WO2000048157A1 - Measuring transducer and method for evaluating the supply to a measuring transducer - Google Patents

Abstract

The invention relates to a measuring transducer and a method for evaluating the supply to a measuring transducer which can be connected to at least one two-wire line (2) for supplying the energy required for operation and for transmitting a current signal that represents a measured variable. The electric voltage at the terminals (6, 7) is determined in the measuring transducer, whereby said voltage is provided for the two-wire line for supplying the measuring transducer. A signal for displaying the supply quality is generated in the measuring transducer according to the voltage value or an increase in resistance.

Description

description

Transmitter and method for diagnosing the supply of a transmitter

The invention relates to a transmitter according to the preamble of claim 1 and a method for diagnosing the supply of a transmitter according to the preamble of claim 6.

A transmitter is already known from EP 0 244 808 A1, which is connected to an evaluation device by a two-wire line. The two-wire line transmits, on the one hand, the direct current energy required for the operation of the transmitter from the evaluation device to the transmitter and, on the other hand, the measured value signal representing the measured variable from the transmitter to the evaluation device. The transmitter is connected to the two-wire line via a transmitter interface, which takes the direct current energy required by the transmitter from the two-wire line and sets a current signal in the two-wire line that represents the measured variable. The evaluation device is connected to the two-wire line via an evaluation interface which is designed to apply the DC supply voltage to the two-wire line and to receive the measured value signal transmitted via the two-wire line. The evaluation device thus also has the function of a supply device. In addition, a communication interface is provided in the evaluation device and transmitter, which enables bidirectional digital data transmission via the two-wire line.

The voltage available at the connection terminals of the transmitter is reduced by the voltage drop of the supply lines compared to the output voltage of the supply unit. When used in potentially explosive atmospheres with the "intrinsically safe" protection type, a current limiting resistor is also provided in the power supply to limit the short-circuit current. If the arrangement is in rough environment, for example in the vicinity of a chemical process with aggressive substances, corrosion in particular leads to a gradual increase in the contact resistance at the connecting terminals of the transmitter. Because of this increase in resistance, the supply voltage at the transmitter can drop below a permissible minimum value, below which the transmitter no longer works correctly or even fails completely. In order to avoid such a malfunction, it is necessary in process engineering systems to check the connection terminals in specified maintenance cycles and to examine whether the resistance at the terminals has changed in a critical manner. This check can only be carried out when the system is switched off and is very time-consuming. Another cause of problems can be a faulty voltage supply, so that a sufficient supply voltage is not already available on the two-wire line.

The invention has for its object to provide a transmitter and to find a method for diagnosing the supply of a transmitter, by which the maintenance effort in a process plant is reduced.

To solve this problem, the new transmitter of the type mentioned has the features specified in the characterizing part of claim 1. To carry out the new method for diagnosing the supply of a transmitter, the method steps mentioned in the characterizing part of claim 6 are carried out. Advantageous developments of the invention are described in the subclaims.

The invention has the advantage that an unreliable power supply, caused, for example, by defects in the supply device or by corrosion of the connection terminals, is recognized and can be displayed for diagnosis and maintenance requests. The operator of the system can thus provide information about collect the quality of the transmitter supply, since the measured voltage monitors the supply directly at the transmitter. A reduction in the supply voltage can already be determined before a critical condition arises.

The means which are provided for detecting the electrical voltage at the terminals of the transmitter and for generating a signal for indicating the quality of supply as a function of the voltage value can be designed such that a first predetermined value of the current signal is set at a first point in time, an associated value of the electrical voltage at the terminals of the two-wire line is detected and stored, that at a second time which differs from the first, the first predetermined value of the current signal is set and an associated value of the electrical voltage is detected, and that by comparing the first and at the second point in time values of the electrical voltage, a signal is generated to indicate an expected value when the supply quality will fall below a threshold. Based on the expected value, needs-based maintenance is possible, particularly for cyclical maintenance work. If the expected fall below the threshold does not fall within the operating period following the respective maintenance cycle, the transmitter can be serviced until the next maintenance cycle. In addition, a trend statement is obtained, based on which the speed of the quality reduction can be assessed.

