JPH07324959A - Electromagnetic flowmeter - Google Patents

Abstract

PURPOSE:To obtain an electromagnetic flowmeter in which the measurement accuracy can be exhibited depending on the measuring capacity of each detector. CONSTITUTION:A control circuit 17 reads out a corresponding exciting current from a ROM 19 based on the preset type information. It is employed as an upper limit in the selection of an appropriate exciting current from the relationship between the output current and the exciting current depending on the flow rate thus setting the exciting current for an exciting circuit 12. The exciting circuit 12 feeds the exciting current thus set to an exciting coil 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic flow meter, and more particularly to an electromagnetic flow meter for switching and controlling an exciting current supplied to an exciting coil of a detector.

[0002]

2. Description of the Related Art Generally, in an electromagnetic flow meter, in a detector installed in a tube for measuring a flow rate, detection is made by a pair of electrodes provided on the inner wall of the tube and at a position orthogonal to a magnetic flux generated by an exciting coil. It is known that the generated signal electromotive force is proportional to the flow velocity of the fluid flowing in the tube and is proportional to the density of the magnetic flux generated by the exciting coil. Assuming that the magnetic flux density is B, the tube diameter is d, and the fluid flow velocity is v, the signal electromotive force e generated in the electrode is e = kBvd (k = proportional constant), which is larger. It is understood that the magnetic flux density B should be increased in order to obtain the signal electromotive force e.

Here, since the magnetic flux density B of the magnetic flux generated by the exciting coil is proportional to the exciting current flowing through the exciting coil, increasing the exciting current increases the magnetic flux density B, and in response to this. The signal electromotive force e generated in the electrode is also increased, and the S / N ratio for various fluid noises is also improved.

From such a viewpoint, conventionally, in a two-wire type electromagnetic flowmeter which uses an output current indicating a process measurement value as an operating power source, switching control of an exciting current supplied to an exciting coil in accordance with the output current has been performed. , S / N ratios have been proposed (for example, Japanese Patent Application No.
64829).

FIG. 3 is an explanatory diagram showing switching control of the exciting current with respect to the output current. This is to switching control stepwise excitation current according to the output current from the electromagnetic flow meter, if the output current according to FIG. 3 of 4~12mA is the excitation current and I _L (4mA) , Output current is 12 ~ 20m
In the case of A, the exciting current is set to I _H (12 mA), and the exciting current supplied to the exciting coil is controlled in two steps based on the output current. Further, FIG. 4 is an explanatory diagram showing a detection signal indicating a signal electromotive force detected from the electrodes of the detector by these exciting currents. In FIG.
And 42 are detection signals indicating an exciting current of 4 mA and a signal electromotive force generated in the electrodes at that time, and 45 and 46 are 1
A detection signal indicating an exciting current of 2 mA and a signal electromotive force generated at the electrode at that time, t is a period of the exciting current waveform, t _a ,
t _b is the rise time of the detection signal waveform at both excitation current values, and t _s is the period during which the detection signal is sampled.

When these detection signals 42 and 46 are sampled and converted into digital values, the rising delay of the detection signal waveform that transiently changes due to the inductance component of the exciting coil of the detector and the exciting current is taken into consideration. The latter half period t _s (hatched portion in FIG. 4) is sampled, and by this sampling, E _a and E _b are detected as the voltage of the detection signal. After that, the detected voltages E _a and E _b are converted according to the ratio of the exciting currents. In this case, since the voltage E _b is the output voltage when the exciting current is 12 mA which is three times as large as the exciting current 4 mA when the voltage E _a is measured, the case where the exciting current is 4 mA is used as a reference. Is E _b / (12mA / 4m
It is converted by A), and the flow rate is calculated based on the converted voltage, that is, the signal electromotive force.

[0007] Here, the excitation coil of the detector, therefore the impedance by the diameter of the shape and the flow measuring tube are different, rise delay time t _a of the detection signal, t _b also becomes different accordingly, stable In consideration of obtaining the sampling period t _s and the commonality of the converters, the exciting current supplied from the converter to the exciting coil has the smallest current value among the various detectors connected to the converter. It was supposed to correspond to what I had.

[0008]

Therefore, in such a conventional electromagnetic flowmeter, the exciting current value is determined corresponding to the one having the smallest current value among the various detectors connected to the converter. Therefore, the obtained signal electromotive force becomes small, and a current value larger than this minimum current value can be used as the exciting current, and a detector that can obtain a larger signal electromotive force compared to fluid noise can detect a signal against fluid noise. There is a problem that the S / N ratio of the electromotive force is insufficiently improved, and the measurement accuracy corresponding to the measuring ability of each detector is not obtained. The present invention is intended to solve such a problem, and it is possible to further improve the S / N ratio of the signal electromotive force with respect to the fluid noise according to the exciting coil of the detector, and to adjust the measuring ability of each detector. It is an object of the present invention to provide an electromagnetic flow meter capable of obtaining measurement accuracy.

