DE1046206B - Tubeless extinguishing circuit for counter tubes - Google Patents

Description

Tubeless extinguishing circuit for counter tubes The use of electronic Break-away circuit for the operation of non-self-extinguishing counter tubes is known. Such circuits, so-called "Extinguishing circles". used with advantage.

An extinguishing circuit in connection with a self-extinguishing counter tube has the task of maintaining the voltage on the counter tube for an adjustable time slightly longer than the recovery time of the pipe is chosen, below the threshold voltage to press down. This prevents the occurrence of secondary discharges and maintains long and flat plateaus, the slope of which also changes in the course of the incense Steam filling not increased. The useful life of the counter tubes is therefore noticeable extended.

The disadvantage of the electronic extinguishing circuit is a certain amount of effort on tubes and circuit as well as the condition that the quenching circuit with its special Feeds for heating and anode voltage are usually attached close to the counter tube must, which can be annoying at times.

There are also known counter tube circuits. at those for the purpose the reduction of the counter tube voltage with increasing radiation intensity Extinguishing resistor in series with one consisting of a resistor and a capacitance Parallel connection is used. These measures to reduce the counter tube voltage thus makes an extinguishing effect in the above sense impossible.

According to the invention, these disadvantages are alleviated by a tube-less extinguishing circuit avoided for counter tubes, which is characterized by this. that he is a passive electrical Network possesses which is dimensioned such that during the formation of the space charge In the counter tube there is practically no charge replenishment to the counter tube. that further after triggering a counter tube discharge, a brief one to erase and prevent Sufficiently strong counter-voltage occurs from I \ Tachentladell, while at the A voltage pulse that rises as steeply as possible arrives at the amplifier input. so that address the usual counting devices.

No tubes are required with this extinguishing circuit. It will rather, in a preferred embodiment, only a small RC combination with hest electrical dimensions matched to the counter tube are connected upstream of the counter tube. The extinguishing effect is almost as good as that of an electronic circuit, and besides the pulses become the amplifier input with practically no loss of edge steepness of the counting device. That is in the practically important cases where that Counter tube is connected to the counting amplifier via a long cable, especially advantageous. This is where the main field of application of the invention will lie.

In a self-extinguishing counter tube that works in the trigger area, a primarily ionizing event causes an avalanche of charge carriers in the immediate vicinity Triggered near the counting wire.

A cloud of electrons is created with the charge - q, which is in fractions one microsecond to the counting wire, and a sluggish positive ion cloud of the Charge + q, which only reaches the cathode after about 200 off. The movement of the Space charges inside the counter tube determine the current flow in the external circuit.

Fig. 1 shows the most commonly used circuit of a counter tube 1 a high voltage source 2 with the constant DC voltage E. To the resistor For example, a counting amplifier (not shown) is coupled to R3. Cz is the capacitance of the counting wire against the earthed cathode, J the current intensity in the external Discharge circuit as a function of time, and R3 J the voltage curve at R3.

A first extreme operating state occurs when R3 is very small is, so that the voltage at the counter tube 1 is constant E during the discharge. Fig. 1 a then shows the time course of J. The process is completed. when the positive space charge q has reached the cathode after around 200 s (end of Recovery time). It is essential that the formation and migration of the electron cloud does after the order of 0.4 ins have ended. After 1 what, i.e. immediately after The start of the migration of the positive ion cloud has the current integral over time already half, after 5, as reached around two thirds of q. So after 5 ys it is the charge equalization mostly over, but only after 200 tis it will Current integral reach the final value q.

A second extreme operating condition occurs when R3 is so large it is chosen that during the internal charge movement in the counter tube no appreciable amount of electricity flows as the conduction current J to the counting wire. the The voltage on the counter tube 1 then drops. Fig. Lb shows the voltage drop on the counter tube 1, which is identical to the applied voltage R3 1 across resistor R3. The curve in Fig. 1 b is almost the integral curve of the curve in Fig. 1 a.

