DE102019112018A1 - Method for setting up a calorimetrically operating flow control sensor - Google Patents

Abstract

One method is used to set up the upper switching point of a calorimetrically operating flow control sensor with its sensor head immersed in a line through which a gaseous medium flows. It is provided that - the gaseous medium is conveyed through the line at its flow rate intended for normal operation, - the flow rate of the conveyed gaseous medium is determined by the flow control sensor and - the flow rate of the gaseous medium determined by the flow control sensor as the setpoint value of the Flow velocity is stored and, based on the determined target value, the upper switching point is either specified as a predefined deviation from the target value or is set and stored, the measuring range of the flow control sensor being designed so that the target value at least by the value of the deviation to the upper switching point is spaced from its detectable maximum flow velocity.

Description

The invention relates to a method for parameterizing the upper switching point of a calorimetrically operating flow control sensor.

Flow control sensors are used to monitor the flow rate of a gaseous medium conveyed through a line. Such sensors have a sensor head which is immersed in the line carrying the gaseous medium and which flows against the gaseous medium when the gaseous medium is in operation. The line to which such a flow control sensor is connected is typically part of a larger system, for example an air conditioning system, an extraction system, an air lubrication system or the like. In such systems, the monitoring of the flow rate is used to monitor the intended operation of the system. If the system is, for example, one with which bearings are to be lubricated and kept clean with an air stream mixed with oil, a hose tear can be detected by means of such a flow control sensor connected to a supply line. If the hose breaks, the flow speed of the gaseous medium conveyed through the line increases, here: typically air, significantly. If the hose breaks, the counterpressure opposing the conveying operation is reduced, which leads to an increase in the flow velocity. If such a sudden change in flow rate is detected by the flow control sensor, it emits an interference signal or a command, for example an operational interruption command. The flow control sensor reacts to a change in the flow rate of the gaseous medium flowing through the line when a predetermined threshold value for the flow rate is exceeded. Since the flow control sensor performs an action when the threshold value is exceeded, this threshold value is also addressed as a switching point. If the flow control sensor is used to monitor an increase in flow velocity, as in the example described above, the switching point is addressed as the upper switching point. Such a flow control sensor can also be used to monitor a drop in flow velocity, for example when it comes to monitoring the degree of contamination of filters in air conditioning systems. The switching point that is then effective is addressed as the lower switching point.

Before commissioning a system, the operation of which is to be monitored by such a flow control sensor, the switching point relevant for the intended application - upper and / or lower switching point - must be set up in the flow control sensor. For this purpose, the flow control sensor (s) are first switched to a setup or parameterization mode. A flow control sensor with a measuring range in which the flow rate of the gaseous medium conveyed through the line is preferably approximately in the middle of the total measuring range in expected normal operation is used for the respective application. This normal flow velocity is assumed to be constant, but in reality it is subject to certain fluctuations. To set up the upper or lower switching point, the gaseous medium is conveyed through the line at the rate at which the switching point or the flow control sensor is to switch, which corresponds to the upper or lower measuring range limit. The respective switching points are then within the measuring range set up in this way, for example at 20% (lower switching point) and 80% (upper switching point). In order to determine the upper switching point, the flow rate of the flow control sensor must be that which is intended to define the upper limit of the total measuring range. The deviation of the switching point from the normal flow rate is greater than the flow rate fluctuation occurring in normal operation. If the total measuring range of such a flow control sensor is specified between 0% and 100% and the normal flow rate is 50% or approx. 50%, the deviation from the upper or lower switching point of 30% or approx. 30% is selected depending on the application. If the measuring range is determined by the corresponding flow of the gaseous medium onto the flow control sensor, this is saved. If an upper switching point and a lower switching point are to be parameterized, this procedure must then be repeated for the other switching point. If the switching point or points are set up, the parameterization mode of the flow control sensor is ended and the system can be put into operation.

Even if a reliable flow rate monitoring of a gaseous medium flowing through a line is possible with such flow control sensors, the device, especially of the upper switching point, is sometimes not without problems. The problem arises from the fact that in the systems in which such a flow control sensor is integrated, the flow rate of the gaseous medium that is required to increase the flow rate can sometimes only be generated with a great deal of effort to set up the upper switching point. In this context, it should be emphasized that the flow velocity of the gaseous medium to be detected with the flow control sensor must be greater than the flow velocity at which the upper switching point should be. In an air lubrication system in which the gaseous medium is conveyed against a counterpressure provided by the bearing openings, it is not possible with the existing conveying units to be able to provide the flow velocity in the line required for the parameterization of the upper switching point. In order to still be able to set up the upper switching point, a line break is simulated by opening the air supply line at a suitable point, downstream of the arrangement of the flow control sensor in the direction of flow of the gaseous medium. This is typically done at the line coupling to the lubrication point. This procedure is complex and can only be carried out when the system is not in operation.

