EP2091030A1 - Robust evaluation of a temperature measurement signal by means of dynamic adjustment of a computational model - Google Patents

Abstract

The device (110) has a modeling unit (120) i.e. adaptive filter, including an input (121) for picking up an input signal (ntc-in) that is indicative of a temperature measurement signal, another input (122) for picking up a feedback signal (slope), and an output (123) for outputting an output signal (iir-model, pre-temp, virtual-temp). The output signal is generated depending on the input signal and the feedback signal by using a computational model that is stored in the modeling unit, where the feedback signal is directly and indirectly dependent on the output signal. Independent claims are also included for the following: (1) a method for evaluating a temperature measurement signal that is variable over time of a temperature measurement facility (2) a computer-readable storage medium having computer-executable instructions for evaluating a temperature measurement signal being variable over time of a temperature measurement facility (3) a program element for evaluating a temperature measurement signal being variable over time of a temperature measurement facility.

Description

The present invention relates to the technical field of evaluation of measurement signals of a temperature measuring device for the purpose of at least partially eliminating a thermal inertia, which are caused by one or more heat capacities, in particular in the case of strong temperature changes. In particular, the present invention relates to an apparatus and a method for evaluating a temperature measurement signal of a temperature measuring device using a computer model. Furthermore, the present invention relates to a danger detector for outputting an alarm message as a function of a temperature detected within a monitoring area, the danger detector having a device of the type mentioned above. In addition, the present invention relates to a computer-readable storage medium and to a program element which contain instructions for carrying out the method according to the invention for evaluating a temperature measurement signal of a temperature-measuring device.

Known thermal hazard detectors include at least one temperature sensor for detecting a temperature within a monitoring range. In order to ensure a fast response and thus meet the commercial standards EN54-5, UL521 and FM3210, the temperature sensor should be as free from surrounding thermal mass as possible.

However, thermal decoupling between the temperature sensor and adjacent thermal masses is limited in practice.

For example, a spatial separation between the temperature sensor and adjacent thermal masses would require a relatively large cavity within a thermal hazard alarm. In order to ensure a good thermal coupling of the temperature sensor to the monitoring area, this cavity should be well flowed through by the ambient air. Furthermore, the temperature sensor should be located in the middle of the cavity. In particular, in combination detectors, which in addition to a thermal sensor input yet another, for example, have an optical sensor input, such a large cavity is not available due to space problems in the rule. In addition, the effective space requirement of such a hazard detector would be very large. This would be unsatisfactory also from an aesthetic point of view.

In addition, there are also restrictions imposed by law on the location of a temperature sensor. This must be protected, for example, from mechanical influences, which means that the temperature sensor can not be mounted completely freely and thus always has an unavoidable and not inconsiderable thermal coupling to other components of the danger detector.

In order to improve the response of a thermal hazard alarm, it is also known to condition the primary temperature measurement signal of a temperature sensor with a view to a faster signal rise with larger temperature changes. As is known, this can be done in an evaluation logic of a thermal hazard alarm. The evaluation logic often includes a thermal model of the temperature sensor and / or the housing of the danger detector. By an appropriate procedure involving inversion of this thermal model, the signal evaluation can be improved for faster response. In this case, a so-called. Virtual temperature is calculated, which then represents the alarm criterion for the thermal hazard detector.

1. 1) Vom Prinzip her ist jede Modellierung des Ansprechens des Temperatursensors und/oder des Gehäuses ein Tiefpass. Die Modellinversion ergibt demzufolge vom Verhalten her einen Hochpass. Das bedeutet, dass z.B. bei Sprungantworten die Modellinversion zu Überschwingern neigt. Dies stellt ein gängiges Problem in der Regelungstechnik dar. Wird ein Überschwinger jedoch zu groß, kann versehentlich ein unerwünschter Falschalarm ausgelöst werden. Deshalb können entsprechende Gefahrmelder vor allem die in Europa geltende gesetzliche Norm EN54-5 und die in China geltende Norm GB4716 häufig nicht erfüllen, welche u. a. vorschreiben, dass bei einer abrupten Temperaturänderung von 5 Grad Celsius auf 50 Grad Celsius kein Alarm ausgelöst werden darf. Dies wird auch als sog. Step Response Test bezeichnet.
2. 2) Die amerikanische gesetzliche Norm FM3210 für thermische Gefahrmelder weist jedem Melder einen sogenannten RTI (rate of time index) Wert zu. Dieser Wert wird im wesentlichen über den sogenannten "plunge tunnel test" ermittelt. Dabei wird gemessen, wie schnell ein thermischer Gefahrmelder ein Alarmsignal ausgibt, wenn er abrupt in einen 197° Celsius heißen Ofen eingeführt wird. Wird dann beispielsweise aufgrund der oben beschriebenen Limitation 1) zum Zwecke der Reduzierung von Überschwingern eine künstliche Verzögerung der Ansprechempfindlichkeit eingeführt, beispielsweise in Form einer Anstiegsbegrenzung ("slope limitation"), so wird der thermische Gefahrmelder zu spät alarmieren und keinen gültigen RTI Wert erhalten. Damit ist eine legale Vermarktung eines derartigen Gefahrmelders in den USA nicht möglich.

