DE19517492A1 - Analogue current interface for converting live-zero input signals - Google Patents

Abstract

The interface has an analogue operational amplifier (4) which converts the input current (Ie+), or the voltage it produces across a resistance (1), into an analogue output signal (U4). The second operational amplifier (10) superimposes, on this signal, a signal one offset to zero, in particular for the conversion of an output signal into an input signal for a summing circuit. Threshold values are given (+US,-US). The sign of the offset signal (+Uref, -Uref) supplied to the second amplifier through MOS-FET switches (27,31) matches the direction of flow of the input current (Ie+, Ie-).

Description

The invention relates to an analog current interface, which an input stream in the form of a "live zero" signal in converts output signal symmetrical to zero, according to Preamble of claim 1.

In automation technology, it is common to use the output si Signals from transmitters in the form of an electrical current signal transferred to. Two lines are used in four-wire transmitters to transfer the supply energy for the transmitter and two lines for the transmission of the measurement signal. This corresponds to an output current of 0 to 20 mA with a measured variable of 0 to 100%. With two-wire transmitters, the supply energy and transmit the measurement signal over the same two lines. An output current of 4 to 20 mA corresponds to a measurement size from 0 to 100%. For the transfer of the pensioners The basic current of 4 mA is available for the transmitter Available.

Occurs between the transmitter and an electrical circuit for evaluation and / or linkage with other signals Interruption of a line or a short circuit between the Lines on is the current that is supplied to the evaluation circuit leads is zero. A current value that is outside the range of 4 mA to 20 mA indicates a fault. Because a mess value of 0% a non-zero value of the output si gnals, e.g. B. 4 mA is assigned, one speaks of a "live zero "signal.

Adjustable current sources, the output current z. B. between 4 mA and 20 mA, u. a. as setpoint generator for rule facilities used.

For the evaluation and linking of electrical signals it is advantageous if they are in the form of tensions. These  Voltages can be changed from analog computing amplifiers to simple ones Be processed further.

Current signals in the form of "live zero" signals only point a polarity. A signal is needed that goes to the zero point is symmetrical, e.g. B. +10 V to -10 V for the range of 4 mA up to 20 mA of the input current, with an output voltage of 0 V corresponds to an input current of 12 mA, becomes the input signal overlays a correction signal that the zero point of the Output signal shifts accordingly. This shift applies but only for one direction of action, d. H. for a falling code line or for a rising characteristic curve with increasing input electricity. The input current can therefore only be in one direction the current interface flow. Swap the input clamping is not permitted.

The invention has for its object an analog current Interface of the type mentioned to create the choice has a falling or an increasing characteristic.

This object is characterized by those in claim 1 Features resolved. The input current is allowed in both directions flow over the current interface. With a polarity reversal of the on The effect of the output clamps is given the same input signals reversed direction without making adjustments to the current cut need to be changed.

Advantageous further developments and refinements of the invention are marked in the subclaims. Falls below Amount of the output signal of the first computing amplifier one Predeterminable threshold value, which is smaller than that of the working corresponding minimum value of the input current is carried out an error message. The disorder can be a sub break or a short circuit of the lines between the current and the current interface. In this case flows the zero current through the input of the current interface.

The invention will be described in more detail below based on exemplary embodiments shown in the drawings len explained in more detail. Show it

Fig. 1 shows the schematic diagram of a first embodiment of the analog current interface and

Fig. 2 shows the principle circuit diagram of a second embodiment of the analog current interface according to the invention.

The same components are provided with the same reference symbols.

Fig. 1 shows the principle circuit diagram of a first example of the present invention exporting approximately analog current interface. In the following it is assumed that the current interface is supplied with an input current whose working range is between 4 mA and 20 mA, and that the current interface provides an output signal in the form of a voltage with a working range from -10 V to +10 V for one increasing characteristic and with a working range of +10 V to -10 V for a falling characteristic. The invention is not limited to the specified values, they only serve to explain the invention.

