DE2513575A1 - Transfer of heat from nuclear power station - to a remote steam generating system, using pressurised water as heat receiving medium - Google Patents

Abstract

In an installation for the supply of steam connected to, but remote from, an atomic power station, with a device for heat transfer from the steam/water circuit of the power station to the steam/water circuit of the remote steam-producing installation (a) this heat transfer device consists of a surface heat exchanger in which the agent receiving the heat is water under pressure heated by steam obtained from the steam circuit of the power station (b) the pressure of the water in this heat exchanger is greater than that of the heating steams and selected so that no vaporisation of the water under pressure is produced in the heat exchanger and that generation of steam remotely from the power station is achieved by removal of the pressure on the heated pressurised water. Eliminates any risk of radioactivity in the remote steam-generating and using circuit e.g. due to a defect in the steam/water circuit at the power station, since the pressure of the water exceeds that of the heating steam from the power station.

Description

Plant for remote steam delivery connected to a nuclear power plant.

The invention relates to a system connected to a nuclear power plant for remote steam delivery with a device for heat transfer from the steam-water cycle of the nuclear power plant to the steam-water cycle of the remote steam generation plant.

The direct extraction of long-distance steam from the steam cycle of a steam turbine nuclear power plant is not possible for safety reasons.

All known reactor systems have to be radioactive to a certain extent Contamination of the work equipment can be expected. For this are safety-related Facilities and monitoring devices provided to prevent damage.

The release of weakly radioactive vapor would also be inadmissible for consumer groups outside the power plant. For example, consumers can be connected to a remote steam supply the food industry, the pharmaceutical industry, the luxury food industry, be connected to the plastics industry or breweries, dairies, etc. where the production steam comes into direct contact with the products. Here lets no Specify the lower threshold value for permissible radioactivity. Therefore, in the case of remote steam output from nuclear power plants, the requirement is to be expected that the remote steam must not contain any radioactivity.

In the case of the known systems for remote steam delivery mentioned at the outset with a device for heat transfer from the steam-water cycle of the nuclear power plant to the steam-water cycle of the district steam generation system, the district steam generated in the nuclear power plant by heat exchange of the working steam via steam converters. This creates an additional barrier against the transfer of radioactive substances given. Even in such cases, however, there is a risk of leaks in the heat exchange system not excluded! that certain amounts of radioactive substances from the steam-x-water circulation of the nuclear power plant get into the district steam cycle. In the case of steam converters, the Vapor pressure on the heat-emitting side of the heat exchange surfaces must be greater than on the heat-absorbing side, otherwise heat will be transported via the heat exchange surfaces not possible. This means that working steam can pass into the district steam in the event of leaks.

Appropriate monitoring equipment could probably reduce the risk contamination of the long-distance steam cycle can be encountered. If this fails However, facilities can prevent radioactive substances from entering the remote steam system not completely rule out what could lead to incalculable consequential damage. When these safety devices respond, the remote steam supply should switch off the nuclear power plant will be interrupted, leading to production losses among consumers would lead. It is also controversial whether the measuring accuracy of such safety devices meets the safety requirements of the various consumer groups.

The present invention is based on the object of a Nuclear power plant to create a system for the delivery of remote steam, in the case of Avoidance of the disadvantages inherent in the known relevant systems the danger radioactive contamination of the steam emitted from the nuclear power plant is excluded can be.

The aforementioned object is achieved according to the invention so that at a system connected to a nuclear power plant for the delivery of remote steam, the facility for heat transfer from the steam-water circuit of the nuclear power plant to the steam-water circuit the remote steam generation system is designed as a surface heat exchanger from which the heat-absorbing agent is removed from the steam cycle of the nuclear power plant Heating steam is heated pressure water, the pressure of which is higher than the heating steam pressure, wherein the pressure level of the pressurized water is chosen so that in the surface heat exchanger no evaporation of the pressurized water occurs and that the remote steam generation through The heated pressurized water is depressurized. Since the invention System the pressure on the heat-absorbing side of the heat exchanger is greater than the pressure on the heat-emitting side, in the event of possible leaks in this Heat exchangers do not transmit any radioactivity into the remote steam system.

The steam generation by heat transfer to pressurized water and subsequent Relaxation for the purpose of phase separation is compared to other methods of remote steam generation with reductions in power generation in the nuclear power plant and also with higher ones Investment expenses associated. However, these disadvantages are the decisive ones Advantage of preventing radioactive contamination of long-distance steam and their possible consequential damage.

The invention is therefore only in connection with the district heating supply from nuclear power plants makes sense; in this context, however, it gains considerable Importance because of the compulsion or economic need to use fossil fuels save in the generation of process steam for industrial purposes or for heating purposes to have to lead to a considerable extent to the emission of district steam from nuclear power plants will.

