DE1861106U - DEVICE ON NUCLEAR REACTORS. - Google Patents

Description

UIITED KIISDOM AIOMIO BEBRSY AUTHORITY Device on nuclear reactors

The! Firing refers to such nuclear reactors that known as reactors moderated and cooled by organic liquid (see e.g. the journal Ir .. 221 of the Geneva Conference on the Peaceful Use of Atomic Energy, 1958, Volume 9, Pages 468 to 489, by O.A. Trilling, who moderated over the experiment with the American organically cooled Reactor reports.) The purpose of the control is to improve the structure of such a reactor.

The reactor according to the innovation is composed of a standing up. Pressure vessel of generally cylindrical shape having a reactor core structure in its lower regions and a shield structure around and below the core structure and in its upper regions heat exchanger arranged in a ring around a hollow column around which extends towards the upper part of the core structure extends, wherein the pressure vessel is filled with an organic liquid, which acts as a moderator and Coolant is used and in the core structure, the shield structure and immersed in the heat exchanger, as well as from a pump to the Causing this liquid to flow in an upward direction through the core structure, along the column, through the heat exchanger as well as through and around the shielding structure and γόη there to the core structure, whereby the arrangement is as follows: that is taken from the shield that is in the shield structure is provided, in connection with the shielding within the organic liquid, the activity on the external

ren surface of the aforementioned boiler to such a degree reduces the possibility of an -AToschirmang outside the container unnecessary.

The firing is based on the "reproducing it" for example Drawing explained in more detail, namely shows.

Fig. 1 in section a ship reactor, while
3? Ig. FIG. 2 is a plan view on the line H-II of FIG. 1
reproduces.

In the drawing, a cylindrical pressure vessel 10 made of silicon steel with a diameter of about 5> 5 m and a thickness of 38 mm is provided within a forged steel housing 51 to accommodate a working pressure of 6.7 kg / cm. The container 10 is divided into an upper area 11 and a lower area 12 by an annular baffle plate 13. A reactor core structure 14 is provided in the lower region 12, which is located between an upper grid 15 and a lower grid 16
is carried and is surrounded by a reflector 17. A shielding structure 18 made of forged steel in spaced apart layers 36, which lie transversely to the path of the neutrons emitted by the reactor core structure 14, consists of two basic components, namely an octagonal side part 19 around the
Core build around and one. Base part 20 below the core structure. In the upper area 11 there are eight heat exchangers 21, each of which has a superheater section 22 and an evaporator section 23. The heat exchangers 21 are
arranged in an annular space around a hollow octagonal column 24 which extends towards the core 14 »
The column 24 is composed of an upper boron steel section 24b (which protects heat exchanger 21) and a lower forged steel section 24a.

The container 10 is filled with "Santowax R" an organic liquid moderator and coolant based on terphenyl (See the journal Ir. 1779 by CA. Trilling, 1958, Geneva Conference, Volume 29, Pages 292 to 311). The liquid has

-3-

iiiciit insignificant neutron absorption properties, is brought into circulation by four pumps 25, which are connected to outlet openings 39-in the container, and runs through external lines 48 (E ¹ Ig .; 2) and through coarse filters 4-2 and separating or Broken pipe y-valves 4-3 ». to get back into the 'container via inlet openings 4ö. The liquid then continues through the shield structure 18, through recesses 5o in the column section 24a, up through the core structure 14? along the interior of the column 24 and down through the heat exchangers 21 as indicated by arrows. The core-Binlassdruck is 6.7 kg / cm and the Kernauslasstemperatur ⁰ 37o C. It is a shunt connection 46 is provided with Yentil 47 between the heat exchangers 21 and the associated pump 25th Steam / water connections 44 are provided after the heat exchangers 21 »

The container Io is on a cylindrical shell or Base 20 held immediately above or above itself - but inside the container Io - a cylindrical one Has outer base or jacket 27, which is fastened at its inner end to an inner cylindrical base 28. A forged steel mesh 'structure 29 is at the lower inde of the base 28, the structure having eight arms 3o extending between the base 28 and a central Ring 31 extend. Below the arms 3o and the base shield 2o is a pressure vessel shield, which consists of Forged steel parts 32, 33 composed. The inside of the container Io is lined with a forged steel shield 45, which is supported at its lower end by the parts 32, 33.- The space between the shield 45 and the shielding structure 18 guaranteed for the circumferential Fluid a path with little resistance.

