BG99288A - Element of a nuclear reaction, in particular absorber element - Google Patents

Abstract

The element has a longitudinal position housing (4), coaxial leading canal (6) for free insertion of a bar (7) and, at the lower housing end (4) there is a coaxial hollow body as a toe of the element (3) to which bar (7) is fixed. A connector for the free move of the bar (7) is fitted in the integral canal (6) to ensure the locking, and the profile locking element is designed to block the head of the fuel element (30) against any removal of the toe of element (3) out in the direction of the longitudinal axis (4a) of the housing (4) and the toe of element (3) by mean of profile connection.

Description

The invention relates to an element of a nuclear reactor, preferably an absorber element, with a longitudinally arranged, having upper and lower end casing, in which an element is formed coaxial to the casing guide channel for free insertion of a rod that engages at the bottom end of the longitudinal housing to the head of the fuel element of one longitudinally positioned combustible fuel stem with a nuclear fuel _f fuel element of a nuclear reactor, and of a heel located at that lower end of the housing which is a coa Housing body is hollow body and has a profile mounting element for the fuel element head.

One such element of a nuclear reactor designed as an absorber element is known on page 50 of Nuclear Engineering

International Special Publications, Fuel Review 91. ^In addition ^{to this} absorber element, the heel of the element is rigidly connected to the housing, and the profile fixing element is a longitudinal slot to accommodate the head of the nuclear reactor fuel element, a radial pin. This longitudinal slot is open at the end face of the element facing the sheath. In a nuclear reactor, the rod inserted through the leading channel is suspended vertically at the upper end while the lower end is locked. with a bayonet connector at the head of the fuel element to the fuel element of the nuclear reactor, so that the fuel element of the:: nuclear reactor is suspended on the bar beneath the absorber element. In this way, the absorber element and the fuel element of the nuclear reactor are oriented rotatably with respect to each other by the radial pin in the longitudinal slot of the heel of the element of the absorber element, however, if the connection in the head of the fuel element of the nuclear reactor fails or is damaged. , the fuel reactor of the nuclear reactor may drop the fuel element of the nuclear reactor alone or together with the absorber element. In any case, there is the risk of damage to the fuel element of the nuclear reactor. If the absorber element falls together with the fuel element, then the absorber element unwanted reaches its shutdown position in the reactor core and this results in a decrease in power in the nuclear reactor. If, for example, due to the friction link, the absorber element remains out of position in the reactor core, then the latter, in place of the fallen fuel element of the nuclear reactor, is only water, as a retardant. This results in an unwanted increase in the capacity of the fuel stalks remaining in the reactor core. Finally, it can also occur when, upon normal insertion of the absorber element into the reactor core, for example, due to the frictional connection, it remains suspended while the linkage on the rod of the nuclear reactor - as it is reliably removed from the reactor core.

The invention seeks to exclude damage of this kind.

In order to accomplish this task, an element of a nuclear reactor of the type mentioned above, according to the invention, should be characterized in that a freewheel clutch is provided to the leading channel inside the housing, which counteracts the removal of the rod from the above the end of the housing in the longitudinal direction of that housing, through a forceful, dynamic connection between the rod and the longitudinally located housing and that the profile locking element of the heel of the element is adapted to block the withdrawal of the combustion head from etat of the element along the longitudinal axis of the housing and fixed by the splined connection (assembly) the fifth element. The freewheel clutch prevents the nuclear reactor element (absorber element) from falling freely into the reactor core along the rod, while the profile fixing element of the heel of the rod forms with the profile element attached to the fuel reactor of the nuclear reactor (fitting) between the nuclear reactor element and the nuclear reactor fuel element, such that the nuclear reactor fuel element is further attached to the nuclear reactor element and cannot be discharged therefrom.

The purpose of separating the nuclear reactor element (absorber element) from the nuclear reactor fuel element can generally be achieved by having a profile joint (assembly) between the nuclear reactor element (absorber element) and the nuclear fuel element the reactor was released again and then the nuclear reactor element (absorber element) was drawn longitudinally on the rod from the nuclear reactor fuel element.

In another embodiment, the freewheel clutch is provided with a housing with a temperature sensor, which releases the reversible (reversible) power connection between the housing and the rod when the temperature of the temperature sensor is less than one, in advance set point, it is possible, with the j / cold reactor switched off and on, for example by rotating the rod around its longitudinal axis, to first release the rod connection with the head of the fuel element of the fuel element therein. and then remove the rod from the nuclear reactor by means of the absorber element. ^ Finally, by means of a lift mechanism, the absorber element and then the fuel element of the nuclear reactor can be pulled first from the nuclear reactor.

The invention and its advantages are explained in more detail by way of an exemplary embodiment shown in the drawings: FIG. 1 shows a perspective view and partial sectional view of an absorber element of the invention that is coupled to a nuclear reactor fuel element FIG. 2 is divided into sections 2A and 2B and shows in longitudinal section the absorber element 'according to Figure 1.

