METHOD FOR IN-SITU CALIBRATION OF AN ANALOG MEASUREMENT TRANSMISSION PATH AND CORRESPONDING APPARATUS

Abstract

A method for in-situ calibration of an analog measurement transmission path coupled with the determining and/or monitoring of a process variable of a medium is disclosed, wherein analog electrical signals are transmitted via the measurement transmission path from a control/evaluation unit to a control unit, wherein the control/evaluation unit is associated with a sensor, which determines and/or monitors the process variable based on at least one component sensitive for the process variable. The sensor is operated either in a measuring mode or in a simulation mode, wherein, in the simulation mode, the control/evaluation unit outputs for a set time span an analog electrical signal, which is unequivocally recognizable as simulated and is recognized and registered by control unit, and the calibrating of the measurement transmission path is performed, in that the control unit determines the deviation between the analog electrical signal and the registered analog electrical signal.

Claims

1-15. (canceled)

16. A method for in-situ calibration of an analog measurement transmission path coupled with the determining and/or monitoring of a process variable of a medium, the method comprising: providing a sensor in communication with a control unit, the sensor including a control/evaluation unit and at least one component sensitive to a process variable, the sensor embodied to determine and/or monitor the process variable using the at least one component, wherein analog electrical signals are transmitted via a measurement transmission path from the control/evaluation unit to the control unit; operating the sensor in either a measuring mode or in a simulation mode; when in the measuring mode, transducing measured values of the at least one component of the sensor into an analog electrical measurement signal representing the process variable using the control/evaluation unit; when in the simulation mode, outputting for a set time period using the control/evaluation unit at least one analog electrical calibration signal that is unequivocally recognizable as simulated and is recognized and registered by the control unit; and when in the simulation mode, calibrating the measurement transmission path, wherein the control unit determines a deviation between the analog electrical measurement signal provided by the control/evaluation unit and the registered analog electrical calibration signal.

17. The method of claim 16, further comprising, when in the simulation mode, storing the deviation between the analog electrical measurement signal provided by the control/evaluation unit and the analog electrical calibration signal registered at the control unit.

18. The method of claim 16, further comprising, when in the measuring mode: when the control unit registers a signal having value less than a minimum analog electrical signal, triggering a first alarm; and when the control unit registers a signal having value greater than a maximum analog electrical signal, triggering a second alarm different from the first alarm.

19. The method of claim 16, further comprising: when in the simulation mode, outputting a preset pattern of analog electrical signals from a fixedly defined value range using the control/evaluation unit; and using the control unit to detect when the sensor is being operated in the simulation mode based on the preset pattern of analog electrical signals.

20. The method of claim 19, wherein the fixedly defined value range is within a range between a minimum analog electrical signal and a maximum analog electrical signal.

21. The method as claimed in claim 20, wherein: analog electrical measurement signals output in the measuring mode are from a useful range; the useful range is parameterized such that the useful range corresponds to a value range between a minimum value and a maximum value of the process variable; the useful range is a real portion of the range between the minimum analog electrical signal and the maximum analog electrical signal; and the value range does not overlap the useful range.

22. The method of claim 21, further comprising, when in the simulation mode, outputting a good message, a warning report and/or an error report concerning a state of the sensor, wherein: in the case of the good message, the control/evaluation unit outputs a first preset pattern of analog electrical signals; in the case of a warning report, the control/evaluation unit outputs a second preset pattern of analog electrical signals different from the first pattern; in the case of an error report, the control/evaluation unit outputs a third preset pattern of analog electrical signals different from the first pattern and second pattern; the analog electrical signals for outputting the good and warning reports lie in the value range; the analog electrical signals for outputting the error report lie outside the value range; and the good and/or warning report is stored.

23. Method as claimed in claim 22, wherein the sensor is returned to the measuring mode after output of a good and/or warning report.

24. The method of claim 16, further comprising transferring into the simulation mode when the at least one component of the sensor assumes a fixed value.

