RU68645U1 - COMBINED HEAT-INSULATING STRUCTURE - Google Patents

Abstract

The prefabricated structure is designed for thermal insulation of pipelines of various shapes and equipment and can be used in various industries: in petrochemistry, radiochemistry, nuclear facilities, etc. The design contains a frame, the ends of which are made in the form of flat rings of detachable - interconnected frames with a crossbar in the middle to accommodate rods connecting the flat rings with the possibility of oncoming movement. The frame fastening elements on the insulated surface in the form of L-shaped two-arm levers are pivotally mounted with the possibility of a predetermined movement at one of its ends. Floating stops in the form of spring-loaded roller eccentrics are likewise pivotally mounted on the opposite end of the frame. Each heat-insulating block is placed on the periphery on each frame between the flat rings of the frame and fixed to each other and with frames by latches of a locking type. Rotary L-shaped frame fastening elements on the insulated surface and spring-loaded eccentric rollers resting on it, in addition to their main functions, perform the functions of compensators of thermocyclic loads on the frame and ensure its stable position in space relative to the pipeline of any shape or equipment, which gives high quality insulation . The design of the frame in the form of a "squirrel wheel" in combination with detachable frames and latches of a locking type in comparison with the prototype, provides high mobility, especially in crowded conditions of limited volume, and reliability with a significant simplification of its manufacture and operation.

1 n.a. and 2 s.p. f-ly, 9 ill.

Description

The utility model relates to thermal insulation of pipelines of various shapes and equipment and can be used in various industries: petrochemicals, mechanical engineering, radiochemistry, nuclear facilities, etc.

Known prefabricated thermal insulation design made in the form of sections interconnected by locks, forming a casing in the form of a polyhedron, with thermal insulation fixed on it (see a / c of the USSR No. 731168, class F16L 53/00, publ. 1978)

This design cannot provide a uniform gap between the insulation and the pipeline, which violates the uniformity of the thermal field throughout the structure. To monitor and diagnose the pipeline, the entire structure must be removed. It is difficult to decontaminate at nuclear facilities, which is necessary for its repeated use.

Known prefabricated heat-insulating structure made in the form of interconnected detachable sections covering a pipe, forming a casing in the form of a polyhedron, the sections consist of inner and outer shells with insulation, and seals are installed in the planes of the connector sections, while the outer and inner shells at the ends are connected between by jumpers made in the form of an open profile and having contact with protective shields installed at the ends of the sections, and stops are installed on the inner shell, The protective shields are perforated or in the form of a mesh, drainage holes are located on the inner and outer shells located in the zone of the jumpers, rigid stops are additionally installed on the section plane of the sections, the height of which is less than the thickness of the seals, and through holes for the flexible fastening elements are made in the hard stops seals made of

hygroscopic material, while the sections are mounted with an offset relative to each other along the length of the pipe, the number of casing faces is a multiple of two, and the stops are adjustable (see US Pat. RF No. 2229654, class F16L 59/10, publ. 2004)

The design described above, compared with the previous one, provides a more uniform thermal field in the volume of the entire structure due to the combination of design features described above. A uniform adjustable gap between the pipeline and thermal insulation allows you to install it on pipelines of various diameters, install various equipment for monitoring the state of the medium under insulation and the state of the welds. This design is easy to assemble and disassemble, which reduces the time spent by staff in the active (contaminated) area. The sections in the form of boxes during the scheduled preventive repairs are easy to replace, and the versatility of the design allows you to install both rigid and soft thermal insulation. The design is easily deactivated.

However, this design cannot completely exclude deformation from thermal effects on it, since rigid stops contacting the pipeline form thermal bridges. This leads to deformation of the structure, which may be larger than the normative.

