RU2575534C2 - Method of heat insulation of stop valves of above-ground pipelines and heat insulation device for method realisation - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: group of inventions relates to devices for heat insulation of stop valves of previously heat-insulated pipelines. A heat insulated box comprises an outer protective shell from galvanised steel with a heat insulation coating at the side of the inner surface of the shell, made as detachable from sections. Number and configuration of sections depend on geometric dimensions of an insulated gate valve. Some sections are made of two stiffly connected segments of a cylinder, oriented in mutually perpendicular directions, made as capable of section installation simultaneously on the gate valve and on the part of the pipeline with factory heat insulation, adjacent to the gate valve, and is equipped by stiffening ribs in the area of stiff connection of section segments. Sections are equipped with shock-absorbing gaskets from foam rubber for box tightness during its multiple assembly and disassembly and a lock mechanism. The heat insulation coating is made of foam glass blocks fixed on the inner surface of the protective shell with the help of a bitumen-based adhesive. A coating for protection of blocks against wear is applied onto the surface of the foam glass blocks at the side of contact with the gate valve.

EFFECT: improved heat insulation.

22 cl, 1 tbl, 5 dwg

Description

The invention relates to the field of pipeline construction and can be used in the arrangement of thermal insulation of shutoff valves (flanges, gate valves, valves, etc.) of main and technological pre-insulated pipelines intended primarily for transporting oil and oil products in difficult climatic conditions ( at low temperatures).

There are various solutions of heat-insulating structures and methods of thermal insulation of valves (including slide gate valves).

In particular, the invention is known as “Thermal insulation construction” (patent for utility model RU 40433, published September 10, 2004, IPC F16L 59/00), in which the thermal insulation construction is collapsible and includes removable shell segments fastened with bandages. The segments are combined in a structure that forms a heat-insulating shell around the pipeline and consists of N sectors, interconnected in a diametrical direction into a lock. The bandages are made in the form of tightening tapes secured by a lingering device equipped with a stopper.

However, this design does not provide for the option of quick removal of individual segments. To ensure access to individual elements of the insulated equipment for maintenance and repair, dismantling of the entire structure is necessary.

Closest to the claimed technical solution is a thermal insulation device for a slide gate valve (patent for utility model RU 119843, published August 27, 2012, IPC F16L 59/00), containing a collapsible structure containing a protective shell, to the inner surface of which a non-combustible heat-insulating material is attached at help mastic. The joints between collapsible structural elements are sealed with gaskets to provide access to the slide gate valve for its maintenance and repair. The thermal insulation design of the slide gate valve can consist of two or more parts, while its shape (rectangular or shaped design) is determined taking into account the shape and size of the slide gate valve, design features, type of connection to the pipeline (welded, flanged) and installation method. The protective sheath is made of galvanized sheet steel. The parts of the thermal insulation are fastened with metal ties with locks, bolts with nuts, and self-tapping screws. The design includes a non-removable part of the thermal insulation of the bottom of the slide gate valve (mounted in the factory) and a part consisting of collapsible elements, which is mounted in the field. As a material of thermal insulation, foam glass is used. Inside the containment with thermal insulation, gas analyzers and nozzles are installed to purge the internal cavity of the insulation before dismantling with an increased content of oil vapor according to the readings of gas analyzers.

The disadvantage of this solution is the more complex design of the thermal insulation of the slide gate valve, in comparison with the claimed solution, which is characterized by greater complexity during installation and maintenance of the slide gate valve during operation of the pipeline. Also, the existing design has an increased fragility of the insulating layer due to the lack of mechanical protection of the insulating layer of foam glass.

The objective of the invention is to improve the design of the thermal insulation of valves (in particular, a thermally insulated duct for slide gate valves) for overhead installation in route conditions, making it possible to manufacture them in factory conditions, simplifying their assembly in route conditions and access to valves in the operation of the pipeline ( including for maintenance and repair) while maintaining its strength and heat-conducting characteristics.

The technical result that can be obtained by implementing the present invention is to reduce the time spent on mounting (assembling) the thermal insulation device of the stop valve, as well as dismantling the individual units of the device to provide access to the elements of the stop valve for maintenance and repair, maintaining high device performance. This is especially important during installation, repair and technological work in the Far North, where the air temperature reaches minus 60 ° C.

