SK23695A3 - Nuclear reactor element, mainly absorber element - Google Patents

Abstract

A nuclear reactor element which acts as a control column consists of a fuel element (31) and an absorber element (2) coupled in the axial direction. A rod (7) extends along the axis (4a) of the cylindrical casing (4) of the overlying absorber element (2) down to the fuel element (31) and is linked thereto by a bayonet connector. To prevent the rod from falling, the rod (7) is detachably linked to the absorber element (2) and the absorber element (2) is detachably linked to the fuel element (31). The rod (7) is linked to the casing (4) of the absorber element (2) by a free-wheel coupling (6, 10, 11, 12, 13, 14, 16, 17, 18). The casing (4) of the absorber element (2) is linked to the fuel element head (30) of the fuel element (31) by a form-fitting retaining element (35, 36, 37).

Description

The element of the nuclear reactor, in particular the absorption element rmc-pr

Technical field

The invention relates to a nuclear reactor element, in particular an absorbent element, having a longitudinal casing body having an upper and a lower end and in which a guide channel coaxial with the casing body is provided for free guiding a rod which is connectable to the lower end of the longitudinal casing. an upper portion of the fuel element, and with a lower portion disposed at the lower end of the housing, representing a hollow body coaxial to the housing, and provided with a retaining element for the upper portion of the fuel element.

BACKGROUND OF THE INVENTION

Such a nuclear reactor element, designed as an absorption element, is known from the prior art

Dormitory ional Special

Publications, Fuel Reviev

1991

In this absorbent element, its lower part is rigidly connected to the housing, and the retaining element is formed as a longitudinal slot for receiving a radial pin provided on the upper part of the fuel element of the nuclear reactor. This longitudinal slot is open at the end edge of the lower part of the absorbent element facing away from the housing.

In the nuclear reactor, the rod guided in the guide channel is vertically suspended at its upper end, while its bottom end is connected by bayonet connection to the upper portion of the nuclear reactor fuel element so that the nuclear reactor fuel element hangs on the rod below the absorbent element.

In this way, although the absorbent element and the nuclear reactor fuel element are a radial pin in the longitudinal slot of the lower portion of the absorbent element, they are oriented relative to each other in a particular rotation, but if betraying the connection in the upper portion of the nuclear reactor fuel element. nuclear reactor fall.

In any case, there is a danger that the fuel element of the nuclear reactor will be damaged.

If both the absorbent element and the fuel element are chewed, the absorbent element will inadvertently reach its shut-off position in the reactor core, resulting in a decrease in nuclear reactor power.

However, if the absorbent element, for example due to the frictional contact, remains outside its switch-off position in the nuclear reactor, only water as the moderator substance is present in the reactor core instead of the collapsed fuel element. This leads to an undesirable increase in the performance of the fuel rods which still remain in the reactor core.

An undesirable increase in the performance of the fuel rods can also occur if the absorbent element, when inserted normally into the reactor core, remains suspended due to frictional contact, for example, while the fuel element of the nuclear reactor is attached to the rod.

- which is made by itself - is withdrawn from the reactor core.

It is therefore an object of the invention to prevent the above-mentioned disorders from occurring.

SUMMARY OF THE INVENTION

This is accomplished by a nuclear reactor element, in particular an absorbent element, with a longitudinal casing having an upper and a lower end and in which a guide channel coaxial with the casing is provided for free guide of the rod which is connectable to the upper part at the lower end of the longitudinal casing. a fuel element, and with a lower part disposed at the lower end of the casing, representing a hollow body coaxial to the casing, and provided with a retaining element for the upper portion of the fuel element according to the invention. which counteracts the pulling of the rod from the upper end of the casing body in the longitudinal direction of the casing by force contact between the rod and the longitudinal casing body, and that the retaining element on the lower part is capable of positive locking to the upper d The fuel element is prevented from being pulled out of the lower part in the direction of the longitudinal axis of the casing body and the lower part.

The freewheel prevents the nuclear reactor element (absorption element) from falling freely into the nuclear reactor along the rod, the holding element forming a shaped element on the lower part of the absorbing element with a similar holding element associated with the nuclear reactor fuel element between the nuclear reactor element and the nuclear reactor fuel element. so that the fuel element hangs additionally on the element of the nuclear reactor or absorption element and cannot be released from it.

The intended separation of the nuclear reactor element (absorbent element) from the fuel element can be effected in such a manner that the positive contact between the nuclear reactor element (absorption element) and the reactor fuel element is removed again. and then the element element) can be pulled along the rod (absorbent from the core fuel element).

