SU1064485A1 - Device for determining electrostatic properties of dielectric materials - Google Patents

Abstract

DEVICE FOR DETERMINING electrostatic properties of dielectric materials comprising the sensor field strength of the electrostatic field with a measuring electrode connected to successively soedinenilm amplifier, detector and recorder modulating screen configured as a disk with sector slots da, rotatably mounted, a source of high voltage and a corona electrode connected to a high-voltage power source, distinguished from ((-, 13 TE g "ICEC1-Ь: itiiBmo-f№: in order to increase To determine the maximum charge on the surface of a material, it is equipped with a reference signal sensor containing a light source, a photovoltaic converter and an additional power source, two delay blocks and two pulse shapers, with elements in pairs (Converter - light source and corona electrode the measuring electrode is installed one against the other on opposite sides of the screen in the area of the slots in it, the source is high, the voltage is made in the form of a control pulse generator, the detector is made stroboscopic, transformed. W the receiver is connected via a resistor to an additional power source, the reference sensor is connected to the inputs of the delay blocks, the output of one of the delay blocks through one of the pulse width drivers is connected to the control input of the detector, and the output of the other delay block through the second driver the duration of the intulses - with yes launched by the input; controlled pulse generator. 4 4: 00 01

Description

The invention relates to a technique for combating the rarefaction of static electricity and can be used in determining the degree of electrification and electrostatic properties of polymer dielectrics, in particular, in studying the effectiveness of antistatic treatment in the textile and chemical industries, as well as for non-contact measurement of electrical resistance of dielectric materials. .

A device for determining the electrostatic properties of sheet materials is known, in which, due to the introduction of a disk driven by an electric motor on which the discharge and measuring electrodes are located, the time elapsed between single acts of sample charging and charge measurement ij is reduced.

The disadvantage of this device is the complexity of the design, as well as the presence in the high-voltage and electrometric circuits of the device for shorting contacts, which limits the sensitivity and accuracy of measurements.

Closest to the present invention is a device for determining the electrostatic properties of dielectric materials, comprising an electrostatic field strength sensor with a measuring electrode, connected to a series-connected amplifier, detector and recorder, a modulating screen mounted in the form of a disc with sector slots, rotatably mounted a high voltage source and a corona electrode connected to a high voltage voltage source 2. .:,

This device also has a low accuracy due to the fact that, due to the sufficiently large distance between the material charging zone and the measurement zone, there is a change in charge on the material surface when it moves from the charging zone: to the measurement zone.

The purpose of the invention is to improve the accuracy of determining the maximum charge.

The goal is achieved by the fact that a device for determining the electrostatic properties of dielectric materials, containing an electrostatic field strength sensor with a measuring electrode, connected to a series-connected amplifier, detector and recorder, a modulating screen made in the form of a disk with sectoral slots, mounted with rotational capability, high voltage source and corona electrode,

connected to a high voltage source, equipped with a reference signal sensor containing a photoelectric converter, a light source and an additional power source, two delay blocks and two pulse width formers, with the elements in pairs converter - a light source and a corona electrode - a measuring electrode installed one against the other on opposite sides of the screen in the area of the slots in it, the high voltage source is made in the form of a controlled generator pulse c, the detector is made stroboscopic, the converter is connected via a resistor to an additional power source, the output of the reference signal sensor is connected to the inputs of the delay blocks, the output of one of the delay blocks is connected to the control input of the detector through the second pulse shaper - with triggering input of controlled pulse generator i

The drawing shows a diagram of the device.

The device contains a measuring electrode 1, to which an amplifier 2, a stroboscopic detector 3 and a recorder 4, as well as a modulating screen made in the form of a disk 5 with sector slots 6, mounted in front of the measuring electrode with an axial rotation, a reference signal sensor, are connected in series consisting of a photoelectric converter 7, a light source 8 (incandescent lamp). At the same time, the incandescent lamp and the photoelectric converter collector are connected via a load resistor 9 to a DC source 10, the output of the converter is connected through the first delay unit 11 and the first pulse width generator 12 connected to the control input of the stroboscopic detector 3. The modulating screen is mounted on the motor axis 13. A corona electrode 14 is mounted above the plane of the modulating screen. It is connected to the output of a controlled high-voltage source 15. and, which triggers the input through a serially connected second block 16 of the delay and the second shaper 17 of the pulse duration is connected to the output of a photoelectric junction converter 7. The sample under study 18 is located under the corona electrode.

