RU2266185C1 - Method for manufacturing intermediate heat exchange units and(or) upper heat exchange unit of heat exchange apparatus and method for manufacturing lower heat exchange unit of heat exchange apparatus - Google Patents

Abstract

FIELD: power machine engineering, possibly manufacture of heat exchange apparatuses, namely heat exchange units of modular or modular-sectioned heat exchange apparatuses of regenerative air heaters.

SUBSTANCE: method of manufacturing intermediate, upper and lower heat exchange units comprises steps of making in manufacturing stations blanks of shells of housings of manifolds, tubes, tube walls and members of unit carcass; bending tubes for forming multi-way bent in plane tubes; pressurizing bent tubes; assembling manifolds for supplying and discharging air and welding-in tube walls to them; mounting unit carcass and manifolds; packing tube bundle and again pressurizing tubes. Unit carcass and manifolds for supplying and discharging air are mounted in fixture at installing on plate fixture of portal frame with struts and upper beam, additional struts with detachable beams provided with coordinate members with supporting vertical surfaces and additional struts for fixing mounted struts of unit carcass. At manufacturing lower heat exchange unit, two-step plate of fixture is used. At mounting manifolds for supplying and discharging air, their ends are fixed along contours and three-dimensional position of housing of each manifold is fixed by means of coordinate and supporting discs secured from lower side of detachable lower beam of portal frame coaxially to central vertical axes of manifolds.

EFFECT: enhanced effectiveness of manufacturing process.

16 cl, 16 dwg

Description

The invention relates to power engineering and can be used in the manufacture of heat exchangers, in particular in the manufacture of heat transfer blocks of block or block-section heat exchangers such as regenerative air heaters.

A known method of manufacturing volumetric assemblies on a slipway, consisting of a central panel and side panels, using a mounting slide designed for installation in a predetermined relative position of the central panel and mounting sectors formed by connecting the side panels together, joint cutting holes for bolts and connecting the central panels with mounting sectors with the installation of connecting plates around the perimeter of the product (RU, patent No.20101010, 1994).

A slipway for assembling volumetric aggregates is known, comprising lower adjustable lodgements, a slipway plate with fixing pins and sliding technological rods with support 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).

There is also a known method of manufacturing and mounting a heat exchanger unit of an air heater with V-shaped tubes, comprising manufacturing a two-pack block of V-shaped tubes with air supply and exhaust manifolds and with a bypass chamber between two tube bundles, mounting on a tube sheet using tube expansion and welding, closing the heat exchanger block with the covering walls, while the two-pack block of V-tubes is made of separate two-pack heat transfer modules from V-tubes with bypass measures and with covering walls (RU №2176051, F 23 L 15/04, 2001).

The objective of the present invention is to increase the efficiency of manufacturing heat transfer units of block or block-section heat exchangers such as regenerative air heaters and individual technologically related devices included in it.

The problem in part of the first claimed object of the invention is solved due to the fact that the method of manufacturing the intermediate and / or upper block of a heat exchanger such as a block or block-section regenerative air heater provides for the element-wise execution of shell shells for supplying and removing heated air, pipes and pipe boards, block frame elements, pipe bending on pipe bending equipment to produce multi-way flat-bent with the last with significantly changing parameters of the branches and elbows connecting them, crimping bent pipes, assembling air supply and exhaust manifolds with welded tube boards, mounting the block frame and air supply and exhaust manifolds, packing the pipe bundle and re-crimping them together with the collectors in the unit, moreover, the installation of the frame of the block and the collectors 4 and 5 of the air inlet and outlet is carried out on the slipway by installing on the slipway plate having racks and a removable upper beam of the portal frame, additional racks with removable beam and having coordinate elements with support-lighthouse vertical, plane-aligned surfaces for fixing and monitoring the position of the tube sheets of the air supply and exhaust manifolds, additional racks for the technological fixation of the mounted frame racks of the block, while mounting the air supply and exhaust collectors the contour of their ends and the spatial position of the body of each collector using coordinate-supporting disks that are mounted on the bottom side of the removable upper beam gantry frame coaxial with the central vertical axes of the air supply and exhaust manifolds.

The gantry frame can be placed on the slipway plate in a vertical plane passing through the central vertical axes of the mounted air intake and exhaust manifolds of the unit, and the gantry frame racks and their supporting parts are placed outside the dimensions of the heat exchanger mounted unit.

To be able to fix and control the position of the tube sheets of the air supply and exhaust manifolds, removable beams can be installed on additional racks with the possibility of technological contact of the upper beam with the outer surface of the upper side section of the tube plate, and the lower of the beams with the external surface of the lower side section of the tube plate.

