JPH0547051B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a level meter, and particularly to an automatically calibrated induction type sodium level meter in a fast breeder reactor or the like that uses sodium. Of course, the automatic calibration induction type sodium level meter of the present invention can also be used for level measurement in general sodium storage tanks.

[Conventional technology]

Generally, in nuclear reactors such as fast breeder reactors, the sodium level is measured using a level meter.

By the way, in a nuclear reactor, it is necessary to constantly monitor the free liquid level of sodium in the reactor vessel.
For this purpose, an inductive sodium level meter as shown in FIG. 4 is usually used as a level meter. In the figure, 10 is an AC power supply, 11 is a primary coil,
12 is a secondary coil, 13 is a signal converter, and 14 is an output indicator.

This induction type sodium level meter uses AC power source 1
The sodium level is continuously measured from the output voltage of the secondary coil 12, which is electromagnetically coupled to the primary coil 11 which is excited at zero.The measurement principle is based on the eddy current generated in the sodium liquid, which is a good conductor. Since the coupling between the primary coil 11 and the secondary coil 12 is weakened and the voltage generated in the secondary coil 12 becomes smaller, by measuring the output voltage of the secondary coil, it is possible to determine the extent to which the coil is immersed in the sodium solution, i.e. It measures sodium levels. That is,
The output voltage value of the secondary coil 12 is large when the sodium level is low and small when the sodium level is high. This secondary coil output voltage is then converted to a standard current level signal 4 to 4 by a signal converter 13.
Converted to 20mA. That is, the current is converted to 4.0 mA at the zero point (lower end of the coil) and 20.0 mA at the span point (upper end of the coil) as shown in diagram a in FIG. Then, the sodium level is displayed on the display device 14 in correspondence with this current value itself.

[Problem that the invention seeks to solve]

However, due to the effects of aging and operating temperature in nuclear power plant facilities, for example, the output current value may be as low as 2.0 mA at the zero point (lower end of the coil), as shown by line b in Figure 5, or at the span point. Even at the upper end of the coil, only a low output current value of 18.5 mA was obtained, and there was a risk that the correct sodium level would not be displayed on the display.

For this reason, initial calibration has been performed prior to actual operation. Initial calibration is done through trials of gradually increasing sodium levels.
In other words, when the sodium level is below the zero point (lower end of the coil), the current level signal does not change during that time. ) to know that the following is true. The observer then controls the signal converter so that the current level signal value at that time becomes a preset value, for example, the current level value is 4.0 mA at the zero point (lower end of the coil). This was used to perform initial calibration of the zero point (lower end of the coil). Similarly, when the sodium level is increased and the sodium level exceeds the span point (the upper end of the coil), there is no change in the current level signal value, so the observer can see that the sodium level is at the span point (the upper end of the coil). It is known that the current level signal value at that time has exceeded the preset value, for example, at the span point (upper end of the coil section).
The signal converter was adjusted to a preset value of 20.0 mA, and the initial calibration of the span point (upper end of the coil) was performed.

As seen from the diagrams a and b in Figure 5, the sodium level and the current level signal are almost linearly proportional. A current signal level produced at an intermediate level will lie on diagram a of FIG. 5 and will indicate the correct sodium level.

In addition, special level detection switch means are separately provided at a level position slightly above the bottom end of the level detection coil and a level position slightly below the top end of the level detection coil section, and the observer can operate the level switch. Some devices let you know when the sodium level has reached a certain point. In this case, for convenience, the level where the lower level switch is installed is the zero point (lower switch position).
For convenience, the position where the upper level switch is provided is called the span point (upper switch position). If such a level detection switch means is provided, the current level signal value at each specific level is set in advance, and the signal converter is adjusted in the same way as before so that the current level signal value is set at each specific level. I did an initial proofreading.

In this specification, when the word "zero point" is simply written without the parentheses, it means that the handling is the same for both the zero point (lower end of the coil) and the zero point (lower switch position) regarding calibration. do. Also, simply writing the term "span point" without the parentheses ( ) means that the handling is the same for both the span point (upper end of the coil section) and the span point (upper switch position) regarding calibration.

