RU38907U1 - STAPEL FOR ASSEMBLY OF HEAT EXCHANGE BLOCK OF HEAT EXCHANGE TYPE REGENERATIVE AIR HEATER - Google Patents

Abstract

The utility model relates to power engineering and can be used in the manufacture of heat exchangers, in particular, in the manufacture of regenerative air heaters. The slipway for assembling the support heat exchanger block of a heat exchanger of the regenerative air heater type comprises a plate mounted on the frame for assembling and mounting at least a frame having additional lower block supports with a combined displacer of the annular heat transfer medium and having air supply and exhaust manifolds installed in cylindrical casings mounted on the plate forming a portal frame a pair of racks with a removable upper portal beam, an additional pair of racks with removable beams mounted on them within the limits of the height of the tube plates to fix and control the position of the tube plates of the unit intake and exhaust manifolds, and additional racks installed in pairs along the length of the slipway for technological fixation of the mounted frame racks of the block, while the portal beam has lengths installed two pairs of support devices, the last of which are located coaxially to the axes of the struts of the portal frame, and the supporting devices of the middle pair located between them are mounted coaxially with the central tikalnym axes of the air supply and evacuation collectors, said plate pile formed with a two-tier arrangement is preferably higher in terms of rectangular section in the zone of placement of portal frames which adopted the axial size of the conditions developed in this utility model. The technical result provided by the utility model is to optimize the manufacturing process of the heat exchange unit of the heat exchanger, to increase the accuracy of installation and assembly of the elements of the heat exchange unit while reducing the complexity of the work and reducing the metal structure.

Description

The utility model relates to a power system, in particular, to devices for the manufacture of collectors for air-cooled gas coolers.

A slipway for assembling volumetric aggregates is known, comprising lower adjustable lodgements, a slipway plate with locking pins and sliding technological rods with stop-racks and screw jacks, while before installing into the slipway, sliding rods are installed on the elements of the upper section of the volumetric assembly to be assembled, provided with oriented downwards stop racks on which screw jacks are installed, then docking plates are attached to the mating elements of the lower section of the assembled unit, the upper section in the slipway, ensuring the coincidence of the elements of the upper and lower sections and the contact of all the struts, stops with floor beams, fix the upper section on the slip plate, and the combination of the mounting base holes in the joined elements of the upper and lower sections is adjusted by the length of the sliding rods and moving by means of a jack support racks (RU, No. 2123965, B 64 F 5/00, 1998).

The analogue closest to the utility model is a slipway for assembling and assembling equipment for assembling assemblies (RU, No. 2079421, B 64 F 5/00, 1997), including a frame with reference platforms and racks, a rigid tool beam with rows of basic coordinate holes, rigid carriers aggregate sizes - mounting standards, while rigid media of dimensions are linked together, and tooling elements are mounted by means of a tool beam with basic coordinate holes that are specified from the construction axes of the assembled assemblies.

The disadvantage of these analogues, including the closest analogue, is the complexity and high complexity of installation and the inability to manufacture devices that are a vessel operating under pressure.

The objective of this utility model is to develop the construction of a slipway, which will optimize the manufacturing process of manufacturing a heat exchange unit of a heat exchange apparatus such as a regenerative air heater, increase the accuracy of installation and assembly of unit elements while reducing the complexity of the work performed.

The problem of the utility model is solved due to the fact that the slipway for assembling the support heat exchanger block of a heat exchanger of the regenerative air heater type contains a plate mounted on the frame for assembling and mounting at least a frame having additional lower block supports with a combined displacer of the annular heat exchange medium and installed in cylindrical bodies tube boards with air supply and exhaust manifolds mounted on the plate forming a portal frame a pair of racks with removable the upper portal beam, an additional pair of racks with tiers installed on them within the height of the tube plates with removable beams for fixing and monitoring the position of the tube plates of the unit intake and exhaust manifolds, and additional racks installed in pairs along the length of the slipway for technological fixation of the unit frame racks mounted, however, the portal beam has two pairs of supporting devices installed along its length, the extreme of which are located coaxially with the axes of the struts of the portal frame, and the supporting middle pair devices are installed coaxially with the central vertical axes of the air supply and exhaust manifolds, while the slipway plate is made two-level with an arrangement of a higher, preferably rectangular, section in the portal frame placement zone, the axial dimension of which along the longitudinal axis of the block is not less than the corresponding axial projection size of each from the air supply and exhaust manifolds in the plan, and in the transverse direction, not less than the distance between the outermost outermost distant from uga projection points in terms of both inlet and reservoir outlet air unit.

