FIELD: measurement equipment.
SUBSTANCE: heat-dependent technological resistor Rαt is installed into a diagonal of bridge circuit power supply, the rating of which is higher than possible values of a compensating heat-dependent resistor Rα. In parallel to the resistor Rαt they install a link. They measure initial unbalance and output signal of the sensor under normal temperature t0, and also temperature t+, corresponding to upper limit of working range of temperatures, and t-, corresponding to lower limit of the working range of temperatures. On the basis of performed measurements they calculate temperature coefficient of frequency (TCF) of strain gauges of a bridge circuit
and
at temperatures t+ and t-, accordingly, and also non-linearity of TCF of strain gauges of the bridge circuit
They measure input resistance of a sensor bridge circuit. A heat-independent resistor Ri=0.5·Rinp is connected. They measure initial unbalance and output signal of the sensor at temperatures t0, t+ and t-. On the basis of completed measurements they calculate TCF of input resistance at t+ and t-. The resistor Ri is disconnected, and the link is removed off the resistor Rαt. They measure initial unbalance and output signal of the sensor at temperatures t0, t+ and t-. On the basis of completed measurements they calculate TCF of a process heat-dependent resistor Rαt at temperatures t+ and t-. If TCF of strain gauges of the bridge circuit and its non-linearity belong to the area of method application, they calculate the rating of the heat-dependent resistor Rα and heat-independent resistor Rsh with usage of produced values of TCF of strain gauges of a bridge circuit, TCF of input resistance and TCF of the resistor Rαt. The resistor Rαt is replaced with a resistor Rα by means of partial engagement. The input resistance of the bridge circuit is shunted with a heat-independent resistor Rsh.
EFFECT: increased accuracy of compensation of multiplicative temperature characteristic of an output signal of a sensor.
2 cl