However, adjustment of the signal converter for initial calibration is performed by a skilled technician by delicately adjusting the output adjustment trimmer in the signal converter using an adjustment screwdriver; However, it was time-consuming and extremely difficult for beginners to adjust to the desired accuracy.

The present invention is intended to solve the above problems,
To enable anyone to easily adjust a level meter, which conventionally could only be done by a skilled engineer, and to eliminate individual differences in adjustment.

[Means for solving problems]

To this end, the automatic calibration induction type sodium level meter of the present invention includes a level detection means, an A/D converter into which the detected level signal is input, a correction value for the zero point and a span point, and an A/D converter. The calculation means calibrates the input signal from the A/D converter based on the correction value, and the display means displays the calibrated output. The correction value is calculated by calibrating the input minimum and maximum level signals to predetermined levels corresponding to the zero point and the span point.

[Function] The automatic calibration induction type sodium level meter of the present invention has two types of adjustment: manual mode and automatic mode. In manual mode, the adjuster sets the zero point when the sodium level falls below the lower measurement limit. When the sodium liquid level rises to the span point, input the output value corresponding to the span point from the keyboard, and press the SET SPAN button, and the span point will be adjusted by the automatic calibration device. In automatic mode, the sodium level is increased from below the lower measurement limit,
The point where the liquid level signal is output is set as the zero point, and the span point is detected by a level switch installed in advance on the detector, and the detection output of this level switch is used as an external input to raise the sodium level from below the measurement limit. By doing so, the zero point and span point are automatically set without any keyboard operations.

〔Example〕

Examples will be described below with reference to the drawings.

FIG. 1 is a diagram showing the overall configuration of an automatic calibration inductive sodium level meter according to the present invention, and FIG. 2 is a block configuration diagram of the automatic calibration apparatus shown in FIG. 1. In the figure,
20 is the coil part of the inductive sodium level meter, 2
1 is the sodium level, 22 is the signal transmission line,
23 is a signal converter, 24 is an A/D converter, 25 is an automatic calibration device, 26 is an A/D converter, 27 is a liquid level indicator, 28 is a tank, 30 is a microprocessor unit (MPU), 31 is RAM, 32 is
ROM, 33 and 34 are peripheral device interface adapters (PIA), 35 is a keyboard, 36 is an indicator, and 37 is a data bus.

First, a voltage signal corresponding to the sodium level 21 is continuously outputted from the level detection coil section 20, and this output signal is applied to the signal converter 23 through the transmission line 22 to generate a voltage of several mA to 20-several mA.
It is converted into a current level signal of approximately This current level signal is converted into a digital computer input signal Ie by the A/D converter 24 and input to the automatic calibration device 25.

In this automatic calibration device, the following calculations are performed and a computer output signal Ie' is output. Now, if the zero point (lower end of the coil) is set to a current level of 4.0mA, the following calculation formula will be applied.

Ie′=[(Ie−Z)−4]×Sk+4 …(1) Ie′: Computer output signal Ie: Computer input signal Z: Zero point calibration correction amount Sk: Span calibration coefficient In the above formula (1) The correction amount Z and the coefficient Sk are values determined in advance through a trial for calibration prior to actual sodium level measurement. The process of determining the correction amount Z and the coefficient Sk will be described below.

Now, if the sodium level is below the zero point (lower end of the coil), it is clear that the Ie value remains constant during that time, and the observed value is
Suppose that Ie _(zerp) (lower end of the coil). It is also clear that when the sodium level is above the span (top of the coil), the Ie value remains constant over that period, and the observed value is (Ie _(spao)
(upper end of the coil part).

The purpose of this trial is that Ie' is 4 at the zero point (lower end of the coil) and Ie' is 4 at the span point (upper end of the coil).
The purpose is to determine the correction amount Z and coefficient Sk to calibrate to a value of 20, so at the zero point (lower end of the coil) 4 = [(Ie _(zerp) - Z) - 4] × Sk + 4 span 20=[(Ie _(spao) −Z)−4]×Sk+4 must hold at the point (upper end of the coil).

Here, it is determined as Z=Ie _(zerp) −4 ...(2) Sk=16/Ie _(spao) −4 ...(3).

In this way, the correction amounts Z and Sk in the calibration equation (1) are determined in advance through trials.

