DE1464878C - Device for generating corpuscular beams, in particular neutron pulses - Google Patents

Description

Accordingly, the invention is based on the object of providing a device by the USA 2960610 known type to further develop that a pulsating radiation with sharp limited neutron pulses of the highest frequency with uninterrupted operation of the device and with constant supply of energy is made possible.

To solve this problem, the invention is based on the fact that the USA 2689 918 is known per se, a device of a similar type except by alternating on and off can also be operated by other means with pulsating radiation. In this known device however, an electrostatic generator according to US Pat. No. 2,960,610 is not arranged, while in the device according to the invention just such an electrostatic generator, in particular a generator driven by a belt drive is used. It has however, it has been shown that during pulsed operation of a device provided with such a generator to the extent that there are difficulties as the various system parameters are precisely selected and must be kept in equilibrium before a reliable neutron emission in satisfactory Way is achieved. If the generator is operated periodically, a malfunction of the occurs very quickly Equilibrium of these parameters. In the case of devices of the type specified, which have an electrostatic Generators are provided as high-voltage generators, could therefore generally only impulses with a duration of more than 0.1 second and a frequency of about five pulses per second be generated.

In contrast, according to the invention, the specified object is achieved in that between the Generator and one of the two ionization electrodes, a trigger element is switched on, which is taking advantage of of the voltages generated in the device, the electrode is intermittently connected to the generator coupled.

In a device designed according to the invention, all other system functions are in kept a stable operating condition while only the ejection of ionizing neutrons in the Ionization of the device is pulsed. There are neutron pulses of just five microseconds Duration at a pulse frequency of at least ten thousand pulses per second possible. In addition, energy is saved instead of wasted, and both the duration of the respective Regulate impulses as well as the rest intervals properly. . >

Some embodiments of the invention are described below with reference to the drawing as examples. It shows' - ■

F i g. 1 shows a simplified representation of the device according to the invention with a trigger element formed by a Geiger-Müller counter,

F i g. 2, 3 and 4 of FIG. 1 corresponding representations of embodiments of the invention, in which the trigger element is each formed by a trigger tube.

The device shown in Fig. 1 is used to generate neutron pulses, such as those in particular for investigating boreholes in the subsurface or for carrying out borehole measurements be applied. The device is for this purpose with an accelerator tube 2 and a belt-driven one electrostatic generator4, e.g. a high-voltage generator according to Van de Graaff. The accelerator tube 2 has a gas-tight housing for receiving a static quantity an ionizable gas or gas mixture 21 which z. B. consists of deuterium or tritium or a mixture of these two gases and below very low pressure. In the central axis of the

ίο Accelerator tube 2, an ionization space ^ is arranged, which is enclosed by two electrodes 23, 24 of which the electrode 23 forms the cathode and the electrode 24 forms the anode. the Anode 24 is preferably designed as a simple wire or a relatively thin rod-shaped electrode, while the cathode 23, which is at free potential, preferably by a circular body is formed from fine wire mesh which surrounds the wire or rod-shaped anode 24 concentrically.

The cathode 23 is preferably arranged on a tube-like support 23/1 made of metal. Also located within the accelerator tube 2 is an annular target 22 made from a thin strip of titanium attached to the inner surface of the housing so that it surrounds the cathode 23 and anode 24. The target 22 is impregnated with either deuterium or tritium or with a deuterium-tritium mixture. In addition, one or more electrodes are arranged between the target 22 and the cathode 23, which represent braking or locking rings 12 and serve to suppress the secondary electron emission of the target 22. The electrostatic generator 4 is provided with a preferably cylindrical housing, which is arranged as an extension of the housing of the acceleration tube 2 and is connected to it via an earth or ground line. The generator is provided with an endless belt 37 made of an electrically non-conductive material, such as leather or fabric, which is guided over two rollers 36 and 38 and is filled with spaced apart, non-illustrated particles of regular dimensions made of electrically conductive material. The one pulley 38 is connected to the drive of the belt 37 with the shaft of an electric motor, not shown. The other deflecting roller 36 can be arranged on a two-part electronic unit, which consists of a lower hollow electrode 35 and an upper hollow electrode 32, both of which are electrically separated from one another by an insulator 33. The two hollow electrodes are insulated from the housings by an insulating support piece 27 which connects the electrostatic generator 4 to the acceleration tube 2. The lower hollow electrode 35 is connected by a line 34 to the anode 24 of the accelerating tube 2, while the upper hollow electrode 32 with the cathode 23 23 A is conductively connected through the previously mentioned carrier. In the area of the drive roller 38, an induction plate 39 is arranged, which is connected to a power source not shown. 7 -i ·: -;,: / ■ ': ■: -; ■■■' Basically, neutrons are generated by one or more of different possible nuclear reactions within the accelerator tube 2, depending on the composition of the ionizable gas or Gas mixture 21 and the target 22. If the ionizable gas 21 consists, for example, of pure deuterium and the target 22 only