At least additional racks can install at least one intermediate removable beam for fixing and monitoring the position of the tube plates.

Intermediate removable beams are positioned along the height of the tube plates of the mounted unit, preferably equidistantly.

Coordinate elements with lighthouse-bearing surfaces, at least on part of the removable beams, can be spaced along the length of the removable beam, and at least four coordinate elements are installed on each beam with at least each pair of the outermost ones within the pipe boards of the mounted block.

Coordinate elements with support-lighthouse vertical surfaces aligned on a plane can be fixed on removable beams with the possibility of adjusting their position.

The problem in part of the second claimed object of the invention is solved due to the fact that the method of manufacturing the lower block of the heat exchanger type block or block-sectional regenerative air heater provides for the element-wise execution at the processing stations of the blanks of the shells of the bodies of the collectors for supplying and discharging heated air, pipes and tube boards, elements block frame, pipe bending on pipe bending equipment with multi-way flat-bent with sequentially changing with the parameters of the branches and their knees connecting, crimping the bent pipes, assembling the manifolds for supplying and discharging air with welding tube sheets in them, installing the frame of the block and manifolds for supplying and discharging air, packing the tube bundle and re-crimping them together with the collectors in the block, installation of the frame of the block and the inlet and exhaust air collectors is carried out on the slipway by installing on the two-level plate the slipway with racks and a removable upper beam of the portal frame, additional racks with removable beams having and coordinate elements with support-lighthouse vertical, plane-aligned surfaces for fixing and controlling the position of the tube sheets of the air supply and exhaust manifolds, additional racks for technological fixation of the mounted frame racks of the block, while installing the air supply and exhaust manifolds, they technologically fix their contour the ends and the spatial position of the body of each collector using the coordinate-supporting disks that are mounted on the bottom side of the removable upper beam portal the first frame coaxially with the central vertical axes of the air supply and exhaust manifolds.

The gantry frame can be placed on the slipway plate in a vertical plane passing through the central vertical axes of the mounted air intake and exhaust manifolds of the unit, and the gantry frame racks and their supporting parts are placed outside the dimensions of the heat exchanger mounted unit.

Block collectors can be mounted in the area of a higher section of the slipway plate, which is preferably rectangular in plan with an axial dimension along the longitudinal axis of the block not less than the corresponding axial projection size of each of the air supply and exhaust manifolds in the plan, and not less than the distance in the transverse direction between the outermost projection points most distant from each other in terms of both manifolds for supplying and discharging air of the unit.

A higher section of the slipway plate can be performed with the excess of the remaining part of the plate above the supporting surface corresponding to the height of the additional lower supports of the lower unit block, and the racks of the portal frame perform a height exceeding the total height of the lower block of the device and its additional lower supports by an amount corresponding to the height interval between the lower contour contact surface of the coordinate-supporting disk and the upper surface supporting the removable upper beam of the portal frame on the rack.

To be able to fix and control the position of the tube sheets of the air supply and exhaust manifolds, removable beams can be installed on additional racks with the possibility of technological contact of the upper beam with the outer surface of the upper side section of the tube plate, and the lower of the beams with the external surface of the lower side section of the tube plate.

At least additional racks can install at least one intermediate removable beam for fixing and monitoring the position of the tube plates.

Intermediate removable beams can be positioned along the height of the tube plates of the mounted unit preferably equidistantly.

Coordinate elements with supporting beacon surfaces can be installed at least on a part of the removable beams with spacing along the length of the removable beam, and at least four coordinate elements are installed on each beam with the location of at least each pair of the outermost ones within the tube plate of the assembly block.

Coordinate elements with support-lighthouse vertical surfaces aligned on a plane can be fixed on removable beams with the possibility of adjusting their position.

The technical result provided by the invention is to increase the efficiency of manufacturing heat exchangers of block or block section heat exchangers such as regenerative air heaters and individual technologically connected devices included in the composition due to the optimal arrangement of bent pipes in the block developed in the invention, the shape of the heat exchangers, and the specified ratio of the lengths of the sections of heat transfer pipes, differently oriented to the direction of movement of the coolant, printing high technological assembly, reducing labor costs in the manufacture, as well as good washability of the surface pipes with a coolant.

