UA105474C2 - Multi-layer elastomer branch - Google Patents

Abstract

The invention relates to multi-layer elastomer branches made of several materials and intended for angular connection of pipes or pipeline fittings in mains for transportation of fluid products under pressure or rarefaction. The multi-layer elastomer branch arranged as a bent multi-layer shell (1) that includes the inner wear-resistant layer (2) made of rubber, inner protective layer (3) made of rubber, connected to each other, intermediate layer (4) placed between those (2 , 3), arranged as a placed with crossing cross and long layers of beams, and end connection elements (5) for connection to neighboring pipes or pipeline fittings, those include circular frames (6) surrounded with intermediate layer (4) by the whole surface, at that the outer protective layer (3) covers the outer surfaces of the bent shell (1) and the end frames (6) of the end connection elements (5) and connected to the inner wear-proofed layer (2) in the place of joint of those. According to the invention, the branch additionally includes the outer armoring layer (7), this surrounds the outer protective layer (3) and comprises several power bandages (8) placed along the axis 0-0 of the multi-layer shell (1) with a gap t between the neighboring power bandages (8). And the circular frames (6) of the end connection elements (5) additionally include cell blocking bandages (9) placed in the outer protective layer (3) and connected to the circular frames (6) of the end connection elements (5) by means of long rods (10) placed in the outer protective layer (3) in perimeter of that one. The invention makes it possible to increase operational reliability and to prolong the term of operation of the branch. 1 n.p. f-la. 3 p.p. f-lae. 3 fig.

Description

frames (6) of end connecting elements (5) and combined with an internal wear-resistant layer (2) at their junction. According to the invention, the lead additionally contains an outer armor layer (7), which covers the outer protective layer (3), and consists of several power bandages (8) located along the 0-0 axis of the bent multilayer shell (1) with a gap between adjacent power bandages (8), and the ring frames (b) of the end connecting elements (5) additionally contain collar blocking bandages (9), which are located inside the outer protective layer (3) and are connected to the ring frames (b) of the end connecting elements (5) with the help of longitudinal rods (10) located inside the outer protective layer (3) along its perimeter. The invention makes it possible to increase operational reliability and increase the service life of the tap. 1 n. p. f-ly. With with p. f-ly. From fig.

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The invention relates to multi-layered elastomeric taps made of several materials and intended for angular connection of pipes or pipe fittings in mains for transporting liquid products under pressure or rarefaction.

From the state of the art, a multi-layer elastomeric outlet is known, made in the form of a bent shell, which contains an internal wear-resistant layer made of rubber, an external protective layer, an intermediate layer located between them and end connecting elements for connecting to adjacent pipes or pipeline fittings. |Output from a composite material and a method of making it" KO 2201550 C2 (Kashin Sergey

Mykhailovych et al.) E161 9/12, 27.03.2003, analogue) (11.

In the known branch |1| the inner wear-resistant layer consists of two layers - lower and upper.

Each of them is made of rubber bands with a width of 0.3-0.34 of the inner diameter of the tap and a thickness of 1 mm.

Rubber belongs to elastomers and is a structural material with high elasticity, that is, the ability to undergo large reverse deformations.

The intermediate layer is located on top of the inner wear-resistant layer.

It consists of a woven tape that is cut from fiberglass with the base positioned along the length of the tape.

The inner part of the intermediate layer is filled with rubber that has penetrated from the upper layer of the inner wear-resistant layer, and the outer part is filled with an epoxy binder.

The outer protective layer consists of an estimated number of double layers.

The bottom layer is formed by flat blanks cut from glass fabric and impregnated with a binder.

The upper layer is located on top of the lower layer.

It consists of a woven tape, which is cut from fiberglass with the base located along the length of the tape and impregnated with a binder.

And the end connection elements for connection with adjacent pipes or pipeline fittings are rigidly connected to the outer protective layer and have the same structure as the outer protective layer.

Thus, in the known tap, the intermediate and outer layers are made mainly of polymer materials that do not have elasticity, that is, of materials that do not have the ability to reverse deformations.

The disadvantage of the known branch is the excessive complexity, as well as the longitudinal and transverse stiffness of the shell and the end connecting elements of the branch.

This leads to an increase in the labor intensity and cost of making taps.

