BG63057B1 - Heat-exchanger for the cooling of a contaminated liquid - Google Patents

Abstract

The heat-exchanger is used in the power industry, in particular in the protection networks of the nuclear power plants. It ensures the cooling of the contaminated hot liquid running out of the housing of the nuclear reactor with the assistance of the cooling liquid directly fed from the external medium without the latter being contaminated with radioactive substances. The heat-exchanger includes a cylindrical housing (1), defining a tank in the interior of which straight and parallel pipes (2) are fitted forming a bunch for the passage of the cooling liquid. Pipes (2) are positioned between the pipe gratings (3 and 3a). Housing (1) ends, at one of its ends, with a head (4) in which a pipe connection (9) is designed for the inlet of the cooling liquid. One of the pipe gratings (3) is fixed to the housing (1) and head (4), and the other tubular grating (3a), together with a cover forms a floating head (5). A pipe connection (8) is designed on the latter for the outlet of the cooling liquid partially determined by bellows (10). Pipes (2) forming the pipe bunch are welded and caulked along the whole thickness of the pipe grating (3a), and it is also welded and caulked to housing (1) along its entire periphery. A pipe connection (7) is designed for the inlet of the contaminated hot liquid in a tank formed by the housing (1), and pipe connection (6) is designed for the outlet. 3 claims, 1 figure

Description

Field of the art

The invention relates to a heat exchanger for cooling a contaminated liquid and finds application in the energetics, in particular in the protective networks of the nuclear power plants. The heat exchanger cools the contaminated hot liquid coming out of the nuclear reactor enclosure by means of a coolant fed directly from the outside without it being contaminated by radioactive substances.

State of the art

At the nuclear power plants are known cooling devices of heated and contaminated liquids using an intermediate heat exchanger. This type of device comprises a first heat exchanger, commonly called an intermediate heat exchanger, which performs heat exchange between the heated and contaminated liquid exiting the atomic reactor and a first coolant. The first cooling fluid passes through a second heat exchanger, whereby heat exchange occurs between the latter and the second coolant, the latter being thrown out.

By using these devices with an intermediate heat exchanger for contamination, the radioactive substances must pass through two walls separating the heat exchange process - one wall per heat exchanger. This ensures double protection of the environment from radioactive contamination.

The coolant and the hot fluid flowing through a heat exchanger have different temperatures. Therefore, it is often subject to temperature gradients and transient thermal events with high amplitude during periods of normal operation of the atomic reactor, and even greater in the event of an accident.

One of the core tasks of nuclear power plant designers is to develop an intermediate heat exchanger that is as mechanical as possible to resist the effort exerted on it as a result of the differences in the deformation of the pipes through which the coolant passes and those of the casing of the heat exchanger through which the warm liquid flows.

The technical solutions described in PCT 712 359 A and OI 1 286 722 A are known in which a bellows and a deformable wall are provided in the intermediate heat exchanger, whose task is to assume the aforementioned deformations.

In another known solution 118 3 850 231 A there is provided a system equipped with an intermediate heat exchanger in which two bellows are provided through which the hot liquid must pass before dirtying the coolant. In this embodiment, in the enclosed space enclosed by the two bellows, the casing and the floating head of the heat exchanger, there is arranged means for detecting the flow of hot liquid through the first bellows.

The solutions described in US 1 286 722 A and 118 3 850 231 A allow to effectively improve the resistance to mechanical deformations due to enlargement by integrating a bellows that assumes these deformations. However, in the heat exchangers according to these two patents there is a reduced density of the contaminated hot fluid because the contaminated hot fluid is in direct contact with the bellows through which it can leak out more easily.

According to U.S. Pat. No. 3,850,231 A, the liquid has to pass through two bellows and not one, as per the British patent, before contaminating the cooling liquid. But this only partially removes the possibility of contamination of the cold liquid. Once the hot fluid can run through the first bell, it is also possible to do so during the second, shorter or longer period. In the event of a normal reactor operation, it will be necessary immediately after the first leakage to stop the operations, which results in significant overflows. In case of a reactor operation, the pollution will be a fact as soon as the hot fluid passes through the second bell.