Thermal insulation is also known, which is a set of frame elements installed on tie braces along the insulated surface and repeating its profile block elements, each of which contains a protective metal shell, a heat-insulating layer and means for securing it, and the protective shell is made in the form of a box with a lid, the box ribs are made with a bevel around the perimeter and equipped with curly brackets, with elongated support shelves, with the help of which the brackets are installed on the bevel of the ribs and fasten extend along the bevel with a given step and the departure of the shelves

washers with the required frequency are installed, flanged in the inner diameter of the washers, on which support pins are fixed, against which flanged holes are made on the lid, threaded sockets are located on the tie rods of the frame, which interact when assembling the insulation with means for securing the block elements, and the joints formed by the bevels of the edges of the protective shells each pair of adjacent block elements, a heat-insulating cord is installed, held in a pressed state at the joint due to the elastic forces of the shelves of curly braces, along uru, decorative zigzagged plates along the axis of the plate are installed under the curly braces, and curly braces with elongated support flanges are made with a bent upper shelf, the distances from the extreme curly brackets to the corners of the box on the vertical and horizontal bevels of its ribs are selected from a certain ratio, the protective metal shell box is prefabricated and when insulating surfaces of large and medium radius of curvature in the cross section, it has the shape of a trapezoid, and supporting bandages at the junction of adjacent block elements along the generatrix of the curved surface they contain additional mounting plates with threaded sockets, and the threaded sockets on the frame are made floating with the possibility of a predetermined movement in horizontal and vertical planes in the housing, while the insulation is equipped with a closing compensation block element (see RF patent No. 2259510 CL F16L 59/10, publ. 2004)

The described design in comparison with the previous one provides thermal insulation of pipelines and equipment with specified temperature conditions on the outer wall. It has a good appearance and reliability during operation. The complete assembly design of thermal insulation guarantees resistance to vibrodynamic influences, high seismic resistance, which is especially important for the equipment of nuclear power plants, installation and dismantling of it takes less time when

repeated use, which is very important for the performance of work in radiation conditions.

However, this design has its drawbacks. First of all, the design remains complex, since it includes a large number of mating parts, which require a lot of time to assemble and disassemble. The presence of floating nuts simplifies their connection with the pins, but after tightening the nuts work as a unit with the structure and can not float with vibration and alternating loads. Welding during installation will lead to deformation of the structure, and welding in the pressurized space where repairs are carried out is prohibited. Welded sockets require a mandatory brace for mounting the structure on the equipment.

Curly braces for fixing the cord through two three bends break. Through the existing pins and tubular ligaments, with the help of which the structure is in contact with the insulated surface, thermal bridges are formed through which heat goes outside and in the pressurized room, in addition to radiation, a high temperature will be maintained.

Thus, the task of creating a quick-detachable thermal insulation of reusable use, which could create more comfortable conditions for personnel to carry out monitoring, diagnostics and repair work, especially in a hermetic volume, remains relevant to this day.

By its essence and technical result, the invention closest to the claimed technical solution is the invention described in patent No. 2259510, class F16L 59/10, publ. 2005, which is selected for the prototype.

The essence of the invention lies in the fact that the proposed self-compensating design, which significantly reduces the deformation of the frame, as the elements of its fastening on the insulated surface and stops in it are made self-regulating, that is, the design is practically freed from

alternating vibrations and additional thermal cyclic loads, since there are practically no thermal bridges and an atmosphere of a uniform thermal field is created. In addition, the proposed design is significantly simplified, more reliable and has an extended service life, it is easy to assemble and disassemble, since the frame in the form of a “squirrel wheel” with latches of locking type between the heat-insulating blocks, as well as the frame included in the structure, provide this.

The above technical result is achieved due to the fact that in a prefabricated heat-insulating structure containing a frame with its fastening elements on an insulated surface, floating stops, as well as a repeating profile of this surface, a set of heat-insulating blocks with fastening elements between them and with the frame, the ends of the frame are made in the form of flat rings interconnected by rods with the possibility of oncoming movement, each ring consists of detachably interconnected frames with a crossbar in the middle, in a cat A swath is made of a guide to accommodate the traction, while the frame fastening elements on the insulated surface are made in the form of L-shaped two-arm levers and with the possibility of a predetermined movement are fixed on the axes between the frames of the flat ring, the floating stops are made in the form of roller eccentrics spring-loaded relative to the insulated surface, similarly fixed between the frames of the opposite flat ring, and the heat-insulating blocks are located on the periphery of each frame of the frame between the flat rings and fixed between themselves and with the frames of these rings, latches of a locking type, while the frames of the flat rings and the crossbar are made of shaped metal and a metal mesh is fixed in each frame.

