SU1627959A1 - Conductance indicator - Google Patents

Abstract

The invention relates to analytical instrumentation, in particular, to means of conductometric control of technological processes. The aim of the invention is to increase the reliability and simplify the design of the conductivity level detector. This is achieved by minimizing the number of conductors of the communication line, which is made three-wire and connects the primary converter and the functional converter of the device. A generator, ballast resistance, two comparators and two threshold devices are entered into the primary converter. Two ballast resistors and a voltage divider are introduced into the functional converter. This makes it possible to realize the use mode of a three-wire communication line simultaneously both as an information transmission line and as a power line. 1 il. cl

Description

The invention relates to analytical instrumentation, in particular, to means of conductometric control of technological processes.

The aim of the invention is to increase the reliability and simplify the design of the detector.

The drawing shows a block diagram of the conductivity level detector.

The device contains a primary converter (PC) 1, a multi-wire communication line (LAN) 2, a functional converter (FC) 3 and a power supply 4, two-pole with respect to the zero bus. PP 1 through LAN 2 is connected to OP 3, which is connected to source 4. PP 1 contains an alternating voltage generator 5, ballast resistance 6, conductivity sensor 7, temperature sensor 8, detector 9, two comparators 10 and 11, two threshold devices 12 and 13. FC 3 includes ballasts 14 and 15, a voltage divider from resistances 16–18, and starting devices 19 and 20 with actuating elements.

The generator 5 through the ballast resistance 6 is connected to the non-grounded electrode of the sensor 7, the same electrode through series-connected temperature sensor 8 and detector 9 is connected to the combined inputs of the comparator 10 and 11, to the outputs of which are connected the corresponding threshold devices 12 and 13. The outputs of the threshold devices 12 and 13 are symmetrical outputs of the primary converter 1 with respect to zero sheOs

th VI th

us LAN 2 is three-wire, and symmetrical inputs of FC 3 are connected via ballast resistors 14 and 15 to the corresponding different polarity buses of source 4. Voltage divider from resistors 16-18 is installed between symmetrical inputs of FPZ. Input of the first trigger device (PU) 19 is connected to the connection point of the second 17 and third 18 resistances of the divider, and the input of the second PU 20 is connected to the connection points of the first 16 and second 17 resistances of the divider. PU 19 and 20 are connected to the corresponding power supply cables of different polarity and zero bus,

The device works as follows.

At a certain value of the resistance of the sensor 7, the voltage value at the connection point of the sensor 7 and the ballast resistance 6 after passing through the sensor 8 and the detector 9 does not trigger any comparator 10 and 11. At this time, the current passing through the LAN 2 wires is small, low voltage drop on ballast resistances 14 and 15 and PU 19 and 20 does not work. The output signal is formed and corresponds to the level of Norm.

When the resistance value of the sensor 7 changes, for example, when its value decreases, the voltage across it decreases. This leads to a decrease in voltage and at the output of the detector 9. The comparator 10 triggers, causing the threshold device 12 to operate. The threshold device 12 in turn includes the load on its power line LAN 2, which provides an increase in the current in it. The increased current in the supply line increases the voltage drop on the ballast resistance 14, which through the voltage divider 16-18 triggers the trigger 19, which generates a Many signal.

Similarly, the circuit works with decreasing conductivity, i.e. with an increase in the impedance of the primary converter, but at the same time a small signal is formed, along the line comparator 11, the threshold

device 13, power supply line LS 2 and ballast resistance 15.

Temperature correction with temperature controlled environment

applied by sensor 8.

Claims (1)

Claims The conductivity level detector comprising a primary transducer connected by a multi-wire communication line with a functional converter connected to a two-pole power source, the primary converter contains conductivity and temperature sensors and a detector, and the functional converter contains two starting devices with executive elements connected to the corresponding different polarity power buses and to the zero bus , characterized in that, in order to increase reliability and simplify the design, an alternating voltage generator, ballast resistance, two comparators are introduced into the primary converter and two threshold devices, the outputs of which are symmetrical outputs of the primary converter with respect to the zero bus, the generator is connected through a ballast resistance to the ungrounded electrode of the conductivity sensor, the same electrode through series-connected temperature sensor and detector is connected to the combined inputs of the comparators, to the outputs of which are connected threshold devices, communication lines are made of three-wire, and balanced inputs of a functional converter are ballast resistance connected to respective a bipolar power supply line, between the symmetrical inputs of the functional converter, a voltage divider of three resistances is installed, with the input of the first starting device connected to the connection point of the second and third resistance of the divider, and the input of the second trigger device is connected to the connection point of the first and second resistance of the divider.