However, such a rigid implementation of the inversion of a thermal model for signal evaluation has the following disadvantages, among others:

1. 1) In principle, any modeling of the response of the temperature sensor and / or the housing is a low pass. The model inversion thus results in a high pass behavior. This means that, for example, the model inversion tends to overshoot in the case of step responses. This is a common problem in control engineering. However, if an overshoot becomes too large, an unwanted false alarm may be triggered inadvertently. For this reason, the corresponding hazard alarm devices are often unable to comply with the legal standard EN54-5 in force in Europe and the GB4716 standard in China, which stipulates, among other things, that no alarm be triggered in the event of an abrupt temperature change from 5 degrees Celsius to 50 degrees Celsius. This is also called a so-called step response test.
2. 2) The American standard FM3210 for thermal hazard detectors assigns each detector a so-called RTI (rate of time index) value. This value is determined essentially via the so-called "plunge tunnel test". It measures how quickly a thermal hazard alarm emits an alarm signal when it is abruptly introduced into a 197 ° C hot oven. If, for example, due to the limitation described above 1) for the purpose of reducing overshoot an artificial delay of the sensitivity introduced, for example in the form of a slope limitation, the thermal hazard alarm will alarm too late and receive no valid RTI value. Thus, a legal marketing of such a hazard detector in the US is not possible.

The present invention is based on the object of evaluating a temperature measurement signal by means of a computer model with regard to (a) to avoid or at least reduce false alarms and (b) to improve a short trip time for real alerts.

This object is solved by the subject matters of the independent claims. Advantageous embodiments of the present invention are described in the dependent claims.

According to a first aspect of the invention, a device for evaluating a temperature measuring signal of a temperature measuring device is described, which device is suitable in particular for evaluating a time-variable temperature measuring signal of a temperature measuring device of a danger detector. The described apparatus comprises a modeling unit having (a) a first input for receiving an input signal indicative of the temperature measurement signal, (b) a second input for receiving a feedback signal, and (c) an output for outputting an output signal. According to the invention, the output signal can be generated by means of a computer model stored in the modeling unit as a function of the input signal and the feedback signal. Furthermore, the feedback signal depends directly or indirectly on the output signal.

The described evaluation device is based on the finding that unwanted artifacts can be avoided in the determination of a real temperature profile by dynamically adapting the calculation model in the course of the evaluation of a temperature profile primarily detected by the temperature measurement device. Such artifacts may be, for example, unwanted overshoots, which may occur in a temperature evaluation by means of a conventional evaluation device without the use of a feedback signal, especially at relatively abrupt temperature changes.

The described dynamic adaptation of the calculation model thus allows a robust tracking of the actual present room temperature.

In the dynamic adaptation of the computational model, therefore, the model settings of the computational model are changed on the basis of the duration of the temperature measurement or the duration of the temperature evaluation of dynamically acquired measured variables. As a result, the calculated temperature signal is stabilized, so that the robustness of the danger detector is improved in particular under real, difficult environmental conditions, such as, for example, strongly fluctuating temperatures and / or strong flow velocities.
The input signal used by the evaluation unit is indicative of the temperature measurement signal. This may mean that the temperature measurement signal and the input signal are identical. Likewise, the input signal can also result from a gain, which is preferably linear, from the temperature measurement signal.

According to one exemplary embodiment of the invention, the calculation model has at least one model parameter whose value is determined by the feedback signal.

