DE1248180B - Neutron source for a geophysical borehole survey device - Google Patents

Description

Neutron source for a geophysical borehole logging device The invention relates to a neutron source for a geophysical borehole investigation device with a low pressure, e.g. B.

10-5 to 10-4 mm Hg, standing deuterium gas-filled chamber in which from a hot cathode to an anode one under the influence of a magnetic field Electron current flows, by means of which ions are generated in the deuterium gas, which are accelerated under the action of a high voltage so that the Impact of the ions on an anticathode made of zirconium with tritium inclusion High-energy neutrons, essentially 14 MeV, are produced as a target electrode.

In known neutron sources of this type, the means of the Electron stream in the deuterium gas generated ions accelerated on a linear path and to an anticathode with a relatively small area, for example in the form a plate or disk. There is a risk of exer- cise here heating of the anticathode, which leads to focal spots. Also can only a comparatively small amount of tritium in a small area anticathode housed, thereby reducing the service life of the anticathode and thus the neutron source is reduced.

The invention aims to provide a neutron source of the introductory to create mentioned type, in which while avoiding the disadvantages of the known Versions guarantee reliable operation and a long service life are.

According to the invention, a neutron source is as mentioned in the introduction Kind characterized in that the anode is located in the center of the chamber that the magnetic field is perpendicular to the electrical field of the cathode-anode system and that the anticathode serving as a targeting electrode delimits the chamber in a ring shape.

Through the invention is a neutron source for a geophysical Borehole logging device created in which a high neutron flux is generated without excessive heating of the anti-cathode, which is designed as a target electrode. Since the collecting electrode according to the invention according to its annular design a has a relatively large area, not only is the heating proportionate low, but the heat generated can also be dissipated much faster.

Furthermore, due to the large area of the target electrode, a comparatively large amounts of trtitium are accommodated in their surface, whereby the Operating time the neutron source is increased considerably.

Another major advantage of the embodiment according to the invention lies in the fact that the ions do not have to be focused on the target electrode. In the known designs, such a focusing of the ion beam is ers required, with all ions that do not hit the intended direction through Masks are prevented from continuing their course. In this way it arises a loss of ions and thus a loss of energy, because many ions are produced but cannot be used to form neutrons.

Another advantage of the embodiment according to the invention, which by the annular formation of the target electrode is obtained is that the Neutrons are generated very close to the earth formations to be penetrated.

The invention is illustrated below with reference to the drawing, for example explained. In detail, FIG. 1 schematically shows the principle of a neutron source according to the invention, FIG. FIG. 2 shows an embodiment of the neutron source according to FIG Invention in section.

In Fig. 1, the measuring arrangement and method are shown schematically. The ErdreichlO is penetrated by a borehole 11, which in a known manner can be lined without this covering is necessary. Through the borehole 11, the examination device 12 is retracted to the desired depth. The device 12 includes a neutral source 14 and a receiver 13 and is attached to a cable 15, which among other things also all necessary electrical lines for connecting the underground device 12 with the measuring devices arranged above ground contains. The cable 15 runs onto the drum 16 when the device 12 is started up and is handled by the latter when lowering.

To carry out the radioactive examination, the device 12 brought to the desired depth.

The neutrons emitted by the transmitter 14 hit the surrounding area Soil, and the secondary effects (gamma rays) generated there, are taken care of by the recipient 13 added. The sign received and transformed into electrical impulses arrives via a line in the cable 15 to the drum 16, from where it is with the help of the slip rings 17 and current collectors (brushes) 18 via the amplifier 19 into the registration device 20 is transmitted. The cable 15 also runs over a measuring roller 22, which mediates of the transmission device 21, the depth of the measuring device 12 in the recording device 20 indicates.

It should be noted that the in FIG. 1 also shown measuring arrangement can be modified. In particular, the amplifier 19 in the underground device can 12 may be provided. Furthermore, the device 12 must be so robustly constructed and executed be that it withstands the mechanical and thermal influences in the interior of the earth, and there must be enough space inside to accommodate all the necessary facilities and auxiliary equipment.

Fig. 2 shows an embodiment of the neutron source that is shown in 1 is provided with the reference number 14. The deuterium-tritium reactor is located in a housing 23 arranged. A filament 24 serving as a hot cathode is located inside the reactor provided, which is connected to a heating battery 25 via lines 26. The filament 24 emits electrons which are attracted to an anode 27. A Anode battery 29, which via lines 28 a voltage of about 100V to the anode 27 sets. The negative poles of batteries 25 and 29 are connected to the housing, which contains the battery, and they serve as a reference potential. Furthermore is perpendicular to the electric field a magnetic field is provided, which is generated by magnets 30 is generated and which the electrons on their way from the hot cathode 24 leads to the anode 27 on circular paths, whereby the ionization paths are lengthened. The magnets 30 are advantageously made of a ferromagnetic alloy, and they are preferably arranged in acceleration anodes 31. The latter will be carried by insulators 32 inside the housing 23. Inside the by the case 23, the insulators 32, the anodes 31 and the magnets 30 formed space 33 is included the deuterium gas, which has a constant pressure of 10-5 to 10-S mm Hg, preferably 10-4 mm Hg.

