RU132108U1 - WATER DRAINAGE PIPE (OPTIONS), DRAINAGE PIPE SECTION (OPTIONS) AND CONNECTION OF DRAINAGE PIPE SECTIONS (OPTIONS) - Google Patents

Abstract

1. Gutter sectional pipe, characterized in that it comprises a receiving section sequentially arranged from top to bottom, an outlet section connected to it, to which at least one middle straight section is connected, connected to the lower section, with the end part of each upper section located in the cavity of the end part of the lower section adjacent to it, each section is made of a composition of woven material and resin, which impregnated the pores of the woven material in such a way that, in the cured state, the composition of each sections forms a flexible and elastic wall of the section or at least one end part of the section, the flexibility of which is greater than the flexibility of the middle part of the section, adjacent sections of the drainpipe are connected by a quick disconnect located on the outer surface of the outer section in the area of its end part, the section of the end part decreases towards the end of the outer section, each upper section rests on the lower section along the beveled surfaces of the interconnected sections. 2. A gutter sectional pipe, characterized in that it comprises a receiving section sequentially arranged from top to bottom, a branch section connected to it, to which at least one middle straight section is connected, connected to the lower section, wherein the end part of each upper section is located in the cavity of the end part of the lower section adjacent to it, each section is made of woven material and resin, which impregnated the pores of the woven material so that in the cured state the composition of each section image It is a flexible and resilient wall section or at least about

Description

This utility model relates to means for draining sewage, mainly rain and melt water, from roof drains to sidewalks, while it also relates to pipe structures from which sections of the drainpipe are made; it also relates to means for connecting sections of a downspout.

A known gutter system for pitched roofs, including a drainage gutter, a drain funnel coated with a waterproofing material, vertical and inclined sections of a composite drainpipe connected to it, pipe corners between them with a plastic sleeve introduced into it along the entire length of the sections, and the drainage gutters are insulated by applying on the walls of the insulating layer of microporous material. The drainage channel is insulated with a drainage channel with a perforated upper or side wall. As a heater, extruded polystyrene foam is used predominantly. Sleeves made of a polymeric material are individually installed in vertical and inclined pipe elements. Inclined elements are treated with a hydrophobic material, mainly Movil. One of the sections of the composite pipe is made modular, allowing the pipe to disconnect, for example, due to a collapsible fixing clamp. The drainage channel is made in the form of a cornice or with a false panel in the form of a cornice. The drainage channel is installed opposite the roof in such a way that the edge of the roof enters the closed insulated drainage channel. An insulated drainage gutter is installed on the roof (RU 2006122378 A, 01/10/2008).

Known downpipe, including a vertical riser mounted on the wall of the building, as well as a tap installed in the collection area of the drain on the roof of the eaves of the roof of the building, and above the tap there is a canopy in the form of a visor fixed to the roof of the cornice. A mesh is installed on the sides of the visor adjacent to the drain. The riser is made in the form of a trough-like base, fixed close to the wall with fasteners, and a face plate, interconnected by fasteners on the base flanges. The vertical riser is mounted on the wall of the building with support on its blind area. The pipe is made with a hydrophobic coating. The front overlay of the base is equipped with elements that repeat the architectural protrusions of the wall of the building. In the drainpipe, the lower part of the faceplate is made in anti-vandal design (RU 100792 U1, 12/27/2010).

Known gutter system containing a drain pipe located at a downward angle to the horizontal, connected at one end to a drain funnel, and the other with a sewer pipe, while the drain pipe is divided into three sections: the first is adjacent to the drain pipe, the second to the drain funnel pipe, the third is flexible and connects the first and second sections. At the junction of the second and third sections made shutter. The inner surface of the second section, the inner surfaces of the funnel and drainpipe are covered with anti-icing material (RU 2435004 C, 11.27.2011). The technical result of the invention is to increase the operational reliability of the drainage system.

A drainpipe is known, which contains series-connected links and fasteners of links to the wall, including steel anchors connected to clamps, the two lower pipe links, including a link with a drain elbow, made of galvanized steel and inseparably connected to each other, each of two the lower links of the pipe consists of an outer corrugated element that is inextricably interconnected with a longitudinal corrugation and a smooth-walled inner element, on the inner surface of which a polymer coating is applied. The outer and inner elements of the two lower pipe links are made with a thickness of 0.3-0.55 mm, the two lower pipe links are made with a total height of 2700 mm with the outer diameter of the outer elements 90-216 mm, the connection angle of the two lower pipe links is 25-40 °, the outer surface of the outer elements of the two lower pipe links is coated with paint, the clamps for attaching the two lower pipe links are corrugated with a longitudinal corrugation. The drainpipe has a connection of the two lower links with the remaining links of the pipe, the connection is made using a movable cuff made of rubber-plastic material. On the end of the lower link with a drain elbow, a sealing ring made of rubber-plastic material is fixed (RU 94596 U1, 05.27.2010).

A known drainage system containing sections connected to each other, equipped at the top with a water intake funnel, and at the bottom with a drain, characterized in that it is made of at least one layer of a coating wound or wrapped around a mandrel or a layer obtained by pultrusion, contains layers of fiberglass fabricated using a mandrel (matrix), onto which a layer of a composition comprising a mixture of resin and hardener is applied, and the section, funnel, after curing and heat treatment is removed mandrel. The mandrel is made of elastic material, such as rubberized or elastic fabric or PVC. The mandrel is made of plastic or metal. Fiberglass is a brand of T-11 (92) silane. The composition further includes a color scheme and / or fire retardant material. Kohler is a pigment based on titanium. Fire-retardant material is a Terma-M brand. The mandrel metal is steel or galvanized steel. The resin is a polyester resin. Used hardener brand "butanox". In the anti-vandal version, the sections are sprinkled with marble or granite chips with fractions of 0.2-5 mm (RU 112229 U1, 01/10/2012).