The at least one model parameter may reflect physical effects such as the magnitude of the thermal coupling between the temperature measuring device and the medium whose temperature is being measured. The model parameter may also consider the heat capacity or thermal inertia of the temperature measuring device and / or other components of a hazard alarm, which components are thermally coupled to the temperature measuring device. Preferably, a separate model parameter is used for each separate influence on the temperature measurement caused by physical effects. There is no principal upper limit with regard to the number of usable model parameters.

According to a further exemplary embodiment of the invention, the computer model represents the inversion of a thermal model of the temperature measuring device.

The thermal model takes into account the heat capacity of the temperature measuring device, wherein the heat capacity may also be the thermal mass of a thermally coupled to the temperature measuring device housing. The heat capacity naturally leads to a strong attenuation of the temperature measurement signal compared to the actual temperature change within a monitoring range of the thermal hazard alarm. In this case, the heat capacity of other components such as holders for the temperature measuring device, the solder joints of the temperature measuring device and / or a housing of a hazard alarm can be taken into account, with which housing the temperature measuring device is thermally coupled.

The thermal model, which describes the thermal response of the temperature measuring device with temperature changes, can be described for example by a first or higher order electrical low-pass filter. In this context, a higher-order low-pass filter is a rear single-load circuit of a plurality of low-pass filters, the number of low-pass filters connected in series corresponding to the order. In this case, the inversion of the thermal model represents a first or higher order electrical high pass. However, as a result of the feedback described, overshoots can also be largely avoided even in the case of so-called step responses to an abrupt temperature change. As this allows the room temperature to be calculated robustly and quickly, the alarm initiation can be kept simple without increasing the false alarm rate. A criterion for alarm initiation could be, for example, by comparing the calculated temperature with a predetermined threshold.

In the case of the description of the response behavior of the temperature measuring device by means of a low-pass filter, naturally at least one characteristic time constant represents an important model parameter.

The reversal of the thermal model, which may be a high pass, depends in general terms on various parameters (P1, P2, P3, ...). These are changed as a function of input variables and output variables (X1, X2, X3, ...). In general terms, this can be represented as follows:

ThermModelInversion (P1, P2, P3, ...) = f (X1, X2, X3, ...)

P1, P2, P3, ... are characteristic parameters of thermal model inversion, such as time constants or multiplication factors. The characteristic parameters P1, P2, P3,... Can result from a linear combination of the measured variables X1, X2, X3,. Alternatively, the parameters P1, P2, P3,... Can also result from a non-linear function from the measured variables X1, X2, X3,.

An example of a non-linear dependence of the parameters P1, P2, P3,... Of the measured variables X1, X2, X3,... Is a so-called threshold value decision. A threshold value decision can, for example, set the parameter P1 defining a characteristic time constant equal to 2 min as soon as the measured variable X1 has a temperature gradient of more than 5 K per second.

According to a further embodiment of the invention, the device additionally comprises a slope calculation unit having (a) at least one input for directly or indirectly recording the output signal of the modeling unit and (b) an output for providing the feedback signal. In this case, the slope calculation unit is set up in such a way that in that the feedback signal provided is indicative of the temporal change of the output signal.

This may mean that the steepness of the calculated output temperature or the output signal serves as input for a controlled change of the model parameters of the thermal model inversion.

The characteristic time constant (s) of the thermal model inversion is thus changed depending on the steepness of the output signal. This causes a reduction of the time constant for steep transients which thus results in a damping of the output signal. The modeling unit thus represents an adaptive filter in this case, which is changed as a function of the transients of the output signal or of the calculated output temperature.

According to a further embodiment of the invention, the device additionally comprises an output filter unit having (a) an input for receiving the output signal of the modeling unit, and (b) an output for outputting an evaluation signal. In this case, the input of the output filter unit is connected to a first input of the slope calculation unit '. Furthermore, the output of the output filter unit is connected to a second input of the slope calculation unit.

The output filter unit can be, for example, a low-pass filter and, in particular, a low-time constant low-pass filter. This can then interact with the slope calculation unit in such a way that the slope of the output signal of the modeling unit is ascertained virtually instantaneously.

According to a further exemplary embodiment of the invention, the device additionally has a first summation unit, which is arranged between the output of the modeling unit and the input of the output filter unit.

The summation unit can ensure that a modified signal compared to the immediate output signal of the modeling unit is supplied to the input of the output filter unit. In this case, a first input of the first summation unit can be connected directly to the output of the modeling unit. A second input of the first summation unit can be supplied directly with the input signal of the modeling unit or the temperature measurement signal. Preferably, an input signal is provided with a negative sign for the signal addition by the first summation unit, so that the first summation unit can also be referred to as a subtraction unit.

