RU2658444C1 - Polyhedral shaped composite pipe (options) - Google Patents

Abstract

FIELD: machine building; construction.

SUBSTANCE: invention relates to mechanical engineering and construction structures and can be used as storm, industrial and domestic sewage pipes, drainage and water intake pipes and channels and tunnels of hydraulic structures. Polyhedral shaped composite pipe consists of straight transversal elements of the channel and (or) box section, which are connected by their ends and (or) through the corner elements in the form of polygonal figures, and lateral sides are connected in a polyhedral figured composite pipe. To increase the longitudinal strength of the pipe, straight longitudinal members of the round and / or tubular section can be inserted through and connected to the lateral sides of the elements. Outside and (or) from within a polyhedral shaped composite pipe, its faces can be connected to straight longitudinal elements of the channel and / or box, and (or) corner and/or flat sections.

EFFECT: polyhedral shaped composite pipe has high strength, low mass, corrosion resistance and relatively low cost, with the possibility of assembling the pipe at the site of production.

24 cl, 6 dwg

Description

The invention relates to mechanical engineering and building structures and can be used as storm pipes, industrial and household sewage pipes, drainage and intake pipes and channels, pipes, channels and tunnels of hydraulic structures.

Sewer pipes are known that have cross-sectional shapes different from round — semicircular, tented, banquet, ovoid, elliptical, semicircular with straight inserts, ovoid inverted, channel, pentagonal, rectangular, trapezoidal (see pages 28-29, “Drainage and wastewater treatment. Textbook for universities ", Voronov Yu.V., Yakovlev SV, Publishing house of the Association of building universities, M., 2006). Such pipes were built from various materials: wood, brick, stone, concrete, reinforced concrete.

Reinforced concrete rectangular pipes for hydraulic structures are known (GOST 26067.0-83 and GOST 26067.1-83, “Rectangular reinforced concrete pipe links of rectangular section for hydraulic structures”, USSR State Committee for Construction, 1983), the maximum size of these pipes is 2500/2000 mm and rectangular pipes for roads and railways (Series 3.501.1-177.93, “Culverts, reinforced concrete rectangular precast pipes for roads and railways,” Ministry of Transport and Construction, 1994), the maximum cross-sectional size of these pipes is 4000/2500 mm.

Known non-circular section of the company HOBAS based on polyester resin reinforced with fiberglass, made by continuous winding on the mandrel of a fiberglass yarn impregnated with polyester resin, the maximum section size of such pipes is 2680 × 2590 mm, section A04 "Non-circular section pipes (NC-Line)", page 11, (Brochure "HOBAS. Technical Data Pressureless Pipeline Systems" [Electronic resource], Publication: 11/2010. Update: 03/2012. Access mode: http: // www.hobas.ru/fileadmin/Daten/PUBLIC /Brochures_World_pdf/RU/Gravity_pipes_RU.pdf).

HOBAS non-circular pipes are a composite shell with a monolithic wall, which in longitudinal section is a flat element that provides only minimal bending strength, which leads to a large wall thickness and large weight, to provide the required lateral strength and ring stiffness of a large non-circular composite pipe diameter. The large size and weight of the composite non-circular pipe and the method of its manufacture, requiring rotation of the pipe and the mandrel on which it is made, limits the maximum diameters of the manufactured non-circular pipes. Large round non-circular pipes from HOBAS have a small lateral stiffness due to the relatively small wall thickness, and are mainly used to repair existing sewer collectors or as an inner shell in the construction of new ones.

Each pipe section has its advantages and disadvantages in terms of hydraulic and strength characteristics, which affect the material consumption, construction complexity, productivity, maintenance complexity and operating costs.

Due to difficulties in the production of non-circular pipes in the USSR, they were abandoned, despite the fact that round pipes are not always the best option for some construction cases, which sometimes leads to cost overruns, worsening of the characteristics of the pipeline, reducing its service life, and increasing operating costs. Of all types of non-circular pipes in the current building codes of the CIS countries, only rectangular reinforced concrete pipes remained.

