DE2148481A1 - Hydraulically operated control absorbers - for pressurised water reactor - Google Patents

Abstract

Reactor control system applicable to pressurised water reactor in which the absorber elements are evenly distributed throughout the core in vertical guide channels in the fuel elements. Multiple guide channels are provided in each fuel element and absorber position is regulated by the pressure different in the guide tube through a solenoid valve situated in the upper guide tube connecting to a pressure chamber attached to the reactor vessel dome. Absorber position is indicated by electromagnetic or electro-hydraulic systems. A pressure head tank applies excess pressure to the chamber to effect an emergency shut-down.

Description

Control and regulating device for water reactors, in particular pressurized water reactors The invention relates to a control and regulating device for water reactors, in particular pressurized water reactors, with longitudinally displaceable within the fuel assemblies adjustable rod-shaped absorber bodies. So far one has generally maintained one to combine a larger number of similarly designed absorber rods into a drive unit and thereby pulling the rods out of the core as a whole bundle, or in introduce this so that the absorption is effective or ineffective in the same amount became. A weakening of local river peaks was only possible in special cases, since these control rods each cover the entire axial core height from only one side, in particular capture from above or below, and that equally massive with a relatively large one Amount of absorber.

The invention is based on the task of improving the control and to create a control system in the sense that the absorber material is much more uniform can be distributed in the core than was previously possible. It is also intended to enable are, partial areas of the core in the radial or axial sense targeted with absorber material to apply independently,) n the respective absorber distribution.

Through this invention, your task is thus achieved (; nt, tali inside the fuel elements several guide tubes approximately evenly distributed are and in these various absorber fingers are movably arranged, whose effective parts extend over different height sections of the core.

At least one of the fingers can be designed so that the absorbent part in the most effective area, i.e. roughly in the middle of the core, is located. With other fingers, the absorber part fills in the bottom layer the upper half of the core and finally the lower half of the core for other fingers. The part of the finger rods that is not filled with absorber can be replaced by a relatively light water-filled tube should be formed, the only leadership and support tasks Has. The adjustment of the absorber fingers can be done in a simple manner by the cooling medium of the reactor itself, with the fingers grouped together in small groups be assigned to a pipeline system within the pressure vessel, which over controllable valves in connection with a space which is also located as a pressure vessel stands in which a reduced pressure is maintained. The individual absorber fingers themselves can thereby in their one end position, each with the lowest absorption effect can be used to close the pipeline almost tightly, with only a small flow of media that is sufficient for cooling is released.

The control valves in the pipeline systems can be considered incomplete sealing non-return valves are formed, which by the pressure difference in the pipeline systems are kept in a closed position.

The invention is to be explained in more detail with the aid of the drawing. the Figures show an embodiment in its essential for the invention Parts in a greatly simplified, partly schematic representation. Same parts are provided with the same reference numerals.

As can be seen ati Figure I 1 (3t, encloses a pressure vessel 1 @, @as l through an unscrewed cover 20 @@ gesch @@ ssen, in itself known way a pressurized water reactor. The core container 21 fixes the fuel assemblies 1, of which only one is drawn for the sake of clarity of illustration is, between the core support plate 22 and the upper core frame with the control rod guide insert 8. The coolant flowing through the core flows in the direction of the arrows and leaves the pressure vessel 19 along the path 51. The heat exchanger 23 produces a steam producer, whose secondary circuit is assigned to a steam power plant Im Brennelerent 1 connects a number of guide tubes 9 to the Prenneleientkopf 17 and the focal point 16 rigidly together. In such a feed tube 9 slides the absorber finger 2. The upper end position of the absorber finger is above and outside the core in the stirring tube 7 of the control rod guide insert 8.

The upper ends of the guide tubes 7 are in groups by means of pipelines 25 and control valves 27 connected to a chamber 11 below the cover 20, in which there is a reduced pressure. A pump 28 can be used to to maintain a pressure in chamber ii which is a few atmospheres lower is, for example by 2 to 4 atmospheres lower than in the space below the Kernes.

Of course, it would also be possible to remove the pump from the chamber 11 28 to be connected to a suitable point in the primary circuit, e.g. 3. right away in front of the circulation pump 24, where a correspondingly reduced pressure prevails.

