EP2204820B1 - Radiation screening enclosure - Google Patents

Abstract

The multi-layered radiation protection wall (110) for the screening of gamma and/or particle radiation consists of a sandwich construction of at least one first (120) and second (130) layer arrangement, whereby the first layer arrangement has at least one primary screening layer (122,124) and the second layer arrangement has at least one secondary screening layer (132,134,136). At least one of first and second layer arrangements is divided into a number of sub-sections (7-12; 13-16). An independent claim is included for a radiation protection chamber (1) for a reaction platform on a particle accelerator and which is equipped with the aforesaid multi-layered radiation protection wall.

Description

Field of the invention

The invention relates to a radiation protection chamber having a multilayer radiation protection wall for shielding gamma and / or particle radiation, in particular for radiation shielding of a reaction site on a high-energy accelerator installation.

Background of the invention

High-energy accelerators for particle beams are being used more and more frequently worldwide. The intensity and energy are constantly increased. Currently, proton accelerators with energies up to the range of tera-electron volts (TeV) are planned, and there are proton accelerators with energies up to several gigahertz electron volts (GeV) and intensities of up to 10 ¹⁶ protons / sec, eg for spallation sources planned.

The latter accelerators are not only planned for basic research as a neutron source, but are also discussed as nuclear facilities for power generation, with which subcritical arrangements with an additional neutron flux can be brought into a critical state. Furthermore, these plants can also be used for so-called inoculation, where long-lived radioactive substances are converted into short-lived.

One problem with operating high energy accelerators is the production of high energy secondary radiation in the target areas (target of the particle beam in which it is deposited) or beam losses during transport on the path of the beamlines of the high energy or primary beam towards the target.

While the charged particles generated in nuclear reactions are often stopped in the structure of the accelerator, the generated neutron and gamma radiation has a high permeability even by meter-thick shields. At very high energies, pions are also generated, among others, which break down into muons. The latter also have very long ranges and must be stopped in special jet killers.

For heavy ion accelerators, the situation is even more difficult, since even at lower intensities similar production rates for secondary radiation occur compared to proton accelerators.

The production of radiation at such accelerator systems has so far led to the installation of mostly very massive shields at the beam loss locations. Concrete or iron was often used as shielding material, as in nuclear technology. Such concrete shields consist of solid cast walls and ceilings, but also individual shielding modules can be assembled as individual parts form an overall shield.

For special requirements on the shield, in addition to normal concrete with typical densities in the range of 2.3 g / cm ³ , heavy concrete types with corresponding aggregates such as magnetite, limonite or barite concrete with densities of up to 3.6 g / cm ³ can be used (see also DIN 25413). In practice, however, usually normal concrete is used in the sense of optimizing costs and the achieved screening result.

The production of radiation depends on the type of radiation, the energy, the intensity and the loss rate. The shielding thickness also depends on the limits to be observed by the national legislation to be observed. The limit values are defined as annual dose limits or related to the dose rate in μSv / h.

Recently, there have been proposals to use shielding arrangements with bulk material. As a bulk material, e.g. Gypsum proposed. Although naturally occurring materials have been poured around these plants as earth, but not directly included in the shield. On the other hand, the use of natural substances in the shield arrangement results in the problem of deactivation since these substances are relatively close to the sources.

From the patent applications DE 103 27 466 (Forster ) and DE 103 12 271 A1 (Brüchle et al. ) gypsum is known as an alternative material for structures for radiation protection structures or shields of high-energy accelerators, which have also proven to be suitable shielding materials.

The use of such shields, which use bulk material as the shielding material, brings about a number of improvements, but the previous developments and proposals for the construction of shields for accelerator systems have mostly been designed with particular regard to the shielding effect.

However, another important and, according to the knowledge of the inventors so far in part insufficiently considered, effect addressed by the present invention is the activation of the radiation protection materials, in particular the generation of radioactivity by the secondary radiation, which triggers nuclear reactions in the shields. In this unwanted side effect, the generation of radionuclides is mainly caused by spallation reactions by protons and neutrons in the shielding layers. By evaporation of nucleons and clusters, a variety of radionuclides can be generated. This problem is aggravated by the fact that the heavier the target core of the shielding material used, the greater the variability of the radionuclides produced.

wobei F_i die tatsächliche Aktivität pro Masse und Radionuklid ist und über alle Radionuklide (i) summiert wird.If the shielding uses natural materials that should be returned to natural use after the plant has been used, the level of radioactivity generated must be below certain limits in order to comply with national legislation. For example, for the unrestricted release of substances under German radiation protection law, a nuclide-specific release value A _i in Bq / g must be undercut. For multiple radionuclides, the total exhaustion must be determined by applying the sum rule be less than one. The total exhaustion G is defined as: $$G={\displaystyle \underset{i=1}{\overset{\mathrm{Max}}{\Sigma }}}\frac{A_i}{F_i}.$$

where F _{i is} the actual activity per mass and radionuclide summed over all radionuclides (i).