At the same time, Germany currently has state standards DIN 4263-1947, 1977, 1991, (DEUTSCHE NORMEN, Juni 1947, Leitungsquerschnitte des Wasserbaus, DIN4263, Fachnormenausschuβ Wasserbau und Wasserwirtschaft im Deutschen Normenausschu (June) 1947, “Cross-sections of pipelines in hydraulic structures”, DIN4263, Committee for Special Standards for Hydrotechnical Construction and Water Management in the German Committee for Standards), which shows the following types of sections:

page 1, rectangular cross sections, maximum size - 3000/3000 mm;

p. 1) circular cross-section, maximum diameter - 3000 mm;

p. 2) an overestimated egg-shaped cross section, the maximum size is -1000/1750 mm;

p. 3) the usual egg-shaped cross section, the maximum size - 1600/2400 mm;

p. 4) a wide egg-shaped cross section, the maximum size is 2400/3000 mm;

p. 5) a compressed egg-shaped cross section, the maximum size - 3200/3200 mm;

p. 6) oversized trough cross-section, maximum size - 3200/3200 mm;

p. 7) the usual trough cross-section, the maximum size - 4000/3000 mm;

p. 8) a compressed trough cross-section, the maximum size is 4000/2500 mm;

p. 9) banquet cross section with one-sided lifting, maximum size - 2400/3200 mm;

p. 10. banquet cross-section with two-way lift, maximum size - 3600/3600 mm.

As you can see from a comparison of the sizes of non-circular pipes from HOBAS, the maximum size of which is 2680/2590 mm, and the sizes of cross-sections according to DIN4263 - there is no delivery from manufacturers of a number of fiberglass non-circular pipes of large cross-sections specified in DIN4263.

This is due to the fact that the walls of the fiberglass non-circular pipe in longitudinal section are a flat element that provides only minimal bending strength. The main strength characteristic of any pipe is the value of the ring stiffness of the pipe. The ring stiffness class shows the maximum allowable load per unit surface area of the pipe with 4% deformation of its vertical diameter, without taking into account lateral resistance, the pipe walls at this load work in bending. In round and non-circular pipes with a solid wall, ring stiffness provides material strength and wall thickness, the larger the pipe size, the thicker the wall to provide the same ring stiffness. The walls of such a pipe are a flat element that does not give much bending strength, because of this, with large diameters of the pipes, the wall thickness reaches a very large size and mass, which limits the size of the pipes produced.

Fiberglass rectangular pipes do not exist at all due to the fact that the flat upper wall, acting as a horizontal beam, will bend much earlier than the load reaches a predetermined value.

Ovoid-shaped sewer pipes laid out of brick are known (see Fig. 95, p. 168, “Calculation of pipes laid in the ground”, G.K. Klein. Gosstroyizdat, M, 1957), brick pipes were built in 19 - beginning of the 20th century, these pipes were laid out of brick on cement mortar manually at the place of work. The work was conducted in an open way and took a lot of time. Despite the relatively low strength of the bricks and their mortar, some collectors built in the 19th century still work in the 21st century. A brick pipe has a very large weight and a relatively small transverse and longitudinal strength, which leads to its destruction in case of soil movement.

The closest analogue of the proposed technical solution is an ovoid sewer pipe, laid out of brick, indicated earlier. A non-circular brick pipe built from straight bricks (elements) with angles between these elements is actually a prototype of a multifaceted figured composite pipe. The disadvantages of a brick non-circular pipe are:

1) the ability to lay out a brick pipe exclusively at the place of work;

2) the small size of the brick;

3) a large weight of a brick pipe;

4) low bending strength of the pipe walls;

5) low transverse and longitudinal strength of the pipe.

The main technical problem is the creation of a composite pipe from direct composite elements, in which the above disadvantages are eliminated. The cross section of such a pipe is a polygonal figure. Therefore, we need to solve the technical problem of creating a polygonal figured composite pipe.

The definition of a polygonal figure is as follows: “We call a polygonal figure any set of points on a plane that can be decomposed into a finite number of triangles that do not have common internal points. ... a polygonal figure is a limited enclosed area. ... a polygon is defined as “a part of a plane bounded by a closed broken line” ... it can be shown that every polygon (in the sense just indicated) is a polygonal figure. ”(See page 17,“ Encyclopedia of Elementary Mathematics. Book Five - geometry ”, P.S. Aleksandrov, M., 1966).