The drainage system, as follows from patent RU 112229, is made of a layer wound on a mandrel of a coating or of a layer obtained by pultrusion, and the system contains layers of fiberglass made using a mandrel, on which a layer of the composition is applied - a mixture of resin and hardener. A significant drawback of this known drainpipe (which is called the “system” in the description of the utility model) is that one pipe section having a taper at the end, after it is inserted into the cavity of the outer section, exerts, with its tapering forces, on the end edge of the outer section, that under the conditions of wind loads on the pipe during its operation, it leads to ruptures of the end edge of the outer section and to premature damage to the entire drainpipe. At the same time, a layer of a mixture of resin and hardener applied to the glass fabric during the operation of the pipe leads to the fact that the connected sections by introducing the conical end of one section into the cavity of the adjacent section can create an integral connection from thermal effects, which makes it impossible to replace the damaged section with a new one section. In this case, the entire drain pipe must be replaced or it becomes necessary to repair the damaged section located at the height, which is associated with the great complexity of installation work. By a damaged section is meant a section, the edges of which at the junctions of the conical end of the upper section are subjected to breaks and water leakage through these breaks.

A fiberglass sheath pipe is known, the end of which is made conical for connection with a similar pipe, the pipe having an inner and outer shell, between which a heat insulating material is located (SU 319490 A, 02.11.1971).

A sealed detachable connection of one or several plastic pipes with a connecting part crimped around the perimeter is known, a rubber connecting ring is installed between the part and the pipes, while the sealing ring is pushed onto the connecting part and radially crimped (EP 0390746 C, 03.10.1990).

A fiberglass sheath pipe made of composite materials is known, including ring girdles, a metal cage with an edge thickened zone, while the girdles in cross section are made in the form of trapezoids, the side faces of which are made with a constant inclination (SU 518597 A, 06/25/1976).

Known shell made of composite material containing a frame made of threads wound along intersecting spirals, moreover, to simplify manufacture, the frame is equipped with a rigid locking element in the form of a local zone of curvature change of the shell made of transverse to the longitudinal axis of the shell threads superimposed on the frame and fixed with ends on spirals of winding around the perimeter of the local zone, and the threads of spiral winding are laid at an angle of 4 ... 54 ° to the longitudinal axis of the sheath (SU 1707399 A1, 01/23/1992).

Known sheath made of composite materials containing a frame of impregnated binder yarns wound along spirals intersecting at an angle of 55-86 ° to the longitudinal axis, as well as connecting ends (SU 1791657 A1, 01/30/1993).

Known sections of pipes made of composite material, each of which includes a middle part, a socket and a nipple at the ends, while the working surface of the socket and nipple is designed to connect with other sections made with conical ridges and cavities located between them for placement in the cavities of the sealing made of plastic cord (US 5520422 A, 05/28/1996).

Known pipe made of composite material containing a power frame formed by layers of composite fiberglass material consisting of a system of reinforcing fibers laid and interconnected in a given direction in a predetermined pattern, which are bonded to each other and to other elements structurally cured by a polymeric binder, lined on the inner surface of the protective coating, while the pipe has ends, one of which is a nipple, and the other a bell, the pipe also has a concentric s layers with an annular arrangement of glass fiber reinforced portion of the pin, the reinforcing rings are made of a composite material (RU 2166145 C1, 27.04.2001).

Known pipe made by winding fibers, including several cylindrical hollow open at the ends of the bearing shells located between the radially spaced fiber layers of the composite pipe, the pipe at the ends made with a nipple and a socket, on the working surfaces of which there is a thread, while the ends are electrically welded to the middle part of the pipe having metal layers (US 4,530,379 A, 07.23.1985).

A known method of manufacturing a plastic pipe by heating the outer surface of the inner thermoplastic layer, applying a reinforcing filler of a polymer or mineral material on it in the form of continuous filament winding with tension and applying the outer protective layer (RU 2197387 C2, 01.27.2003).

A known method of manufacturing a pipe, worn on a mandrel, which is applied to the primer and composite fiber materials, followed by heat treatment, carried out with a plastic billet mechanically constrained in a closed volume (RU 2191313, 10/20/2002).

A known method of manufacturing a pipe from plastic, including reinforcing a thermoplastic tubular billet with composite fiber material, machining end sealing elements, the method providing for the execution of working surfaces with grooves and undercuts and / or inverse cones on adjacent to the ends of the outer surfaces or inner surfaces of the pipe ends intended for connection with the working surfaces of other pipes (RU 2190531 C1, 10.10.2002).

A known method of manufacturing a pipe, comprising impregnating a filler filler with a binder, winding the filler onto the forming body, curing the polymer material and the finished product coming off the forming body (RU 2161089 C1, 12.27.2000).

In another method of manufacturing a reinforced three-layer plastic pipe, layers of a reinforcing tape are applied to the pipe billet and a protective coating is applied to the reinforcing layer (RU 2186685 C2, 08.10.2002).

In the known method of manufacturing a pipe, the fibrous material is passed through a binder, twisting the reinforcing material into bundles, they are spirally cross-wound onto a mandrel with the formation of through slots between the bundles and subsequent polymerization (RU 2215228 C1, 10.27.2003).

A known method of manufacturing a pipe from polymer composite materials, including molding the body of the pipe by winding on the mandrel a double spiral layer of the roving, while in the zone of its rotation, located at the end of the formed bell and (or) the large diameter of the inner conical surface of the pipe, the roving layer is subjected to numbing from axial displacement under the action of shrinkage towards a smaller diameter of the inner conical surface of the pipe by forming by means of winding a locking joint between a double joint package ral layers of the roving tape and the forming element of the mandrel, while in the area of the castle connection, 5-10 annular layers of roving impregnated with a binder are wound, the method being implemented using a mandrel in the form of a cylinder with an annular protrusion on its outer surface (RU 2190795 C1, 10.10.2002 )

Known pipe made of a composite material based on a binder and roving or fabric containing a load-bearing layer of the pipe (hereinafter - the bearing layer) located on the carrier layer of the pipe insulation, which is attached to the outer protective sheath, while the composite fiber material has a lower temperature polymerization than the temperature of preparation for curing the primer layer (RU 2211983 C2, 09/19/2003).