On the basis of this discussed prior art, the invention is therefore based on the object of proposing a method with which the upper switching point of a flow control sensor can be set up with less effort and, in particular, even while the system is in operation.

• - das gasförmige Medium mit seiner für einen Normalbetrieb vorgesehenen Strömungsgeschwindigkeit durch die Leitung gefördert wird,
• - die Strömungsgeschwindigkeit des geförderten gasförmigen Mediums von dem Strömungskontrollsensor ermittelt wird und
• - die von dem Strömungskontrollsensor ermittelte Strömungsgeschwindigkeit des gasförmigen Mediums als Soll-Wert der Strömungsgeschwindigkeit gespeichert wird und ausgehend von dem ermittelten Soll-Wert der obere Schaltpunkt entweder als vordefinierte Abweichung von dem Soll-Wert vorgegeben ist oder eingestellt und gespeichert wird, wobei der Messbereich des Strömungskontrollsensors ausgelegt ist, dass der Soll-Wert zumindest um den Wert der Abweichung zum oberen Schaltpunkt von seiner erfassbaren Maximalströmungsgeschwindigkeit beabstandet ist.

This object is achieved according to the invention by a method for parameterizing the upper switching point of a calorimetrically operating flow control sensor immersed with its sensor head in a line through which a gaseous medium flows

• - the gaseous medium is conveyed through the line at its intended flow rate for normal operation,
• - The flow rate of the conveyed gaseous medium is determined by the flow control sensor and
• - The flow rate of the gaseous medium determined by the flow control sensor is stored as the target value of the flow rate and, based on the determined target value, the upper switching point is either specified as a predefined deviation from the target value or is set and stored, with the measuring range of the Flow control sensor is designed that the target value is spaced at least by the value of the deviation from the upper switching point from its detectable maximum flow speed.

With this method it is not necessary to set up the upper switching point of the flow control sensor in the line to which the flow control sensor is connected to convey the gaseous medium at the flow rate required to establish the upper switching point. In the method according to the invention, the normal flow rate is recorded with the flow control sensor, i.e. the flow rate at which the gaseous medium flows through the line when the system to which this line belongs is in normal operation. The reference value for setting the upper switching point in this method is the normal flow velocity. In the previously known method, as described at the outset, the reference point is the maximum detectable flow velocity, which is specified as 100% in the previously known method. In normal operation it is provided that the flow velocity of the gaseous medium is constant within the possible fluctuation range. The determined flow velocity is saved as a target value. According to one embodiment of such a flow control sensor, it has a corresponding electronic memory. If the flow control sensor is connected to a control device, for example a central control device, for example via a data bus, the setpoint value can also be stored elsewhere. In the claimed method, the target value is the basis or the reference point for setting up the upper switching point. This can, for example, be defined as 100% on a relative display area. The upper switching point is defined as the deviation from the target value. It is possible that the deviation of the upper switching point from the target value is specified as a relative and / or absolute value. If a relative deviation is provided, in an embodiment in which the target value is 100%, the upper switching point can be 200%. Alternatively, the deviation of the upper switching point from the target value can be set individually. The latter is also possible if a predefined upper switching point is to be brought to a different deviation value than that specified.

In this method, a flow control sensor is used, the total measuring range of which is designed so that the target value is at least spaced apart by the value of the predefined or desired deviation from the upper switching point from the maximum flow velocity that can be detected with the flow control sensor. This measure is intended to ensure that the set upper switching point is always within the measuring range even if there are fluctuations in the measuring accuracy of the flow control sensor. The distance between the upper switching point and the The maximum flow rate therefore need not be selected to be large or excessively large. The same applies in the event that a lower switching point should also be set up for the flow control sensor. The real measuring range of the flow control sensor is typically used, based on the target value, which is defined as 100%, for example, to provide the deviation from the upper and possibly the lower switching point in the form of a percentage deviation from the target value, with the upper switching point is defined and set up at 200% and, if available, the lower switching point at 0%. This useful area is a section from the flow velocity range that can actually be detected with the flow control sensor. The extent of the deviation of the upper and, if present, also the lower switching point from the target value will be documented with such an amount that the change in flow rate to be detected, indicating an error in the operation of the system, is reliably detected, but incorrect switching triggers as a result of fluctuations in normal operation are effectively avoided.