The base part 2o of the shield structure 18 is supported in the middle of the arms 3o and consists of a series of spaced plates 34 which are 35.perforiert suitably provided with twenty-one holes, to allow passage of the coolant and to allow the lower ends of set vertically aligned cross-shaped control bars. To preserve

For the sake of clarity, the control rods are not shown in the figures; However, they support the conventional structure and consist of 4 $ boron steel, encased in stainless steel. The control rods are moved by a mechanism that is located in standpipes 38, which are fitted with a flanged dome 37 in the Container Io are firmly connected.

The core assembly 14 is of conventional construction and has 88 fuel elements, which are located at the ends in the grids 15. Each fuel element has a tubular, with the coolant in contact housing, which includes bundles of 100 fuel rods, which are in the shape of a square grid are arranged. The G-ehäuses are arranged in a square division at a distance from each other, with the rooms serve as a moderator space between them. The fuel elements are in the grids 15, 16 under spring tension, so they withstand shock loads acting on the pressure vessel Io via the hull of the ship in which the reactor is located.

The reactor fuel consists of stoichiometric UO ₉ , which is pressed and sintered in tablet form with a density of 10.5 g / omr. The tablets are ground into regular circular cylinders with a diameter of 7.7 mm. The fuel cladding is made from vacuum melted 18/8 BTb steel. The shell has a wall thickness of 0.25 mm, "a length" of about 1.5 m and is exposed to a thermal load of 600 ° C. with the fuel pellets. The tubular G-housings are made from 18/8 stainless steel 0.13 mm thick.

The shield that is inside the pressure vessel 10 is formed around the core by the moderator layers and the forged steel, any external shielding is unnecessary. The moderator coolant, which is a hydrocarbon, slows down or decelerates fast neutrons emitted by the core 14 originate so that they can be caught by the forged steel, and also absorb decelerated or decelerated Neutrons, primarily because of their hydrogen content. A high degree of protection against radiation is achieved in this way for the container material. One can

-5-

approach the inner surface of the container IO for inspection purposes, unhindered by an external shield; since the activity of the surface is reduced to an acceptable level. The depth of the moderator in the column 24 is unnecessary the otherwise necessary steel shielding above the core 14-. Create ferrous shield assemblies 18, 20, and 45 economical neutron absorbers *

In the "Recommendations of the International Commission for Radiation Protection "- /" Recommendations of the International ö Commission on Radiological Protection "/ (Pergamon Press) the maximum radiation doses given by various Personnel categories or groups can be safely accepted or endured, and the lorm / of the organization is determined, those used in areas exposed to radiation should come, whereby the present innovation is based on these recommendations. For example are under The following values are given under normal operating conditions: Access to Reactor housing 51 for 20 minutes per week at one dose of 1 rem (biological X-ray equivalent) per week or 10 hours for a maximum single dose of 3 rem and after Shutdown of the reactor for a period of ί

I) 15 minutes, 15 minutes after shutdown for a total dose not exceeding 12 rem, or

II). 45 minutes, 5 hours after shutdown for one

Total dose not exceeding 12 rem, or

III) -8 hours per day for a 3-week repair period, starting two weeks after switching off, for a total dose of no more than 2 rem.