According to a further preferred embodiment of the invention, in which the freewheel associated temperature sensor device is disposed in the housing, the force contact between the housing and the rod reversibly reverses when the temperature on the temperature sensor is less than a predetermined value; therefore, by cooling the reactor, for example by rotating the rod about its longitudinal axis, first release the connection of the rod to the upper part of the fuel element of the nuclear reactor and subsequently pull the rod out of the nuclear reactor through the absorption element.

It is then possible to first lift the absorption element from the nuclear reactor with the fuel element by means of the device.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be illustrated by way of example with reference to the accompanying drawings, in which: FIG. 1 shows a perspective and partial cross-sectional view of an absorbent element according to the invention which is connected to a fuel element of a nuclear reactor; FIG. 2 is divided into FIG. 2A and 2B and show the longitudinal section of the absorbent element of FIG. 1, and FIG. 3 shows a modified embodiment of one part of the absorbent element of FIG. 1 and 2.

DETAILED DESCRIPTION OF THE INVENTION

The absorbent element 2 of FIG. 1 and 2, the lower part 3 has a hollow cylinder shape. On this hollow cylinder-shaped lower part 3, a longitudinal casing body 4, which is designed as a hollow body, is arranged coaxially and spaced from the lower part 3. This lower part 3 is mounted in the housing 4 rotatable about its longitudinal axis and, with its collar 5 directed outwardly from the housing surface of the lower housing 3, is held in the housing 4 non-slidingly in the direction of the longitudinal axis 4a of the housing 4. the casing body 4 above one another and coaxially arranged rings 41 of a strongly neutron absorbing substance which are retained inside the casing body 4.

While the lower portion 3 protrudes from the lower end of the housing body 4 at its lower end, the upper end of the lower body 3 is located near the upper end of the housing body 4 within the housing body 4.

At this upper end, the lower part 3 carries a freewheel.

This freewheel is associated with a guide channel 6 for the rod 7, which is arranged inside the bottom part 3 and is coaxial with the bottom part 3 and the housing body 4.

For example, a freewheel constructed of three may be of the same size. 1 and 2, only one of the bodies 8 are situated in their cross-sectional plane of the free bodies 8 by which the balls are and from which they are on the body 8. The balls forming the center of each other on the bottom part 3.

All three bodies 8 have the same angular distance with respect to the longitudinal axis 4a of the casing body 4. Each of these free bodies 8 rolls on a rolling surface 9 forming an oblique plane, which is always arranged on the inner side of the bottom part 3 at the upper end of the casing body 4. Each of the oblique planes is inclined relative to the longitudinal axis 4a of the casing body 4. with the same cross-section of the housing body of the longitudinal axis 4a the same.

is a

Furthermore, the distance between the inclined planes and the distance between the inclined planes and the longitudinal axis

4a of the casing body 4 slowly decreases towards the upper end of the casing body 4, so that the body 8 can roll on oblique planes in the direction of the longitudinal axis 4a with a distance to the longitudinal axis 4a of the casing body 4 which also the end of the casing body 4 decreases slightly.

Each inclined plane at its end facing the lower end of the housing 4 is covered by a cover 10 which is fixed on the inner side of the lower part 3.

Between the cover body 10 and the respective body 8, a pre-tensioned spring 11 is formed as a coil spring whose longitudinal axis is parallel to the longitudinal axis 4a of the casing body 4. This spring 11 is subjected to pressure and bears at its one end against the cover body 10a. its other end by the free body 8.

A temperature sensor assembled from a longitudinal bimetallic body which is formed of two tubes coaxial to each other relative to the casing body 4 and therefore also to the lower part

3. The inner tube as the second metal body 13 has a greater thermal expansion coefficient than the outer tube as the first metal body 12. The inner tube is additionally part of the guide channel 6 intended for the rod 7. While the two tubes are attached at one end to each other, an outer tube at the other end secured to the cover body 10 on its side facing the lower end of the casing body 4. The other end of the inner tube is each provided with a driving body 14 for each body 8 which freely extends above the rolling surface 9 and abuts the respective body 8 in a position between the upper end of the casing body 4 and the body 8.

Furthermore, the inner tube is provided for each body 8 with a through window 15, which is a longitudinal opening extending in the direction of the longitudinal axis 4a of the casing body 4 and through which the respective body 8 can be guided in this through window 15 by force. a body 8 made of particularly hard, for example of an iron-chromium-molybdenum alloy, of a material, and may have a scoring surface.

At the end of the lower part 3, a collar 16 is provided at the upper end of the casing body 4, which is arranged coaxially with the casing body 4 and hence with the lower part 3 and which contributes to the formation of the guide channel 6. This collar 16 is provided with three vanes. 17, which have an angular distance from the sleeve with respect to the longitudinal axis.

