JP4185369B2 - 2-wire electromagnetic flow meter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a two-wire electromagnetic flow meter, and more particularly to a two-wire electromagnetic flow meter that transmits a measured flow value via a pair of signal lines to which power is supplied.
[0002]
[Prior art]
It is known that when a fluid flows in a magnetic field, a signal electromotive force corresponding to the flow velocity of the fluid is generated, and an electromagnetic flowmeter applies this principle. In general, as shown in FIG. 5, the electromagnetic flow meter applies a magnetic field to a fluid flowing through a pipe line 122 by a coil 121 and detects an electromotive force generated in the fluid, and generates a magnetic field to the detector 102. Is supplied from the excitation circuit 111, the flow rate is calculated by the signal processing circuit 112 based on the electromotive force obtained from the detector 102, and this is transferred to the processing device (control controller) as a measured flow rate value. And the device 101.
Many of the electromagnetic flowmeters are installed at a location distant from the processing device. Therefore, both are connected by a signal line, and power is supplied from the processing device to the electromagnetic flowmeter via the signal line. The measured flow rate value is transmitted from to the processing device.
[0003]
Conventionally, a pair (two wires) of signal lines are used as signal lines connecting the electromagnetic flow meter and the processing device, and the DC flow is supplied to the electromagnetic flow meter by the direct current flowing through the signal lines. Two-wire electromagnetic flow meters that transmit measured flow values to processing devices based on the values are widely used.
In such a two-wire electromagnetic flow meter, an analog transmission method for transmitting a measured flow value based on an analog DC current value of 4 to 20 mA is widespread, and according to this transmission method, an extremely small current of at least 4 mA is used. It is necessary to operate an excitation circuit that supplies an excitation current to the detector, and a signal processing circuit that calculates a flow rate based on a signal electromotive force from the detector and outputs it as a measured flow rate value.
[0004]
Conventionally, as such a two-wire electromagnetic flow meter, as shown in FIG. 5, the operating current is effectively utilized by connecting the excitation circuit 111 and the signal processing circuit 112 in series to the signal lines LA and LB. What has been made possible has been proposed (see, for example, Patent Document 1). According to this, a current of at least 4 mA can be supplied to both the excitation circuit 111 and the signal processing circuit 112, and the deterioration of the S / N ratio due to the reduction of the excitation current and the decrease in responsiveness due to the intermittent excitation can be avoided.
[0005]
The applicant has not yet found prior art documents related to the present invention by the time of filing other than the prior art documents specified by the prior art document information described in this specification.
[Patent Document 1]
JP-A-4-370715 [0006]
[Problems to be solved by the invention]
In recent years, as a transmission method between various field devices including an electromagnetic flow meter and a processing device, a field bus method, which is a communication standard common to industrial instrument manufacturers, is being introduced. However, the conventional two-wire electromagnetic flowmeter in which the excitation circuit and the signal processing circuit as described above are connected in series cannot support the fieldbus method and cannot obtain a good S / N ratio and responsiveness. There was a problem.
As one of the fieldbus systems, a DC voltage of 9 to 32V is supplied from the processing device to the electromagnetic flow meter via a pair of signal lines, and the measured flow value is transferred from the electromagnetic flow meter to the processing device by digital data transmission. There is a transmission method. In such a fieldbus system, the current consumption in the electromagnetic flowmeter is not so limited, but the voltage is limited to a minimum of 9 V. Therefore, when the excitation circuit and the signal processing circuit are connected in series as in the conventional case, The power supply voltage that can be used in both circuits is divided into two, and the excitation circuit and the signal processing circuit must be operated with a relatively low power supply voltage. Decrease in response due to excitation becomes a problem.
[0007]
On the other hand, as shown in FIG. 6, there is an electromagnetic flow meter that supports the fieldbus system by connecting the excitation circuit 111 and the signal processing circuit 112 in parallel to the signal lines LA and LB. According to this configuration, since at least 9 V is supplied to both the excitation circuit 111 and the signal processing circuit 112, a good S / N ratio and responsiveness can be obtained. Here, in the field where the electromagnetic flowmeter is actually installed, both the conventional analog transmission type processing device and the fieldbus type processing device are used together. It is necessary to install in. However, when the processing apparatus is changed in accordance with the specification change, it is necessary to change the electromagnetic flowmeter accordingly, and the burden of work and cost is extremely large.
