CS275772B6 - Circuit connection for evaluation of thermoelectric salt signal voltage signal - Google Patents

Abstract

The circuit is intended for input circuits of series and control devices. It ensures compensation of measurement errors caused by temperature effects on the comparison ends of the thermoelectric cell, caused by the temperature instability of the components used and the tuning sources and enables indication of the interruption of the thermoelectric cell circuit. The circuit compares the voltage signal of the thermoelectric cell (18) with the reference voltage of the setpoint, i.e. the voltage between the slider of the potentiometer (5) of the setpoint and the slider of the adjustment potentiometer (12). The resulting tuning difference is amplified and further processed as a control deviation signal from the output (28) of the amplifier (23). The diode (3) senses the temperature of the comparison ends of the thermoelectric cell (18). With a change in this temperature, the threshold voltage of the diode (3) changes, which ensures a change in the reference voltage of the setpoint just large enough to compensate for the change in the thermoelectric voltage caused by a change in the temperature of the comparison ends of the thermoelectric cell (18). The influence of compensation is determined by the size of the temperature dependence of the change in the threshold voltage of the diode (3) and the size of the first resistor (8) of the influence of compensation, the second resistor (9) of the influence of compensation, the variable resistor (10) and the equalizing resistor (14).

Description

The invention relates to the connection of a circuit for evaluating the voltage signal of a thermocouple, consisting of a resistive bridge acting as a source of a variable reference setpoint voltage, a temperature compensation circuit of the thermocouple comparison ends and a control deviation amplifier with correction circuits.

Thermoelectric cells are very often used as temperature sensors, especially for higher temperatures, eg above 500 ° C, or as temperature sensors for special purposes, for point temperature sensing, for measurements with a small time constant, etc. Sensor output voltage under precisely defined conditions the measurement arrangement is a predefined unambiguous function of temperature.

When processing the voltage signal of the thermocouple in the control devices, the voltage is compared with the variable reference voltage of the setpoint and the resulting difference is amplified or further adjusted as a control deviation signal. The reference voltage circuits, the amplifier and other auxiliary circuits must be independent of all influencing factors, ie mains fluctuations, the effect of ambient temperature, aging and the stability of the individual components. Furthermore, it is necessary to keep the temperature of the comparison ends of the thermoelectric cell at a certain constant temperature or to ensure compensation of the influence of the ambient temperature on these comparison ends. The voltage thus obtained is then a function of the difference between the temperature of the specific ends of the thermocouple and the reference voltage and can be further processed as a control deviation signal.

Because the achievable voltage values are of the order of millivolts and evaluable changes are tens of microvolts, it is necessary to use connections with high accuracy, stability and resistance to interfering signals. Circuits for processing voltage signals of thermoelectric cells must also provide protection in case of interruption of the thermoelectric cell circuit.

Connections are known where monolithic operational amplifiers are used to amplify the signal, voltage dividers supplied from constant voltage sources are often used as sources of variable reference voltage and sources of voltage signal variable with ambient temperature of control or measuring instrument terminals are used as compensation circuits of thermocouple comparison ends. . The actual temperature sensor around the terminals, ie the temperature sensor of the comparator ends, is, for example, a thermoelectric cell, diode or resistor wound from a nickel conductor, connected in the circuit of a voltage divider at some input of the amplifier. The sensor must be selected and adjusted before connection to the circuit so that the effect of temperature compensation corresponds to the type of thermocouple used. Selecting a sensor and adjusting the temperature compensation is a relatively difficult task. However, this method of temperature compensation does not eliminate other possible additional measurement errors, such as temperature drift and fluctuations in voltage asymmetry of the amplifier with temperature, the effect of temperature on the reference voltage source, or additional errors of other components used in the overall connection. Additional errors must then be eliminated by using high-quality and therefore also expensive amplifiers and other components.

