DE102007062394A1 - Field device and method for checking the calibration of a field device - Google Patents

Abstract

A field device of the process automation technology, with an interface for connecting a field bus, comprises a timer for generating a time signal and a control module which is adapted to compare a programmable from the fieldbus start time of a measurement with the time signal to start the measurement in accordance, and store a measurement result of the measurement under an address which can be read out from the fieldbus (FIG. 1).

Description

The The invention relates to a field device according to the generic term of claim 1 and a field bus system according to the preamble of Anspurchs 3. Furthermore, the invention relates to a method for starting a measurement in a field device according to the generic term of claim 20 and a method for checking the calibration of a field device according to the generic term of claim 21.

In Process automation technology is often used in field devices, which serve to detect and / or influence process variables. examples for such field devices are level gauges, mass flow meters, pressure and temperature measuring devices etc., as sensors, the corresponding process variables level, Record flow, pressure or temperature.

to Influence of process variables serve actuators, eg. B. valves or pumps over the flow of a liquid be changed in a pipe section or the level in a container can.

When field devices In principle, all devices are called, which are used close to the process and the process-relevant information deliver or process.

A Variety of such field devices is manufactured and distributed by the company Endress + Hauser.

During the The field devices become operational partly operated under aggressive environmental conditions. insofar it comes to soiling, deposits, corrosion, and this affects also the accuracy of the measured values delivered by the field device. Out these reasons It is necessary to know the accuracy of a field device in certain intervals with the help of a reference device of the same type. From the reference device is known to be calibrated correctly and correct readings supplies.

to execution a comparison measurement between a DUT field device and a Reference field device Previously, it was required, each via a service interface to access the two devices. About the Service interface was a time-synchronous measurement by DUT and reference device and then the results measured in this way were compared. Disadvantage of this procedure is that the review of Calibration due to the latency of the fieldbus not over the Fieldbus itself can be done, but a separate service interface is required.

task The invention is a review of Calibration of a field device to simplify.

Is solved this object by the specified in claims 1, 3, 20 and 21 Characteristics.

advantageous Further developments of the invention are specified in the subclaims.

Around to enable a timely start of a measurement is in the inventive solution a desired Start time written from the fieldbus to the field device. There is a timer on the field device is provided, which generates a local time signal, with a parent System time can be synchronized. The saved start time will be compared with the local time signal, and if coincident, the measurement becomes through the field device automatic started.

With Help this trigger mechanism for the measurement a timely start of the measurement is made possible. This will make it possible to get one desired measurement over the Fieldbus set up at the timing of the measurement but of the latencies independent on the fieldbus to be. Would start the measurement by transmitting a start command via the fieldbus will come it delays, which are due to the cycle time of the fieldbus.

The Use of such a triggering mechanism allows in particular, a comparison measurement between a test field device and a To perform a reference field device. For this will over the fieldbus a common start time to the DUT field device and to transferred to the reference field device and on the respective device stored. Both on the DUT field device and on the reference field device the measurement is started at the scheduled start time. On this way is made possible that the measurement and the reference measurement are performed exactly synchronously. Since the DUT field device and the Reference field device the same measure physical size and the measurement is time-synchronized, should be determined by the DUT Exactly match the reference value determined by the reference field device. By comparing those from the examinee and from the reference device Therefore, the measurement accuracy of the device under test can be assessed become. This is especially for the quality management essential in process engineering.

The closer the measured value determined by the test specimen to the reference value, the better the measuring accuracy of the test specimen. If the deviation between the measurement result of the test specimen and the reference value of the reference device, on the other hand, exceeds a certain limit, then the measurement accuracy of the device under test is no longer sufficient. In this case recalibration of the device under test is required. By redetermining the calibration parameters of the test specimen, the measurement accuracy can be restored to its former level.

at an advantageous embodiment will be in case of a bad match between those of the examinee and from the reference device measured values are automatically recalibrated. For this be from a parent Control unit off, for example, from a master, the Recalibration required measurements initiated. The newly determined calibration parameters are then over the Transmit fieldbus to the DUT field device, saved and used from now on.

at The solution according to the invention can both the comparison measurement as well as the recalibration exclusively over the Fieldbus performed become. additional Service interfaces and elaborate Calibration tools are no longer required.

following The invention is explained in more detail with reference to an embodiment shown in the drawing.

