JPH064307Y2 - Temperature compensation circuit for pressure measuring instrument - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention relates to a temperature correction circuit of a pressure measuring device used for process measurement or the like.

(B) Conventional Technology As shown in FIG. 4, the conventional pressure measuring device includes a pressure sensor 41, a temperature sensor 42, a pressure sensor 41 and a temperature sensor 4.
A converter 43 for converting the output of the pressure sensor 41 or the temperature sensor 42 input from the multiplexer 43 into a digital signal.
The pressure sensor 41 includes a PU 45, a ROM 46, a display 47, and a RAM 48, and a semiconductor pressure sensor is often used as the pressure sensor 41.

In general, the characteristics of the semiconductor pressure sensor change depending on the temperature. Therefore, the pressure sensor alone may be a temperature-compensated resistor provided with a temperature compensation resistor. However, in the pressure measuring instrument, the temperature correction of the pressure sensor alone is not sufficient for correction, so first change the temperature without temperature compensation other than the pressure sensor, measure zero change, span change, measure temperature error, The data for correcting this has been written in the ROM 46.

(C) Problems to be solved by the device In the temperature correction of the above-mentioned conventional pressure measuring instrument, it is necessary to measure the zero change and the span change by changing the temperature and individually adjust the pressure measuring instrument. There is a problem that it takes a very long time to sufficiently perform temperature correction over the range of use, the circuit is complicated, and the correction accuracy is not so good.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a temperature correction circuit for a pressure measuring instrument that can easily and easily perform temperature correction even at a measurement site.

(D) Means and Actions for Solving Problems The temperature compensating circuit of the pressure measuring device of the present invention is a
The signal detected by (1,2) is amplified by the amplifier (3), and the amplified output is A / D converter (4) which operates based on the reference voltage.
In the pressure measuring device that converts into a digital value by
A voltage generator circuit (8, 9, 12) that receives a DC voltage at its input and generates a voltage proportional to the ambient temperature, and the input DC voltage to this voltage generator circuit is varied to A first regulator (7) capable of adjusting the output voltage of the voltage generating circuit to zero volt, and second and third regulators (7) capable of receiving the output voltage of the voltage generating circuit and varying the voltage value to an arbitrary value. Receiving the output of the regulator (13,14) and this second regulator,
A first function generator (15) that generates a voltage corresponding to this output value only when the output value exceeds zero volt on one side,
A second function generator (16) which receives the output of the third regulator and generates a voltage corresponding thereto only when the output value exceeds zero volt on the other side, and the first and second The output voltage of the second function generator and a direct current voltage having a predetermined value are received, and the direct current voltage and the output voltage of the first or second function generator are added based on an appropriate instruction or It is characteristically provided with an arithmetic unit (17) for performing a subtraction operation and supplying the operation result voltage as a reference voltage to the A / D converter.

The voltage generation circuit is a circuit that generates a voltage proportional to the ambient temperature. By adjusting the first regulator, the output voltage at a predetermined reference temperature (for example, normal operating temperature) is adjusted to zero volts. can do.

The first function generator is a circuit that generates a voltage corresponding to the input voltage when receiving an input voltage of, for example, 0 volt or higher, and the second function generator is an input of, for example, 0 volt or lower. It is a circuit that generates a voltage corresponding to an input voltage when receiving a voltage. Therefore, after adjusting the output of the voltage generating circuit to zero volts by the first regulator, the first function generator becomes a circuit that generates a voltage corresponding to the ambient temperature only above the reference temperature, and The second function generator is a circuit that generates a voltage corresponding to the ambient temperature only at the reference temperature or lower.

The computing unit functions as an adding circuit or a subtracting circuit based on an appropriate instruction from the operator, and the "DC voltage of a predetermined value +
(Or −) first function generator output ”or“ predetermined value of DC voltage + (or −) second function generator output ”.

When the reference voltage changes, the A / D converter outputs different digital data even for analog signals of the same level. Therefore, the output of the arithmetic unit (that is, the reference voltage of the A / D converter) is set to the first value. The temperature of the pressure measuring device can be corrected by appropriately adjusting with the third adjusting device.

The adjustment procedure will be described in detail below. The first regulator is varied to adjust the output voltage of the voltage generating circuit at the reference temperature (for example, the normal temperature using the pressure measuring instrument) to zero volt. Then, for example, at the site, the temperature is measured above or below the reference temperature, and the pressure measurement device for calibration is measured in parallel so that the measured values become the same.
Adjust the adjuster of.