The shortcomings are largely eliminated by the connection of the circuit for evaluating the voltage signal of the thermoelectric cell according to the invention, the essence of which consists in the positive supply terminal being connected to the first terminal of the first bridge resistor and to the first terminal of the third bridge resistor. resistor and on the one hand with the first terminal of the ballast resistor, the second terminal of which is connected on the one hand to the first terminal of the first resistance of the compensation effect and on the other hand to the anode of the diode. The cathode of the diode is connected on the one hand to the terminal of the voltage center and on the other hand to the first terminal of the balancing resistor,.

on the one hand and the first terminal of the second supply resistor and on the other hand with the first terminal

CS 275 772 B6 * 2 second resistance of the compensation effect. The second terminal of the second compensation effect resistor is connected to the second terminal of the first compensation effect resistor, to the first terminal of the variable resistance, and to the second terminal of the parallel combination of the setting resistor and the setpoint potentiometer, the second terminal of which is connected to the second terminal of the first bridge resistance. The slider of the setpoint potentiometer is connected to the first terminal of the thermocouple, the second terminal of which is connected to the first input of the amplifier and to the first terminal of the protective resistor. The second terminal of the protective resistor is connected on the one hand to the negative supply terminal and on the other hand to the negative supply input of the amplifier, the second input of which is connected to the slider of the adjustment potentiometer. The second terminal of the third bridge resistor is connected to the first terminal of the adjustment potentiometer, the second terminal of which is connected via the fourth bridge resistor to the second terminal of the variable resistor and to the second terminal of the balancing resistor. The second terminal of the second supply resistor is connected to the second terminal of the first supply resistor and to the positive supply input of the amplifier, the output of which is the output of the entire circuit.

The advantage of connecting a circuit for evaluating the voltage signal of a thermocouple according to the invention is that it allows not only to compensate for the effect of temperature on the comparison ends of the thermocouple, but also to compensate for temperature effects on the amplifier and resistor bridge, i.e. the source of variable reference voltage. The temperature compensation circuit is very simple and its influence can be easily adjusted for any type of thermoelectric cell used. The resistor bridge is preferably supplied from the same source as the amplifier, for which a frequent request for the magnitude of the positive output voltage signal can be ensured by a suitable choice of the first and second supply resistors. The circuit also provides signaling of interruption or interruption of the thermocouple supply. In this case, the effect of the protective resistor prevails at the first input of the amplifier, through which a signal is supplied from the negative supply terminal to the amplifier, which corresponds to a significant increase in temperature at the measured location. The control device therefore triggers an action to prevent the supply of energy to the controlled system. The advantages of connecting a circuit for evaluating the voltage signal of a thermoelectric cell can be added simplicity and small demands on the space in which the circuit is installed. This reduces production costs and increases shock resistance and function reliability.

An example of a circuit connection for evaluating the voltage signal of a thermoelectric cell is schematically shown in the drawing.

The positive supply terminal 2 is connected to the first terminal of the first bridge resistor 4, to the first terminal of the third bridge resistor 21, to the first terminal of the first supply resistor 15 and to the first terminal of the ballast resistor 2, the second terminal of which is connected to the first terminal. The cathode of the diode 2 is connected to the voltage center terminal 17, to the first terminal of the balancing resistor 24, to the first terminal of the second supply resistor 16 and to the first terminal of the second resistance 2 of the compensation effect. . The second terminal of the second compensating resistor 2 is connected to the second terminal of the first compensating resistor 8, to the first terminal of the variable resistor 10 and through the second bridge resistor 7 to the first terminal of the parallel combination of setting resistor 6 and setpoint potentiometer 2, the second terminal of which is connected to the second terminal of the first bridge resistor £. The slider of the setpoint potentiometer 2 is connected to the first terminal 19 of the thermocouple 18, the second terminal 20 of which is connected to the first input 24 of the amplifier 22 and to the first terminal of the protective resistor 21. The second terminal of the protective resistor 21 is connected to the negative supply

CS 275 772 B6 terminal 22 and on the one hand with the negative supply input 27 of the amplifier 23, the second input 25 of which is connected, to the slider of the adjusting potentiometer 12. The second terminal of the third bridge resistor 11 is connected to the first terminal of the adjusting potentiometer 12. the bridge resistor 13 is connected on the one hand to the second terminal of the variable resistor 10 and on the other hand to the second terminal of the balancing resistor 14; is the output of the whole circuit.

