RU82020U1 - MULTILAYER ELASTOMER PIPE - Google Patents

Abstract

1. A multilayer elastomeric pipe made in the form of an elongated shell (10) containing interconnected inner wear-resistant layer (11) made of rubber and an outer protective layer (12), flexible bundles located between them (11, 12) (14) ) and end connecting elements (15) for connection with adjacent pipes or pipe fittings, characterized in that the shell (10) further comprises at least one side pipe (20), hermetically connected and communicated with the shell (10) and containing wear resistant a layer (21) made of rubber, an outer protective layer (22) and flexible bundles (24) located between them (21, 22), and at the shell (10), flexible bundles (14) are made in the form of transverse and longitudinal layers (14a 14b) of the bundles (14), the end connecting elements (15) contain annular frames (15a) connected to the longitudinal layers (14b) of the bundles (14) so that the longitudinal layers (14b) of the bundles (14) with loops (14c) cover the above-mentioned ring frames (15a) of the end connecting elements (15) over the entire surface, and the transverse and longitudinal layers (14a, 14b) of the bundles (14) They are cross-wired, and the outer protective layer (12) is made of rubber and covers the outer surfaces of the shell (10) of the pipe and its end connecting elements (15), and for each branch pipe (20) flexible bundles (24) are made in the form of transverse and longitudinal layers (24a, 24b) of the tows (24), the transverse and longitudinal layers (24a, 24b) of the tows (24) are located crosswise, and the outer protective layer (22) is made of rubber. ! 2. A multilayer elastomeric pipe according to claim 1, characterized in that the lateral part of the longitudinal layers (24b) of the bundles (24) of each pipe (20) covers the shell (10

Description

The utility model relates to composite reinforced pipes made of several materials and intended for transportation and distribution of liquid products under pressure or vacuum.

From the prior art, the multilayer elastomeric pipe made in the form of an elongated shell containing interconnected inner wear-resistant layer made of rubber and an outer protective layer, flexible bundles and end brackets located between them is known to be closest to a utility model in terms of the number of common features and the achieved result. connecting elements for connection with adjacent pipes or pipe fittings / "Multilayer pipe and method for manufacturing a multilayer pipe" UA70421C2 (Kushchenko S.N. and Lipitsky th S.G.), 10/15/2004, the closest prototype analogue.

The inner wear-resistant layer is made of an elastomer, for example rubber, or of a wear-resistant solid material having low adhesive properties, such as glass, porcelain, fluoroplastic or other material with similar properties.

The pipe also contains an intermediate layer, which is made of polymer concrete reinforced with longitudinal rods, which are a rod reinforcing frame.

The inner wear-resistant layer and the intermediate layer are fastened together by flexible braids.

The outer protective layer is made of composite material.

Longitudinal rods are rigidly fastened with end connecting elements (tips) into reinforcing frames.

Known multilayer elastomeric pipe does not have the ability to separate the input stream of the transported liquid product into several output streams, since in addition to the existing end connecting elements it does not

additional output channels, which limits its functionality and is its significant drawback.

A disadvantage of the known pipe is also the excessive longitudinal and transverse stiffness of the pipe itself, as well as the rigidity of the fastening of its end connecting elements.

This leads to the following consequences.

When connecting such rigid pipes with rigid fastening of the end connecting elements to the pipeline line, due to the misalignment of the pipes being connected, gaps in the joints arise, which reduces their tightness and reliability, and also reduces the life of the pipes.

In addition, during the operation of a known pipe in a pipeline line under various climatic conditions, a change in the temperature regime entails the emergence of temperature stresses that lead either to deformation and destruction of the walls of the joined rigid pipes, or to a violation of the tightness of the joints of the pipe end connecting elements, and a decrease in reliability and reducing the life of the pipes.

The technical problem to which the utility model is directed is the creation of such an improved design of the multilayer elastomeric pipe so that it has additional output channels, longitudinal flexibility and lateral flexibility, as well as elastic fastening of the end connecting elements.

The technical result, which is achieved by using the utility model, is to expand the functionality while increasing the operational reliability and service life of the multilayer elastomeric pipe.