Known pipe made of a composite material based on a binder and roving or fabric containing a load-bearing layer of the pipe (hereinafter referred to as the bearing layer) located on the carrier layer of the pipe insulation, which is attached to the outer protective sheath, while the insulation is made of foam and the pipe includes panels of glass-basalt material (RU 2115056 C1, 07/10/1998).

Known methods of manufacturing pipes that have a carrier layer, insulation and outer shell, each of the known methods includes the operation of winding on the mandrel of a composite material based on an epoxy binder, roving or fabric, forming the carrier layer of the pipe, socket and nipple or socket and socket, or nipple and nipple, curing the carrier layer of the pipe, and first make one layer of the pipe and cure it, then make and cure the second layer of the pipe (RU 2221183 C2, 10.01.2004).

Known methods of manufacturing pipes that have a carrier layer, insulation and outer shell, each of the known methods includes the operation of winding on the mandrel of a composite material based on an epoxy binder, roving or fabric, forming the carrier layer of the pipe, socket and nipple or socket and socket, or nipple and nipple, curing of the carrier layer of the pipe, and when winding the sealing layer of the pipe at the same time form a bell and nipple (SU 1788379 A1, 01/15/1993).

A known method of manufacturing pipes from polymer composite materials, including forming on the mandrel a sealing layer of rubber and the subsequent winding of the power frame by winding the spiral layers of a roving tape impregnated with a polymer binder (GB 1229938, 7 F16L 9/12, 04/28/1971).

A known method of manufacturing pipes from polymer composite materials, including winding the rubber lining layer on a pre-assembled and coated with a release layer mandrel, forming a package of adhesive layers on top of the lining layer and winding the pipe body with an internal conical surface with the simultaneous formation of connecting elements in the form of a bell or nipple , or a collar at the ends of the pipe by sequentially winding a packet of double spiral layers of roving tape, impregnated with a binder, which in the area of the connecting elements reinforce the winding of the pre-impregnated binder fabric layers and the annular layers of the roving tape, as well as the subsequent polymerization of the pipe in a heat chamber and removal of the cured pipe from the mandrel (RU 2154766, 7 F16L 9/12, 08/20/2000).

Known fiberglass section of the pipeline, comprising a cylindrical body with end sections and at least one thickening at the end under a threaded socket or nipple, the wall of the body, which is formed by impregnated fiberglass binder threads wound in several layers along radial-axial spirals in opposite directions, moreover, the thickening of the end section and the middle cylindrical part of the section between its end sections is formed by groups of threads, which in the middle part of the section between the end sections are arranged with a predetermined step along the length of the section and overlapping the threads of other groups intersecting with them, forming a checkerboard pattern of interwoven groups of threads at an angle of 45 ÷ 65 ° to the longitudinal axis of the section, and in the transition zone between the thickening and the cylindrical part of the section, in the thickening of the bell or the nipple in which the thread is made, groups of threads are lapped onto each other in a radial-axial spiral and are located at an angle of 80-100 ° to the longitudinal axis of the section. In the end thickening of the socket or nipple of the section in which the thread is made, the fiberglass threads are located along the helical lines of the threads. In the thickening of the socket in which the thread is made, its working surface is stepped, the outer stage of which is made smooth conical, the middle stage of the socket is made conical with tapered thread on it, the inner stage is smooth and conical, and in the thickening of the nipple formed by radial turns of fiberglass , its working surface is made with an external conical smooth step with beveled thread crests and an internal conical step on which the nipple conical thread is located In this case, in the outer layer of the bulge thickening, the groups of threads are lapped onto each other in a radial spiral. In the bulge thickening formed by the radial turns of fiberglass threads, its working surface is stepped, the inner step of which is smooth conical, the middle step of the bell is threaded, the outer step is made with a smooth cylindrical section at the end, and in the thickening of the nipple formed by radial turns of fiberglass threads the surface is made with a conical smooth step, a second middle cylindrical step and a third cylindrical step, on which nipple thread is located. In the thickening of the bell formed by radial turns of fiberglass filaments, its working surface is formed by an outwardly expanding cone formed by an external smooth conical step, an average threaded conical step and an internal conical threaded step, the taper of which is greater than the conicity of the average threaded step and more than the taper of the external smooth conical step, while the taper the latter is larger than the taper of the middle threaded step, and in the thickening of the nipple formed by the radial turns of glass strands a fiber, its working surface is conical with an external smooth step, with a conical middle threaded step and a conical inner step tapering towards the end of the nipple, while the middle threaded step is made with beveled truncated threads, and the cone of the thread of the nipple is made along a tangent line passing through the beveled crests of thread turns to the horizontal at an angle of 15 ÷ 20 °. In the filaments formed by the radial turns of fiberglass yarns of the two sockets located at the ends of the socket section, the inner surface of each socket is formed by a conical step with a conical thread on it, adjacent to the conical step by an additional conical step and an end conical step, the taper of which is greater than the conicity of the additional conical step, and the taper of the latter is greater taper of a threaded conical step (RU 2278314 C1, 06/20/2006).

Hollow shells and pipes made of woven materials or fibers impregnated with cured resin are known (RU 2355575 C1, 12/10/2008; RU 2333103 C1, 02.27.2008 with reference to US 4646618 A, 1987 and FR 2445922 A, 1980. RU 2344934 C1 , 01.27.2009; RU 2153419 C1, 07.27.2000 with links to WO 93/07412 A, 04.15.1993 and US 5200251 A, 04/06/1993; RU 2161089 C1, 12/27/2000 with links to FR 2622506 A, 05/05/1989 and US 3441439 A, 04.29.1969; RU 2060159 C1, 05.20.1996 with reference to JP52-149734, 1979; US 4494436 A, 1979 and US 3959350 A, 1976).