An input current Ie + flows from an input terminal 2 to a further input terminal 3 via a resistor 1 , which is connected to a current transmitter, also not shown, via lines, not shown. The direction of the input current Ie + is shown by a black arrow. The input current Ie + has a working range from 4 mA to 20 mA. The voltage drop across the resistor 1 is fed to a potential-free differential input of a first computing amplifier 4 . The computing amplifier 4 contains an operational amplifier 5 and four resistors 6 , 7 , 8 and 9 . The output voltage of the computing amplifier 4 is denoted by U₄, it is inverted relative to the voltage drop across the resistor 1 . The gain factor results in a known manner from the dimensioning of the resistors 6 to 9 . With an input current Ie + that flows from the input terminal 2 to the input terminal 3 , the voltage U₄ is negative. The working range of the input current Ie + from 4 mA to 20 mA corresponds to a range of the voltage U₄ from -0.2 V to -1.0 V. The voltage U₄ is fed to a second computing amplifier 10 . The computing amplifier 10 is designed as an inverting summing amplifier. It contains an operational amplifier 11 , three input resistors 12 , 13 , 14 and a feedback resistor 15 . The output voltage of Re chenamplifiers 10 is designated U₁ U, it is inverted with respect to the resistors 12 to 14 supplied voltages. The gain of the computing amplifier is determined by the resistors 12 and 15 .

The voltage U₄ is fed via a line 16 to the input of a comparator circuit 17 with two operational amplifiers 18 and 19 . The operational amplifier 18 compares the voltage U₄ with a positive threshold voltage + U _S. The operational amplifier 19 compares the voltage U₄ with a negative threshold voltage -U _S. The threshold voltages + U _S and -U _S are tapped at two voltage dividers. One voltage divider consists of two resistors 20 and 21 and is connected to a voltage + U _ref . The other voltage divider consists of two resistors 22 and 23 and is connected to a voltage U _ref . The threshold voltages + U _s and -U _S are equal in terms of amount. They are chosen so that they correspond to a value of the voltage U₄ which arises when the input current Ie + is less than the minimum value of the working range. In this example it was assumed that the working range of the input current Ie + is between 4 mA and 20 mA. The threshold value voltages + U _S and -U _S are selected so that they correspond to half the minimum value of the working range, ie 2 mA in the example considered here. The threshold voltages thus result in + U _S = 0.1 V and -U _S = -0.1 V. The output voltage of the operational amplifier 18 is fed to a further voltage divider consisting of two resistors 24 and 25 . The connection point of the resistors 24 and 25 is connected via a line 26 to the gate connection of a first MOS-FET switch 27 . The output voltage from the operational amplifier 19 is fed to a further voltage divider made up of two resistors 28 and 29 . The connection point of the resistors 28 and 29 is connected via a line 30 to the gate connection of a second MOS-FET switch 31 . The MOS-FET switch 27 connects the resistor 14 in the closed state with a constant negative voltage -U _ref . The MOS-FET switch 31 connects the resistor 13 in the closed state with a constant positive voltage + U _ref .

If the current + Ie flows from the input terminal 2 to the input terminal 3 , the voltage U₄ is negative because of the inverting mode of operation of the computing amplifier. The output voltage of the operational amplifier 18 is the negative operating voltage, since the voltage + U _S supplied to its inverting input is greater than the negative voltage U₄ supplied to its non-inverting input. The gate terminal of the MOS-FET switch 27 is supplied with a negative voltage via line 26 , the MOS-FET switch 27 is open. The output voltage of the operational amplifier 19 is the positive operating voltage, since the negative voltage U₄ supplied to its inverting input is smaller than the voltage -U _S supplied to its non-inverting input. The voltages + U _S and -U _S were - as stated above - chosen so that their amounts are smaller than the voltage U Spannung. The gate terminal of the MOS-FET switch 31 is supplied via line 30 with a positive voltage which switches it to the conductive state. The inverting input of the operational amplifier 11 of the inverting computing amplifier 10 is supplied with the negative voltage U negative via the resistor 12 and the positive voltage + U _ref via the resistor 13 . The voltage + U _ref and the resistor 13 are chosen so that in the example considered at an input current of 12 mA (corresponding to 50% of the input signal), the output voltage U₁₀ of the second computing amplifier 10 is zero volts. With an input current of 4 mA, the voltage U₁₀ = -10 V and with an input current of 20 mA, the voltage U₁₀ = +10 V. With increasing input current, the output voltage also increases; the current interface has an increasing characteristic curve for an input current Ie + which flows from input terminal 2 to input terminal 3 .

