JPH0455007B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a receiving device that receives a signal indicated by a current value and controls a device to be controlled such as a valve in an industrial process or the like.

[Conventional technology]

In industrial processes, etc., when remotely controlling valves, etc., a receiving device generally called a positioner is provided, and for example, 4 to 4
A signal is transmitted using a current value that varies over a range of 20 mA, and a receiving device receives the signal and performs control according to the current value.

However, in the past, a two-wire transmission line was required to transmit the current value indicating the signal, and a separate two-wire power supply line was required to supply the power required by the receiving device. Four lines are indispensable, resulting in an increase in the amount of wire required for the line and the number of man-hours for laying the line, resulting in high equipment costs.

As a countermeasure against this, a basic configuration has been proposed in the "receiving device" (Japanese Patent Application No. 113009/1982) filed separately by the present applicant. A current indicating a signal value varying in a range such as 0 to 16 mA is extracted from a current that varies as 0 to 16 mA, and a bias component such as 4 mA is extracted to be used as a local power supply.

[Problem that the invention seeks to solve]

However, in the same application, first and second control circuits using differential amplifiers, etc., and means for controlling the reference voltage applied to these are required.
The structure becomes complicated and expensive, and it is difficult to reduce the storage space, causing problems such as hindering the miniaturization of devices that is increasingly required in recent years.

The present invention aims to fundamentally solve these drawbacks of the conventional technology, and provides a highly effective receiving device that uses only a control circuit that is substantially equivalent to the control means described above. .

[Means for solving problems]

Therefore, the object of the present invention is achieved by the following configuration.

That is, a first variable impedance element and a reception impedance element are inserted in series in a two-wire transmission line, and the impedance of the variable impedance element is controlled in a direction that keeps the line voltage of the transmission line constant. A series circuit consisting of a series impedance element and a second variable impedance element is connected in parallel with these, and the line voltage and the voltage at the connection point between the series impedance element and the second variable impedance element are detected. The current flowing through the impedance element is controlled to maintain a constant value according to the bias component, and these controls are performed by a single control circuit, and a control circuit serving as a load circuit is connected in parallel to the second variable impedance element. It is assumed that it will be connected.

[Effect]

Therefore, only the current indicating the signal value passes through the receiving impedance element, and reception can be performed using this, and the power supply current can be freely passed through the load circuit within the range of the bias component. Become.

〔Example〕

Hereinafter, details of the present invention will be explained with reference to figures showing examples.

FIG. 1 is a block diagram showing the whole, and the two-wire transmission line L connected via line terminals t ₁ and t ₂ is
It consists of lines L ₁ and L ₂ , into which a first variable impedance element (hereinafter referred to as element) Z ₁ is inserted, and a resistor R _S is connected in series as a receiving impedance element. On the other hand,
A series circuit including a resistor R _C as a series impedance element and a second element Z ₂ is connected in parallel with these.

In addition, a control circuit CNT is connected in parallel with the element Z ₂ as a load circuit, and the circuit CNT has a line voltage V _L and a resistor R _C with respect to the line terminal t ₂ side.
The load side voltage V _C , the terminal voltage V _S of the resistor R _S , and the actual measured value from the drive device DR, which will be described later, are given, and the control circuit CNT controls the first voltage according to the voltages V _L and V _C .
and second control voltages Vd ₁ and Vd ₂ to control the impedance of each element Z ₁ and Z ₂ to keep the voltage V _L at a constant value of, for example, 10 V and the voltage V _C at a constant value of, for example, 7 V, and also control the voltage V Control calculations are performed according to the received value based on _S and the actual measured value from the drive device DR, and a control signal is sent to an electro-pneumatic converter E/P, which will be described later.

Here, the current I _C flowing through the resistor R _C is expressed by the following equation.

I _C =V _L −V _C /R _C ...(1) Therefore, the impedance of element Z ₁ is controlled in the direction of keeping V _L constant, and the impedance of element Z ₂ is controlled in the direction of keeping V _C constant. By controlling the impedance and adjusting the current I ₁ passing through it, the current I _C becomes constant regardless of the load current I ₂ and the following equation holds true.