The implementation of the frame in the form of flat rings interconnected by rods with the possibility of oncoming movement significantly simplifies the design of the frame and makes it easier and more reliable, and the implementation of the rings from detachably connected between

a frame with a crossbeam in the middle with a guide to accommodate the thrust allows this design to be easily and quickly mounted and dismantled in confined hermetic conditions, that is, it makes the structure more mobile, which is very important when performing work by personnel in conditions of crowding, elevated temperature and radiation, in addition, adjustable rods allow you to adjust the gap between the heat-insulating blocks and the frame, which provides the required compression ratio of the gaskets that are laid in these gaps.

The implementation of the fastening elements of the frame on the insulated surface in the form of L-shaped two-arm levers that are fixed with the possibility of a predetermined movement on the axes between the frames of the flat ring allows you to use them not only as fasteners on the insulated surface of the frame with heat-insulating blocks, but also as compensators for additional thermal cyclic loads, since the almost point contact between the L-shaped levers of the fastening elements and the insulated surface significantly reduces thermal mos tics, and therefore heat transfer, creating a uniform thermal field, and hence the absence of structural deformation.

The implementation of floating stops in the form of roller eccentrics spring-loaded relative to the insulated surface makes it possible to use them not only as stops increasing the reliability of the heat-insulating structure, but also as compensators for additional thermal cyclic loads, providing almost point contact with the insulated surface and significantly reducing thermal bridges, which helps to create uniform thermal field. Thus, the original implementation of the fastening elements and floating stops in contact with the insulated surface, provides a stable position of the insulating structure relative to the insulated surface in space.

Placing heat-insulating blocks on the periphery of the frame and fixing them between themselves and with the frame - flat ring frames with locking latches allows you to quickly and easily remove any heat-insulating block, for example, to replace a heat-electric heating element (PETN) in a pressurized chamber or to carry out diagnostics and repair work.

The implementation of the framework of flat rings of profile metal allows you to fix the position of each heat-insulating block in the frame, especially when placing the structure in an upright position.

The fastening in each frame of the metal mesh helps to reduce heat transfer to the pressurized room, and also serves as a place for placement of heat-insulating blocks.

The signs given in the claims are necessary and sufficient to achieve the specified technical result, that is, they are essential.

The proposed solution is not known from available sources of information, does not explicitly follow from the prior art.

The essence of the claimed technical solution is illustrated by graphic images.

Figure 1 shows a sectional view of the proposed prefabricated insulating structure mounted on an insulated surface of the equipment.

Figure 2 shows a top view And the proposed prefabricated heat-insulating structure, mounted on an insulated surface of the equipment.

Figure 3 shows the design of the frame made of shaped metal with a crossbeam in the middle and a metal mesh in which a guide is made to accommodate the traction.

Figure 4 shows the layout of rods in the upper flat ring of the frame of the proposed prefabricated heat-insulating structure.

Figure 5 shows a section B-B of figure 1 of the frame of a prefabricated heat-insulating structure fixed to the insulated surface of the equipment.

Figure 6 shows the L-shaped element for mounting the frame on the insulated surface of the equipment.

7 shows a floating emphasis in the insulated surface of the equipment in the form of a roller eccentric.

Fig. 8 shows a layout of heat-insulating blocks relative to the heating elements and latches of the locking type, which hold these blocks together and with the frame.

Figure 9 shows the contact diagram of the fastening elements, floating stops with the insulated surface of the product, as well as latches of the locking type in the form of shaped latches of heat-insulating blocks with a frame structure.