The present invention is intended to solve such problems, and an object thereof is to provide a two-wire electromagnetic flow meter that can be used in both an analog transmission system and a fieldbus system.
[0008]
[Means for Solving the Problems]
In order to achieve such an object, a two-wire electromagnetic flow meter according to the present invention detects a coil that applies a magnetic field to a fluid flowing through a pipeline, and an electromotive force generated in the fluid by the magnetic field applied from the coil. A flow rate of fluid based on a detector having a pair of electrodes, an excitation circuit for supplying an excitation current for generating a magnetic field to a coil of the detector, and an electromotive force detected from the pair of electrodes of the detector And a converter having a signal processing circuit, which operates based on a power source supplied from the processing device via a pair of signal lines, measures the flow rate of the fluid flowing through the pipeline, and obtains the obtained flow rate the in two-wire electromagnetic flowmeter for transmitting to the processing unit via the signal line as the measured flow rate value, switching to one of the connection state of the series connection or parallel state with respect to the excitation-circuit and the signal line a signal processing circuit switching hand A step.
[0009]
At this time, the switching means transmits the flow rate measurement value by the amount of current flowing through the signal line, and when using the two-wire electromagnetic flow meter in the analog transmission system using the current value as an operating power source. The excitation circuit and the signal processing circuit are switched to the connection state in series connection with the signal line.
Further, the switching means transmits the measured flow rate value by performing digital data transmission through the signal line, and also uses the two-wire electromagnetic system in a fieldbus system using the power supply voltage supplied through the signal line as the operation power supply. When the flow meter is used, the excitation circuit and the signal processing circuit are switched to a connection state in which the signal line is connected in parallel.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a two-wire electromagnetic flow meter according to an embodiment of the present invention.
The electromagnetic flow meter is obtained from the detector 2 while applying a magnetic field to the fluid and detecting an electromotive force generated in the fluid, and supplying an excitation current for generating the magnetic field to the detector 2. And a converter that calculates a flow rate based on the electromotive force and transmits the flow rate as a measured flow rate value to a higher-level processing device (control controller: not shown).
[0011]
The detector 2 is provided with a coil 21 that applies a magnetic field to the fluid flowing in the conduit 22 and a counter magnetic field applied from the coil 21 to the inner wall of the conduit 22 so as to be in contact with the fluid. Thus, a pair of electrodes 22A and 22B for detecting an electromotive force generated in a size corresponding to the flow velocity of the fluid is provided.
[0012]
The converter 1 calculates the flow rate based on the electromotive force detected from the excitation circuit 11 that supplies an excitation current for generating a magnetic field to the coil 21 of the detector 2 and the electrodes 22A and 22B of the detector 2. When using the analog transmission method, the signal processing circuit 12 outputs an analog direct current corresponding to the flow rate to the signal lines LA and LB as the measured flow value, and when using the field bus method, the signal line LA and LB is used as a digital signal. The field flow circuit 13 that transmits the measured flow rate value calculated by the signal processing circuit 12 by digital transmission using digital data, and the excitation circuit 11, the signal processing circuit 12, and the like when the analog transmission method / field bus method is used. A switch 14 (14A to 14E: switching means) for switching and connecting the fieldbus circuit 13 is provided. That.
[0013]
As a specific example, as shown in FIG. 1, one end N1 of the excitation circuit 11 is connected to the signal line LA, and one end N4 of the signal processing circuit 12 is connected to the signal line LB. The switch 14A is provided between the other end N2 of the excitation circuit 11 and the other end N3 of the signal processing circuit 12. Further, the switch 14B is provided between the signal line LA and the other end N3 of the signal processing circuit 12, and the switch 14C is provided between the signal line LB and the other end N2 of the excitation circuit 11.
The switch 14D is provided between the signal line LA and one end N5 of the fieldbus circuit 13, and the switch 14E is provided between the signal line LB and the other end N6 of the fieldbus circuit 13.
[0014]
The excitation circuit 11 is connected in series with the coil 21, and a constant current circuit 11A that supplies the current supplied from the signal line LA, that is, one end N1, as an excitation current to the coil 21 with a constant current, and one end N1 and the other end N2. , That is, a constant voltage circuit 11B that is connected in parallel with the series connection of the coil 21 and the constant current circuit 11A and generates a constant voltage between the end points N1 and N2.