FIG. 3 shows a modified separate part of the absorber element according to FIGS. 1 and 2

The absorber element 2 of FIGS. 1 and 2 has a hollow cylinder shaped element heel 3. On this hollow cylinder shaped element heel 3 is arranged coaxially and at a distance from the heel of the element 3 consisting of a hollow body, longitudinally disposed housing 4 This member of the element 3 is supported by a sliding-io possibility of rotating about its longitudinal axis in the housing 4 and by means of a bearing connection beyond the surface of the housing of the heel of the fuel element 3 is kept stationary in the direction of the longitudinal axis 4a of the housing 4. further between the heel of the ele HTA 3 and the casing 4 are arranged one above the other and coaxially with each other rings 41 of highly absorbent material neutrons and they are retained within the housing 4.

While the heel of the element 3 is shown with its lower end outside the lower edge of the housing 4, the upper end of the heel of the element 3 is located inside the housing 4, near its upper end.

At this upper end, this heel of element 3 carries the freewheel connector. This stroke coupling corresponds to a guide groove 6 for a rod 7 which is located in the interior 5 of the heel of the element 3 and is coaxial to the heel of the element and the housing 4.

The freewheel connector has three freewheel locking bodies 8 which are, for example, equally large spheres and only one single locking body 8 is shown in Figures 1 and 2. These spheres with their spherical center points are always at one another in a transverse plane of the heel of the element 3.

All three retaining pin 8 have the same angular distances to each other with respect to the longitudinal axis 4a of the housing 4. Further, each of these free retaining bodies 8 is rolled on a slanting plane, a rolling surface 9 about which is located on the inside of the heel. per item. each of the inclined planes is inclined at the same angle to the longitudinal axis 4a of the housing 4 and in the same cross-section of the housing 4, the distance of the inclined planes to the longitudinal axis 4a of the housing 4 are the same. Further, the distance between the inclined planes and the longitudinal axis 4a of the housing 4 decreases gradually in the direction of the upper end of the housing 4, so that the fixing bodies 8 can also roll away from the longitudinal axis 4a of the housing 4 on the inclined planes in the direction of this longitudinal axis 4a, which gradually reduces the distance in the direction of the upper end of the housing 4.

Each inclined plane of its facing edge to the lower end of the housing 4 is covered by a cover body 10 that is secured to the inside of the heel of the element 3. Between the cover body 10 and the corresponding retaining body 8 is formed by a coil spring 11 whose longitudinal axis is parallel to the longitudinal axis 4a of the casing 4. This spring 11 is tense and with one end rests on the roof body 10 and the other end with the free locking body 8.

One temperature sensor consists of a longitudinally arranged bimetallic body, which is formed by two coaxial to each other and to the housing 4 and thus to the heel of the element 3, pipes. The inner tube as the second metal body 13 has a higher thermal expansion coefficient than the outer tube, referred to as the first metal body 12, which houses the inner tube. In addition, the inner tube forms a portion of the leading groove 6, which is designed for the pinch 7. While the two pipes are attached to each other at one end, the outer tube at the other end is secured to the side facing the lower end of the housing 4. of the roof body 10. The other end of the inner tube has one clamping body 14 for each locking body 8, which is freely fastened above the rolling surface 9 and grips behind said locking body 8 between the upper end of the housing 4 and this locking body 8.

Further, the inner tube has a through window 15 for each locking body 8, which is positioned along the longitudinal axis 4a of the housing 4, a longitudinal opening and through which the corresponding locking body 8, which can be forcefully assembled to the rod, through the passage window 15. . It is advantageous for each retaining body 8 to be made of a particularly rigid material, for example an alloy of iron-chromium-molybdenum, and to have a grooved outer surface.

At the end of the heel of the element 3, at the upper end of the housing 4 there is a socket 16 which is coaxially located on the housing 4 and also on the heel of the element 3 and participates in the formation of the leading channel 6. This socket 16 has three blades outwards. 17, which conclude the same angle with respect to the longitudinal axis of the sleeve 16. These blades 17 lead freely (with clearance) the sleeve 16 in

Τϊ heel of element 3. On these blades 17 there is a spiral spring 18 which with one end rests on the three blades 17 and with the other end rests on one arm 19 on the inner surface of the heel of element 3. - less than one of the blades 17 has a tongue 20 that engages it freely, but extends from the edge of the end of the heel of the element 3, longitudinal slot 21.

Further, each blade 17 forms a prong directed to the upper end of the housing 4 supports 22. The supports 22 terminate in a coaxial to the housing 4 ring 23, which is freely supported in one head 24. This head 24 is located at the upper end of the housing 4 and is screwed securely with screw 25 to this housing 4.