It demonstrate:

1 Field device for the timely execution of a measurement;

2A Comparative measurement according to the prior art;

2 B Comparison measurement according to an embodiment of the invention;

3 Block diagram of a measuring arrangement.

1 shows a field device 1 according to an embodiment of the present invention, which via a fieldbus interface 2 and a fieldbus 3 with a higher-level control unit 4 communicates. At the higher-level control unit 4 can it be z. For example, a master of the class 2 act. The field device 1 serves to detect a process variable relevant to the process, for example, one or more of the following: volume flow, mass flow, pressure, temperature, differential pressure, level, pH, etc.

When transmitting commands and data over the fieldbus 3 There are latencies that are primarily caused by the cycle time of the fieldbus. Further delays arise due to device cycle times and system cycle times. Despite these latencies, the field device according to the invention makes it possible 1 , a measurement exactly to one of the higher-level control unit 4 to start from programmable starting time. This is on the field device 1 a local timer 5 which is synchronized with a system-wide system time. This system time is controlled by a system timer 6 generated on the part of the parent control unit, for example 4 can be arranged.

The way how the synchronization between the local timer 5 and the system timer 6 is made, differs depending on the type of fieldbus used. When as a fieldbus 3 a Foundation Fieldbus is used, the synchronization can be accomplished by means of a broadcast command. The system timer 6 sends a broadcast command to all local timers at a given time 5 and thus allows synchronization of the local time with the system time. For other fieldbus standards, such as the Profibus, there is no broadcast command. In such standards, it is necessary for the synchronization of the timer, from the parent control unit 4 from each of the local timers 5 one telegram in succession with the current system time of the system timer 6 to send. In this way, even if no broadcast command is available, a synchronization between the local timer 5 and the system timer 6 be achieved.

The field device 1 further comprises a plurality of memory cells 7 that over the fieldbus 3 can be addressed. In the case of a Profibus device, the data can usually be addressed via the "physical block", whereas the data in a Foundation Fieldbus device can be addressed via the "Transducer Block".

In the memory cells 7 Parameters of the measurement to be performed are stored. in particular, in the memory cells 7 Parameters such as a start time 8th , a measurement period 9 as well as a measurement mode 10 be filed. These parameters of the measurement to be performed are taken from the parent unit 4 from via the acyclic data traffic of the fieldbus 3 in corresponding memory cells 7 written.

The measurement is carried out by a control module 11 controlled. The control module 11 is designed to carry out the measurement as a function of those in the memory cells 7 control stored parameters. The control module 11 compares the from the local timer 5 to disposal set time with the start time 8th , and if coincident, the measurement is started. To carry out the measurement, the field device comprises 1 a sensor 12 which provides a measurement signal, for example a current signal. On the field device 1 calibration parameters are stored to convert the measurement signal into a physical measurand 13 convert. Measurements such. As a pH measurement, pressure measurement or temperature measurement are performed at a given time. In the case of volume flow or mass flow measurements, on the other hand, the measurement duration is longer than a specified period 9 away the volume or mass of the sensor 12 flowing liquid is integrated. The determined physical quantity 13 is in one of the memory cells 7 saved and can from the parent control unit 4 out over the fieldbus 3 be read out in acyclic data traffic.

The basis of 1 described mechanism for the timely execution of a measurement is particularly suitable to check the calibration of a field device using a reference field device and optionally recalibrate the field device.

In 2A It is shown how the verification of the calibration of a field device is made in the solutions of the prior art. The respective measured variable, for example a volume flow 14 in a pipeline 15 , is simultaneously passed through a device under test field device 16 and by a reference field device 17 measured. From the reference field device 17 It is known that it is calibrated correctly and provides correct readings. The DUT field device 16 can be connected to a fieldbus 18 be connected. However, the calibration measurement is not from the fieldbus 18 initiated from. Instead, both are the DUT field device 16 as well as the reference field device 17 each with a service interface 19 . 20 fitted. To these service interfaces 19 and 20 becomes a service device 21 , for example, a laptop, connected. Under the control of the service device 21 is the volume flow from the DUT field device 16 and from the reference field device 17 measured synchronously. After the measurement, that of the device under test becomes 16 determined measured value with that of the reference field device 17 compared to the reference value determined. If that of the DUT field device 16 measured value deviates only slightly from the reference value, there is no recalibration of the device under test 16 required. On the other hand, if the deviations are greater, it is necessary to use the ones in the test unit field device 16 to re-defined stored calibration parameters.