The connection works so that the voltage proportional to the measured or regulated temperature at the first terminal 19 of the thermocouple 18 and the second terminal 20 of the thermocouple 18 is subtracted from the diagonal voltage of the resistor bridge on the setpoint and adjustment potentiometer sliders 5. Diagonal voltage, in case of circuit failure the compensation of the thermoelectric cell from the operation when the variable resistor 10 has a zero value is proportional to the setpoint. The resulting voltage difference, the magnitude and polarity of which correspond to the magnitude and meaning of the control deviation, is amplified in the amplifier 23. The minimum and maximum voltage values of the diagonal, ie the range of controller setpoints, are set by adjusting resistor 6 and adjusting potentiometer 12. the influence of the voltage asymmetry of the amplifier 23. The influence of temperature changes of the comparison ends of the thermocouple 18 on the measurement accuracy is compensated by a diode 2 located as a temperature sensor near terminals 19 and 20 of the thermocouple 18. The required temperature compensation effect depends on the type of thermocouple used is roughly set by the first resistance influence resistor 8 and by the second compensation influence resistor 2. Precise setting of the compensation effect, which also eliminates the effect of other possible additional errors, such as temperature drift of the amplifier 23 and the supply voltage source, is performed by precise selection of the balancing resistor 14 and setting of the variable resistor 10. In the extreme case 10 is equal to zero, the influence of the compensation circuit is minimal. In the case where the conductivity value of the variable resistor 10 is equal to zero, the influence of the compensation circuit is maximum. The exact setting is made at room temperature and further in a room where the temperature is maintained at approximately 50 ° C. Said adjustment ensures the exact effect of the temperature compensation of the comparison ends and eliminates additional errors of the used components in the range of operating temperatures of the controller. This allows cheaper components to be used.

If the circuit of the thermoelectric cell 18 is interrupted » a potential drop occurs at the first input 24 of the amplifier 23 due to the protective resistor 21 and the negative supply terminal 22. Said potential drop is amplified and a signal appears at the output 28 of the amplifier 23 which closes the power supply to the system after evaluation by the output member. This ensures that when the Sensor circuit is interrupted, there is no emergency situation and no over-regulation of the system.

The frequent requirement to limit the positive level of the amplifier output signal is solved by setting the appropriate voltage at the positive supply input 26 of the amplifier 23 by means of a voltage divider formed by the first supply resistor 15 and the second supply resistor 16.

The invention is used in measuring and control technology in the construction of measuring and control devices.

Claims (1)

PATENT CLAIMS Circuit circuit for evaluating the voltage signal of a thermoelectric cell, characterized in that the positive supply terminal (1) is connected to the first terminal of the first bridge resistor (4) and to the first terminal of the third bridge resistor (11) and to the first terminal of the first supply resistor (15) and on the one hand with the first terminal of the ballast resistor (2), the second terminal of which is connected to the first terminal of the first resistance resistor (8) and to the anode of the diode (3), the cathode of which is connected to the terminal (17) voltage center, on the one hand with the first terminal of the balancing resistor (14), on the other hand with the first terminal of the second supply resistor (16) and on the other hand with the first terminal of the second compensating effect resistor (9), the second terminal of which is connected to the second terminal of the first resistor (8) compensating effect, on the one hand with the first terminal of the variable resistor (10) and on the other hand via the second jumper resistor (7) with the first terminal of the parallel combination of the adjusting resistor (6) and the setpoint potentiometer (5) The terminal is connected to the second terminal of the first bridge resistor (4), while the slider of the setpoint potentiometer (5) is connected to the first terminal (19) of the thermocouple (18), the second terminal (20) of which is connected to the first input (24). ) of the amplifier (23) and on the one hand with the first terminal of the protective resistor (21), the second terminal of which is connected on the one hand to the negative supply terminal (22) and on the other hand to the negative supply input (27) of the amplifier (23) connected to the slider of the adjusting potentiometer (12), while the second terminal of the third bridge resistor (11) is connected to the first terminal of the adjusting potentiometer (12), the second terminal of which is connected via the fourth bridge resistor (13) to the second terminal of the variable resistor (10). and with the second terminal of the compensating resistor (14), while the second terminal of the second power resistor (16) is connected both to a second terminal of the first power resistor (15) and secondly to the positive power supply input (26) of the amplifier (23), _f whose output (28 ) is the output of the whole community you.