DE102005031552A1 - Gas sensor measurement unit operation test procedures compare stored time series deviations caused by control of actuator or heater components with reference values - Google Patents

Abstract

A gas sensor measurement unit operation test procedures compares deviations caused by control of actuator or heater components for relaxation of the sensor, detector and operation parameters to determine the component status by comparison of stored variation and response value time series (A, B).

Description

The The invention relates to a method for operating a measuring device according to the generic term of the patent claim 1.

The Field of the invention relates essentially to automatic analyzers, the also as field devices are in use and are used for chemical gas analysis. Possible are but also gas analyzers in the wet chemical field, ie the analysis of liquids. To operating conditions generally monitor such gas analyzers or measuring devices to be able to limit values are used, which, for example, fall short of a minimum flow of measuring media, or if exceeded on the device Generate alarm. Often, however, with the appearance of this message is usually already a simultaneous or even before beginning reduction of the quality the measured values or a failure of the measurement as such. This shows that important information in advance of Alarm messages are not yet available metrologically.

alternative could do this Sensors are attached to the measuring device, which has certain components additionally sensory monitor, taking however additional Operating data arise which must also be evaluated. This conditionally a higher one technical, but also hardware effort from the cost point of view however, rarely is it justifiable.

Of the Invention is therefore the object of a method of the generic type To improve to that with simple and existing means a diagnosis of the measuring device is made possible such that malfunctions in Apron can be detected.

The asked task is in a method of the generic type according to the invention by the characterizing features of claim 1.

Further advantageous embodiment of the method according to the invention are in the specified dependent claims.

core the method according to the invention Here is that a deviating from the measurement process disturbance Control of one or more components of the measuring device generated and then the relaxation of the affected sensor / detector and / or Operating parameter value is determined, and the current relaxation values with Comparing comparison values and automatically the aging state the respective components of the measuring device is determined.

In order to will not be additional Sensor values necessary, but it will be the operating data and detector values used, which are available anyway at the measuring device. When imprinting a now predefined disorder, that as a disorder only because it is different from the actual Measurement task to be changed, now changes are brought about, and after completion of the modulation of such a fault the Relaxation time and / or relaxation behavior back to the Normal value is determined. From this relaxation can be concluded on the Pull the aging state of the measuring device. Previous relaxation data are stored in a data field, being compared here with legacy data can.

is the measuring device new, so can first relaxation data of a conscious or controlled disturbance then are stored as calbration output values. Arises at the relaxation now over the time a significant drift for the worse, i. to an extension the relaxation time, this indicates an aging of a or more of the components of the measuring device out. From the time behavior The relaxation or its development can then be expected errors or maintenance intervals or anticipated future failures of Measuring device to be closed. This always happens when certain limit values or below, so that the desired and otherwise assured Measurement accuracies are no longer achievable.

All in all This results in a prediction of expected malfunctions of measuring equipment of the type mentioned, without the additional Sensors are provided. This will be detector or sensor values used, in any case already before in the measuring device for their operation are implemented. You can do this include temperature sensors at the cuvettes, the detectors themselves, pressure sensors within the piping systems, Etc.

In advantageous embodiment is indicated that the provoked disorder by operation or control of existing actuators or heating elements in the Measuring device is generated. That for diagnosis are usual control signals generated, after which then the relaxation is determined.

Furthermore, it is advantageously configured that the relaxation of a measured value or another Value after a provoked disturbance is stored in correlation to the magnitude of this modulation of this provoked disorder. As a result, the signal output as well as the corresponding response of the system are stored as a correlation and thus evaluable.

Farther is designed that the readings or other values that are at the relaxation result, are stored as time series.

In order to the automatic self-observation of the measuring device becomes historical filed and evaluated, from which tendencies are removable.

The Relaxation data are made by comparison with reference data and also their temporal change followed by the relaxation behavior, and closed for defects in advance becomes. So can be planned in advance, whether the respective measuring device for one following longer Measuring task expectedly trouble-free stays or not.

That the device specific Data in the device or devices addressed in a data network are available has the advantage that such a Whole field system can be constructed, the inventive automatic Device self-diagnosis and their integration into the overall process in this way easy is feasible.

On this way is the entire production process performed on it agreed that said measuring devices as field devices in one Production or monitoring process and that the predictable maintenance of each Organization in the overall process is logistically taken into account.

Here 2 embodiments of the invention will now be described.

Example 1:

A process in which transients obtained data but not yet recorded and therefore not used is calibration. This process must be done regularly in gas concentration measuring instruments to compensate for creeping changes. This generates a wealth of data that has not yet been collected. During calibration, a sudden change in the gas concentration at the inlet of the device is obtained by switching a valve and the system relaxes to the new equilibrium state. This gas concentration is known, the system relaxes to the new gas concentration, in this case it is the zero gas at which the measured value is set to "zero." This reverses changes in the device (zero point drift), ie this value becomes the calibration According to the prior art, only the concentration indicative of the meter at the end of the relaxation is registered and recorded (equilibrium value) .The same is done with the end point of the metering range using an end point gas Component in the concentration that corresponds to the upper measurement range Generally speaking, the dynamics of the process, which in 1 is shown, not registered.

Example 2

Devices for measurement Gas concentrations flow through the gas to be analyzed. One such device So it has a certain volume, which is exposed to the gas to be measured is. Many in today's devices occurring disturbances are due to the fact that gas-carrying Parts wear out; these are seals, hoses, Piping, flanges, etc. If this occurs, then a defect occurs on, and the readings are no longer usable. The detection Such defects before they lead to equipment failure is desirable.