The technical result is achieved due to the original constructive implementation of both the entire claimed device for thermal insulation of valves, and its individual blocks (sections). The presence of easily removable sections ensures the maintenance of shut-off valves without the complete dismantling of thermal insulation.

The problem is solved in that the device (heat-insulated box) for thermal insulation of the slide gate valve located on the pipeline contains an external protective shell made of galvanized steel with a heat-insulating coating on the side of the inner surface of the shell, made of collapsible sections, the number and configuration of which is determined based on of the geometric parameters of the insulated gate valve, while part of the sections is made of two rigidly interconnected segments of the cylinder oriented in aimno perpendicular directions, adapted to the installation section simultaneously on the valve and a portion of pipe insulated with the factory adjacent to the valve and is provided with stiffening ribs in rigid connection section area segments; the sections are equipped with sealing shock-absorbing gaskets made of foamed rubber (foam rubber), ensuring the tightness of the box when it is repeatedly assembled and disassembled, and elements of the locking mechanism located on the outer surface of the shells of adjacent sections with the possibility of their connection, and the thermal insulation coating is made of foam glass blocks (foam glass ) installed close to each other, having a profile that repeats the profile of the slide gate valve at the place of installation of the corresponding segments on it, and closes captured on an inner surface of the containment shell and to each other using an adhesive based on bitumen, wherein the surface of the foam glass blocks by contacting the hinged door is coated to protect the said units from abrasion.

In a particular embodiment of the invention, the number of sections configured to be installed simultaneously on the gate valve and on a part of the factory-insulated pipeline adjacent to the gate valve is selected to be eight, with the segment segments being a quarter of the cylinder. The protective shell on the segments intended for placement on the pipeline is made of galvanized sheet with pre-cut and bent edges for rigidly fixing said segments on the segments intended for placement on the valve using self-tapping screws. The notches for connecting the segments of the sections placed on the pipeline with the segments of the sections placed on the valve are made from 5 to 10 cm in depth.

In a particular embodiment, the stiffening rib is a metal plate, for example, a triangular one, one rib of which is welded perpendicular to the surface of the segment of the section intended for placement on the pipeline, and the second is welded perpendicularly to the surface of the segment of the section intended for placement on the valve. In this case, the stiffeners are installed at a distance of at least 20 cm from each other.

K-Flex, Armaflex foam rubber gaskets can be used as sealing shock-absorbing gaskets, as an adhesive on a bitumen basis for fixing foam glass (foam glass) blocks on the inner surface of the protective shell, and among themselves TechnoNikol bitumen can be used, for To protect foamed glass blocks from abrasion, a composition is used that includes non-combustible cement with a reinforcing fiberglass mesh. As blocks of foamed glass, material (foam glass) with a thickness of at least 100 mm is used, the outer protective shell of galvanized steel has a thickness of 0.8-1 mm. The sections are equipped with at least one handle for ease of assembly / disassembly.

The problem is also solved by the fact that the method of manufacturing a thermally insulated box for arranging thermal insulation located on the pipeline of the gate valve includes determining the number of sections required for thermal insulation of the valve, the manufacture of a protective shell made of galvanized steel for each section, followed by fixing (gluing) with adhesive on a bituminous basis of foam glass (foam glass) blocks from the side of the inner surface of the shell with the formation of a heat-insulating coating Ia, coating the inner surface of blocks of foam glass coating to protect them from abrasion, after which the short sides along the perimeter of the assembled sections are glued sealing gaskets of foamed rubber (penokauchuka) ensuring tightness design with repeated assembling and disassembling the box; the protective shell made of galvanized steel for part of the sections is made of two cylinder segments oriented in mutually perpendicular directions, configured to install the section simultaneously on the valve and on the part of the pipeline with factory insulation adjacent to the valve, the segments are rigidly interconnected, and stiffening ribs are installed in the connection zone.

The inventive method also has the features listed in the description of the device, which can also be used in the manufacture of boxes.

The invention is illustrated by drawings, where in FIG. 1 shows an embodiment of a thermally insulated duct for arranging thermal insulation of a slide gate valve, FIG. 2 - an option for attaching adjacent sections of a thermally insulated duct, in FIG. 3 shows an embodiment of a removable section of the middle tier of a thermally insulated duct, FIG. 4 is an embodiment of a removable section of the upper / lower tier of a thermally insulated duct, FIG. 5 - insulated box assembly.