When connecting such rigid taps with rigid fastening of end connecting elements with similar end connecting elements of pipes or pipeline fittings in the pipeline line, due to the mismatch of the actual and design geometric position of the end connecting elements of the tap and the connecting pipes, gaps arise in the connections, which reduces their tightness and reliability, as well as reduces the service life of the tap.

In addition, during the operation of a known tap in the pipeline line in different climatic conditions, a change in temperature causes the occurrence of thermal stress, which leads to either longitudinal and/or transverse deformation and destruction of the wall of the rigid tap, or to a violation of the tightness of the end joints connecting elements of the tap, which reduces reliability and shortens the service life of the tap.

From the state of the art, the closest to the invention in terms of the number of common features and the result achieved is a multi-layered elastomeric outlet, made in the form of a bent multi-layer shell, containing an interconnected inner wear-resistant layer made of rubber, an outer protective layer made of rubber, an intermediate layer is located between them, made in the form of transversely arranged transverse and longitudinal layers of bundles, and end connecting elements for connection with adjacent pipes or pipeline fittings, containing ring frames covered by an intermediate layer over the entire surface, and the outer protective layer covers the outer the surface of the bent shell and the ring frames of the end connecting elements and combined with the internal wear-resistant layer at the point of their junction ("Multilayer elastomeric outlet" SH29034 ())) (Kushchenko Serhiy Mykolayovych (OA),

Stanislav Hryhorovych Lipytskyi (USA)) E161 43/00, 12/25/2007, the closest analogue is the prototype (21.

The disadvantage of the known tap |2| there is an imperfection in its design, caused by the insufficient strength of the shell in the radial and axial directions during operation under conditions of high pressure and hydraulic shocks, especially in pipeline systems of large diameters (up to 1000 mm and more), which leads to a decrease in operational reliability and a reduction in the service life of the multilayer elastomer tap.

The insufficient strength of the shell in the radial direction is explained by the fact that under conditions of high pressure and hydraulic shocks, the main stress from the action of internal pressure occurs on the structural wall on the outer side of the bent shell, which, with insufficient strength of the wall and the absence of annular reinforcing elements, leads to the rupture of the wall of the shell and the destruction of the multi-layer elastomeric tap.

The insufficient strength of the shell in the axial direction is explained by the fact that the ring frames of the end connecting elements are covered over the entire surface only by an intermediate layer - a strength frame made in the form of crosswisely located transverse and longitudinal layers of bundles, they do not have additional reinforcing elements, which does not ensure sufficient strength of the attachment of the end connecting elements to the shell in the axial direction and leads to the rupture of the wall of the shell at the place of the mentioned connection and the destruction of the multi-layer elastomeric tap.

As a result, such an arrangement of the layers of the wall of the bent multilayer shell and such a connection of the end connecting elements with the shell do not provide sufficient strength of the shell in the radial direction, as well as the necessary strength of the attachment of the end connecting elements to the shell in the axial direction, which leads to a loss of shell strength of the known multi-layer elastomeric diverter when using it in pipeline systems of large diameters (up to 1000 mm and more) at high pressure of the flowing liquid medium and resulting hydraulic shocks.

The invention is based on the technical task of improving a multilayer elastomeric pipe by introducing an additional strong outer layer with annular reinforcing elements and providing the annular frames of the end connecting elements with additional reinforcing elements, due to which an increase in the strength of the shell in the radial and axial directions is ensured under conditions of high pressure and hydraulic shocks, especially in pipeline systems of large diameters (up to 1000 mm and more).

At the same time, longitudinal flexibility, transverse flexibility and possibility are preserved

From elastic fastening of end connecting elements to adjacent pipes or pipeline fittings.

The technical result achieved when using the invention consists in increasing the operational reliability and increasing the service life of the multilayer elastomeric diverter in pipeline systems of large diameters (up to 1000 mm and more) at high pressure of the fluid medium and resulting hydraulic shocks.

The set technical task is solved, and the expected technical result is achieved by the fact that a multi-layer elastomeric outlet, made in the form of a bent multi-layer shell, containing an internal wear-resistant layer made of rubber, an outer protective layer made of rubber, an intermediate layer located between them , made in the form of transversely arranged transverse and longitudinal layers of bundles, and end connecting elements for connection with adjacent pipes or pipeline fittings, containing ring frames covered with an intermediate layer over the entire surface, and the outer protective layer covers the outer surfaces of the bent shell and ring frames of the end connecting elements and combined with an internal wear-resistant layer in the place of their junction, according to the invention, additionally contains an external armor layer that covers the external protective layer, and consists of several power bandages located along the 0-0 axis of the bent multilayer shell with a gap betweenadjacent power bandages, and the ring frames of the end connecting elements additionally contain collared blocking bandages, which are located inside the outer protective layer and are connected to the ring frames of the end connecting elements with the help of longitudinal rods located inside the outer protective layer along its perimeter.