Fiberglass pipe sections made of resin-impregnated glass materials are also known, and the wall of such sections is obtained by winding glass materials on mandrels in different directions with respect to the longitudinal axis of the mandrel (RU 2285187 C2, 10.10.2006; RU 2191313 C1, 10.20.2002 with links on FR 1597423 A, 05.20.1972 and DE 3132435 A, 02.24.1983. RU 2186685 C1, 10.10.2000 with links to FR 2404507 A1, 04/27/1979; FR 2728043 A1, 06/14/1996; FR 2290293 A1, 06/04/1976 and EP 0099999, 02/08/1984. RU 2190795 C1, 10/10/2002 with reference to W0 00/67995, 11/16/2000; W0 97/03815, 02/06/1997 and US 3259533 A, 06/05/1966). These pipe sections are designed for the manufacture of pressure pipelines. In this regard, the end parts of the sections are made on the basis of their tight connection with adjacent sections.

A known pipe for a drainage system made of at least one layer of wound coating, and the pipe contains layers of fiberglass wound using a matrix, on which a composite layer is applied as an impregnation, which is a mixture of a polyester resin and butanox hardener, this pipe is sprinkled with marble or granite chips with fractions of 0.2-5 mm (RU 112863 U1, 01.27.2012). Silane of the T-11 grade (92) was used as fiberglass, and the pigment based on titanium and the fire-retardant material of the Terma-M brand were additionally introduced into the composite.

A disadvantage of the known pipe according to patent RU 112863 is that its shape provides for connection with an adjacent pipe according to the “pipe in pipe” type, one of which is an upper pipe having a taper for introducing the conical end into the cavity of the adjacent lower section of the drainpipe. Such a connection is traditional and more acceptable for the connection of such sections of the drainpipe, which are made of metal. However, the specified connection of the pipe sections made of woven material and cured resin has unsatisfactory strength at the joints of the pipe sections due to bursting forces that adversely affect the edges of the outer lower section of the drainpipe. Another disadvantage of the known pipe according to patent RU 112863 is that each conical end of the upper pipe section inserted into the cavity of the lower pipe section having a rectilinear wall, at the junction, forms a drop of the inner surfaces of the sections with the rectilinear surface, which leads to the fact that small particles dirt and debris passing along the drainpipe together with water have the ability to form mud growths in the places of the indicated drops, which are the reason for the formation of larger growths from large fractions th dirt and garbage. All this with prolonged use of the drainpipe reduces the permeability of these particles and water in it, and in the cold season, these growths cause the formation of ice on them. These drawbacks also have a drainpipe containing interconnected sections, having junction points of the inner surfaces of the sections at the junction (RU 94596 U1, 05.27.2010). This patent provides for the connection of the sections using a movable rubber cuff in the connection.

Also known is a pipe made of a layered material, which is used as fiberglass, while the pipe is made by means of an elastic inflatable mandrel (RU 114906 U1, 04.20.2012).

Also known is a glass-basalt-plastic pipe containing layers of a composite material based on an epoxy binder and glass-basalt roving or fabric, while the components of the composite material in its total mass are contained in the following proportion, parts by weight: glass-basalt roving or fabric - 0.72-0.65 ; epoxy binder - 0.28-0.35 (RU 2313717 C2, 07.27.2007 with reference to US 4139025 A, 02/13/1979).

A tubular product is known made of a reinforcing fiber impregnated with a plastic composite material, the product obtained by winding the fibers on a mandrel (EA 201190022 A1, 2012.02.28). Also known is a tubular product made of reinforcing fiberglass impregnated with a polyamide material (EA 201190022 A1, 2012.02.28). Pipes made of composite material are also known (RU 84082 U1, 06.27.2009; RU 15377 U1, 10.10.2000; RU 2167357 C1, 05.20.2001; RU 2200661 C1, 03.20.2003 and RU 2270393 C1, 02.20.2006).

Known from the following patent, an insulated pipe-in-pipe assembly comprising at least one inner pipe having an outer surface, at least one container containing compressed, porous, resilient, compressible material and attached to the inner pipe, and an outer pipe located on top of the container so that the inner surface of the outer pipe and the outer surface of the container are fully or partially in direct contact. In this assembly, the outer tube is located on a container made by at least one of the methods selected from wrapping, extrusion, spraying, molding, or crimping. The outer tube consists of a material selected from the group consisting of the following: elastomers, silicone, thermosetting polymers, thermoplastic polymers, foamed polymers and composites. In the assembly, the container is previously completely or partially surrounded by a casing before the location of the outer pipe. In the assembly, the inner and outer pipes are made of a material selected from the group consisting of metals, metal alloys, elastomers, thermosetting polymers, thermoplastic polymers, foamed polymers, composites and ceramics. The assembly further comprises additional insulating material located in the annular space. In another embodiment, the insulated pipe-in-pipe assembly comprises at least one inner pipe having an outer surface, an outer pipe having an inner surface located around at least one inner pipe, an annular space between the inner surface of the outer pipe and the outer surface at least one inner pipe, and at least one container containing compressed, porous, elastic, compressible material located in the annular space and partially or completely surrounded by a casing ohm An assembly in which the casing contains one or more materials selected from the group consisting of aluminum, steel, galvanized steel, stainless steel, elastomers, thermosetting polymers, thermoplastic polymers, foamed polymers and composites. An assembly in which the casing is an elastic material. A unit in which the inner and outer pipes are made of a material selected from metals, an alloy of metals, elastomers, thermoset polymers, thermoplastic polymers, foam polymers and their combinations and ceramics. A unit in which additionally contains additional insulating material located in the annular. In a third embodiment, the insulated pipe-in-pipe assembly comprises at least one inner pipe having an outer surface, an outer pipe having an inner surface located around at least one inner pipe, an annular space between the inner surface of the outer pipe and the outer surface of at least at least one inner pipe, at least one container containing compressed, porous, elastic, compressible material and located in the annular space, and a casing located between the container and compressible material. In this embodiment of the assembly, the inner and outer pipes are made of a material selected from the group consisting of metals, metal alloys, elastomers, thermosetting polymers, thermoplastic polymers, foamed polymers, composites and ceramics. The assembly further comprises additional insulating material located in the annular space. An assembly in which the casing contains at least one of aluminum, galvanized steel, stainless steel, elastomers, thermoset polymers, thermoplastic polymers (RU 2011102918 A, 08/10/2012). This connection has the above disadvantages, which are unacceptable for connecting sections of the drainpipe.