On their circular paths from the hot cathode 24 to the anode 27 The electrons collide with deuterium atoms before they reach the anode 27. The frequency of the collisions can be determined by the structural design of the ionization space still be enlarged. The deuterium ions generated by the electron impact move because of their positive charge towards the cathode 24, under the influence the voltage between the cathode 24 and anode 27 of 50 to 150 V, preferably 100 V. Most of the deuterium Ions do not hit the cathode 24, but get there into the chamber 33. In this there is an electric field, which is generated by a high voltage source 34 is generated, the negative pole of which via a line 35 to the housing 23 and its positive pole via another line 35 to the negative pole of the heating battery 25 or the anode battery 29 is connected.

An anti-cathode 36 serving as a targeting electrode is attached to the housing 23 connected and preferably cylindrical or ring-shaped. she pulls the positively charged deuterium ions. The anticathode 36 is advantageously made made of zircon, which has the property of adsorbing large amounts of tritium. As a result of the large area of the anti-cathode 36 there is no risk of a Burning spots and the associated local overheating.

Electrodes 37 homogenize the electric field, so that the deuterium ions have a directional acceleration on the anticathode 36 where they mainly hit the adsorbed tritium atoms. before the anticathode 36 is a ring-shaped braking grid 40 is provided, which of a Grid battery 38 receives a weakly negative bias voltage via lines 39. the The effect of this grating 40 is, if necessary, at the anticathode 36 generated secondary electrons to retain those without the grid 40 on the anodes 31 could reach and thus cause energy losses.

The high voltage source 34 generates a voltage of 50,000 to 200 000 V, preferably 100 000 V. Compared to the housing 23, it is through a high quality Isolation 41 isolated. Its negative pole is connected to the housing 23. The batteries 25 and 29, likewise the magnets 30 and the anodes 31 must opposite the housing 23 must also be well insulated. because they have high potential for them.

When the high-energy deuterium ions collide with the tritium atoms on the anticathode 36, neutrons are generated. The cross section depends on the kinetic energy of the deuterium ions, d. H. of the deuterium nuclei.

The optimum is around 100 keV, and the mean is estimated 50 keV. For a thick anticathode, the effective volume naturally depends on the Energy from the impact particles. As the thickness increases, the number of reactants increases Particle too. Alpha particles are formed during the reaction between deuterium and tritium and neutrons. The energy of the neutrons produced is around 14 MeV and is quite constant, including only the amount of kinetic energy of the bombarding ions comes, which is also given off to the neutrons. The ones created in this way Neutrons are emitted into the surrounding earth as related with F i g. 1 has been explained.

The reaction described above, in which deuterium ions at the on the anticathode adsorbed tritium atoms generate neutrons, is the essential There are other elements, however, and so can other reactions take place. In particular, the gas also contains tritium, and the anticathode also absorbs deuterium atoms, especially the adsorption of tritium not completely done on zirconium and always a part of the tritium atoms diffused back into the gas. As a result, the electrons also become tritium ions generate, which then hit on the anticathode 36 on deuterium atoms and also Generate neutrons. In this way, the same energy of about 14 MeV is obtained, however These effects occur less often because the larger tritium particles have higher ionizations require to have the same speed as the deuterium ions, too obtain. A reaction between tritium ions and tritium atoms occurs practically do not, however, generate collisions between deuterium ions and deuterium atoms to a small extent also neutrons, with an energy of about 2.5 MeV. The ions hitting the zircon do not produce any neutron radiation.

Neutron generation can be achieved by switching the high voltage source on and off 34 can be initiated or stopped. The high voltage source 34 can also be used Start or interrupt operation in pulses. To this end, the arrangement is a relay which is actuated from above ground via a line 42 is advantageous can be. This arrangement is shown in FIG. 2 only indicated schematically.

The heating battery 25 shown in Figure 2 and the anode battery 28 only represent exemplary embodiments. Accumulators can also be provided be that are charged via lines in the cable 15 from the top layer. The energy supply can also be done entirely without local voltage sources via cables from above ground made from. The insulation of the cathode 24 and the anode 27 must be provided by the high voltage source 34 supplied high voltage are sufficient. Therefore, to power the low-voltage parts the means known per se, such as isolating converters or motor-generators with isolating shafts or belt drive, etc., may be provided.

In this case, too, switching the Anode voltage source 28 can be used with advantage. To get the impulse faster and to make it more effective, one can do that Reverse the polarity of the anode voltage source 28, so that in the switched-off state the cathode to be moved between. The impulse itself can be through a built-in oscillator or from above through the cable 15 take place.

Claims (3)

Claims: 1. Neutron source for a geophysical borehole investigation device with a low pressure, e.g. B. 10-S to 10-4 mm Hg, standing deuterium gas filled chamber in which from a hot cathode to an anode one under the influence a magnetic field a standing electron current flows, by means of which in the deuterium gas Ions are generated, which accelerated under the action of a high voltage be that when the ions hit a zirconium with tritium inclusion Anticathode as a target electrode, neutrons of high energy, essentially of 14 MeV, arise, characterized in that the anode (27) is in the center of the chamber that the magnetic field is perpendicular to the electrical field of the cathode-anode system and that the anticathode (36) serving as a targeting electrode forms a ring around the chamber limited. 2. Neutron source according to claim 1, characterized in that the The target electrode (36) and the housing (23) are at the same potential. 3. Neutron source according to claim 1 or 2, characterized by a ring-shaped braking electrode (40) which is negative with respect to the targeting electrode (36) The potential is around the secondary electrons emitted by the target electrode (36) to suppress. Publications considered: German Patent No. 736 811; U.S. Patent No. 2211,668; Plupica, B. IV (1937), No. 11, pp. 1190 bis 1193