Although, according to German law, in addition to the unrestricted release, there is another limit to the restricted release (releasable for disposal), however, as far as possible from any legal limit values, the lowest possible activation is desirable.

Calculations by the inventors have shown, however, that when operating a high-energy accelerator system at very high intensities over several decades, the shielding materials used are so strongly activated that they are not even after release of the system and in the decommissioning phase, not even limited release and under Be stored for a few years or decades before they can be released. This also applies to natural fillers (earth, sand, water, etc.), which are used precisely because they should be returned to natural use as soon as possible after the end of the use of the plant. However, if their exhaustion is above the legal limits, this objective can not be achieved, as the materials are either stored over a long period or under storage enormous costs would have to be disposed of as radioactive waste.

From the patent application DE 103 27 466 A1 is a manufactured in sandwich construction structure for a radiation protection structure known. However, this is based on proton treatment rooms for the medical sector, whose requirements are not comparable due to the much lower energies.

From the JP 62032395 A is a radiation shield with two radiation shields known. However, this document essentially deals with a fastening device with a threaded rod, a stainless steel nut and a recessed ceramic nut, by means of which the two radiation shields are screwed.

In summary, in particular, multi-layer radiation protection arrangements or walls for high-energy accelerator systems with regard to the radioactive activation of the materials and their Abklingverhalten continue to improve, based on the operation of several years or decades of high beam energies and intensities and the subsequent disposal. This aspect is of particular importance when natural shielding materials are used which, on the one hand, are radioactively activated after use of the system and, on the other hand, have little experience in dealing with large amounts of these substances.

General description of the invention

The invention is therefore based on the object to provide a radiation protection chamber with a multi-layer radiation protection wall, in particular for shielding high-energy gamma and / or particle radiation from high energy and / or nuclear reactions, which even after a long period of operation and high beam energies and intensities with respect to the subsequent disposal of the materials used has good manageable radioactive activation and their constituents are at least partially recyclable.

Yet another object is to provide such a radiation protection chamber for a high-energy accelerator system in which as little as contaminated material to be disposed of during decommissioning and as much material as possible under the predetermined limits and can be reused.

In particular, it is an object of the invention to provide a radiation protection chamber, which are inexpensive to manufacture, build, dismantle and dispose of with little effort.

Another object is to provide such a radiation protection chamber which avoids or at least reduces the disadvantages of known shields.

The problem is solved in a surprisingly simple way already by the subject-matter of patent claim 1. Advantageous developments of the invention are defined in the subclaims.

According to the invention, a radiation protection chamber with a radiation shield wall positioned downstream is provided for shielding high-energy gamma and / or particle radiation, in particular from high-energy and / or nuclear reactions, generated by primary radiation in the range above 1 GeV, in particular above 10 GeV or even higher. Hereby, preferably, the radiation is shielded or attenuated from a reaction site at a high energy particle accelerator facility. The radiation to be shielded is in most cases secondary radiation, which results from a reaction of the primary beam with a target, but may also be a remainder or part of the primary beam itself.

The radiation protection wall has a sandwich-type construction of at least one first and second layer arrangement, wherein the first layer arrangement comprises at least one primary shielding layer and the second layer arrangement comprises at least one secondary shielding layer, which in particular consists of different materials and is functionally different.

In order to be able to shield the high-energy radiation effectively, the primary shielding layer is preferably formed as a spallation layer and the secondary shielding layer is preferably in the form of a moderation layer.

According to the invention, the first or second layer arrangement, particularly preferably both, are formed in several parts or into a plurality of adjacent and already predefinably separable during the construction subsections divided, so that a simple, separate dismantling and a separate and selected recycling or disposal of the sections are possible. The subdivision into subsections can be realized by division into a plurality of adjacent separate moderation layers and / or spallation layers and / or by lateral (transversely to the layer plane) division of the moderation layer (s) and / or the spallation layer (s).

This has the enormous advantage that in the planning of the radiation protection wall, or a radiation protection chamber, so-called "cave", which is at least partially built up from such radiation protection walls, can already be divided into sections with predictable high radiation exposure and those with predictable low radiation exposure and this Subsections are separable or separable constructed to dispose of the higher and less highly irradiated sections separately during deconstruction and / or to be able to recycle. As a result, the disposal costs can be significantly reduced.

In other words, according to the invention, the subsections which experience a high activation by the operation are separated from the subsections which, although having a shielding effect and, to a lesser extent, a deactivation, ie lower in their activity level. These layers, which may contain, for example, natural substances and are activated only slightly, are soon after the end of use again without restriction or at least released for release and are then available again for natural use. However, it is apparent that the invention is not limited to the Compliance with any national limit regulations.

The more heavily activated subsections are either temporarily stored after decommissioning of the plant or continue to be used in other similar nuclear facilities.