The positions in the drawings indicate:

1. Gate valve

2. Trunk branch pipes of a gate valve,

3. The protective shell of the insulated duct,

4. The heat-insulating coating of the insulated duct,

5. Sections of a thermally insulated duct (or protective shell with a heat-insulating coating on the side of the inner surface of the shell),

6. The upper tier of thermal insulation (sections),

7. The lower tier of thermal insulation (sections),

8. The middle tier of thermal insulation (sections),

9. The side wall of the insulated housing,

10. The end wall of the insulated housing,

11. The segment section of the upper / lower tiers, which is part of the side wall of a thermally insulated body,

12. The segment section of the upper / lower tiers, which is part of the end wall of the insulated body,

13. The segment section of the middle tier, which is part of the side wall of the insulated body (designed to be placed on the slide gate valve),

14. The segment section of the middle tier, designed to be placed on the pipeline,

15. The stiffener,

16. Blocks of foam glass (foam glass),

17. Sealing shock-absorbing gaskets made of foam rubber (foam rubber),

18. The locking mechanism

19. A rigid connection of the segments of the section of the protective shell of the middle tier,

20. Fasteners,

21. The handle.

Used terminology.

Shutoff valves - valves designed to shut off the flow of a working medium with a certain tightness.

A gate valve is an industrial pipeline valve in which a shut-off element reciprocates, moving perpendicular to the axis of the flow of the working medium.

Gate valve - a parallel gate valve, in which the locking element is made in the form of a gate.

Corrosion protection - a set of works, including the preparation of a steel surface to be protected against corrosion, the application and curing of paints and varnishes, quality control, etc.

Corrosion-resistant coating - a system of sequentially applied and adhesive bonded layers of paints and varnishes.

Foamed glass (foam glass) is a heat-insulating material consisting entirely of inorganic matter without a binder with a foam structure, obtained by sintering finely ground glass powder and a blowing agent.

The thermal insulation device of the slide gate valve 1 is made in the form of a thermally insulated box, which is a protective shell 3 made of galvanized steel (metal casing) with a heat-insulating coating 4 from the side of the inner surface of the shell. In this case, the box is made of collapsible sections, the number and configuration of which is selected taking into account the geometric dimensions of the stop valves, the features of its design, the type of connection to the pipeline (welded, flanged) and the installation method (on the foundation, without foundation). Further, a detailed description of the invention is presented by the example of arranging thermal insulation of a slide gate valve 1 located on a pipeline (see Fig. 1).

In particular, for thermal insulation of the slide gate valve 1, the thermally insulated box (assembled, see Figs. 1, 4) has a first cylindrical part oriented vertically, intended for thermal insulation of the direct gate valve, and the second and third cylindrical parts associated with it, oriented horizontally designed for thermal insulation of the main pipes 2 of the valve 1 and located on opposite sides of the vertical part.

For the design of the gate valve, it is optimal to perform a heat-insulated box of sixteen removable sections 5, eight of which are designed to be installed (four sections each) on the upper and lower parts of the gate valve (forming the lower 7 and upper 6 tiers of thermal insulation), and the remaining eight - on the central part of the slide gate valve (form the middle tier 8 of thermal insulation).

The sections intended for the upper 6 and lower 7 tiers are made of two segments 11 and 12 rigidly interconnected, one of which is 11, is part of the side wall 9 of the insulated box and is made in the form of a quarter of a cylinder, and the second segment 12 connected ( conjugate) with the first segment along the circumference line, is part of the end wall 10 of the insulated duct and is made in the form of an angular segment with a technological recess for the protruding parts of the slide gate valve (see Fig. 4).

The middle tier 8 is formed of eight sections 5 arranged in two rows (see Fig. 5). Section 5 of the middle tier 8 is made of two rigidly interconnected segments 13 and 14, each of which represents a quarter of the cylinder (see Fig. 3). In this case, segments 13 and 14 are oriented in mutually perpendicular directions, ensuring their installation at the same time on the valve (segment 13) and on the pipeline part (segment 14) with factory insulation adjacent to the valve. Thus, one segment 13 is part of the side wall of a thermally insulated duct (i.e., designed to be installed on a valve), and the second, 14, is designed to be installed on a pipeline with factory thermal insulation (including trunk pipes 2).