From the above it follows that within the actually detectable measuring range of the flow control sensor, based on the nominal value representing the normal flow velocity, this value and the deviation from the upper switching point and, if available, also from a lower switching point, are in any one within the real total measuring range Excerpt can be settled and defined or escalated. Both the selection of the section as a display area and the scaling of the same - the measuring range between the target value and the upper switching point or, if available, the measuring range between the lower and the upper switching point - can thus be freely defined with regard to the scaling.

If an upper switching point and a lower switching point are to be set up for a flow control sensor, the respective deviation from the target value does not have to be the same. When using such a flow control sensor in an air lubrication system, especially if oil is added as a lubricant to the gaseous medium, the deviation to the lower switching point can be selected to be smaller than to the upper switching point, since the intended lubrication may no longer be given depending on the design of the system when the flow rate of the gaseous medium transporting the oil is already experiencing a lower flow rate reduction compared to the flow rate during normal operation. In an oil-air lubrication system, such as that used for the lubrication of industrial systems such as continuous casting systems, rolling mills and the like, if the normal flow rate is assumed to be 3 m / sec, for example, the upper switching point for a flow rate between 5 m / sec and 6 m / sec, while the deviation from the lower switching point is only 1 m / sec and thus the lower switching point is set at a flow velocity of 2 m / sec.

The target value as well as the upper switching point and, if available, the lower switching point can be displayed on the flow control sensor. For this purpose, according to one embodiment, the flow control sensor has a display designed as a display on which these values are or can be displayed as absolute values. In addition to or instead of absolute values, relative values can also be shown on the display, namely the position of the switching point or points as a percentage on the scale of the set display range from 0% to 200%, for example. The relative scaling within this range can of course also be selected differently, for example from 0% to 100%. The target value would then be 50% if it was in the middle between the upper switching point and the lower switching point.

In one embodiment of such a flow control sensor, it is designed so that its measurement sensitivity and thus the overall measurement range can be established. When using such a flow control sensor, it is possible to place the recorded normal flow velocity - the setpoint value - within the total measuring range by adapting the sensor sensitivity accordingly to the point that is favorable for its parameterization and thus for setting up his or her switching points. If, for example, only an upper switching point is to be parameterized with a relatively large distance from the target value, the sensitivity of the flow control sensor will be set after the normal flow has been recorded so that it is, for example, in the range of 20% to 30% of the total measuring range that can actually be recorded with the flow control sensor 0% to 100%.

The above information on the position of the switching points within the total measuring range of the flow control sensor is exemplary information. It goes without saying that the upper switching point and also the lower switching point, as well as the position of the target value within the total measuring range, can be freely selected, taking into account the necessary boundary conditions.

To record the target value, the system in which the line with the flow control sensor is integrated is operated in normal operation and the flow rate of the gaseous medium in the line is recorded by means of the flow control sensor over a certain time at a certain sampling rate. The flow velocity values obtained are then evaluated to define a flow velocity value as a setpoint value, for example by averaging, which can also be carried out in a weighted manner. In this way, a flow rate fluctuation inherent in operation of the system flows into the determination of the setpoint value as the normal flow rate. The setpoint value can be set accordingly precisely within the total measuring range despite fluctuations in the normal flow velocity. The fluctuation range of the normal flow velocity can also be evaluated. A range of fluctuation in relation to the normal flow velocity can then be defined. A specified switching point or a switching point to be set up would have to lie outside the range of fluctuation of the normal flow velocity in order to avoid incorrect switching. In this respect, the normal flow velocity fluctuation determined can serve as a basis for determining a flow velocity distance to be maintained between a switching point and the fluctuation range.

By recording the normal flow speed over a certain period of time, the flow speed range can be dimensioned relatively narrow without triggering the switching point, whereby the requirement of causing as few incorrect switching as possible is still met. The reason for this is that the output for the parameterization of the upper and possibly also the lower switching point is the normal flow rate of the gaseous medium conveyed through the line.

In previously known methods, the parameterization takes place on the basis of the measured value range provided by the flow control sensor used and the defined upper switching point and the possibly defined lower switching point. How high the normal flow velocity actually is is not recorded in the prior art discussed at the beginning.

It has already been explained above that the particular advantage of this method is its suitability for performing the flow control sensor device while the system is in operation. This advantage also allows a system in which the line is integrated with the flow control sensor to be operated in different operating modes, that is to say with different flow speeds of the gaseous medium through the line. It goes without saying that, in every operating mode, the line with the flow control sensor promotes a constant normal flow velocity with its system-related fluctuations. As soon as the system is operated in a new operating mode, which results in a different normal flow rate of the gaseous medium, the flow control sensor is re-parameterized or its upper and possibly lower switching point is set up anew. If the flow control sensor is connected to a central control unit, this device can be triggered by the central control unit by means of a corresponding parameterization command. An operational shutdown is not necessary for this.