25. The method of claim 16, further comprising switching into the simulation mode in response to a manual trigger.

26. The method of claim 25, wherein the manual trigger is a voltage interruption of the sensor, an actuation of a magnetic switch, and/or a near-field communication.

27. An apparatus for in-situ calibration of an analog measurement transmission path coupled with the determining and/or monitoring of a process variable of a medium, the apparatus comprising: a sensor including at least one sensitive component and a control/evaluation unit; and a control unit, wherein the control/evaluation unit is in communication with the control unit via the measurement transmission path, and wherein: the control/evaluation unit is configured to operating the sensor in either a measuring mode or in a simulation mode; when in the measuring mode, transducing measured values of the at least one component of the sensor into an analog electrical measurement signal representing the process variable using the control/evaluation unit; when in the simulation mode, outputting for a set time period using the control/evaluation unit at least one analog electrical calibration signal that is unequivocally recognizable as simulated and is recognized and registered by the control unit; and when in the simulation mode, calibrating the measurement transmission path, wherein the control unit determines a deviation between the analog electrical measurement signal provided by the control/evaluation unit and the registered analog electrical calibration signal.

28. The apparatus of claim 27, wherein: the sensor has a temperature sensitive component and a reference element, which experiences a phase transformation at at least one predetermined temperature point; the control/evaluation unit calibrates the temperature sensitive component at the predetermined temperature point and determines a deviation of the temperature sensitive component from the predetermined temperature point; and the control/evaluation unit causes the sensor to switch from the measuring mode to the simulation mode when the reference element passes through the predetermined temperature point.

29. The apparatus as claimed in claim 28, wherein: when in the simulation mode and after calibrating the temperature sensitive component and the measurement transmission path, the control/evaluation unit outputs for a set time period a constant analog electrical signal that corresponds to the deviation of the temperature sensitive component from the predetermined temperature point provided by the reference element; and based on a deviation of the constant electrical signal output by the control/evaluation unit from a fixed analog electrical signal and based on the parameterization of the measurement transmission path, the control unit detects the deviation of the temperature sensitive component from the predetermined temperature point.

30. The apparatus as claimed in claim 29, wherein, when in the simulation mode, the control unit stores the deviation of the temperature sensitive component from the predetermined temperature point.

31. The apparatus as claimed in claim 29, wherein: when the deviation of the temperature sensitive component from the predetermined temperature point subceeds a fixed lower limit value, the control/evaluation unit produces a good message; and when the deviation of the temperature sensitive component from the predetermined temperature point exceeds a fixed upper limit value, the control/evaluation unit produces a warning report.

Description

[0035] The invention will now be explained in greater detail based on the appended drawing, the figures of which show as follows:

[0036] FIG. 1 a schematic representation of an embodiment of the apparatus of the invention;

[0037] FIG. 2 a ramp profile, which can be used for calibrating the measurement transmission path; and

[0038] FIG. 3 the different signal regions of the analog electrical signal.

[0039] FIG. 1 shows the schematic arrangement of the sensor 2, the measurement transmission path 1 and control unit 3, as well as the different sensor components. The sensor includes, in such case, at least one sensitive component 22 and a control/evaluation unit 21. The signal direction of the analog electrical signal is directed from the control/evaluation unit 21 via the measurement transmission path 1 to the control unit 3.

[0040] In an especially preferred embodiment, the sensitive component 22 is composed of a temperature sensor. A reference element 23 is used for calibrating the first temperature sensitive component 22. The calibrating of the sensor occurs at a fixed temperature point, at which the reference element 23 experiences a phase transition. In this example of an embodiment, the simulation mode for calibrating the measurement transmission path 1 can preferably be triggered by the fact that the fixed temperature point for calibrating the sensor 2 was passed through. Then, one after the other, both the sensor 2 as well as also the analog measurement transmission path 1 are calibrated. Then, the information established in the case of the calibrating can, in each case, for the sensor 2 and the measurement transmission path 1, be transmitted and documented in individual and/or combined, automatically produced, calibration protocols.

