FR2954043A1 - Device for destructing dipterous insect e.g. mosquito, by diffusing ultrasonic signal, has oscillator designed to generate signal at fixed ultrasonic frequency, and modulation unit to modulate frequency of signal by control signal - Google Patents

Abstract

The device (D) has a voltage control oscillator (OP) designed to generate an ultrasonic signal (S) at a fixed ultrasonic frequency i.e. carrier frequency. A modulation unit (MOD) modulates the ultrasonic frequency of the signal by a control signal (CO). The voltage control oscillator is mounted in an unstable manner such that the carrier frequency depends on a charging duration of a capacitor (C). The modulation unit is designed to modify the charging duration of the capacitor based on the temporal evolution of the control signal.

Description

The present invention relates to a device for repelling a dipteran, such as a mosquito or a fly, by diffusion of an ultrasonic signal. Numerous devices are known for repelling a dipteran by diffusion of an ultrasonic signal. The principle of these devices is to generate a signal at an ultrasonic frequency in the frequency band between 10 and 40 KHz and convert this signal into a wave through a transducer wave which is then broadcast in a zone delimited by the power of emission of this wave. Thus, according to this principle, the wave scattered at the selected ultrasonic frequency is supposed to reproduce an ultrasound which disturbs the dipteran so that this dipteran leaves the diffusion zone. The inventor has observed that the diffusion of an ultrasonic signal at a fixed frequency does not effectively repel a Diptera which gets used to this signal over time. The problem solved by the present invention is to improve the efficiency of current devices used to repel a dipteran by diffusion of an ultrasonic signal. To this end, the present invention relates to a device for repelling a dipteran by diffusion of an ultrasonic signal which is characterized in that it comprises an oscillator provided for generating a signal at a fixed ultrasonic frequency and means for modulating in frequency the signal thus generated by a so-called control signal. Thus, the inventor has observed that by diffusing a frequency-modulated signal, the frequency variations caused in the dipteran a panic effect which does not occur when the frequency of this scattered signal remains fixed, that is, say in the absence of frequency modulation of the ultrasonic signal. According to one embodiment, the oscillator is a voltage controlled oscillator, and mounted in astable so that the carrier frequency depends on the charging time of a capacitor. The means for modulating in frequency are then provided to modify the charging duration of this capacitor according to the time evolution of the control signal. This mode is advantageous because it is very economical to produce. The characteristics of the invention mentioned above, as well as others, will emerge more clearly on reading the following description of an exemplary embodiment, said description being given in relation to the attached drawings, among which: FIG. . 1 schematically represents an embodiment of the device for repelling a dipteran, FIG. 2 shows timing diagrams showing the operation of a voltage controlled oscillator, FIGS. 3-7 schematically show other embodiments of the device for repelling a dipteran, and FIG. 8 shows an embodiment of a rectangular oscillator. In general, the present invention relates to a device D for repelling a dipteran by diffusion of an ultrasonic signal S.

According to one characteristic, the device D comprises an oscillator OP designed to generate a signal S at a fixed ultrasonic frequency F, said carrier, and means MOD for modulating in frequency this signal S by a so-called control signal CO. According to an embodiment shown schematically in FIG. 1, the oscillator OP is a voltage controlled oscillator (Voltage controlled oscillator in English and VCO abbreviated) and mounted in astable. For this, according to an example, the oscillator OP comprises an NE555 circuit mounted astable. This type of oscillator is widely known in the state of the art. For the most part, the astable assembly of the oscillator OP consists of associating the circuit NE555 with a divider bridge of two resistors R1 and R2 connected to a DC voltage VCC and to an integration capacitor C. In the case where these resistance and / or capacitor values are variable, the fixed frequency of the signal S, present at the output of the oscillator, can be set to a particular value by fixing the values of these components. Fig. 2 represents the time evolution of the signal Vc at the terminals of the integration capacitor C and the signal S (present at the OUT terminal of the circuit NE555). The duration T of a complete oscillation of the signal S is the sum of the load duration TC and discharge TD of the integration capacitor C. During the charging time TC, the signal S is at a high level and during the duration of TD discharge, signal S is at a low level. The signal S is rectangular and its oscillation frequency is equal to 1 / T.