The prefabricated heat-insulating structure contains a frame 1, the ends of which are made in the form of flat rings 2, 3 (see Fig. 1), each of which consists of a frame 4 detachable with bolts between each other at the upper end and 5 (see Fig. 2 , 3) in the lower end, respectively, with the crossbars 6, 7 in each frame in the middle. Each of the frames 4, 5 and the crossbars 6, 7 are made of shaped metal and a metal mesh is fixed in each frame 4, 5 (see figure 2, figure 3). In each crossbar 6, each frame 4, 5, a hole 8 is made (see Fig. 3), through which a rod 9 (see Figs. 1, 4, 5) is passed through the flat ring 2 of the upper end, which is opposite with the handle 10 the end with a thread 11 is rotary sealed in a nut 12 with a mating thread, which is fixed in each crossbar 7 of the frame 5 of the flat ring 3 of the lower end of the frame 1 (see Figs. 1, 5). To the sides of the frames 4, 5 that are joined together, respectively, cheeks 13, 14 are fixed with holes in which the axis 15 is fixed from the side of the upper end 2 of the frame 1 and the axis 16 from the side of the lower end 3 (see Figs. 6, 7).

On the axes 15 of the upper end there are L-shaped two-arm levers 17 (see Fig. 6) (fastening elements of the frame 1 on the equipment 18), the oval holes 19 in the corner of which provide them with a given movement. On the axes 16 of the lower end 3 of the frame 1 (see Fig. 7), floating stops are arranged in the form of roller eccentrics 21 spring-loaded with flat springs 20 relative to the insulated surface of the equipment 18, which rotate around axis 16.

On the periphery of the flat ring 3 of the lower end, heat-insulating blocks 22 are installed on each frame 7, which are respectively attached to the flat rings 2, 3 using latches 23 and 24 of the locking type, and are interconnected using the latch 25 of the locking type (see Fig. 8 )

The prefabricated heat-insulating structure works as follows: first, all the L-shaped two-arm levers 17 are assembled onto a cable (not shown in Fig.), Passing it through the oval holes 19 made in each arm 17 — the fastening element. The free ends of the cable are interconnected. The assembly of the frame 1, begin with the assembly of the upper flat ring 2. To do this, all frames 4 with bolts (not shown in Fig.) Are assembled in pairs by the cheek 13 of one frame 4 to the cheek 13 of another frame 4, forming a gap between them (in Fig. Not shown), into which the L-shaped two-arm lever 17 is inserted and the axis 15 is passed through the hole 19 in it and the holes in the cheeks 13 (not shown in Fig.), fixing it so that the lever 17 can freely rotate around the latter.

Next, each pair of frames 4 with a lever 17 is put on the upper end of the equipment 18 and the pairs are already connected to each other, fixing the levers 17 in the same way. A flat ring 2 is formed, which is held on the upper end of the equipment 18 using fasteners in the form of G -shaped levers 17, with the possibility of a predetermined movement around the axis 15. Then, similarly, on the same stand, the lower flat ring 3 is assembled, for which the frames 5 are connected with each other using bolts

cheeks 14, between which on the axles 16 the roller eccentrics 21 with springs 20 are pivotally mounted on their working surfaces. After the assembly of the lower flat ring 3, each rod 9 is passed through each hole 8 made in each crossbar 6 of the frame 4 and, by turning it with the handle 10, the position of the rod 9 is fixed, passing through the thread 11 in the nut 12 fixed in each crossbar 7 of each frame 5.

Next, determine the desired position of the lower 3 and upper 2 flat rings relative to each other and using the handles 10 the lower flat ring 3 is pulled to the upper flat ring 2 by the required distance. Thus, the frame 1 in the form of a "squirrel wheel" is assembled and worn on equipment 18 with thermoelectric heating elements - heaters 26. Then, along the perimeter of the lower flat ring 3, a heat-insulating block is installed on each metal 5 (see Fig. 2, 3) 22 and a latch of a locking type 23 and 24 fasten it to the upper and lower flat rings 2, 3, respectively, and between them with latches 25.