The control valve 27 is in the illustrated embodiment operated by a magnet system 58. The function of the magnet system is intended on the occasion the description of Figure 3 will be explained in more detail below.

In the shut-off position, the absorption fingers are in their deepest position in the core. The magnet system 58 fttr the control valve 27 is de-energized, but the valve ball is in its upper end position, because they are caused by the pressure difference in spaces 42 and i7 when the pump is working 28 is pushed up. The PUhrtgsrohre 9 and 7 are only relative a small amount of coolant flowed through, which is sufficient for cooling the absorber fingers, but it is not big enough to carry it up with you.

This cooling flow is caused by a deliberately leaky design of the control valve 27 allows and flows from space 42 below the core through suitable inflow openings in the guide tubes 9 within the same and further through the pipelines 25 via the now tightly closing valve 27 to chamber i1. In this position there is no conceivable pressure distribution in the reactor that the absorber fingers lift, so could move away from their lowest shutdown position as long as the core structure and the control rod guide insert remain reasonably intact. To be on the safe side the design can be done in such a way that the operational pressure difference in the Spaces above and below the reactor core due to the flow resistance as a result, the core is not sufficient to even with broken guide tubes 7 the Raise absorber finger.

To lift the absorber finger is activated by energizing the solenoid 58 the valve 27 opened, in which the ball is pressed down, so that the Connection between rooms 11 and 42 becomes free. The pressure difference between these spaces, caused by the head of the pump 28 and upright is obtained causes the absorber fingers 2 within the tubes 9 to be raised and 7. The fingers are relatively wide compared to their guide tubes Game, but the arrangement is to be made so that the flowing past the finger so-called leakage is greater than this with a tight clearance in-dblicher way otherwise formed piston is the case. The delivery head of the pump 28 is natural to be dimensioned so that the pressure difference is sufficient to the absorber fingers in spite of this wide game in the Safe to raise the guide tubes.

In addition, one can think of either using the absorber finger to provide thickened areas like a piston or bottlenecks on the guide tubes to attach to the best compromise between the flow rate and the Safety against jamming of the fingers in the guide tubes to take into account.

In the top position, the fingers throttle by resting against the here the wall narrowed the flow to a minimum again. The absorber fingers stay in this position as long as no command is given, they return to the Bring rest position. To move it back to the starting position, the Magnet winding 58 is de-energized so that the control valve with the ball 27 is guided upwards is and closes, although a certain amount of leakage continues to flow through can. Now the pressure difference between spaces 42 and i1 is no longer sufficient to keep the absorber fingers in their upper end position. You fall therefore due to their gravity, go down and take their starting position again a. As mentioned at the beginning, the small amount of leakage from the upwards on the absorber fingers is sufficient The medium flowing past does not have to keep the fingers in their upper position or them to raise at all, rather it only provides the necessary cooling causes.

To prevent the absorber fingers from moving down in the event of an emergency shutdown to accelerate, a pressure accumulator 15 can be provided by its discharge temporarily cause a greatly increased pressure in the chamber 11, which the Absorber finger 2 accelerates to its lowest position, i.e. in the shut-off position, brings.

In Figure 2, a fuel assembly is illustrated with guide tubes, in the case of the stoh different absorE) er fingers are located in separate guide tubes. A fuel assembly 1 is at illustrated embodiment three Guide tubes 9a, 9b and 9c illustrated, in which the absorber fingers 2, 3 and 4 are located. The effective part of these fingers is shown hatched and extends, for example, over half the core height. It could also naturally other lengths come into consideration, 2.3. about three-quarters or the entire core height. Essential is that with a number of fingers the absorber is in the most effective In the middle of the core, while with other fingers the absorber part is in the lowest Position fills the upper half of the core, while the lower half of the core in the case of the finger 4 is applied. The part of the finger stick that is not filled with absorber will be through formed a relatively light, water-filled tube, which only funnings and Has support tasks. In front of the lower inflow openings to the guide tubes 9a, 9b and 9c, filters 10a, 10b and 10c are located in the foot 16 of the fuel assembly 1.