The invention is illustrated by drawings, which depict:

figure 1 shows a block-sectional regenerative air heater, side view;

figure 2 is the same, a top view;

figure 3 - heat transfer unit regenerative air heater, top view;

figure 4 - four-branch curved heat transfer pipe, top view;

figure 5 - heat transfer unit regenerative air heater in a perspective view;

figure 6 is a section of a regenerative air heater, the main view;

Fig.7 is the same side view;

on Fig - collector supply or exhaust air with a tube plate, the main view;

figure 9 is the same in plan;

figure 10 - node a in figure 9;

Fig. 11 is a slipway for mounting intermediate and / or upper heat exchanger unit of a heat exchanger, top view;

on Fig 12 is the same side view;

in Fig.13 is a view along BB in Fig.11;

on Fig - slipway for mounting the lower heat exchange unit of the heat exchanger, top view;

on Fig is the same side view;

Fig.16 is a view along BB in Fig.14.

A method of manufacturing an intermediate 1 and / or upper 2 heat exchanger block of a heat exchanger of the type of a block or block-section regenerative air heater, it provides for step-by-step execution at workpieces (not shown in the drawings) of shell blanks for casings 3 of supply manifold 4 and outlet 5 of heated air, pipes 6 and tube plates 7, frame elements of the block 1, 2, bending pipes 6 on pipe bending equipment (not shown in the drawings) to obtain multi-way flat-bent with successively changing the parameters of the branches 8 and their knees 9 connecting them, crimping the bent pipes 6, assembling the collectors 4 and 5 for supplying and discharging air with welding tube sheets 7 in them, installing the frame of the block 1, 2 and the collectors 4 and 5 for supplying and discharging air, packing the beam pipes 6 and their re-crimping together with the collectors 4 and 5 as part of block 1, 2, and the installation of the frame of block 1, 2 and the collectors 4 and 5 of the supply and exhaust air is carried out on the slipway 10 by installing on the plate 11 of the slipway 10 with a rack 12 and removable upper beam 13 of the portal frame 14, additional stoy 15 with removable beams 16 having coordinate elements 17 with support-lighthouse vertical, plane-aligned surfaces for fixing and monitoring the position of tube plates 7 collectors 4 and 5 of air supply and exhaust, additional racks 18 for technological fixation of mounted racks of the block frame 1, 2 at the same time, when installing the collectors 4 and 5 of the air supply and exhaust, technological fixation of the contour of their ends and the spatial position of the body 3 of each collector 4 and 5 of the air supply or exhaust using coordinate PORN disc 19 which is fixed to the lower side of the removable upper beam 13 of the portal frame 14 coaxially with the central vertical axis collectors 4 and 5, the inlet and exhaust air.

The portal frame 14 is placed on the plate 11 of the slipway 10 in a vertical plane passing through the central vertical axis of the mounted manifolds 4 and 5 of the air supply and exhaust unit 1, 2, and the racks 12 of the portal frame 14 and their supporting parts are placed outside the dimensions of the mounted unit 1, 2 heat exchanger.

To be able to fix and control the position of the tube plates 7 of the intake and exhaust manifolds 4 and 5, the removable beams 16 are installed on additional racks 15 with the possibility of technological contact of the upper of the beams 16 with the outer surface of the upper side section of the tube plate 7, and the lower 16 of the beams with the outer surface of the lower parietal portion of the tube plate 7.

At additional racks 15 install at least one intermediate removable beam 16 for fixing and monitoring the position of the tube plates 7.

Intermediate removable beams 16 are positioned along the height of the tube plates 7 of the mounted unit, preferably equidistantly.

Coordinate elements 17 with supporting beacon surfaces, at least on a part of the removable beams 16, are installed with spacing along the length of the removable beam 16, and on each beam 16, at least four coordinate elements 17 are installed with at least each pair of extreme them within the tube plate 7 of the mounted unit 1, 2.

Coordinate elements 17 with support-lighthouse vertical surfaces aligned on a plane are fixed on removable beams 16 with the possibility of adjusting their position.