Sections 5 of the middle tier 8 are equipped with stiffeners 15 installed in the zone of mating (connection) of the segments of the section. In a particular embodiment, the stiffener 15 is a triangular metal plate, one edge of which is welded perpendicular to the surface of the segment 14, intended for placement on the pipeline, and the second is welded perpendicular to the surface of the segment 13, intended for placement on the valve. Stiffeners are installed at a distance of at least 20 cm from each other.

The heat-insulating coating 4 is made of blocks of foamed glass (foam glass) 16, mounted close to each other, having a configuration (shape) that repeats the configuration (shape) of the valve surface at the installation site of the corresponding segments, and fixed to the inner surface of the protective shell and with each other using an adhesive on a bitumen basis, for example, the TechnoNicol brand. To perform the heat-insulating coating of the duct designed for the thermal insulation of the slide gate valve installed on the pipeline in the extreme north (with air temperature up to minus 60 ° C), it is recommended to use foamed glass with the technical characteristics presented in Table 1.

The thickness of the thermal insulation coating (the thickness of the foam glass blocks) is determined by the heat engineering calculation performed individually for each construction site.

On the surface of the foam glass blocks in contact with the slide gate valve, a protective coating is applied based on non-combustible gypsum cement, which protects the foam glass from mechanical influences.

The sections are equipped with sealing shock-absorbing gaskets 17 made of foamed rubber (foam rubber), which ensure tightness of the structure during repeated assembly-disassembly of the box, and elements of the locking mechanism 18 located on the outer surface of the shells of adjacent connected sections. In particular, the locking mechanism can be made in the form of metal ties with locks, while the metal coupler is located on one section, and the lock from the mechanical coupler is on the adjacent section (see Fig. 2).

The design of the box (all its sections) is made in the factory, and the installation of the manufactured sections on the slide gate valve is carried out on site (in the field) (see Fig. 5). The material for the implementation of the protective shell is thin-sheet galvanized steel with a thickness of 1.0 mm, which protects the thermal insulation coating from environmental influences and mechanical damage during installation and operation.

The application of the proposed insulated duct provides thermal insulation of the slide gate valve using fireproof materials with access for its maintenance and repair.

A method of manufacturing a heat-insulated duct for arranging thermal insulation located on the pipeline gate valve, includes the following operations. First, determine the number of sections (including shapes and sizes) required for thermal insulation of the valve. For each section, foam glass blocks are made with a profile repeating the valve profile at the section installation site. The outer protective shell for each section is made of galvanized sheet, which is cut to the appropriate section sizes (foam glass blocks assembled for each section), then the foam glass blocks are glued to the outer protective shell using adhesive on a bitumen basis. Then, on the inner surface of the blocks from the side of their contact with the surface of the slide gate valve, a protective coating is applied from the abrasion of the blocks. Sealing gaskets made of foamed rubber (foam rubber), for example, K-Flex, Armaflex grades, are glued from the ends of the sections obtained around the entire perimeter, which ensure tightness of the structure during repeated assembly-disassembly of the box.

A method of thermal insulation of a slide gate valve located on a pipeline includes assembling a heat-insulated duct made of collapsible from sections (as described above), and securing the sections by means of metal locks.

Claims (22)

