SK91996A3 - Heat exchanger for a contaminated fluid - Google Patents

Abstract

A heat exchanger, in particular for a contaminated fluid in the nuclear industry. The tubes (2) forming the tube core are welded and crimped across the whole width of the tubular plate (3) which defines the floating head (5) together with the sealing cover, and said tubular plate is also welded and crimped to the calandria (1) along the whole of its periphery.

Description

Heat exchanger for contaminated fluid

Technical field

The present invention relates to heat exchange devices, and in particular to devices for cooling a hot fluid that has been contaminated with radioactive substances or that leaves the periphery of a nuclear reactor.

BACKGROUND OF THE INVENTION

Nuclear power plants include equipment for cooling hot and contaminated fluids using intermediate heat exchangers.

This type of device consists of a first heat exchanger, commonly referred to as an intermediate heat exchanger, in which a reactor coincides with a hot and contaminated fluid and a first coolant, a heat in which the (intermediate) first heat exchange leaving the nuclear between the first cooling fluid and the second cooling fluid, the latter cooling fluid being discharged out of the nuclear power plant.

When using these devices having an intermediate heat exchanger, double protection of the external environment against leakage of radioactive substances into the environment is ensured. If to infest the external radioactive heat exchanger separation wall).

even in this case had the environment, two separation heat is one to penetrate through (in each exchanger

Because of the fluid, temperature, gradient amplitudes which are that the cooling enters the heat exchanger * heat exchanger often and the transient temperature during normal fluid and hot heat, exposed to different operating temperatures have a temperature with large core reactor and with even greater amplitudes in case nuclear reactor operation failures.

One of the primary objectives of nuclear power plant designers is to make the intermediate heat exchanger as mechanically resistant as possible to the stresses to which the heat exchanger is subjected due to the difference between the deformations of the coolant circulation pipe and those of the heat exchanger calender through which the hot fluid passes.

To this end, the French patent

712,359 and the British patent configuration and propose a deformable wall

1286722 moss application in the intermediate heat exchanger, whose function is to eliminate the above deformations.

Likewise, US-A-3850231 proposes a device having an intermediate heat exchanger in which two fluids are arranged to pass through the cooling bellows rather than infect the hot fluid, and the means arranged in an enclosed space delimited by both bellows, a calender and a loosely positioned head for detecting hot fluid leakage through the first bellows.

British patent GB-A-1286722 and patent

US-A-3850231 makes it possible to effectively improve the resistance of a heat exchanger to deformations of said mechanical nature that are of different dilatations, as a result of the above-described designs eliminating said deformations.

However, in the heat exchangers, the contaminated hot patents deteriorate because the contaminated hot fluid is in direct contact with the bellows through which it can penetrate more easily.

It is true that, according to US-A-3850231, hot fluid must pass through two bellows instead of one according to the British patent before it can contaminate the coolant, but this cannot completely eliminate the possibility of contaminating the coolant. In fact, if hot fluid can escape through the first moss, it will penetrate the second moss as well, with a shorter or longer delay. In the case of normal reactor operation, it will be necessary to stop the reactor operation when the first leak is detected, which greatly increases the operating costs of the reactor, while in the event of a reactor malfunction, the surrounding environment may be contaminated.

The limited tightness of these prior art intermediate heat exchangers between which the heats falling within the design of the equipment by the surrounding heat exchanger would also be heat.

heat was formed by heat exchangers not allowing reactors and only one

The object which should deform the invention is to develop an equally good device for mechanical exchange of heat resistance, to equipment caused by temperature as previously known when made up of only one heat exchanger, this can be a gradient for heat exchange and which would have significantly better tightness, The heat exchanger with a single heat exchanger can be placed in the emergency circuits ensuring cooling of the contaminated reactor circuit by cooling the nuclear core fluid of the fluid reactor directly counting even for leaving discharged into the surrounding environment, to an earlier nuclear power plant lacking space to store the equipment comprising two heat exchangers.

SUMMARY OF THE INVENTION

The heat exchanger according to the invention comprises:

A cylindrical calender that defines a container having at one of its ends an inlet (outlet) coolant connection; a pair of tubular tubes arranged in the container. One of the tubes is firmly attached to the calender. The other is welded to the calender along its entire circumference and defines a loosely positioned head with a closure cap in which the coolant outlet (inlet) connection is provided, a bundle of substantially parallel tubes. One end of these tubes is rigidly connected to a tube sheet which is rigidly connected to the calender. The other ends of the tubes are planted and welded over the entire thickness of the tube sheet, which is welded to the calender along its entire perimeter.

The coolant outlet (inlet) arranged on the loose head is at least partially formed by a bellows.

The contact between the moss and the hot fluid which occurred in embodiments according to the prior art patents and which constituted a critical point in the impermeability of radioactive substances does not exist in the heat exchanger according to the invention. Instead, there is contact in the heat exchanger according to the invention between the hot liquid and the plate embedded and welded in the calender, which is significantly more impermeable to the radioactive substances.