[0015]
The signal processing circuit 12 is provided between the flow rate calculation circuit 12A that calculates the measured flow rate based on the electromotive force detected from the electrodes 22A and 22B of the detector 2 and the end points N3 to N4, and is used in the analog transmission method. An analog output circuit 12B is provided for outputting an analog DC current corresponding to the measured flow rate to the signal lines LA and LB as a measured flow value.
[0016]
The field bus circuit 13 is provided between the signal lines LA and LB (end points N5 to N6). When used in the field bus method, the field bus circuit 13 performs data transmission with a host processor in the field bus method, and measures flow values and various control data. And a control circuit 13B for controlling the excitation circuit 11 and the signal processing circuit 12 as necessary based on the control data from the host processing device received by the transmission circuit 13A. .
[0017]
Next, the operation of the present invention will be described with reference to FIGS. FIG. 2 is an explanatory diagram showing a switching state of the switches 14A to 14E of FIG.
When the electromagnetic flowmeter is used in the analog transmission system, as shown in FIG. 2, the switch 14A is turned on (short circuit state), and the switches 14B to 14E are all turned off (open state).
As a result, the other end N2 of the excitation circuit 11 and the other end N3 of the signal processing circuit 12 are connected via the switch 14A. As a result, the excitation circuit 11 and the signal processing circuit 12 are connected in series between the signal lines LA and LB. Will be.
[0018]
Therefore, as in the conventional analog transmission system, a current of at least 4 mA can be supplied to both the excitation circuit 11 and the signal processing circuit 12, and the S / N ratio is deteriorated due to the reduction of the excitation current and the response is lowered due to the intermittent excitation. Can be avoided.
In this case, since the switches 14D and 14E are turned off, the field bus circuit 13 is disconnected from the signal lines LA and LB and does not operate.
[0019]
The flow rate calculation circuit 12 </ b> A of the signal processing circuit 12 outputs an excitation signal having a predetermined excitation frequency to the excitation circuit 11. In the constant current circuit 11A of the excitation circuit 11, an excitation current having a predetermined excitation frequency is supplied to the coil 21 of the detector 2 as a constant current based on the excitation signal.
The flow rate calculation circuit 12A calculates the flow rate of the fluid flowing in the conduit 22 based on the electromotive force generated in the electrodes 22A and 22B of the detector 2, and outputs the calculated flow rate value to the analog output circuit 12B. The analog output circuit 12B outputs an analog DC current corresponding to the measured flow rate value to the end points N3 and N4 by an analog transmission method. Accordingly, the measured flow rate value is transmitted to the upper processing apparatus via the signal lines LA and LB by the analog transmission method.
[0020]
On the other hand, when the electromagnetic flowmeter is used in the fieldbus method, contrary to the analog transmission method, the switch 14A is turned off (open state), and the switches 14B to 14E are all turned on (short circuit state).
As a result, the other end N2 of the excitation circuit 11 is connected to the signal line LB via the switch 14C, and the other end N3 of the signal processing circuit 12 is connected to the signal line LA via the switch 14B. As a result, the signal line The excitation circuit 11 and the signal processing circuit 12 are connected in parallel between LA and LB.
The signal line LA and one end N5 of the field bus circuit 13 are connected by a switch 14D, and the signal line LB and the other end N6 of the field bus circuit 13 are connected by a switch 14E.
[0021]
In this case, the flow rate calculation circuit 12A of the signal processing circuit 12 outputs an excitation signal having a predetermined excitation frequency to the excitation circuit 11. In the constant current circuit 11A of the excitation circuit 11, an excitation current having a predetermined excitation frequency is supplied to the coil 21 of the detector 2 as a constant current based on the excitation signal.
The flow rate calculation circuit 12A calculates the flow rate of the fluid flowing in the pipe line 22 based on the electromotive force generated in the electrodes 22A and 22B of the detector 2, and outputs the calculated flow rate value to the fieldbus circuit 13.
[0022]
The transmission circuit 13A of the fieldbus circuit 13 outputs digital data indicating the counted flow rate value from the flow rate calculation circuit 12A between the terminals N5 and N6 by the fieldbus method. As a result, the measured flow rate value is transmitted to the host processing apparatus via the signal lines LA and LB by the fieldbus method.