5 6

Contains deuterium, and if the deuterium continues, the electrostatic generator 4 is used in addition to being ionized for circulating gas and finally the deuterium generation of ions through the acceleration gap 26 is accelerated in the direction of the ion flow impregnating with deuterium, also to the developed target 22 the development of a corona current flow between the upper DD reaction (Deuterium-Deute- 5 hollow electrode 32 and the generator housing. Da rium reaction) to generate neutrons with the upper hollow electrode 32 not only against the uneiner energy of about 2.2 million Electric voltage. tere hollow electrode 35, but also to ground the well-known io tion current between the anode 24 and the cathode DT reaction (deuterium-tritium reaction), at 23 the gas 21 ionizes until a current flow entder neutrons with an energy of 14.4 million winds between the upper hollow electrode 32 electric volts can be generated. Because the DT reaction and the case proceeds. In order to generate a much larger number of neutrons, a pointed corona electrode 31 and neutrons with an energy of 14.4MiIUo 15 are preferably located on the inner surface of the generator gene Elektrovolt for the investigation of deep boring houses opposite the upper hollow electrode 32 are more suitable, is all stipulated in this case. Since the distance between the tip of the Korogemein worked with the DT reaction. The near electrode 31 and the adjacent surface of the DT reaction also takes place when the ionizable upper hollow electrode 32 is smaller than the distance gas 21 consists of tritium and the target 22 is impregnated with 20 between the latter and any other earthed part of deuterium. In this case, of the electrostatic generator 4, all of the tritium ions are accelerated in the direction of the deuterium contained in the target loss flow between the upper hollow electrode 32, with and mass (apart from the ion flow) between. Neutrons with an energy of 14.4 million of the corona electrode 31 and which this adjacent electric volts are generated. However, the 25th part of the upper hollow electrode 32 requires concentrated, heavy tritium atoms that much more energy is required. As is well known, it is a property of a corona that the target 22 must be accelerated. This charge, that the magnitude of the current flow is negligible, is therefore seldom used in investigations at depths until the voltage on a certain borehole is seldom used; because it always makes value is brought. However, as soon as the voltage die-difficulties, the electrostatic generator exceeds the 30 sen value, the current flow in unnecessary energy increases in an increasing degree for several thousand meters, and if the voltage to feed the deep borehole. As an exception, accelerator tubes with an ionic electrode 32 and the corona electrode 31 are also used in the device between the upper hollow area. 35 contains relatively strong fluctuations in the corona flow, mixed with deuterium and tritium, like the gas, which can only be ionized to relatively small fluctuations in voltage. , 'between the corona electrode 31 and the upper When the device is in operation, the inductive hollow electrode 32 is applied - 40 the acceleration gap 26, since the corona plate generates a correspondingly high positive charge on electrode 31 and the target 22 both essentially on the lower roller 38. The electric motor 5 earth voltage is applied. The voltage on the rotates the lower roller 38 so that the conductive acceleration gap 26 becomes part of the endless belt 37 during the ion flow with other parameters of the transport. The device flows from the upper roller 36 in a relatively stable manner,
this positive charge via the lower hollow electrode between the generator 4 and the ionization 35 and the line 34 to the anode 24 1 ven charge on the anode 24 opposite the cable through a method 23 and the target 22 arranged in the line 34, until between the. self-erasing Geiger-Müller counter 40 gebil-anode and the cathode is a voltage threshold whose threshold voltage is greater than the range at which electrons begin to flow from the cathode 23 threshold voltage of the ionization electrode 24 to the anode 24 and the Anode with respect to the ionization electrode 23. The center-cathode capacitance is discharged. This the ionization 55 electrode 41 of the Geiger-Müller counter 40 is connected to the lower hollow electrode 35 with tion gap 25 flowing electron stream, while in this area the from the deuterium or the jacket 43 of the counter 40 with the anode 24 of the the tritium existing ionizable gas 21 is conductively connected to ionic accelerator tube 2. While sieren, these positively charged ions from the operation of the device, a positive La cathode 23 will be attracted accordingly. Since the cathode 23 is lattice-shaped through the endless belt 37 to the upper roller, the 36 and then most ions penetrate through the cathode 23 and are transported to the lower hollow electrode 35 in the manner already described At high speeds due to the arrangement of the Geiger-Müller counter 40, the acceleration gap 26 on the brake ring, no current flows to the anode 24, since the endgen 12 moves past the target 22. As already mentioned 65 loose tape 37 of the center electrode 41 of the counter 40, it is this acceleration that supplies hydrogen with a steadily increasing charge, isotopions develop on the isotopic nuclei in the target 22, which leads to the various voltages in the device to generate the neutrons . the capacities formed by the electrodes,

