DE893374C - Directly displaying frequency measuring device - Google Patents

Description

Directly displaying frequency measuring device The previously known facilities for direct frequency measurement, based on the principle of periodic charge reversal of a working in a direct current circuit capacitor through the currents to be measured (see patent 679 048), all have two grid-controlled charging tubes, one of which one changes the state of charge of the capacitor, the other the original one State of charge restored. The control of these charging tubes by the measuring voltage now causes certain difficulties, especially when the grid voltage is the Charging tubes influenced their charging characteristics. To avoid the resulting The amplitude influence is already the installation of glow lamps or the use a separate control circuit for the charging tubes became known. Disadvantageous is the high input voltage requirement for the former and for the latter Measure the great expense of tubes.

The invention has set itself the task of the existing in practice to meet the urgent need for a measuring device with significantly reduced Effort, especially on tubes, and no high input voltage requirement having.

The invention relates to a directly indicating frequency measuring device, based on the principle of periodic charge reversal in a DC circuit Capacitor based on the currents or voltages to be measured, their special Identifier in: If only one is used Charging tube for charging the capacitor and an ohmic resistor to discharge the capacitor consists.

The invention is illustrated below with reference to one in the drawing Embodiment explained in more detail: C designates the measuring capacitor. He is lying in series with a direct current measuring instrument, which has a rectifier G (in Graetz circuit) and a moving coil instrument J in the anode circuit of a charging tube I. The The anode voltage for this tube is supplied by a voltage stabilizer S connected in series with further series resistors R1, R3, R4 and R5 as voltage dividers over the operating voltage source is switched. The positive pole of the stabilizer S is via an ohmic resistance R1 connected to the anode of the charging tube I.

Is the tube I energized, i. H. flows from the positive pole of the stabilizer S a direct current through R1 and 'the tube I to the negative pole of the stabilizer, so the measuring capacitor C is charged to the voltage across the resistor R1. If, on the other hand, the tube I is de-energized, then the capacitor C over discharges again the resistor R1. The mean value of the charging and discharging currents is recorded in the instrument J displayed.

The control of the charging tube I takes place via one in its control grid circuit lying resistor R2.

This resistance is at the same time in the anode circuit of a control tube II, the control grid voltage via an ohmic resistor R6 from that of the Terminals a, b supplied measuring voltage is controlled. The anode of tube II is connected directly to the control grid of tube 1, its cathode to the middle between the series resistors R4 and R5, the latter of which is used to generate a fixed, negative bias Ides control grid is used.

The purpose of the control tube II is to measure the voltage drop across the discharge resistor R1 constant during charging, regardless of the magnitude of the amplitude of the measurement voltage to keep what is an important requirement for the correct working of the circuit represents.

The mode of action is as follows: If the amplitude of the Measurement voltage is the control tube II during a half-wave of this voltage high negative grid voltage completely blocked. So the control grid voltage value flows. Anode direct current corresponding to zero of the charging tube I via the resistor R1, and the measuring capacitor is charged.

The control grid voltage becomes at the next half-cycle of the measuring voltage the tube II is shifted so far in the positive direction that the tube is live will. The one from the negative pole of the stabilizer via R2, tube II to the middle between R4 and R5 flowing direct current causes such a strong negative voltage drop across R2 shows that the charging tube does not carry an anode current. The measuring capacitor discharges thus to the value zero via the resistance R1. The control tube II causes here, that generates approximately rectangular alternating grid voltages on the grid of the charging tube will.

A charging tube with a low internal resistance is expediently used used, as a control tube expediently a screen grid tube.

Claims (7)

PATENT CLAIMS: 1. Direct-reading frequency meter that on the principle of the periodic charge reversal of a circuit in a DC circuit Kendensators (C) is based on the currents or voltages to be measured by using only one charging tube (I) to charge the capacitor and an ohmic resistor (R1) to discharge the capacitor. 2. Device according to claim I, characterized in that means a control tube (II) on the grid of the charging tube (I) approximately rectangular grid alternating voltages be generated. 3. Device according to claim I and 2, characterized in that the anode voltage for the charging tube (I) is taken from a stabilizer (S). 4. Device according to claim} to 3, characterized in that the operating voltages for the control tube (II) series resistors (R3 to R5) of the Stabilizer are removed. 5. Device according to claim 1, characterized in that the loading and discharge currents of the capacitor through a dry rectifier arrangement connected in a Graetz circuit be measured. 6. Device according to claims I to 5, characterized in that a charging tube with a low internal resistance is used as the charging tube. 7. Device according to claim I to 6, (characterized in that a screen grid tube is used as the control tube (II).