Preferably, the first and / or second layer arrangement are in turn separable multilayered. In other words, the first layer arrangement comprises a plurality of 2, 3 or more spallation layers and / or the second layer arrangement comprises a plurality of 2, 3 or more moderation layers in order to achieve a separability along the layer normal in addition to the lateral separability. As a result, the deconstruction planning in the design in two dimensions - in polar coordinates azimuthally and radially - can be adapted to the expected radiation exposure, so that a two-dimensional modular or differentiated deconstruction is possible.

These advantages are particularly useful if the moderation layer (s) and / or the spallation layer (s) are formed as bulk material layer (s), since a separate deconstruction is particularly easy to accomplish here.

In order to confine the bulk material layers, the radiation protection wall on both sides of the spallation layer (s) and the moderation layer (s) has a solid static concrete support layer. Furthermore, between the spallation and moderation layers or layers of bulk material (thin) Partitions, eg made of concrete, intended to ensure separate disposal. On the front side, laterally adjacent sections of bulk material layers are separated from one another by separating elements. In other words, the separating layers and separating elements form contiguous containers or filling spaces into which the spallation material or the moderation material is filled so as to form the two-dimensionally sectioned radiation protection wall with spallation material and moderating material which are separated from one another.

• eine erste feste (Beton-)Tragschicht,
• eine Spallationsschicht
• eine erste Trennwand
• eine erste Moderationschicht
• eine zweite Trennwand
• eine zweite Moderationschicht
• eine zweite feste (Beton-)Tragschicht.

According to a particularly preferred embodiment of the invention, the radiation protection wall at at least one lateral position, in particular in a central region at least following layer structure downstream in the following order:

• a first solid (concrete) base course,
• a spallation layer
• a first partition
• a first moderation shift
• a second partition
• a second moderation shift
• a second solid (concrete) base course.

Preferably, several or all of the moderation layers or sections contain (more than 50%) mainly elements with an atomic number less than 30 or consist of such. These elements are particularly suitable for the moderation of light core fragments and nucleons. For moderation, especially of neutrons, moderation layers of gypsum or other materials with bound water, have proven to be particularly suitable. But also liquid sections or Layers, eg of water are conceivable. In addition, it has been found that ordinary earth excavation, sand, gravel, feldspar, lime feldspar, potash feldspar or similar natural raw materials can also be used as moderation layer (s).

On the other hand, the spallation layer (s) disposed on the upstream side of the moderation layer (s) mainly contains (more than 50%) elements with or have an atomic number greater than 20 or 25. As spallation material has e.g. an iron-containing material is especially proven. This material is inexpensive to procure and advantageous to dispose of or recycle if necessary.

Preferably, the moderation layer (s) have a density of less than or equal to 3.5 g / cm ³ and the spallation layer (s) have a density of greater than or equal to 3.0 g / cm ³ .

The radiation protection wall according to the invention forms the downstream wall of the radiation protection chamber into which a primary high-energy beam from a particle accelerator is directed onto a reaction site or a target.

• eine strahlabwärts positionierte erste Strahlenschutzwand mit dem vorstehend beschriebenen sektionierten Aufbau,
• eine strahlaufwärts positionierte zweite Strahlenschutzwand mit einem Eintrittsbereich für den Hochenergiestrahl,
• seitliche Strahlenschutzwände sowie
• einen Boden und eine Decke,

wobei die Strahlenschutzwände, der Boden und die Decke gemeinsam einen um den Reaktionsplatz im Wesentlichen geschlossenen Strahlenschutzkäfig bilden.The radiation protection chamber therefore has at least the following components:

• a radiation shield wall positioned downstream with the above-described sectioned structure,
• a second radiation protection wall positioned upstream with an entry region for the High energy beam
• lateral radiation protection walls as well
• a floor and a ceiling,

wherein the radiation protection walls, the floor and the ceiling together form a radiation protection cage substantially closed around the reaction site.

In this case, the first radiation protection wall thus has a central region for attenuating the radiation emerging from the reaction site at a predetermined solid angle around the forward direction of the high-energy beam and a peripheral region around the central region and is constructed from separate subsections such that during the dismantling subsections from the central Area and subsections of the peripheral area separately from each other or dismountable and recyclable or disposable.

The lateral radiation protection walls may have a different layer structure.

For particularly high beam energies, it may be advantageous if an additional beam destroyer, so-called "beam dump", is arranged in the forward direction of the primary high-energy beam or downstream of the reaction station. The jet destroyer preferably adjoins the first radiation protection wall downstream of the radiation protection chamber, or is at least partially integrated in the latter.

In the following the invention will be explained in more detail by means of embodiments and with reference to the drawings, wherein the same and similar Elements are partially provided with the same reference numerals and dre features of the various embodiments can be combined.