If a falling characteristic of the current interface is required, input terminals 2 and 3 must be interchanged. In this case, the input current Ie flows from input terminal 3 to input terminal 2 . The direction of the input current Ie is shown by a white filled arrow. With an input current Ie- that flows from the input terminal 3 to the input terminal 2 , the voltage U₄ at the output of the inverting amplifier amplifier 4 is positive. The working range of the input current Ie- from -4 mA to -20 mA corresponds to a range of the voltage U₄ from +0.2 V to +1.0 V. The comparator circuit 17 compares the positive voltage U₄ with the threshold voltages + U _S and - U _S. The output voltage of the operational amplifier 19 is the negative operating voltage, since the positive voltage U₄ supplied to its inverting input is greater than the voltage -U _S supplied to its non-inverting input. The gate to the circuit of the MOS-FET switch 30 is a ne gative voltage supplied via line 30 , the MOS-FET switch 31 is open. The output voltage of the operational amplifier 18 is the positive operating voltage, since the voltage + U _S fed to its inverting input is smaller than the positive voltage U₄ fed to its non-inverting input. The gate to the circuit of the MOS-FET switch 27 is supplied with a positive voltage via the line 26 , which switches it to the conductive state. The inverting input of the operational amplifier 11 of the inverting operational amplifier 10 is connected via the reflection stand 12, the positive voltage U₄ and via the resistor 14, the negative voltage -U _ref supplied. The voltage -U _ref and the resistor 14 are chosen so that in the example under consideration at an input current of -12 mA (corresponding to 50% of the input signal) the output voltage U₁₀ of the second computing amplifier 10 is zero volts. With an input current of -4 mA, the voltage U₁₀ = +10 V and with an input current of -20 mA, the voltage U £ ¢ = -10 V. As the input current increases, the output voltage drops, the current interface has an input current, which flows from input terminal 3 to input terminal 2 , a falling characteristic.

Depending on the direction in which the input current flows through input terminals 2 and 3 , you get an increasing or falling characteristic of the current interface.

Fig. 2 shows the basic circuit diagram of a second example of the present invention exporting approximately analog current interface. The first computing amplifier 4 has the same structure as in FIG. 1. The second computing amplifier 10 'has essentially the same structure as the second computing amplifier 10 of FIG. 1. The resistors 13 and 14 are replaced in FIG. 2 by a resistor 13 '. The output voltage U₄ of the first computing amplifier 4 is fed to a first input of the second computing amplifier 10 'and via line 16 to the input of a comparator circuit 17 '. The comparator circuit 17 'has a first operational amplifier 32 , the non-inverting input of which leads to the threshold voltage + U _S. The voltage U₄ is supplied to the inverting input of the operational amplifier 32 . The comparator circuit 17 'has a second operational amplifier 33 , the non-inverting input of which the threshold voltage -U _{S is} supplied. The voltage U₄ is supplied to the inverting input of the operational amplifier 33 . The outputs of the operational amplifiers 32 and 33 are connected to a line 36 via diodes 34 and 35, respectively.

The line 36 connects the output of the comparator circuit 17 'with a switching device 37 which, depending on the polarity of the output voltage of the comparator circuit 17 ', a positive or negative voltage + U _ref or -U _ref to a further input of the second computing amplifier 10 'Switches. From the output of the comparator circuit 17 'leads a line 38 to a signaling device 39th

At an input current Ie + of the current interface, which flows from the input terminal 2 to the input terminal 3 , the voltage U₄ is negative. The direction of the input current Ie + is shown by an arrow filled in black. The output voltage of the operational amplifier 32 is the positive operating voltage since the negative input supplied to its inverting input. Voltage U₄ is less than the voltage + U _S supplied to its non-inverting input. The output voltage of the operational amplifier 33 is the positive operating voltage, since the negative voltage U₄ supplied to its inverting input is smaller than the voltage supplied to its non-inverting input -U _S. From the output of the operational amplifier 33 flows through the diode 35 , the line 36 , a resistor 40 of the switching device 37 and the resistor 13 'a current to the inverting input of the operational amplifier 11th The inverting input of the operational amplifier 11 is practically at zero potential. The voltage at the common circuit point of the diodes 34 and 35 is the positive operating voltage reduced by the forward voltage of the diode 35 . Since the output voltage of the operational amplifier 32 is the positive operating voltage, the diode 34 blocks.