Wearing the same at the bottom

Third

a coil spring 18 abuts, with its one end resting on the three blades 17 and at its other end resting on the shoulder 19 on the inner surface of the lower part 3. At least one of the blades is provided with a protrusion which freely protrudes into the longitudinal slot starting from the edge at the end of the bottom panel

Third

Furthermore, each blade forms a strut facing the upper end of the housing body 4. The struts 22 terminate in a ring

23, coaxial with the casing body 4, and loosely inserted in the upper part 24.

This upper part 24 is inserted in the upper end of the casing body 4 and is screwed to the casing body 4 by means of screws.

Further, at least one rib is provided outside the ring 23

26 which extends into the longitudinal notch 26a extending from the end edge of the top panel

24. formed as a hollow ace.

A portion of the lower portion protruding from the lower end of the casing body 4 extends into the upper portion 30 of the fuel element.

formed as a hollow body which is fixedly inserted in the upper end of the nuclear reactor longitudinal fuel element receptacle, where a snap-in connection 30a is connected to the receptacle by a bayonet connection 30a

31. In the receptacle 31 are arranged in a row of mutually parallel fuel rods filled with nuclear fuel.

The upper element 30 of the fuel element has transitions, for example for liquids, on the outer side of which the first coupling half 32 of the disassembled coupling (e.g., 1 ad bayonet coupling) is formed, which is coaxial with the longitudinal axis 4a of the housing. This first connection half 32 to the guide channel 6 in the absorbent element

Second

The rod 7 guided by the guide channel is provided at its end located in the first coupling half 32 with a second coupling half of this releasable coupling.

The first coupling half 32 is connected to the second coupling half 33.

Two rows of pins are provided on the upper element 30 of the fuel element

These radial pins 34 extend in each case into a circumferential slot 35, which is provided as a form-fit holding element to form perpendicularly to the longitudinal axis 4a of the hollow cylinder forming the lower part of the absorbent element. it is also possible to provide a groove and a latch on the hollow cylinder of the lower part 3, which forms a radial projection on the hollow cylinder of the lower part 3. direction of hollow cylinder reversible sliding.

However, the retaining element for making a positive fit can also be a radial depression and a radial passage in the hollow cylinder of the lower part 3.

The casing body 4 is provided at its lower end edge with at least one pin parallel to the end-longitudinal direction of the casing body

4, forming a latching device 36 which extends into a groove 37 parallel to the longitudinal axis of the absorbent element and the fuel element suspended on the rod 7 in a particular rotation.

4a of the housing

4, which extends from the edge at the upper end of the upper part

30th

When inserted into the fuel element, the absorbent element is first mounted coaxially on the upper element 30 of the fuel element such that its lower element 3 at the lower end of the casing body 4 extends into the upper element 30. The radial pins 34 are each guided by a longitudinal slot 38. the end edge of the hollow body of the lower part 3, to the peripheral slot 35.

The tool 24 is then pushed through the upper part 24 of the absorbent element 2 by means of which the sleeve 16 is moved towards the upper part 30 of the fuel element 29 against the force of the coil spring 18. At the same time rotates about the longitudinal axis 4a of the casing body 4 until the ribs 26 engage the respective longitudinal notches 26a in the upper portion 24 of the absorbent element 2. After removal of the tool, the ribs 26 snap into the longitudinal notches 26a so that the lower portion 3 is in this advance a fixed pivoting position, latched in the casing body, as desired, are located in the hollow cylinder of the lower part 3.

The rod is then finally inserted and the radial pins 34 are inserted into the guide channel in the circumferential slot 35 and the connecting halves 32, 33 are connected to each other by rotating the rod 7 about its longitudinal axis. Then, the fuel element 29, now hung on the rod 7, is pulled upwardly from the bottom into the core of the nuclear reactor, while the absorbent element 2 is pulled upward from the core of the nuclear reactor.

When the coolant flowing through the fuel element 29 and the absorption element 2 has reached its operating temperature, the bimetallic body made of metal bodies 12, 13 causes a force contact between the body 8 of the absorbent element 2 and the rod 7, which is reversible or reversible. since this force contact is again canceled after the nuclear reactor has been switched off and the coolant has cooled.

If the coupling between the rod 7 and the upper member 30, made up of the two coupling halves 32, 33, fails during operation of the nuclear reactor, the rod 7 cannot be pulled out of the guide channel 6 towards the upper member 24 of the absorbent element 2 at the upper end of the housing 4 That is, the fuel element 29 is not supported, the lie remains suspended by means of radial pins 34 on the absorption element 2, which is suspended due to the force contact between the absorption element 2 and the rod 7 by means of the bodies 8 on the rod 7.

To shut down the nuclear reactor, the fuel element 29 is again slid down from the reactor core, and at the same time the absorbent element 2 is inserted into the reactor core.

