SU983553A1 - Measuring converter - Google Patents

Description

(5) MEASURING CONVERTER

one

The invention relates to measuring equipment, in particular, to measuring transducers of resistance to direct voltage (current), designed, for example, to accurately measure temperature, pressure, signal, etc. These converters are widely used in systems for centralized monitoring and control of technological processes (objects), measurement information systems and complexes.

Devices are known for converting active resistance to direct current voltage, containing a measuring bridge, in one of which a measured resistance is included, and a direct current amplifier covered by negative feedback.

The disadvantage of these devices is a significant measurement error; NIN at change of resistance of wires of a communication line, caused by change of external conditions.

It is also known a device containing a measuring bridge, in one of the arms of which, using a three-wire communication line, includes a measurable resistance, a bridge power supply and a differential DC amplifier, ..

Claims (2)

The compensation of the line effect in this circuit is made by applying a three-wire line, with the first wire of which the first output of the measured resistance is connected to the measuring diagonal of the post and to the non-inverting input of the differential DC amplifier. The second terminal of the measured resistance is connected via the second wire of the communication line only to the lower arm of the bridge, and through the third wire to the power supply source and the common bus, the differential amplifier. With this inclusion of the measured resistance, the first and second wires of the communication line are switched on the opposite shoulders of the bridge, and as the resistances of these wires change, the resistances of the bridge shoulders change simultaneously. Bridge debalance does not occur, i.e. the effect of the G 2J link is compensated. The disadvantage of the device is that the resistance of the second wire of the communication line to the lower arm of the negative feedback amplifier of the amplifier and the change in the magnitude of the resistance of the communication line changes the transmission coefficient of the whole transform, which leads to significant errors from the front, especially low impedance measurable resistances. The aim of the invention is to improve the accuracy of the measurement. The goal is achieved by the fact that in a measuring transducer containing a power source, a differential DC amplifier and a four-shouldered measuring bridge consisting of four resistors, one of them, measured, is connected to the four-blade measuring bridge using a three-wire communication line, through the first the wire of which one output of the measured resistor is connected to the first output of the first resistor of the four-arm measuring bridge and the non-inverting input of the differential DC amplifier, The output of the latter through a feedback resistor is connected to the inverting input of the differential amplifier and to the second and third resistors of the four-arm measuring bridge, another output of the second resistor VDn1nn with the first output of the power supply source and the second output of the first resistor of the four-shoulder measuring bridge, the second output of the measured resistor is connected through the second wire of the communication line to the common bus of the differential amplifier of constant current and to the second output of the third resistor of the four-arm measuring bridge And through a third wire if SRI communication - to the second terminal of the power supply. The drawing shows a diagram of this device. Measuring bridge 1 consists of four resistors 2-5 (resistor 5 being measurable). The power supply diagonal of the bridge (points 6 and 1) is connected to the power supply 8, the measured resistor 5 to the measuring bridge through two resistances of the wires 9 and 10 of the communication line, and to the power supply through the resistance of the wire 11 of the communication line. A non-inverting k and inverting 15 inputs of a differential DC amplifier 16 are connected to pins 12 and 13 of the measuring diagonal of the bridge. The common bus 17 of the amplifier is connected to the bridge resistor k and to the resistance of the wire 10 of the communication line. In addition, by means of the resistor 18, the DC amplifier 16 is covered by negative feedback. The output of the amplifier 1b is connected load 19 The scheme works as follows. The resistance of the measuring bridge is chosen kj3 of the following relations: the resistance of resistor 2 is equal to the resistance of resistor 3 and the resistance of resistor k is equal to the sum of the resistances of resistor 5 and wires 9 and 10. Under this condition, the voltage on the pins 12 and 13 of the measuring diagonal of the bridge is zero and the signal in the load 19 is also zero. When the measured resistance of the resistor 5 changes, the bridge goes out of balance and a misalignment signal appears in the measuring diagonal, which goes to the outputs of amplifier 16. The error signal amplified by amplifier 16 goes to load 19, and the gain of the amplifier is determined by the ratio of the reverse resistor 18 connection and resistance of the bridge resistor k. Consider how the compensation of the link effect occurs in this scheme. The non-inverting input of the amplifier is supplied with a voltage taken from the measured resistor 5 and from the resistances of the wires 9 and 10 of the communication lines. The currents from the power supply source 8 of the bridge flow along the resistances of the wires 9 and 10 of the communication lines in such a way that the voltage drops generated by them on these resistances relative to the common bus 17 are turned on counter-current and, thus, the voltage removed from points 12 with respect to the common bus, equal to the voltage across the measuring resistor 5. With simultaneous changes in the line resistances, the potential of point 12 with respect to the common bus does not change, since the voltages on the line resistances change equally and also compensate are each other. The resistance of the resistor k is connected to the common busbar and the potential of point 13 does not change with changes in both the measured resistance and the resistance of the communication lines. Since the feedback circuit does not include the resistance of the communication line, the change in the resistance of the communication line does not affect the gain of the converter. Thus, in the proposed scheme, changes in the resistance of the communication lines do not affect the measurement accuracy. Invention A measuring transducer comprising a power source, a DC differential amplifier and a four-arm measuring bridge consisting of four resistors, one of which is measurable, is connected to a four-arm measuring bridge using a three-wire communication line. , through the first wire of which one output of the measured resistor is connected to the first output of the first resistor 98 of the four-arm measuring bridge and the non-inverting input of the differential DC amplifier, the output of the last through a feedback resistor connected to the inverting input of the differential amplifier and to the second and third resistors of the four-arm measuring bridge, another terminal of the second resistor is connected to the first output of the power supply and the second terminal of the first four-meter measuring resistor, bridge, characterized in that, in order to improve accuracy measurement, the second output of the measured resistor is connected via the second wire of the communication line to the common bus of the differential DC amplifier and to the second output of the third its four-arm measuring bridge resistor, and via the third wire of the communication line to the second, the output of the power source. Sources of information taken into account at experts; Ze 1.Patent USA ff 35680, cl. 323/75, published. 1972. 2. Leitman M.B. and others. Compensation measuring converters of electrical quantities. M., Energie, 978 ,. 4. UO, fig. 5-1 (prototype ;.