The stated technical problem is solved, and the expected technical result is achieved by the fact that in a multilayer elastomeric pipe made in the form of an elongated shell containing interconnected internal wear-resistant layer made of rubber and an outer protective layer, flexible bundles and end connecting elements located between them for connecting with adjacent pipes or pipe fittings, according to a utility model, the shell further comprises at least one side pipe, hermetically connected and communicated with the sheath and containing an internal wear-resistant layer made of rubber, an outer protective layer and flexible strands located between them, moreover, the flexible strands of the sheath are made in the form of transverse and longitudinal layers of strands, end connecting elements contain ring frames,

connected to the longitudinal layers of the bundles so that the longitudinal layers of the bundles loops cover the said annular frames of the end connecting elements over the entire surface, the transverse and longitudinal layers of the bundles being located crosswise, and the outer protective layer is made of rubber and covers the outer surfaces of the pipe shell and its end connecting elements , and at each branch pipe flexible bundles are made in the form of transverse and longitudinal layers of bundles, and the transverse and longitudinal layers of bundles are located crosswise, the outer protective layer is made of rubber.

These signs are significant, since in aggregate they are sufficient to solve the technical problem and achieve the expected technical result, and each separately is necessary to identify and distinguish the claimed multilayer elastomeric pipe from similar technical solutions known from the prior art.

This combination of common and distinctive essential features that characterize the claimed multilayer elastomeric pipe is unknown from the prior art, is new and sufficient in all cases to which the scope of legal protection applies.

The causal relationship of the distinctive features in their interaction with the known features in achieving the expected technical result due to the technical task is as follows.

Due to the fact that the shell further comprises at least one side pipe sealed and connected to the shell and containing an internal wear-resistant layer made of rubber, an external protective layer and flexible bundles located between them, additional output channels are formed, which expands the functionality of the pipe as a whole.

In addition, the compositional structure of the pipe wall is formed similar to the compositional structure of the shell wall.

Due to the fact that in the construction of the sheath, flexible bundles are located between the inner wear-resistant layer and the outer protective layer and are made in the form of transverse and longitudinal layers of bundles, a spatial system of bundles is formed.

Such a spatial system of bundles forms a bundle reinforcing shell casing.

In addition, the tourniquet frame forms an elastic sheath of tourniquets, capable of contracting with elastic longitudinal or transverse deformation of the pipe

in the longitudinal direction and bend in the transverse direction without reducing the strength of the pipe wall.

Due to the fact that the end connecting elements contain annular frames connected to the longitudinal layers of the bundles so that the longitudinal layers of the bundles loops cover the said annular frames of the end connecting elements over the entire surface, they provide flexible and reliable fastening to the pipe wall.

In this case, the end connecting elements receive sufficient elastic flexibility relative to the pipe wall, which, when connecting the pipes and not parallel to the ends of their end connecting elements, provides elastic rotation, tight fit of the end connecting elements and the tightness of the connection of adjacent pipes.

Due to this, the operational reliability and service life of the pipes increases.

The location of the transverse and longitudinal layers of the bundles cross provides the formation of a mesh structure in the form of a bundle reinforcing shell shell.

Such a towing reinforcing cage provides both the necessary strength and the longitudinal flexibility and lateral flexibility of the pipe shell wall, which increases operational reliability and increases the service life of the pipe.

The implementation of the outer protective layer of the shell of rubber, that is, an elastomer having, as is known, high elasticity, that is, the ability to large reversible deformations, further increases the ductility of the pipe shell wall in the longitudinal direction and flexibility in the transverse direction.

And due to the fact that the outer protective layer made of rubber covers the outer surfaces of the pipe shell and its end connecting elements, the wall and end connecting elements of the pipe are reliably protected from damage during mechanical action or exposure to aggressive media.

In addition, the formation of elastic gaskets made of rubber between the ends of the connecting elements (ring frames) of the connected pipes is achieved.

Due to this, it ensures the tightness of the joints and high operational reliability of the pipes, which significantly increases their service life.

In addition, during the operation of the known pipe in the pipeline in different climatic conditions, a change in temperature regime, which entails the emergence of temperature stresses, due to the longitudinal ductility and lateral flexibility of the pipe, does not lead to deformation and destruction of the walls of the joints

rigid pipes, or to a violation of the tightness of the joints of the end connecting elements of the pipes.

Due to this, reliability is significantly increased and the service life of pipes increases.

Due to the fact that each pipe has flexible bundles in the form of transverse and longitudinal layers of bundles, the transverse and longitudinal layers of bundles being located crosswise, and the outer protective layer is made of rubber, a wall structure similar to the shell wall structure is formed.