According to a further embodiment of the invention, the device additionally has a second summation unit and a multiplication unit, which are arranged between the output of the first summation unit and the input of the output filter unit.

In this case, the multiplication unit can be connected downstream of the first summation unit and multiply the output signal of the first summation unit by a specific multiplication factor. The multiplication factor can be supplied via a special input by means of a suitable signal. Thus, the multiplication factor can be adjusted at any time in a suitable manner.

The multiplied signal can then be supplied to a first input of the second summation unit. A second input of the second summation unit, the input signal of the modeling unit or the temperature measurement signal can be supplied. In this case, the output signal of the second summation unit adds an addition between the multiplied signal and the output signal of the multiplication unit on the one hand and the original temperature measurement signal on the other.

According to another aspect of the invention, a hazard alarm is provided for outputting an alarm message in response to a sensed temperature within a surveillance area. The danger detector has (a) a temperature measuring device for detecting the temperature within the monitoring area and (b) a device of the type described above for evaluating a temperature measuring signal of the temperature measuring device.

The danger detector is based on the knowledge that the above-described evaluation device for evaluating the primary temperature measurement signal of the temperature measuring device can help to avoid unwanted artifacts such as overshoots in the attempt to determine the real temperature profile in the monitoring area. According to the invention, the evaluation device is set up to dynamically adapt the respectively used calculation model in the course of an evaluation. In doing so, model settings of the computational model can be determined on the basis of dynamically acquired measured variables online, i. be changed instantaneously.

The danger detector described may be a thermal or a so-called. Combination detector, which in addition to a thermal sensor input another, for example, has an optical sensor input. In the case of a combination detector, the various sensor inputs can be suitably combined in the evaluation of the respective measured variables with regard to rapid and at the same time false-alarm-proof initiation of alarm messages.

According to a further aspect of the invention, a method for evaluating a time-varying temperature measurement signal of a temperature measuring device is specified. The method is particularly suitable for evaluating a time variable temperature measuring signal of a temperature measuring device of a hazard detector. The method comprises (a) receiving an input signal indicative of the temperature measurement signal from a first input of a modeling unit, (b) receiving a feedback signal from a second input of the modeling unit, and (c) outputting an output signal at a Output of the modeling unit. According to the invention, the output signal is generated by means of a mathematical model stored in the modeling unit as a function of the input signal and the feedback signal. Furthermore, the feedback signal depends directly or indirectly on the output signal.

The analysis method described is also based on the knowledge that unwanted artifacts such as overshoots in the determination of a real temperature profile can be avoided by dynamically adapting the computer model in the course of the evaluation of the temperature profile primarily detected by the temperature measuring device.

In the described dynamic adaptation of the computational model, the model settings of the computational model are changed based on the duration of the temperature measurement or the temperature evaluation of dynamically acquired measured variables. Apart from unavoidable running times of the measurement signals and / or of a required computing or evaluation time, the evaluation thus takes place instantaneously with the temperature measurement by the temperature measuring device.

It should be noted that the evaluation method described can be developed in a manner analogous to the evaluation device described above. This means that the above-described features of the device-related claims can also be combined with the features of the described method for evaluating a time-varying temperature measurement signal.

According to a further aspect of the invention, a computer-readable storage medium is described, in which a program for evaluating a time-varying temperature measurement signal of a temperature measuring device, in particular for evaluating a time-variable temperature measurement signal of a temperature measuring device of a danger detector is stored. The program, when executed by a processor, is set up to perform the above procedure.

According to a further aspect of the invention, a program element for evaluating a time-varying temperature measuring signal of a temperature measuring device, in particular for evaluating a time-variable temperature measuring signal of a temperature measuring device of a danger detector, is described. The program element, when executed by a processor, is set up to perform the above procedure.

The program and / or program element may be implemented as a computer-readable instruction code in any suitable programming language such as JAVA, C ++, etc. The program and / or the program element can be stored on a computer-readable storage medium (CD-ROM, DVD, removable drive, volatile or non-volatile memory, built-in memory / processor, etc.). The instruction code may program a computer or other programmable device to perform the desired functions. Furthermore, the program and / or the program element can be provided in a network, such as the Internet, from where it can be downloaded by a user as needed.

