DE1091245B - Load change procedure for a reactor power plant and a reactor power plant to carry out the procedure - Google Patents

Description

GERMAN

The invention relates to a load change method for a reactor power plant, its cooling gas supply contains several parallel turbo compressors that can be switched on and off individually, furthermore to a reactor power plant to carry out the process.

In a known load change method, when a compressor is switched to one or more other, compressors that are already in operation are to be switched on, the compressor to be switched on switched on while the shut-off device in its pressure line is completely closed, and gradually brought to the same pressure as the other compressors. Then that will Shut-off valve open. When a compressor is switched off, the procedure is reversed: First the shut-off device in question is closed and the compressor is then shut down.

In contrast, the process according to the invention is that when the load increases, an in to the reactor leading cooling gas supply line of a compressor to be switched on already lying shut-off is opened before the pressure generated by the compressor the necessary positive delivery Height has reached, and that thereupon the pressure on the compressor to be connected up to the amount of The pressure of the other compressor is increased, while the shut-off device is reversed when the load drops is only closed after the pressure of the compressor to be switched off the positive delivery has fallen below the required amount, after which the compressor to be switched off is shut down. Of the Pressure of the compressor to be switched on or off can after opening or before closing the associated Shut-off device, e.g. B. by adjusting the compressor blades or the compressor speed changed will.

In the method according to the invention, the cooling gas flows through the compressor to be switched on or off temporarily backwards. The backward flowing amount can be kept low and z. B. 10% of the normal flow rate of the compressor. Likewise, the time during which the return flow occurs, are kept briefly, so that the state of the total cooling gas flow passing through the reactor is not significantly affected. It is then avoided that the gas is switched on or off in the Compressor becomes excessively hot, as is the case with the aforementioned known method where one and the same amount of gas included in the compressor during the entire start-up or shutdown time remain. In the process according to the invention, the reactor receives z. B. when the load increases after opening the shut-off device is not suddenly much hotter

Load change procedure

for a reactor power plant

and reactor power plant for implementation

of the procedure

Applicant:

Sulzer Brothers Aktiengesellschaft,
Winterthur (Switzerland)

Representative: Dipl.-Ing. H. Marsch, patent attorney,
Schwelm, Drosselstr. 31

Claimed priority:
Switzerland of March 13, 195Θ

Kurt Feer, Winterthur (Switzerland),
has been named as the inventor

Cooling gas, which leads to an impermissible increase in temperature of the sensitive, neutron-permeable light metal, z. B. aluminum, existing casings of the fissile material elements would lead.

It is also advantageous for the compressor to be switched on or off if this is located in it Gas is not heated too quickly and too much, because then the surfaces of the blades are less be heated quickly and less strongly.

In one embodiment of a reactor power plant for carrying out the method, a further invention a main shut-off element in the pressure line of each compressor and, in parallel, a secondary shut-off element of - in comparison to the passage cross-section of the main shut-off element - small passage cross-section arranged. The method can then be designed so that, for. B. when switching on the engine of the compressor to be switched on, the associated main shut-off element remains closed and only that Nebenabsperorgan is opened and thereupon the pressure on the compressor to be connected up to almost the amount necessary for positive funding is increased and then the main shut-off device fully open, if necessary, the secondary shut-off device is closed and then the pressure continues on the amount the remaining compressor is increased.

009 628/324

Further characteristics result from the following Description of an embodiment in connection with the drawing and the claims.

The drawing shows a scheme of an inventive trained reactor power plant, in which the load change method corresponding to the invention is used.

A nuclear reactor designated as a whole with 1 receives cooling gas, for example carbon dioxide (CO ₂ ), from four compressors 2 to 5 lying parallel to one another, which are driven by electric motors 6 to 9. The compressors are connected to the reactor via pressure lines 15 to 18 containing main shut-off devices 11 to 14 and a common supply line 19. The pressure lines 15 to 18 have bypass lines 25 to 28 having secondary shut-off elements 21 to 24. The passage cross section of the secondary shut-off elements 21 to 24 is small compared to that of the main shut-off elements 11 to 14. A cooling gas discharge line 29 leads from the reactor 1 to the primary channels of four heat exchangers 31 to 34 lying parallel to one another, which are connected to the suction side of the compressors 2 to 5 via suction lines 35 to 38. The secondary channels of the exchangers 31 to 34 are connected to water or steam lines 41 to 44, 45 to 48, via which turbines (not shown) belonging to the power plant and electrical generators are driven by them.

