DE2914151C3 - Fast core discharge system for bulk reactors - Google Patents

Description

The turn refers to a core fast discharge system for bulk reactors, especially high temperature reactors with spherical fuel elements, with in a (in particular on both sides from the outside by water-cooled) ringfaum below the Reactor floor with a sufficiently large surface in each case, in order to avoid an inadmissibly high influx of heat, downward-leading, with shut-off Accidental eniladurigs lines that Brerinele branch off the core collection lines, such Extraction lines are at the fuel element inlet point of the core for the withdrawal of spent fuel Elements provided and usually run vertically downwards.

A similar core rapid discharge system is also visibly from its functional principle, among other things, from the diploma thesis by H.-W. Bailly from the year 1976 known It offers the possibility of the fuel elements contained in the reactor core in one Incident when all systems that dissipate residual heat

should fail by opening the locking devices spontaneously to drain in a room with a relatively large surface, the geometry of which a significant build-up of heat

In the above investigation,

π however, the arrangement of a cavern interspersed with cooling columns directly under the reactor core over the distribution of the fuel elements in an annular space, as in the case of the A.G., given preference, with A disadvantage of the annulus concepts is the difficulty in keeping the annulus evenly to fill even if a complicated system of discharge lines is provided.

The arrangement of a receiving cavern under the tensioning chamber recommended by Mr Bailly

- '> the reactor core's concrete tank also has certain disadvantages to which static problems in the foundation / ies reactor belong Annular space concept can be solved much more cheaply. The invention is therefore based on the object that

! 0 Core fast discharge systems with an annular space in the Way to improve that a uniform and intensive heat dissipation favoring distribution of Fuel elements via the annulus is reached in a simple manner, with additional heat dissipation

i " ¹ intensifying measures should contribute to increasing the safety value of the annulus.

This object is achieved according to the invention in the case of the core rapid discharge system mentioned at the outset gelosi that the annulus floor each from the

* ° lying below the discharge line termination Point of impact of the bulk material starting on both sides in the circumferential direction d <* <; Ringraiimes with a dem Schältwinkcl the bulk body "nt corresponding inclination is sloping downward

* ' For an approximately even filling of the annulus, a sensible coordination of the annulus dimensions with the core filling should be carried out, whereby the absorption capacity of the depression lying below the plane connecting the points of impact should preferably be less than or approximately equal to half the amount of fuel that is placed on the ( a discharge line associated) annulus section between two discharge points is omitted. Such an adjustment can be made by varying

■ "Number and distance of the spherical outlets of the annulus radius · us and the annulus width can be achieved.

Fine functional design of the core Schnell discharge system according to the invention includes Fntla manure lines, which initially only incline from the horizontal by about 60 "from the fuel assembly extraction lines branch off radially outwards,

^{This more inclined section of the 1} pipes, acting as the "inlet section", merges into a main section which is inclined by about 30 ° to the horizontal and leads outwards to vertically over the annulus above which the discharge line is bent vertically downwards and preferably in a downpipe

opens, the two legs inclined by .10 ° to the horizontal in the middle of the annulus extending cylinder surface striving apart and end in two adjacent ball run-out pieces, which to the evenly over the cylinder surface distributed discharge points belong.

In practice, of course, there is no need for the Y-pipe construction (according to the annulus curvature) use curved legs, but rather the main section of the discharge line under m Taking into account the leg length lead less far radially outwards and accordingly already before the Let the cylinder surface bend.

Special attention should be paid to intensive heat dissipation possible because the up '.ί hot to about 1200 ⁰ C fuel element balls must not heat up more than 1,500 ⁰ C (by Nachwärmej to an unacceptable release to prevent fission products.

