DE1261598B - Method and device for measuring the energy of short electrical voltage pulses by means of a tube filled with inert gas - Google Patents

Description

Method and device for measuring the energy of short electrical Voltage pulses by means of a tube filled with noble gas It is known in electrical To use electrical circuits as switching devices with tubes filled with noble gas, the have two stable working states, in one of which the tube is conductive and in which other it is non-conductive. To get such an interrupter from the non-conductive To switch the state to the conductive state, one of its electrodes becomes a control pulse fed from a certain height, which ionizes the noble gas. Once the tube is through such a control pulse has been made conductive, then it remains in the conductive State until the inert gas filling is deionized again by a new control pulse will.

In contrast, the object of the invention is to use a noble gas filled tube for another purpose, namely to use the energy short electrical voltage impulses, the duration of which is only a few thousandths of a microsecond can be to measure.

So far it was not possible to use the energy of short voltage pulses to measure immediately. It could only be the peak value of such voltage pulses be measured. Since the energy of pulses of the same form the peak voltage of the Pulse is proportional, could by measuring these peak voltages by means of conventional devices only one changes in the energy between the individual pulses can be determined, and moreover, the devices used for this had a very complicated training.

A most widely used known device for measuring the Peak voltage of pulses consists of an array of flip-flops from of the triode or thyratron type. The peak voltage can be approximated to a certain extent thereby determine that the tilting devices, whose polarization threshold is smaller than the voltage to be measured is triggered and the other tilting devices do not to be triggered. It is then known that the peak voltage has a value between the highest polarization threshold of the triggered flip-flops and the lowest The polarization threshold of the non-triggered tilting devices is. Such The arrangement is extremely complex and naturally provides inaccurate measurement results, and all the more so as the number of tilting devices is difficult in practice to be chosen large enough to cover the interval between the successive threshold values to reduce to a sufficiently low amount necessary to achieve a satisfactory Measurement accuracy is necessary.

According to the invention, a method of measuring energy is shorter electrical voltage impulses created by means of a tube filled with noble gas, which is characterized in that the noble gas in the tube is thereby continuously ionized state that a DC voltage is applied to two in the tube arranged electrodes is applied, the distance between which is chosen such that the Product of this distance (in millimeters) and the pressure of the noble gas in the tube (in millimeters Hg) a value between 12.5 and 125 results in the one electrode the short voltage pulses are supplied, which increase the conductivity of the noble gas change and thereby voltage changes at the other electrode (approximately in the form of of square waves), and that the duration of these voltage changes (width square waves), which is proportional to the product of the size and duration of the short pulses is measured.

Since in the method according to the invention the duration of the output the voltage changes occurring in the tube are generally 100 to 100,000 times the Duration of the short pulses fed to the tube, it can be conveniently measured and thus the energy of the impulses can be easily determined.

One suitable for carrying out the method according to the invention Device contains a tube filled with a noble gas, the one or two center electrodes and a peripheral electrode, one of which is the center electrode receives the short pulses to be measured and the peripheral electrode with a device for measuring the voltage changes caused on it is connected, and a DC power source connected between the center electrode and the peripheral electrode DC voltage is generated, which keeps the noble gas in the tube in a permanently ionized state holds.

The noble gas in the tube can be made up of helium, neon, argon, or krypton Xenon exist.

The electrodes of the tube are preferably made of nickel, aluminum or molybdenum.

The invention is explained below with reference to the drawing at various Embodiments explained.

F i g. 1 is a schematic representation of a device according to FIG of the invention, which has a tube 11 filled with noble gas, which has a rod-shaped Center electrode 12 and a cylindrical circumferential electrode arranged coaxially therewith 15 contains.

The center electrode 12 is on the input side to a conductor 13 and on the output side connected to a conductor 14 which is connected to earth via a resistor t9 is. The peripheral electrode 15 is by means of a conductor 16 via a resistor 18 connected to the negative pole of a DC voltage source 17, the other Pole is grounded. In this way, a DC voltage is applied to electrodes 12 and 15 which is greater than the ignition voltage of the tube and the inert gas filling in permanently ionized state.