If, for example, the compressors 2 to 4 are in operation and the load on the reactor 1 is to be increased, the procedure is as follows. The main shut-off devices 11 to 13 are open, the secondary shut-off devices 21 to 23 are usually closed. Furthermore, the main shut-off element 14 and the secondary shut-off element 24 of the compressor 5 are closed, the compressor 5 is shut down. The motor 9 is now switched on, that is to say the compressor 5 is set in motion and at the same time the associated secondary shut-off element 24 is fully opened. As a result of the relatively small flow cross-section of the throttling member 24, a small amount of CO ₂ gas is now forced out of the supply line 19 via the line 30, 28 backwards through the compressor 5 (negative conveyance). When the speed of the compressor 5 has increased so much that the pressure in lines 18, 28 has reached an amount which would be almost sufficient for positive promotion of the compressor 5, the speed is increased further and the main shut-off element 14 is fully opened. When the speed of the compressor 5 is increased, the state is now passed through in which there is briefly no flow in the compressor 5, whereupon the operating state is reached where the compressor 5 delivers positively. The gas now also flows in the compressor 5 from the suction line 38 via the pressure line 18 into the supply line 19 and the reactor 1. The system is now running with increased load.

If, with the mentioned switch-on procedure for the compressor 5, the blades during operation are adjustable and z. B. the blades or vanes or a Vorleitapparat this compressor initially are not in full operating position, full speed can be achieved with the compressor as long as the Pressure of the compressor is still below the amount necessary to positive promotion, so that also with normal operating speed of the compressor 5 gas through this in the direction of line 28 to line 38, so flows backwards. When the organ 14 is opened, the blades or the Vorleitapparat the compressor 5 gradually in the position of greatest effect, so the greatest pumping capacity to bring, whereby - at constant operating speed of the compressor 5 - the reverse flow gradually decreases, there is briefly no flow through the compressor 5 and then the normal forward flow sets in, the amount of which ultimately corresponds to that of the previously in operation Compressor 2 to 4 reached.

In another embodiment of the aforementioned load increase method, the pressure in the lines 15 to 17 about the time of opening of the organ 14, z. B. by reducing the speed or adjusting the blades or the inlet guide device in the compressors 2 to 4, slightly lowered so that the flow in compressor 5 relatively rapidly from the reverse to the normal forward direction of line 38 reverses after line 18 and the total flow rate of all four compressors 2 to 5 is about as large as the The delivery rate of compressors 2 to 4 was before compressor 5 was switched on. Pressure and Delivery rate for all compressors 2 to 5 increased evenly to the full amount.

If the load of the reactor 1 is to be reduced, the main shut-off element 14 is, for example, at Full load of compressors 2 to 4 closed; the secondary shut-off element 24 is open. Then the The speed of the compressor 5 is reduced, or the blades or the inlet guide device are reduced to a lower level Effect posed. Now there is a return flow through the compressor 5 through the line 28 after line 38, finally the element 24 is closed and then the speed continues

decreased and the compressor 5 stopped. If necessary, organ 14 can only be closed after the return flow has started.

In a modified embodiment of the last-mentioned load reduction method, first all compressors 2 to 5 are set to three-quarters load, for example. Thereupon the main shut-off element is 14 closed; the secondary organ 24 is open. Then the speed of the compressor 5 continues decreased and that of the compressors 2 to 4 increased again or the same effect by adjustment the shovels or Vorlei tapp arate achieved. Compressors 2 to 4 will soon work at full load again, and a reverse flow from line 28 to line 38 occurs at compressor 5. Then it will be Organ 24 closed and the speed of the compressor 5 decreased more and more until the compressor stopped is.