Recall that in this type of assembly, the integration capacitor C charges up to 2/3 of the DC voltage VCC and discharges at 1/3 of this voltage VCC. During charging, a charging current flows through the resistors R1 and R2 connected in series with the capacitor C, and the discharge takes place through the resistor R2 only (and the DISCH terminal of the circuit NE555).

The oscillation frequency F of the signal S is given by 1.44 F = (RI + 2R2) xC According to the present invention, the values of the resistors R1, R2 and of the capacitor C are chosen so that the frequency F is equal to one. ultrasonic frequency which disturbs a Diptera, that is to say included in a frequency band spreading between 18 and 40 KHz. The inventor observed that a frequency F equal to 37 Khz, 50 Khz or 100 Khz was particularly suitable for repelling mosquitoes.

The device D also comprises an amplifier A for amplifying the signal S coming out of the oscillator OP and an HP piezoelectric transducer designed to emit a wave when it is excited by the amplified signal S.

According to the embodiment of the oscillator OP of FIG. 1, the means MOD for modulating in frequency the signal S are formed of a divider bridge of two resistors R3 and R4, one of the terminals of the resistor R3 receives the control signal

15 CO, one of the terminals of the resistor R4 is connected to the ground and the link between the resistors R3 and R4 is connected to the integration capacitor C.

Thus, during the charging of the integration capacitor C, when the control signal CO is different from 0, the charging duration TC decreases because the charging current is then greater than that which passes through the resistors R1 and R2 in the absence of signal

20 of control. When the control signal CO is zero during the charging of the integration capacitor C, the charging time TC is then equal to that defined by the values of the components of the astable assembly of FIG. 1 because the integration capacitor C is then charged by the current flowing through the resistors R1 and R2. It may be noted that the control signal CO has no influence on the discharge duration TD of the

25 integration capacitor C which continues to discharge via the resistor R2 and the DISCH pin of the circuit NE555.

Thus, the temporal evolution of the control signal CO modifies the charging time TC of the integration capacitor C and consequently modifies the frequency F of the signal S, ie the control signal CO modulates in frequency the signal

Ultrasonic S.

According to another characteristic, the means MOD comprise means MOC for forming the control signal CO from at least one rectangular signal of single frequency and lower than the carrier frequency.

According to one embodiment, the MOC means comprise an oscillator O1 intended to generate a rectangular signal S1 of frequency F1 that is unique and lower than the frequency F. According to an embodiment shown schematically in FIG. 3, the control signal CO is then equal to this signal S1. The inventor has observed that the frequency F1 should be chosen sufficiently far from the frequency F to create a random effect of the variations of the frequency F, thus amplifying the panic effect in the dipteran. Preferably, the frequency F1 is chosen equal to 1 Hz when the frequency F is equal to 37 KHz, 50 Khz or 100 Khz.