Due to the fact that the improved multilayer elastomeric diverter additionally contains an outer armor layer, which covers the outer protective layer, and consists of several power bandages located along the 0-0 axis of the bent multilayer shell with a gap between adjacent power bandages, a high strength of the wall of the bent multilayer shell in the radial direction.

And the installation of power bandages of the armor layer with a gap between adjacent power bandages ensures the elasticity of the bent multilayer shell in the places of the gaps, as well as longitudinal compliance and transverse flexibility.

Due to the fact that the ring frames of the end connecting elements additionally contain collared locking bandages, which are located inside the outer protective layer and are connected to the ring frames of the end connecting elements with the help of longitudinal rods located inside the outer protective layer along its perimeter, a significant strengthening of the fastening of the ring frames of the connecting elements is achieved elements inside the outer protective layer of the bent multilayer shell, which significantly increases the strength of the attachment of the connecting elements in the axial direction and the multilayer elastomeric tap as a whole.

Due to the mentioned improvements of the multi-layer elastomer branch, its operational reliability is significantly increased and the service life is increased when used in pipeline systems of large diameters (up to 1000 mm and more) with high pressure of the fluid medium and emerging hydraulic shocks.

At the same time, the improved multi-layer elastomeric tap also retains the necessary longitudinal flexibility, transverse flexibility and the ability to elastically attach its end connecting elements to the end connecting elements of adjacent pipes or pipeline fittings when their position in the joint is not matched.

In addition to the mentioned main differences, the improved multi-layer elastomeric tap has additional differences that create an additional technical result.

In the multi-layer elastomeric tap, according to the invention, the power bandages of the armor layer are made in the form of pipe segments.

Due to this, their manufacture and installation is simplified, as well as their location along the 0-0 axis of the bent multilayer shell with a specified gap between adjacent power braces to ensure the necessary longitudinal compliance and transverse flexibility is ensured.

In the multi-layer elastomeric duct, according to the invention, the power bandages of the armor layer are located along the 0-0 axis of the bent multilayer shell with a gap i between adjacent power bandages, which, depending on the thickness of the bent multilayer shell, is chosen from the ratio i - (0.5-1.5 )and.

Selection of the gap between adjacent power braces depending on the thickness of the bent P

Ko) of the multilayer shell with the ratio и - (0.5-1.5)n, provides it with the necessary longitudinal flexibility and transverse flexibility.

In the multi-layer elastomeric tap, according to the invention, the end connection elements from the inner sides additionally contain flanges connected to the sections of the outer protective layer covering the ring frames of the end connection elements.

The presence of the mentioned flanges provides the possibility of forceful and hermetic tightening of the joints of the end connecting elements of the multi-layer elastomeric outlet and the connecting elements of adjacent pipes or pipeline fittings.

At the same time, the mentioned flanges can be made folded to ensure their installation from the inner sides of the end connecting elements.

Further, the invention is explained by a detailed description of an example of the implementation of a multilayer elastomeric tap, its manufacture and operation with references to the attached drawings.

In fig. 1 shows a multilayer elastomeric lead, general view.

In fig. 2 shows view A in fig. 1.

In fig. C shows fragment B in fig. 1.

The multi-layer elastomeric outlet (Fig. 1-3) is made in the form of a bent multi-layer shell 1 (Fig. 1), which contains an interconnected inner wear-resistant layer 2, made of rubber, an outer protective layer 3, made of rubber, located between them 2 , C intermediate layer 4, made in the form of transversely arranged transverse and longitudinal layers of bundles, and end connecting elements 5 for connection with adjacent pipes or pipeline fittings, containing ring frames b, covered by the intermediate layer 4 over the entire surface, and the outer protective layer C covers the outer surfaces of the bent shell 1 and the ring frames 6 of the end connecting elements 5 and is combined with the internal wear-resistant layer 2 at their junction.

The main features of the multi-layer elastomeric diverter are the following improvements in its design.

