SU1330584A1 - Device for measuring electrical conductance of liquids - Google Patents

Abstract

The invention can be used in a hydrophysical measuring apparatus, as well as in systems for measuring and controlling the conductivity of liquids. The invention makes it possible to simplify the device and reduce power consumption and makes it possible to obtain a frequency input signal. The device contains a single-ration amplifier 1, an AC-DC converter 2, two toroidal transformers 3 and 4 made in the form of cores, an excitation winding 5, a magnetizing winding 6, an output winding 7 a capacitor 8, resistors 9, 10 and 11 Magnetic toroidal cores 3 and 4 are installed in the test liquid. The first winding coils 5 and 6 are wound, and the second winding 7. The winding 6 is supplied with a direct current, which changes the magnetic flux in the core of the transformer 3, the x :: amy change the inductance in the winding 5, and therefore , and the resonant frequency of the LC circuit of the generator. The voltage is removed from the generator output, the frequency of which is functionally dependent on the electrical conductivity of the liquid under study. 1 il. i 00 oo o ate X 4

Description

The invention relates to a measurement technique and is intended for use in a hydrophysical measuring apparatus, and can also be used in systems for measuring and controlling the conductivity of liquids.

The aim of the invention is to simplify the device and reduce the energy consumption of the child while ensuring the possibility of obtaining a frequency extrinsic signal.

The drawing is principled

20

Diagram of a device for measuring an electric generator 5 ac 2 in the conductivity of liquids.

The device contains an operational amplifier 1, the Converter. AC to DC, two toroidal transformers (in the form of cores) 3 and 4, excitation winding 5, bias biasing winding 6, output winding 7, capacitor 8 and resistors 9-11.

Magnetic toroidal cores 3 and 4 are installed in the test liquid, the first winding excitation winding 5 and the secondary winding 6 winds up, and the second output winding 7. The capacitor 8 is connected in parallel with the WHO-OQ winding. One output winding 5 excitation windings connected to the non-inverting input of amplifier 1 and through a resistor 9 to the output of amplifier 1, and the other output to the total device thickness and second terminals of the output winding 7 and winding 6 bias, the first terminals of which are connected respectively to the input and output photoelectret 2 AC-to-DC, the inverting input of amplifier 1 through the resistor 11 is connected to the common bus and, through resistor 10 - with its output, which is the output of the apparatus.

The device for measuring the electrical conductivity of the liquid works as follows.

The winding 5 of the transformer 3, having an inductance L, together with the capacitor 8, constitutes a resonant oscillating circuit. This circuit is included in the positive feedback of amplifier i and determines the initial value of the oscillator frequency,

formed by the amplifier 1, LC circuit - 55 magnetization.

that nny. A constant current is applied from the output of the converter 2 to the biasing winding 6, which changes the magnetic flux in the core of the transformer 3, thereby changing the inductance L of the winding 5, and hence the resonant frequency of the oscillator LC circuit. The output voltage is removed from the generator output, the frequency of which functionally depends on the electrical conductivity of the liquid under study.

Claims (1)

Invention Formula A device for measuring the electrical conductivity of liquids, containing two toroidal transformers, one cat; one has excitation and biasing windings, and the other an output winding, each winding is connected to a common busbar by a first terminal, as well as an amplifier with a fixed gain factor and an AC current converter DC, characterized in that, in order to simplify the device and reduce power consumption while ensuring the possibility of obtaining a frequency output signal, a capacitor is introduced into it, p a capacitor, the capacitor is connected in parallel with the field winding, the second terminal of this winding is connected to a non-inverting input-amplifier and, via a resistor, to the output of the amplifier, which is the output of the device, and the second terminal of the output winding is connected to the input of an AC-DC converter, output which is connected to the second output winding under 35 40 45 50 VN5Sh11I Order 3579/48 Edition 730 Random polygons pr-tie, Uzhgorod, st. Design, And rum and resistors 9-11. The winding 5 excites the magnetic flux in the core of the transformer 3 and along the communication circuit forming during the disturbance of the toroidal magnetic cores 3 and 4 in the test liquid, excites the magnetic flux in the core of the transformer 4. The magnetic flux in the core of the transformer 4 induces alternating current in the output winding 7 the value of which functionally depends on the conductivity of the communication circuit entering the input razer 2 ac in pos that nny. From the output of the converter 2 to the bias winding 6, a direct current is applied, which changes the magnetic flux in the core of the transformer 3, thereby changing the inductance L of the winding 5, and hence the resonant frequency of the oscillator LC circuit. The output voltage of the generator is removed, the frequency of which is functionally dependent on the electrical conductivity of the liquid under study. Q Invention Formula A device for measuring the electrical conductivity of liquids, containing two toroidal transformers, one cat; one has excitation and biasing windings, and the other an output winding, each winding is connected to a common busbar by a first terminal, as well as an amplifier with a fixed gain factor and an AC current converter DC, characterized in that, in order to simplify the device and reduce power consumption while ensuring the possibility of obtaining a frequency output signal, a capacitor is introduced into it, p a capacitor, the capacitor is connected in parallel with the field winding, the second terminal of this winding is connected to a non-inverting input-amplifier and, via a resistor, to the output of the amplifier, which is the output of the device, and the second terminal of the output winding is connected to the input of an AC-DC converter, output which is connected to the second output winding under5 0 five 0 Subscription