Brief description of the figures

Fig. 1

einen schematischen Querschnitt durch eine Strahlenschutzkammer gemäß einer ersten Ausführungsform der Erfindung von oben,

Fig. 2

den Ausschnitt A aus Fig. 1,

Fig. 3

ein berechnetes Dosisprofil an der Strahlenschutzkammer nach Fig. 1,

Fig. 4

eine berechnete Radioaktivität aufgeteilt nach Isotopen des Abschnitts 8 in Fig. 1,

Fig. 5

einen schematischen Querschnitt durch eine Strahlenschutzkammer gemäß einer zweiten Ausführungsform der Erfindung von oben.

Show it:

Fig. 1

a schematic cross section through a radiation protection chamber according to a first embodiment of the invention from above,

Fig. 2

the section A from Fig. 1 .

Fig. 3

a calculated dose profile at the radiation protection chamber Fig. 1 .

Fig. 4

a calculated radioactivity divided into isotopes of Section 8 in Fig. 1 .

Fig. 5

a schematic cross section through a radiation protection chamber according to a second embodiment of the invention from above.

Detailed description of the invention

As an example of the radiation protection wall or chamber according to the invention, the irradiation chamber for nuclear collisions, which is currently being planned by the applicant within the scope of the FAIR project (= Facility for Antiproton and Ion Research), is used here.

Fig. 1 shows this radiation protection chamber 1 constructed of a first beam downstream positioned (front) radiation protection wall 110, a second upstream (rear) radiation protection wall 210 and two side radiation shields 310, 410, which together with unillustrated floor and ceiling a substantially closed cage as Reationscave around Form target 50. The chamber 1 has a labyrinth-shaped entrance area 60.

The high-energy primary beam 70 enters the chamber 1 through a jet entry region 80 and strikes the target 50. The primary beam 70, in this example generates 10 ¹² protons / sec at an energy of 30 GeV secondary radiation 90, although in all directions is emitted, but still has a maximum in the forward direction. In particular, this secondary radiation 90 should be effectively shielded.

The radiation protection walls 110, 210, 310, 410 each have an inner solid support layer or load-bearing concrete layer 140, 240, 340, 440 and an outer solid support layer or load-bearing concrete layer 150, 250, 350, 450, respectively. The front and side outer concrete layers 150, 350 and 450 are in turn two-layered in layers 152, 154; 352, 354 and 452, 454 formed.

The radiation protection walls 110, 210, 310, 410 further each comprise an inner layer arrangement 120, 220, 320, 420 of a spallation material, such as e.g. Iron, iron granules or iron ore. The front spallation layer arrangement 120 is in turn constructed in two layers in spallation layers 122, 124. The lateral spallation layer arrangements 320, 420 have only one spallation layer 322, 422 each.

Externally adjacent to the spallation layer arrangements 120, 220, 320, 420, respectively moderation layer arrangements 130, 230, 330, 430 are made of earth. The front moderation layer assembly 130 is in turn constructed in three layers in moderation layers 132, 134, 136. The side moderation layer arrangements 330, 430 each have two moderation layers 332, 334 and 432, 434, respectively.

The concrete layers 140, 152 serve as inner and outer supporting wall for filling with iron ore bulk material for the Spallationsschichten or pourable soil for the moderation layers. The earth has a composition that is common at the location of the research facility. Intermediate layers and tie rods (in Fig. 1 not shown) are installed to meet the static requirements.

The spallation layers are made of higher atomic number materials than the moderation layers. In the spallation layers, spallation reactions are triggered mainly by high-energy neutrons, which, among other things, result in the production of evaporation neutrons. The evaporation neutrons have smaller energies than the neutrons of the secondary radiation, the generation of further radionuclides is less likely. If the layer thickness is sufficiently large, a large part of the neutrons of the secondary radiation is converted into neutrons of the evaporation cores. If this layer thickness is adapted to the primary beam (ionic species, energy, intensity) and the target (element, thickness) so that the secondary radiation generated in the target is strongly scattered and weakened, the downstream layers are only weakly activated, the level of radioactivity generated is low.

• • Die innere Betonschicht 140 weist einen zentralen Teilabschnitt 21 und zwei periphere Teilabschnitte 20 auf.
• • Die erste Spallationsschicht 122 weist einen zentralen Teilabschnitt 15 und zwei periphere Teilabschnitte 13 auf.
• • Die zweite Spallationsschicht 124 weist einen zentralen Teilabschnitt 16 und zwei periphere Teilabschnitte 14 auf.
• • Die erste Moderationsschicht 132 weist einen zentralen Teilabschnitt 10 und zwei periphere Teilabschnitte 7 auf.
• • Die zweite Moderationsschicht 134 weist einen zentralen Teilabschnitt 11 und zwei periphere Teilabschnitte 8 auf.
• • Die dritte Moderationsschicht 136 weist einen zentralen Teilabschnitt 12 und zwei periphere Teilabschnitte 9 auf.
• • Die äußeren Betonschichten 152, 154 sind jeweils einteilig ausgebildet.