These shortcomings lead to the need for hardening the walls of the pipe sections, as applied to their use in drain pipes, which is associated with a large consumption of material, increased energy consumption and the complexity of manufacturing sections of drain pipes. Moreover, the thickening of the walls of the sections and their ends leads to the need to change the shape of the ends of the connected pipes and to change the methods of installation and dismantling of drainpipes, complicating the processes of both production of drainpipes and their installation and dismantling.

The technical result of the solutions presented in this description is to reduce the material consumption, energy consumption and the complexity of manufacturing a drainage sectional pipe and its sections, as well as reducing the complexity of mounting and dismounting a drainage pipe.

The technical result is obtained by a gutter sectional pipe, characterized in that it contains a receiving section sequentially arranged from top to bottom, a branch section connected to it, to which at least one middle straight section is connected, connected to the lower section, with the end part of each upper section is located in the cavity of the end part of the lower section adjacent to it, each section is made of a composition of woven material and resin, which impregnated the pores of the woven material in such a way that In the m state, the composition of each section forms a flexible and elastic wall of the section or at least one end part of the section, the flexibility of which is greater than the flexibility of the middle part of the section, adjacent sections of the drainpipe are connected by a quick disconnect located on the outer surface of the outer section in the area of its end part , the section of the end part decreases toward the end of the outer section, each upper section rests on the lower section along the beveled surfaces of the interconnected sections.

The technical result is obtained by a gutter sectional pipe, characterized in that it contains a receiving section sequentially arranged from top to bottom, a branch section connected to it, to which at least one middle straight section is connected, connected to the lower section, with the end part of each upper section is located in the cavity of the end part of the lower section adjacent to it, each section is made of woven material and resin, which impregnated the pores of the woven material in such a way that in the cured state the composition of each section forms a flexible and elastic wall of the section or at least one end part of the section, the flexibility of which is greater than the flexibility of the middle part of the section, adjacent sections of the drainpipe are connected by a quick disconnect located on the outer surface of the outer section in the area of its end part, with each upper section rests on the lower section along the stepped surfaces of the interconnected sections.

The technical result is obtained by the section of the drainage sectional pipe, characterized in that it contains coils of woven fabric impregnated with cured resin, at the ends of the section coils are overlapped in the radial and longitudinal directions, in the middle of the section coils are arranged on top of each other in a spiral and made from strips of woven fabric, the longitudinal axis of each strip of fabric is located within 45-85 ° to the longitudinal axis of the pipe section, the pipe section and its end parts are flexible and elastic, wall thickness At least one end part of the section is less than the wall thickness of the section in its middle part.

The technical result is obtained by a drainage sectional pipe, characterized in that it contains coils of woven fabric impregnated with cured resin, at the ends of the coils section they are overlapped in the radial and longitudinal directions, in the middle part of the coils section they are arranged on top of each other in a spiral and made of strips of woven fabric, the longitudinal axis of each strip of fabric is located within 45-85 ° to the longitudinal axis of the pipe section, the pipe section and its end parts are flexible and elastic, the end parts of the section or one and its end portion has a stepped surface.

The technical result is obtained by connecting the sections of the drainpipe, characterized in that one end part of one flexible elastic section is located in the cavity of the end part of the other flexible elastic section, the end parts of the sections are fixed relative to each other on the contacting beveled surfaces of the sections, the end parts of the sections at the junction conical, on the end part of the outer section, in the connection zone of the sections, there is a screed, on the screed around it is a clamp connecting sections.

The technical result is obtained by connecting the sections of the drainpipe, characterized in that one end part of one flexible elastic section is located in the cavity of the end part of the other flexible elastic section, the end parts of the sections are fixed relative to each other on the contacting stepped surfaces of the sections, on the end part of the outer section, in the zone connection sections, the screed is located, on the screed around it is a clamp connection sections.

Figure 1 shows one example of a gutter sectional pipe in its working position;

figure 2 is a section aa in figure 1;

figure 3 is a section bB in figure 1;

figure 4 is a cross-section bb in figure 1;

figure 5 shows one example of a section of a drainpipe in longitudinal section (in a horizontal position);

in Fig.6 is a view of D in Fig.5;

in Fig.7 is a view of G in Fig.5;

on Fig - arrangement of the turns of the woven strip in the wall of the pipe section in its longitudinal and radial directions;

figure 9 is a diagram of the location of the pipe sections to their connection (in the first embodiment of the connection);

figure 10 is a first variant of the connection of the sections of the drainpipe (working position of the connection);

figure 11 is a stepwise connection of the walls of the sections of the drainpipe in the working position (second connection option, fragment, longitudinal section of the walls of the connected sections on their one side).