[0009]

In order to achieve such an object, an electromagnetic flow meter according to the present invention has a storage means for storing an exciting current value according to type information indicating the type of various detectors, and an exciting current value. Exciting current switching means for switching and outputting the current, and control means for reading the corresponding exciting current value from the storage means based on preset type information, and controlling the exciting current switching by the exciting current switching means based on this exciting current value. It is equipped with. Further, a storage unit that stores an excitation current value corresponding to type information indicating the type of each detector, and a corresponding excitation current value is read from the storage unit based on preset type information, and this excitation current value is set to an upper limit value. And a control means for switching and controlling the exciting current according to the output current. Furthermore, the type information indicates a difference in at least one of the wire diameter, the number of turns, the shape, and the bore of the measuring tube of the exciting coil used in the detector.

[0010]

Therefore, the control means reads out the corresponding exciting current value from the storing means on the basis of the preset type information, and the exciting current is controlled to be switched through the exciting current switching means on the basis of the exciting current value. . Also, by the control means,
A corresponding exciting current value is read from the storage means based on preset type information, and the exciting current is switched and controlled according to the output current with the exciting current value as an upper limit value.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a two-wire electromagnetic flowmeter which is an embodiment of the present invention. In the figure, 1 is a two-wire transmission line through which a process signal is transmitted, 2 is a DC power supply for supplying a DC current to the transmission line 1, and 3 is a resistor for detecting a process signal. The two-wire electromagnetic flow meter is a detector 5 that detects a signal electromotive force proportional to the flow rate from a pipe that measures the flow rate, and a process signal that processes the detected signal electromotive force and outputs a process signal indicating the flow rate to the transmission line 1. The detector 5 is composed of a pair of electrodes 8 provided inside the tube 7 and an exciting coil 6 for generating a magnetic field of a predetermined magnetic flux density with respect to the fluid.

In the converter 10, 11 is a constant voltage circuit that outputs a constant voltage based on the DC current supplied from the DC power supply 2 via the transmission line 1, and 12 is a constant voltage output from the constant voltage circuit 11. An exciting circuit that supplies a predetermined exciting current to the exciting coil 6 as a power source, 13 is a differential amplifier circuit that amplifies the signal electromotive force detected from the electrode 8, and 14 is a low-frequency component of the output from the differential amplifier circuit 13. Is a sample / hold circuit (hereinafter, referred to as S / H circuit) that samples the output of the high-pass filter 14 at a predetermined cycle. Further, 16 is an analog / analog for converting the output from the S / H circuit 15 into a digital quantity.
Digital conversion circuit (hereinafter referred to as A / D conversion circuit),
Reference numeral 17 denotes a control circuit that calculates the flow rate according to the output from the A / D conversion circuit 16 and controls each part of the converter 10,
Is an output I / that outputs a 2-wire process signal that is an analog current signal as an output current based on the calculated flow rate.
The F circuit, 19 stores an upper limit value of the exciting current according to the type information indicating the type of the exciting coil 6 and the diameter of the tube 7 R
OM.

Next, the operation of the present invention will be described with reference to FIG. Note that each detector is provided with type information indicating the difference in coil wire diameter, number of turns, shape, and tube diameter as information indicating the difference in excitation coil impedance, and control is performed prior to the flow rate measurement operation. It is assumed that type information indicating the detector 5 used for flow rate measurement is input from a key unit (not shown) connected to the circuit 17 and set in the control circuit 17.

First, the control circuit 17 reads a corresponding exciting current value from the ROM 19 based on preset type information, and sets this as an upper limit exciting current value, and the relationship between the output current and the exciting current according to the flow rate ( (See FIG. 3), an appropriate exciting current is selected, the exciting current is set to the exciting circuit 12, and the exciting circuit 12 supplies the exciting current set to the exciting coil 6 accordingly. As a result, the signal electromotive force generated at the electrode 8 is amplified by the differential amplifier circuit 13, and then the fluid noise generated in the low frequency region is removed by the high pass filter 14, and the S / H circuit is used as a detection signal (see FIG. 2). 1
Input to 5.

Here, the control circuit 17 adjusts the amplitude of the detection signal obtained in proportion to the magnitude of the exciting current to the amplitude of the detection signal obtained when the exciting current serving as the reference is supplied. The signal amplification factor is set in advance for the S / H circuit 15 according to the current ratio to the exciting current.
The detection signal input to the / H circuit 15 is sampled / held after its amplitude is amplified and normalized based on this amplification factor, and this is converted into a digital amount by the A / D conversion circuit 16 and controlled as a voltage value. It is input to the circuit 17. Next, the control circuit 17 calculates the flow velocity based on the voltage value from the A / D conversion circuit 16, and outputs the data indicating the flow rate per unit time based on the calculated flow velocity to the output I / F circuit 18 and outputs the output I / F circuit 18. The / F circuit 18 converts the process signal into an analog current signal and outputs the process signal to the transmission line 1.