At the same time, the implementation of the flexible bundle of nozzles in the form of transverse and longitudinal layers of bundles located crosswise provides the formation of a mesh structure in the form of a bundle reinforcing frame of the nozzle.

Such a harness reinforcing frame of the pipe provides him with both the necessary strength and the longitudinal flexibility and lateral flexibility of the pipe shell wall, which increases operational reliability and extends the life of the pipe.

The implementation of the outer protective layer of the pipe made of rubber, that is, an elastomer, which is known to have high elasticity, characterized by the ability to large reversible deformations, further increases the ductility of the pipe wall in the longitudinal direction and flexibility in the transverse direction.

The multilayer elastomeric pipe has other differences that characterize it in individual cases of execution and improves its properties.

In a multilayer elastomeric pipe, according to a utility model, the lateral part of the longitudinal layers of the bundles of each nozzle covers the shell along an open perimeter and is a continuous part of the transverse layers of the bundles of the shell, while the transverse layers of the bundles of the shell in front of the nozzle cross-wrap the shell in the direction of the nozzle, continuously passing into the transverse layers pipe harnesses, and behind the pipe cross-wrap the sheath in the opposite direction and continuously pass into the subsequent transverse layers of the sheath harnesses.

Such an arrangement of the longitudinal and transverse layers of the sheaths of the sheath and the nozzles forms their mutual interweaving, which ensures reliable and flexible fastening of the nozzles to the sheath.

In a multilayer elastomeric pipe, according to a utility model, the axis of the nozzle is located to the axis of the sheath at an angle α = 90-30 °.

This allows, depending on technological needs, to expand the range of multilayer elastomeric pipes containing both perpendicular and oblique along the length of the shell side pipes.

From the prior art, the applicants have not identified technical solutions that match the general and distinctive features of the inventive multilayer elastomeric pipe, which indicates that the proposed technical solution is not part of the prior art and meets the criterion of the novelty utility model.

In the future, the utility model is illustrated by a detailed description of its design and operation with reference to the accompanying drawings.

Figure 1 shows a multilayer elastomeric pipe, General view.

Figure 2 shows the arrangement of the longitudinal layers of the bundles of the sheath of the shell of a multilayer elastomeric pipe.

Figure 3 shows the layout of the longitudinal layers of the bundles of pipes, which are a continuous part of the transverse layers of the bundles of the shell.

Figure 4 shows the arrangement of the transverse layers of the bundles of the sheath and the transverse layers of the bundles of the nozzles.

The multilayer elastomeric pipe (Figs. 1-4) is made in the form of an elongated sheath 10 (Fig. 1) containing interconnected inner wear-resistant layer 11 made of rubber and an outer protective layer 12, flexible bundles 14 located between them 11, 12 and end connecting elements 15 for connection with adjacent pipes or pipe fittings.

According to a utility model, the sheath 10 further comprises at least one side pipe 20 sealed and connected to the sheath 10 and comprising an inner wear-resistant layer 21 made of rubber, an outer protective layer 22 and flexible strands located between them 21, 22 .

Moreover, at the sheath 10, the flexible harnesses 14 are made in the form of transverse and longitudinal layers 14a, 14b of the harnesses 14, the end connecting elements 15 comprise ring frames 15a connected to the longitudinal layers 14b of the harnesses 14 so that the longitudinal layers 14b of the harnesses 14 loops 14b cover the said ring frames 15a of the end connecting elements 15 over the entire surface, the transverse and longitudinal layers 14a, 14b of the bundles 14 being located crosswise, and the outer protective layer 12 is made of rubber and covers the outer surfaces of the pipe shell (10) and then tsovyh connecting elements 15.

And at each nozzle 20, flexible bundles 24 are made in the form of transverse and longitudinal layers 24a, 24b of bundles 24, the transverse and longitudinal layers 24a, 24b of bundles 24 being located crosswise, and the outer protective layer 22 is made of rubber.

The lateral part of the longitudinal layers 24b of the bundles 24 of each pipe 20 covers the shell 10 along an open perimeter and is a continuous part of the transverse layers 14a of the bundles 14 of the shell 10.