Further useful refinements and features of the invention are specified in the subclaims. So can according to one of the features of the claim 2, i.e. by having several surface heat exchangers connected in series for the heat transfer from the steam-water cycle of the nuclear power plant to the Steam-What-he cycle of the remote steam generation system are provided and thus a multi-stage heat transfer takes place, a better energy utilization is achieved will. By training the system according to the invention according to the characteristics of claim 4, i.e. by the arrangement of a steam superheater for the district steam, the formation of condensation in the long-distance steam transport lines can be avoided.

An embodiment of the system according to the invention with an appropriately dimensioned one Additional water treatment system, according to one of the proposed in claim 6 Measures are recommended if there are remote steam consumers that use the remote steam Consume directly as production steam so or so completely that a return delivery of condensate is not possible (for example in the case of breweries or the like.

Manufacturing companies) or if they are consumers which the condensate of the remote steam is loaded with fiber in such a way that a processing plant for such Condensate would be too costly and would not be profitable.

The further measure proposed in claim 6, that the remote steam generation system Equipment for preheating and degassing of the returning heating steam condensate the district heating consumer and the treated make-up water by means of the in the Has steam generated in the district steam generation system, in turn contributes to a clean separation between the steam-water cycle of the nuclear power plant and to reach the steam-water cycle of the remote steam generation plant and thus to ensure that a transfer of radio activities from the first-mentioned cycle in the second-mentioned cycle is avoided with certainty.

In an embodiment of the system according to the invention according to claim 7 provided preheating turbine has the advantage that in the Fen steam generation plant in addition, electrical power can be generated for heating such Can serve heat consumers, which via heat transfer pipelines (remote steam transport lines) are not attainable or would only be attainable in an uneconomical manner.

In the following an embodiment of the invention is based on the Drawing described. In the drawing, which is schematically to the left of the vertical, The dash-dotted line shows the remote steam generation system is the aforementioned on the right dash-dotted line the actual, not shown in the drawing, nuclear power plant to think. 1 with a surface heat exchanger is referred to, in which the warming up of pressurized water with condensing heating steam supplied by the power 15 takes place from the steam cycle of the nuclear power plant. The heating steam condensate off This heat exchanger is used in the water cycle of the nuclear power plant 16 returned.

The heat absorbing agent in the heat exchanger 1 is under overpressure standing water. The overpressure of the heat-absorbing pressure is controlled by a Maintain pump 2. The water-side overpressure in heat exchanger 1 is higher than the heating steam pressure of this heat exchanger. Here is the pressure head of the pressurized water at the same time also chosen so that no evaporation in the surface heat exchanger1 of the author enters. The pressure water heated in the heat exchanger -1 is over a power 17, the steam superheater 3 and a power 18 in the expansion vessel 4 initiated. The phase separation takes place by relieving the pressure in the expansion vessel 4. of the heated pressure vessel in steam and condensate. The required steam pressure according to the steam superheater 3 is maintained by a control element 5. At 19 she is Point in the steam line 21 denotes at which the actual value of the steam pressure is removed. In addition, the control device, as it is of a known type can be, not shown in detail. Serves to overheat the remote steam, as from the drawing shows the heated pressurized water. In the steam superheater 3 is thus a corresponding proportion of the heat of the heated pressurized water to that in the expansion vessel 4 generated steam transferred. The one generated in the expansion vessel 4 and in the steam superheater 3 superheated steam is used as production steam for the remote steam generation plant Consumer connected via line 22 6. The arrangement of a superheater 3 or the overheating of the generated in the expansion vessel 4 by pressure relief Saturated steam is not absolutely necessary. However, like this, it can The embodiment shown is the case - provided if this is to avoid of condensate failure in the long-distance steam transport line is required.

The condensate obtained during the phase separation in the expansion vessel 4 is returned via a line 20 to a collecting tank 7, which acts as a degasser table preheater can be formed.

An amount of water corresponding to the remote steam supply must be returned to be fed into the circuit of district steam generation.

This can be done either by the consumers 6 in the remote steam generation system be returned heating steam condensate or make-up water. In the chosen embodiment a possible design case is envisaged or shown in the drawing, in which no heating steam condensate is returned from the steam consumers 6. In this case, an additional water quantity corresponding to the remote steam supply must be treated and introduced into the circuit of remote steam generation. This additional water is by means of a pump 27 resp.

the line 24 is routed through an additional water treatment system 8, heated in the mixing preheater 9 and pre-degassed to continue via the pump 25 containing Line 26 to be fed to a preheater chain 10a, 10b, 10c. As superheated steam for the mixing preheater 9, the one fed to the mixing preheater via the bedding 27 is used Exhaust steam from a preheating turbine 11. The further heating of the make-up water in the Preheater chain 10a, 10b, 10c is carried out with that supplied via lines 28, 29, 90 Extraction steam from the aforementioned preheating turbine 11. Finally, the make-up water is in the collecting tank 7 is introduced, from which it is fed by the pump 2 into the surface heat exchanger 1 is pressed.