The low leakage of the known intermediate heat exchangers prevents the creation of a heat exchange system between the nuclear reactor and the external environment with only one heat exchanger.

SUMMARY OF THE INVENTION

The object of the invention is to provide a heat exchanger having such mechanical deformation characteristics due to the temperature gradient that is as good as the known heat exchangers and at the same time to have significantly improved hermetic characteristics. This will allow it to be independently deployed in the nuclear power stations of a nuclear power plant as well as in old nuclear power plants where there is no room for a two-heat exchanger system to ensure the cooling of the contaminated hot liquid coming out of the nuclear reactor enclosure cooling liquid supplied directly from the outside environment without being contaminated.

The liquid-cooled heat exchanger according to the invention comprises a cylindrical housing defining a reservoir and a pair of tubular grilles mounted in the tank. Inside the cylindrical housing there are parallel tubes forming a tubular bundle, the opposite ends of which are fixed to the two tubular grilles. To the tank are formed two nozzles - a nozzle for the inlet of the contaminated hot liquid in it and a nozzle for the outlet of the contaminated hot liquid from it. At one end, the housing ends with a head in which a coolant inlet (outlet) is located. One of the tube grids is fixed to the casing and the head, and the other tube grid, together with a lid, forms a floating head. The float head has a nozzle for the coolant outlet (inlet). The bellows is partly determined by bellows.

The pipes forming the tubular bundle are welded and twisted along the entire thickness of the tubular grid, which together with the hood defines the floating head. This tube grid is also welded to the casing along its entire periphery.

The bellows-hot contact according to the prior art patents representing the weakness of the leak-tightness of the radioactive substances in the heat exchanger according to the invention has been removed. It is replaced by a single hot fluid contact - a tubular grille, welded and snapped to the casing, much more airtight with respect to radioactive substances. This leakage is due to the fact that the edges of the tubes are welded to the tubular grid of all thickness, and it is itself welded and creased all over its periphery to the casing.

The welds described may give rise to the doubt that the tube grid will become very sensitive to the thermal stresses that would lead to deterioration of the tightness.

By using a bellows away from the space reserved for the hot liquid but sufficiently close to the tube grid, a good absorption of thermal loads is achieved to protect the tubular grid from thermal loads. The bellows protects the tube grille from thermal loads, while the grille protects the bell from contact with the hot fluid.

According to one embodiment of the invention, the coolant outlet nozzle, defined in part by the bellows, is more closely spaced with respect to the axis of the casing to the tubular grid that is welded and snapped to the casing rather than the top of the floating head.

Deformations due to the temperature gradient are most significant in the contact of the tube grid and the casing. The silfoon, located adjacent to the tube grid, assumes the most significant deformations as quickly as possible.

The heat exchanger according to this embodiment is mechanically overheated and more resilient than the prior art solutions, and in particular from those described in GB 1 286 722 A and C5 3 850 231 A.

According to another embodiment of the invention, the coolant outlet nozzle, partly defined by the bellows, and the inlet nozzle of the contaminated hot liquid are located on the same casing formed by the casing.

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In this embodiment, the bellows is positioned as close as possible to the point of contact of a hot fluid - a tubular grid where the temperature gradient is maximum. The position of the bell to the grille provides even greater efficiency when taking deformations from it.

The heat exchanger according to the invention is of good tightness and mechanical resistance. This allows it to be used in the atomic reactor enclosure protection circuit and in the event of an accident to cool the radioactively contaminated hot liquid emanating from the housing with a cooling liquid that is poured directly out without the risk of radioactive contamination of the environment .

As noted above, the cooling systems known to date include at least two heat exchangers to provide the necessary system tightness. With the creation of a heat exchanger according to the invention there is no need to include a second heat exchanger, which reduces the production costs of a nuclear power plant. It also makes it possible to modernize existing old nuclear power plants.