7 8

For example, between the center electrode 41 and the man- preferably made of an impermeable material so tel 43 of the meter 40 between the anode 24 and the that the recess serves to collect the radiation emitted by the upper trigger hollow electrode 32 between the two hollow elec- tronics. Thus 32 and 35 trode, furthermore between the support tube, the trigger element 44 causes a radiation 23 A and the anode 24 and between the cathode 5 to bundle the counter 40 with each revolution of the obe-23 on the one hand and the brake rings 12 and the tar- ren roller 36 passes over. The speed of the upper get 22 on the other hand. If the Geiger-Müller counter roller and thus also the pulsation speed 40 in the device is arranged so that it can be hit by the neutron source by appropriate incident radiation, the speed of the drive roller of the gene flows every time the incident radiation inner- io rators4 driving electric motor can be determined half of the counter by reducing the threshold. 1 of the Geiger-Müller counter 40 either by a current from the center electrode 41 to the jacket 43 a light-sensitive or by a counter tube sensitive to ultraviolet of the counter 40 and from there to the anode 24 and radiation or a photo of each of these separate current pulses generates 15 each diode to be replaced. In this case the furi cannot have an "impulse" of the ionization current. Corresponding to the trigger element 44, a device generates each pulse of the ionization current, which generates a pulsating visible beam current pulse, which in turn generates a correspondingly delimited neutron pulse for generating a ren or ultraviolet beam with earth potential. This device can lead to any ses. It can be seen that the neutron pulses generated in this way 20 point outside the high-voltage terminal only occur when the are ordered, instead of on the upper roller 36.
Geiger-Müller counter 40 due to incident radiation. In the embodiment shown in FIG. 2, it is hit and therefore triggered. This radiation between the electrostatic generator 4 and can originate from an alpha, beta or gamma radiation from both ionization electrodes 23, 24 sound sources in the vicinity of the meter, or a conventional trigger element can be beta -Radiation from the target 22-filled trigger tube 51 is formed, the anode 53 of which and or around the control grid 52 created within the neutron source have no external connection. The x-rays act. Furthermore, the beam cathode 55 and the holding electrode 54 can be composed of alpha particles generated in the anode 24 of the accelerator tube 2 or the lower connection with the neutrons, or hollow electrode 35 connected. With this arrangement of gamma rays, which ignite in the accelerator tube 2, the trigger tube 51 is produced in a reproducible manner because an inelastic scattering threshold voltage of about 200 to 300 V and the neutrons occur here. Thus, the automatic deletion occurs whenever neutron pulses are generated in a random manner and in a comparatively uncontrolled manner developed by the electrostatic generator 4. If the current is less than a critical value, which in many applications of the invention this range from about 40 to 100 microamps, can be undesirable. . . If a shunt capacitor 56 of 50 Mi-According to FIG. 1, therefore, a lead screen microfarad is further arranged between the cathode 55 and the 42, which lies around the Geiger-Müller counter 40 holding electrode 54 and if a capacitor can be arranged around so that essentially 40 57 out of 100 microfarads between the holding all radiation is kept away from the meter. With electrode 54 and the upper I foal electrode 32 at this arrangement, the electrostatic closed is increased, it is shown that this arrangement generator 4 the charge of the center electrode 41 'of the ionization current pulses at the ionization gap 25 counter 40 until the voltage applied to this counter 40 _{reached with} a frequency of 500 to 5000 pulses per Se- 'certain threshold. As soon as this happens, 45 seconds are generated, the duration of the pulses in the "ignites" the Geiger-Müller counter 40, and an order of magnitude of 100 microseconds or the current surge arrives in the manner described below. This depends in each case on the electrical anode 24. This see values of the circuit elements used flowing through the counter 40. Current is relatively short-lived, however, because if the voltage applied to the meter for capacitors 56 and 57 falls as a result of the current flowing through it, the discharge will be charged. .