A downspout sectional pipe or hereinafter referred to as a pipe (Fig. 1) comprises a receiving section 1 with a socket, successively arranged from top to bottom, outlet sections 2 interconnected, one of which is connected to a reception section, and the other outlet section is connected to a straight middle section 3, which is connected to the lower branch section 4. The pipe may contain several series-connected middle sections 3. Since the working position of the drainpipe is mainly its vertical position, each pair of adjacent sections It has an upper and a lower section, wherein always the upper end section located inside the lower section. In this regard, each pair of adjacent sections has an upper, conditionally internal, section, and a lower, conditionally external section.

One end part z (Figs. 9, 10) of each upper section of the drainpipe is located in the cavity of the end part z of the lower section. In the embodiment of the drainpipe, the lower end part of section 2 is located in the cavity of the upper end part of section 3 (Fig. 4, the upper part of the drawing), and the lower end part of section 3 is located in the upper cavity of the end part of section 4 (Fig. 4, lower part of the drawing )

Each specified section of the drainpipe is made of a composition of woven material and resin. The pores of the woven material are impregnated with the resin in such a way that, in the cured state, the woven material and the resin represent the elastic wall of the pipe section having a given flexibility, and the ends of such a section have more flexibility than the middle part of the pipe. As a result, the pipe section along the length of its end part z has such flexibility that is greater than the flexibility of the middle part of the section and this flexibility increases towards the end of the section.

The upper receiving section 1 of the pipe and the lower outlet section 4 of the pipe have one beveled end part z, and all other sections of the pipe located between sections 1 and 4, in particular, sections 2 and 3 have two beveled end parts z (Fig. 5), located at the ends of these sections. Each beveled end part z forms a beveled surface 5, while the beveled surfaces 5 of one section are parallel. The interconnected sections are flush with respect to each other as shown in Fig. 4, while the sections form one smooth surface 6 of the drainpipe at the junction of the sections along their connector line.

Each two adjacent sections of the drainpipe are interconnected by a screed 7, located on the outer surface of each connected section. The screed is made of elastic elastic material and after connecting adjacent sections it performs the function of a gasket located under the clamp 8. The clamp is located around the connected pipe sections on the screed 7 and it completely covers the screed. All the clamps of the drainpipe have the means of their connection with the brackets (in Fig. 1, the brackets are conventionally shown with dashed lines, the clamp of the clamp is not shown).

In the second embodiment of the drainpipe, all the features of the first embodiment are used, with the exception of the beveled surfaces of the sections. Instead of the beveled surfaces at the ends of the sections of the second variant of the drainpipe, the stepped surfaces described below are made, along the contour of which adjacent sections are connected. The second option is preferable for its use in the construction of drainpipes of large diameter, having a large wall thickness of the connected pipe sections.

The section of the drainpipe (Figs. 1, 5) in this embodiment is represented by the straight middle section 3 (Fig. 5). Like other pipe sections having other, curved shapes, the middle section contains turns 9 (Fig. 8) of woven fabric impregnated with cured resin 10, conventionally shown by dotted hatching in Fig. 8. The woven fabric and resin in the cured state are an array of composite material (shown by cross-hatching in figure 5), from which the wall 11 of the pipe section 3 is formed. Over the entire length of the section, the coils 9 of woven fabric (Fig. 8) are overlapped on each other and wound in a spiral pattern of the composite material of the pipe wall in the longitudinal direction of the section. One or two end parts z, each of which is limited by a given length, as well as the middle part of the section, have turns made of strips 12 of woven fabric, preferably made of strips of fiberglass. The longitudinal axis of each spiral strip of fabric is located at an angle α selected between 45-80 ° to the longitudinal axis of the pipe section. The pipe section is made flexible and elastic, from the inside it is cylindrical and smooth, its end parts z are beveled as shown in Fig. 5, and the wall thickness of the end part z of the section in any cross section is smaller than the wall thickness of the pipe section in its middle parts. The beveled surface 5 of the right (in FIG. 5) end part z is inclined to the longitudinal axis of the section, and the beveled surface 5 of the left end part z is inclined from the longitudinal axis of the section.

The arrangement of the bands of woven fabric 12 (Fig. 8) provides that the edges of each strip of fabric are arranged so that they overlap the area of the bands adjacent to them within (0.2-0.5) L, where L is the width of the strip of woven fabric . The extreme stripes 12 (Fig. 8) are bent into the internal cavity of the section and form the ends of the section. After the manufacture of the pipe section, the woven fabric strips 12 are radially compressed so that they form a continuous solid wall 11 (FIG. 5). Other sections of the drainpipe, which have curved sections, are structurally made in the same way as the above rectilinear section 3. Moreover, the elbows of the curved sections are made using special technology, which is not disclosed in the present description. The upper receiving section 1 and the lower outlet section 4 have one end part with one beveled surface 5 with which the beveled surface in contact with the adjacent adjacent section contacts.

A second variant of the gutter pipe section is provided, in which stepped surfaces 13 (Fig. 11) are made at the ends of the sections, interacting with similar stepped surfaces of adjacent sections connected to them in the vertical position of the pipe, as shown in the drawing. On the outer surface of the pipe sections connected by a stepped connection, there is the aforementioned screed 7, covered by the clamp 8 in the same manner as described in the first embodiment of the drainpipe.

The connection of the sections of the drainpipe, in particular the upper section 3 with the lower section 4 (FIG. 1) of the drainpipe, is made by positioning the end part z of the upper section 3 (FIG. 10) of the drainpipe in the end part z of the lower section 4 when the connection is in assembled working position. The above end part z of each upper pipe section 3 is made beveled toward the longitudinal axis of the section 3. The end part z of the upper part of the lower pipe section 4 is beveled away from the longitudinal axis of the section. Sections having two chamfered surfaces 5 (FIG. 5) are designed so that these chamfered surfaces are parallel, and the planes in which the chamfered surfaces 5 are located are inclined with respect to the longitudinal axis of the section (FIGS. 5, 8). The cross section of each beveled end part z of the section decreases toward the end of the end part of the section. The length of the end part z of the section is determined by the connection of this section with another adjacent pipe section and the wall thickness of the sections, the connection being characterized by the contact point of interconnected adjacent sections along the beveled surfaces 5. In the longitudinal section of the pipe (Fig. 4), the inner surfaces of 6 adjacent sections 3 and 4 are located on one straight line, which is essential to eliminate the delay of dirt particles at the junction of the sections.

