DE2430787A1 - Pressurised water reactor with safety valve outside containment - to give easy access but connected upstream of internal cut-off valve - Google Patents

Abstract

The parent patent describes a pressurised water reactor power plant comprising a safety containment, through which a steam line leads outwards, having one cut-off valve inside the containment and another cut-off valve outside it, with a safety valve upstream of the inner cut-off valve but discharging outside the containment. In the Patent of Addition, the safety valve is itself outside the safety containment and can be cut off by an internal cut-off valve. In a preferred embodiment, there is a second safety valve in parallel with the first, having a higher response pressure, also situated outside the containment, and pref. having a throttle upstream of it in the wall of the containment. The first safety valve may have a bypass blowdown line containing two cut-off valve in series. The safety valve serves the same function as in the Parent Patent, but being outside the safety containment is easily to maintain, on account of unrestricted access. Also, if the safety valve should fail, it can but cut off.

Description

Pressurized water reactor addendum to patent. ... ... (Note: P 23 45 580.3 = VPA 73/9452) In the main patent. ... ... (Note: P 23 45 580.3) it is about a pressurized water reactor with a safety cover and a main steam pipe coming out of the safety cover leads out and a shut-off valve inside the safety envelope and a second Shut-off valve outside the safety envelope and one of the inner shut-off valve has upstream safety valve, the blow-off line outside of the safety envelope ends. Due to the arrangement of the main steam valve in the safety envelope protection against external influences can be provided without additional structural effort, because the safety envelope itself is already protected against external influences. In addition, it avoids that ureter circumstances radioactively contaminated Steam can escape, because even if the main steam line breaks A barrier inside the security envelope is still possible. However a higher effort for the maintenance of the main steam valve will come into question here because the fitting, in contrast to it, is arranged outside the safety envelope not always without being widely accessible.

The safety valve upstream of the internal shut-off valve blows the steam to be emitted in the event of malfunctions out of the safety envelope. To However, according to the arrangements specified in the main patent, it is inside the safety envelope, so that it is largely protected in the same way as the main steam shut-off valve is.

The invention has a further embodiment of the arrangement according to to the Main patent for the goal, with which the ease of maintenance of the system without loss can be increased in security.

This is done in that in the pressurized water reactor outlined at the beginning the safety valve arranged outside the safety envelope and through an inner Valve is lockable. Safety valves outside of the safety envelope are indeed known per se (compare for example VG3 nuclear power plant seminar 1970, page 66, Illustration 1). There, however, the fittings provided for in the main patent are missing inside the safety envelope, which shuts off the safety valve for the In the event of its failure.

A safety valve with a higher response pressure be connected in parallel, preferably also outside the safety envelope is arranged. Here it recommends the higher set Safety valve to be connected upstream of a throttle in the wall of the safety envelope. Preferably the throttle point is a tightly closable shut-off valve. Especially gt'4, Istig is an arrangement in which two lines leading out of the containment can be controlled by two valves coupled to one another in such a way that when closing one line opens the other. Here is the indispensable one Relief possibility ensured, which can be achieved with the safety valve target. On the other hand, a shut-off can always be made if one of the lines should be defective.

The blow-off line of the safety valve can be in a closed Lead blow-off tank. You can avoid radioactivity when opening the Safety valve with live steam escapes from the safety envelope in an uncontrolled manner.

If you provide the blow-off tank with a recooling circuit, you can The arrangement can also be used to dissipate decay heat, so that return cooling lines can be used saves that would otherwise have to be passed through the safety envelope.

For a more detailed explanation of the invention are based on the enclosed Figures some embodiments described. The representations show simplified Pipeline plans, the construction of which are carried out in a known manner can.

In Fig. 1 is of a pressurized water reactor for commercial power generation for example 1000 MW, the security envelope 1 is drawn, all of which lead to the activity Components, for example a reactor pressure vessel with the reactor core and the Primary cooling circuit includes. For the sake of simplicity, this is just a steam generator 2 drawn, while with such great achievements usually several, for example four steam generators are connected to the reactor pressure vessel. The main steam pipes the other steam generators can, however, be designed in the same way.

In the steam generator 2, this is done by a feed water line (not shown) incoming water evaporates. The highest intended operating pressure is for example 90 bar.

The steam exits through a steam outlet 3, which is located inside the security envelope 1 branches. A line 4 leads through a bushing 5 through the safety envelope to a turbine, not shown. This main steam pipe 4 with a nominal width of, for example, 700 mm is with one inside the security envelope 1 horizontal shut-off valve 6 provided.

In the event that the steam pressure increases impermissibly in the event of a turbine failure, a blow-off line 8 is additionally passed through the safety envelope 1 at 9. In the line 9 sits a safety valve 10 with a blow-off pressure of 90 bar outside the safety envelope 1. The line 8 is, however, with a shut-off valve 12 lockable inside the safety envelope 1.

The blow-off line 8 is a line 14 connected in parallel, the at 15 also through the safety shackle 1 and a second safety valve 16 contains. The response pressure of this safety valve 16 is 100 bar, it is thus higher than that of valve 10. Since this valve does not normally respond, it does not require an upstream shut-off valve in the event that it does not close after speaking.