Already after about 0.2 ys the voltage on the counting wire has dropped noticeably, after 5 µs the fall is essentially complete, but the final value becomes qlCz reached only after about 200 ps.

Of practical importance are three cases between these two extremes Operating states are: 1st case: The time constant R3Cz is small around 5 s, i. H. small compared to the essential duration of the internal charge equalization in the counter tube. - The case is given when R3 is less than 100kOhm (Cz = approx. 5pF at average Pipe size). The voltage drop at R3 then essentially follows the modalities the first extreme operating condition. A very short voltage spike occurs R3J corresponds to the current j in FIG. 1 a. The operating condition is unfavorable. the The voltage peak has only a small amplitude because R3 is small according to the assumption. Also after-discharges, which worsen the plateau and the service life of the counter tube diminish can occur as they are neither suppressed nor their emergence is made more difficult.

2nd case: R3 Cz is of the order of 5 ys. -That's with one Resistance R3 of the order of 1 megohm is the case (C, = about 5 pF). It takes place then in the first microsecond, in which the inner counter tube discharge is largely runs out, practically no replenishment of charge to the counting wire, and the voltage at the counter tube falls steeply according to the modalities, n of the second extreme operating state away. Further compensation takes place according to modalities that exist between the first and second extreme operating condition. After 5 es, so after the main one Part of the inner counter tube discharge, the voltage on the counter tube is roughly the total 1/2. q / C2 please. Then Cz is recharged via R3 with the time constant R3 Cz. Fig. 1 c shows the corresponding voltage curve R which is characterized by an initially steep increase during the first 5 µs is.

Since the voltage on the counter tube already after 0.2 ps, i.e. already during the formation time of the electron and ion cloud, has noticeably decreased the space charge q and the current integral of J only compare to about 80% the 1st case. This will cause post-discharges to occur after higher voltages E shifted, and counter tube plateau and I, service life are improved a little.

3rd case: R2 C2 is as long as the recovery time of the counter tube, that is, of the order of magnitude of 200 ills.

This corresponds to an R3 of around 40 megohms fCz = around 5 pF). The ratios are then initially as in the second extreme operating state. Fig. 1d shows the voltage pulse at R3, which, however, decays here with the time constant 200 lls.

Space charge and current integral are again only 80 ° lo their size compared to Case.1, which has a positive impact on plateau properties and service life affects. It is more important, however, that when the positive ion cloud arrives at the Cathode, i.e. after around 200 s, the counter tube voltage is still so reduced. that no after-discharges can occur and the tube is fully deionized. pitch and length of the plateau are now against the 2nd case and even more against the 1st case is significantly improved, and the service life is also longer. These advantages are not sold by a loss of edge steepness of the first rise in voltage R3J, which, as in the 2nd case, takes place in 5 Fs, which for the later differentiation of the pulses is important in the amplifier input.

An even greater time constant R3Cz than in the third case would not result in any further Bring benefits, but only through the artificial extension of the recovery time worsen the resolving power of the counter tube circle.

The simple relationships outlined here are now in reality mostly not before. Usually the counter tube 1 is shown in FIG. 2 via a shielded cable line 4 connected to a counter with high resolution. The cable line 4 can easily be used in the case of radioactive level gauges and borehole probes some 100 m long and have a capacitance C4 of 20,000 pF and more.

With the usual counting devices for laboratory use, 4 is only a short connection cable with about 150pF. But that's enough about the circumstances to be fundamentally modified in an arrangement according to FIG. 1, such as that shown in FIG Equivalent circuit of the arrangement according to FIG. 2 shows.

A sufficient level of the voltage pulse at R5 that the input sensitivity of the commercially available counting devices is adapted (order of magnitude 1 volt), can only be achieved by setting the time constant - as is common practice R2 makes C4 very large compared to all other time constants of the counter tube circuit. the Capacitance C4 is then slightly increased by a pulse of J of short duration T. discharged without a noticeable drop in charge taking place via R5, and then, when 1 has decayed, recharged via R5 with the large time constant R5 C4. The maximum height of the voltage pulse at C4 and thus also at R5 is approximated equal to the current integral of 1 divided by C4 or equal to q / C4. The pulse height in all practical cases is at most a few volts.