In 2 B is an inventive system for performing a calibration measurement with a DUT field device 22 and a reference field device 23 shown. The DUT field device 22 and the reference field device 23 are designed to handle the flow 24 in a pipeline 25 to eat. Both the DUT field device 22 as well as the reference field device 23 correspond to the in 1 shown embodiment of the invention and are therefore able to automatically perform a measurement at a freely programmable start time.

The DUT field device 22 and the reference field device 23 are over a fieldbus 26 with a master 27 connected. The master writes in order to carry out the comparison measurement 27 a start time for the start of the measurement in the two field devices 22 and 23 , The DUT field device 22 and the reference field device 23 From the specified start time, a flow measurement is carried out absolutely synchronously, with the measurement results obtained in each case in the test device field device 22 and in the reference field device 23 be stored. After completion of the measurement, those of the two field devices 22 . 23 determined measured values from the master 27 from queried and compared. If that of the DUT field device 22 determined measured value sufficiently close to that of the reference field device 23 measured value, then the test device field device works 22 still sufficiently accurate and does not need to be recalibrated. If that of the DUT field device 22 On the other hand, if the measured value measured lies outside of a tolerance window around the reference value, then a recalibration of the test device field device takes place 22 required. Recalibration is performed by the DUT field device 22 and from the reference field device 23 performed a series of different measurements. For example, measurements are made at various flow rates, pressures, temperatures, etc. Based on the obtained measured values and reference measured values, the calibration parameters of the test device field device 22 be redefined.

Based on 2 B It can be seen that through the use of field devices according to the invention 22 . 23 the comparison measurement via the fieldbus 26 can be controlled. With the aid of the measurement triggering mechanism according to the invention, if the respective local timers are synchronized, the required measurements can be carried out absolutely synchronously. It is therefore no longer necessary, the DUT field device 22 and the reference field device 23 each equipped with separate service interfaces.

In 3 the measuring system according to the invention is shown in a more detailed block diagram. The measuring arrangement comprises a device under test field device 28 that has a fieldbus interface 29 and a fieldbus 30 with a master 31 and a reference field device 32 that has a fieldbus interface 33 and the fieldbus 30 with the master 31 connected is. On the DUT field device 28 is a first timer 34 arranged, and on the reference field device 32 there is a second timer 35 , Both the first timer 34 as well as the second timer 35 are with one on the master's side 31 arranged system timer 36 synchronized. The system timer 36 sets the system time for the entire in 3 shown measuring arrangement available.

The DUT field device 28 also includes a first sensor 37 , a first control module 38 which controls the performance of the measurement, as well as memory cells 39 in which parameters of the measurement to be carried out, measurement results and calibration parameters can be stored. Accordingly, the reference field device includes 32 a second sensor 40 , a second control module 41 for controlling the reference measurement, as well as memory cells 42 in which parameters of the reference measurement, measurement results and calibration parameters can be stored.

To carry out a comparison measurement between the test device field device 28 and reference field device 32 be a start time 43 and a measurement period 44 from the master 31 from into corresponding addresses of the memory cells 39 . 42 enrolled. This write operation takes place in the acyclic data traffic of the fieldbus 30 , In the first control module 38 will be the start time 43 with the first timer 34 compared time generated. If there is a match, the unit under test leads 28 a measurement by, with the measurement duration 44 is predetermined. The result obtained in this way 45 is under a designated memory address of the memory cells 39 stored. Also the second control module 41 in the test field device 32 performs a comparison between that of the second timer 35 generated time and start time 43 by. When the start time is reached, the reference measurement is started, the duration of which is determined by the duration of the measurement 44 is predetermined. The thus determined reference measurement result 46 is under a designated address of the memory cells 42 stored.