The box and channel section profile has many times greater bending strength than a flat element of the same material with the same weight. The wall of a pipe from a hollow profile located in a plane perpendicular to the axis of the pipe is many times stronger in bending than a solid wall of the same material, of the same mass, i.e. at the same strength, a pipe from a composite profile is many times lighter than a pipe from a composite with a continuous wall.

Composite materials are more durable than brick and cement mortar, concrete and reinforced concrete, and much lighter.

The main technical problem is the creation of a multifaceted figured composite pipe of any large diameter, any required ring stiffness, lateral and longitudinal strength, from direct composite profiles of box, channel, round, tubular and other sections of the required size. The transverse and longitudinal elements of a multifaceted figured composite pipe are made of direct composite profiles obtained by pultrusion molding, extrusion, pressing or any other production methods, from any composite materials containing fibers (glass, basalt, organic, carbon, boron, etc. .p.) and polyester, epoxy and other synthetic resins.

The technical result of the invention is the creation of a multifaceted figured composite pipe with high ring stiffness and longitudinal strength with a minimum weight, any shape, any larger size and length, using elements from straight composite profiles and not requiring rotation in the production of a multifaceted figured composite pipe.

If the faces of a multifaceted figured composite pipe are tangent to lines of standard non-circular section, and the joints of the faces are beyond this line, in this case, the internal sectional area of a multifaceted figured composite pipe is larger than the area of a standard section, which compensates for the additional flow resistance due to the angles of a multifaceted figured composite pipe.

The main technical problem is solved and the technical result is achieved due to the fact that:

Option 1. A multifaceted figured composite pipe, consisting of straight transverse elements of the channel and (or) box sections, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and connected to the multifaceted figured composite pipe by their sides.

The minimum number of faces of a multifaceted figured composite pipe is equal to three faces, the number of faces can be any required quantity. An increase in the number of faces leads to a rise in the cost of production of a multifaceted figured composite pipe, so the number of faces should be optimal for each specific case. The length of a segment of a multifaceted figured composite pipe can be any convenient for transportation and installation.

The transverse arrangement of the profile elements, we obtain the maximum ring stiffness and lateral strength of the multifaceted figured composite pipe.

Option 2. A multifaceted figured composite pipe, consisting of straight transverse elements of a channel and (or) box section, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and are connected by their sides to a polyhedral figured composite pipe, through holes in the lateral sides of the elements are inserted and connected to them, straight longitudinal elements of circular and (or) tubular section.

By adding longitudinal elements inside the faces of a multifaceted figured composite pipe, we increase the longitudinal strength of the pipe without increasing the wall thickness of the multifaceted figured composite pipe.

Option 3. A multifaceted figured composite pipe, consisting of straight transverse elements of a channel and (or) box section, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and are connected by their sides to a polyhedral figured composite pipe, outside and ( or) from the inside of a multifaceted figured composite pipe, its faces are connected with direct longitudinal elements of a channel, and (or) box-shaped, and (or) angular, and (or) flat section.

This solution allows you to get a multifaceted figured composite pipe with large ring stiffness, transverse and longitudinal strength, with any characteristics of each face.

In a multifaceted figured composite pipe, the transverse elements can be stacked so that the transverse elements of the multifaceted figured composite pipe are stacked so that the ends of the transverse elements of one face intersect the ends of the transverse elements of the other face.

In a multifaceted figured composite pipe, angular elements can be used to connect the transverse elements at the junction of the faces of the multifaceted figured composite pipe, which are inserted into the slots in the transverse elements and connected to them.

In a multi-faceted figured composite pipe, angular elements of flat section can be used to connect the transverse elements at the junction of the faces of the multi-faceted figured composite pipe.

In a multifaceted figured composite pipe, angular elements with protrusions and (or) depressions for fixing the transverse elements can be used to connect the transverse elements at the junction of the faces of the multifaceted figured composite pipe.

The above solutions increase the strength of the connection elements in the corners (ribs) of a multifaceted figured composite pipe.