In addition to the resistor 40, the switching device 37 contains two operational amplifiers 41 and 42 and two diodes 43 and 44 . The voltage -U _{ref is} fed to the non-inverting input of the operational amplifier 41 and the voltage + U _{ref is} fed to the non-inverting input of the operational amplifier 42 . The inverting inputs of operational amplifiers 41 and 42 are connected to the common node of resistors 40 and 13 '.

If the voltage U₄ is negative, then - as explained above - the output voltage of the comparator circuit 17 'is positive. The voltage at the inverting inputs of operational amplifiers 41 and 42 is positive. The output voltage of the operational amplifier 41 is the negative operating voltage, since the voltage at its inverting input is greater than the voltage -U _ref at its non-inverting input. The diode 43 blocks. The output voltage of the operational amplifier 42 is fed back via the diode 44 to its inverting input, ie the output voltage of the operational amplifier 42 is set such that the voltage at the inverting input is equal to the voltage + U _ref . Thus, the inverting input of the operational amplifier 11 of the inverting arithmetic amplifier 10 'is supplied with the negative voltage U Spannung via the resistor 12 and the positive voltage + U _ref via the resistor 13 '. As in FIG. 1, there is an increasing characteristic curve between the input current and the output voltage of the current interface when the input current Ie + flows from the input terminal 2 to the input terminal 3 .

A falling characteristic curve arises when the input current Ie flows from the input terminal 3 to the input terminal 2 . The direction of the input current Ie is represented by an arrow filled in white. The voltage U₄ is positive. The output voltage of the operational amplifier 33 is the negative voltage operation, since its inverting input supplied posi tive voltage U₄ is larger than that its noninverting A gear supplied voltage -U _S. The output voltage of the operational amplifier 32 is the negative operating voltage, since the positive voltage U₄ supplied to its inverting input is greater than the voltage + U _S supplied to its non-inverting input. From the practically zero potential inverting input of the operational amplifier 11 , a current flows through the resistor 13 ', the resistor 40 and the diode 34 to the negative operating voltage. The voltage at the common node of the diodes 34 and 35 is greater than the negative operating voltage by the forward voltage of the diode 34 . Since the output voltage of the operational amplifier 33 is the negative operating voltage, the diode 35 blocks. The voltage at the inverting inputs of the operational amplifiers 41 and 42 is negative. The output voltage of the operational amplifier 42 is the positive operating voltage since the voltage at its inverting input is less than the voltage + U _ref at its non-inverting input. The diode 44 blocks. The output voltage of the operational amplifier 41 is fed back via the diode 43 to its inverting input, ie the output voltage of the operational amplifier 41 is adjusted so that the voltage at the inverting input is equal to the voltage U _ref . So that the inverting input of the operational amplifier 11 of the re chenamplifiers 10 'leads via the resistor 12, the positive voltage U₄ and via the resistor 13 ' leads to the negative voltage -U _ref . As in FIG. 1, there is a falling characteristic curve between the input current and the output voltage of the current interface when the input current Ie flows from the input terminal 3 to the input terminal 2 .

So far it has been assumed that the input current as a "live zero" signal has a value between a minimum value, e.g. B. 4 mA and a minimum value, e.g. B. 20 mA. If there is an interruption in a line between the current transmitter and the current interface, no current flows through the current interface. The same applies if a short circuit occurs between the lines leading from the current transmitter to the current interface. In this case, the output voltage U₄ of the inverting amplifier 4 is zero volts. The output voltage of the operational amplifier 32 is now the positive operating voltage, since the voltage U₄ at the inverting input is less than the voltage + U _S at the non-inverting input. The output voltage of the operational amplifier 33 is the negative operating voltage since the voltage U₄ at the inverting input is greater than the voltage -U _S at the non-inverting input. The diodes 34 and 35 are acted on in the reverse direction. The voltage on line 36 is zero volts. The inverting input of the operational amplifier 11 is supplied via the resistor 12 and the resistor 13 'the voltage zero volts. So that the output voltage U _{10 'of} the current interface is also zero volts. This voltage corresponds to an input signal of 50%. An actuator driven by the voltage U _{10 '} is moved into its central position.