Because the first timer 34 and the second timer 35 both with the system timer 36 synchronized and the respective start time and duration of the test unit field device 28 and from the reference field device 32 measurements carried out, the two measurements are performed synchronously.

From the master 31 out can the measurement result 45 as well as the reference measurement result 46 from the test field device 28 and from the reference field device 32 over the fieldbus 30 be retrieved, the data transfer is again in the acyclic data traffic. On the part of the master 31 can now be judged whether the DUT field device 28 Sufficiently accurate measures or not. This is the result of the measurement 45 with the reference measurement result 46 compared. If the deviation between the two measurement results is below a predefined threshold value, then the test device field device operates 28 sufficiently accurate. In this case, there is no recalibration of the device under test 28 necessary. When the measurement result 45 but outside of the reference measurement result 46 defined tolerance range, then there is a recalibration of the device under test 28 required.

According to a preferred embodiment of the invention, this recalibration is also under the control of the master 31 carried out. For example, both the DUT field device 28 as well as from the reference field device 32 a number of measurements are performed, wherein the physical quantity to be measured is varied. For example, readings can be taken at different pressures, temperatures and at different flow rates. In the case of a flow measurement different liquids with different density can be measured. From the measured values determined in this way, new calibration parameters for the device under test can be obtained 28 determine. These calibration parameters determine how that of the measuring sensor 37 supplied measurement signal can be converted into a physical measurement. The calibration parameters are determined by a calculation unit 47 on the part of the master 31 determined and then via the fieldbus 30 in acyclic operation to the DUT field device 28 transfer. There, the calibration parameters are stored and henceforth used for the conversion of the measurement signal into the measured variable.

The calibration method according to the invention offers the advantage that the calibration measurement via the fieldbus 30 can be controlled and programmed. As a result of the triggering mechanism according to the invention, the latency of the field bus does not adversely affect the temporal accuracy of the measurements. The calibration measurement can be done by the master 31 in accordance with a schedule at regular time intervals, for example at weekly or monthly intervals, in order to achieve the measurement accuracy of the device under test 28 to monitor for longer periods of time. The respective results of the calibration measurements can be documented and archived. This is particularly important in the context of quality management. By regularly checking the field devices used, deterioration of the measuring accuracy as a result of contamination or wear can be detected and corrected at an early stage in order to achieve a defined measuring accuracy of the field used to be able to guarantee advice.

Claims (23)