In the case of the embodiment of the device according to FIG. 3, only when the counter has recovered, and in FIG. 3, the upper hollow electrode 32 A corresponds to the threshold voltage again. has been achieved. When the upper hollow electrode 32 of FIG. 1 and 2 The hollow counter 40 with the correct threshold value selected ₅₅ electrode 32 A , however, is not conductive with the cable and the operation of the electrostatic generator 4 method 23 of the accelerator tube 2 connected. This is controlled accordingly, so the pulse is as between the generator 4 and the two frequencies of the neutron source, within certain ionization electrodes 23, 24 activated trigger limits can be properly regulated. . .,. element a gas-filled trigger tube 61 is arranged. In the embodiment of the invention according to 60 its holding electrode 64 is electrically connected to the cathode FIG. The case is a very small amount of a radioactive - method 65 of the trigger tube 61 is connected to the modified substance in a recess 45 on the circumference of the upper hollow electrode 32A . Furthermore, the upper roller 36 can be arranged. A shunt capacitor 66 can also be connected to the trigger tube 61 consisting of the Blcischirm42, while the control grid 62 and the anode are designed so that the Geiger-Müller counter 40 63 of the trigger tube 61, as in FIG Direction of the upper roller 36 is accessible. are connected.
In this arrangement, the upper roller 36 consists of the embodiments shown in FIGS.

9 10

Men of the invention generally work properly with a sudden increase in the voltage at the free, but if in these embodiments shunt capacitor 79 Λ leads. If certain electrical values are not selected, the increase in voltage also affects the neutron generation of the method 75 and the holding electrode 74 of the trigger tube accelerator tube 2 after each output pulse only 5 71, so that a short current pulse between the slow goes out. In addition, the accelerator anode 73 and the cathode 75 of the trigger tube 71 can be triggered again to a limited extent with the generation. However, every current flow causes neutrons to begin before the anode 73 and the control grid 72 of the trigger elements 40 or 51 or 61 used ignite, so that the trigger tube 71, that the corona regulator tube 78, the neutron pulses, which are generated with a very high frequency. io table is switched off and is deleted by the fact that the sequence generated is not as sharply delineated as the voltage between its cathode 78 A and its are, as is desired. . Anode 78 B is reduced to a value that