In a multifaceted figured composite pipe, angular elements with a rounded corner from the outside and (or) from the inside of the multifaceted figured composite pipe can be used to connect the transverse elements of the multifaceted figured composite pipe.

In a multi-faceted figured composite pipe, a fabric made of high-modulus fibers impregnated with synthetic resin can be glued to the corners of the multi-faceted figured composite pipe.

In a multifaceted figured composite pipe, on the verge of a multifaceted figured composite pipe, a fabric made of high-modulus fibers impregnated with synthetic resin can be glued on the outside and (or) inside.

The multifaceted figured composite pipe can be glued on the outside and (or) inside with a fabric of high-modulus fibers impregnated with synthetic resin.

The above solutions increase the strength of the connection elements in the corners and faces of a multifaceted figured composite pipe.

A multifaceted figured composite pipe can be glued on the outside and (or) inside with flat and (or) sheet and (or) film materials.

The multifaceted figured composite pipe can be outside and (or) inside covered with rubber-like materials.

Coating materials may be materials such as polyurethanes, etc.

These solutions increase the wear resistance and tightness of a multifaceted figured composite pipe.

A multifaceted figured composite pipe can be coated on the outside and (or) inside with materials that provide flame retardant, and (or) antifriction, and (or) antistatic properties.

The corners of a multifaceted figured composite pipe from the outside and (or) from the inside can be connected with the longitudinal elements of the corner section.

This increases the longitudinal strength and closes the cavity of the transverse elements, increasing the tightness of the multifaceted figured composite pipe.

In a multifaceted figured composite pipe, elements can have protrusions and (or) depressions that, when assembling a multifaceted figured composite pipe, enter each other.

This solution simplifies the assembly of elements and enhances their connection.

In a multifaceted figured composite pipe, the elements may have holes and / or selections in the walls of the elements.

To lighten the weight of the pipe, holes and material sampling profiles can be made in places that do not bear the load.

In a multifaceted figured composite pipe, the elements can be interconnected by an adhesive and (or) mechanical connection.

In a multifaceted figured composite pipe, longitudinal elements of angular section with a rounded corner can be installed in the corners of the faces from the inside of the multifaceted figured composite pipe.

In a multi-faceted figured composite pipe, rounding corners from composite material can be formed in the corners of the faces from the inside of the multi-faceted figured composite pipe.

Rounding corners may be required to improve flow characteristics in a multifaceted figured composite pipe.

In a multifaceted figured composite pipe, the cavities of the elements can be closed with plugs.

Corks can be inserted into all or some elements before assembling a multifaceted composite pipe or after assembling a multifaceted figured composite pipe into elements whose cavities remained open during assembly according to paragraph 4 of the claims.

Closing the ends of the profiles before assembling the polyhedral shaped composite pipe increases the bonding surface, i.e. durability of a many-sided figured composite pipe. Cork closure also increases the tightness of the multi-faceted curly composite pipe.

In a multifaceted figured composite pipe, the cavities of the elements can be filled with polymer foam, and (or) foam concrete, and (or) concrete, and (or) reinforced concrete.

You can get a heat-insulated, weighted or especially durable multifaceted figured composite pipe, increase its tightness and reliability.

In a multi-faceted figured composite pipe, end parts can be attached to the ends of the multi-faceted figured composite pipe to connect the multi-faceted figured composite pipes to each other end-to-end, either into a socket, or using sliding couplings, or using flanges.

Polyhedral shaped composite pipes can be assembled together just like round pipes.

Auxiliary elements can be attached to the multifaceted figured composite pipe for laying, and (or) installation, and (or) joining the many-sided figured composite pipes to supports and (or) to building structures.

Polyhedral shaped composite pipes can be assembled into pipelines in the same ways as round pipes.

These distinguishing features of the invention are essential, each of which together provide a new technical result.

There may be various combinations of making a multifaceted figured composite pipe with respect to the shape, size and location of elements and faces.

In addition to direct composite profiles of box-shaped, channel, round, tubular and continuous sections, composite profiles of special sections specially designed for multifaceted figured composite pipes, with cavities and recesses, with special shapes, the number and different thicknesses of internal partitions and (or) external walls. Various combinations of profile shapes can be used in the same design of a multifaceted figured composite pipe. The material of the profiles can be different and combined in the design of a multifaceted figured composite pipe, depending on the required characteristics.