A noteworthy reaction of the R5 C4 element on counter tube 1 therefore does not take place, and the course of J takes place as if the R5 C4 element would not be present at all, d. H. as in the case of an arrangement according to FIG. 1. The time constant R5 C4 tends to be on the order of 0.15 to 2.0 ms.

(For a borehole probe with C4 = 20,000 pF, e.g.

R5 = 100 kOhm and R5C4 = 2 ms. With commercially available counting devices Ró = 1 Megohm and the capacity of the short connecting cable C4 = 150pF, i.e. R5 C4 = 0.15 ms.) The usual shape of the voltage curve as given under the condition the arrangements of FIGS. 2 and 3 occurs, Fig. 3a shows for four pulses.

There is no noticeable reaction of the R5 C4 element on the counter tube takes place and the high voltage at C4 is practically constant, the counter tube works 1 under the same conditions as in the case of an arrangement according to FIG. 1, when R3 = 0, so under the conditions of the first extreme operating state. J proceeds accordingly Fig. 1 a. The time T of the steep rise of the pulses at R5 is approximately 5 ills, corresponding to the fact that already after 5 Fs the charge transport through J in the The main thing is finished. The subsequent slow fall takes place with the large one Time constant R5 C4. By a (not shown) differentiating RC element in the Amplifier input it is achieved that the amplifier only responds to the steep edges in Fig. 3a, which are converted into short single impulses and to trigger the following coasters or a univibrator.

The widespread arrangement according to FIG. 2 is favorable in that as it delivers steep increases in voltage to R5. On the other hand, however, works the counter tube under the very unfavorable operating conditions of the 1st case (above). Post discharges are not suppressed and the circuit does not contain any elements to improve the counter tube plateaus and the service life. In addition, there is unfavorable gas fillings increase the risk of flashovers on the insulators inside of the counter tube 1, because the tube without an upstream protective resistor on the High voltage charged cable capacitance C4 is.

It is therefore occasionally recommended, as shown in FIG. 4, immediately to connect a resistor R0 of one or a few megohms in front of the counting wire. This avoids the risk of rollovers.

Otherwise, the counter tube is now unloaded according to the modalities of the 2nd case (above). One can estimate based on Fig. 1 c that after 10 ills the current integral of J has essentially reached the maximum value q, so that the rise time T in Fig. 3a about 10, us lasts about 5 Fs in the arrangement of the Fig. 3. The rise time is therefore not significantly impaired. on the other hand are in the arrangement according to FIG. 4 for the same reasons as in the 2nd case (top) the plateau properties and the service life compared to the case of FIG. 3 thereby slightly improved that the space charge q is only about 80%. However, the subsequent discharges are not suppressed here either.

After all, the resistor R6 represents a step forward, especially since it is with no significant deterioration in the slope of R5 i is bought.

The suppression of the secondary discharges and thus a significant flattening and extension of the plateau, combined with an increase in the service life of the counter tube and security against internal flashovers is only achieved when R6 is on the order of magnitude 40 megaohms is increased. The time constant R6 Cz is then about 200 ills, and the counter tube works under the very favorable operating conditions of the 3rd case (above). Nevertheless, the arrangement is practically useless because of the charge transport by J only after the time R6 Cz, i.e. only after about 200 Fs in the main over is (Fig. 1 d). The rise time T in FIG. 3a is therefore also of the order of magnitude 200 Fs, which means that the slope of the rise is so small that without additional Gain and amplitude limitation with the usual counting devices are not sufficient high and short pulses behind a differentiating RC element at the amplifier input can be achieved.

By a tube-less extinguishing circuit according to the invention this Additional effort in amplification and pulse shaping avoided and still good edge steepness and extinguishing effect achieved. In this preferred embodiment of the invention there is this tubeless quenching circuit made up of a resistor and a resistor and a capacitance existing parallel connection and is direct to the counter tube upstream.