Each supporting device of the middle pair can be equipped with a coordinate-supporting disk attached to it from the bottom of the portal beam for technological fixation of the contour of the ends and the spatial position of the housing of the corresponding manifold of supply or exhaust air in the process

assembly and installation of the unit, and the excess of the supporting surface of the higher section above the supporting surface of the rest of the slipway plate corresponds to the height of the additional lower supports of the block, and the height of the racks of the portal frame is taken to exceed the total height of the block and its additional lower supports by an amount corresponding to the height interval between the lower contour the contact surface of the coordinate-supporting disk and the upper surface of the support of the portal beam on the rack.

The slipway can be made with removable beams installed in tiers on additional racks, equipped with coordinate elements that are adjustable and mounted on them with support-lighthouse vertical surfaces aligned on a plane.

The slipway can be made in such a way that the portal frame is located on the slipway plate in a vertical plane passing through the central vertical axes of the block air supply and exhaust manifolds, and the width of the slipway plate is taken from the condition that the struts of the portal frame and their supporting parts are outside the dimensions of the mounted block.

The building berth can be made so that the upper removable beam is mounted on additional racks with the possibility of technological contact with the outer surface of the upper side section of the tube plate.

The slipway can be made so that the lower removable beam is mounted on additional racks with the possibility of technological contact with the outer surface of the lower pritortsevoy section of the tube plate.

The slipway can be made so that the number of tiers of the removable beams is at least three, while the beam of the intermediate tier or the beams of the intermediate tiers are preferably equidistant along the height of the tube sheets.

The slipway can be made in such a way that coordinate elements with support-lighthouse surfaces are at least part of the tiers spaced along the length of the removable beam and are made of at least four, and they are distributed along the length of the beam with at least each pair of extreme of them within the tube plate.

The slipway can be made so that at least three coordinate elements

with supporting and lighthouse surfaces are located in the area adjacent to the displacer of the annular heat transfer medium.

The technical result provided by the utility model is to optimize the manufacturing process of manufacturing a heat exchange unit of a heat exchanger of the type of a regenerative air heater, to increase the accuracy of installation and assembly of the elements of the heat exchange unit while reducing the complexity of the work performed and reducing the metal consumption of the structure.

The essence of the utility model is illustrated by drawings, where:

figure 1 shows a top view of the slipway for the manufacture of a heat exchange unit of a heat exchange apparatus such as a regenerative air heater;

figure 2 is the same side view;

figure 3 is a section aa of figure 1.

The slipway for assembling the support heat exchanger block of a heat exchanger of the regenerative air heater type (not shown in the drawings) contains a plate 2 mounted on the frame 1 for assembling and mounting at least a frame having additional lower block supports with a combined displacer of the annular heat exchange medium (not shown in the drawings ) and having installed in cylindrical housings 3 tube boards 4 collectors for supply 5 and exhaust 6 installed on the plate 2 forming a portal frame 7 a pair of racks 8 with removable the upper portal girder 9, an additional pair of racks 10 with tiers installed on them within the height of the tube plates 4 removable beams 11 for fixing and monitoring the position of the tube plates 4 supply manifolds 5 and air exhaust unit 6, and additional racks 12 installed in pairs along the length of the slipway technological fixation of mounted racks of the block frame (not shown in the drawings). The portal beam 9 has two pairs of support devices 13 installed along its length, the extreme of which are located coaxially to the axes of the struts of the portal frame 7, and the supporting devices 13 between them of the middle pair are installed coaxially with the central vertical axes of the inlet 5 and air exhaust manifolds 6 and each of them equipped with a coordinate-supporting disk 14 attached to it from the bottom of the portal beam 9 for technological fixation of the contour of the ends 15 and spatial position

body 16 of the corresponding manifold supply 5 and exhaust 6 air in the process of Assembly and installation of the unit.

The slipway plate 2 is made two-level with an arrangement of a higher section 18, preferably rectangular in plan, in the portal frame placement zone, the axial dimension of which is taken along the longitudinal axis of the block at least the corresponding axial dimension of the projection of each of the supply manifolds 5 or air outlet 6 in the plan, and the transverse direction C is not less than the distance between the outermost outermost projection points in terms of both collectors for supply 5 and air outlet 6 of the unit, and the excess of the reference surface The height of this section D above the supporting surface of the rest of the slipway plate corresponds to the height of the additional lower block supports (not shown in the drawings). The height of the racks of the portal frame is taken to exceed the total height of the block (not shown in the drawings) and its additional lower supports (not shown in the drawings) by an amount corresponding to the height interval between the lower contour contact surface of the coordinate-supporting disk 14 and the upper abutment surface of the portal beam 9 on rack 8.