A method of manufacturing the lower heat exchanger block 20 of a heat exchanger of the type of a block or block-section regenerative air heater provides for step-by-step execution at workpieces (not shown in the drawings) of shell blanks for housings 3 of collectors 4 and 5 for supplying and discharging heated air, pipes 6 and tube plates 7, elements frame of unit 20, bending of pipes 6 on pipe bending equipment (not shown in the drawings) to obtain multi-way flat-bent with sequentially changing parameters of vei 8 and connecting their elbows 9, crimping the bent pipes 6, assembling the collectors 4 and 5 for supplying and discharging air with welding tube sheets 7 in them, mounting the frame of the block 20 and collectors 4 and 5 for supplying and discharging air, stuffing the bundle of pipes 6 and their re-crimping together with the collectors 4 and 5 as part of the block 20, and the installation of the frame of the block 20 and the collectors 4 and 5 of the supply and exhaust air is carried out on the slipway 21 by installing on the two-level plate 22 of the slipway 21 having a rack 12 and a removable upper beam 13 of the portal frame 14 additional racks 15 with removable and beams 16 having coordinate elements 23 with vertical beacon support, plane-aligned surfaces for fixing and controlling the position of the tube plates 7 of the intake and exhaust manifolds 4 and 5, additional struts 18 for technological fixation of the mounted frame racks of the block 20, while the installation of manifolds 4 and 5 of the air supply and exhaust make technological fixation of the contour of their ends and the spatial position of the housing 3 of each collector 4 and 5 using the coordinate-supporting disks 19, which are mounted from the bottom the sides of the removable upper beam 13 of the portal frame 14 coaxially with the central vertical axes of the collectors 4 and 5 of the supply and exhaust air.

The portal frame 14 is placed on the plate 22 of the slipway 21 in a vertical plane passing through the central vertical axis of the mounted manifolds 4 and 5 of the air supply and exhaust unit 20, and the racks 12 of the portal frame 14 and their supporting parts are placed outside the dimensions of the mounted unit 20 of the heat exchanger.

The collectors 4 and 5 of the supply and exhaust air of the block 20 are mounted in the area of the location of the higher section 23 of the plate 22 of the slipway 21, which is preferably rectangular in plan with an axial dimension along the longitudinal axis of the block 20 not less than the corresponding axial projection size of each of the collectors 4 and 5 air supply and exhaust in plan, and in the transverse direction, not less than the distance between the outermost outermost projection points in the plan of both collectors 4 and 5 of the air supply and exhaust unit 20.

The higher section 23 of the plate 22 of the slipway 21 is performed with the excess of the remaining part of the plate 22 above the supporting surface corresponding to the height of the additional lower supports 24 of the lower unit 20 of the apparatus, and the racks of the portal frame 14 are made higher than the total height of the lower block 20 of the apparatus and its additional lower supports 24 by an amount corresponding to the height interval between the lower contour contact surface of the coordinate-supporting disk 19 and the upper surface of the support of the removable upper beam 13 of the portal frame 14 on the rack 12.

To be able to fix and control the position of the tube plates 7 of the intake and exhaust manifolds 4 and 5, the removable beams 16 are installed on additional racks 15 with the possibility of technological contact of the upper of the beams 16 with the outer surface of the upper side section of the tube plate 7, and the lower of the beams 16 with the outer surface of the lower parietal portion of the tube plate 7.

At additional racks 15 install at least one intermediate removable beam 16 for fixing and monitoring the position of the tube plates 7.

Intermediate removable beams 16 are positioned along the height of the tube plates 7 of the mounted block 20, preferably equidistantly.

Coordinate elements 17 with supporting beacon surfaces are installed at least on a part of the removable beams with spacing along the length of the removable beam 16, with at least four coordinate elements 17 being installed on each beam 16 with the location of at least each pair of extreme ones within tube plate 7 mounted block 20.

Coordinate elements 17 with support-lighthouse vertical surfaces aligned on a plane are fixed on removable beams 16 with the possibility of adjusting their position.

Claims (16)

