SU1129669A1 - Device for measuring pressure in picture tube - Google Patents

Abstract

KINESCOPE PRESSURE MEASUREMENT DEVICE, containing a channel voltage source connected to terminals for connecting a kinescope heat source, a voltage source of a modulator, an accelerating voltage, connected to terminals for connecting an accelerating electrode, a resistor, the first output of which is connected to a common bus , the second is connected to the terminal for connecting the modulator, the current amplifier, the first input of which is connected to the terminal for connecting the anode of the kinescope, and the second to the common bus, and an indicator that distinguishes it from accuracy and speed of measurements, the first and second keys, a pulse generator, a logic inverter, the first and second sampling and storage elements, a differential amplifier, a multiplier, a reference voltage source, a transducer voltage — frequency and current frequency, the counter and the differentiator, and the output of the voltage source 1 of the modulator through the first switch is connected to the terminal for connecting the kinescope modulator, the control input of the first switch is connected to the control looking for the input of the second sample element and x wound and the output of the logic inverter, the input of which is connected to the output of the pulse generator and to the control input of the first sample and storage element, the inputs of the first and second sample and storage elements are connected to the current amplifier, and the outputs are connected to the noninverting and inverting inputs of the differential amplifier, output which is connected to the first input of the multiplier, to the second input of which the output of the reference voltage source is connected, the output of the multiplier is connected to the input of the voltage converter The output of which is connected to the outputs of the differentiator and the second key, the control input of which is connected to the output of the current-frequency converter, the first input of which is connected to the terminal for connecting the cathode of the kinescope, the second is connected to the common bus, the output of the second key is connected to the input of the counter, control input This is connected to the output of the differentiator, and the output is connected to the input of the indicator.

Description

 The invention relates to electrical measurements and can be used to measure vacuum in kinescopes during their manufacture and operation.

It is known a device for measuring pressure in refilled electrovacuum devices, which contains sources of voltage, control electrodes, cathode displacements, memory amplifiers, a control unit. This device measures the difference between the ion and background currents at a certain electron current, as determined by the control unit. This value is proportional to the residual gas pressure m.

However, cathode-depleted kinescopes may not provide the required electron current, then the known device is rendered inoperative. In addition, the need to manually switch the voltage on the control electrode significantly reduces its speed.

The closest to the technical essence of the invention is a device for measuring pressure in a kinescope containing a voltage source connected to terminals for connecting a kinescope heater, a modulator voltage source and an accelerating voltage connected to terminals for connecting an accelerating electrode , a resistor, the first terminal of which is connected to the common bus, and the second is connected to the terminal for connecting an accelerating electrode, the resistor, the first terminal of which is connected to the common bus, and the second is connected to terminal d l connect the modulator, the current amplifier the first input of which is connected to the terminal for connecting the kinescope, and the second - to the common bus, indicator 2

The disadvantage of this device is due to the dependence of its work temperature. In addition, the device requires manual control and calculation of the value of the vakzota, and therefore its speed is low.

The purpose of the invention is to improve the accuracy and speed of measurements.

The goal is achieved by the fact that the device containing

jacal voltage source connected to terminals for connecting the kinescope heat source, modulator voltage source, accelerating voltage connected to terminals for connecting the accelerating electrode, resistor, the first terminal of which is connected to the common busbar, and the second terminal is connected to the terminal To connect the modulator, the current amplifier, the first input of which is connected to the terminal for connecting the anode of the kinescope, the second - to the common bus and the indicator, the first and second keys, the pulse generator, the logical inverter, the first and the second element are entered Sampling and storage s, differential amplifier, multiplier, voltage source, voltage-frequency and current-frequency converters, a counter and a differentiator, and the output of the voltage source of the modulator is connected to the terminal for connecting the kinescope modulator controlling the input of the first key is connected to the control input of the second element of the sample and storage and the output of the logic inverter, the input of which is connected to the output of the pulse generator and to the control input of the first element of the sample and storage and, the inputs of the first and second elements of the sample and storage are connected to the output of the current amplifier, and the outputs are connected to the non-inverting and inverting inputs of a differential amplifier, whose output is connected to the first input of the multiplier, to the second input of which the output of the reference voltage source is connected, the output of the multiplier is connected with the input of the voltage converter, the output of which is connected to the outputs of the differentiator and the second key, the control input of which is connected to the output of the current frequency converter, the first second input coupled to a terminal for connecting the cathode of the kinescope and the second is connected to the common bus, vghod second switch is connected to counter input kmtsy control input of which is connected to the output of the differentiator, and vghod connected to input indicator.