Further details are illustrated in FIG. Here is the one Lower part of the guide tubes 9 by a suitable constriction or expansion at the point 43 designed as a shock absorber. The upper part is centered over tubes 18 tight in the control rod guide insert 8. In its uppermost position, the finger closes with its tip 5 the flow path through the guide tubes at point 29 almost tight off. Only a small amount of working fluid used for cooling can continue enforce the pipe system.

The chamber li, in which there is a reduced pressure, is on the one hand limited by the cover 20, on the other hand by a plate 30. The plate 30 is with Bolt 31 is tightly connected to the cover, this connection when changing the fuel assembly el can be solved. The control valves 58, which are magnetic, are located in the cover 20 be operated. The valve ball 27 is moved via a plunger that can move with a lot of play 32 pushed open when the solenoid 12 is de-energized. After the tight closure A pressure-resistant hat 35 forms at the top, pointing towards the top a cylindrical Extension carries. In this Verrangerung the approach 36 of the anchor moves 33 and, together with a measuring coil 13, forms an independent display for the respective Position of the valve and thus the absorber finger.

In addition, to always prepare the upper position of a number Hydraulic and electrical display systems can report to the outside world with absorber fingers be used.

The space for hydraulic signaling is just below the constriction 29 ii guide tube connected to a flexible bellows 38 via a thin tube 37, the movement of which is sensed from the outside via the pin 39 and the measuring coil 14. An electrical sensor, e.g. a waterproof one, suffers from electrical signaling encapsulated measuring coil 40, the upper layer of the absorber finger 6 to the outside. Appropriate the leads on the measuring coil 40 go through the same openings 41 to the outside, used by the core instrumentation. A high level of operational reliability will be due to a relatively large play of the fingers in the guide tube and the upstream Filter ensures that foreign bodies cannot get in and jam the Fingers could cause fear, prevented.

The opening of the valve 27, i.e. the downward movement of the valve ball 27 takes place via the plunger 32, on which the magnet armature 33 strikes as soon as the magnet coil 12 is excited.

By utilizing the impact force of the armature, the magnetic coil 12 be dimensioned weaker than otherwise with a rigid design of the magnet system would be required. The release force of the closed valve 27 is namely great compared to the holding force when the valve is open, since in one case it is almost the full Pressure difference in the spaces 42 and 11 comes into play, while in the other Case the flow resistance of the valve ball 27 taking into account its weight of the plunger 32 is important. When the coil 12 is de-energized, the armature 33 is broken the force of the compression spring 34 moved up. If the coil 12 de-energized, the compression spring 34 lifts the armature 33, with the plunger 32 the valve ball is initially raised, but then by the flow pressure through the Leak at the point 29 is completely pushed up and thereby closes.

If several fingers are grouped together, you can do this individual or all fingers are combined in a single fuel element, as well as groups within a 3rennelementes or for several fuel assemblies together are formed.

8 claims 3 figures

Claims (8)

Claims Ql control and regulating device for water reactors, in particular pressurized water reactors, with longitudinally displaceable within the fuel assemblies adjustable rod-shaped absorber bodies, characterized in that inside of the fuel assemblies several guide tubes, preferably evenly distributed and in These various absorber fingers are movably arranged, their effective Parts extend over different height sections of the core. 2. Device according to claim 1, characterized in that at at least one of the fingers, the absorber is in the effective area, especially in the middle of the core is located. 3. Device according to claim 2, characterized in that at at least one of the fingers the absorber is in the area of the upper half of the core. 4. Device according to claim 2 and 3, characterized in that with at least one of the fingers the absorber is located in the lower core half. 5. Device according to claim 1 to 3, characterized in that the part of the finger that is not filled with absorber by a relatively light water-filled one Tube is formed, which contributes to the guidance and support of the finger stick. 6. Device according to claim 1 to 5, characterized in that the absorber fingers grouped together within a pipeline system of the pressure vessel are assigned, which also has controllable valves with a is located inside the pressure vessel chamber in communication, in which a lowered Pressure is created and maintained. 7. Device according to claim 6, characterized in that rlie Absorher catchers themselves correspond to @ rler in their end date least Absorber effect used to close the pipeline system almost tightly are, with only a small, sufficient for cooling media flow released is. 8. Device according to claim 6 or 7, characterized in that the control valves in the pipeline systems as non-fully sealing non-return valves are formed, which due to the pressure difference in the pipeline 3 systems in closed Can be held. Blank page