5 and 7 are two exemplary embodiments of counter tube circuits shown with the extinguishing circuit according to the invention. Fig. 6 is the equivalent circuit the arrangement according to Fig. 5. As indicated in the drawing interpreted, it becomes the resistance R1 and the quenching circuit according to the invention consisting of the parallel connection of R2 with C7 interconnected with the counter tube 1 in such a way that longer connecting lines are not required. In the exemplary embodiments, the resistor R1 is connected to the counting wire 8.

However, R1 and the parallel connection can also be interchanged.

In another, not shown embodiment of the invention the parallel connection (R2, C7) with the counting wire and the resistor R1 with the counter tube jacket or the parallel connection with the counter tube jacket and the resistor Rj connected to the counting wire. However, it is also possible to use the inventive Design the RC combination in such a way that, on the one hand, from the parallel connection of R2, with the series combination Ri + C7 on the other hand and the overall combination either upstream of the counting wire or the casing of the counter tube.

The operation of the extinguishing circuit according to the invention should be based on hand the equivalent circuit in Fig. 6 will be explained.

The time constant R2 C4 is, as usual, 0.15 to 2.0 ms. C7 should advantageously have the same size as C2, i.e. H. about 5 pF, with large counter tubes 10 pF.

- For Ru this requirement applies that the time constant t1 = Rj C7 Cz: (C7 + C2), that is the time constant of the series connection of R1, C7 and Cz, on the one hand is large compared to the formation time of the space charge, which is about 0.4 Zs, on the other hand but to achieve as steep a rise as possible from R5 i about 5 Iris, that is does not exceed the essential duration of the internal charge equalization in the counter tube. In general, Rt will be approximately 1 to 2 megohms. - R2 is chosen so that the time constant t2 = R2 (C7 + C2) is roughly equal to the recovery time of the counter tube, which is around 200 ills. One arrives at values in the order of magnitude for R2 20 megohms. - Under these conditions, the discharge process takes place in three parts Phases from: The first phase proceeds as if the high resistance R2 does not exist were. It is handled according to the modalities of the 2nd case (above). From the fixing The time constant t shows that during the first part of the charge movement in counter tube 1, d. H. in the first microsecond, no significant charge replenishment to the counting wire 8 via R1. The voltage on the counter tube therefore drops steeply at first from (Fig. 6 a, part AB). The counter tube 1 is then recharged with the Time constant tt through current 1 (Fig. 6 a, part BC).

The recharging of the counter tube does not go up to the original one Voltage E, because through J at the same time C7 is charged to an opposite voltage to which reduces the original voltage E on the counter tube. For the counter tension from C7 at the end of the equalization we get q:: q: (C7 + Cz). The duration of the whole Compensation ABC is about 2 t.

In FIG. 6 a, the value 5 Fs is assumed for t1.

The charge transport of J associated with the equalization results to q C7: (C7 + C2). It is now essential that this current integral, which during the Time 2 t1 comes about, in this short time the voltage at C4 by q C7: (C7 + Cz) C4, because the time constant R5C4 is usually large compared to t ,. A voltage drop R5i therefore occurs at R5, which occurs in time 2 t1, i.e. in about 10 Fs, steeply to the value q C7: (C7 + Cz) C4 increases. In Fig. 6b, part AC is the steep rise of R5i in the case of two closely spaced collisions applied.

This ends the first phase. First, the result is a steep one Voltage rise at the amplifier input in around 10 Fs and secondly the charging of C to the counter voltage q: (C7 + Cz) and thus the reduction of the counter tube voltage by this amount, whereby an extinguishing effect is achieved.

Resistance R2 could be overlooked until now because of the duration 2 t of the first phase is very short compared to the time constant t, 2 with which C7 discharges again.