The multilayer elastomeric duct additionally contains an outer armor layer 7 (Fig. 1), which covers the outer protective layer 3, and consists of several power bandages 8 located along the 0-0 axis of the bent multilayer shell 1 with a gap between adjacent power bandages 8. and the ring frames 6 of the end connecting elements 5 additionally contain collared blocking bandages 9 (Fig. 3), which are located inside the outer protective layer Z and are connected to the ring frames b of the end connecting elements 5 with the help of longitudinal rods 10 located inside the outer protective layer Z its perimeter.

Additional features of the multi-layer elastomeric diverter are the following improvements in its design.

Power bandages 8 of the armor layer 7 are made in the form of pipe segments.

In addition, the power bandages 8 of the armor layer 7 are located along the axis 0-0 of the bent multilayer shell 1 with a gap i between adjacent power bandages 8, which is chosen depending on the thickness of the bent multilayer shell 1 from the ratio i - (0.5-1.5 )M.

The end connecting elements 5 from the inner sides additionally contain flanges 11, connected to the sections of the outer protective layer C, covering the ring frames 6 of the end connecting elements 5.

In the end connecting elements 5 and in the flanges 11, through holes 12 (Fig. 2, C) are made for fastening bolts for the flanged bolted connection of the multilayer elastomeric tap with the flanges of adjacent pipelines or pipeline fittings.

A multi-layer elastomer tap is made as follows.

First, with the help of a folded detachable mandrel, the inner wear-resistant layer 2 of the tap is formed from raw wear-resistant rubber.

Then an intermediate layer 4 of the tap is formed, consisting of transverse and longitudinal layers of harnesses.

Cord, cord or other similar flexible material of different cross-section is used as harnesses.

In the end parts of the bent shell 1 of the outlet, ring frames 6 of the end connecting elements 5 are installed, which additionally contain collared blocking bandages 9, located inside the outer protective layer З and connected to the ring frames b of the end connecting elements 5 with the help of longitudinal rods 10 located inside the outer protective layer of layer C along its perimeter and begin to form end connecting elements 5 for connection with adjacent pipes or pipeline fittings.

For this, the longitudinal layers of harnesses of the intermediate layer 4 loops cover the mentioned ring frames 6 of the end connecting elements 5 over the entire surface.

And then with the help of raw rubber, the outer protective layer Z of the bent multilayer shell 1 of the tap is formed so that the outer protective layer Z covers the outer surfaces of the bent shell 1 and the ring frames 6 of the end connecting elements 5 and is connected to the inner wear-resistant layer 2 at their junction.

After cold or hot vulcanization of the bent multilayer shell 1, the outer armor layer 7 (Fig. 1) is installed, which covers the outer protective layer 3, and consists of several power bandages 8 located along the 0-0 axis of the bent multilayer shell 1 with a gap between adjacent power bandages 8.

Power bandages 8 of the armor layer 7 are placed along the axis 0-0 of the bent multilayer shell 1 with a gap U between adjacent power bandages 8, which is chosen depending on the thickness Y of the bent multilayer shell 1 from the ratio y - (0.5-1.5)y.

For ease of installation, power bandages 8 are cut, and after installation in the design position on the outer protective layer 3, their free ends are tightened and connected, for example, by welding.

Then, on the end connecting elements 5 from the inner sides, folded flanges 11 are additionally installed, connected to the sections of the outer protective layer 3, for example, with the help of glue or vulcanization.

And in the end connecting elements 5 and in the flanges 11, through holes 12 (Fig. 2, 3) are made for fastening bolts for the flanged bolted connection of the multilayer elastomeric branch with the flanges of adjacent pipelines or pipeline fittings.

After that, the finished multi-layer elastomer tap is removed from the mandrel and handed over for use.

A multi-layer elastomer tap is used as part of the pipeline as follows.

The manufactured multi-layer elastomer tap is connected to the pipe or pipeline fittings using flange connections.

At the same time, the multi-layer elastomer tap and the pipe or pipe fitting are oriented in space so that the axis of the pipe or pipe fitting coincides with the axis of the end connecting element 5 of the tap.

Bolts are inserted into the holes 12 of the multilayer elastomeric tap and the end connecting elements 5 of the tap are cross-tightened with similar end connecting elements of the pipe or pipeline fittings with the help of bolts, washers and nuts.