Specifically, there are two types of initial calibration for determining Z and Sk: manual mode and automatic mode.

In manual mode, when the sodium level is below the lower measurement limit and you press the Set Zero button, the zero point is automatically adjusted to the lowest output of 4mA, and the span point is adjusted automatically when the sodium level rises to the specified span point. When you input the output value corresponding to the point from the keyboard and press the Set Span button, Z and Sk are automatically determined. In automatic mode, a separate level switch is attached to the level measuring coil in advance, and if the start button is pressed when the sodium level is below the lower limit and the liquid level is raised, a detection signal from the lower level switch is output. The zero point (lower level switch position)
Also, the point where the upper level switch is activated is set as the span point (upper level switch position), and the Z and Sk values are automatically determined by the microcomputer program without any input from the keyboard.

Then, what is the value of the computer output signal Ie′ set at the zero point (lower switch position)?
The indicator 36 displays how much the computer output signal is set to be at the span point (upper switch position). Calibration equations and calculation programs are stored in the ROM32, and the A/D converter 2 is loaded into the RAM31 through the PIA33.
The sodium level signal from 4 is calibrated using the calibration formula using MPU30, and the calibrated output is sent to PIA.
33 to the A/D converter 26 as well as the display 2
Level is displayed at 7.

In other words, for linear objects where the output is uniquely determined by the input, the input and output can be calibrated by determining the zero point and span point, that is, the slope of the input/output characteristic. Even if there is a deviation, it is possible to obtain an output commensurate with the original input by the calibration according to the present invention.

The above calibration procedure will be explained using the automatic calibration flowchart shown in FIG. 3. First, the detection signal from the level meter is A/D converted in a step, and then the zero point is set in a step. In the step, setting is performed by manual input using a keyboard or the like in the manual mode, or by level switch output when a liquid level signal is detected in the automatic mode. Next, the span is set in steps. Similar to the step, settings are made using the keyboard or level switch output in manual mode and automatic mode, respectively. The zero point and span point adjusted signals are D/A converted in steps, and 4-
Outputs as a 20mA calibrated signal.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, the zero point and span point adjustment of the sodium level meter can be performed by simply pressing a button on the keyboard, and the zero point can be adjusted when the sodium level is below 0%. When you press the button to set, the output signal will be automatically
Set to 4mA. In addition, if you enter a known span point as a percentage and press the button to set the span point when the sodium level rises to that span point, the span value set by the automatic calibration device will be set even if there is an error in the converter output. The output is calibrated.

That is, by programming to determine the zero point and span point, calibration can be performed without operator intervention simply by raising the liquid level from the lower limit.

Therefore, even if the detector signal deviates, it can be easily adjusted using the present invention, and this method can be applied to any linear type where the input and output signals are uniquely determined. be.

[Brief explanation of drawings]

Fig. 1 is a diagram showing the overall configuration of the automatic calibration induction type sodium level meter according to the present invention, Fig. 2 is a block diagram of the automatic calibration device of Fig. 1, Fig. 3 is a flowchart of automatic calibration, and Fig. 4 5 is a block diagram of a conventional inductive sodium level meter, and FIG. 5 is an explanatory graph showing the relationship between the sodium level and the current level signal. 20... Coil part of inductive sodium level meter, 21... Sodium level, 22... Signal transmission line, 23... Signal converter, 24... A/D
Converter, 25... Automatic calibration device, 26... D/A
converter, 27... liquid level indicator, 28... tank,
30...Microprocessor unit (MPU),
31...RAM, 32...ROM, 33, 34...
…Peripheral device interface adapter (PIA),
35...Keyboard, 36...Indicator, 3
7...Data bus.

Claims (1)

[Claims] 1 Level detection means, an A/D converter into which the detected level signal is input, calculates correction values for the zero point and span point, and calibrates the input signal from the A/D converter based on the correction values. Equipped with a calculation means and a display means for displaying the calibrated output,
The calculation means calibrates the minimum and maximum level signals input from the A/D converter to predetermined levels corresponding to the zero point and the span point by manual input or trigger input from a level switch, and calculates the correction value. An automatic calibration induction type sodium level meter characterized by the ability to calculate.