The connection of the drainpipe sections provides that adjacent sections of the drainpipe are detachably interconnected and fixed relative to each other by a flexible coupler 7, covering on the sides the connector line of adjacent sections from the outside of the drainpipe along its perimeter. The screed in this embodiment is made in the form of a flexible and sticky tape on one side, on which side an adhesive composition is applied. The coupler with an interference fit is located on the connection of the sections and closes the line of the connector sections. The screed can also be made in the form of a nylon tape with self-locking elements located on two branches of the screed entering one another.

The wall of each section is preferably circular in cross section, which does not exclude other known pipe shapes. From the inside, the inner surface of each pipe section is smooth. At the junction of the sections (Fig. 10), the inner surfaces of the upper section 3 and the lower section 4 in their longitudinal section are located on one straight line when the connection of the sections of the drainpipe is in the working position.

It is significant that in one embodiment, the connection of the sections is made on bevelled contacting surfaces 5, providing the possibility of decomposition of the static vertical load on the connection into two components of force - vertical and horizontal (radial) with respect to the longitudinal axis of the pipe. Reactions from these forces are directed in opposite directions. The vertical reaction Rx is directed upward from the contacting surfaces parallel to the longitudinal axis of the joint, the horizontal reaction Ry is directed perpendicular to the longitudinal axis of the connected sections, and the resultant reaction is perpendicular to the contact line of the sections. Moreover, the smaller Ry, the smaller the bursting loads experienced by the edge of the outer section 4, which covers the inner upper section 3 included in it (Fig. 10), the higher the bond strength.

In another, stepwise version of the connection of the sections, which is shown in FIG. 11 in the form of a longitudinal section of the walls of the connected sections, there is no lateral component of the force from the static load, since the vertical load on the lower outer section 4 from the weight of one or more upper sections 3 is transmitted from the ends of the stepwise the surface 13 of the upper section at the ends of the steps of the stepped surface 13 of the lower section 4. In this case, Ry = 0 and the bursting loads on the edge of the outer section are reduced to zero. The above-described options for connecting sections allow you to apply the first connection to thin-walled pipe sections, and the second connection is used to connect thick-walled sections of drainpipes having large diameters.

On the screed 7 around the perimeter of the pipe there is a clamp 8, covering and compressing the screed 7 and the end parts of the pipe sections connected to each other. The clamp clamps the screed 7 to the longitudinal axis of the pipe. Each clamp 8 has a means of its connection with the bracket for attaching the pipe to the wall of the building (the brackets in figure 1 are shown with dashed lines, since they are not included in the pipe structure).

In the second embodiment, the connection of the pipe sections, its flexibility, elasticity and wall thickness are constant over the entire length, and the ends of the adjacent sections are joined together by steps, each of which is made on the end part of the section. In this case, the adjacent sections are interconnected along the stepped surfaces 13 (11), made at the ends of adjacent sections 3 and 4.

The downpipe works as follows. At the construction site, the end part of each upper section is sequentially introduced into the cavity of the end part of each lower pipe section until the contact beveled surfaces 5 or stepped surfaces 13 interact with each other. After that, the flexible sections 7 tighten the section connection as shown in Figs. 4 and 10 Tightening the connection of the sections is carried out by tightening the aforementioned adhesive tape of the coupler 7 in a spiral to connect the sections 3 and 4 with the possibility of overlapping turns of the coupler of the connecting line of the sections 3 and 4. Moreover, each turn of the screed tape is glued to the downstream screed tape 7. The turns of the screed 7 superimposed on each other in their working position fix the sections from their displacement in the longitudinal direction of the drainpipe. After forming the screed 7, it in its working position forms a flexible and elastic cylindrical ring, which is used for another purpose - as a gasket between the clamp 8 and the connected pipe sections. Put on the screed 7 and the clamp 8 as shown in Figs. 4 and 10 and the clamp 8, additionally compress the end parts z of the sections 3 and 4, and fix the sections and the screed in the working position.

Each section of the drainpipe in the cured state has flexibility and resilience, and the end part z of each outer section has greater flexibility compared to the flexibility of the middle part of the section. In this regard, the couplers 7 in the process of tightening the sections between themselves in the radial direction, the end parts z of the sections are easily bent in places of their tightening. The end part z of section 4 is bent and pressed with its beveled surface 5 to the beveled surface 5 of the end part z of section 3. The end parts z of sections 3 and 4 are pressed against each other so that their inner surfaces 6 (Fig. 4) are located on one a straight line - on the generatrix of the inner surface of the drainpipe.

After fixing the sections in the working position, the assembled drain pipe is lifted in a known manner to the design vertical position. The pipe is connected by means of clamps 8 with brackets fixed to the wall of the building and the pipe is installed in a vertical position. In a similar manner, sections 3 and 4 are connected having step surfaces 13 at the ends (FIG. 11).

In the working position of the pipe, the static load is transmitted from top to bottom through beveled surfaces 5 (Fig. 5) or via stepped surfaces 13 (Fig. 11), in the first case, the radial component of the force acting on the end edge of each enclosing outer section in the area of adjacent adjacent sections is minimized. In another embodiment, in the case of a stepwise connection of adjacent sections, the indicated radial component of the force is absent and there is no effect on the end edge of the covering outer section. The same applies to dynamic loads arising mainly from wind loads.