In addition, the means can advantageously be designed such that a first value and a second value of the current signal deviating from the first value are set in succession substantially at a first point in time, associated values of the electrical voltage are recorded and stored such that a first value of the ohmic resistance in the supply lines based on the ratio of the differences in the voltage values to the differences in the current values, stored at the first point in time, it is determined that a third value of the current signal is set and the associated value of the electrical voltage is detected at a second point in time which differs from the first point in time, that a second value of the ohmic resistance is determined on the basis of the values recorded at the first and second point in time is determined and that, depending on the difference between the two values of the ohmic resistance, a signal for indicating the quality of supply is generated. Advantageously, the increase in resistance in the supply lines, which is caused in particular by corrosion of the connection terminals, is detected directly. Maintenance can be requested, for example, if the terminal resistance exceeds a predetermined value or if a trend statement that can be made on the basis of the speed of the resistance increase means that a malfunction in the next operating period between two maintenance cycles can no longer be ruled out.

Carrying out the first voltage measurements during commissioning of the transmitter has the advantage that changes can be determined which have occurred during operation compared to the initial state of the transmitter.

The transmitter can be used in an advantageous manner without adaptation problems if a widespread, standardized 4 to 20 mA interface is provided for connection to the two-wire line.

Based on the drawing, in which an embodiment of the invention is shown, the invention as well as embodiments and advantages are explained in more detail below.

A transmitter 1 is connected to a supply device 3 via a two-wire line 2. The electrical behavior of the supply device 3 can be simulated by connecting a direct voltage source with the direct voltage U0 and an internal resistance Rv in series. Other circuit parts, which are arranged for communication or for further processing of the transmitter signals in the feed device 3 have not been shown for reasons of clarity. The two-wire line 2 is connected with terminals 4 and 5 to the power supply 3, with terminals 6 and 7 to the transmitter 1. On

Resistor Rk simulates the ohmic resistance of the two-wire line 2 and a resistor Rx the ohmic resistance at terminals 4 ... 7. In the transmitter 1, a current I is conducted on the two-wire line 2 essentially via a transistor T, a circuit 8 for generating the supply voltage of the transmitter 1 and a measuring resistor Rs. By tapping a voltage Ui at the measuring resistor Rs, the current I in the two-wire line 2 is detected and given as an actual value to a circuit 9 for current regulation. The circuit 9 is used to set the current I to one

Setpoint value Is, which is specified by a microprocessor 10. An output signal 11 of the circuit 9 is fed to the base connection of the transistor T for current adjustment. The transistor I thus sets the current I to a value which is set by the microprocessor 10. Via a voltage divider consisting of resistors Ra and Rb, an electrical voltage U is determined, which, if the small voltage drop across the measuring resistor Rs is neglected, corresponds to the voltage between the connecting terminals β and 7 of the transmitter 1. To measure the voltage U, the voltage drop across the resistor Rb is applied via a multiplexer 12 to an analog input of an A / D converter 13, the digital output value of which can be read out by the microprocessor 10. In addition to the program and data memory usually present in microprocessors, a non-volatile memory 14 is provided for the microprocessor 10, in which operating parameters can be written. The memory 14 can be implemented, for example, by an EEPROM. A sensor 15 is used to convert the physical quantity to be detected by the measuring transducer into an electrical voltage signal, which is likewise controlled by the microprocessor 10 via the multiplexer 12 the A / D converter 13 can be routed to digitize the measured value. The microprocessor 10 uses an analog output to set the target value Is for the circuit 9 in such a way that the current I in the two-wire line 2 corresponds to the measured variable detected by the sensor 15. The 4 to 20 mA standard is used to display the measured variable. The circuit 9 for current regulation is also connected to a communication device 16. The communication device 16 is used to send and receive a frequency-modulated signal via the two-wire line 2 and thus enables bidirectional digital transmission of data between the supply device 3 and the transmitter 1. The digital data transmission satisfies the HART specification. For example, diagnostic data, operating parameters and measurement results can be exchanged digitally between the transmitter 1 and the supply device 3. Furthermore, the transmitter is provided with a keypad 17 and a display 18 for manual operation on site, which are controlled by the microprocessor 10.