The second phase consists precisely in this long-lasting discharge from C7 to R2. This means a decrease in the counter-voltage at C7 and at the same time Slow increase of the counter tube voltage to the original value E with the time constant t2, which is about 200 ins (Fig. 6a, part CD). Since t2 is about the assumption Corresponds to the recovery time of the counter tube, the voltage on the counter tube remains during humiliated throughout the recovery period. the tube is deionized, and post-discharges, otherwise towards the end of the recovery period when the positive ion cloud arrives on the cathode can be triggered under certain circumstances, are suppressed. There the time constant t2 is decisive for the resolution of the counting arrangement, there would be no point in making them much larger than necessary; d. H. greater than to choose the recovery time of the counter tube.

The charge transport of J in the second phase provides the amount of electricity q C2: (C7 + Cz), which discharges C4 and a second one at R5, but this time slowly Voltage rise with the time constant t2 up to the final voltage qiC4 (Fig. 6b, part CD).

The third and final phase of the whole process is recharging of Cd with the large time constant RãC ,,. This creates a very slowly with the Time constant R; C4 decaying voltage at R5 (Fig. 6b, part DF). A differentiating one The RC element at the amplifier input does not respond to this.

It can only affect the entire voltage curve in FIG. 6b to address steep flanks AC.

Only these are decisive and are converted into short individual impulses.

The balance over all three phases shows an extinguishing effect on the Counter tube that lasts for the entire recovery time and subsequent discharges arise with special needs. At the same time, there are steep voltage edges at the amplifier input on. that the ühlichen counters respond.

The dimensioning of C7 is important.

If you measure C7 as large against C. then the steep climbs AC fall the voltage at R5 (Fig. 6b) is very large. but the smaller is the counter-tension at C7, the smaller the voltage drop on the counter tube (Fig. 6a) and the extinguishing effect is all the worse. The rings are the other way around if you make Cr small compared to C2. A good compromise is roughly C7 = C2.

The extinguishing effect is essential and additionally due to the fact supports. that the voltage on the counter tube is already down because of the setting above t1 0.2 L1S, i.e. already during the formation time of the electron and ion cloud in the counter tube has dropped noticeably (Fig. 6 a, part AB). It is therefore formed when it is present of the quenching circle the positive and negative space charge q only to about 80 ovo of the height that it would reach without an extinguishing circle. Reducing the space charge through the inventive extinguishing circle not only extends the life duration of the counter tube, but the occurrence of post-discharges is also postponed to higher voltages and thus the steepness and length of the plateau improved even further.

This additional extinguishing effect does not apply if the time constant t1 is too small in the extinguishing circle according to the invention, d. H. if R1 selected too small or omitted entirely. Then, in Fig. 6a, the transition from A to C takes place lengthways the dashed line, and there is no noticeable development after 0.2 ps the drop in voltage on the counter tube inhibiting the space charge. On the other hand, the Time constant t ,. d. H. the resistance Rs, not to be made unnecessarily large so the desired steep edge steepness of the pulses at the amplifier input does not suffer. The existence and proper sizing of R1 are therefore essential for optimal functioning of the extinguishing circuit is essential. Furthermore, in each case a through the resistor R1 Internal breakdown in the counter tube due to excessive voltage or unsuitable filling certainly prevented.

It is favorable to use the extinguishing circuit according to the invention in the first place to be used for self-extinguishing counter tubes.

The applicability of the circle of vision according to the invention is not applicable the .9cl2aitung shown in Fig. 5, where the extinguishing circuit between the Counter tube 1 and the input of a downstream amplifier is arranged on which then negative input pulses occur. The mode of action is also with others Coupling to the high voltage source the same. For example, in FIG. 7 Ine embodiment of a counter tube circuit with the extinguishing circuit according to the invention shown in which the cathode of the counter tube to achieve positive input pulses 1 with the input of a not shown connected to a working resistor R5 Amplifier is connected. In all cases, however, it is advantageous to ensure that that the RC combination is attached as directly in front of the counting wire as possible, because a longer connecting line between the counter tube 1 and R, the effective Increase the counter tube capacity Cz and thus unnecessarily impair the extinguishing effect would. A useless increase in the effective counter tube capacity C2 and thus a The extinguishing effect is also impaired if R1 or the parallel circuit from R2 to C7 or both are connected upstream of the counter tube casing instead of the counting wire are. The arrangement is therefore corresponding among the various possibilities FIGS. 5, 6 and 7 are most favorable.