These embodiments are in the 1 and 2 shown and described in more detail.

It shows

1 : Comparison of Curves

2 : Self-diagnosis using the example

1 Two curves (A, B) of the time dependence with which a device for gas analysis adjusts to new gas concentration (eg zero gas) (relaxes). Curve A is the reference curve and is registered with the new device (perfect condition). Curve B is the chronological record of the same process after a certain period of operation. The magnitude of the signal represents the concentration of a component in a gas stream registered by the device; this is recorded as a time function. The differences between reference and current measurement (after × operating hours) are evaluated.

• • dass das System nach × Betriebsstunden später beginnt sich auf die neue Gaskonzentration hin zu verändern; Verzögerung des Absinkens der Kurve B
• • dass das Mess-Signal B nach × Betriebsstunden weniger steil abfällt als das Referenzsignal A.

1 FIG. 10 shows the comparison of a relaxation at a changed concentration of a measurement component in a gas at time zero, ie, for example, a new device (curve A), with the relaxation after x hours of operation on the same gas (curve B). It can be seen

• • That the system starts operating after hours of operation later begins to approach the new gas concentration change; Delay of the decrease of curve B
• • that the measuring signal B falls less steeply after the operating hours than the reference signal A.

These characteristic changes between curve A and B in 1 are caused by changes in the measuring device: Possible changes are degradation of the measuring optics, lower pump performance, higher pressure drop in the measuring device. The significance of impending disturbances and their timing is subject to the characteristics and technical design of the gas analyzer itself. The transient values are collected and used to predict future failures.

2 Representation of a gas-conducting part in a gas analyzer. The gas-carrying line 5 is with a pump 4 equipped with a constant amount of gas through 5 to the measuring device 2 transported for gas concentrations. 1 is a valve that closes at the beginning of the test. The pressure of the gas is by means of a pressure measuring device 3 registered.

• • der Unterdruck baut sich rasch, der Referenzkurve entsprechend, auf: dann ist das System dicht
• • der Druck senkt sich weniger ab als die Referenzkurve vorgibt und die chemische Zusammensetzung des Gases verschiebt sich in die Reichtung der Zusammensetzung von Luft (z.B. sinkt die Konzentration des CO auf Null): dann liegt eine Leckage vor, durch welche Umgebungsluft angesogen wird. Aus der Geschwindigkeit, mit der sich diese Konzentrationsänderung abspielt, wird auf die Größe der Lackage geschlossen
• • der Druck senkt sich weniger ab als die Referenzkurve vorgibt und die chemische Zusammensetzung des Gases bleibt nahezu gleich: dann ist das Ventil defekt und es wird immer noch Prozessgas angesogen.

Since these are creeping processes that cause a failure, it can be detected early (this is in 2 shown):
A gas meter is equipped with a pump 4 equipped, so that the measuring cell 2 be subjected to a constant gas flow. One way to diagnose is to use one of the existing valves 1 in the device (as far as possible in front of the pump) for a few seconds to close while the change in pressure (by means of pressure sensor 3 ) and the measured gas component (by means of analyzer 2 ) in the device. By means of the flow and pressure sensors for normal operation in the device and the gas concentration measuring device, leaks in the system can be inferred. For the following reason:
A pump (a suction pump) ensures that a constant volume flow of the gas to be measured flows in an analyzer. If a valve in front of the pump is closed, the pump builds a negative pressure between the valve and just this pump. This negative pressure can be measured / tracked and recorded by means of a pressure sensor which is present in such devices. Likewise, the change in the concentration of the gas to be measured is registered and recorded in the gas analyzer. Two basic processes can be registered:

• • The vacuum builds up quickly according to the reference curve: then the system is tight
• • The pressure drops less than the reference curve and the chemical composition of the gas shifts to the direction of the composition of air (eg, the concentration of CO drops to zero): then there is a leak through which ambient air is sucked. From the speed with which this concentration change takes place, the size of the coating is closed
• • The pressure drops less than the reference curve and the chemical composition of the gas remains almost the same: then the valve is defective and process gas is still sucked in.

These reversible disorder and the associated relaxation takes only a few seconds, but the insights gained are great.

A The essential prerequisite is the possibility of data storage and processing in the device or its immediate surroundings.

Claims (7)

Method for operating testing of a measuring device, characterized in that a deviating from the measurement process disturbance generated by driving one or more components of the measuring device and then the relaxation of the affected sensor / detector / operating parameter value is determined, and the current relaxation values compared with comparative values and automatically the aging state of the respective component of the measuring device is determined. Method according to claim 1, characterized in that that the provoked disorder by operation or control of existing actuators or heating elements in the Measuring device is generated. Method according to one of the preceding claims, characterized characterized in that the relaxation of a measured value or a other value after a provoked disturbance correlates to the size of this Control of this provoked disorder is stored. Method according to claim 3, characterized that the readings or the rest Values resulting from the relaxation as a temporal data series be stored. Method according to claim 4, characterized in that that the relaxation data by comparison with reference data and also their temporal change of relaxation behavior, and defects in advance is closed. Method according to one of the preceding Claims, characterized in that the device-specific data in the device or device-addressed in a data network are available. Method according to one of the preceding claims, characterized characterized in that said measuring devices are used as field devices in a production or monitoring process and that the predictable maintenance of each Organization in the overall process is logistically taken into account.