A field device ( 1 ) of process automation technology, with an interface ( 2 ) for connecting a field bus ( 3 ), characterized by - a timer ( 5 ) for generating a time signal, - a control module ( 11 ) designed to receive one from the fieldbus ( 3 ) from programmable start time ( 8th ) to compare a measurement with the time signal, to start the measurement in case of agreement, and a measurement result ( 13 ) of the measurement under one of the fieldbus ( 3 ) from readable address. field device according to claim 1, characterized in that the time signal with an external system time is synchronized. A fieldbus system with a first field device ( 28 ), which via a field bus ( 30 ) with a higher-level unit ( 31 ), characterized in that the first field device ( 28 ): - a first timer ( 34 ) for generating a first time signal, - a first control module ( 38 ) designed to receive one from the fieldbus ( 30 ) from the programmable first start time of a first measurement with the first time signal to compare, to start the first measurement in agreement, and a first measurement result ( 45 ) of the first measurement under one of the fieldbus ( 30 ) from the readable address, the parent unit ( 31 ) is adapted to the first start time ( 43 ) of the first measurement via the fieldbus ( 30 ) to the first field device ( 28 ) and that of the first field device ( 28 ) determined first measurement result ( 45 ) from the first field device ( 28 ). Fieldbus system according to claim 3, characterized by a reference field device ( 40 ), which is connected to the fieldbus, with a second timer ( 35 ) for generating a second time signal, - a second control module ( 41 ) designed to receive one from the fieldbus ( 30 ) from programmable second start time of a reference measurement to compare with the second time signal to start the reference measurement in case of agreement, and a reference measurement result ( 46 ) of the reference measurement under one of the fieldbus ( 30 ) from readable address. Fieldbus system according to claim 4, characterized in that that it is the first measurement and the reference measurement by one of: volume flow measurements, Mass flow measurements, pressure measurements, temperature measurements, differential pressure measurements, Level measurement, Measurements of the pH, measurements of the integrated volume flow, Measurements of the integrated mass flow. Fieldbus system according to claim 4 or claim 5, characterized characterized in that the first time signal and the second time signal are synchronized with a system time. Fieldbus system according to one of claims 4 to 6, characterized in that the higher-level unit a system timer ( 36 ) for generating a system time, wherein the first timer and the second timer are synchronized with the system time generated by the system timer. Fieldbus system according to claim 6 or claim 7, characterized characterized in that the parent Unit is designed to synchronize the first timer and the second timer with the system time a current one Status of the system time successively to the first timer and to to transmit the second timer. Fieldbus system according to one of claims 4 to 8, characterized characterized in that the parent Unit is designed to perform a comparison measurement the same start time over the fieldbus to the first field device and to the reference field device transferred to. Fieldbus system according to one of claims 4 to 9, characterized in that the first measurement with time synchronization the reference measurement performed becomes. Fieldbus system according to one of claims 4 to 10, characterized in that the superordinate unit designed for this purpose is, additional Measurement parameters via the fieldbus to the first field device and to the reference field device transferred to. Fieldbus system according to claim 11, characterized in that that the extra Measurement parameters include one or more of the following: Measuring mode, measuring method, type of liquid measured, Set volume control. Fieldbus system according to one of claims 4 to 12, characterized in that the superordinate unit designed to is, the first measurement result over the fieldbus from the first field device read out and read the reference measurement result via the fieldbus from the reference field device. Fieldbus system according to claim 13, characterized in that the superordinate unit is designed to determine whether the first measurement result is within a tolerance range to the reference measurement result. Fieldbus system according to claim 13 or claim 14, characterized in that the superordinate unit is designed for this purpose determine if recalibration of the first field device is required is. Fieldbus system according to one of claims 4 to 15, characterized in that the superordinate unit designed to is to automatically recalibrate the first field device if a recalibration of the first field device is required. Fieldbus system according to one of Claims 4 to 16, characterized in that the higher-order unit has a calibration unit ( 47 ) configured to redetermine one or more calibration parameters of the first field device. Fieldbus system according to one of claims 4 to 17, characterized in that the superordinate unit designed for this purpose is, newly determined calibration parameters via the fieldbus to the first field device transferred to. Fieldbus system according to one of claims 4 to 18, characterized in that the superordinate unit designed to is, comparison measurements of the first field device and the reference field device accordingly to schedule automatically at predetermined times. Method for starting a measurement in a field device ( 1 ) of process automation technology, which is an interface ( 2 ) for connecting a field bus ( 3 ), characterized by the following steps: - generating a time signal, - comparing a programmable starting time from the fieldbus ( 8th ) of the measurement with the time signal, - starting the measurement if the start time coincides ( 8th ) with the time signal, - determining a measurement result ( 13 ), - saving the measurement result ( 13 ) under one of the fieldbus ( 3 ) from readable address. Method for checking the calibration of a first field device ( 28 ) by means of a reference field device ( 32 ), the first field device ( 28 ) and the reference field device ( 32 ) via a field bus ( 30 ) with a higher-level unit ( 31 ), characterized by the following steps: - starting a first measurement by the first field device ( 28 ) to one from the field bus ( 30 ) from programmable first start time, - determining a first measurement result ( 45 ), - saving the first measurement result ( 45 ) under an address of the first field device which can be read out from the fieldbus ( 28 ), - starting a reference measurement by the reference field device ( 32 ) to a second start time programmable by the fieldbus, - determination of a reference measurement result ( 46 ), - storing the reference measurement result ( 46 ) under one of the fieldbus ( 30 ) from the readable address of the reference field device ( 32 ), - readout of the first measurement result ( 45 ) from the first field device ( 28 ) and the reference measurement result ( 46 ) from the reference meter ( 32 ) by the superordinate unit ( 31 ). A method according to claim 21, characterized by following further step: Compare the first measurement result with the reference measurement result and determine if recalibration of the first field device is required. A method according to claim 21 or claim 22 by the following further step: if a recalibration of the first field device necessary, automatic determination of new calibration parameters for the first field device, and submit the new calibration parameter via the fieldbus to the first field device.