SU974280A1 - Remote converter of resistannce increment to current ratio - Google Patents

Description

one

The invention relates to electrical measuring equipment and can be used to convert a change in active resistance to a current.

An unbalanced automatic bridge is known, comprising a power source, a measuring resistor, a compensation resistor, an amplifier and a logometer, one of the frames of which is attached, and connected in parallel with the power source, and the other with a compensation resistor forms a feedback circuit of amplifier 1.

The disadvantage of this device is the narrow scope due to errors associated with scale non-linearity, temperature changes in the resistance of the gauge frame 20 and communication lines, and the use of a gauge with galvanically separated frames that the industry does not produce.

The closest to the proposed technical entity is an autocompensation device for remote measurement of active resistance, containing a logometer, amplifier and balanced bridge, one of the arms of which contains the measured resistor, compensation resistor and communication line, and one of the frames of the logometer is connected in series to the power source in the supply diagonal of the bridge, and the other with a compensation resistor forms a feedback circuit of amplifier 21.

15

The disadvantage of this device lies in the low sensitivity and complexity of manufacturing, due to the need to use logometers with galvanically separated frames, which the industry does not produce.

The purpose of the invention is to simplify and increase the sensitivity.

The goal is achieved in that the converter contains a logometer, an amplifier and a balanced bridge, the power supply diagonal of which contains the communication line, as well as the first output terminal of the added resistor, the Power source and the first output of the logometer frame, the second output of which is connected to the first vertex of the diagonal power supply of the bridge, the first arm of which contains a compensation resistor connected in series, a second communication line and a first terminal of the measured resistor, a second shoulder containing a third communication line and the third resistor, the third and fourth shoulders, containing the second and third resistors, respectively, connected to the first and second vertices of the measuring dig of the bridge; the corresponding inputs of the amplifier; connected to the common output of the second communication line and the compensation resistor, the other output of which is connected to the second output of the frame of the gauge and the first vertex of the diagonal of the bridge with which it is connected the first output of the communication line, the second output of which is connected to another output of the third communication line, and the other output of the first resistor is connected to the first vertex of the measuring diagonal of the bridge, which is connected to the second vertex of the bridge supply diagonal resistor and, the first, the output of the third resistor, the second output of which is connected to the curtain by the measuring vertex of the bridge, which is additionally connected by a communication line with the second output of the measured resistor

The drawing shows a block diagram of the device

The device contains the measured resistor 1t four lines of communication 2-5, the compensation eesistor 6, the resistors of the shoulders of the suspended bridge, the additional resistor 10, the logometer 11 with the rollers 12 and 13, the amplifier H,

The device works the same way.

When the resistance of the measured resistor 1 changes, the current I flowing through it changes as a result

what appears on the measuring diagonal of the bridge is the voltage that is applied to the input of the amplifier,.

The voltage drop across the measured resistor is automatically compensated by the voltage across the compensation resistor 6, which is proportional to the load current 3 (amplifier 1.

The ratio of the load current of the amplifier Iff to the current flowing through the measured resistor 1 will be directly proportional to the increment LK of the measured resistor 1, i.e.

To one

DK.

As in the prototype device, the magnitude of the resistance of the link-to-link line 20 and the supply voltage do not affect the accuracy of the conversion.

Claims (1)

1. Ornatsky PoP, Automatically measuring devices Kiev, Technique, 19b5, s, U2, fig. 57 c. 2 „Author's testimony of the USSR №, cl. G 01 R 17/02, 1973.