[0041] FIG. 2 shows a ramp profile, such as could be used in the simulation mode for calibrating the measurement transmission path 1 in the time span between t.sub.1 and t.sub.2. The measuring range 5 is, in such case, defined by S.sub.a and S.sub.c. The ramp profile samples the total measuring range 5. This happens in the illustrated example in that the control/evaluating unit 21 outputs, one after the other, for defined periods of time, constant signals S.sub.a, S.sub.b and S.sub.c, wherein S.sub.a is less than S.sub.b and S.sub.b is less than S.sub.c. Since the control unit 3 is embodied such that it knows the profile output from the control/evaluating unit 21, the control unit 3 can calibrate the measurement transmission path. In a variant, all following signals are then correspondingly corrected.

[0042] If the preferred embodiment of the invention contains a temperature sensitive component 22 and a reference element 23, the control/evaluation unit 21 then additionally outputs the deviation of the first temperature sensitive component from the temperature point provided by the reference element 23. In such case, it is established, with which signal the deviation should be output (dashed line). This set signal can, in such case, be set by the user. A possibility, in such case, is to set the signal, with which the deviation is to be output, at start-up of the sensor. The user can, for example, set a parameter at a certain value. The control unit can determine the deviation S and, based on the parameterization and the calibration of the measurement transmission path, then convert this into a temperature difference. The temperature difference can then be stored and/or furnished in a calibration protocol.

[0043] FIG. 3 shows the relevant signal regions of the analog electrical signal and their positions relative to one another. The measuring range 5 is, as a rule, a standardized measuring range 5. If the analog electrical signal is an electrical current, the standardized region is preferably from 4-20 mA. Outside of the measuring range 5 lie the standardized alarm limits S.sub.min=3.8 mA and S.sub.max=20.5 mA. The control unit 3 triggers a first alarm, when it registers an electrical current, whose value is less than 3.8 mA, and a second alarm different from the first alarm, when it registers an electrical current, whose value is greater than 20.5 mA. In an embodiment of the invention, the region between 3.8 mA and 20.5 mA can be utilized for display of the simulation mode.

[0044] The useful range 4 is contained in the measuring range. The useful range is, in such case, so selected that it corresponds to the maximum and minimum that the process variable assumes in the process. It is a real portion of the measuring range. This means that there are always unused regions in the measuring range. For example, the standardized electrical current range of 4-20 mA parameters the temperature interval from 50-180 C., while, in the application, only minimum temperatures of 80 C. and maximum temperatures of 150 C. are achieved. Therefore, there is an unused signal range contained in the measuring range. Especially, the unused signal range is a first signal range, which corresponds to temperatures between 50-80 C., and a second signal range, which corresponds to temperatures between 150-180 C. This unused signal range can be utilized in the present invention preferably for display of the simulation mode. In preferred manner, in such case, the lower barrier of the first unused (lower) signal range is expanded down to 3.8 mA, and the upper barrier of the second unused (upper) signal range is expanded up to 20.5 mA. The pattern of signals for display of the simulation mode is then preferably so selected that alternately values from the lower and the upper unused region are output from the control/evaluation unit. The idea, in such case, is to detect the simulation mode unequivocally, in that a signal sequence output by the control/evaluation unit is present in the measuring mode with disappearing probability.

LIST OF REFERENCE CHARACTERS

[0045] 1 measurement transmission path

[0046] 2 sensor

[0047] 21 control/evaluation unit

[0048] 22 first sensitive component

[0049] 23 reference element

[0050] 3 control unit

[0051] 4 useful range

[0052] 5 measuring range

[0053] S.sub.min minimum analog electrical signal

[0054] S.sub.max maximum analog electrical signal

[0055] S analog electrical signal, which corresponds to the deviation of the first temperature sensitive component from the temperature point provided by the reference element