Further, the temperature may be corrected at three points on site. That is,
The first regulator is varied to adjust the output of the voltage generation circuit at the reference temperature at each site to zero volt, and then at the predetermined temperature above and below the reference temperature, the measured value of the pressure measuring instrument for calibration is used. The second and third adjusters may be adjusted to be the same.

In any case, in this pressure measuring device, the temperature of the A / D converter can be easily and accurately corrected by appropriately adjusting the reference voltage of the A / D converter by the first to third adjusting devices.

(E) Embodiment Hereinafter, the present invention will be described in more detail with reference to embodiments.

FIG. 1 is a circuit diagram of a pressure measuring instrument showing an embodiment of the present invention. This pressure measuring device comprises a semiconductor pressure sensor 1, a constant current source 2 for driving the semiconductor pressure sensor 1, a signal amplifier 3 for amplifying the output of the semiconductor pressure sensor 1 and an A / D converter 4, and further temperature correction The circuit 5 is additionally provided. Although not shown, the A / D converter 4
Output is captured by the CPU and appropriately displayed on the digital display.

The temperature correction circuit 5 includes a reference voltage source 6, and a resistance voltage divider 7 is connected in parallel with the reference voltage source 6.
The divided voltage E _{1 at} the variable terminal of the resistance voltage divider 7 is
And is converted into the output E ₀ by the arithmetic unit 9. Between the positive side of the reference voltage source 6 and the output terminal of the arithmetic unit 9, a resistor 10,
11 is connected and the divided voltage E ₁ and the output voltage E ₀ have opposite polarities, so that the resistors 10 and 11 form a subtractor 12. The output of the subtractor 12, that is, the voltage at the point P is divided by the resistance voltage dividers 13 and 14 and input to the function voltage generators 15 and 16, respectively. As shown in FIG. 2 (a), the function voltmeter 15 generates a function voltage in which the output voltage also increases in the negative direction when the temperature rises above a reference temperature (eg, 25 ° C.). The generator 16 has a second characteristic
As shown in FIG. 6B, when the temperature drops below the reference temperature, the output voltage also generates a function voltage that increases in the negative direction. The characteristic gradients of these function voltage generators 15 and 16 are adjusted by the resistance voltage dividers 13 and 14. The output voltages of the function voltage generators 15 and 16 are input to the adder / subtractor 17, and the voltage of the reference voltage source 6 is also input to the adder / subtractor 17. The adder / subtractor 17 is connected to switches 18 and 19 for switching the polarities of the voltages supplied from the function voltage generators 15 and 16, respectively. These switching devices 18, 1
By switching the polarities according to 9, the adder / subtractor 17 adds or subtracts the voltages of the function voltage generators 15 and 16 to the voltage of the reference voltage source 6 and outputs it. The output voltage of the adder / subtractor 17 is input as the reference voltage of the A / D converter 4.

Next, the case where the temperature is corrected in the pressure measuring instrument of the above embodiment will be described. As the temperature characteristics of the pressure sensor 1, two cases of a (solid line) and b (broken line) in FIG. 3 are assumed. In both a and b, the temperature error at the reference temperature of 25 ° C. is 0%, and in the case of a, the temperature error linearly increases in the + direction as the temperature rises from the reference temperature, and becomes +3 at 50 ° C.
%, And conversely when the temperature drops below the reference temperature,
This is the case where the temperature error linearly increases in the + direction and becomes + 1% at 0 ° C. In b, the temperature error increases linearly in the-direction with increasing temperature from the reference temperature to -1% at 50 ° C, and when the temperature decreases from the reference temperature, the temperature error increases linearly in the + direction. However, it is a case where the temperature becomes + 3% at 0 ° C.

The temperature change of the pressure sensor 1 includes a zero point change and a span change. For zero point adjustment, open the input pressure and the displayed value is 0.
If the offset voltage of the amplifier A ₃ of the signal amplification unit 3 is adjusted so that What is important here is compensation by the temperature correction circuit 5 for changes in the span temperature.

First, the pressure measuring device is placed under a reference temperature (25 ° C.), the voltage at the output point P of the subtractor 12 is monitored, and the resistance voltage divider 7 is adjusted to 0V. After completion of this adjustment, if this pressure measuring instrument is used for actual measurement, if the temperature is the reference temperature, the voltage at the point P is 0 and the function voltage generators 15 and 16 are
Since the output of is also 0 [see FIGS. 2 (a) and 2 (b)], the voltage of the reference voltage source 6 is input as the reference pressure reduction of the A / D converter 4.