The device works as follows.

When the modulating disk 5 rotates uniformly, it periodically shields and exposes the measuring electrode 1 in the field of the test sample 18. At the same time, an alternating current flows through the input circuits of the amplifier 2 and is amplified and fed to the signal input of the stroboscopic detector 3, the moment of switching on which is determined by the reference signal. A converter 7 located near the incandescent lamp, the light of which is modulated by the rotation of the disk 5, is used as a reference signal sensor. From the collector of the converter 7, the reference signal through the first delay unit 11 and the first pulse width generator 12 goes to the control input of the strobe detector 3 and starts him. In addition .go, the reference signal through the second block

16 delay and second shaper.

The pulse duration enters the triggering input of the controlled high voltage source 15 and starts it. The duration of the high-frequency pulse produced by the source 15 is small compared to the half-period of modulation, which allows the adjustment of the delay unit 16 to achieve the passage of the high-voltage pulse at the moment of complete shielding of the measuring electrode 1 by the modulating screen.

Shielding the measuring electrode prevents the amplifier from being overloaded with a powerful high-voltage pulse signal.

; A high-voltage pulse arrives at the corona electrode 14 and charges the test material 18. The pulse width former 12, for which use: a single-shot, at the time of arrival

the reference signal generates a short gating pulse, the duration of which is short compared with the half-period of modulation. Adjusting the delay unit 11 ensures that a short strobe pulse arrives at the control input of the stroboscopic detector 3 at the time of full exposure of the measuring elecrode 1 in the field of the material 18 under investigation, charged with a high-voltage pulse, while the stroboscopic detector remembers only the dielectric field during the modulation period amplitude value of the current induced in the input circuit of the amplifier. At the output of the detector 3, the signal is recorded by the recorder 4, for which a direct current voltmeter is used.

As a controlled generator of high-voltage pulses, a single-oscillator with a power amplifier can be used, which operates on a Tesla transformer with the subsequent extraction of a unipolar pulse.

5 The switching of the outputs of the high-voltage rectifier connected after the Tesla transformer makes it possible to investigate the process of charging a material with pulses, both positive and

0 negative polarity and evaluate the degree of charge selectivity.

The technical and economic effect consists in determining the accuracy of determining the parameters of the electrification of polymeric dielectrics - maximally the surface charge applied during the charging process.

As tests have shown, the relative error in determining electro-static properties is 5%, while with the prototype it can reach up to 30% for materials with fast relaxation of charge.

Claims (1)

DEVICE FOR DETERMINING ELECTROSTATIC PROPERTIES OF DIELECTRIC MATERIALS, comprising an electrostatic field intensity sensor with a measuring electrode connected to a series-connected amplifier, detector and registrar, a modulating screen made in the form of a disk with sector slots, mounted for rotation, a high voltage source and coronas connected to a source of high Ha * aryada material surface is provided with a sensor reference signal, comprising a light source, a photoelectric converter and an additional power source, the two units of delay and two formers · length, pulse duration, with the elements in pairs | transducer _g - Light Source minutes corona electrode measuring electrode are set against one another on different sides of the screen in the location of slots therein, a source of high voltage configured in the form of direct upravlyav- _ώ pulser detective OR is made stroboscopic, vreobra-. The caller is connected via an resistor to an additional power source, the output of the reference signal sensor is connected to the inputs of the delay units, the output of one of the delay units through one of the pulse shapers is connected to the control input of the detector, and the output of the other delay block through the second pulse shaper is connected to the triggering input ; controlled gene ·: pulse generator. _ SU „, Ϊ 064485 A 1064465