This tightness and impermeability is due to the entire thickness of the tube sheet and the fact that the tube sheet itself is embedded and welded to the calender along its entire perimeter.

Such a welding method could raise concerns that the tube sheet will be too sensitive to thermal stresses, which could result in insufficient tightness.

However, by providing a moss remote from the hot fluid space but close enough to said tubesheet, a sufficient absorption of thermal stresses is achieved, as a result of which the tubesheet is protected from the undesirable effects of said thermal stress, thereby protecting the tubesheet from heat stressing, while the tube sheet protects the moss against contact with hot liquid.

According to a preferred embodiment of the invention, the moss along the axis of the calender is closer to the tubing embedded and welded in the calender than to the top of the loosely positioned head. The deformations caused by the temperature gradients are greatest at the level of contact of the tube and calender, and the fact that the moss is in the immediate vicinity of the tube ensures that the moss absorbs as much as possible the most pronounced deformations.

and the GB-A-128 advantageously more durable than hitherto known forms

Thus, the heat exchanger according to and mechanically than the heat exchangers according to British patent US-A-3850231.

heat exchangers in particular

6722 a

According to another preferred embodiment of the invention, the heat exchanger connection associated with the moss is arranged on the same side of the calender as the inlet connection of the hot, in particular liquid,

This implies the closest proximity to the tubesheet where on the same moss the surface is found in line until the calender.

maybe what.

The bellows is placed in the zone of contact between the hot maximum as much as possible by the fluid and the tube bed is a temperature gradient.

By doing this, a greater efficiency of said moss in absorbing the aforementioned deformations is ensured even more closely.

The tightness and mechanical resistance of the heat exchanger according to the invention thus make it possible to use the heat exchanger in the emergency circuit of the nuclear reactor, which in the event of an accident cools the hot contaminated liquid leaving the reactor body with cooling water which can then be discharged directly into the environment.

In the case of the prior art device this was not possible and the prior art devices had to be formed by at least two heat exchangers in order to ensure a suitable tightness. The heat exchanger according to the invention thus makes it possible to reduce the installation costs of nuclear power plants and to renovate previously built nuclear power plants.

In the accompanying figure, which is exemplary only, one possible embodiment of a heat exchanger according to the invention is shown.

The illustrated heat exchanger comprises a calender 1 in which a bundle of substantially parallel tubes for coolant passage is arranged. This bundle of tubes, shown only partially, is fixed between the tubesheets. The tubes 2 are embedded and welded over the entire thickness of the tube 3. The calender 1 is terminated by a head 6 in which an inlet (outlet) coolant connection 6 is arranged. The head 5 is loosely supported on the calender 11. An inlet (outlet) connection of contaminated hot fluid is also provided on the calender. Output (input) connection. 8 of the cooling fluid is arranged on a loosely positioned head 5. Port 8 is partly formed by bellows 10. The axis ZZ 'is the main axis of the cylinder calender 1', the axis XX 'is the axis of the connector 8' arranged in the loosely positioned head, and the axis YY 'is the axis of the connector 7 arranged on the calender for hot fluid inlet (or outlet).

The connection 8 is closer to the tube sheet 3 along the axis ZZ 'than to the top of the loose head 5'.

Accordingly, the bellows 10 absorbs more rapidly the deformations that occur in the zone of attachment of the tube sheet to the calender, i. j. in the zone where the maximum temperature gradient is.

In a preferred embodiment of the heat exchanger according to the invention, the angle formed in the plane perpendicular to the axis ZZ 'between the projection of the axis XX' to this plane and the projection YY 'to the same plane is zero. The moss is thus as close as possible to the zone in which there is a maximum temperature gradient, which allows it to quickly absorb the deformations that occur.

Claims (3)

A heat exchanger designed to indirectly exchange heat between a contaminated hot fluid to be cooled and a cooling fluid and comprising a cylindrical calender (1) defining a vessel and terminated by a head (4) in which an inlet (outlet) connection ( 9) a coolant, a pair of tubing (3) housed in said container, one tubular being fixedly fixed to the calender and the other tubing defining a loosely positioned head (5) with a closure cap, into which an outlet (inlet) connection (8) for the coolant a fluid bundle, a bundle of substantially parallel tubes having opposite ends attached to the tubesheets, an inlet connection (7) for supplying contaminated hot liquid to said container arranged on a calender and an outlet connection (6) for discharging contaminated hot liquid from said container arranged on a calender, wherein the coolant inlet (9) is at least partially t (10), characterized in that the tubes (2) forming the bundle of tubes are embedded and welded over the entire thickness of the tube sheet, which defines a loosely laid head (5) with the closure cap, and the tube sheet is likewise embedded and welded to the calender all over circuit. Heat exchanger according to claim 1, characterized in that the connection (8) formed at least partially by the bellows (10) is arranged along the calender axis closer to the tube sheet, which is embedded and welded to the calender than to the top of the loosely positioned head. Heat exchanger according to claim 1 or 2, characterized in that the connection (8) and connection (7) are on the same surface line of the calender.