This is important in the embodiment of the invention under the. Forward voltage is. This avoided according to Fig.4. In this embodiment, the trigger tube 71 is "extinguished" so that it is the trigger element, in turn, a gas-filled current flow between its anode 73 and its control trigger tube 71. The cathode 75 of the trigger tube is grid 72 interrupted, whereby the flow of current, however, is interrupted the. The anode 24 of the accelerator tube 2 is connected to the anode 24 of the accelerator tube 2, while the anode 73 is connected via the line. As already with regard to the capacitor 57 34 to the lower hollow electrode 35 and the upper one according to FIG. 2 illustrates, the capacitor of the electrostatic generator determines roller 36 4 20 79 B reasonable depending on its electrical characteristics is the Freschlossen. Both the holding electrode 74 and the frequency with which the anode 24 of the accelerator, the control grid 72 of the trigger tube 71 are supplied with the tube 2 current pulses.
ISA cathode corona regulator tube 78 connectedness During operation of the Ausfühden shown in Figure 4, the anode 78 B to the anode 73 of the trigger induces the approximate shape 39 supplied via the tube-plate is connected 71st The cathode 78 A of the 35 voltage as in the other embodiments of the corona regulator tube 78 is also connected to one side of the endless belt 37 of the generator with a ^1- posieines shunt capacitor 79 A , tive.Ladung, which by means of the upper roller 36, the other terminal of which is connected to the cathode 75 ″ of the lower hollow electrode 35 and the line 34 of the trigger tube 71. In this arrangement anode 24 of the accelerator tube 2 is fed The shunt capacitor 79 A has been supplied with a large charge in order to trigger the trigger process connected in parallel to the trigger tube 71, the distribution divider is the charge that is collected between the tube 78 and is connected to the anode 24 of the accelerator and the capacitor 79 A Part with the niger tube is discharged. This causes the control grid 72 and the holding electrode 74 the trigger 35 the voltage difference at the ionization gap tube 71 is connected. The corona regulator tube 78 25 exceeds a threshold value, and when viewed in isolation, lies parallel to the anode 73 from the cathode 23 of the accelerator tube and the control grid 72 of the trigger tube 71. As. Paths of the cold cathode emission to the anode 24 flie-corona regulator tube 78 is chosen whose ßen. Since a current flows to the anode 24, the threshold voltage being lower than the threshold voltage of the trigger tube 71 that lies between the electrodes developed at the ionization gap 25, special trigger tube 71 also carries an increasing charge between other electrodes of the device. B. at the acceleration gap 26 between 78 at a speed that, according to the 45, the brake rings 12 and the target 22 and between the size of the capacitance between the upper Hohlelek- see the cathode 23 and the brake rings 12. trode 32 and the cathode 23 the accelerator- When a current flows through the ionization gap 25, tube 2 directs. Therefore, preferably a con- the voltage difference between the Kadensator 79 B is provided in order to reduce this speed, method 23 and the anode 24 proportional to the size that determines the pulse frequency of the device, 50 of the transported charge. When set to the desired value. Conductivity of the trigger element ceases, so-

When on the corona regulator tube 78 the threshold with the voltage difference between the cathode

voltage is reached, this tube lets a current 23 and the anode 24 immediately to the threshold value

from the anode 73 of the trigger tube 71 back to the one at which the conductivity ceases. So hear

Control grid 72 and the holding electrode 74 flow. 55 the ionization in the accelerator tube, and the

Each corona regulator tube, however, has the property that generation of neutrons is interrupted until that their forward voltage is considerably lower and the cycle is repeated after

as their threshold voltage, so that the voltage has accumulated a charge by which the

drop at the corona regulator tube 78 to a corresponding trigger element is triggered again. _^:: "

1 sheet of drawings

Claims (6)