When the drainpipe is operating, the wastewater enters the cavity of the receiving section 1 (FIG. 1) and exits through the outlet section 4, with the wastewater passing through all sections of the pipe. A drainpipe, which has flexibility and elasticity within specified limits, performs microoscillations in the radial and longitudinal directions during operation. With the passage of water, ice particles and dirt of the end parts of the z sections facing the inside of the pipe, water, ice particles and dirt do not linger at the junction of the sections due to the smoothness of these junction and the absence of surface drops at these points along the connector lines of the connected sections. As a result, the cavity of the drainpipe is well self-cleaning, no accumulations of the indicated particles are formed at the junction of the sections and in these places the pipe cross sections are not narrowed. All this provides a good cross of water and dirt through the drainpipe and increases the reliability of its work. It is significant that the flexibility and resilience of the pipe reduces the possibility of freezing on its inner surface of the ice. The connection of the sections is made on the basis of reducing the complexity of the installation and dismantling of the drainpipe by providing quick and convenient connection of the sections and their connector. The connection makes it possible to self-clean the drainpipe from debris and dirt contained in wastewater entering the drainpipe from the roof of the building, as well as self-cleaning from ice crystals freezing into ice lumps in the pipe in the cold season.

The section of the drainpipe operates as follows. When passing through the cavity of the section of water, ice particles, debris coming together with water from the roof of the building, as well as when the section is exposed to retrovy loads, the section experiences loads that are damped by the brackets of the drainpipe. In this case, loads from the section are transferred to adjacent sections, which tend to return the section to its original position. In this case, the section experiences longitudinal and bending loads, which, due to the elasticity and flexibility of the section, bend it in the transverse direction and, together with other sections, vibrate in mutually opposite directions. Due to these vibrations, the inner surface of the drainpipe is partially self-cleaning of microparticles; no growths are formed on it, which cause a delay in the cavities of sections of more fragile fractions of ice and debris. The section design provides for connection with an adjacent section along the aforementioned beveled surfaces of the end parts z, which made it possible to create a unified connection of sections and at the same time eliminate bursting forces acting on the edges of the adjacent lower section, which includes the upper section with a conical end. Rolled inward extreme stripes 12 of fabric allowed to increase the strength of the ends of the sections, as well as to eliminate the need for trimming the ends of the sections after their manufacture. Together, all these positive factors made it possible to reduce the complexity of manufacturing the section, reduce the complexity of mounting the section in conjunction with other sections, and increase the life of the section. The above-described installation of the pipe significantly reduces its complexity, and the layout solution of the drainpipe reduces the complexity of its manufacture, since each section of the pipe is such a part of the pipe that does not require additional operations after its manufacture, associated with cutting its ends and operations associated with performing external ends conical pipes included in the spacer in the inner pipe. Due to the reduction in one case and the exclusion in the other case of bursting forces at the ends of the outer sections (which cover the inner sections), the reliability of the drain pipe and its service life are increased.

Claims (6)

1. Gutter sectional pipe, characterized in that it comprises a receiving section sequentially arranged from top to bottom, an outlet section connected to it, to which at least one middle straight section is connected, connected to the lower section, with the end part of each upper section located in the cavity of the end part of the lower section adjacent to it, each section is made of a composition of woven material and resin, which impregnated the pores of the woven material in such a way that, in the cured state, the composition of each section forms a flexible and elastic wall of the section or at least one end part of the section, the flexibility of which is greater than the flexibility of the middle part of the section, adjacent sections of the drainpipe are connected by a quick disconnect located on the outer surface of the outer section in the area of its end part, the section of the end part decreases towards the end of the outer section, each upper section rests on the lower section along the beveled surfaces of the interconnected sections. 2. A gutter sectional pipe, characterized in that it comprises a receiving section sequentially arranged from top to bottom, a branch section connected to it, to which at least one middle straight section is connected, connected to a lower section, with an end part of each upper section located in the cavity of the end part of the lower section adjacent to it, each section is made of woven material and resin, which impregnated the pores of the woven material so that in the cured state the composition of each section is treated it is a flexible and elastic wall of the section or at least one end part of the section, the flexibility of which is greater than the flexibility of the middle part of the section, adjacent sections of the drainpipe are connected by a quick disconnect located on the outer surface of the outer section in the region of its end part, with each upper the section rests on the lower section along the stepped surfaces of the interconnected sections. 3. A section of a drainpipe, characterized in that it contains coils of woven fabric impregnated with cured resin, at the ends of a section of coils are overlapped in the radial and longitudinal directions, in the middle of the section coils are arranged on top of each other in a spiral and made of strips woven fabric, the longitudinal axis of each strip of fabric is located within 45-85 ° to the longitudinal axis of the pipe section, the pipe section and its end parts are flexible and elastic, the wall thickness of at least one end part of the section of men earlier than the wall thickness of the section in its middle part. 4. Section of the drainpipe, characterized in that it contains turns of woven fabric impregnated with cured resin, at the ends of the section of the coil are overlapped in the radial and longitudinal directions, in the middle of the section of the coil are arranged on each other in a spiral and made of strips woven fabric, the longitudinal axis of each strip of fabric is located within 45-85 ° to the longitudinal axis of the pipe section, the pipe section and its end parts are flexible and elastic, the end parts of the section or one of its end parts has a step thawed surface. 5. Connection of the drainpipe sections, characterized in that one end part of one flexible elastic section is located in the cavity of the end part of the other flexible elastic section, the end parts of the sections are fixed relative to each other on the contacting beveled surfaces of the sections, the end parts of the sections are made conical , on the end part of the outer section, in the connection zone of the sections, there is a screed, on the screed around it there is a clamp of connection of the sections. 6. Connection of the drainpipe sections, characterized in that one end part of one flexible elastic section is located in the cavity of the end part of the other flexible elastic section, the end parts of the sections are fixed relative to each other on the contacting stepped surfaces of the sections, on the end part of the outer section, in the connection zone sections, the screed is located, on the screed around it is a clamp connecting sections.

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