The removable beams 11 installed in tiers on the additional racks 10 are provided with coordinate elements (not shown in the drawings) that are adjustable and fixed on them with support-lighthouse vertical surfaces aligned on a plane.

The portal frame 7 is located on the plate 2 of the slipway in a vertical plane passing through the central vertical axis of the manifolds for supplying 5 and air exhaust 6 of the unit, and the width of the plate 2 of the slipway is adopted from the condition of the racks 8 of the portal frame 7 and their supporting parts outside the dimensions of the mounted block.

The upper removable beam 9 is installed on additional racks 8 with the possibility of technological contact with the outer surface of the upper pritortsevoy section of the tube plate 4.

The lower removable beam (not shown in the drawings) is mounted on additional racks with the possibility of technological contact with the outer surface of the lower side of the pipe section 4 of the tube.

The number of tiers of removable beams is at least three. Intermediate beam

tiers or beams of intermediate tiers are arranged along the height of the tube sheets preferably equidistantly.

Coordinate elements with lighthouse surfaces are at least part of the tiers spaced along the length of the removable beam 9 and are made of at least four, and they are distributed along the length of the beam with the location of at least each pair of the outermost ones within the tube plate 4. At least three coordinate elements with support-lighthouse surfaces are located in the area adjacent to the displacer of the annular heat transfer medium (not shown in the drawings).

Claims (9)

1. A slipway for assembling a supporting heat exchanger block of a heat exchanger of the type of a regenerative air heater, characterized in that it comprises a plate mounted on the frame for assembling and mounting at least a frame having additional lower block supports with a combined displacer of the annular heat exchange medium and having installed in cylindrical housings tube boards with air supply and exhaust manifolds mounted on the plate forming a portal frame, a pair of racks with a removable upper portal ball oh, an additional pair of racks with tiers installed on them within the height of the tube plates, removable beams for fixing and monitoring the position of the tube plates, air supply and exhaust manifolds of the unit, and additional racks installed in pairs along the length of the slipway for technological fixation of the mounted frame racks of the unit, with this portal beam has two pairs of supporting devices installed along its length, the extreme of which are located coaxially to the axes of the struts of the portal frame, and the supporting devices of the middle pair located between them installed coaxially with the central vertical axes of the air supply and exhaust manifolds, while the slipway plate is made two-level with an arrangement of a higher, preferably rectangular in plan, section in the portal frame placement zone, the axial dimension of which along the longitudinal axis of the block is taken to be no less than the corresponding axial projection size of each collectors for supplying and discharging air in the plan, and in the transverse direction, not less than the distance between the outermost, farthest projection points from each other in terms of both manifolds supply and exhaust air unit. 2. The slipway according to claim 1, characterized in that each supporting device of the middle pair is provided with a coordinate-supporting disk attached to it from the bottom of the portal beam for technological fixation of the end contour and spatial position of the housing of the corresponding air supply or exhaust manifold during assembly and installation block, moreover, the excess of the supporting surface of the higher section above the supporting surface of the rest of the slipway plate corresponds to the height of the additional lower block supports, and the height of the racks port the total frame is taken to exceed the total height of the block and its additional lower supports by an amount corresponding to the height interval between the lower contour contact surface of the coordinate-support disk and the upper surface of the support of the portal beam on the rack. 3. The slipway according to claim 1, characterized in that the removable beams installed in tiers on the additional racks are equipped with coordinate elements that are adjustable and fixed on them with support-lighthouse vertical surfaces aligned on a plane. 4. The slipway according to claim 1, characterized in that the portal frame is located on the slipway plate in a vertical plane passing through the central vertical axis of the block air supply and exhaust manifolds, and the width of the slipway plate is taken from the condition of placement of the struts of the portal frame and their supporting parts outside dimensions of the mounted unit. 5. The slipway according to claim 1, characterized in that the upper removable beam is mounted on additional racks with the possibility of technological contact with the outer surface of the upper pritortsevoy section of the tube plate. 6. The slipway according to claim 1, characterized in that the lower removable beam is mounted on additional racks with the possibility of technological contact with the outer surface of the lower pritortsevoy section of the tube plate. 7. The slipway according to claim 1, characterized in that the number of tiers of the removable beams is at least three, while the intermediate tier beam or intermediate tier beams are preferably equidistant along the height of the tube plates. 8. The slipway according to claim 3, characterized in that the coordinate elements with supporting-lighthouse surfaces are at least part of the tiers spaced along the length of the removable beam and are made of at least four, and they are distributed along the length of the beam with an arrangement of at least at least each pair of extreme ones within the tube plate. 9. The slipway according to claim 8, characterized in that at least three coordinate elements with supporting-lighthouse surfaces are located in the area adjacent to the displacer of the annular heat transfer medium.