The following equation results for the voltage U from this equivalent circuit diagram:

U = U0 - (Rv + Rk + Rx + Rs) • I.

The voltage Um actually fed in at terminals 6 and 7 of the transmitter 1 can be obtained in a simple manner by adding the product Rs • I.

To simplify the spelling, an auxiliary variable R is introduced below

R = Rv + Rk + Rx.

When the transmitter 1 is started up, a first value II, preferably 4 mA, and then a second value is obtained

Value 12, preferably 20 mA, set by the microprocessor 10. The corresponding values Uml or Um2 of the voltage between the terminals 6 and 7 are detected and stored in the non-volatile memory 14. The following applies to the values Uml and Um2 of the voltage:

Uml = U0 - R • II and Um2 = U0 - R • 12.

By subtracting the two equations and solving them according to the auxiliary variable R we get:

R = (Uml - Um2) / (12 - II).

After inserting it into the determination equation for the value Uml, U0 can be calculated as:

U0 = Uml + (Uml - Um2) / (11 - 12) ^• II.

During the later operation of the transducer 1, further measurements of the value Um3 of the voltage between the connecting terminals 6 and 7 can be carried out for any values 13 of the current signal. If the ohmic resistance in the supply lead changes, for example due to corrosion, by the value ΔR, SO applies to the value Um3 of the voltage:

Um3 = U0 - (R + ΔR) • 13.

The change in resistance ΔR can be determined by changing the equation to:

ΔR = ((U0 - Um3) / 13) - R.

If the value ΔR of the change in resistance exceeds a predetermined threshold, for example 300 Ω, the transmitter 1 generates a signal to indicate the quality of supply in such a way that correct functioning of the transmitter 1 can no longer be guaranteed due to insufficient power supply. The signal can be set, for example can be given by indication on the display 18 or by a digi ^¬ tale communication with the supply unit 3 of a fault current, which lies outside the 4 to 20 mA range. With additional evaluation of the period between the measurements, a trend statement can be derived from the measurement results, which reflects the change in the quality of supply over time.

Instead of the value ΔR of the change in resistance, the value Um3 can alternatively be used directly

Voltage between the terminals β and 7 of the transmitter 1, a signal to indicate the quality of supply are generated.

The measurement results can be logged and evaluated in the transmitter 1 or in the case of communication via the two-wire line 2 in a higher-level control unit, of which the supply device 3 is a part. This enables the user to carry out a fault diagnosis in a process plant and to localize sources of error more precisely.

It is essential that the electrical voltage that arrives at the electronics of the transmitter is used directly or indirectly to generate a signal to indicate the quality of supply. This voltage can be detected directly at the connection terminals which are provided for the two-wire line for supplying the transmitter. An indirect measurement of the supply voltage, in which the supply voltage is inferred from an internally measured variable, as described in the exemplary embodiment, can be carried out.

The exemplary embodiment shows a transmitter 1, in which measured values and operating energy are transmitted via the same two-wire line. Deviating from this, in other embodiments a two-wire line can be carrying the measured values and a two-wire line for transmitting the energy required for operation are provided. In this case, in order to generate a signal to indicate the quality of supply, the electrical voltage at the connection terminals which is provided for the two-wire line for supplying the transmitter with operating energy is detected. The circuit 8 for supply generation is then missing in the circuit parts which are available for the transmission of measured values, and the operating energy is fed into the transmitter via two separate terminals. In this case, the voltage on the two-wire line, which is provided for the transmission of the measured values, can also be monitored as the supply voltage of the 4 to 20 mA interface.

The current-setting transistor T and the circuit 8 for supply generation form the essential parts of the so-called loop interface. In other embodiments, a circuit 8 can also be arranged parallel to the current-setting element.