The manufactured multifaceted figured composite pipe of any large size, using the solutions considered, has a minimum weight, with any required ring stiffness, lateral and longitudinal strength, high corrosion resistance, manufacturability, versatility and relatively low cost.

A new technical solution for the production of multifaceted figured pipes does not require the rotation of the figured pipe during its manufacture, reproducible under production conditions and even outside it, when assembling a multifaceted figured composite pipe from elements of different degrees of readiness at the construction site. This allows you to save big money on the transportation of finished pipes, provides a solution to a technical problem and the achievement of a new technical result, in the proposed set of features meets the criterion of "industrial applicability", that is, the level of invention.

Brief Description of the Drawings

In FIG. 1 shows a multifaceted curly composite pipe similar to the shape of section 1. A multifaceted curved composite pipe consists of transverse elements 2 (box section) glued at their ends in the form of polygonal shapes. The lateral sides of the transverse elements 2 are glued into a multifaceted figured composite pipe. For clarity, a rectangular cutout is made at the end of a multifaceted figured composite pipe.

In FIG. 2 shows a multifaceted figured composite pipe similar to a cross-sectional shape 1. The multifaceted figured composite pipe is assembled from transverse elements 3 (box-shaped section with holes in the side walls) and longitudinal elements 4 (round section) passing through the holes in the transverse elements 3. Cross elements 3 are glued together in a multifaceted figured composite pipe in such a way that the ends of the transverse elements 3 of one face intersect the ends of the transverse elements 3 of the other face. For clarity, a rectangular cutout is made at the end of a multifaceted figured composite pipe.

In FIG. 3 shows a multifaceted figured composite pipe of rectangular cross section, assembled from transverse elements 2 (box section) and longitudinal elements 5 (box section). The lower edge of the multifaceted figured composite pipe consists of two layers of transverse elements 2, between which there is a layer of longitudinal elements 5. Corner elements are glued to the corners of the multifaceted figured composite pipe 6. The upper face of the multifaceted figured composite pipe is assembled from two layers of transverse elements 2.

Figure 4 presents a multifaceted figured composite pipe of rectangular cross section, consisting of transverse elements 7 (channel section) assembled using mechanical bolt joints 8. The transverse elements 7 are assembled so that the ends of the transverse elements 7 of one face intersect the ends of the transverse elements 7 of another facet. The longitudinal elements 6.1 (corner section) are glued to the inner corners of a multifaceted figured composite pipe.

In FIG. 5 shows a multifaceted figured composite pipe similar to cross section 1, consisting of transverse elements 3 (box section with holes in the side walls) and longitudinal elements 4 (round section) passing through holes in the transverse elements 3. On the outer and some inner faces near ribs of a multifaceted figured composite pipe glued longitudinal elements 9 (flat section). For clarity, a rectangular cutout is made at the end of a multifaceted figured composite pipe.

In FIG. 6 shows a multifaceted figured composite pipe similar to cross section 1, consisting of transverse elements 2 (box section). The transverse elements 2 are assembled in the form of polygonal figures using angular elements 11 inserted into the transverse elements 2. On the sides, the transverse elements 2 and the corner elements 11 are glued into a multifaceted figured composite pipe. Some corner elements 11 have an outer and inner rounding. For clarity, a rectangular cutout is made in a multifaceted figured composite pipe.

The implementation of the invention

A multifaceted figured composite pipe section similar to the semicircular with straight inserts cross-sectional shape is assembled in accordance with FIG. 2. The outer size of the section: length - 980 mm, width - 960 mm, height - 1660 mm. The multifaceted figured composite pipe is assembled from pultruded profiles of a hollow rectangular section measuring 80/60 mm, with a wall thickness of 5 mm, and pultruded round rods with a diameter of 19 mm. 80 meters of a hollow rectangular profile, 24 meters of a round bar and 8 liters of polyester resin with a hardener were used up. The transverse elements are glued to each other with alternating alternation of the ends of the elements of one face with the elements of another face. Fiberglass profiles are glued with polyester resin. The weight of the section is 128 kg. This design has a high longitudinal and lateral strength from soil pressure.