The invention can be implemented either by means of a computer program, ie by means of software, or by means of one or more special electrical circuits, ie in hardware or in any hybrid form, ie by means of software components and hardware components.

Figur 1

zeigt einen thermischen Gefahrmelder mit einer Temperaturmesseinrichtung und einer einen adaptiven Filter darstellenden Auswerteeinheit für das Temperaturmesssignal der Temperaturmesseinrichtung.

Figur 2

zeigt in einem direkten Vergleich das zeitliche Verhalten (a) einer auf einem adaptiven Filter basierenden Temperaturauswertung gemäß einem Ausführungsbeispiel der Erfindung und (b) einer bekannten Temperaturauswertung unter Verwendung einer künstlichen Anstiegsbegrenzung.

Further advantages and features of the present invention will become apparent from the following exemplary description of presently preferred embodiments. The individual figures of the drawing of this application are merely to be regarded as schematic and not to scale.

FIG. 1

shows a thermal hazard detector with a temperature measuring device and an adaptive filter representing evaluation unit for the temperature measurement signal of the temperature measuring device.

FIG. 2

shows in a direct comparison the temporal behavior (a) of an adaptive filter-based temperature evaluation according to an embodiment of the invention and (b) a known temperature evaluation using an artificial increase limit.

FIG. 1 shows a thermal hazard detector 100, which has a NTC (negative temperature coefficient) resistance temperature measuring device 102. An output signal ntc_in the temperature measuring device 102 is supplied to an evaluation device 110. The output signal ntc_in thus represents the input signal for the evaluation device 110.

As will be explained in more detail below, the evaluation device 110 is set up in such a way that, in the case of a dangerous situation, a time increase of the output signal ntc_in is optimized with respect to the fastest possible triggering of the alarm and avoidance of artifacts that could lead to false alarms ,

The evaluation device 110 is followed by a microprocessor 105, which checks the evaluation signal provided by the evaluation device 110 virtual_temp in terms of its relevance to a dangerous situation and possibly causes an alarm message. According to the embodiment shown here, the alarm message is acoustically via a microprocessor 105 downstream amplifier 107 and connected to the amplifier 107 speaker 108th

It should be noted that the microprocessor 105 and the evaluation device 110 can also be realized by means of a common component, for example a microcontroller. The same applies to the microprocessor 105 and the amplifier 107.

The evaluation device 110 has an input 111 and an output 112. The input 111 is supplied with the output signal ntc_in in the temperature measuring device 102. At the output 112, the evaluation signal virtual_temp is provided.

According to the exemplary embodiment illustrated here, the evaluation device 110 also has three components which are each connected to the input 111 via a suitable signaling line. How out FIG. 1 As can be seen, the input 111 of the evaluation device 110 is connected to a first input of a modeling unit 120. In addition, the input 111 is connected to the positive input 131 of a first summation unit 130 designed as a subtraction unit and to a first input 151 of a second summation unit 150.

In the modeling unit 120, a thermal model of the temperature measuring device 102 is stored. The thermal model also takes into account thermal masses or heat capacities that are associated with the temperature measuring device 102 thermally coupled. This is especially true for a in FIG. 1 not shown housing of the hazard detector 100th

The thermal masses lead in a known manner to the fact that the temperature profile indicated by the temperature measuring device 102 lags behind the true, actually existing temperature profile. According to the embodiment shown here, this thermal inertia is described by a low-pass behavior. This low-pass behavior is determined by at least one characteristic time constant, which represents an important parameter of the thermal model.

In contrast to known evaluation methods for temperature measurement signals, the characteristic time constant does not necessarily have to be constant in the case of the evaluation device 100 described here. Rather, the characteristic time constant depends on a feedback signal slope (T_model = f (slope)). As will be explained in detail later, according to the exemplary embodiment illustrated here, the magnitude of the feedback signal slope depends on the current slope or the magnitude of the temporal change of the evaluation signal virtual_temp.

How out FIG. 1 Furthermore, an output signal iir_model is supplied to the modeling unit 120 via an output 123 of the modeling unit 120 to a negative input 132 of the subtraction unit 130. According to the exemplary embodiment illustrated here, the modeling unit 120 is a low-pass filter. The difference signal diff formed in the subtraction unit 130 between the input signal ntc_in and the output signal iir_model is then supplied via an output 133 of the subtraction unit 130 to an input 141 of a multiplication unit 140. In the multiplication unit 140, the difference signal diff is multiplied by a factor, which factor is calculated by means of a control signal factor_model via a control input 146 of the multiplication unit 140 is determined. This multiplication factor can also be readjusted or corrected at any time during operation of the evaluation device 110.