Outside of the ring 23 is located at least one rib 26 which engages in a projecting head 24 formed from a hollow body extending from the end edge of the hollow body 26a.

The portion of the heel of the element 3 projecting from the lower end of the housing 4 is inserted into a hollow body of the fuel element 30 that is fixedly fixed at the upper end of the housing of the fuel element 31 of the longitudinally located nuclear fuel element reactor there and locks it to the housing element 31 through a bayonet connector 30a.

In the housing of fuel element 31 are arranged multiple, parallel to each other, filled with nuclear fuel, fuel stalks. The head of the burner element 30 is provided with openings, for example, for liquid. The bottom, on the outer side of which coaxially forms on the longitudinal axis of the casing 4, a first coupling half 32 of a releasable coupling (eg bayonet coupling). This first connecting half 32 is open to the guide channel 6 in the absorber element 2. The rod 7 passed through the leading channel 6 has at the end of the first connecting half 32 one second connecting half 33 of this releasable connection. Its first connecting half 32 is connected to the second connecting half 33.

At the head of the fuel element 30, two radial pins 34 are located on its inner surface. These radial pins 34 enter respectively into a peripheral slot 35, which is located as a profile locking element (due to its shape element) inclined at right angles to the longitudinal axis 4a of housing 4 in the hollow cylinder of the heel of the element element 3 of the absorber element 2. Instead, a peripheral groove (channel) may be located on the outside of the housing of the housing of the hollow cylinder of the element 5's heel. The profile locking element may also be a single lock or a blade that form a radial projection in the hollow cylinder of the heel of the element, which is movable back and forth in the radial direction of the hollow cylinder. The profile locking element may also be a radial recess and. radial passage in the hollow cylinder of the heel of the element 3.

At its lower end, at its end edge, the housing 4 has at least one longitudinally parallel to the housing 4 of the neck as a locking element 36 which engages the rotating element of the absorber element 2 and the fuel element of the nuclear reactor 29 hanging on the rod 7. in a corresponding groove 37 extending from the edge of the upper end of the head of the fuel element 30 parallel to the longitudinal axis 4a of the housing 4a.

In operation, the absorber element 2 is coaxially inserted first into the fuel element of the nuclear reactor 29 coaxially on the head of the fuel element 30 of the fuel element of the nuclear reactor 29 so that the heel of the element 3 at the lower end of the housing 4 enters the head of the fuel element 30. In this case, the radial pins 34 are inserted through an exiting edge of the hollow body of the heel of the element 3, a longitudinal slot 38 to the peripheral slot 35.

Then a tool is inserted through the head 24 of the absorber element 2 to move the sleeve 16 in the direction of the head of the fuel element 30, overcoming the force of the coil spring 18. At the same time, the sleeve 16 is rotated with the tool 22 attached to the supports. in addition, the hollow cylinder of the heel of the element 3 about the longitudinal axis 4a of the housing 4 until the ribs 26 can enter the corresponding grooves (slots) 26a in the head of the element 24. After removal of the tool ^ the ribs 26 engage in the grooves 26a yes That the heel element 3 is fixed in this predetermined angular position of rotation of the casing 4 and the radial pins 34 as desired, are located in the circumferential groove 35 in the barrel of the heel element 3.

Finally, the bar 7 is inserted into the guide groove 6 and the connecting halves 32 and 33 are connected to each other by rotating the bar 7 about its longitudinal axis. The fuel reactor element 29 of the nuclear reactor 29 is then drawn inwardly upward into the nuclear core of the nuclear reactor, while the absorber element 2 is drawn upward from the reactor core.

Once the coolant flowing through the fuel element of the nuclear reactor 29 and the absorber element 2 reaches its operating temperature, the bimetallic body formed by the two tubes 12 and 13 causes, through the locking bodies 8, a dynamic connection between the housing 4 of the absorber element 2 and the rod 7, which is reversible, since this dynamic power connection is released again after shutting down the nuclear reactor and cooling the coolant.

If the connection formed between the connecting halves 32 and 33 between the rod 7 and the head of the fuel element 30 during operation of the reactor, the rod 7 cannot be withdrawn from the guide channel 6 towards the head of the element 24 at the upper end of the housing 4. This means that the fuel element of the nuclear reactor 29 is not supported but remains suspended by the radial pins 34 of the absorber 21 element, which in turn, due to the power dynamic connection / assembly / between the absorber element 2 and the rod 7 through locking bodies 8 hangs on rod 7. To shut down the nuclear reactor, the fuel element of the nuclear reactor 29 is again drawn down from the reactor core and at the same time the absorber element 2 is transported inward into the reactor core.

After cooling the coolant ^, the power dynamic link is again released through the locking bodies 8 by actuating the respective gripping body 14 so that the rod 7 can be pulled upwards from the guide duct to the head of the fuel element 30. After releasing the coupling 30. a special tool can be pulled up from the reactor core one after the other first, the absorber element 2 and then the fuel element of the nuclear reactor 29.

