RU2341749C1 - Heat exchanger - Google Patents

Abstract

FIELD: nuclear power engineering.

SUBSTANCE: heat exchanger consists of a central header with a distributing and collecting chambers arranged in a shell and a ring-shaped bank of tubular platens with upper and lower sections arranged in the shell as well and connected with radial tube ends to the appropriate header chambers made, in plan view, as bent to one side in the direction from header to shell and communicating between each other along the tube space by means of appropriate middle platen sections; at that in each platen the upper and lower sections are connected to each other at least with one vertical tube spacer in the platen, which is connected with one of its ends to support-and-ring horizontal beam, and with the other end - with horizontal ring of platen spacer ring in the bank. Each vertical tube spacer in the platen is connected with support-and-ring horizontal beam by means of a hinge, and the above horizontal ring consists of horizontal plates throughout its length, each of which is installed so that it mates the adjacent plate.

EFFECT: providing free thermal tube elongation in each platen and constant pitch between platens, and avoiding extreme tube bank vibrations and local platen tube wear.

4 cl, 8 dwg

Description

The invention relates to nuclear energy and can be used in the design of air heat exchangers for emergency cooling systems (CAPX) and passive heat removal systems (SPOT) of reactor plants, as well as in the design of pipe systems of separator superheaters of turbine plants of nuclear power plants.

A heat exchanger is known comprising a central collector located in the housing with distributing and collecting chambers and an annular bundle of tubular screens with upper and lower sections connected by radial ends of the pipes to the respective collector chambers, curved in one direction in the direction from the collector to the housing and communicated between along the pipe space by means of the corresponding middle sections of the screens, and in each screen the upper and lower sections are interconnected by at least one vert an external device for spacing pipes in the screen, and the outer pipes of the screens are connected to supporting annular horizontal beams (see Development of compact heat exchangers. / Ostretsov I.N. et al. // Power Engineering. No. 5. 1989. P. 31-34) .

Such a heat exchanger device is acceptable when using screens of relatively small lengths (up to 2 meters) and weight. When using long screens with large weight loads, the described mounting and spacing system is unable to absorb the beam weight and at the same time ensure vibrations in the beam within acceptable limits, so during operation there is severe wear of the pipes at their junctions with the spacing bars and supporting-ring beams, which reduces the life of the heat exchanger.

The closest technical solution known (prototype) to the present invention is a heat exchanger containing a central collector located in the housing with distributing and collecting chambers and an annular bundle of tubular screens with upper and lower sections connected by radial ends of the pipes to the corresponding collector chambers, curved in plan in one direction in the direction from the collector to the housing and communicated with each other through the pipe space by means of the corresponding middle sections of the screens, m in each screen, the upper and lower sections are interconnected by at least one vertical pipe spacing device in the screen, which is connected at one end to a supporting annular horizontal beam and the other to a horizontal ring spacing ring in the beam (see US patent No. 3376858. N. Cl. 122-32. 1968).

Such a heat exchanger provides vibrations of screens in the beam to within acceptable limits when using long screens, but provided that the temperatures of the coolants of the pipe and annular spaces, and hence the temperatures of the pipes and spacing bars, do not differ much from each other (up to 50 ° C).

However, when using such a technical solution as an air heat exchanger CAPX, the indicated temperature difference can reach 400 ° C, given that the temperature of the cooling air in winter can have negative values.

The large temperature difference between the pipes and the distance bars in the prototype is exacerbated by the rigid design of the distance spacing rings in the beam, the rigid connection of the distance bars to the support-ring beam, which, given the complicated configuration of the screens, leads to pinching of the pipes in the distance bars and the appearance of increased temperature compensation voltages in them that reduce the operational reliability of the heat exchanger.

Thus, the disadvantage of the heat exchanger adopted as a prototype is its low operational reliability due to the increased temperature compensation stresses in the pipes of the screens.

An object of the invention is to increase the operational reliability of the heat exchanger by lowering the temperature compensation stresses in the pipes of the screens.

The technical problem of the invention is solved in a heat exchanger containing a central collector located in the housing with distributing and collecting chambers and an annular bundle of tubular screens with upper and lower sections connected by radial ends of the pipes to the respective chambers of the manifold, curved in one direction in the direction from the collector to the housing and communicated with each other through the pipe space by means of the respective middle sections of the screens, and in each screen the upper and lower sections are connected between at least one vertical pipe spacing device in the screen, which at one end is connected to the supporting annular horizontal beam and the other to the horizontal screen spacing ring in the beam, with each vertical pipe spacing device in the screen connected to the supporting ring horizontal beam by means of a hinge, and the horizontal ring of distance of screens in the beam is made along the length of the composite of horizontal plates, each of which is installed adjacent to adjacent th plate.