Via an output 143 of the multiplication unit 140, the multiplied signal mult is supplied to a second input 152 of the second summation unit 150. In the second summation unit 150, the multiplied signal mult is then added to the input signal ntc_in fed via the first input 151 of the second summation unit 150. As a result, a summation signal pre_temp is formed, which represents the output signal of the second summation unit 150.

How out FIG. 1 Furthermore, the output signal pre_temp is fed via an output 153 of the second summation unit 153 to an input 161 of an output filter unit 160. According to the exemplary embodiment illustrated here, the output filter unit 160 represents a low-pass filter. The low-pass filter can be a low-pass filter of any order. The low-pass converts the output signal pre_temp into a filtered evaluation signal virtual_temp, which is provided at an output 162 of the output filter unit 160. As already described above, the evaluation signal virtual_temp is supplied to the microprocessor 105 via the output 112 of the evaluation device 110.

In the following, the feedback of the evaluation signal virtual_temp to the modeling unit 120 is described, which makes the modeling unit 120 the adaptive filter: According to the exemplary embodiment illustrated here, the feedback takes place via a slope calculation unit 170. The slope calculation unit 170 has (a) a first input 171, (b) a second input 172, to which the evaluation signal virtual_temp is supplied, and (c) an output 173. At the output 173, the feedback signal slope, which is supplied via a second input 122 of the modeling unit 120 thereof. According to the exemplary embodiment illustrated here, the gradient, ie the magnitude of the temporal change of the output signal pre_temp and / or of the evaluation signal virtual_temp, is determined in the slope calculation unit 170 based on the two signals pre_temp and virtual_temp. This relationship can generally be described by the following equation: slope = f (pre_temp, virtual_temp)

According to the embodiment illustrated here, the feedback signal slope determines the characteristic time constant of the model inversion.

At the in FIG. 1 Evaluation device 110 shown thus the characteristic time constant of the thermal model inversion as a function of the steepness of the evaluation signal virtual_temp is changed. In the case of a particularly steep transient, this causes a reduction of the time constant, which as a result causes a damping of the evaluation signal virtual_temp. The modeling unit 120 thus represents an adaptive filter which is changed as a function of the output transient.

In this case, the steepness of the evaluation signal virtual_temp is measured as the difference between the signal at the input 161 and the signal at the output 162 of the low-pass linear output filter 160. The low pass of the output filter has a comparatively short time constant. The difference signal can be compared in the modeling unit 120 with a threshold value. If the threshold value is exceeded, the model's time constant is set to a shorter value. In this case, for example, a comparatively large time constant is selected when the feedback signal slope is small. If the feedback signal slope is comparatively large, then a smaller time constant is chosen for the thermal model currently used in the modeling unit 120. This dependence of the time constant used by the feedback signal slope thus represents an adaptive control in the evaluation of the output signal ntc_in the temperature measuring device 102.

FIG. 2 shows in a diagram 290 in an illustrative manner the characteristic behavior of the described evaluation device 110. It is based on a sudden temperature change from 5 ° Celsius to 50 ° Celsius in a monitored room. The temperature measuring device 102 thus supplies as input signal ntc_in a corresponding step response 291. This is attenuated as a result of the thermal mass of the temperature measuring device and shows the characteristic behavior of a second-order low-pass filter.

The reference numeral 292 is in FIG. 2 a standard implementation of a known evaluation device shown, which in comparison to the step response has a faster increase and thus would be suitable in principle for a quick alarm triggering. To avoid an extremely strong overshoot, the standard implementation has an artificial increase limit. Despite this increase in limitation, however, the evaluation signal 292 has an overshoot, which briefly rises above an alarm threshold 295 at about 90 s after the beginning of the abrupt temperature change and thus triggers a false alarm.

It should be noted that the overshoot could be avoided or at least reduced by a greater increase in the limit. However, this would result in a significantly slower increase of the evaluation signal 292, so that real alarm messages could be triggered only significantly delayed. This would mean that the American standard FM3210 could not be met.

