SU838468A1 - Device for measuring ratio of two pressures - Google Patents

Description

The invention relates to measuring equipment and can be used for remote measurement of the ratio of two pressures of gases, or of liquids and in particular for measuring the degree of compression or ^e discharging gases in various industrial processes.

A device for remote control is known. _ measuring the ratio of two pressures, containing two pressure sensors connected to the division unit [1J.

However, such a device does not allow measuring the pressure ratio over a wide range of measured quantities.

Closest to the proposed one is a device for measuring the pressure ratio, built on 20 sensors with an analog output, direct current or voltage, connected to the division unit, the output of which is connected to the measuring device [2}. .

However, such a device also does not 25 provides a sufficiently wide range of measured pressure ratios due to the limited up to->

the allowable ratio of the input signals of the division block. thirty

The purpose of the invention is the expansion of the range of relations of measured pressures while maintaining a given accuracy.

To achieve this goal, two switching units are introduced into the device for measuring the ratio of two pressures, which contains a group of sensors for each of the measured pressures, a division unit and a measuring device, the analog inputs of which are connected respectively to the sensors of each group, and the analog outputs are connected to the corresponding inputs of the unit division, the logical information processing unit, consisting of two-input matching elements, the inputs of each of which are connected respectively to the discrete outputs of both switching units, and ma a scaling unit, the analogue input of which is connected to the output of the division unit, control inputs - with the corresponding outputs of the logical information processing unit, and the output - with the measuring device.

The drawing shows a functional diagram of the proposed device.

The device contains sensors L,; 1c and 2, - 2 _{t of} converting the first and second pressures to analog signals, connected respectively through blocks 3 and 4 of switching to block 5 of division, and discrete outputs of blocks 3 and 4 are connected to the corresponding inputs of two-input matching elements block 6 of the logical processing of information, the output of each matching element of block b is connected to the corresponding discrete input of the scaling unit 7, which contains a set of scaling Elements (shunts, additional resistors, etc.), while to the second the output of the scaling unit 7 is connected to the output of the division unit 5, and the output of the scaling unit 7 is connected to the measuring device 8.

The number of sensors that measure each of the two pressures depends on the multiplicity of measured pressure _p = P K _IACS / / p _ICS and allowed multiplicity of analog measurement signals _AD0P divider K = A _H ohms. / ^A · vh.Lin ^This number may be defined as N U Cr / / £ d K _ADop . For example, when P _{ma (. C} = 400 kPa kPa Pmin = 1 and _n = 5 Kddo N 7 U 100 / U 5> 2.6, i.e. N = 3.

The sensitivities of the sensors included in each group or the nominal values of the pressures for which they are designed (their scales) must also be in accordance with Cddo _P. In the example given, one sensor L is taken at 100 kPa, the second sensor is 1% at 20 kPa and the third sensor Ι-j - by 4 kPa, i.e. with a multiplicity of five.

<The device operates as follows.

Using sensors 1 ^ - 1 _υ , the first pressure P ^ is measured using sensors 2 _L - 2 _t second pressure. When measuring controlled. of pressure Р ^ and Р ^ by means of switching blocks 3 and 4 are automatically or manually selected for operation, respectively, from the sensors 1 ₄ - l _h and 2 _L - 2 _gp , which provide analog signals with the level Αθ _χ at the input of block 5 of division > A _nom . / Kdd _op · Analog signals from the selected sensor signals are fed to the input of block 5 division. At the same time, discrete signals equal to a logical unit are received from the digital outputs of the switching units 3 and 4, to the inputs of that of the matching elements of the logical processing unit 6, which corresponds to a given pair of selected sensors.

the output of the same coincidence element is connected to that element of the scaling unit 7, which introduces the scale factor specified for this pair of sensors. An analog signal, taking into account the coefficient implemented by block 7, is supplied to the measuring device 8.

Thanks to the use of groups of sensors.pressures of various sensitivities for each of the measured pressures and switching units 3 and 4, the division unit 5 and the pressure sensors themselves continuously operate in the zone of least errors, which ensures a wide-range measurement of the pressure ratio while maintaining measurement accuracy.