The short pulse to be measured becomes the center electrode 12 of the tube 11 fed via the conductor 13. The change in the Conductivity of the noble gas causes a change in the point P of the outlet conductor 16 lying voltage, in this case the peripheral electrode 15 a has negative polarity.

The change in voltage at the point P, which is due to the momentum caused increase in the conductivity of the gas turns out to be represents an approximately square-wave voltage increase that is maintained over a period remains which of the energy of the applied short pulse, i. H. the product is proportional to its size and duration. All the point P can therefore be one Voltage, which has approximately the shape of a square wave, whose Width (length of their crest) corresponds to the energy of the pulse. The duration of this Square-wave voltage change can be made with any appropriate Device are measured, for example with a cathode ray oscilloscope for alternating current or with one with a capacitor or a rectifier, like a diode, connected galvanometer.

The one on the circumferential electrode 15 of the tube, i.e. H. occurring at point P. rectangular voltage wave is always a result of the capacitive effect between the center electrode and the circumferential electrode are preceded by a voltage surge Amplitude is usually greater than the height of the rectangular voltage wave, like this from FIG. 2 can be seen.

Given the relative importance of this preceding surge with respect to the approximately square wave-shaped voltage change desires it may be beneficial to have a tube. of the in F i g. 3 shown schematically Execution to use. This tube 21 contains two rod-shaped central electrodes 22 and 23 and a cylindrical peripheral electrode 25. The one center electrode 22 receives the impulses to be measured, which are fed to it via a conductor 24, while the DC voltage which keeps the noble gas of the tube in a permanently ionized state is applied to the second center electrode 23 and the peripheral electrode 25 these two electrodes are connected in a circuit containing a battery 27 and a resistor 26. The square wave voltage changes according to the changes in conductivity caused by the short pulses supplied of the ionized gas are taken off at the point Q.

The embodiment shown in Figure 4 is that according to Similar to Fig. 1, but here an electromagnetic field, which the change the conductivity of the ionized noble gas inside the tube from the outside induced, instead of inside the tube by means of one guided over the center electrode Impulse to be generated. It was found that with a sufficiently strong electromagnetic field, for example by means of those used in telecommunications Hertzian rays or by means of Rådar rays is generated, the conductivity of the Noble gas can be changed from the outside of the tube, creating a very simple and effective means of detecting and measuring electromagnetic Waves is given. In such a case, a center electrode would not be required be. Two electrodes of a bellebi type could be provided in the tube which a voltage is applied, the type and arrangement of these electrodes in the tube doesn't matter.

In Figure 4 there is also one in connection with the one filled with noble gas Tube to be used measuring device shown, which consists of a diode 28 and a Galvanometer 29 is formed, which the strength of the through the diode Irindurchenenden Current that is characteristic of the output signal.

Although in Figures 1, 3 and 4 a cylindrical peripheral electrode is shown, one can just as easily have one or more peripheral electrodes of others Use shapes such as B. plates, pipe sections or spherical segments, as the shape the electrode is of relatively little importance for the result obtained.

In general, however, center electrodes are used for the sake of simplicity in rod or ribbon form and a cylindrical peripheral electrode or one of a or multiple plates use a circumferential electrode. Are multiple covering electrodes provided, these are preferably at the same distance from the center electrode arranged. In the latter case, each of the plates is the peripheral electrode with the Power source connected or grounded, depending on which electrode is being polarized solf.

The electrodes can be made of any metal that can be found in the tube used gas only slightly astriated and which little tends to to evaporate under the applied reduced pressure, such as z. B. made of nickel, aluminum or molybdenum.

The gases used in the tube are noble gases such as helium, neon, Argon, krypton and xenon.

The pressure of the gas in the tube depends on the distance set between the center electrode and the circumference electrode as follows, that the product of the pressure p (in millimeters Hg) and the distance d between the Electrodes (in millimeters) gives a value between 12.5 and 125. This area corresponds essentially to the minimum zone in FIG. 7 shown Paschen curve, which is the change in the ignition voltage of the gas-filled tube as a function of the above called product p d reproduces.