In this case, the transverse layers 14a of the bundles 14 of the sheath 10 in front of the nozzle 20 cross-wrap the sheath 10 in the direction of the nozzle 20, continuously transition into the transverse layers 24a of the bundles 24 of the nozzle 20, and behind the nozzle 20 cross-wrap the sheath 10 in the opposite direction and continuously transition to the subsequent transverse layers 14a bundles 14 of the sheath 10.

The axis of the pipe 20 can be located to the axis of the shell 10 at an angle α = 90-30 °.

Improved multilayer elastomeric pipe has additional output channels in the form of side pipes 20, longitudinal compliance and lateral flexibility, as well as elastic fastening of the end connecting elements 15.

Due to this, the expansion of functionality is achieved while increasing the operational reliability and service life of the multilayer elastomeric pipe.

A multilayer polymer pipe is made as follows.

First, with the help of a composite detachable mandrel, an inner wear-resistant layer 11 of the shell 10 and an inner wear-resistant layer 21 of each nozzle 20 are formed from crude wear-resistant rubber.

The composite detachable mandrel has removable liners for forming the nozzles 20, which, depending on the need, can be positioned so that the axis of the formed nozzle 20 will be located to the axis of the sheath 10 at an angle α = 90-30 °.

Then, in a certain sequence, flexible plaits 14 of the shell 20 are formed, made in the form of transverse and longitudinal layers 14a, 14b of plaits 14 and flexible plaits 24 of each pipe 20 in the form of transverse and longitudinal layers 24a, 24b.

First, on the inner wear-resistant layer 11 of the shell 10 lay the longitudinal layers 14b of the bundles 14 (figure 2).

In the end parts of the pipe, ring frames 15a are installed and the connecting elements 15 of the shell 10 begin to form for connection with adjacent pipes or pipe fittings.

For this, the longitudinal layers 14b of the bundles 14 of the sheath 10 with the hinges 14b cover the said annular frames 15a of the connecting elements 15 over the entire surface.

Then lay the lateral part of the longitudinal layers 24b of the bundles 24 of each pipe 20 so that they cover the shell 10 along the open perimeter and are a continuous part of the transverse layers 14a of the bundles 14 of the shell 10 (Fig.3).

After that, the transverse layers 14a of the bundles 14 of the sheath 10 and the transverse layers 24a of the bundles 24 of the nozzle 20 are formed so that the transverse layers 14a of the bundles 14 of the shell 10 in front of the nozzle 20 cross-wrap the sheath 10 in the direction of the nozzle 20 and continuously pass into the transverse layers 24a of the bundles 24 of the nozzle 20 and behind the pipe 20 cross-wrap the sheath 10 in the opposite direction and continuously pass into the subsequent transverse layers 14a of the bundles 14 of the sheath 10 (Fig. 4).

And then, with the help of crude rubber, the outer protective layer 12 of the shell and the outer protective layer 22 of each pipe 20 are formed of rubber, with rubber covering all the external surfaces of the pipe shell 10, its end connecting elements 15 and the ends of the pipes 20.

Thus, a sheath 10 is formed in which the flexible bundles 14 are made in the form of transverse and longitudinal layers 14a, 14b of bundles 14, the end connecting elements 15 comprise ring frames 15a connected to the longitudinal layers 14b of bundles 14 so that the longitudinal layers 14b of bundles 14 loops 14c cover the annular frames 15a of the end connecting elements 15 over the entire surface, the transverse and longitudinal layers 14a, 14b of the bundles 14 being located crosswise, and the outer protective layer 12 made of rubber and covers the outer surface the shell 10 of the pipe and its end connecting elements 15.

At the same time, each nozzle 20 is also formed, in which the flexible bundles 24 are made in the form of transverse and longitudinal layers 24a, 24b of bundles 24, the transverse and longitudinal layers 24a, 24b of bundles 24 being located crosswise, and the outer protective layer 22 is made of rubber.

After cold or hot vulcanization, the finished multilayer elastomeric pipe is removed from the mandrel and transferred to operation.

Use a multilayer elastomeric pipe in the composition of the pipeline as follows.

The manufactured pipe is connected to a similar pipe using, for example, flange connections.

For this, in the end connecting elements 15 of the shell 10 of adjacent pipes, through holes are made uniformly spaced around the circumference and parallel to the axes of the pipes.

Then adjacent pipes are oriented in space so that the axis of one pipe coincides with the axis of the other pipe.