Claims (2)

The invention relates to a measuring technique and can be used to remotely measure the ratio of two pressures of gases or liquids and, in particular, to measure the degree of compression or discharge of gases in various technological processes. A device for remotely measuring the ratio of two pressures is known, containing two pressure sensors connected to the dividing unit Ij. However, such a device does not allow measuring the pressure ratio in a wide range of measured values. Closest to the proposed device is a pressure ratio measurement device built on sensors with analog current or voltage output connected to a dividing unit whose output is connected to a G2 measuring instrument}. However, such a device also does not provide a sufficiently wide range of ratios of measured scientific research institutes due to the limited allowable ratios of the input SIGNS of the dividing unit. The purpose of the invention is to expand the range of ratios of measured pressures while maintaining a given accuracy. To achieve this goal, two switching units are introduced into the ratio measuring device, containing a group of sensors for each of the measured pressures, a dividing unit and a measuring device, the analog inputs of which are connected respectively to the sensors of each group, and the analog outputs to the corresponding inputs of the division unit, the logical information processing unit, the states of two-input elements spinning, the inputs of each of which are connected respectively to the digital outputs of both switching units, and scaling unit, an analog input coupled to an output of dividing unit controlling kedie inputs - outputs a corresponding logical unit information processing and output - with a measuring instrument. The drawing shows a functional diagram of the proposed device. The device contains sensors 1 1 and 2 - 2 converting the first and second pressures into analog signals connected via switching blocks 3 and 4 to dividing unit 5, respectively, and the discrete outputs of blocks 3 and 4 are connected to the corresponding inputs of two input matching elements of block 6 the logical processing of information, the output of each e / 1 match of the block b is connected to the corresponding discrete input of the scaling block 1, which contains a set of scaled elements {shunts, additional resistors, etc.), with a second The output of the scaled unit 7 is connected to the output of the dividing unit 5, and the output of the scaled unit 7 is connected to the measuring device 8.. The number of sensors measuring each of the two pressures depends on the multiplicity of the measured pressure Cp P, & omc / and the allowable multiplicity of the measured analog signals of the Kldop division unit .Р. This number can be defined as N: Vd K I AAoiT, for example, at 4.00 kPa, PMICH 1 kPa and Cddop 5 N 7 eg 10 O / Eg 5 2.6, i.e. N 3. The sensitivities of the sensors belonging to each group or the nominal values of the pressures for which they are designed (their scales) must also be in accordance with, KdqQf ,, In the example, one sensor is taken at 100 kPa, the second sensor is 1 at 20 kPa and the third sensor 1 - 4 kPa, i.e. with multiplicity of five. The device works as follows. Using sensors 1) -1, the first pressure P is measured using 2-2 fT, the second pressure of sensors P, j. When measured controlled. pressure P; and P, with the help of switching units 3 and 4, automatically those of sensors 1 - 1 are automatically or manually selected for operation (and 2 - 2f, KOTOpHe provide, at the input of dividing unit 5, analogue signals with the level Agx A ом ohm / K) additional analog signals From the sensors selected by the switches, the sensor signals arrive at the input of dividing unit 5. Simultaneously, discrete signals equal to a logical unit are sent from the discrete outputs of block 3 and 4 of the switching to the inputs of that of the matching elements of the logical information processing unit 6, which corresponds to this pair The selected sensors output of the same element matches the element of the scaling unit 7, which introduces the scale factor specified for this pair of sensors. The analog signal, taking into account the coefficient implemented by block 7, is fed into the measuring device 8. Through the use of pressure sensor groups of different sensitivities each of the measured pressures and switching units 3 and 4, the dividing unit 5 and the pressure sensors themselves operate continuously in the zone of the smallest errors, which ensures a wide range onnoe dimension ratio of pressures while maintaining measurement accuracy. The invention The device for measuring the ratio of two pressures, containing a group of sensors for each of the measured pressures, a dividing unit and a measuring device, characterized in that, in order to expand the range of ratios of measured pressures while maintaining a given accuracy, it additionally contains two switching units, analog the inputs of which are connected respectively to the sensors of each group, and the analog outputs to the corresponding inputs of the dividing unit, a block of logical information processing consisting of two inputs O coincidence elements, each of which inputs are connected respectively to the outputs diskretnEomi both switching units, and scaling unit, an analog input coupled to an output of dividing unit, control inputs - outputs a corresponding logical unit information processing and output from the measuring device. Sources of information taken into account in the examination 1.Shornikov E.A. Measuring instruments and systems. M., Energie, 1973, fig. 17 2.Melnichenko P.M. and Chaly A.A. Analysis of methodological errors in the automatic determination of the boundaries of the surge. Sat Automation of chemical production. Kiev, Naukova Dumka, vol. 10, 1975, p. 102, fig. 1 (prototype).