Therefore, similarly to the conventional field bus system, a voltage of at least 9 V can be supplied to both the excitation circuit 11 and the signal processing circuit 12, and the S / N ratio is deteriorated by reducing the excitation current and the responsiveness is lowered by intermittent excitation. Can be avoided.
[0023]
In this embodiment, in this way, an excitation circuit that applies the next time to the fluid in the pipeline, and a signal that calculates the flow rate of the fluid from the electromotive force generated in the fluid in the pipeline by the applied magnetic field Since the processing circuit is switched to a connection state of either a serial state or a parallel state with respect to the signal line using a switch, a sufficient current or current can be obtained in either the analog transmission method or the field bus method. Voltage can be supplied to both the excitation circuit and the signal processing circuit, and a stable measurement operation can be realized. In particular, in the case of the analog transmission method, since the excitation circuit and the signal processing circuit are connected in series, a sufficient current of at least 4 mA can be supplied to both circuits. In the case of the field bus system, since the excitation circuit and the signal processing circuit are connected in parallel, a sufficient voltage of at least 9 V can be supplied to both circuits.
[0024]
Therefore, both the analog transmission method and the fieldbus method can be supported with the same electromagnetic flow meter without changing the equipment. For example, the transmission method from the analog transmission method to the fieldbus method according to the transmission method of the host processor. Even when switching, it is possible to respond immediately, and the work and cost burden required for switching the transmission method can be greatly reduced.
In FIG. 1, the case where the switches 14D and 14E are provided between the field bus circuit 13 and the signal lines LA and LB to cut them both is described as an example. However, only one of the switches 14D and 14E is provided. It may be a single piece in which the other is short-circuited.
[0025]
Next, a case where the fieldbus circuit is unitized will be described with reference to FIG. FIG. 3 is an explanatory diagram showing a mounting example when the fieldbus circuit is unitized.
When the electromagnetic flow meter is used in the analog transmission system, the field bus circuit 13 is not necessary, and is required only when the field flow system is used. Therefore, the field bus circuit 13 is mounted on a separate field bus unit 1B, for example, a board unit separate from the main unit 1A on which the excitation circuit 11 and the signal processing circuit 12 are mounted, and the connector 1C is connected to the main unit 1A. You may make it mount via.
[0026]
At this time, as shown in FIG. 3, a jumper J (mounting notification means) is provided on the fieldbus unit 1B side, the presence / absence of the fieldbus unit 1B is automatically detected on the main unit 1A side, and each switch is analog-transmitted. Switching from the system to the fieldbus system may be controlled.
Specifically, the jumper J on the field bus unit 1B side is connected to the two terminals of the connector 1C. On the other hand, on the main unit 1A side, one of the terminals is connected to the ground potential, and the other is pulled up to the power supply voltage Vcc and connected to the input port IN of the CPU of the signal processing circuit 12. Thus, when the fieldbus unit 1B is not mounted, the input port IN is at the power supply voltage Vcc. When the fieldbus unit 1B is mounted, the input port IN is grounded via the jumper J. Become.
[0027]
Therefore, in the CPU, if the input port IN is at a high level, that is, the potential of the power supply voltage Vcc, the CPU determines that the fieldbus unit 1B is not mounted and operates in an analog transmission system, so that a control signal from the output port OUT is used. The switch 14A is turned on, and the other switches 14B to 14E are controlled to be turned off. Thereby, as described above, the excitation circuit 11 and the signal processing circuit 12 are connected in series to the signal lines LA and LB.
On the other hand, if the input port IN is at the LOW level, that is, the ground potential, it is determined that the fieldbus unit 1B is mounted, and the switch 14A is turned off by the control signal from the output port OUT in order to operate in the fieldbus system. Then, the other switches 14B to 14E are controlled to be turned on. Thereby, as mentioned above, the excitation circuit 11 and the signal processing circuit 12 are connected in parallel to the signal lines LA and LB.
[0028]
In this way, the fieldbus unit 1B is provided with a mounting notification means for outputting a predetermined mounting signal to a predetermined terminal of the connector 1C, and the main unit 1A side switches according to the presence or absence of the mounting signal from the terminal of the connector 1C. 14 is controlled, the switch 14 is automatically switched according to whether or not the fieldbus unit 1B is mounted, so that a connection configuration corresponding to the analog transmission method / fieldbus method is obtained. As a result, the switching setting operation of the switch 14 required when the fieldbus unit 1B is mounted / removed becomes unnecessary, and problems due to unset or incorrect settings can be completely avoided.