As stated above, in normal operation the voltage on line 36 is positive or negative. The voltage on line 36 is zero volts only in the event of a fault. This relationship is used to report errors. As long as a positive or a negative voltage is supplied to the signaling device 39 via the line 38 , there is no fault message. Receives the signaling device 39 no more voltage in the event of a fault, includes a switch, not shown in FIG. 2, which is controlled by the voltage on line 38 , and connects a lamp 45 to the operating voltage. The illuminated lamp 45 signals the occurrence of a fault. In addition to or instead of the optical fault signaling, an acoustic fault signaling is possible. It is also possible to supply the fault signal to a control circuit for further signal linking.

Claims (7)

1. Analog current interface, which converts an input current in the form of a "live zero" signal into an output signal that is symmetrical to the zero point, with a first analog computing amplifier which converts the input current or the voltage falling across a resistor through which the input current flows into a voltage Forms input current proportional analog output signal with a second analog arithmetic amplifier, which overlays an offset signal shifting the zero point of the output signal of the current interface to the analog output signal of the first arithmetic amplifier, in particular for converting the output current of a current generator into an input signal for an electrical logic circuit, thereby characterized in that the algebraic sign of the offset signal (+ U _ref , -U _ref ) fed to the second arithmetic amplifier ( 10 ; 10 ′) is adapted to the direction of flow of the input current (Ie +, Ie-). 2. Current interface according to claim 1, characterized in that the output signal of the first computing amplifier ( 4 ) is fed to a comparator circuit ( 17 ; 17 ') and that the output signal of the comparator circuit ( 17 ; 17 ') switches ( 27 and 31 ; 41 , 43 and 42 , 44 ) controls, depending on the sign of the output signal (U₄) of the first arithmetic amplifier ( 4 ) the second arithmetic amplifier ( 10 ; 10 ′) a positive reference signal (+ U _ref ) or a negative reference signal (- U _ref ) as an offset signal. 3. Current interface according to claim 2, characterized in that the comparator circuit ( 17 ; 17 ') outputs a first output signal (positive voltage on line 26 ; negative voltage on line 36 ) when the output signal (U₄) of the first computing amplifier ( 4 ) is positive and greater than a predeterminable threshold value (+ U _S ), and that the comparator circuit ( 17 ; 17 ') outputs a second output signal (positive voltage on line 30 ; positive voltage on line 36 ) if that Output signal (U₄) of the first Rechenver amplifier ( 4 ) negative and its amount is greater than the amount of the predeterminable threshold value (-U _S ), the amount of the predeterminable threshold value (+ U _S , -U _S ) being chosen smaller than that minimum value corresponding to the working range of the input current (Ie +, Ie-). 4. Current interface according to claim 2 or claim 3, characterized in that the input current (Ie +, Ie-) flows through a resistor ( 1 ), that the first computing amplifier ( 4 ) has a potential-free differential input, that the connections to the resistor ( 1 ) are connected to the differential input of the most arithmetic amplifier ( 4 ) that the second re chen amplifier ( 10 , 10 ') is a summing amplifier that the output from the first arithmetic amplifier ( 4 ) with a first input of the second arithmetic amplifier ( 10 ; 10 ') And is connected to the input of the comparator circuit ( 17 , 17 '), and that the switches ( 27 and 31 ; 41 , 43 and 42 , 44 ) driven by the comparator circuit ( 17 , 17 ') are offset voltages (+ U _ref , -U _ref ) switch opposite polarity to another input of the second computing amplifier ( 10 , 10 ') on. 5. Current interface according to claim 4, characterized in that the two computation amplifiers ( 4 , 10 ; 4 , 10 ') are inverting amplifiers that when the first output signal of the comparator circuit ( 17 ; 17 ') occurs, a first switch ter ( 27 ; 41 , 43 ) closes, the further input of the second arithmetic amplifier ( 10 ; 10 ') leads to a negative voltage (-U _ref ), and that when the second output signal of the comparator circuit ( 17 ; 17 ') occurs, the second switch ( 31 ; 42 , 44 ) closes, which supplies a positive voltage (+ U _ref ) to the second input of the second computing amplifier ( 10 , 10 '). 6. Current interface according to one of claims 3 to 5, characterized in that the comparator circuit ( 17 ') emits a third output signal (0 volts) when the amount of the output signal (U₄) of the first computing amplifier ( 4 ) is less than the amount of predeterminable threshold value (+ U _S , -U _S ). 7. Current interface according to claim 6, characterized in that the output of the comparator ( 17 ') is connected to a signaling device ( 39 ).