Reference numeral 293 is the temporal behavior of the evaluation signal virtual_temp in the FIG. 1 shown evaluation device 110 shown. It can be seen very nicely that the signal 293 as well as the evaluation signal 293 rises steeply. Thus, in the case of a thermally displayed danger situation as well as a timely alarm is possible. In addition, an overshoot is advantageously avoided in the signal 293 and the evaluation signal 293 is always sufficiently far from the alarm limit 295. Thus, an undesirable false alarm can be reliably avoided.

1. 1) Die Auswertevorrichtung 110 trägt auf vorteilhafte Weise zu einer Stabilisierung eines an sich instabilen Rechenmodells bei, welches die Inversion eines thermischen Modells darstellt, welches die thermische Trägheit der Temperaturmesseinrichtung und ggf. die thermische Trägheit von mit der Temperaturmesseinrichtung thermisch gekoppelte Wärmekapazitäten beschreibt. Das Rechenmodell ist vom Verhalten her einem Hochpass ähnlich. Die beschriebene Temperaturauswertung führt bei gleichzeitig schnellem Ansprechen zu keinen bzw. zu lediglich sehr kleinen Überschwingen. Die Dynamik der Temperaturauswertung wird insbesondere nicht durch bekannte künstliche Steilheitsbegrenzungen eingeengt. Damit ergeben sich weitere Vorteile auch unter "realen" Bedingungen, welche in den relevanten Normen nicht getestet werden. Beispielsweise wird der Gefahrenmelder auch bei stark schwankenden Temperaturen oder hohen Windgeschwindigkeiten robuster. Unter diesen Bedingungen verändern sich normalerweise die Parameter eines thermischen Systems drastisch. Beispielsweise kann bei hohen Windgeschwindigkeiten der Sensor plötzlich anders angeströmt werden und dadurch sehr viel schneller reagieren. Ein "starres" System hätte hier einige Probleme mit auftretenden Instabilitäten.
2. 2) Durch die beschriebene Rückkopplung bzw. durch die adaptive Filterung können alle für thermische Gefahrenmelder relevanten Normen wie insbesondere die Normen EN54-5 A1S und BS und die Norm FM3210 erfüllt werden. Dies ist insofern bemerkenswert, da diese Normen, wie oben bereits dargestellt, eigentlich gegensätzliche Anforderungen enthalten (die FM3210 erfordert eine möglichst schnelle Alarmierung, die EN54-5 "S" erfordert eine Vermeidung von Falschalarmen).
3. 3) Ein weiterer Vorteil der beschriebenen Auswertevorrichtung 110 besteht darin, dass obige Normen mit dem gleichen Algorithmus erfüllt werden können. Es muss also keine umständliche Umparametrierung erfolgen. Damit wird ein mit der Auswertevorrichtung 110 bestückter Gefahrmelder so gut, dass alle relevanten Normen erfüllt werden können.
4. 4) Die beschriebene Auswertevorrichtung 110 kann bei herkömmlichen thermischen Gefahrmeldern durch eine einfache Programmierung realisiert werden. Spezielle Hardware Komponenten sind in der Regel nicht erforderlich.

The described evaluation device 110 with the modeling unit 120 representing an adaptive filter has in particular the following advantages:

1. 1) The evaluation device 110 advantageously contributes to a stabilization of an inherently unstable computation model, which represents the inversion of a thermal model which describes the thermal inertia of the temperature measurement device and optionally the thermal inertia of heat capacities thermally coupled to the temperature measurement device. The calculation model is similar in behavior to a high pass. The temperature evaluation described leads to no or only very small overshoot while simultaneously responding quickly. In particular, the dynamics of the temperature evaluation are not restricted by known artificial steepness limits. This results in further advantages even under "real" conditions, which are not tested in the relevant standards. For example, the hazard alarm becomes more robust even with strongly fluctuating temperatures or high wind speeds. Under these conditions, the parameters of a thermal system usually change drastically. For example, at high wind speeds, the sensor can be suddenly flowed differently and thus react much faster. A "rigid" System here would have some problems with occurring instabilities.
2. 2) The described feedback or adaptive filtering enables all standards relevant to thermal hazard detectors, in particular the EN54-5 A1S and BS standards and the FM3210 standard, to be met. This is remarkable in that these standards, as stated above, actually contain conflicting requirements (the FM3210 requires the fastest possible alarm, the EN54-5 "S" requires avoidance of false alarms).
3. 3) Another advantage of the described evaluation device 110 is that the above standards can be met with the same algorithm. So it must be done no complicated Umparametrierung. Thus, a danger detector equipped with the evaluation device 110 becomes so good that all relevant standards can be met.
4. 4) The described evaluation device 110 can be realized in conventional thermal hazard detectors by a simple programming. Special hardware components are usually not required.