Description of the attached figures

An exemplary embodiment of the dirty heat exchanger according to the invention is shown in the accompanying figure.

An embodiment of the invention

According to one embodiment of the invention, as shown in the figure, the heat exchanger for the contaminated hot fluid comprises a cylindrical housing 1 defining a reservoir inside which straight and parallel tubes 2 forming a beam are arranged to pass the coolant . This bundle tube 2, which is shown partly in the figure, is mounted between the tube grids 3 and 3a.

The casing 1 ends at one end with a head 4 in which a nozzle 9 is provided for the coolant inlet (outlet). One of the tubular grids 3 is fixed to the casing 1 and the head 4 and the other tube grid 3a together with a cover forms a floating head 5. A nozzle 8 is provided on the floating head 5 for the coolant inlet (inlet). The blower 8 for the coolant outlet (inlet) is determined in part by a bellows 10.

The tubes 2 forming the tubular bundle are welded and snapped over the entire thickness of the tubular grid 3a which together with the lid defines the floating head 5. The tubular grid 3a is also welded and snapped to the hood

1 all over its periphery.

A nozzle 7 is provided for the inlet of the contaminated hot fluid into the reservoir 1 formed by the casing 1. A nozzle 6 is provided for the outlet of the contaminated hot liquid from the thus formed tank.

The attached figure shows three axes, such as:

- ZZ 'is the main axis of the cylindrical housing 1;

XX is the axis of the nozzle 8 for the outlet of the cooling liquid provided in the floating head 5;

- YY is the axis of the nozzle 7 for the inlet (outlet) of the hot contaminated liquid provided in the casing 1.

In a preferred embodiment of the heat exchanger according to the invention, the coolant outlet nozzle 8, with respect to the main axis ZZ 'of the housing 351, is located closer to the tube grid 3 than to the top of the floating head 5.

In this way, the bellows 10 assumes more quickly the deformations occurring in the zone of joining of the 40 gauge tube grid 1, an area in which the temperature gradient is the highest.

In the preferred embodiment of the heat exchanger as shown in the figure, the angle formed in the normal plane of the axis ZZ 'between the projection of the axis XX' on that plane and the projection of the axis YY 'on the same plane is zero. In this way, the bellows is as close as possible to the area where the temperature gradient is maximum, allowing it to quickly overcome the deformations.

Claims (3)

Claims A contaminated liquid coolant heat exchanger comprising a cylindrical casing (1) defining a single tank and a pair of tube grilles (3) and (3a) mounted in the tank, with parallel tubes (1) arranged inside the cylindrical casing (1). 2) forming a tube bundle, the opposite ends of which are fixed to the two tube grilles (3) and (3a), two nozzles (7) for the inlet of the contaminated warm liquid into it and a nozzle (6) for the reservoir. the outlet of the contaminated warm liquid from it, and at one end the casing (1) ends with a head a (4), in which is located a nozzle (9) for the inlet (outlet) of the coolant, with one of the tube grilles (3) is fixed to the housing (1) and the head (4) and the other tube grate (3a) , together with one lid, forms a floating head (5) in which a nozzle (8) is arranged for the outlet (inlet) of the coolant, the latter being partly determined by a bellows (10), characterized in that the pipes (2 ) forming the tube bundle are welded and hammered along the entire thickness of the tube grate (3a), which together with the lid 5 defines the floating head (5), the tubular grille being also welded and secured to the casing (1) along its entire periphery. 2. Contaminated liquid coolant heat exchanger according to claim 1, 10, characterized in that the nozzle (8), partly defined by the bellows (10), is more closely positioned relative to the axis of the housing (1) to the tube grate (3a), which is welded and latched to the housing (1). ) than before 15 the tip of the floating head (5). 3. Contaminated liquid coolant heat exchanger according to claim 1 or 2. characterized in that the coolant nozzle (8) and the nozzle 20 (7) for the inlet of the contaminated hot liquid, are located on the same cylinder forming unit defined by the housing (1). Attachment: 1 figure