<· Invention, besides a relatively small annulus width provided an execution of the side walls of the annular space in the form of kühlmitteldurchsiromten fins walls to the ring towards the interior of a thermal insulation - inter alia, particularly from Kohlestei- ·.> - have NEN: To intensify the heat transfer is in accordance. This thermal insulation protects the fin wall, which is usually made of steel, from inadmissibly high levels of heat from the heated firing pellets

Between the inner coal stone lining and that as h> Limiting-acting fin wall, is preferably graphite powder, a plastic material, with good Thermal conductivity, as expansion compensation between the fin wall and the carbon star lining of the Fuel assembly receptacle, provided. ü

The annular space according to the invention with bottom depressions between the ball impact points shows at Observance of the above-mentioned geometrical requirements automatically ensure a complete equal distribution of the in the Annular drained balls, which in compliance with 4 » existing safety regulations (in an assumed case of damage) without difficulty, starting out from the sinks, from the ring roughness can be removed and possibly (after appropriate Check) can be used for re-loading.

This concept of reloading places consistently functioning, repeatable testable in the discharge lines Shut-off devices, which preferably have the following features: These shut-off devices > n are formed by two bar rakes that can be moved against each other and that complement each other to form a barrier wall in particular on the side facing the reactor core in the direction of the rod, spherical grooves form their bottoms by the bars dss one rake and its sides are formed by the bars of the other rake. The two rakes are particularly useful from top to bottom and from bottom to top move from the open to the closed position, in particular the bars of the rake moved from top to bottom M) into the closed position generally have an I-shaped cross-section and engage with bearing journals in recesses in the pipe wall, while the bars of the rake moved from bottom to top into the closed position, which the Complement the X-shaped bars of the other rake to form a closed wall, designed as a hollow body are and such different lengths and

beveled ends lift that the in the open position moved rake the wall provided with bushings for the rods by means of the rod ends added. At the end of the upper half of the pipe wall, the lower rake also bears a semi-reef-shaped Cover with slots for the passage of the rods moving into the closed position from above I profile.

The invention is described in detail below of the drawings. It shows

F i g. 1 a section through the left half of a mn a fast core discharge system according to the invention provided pebble bed reactor in the scheme;

F i g. 2 shows a vertical section along the central cylinder surface through the annular space (a Detail in developed form);

F i g. 3 is a schematic representation of part of the fin wall forming the annulus side wall;

F i g. 4 shows a section perpendicular to fin tubes connected to one another;

Fig. 5 the arrangement of the fin walls with vertebrae ier- and collecting lines on the Ringiärnseüen.

FIG. 6 shows a ball shut-off device for the discharge lines in the scheme;

Fig. 7 is a sketch to illustrate the interaction between the bars of the locking member;

l · ι g. 8 a section perpendicular to the barrier wall made of the interlocking bars of the barrier element with balls arranged above

According to FIG. 1 will be a rapid discharge system for a working with a pebble bed reactor core (core) 1 through an annular space 2 below the Reactor core formed, open into the discharge lines 3, from the fuel assembly extraction lines 4 of the reactor and with a Kugelabsperrorgp.n 5 and three gas shut-off valves 6 are provided.

According to the invention, the annular space floor 7 (see FIG. 2) is on both sides of the discharge duct 8 opposite ball impact point 9 inclined downwards with a natural angle of repose de. Balls corresponding inclination. This downward inclination creates depressions 10. their ball capacity below the connection plane 11 (indicated by dashed lines in the drawing) Points of impact 9 at most approximately equal to half the amount of balls received in the relevant area of the annulus (e.g. as shown in the drawing, filled in by the sum of the Sinks 10 and a right and left "Schüttberg half" 12 is formed).

According to a preferred embodiment, the discharge lines 3 initially branch at an angle of 60 ° from the horizontal) from the sampling lines 4 from. namely in the form of discharge lines which are inclined by 30 ° to the horizontal and which Form main sections of the discharge lines. These reach almost over the annulus, then kink vertically downwards and branch out in the form of a Y-pipe :, 13, the legs 14 of which with a Strive away from each other at an inclination of 30 'to the horizontal and vertically above the annular space bend downwards.