1 2 • shunt capacitor (79 Λ) of existing voltage claims: voltage divider is located with a part between its "main parts (78 and 79 A) 1. Device for generating the body of the control grid (72) and the holding electrode larstrahlimpulsen, in particular from neutrons 5 (74) of the trigger tube (71) is connected, wherein pulses, with a resting amount of the corona regulator tube (78) considered for itself, to be ionized gas containing housing, parallel to the anode (73) and the control grid two electrodes in an ionization space (72) of the trigger tube (71). close and of which the one acting as a cathode is at free potential, a target, io ■ - that with one of the two ionization electrodes an acceleration distance for those from the
Ionization chamber forms extracted ions, as well as an electrostatic generator, which both The invention relates to a device for erionizing Voltage impulses as well as the generation of corpuscular beam impulses, especially accelerating ones DC voltage supplies, that of neutron pulses, with a one characterized by that between the quantity of a gas to be ionized contained Generator and one of the two ionization housings, two electrodes that enclose an ionization electrode (23, 24), a trigger element (40, 51, 61 space and of which the cathode or 71) is switched on, the active potential is at free potential using 20, a target, the voltages generated in the device correspond to one of the two ionization electrodes Electrode intermittently to the generator - Accelerating path for the ions extracted from the ionization coupling, forming space, as well as an electro- 2. Device according to claim 1, characterized in a static generator which characterizes both ionizing chips, that the trigger element (40) by 25 voltage pulses as well as the accelerating equinox Geiger-Müller counter is formed whose voltage supplies. Threshold voltage is greater than the threshold voltage There has long been an effort to voltage of the ionization electrode (24) with respect to services of this type, e.g. for their use for the ionization electrode (23). To train borehole measurements so that they have a 3. Apparatus according to claim 2, generate with a 30 abruptly pulsating neutron radiation, electrostatic generator with one of two The practical realization of this endeavor in Rollers driven, endless revolving in such a way that pulsating radiations with an imband, characterized in that in a pulse duration of less than one hundred microseconds and saving (45) of the Geiger-Müller counter (40) a pulse duration of 500 to 5000 pulses in the adjacent drive roller (36) of the endless, 35 seconds can be generated, but has been found to be circumferential belt (37) a small amount (44) proved difficult. a radioactive material is housed and in principle, a device of the gedaß the material of the drive roller (36) for the type mentioned can be operated in such a way that newly emitted radiation is impermeable, so that tron impacts only by switching on and off every revolution of the drive roller a reduction of 4 ° of the power supply for the operation of the electrostation the threshold voltage brings about. table generator. This kind of 4. Apparatus according to claim 1, characterized in that pulse generation is also described in the USA patent indicates that the trigger element (51) is described by 2960 610, which is a device of the voreine gas-filled trigger tube is formed, the type specified standing shows as known and in Anode (53) and control grid (52) do not have an external 45 which is indicated, among other things, that with this connection have, while the cathode (55) known device neutron pulses are generated by connecting and holding electrode (54), optionally switching the power supply on and off can through between the holding electrode (54). Since the known device in the rest and the cathode (55) or between the holding no other means for generating pulse electrodes (54) and the ionization electrode (23) 50 sen and such other means are arranged in the pa Capacitors (56 and 57), which are also not mentioned in the initial publication in any way, is have required threshold voltage. - only the pulse generation through this patent specification 5. The device according to claim 1, characterized by turning the electrostatic on and off, that the trigger element (61) is known by nerators. Such a pulse generation is one between the electrostatic generator 55 but not useful for practical purposes because the . and the ionization electrode (23) arranged device after the respective shutdown of the gas-filled trigger tube (61) is formed, with power supply always a relatively long the capacities of the holding electrode (64) and the time it takes to become fully effective, and therefore Cathode (65) possibly by a Kon neutron pulse in this way only with lower capacitor (66) are bridged. 60 frequency and generated only fuzzy and indefinitely 6. Apparatus according to claim I, can be thereby. In addition, when pulsing in indicates that the trigger element (71) in this way only very few neutrons in one leg Trigger tube (71) is formed, the anode of which are generated at the correct time. Practically useful (73) with the electrostatic generator and devices of this type must, for. B. for drilling its Cathode (75) with the ionization electrode 65 hole measurements to be able to generate neutron pulses (24) are connected and that parallel to the very high, predeterminable frequency, so to he trigger tube (71) one from a corona regulator testify that every impulse is precisely defined and sharp tube (78) and a series-connected Ne- is delimited.