The mounting notification means is not limited to the jumper J that connects the two terminals of the connector 1C as described above, and outputs a predetermined mounting signal, for example, a predetermined potential or current to the main unit 1A side. Any one can be used. Further, the switches 14D and 14E may be substituted by the terminals of the connector 1C.
[0029]
FIG. 4 shows a configuration example of the switch 14.
As shown in FIG. 3, when each switch 14 is controlled by a circuit, the analog switch in FIG. 4 (a), the transistor in FIG. 4 (b), or the field effect transistor (FET) in FIG. 4 (c). ) Etc. can be used. On the other hand, when the stitches 14 are manually switched, a mechanical switch such as a dip switch shown in FIG. In particular, a mechanical switch is useful when an analog transmission method is adopted in a state where a fieldbus circuit is mounted.
[0030]
【The invention's effect】
As described above, the present invention is an excitation circuit that applies a magnetic field to a fluid in a pipeline, and a signal that calculates the flow rate of the fluid from an electromotive force generated in the fluid in the pipeline by the applied magnetic field. Since the processing circuit is switched to a connection state of either a serial connection or a parallel state with respect to the signal line using a switch, sufficient current or current can be obtained in either the analog transmission method or the field bus method. Voltage can be supplied to both the excitation circuit and the signal processing circuit, and a stable measurement operation can be realized.
Therefore, both the analog transmission method and the fieldbus method can be supported with the same electromagnetic flowmeter without replacing the equipment, and the transmission method from the analog transmission method to the fieldbus method is adapted to the transmission method of the host processor. Even when switching, it can be handled immediately, and the work and cost burden required for switching the transmission method can be greatly reduced.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a two-wire electromagnetic flow meter according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a switching state of switches.
FIG. 3 is an explanatory diagram showing a mounting example when a fieldbus circuit is unitized.
FIG. 4 is an explanatory diagram illustrating a configuration example of a switch.
FIG. 5 is a block diagram showing a conventional two-wire electromagnetic flow meter (analog transmission method).
FIG. 6 is a block diagram showing a conventional two-wire electromagnetic flow meter (field bus method).
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Converter, 1A ... Main unit, 1B ... Fieldbus unit, 1C ... Connector, 11 ... Excitation circuit, 11A ... Constant current circuit, 11B ... Constant voltage circuit, 12 ... Signal processing circuit, 12A ... Flow rate calculation circuit, 12B ... analog output circuit, 13 ... field bus circuit, 13A ... transmission circuit, 13B ... control circuit, 14A-14E ... switch, 2 ... detector, 21 ... coil, 22 ... pipe, 22A, 22B ... electrode, LA, LB ... Signal lines, N1 to N6 ... end points.

Claims (3)

A detector having a coil for applying a magnetic field to a fluid flowing through a pipe, a pair of electrodes for detecting an electromotive force generated in the fluid by a magnetic field applied from the coil, and for generating a magnetic field in the coil of the detector And a converter having an excitation circuit that supplies the excitation current and a signal processing circuit that calculates a flow rate of the fluid based on an electromotive force detected from a pair of electrodes of the detector, and a pair of signal lines The flow rate of the fluid flowing through the pipe line is measured based on the power source supplied from the processing device via the, and the obtained flow rate is transmitted to the processing device via the signal line as a measured flow rate value 2 In wire type electromagnetic flow meter,
Before SL excitation circuit and the signal processing circuit 2-wire electromagnetic flowmeter, characterized in that it comprises switching means for switching to either the connected state of the series connection or parallel state with respect to the signal line. The two-wire electromagnetic flow meter according to claim 1,
The switching means transmits the flow rate measurement value with the amount of current flowing through the signal line, and when using the two-wire electromagnetic flow meter in an analog transmission method using the current value as an operating power source, A two-wire electromagnetic flowmeter, wherein the excitation circuit and the signal processing circuit are switched to a connection state in series connection with the signal line. The two-wire electromagnetic flow meter according to claim 1,
The switching means transmits the measured flow rate value by performing digital data transmission through the signal line, and uses the power supply voltage supplied through the signal line as the operation power supply in the two-wire system. When using an electromagnetic flow meter, the two-wire electromagnetic flow meter is characterized in that the excitation circuit and the signal processing circuit are switched to a connection state in parallel connection with the signal line.

Images