Thus, the heat-insulating structure is assembled and put on the equipment 18. During the operation of the equipment, its surfaces are heated to 350 ° C, as a result of which the frame 1 starts moving along the vertical and the radius, while the two-arm L-shaped levers 17 (fastening elements) remain in one and in the same position, because thanks to the oval holes 19 in the corner of the L-shaped levers 17 they make a predetermined movement around the axes 16, while maintaining the stability of the position of the frame 1, and therefore the heat-insulating blocks 22 include flax insulated surface, and contribute to the same floating stops a rotary roller cams 21 of the flat bottom end 3 of the ring, as due to the spring 20, they are in constant contact with the insulated surface. The spring 20 under the influence of temperature changes then straightens, then bends and rotates the roller eccentrics 21 with a smaller or a larger radius to the insulated surface and thus stabilizes the position of the frame in space.

Currently, a prototype of the proposed design has been manufactured and tested. Tests of the product at nuclear power plants showed that the use of this utility model provides a uniform thermal field in the volume of the entire structure, since there are practically no thermal bridges between the product and the frame, which is achieved by a combination of design features, in particular, almost point contacts between the fastening elements in the form of rotary G -shaped levers with oval openings and flat springs of roller eccentrics (floating stops), which provide the squirrel-wheel frame with a given movement relative to the insulated surface, thus creating a stable position of the insulating blocks relative to this surface.

Thus, in comparison with the prototype, a self-compensating prefabricated heat-insulating structure with a significantly increased service life is created. The design lends itself well to decontamination. It is mobile, easy to assemble and dismantle.

Since its ends are assembled from a set of frames, the proposed design, depending on the crowding of the room, can be sectionally assembled outside this room, and then finally assembled in it. If there are no conditions for crowding, then its flat rings can be made of rings or half rings of shaped metal with transverse rails under the rods placed at a given distance from each other around the circumference.

The proposed design itself compensates for temperature shifts of the frame and, as a result, occupies a stable position in space relative to the insulated surface, since it practically does not deform. This leads to the fact that, if necessary, it is easy to mount and dismantle any of their heat-insulating blocks from the "squirrel wheel", which is very important when performing work in radiation conditions. In addition, this design in comparison with the prototype significantly

reduces the temperature in the pressurized volume, which creates more comfortable conditions for staff.

The proposed design is not difficult to manufacture and expensive parts, it is much lighter than the design described in the prototype, and more reliable.

Thus, the proposed design provides high quality work, creates comfortable conditions for staff. Compared with the prototype significantly reduced the cost of its manufacture.

The applicant is not aware of a similar design, which when used provides the above technical result.

From the foregoing, it follows that the claimed utility model is aimed at solving the problem and at the same time meets the eligibility requirements under current law.

Claims (3)

1. A prefabricated heat-insulating structure containing a frame with its fastening elements on an insulated surface, floating stops, as well as a repeating profile of this surface, a set of heat-insulating blocks with fastening elements between them and with a frame, characterized in that the ends of the frame are made in the form of flat rings, interconnected by rods with the possibility of oncoming movement, each ring consists of detachably interconnected frames with a crossbar in the middle, in which a guide is made to accommodate t gi, while the fastening elements of the frame on the insulated surface are made in the form of L-shaped two-arm levers and with the possibility of predetermined movement are fixed on the axes between the frames of the flat ring, floating stops are made in the form of roller eccentrics spring-loaded relative to the insulated surface, similarly fixed between the frames of the opposite flat ring and heat-insulating blocks are located on the periphery of each frame of the frame between the flat rings and are fixed to each other and with the frames of these rings with latches apornogo type. 2. The prefabricated heat-insulating structure according to claim 1, characterized in that the frames of the flat rings and the crossbeams are made of profile metal. 3. The prefabricated heat-insulating structure according to claim 1, characterized in that a metal mesh is fixed in each frame.