After the coolant has cooled down, the force contact formed by the bodies 8 is again canceled by the action of the respective carrier 14, so that the rod 7 can be pulled up from the guide channel after releasing the coupling with the upper element 30 of the fuel element. The reactor core can then be lifted one after the other by means of a special lifting device.

In FIG. 3 it is shown that the circumferential nip i on the hollow cylinder of the lower part 3 at its end below the longitudinal axis 4a passes sharply into the longitudinal nip 38.

angle to

At the other end, the circumferential slot 35 extends into another longitudinal slot

40, arranged between this second end and the lower end of the housing

4. In this way, it is possible to provide a rotation orientation between the upper part 30 of the fuel element 29 on one side and the lower part 3 on the other side.

so either the latching device 36.

assembled from pins and a lower edge of the housing 34.

or the sleeve 16 may fall off.

Claims (12)

PATENT CLAIMS A nuclear reactor element, in particular an absorption element (2). with a longitudinal casing body (4) having an upper and a lower end and in which a guide channel (6) is formed coaxial with the casing body (4) for free guidance of the rod (7) which is at the lower end of the longitudinal casing body (4) attachable to the upper member (30) of the fuel element (29), and with the lower member (3) disposed at this lower end of the housing (4) representing the hollow body coaxially with the housing (4) and provided with a retaining element for the upper portion (30) fuel element (29), characterized in that a freewheel is associated with the guide channel (6) inside the housing (4), which counteracts the pulling of the rod (7) from the upper end of the housing (4) in the longitudinal direction the casing body (4) by force contact between the rod (7) and the longitudinal casing body (4), and that the retaining element on the lower part (3) is capable of positive locking to block the upper part (30) of the pallet of the element (29) against being pulled out of the lower part (3) in the direction of the longitudinal axis (4a) of the casing body (4) and the lower part (3). A nuclear reactor element according to claim 1, characterized in that the retaining element belongs to the group comprising a peripheral slot (35). which is inclined relative to the longitudinal axis (4a) of the casing body (4), a circumferential groove that is inclined relative to the longitudinal axis (4a) of the casing body (4), and a radial projection. Nuclear reactor element according to claim 1, characterized in that the retaining element is provided outside or inside the jacket surface of the lower part (3). 4th The nuclear reactor element according to claim 1, wherein it is displaceable in a radial direction. 5th The nuclear element according to claim 1, wherein the lower part (3) is reversible 2 is mounted in the housing (4) rotatable about a longitudinal axis (4a) of the housing (4). A nuclear reactor element according to claim 1, characterized in that the freewheel is associated with a temperature sensor device disposed in the housing (4), which reversibly eliminates the force contact between the housing (4) and the rod (7) when the temperature is on a temperature sensor lower than a predetermined value. 7th The nuclear reactor element according to claim 1, characterized in that the freewheel is formed from a free body (8) for engagement by force contact with a rod (7) which rolls on a rolling surface disposed within the housing (4) at a distance from the housing. a longitudinal axis on the casing body (4a) which gradually decreases towards the upper end of the casing body (4) and is provided with a spring (11) which bears at one end on the casing body (4) and its the other end acts on the body (8) by a resilient force directed towards the upper end of the casing body (4). A nuclear reactor element according to claims 6 and 7, characterized in that. that the temperature sensor is an elongated bimetallic body comprising 2 first metal bodies (12), which is fixed at one end to the casing body (4) and with its other end fixed at one end of the second metal body (13), and that the other metal the body (13) has a greater coefficient of thermal expansion than the first metal body (12), and at its other end is provided with a drive body (14) on the body (8) away from the upper end of the casing body (4). The nuclear reactor element according to claim 5, characterized in that the lower part (3) is a hollow cylinder which is arranged coaxially in (4) and non-slideably in the longitudinal direction (4), and in that the casing body (4) is provided by the device (36). ) on the fuel element (29). the longitudinal casing body of the casing body axis (4a) is provided with a latching member on the upper part (30) Nuclear reactor element according to claim 5, characterized in that the lower part (3) is lockable in a predetermined pivot position in the housing (4). Nuclear reactor element according to claim 2, characterized in that the peripheral slot (35) or the peripheral groove, at its end into the lower part of the longitudinal slot (3), passes on one (40) or longitudinal groove arranged between this end of the circumferential slot (35) or the circumferential groove and the lower end of the casing body (4). Nuclear reactor element according to claim 1, characterized in that the rod (7) is guided through the guide channel (6). which is detachably connected to the upper member (30) of the fuel element (29), and that the upper member (30) of the fuel element (29) is a positive fit connection in which the holding element participates. suspended from the bottom (3).