The blow-off lines 8 and 14 lead to a common outlet 17, which can be assigned a muffler, not shown. In this leads also another blow-off line 18 which leads out of the safety envelope at 19.

In line 18 there is a relief control valve 20 outside the safety envelope 1 and a shut-off valve 21 inside the safety envelope 1 connected in series. The relief control valves 20 and 21 are opened when the decay heat to Example in the event of a malfunction, led out of the safety envelope 1 in the form of steam shall be. It is assumed that the reactor output is only a few percent the nominal power. The safety valves 10 and 16, however, are for the designed for full reactor output.

With four steam generators and the same in Fig. 1 gezeichne th arrangement for each steam generator this means that the safety valves 10 and 16 as well the blow-off lines 8 and 14 and the muffler in the outlet 17 for a thermal Power of about 750 MW are rated.

The embodiment shown in Fig. 2 differs of the arrangement according to FIG. 1 in that the second safety valve 16 ' is arranged outside the safety envelope 1. Here the implementation is 15 ' executed by the safety envelope 1 as a throttle point. This is in the hypothetical In the event of a break in the safety valve, the steam leakage rate will not increase adopts dangerously high value, which leads to an over-rapid cooling of the switched-off Reactor plant could lead.

The two valves of the blow-off line 18 are 20 'and 21' designated and arranged together outside the safety envelope 1. However, you lie with the shut-off valve 12 'of the line 8 in series, so that even if there is a defect in the Valves 20 ', 21' can be shut off to prevent radioactivity from entering to avoid from the safety envelope.

The outlet 17 and the main steam line 4- correspond to the arrangement according to-Fig. 1.

In the exemplary embodiment according to FIG. 3, the safety valve 10 is assigned to the main steam line 4, in which the shut-off valve 6 is outside the safety envelope is arranged.

In addition, a shut-off valve 25 is provided in line 4. This3 Valve cooperates with a valve 26 in line 14 ', which leads to the second Safety valve 16 'leads. The valves 25 and 26 are connected via linkages 27 and 28 a common drive 29 coupled The coupling is designed so that both Valves are at most half open at the same time and that one valve closes, we: the other is opened wider. This arrangement ensures that the full cross-section is always available for discharging the nominal power of the reactor stands.

On the other hand, there is an alternating shut-off of the two lines 4, 14 'possible in the event that these lines are damaged.

In the exemplary embodiment according to FIG. 4, a valve is in the line 14 ″ 30 is provided, which opens depending on the pressure. For this purpose it is with a piston drive 31 provided, which via valves 32 and 33 from the Fridschdampfauslaß 3 of the steam generator 2 is applied. The valve 30 opens at pressures that are greater than 80 bar, and closes at pressures below 70 bar. That is why the safety valve 161 effective only if the safety valve 10 should fail. In the event of a break the outlet line and normal pressure, however, is safe through the valve 30 locking guaranteed.

In Fig. 4 it is also indicated by dashed lines that the outlet of the safety valves 10, 16 'and the blow-off control valves 20', 21 'do not lead to the outside via the outlet 17 must, but can be connected to a blow-off tank 35, which has a a pump 36 and a heat exchanger 37 existing recooling circuit 38 has. Also in malfunctions that lead to the safety valves 10, 16 'responding thus possibly radioactively contaminated steam can only get into the blow-off tank 35.

8 claims 4 figures

Claims (8)

Claims 1. Pressurized water reactor with a safety envelope and a main steam line that leads out of the safety envelope and a shut-off valve inside the safety envelope and a second shut-off valve outside the safety envelope as well as a safety valve upstream of the inner shut-off valve, whose blow-off line ends outside the safety envelope, according to the patent. ... ... (Note P 23 45 580.3 - VPA 73/9452), characterized in that the safety valve (10) arranged outside the safety envelope (1) and by an internal fitting (6) can be shut off. 2. Pressurized water reactor according to claim 1, characterized in that the outer safety valve (O) a safety valve (16 ') with a higher Response pressure is connected in parallel (Fig. 2). 3. Pressurized water reactor according to claim 2, characterized in that the higher set safety valve (.16 ') also outside the safety cover (1) is arranged. 4. Pressurized water reactor according to claim 3, characterized in that the higher set safety valve (16 ') a throttle (15') in the wall of the Safety sheath (1) is connected upstream (Fig. 2). 5. Pressurized water reactor according to one of claims 1 to 4, characterized in that that the outer safety valve (10) has a blow-off line (18) with two in series lying shut-off valves (20,21) is connected in parallel. 6. Pressurized water reactor according to one of claims 1 to 5, characterized in that that two lines (4, 14 ') leading out of the safety envelope (1) through two valves (25, 26) coupled to one another can be controlled in such a way that when they close one line opens the other (Fig. 3). 7. Pressurized water reactor according to one of claims 1 to 6, characterized in that that the blow-off line (14 ") leads into a closed blow-off tank (35). 8. Pressurized water reactor according to claim 7, characterized in that the blow-off tank (35) has a recooling circuit (38).