As shown in Figure 3, the peripheral slot 35 may deviate from this longitudinal slot 38 in the hollow cylinder to the heel of the element 3 at one end of the slot, at an acute angle to the longitudinal axis 4. 4a and the longitudinal slot 38. At the other end of the slot, this peripheral slot 35 passes to another longitudinal slot 40, which is located between that other end of the slot and the lower end of the housing 4. In this rotational orientation between the head of the fuel element 30 of the fuel element of the nuclear reactor 29, on the one hand, and the heel of the element 3, on the other hand, is ensured that the locking element 36 consisting of the neck at the lower edge of the housing 4 or the socket 16 may be dropped.

Claims (12)

Patent Claims A nuclear reactor element, in particular an absorber element (2), having a longitudinally arranged housing having an upper and lower end casing (4) in which a coaxial guide passage (6) is formed coaxially to the casing (6) one rod (7) that engages at the lower end of the longitudinally housed housing ($) to the head of the fuel element (30) of one longitudinally positioned, having fuel stalks with nuclear fuel, nuclear reactor fuel element (29), as and with one located at that lower end of the housing (4) a heel of the element (3) which is coaxial to - a hollow body (4) having a hollow body and having a profile fixing element for the head of the fuel element (30), characterized in that a freewheeling counter is provided on the guide channel (6) inside the housing (4) which counteracts of removing the rod (7) from the upper end of the housing (4) in the longitudinal direction of that housing (4) by a force dynamic connection between the rod (7) and the longitudinally located housing (4) and that the profile locking element of the heel of the element ( 3) is capable of blocking the removal of the fuel element head (30) from the heel element (3) in the direction of the longitudinal axis t 14a) of the housing (4) and secure the heel of the element (3) by means of a profile connection (assembly). Nuclear reactor element according to claim 1, characterized in that the profile fixing element belongs to the group: a peripheral slot (35) that is inclined to the longitudinal axis (4a) of the housing (4), a peripheral groove (37), which is inclined towards the longitudinal axis (4a) of the housing (4). a radial recess and a radial passage, as well as a radial protrusion Nuclear reactor element according to claim 1, characterized in that the profile fixing element is located externally or internally on the surface of the casing of the heel of the element (3). A nuclear reactor element according to claim 1, characterized in that the radial projection is movable backwards in a radial direction Nuclear reactor element according to claim 1, characterized in that the heel of the element (3) is mounted in a casing (4) capable of rotating about a longitudinal axis (4a) of that casing (4) Nuclear reactor element according to claim 1, characterized in that a temperature sensor device is provided in the freewheel clutch (4), which releases the reversible force dynamic connection / assembly / between the housing (4) and the rod (7) when the temperature on the temperature sensor is less than one preset value. Nuclear reactor element according to claim 1, characterized in that the freewheel connector has a loose locking body (8) for a force dynamic connection to the rod (7), which rolls into one located inside the casing (4 ) a rolling surface (9) at a distance from the longitudinal axis (4a) of the housing (4), which gradually diminishes, viewed in the direction of the upper end of the housing (4) and is provided with one end supported on the housing (4) a spring (11) which, with its other end, exerts a spring pressure directed at a the arched end of the housing (4), on the retaining bodies (8). • · Nuclear reactor element according to claims 6 and 7, characterized in that the temperature sensor is a longitudinally arranged bimetallic body with one first metal body (12), which is attached at one end to the housing (4) and to the other end. its end to one end of one second metal body (13) and that the second metal body (13) has a greater coefficient of thermal expansion than the first metal body (12) and at its other end has a gripping body (14) for the locking body (8), located in the direction opposite to the upper end of the housing (4). A nuclear reactor element according to claim 5, characterized in that the heel of the element (3) is a hollow cylinder which is coaxially arranged in a longitudinally arranged casing (4) and stationary in the direction of the longitudinal axis (4a) of the casing (4) and that the housing (4) has a locking element (36) for fixing to the head of the fuel element (30). Nuclear reactor element according to claim 5, characterized in that the heel of the element (3Ϊ can be fixed in a predetermined angular position of rotation to the housing (4). A nuclear reactor element according to claim 2, characterized in that the peripheral slot (35) or. the peripheral groove (37) in the heel of the element (3) passes at one end of the slot, respectively the groove in one longitudinal slot (40), respectively. a longitudinal groove located between this end of the slot of the peripheral slot (35) or. on the peripheral groove and the lower end of the housing (4). A nuclear reactor fuel element according to claim 1, characterized in that an ad? a rod (7) which is fixed to the head of the fuel element (30) by means of a releasable connection and that the head of the fuel element (30) is attached to the heel of the element (3) by a connection with a special profile, which includes the profile lock element.