The preheating turbine 11, which drives the electric generator 33, is via a line 31 with a partial flow of the in the remote steam generation plant produced steam applied.

The collecting tank 7 also serves as a degasser mixing preheater, as in the case of the illustrated embodiment, as Ileizdampf for This Misclivorwärmer a partial flow of the steam generated in the expansion vessel 4 used, which is fed to the container 7 via the steam line 32. With these Measures are achieved that in the mixing preheaters 7 and 9 no mixing of Steam and water of the circuits of the nuclear power plant and the district steam supply entry.

The remote steam generation system can of course also be designed in such a way that that the degassing of the make-up water and possibly that of the remote steam consumers returning heating steam condensate only takes place in the mixing preheater 9 and one further degassing in the collecting container 7 is not necessary. Also degassing only in the collecting tank 7 alone would be conceivable. However, apart from degassing in the collecting tank, it is recommended 7 still a pre-degassing in the mixing preheater 9 (as in the case of the exemplary embodiment) to undertake, since in the event that degassing is only carried out in the collecting container 7, there is a risk of corrosion for the preheater chain 10a, 10b, 10c or this preheater chain to avoid it the risk of corrosion from expensive, i.e.

Made of a material that is sufficiently resistant to corrosion would have to be.

In summary it can be said that with the heat transfer in Heat exchanger 1 from the steam circuit of the nuclear power plant to pressurized water, its pressure, is selected as indicated in claim 1, and with the use of that described in US Pat District steam generation plant generates production steam for preheating and degassing the required make-up water and, if applicable, that returned by the consumers 6 Heating steam condensate, a transfer of radio activities from the steam-water cycle of the nuclear power plant in the steam-water circuit on the remote steam generation plant Security is avoided.

Claims (9)

Claims Plant connected to a nuclear power plant for the delivery of remote steam with a device for heat transfer from the steam-water cycle of the nuclear power plant to the steam-water circuit of the remote steam generation system, characterized in that that the device for heat transfer from the steam-water cycle of the nuclear power plant to the steam-water circuit of the Feidainpferzeugungsanlage as a surface heat exchanger (1) is designed in which the heat-absorbing agent with from the steam cycle the heating steam taken from the nuclear power plant is heated pressurized water, the pressure of which is higher than the heating steam pressure, the pressure level of the pressurized water being selected in this way is that in the surface heat exchanger (1) no evaporation of the pressurized water occurs and that the remote steam generation by depressurizing the heated pressurized water he follows. 2. System for remote steam delivery according to claim 1, characterized in that that the device for heat transfer from the steam-water cycle of the nuclear power plant to the steam-water circuit of the remote steam generation system from several surface heat exchangers is formed, which are connected in parallel or in series on the pressurized water side. 3. Plant for remote steam delivery according to claim 1 or 2, characterized in that that the pressure relief of the heated pressurized water and its phase separation in Steam and condensate takes place in an expansion vessel (4). 4, system for remote steam delivery according to claim 3, characterized in that that the expansion vessel (4) is followed by a steam superheater (3) on the steam side is, whereby the in the surface heat exchanger (1) heated pressurized water is used and the superheater (3) On the water side, for example, the surface heat exchanger (1) and the expansion vessel (4) is switched. 5. Plant for remote steam delivery according to one of claims 1 to 4, characterized characterized in that an additional water treatment system (8) to replace the in the Remote steam generation system or water lost in the remote steam pipes is provided. 6. System for remote steam delivery according to claim 5, characterized in that that to replace the water volume corresponding to the remote steam supply return lines for the heating steam condensate of the district heating consumer and / or a corresponding one dimensioned additional water treatment system (8) are provided and that the District steam generation facilities for preheating and degassing of the returning Heating steam condensate 5 of the district heating consumers and the treated make-up water having by means of the steam generated in the remote steam generation plant. 7. Plant for remote steam delivery according to claim 6, characterized in that a preheating turbine (11) is provided, the working steam of which the district steam generating plant is taken, and their exhaust steam for preheating and degassing and their bleeding steam for further heating of the make-up water and, if necessary, of the returning heating steam condensate the remote steam consumer (6) in the steam-water circuit of the remote steam generation system serves. 8. Plant for remote steam delivery according to claim 7, characterized by a mixing preheater (9), which receives the exhaust steam from the preheating turbine (11) and the the additional water to be preheated and degassed and, if applicable, the return The end of the heating steam condensate can be supplied to the district steam consumer and through a preheater chain (10a, 10b, 10c), in which the additional water preheated and degassed in the mixing preheater (9) or heating steam condensate is further heated by bleed steam from the preheating turbine (11) and by one between the last preheater (10c) and the surface heat exchanger (1) arranged collecting container (7). 9. Plant for remote steam delivery according to claim 8, characterized in that that the collecting container (7) is also designed as a degasser mixing preheater, a partial flow of the steam generated in the expansion vessel (4) can be supplied as heating steam is. L e r s e i t e