In another embodiment, the flow control sensor is designed to be self-learning with regard to a changing normal flow rate of the gaseous medium conveyed through the line. For this purpose, the normal flow velocity detected by the flow control sensor is recorded and evaluated at a certain frequency (rate), for example as was explained above for determining the target value, but with a typically lower frequency and over a significantly longer period of time. If a normal flow rate change is determined that is outside a specified tolerance range, the flow control sensor is re-parameterized with regard to its upper and, if available, lower switching point based on this newly determined normal flow rate - the new target value. In this way, the switching point (s) is or are automatically adapted to a changed normal flow velocity. Even with normal flow velocities changing to a certain extent, the probability is not increased that there will be an incorrect switching. Finally, the value of the deviation of the switching point (s) from the target value remains the same.

In systems that work with the delivery of gaseous media, it is sometimes necessary to distinguish between summer operation and winter operation due to environmental conditions that change due to the seasonal change. In the case of methods from the prior art, as described at the outset, such a change means a new parameterization of the flow control sensors, which is not only labor-intensive, but also necessarily requires an operational standstill. This applies in particular to systems in which a large number of such flow control sensors are typically used. If the method is designed as outlined above, such a new parameterization of the flow control sensor (s) takes place automatically and in particular without interrupting operation. In principle, such an automatic new parameterization can also be carried out at shorter time intervals or also continuously. It goes without saying that the flow velocity range in which such an automatic new parameterization takes place has a smaller deviation from the setpoint value than the upper and possibly the lower switching point.

In a preferred embodiment it is provided that an oil-air lubrication system is equipped with such flow control sensors. It can be provided that air or another gaseous medium flows against the flow control sensor and oil is only introduced into the flow control sensor downstream of the flow control sensor with respect to the direction of flow of the conveyed gaseous medium. It is also possible for the gaseous medium already mixed with oil to flow against such a flow control sensor.

The invention has been described on the basis of exemplary embodiments. Without departing from the scope of the applicable claims, there are numerous further possibilities for a person skilled in the art to implement them without this having to be explained in detail in the context of these explanations.

Claims (8)

Method for setting up the upper switching point of a calorimetrically operating flow control sensor with its sensor head dipping into a line through which a gaseous medium flows, wherein - the gaseous medium is conveyed through the line at its intended flow rate for normal operation, - The flow rate of the conveyed gaseous medium is determined by the flow control sensor and - The flow rate of the gaseous medium determined by the flow control sensor is stored as the target value of the flow rate and, based on the determined target value, the upper switching point is either specified as a predefined deviation from the target value or is set and stored, with the measuring range of the Flow control sensor is designed that the target value is spaced at least by the value of the deviation from the upper switching point from its detectable maximum flow speed. Procedure according to Claim 1 , characterized in that in the process of parameterizing the flow control sensor, a lower switching point is also set up, in that the lower switching point is specified as a predefined deviation from the nominal value or is set and stored after the target value has been recorded, the measuring range of the flow control sensor is designed so that the target value is at least spaced apart by the value of the deviation from the lower switching point from the detectable minimum flow velocity. Procedure according to Claim 1 or 2 , characterized in that the target value and the upper switching point and / or the lower switching point are displayed on a display of the flow control sensor. Method according to one of the Claims 1 to 3 , characterized in that the flow control sensor is re-parameterized with respect to its upper switching point and / or, if available, with respect to its lower switching point at time intervals during pumping operation of the gaseous medium through the line. Method according to one of the Claims 1 to 4th , characterized in that the actual flow rate of the gaseous medium is recorded at a specified frequency and the actual flow rate is evaluated in relation to a deviation from the stored target value and that when a predefined deviation threshold amount is detected, the flow control sensor with regard to its The upper and, if available, lower switching point is parameterized as the new setpoint with this determined actual flow rate. Method according to one of the Claims 1 to 5 , characterized in that the method is carried out on a flow control sensor which is mounted on a line through which the gaseous medium is conveyed at different normal flow rates in different operating modes and that at the beginning of a changed operating mode, the flow control sensor is parameterized to the new operating mode. Method according to one of the Claims 1 to 6th , characterized in that the method is carried out on a flow control sensor connected to an oil-air lubrication line of an oil-air lubrication system for supplying lubrication points of an industrial system. Method according to one of the Claims 1 to 7th , characterized in that a plurality of each to one of a gaseous medium flow control sensors connected to the flow-through line are connected to a central control unit and that a parameterization command is issued from the central control unit to the flow control sensors when the target value is to be re-parameterized and at least the upper switching point is to be re-established.