I _L = I _S + I ₁ + I ₂ = I _S + I _C ∴I _S = I _L − I _C ...(2) In other words, by setting I _C equal to the bias component, the line current I _L can be set to 4 to 20 mA, for example. in the case of,
Since the current I _S flowing through the resistor R _S has only a signal component of 0 to 16 mA, the received value can be detected using the voltage V _S .

Further, when I _L is 4 to 20 mA, a maximum power current of 4 mA can be freely supplied.

Note that on the central control device side (not shown in the figure), the line current I _L is sent out by a constant current circuit, so even if the input impedance on the receiving end side changes, the current value is not affected.

In other words, the current value of the signal (4
~20mA) is performed by a constant current circuit. This constant current circuit operates so that a set constant current value always flows, and when the above signal current is set to any value between 4 and 20 mA, that signal current value is currently flowing. If the current value is greater than the current value, the voltage must rise in order to increase the current, so the terminal voltage is increased. This terminal voltage is the line voltage of the transmission line.
V _L , the receiver detects this rise in line voltage V _L , and variable impedance element Z ₁ acts to increase current I _S to keep line voltage V _L constant. Control as much as possible. At this time,
The line current I _L increases by the amount that the receiver current I _S increases.

In the constant current circuit on the control device side, the voltage increase operation continues until the line current I _L reaches the set signal current value, and the voltage increase stops when the output current reaches the set signal current value. . At this time, the current value output from the constant current circuit is the set signal current value, and the current value of the receiving device I _S increases by the current value increased by the setting of the constant current circuit. .

Furthermore, if changes in the voltage V _C affect the operation of each load circuit, a voltage stabilizing circuit may be inserted into the portion through which the current I ₂ flows.

In addition, elements exhibiting controllable variable impedance, such as transistors and photocouplers, may be used as the elements Z ₁ and Z ₂ .

Figure 2 is a block diagram of the control circuit CNT.
Mainly processor CPU such as microprocessor, fixed memory ROM, variable memory RAM, analog/digital converter (hereinafter referred to as ADC) A/
D. Digital to analog converter (hereinafter referred to as DAC)
D/A ₁ to D/A ₃ are arranged around the periphery and connected by a bus, and the processor CPU executes instructions in the fixed memory ROM and controls the specified data while accessing the variable memory RAM. It has become something that performs actions.

In addition, the voltage V _C shown in Figure 1 is
It is stabilized in REG and is supplied to each part as local power E.

On the other hand, on the input side of the ADC/A/D, there is a multiplexer MPX controlled by the processor CPU, which sequentially outputs the actual measured values from each voltage V _L , V _C , V _S and the drive device DR. They are selected repeatedly and converted into digital signals by ADC/A/D, and then sent to the processor CPU.
In order for the processor CPU to give control data to the DAC・D/A ₁ to D/A ₂ according to these, the control voltages Vd ₁ , Vd ₂ and electro-pneumatic signals converted to analog signals are A control signal for converter E/P is sent out.

FIG. 3 is a flowchart of the control situation by the processor CPU, in which the voltage "V _L capture" 101 is performed via the multiplexer MPX and the ADC/A/D, and then the voltage is stored in the fixed memory ROM in advance. By comparison with the first reference voltage Vr ₁ , it is determined whether "V _L = Vr ₁ ?" 102, and if this is N (NO), the control voltage "Vd ₁ is corrected" 103 according to the value of V _L , This is repeated until step 102 becomes Y (YES).

Next, as in step 101, input the voltage “V _C ”.
After performing step 111, as in step 102, it is compared with the second reference voltage Vr ₂ to determine "V _C = Vr ₂ ?" 112. If this is N, as in step 103,
Control voltage "Vd ₂ correction" 113 is performed until this becomes Y.

After making V _L and V _C constant as described above, in the same manner as in step 101, the voltage "V _S acquisition" 121 and the "actual measurement value acquisition" 122 from the drive device DR are carried out.
In addition to performing “control calculations”123 according to these,
"Sending control signal" 124 via the DAC/D/A ₃ is performed, and steps 101 and subsequent steps are repeated.