Any potential isolation that may be required can be inserted between the microprocessor 10 and the A / D converter 13. It is advantageous in the exemplary embodiment shown to use only one A / D converter 13 both for the voltage signal U and for the analog signal from the sensor 15. If a separate A / D converter is used for the voltage signal U, for example according to the principle of a voltage -Frequency conversion, to be added, a potential separation can also be inserted between this and the microprocessor.

Claims

claims

1. Transmitter which can be connected to at least one two-wire line (2) for supplying the energy required for operation and for transmitting a current signal representing a measured variable, characterized in that means (Ra, Rb, T, Rs, 8 ... 14 , 16) are present in order to detect the electrical voltage at the connection terminals (6, 7) which are provided for the two-wire line (2) for supplying the transmitter and to generate a signal for indicating the quality of the supply as a function of the voltage value.

2. Transmitter according to claim 1, characterized in that the means (Ra, Rb, T, Rs, 8 ... 14, 16) are designed such that a first predetermined value of the current signal is set at a first point in time Associated value of the electrical voltage at the connection terminals (6, 7) of the two-wire line (2) is recorded and stored, that at a second time which differs from the first, the first predetermined value of the current signal is set and an associated value of the electrical voltage at the connection terminals (6, 7) of the two-wire line (2) is detected and that, by comparing the values of the electrical voltage recorded at the first and second point in time, a signal is generated to indicate an expected value when the supply quality will fall below a threshold.

3. Transmitter according to claim 1, characterized in that the means (Ra, Rb, T, Rs, 8 ... 14, 16) are designed such that a first value (II) and a substantially at a first time in succession second value (12) of the current signal (I) deviating from the first value is set, associated values (Uml, Um2) of the electrical voltage are recorded and stored, that a first value (R) of the ohmic resistance in the supply feed is determined on the basis of the ratio of the differences in the voltage values to the differences in the current values that were stored at the first point in time, that a third value deviates from the first point in time (13) of the current signal (I) is set and the associated value (Um3) of the electrical voltage is detected, that the change (ΔR) in the ohmic resistance in the supply lead is determined and that a signal is dependent on the change (ΔR) in the ohmic resistance is generated to display the quality of care.

4. Transmitter according to one of claims 2 or 3, characterized in that the first time is during commissioning.

5. Transmitter according to one of the preceding claims, characterized in that a 4 to 20 mA interface is provided for connection to the two-wire line (2).

6. A method for diagnosing the supply of a transmitter which is connected to at least one two-wire line (2) for supplying the energy required for operation and for transmitting a current signal (I) representing a measured variable, characterized in that the electrical voltage at the connecting terminals (6, 7), which are provided for the two-wire line (2) for supplying the transmitter, is detected and that a signal for indicating the quality of supply is generated as a function of the voltage value.

7. The method according to claim 6, characterized in that at a first time a first predetermined value of the current signal is set, an associated value of the electrical voltage at the connecting terminals (6, 7) of the two-wire line (2) is detected and stored, that at a second time different from the first, the first predetermined value of the current signal is set and an associated value of electrical voltage at the connection terminals (6, 7) of the two-wire line (2) is detected and that, by comparing the values of the electrical voltage recorded at the first and second point in time, a signal is generated to indicate an expected value when the supply quality falls below a threshold becomes.

8. The method according to claim 6, characterized in that essentially at a first point in time a first value (II) and a second value (12) of the current signal (I) deviating from the first value are set, associated values (Uml, Um2) of the electrical voltage are recorded and stored, so that a first value (R) of the ohmic resistance in the supply lead is determined on the basis of the ratio of the differences in the voltage values to the differences in the current values which were stored at the first point in time second, from the first point in time, a third value (13) of the current signal (I) is set and the associated value (Um3) of the electrical voltage is detected, that the change (ΔR) of the ohmic resistance in the supply supply is determined and that depending the change (ΔR) in the ohmic resistance, a signal for indicating the quality of supply is generated.

9. The method according to claim 7 or 8, characterized in that the first time is during commissioning.

10. The method according to any one of claims 6 to 9, characterized in that a 4 to 20 mA interface is provided for connection to the two-wire line.