Claims (24)

1. A multifaceted figured composite pipe, consisting of straight transverse elements of a channel and (or) box section, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and connected by their sides to a multifaceted figured composite pipe. 2. A multifaceted figured composite pipe, consisting of straight transverse elements of a channel and (or) box section, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and are connected by their sides to a multifaceted figured composite pipe, through holes in the side the sides of the elements are inserted and connected with them direct longitudinal elements of circular and (or) tubular cross section. 3. A multifaceted figured composite pipe, consisting of straight transverse elements of a channel and (or) box section, which are connected by their ends and (or) through corner elements in the form of polygonal figures, and are connected by their sides to a multifaceted figured composite pipe, outside and (or ) from the inside of the multifaceted figured composite pipe, its faces are connected with straight longitudinal elements of the channel, and (or) box-shaped, and (or) angular, and (or) flat sections. 4. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the transverse elements of the multifaceted figured composite pipe are laid so that the ends of the transverse elements of one face intersect with the ends of the transverse elements of the other face. 5. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that for connecting the transverse elements in the junction of the faces of a multifaceted figured composite pipe, angular elements are used that are inserted into the slots in the transverse elements and connected to them. 6. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that for connecting the transverse elements in the junction of the faces of a multifaceted figured composite pipe, longitudinal angular elements are used. 7. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that for connecting the transverse elements in the junction of the faces of a multifaceted figured composite pipe, angular elements with protrusions and (or) depressions are used to fix the transverse elements. 8. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that for connecting the transverse elements of a multifaceted figured composite pipe, angular elements are used with a rounded corner on the outside and (or) from the inside of the multifaceted figured composite pipe. 9. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that at the corners of a multifaceted figured composite pipe, a fabric of high modulus fibers impregnated with synthetic resin is glued on the outside and (or) inside. 10. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that on the verge of a multifaceted figured composite pipe, a fabric of high modulus fibers impregnated with synthetic resin is glued on the outside and (or) inside. 11. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the multifaceted figured composite pipe is glued on the outside and (or) inside with a fabric of high modulus fibers impregnated with synthetic resin. 12. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the multifaceted figured composite pipe is glued on the outside and (or) inside with flat, and (or) sheet, and (or) film materials. 13. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the multifaceted figured composite pipe outside and (or) inside is covered with rubber-like materials. 14. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the multifaceted figured composite pipe is coated on the outside and (or) inside with materials that provide flame retardant, and (or) antifriction, and (or) antistatic properties. 15. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the corners of a multifaceted figured composite pipe outside and (or) inside connected to the longitudinal elements of the corner section. 16. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the elements of the multifaceted figured composite pipe have protrusions and (or) depressions that, when assembling the multifaceted figured composite pipe, entered into each other. 17. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the elements of the multifaceted figured composite pipe have holes and (or) samples in the walls of the elements. 18. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the elements of the multifaceted figured composite pipe are interconnected by adhesive and (or) mechanical connection. 19. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that in the corners of the faces from the inside of the multifaceted figured composite pipe installed longitudinal elements of angular section with a rounded corner. 20. The multifaceted curly composite pipe according to any one of paragraphs. 1-3, characterized in that in the corners of the faces from the inside of the multifaceted figured composite pipe, rounding off the corners is made of composite material. 21. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the cavity elements of a multifaceted figured composite pipe are closed with plugs. 22. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that the cavities of the elements of a multifaceted figured composite pipe are filled with polymer foam, and (or) foam concrete, and (or) concrete, and (or) reinforced concrete. 23. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that end parts are attached to the ends of the multifaceted figured composite pipe to connect the multifaceted figured composite pipes to each other end-to-end, either into a socket, or using sliding couplings, or using flanges. 24. The multifaceted figured composite pipe according to any one of paragraphs. 1-3, characterized in that to the polyhedral shaped composite pipe auxiliary elements are attached for laying and (or) installing, and (or) attaching the multi-faceted shaped composite pipes to supports and (or) to building structures.

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