It is within the scope of the invention to consist of a resistor and a composed of a resistor and a capacitance in parallel Replace the extinguishing circuit by electrically equivalent networks, with these - accordingly the above can be dimensioned such that once during the development the space charge in the counter tube has practically not yet been replenished to the counting wire, and that on the other hand the voltage on the counter tube is sufficient during the recovery time is reduced, and that furthermore a voltage pulse which rises as steeply as possible reaches the amplifier input.

If several counter tubes are connected in parallel, each individual tube must be provided with an extinguishing circuit according to the invention. With a common extinguishing circle for all counting tubes, not only would the resolution of the counting arrangement be considerable deteriorated, but also the extinguishing effect because of the increase the effective counter tube capacity Cz can be greatly reduced.

PATENT APPROACH 1. Tubeless extinguishing circuit for counter tubes, marked by a passive electrical network, which is dimensioned such that during the Formation of the space charge in the counter tube, practically no charge replenishment to the counter tube takes place that further after triggering a counter tube discharge a short-term, Sufficiently strong counter-voltage to extinguish and prevent subsequent discharges occurs, while at the amplifier input a voltage pulse rising as steeply as possible arrives, so that the usual counting devices respond.

Claims (1)

2. extinguishing circuit according to claim 1, characterized in that the electrical Network of a resistor (R1) in series to a parallel circuit of one Resistance (R2) and a capacitance (C7). 3. extinguishing circuit according to claim 2, characterized in that the resistor (Rl) and the mentioned parallel connection are connected directly to the counter tube, so that longer connecting lines are not required. 4. extinguishing circuit according to claim 3, characterized in that the resistor (Rl) is arranged between the parallel circuit and the counter tube (1). 5. extinguishing circuit according to claim 4, characterized in that the resistor (Rl) is connected to the counting wire (8) of the number tube. 6. extinguishing circuit according to claim 2 or one of the following, characterized in that that the size of the resistor (Rl) is chosen so that the time constant of the series circuit (Rt, C7 and Cz) on the one hand is large compared to the formation time of the space charge in the counter tube (1), so that no substantial charge replenishment occurs during the development of the space charge to the counting wire takes place, and that on the other hand the time constant a few microseconds does not exceed, so that the desired steep increase in the voltage at the work resistance (R5) is not unnecessarily flattened. 7. extinguishing circuit according to claim 2 or one of the following, characterized in that that the size of the capacity (C7) is chosen so that after recharging counter-voltage occurring in the counter tube (1) at (C7) the voltage at the counter tube (1) depresses sufficiently to reduce the likelihood of recharge during to effectively reduce the recovery time of the counter tube (1). 8. extinguishing circuit according to claim 7, characterized in that the capacity (C7) is selected to be approximately equal to the counter tube capacity (Cz). 9. extinguishing circuit according to claim 2 or one of the following, characterized in that that the resistance (R2) and thus the time constant of the resistance (R2) and the sum of the capacitances (C7 and Cz) formed RC circuit is chosen such, that the time constant is approximately equal to the recovery time of the counter tube (1). 10. Use of the extinguishing circuit according to claim 1 or one of the following for self-extinguishing counter tubes. 11. counter tube assembly with an extinguishing circuit according to claim 1 or one the following, characterized in that this between the counter tube (1) and the input of a downstream amplifier is arranged. 12. counter tube assembly with an extinguishing circuit according to claim 1 or one of the following claims 2 to 10, characterized in that the cathode of the counter tube (1) connected to the amplifier input and a load resistor (R5) provided is. 13. Use of the extinguishing circuit according to claim 1 or one of the following with counter tubes connected in parallel, characterized in that each individual Counter tube is provided with an extinguishing circuit. Documents considered: French patent specification No. 1,082,484; Korff: "Electron and Nuclear Counters", 1955, p. 266.