FIG. 4 is a block diagram showing the entire configuration of the receiving device side. The received output from the receiving device FE shown in FIG. 1 is given to the electro-pneumatic converter E/P, where the pressure P is The pressure corresponds to the current opening, which is sent to the drive device DR such as an air cylinder, which drives the valve V to control the opening.A potentiometer connected to the drive shaft also controls the current opening to the actual measured value. It is detected as such and provided to the receiving device RE.

FIGS. 5 and 6 show a first embodiment showing another embodiment.
This is a block diagram similar to the one shown in the figure. In Figure 5, the resistor R _C is inserted to the line terminal t ₂ side, and in Figure 6, the resistor R _S is further inserted to the line terminal t ₁ side. The rest is the same as in Figure 1.

Note that in the control circuit CNT, it is necessary to select the detection reference voltage for each voltage depending on the insertion position of the resistors R _S and R _C , and the configuration shown in Figure 2 may be slightly changed accordingly. .

Therefore, the purpose can be achieved with only a single control circuit CNT, and since the circuit CNT is entirely composed of digital circuits, the control situation becomes stable and miniaturization becomes easy.

However, instead of the resistor R _S , an impedance element such as a diode or a circuit that directly detects the current value may be used, and as the resistor R _C ,
A constant voltage diode or the like may also be used.

Note that the bias component of the line current may be determined according to the required power supply current of the load circuit, and a motor or the like may also be used as the load circuit.

In addition, in FIG. 4, the device may be driven by a motor or the like, and in addition to the valve V, a damper, a pump, etc. may also be controlled equipment, and the present invention can be modified in various ways.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, the control circuit becomes single and can be easily miniaturized, so that remarkable effects can be obtained in terms of control and power supply to various controlled devices.

In addition, the communication device side can receive the necessary power only through the two-wire transmission line and receive signals based on current values, which allows accurate signal reception from the control device side. While retaining the conventional function of power supply, there is also the benefit of eliminating the need for a separate power supply path and significantly reducing line equipment costs.

[Brief explanation of the drawing]

The figures show an embodiment of the present invention, in which Figure 1 is an overall block diagram, Figure 2 is a block diagram of a control circuit, and Figure 3 is a block diagram of a control circuit.
FIG. 4 is a block diagram showing the entire configuration of the receiver side, and FIGS. 5 and 6 are block diagrams similar to FIG. 1 showing other embodiments. L...Two-wire transmission line, _Z1 , _Z2 ...Element (variable impedance element), R _S , R _C ...Resistor (impedance element), CNT...Control circuit (load circuit), CPU...
Processor, ROM...fixed memory, RAM...variable memory, MPX...multiplexer, A/D...ADC
(analog-digital converter), D/A ₁ to D/
A ₃ ...DAC (digital to analog converter), V _L ...
Line voltage, I _C … current.

Claims (1)

[Claims] 1. A receiving device that supplies a signal current from a constant current circuit of a control device to a two-wire transmission line and receives a signal indicated by the current value of a line current flowing through the two-wire transmission line, a series circuit of a first variable impedance element and a receiving impedance element inserted in series with the transmission path; and a series circuit of the first variable impedance element and a receiving impedance element inserted in parallel with the series circuit of the first variable impedance element and a receiving impedance element. a series circuit of a series impedance element and a second variable impedance element connected in series, and a series circuit connected in parallel to the second variable impedance element as a power supply load, and a line voltage, a first variable impedance element and a receiving circuit. The voltage at the connection point with the impedance element and the voltage at the connection point between the series impedance element and the second variable impedance element are respectively inputted, and the voltage at the connection point between the series impedance element and the second variable impedance element is inputted, and the voltage at the connection point between the series impedance element and the second variable impedance element is input, and a control circuit that controls the impedance of the first variable impedance element and controls the impedance of the second variable impedance element so as to keep the value of the current flowing through the series impedance element constant. receiving device.