In particular, the front radiation protection wall 110 or its layers are on the one hand laterally, ie transversely to the respective layer plane and on the other hand divided by subdivision of the layer assemblies 120, 130 into further separate layers 122, 124, and 132, 134, 136 into subsections. In this example, the subdivision, as seen from the inside outwards, is carried out as follows:

• The inner concrete layer 140 has a central partial section 21 and two peripheral partial sections 20.
• The first spallation layer 122 has a central partial section 15 and two peripheral partial sections 13.
• The second spallation layer 124 has a central partial section 16 and two peripheral partial sections 14.
• The first moderation layer 132 has a central partial section 10 and two peripheral partial sections 7.
• The second moderation layer 134 has a central partial section 11 and two peripheral partial sections 8.
• The third moderation layer 136 has a central partial section 12 and two peripheral partial sections 9.
• The outer concrete layers 152, 154 are each formed in one piece.

• Die innere Betonschicht 340 weist einen ersten Teilabschnitt 22 und einen zweiten Teilabschnitt 23 auf.
• Die einzige Spallationsschicht 322 weist einen ersten Teilabschnitt 17 und einen zweiten Teilabschnitt 18 auf.
• Die erste Moderationsschicht 332 weist einen ersten Teilabschnitt 2 und einen zweiten Teilabschnitt 4 auf.
• Die zweite Moderationsschicht 334 weist nur einen Abschnitt 3 auf.
• Die innere Betonschicht 440 weist nur einen Abschnitt 441 auf.
• Die Spallationsschicht 422 weist nur einen Abschnitt 443 auf.
• Die erste Moderationsschicht 432 weist einen ersten Teilabschnitt 6 und einen zweiten Teilabschnitt 433 auf.
• Die zweite Moderationsschicht 434 weist nur einen Abschnitt 5 auf.

The lateral radiation protection walls 310 and 410 are also subdivided as follows:

• The inner concrete layer 340 has a first partial section 22 and a second partial section 23.
• The single spallation layer 322 has a first partial section 17 and a second partial section 18.
• The first moderation layer 332 has a first partial section 2 and a second partial section 4.
• The second moderation layer 334 has only one section 3.
• The inner concrete layer 440 has only a portion 441.
• The spallation layer 422 has only a portion 443.
• The first moderation layer 432 has a first partial section 6 and a second partial section 433.
• The second moderation layer 434 has only one section 5.

• Die innere hintere Betonschicht 240 einteilig ausgebildet (Abschnitt 24).
• Die Spallationsschicht 222 weist nur einen Abschnitt 19 auf.
• Die Moderationsschicht 232 weist nur einen Abschnitt 1 auf.
• Die äußere Betonschicht 250 ist einteilig ausgebildet.

Further, with respect to the rear radiation shield wall 210,

• The inner rear concrete layer 240 integrally formed (section 24).
• The spallation layer 222 has only one section 19.
• The moderation layer 232 has only one section 1.
• The outer concrete layer 250 is integrally formed.

Between the spallation layers and moderation layers are in the Fig. 1 Partitions not shown provided. Furthermore, frontally adjacent subsections, for example the sections 13 and 15, are separated from one another at their front sides by separating elements.

Fig. 2 10 shows a section enlargement of the sections 15, 16 of the spallation layer and 10, 11, 12 of the moderation layer and the outer load-bearing concrete layers 152, 154 and the section 21 of the inner load-bearing concrete layer 140. The sections of the spallation layer and the moderation layer are formed by partitions 92 and partitions 94 and the adjacent load-bearing concrete layers.

As a result of the sectioning according to the invention, in particular the front radiation protection wall is adapted to the anisotropy of the secondary radiation 90.

The inner, i. The central layer sections 21, 15 and 16 facing the target 50 have the strongest shielding effect and therefore also have the strongest activations. The remaining sections are less activated due to their peripheral location or their outermost position. Most of the remaining sections are therefore immediately after use of the system or after a short wait fully unlockable. Advantageously, on the one hand so little material with the necessary layer thickness and unavoidable increased activation and on the other hand, as much natural material as necessary to be installed to receive the dose rate outside the chamber 1 or the building below a certain value.

1. 1. Die Verteilung von Radioaktivität innerhalb der verschiedenen Teilabschnitte 1-24 der Strahlenschutzwand 110, 210, 310, 410 und
2. 2. die zu unterschreitende Dosisleistung außerhalb der Kammer 1.

The invention described here thus optimizes two quantities:

1. 1. The distribution of radioactivity within the various sections 1-24 of the radiation protection wall 110, 210, 310, 410 and
2. 2. the dose rate to be undershot outside the chamber 1.

• die Spallationsschichten 122,124 von den Moderationschichten 132, 134, 136 getrennt,
• mehrere Spallationsschichten 122, 124 voneinander getrennt,
• mehrere Moderationsschichten 132, 134, 136 voneinander getrennt und
• die Spallationsschichten 122, 124 und die Moderationsschichten 132, 134, 136 jeweils lateral in Teilabschnitte 13-16 bzw. 7-12 unterteilt.