After the adjustment of the resistance voltage divider 7, this time, the pressure measurement device is placed at a temperature higher than the reference temperature, for example, 40 ° C., and compared with the calibrated standard pressure measurement device. Adjust 13. For example, when the pressure sensor of the characteristic a is used, the switch 18 is set to the negative side and the slope of FIG. 2 (a) is changed to compensate for the increase error of the characteristic a. To do. On the contrary, when the characteristic of the pressure sensor 1 is the characteristic b of FIG. 3, the switching device 18 is set to the positive side and the resistance voltage divider 13 is also adjusted to eliminate the temperature error in the negative direction of the characteristic b. Cancel.

Next, this time, in the case of performing correction at a site below the reference temperature (for example, 10 ° C.), comparison measurement is also performed with the standard pressure measuring device at that site so that the measurement displays of both measuring devices match.
Adjust resistance divider 14. For example, in the case of using the pressure sensor having the characteristic a, the switching device 19 is set to the negative side, and the resistance voltage divider 14 changes the gradient of FIG.
The increase error of the characteristic is canceled.

Although the reference temperature is set to 25 ° C. in the above embodiment, the reference temperature can be set freely. For example, when the reference temperature is 20 ° C., the output point of the subtractor 12 is 20 ° C. below. It suffices to adjust the resistance voltage divider 7 so that the voltage of P becomes zero.

Further, in the above embodiment, the characteristic of the function voltage generator is
The temperature characteristic of the temperature-sensitive resistor is also linear in order to correspond to it, but if a non-linear characteristic such as a thermistor is used as the temperature-sensitive resistor, the non-linear characteristic should be changed accordingly. You can use it.

(F) Effect of the device According to this device, since the temperature error of the pressure measuring device is canceled by using the function voltage generator and the voltage adjusting air, a correction circuit with a constant different for each pressure measuring device is prepared. Since it is not necessary to perform the adjustment and the adjustment only needs to be performed by operating the knob of the adjuster, it is extremely simple and can be easily corrected even at the measurement site if there is a reference pressure measuring device for calibration. Further, by narrowing the compensation temperature range, the accuracy of temperature compensation can be further improved.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a pressure measuring device showing an embodiment of the present invention, and FIGS. 2 (a) and 2 (b) are characteristic diagrams of a function voltage generator for calibrating a temperature correction circuit of the pressure measuring device. FIG. 3 is a diagram showing an example of temperature characteristics of a pressure sensor of the pressure measuring instrument, and FIG. 4 is a block diagram showing a conventional pressure measuring instrument. 1: Pressure sensor, 2: Constant current source, 3: Signal amplification unit, 4: A / D converter, 5: Temperature correction circuit, 6: Reference voltage source, 7.13 / 14: Resistance voltage divider, 8: Sensing Temperature resistance, 9: amplifier, 12: subtractor, 15 · 16: function voltage generator, 17: adder / subtractor.

Claims (1)

[Scope of utility model registration request] 1. A signal detected by a pressure sensor (1, 2) is amplified by an amplifier (3), and the amplified output is converted into a digital value by an A / D converter (4) which operates based on a reference voltage. In the pressure measuring instrument to be converted, the voltage generator circuit (8, 9, 12) that operates by receiving a DC voltage at the input and generates a voltage proportional to the ambient temperature, and the DC voltage input to this voltage generator circuit are changed. A first regulator (7) capable of adjusting the output voltage of the voltage generating circuit at a predetermined reference temperature to zero volt, and receiving the output voltage of the voltage generating circuit and varying the voltage value to an arbitrary value. The second and third regulators (13, 14) to be obtained and the output of this second regulator are received, and a voltage corresponding to this is generated only when this output value exceeds zero volt on one side. Receiving the output of the first function generator (15) and the third regulator, the output value of which exceeds zero volt to the other side. Only in this case, a second function generator (16) for generating a voltage corresponding thereto, an output voltage of the first and second function generators, and a direct current voltage of a predetermined value are received, and the direct current voltage , An addition or subtraction operation is performed between the output voltage of the first or second function generator based on an appropriate instruction, and the operation result voltage is used as a reference voltage for the A / D converter. A temperature compensation circuit for a pressure measuring instrument, comprising: a computing unit (17) for supplying.