SU386401A1 - DEVICE FOR DETERMINING MEDIUM - Google Patents

Description

one

The device relates to the field of computing.

A device is known for determining the arithmetic mean value and coefficient of variation of parameters during processing of objects testing, which contains a transformer, to the secondary windings of which are connected reahords of measuring electrolytic potentiometer with collector conductor, reference scales, sensor relays of objects, resistors and actuator for moving a layer of electrically conductive measuring potentiometer liquid .

The known device is complex, expensive, less reliable.

The proposed device differs in that it contains a load electrolytic potentiometer with its actuator and two phase-sensitive elements, the outputs of which are connected respectively to the inputs of the actuators of the measuring and load electrolytic potentiometers. One of the inputs of the first phase-sensitive element is grounded, and the second through the limiting resistors and the first group of contacts of the relay is connected to the taps of the secondary winding of the transformer to which one of the rheochords of the measuring potentiometer is connected with scales of the arithmetic average of the parameters. The current collector conductor of the measuring electrolytic potentiometer is grounded, and all its rheochords, except the first one, have average leads that are connected to the taps of the respective secondary transformer windings and through the second group of relay contacts and the limiting and load resistors are connected to the first input of the second phase-sensitive element. The second input of the second phase-sensitive element is connected to the current-collecting conductor of the load electrolytic potentiometer with the reference scale of the coefficient of variation of the parameters, the rheochord of which

through limiting resistors and the third group of contacts of the relay is connected to the branches of the secondary winding of the transformer with an extreme terminal connected to the zero-voltage bus.

This has improved the accuracy and speed of the device.

The drawing shows a diagram of the device.

It consists of a multidirectional secondary

winding / transformer for calculating the arithmetic average value, to the external terminals of which is connected a reochord 2. Secondary winding taps / through contacts 3 and limiting resistors 4 are connected to the phase-sensitive element 5. The phase-sensitive element is connected to the actuator 6, which is controlled by a layer of conductive body 7. The layer of the electrically conducting fluid, which plays the role of a slider, grounds the reichord 2 to the nano conductor 8. The taps of the multi-limiting secondary winding 9 for the sum counting are connected through a terminal Acts 10 and limiting resistors 11 to the load rheochord 12. The reichords 13 are connected to the middle points by the terminals of the transformer 14 windings and through contacts 15 and the limiting resistors 16 are connected to the load resistor 17 and the first input of the phase-sensitive element 18, the second input of which is connected to the collector conductor 19. An actuator 20 is connected to the output of the phase-sensitive element 18, which, in turn, is controlled by a layer of electrically conductive liquid 21. The location of the contacts for their intended use corresponds to t the parameters under study, which is determined at the slit 22. The arithmetic average value is measured on a scale of 23, and the coefficient of variation of the parameters at the slit 24. We denote the parameters under study by x,

., n, / f ffvf, vf ffvff, vff

Xi, Xn, X, Xi, Xi + 3, Xn, X., Xi, Xi + 3, XnIn the device, the presence of these parameters, for example, Xg and Xg + 3, corresponds to the closed state of the contacts, and groups of contacts 3, 10 and 15 corresponding to the parameters x, x, x are blocked among themselves.

The principle of operation of the device is as follows.

The numbers obtained during the tests equate the scaling and dividing scales and include the corresponding interlocked contacts. The average value is determined as follows. After the supply of non-recurring voltage to the secondary winding 1 of the transformer, the alternating current is supplied to the reochord 2, to the layer of electrically conductive fluid 7 and through the current collecting conductor S to the ground. At the same time, a circuit is formed through the branches of the secondary winding / J closed contacts 3 (for example, corresponding to the parameters Xg and Xg + 3) and limiting resistors 4 to the input of the phase-sensitive element 5 and to the ground. The secondary winding 1 and the reichord 2 form a bridge circuit, in case of unbalance of which voltage appears at the output of the phase-sensitive element. The phase-sensitive element 5 not only adjusts the amplifying mechanism 6 in amplitude, phase, and phase; therefore, the latter moves the layer of electrowin-water liquid 7 up and down, i.e. towards the balance of the bridge. When the balance arrives, the phase-sensitive element 5 stops the signal to the actuator 6, which, in turn, stops the movement of the fluid 7. As a result, the average value of the parameters is determined from the level of the liquid 7 by means of the scales 23. In this case:

X 2

If there are numbers obtained when testing numbers, the average value will be expressed by the following equation:

P

-. „X

t i

The determination of the coefficient of variation of the parameters is as follows.

The secondary winding 9 is connected to the ground by the bottom output, but therefore the current flows along the branches through the closed contacts 10, for example, corresponding to the numbers Xi and then through the limiting resistors 11 and the load rheochord 12. In this circuit, the current flowing through the load rheochord 12 is proportional to the sum of the numbers (Xi -} - Xi s). The second circuit is formed by a grounded current-collecting conductor 8, liquid 7, parts of reochord 7 (3 between liquid 7 and their midpoints, closed contacts 15, limiting resistors 16 and 5 of the load resistor P. The voltage drop across the load resistor 17 is measured by phase-sensitive element 18, to the second input of which the part of the voltage drop from the load rail 12 via the collector conductor 19 and the liquid 21.

A bridge circuit is also created here, the voltage unbalancing of which affects the actuator 20, which moves the fluid layer 21 in the direction of the balance of the bridge.

Since the position along the bar 22 of the midpoints of reichords 13 corresponds to numbers, the potential difference between the midline (layer of conductive liquid) and the midpoints of reichords 13 characterizes the deviation from the average or the desired coefficient of variation. Since the potential gain from the midpoint is symmetrical both in amplitude and phase, the deviation is measured in absolute values. Thus, the magnitude of the current flowing through the load resistor 17 will be determined by the sum of the absolute deviations. In this case, the amount will be equal to

 + | .-; g, + h |

If the resistances of the load resistor 12 and the load resistor 17 are equal, then when the bridge is in equilibrium, the liquid 21 according to the scale 24 will show the relation:

X + X, +,

 + / - | 3

When connecting n obtained during the testing of numbers, the coefficient of variation is determined by the relation:

one

Y

px