SU801126A1 - Integrating converter with electric sensing - Google Patents

Description

(54) INTEGRATING CONVERTER WITH ELECTRICAL

READING

The invention relates to electrochemical converters of electrical quantities and can be used in devices for automatic control, information processing, communication systems, etc.

Known integrators with electrical readout based on electrochemical coulometers with a significant temperature dependence 1.

The closest in technical essence and the achieved result to the proposed is a device containing a mercury electrolytic cell with a resistive output, a control circuit, a read circuit and a coupling capacitor 2

The disadvantages of this electrochemical integrator with electrical readout are the non-linear dependence of the coefficient of temperature error on the load resistance, a small temperature range in which a decrease in temperature error is achieved. In addition, to realize this electrochemical converter with electrical reading, it is necessary to use a voltage source in the read circuit, which leads to an additional decrease in the value of the output impedance of the converter as a whole. This in turn makes it difficult to further transfer information from the converter.

The purpose of the invention is to improve the accuracy by compensating for the temperature error.

The goal is achieved by introducing a second mercury electrolytic cell, an amplifier, a coupling capacitor, and limiting resistors, the second mercury electrolytic cell, a coupling capacitor, and a limiting resistor connected in series and connected to the input of the amplifier, to the output of which the first mercury electrolytic cell is connected.

The drawing shows an integrating converter circuit with electrical readout.

Claims (2)

An electrical readout integrating transducer consists of a capillary mercury electrolytic cell 1, a limiting resistor 2, a separating capacitor 3, a limiting resistor 4, an amplifier 5, a resistor b feedback amplifier, a limiting resistor 7, a separating capacitor 8 ,. a capillary mercury electrolytic cell 9 and a limiting resistor 10. When a unipolar signal flows through the control circuit of a unipolar signal through a resistor 10 and through a capillary mercury electrolysis element 9, metal is transferred from one of its electrodes to another. As a result, the resistance of a capillary mercury electrolytic cell is changed. To read this resistance, a read signal (a bipolar signal) (enters the input of a capillary mercury electrolytic cell 1 and through the separation capacitor 3, the resistor 4 enters the input of the amplifier 5, which is a conventional microcircuit, after which the amplified readout signal through the resistor 7 and the separation capacitor 8 enters the readout circuit of the capillary mercury electrolytic cell 9. As the temperature rises environment, the resistance of the capillary mercury electrolytic cell 1 decreases as the cell has a negative temperature coefficient, and the current flowing through the capillary mercury electrolytic cell 1 increases, the voltage at the output of the amplifier 5 increases accordingly, and the current passing through capillary mercury electrolytic cell 9. The voltage drop across resistor 2 is o-Ubx., (1) where Rg is the resistance of resistor 2 R is the resistance of capillary mercury electrolytic cell 1, while rini may that. The voltage at the output of the amplifier is defined as, (2). Where UQ is the voltage drop across resistor 2; R is the resistance of the resistor in the feedback of the amplifier; R is the resistance of the limiting resistor. The resistance of the resistor 10 is chosen to be much greater than the resistance of a capillary mercury electrolytic cell, element 9 (Rg), i.e. The voltage at the outlet of the mercury electrolytic cell 9 has the form - - ki Ubb .; 1) d, R where is the gain. From the last expression it can be seen that and -yx does not depend on temperature. An electrical readout integrating transducer allows temperature compensation in a wide range of temperatures (operating temperature of capillary mercury electrolytic transducers from -20s to) to improve the accuracy and linearity of the output signal. An electric readout integrating converter containing a mercury electrolytic cell with a resistive output, a control circuit, a read circuit, a coupling capacitor, characterized in that, in order to improve the accuracy by compensating for temperature error, a second mercury electrolytic cell is introduced into it, amplifier, coupling capacitor and limiting resistors forming the readout circuit, the second mercury electrolytic element separating condensate p and the limiting resistor are connected in series and connected to the input of the amplifier, the output of which is connected to the first mercury electrolytic cell. Sources of information taken into account during the examination 1.VT.T. Electrochemical devices. M., Soviet Radio, 1978, p. 25 2. USSR author's certificate number 392559, cl. H 01 G 9/22, 12.10.71 (prototype).