EP1001226A2 - Ultrasonic sensor for smoke extracting hoods - Google Patents

Abstract

The sensor (5) monitors steam from cooking pots and has a system-specific resonant frequency. An electronic monitoring circuit is provided, which sweeps the frequency band of the ultrasound transmitter (5a) signal in the area around the resonant frequency from both sides in predetermined intervals during the sensor operation. The circuit measures the maximum amplitude of the transmitter signal, to form an average frequency. The average frequency is taken to be the resonant frequency until the next time it is measured and amended.

Description

The invention relates to an ultrasonic sensor for an extractor hood with automatic adjustment of the temperature and aging drift, whereby the ultrasonic sensor, consisting of transmitter and receiver, from the food to the cooker hood ascending vapors are monitored and being the ultrasonic sensor has a system-specific resonance frequency.

From EP 0 443 141 B1 it is known to use ultrasonic sensors to control the To use fans with extractor hoods. You get the knowledge here to use that the rising haze the amplitude of the ultrasonic signal changed and the more the vapor formation is stronger. For ultrasonic sensors it is known to automatically adjust the temperature drift it So far, however, has given no clues as to how the sensor's aging drift during the current operation of the ultrasonic sensor. The aging drift leads to a change in the resonance frequency of the sensor and must therefore be monitored become. So far, the necessary adjustment has only been made for an air-calmed signal path possible, it was previously also a strict assignment of sensor and associated electronics required, since the adjustment is generally not in built-in Condition could take place.

It was an object of the invention to avoid these disadvantages and an ultrasonic sensor propose with a monitoring circuit that an automatic Alignment of the aging drift while the sensor is running enables.

For this purpose, the invention proposes the features characterized in claim 1.
The essence of the invention is, therefore, that the monitoring circuit operates the ultrasound sensor at predetermined time intervals in succession with different frequencies in a frequency range close to the resonance frequency and thereby detects the occurring amplitudes to the maximum. A frequency of the sensor is assigned to each such maximum and an average frequency f (q) is determined from several such individual frequencies, which is initially used as the new resonance frequency f (o). This applies until a new attempt to reconcile is made. Each such attempt is carried out for a very short time so as not to disturb the ongoing operation of the ultrasonic sensor when monitoring the vapor. The frequency of the attempts is determined empirically.

In a preferred further embodiment of the invention it is provided that the monitoring circuit when traversing the frequency band the occurring Determines frequency values assigned to maximum amplitudes and stores that the monitoring circuit from the frequency distribution of the respective maximum amplitudes and thus the associated frequency values in a statistical calculation process the standard deviation and the center frequency f (q) are calculated and that they use this frequency as the resonance frequency f (o) for the operation of the sensor used until the next detected change in the center frequency f (q). This statistically calculated center frequency corresponds to the above-mentioned average frequency and in the best case is the same as the one originally specified Resonance frequency f (o), but it is at least in the vicinity.

In a further preferred embodiment of the invention it is provided that for the determination the standard deviation and the center frequency f (q) only those frequency values are stored at a predetermined frequency distance from the resonance frequency f (o) lie, such as ± 1 kHz, ± 2 kHz.

A particularly useful development of the invention provides that the ultrasonic sensor Transmitter and receiver in one housing that contains it alternately works in the transmitting and receiving mode and the vapors in the reflection process scans.

The monitoring circuit has a microcontroller as an essential component on, on the one hand the control of the fan of the extractor hood and on the other initiates the automatic drift compensation. This automatic comparison also enables the compensation of the temperature drift in the same test cycle, so that no special effort is required for this.

The invention will be explained in more detail below using an exemplary embodiment become.

Figur 1

ein Blockschaltbild der Überwachungsschaltung;

Figur 2

die Resonanzkurve eines Ultraschallsensors;

Figur 3

die Häufigkeit von gemessenen Einzelfrequenzwerten an vorgegebenen Stellen im Umgebungsbereich der Resonanzfrequenz.

Show it:

Figure 1

a block diagram of the monitoring circuit;

Figure 2

the resonance curve of an ultrasonic sensor;

Figure 3

the frequency of measured single frequency values at predetermined locations in the vicinity of the resonance frequency.

A microcontroller 1 with a microcomputer 1a is located at an output A1 a control circuit 2 for controlling the fan motor 8 of an extractor hood. The speed of the motor 8 does not depend on that of one shown heated food controlled rising vapors. The requirement which speed is assigned to which amount of ascending vapors the control circuit 2 from the microcomputer 1a.

The microcontroller 1 has an oscillator 3 at an output A2 and this one Sensor control 4 downstream. The output signal of the oscillator 3 is on an input E1 of the microcontroller 1 is returned and enables there Measurement of the output frequency on the oscillator. The sensor control 4 receives via a second input, which is located at the output A3 of the microcontroller 1 Switching signal, which switches between transmission and reception mode downstream ultrasound sensor 5 performs. This ultrasonic sensor is in an extractor hood installed at a suitable location and gropes in the reflection process the vapors 6 rising from a food not shown above the reflector 6a. In this ultrasonic sensor 5 there are a transmitter 5a and a Installed receiver 5b, which is operated by the sensor control 4 can be switched on alternately.