In particular, in the front radiation protection wall 110 according to the invention are also

• the spallation layers 122, 124 are separated from the moderation layers 132, 134, 136,
• a plurality of spallation layers 122, 124 separated from each other,
• a plurality of moderation layers 132, 134, 136 separated from each other and
• the spallation layers 122, 124 and the moderation layers 132, 134, 136 each divided laterally into sections 13-16 and 7-12.

The various layers can be provided as solid layers (concrete support layers) or as bulk material layers (spallation layers, moderation layers) or even as liquid layers (moderation layers). More specifically, the moderation layers contain bulk materials as shielding materials, e.g. natural materials such as gypsum, earth, sand, etc. and the inner and outer base layers 140, 152, 154 are reinforced concrete layers which serve to structurally structure the chamber.

Fig. 3 shows a calculated dose profile for operation with the proton beam 70 of energy 30 GeV and intensity 10 ¹² protons / sec. The dose rate is given in the unit μSv / h.

1. 1. Es werden niedrige Strahlenpegel außerhalb des Gebäudes während des Strahlbetriebs erzielt.
2. 2. Die räumliche Aktivierung innerhalb der Strahlenschutzwände ist auf das natürliche Abschirmmedium Erde angepasst.

The irradiation chamber has been optimized in two ways:

1. 1. Low radiation levels are obtained outside the building during blasting operation.
2. 2. The spatial activation within the radiation protection walls is adapted to the natural shielding medium earth.

In Fig. 3 It can be seen that by using natural shielding materials, in this example iron ore as spallation material and earth as moderation material, the generated radiation is effectively weakened. In the vicinity of the target 50, the dose rate is very high (1 Sv / h and higher), outside the radiation protection chamber 1 (except immediately in the forward direction) it is at a level between 0.1 and 1 μSv / h. The requirements of the national legal limits can thus be met.

The calculations were carried out using the radiation transport program FLUKA ( A. Fasso, A. Ferrari, J. Ranft, PR Sala: New developments in FLUKA, modeling hadronic and EM interactions Proc. 3rd Workshop on Simulating Accelerator Radiation Environments, CEC, Tsukuba (Japan) 7-9 May 1997. Ed. H. Hirayama, KEK Proceedings 97-5 (1997), p. 32-43 ) carried out.

In Table 1, the activation in the various sections 1 to 24 is calculated for a beam time of 30 years and a mean intensity of 1.00E + 12 protons / sec at 30 GeV. The target causes a proton reaction rate of about 1%. It generates an intense high-energy secondary radiation (neutrons, protons, pions, muons). This in turn generates radioactivity in the shielding layers as follows. The sections 1 to 12 consist of earth, the sections 13 to 19 of iron ore and the sections 20 to 24 made of concrete. Activation is expressed in units of total unused unrestricted release for three different cooldowns, 5 years, 1 year and 1 month. Values less than 1 mean unrestricted release. <u> Table 1: </ u> cooldown 5 years 1 year 1 month section 1 4.00E-04 9.40E-04 1.28E-03 2 1.10E-04 2.66E-04 3.71E-04 3 4.60E-04 1.26E-03 1.80E-03 4 4.30E-03 1.04E-02 1.43e-02 5 4.50E-04 1.24E-03 1.78E-03 6 4.00E-03 9.89E-03 1.37e-02 7 5.80E-03 1.49E-02 2.09E-02 8th 1.00E-03 2.88E-03 4.21E-03 9 3.40e-04 9.76E-04 1.43e-03 10 1.05E + 00 2.73E + 00 3.83E + 00 11 2.61E-01 7.18E-01 1.02E + 00 12 7.15E-02 2.01E-01 2.88E-01 13 8.33E-02 1.84E + 00 4.95E + 00 14 8.54E-03 1.87E-01 5.00E-01 15 4.62E + 00 9.77E + 01 2.75E + 02 16 9.62E-01 2.07E + 01 5.71E + 01 17 9.15E-03 2.01E-01 5.14E-01 18 5.00E-04 1.08E-02 2.67E-02 19 9.67E-04 2.20E-02 5.40E-02 20 1.91E + 00 5.65E + 00 7.54E + 00 21 3.63E + 01 1.07E + 02 1.42E + 02 22 6.69E-01 2.00E + 00 2.68E + 00 23 4.88E-02 1.49E-01 2.05E-01 24 4.84E-02 1.49E-01 2.06E-01

It can be seen that almost all sections containing Earth are already fully unlockable after a month of cooldown. Only section 10 after one month with a utilization rate of 3.83 is significantly above the release value. A five-year wait brings this shift to a value of about one. Alternatively, however, the iron ore layer thickness of the sections 15 and / or 16 can be increased in order to bring the exhaustion of the earth activation to a value less than one even after a 1-month cooldown.

