DE1228347B - Device for measuring the neutron flux density - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

GOIt

German class: 21g -18/01

Number: 1228 347

File number: S 82760 VIII c / 21 g

Filing date: December 7, 1962

Opening day: November 10, 1966

The invention relates to a device for measuring the neutron current density, preferably in nuclear reactors, with a built-in measuring probe, ζ. B. an ionization chamber which is surrounded by moderator and / or reflector material. Known devices of this type are designed so that the measuring probe is embedded in or surrounded by a moderator substance. For many applications, however, the sensitivity of such measuring devices is insufficient, especially when a certain neutron spectrum is to be recorded. Sensitivity is understood to mean the ratio of the signal value, that is to say the ionization chamber current, or, if a counter tube is used, the pulse rate, to the neutron current density at the measuring location with the measuring device removed.
. The spatial configuration of the measuring device, called the measuring head for short, also plays an important role here. Up to now, this had to be relatively large and therefore also costly in order that sufficient sensitivity could be achieved. These disadvantages are substantially reduced by the invention.

According to the invention, a plate of moderator material is arranged on the radiation inlet side of the device in front of the measuring probe, the material composition and spatial configuration of which is selected according to the desired spectral sensitivity of the measuring device, and the measuring probe is on the other sides with mean air gaps of at least the order of magnitude of the reflector thickness of surrounded by a neutron reflector.

Compared to known measuring devices, the actual measuring probe is no longer direct surrounded by moderator material or embedded in such a material. After an older, but not pre-published It is true that the proposal is also surrounded by a reflector with an air gap; however, this distance is only provided as space for the arrangement of a rotating screen and sized accordingly. This special device is used to generate pulsating Measuring currents and therefore does not correspond to the present subject matter of the invention either in terms of structure or function vicinity.

The sensitivity of the relatively small measuring heads according to the invention is greater than in arrangements of the same spatial extent in which the measuring probe is embedded directly in moderator material. This is explained by the fact that as the moderator layer becomes thinner, the ratio between the efficiency by the mode device for measuring
the neutron flux density

Applicant:

Siemens-Schuckertwerke Aktiengesellschaft,

Berlin and Erlangen,

Erlangen, Werner-von-Siemens-Str. 50

Named as inventor:
Dipl.-Phys. Karl Janner, Erlangen

The reduction and weakening of the thermal neutron flux due to reflection and absorption are less favorable will. This transition is of course stepless and continuous and depends also on the type of moderator, the shape of the measuring head and the energy of the neutrons to be detected.

In the measuring head according to the invention, the moderation of the fast neutrons takes place in the moderator plate on the beam entry side of the measuring head as well as in the reflector, which the sensor with Distance surrounds, instead of .. As an indication of the size of a measuring head without moderator filling, the sensitivity of which is greater than that of a measuring head with a moderator filling The dimensions of the beam entrance surface are approximately 300 x 300 mm. Have the measuring heads themselves thereby a cylindrical or prismatic structure. The moderator plate on the beam entry side, the z. B. may consist of polyethylene, is much more permeable for fast neutrons than for slow. This is partly due to the fact that, due to the small atomic weight of hydrogen, fast neutrons are predominantly forward scattered, on the other hand from the fact that the scattering cross-section in the case of hydrogen increases sharply with decreasing neutron speed. The entering will be fast neutrons that is, with a suitable thickness of this moderator layer, is reflected to a much lesser extent than from inside the measuring head onto the layer. at the entry surface, as the latter Neutrons are much lower in energy. This creates a trap effect, i. i.e., the entry of the neutrons in the measuring head is favored over the exit, which also turns out to be a

609 710/231

Increases the sensitivity of the measuring head. .,. ,,

A further increase in sensitivity is achieved with small measuring heads if the measuring head is and thus practically also the reflector, not a prismatic, but a truncated pyramid or a frustoconical shape. This effect is based on the fact that the sources are more thermal Neutrons the sensitive volume of the measuring probe in this. Form of training closer on average are so that the neutrons the sensitive volume of the measuring probe with a greater probability meet. The reflector can be used to improve the reflectivity or to improve it the dimensional stability also consist of several layers, z..B. from an outer layer made of polyethylene and an inner one made of beryllium.

1 to 5 show different embodiments of such a measuring head according to the invention. It contains the actual measuring probe (e.g. an ionization chamber or a counter tube) with a 2 that surrounds it Reflector, e.g. B. made of paraffin, with 3, the moderator plate arranged on the radiation entrance side, e.g. made of polyethylene, marked 4. The sensitive volume 21 of the measuring probe is with dash-dotted lines and the air-filled space between the measuring probe and reflector denoted by 5.

The F i g. 1 and 1a represent a truncated pyramid-shaped measuring head, the beam entrance area of which is about 300 × 300 mm, the depth of which is about 360 mm and the reflector thickness of about 45 mm. The measuring probe is arranged coaxially to the measuring head and, as in the other figures, in close proximity to the moderator plate 4.

The F i g. 2 shows a similar measuring head in cross-section, but it is also frustoconical can be constructed. In contrast to the measuring head according to FIG. 1 is according to FIG. 2 the moderator plate 41 perforated on the beam entry side. These symmetrically arranged holes all have towards the sensitive volume 21 of the probe.

According to Fig. 3, the holes are in the moderator plate 42 also aimed at the sensitive volume of the probe, but are blind holes educated. In this case, they can also use corresponding annular grooves with the same directional tendency be replaced.