In addition, in each screen, the middle section can be made with a horizontal pipe spacing device in the screen, which is connected on the housing side via an additional hinge with a bandage covering the beam of screens, and is fastened to the vertical pipe spacing device in the screen on the side of the central collector.

In addition, each vertical pipe spacing device in the screen by a portion located between the hinge and the screen bundle can be connected to an additional horizontal screen spacing ring in the beam.

In addition, each vertical pipe spacing device in the screen with a section located between the upper and lower sections of the screens can be connected to an additional horizontal ring for spacing the screens in the beam.

The connection of each vertical pipe spacing device in the screen with the supporting annular horizontal beam by means of a hinge and the execution of the horizontal ring spacing of the screens in the beam along the length with a composite of horizontal plates, each of which is installed adjacent to the adjacent plate, lead to the mentioned ring, continuing to perform the functions of spacing screens between themselves, it has become more malleable to the temperature movements of pipes in the screen. This significantly reduced the temperature compensation stresses in the screen tubes, which increased the operational reliability of the heat exchanger.

Additional ring spacers in the bundle and horizontal spacers for middle pipe sections in the screen, connected by additional hinges with bandages covering the bundle and fastened on the side of the central manifold to the vertical pipe spacer in the screen, reduce the temperature compensation stresses in the pipes even more screen, which further increases the operational reliability of the heat exchanger.

The invention is illustrated by drawings, where figure 1 shows a General view of the heat exchanger; figure 2 is a section aa of figure 1; figure 3 is a section bB of figure 2; figure 4 is a fragment of a horizontal ring spacing screens in the beam; figure 5 is a view of figure 4; figure 6 - node D of figure 4; Fig.7 is a cross-section EE of Fig.6; in Fig.8 is a section FJ of Fig.1.

The heat exchanger comprises a housing 1, in which a central manifold with a distribution chamber 2 and a collecting chamber 3 is placed, as well as an annular bundle of tubular screens with upper sections 4 and lower sections 5. The upper sections 4 of the bundle of tubular screens are connected by the radial ends of the pipes to the distributing chamber 2 of the collector, and the lower sections 5 of this bundle - with similar ends to its chamber 3. The distributing chamber 2 is connected to the pipeline 6 for supplying the coolant of the pipe space of the screens, and the collecting chamber 3 is connected to the pipeline 7 of the removal of this coolant.

Sections 4 and 5 of the screens are made in plan curved in one direction in the direction from the collector to the housing 1 (see figure 2) and communicated with each other through the tube space by means of the corresponding middle sections of 8 screens.

In each screen, sections 4 and 5 are interconnected by at least one pipe spacing device 9 in the screen. Devices 9 are installed in a bundle of screens in annular rows around the collector. In this example of a specific implementation of the invention, devices 9 are installed in three annular rows (see FIG. 2).

Each device 9 (see figure 3) in the area of the pipe sections 4 and 5 is made of two corrugated strips 10 and 11 located on both sides of the pipe screens and interconnected in the gaps between the pipes by means of fasteners 12.

Each device 9 in each annular row at one end is connected via a hinge 13 to the corresponding supporting annular horizontal beam 14, and the other to the corresponding horizontal ring 15 for spacing the screens in the beam.

The drawing shows that the device 9 with its upper ends by means of the upper hinges 13 are connected to the supporting-annular horizontal beams 14, which are located above the beam of screens. In this case, the rings 15 are located under a beam of screens. Thus, the suspended option of fixing the beam in the heat exchanger is realized.

However, in the general case, a support option for fixing the beam is also possible. In the support version, which is not shown in the drawing, the pipe spacing devices in the screen with their lower ends by means of lower hinges will be connected to supporting annular horizontal beams located under the beam of the screens. In this case, the distance rings of the screens will be located above the beam of screens.

In the suspended embodiment of the beam fastening, which is adopted as an example of a specific implementation of the present invention, a support shell 16 is mounted on the central manifold (see Fig. 1), and brackets 17 are mounted on the housing 1. In this case, the support-ring horizontal beams 14 are connected to the cross 18, which with the ends located on the side of the collector is fixedly fixed to the support shell 16, and the other ends located on the side of the housing 1 are connected to the brackets 17 with the possibility of movement relative to them.

Each ring 15 spacing screens in the beam (see figure 4 and 5) is made along the length of a composite of horizontal plates 19, each of which is installed adjacent to the adjacent plate 19, that is, the plate 19 is movably and sequentially connected to one another to form a ring fifteen.