The concrete and iron ore layer sections are partly strongly activated. Thus, in the forward direction, the iron ore sections 15 and 16 are most activated with a value of exhaustion of the release activity of 275 (section 15) after a 1 month decay phase. Accordingly, the layer of concrete in front of it is also heavily activated (Section 21) with a value of 142. Even a 5-year waiting period is not sufficient to bring the exhaustion levels below one. These materials are not fully releasable, ie they can be used again as shielding in other facilities or disposed of in landfills according to national radiation protection regulation.

Fig. 4 shows by way of example the distribution of the generated radioactivity for the sub-section 8 consisting of earth Fig. 1 ,

The most important radionuclides are given. The degree of exhaustion of the release value (unrestricted release) according to the German Radiation Protection Ordinance is shown for a 30-year operation with 10 ¹² protons / sec and a 1-month cooldown.

The highest relative exhaustion here is the radionuclide Na-22 (half-life 2.6 years). Other radionuclides that are formed are H-3, Be-7, Mn-52.54, Sc-46, V-48, Cr-51, Fe-55.59 and the cobalt isotopes Co-56, 58, 60.

Fig. 5 shows a radiation protection chamber 1 according to the in Fig. 1 but with an additional beam destroyer 95 made of iron with a concrete casing 96. The beam destroyer 95 is centrally embedded in the moderation layers 132, 134, 136, more precisely in the sections 10, 11, 12 and thus causes a further reduced activation of these sections. An inlet channel 98 is provided in the layers arranged upstream of the jet destructor and preferably in the inlet region of the jet destructor 95.

1. 1. Konzentration des radioaktiven Inventars auf Abschirmschichten, die später leichter getrennt werden können von den Schichten, die nur leicht aktiviert sind.
2. 2. Die Trennung von schwach und stärker aktivierten Schichten stellt eine Optimierung hinsichtlich des Strahlenschutzes dar, da die Gesamtmasse der zu entsorgenden (oder wieder zu verwendenden) Stoffe reduziert wird und damit die Entsorgung vereinfacht wird.
3. 3. Bei Verwendung von natürlichen Abschirmmaterialien (Erde, Sand, Schluf, Gips etc.), die nur schwach aktiviert sind, besteht ein doppelter Vorteil: Diese Stoffe sind meist einfach in der Beschaffung und im Transport zu organisieren und in der Abbauphase sind sie aus den gleichen Gründen einfach zu entsorgen (unter der Voraussetzung, dass sie nur schwach radioaktiv sind und zumindest unter den gesetzlichen Grenzwerten für die Ausschöpfung liegen).
4. 4. An- und Abtransport von Stoffen, die zum Teil notwendigerweise von weit her erfolgen müssen (Eisenerz etc.) wird auf ein Minimum dessen reduziert was wirklich gebraucht wird; die natürlichen Abschirmmaterialien können meist in der Nähe oder am gleichen Ort der zu errichtenden Beschleunigeranlage besorgt werden. Somit werden der Transportaufwand und die eingesetzte Energie reduziert.
5. 5. Nach einem mehrjährigen Betrieb der Anlage, wenn die Entscheidung für den Rückbau der Anlage zu treffen ist, wird oft so verfahren, dass unter Nutzung der Kenntnisse des Betriebspersonals die Anlage möglichst schnell abgebaut werden soll. Dies wird dadurch vereinfacht, dass eine klare Trennung zwischen den Abschnitten, die radioaktiv belastet sind und denen die uneingeschränkt und/oder eingeschränkt freigabefähig sind, existiert. Denn beim Rückbauverfahren können die Abbauphasen unter denen mit radioaktiver. Kontaminationsgefahr und direkter möglicher Strahlenexposition gearbeitet werden soll und der Phase mit rein konventionellen Abbauverfahren besser getrennt werden. Der Aufwand zur.Verhinderung von Kontaminationsausbreitungen und dem vorzunehmenden Arbeitsund Strahlenschutzmaßnahmen des involvierten Personals kann besser auf die genannten Abbauphasen angepasst werden.
6. 6. Ein Großteil der Abschirmungsmassen kann sofort nach einer langjährigen Nutzung der Anlage uneingeschränkt freigegeben werden.

In summary, it can be stated that the consideration of the resulting radioactivity in the construction of the shielding building in the different subsections has the following advantages:

