SU840748A1 - Device for measuring non-electric parameters, e.g. temperature - Google Patents

Description

The invention relates to measuring technique and is intended for use in the implementation of automatic control systems and regulation of temperature, pressure, humidity, etc.

A device for measuring parameters of non-electric formed on the basis of the transmitter and incorporated with it the post-linearizing unit sequence _f £ 1].

However, in the practical application of such a device, there is a significant additional measurement error introduced by the linearizing link, which limits the scope of the possible use of the device.

Closest to the proposed technical solution is a device for measuring non-electric ₂ parameters, for example, temperature, containing a measuring transducer, the signal inputs of which are connected to the signal outputs of the current and final values of the setpoint of the controlled parameter, a multiplication unit, a voltage divider, an amplifier, and an actuator £ 2j.

A disadvantage of the known device using the linearization method of the characteristics of the measuring transducer by means of reciprocal transformations is also associated with a significant measurement error.

The purpose of the invention is to improve the accuracy of the measuring device.

This goal is achieved by the fact that in the device for measuring non-electrical parameters, for example, temperature, containing a measuring transducer, the signal inputs of which are connected to the signal outputs of the current and final values of the setpoint of the controlled parameter, a multiplication unit, a voltage divider, an amplifier and an actuator, a division unit is introduced , a subtraction unit and an extremum determination unit, the first inputs of the division and multiplication units being connected respectively to the outputs of the signals of the final and current values, the second input of the division unit is connected to the output of the signal of the final value of the measuring transducer, and the output is connected to the second input of the multiplication unit, the first input of the subtraction unit is connected to the output of the signal of the current value of the measuring transducer, the second input is connected to the output of the multiplication unit, and the output is connected to the input of the extremum determination unit, the output of which is through a voltage divider, amplifier, and actuator connected to the control input of the measuring transducer. The drawing shows a functional diagram of the proposed device for measuring non-electrical parameters, such as temperature.

The device comprises a measuring transducer 2, a division unit 3, a multiplication unit 4, a subtraction unit 5, an extremum determination unit 6, a voltage divider 7, an amplifier 8, an actuating element 9 connected to the controller 1 of the controlled parameter 1. The diagram also shows a computer 10 with which obtaining the final measurement results.

The signal output of the current value of the setpoint 1 is connected to the input 11 of the measuring transducer 2, and the input 1 2 of the block 4 multiplication. The output signal of the final value of the setpoint 1 is connected to the input 13 of the measuring transducer 2 and to the input 14 of the division unit. The output of the signal of the current value of the measuring transducer 2 is connected to the input ^{15 of the} subtraction unit 5, and the output of the signal of the final value of the measuring transducer 2 is connected to the input 16 of the unit 3 of the division.

The proposed device operates as follows.

The master 1 generates the signals of the current and final values of the monitored parameter, respectively, received at the inputs 1I and 13 of the measuring transducer 2, which converts the signals of the master 1 and generates, in turn, the signals of the current and final values of the converted parameter, respectively, to the input 15 of block 5 subtraction n input 16 block 3 division.

• Block 3 division generates a signal proportional to the ratio of the final _s values of the converted and the original controlled parameter, ie the conversion coefficient of the measuring transducer 2. The multiplication unit 4 generates signals that display the product of the current values of the transmitter 1 by the conversion coefficient of the transducer 2. In the subtraction unit 5, the signals of the current values of the converted parameter 15 and the linearized characteristic of the transducer 2 are subtracted. 'its output signal corresponding to the maximum linearization error.

Divider 7 divides this signal in half, and amplifier 8 amplifies it.

The actuating element 9 acts on the body of the zero-construction of the measuring transducer 2 and shifts 25 the characteristic of the transducer 2 from zero by a value proportional to half the linearization error.

Thus, in the proposed device, as in a number of well-known ones, a linear transformation characteristic is used instead of non-linear, but the approximation error is only half the maximum non-linear error.

The signals corresponding to half of the linearization error and the conversion coefficient of the Converter 2 are received for further processing in the computer 10.

Claims (2)

1. Volgin L.I. Linear-electric converters for measuring devices and systems. M, Sovetskoye glad, 1971, p. nineteen. , 2. Ibid, p. 20. one / b. g