The F i g. 4 shows compared to the previous examples a measuring head in which the sensor is parallel to the beam entry side and thus z. B. parallel to the jacket surface of a nuclear reactor. The reflector 3 expediently surrounds the sensor in the form of a half cylinder shown. The radiation entrance surface can again as in the previous examples by a smooth or perforated moderator plate 4 or 41 or 42 to be completed.

FIG. 5 shows the measuring head according to FIG. 4 in a section transverse to the longitudinal axis of the probe.

The choice of the thickness of the moderator or hydrogen-containing Layer on the beam entry side of the measuring head, which leads to the highest sensitivity, depends on the energy spectrum of the neutrons to be recorded and on the layer material itself. For polyethylene and fission neutrons, the maximum sensitivity is around 15 mm. Will be at this If the energy distribution of the neutrons increases the layer thickness, the sensitivity of the measuring head decreases as a result of absorption in the faceplate, if it is reduced it decreases because of the increase in the Absorption in the reflector walls 3 as a result of the deeper penetration of the neutrons.

If the moderator plate according to FIG. 2 or 3 with a different but symmetrical wall thickness distribution is constructed, there is a further increase in the sensitivity for the detection of fission neutrons. By suitable choice of the different wall thicknesses, i.e. the thicknesses of the perforated and the non-perforated part of the moderator plate 41 and 42, as well as by the Ratio of the hole or groove area to the remaining area of the polyethylene plate and the shape and Size of the openings can affect the sensitivity (measuring range), the dependence of the sensitivity the measuring head from the neutron energy, d. H. the spectral sensitivity and the direction

zo processing dependence, are affected. Accordingly, the greatest sensitivity for thermal neutrons and the smallest for high-energy neutrons would be obtained if the moderator plate on the radiation entry surface were completely omitted.

If a front plate with holes is selected (41 in FIG. 2), the free cross-section decreases as the free cross-section decreases same and with increasing thickness of the plate the sensitivity to low-energy neutrons now and then for high energy too. The directional dependence of the sensitivity increases with rounds or square openings or also in the case of annular grooves with an increasing ratio of depth to cross-section of the perforations too. The same considerations naturally also apply to the measuring heads according to FIGS. 4 and 5.

These measuring heads also have the advantage that, compared to known arrangements, the ratio the neutron sensitivity to the interference radiation sensitivity increases, since the neutron sensitivity with the same entrance area increases, the sensitivity to the interference radiation, however, that of enters the front or originates in the sensor remains the same. The one coming from other sides Interfering radiation can of course be shielded by known means; so it is possible that Reflector layer 3 to the outside with a gamma-ray shield, e.g. B. lead, as well to surround an absorber shirt.

In summary, it should be said that the invention Training the measuring heads has the following advantages: "

Much smaller design of the measuring head, at least equal in achieving sensitivity in ¹ compared to prior art, considerably larger Meßkopfausbildungen with embedded probe or in other words, at this spatial reduction of the measuring head increase of the sensitivity with the same entry surface towards a container filled with moderator measuring head of equal size.

Furthermore, increase the ratio of the sensitivity from neutron radiation to interference radiation, adaptability of the sensitivity to the neutron spectrum and also only a slight weakening of the mechanical strength of a reactor shield in the case of the installation of the measuring head in such a shield, since the beam entrance surface is comparable Sensitivity compared to that of conventional measuring heads is significantly lower.

Claims (6)

Patent claims: 1. Device for measuring the neutron flux density, preferably on nuclear reactors, with a built-in probe, e.g. B. an ionization chamber made of moderator and / or reflector material is surrounded, characterized in that on the beam entrance side a plate (4, 41, 42) made of moderator material is arranged in front of the measuring probe (2) of the device is, the material composition and spatial configuration according to the desired spectral sensitivity of the measuring device is selected, and that the measuring probe (2) on the other sides with medium air gaps of at least the order of magnitude of the reflector thickness of a neutron reflector (3) is surrounded. 2. Measuring device according to claim 1, characterized in that the measuring probe (2) with ao Distance surrounding reflector (3) the shape of a thick-walled truncated cone or pyramid has, its open bottom surface facing the object to be measured with a plate (4) made of moderator material is covered. 3. Measuring device according to claim 2, characterized in that the plate (42) made of moderator material with symmetrical on the measuring probe (2) directed blind holes distributed over the plate surface and open towards the measuring probe or annular grooves is provided. 4. Measuring device according to claim 2, characterized in that the plate (41) made of moderator material with symmetrically directed towards the measuring probe (2) and distributed over the plate surface through holes is provided. 5. Measuring device according to claim 1, characterized in that the preferably parallel measuring probe (2) arranged on the beam exit surface of the measuring object from a reflector (3) is surrounded in the form of a cylindrical shell section and its open side with a plate (4) from moderator material is completed. 6. Measuring device according to claim 1, characterized in that the neutron reflector (3) is made up of several layers of the same or different reflector materials. Considered publications:
"Atompraxis", Vol. 5, 1959, No. 10/11, p. 414;
E. Fünfer and H. Neuert, "counting tubes and scintillation counters", 1959, p. 211; "Siemens-Zeitschrift", 1958, no. 5, p. 282. Legacy Patents Considered:
German Patent No. 1210 093. 1 sheet of drawings 609 710/231 11.66 © Bundesdruckerei Berlin