According to a special embodiment of the rapid discharge system according to the invention, the annular space 2 (of a 3000 MW _t h pebble bed reactor) has an average diameter of 50 m, and that of the six here is uniform over the circumference

Distributed fuel assembly lines 4 of the core I branching discharge lines 3 end (after their transition into a Y-pipe) in a double number of outlet openings 8, which are evenly distributed over the annulus at a distance of about 13 m. The annulus width [Ar) is 0.8 m and the mean dump height is 4.2 m.

The rope walls 15 (see FIG. I) of the annular space 2 as shown in FIG. 5 is indicated, formed by fin walls, which are shown schematically in Figure 3 and are shown in section in FIG. You insist from Kühlmitteldufchströriueh pipes 16, which through Web 17 are connected to one another. The coolant flows through distribution and collecting lines 18 and 19, which via main supports 20, 21 with a connected cooling circuit (in particular with a feed pump) are connected. The insides of the annulus are provided with thermal insulation 22 made of carbon fiber TiEJT SU; £ ck! Eide !. for them! ! "armplpifpnrle Verhinrliinir provides a plastic mass of graphite powder with the fin wall.

The ones provided in the core discharge lines S. Ball shut-off devices 5 must function with certainty in the case of need and therefore (during the normal power operation of the reactor) can be checked repeatedly without being checked even a change in the system takes place.

For this purpose, the rapid discharge lines are provided with shut-off devices, as shown in Fig. 6 The following are indicated: These locking organs are each provided by two interlocking bar rakes 23, 24 formed (see F i g. 7), the interlocking rods form a closed wall, each of which Gaps between the bars of the individual rakes are smaller than the ball diameter. Preferably the barrier wall formed in this way has spherical tabs running in the direction of the rod on the side facing the core on, the bottoms 27 of which by the rods 25 of the Rake 24 are formed while the Kugeirinnenseiten 28 formed by the rods 26 of the rake 23 moving into the pipe cross-section from below will.

The profiles of the bars 25, 26 of the interlocking rakes shown in detail in FIG a mechanically particularly expedient behavior of the slide bars, which, however, also - apart from the Ball grooves forming flanks - could be designed similar in general.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1.Core rapid discharge system for bulk reactors, especially high-temperature reactors with spherical fuel elements, with in one (in particular on both sides cooled from the outside by water) annulus below the reactor bottom each with a sufficiently large surface to avoid an unacceptably high build-up of heat, downward discharge lines provided with shut-off devices leading from the fuel assembly extraction lines branch of the core, characterized in that the annular space floor (7) each from the one below the discharge line mouth (8) lying point of impact (9) of the bulk material starting on both sides in the circumferential direction of the annular space (2) inclined downwards with an inclination corresponding to the angle of repose of the bulk bodies is. 2. Entlaii-'ngssystem according to claim 1, characterized due to discharge lines inclined by about 30 ° to the horizontal in their main section (3) with inlet sections branching off from the extraction lines (4) at an angle of about 60 ° and an outlet piece bent vertically downwards. 3. Discharge system according to claim 2, characterized in that the vertically downward bent extraction lines (4) each open into a Y-pipe, both of which by 30 ° against the Horizontal inclined legs (14) running in the cylinder surface going through the annular refill Strive apart and jnHen in two adjacent ball outlet pieces (8) that lead to the evenly outlet points that are venous over the cylinder surface belong. 4. Discharge system according to one of the preceding claims, characterized in that the Side walls (15) of the annular space (2) with an inner fin walls through which coolant flows Thermal insulation (22) preferably constructed from coal bricks, with a plastic mass with good thermal conductivity to absorb differences in thermal expansion of the Overall system is provided. 5. Discharge system according to one of the preceding claims, characterized by repeatable Shut-off elements (5) in the discharge lines (3) in the form of interlocking Rod rakes (23, 24), which in particular have grooves for fuel element balls Add the barrier wall perpendicular to the discharge tube axis.