In another type of reactor system, there are no bypass lines 25 to 28 and no secondary shut-off devices 21 to 24 available. When the load increases (switch on compressor 5 to those already in operation Compressors 2 to 4) located there, then the compressor 5 - expediently in the throttled position of organ 14 - switched on and ramped up until the pressure in line 18 is close to that for positive promotion is necessary amount. The speed of the compressor 5 is then increased further, or the blades or the inlet guide device are set to a greater effect, and this is Organ 14 fully open. After a point in time at which there is no flow in the compressor 5 prevails, the normal forward flow and the normal pressure of compressors 2 to 4 then arise same operating pressure. In this example, too, the load on compressors 2 to 4 can be

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driving the compressor 5 are temporarily set to a fraction of the full load, such that - after temporary backflow through compressor 5 - all compressors 2 to 5 together for a certain period of time have the same delivery rate as before the compressors 2 to 4 operated at full load all four compressors 2 to 5 gradually brought to full load.

In the corresponding load reduction method in a system without secondary shut-off devices, z. B. the Compressor 5 is brought to a lower speed and the member 14 is brought into the throttle position. In the compressor 5 then a certain backflow occurs. The compressor is then shut down and that Organ 14 completely closed.

In all cases it is avoided that when the organs 14, 24 are closed, high energy originating from the electric motor 9 and transferred to the compressor 5 is transferred to the CO ₂ gas enclosed in the compressor in the form of heat. If the organ 14 suddenly opens, excessively hot gas cannot get into the reactor, especially into its gap element cooling spaces, via line 19. Temperature fluctuations such as would set themselves in the reactor taking into account the fact that the particularly hot gas from line 18 mixes with the gas from lines 15 to 17 in line 19 are then avoided. Furthermore, the compressor 5 itself, in particular the surface of its blades, is prevented from becoming excessively hot. Finally, the method according to the invention also prevents the reactor 1 from becoming heavily cooled. In the method in which the element 14 is only opened after the compressor 5 has reached full load, this can occur in that the initially very hot gas flowing from the line 18 into the reactor is temporarily followed by particularly cool gas that was previously was in the exchanger 34, which had not been in operation until then. The method according to the invention also avoids malfunctions of the compressor 5 to be connected, which can arise in the last-mentioned case, for example, because the compressor 5 has to convey gas of high temperature and thus greatly reduced density when organ 14 is opened during full load due to which it is not able to generate a pressure which corresponds to the pressure of the other compressors.

Claims (6)

Patent claims: 1. Load change method for a reactor power plant, the cooling gas supply several parallel Contains turbocompressors lying opposite one another, which can be switched on and off individually, characterized in that that when the load increases, one in the cooling gas supply line (18) leading to the reactor (1) is one to be switched on compressor (5) lying shut-off element (14) is already opened before the pressure generated by the compressor (5) reaches the level necessary for positive delivery has, and that thereupon the pressure on the compressor (5) to be connected up to the amount of the The pressure of the other compressors (2 to 4) is increased, while vice versa when the load drops the shut-off element (14) is only closed after the pressure to be switched off Compressor (5) has fallen below the amount necessary for positive funding, after which the the compressor to be switched off is shut down. 2. The method according to claim 1, characterized in that the pressure of the to be switched on or off Compressor (5) after actuating the shut-off device (14) by adjusting the compressor blades is changed. 3. The method according to claim 1, characterized in that the pressure of the to be switched on or off Compressor (5) after actuating the shut-off device (14) by adjusting the compressor speed is changed. 4. The method according to any one of the preceding claims, characterized in that during the load change caused by one compressor (5), the pressure on the other compressors (2 to 4) temporarily lowered and - after reaching the same pressure on all compressors (2 to 5) - the pressure on all compressors (2 to 5) brought evenly to the desired level will. 5. reactor power plant for performing the method according to any one of claims 1 to 4, characterized characterized in that in the pressure line (15 to 18) of each compressor (2 to 5) a main shut-off element (11 to 14) and parallel to it a secondary shut-off device (21 to 24) of - compared to Passage cross-section of the main shut-off element - small passage cross-section. 6. Load increase method according to one of claims 1 to 4 on a system according to claim 5, characterized in that when the motor (9) of the compressor (5) to be connected is switched on the associated secondary shut-off element (24) is opened and then the pressure on the one to be switched on Compressor (5) is increased to almost the amount necessary for positive promotion and that then the main shut-off element (14) of the compressor (5) to be connected is fully opened and the pressure is further increased to the value of the pressure of the remaining compressors (2 to 4) will. 1 sheet of drawings