Claims (11)

Device for evaluating a temperature measuring signal (ntc_in) of a temperature measuring device (102), in particular for evaluating a time-variable temperature measuring signal (ntc_in) of a temperature measuring device (102) of a danger detector (100), the device (110) comprising a modeling unit (120) A first input (121) for receiving an input signal (ntc_in) indicative of the temperature measurement signal, A second input (122) for receiving a feedback signal (slope), and An output (123) for outputting an output signal (iir_model, pre_temp, virtual_temp), - wherein the output signal (iir_model, pre_temp, virtual_temp) can be generated by means of a mathematical model stored in the modeling unit (120) in dependence on the input signal (ntc_in) and the feedback signal (slope), and - wherein the feedback signal (slope) depends directly or indirectly on the output signal (iir_model, pre_temp, virtual_temp). Apparatus according to claim 1, wherein the calculation model comprises at least one model parameter (T_model) whose value is determined by the feedback signal (slope). Device according to one of claims 1 to 2, wherein the calculation model represents the inversion of a thermal model of the temperature measuring device (102). Device according to one of claims 1 to 3, additionally comprising a slope calculation unit (170) with • at least one input (171, 172) for directly or indirectly recording the output signal (pre_temp, virtual_temp) of the modeling unit (120) and An output for providing the feedback signal (slope),
wherein the slope calculation unit (170) is arranged such that the provided feedback signal (slope) is indicative of the temporal change of the output signal (pre_temp, virtual_temp). Apparatus according to claim 4, further comprising an output filter unit (160) An input (161) for receiving the output signal (iir_model, pre_temp) of the modeling unit (120), and An output (162) for outputting an evaluation signal (virtual_temp),
in which - the input (161) of the output filter unit (160) is connected to a first input (171) of the slope calculation unit (170) and - The output (162) of the output filter unit (160) is connected to a second input (172) of the slope calculation unit (170). The apparatus of claim 5, further comprising a first summation unit (130) disposed between the output (123) of the modeling unit (120) and the input (161) of the output filter unit (160). Apparatus according to claim 6, further comprising a second summation unit (150) and a multiplication unit (140) arranged between the output (133) of the first summation unit (130) and the input (161) of the output filter unit (160). Danger detector for outputting an alarm message as a function of a detected temperature within a monitoring area, the danger detector (100) having A temperature measuring device (102) for detecting the temperature within the monitored area and • A device (110) according to one of claims 1 to 7 for evaluating a temperature measurement signal (ntc_in) of the temperature measuring device (102). Method for evaluating a time-varying temperature measuring signal (ntc_in) of a temperature measuring device (102), in particular for evaluating a time-variable temperature measuring signal (ntc_in) of a temperature measuring device (102) of a danger detector (100), comprising the method Receiving an input signal (ntc_in) indicative of the temperature measurement signal from a first input (121) of a modeling unit (120), • picking up a feedback signal (slope) from a second input (122) of the modeling unit (120), and Outputting an output signal (iir_model, pre_temp, virtual_temp) at an output (123) of the modeling unit (120), wherein the output signal (iir_model, pre_temp, virtual_temp) is generated by means of a computing model stored in the modeling unit (120) in dependence on the input signal (ntc_in) and the feedback signal (slope), and - wherein the feedback signal (slope) depends directly or indirectly on the output signal (iir_model, pre_temp, virtual_temp). Computer-readable storage medium, in which a program for evaluating a time-varying temperature measurement signal (ntc_in) of a temperature measuring device (102), in particular for evaluating a time-variable Temperature measurement signal (ntc_in) of a temperature measuring device (102) of a hazard detector (100), which, when executed by a processor (110) is arranged to perform the method according to claim 9. Program element for evaluating a time-varying temperature measuring signal (ntc_in) of a temperature measuring device (102), in particular for evaluating a time-variable temperature measuring signal (ntc_in) of a temperature measuring device (102) of a danger detector (100) which, when executed by a processor (110) is set up to carry out the method according to claim 9.

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