The signal of the receiver 5b, the so-called echo signal, originated from the Reflection on the vapor 6 is given to the input of an amplifier 7, which is connected to an input E2 of the microcontroller 1. Via an exit A4 of the microcontroller 1, the signal amplification at the amplifier 7 is set.

FIG. 2 shows the resonance curve f (o) of an ultrasound sensor 5. The typical resonance frequency of such a sensor is 200 kHz. Through the The aforementioned drift, caused by temperature changes or aging of the sensor, this resonance curve can move towards lower or higher Shift frequencies. Compensate for this shift and the ultrasonic sensor 5 must always be operated with the currently given resonance frequency Core problem of the invention.

This deviation from the resonance frequency f (o) is determined briefly again and again in a cyclical sequence during the operation of the Ultrasonic sensor when monitoring the vapor. For this purpose the Control frequency for the ultrasonic sensor by adjusting the oscillator 3 in a repeated passage through the frequency range below and above the Changed resonance frequency. For this purpose, the oscillator is increasingly in Detuned towards lower and then towards higher frequencies than the resonance frequency. The amplitude maximum of the echo signal is in each case measured via the amplifier 7. This process is repeated several times. The number of amplitude maxima, which are measured at -1 kHz or +1 kHz, will be saved. The same applies to the frequency -2 kHz or +2 kHz to the resonance frequency. In this way you get a number of one or more frequency values, which amplitude maxima are assigned. Would be the number for measurements above and below the resonance frequency would be the same new center frequency exactly match the original resonance frequency. Is however, if this is not the case, the statistical evaluation shifts this Number the center frequency in the direction where the larger number of single values was measured. The center frequency f (q) thus differs somewhat from the original resonance frequency f (o). This frequency f (q) is called new Resonance frequency of the ultrasonic sensor defined and the oscillator 3 is up used as the new resonance frequency f (o) for the next adjustment attempt.

The new center frequency f (q) is calculated according to a statistical one Evaluation procedure via the calculation of the standard deviation. The Art this statistical evaluation is as a possible way of calculating this Center frequency. The invention is not based on the use of this calculation method limited.

Claims (8)

Ultrasound sensor for an extractor hood with automatic adjustment of the temperature and aging drift, the ultrasound sensor, consisting of transmitter and receiver, monitors the vapors rising from the food to the extractor hood, and the ultrasound sensor has a system-specific resonance frequency,
characterized,
that an electronic monitoring circuit (ÜS) is present, which during the operation of the ultrasonic sensor (5) passes through the frequency band of the transmission signals in the range around the resonance frequency f (o) on both sides ("wobbles"), the maximum amplitudes of the measured received signals, thereby forming an average frequency f (q) from the frequencies assigned to them and using this frequency f (q) as the resonance frequency f (o) for the sensor until the next detected change in frequency f (q). Ultrasonic sensor according to claim 1,
characterized,
that the monitoring circuit (ÜS) detects and stores the frequency values associated with the occurring maximum amplitudes when passing through the frequency band and that the monitoring circuit (ÜS) uses the frequency distribution (bell curve) of the respective maximum amplitudes and thus the associated frequency values in a statistical calculation method to determine the standard deviation and the center frequency f (q) calculated and that this frequency is used as the resonance frequency for the operation of the sensor until the next detected change in the center frequency f (q). Ultrasonic sensor according to claim 2,
characterized,
that to determine the standard deviation and the center frequency f (q) only those frequency values are stored which are in a predetermined frequency distance from the resonance frequency f (o), such as. B. ± 1 kHz, ± 2 kHz. Ultrasonic sensor according to one or more of claims 1 to 3,
characterized,
that the monitoring circuit (ÜS) cyclically carries out the drift adjustment for a short time and carries out the monitoring of the vapor (6) in the remaining time. Ultrasonic sensor according to one of claims 1 to 4,
characterized,
that it contains transmitter (5a) and receiver (5b) in one housing, that it works alternately in the transmitting and receiving mode and scans the vapors (6) via the reflector (6a) in the reflection process. Ultrasonic sensor according to claim 1,
characterized,
that the monitoring circuit (ÜS) has a microcontroller or ASIC (1) which on the one hand controls the ventilation of the extractor hood and on the other hand automatically drift compensation. Ultrasonic sensor according to claim 6,
characterized,
that the microcontroller (1) has an adjustable oscillator (3), a sensor control circuit (4) and the ultrasonic sensor (5) and that the latter outputs its received signal to an A / D converter in the microcontroller (1). Ultrasonic sensor according to claim 7,
characterized,
that the oscillator (3) and sensor control circuit (4) are part of the microcontroller.

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