FIG. 2 is an explanatory diagram showing a detection signal waveform when the exciting current is switched and controlled in two stages (I _H / I _L ) for detectors having different exciting coils. In FIG. (a) shows the case where the impedance of the exciting coil is relatively large, (b) shows the case where the impedance is relatively small, and 21 and 25 show the exciting current I
For _H, 22, 26 are detection signal waveform, the hatched portion when the exciting current is I _L is the sampling period.

When the type information preset in the control circuit 17 indicates the exciting coil 6 having a relatively high impedance, the rising delay of the detection signal becomes remarkable as shown in FIG. 2 (a), and the exciting current increases. Since it becomes difficult to obtain a sufficient sampling interval in accordance with the above, the upper limit value (I _H ) 21 of the exciting current read from the ROM 19 based on this type information shows a relatively low value. on the other hand,
If the type information preset in the control circuit 17 indicates the exciting coil 6 having a relatively low impedance,
As in (b), the rising delay of the detection signal becomes slow, and it is possible to obtain a sufficient sampling interval even if the exciting current is increased. Therefore, the ROM is based on this type information.
The upper limit value (I _H ) 25 of the exciting current read from 19 shows a relatively high value.

Therefore, an appropriate exciting current value is read from the ROM 19 on the basis of the type information indicating the type of the exciting coil 6 and the diameter of the tube 7 used in the detector 5, and this value is used as the upper limit value for the output current. According to the type of the exciting coil 6 used in the detector 5 and the diameter of the tube 7, the S / N ratio of the signal electromotive force to the fluid noise is improved.

In the above description, the two-wire type electromagnetic flowmeter in which the output current is used as the operating power source and the exciting current output to the exciting coil of the detector is also limited by the output current has been described as an example. This may be, for example, an electromagnetic flow meter in which the operating power supply for the exciting current is supplied separately from the output current, depending on the type of exciting coil 6 used in the detector 5 and the diameter of the tube 7, The S / N ratio of signal electromotive force to noise is improved, and even detectors of different types can be dealt with by changing the setting of the type information.

[0020]

As described above, the present invention is provided with the storage means for storing the exciting current value according to the type information indicating the type of various detectors, and the exciting current switching means for switching and outputting the exciting current. Then, the control means reads out the corresponding excitation current value from the storage means based on the preset type information, and the excitation current switching means controls the excitation current switching based on this excitation current value. Therefore,
In the electromagnetic flowmeter, the S / N ratio of the signal electromotive force to the fluid noise can be further improved according to the exciting coil of the detector, and the measurement accuracy according to the measuring ability of each detector can be obtained. Even if different detectors are used, it is possible to deal with them by changing the setting of the type information.

[Brief description of drawings]

FIG. 1 is a block diagram of a two-wire electromagnetic flow meter according to an embodiment of the present invention.

FIG. 2 is a signal waveform diagram showing detection signals by different detectors.

FIG. 3 is an explanatory diagram showing switching control of an exciting current with respect to an output current.

FIG. 4 is a signal waveform diagram showing a detection signal based on excitation current switching control.

[Explanation of symbols]

1 ... Transmission path, 2 ... DC power supply, 3 ... Resistance, 5 ... Detector, 6
... excitation coil, 7 ... tube, 8 ... electrode, 10 ... transducer, 11
... constant voltage circuit, 12 ... excitation circuit, 13 ... differential amplifier circuit,
14 ... High-pass filter, 15 ... Sample / hold circuit (S / H circuit), 16 ... Analog / digital conversion circuit (A / D conversion circuit), 17 ... Control circuit, 18 ... Output interface circuit (I / F circuit), 19 ... ROM.

Claims (3)

[Claims] 1. A signal processing means for outputting a detection signal corresponding to a flow rate from a signal electromotive force obtained by a detector based on an exciting current, and outputting an output current indicating a flow rate calculated from the detection signal. In the electromagnetic flowmeter, storage means for storing an exciting current value according to type information indicating the type of various detectors, exciting current switching means for switching and outputting the exciting current, and the above-mentioned type information preset based on the type information. An electromagnetic flowmeter, comprising: a corresponding excitation current value read from a storage means; and a control means for switching and controlling the excitation current by the excitation current switching means based on the excitation current value. 2. An exciting current switching means for switching and outputting an exciting current, and a signal processing means for outputting a detection signal according to a flow rate from a signal electromotive force obtained by a detector based on the exciting current, A two-wire type electromagnetic flow meter that outputs an output current indicating a flow rate obtained from the detection signal and controls switching of an exciting current according to the output current, in accordance with classification information indicating classifications of various detectors. Storage means for storing a current value, and a control for reading a corresponding exciting current value from the storing means on the basis of the preset type information, and controlling the switching of the exciting current according to the output current with the exciting current value as an upper limit value. A two-wire type electromagnetic flowmeter comprising: 3. The electromagnetic flowmeter according to claim 1, wherein the type information is at least one of a wire diameter, a winding number, a shape, and a diameter of a measuring tube of an exciting coil used in the detector. An electromagnetic flowmeter characterized by showing two differences.