For example, for a distance of 25 mm between the electrodes a pressure between 0.5 and 5 mm Hg and for a distance of 12.5 mm a pressure between 1 and 10 mm can be selected.

In practice, the pressure zone in which the evaporation occurs will be avoided of the metal used for the electrodes becomes noticeable by changing the distance appropriately adjusts between the electrodes, but within the most favorable Conditions remain that correspond to the minimum zone of the Paschen curve. With gas-filled Tubes that meet these conditions will produce voltage changes at the output obtained from particularly good square waveform. However, it is always possible to deviate from these favorable conditions and still enjoy the advantages of the invention to take advantage of it to a large extent.

F i g. 5 shows input pulses of the same duration (6 / ion microseconds) and different amplitudes (pulses 11, 12 and 13). The with the invention formed device obtained measurement signals are from the in F i g. 5 a shown and with St, S2 and S3 designated type, if the above for the gas-filled tube specified conditions apply, which correspond to the minimum zone of the Paschen curve. The square wave voltage changes obtained as measurement signals have a Duration of a few thousandths of a second and can therefore be measured very easily will.

From Fig. Sb can be seen that the received signals, s2 and s3 have a relatively short duration and different peak voltages when one from the most favorable conditions, those of the minimum zone of the Paschen curve (F i G. 7) are removed, which complicates the measurement.

However, these signals still have a duration of a few hundredths Microseconds, and therefore one of the greatest advantages of the present invention remains Conversion still exist.

In Fig. 6 is a pulse with variable peak voltage (i " i2, i3), which is directly linked to a stronger impulse l of invariable Shape and amplitude follows, these successive pulses being periodic repeat.

The changes can be made with the pulse measuring methods known up to now the amplitude of the small neren impulses i cannot determine because the tilting circles only triggered by the stronger impulse l.

In contrast, in this case the device according to FIG the invention provides an accurate measurement of the change in the pulses i, as shown in FIG. 6th a shows which the square-wave voltage changes r1, r2, and r3 am Tube output corresponding to pulses 11, i2, and i3 in FIG and the duration of which is extremely easy to measure.

The signals obtained according to the invention are caused by the noise floor of the tube hardly changes its height in the case of tubes which meet the above conditions does not exceed a few millivolts compared to a signal of several volts.

Claims (4)

Claims: 1. Method for measuring the energy of short electrical Voltage impulses by means of a tube filled with noble gas, a d u r c h g e k e n n -z e i c h n e t that the noble gas in the tube I thus in permanently ionized State is held that a DC voltage is arranged on two in the tube Electrodes is applied, the distance between which is chosen such that the product from this distance (in millimeters) and the pressure of the noble gas in the tube (in millimeters Hg) a value between 12.5 and 125 shows that one electrode has the short Voltage pulses are supplied, which change the conductivity of the noble gas and thereby voltage changes at the other electrode (approximately in the form of Square waves), and that the duration of these voltage changes (width of the square waves), which is proportional to the product k of the size and duration of the short pulses is measured. 2. Apparatus for carrying out the method according to claim 1, characterized through a tube (11 or 21) filled with a noble gas, the one or two center electrodes (12 or 22, 23) and a circumferential electrode (15 or 25), of which the or one of the center electrodes receives the short pulses to be measured and the circumferential electrode with a device for measuring the changes in voltage caused on it is connected, and a DC power source connected between the center electrode and the circumferential electrode generates a DC voltage, which the noble gas in the tube keeps in a permanently ionized state. 3. Apparatus according to claim 2, characterized in that the tube is filled with helium, neon, argon, krypton or xenon. 4. Apparatus according to claim 2 or 3, characterized in that the electrodes are made of nickel, aluminum or molybdenum. References Considered: U.S. Patents No. 2 427 086, 2729762; "The Bell System Technical Journal," May 1957, pp. 735-768.