There are many options for the movable connection of the plates 19 to each other. An example of a specific implementation of the invention shows one of these options. In accordance with Fig. 4, each pair of adjacent plates 19 is connected by a bolt 20 to a nut 21. In this case, a cylindrical hole 22 for a bolt 20 is made in one plate 19, and an adjacent plate 19 is made with an oval hole 22 for a bolt 20 for the plates 19 to be moved relative to each other during the operation of the heat exchanger.

In the case of large dimensions of the annular beam of screens of one ring 15, the spacing of the screens in each annular row of devices 9 may be insufficient so that the vibrations in the beam are within acceptable limits. In this case, in each annular row of devices 9, an additional horizontal ring 23 is used for spacing the screens in the beam (see FIG. 3), to which each device 9 is connected by a section located between the hinge 13 and the beam of screens. If this is not enough, then use another additional horizontal ring 24 for spacing the screens in the beam, with which each device 9 is connected by a section located between the upper and lower sections 4 and 5, respectively, of the screen.

Each of the additional rings 23 and 24 is made by analogy with the ring 15 composed of additional horizontal plates, each of which is installed adjacent to an adjacent additional plate, that is, additional plates are movably and sequentially connected to each other with the formation of the corresponding rings 23 or 24. Additional plate rings 23 and 24 in the drawing conventionally not shown.

In each screen, the middle section 8 is made (see Fig. 8) with a horizontal pipe spacing device 25 in the screen. The device 25 from the side of the housing 1 is connected via an additional hinge 26 with a bandage 27 covering the bundle of screens, and from the side of the central collector is attached to the vertical device 9 for spacing pipes in the screen.

Each device 25 is made of a curved strip, parts 28 and 29 of which are located on both sides of the pipe screens and are interconnected in the gaps between the pipes by means of fasteners 30.

When operating as an air heat exchanger of the emergency cooling system of a reactor installation with a liquid metal coolant, the latter with a temperature of 505 ° C is fed through a pipe 6 to the chamber 2 of the central manifold. Next, the coolant passes sequentially through the pipes of sections 4, 8 and 5 of the screens, in which it is cooled to 300 ° C. The cooled coolant is collected in the chamber 3 of the central manifold, from which it is discharged by the pipeline 7.

The coolant is cooled by external air, which due to natural traction in the housing 1 passes through the annular space of the beam of screens. The estimated air temperature in winter is -43 ° C.

During operation of the heat exchanger, the pipes of the screens have a temperature close to the temperature of the cooled coolant, and devices 9, 25 and rings 15, 23, 24 have the air temperature. As a result, a very large temperature difference is established along the height of the beam, which leads to different temperature movements of the pipes at the inlet and outlet sections 4 and 5, respectively. However, due to the hinges 13 and the implementation of the rings 15, the spacing of the screens in the beam along the length of the composite of horizontal plates 19, each of which is installed adjacent to the adjacent plate 19, provides free temperature elongation of the pipes in each screen and a constant pitch between the screens. At the same time, it is possible to avoid strong vibrations in the beam and local wear of the pipe tubes, which increases the operational reliability of the heat exchanger.

Claims (4)

1. A heat exchanger comprising a central collector located in the housing with distributing and collecting chambers and an annular bundle of tubular screens with upper and lower sections connected by radial ends of the pipes to the respective collector chambers, curved in one plan in the direction from the collector to the housing and communicated between each other through the tube space by means of the corresponding middle sections of the screens, and in each screen the upper and lower sections are interconnected by at least one vertical a pipe spacing device in a screen, which is connected at one end to a supporting annular horizontal beam and the other to a horizontal screen spacing ring in a beam, characterized in that each vertical pipe spacing device in a screen is connected to a supporting annular horizontal beam through a hinge, and the horizontal distance ring of the screens in the beam is made along the length of the composite of horizontal plates, each of which is installed adjacent to the adjacent plate. 2. The heat exchanger according to claim 1, characterized in that in each screen the middle section is made with a horizontal pipe spacing device in the screen, which is connected from the housing side via an additional hinge with a bandage covering the bundle of screens, and fastened to the vertical device from the side of the central collector pipe spacing in the screen. 3. The heat exchanger according to claim 1, characterized in that each vertical pipe spacing device in the screen with a portion located between the hinge and the screen bundle is connected to an additional horizontal screen spacing ring in the beam. 4. The heat exchanger according to claim 1, characterized in that each vertical pipe spacing device in the screen by a portion located between the upper and lower parts of the screens is connected to an additional horizontal ring spacing ring in the beam.

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