Bolts are inserted into the holes of the end connecting elements 15 and the connecting elements 15 are cross-tightened by threaded connections with bolts, washers and nuts.

A slight deviation from the parallelism of the ends of the end connecting elements 15 is compensated by the elastic properties of the rubber of the outer protective layer 12, the flexibility of the end connecting elements 15, as well as the flexibility of the pipe in the longitudinal direction and the flexibility of the pipe in the transverse direction in the case when the pipe is installed between two fixed pipes .

In addition, during the operation of this pipe in the pipeline in different climatic conditions, a change in temperature regime, which entails the emergence of temperature stresses due to the longitudinal ductility and lateral flexibility of the pipe, does not lead to deformation and destruction of the walls of the joined rigid pipes, or to a violation tightness of joints of end connecting elements of 15 pipes.

Due to this, reliability is significantly increased and the service life of pipes increases.

And the side pipes 20 form additional output channels for separating the axial flow of the liquid product flowing inside the shell 10 of the multilayer elastomeric pipe, and distributing it to an additional number of consumers, which expands its functionality.

The proposed multilayer elastomeric pipe can be repeatedly manufactured in industrial production using standard equipment, modern materials and technology at any polymer engineering enterprise, which indicates that this technical solution meets the criterion of the utility model “industrial applicability”.

Notation list

10. The elongated shell.

11. The inner wear-resistant layer of the shell 10.

12. The outer protective layer of the shell 10.

14. Flexible harnesses of the sheath 10.

14a. The transverse layers of the bundles 14 of the shell 10.

14b. The longitudinal layers of the bundles 14 of the shell 10.

14th century The loops of the longitudinal layers 14b of the bundles 14 of the shell 10.

15. End connecting elements of the shell 10.

15a. Ring frames of connecting elements 15 of the shell 10.

20. Side pipe.

21. The inner wear-resistant layer of the pipe 20.

22. The outer protective layer of the pipe 20.

24. Flexible pipe harnesses 20.

24a. The transverse layers of the bundles 24 of the pipe 20.

24b. The longitudinal layers of the bundles 24 of the pipe 20.

Claims (3)

1. A multilayer elastomeric pipe made in the form of an elongated shell (10) containing interconnected inner wear-resistant layer (11) made of rubber and an outer protective layer (12), flexible bundles located between them (11, 12) (14) ) and end connecting elements (15) for connection with adjacent pipes or pipe fittings, characterized in that the shell (10) further comprises at least one side pipe (20), hermetically connected and communicated with the shell (10) and containing wear resistant a layer (21) made of rubber, an outer protective layer (22) and flexible bundles (24) located between them (21, 22), and at the shell (10), flexible bundles (14) are made in the form of transverse and longitudinal layers (14a 14b) of the bundles (14), the end connecting elements (15) contain annular frames (15a) connected to the longitudinal layers (14b) of the bundles (14) so that the longitudinal layers (14b) of the bundles (14) with loops (14c) cover the above-mentioned ring frames (15a) of the end connecting elements (15) over the entire surface, and the transverse and longitudinal layers (14a, 14b) of the bundles (14) They are cross-wired, and the outer protective layer (12) is made of rubber and covers the outer surfaces of the shell (10) of the pipe and its end connecting elements (15), and for each branch pipe (20) flexible bundles (24) are made in the form of transverse and longitudinal layers (24a, 24b) of the tows (24), the transverse and longitudinal layers (24a, 24b) of the tows (24) are located crosswise, and the outer protective layer (22) is made of rubber. 2. A multilayer elastomeric pipe according to claim 1, characterized in that the lateral part of the longitudinal layers (24b) of the bundles (24) of each pipe (20) covers the shell (10) along an open perimeter and is a continuous part of the transverse layers (14a) of the bundles (14 ) shell (10), while the transverse layers (14a) of the bundles (14) of the shell (10) in front of the pipe (20) cross-wrap the shell (10) in the direction of the pipe (20), continuously go into the transverse layers (24a) of the bundles (24) ) of the nozzle (20), and behind the nozzle (20) cross-wrap the shell (10) in the opposite direction and continuously go to the subsequent transverse layers (14a) of the bundles (14) of the shell (10). 3. A multilayer elastomeric pipe according to claim 1, characterized in that the axis of the pipe (20) is located to the axis of the shell (10) at an angle α = 90-30 °.