1. A heat-insulated box for arranging thermal insulation of a slide gate valve located on a pipeline, characterized in that it contains an external protective shell made of galvanized steel with a heat-insulating coating on the side of the inner surface of the shell, made of collapsible sections, the number and configuration of which is determined based on geometrical parameters of the insulated gate valve, while part of the sections is made of two rigidly interconnected segments of the cylinder, oriented in mutually perpendicular directions, adapted to the installation section simultaneously on the valve and a portion of pipe insulated with the factory adjacent to the valve and is provided with stiffening ribs in rigid connection section area segments; the sections are equipped with sealing rubber shock-absorbing gaskets made of foam rubber, ensuring the tightness of the box when it is repeatedly assembled-disassembled, and elements of the locking mechanism located on the outer surface of the shells of adjacent sections with the possibility of their connection, and the heat-insulating coating is made of foam glass blocks installed close to each other to a friend having a profile repeating the profile of the slide gate valve at the place of installation of the corresponding segments on it, and fixed on the inner the surface of the protective shell and with each other using an adhesive on a bituminous basis, while the surface of the foam glass blocks is contacted with the slide gate to protect the blocks from abrasion. 2. A heat-insulated box according to claim 1, characterized in that the number of sections configured to be installed simultaneously on the valve and on a part of the pipeline with factory insulation adjacent to the valve is selected to be eight, while the segments segments represent a quarter of the cylinder. 3. The heat-insulated box according to claim 1, characterized in that the protective shell on the segments intended for placement on the pipeline is made of galvanized sheet with pre-notched and bent edges for rigidly fixing said segments on segments intended for placement on the valve by means of self-tapping screws. 4. The insulated box according to claim 3, characterized in that the notches for connecting the segments of the sections placed on the pipeline with the segments of the sections placed on the valve are made from 5 to 10 cm in depth. 5. The heat-insulated box according to claim 1, characterized in that the stiffener is a metal plate, for example, a triangular one, one of which is welded perpendicular to the surface of the segment of the section intended for placement on the pipeline, and the second is welded perpendicular to the surface of the segment of the section, intended for placement on a valve. 6. The insulated box according to claim 1, characterized in that the stiffeners are installed at a distance from each other of at least 20 cm 7. The insulated box according to claim 1, characterized in that the outer protective shell of galvanized steel has a thickness of 0.8-1 mm 8. The insulated box according to claim 1, characterized in that the sections are equipped with at least one handle for ease of installation / dismantling. 9. A heat-insulated box according to claim 1, characterized in that K-Flex and Armaflex gaskets are used as sealing shock-absorbing gaskets. 10. The heat-insulated box according to claim 1, characterized in that as an adhesive on a bitumen basis for fixing blocks of foamed glass on the inner surface of the protective shell and between each other, use bitumen of the TechnoNikol brand. 11. A heat-insulated box according to claim 1, characterized in that for the protection of foam glass blocks from abrasion, a composition is used, including non-combustible cement with a reinforcing fiberglass mesh. 12. A thermally insulated box according to claim 1, characterized in that the blocks of foamed glass have a thickness of at least 100 mm. 13. A method of manufacturing a thermally insulated duct according to claim 1 for arranging thermal insulation of a slide gate valve located on the pipeline, characterized in that it includes determining the number of sections required for thermal insulation of the gate valve, manufacturing a galvanized steel protective sheath for each section, followed by fixing with adhesive on a bituminous basis of foam glass blocks from the side of the inner surface of the shell with the formation of a heat-insulating coating, application to the inner surface the foam glass covering blocks to protect them from abrasion, after which sealing foams made of foam rubber are glued from the end sides around the entire perimeter of the assembled section, ensuring tightness of the structure during repeated assembly-disassembly of the box; the protective shell made of galvanized steel for part of the sections is made of two cylinder segments oriented in mutually perpendicular directions, configured to install the section simultaneously on the valve and on the part of the pipeline with factory insulation adjacent to the valve, the segments are rigidly interconnected, and stiffening ribs are installed in the connection zone. 14. The method according to p. 13, characterized in that the protective sheath for the segments intended for placement on the pipeline is made of a steel sheet whose edges in the connection zone with the segments intended for installation on the valve are cut and unbent to firmly fix said segments by means of self-tapping screws. 15. The method according to p. 14, characterized in that the notches for connecting the segments of the sections placed on the pipeline, with the segments of the sections placed on the valve, perform a depth of from 5 to 10 cm 16. The method according to p. 13, characterized in that the stiffener is made of a metal plate, for example, triangular in shape, while one edge of the plate is welded perpendicular to the surface of the segment of the section intended for placement on the pipeline, and the second to the surface of the segment of the section, intended for placement on a valve. 17. The method according to p. 13, characterized in that the stiffeners are installed at a distance from each other of at least 20 cm 18. The method according to p. 13, characterized in that the outer protective shell is made of galvanized iron sheet with a thickness of 0.8-1 mm 19. The method according to p. 13, characterized in that as a sealing shock-absorbing gaskets use foam rubber gaskets of the brands K-Flex, Armaflex. 20. The method according to p. 13, characterized in that as an adhesive on a bitumen basis for fixing blocks of foamed glass on the inner surface of the protective shell and between themselves using bitumen brand TekhnoNikol. 21. The method according to p. 13, characterized in that to protect the blocks of foamed glass from abrasion, use a composition comprising cement on a non-combustible base with a reinforcing fiberglass mesh. 22. The method according to p. 13, characterized in that the blocks of foamed glass perform a thickness of at least 100 mm

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