In addition, there is uninterrupted access to controlled areas outside the reactor housing (e.g. to the reactor control room) 8 hours per day for a dose not exceeding 0.5 rem per year »

The total heat or total heat that is in the shield 18 is generated during reactor operation / becomes coolant recirculated as the coolant through and around the shield flows around, - with the side part 19 close to the reactor-

-6-

core 14 absorbs the greater part of the coolant flow. In the parts that are remote from the core 14, there is basically a flow a small proportion to a standstill respectively .. a. To prevent stagnation. The construction requires only a few accessories for the pressure vessel, a feature that is of particular importance in ship reactor systems, the essentials Are exposed to shock and acceleration forces, whereby the accessories form weak points *

Since the coolant pressures are not very high in a reactor that is moderated and cooled by organic liquid

need to be (e.g. 7, o3kg / cm) «are the costs for the adjustment or the installation of the shielding structure 18 within the pressure (pressure area) by seeing a larger pressure vessel quite affordable.

The internal one also has an effect on the heat exchangers 41, which are arranged inside the pressure vessel Io Shielding created by the moderator liquid, the shielding structure 18 and the column section 24b is formed, favorably.

Typical dimensions for the intended shield are as follows:

Column 24 upper section 24b- 3/4 in. (19.05 mm) boron steel

lower "24a-3/4 in. (19> O5 mm) forged steel Side shield (from the core to the outside)

6 inch (152.4 mm) Santowax "., '. (Reflector 17)

4 in. (101.6 mm) steel

4 in. (101.6 mm) Santowax

4 in. (101.6 mm) steel

4 in. (101.6 mm) Santowax

6 in. (152.4 mm ") steel

1/4 in. (6.35 ii) Santowax

6 in. (152.4 mm) steel

1/4 inch (6.35 mm) Santowax

2 in. (50.8 mm) steel

30 in (762 mm) Santowax

4 in. (101.6 mm) steel (shield 45)

-7-

-7-

Boa shield. (from the core down)

6 inch (152.4 mm) Santowax (reflector 17) 3/8 inch (9.525 mm) steel (grille 16)

9 inch (228.6 mm) Santowax 3/8 inch (9.525 mm) steel (grid 16) In. (838.2 mm) Santowax 3 in. (76.2 mm) steel

3 in (76.2 mm) Santowax 3 in (76.2 mm) steel

3 in (76.2 mm) Santowax 6 in (152.4 mm) steel
Inch (457.2 mm) Santowax 3 nominal (76.2 mm) steel (shield 32)

Upper shield. (from the core up)

6 inch (152.4 mm) Santowax (reflector 17)

3/8 inch (9.525 mm) steel (grid 15)

9 in. (228.6 mm) Santowax

3/8 inch (9.525 mm) steel (grid 15)

Inch (6.35 m) Santowax

Protection claims

Claims (2)

DIPL-ING. ERICH SCHUBERT 11 "" "" T vthhV Cologne 1 00931, Essen 20362 Section: Patent attorney Dipl.-Ing. SCHUBERT, Siegen i. Westf., Qranienstrasse 14, Postfach 325 Bank accounts: Deutsche Bank AG. Oberhausen (RhId.) And Siegen branch 61 178 I / Br. , 'U 5200 / 2l'g Gm 26.6.1962 UiTITED KIIG-DOM ATOMIC ElBEGY AUTHORITY claims for protection 1.) Device on nuclear reactors with an upright cylindrical pressure vessel which includes a core structure and a heat exchanger and is provided with means is to circulate the core coolant first through the core and then through the heat exchanger to circulate through it, with the core structure in the pressure vessel at the bottom and the heat exchanger at the top, characterized in that the heat exchanger (21) extends in an annular shape around a hollow column (24) which extends downwards after the apex of the core structure (14) that the Pressure vessel is filled with an organic liquid, which acts as a moderator and coolant that a Shielding device (18) around the core structure (14) and is provided below it, and that the liquid is to flow upwards through the core structure (14), through the heat exchanger (21), through and around the shielding device (18) and from there back to the core assembly (14) is brought, the shielding extent, due to the shielding device (18) together with the shield by the liquid, the activation or the radiation intensity on the outer surface of the pressure vessel (10) on one Limited value which makes shielding outside the container (10) unnecessary. —2— 2.) Device according to. Claim 1, characterized in that that the shielding structure (18) is a number of spaced apart arranged layers (34 »36) of neutron absorbing material, the spaces between the Layers form flow paths for the liquid.