FIG. 1 shows a block diagram of the proposed device; Fig 2 (q) - ep $ oors of currents and

voltages at characteristic points of the device.

A device for measuring pressure in a kinescope contains 1-6 for connecting the kinescope electrodes, an accelerating voltage source 7, a glow voltage source 8, a resistor 9, a modulator voltage source 10, a first switch 11, whose input is connected to the output of the source 10, and the output is connected to terminal 4 and the first terminal of the resistor 9. The pulse generator 12 is connected to the input of the logic inverter 13 and to the control input of the first sample and storage element 14. The inputs of the first 14 and second 15 elements of sampling and storage are connected to the output of current amplifier 16, the first input of which is connected to terminal 6 of the anode of the kinescope and the second is connected to the common bus. The outputs of the first 14 and second 15 elements of the sample and storage are connected to the inputs of the differential amplifier 17, the output connected to the first input of the multiplier 18, the second input of which is connected to the output of the source 19 of the reference voltage. The output of the multiplier 19 through the voltage converter 20 is the frequency and the output of the converter 21 is the current frequency connected to the inputs of the second switch 22, the control input of which is connected to the output of the current amplifier 16 and the output to c. the input of the counter 23 is the control input of the counter 23 connected to the output of the differentiator 24, and the output of the counter 23 is connected to the input of the indicator 25.

A device for measuring pressure in a kinescope operates as follows.

Sources 7 and 8. The voltages apply to the kinescope a nominal filament voltage and an accelerating voltage of about 300-500 V, respectively. The cathode current flows through the input circuit of the current-to-frequency converter 21. The positive ion collector is the anode of the kinescope connected to terminal 6. This mode ensures maximum accuracy of vacuum measurement.

The pulse generator 12, whose shape is shown in FIG. 2 generates rectangular pulses applied to the control input of the sample and storage element 14 and through

a logical inverter 13 is connected to the first key 11 and the control input of the second element 15 for sampling and storage. During the pulse at the output of the inverter 13 there is a logical O, the key 11 is locked, the modulator of the kinescope is connected via a resistor 9 to the common bus, the voltage, the voltage of the modulator - the cathode is zero.

The residual gas current generated (ion current) and leakage current D and flow through the anode circuit through terminal 6 to the input of the amplifier 16. The voltage from the output of the latter, proportional to the sum of the currents 3 / + 3it, is fed to the input of the first element 14 of the sample and storage and is stored therein (Fig. 2S).

In the pause between pulses, at the output of the inverter 13 there is a logical -C, the key 11 is unlocked, a negative blocking voltage is applied to the tube modulator from the source 10.

The value of the locking voltage of the source 10 must be established on the basis of the insignificance of the residual electron current in comparison with the leakage current of the kinescope. On the other hand, this value should not exceed the voltage of the breakdown of the modulator-cathode section of the kinescope. In this mode, ionization and ion current are absent, only a leakage current of the kinescope flows in the input circuit of the current amplifier. A proportional voltage is applied to the second sampling and storage element 15, at a control input of which logical 1 is enabled for memorization (Fig. 2b).