1. A method of manufacturing an intermediate and / or upper block of a heat exchanger of the type of a block or block-section regenerative air heater, characterized in that it provides for the element-wise execution of shell shells for supplying and discharging heated air, pipes and tube boards, block frame elements at technological posts of blank shells. , bending pipes on pipe bending equipment to obtain multi-way plane-bent with successively changing parameters of the branches and connecting them to yen, crimping bent pipes, assembling manifolds for supplying and discharging air with welded tube boards in them, installing the frame of the block and collectors for supplying and discharging air, packing the tube bundle and re-crimping it together with the collectors in the block, and mounting the frame of the block and collectors for supplying and air exhaust is produced on the slipway by installing on the slipway plate having racks and a removable upper beam of the portal frame, additional racks with removable beams having coordinate elements with support-lighthouse vertical, surface-aligned surfaces for fixing and monitoring the position of the tube sheets of the air supply and exhaust manifolds, additional racks for technological fixation of the mounted frame racks of the unit, while installing the air supply and exhaust manifolds, technological fixation of the ends of the ends and the spatial position of each collector body is carried out using coordinate support discs, which are mounted on the lower side of the removable upper beam of the portal frame coaxially with the central vertical axes of the collectors supply and exhaust air. 2. The method according to claim 1, characterized in that the portal frame is placed on the slipway plate in a vertical plane passing through the central vertical axis of the mounted manifold supply and exhaust manifolds, and the portal frame racks and their supporting parts are placed outside the dimensions of the mounted heat exchanger unit . 3. The method according to claim 1, characterized in that for the possibility of fixing and monitoring the position of the tube sheets of the intake and exhaust manifolds, the removable beams are mounted on additional racks with the possibility of technological contact of the upper of the beams with the outer surface of the upper side section of the tube plate, and the lower of beams - with the outer surface of the lower frontal section of the tube plate. 4. The method according to claim 3, characterized in that at least one additional intermediate beam is installed on additional racks for fixing and monitoring the position of the tube plates. 5. The method according to claim 4, characterized in that the intermediate removable beams are preferably equidistantly arranged along the height of the tube plates of the mounted block. 6. The method according to claim 1, characterized in that the coordinate elements with supporting-lighthouse surfaces are installed at least on a part of the removable beams with spacing along the length of the removable beam, and at least four coordinate elements with at least each position are installed on each beam pairs of extreme ones within the tube plate of the mounted block. 7. The method according to claim 1, characterized in that the coordinate elements with support-lighthouse vertical surfaces aligned on a plane are fixed on removable beams with the possibility of adjusting their position. 8. A method of manufacturing a lower block of a heat exchanger of the type of a block or block-sectional regenerative air heater, characterized in that it provides for step-by-step execution of shell shells for supplying and discharging heated air, pipes and tube plates, block frame elements, at pipe billets, pipe bending pipe-bending equipment to obtain multi-way plane-bent with successively changing parameters of the branches and their knees connecting them, crimping pipes, assembling the manifolds for supplying and discharging air with welding tube sheets in them, mounting the frame of the block and collectors for supplying and discharging air, packing the tube bundle and re-crimping it together with the manifolds in the block, and mounting the frame of the block and collectors for supplying and discharging air produced on a slipway by installing on a two-level slab slipway with racks and a removable upper beam of the portal frame, additional racks with removable beams having coordinate elements with support-lighthouse vertical, adjusted surfaces on a plane to fix and control the position of the tube sheets of the air supply and exhaust manifolds, additional racks for technological fixation of the mounted frame racks of the unit, while installing the air supply and exhaust manifolds, technological fixation of the ends of the ends and the spatial position of the body of each collector is carried out using coordinate support discs, which are mounted on the lower side of the removable upper beam of the portal frame coaxially with the central vertical axes of the collectors and air vent. 9. The method according to claim 8, characterized in that the portal frame is placed on the slipway plate in a vertical plane passing through the central vertical axis of the mounted manifold supply and exhaust manifolds, and the portal frame racks and their supporting parts are placed outside the dimensions of the mounted heat exchanger unit . 10. The method according to claim 8, characterized in that the collectors of the block are mounted in the area of the location of the higher section of the slipway plate, which is preferably rectangular in plan with an axial dimension along the longitudinal axis of the block not less than the corresponding axial projection size of each of the inlet and outlet collectors air in the plan, and in the transverse direction - not less than the distance between the outermost outermost projection points from each other in the plan of both manifolds for supplying and discharging air of the unit. 11. The method according to claim 8, characterized in that a higher section of the slipway plate is performed with the excess of the remaining part of the plate above the supporting surface corresponding to the height of the additional lower supports of the lower unit, and the gantry frame racks are higher than the total height of the lower unit and its additional lower supports by an amount corresponding to the height interval between the lower contour contact surface of the coordinate-supporting disk and the upper surface of the support of the removable upper beam portal frame on the rack. 12. The method according to claim 8, characterized in that for the possibility of fixing and controlling the position of the tube sheets of the intake and exhaust manifolds, the removable beams are mounted on additional racks with the possibility of technological contact of the upper of the beams with the outer surface of the upper side section of the tube plate, and the lower of beams - with the outer surface of the lower frontal section of the tube plate. 13. The method according to p. 12, characterized in that at least additional racks install at least one intermediate removable beam for fixing and monitoring the position of the tube plates. 14. The method according to item 13, wherein the intermediate removable beams are preferably equidistant on the height of the tube plates of the mounted block. 15. The method according to claim 8, characterized in that the coordinate elements with supporting and lighthouse surfaces are installed at least on a part of the removable beams with spacing along the length of the removable beam, and at least four coordinate elements with at least each position are installed on each beam pairs of extreme ones within the tube plate of the mounted block. 16. The method according to claim 8, characterized in that the coordinate elements with support-lighthouse vertical surfaces aligned on a plane are fixed on removable beams with the possibility of adjusting their position.

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