1. 1. Concentration of the radioactive inventory on shielding layers, which later can be more easily separated from the layers which are only slightly activated.
2. 2. The separation of weak and more activated layers represents an optimization with regard to radiation protection, since the total mass of the substances to be disposed of (or reused) is reduced and thus the disposal is simplified.
3. 3. When using natural shielding materials (earth, sand, soil, gypsum, etc.), which are only weakly activated, there is a double advantage: These substances are usually easy to organize in the procurement and in the transport and in the mining phase they are off simply disposable for the same reasons (provided that they are only weakly radioactive and at least below the legal limits for exhaustion).
4. 4. The transport of materials, which in some cases necessarily have to be carried out from afar (iron ore, etc.), is reduced to a minimum of what is really needed; the natural shielding materials can usually be obtained in the vicinity of or at the same location of the accelerator plant to be constructed. Thus, the transport cost and the energy used are reduced.
5. 5. After several years of operation of the plant, when the decision to dismantle the plant has to be made, it is often the case that the plant should be dismantled as quickly as possible, using the knowledge of the operating staff. This is simplified by having a clear Separation between the sections which are radioactively contaminated and which are fully and / or restrictedly releasable exists. Because in the dismantling process, the degradation phases under those with radioactive. Danger of contamination and direct exposure to possible radiation to be separated and the phase with purely conventional degradation process better. The effort for the prevention of contamination and the work and radiation protection measures to be taken by the personnel involved can be better adapted to the abovementioned dismantling phases.
6. 6. A large part of the shielding compounds can be released immediately after a long-term use of the system without restriction.

However, the invention is not only applicable to high energy accelerator equipment, but e.g. also applicable to installations where neutrons with smaller energies or thermalized neutrons are released, such as Nuclear reactors for power generation or research reactors (activation by neutron capture with n, γ reactions) or spallation neutron sources. In general, the invention is applicable to types of radiation that cause activation in the radioactive sense of substances and materials.

Claims (12)

1. Radiation screening enclosure (1) for a reaction site on a particle accelerator from which a primary high-energy beam (70) can be directed into the radiation screening enclosure (1), the radiation screening enclosure having at least
   a downstream-positioned first radiation screening wall (110),
   an upstream-positioned second radiation screening wall (210) with an entry region for the high-energy beam, lateral radiation screening walls (310, 410) as well as a floor and a ceiling,
   the radiation screening walls, the floor and the ceiling together forming a radiation screening cage substantially enclosing the reaction site,
   the downstream-positioned first radiation screening wall (110) being formed from multiple layers and having a central region (10-12, 15, 16, 21) for attenuating the radiation leaving the reaction site in a predetermined solid angle around the forward direction of the high-energy beam (70) and a peripheral region (7-9, 13, 14, 20) around the central region,
   the downstream-positioned first radiation screening wall (110) being made up of segments (7-12, 13-16, 20, 21) that are separated laterally, i.e. transversely in relation to the plane of the respective layer, in such a way that the segments from the central region and the peripheral region are put together during assembly such that they can be laterally separated from one another, in order to allow a separate disassembly of the segments of the central region and the peripheral region.
2. Radiation screening enclosure (1) according to Claim 1, the first radiation screening wall (110) and the lateral radiation screening walls (310, 410) being constructed differently.
3. Radiation screening enclosure (1) according to one of the preceding claims,
   a beam dissipator (95) being arranged in the forward direction.
4. Radiation screening enclosure (1) according to one of the preceding claims,
   the downstream-positioned first radiation screening wall (110) having a sandwich-like structure made up of at least a first and a second layer arrangement (120, 130), the first layer arrangement (120) comprising at least one primary shielding layer (122, 124) and the second layer arrangement comprising at least one secondary shielding layer (132, 134, 136),
   the primary shielding layer being formed as a spallation layer and the secondary shielding layer being formed as a moderation layer, and
   separating walls being provided between the spallation layers and the moderation layers in order to ensure separate disposal for the segments of the primary and secondary shielding layers.
5. Radiation screening enclosure (1) according to Claim 4, the moderation layer (132, 134, 136) mainly containing elements with an atomic number of less than 30.
6. Radiation screening enclosure (1) according to either of Claims 4 and 5,
   the spallation layer (122, 124) mainly containing elements with an atomic number of greater than 20.
7. Radiation screening enclosure (1) according to one of Claims 4 to 6,
   the moderation layer (132, 134, 136) having a density of less than or equal to 3.5 g/cm³.
8. Radiation screening enclosure (1) according to one of Claims 4 to 7,
   the spallation layer (122, 124) having a density of greater than or equal to 3.0 g/cm³.
9. Radiation screening enclosure (1) according to one of Claims 4 to 8,
   the moderation layer (132, 134, 136) containing excavated earth, sand, gravel, feldspar, lime feldspar, common feldspar and/or gypsum.
10. Radiation screening enclosure (1) according to one of Claims 4 to 9,
    the first layer arrangement being made up of multiple layers and comprising a number of spallation layers (122, 124) that can be separated from one another.
11. Radiation screening enclosure (1) according to one of the preceding claims,
    the downstream-positioned first radiation screening wall (110) having at least the following layer structure:

    - a first solid supporting layer (140),

    - a spallation layer (122)

    - a first separating wall (92)

    - a first moderation layer (132)

    - a second separating wall (92)

    - a second moderation layer (134)

    - a second solid supporting layer (152).
12. Radiation screening enclosure (1) according to one of the preceding claims,
    the downstream-positioned first radiation screening wall (110) having in its operating position, when seen from above, a structure that is subdivided in a two-dimensionally modular manner.

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