Thus, the potential at the outputs of the elements 14 and 15 of the sample and storage is proportional to the total current and leakage current, respectively. Their difference, which is formed on the upper side of the differential amplifier 17, is proportional to the ion current (Fig. 22). The input to the first input of the multiplier 18, the indicated value is multiplied by a coefficient (gauge constant), depending on the design parameters of the kinescope, the value of which is found experimentally and is displayed as a certain reference voltage of source 19. The signal from the multiplier, the last frequency converter, represents rectangular pulses (Fig. 2c) with a duty cycle of 2, the duration of which is inversely proportional to the magnitude. . This signal is fed to the control input of the key 22, to the signal input of which a pulse voltage is applied: output from the converter 21 current-frequency. The latter is proportional to the electron current of the cathode (Fig. 2c.). Thus, at the output of the key 22 controlled by the signal of FIG. 2 with converter 20, there are bursts of pulses, limited in duration by the front and cut of the pulses of FIG. 2a with a filling frequency proportional to a cathode current of 3g. The number of pulses in a packet is recalculated by counter 23, resetting to eight 8, the initial state by negative pulses from the output of differentiator 24 (Fig. 2). Note that the number of pulses accumulated in the counter is directly proportional to the product of the io current per gauge coefficient and back proportional to the electron current of the cathode, i.e. the value displayed on the (digital) Indicator is equal to RK. The value obtained by P is a measure of the pressure of the residual rai3OB, i.e. kinescope vacuum. With correctly selected values of the reference voltage of source 19, transfer factors of amplifier 16, multiplier 18, and converter 21, the indicator readings are in mm Hg. Thus, in the proposed device, the direct reading of the residual gas pressure in the kinescope is realized. 69 Compared with the prototype device chosen as the base object, the proposed device has a higher pressure measurement accuracy due to the exclusion of elements from it that introduce significant logarithmist errors on diodes and others. Typical error of the elements included in the proposed device taking into account the temperature the drift collected on serial operational amplifiers is about 1%, i.e. approximately one order of magnitude better than the diode logarithm. In general, the accuracy of the proposed device exceeds the accuracy of the base object by no less than three times. In addition, the implementation of direct digital readout significantly reduces the likelihood of subjective operator errors and increases the speed of the device. The device operates in the actomatic cyclic mode, measuring the total current, leakage current and electron current, comparing them in accordance with relation (1) and gives the result in the center view, which does not require additional recalculation. The measurement time is the sum of the generator pulse duration 12 and time displays accumulated in the counter 23 pulses (digital) indicator 25 and is about 300-600 ms. The measurement time of the device-prototype is limited, in particular, by the need to manually control the kinescope mode. Taking into account the time of calm of the indicator of the analog indicator and the time required for the calculation of the final result taking into account the gauge constant, it is 2-3 minutes, i.e. the speed of the proposed device is more than an order of magnitude higher than that of the base object.

Claims (1)

DEVICE FOR MEASURING PRESSURE IN A KINESCOPE, containing a channel voltage source connected to terminals for connecting the kinescope filament, a voltage source for a modulator, accelerating voltage, connected to terminals for connecting an accelerating electrode, a resistor, the first output of which is connected to a common bus and the second is connected to a terminal for connecting a modulator, a current amplifier, the first input of which is connected to the terminal for connecting the anode of the kinescope, and the second to a common bus, and an indicator, which differs in that, in order to increase I have the accuracy and speed of measurements, the first and second keys, a pulse generator, a logical inverter, the first and second sampling and storage elements, a differential amplifier, a multiplier, a reference voltage source, voltage-frequency and current frequency converters, a counter and a differentiator are introduced into it, and the output the voltage source ^ of the modulator through the first key is connected to the terminal for connecting the kinescope modulator, the control input of the first key is connected to the control input of the second sampling and storage element and the output ohm of a logical inverter, the input of which is connected to the output of the pulse generator and to the control input of the first sampling and storage element, the inputs of the first and second sampling and storage elements are connected to the output of the current amplifier, and the outputs are connected to the non-inverting and inverting inputs of the differential amplifier, the output of which is connected to the first input of the multiplier, to the second input of which g is connected the output of the reference voltage source, the output of the multiplier is connected to the input of the voltage-frequency converter, the output of which connected to the outputs of the differentiator and the second key, the control input of which is connected to the output of the current-frequency converter, the first input of which is connected to the terminal for connecting the picture tube cathode, and the second is connected to the common bus, the output of the second key is connected to the counter input, the control input of which connected to the output of the differentiator, and the output is connected to the input of the indicator. 1 1129669 2