have bevels or chamfers, narrowing, or rounding.

The longitudinal groove preferably has a rectangular cross section and has constrictions, fillets, bevels or chamfers at its edges.

The longitudinal protrusion is made of the same material as the material forming the walls of the groove. The device is illustrated by drawings.

In FIG. 1 is an isometric view with segments assembled around the pipe to form locks.

In FIG. 2 Isometric view of one heat-insulating element (cylindrical segment) is shown.

In FIG. 3 and 4, the entry of the longitudinal protrusion into the longitudinal groove during the formation of the castle.

In FIG. 5 diagram of the castle (castle connection).

In FIG. 6 is a diagram of the entry of a longitudinal protrusion with a bevel or chamfer into the groove during the formation of the castle.

In FIG. 7 is a diagram of the entry of a protrusion with a rounded end into the groove during the formation of the castle.

In FIG. 8 shows a dismantling diagram.

The self-locking detachable thermal lock for thermal insulation includes a longitudinal groove 1 and, intended to enter into it, a reciprocal longitudinal protrusion 2, and the protrusion 2 is made of an elastic material with the ability to elastic deformations, while the transverse dimension of the protrusion exceeds the transverse dimension of the longitudinal groove, and the walls of the longitudinal groove are also made elastic.

The size "L" of the protrusion 2 exceeds the size "S" of the longitudinal groove 1 by 1-10%, preferably by 4-6%.

The cross section of the longitudinal protrusion 2 has a rectangular shape, or rounded or rounded shape.

To facilitate the entry of the longitudinal protrusion 2 into the longitudinal groove 1, the end parts have constrictions, or fillets, or bevels or chamfers.

Preferably, the longitudinal protrusion is made of the same material as the material forming the walls of the longitudinal groove.

The proposed technical solution is based on the "protrusion-groove" system and is proposed for fibrous and foamed polymer heat-insulating materials, the compressibility of which is more than 1%, and the elasticity is not less than 90%.

The operation of the lock (castle connection) can be illustrated by the example of two joined heat-insulating elements 3 (Fig. 1 and 2). Each of the aforementioned heat-insulating elements 3 is made in the form of a heat-insulating curvilinear (cylindrical) shell of elastic material, on one side of which a longitudinal groove 1 is made, and on the other hand, an elastic longitudinal protrusion 2. The longitudinal groove and protrusion are extended and located along the long side of the element 3. Moreover, the width "L" of the cross section of the longitudinal protrusion of each element is 1-10%, preferably 4-6%, greater than the width "S" of the cross section of the longitudinal groove 1 on the opposite side of the loizolyatsionnogo element 3.

When joining the two described elements 3, the elastic longitudinal protrusion 2 under the action of an external force “F”, with an interference, gradually enters the longitudinal groove 1, firmly fixed in it “by surprise” due to friction forces, and filling the cracks and voids between it and the wall of the longitudinal the groove of the neighboring element due to the elasticity of the material (mineral wool or polyurethane foam) from which the heat-insulating element 3 is made as a whole.

This ensures the adhesion, as well as the sealing of the lock (lock connection). In the same way, dock the next element 3 of a similar design.

To facilitate the entry of the longitudinal protrusion 2 into the smaller longitudinal groove 1, its end parts may have bevels or bevels 4, small contractions, or have rounded 5 (Fig. 6, 7).

Thus, each thermal insulation element 3 is preferably curved to enclose the pipe 6 (Fig. 1) and includes a longitudinal groove 1 intended for the longitudinal protrusion 2 of the adjacent element 3 to enter into it. Moreover, the longitudinal protrusion 2 of each element 3 is made of an elastic material with the ability to reverse elastic deformations, while the transverse dimension of the longitudinal protrusion exceeds the transverse dimension of the longitudinal groove by 1-10%.

The longitudinal groove 1 of the element 3 preferably has a rectangular cross section and may have tapering, rounding, bevels or chamfers on its final parts (edges) to facilitate the entry of the longitudinal protrusion 2 into the longitudinal groove 1 of the adjacent heat insulation element 3 (not shown conditionally in the drawings) .

The heat-insulating elements 3 are made of elastic materials, such as foamed plastic, for example, polyurethane foam or fibrous materials, such as stone wool.

The technical solution is based on the ability of the materials from which the heat-insulating elements 3 are made to compressibility (deformation) and the subsequent at least partial restoration of their shape (elastic deformation). Moreover, when installing a longitudinal protrusion in a longitudinal groove, this connection will self-fix, with the possibility of further opening and closing this thermal lock several times (Fig. 4, 8), if necessary, periodic dismantling and installation of the product).

At the same time, due to the friction force in the self-locking detachable lock (lock connection), it is possible to carry out installation work by the forces of one employee without the use of temporary fixing plates or other mounting devices.

It is also possible to assemble the product in various conditions, bringing it to a high mounting readiness. For example, a cylindrical shell consisting of eight heat-insulating elements 3 (segments) can be assembled in two halves, each of which will consist of previously docked four heat-insulating elements 3 each. Further, it is possible to assemble (dock) the pre-assembled halves directly at the installation site, which is much more convenient in the field or in places where the sequential installation of eight segments (parts) is difficult.

In this case, it is desirable to choose the difference between the transverse dimensions and the areas of the longitudinal grooves and protrusions, thus ensuring reversibility of the deformation of the longitudinal protrusion and groove in order to prevent cracking and tearing of the material, which may impair the joint tightness and also entail the possibility of mounting after disassembling the cylindrical shell .

Based on this condition, empirically, a limit was established for the excess of the size of the longitudinal protrusion over the size of the longitudinal groove of 1-10%, since in case of exceeding the limit of 10%, deformation of the walls of the longitudinal groove and the difficult entry of the longitudinal protrusion 2 into longitudinal groove 1. The lower limit of 1% is due to the fact that with a lower value the necessary interference and fixing and sealing of the longitudinal protrusion in the longitudinal groove will not be provided.

Claims (8)

1. Self-locking detachable thermal lock for heat-insulating elements, characterized in that it includes a longitudinal groove and intended to enter it, the reciprocal longitudinal protrusion, and the protrusion is made of elastic material, while the size of the protrusion exceeds the size of the groove. 2. A self-locking releasable thermal lock according to claim 1, characterized in that the cross-sectional width of the longitudinal protrusion is 1-10%, preferably 4-6%, greater than the cross-sectional width of the longitudinal groove. 3. Self-locking detachable thermal lock according to claim 1, characterized in that the walls of the longitudinal groove are also made elastic. 4. Self-locking detachable thermal lock according to claim 1, characterized in that the cross section of the longitudinal protrusion has a rectangular shape. 5. Self-locking detachable thermal lock according to claim 1, characterized in that the cross section of the longitudinal protrusion has a rounded or rounded shape. 6. Self-locking detachable thermal lock according to claim 1, characterized in that the end parts of the longitudinal protrusion have bevels or chamfers, narrowing or rounding. 7. The self-locking detachable thermal lock according to claim 1, characterized in that the longitudinal groove preferably has a rectangular cross section and has narrowing, rounding, bevels or chamfers at its edges. 8. Self-locking detachable thermal lock according to claim 3, characterized in that the longitudinal protrusion is made of the same material as the material forming the walls of the groove.

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