A slight discrepancy between the actual and the design geometric position of the end connecting connecting elements 5 of the branch and the pipe or pipeline fittings is compensated by the elastic properties of the rubber of the outer protective layer 3, the flexibility of the end connecting elements 5, as well as the longitudinal flexibility of the bent multilayer shell 1 of the branch along its axis and the flexibility of the bent multi-layer shell 1 of the branch in the transverse direction in the case when the branch is installed in the gap between two rigidly fixed pipes or pipeline fittings.

Thus, due to the introduction of an additional strong outer armor layer 7 in the form of a set of several power bandages 8 and providing the ring frames 6 of the end connecting elements 5 with additional reinforcing elements - collared blocking bandages 9 and longitudinal rods 10, an increase in the strength of the bent multilayer shell 1 and multilayer elastomer tap as a whole, both in the radial and axial directions.

At the same time, longitudinal flexibility, transverse flexibility and the ability to elastically attach end connecting elements 5 to adjacent pipes or pipeline fittings are also preserved.

This increases the operational reliability and increases the service life of the multilayer elastomeric diverter in pipeline systems of large diameters (up to 1000 mm and more) with high pressure of the fluid medium and resulting hydraulic shocks.

In addition, during the operation of the tap in the pipeline line in different climatic conditions, a change in the temperature regime, which causes the occurrence of temperature stress, due to the longitudinal compliance and transverse flexibility of the tap, does not lead to deformation and destruction of the wall of the tap connected to the pipe, or to a violation tightness of the connections of the end connecting elements of the 5 tap.

The given information confirms the possibility of industrial applicability of the proposed invention - a multi-layer elastomeric tap, which can be manufactured many times under conditions of industrial production using standard equipment, modern materials and technology at any polymer engineering enterprise.

List of designations: 1) bent multilayer shell 2) inner wear-resistant layer made of rubber 3) outer protective layer made of rubber 4) intermediate layer made in the form of transverse and longitudinal layers of bundles 5) end connecting elements 6) ring frames of end connecting elements 7) outer armor layer 8) power bandages of the outer armor layer 9) collar blocking bandages of ring frames of end connecting elements 10) longitudinal rods connecting collar blocking bandages with ring frames of end connecting elements 11) flanges located on the inner sides of end connecting elements connecting elements 12) holes.

Claims (4)

FORMULA OF THE INVENTION 50 1. A multi-layer elastomeric outlet, made in the form of a bent multi-layer shell (1), containing an internal wear-resistant layer (2), made of rubber, and an outer protective layer (3), made of rubber, located between them (2, 3) an intermediate layer (4), made in the form of crosswise arranged transverse and longitudinal layers of bundles, and end connecting elements (5) for connection with adjacent pipes or a pipeline 55 fittings containing ring frames (6) covered by an intermediate layer (4) over the entire surface, and the outer protective layer (3) covers the outer surfaces of the bent shell (1) and ring frames (b) of the end connecting elements (5) and connected with an internal wear-resistant layer (2) in the place of their junction, which differs in that it additionally contains an external armor layer (7), which covers the external protective layer (3), and consists of several power bandages bo (8) located along the axis 0 -0 bent multilayer shell (1) with a gap y between adjacent power bandages (8), and the ring frames (b) of the end connecting elements (5) additionally contain collared blocking bandages (9), which are located inside the outer protective layer (3) and connected to the ring frames (6) of the end connecting elements (5) with the help of longitudinal rods (10) located inside the outer protective layer (3) along its perimeter. 2. Multi-layer elastomeric lead according to claim 1, which differs in that the power bandages (8) of the armor layer (7) are made in the form of pipe segments. 3. Multi-layer elastomeric lead according to claim 1, which is characterized by the fact that the power bands (8) of the armor layer (7) are located along the 0-0 axis of the bent multilayer shell (1) with a gap Y between adjacent power bands (8), which is knocked out depending from the thickness P of the bent multilayer shell (1) from the ratio 1-05. 4. Multi-layer elastomeric conduit according to claim 1, which is characterized by the fact that the end connecting elements (5) from the inner sides additionally contain flanges (11) connected to the sections of the outer protective layer (3) covering the ring frames (6) of the end connecting elements (5). B i -k i Kk shchi eko as sei ee She Tights Z ож Z SHE 5 VYY mk sei x 7 se I ih ee s more that x x g X as hi i i sha sive u g. Ж och OKO / : ; more : and : more shin X nyah si p y Z E Fig. 1