According to another embodiment, shown schematically in FIG. 4, the MOC means comprise a plurality of other oscillators O2, O3,..., Oi, each intended to generate a rectangular signal S2, S3,..., Si. Each rectangular signal Si has a single frequency and less than the carrier frequency F. The MOC means also comprise means ML for forming a resultant signal R by mixing together these rectangular signals S2, S3,..., Si. The control signal CO is then obtained by mixing the rectangular signal. S1 with the resulting signal R. According to the example of FIG. 4, two resistors R5 and R6 mounted as a divider bridge are used for this purpose. It may be noted that the R and S1 signals are not synchronized with each other, which increases the randomness of the variations of the frequency F, thus amplifying the panic effect in the dipteran. Figs. 5-7 give three particular embodiments of the MOC means which use NAND logic gates and different numbers of oscillators. It will be understood that the scope of the present invention is not limited to these three embodiments which may include multiple variants such as for example the use of more than three oscillators, other methods for mixing rectangular Si signals. However, they do not depart from the context of the present invention which is, let us recall, forming a control signal CO by mixing together rectangular signals of single frequencies and less than the carrier frequency. Fig. 5 shows an embodiment of the device D in which the MOC means comprise two other oscillators O2 and O3 each intended to generate a rectangular signal, in this case S2 and S3, and the means ML are then summarized in a gate N1 of the NAND type with two inputs. The output of the oscillator 02 is connected to an input of the gate N1 and the output of the oscillator 03 is connected to the other input of the gate N1. The resulting signal R, which is then present on the output of the gate N1, is mixed with the signal S1 as explained above. Fig. 6 represents an embodiment of the device D in which the MOC means comprise three other oscillators O2, O3 and O4 each intended to generate a rectangular signal, in this case S2, S3 and S4, and the means ML comprise two logic gates of NAND type, in this case N1 and N2 with two inputs. The output of the oscillator 02 is connected to one of the inputs of the gate N1 and the output of the oscillator 03 is connected to the other input of the gate N1. The output of the oscillator 04 is connected to one of the inputs of the gate N2 and the output of the gate N1 is connected to the other input of the gate N2. The resulting signal R, which is then present on the output of the gate N2, is mixed with the signal S1 as explained above. Fig. 7 shows an embodiment of the device D which is the mode preferred by the applicant to repel mosquitoes.

The MOC means comprise four other oscillators O2, O3, O4 and O5 each intended to generate a rectangular signal, in this case S2, S3, S4 and S5, and the means ML comprise three logic gates of the NAND type, in this case N1, N2 and N3 with two inputs. The output of the oscillator 02 is connected to one of the inputs of the gate N1 and the output of the oscillator 03 is connected to the other input of the gate N1. The output of the oscillator 04 is connected to one of the inputs of the gate N2 and the output of the gate N1 is connected to the other input of the gate N2. The output of the oscillator 05 is connected to one of the inputs of the gate N3 and the output of the gate N2 is connected to the other input of the gate N3. The resulting signal R, which is then present on the output of the gate N3, is mixed with the signal S1 as explained above.

Applicant has observed that this embodiment is particularly effective in repelling mosquitoes when the frequency values of signals S2, S3, S4 and S5 are respectively equal to 0.5 Hz, 25 Hz, 25000 Hz, and 0.2 Hz. when F = 37 KHz, 50 Khz or 100 Khz and F1 = 1 Hz. There are many ways to achieve a rectangular oscillator, for example by using a voltage controlled oscillator mounted in astable such as the oscillator OP described in relation with FIG. 1. However, for economic reasons, at least one of the oscillators Oi of the MOC means is realized as shown in FIG. 8.

This oscillator Oi comprises a two-input NAND type gate, a resistance Pi and a capacitor Ci as illustrated in FIG. 8. The two inputs of the NAND type door are interconnected. The capacitor Ci is connected to these two inputs and to the ground while the resistor Pi connects the two inputs and the output of the NAND type gate. According to a variant of this preferred embodiment of an oscillator Oi, the resistance Pi is variable, which makes it possible to adjust the frequency of the oscillator Oi and consequently the signal of the control signal CO and thus to adjust the carrier frequency F.10

Claims (10)

CLAIMS1) Device for repelling a dipteran by diffusion of an ultrasonic signal (S), characterized in that it comprises an oscillator (OP) designed to generate a signal at a fixed ultrasonic frequency (F), said carrier, and means (MOD) to frequency modulate this signal by a so-called control signal (CO). 2) Device according to claim 1, wherein the oscillator (OP) is voltage controlled, and mounted astable so that the carrier frequency depends on the charging time of a capacitor (C), and the means (MOD) to modulate in frequency are then provided to modify the charging duration (TC) of this capacitor (C) according to the time evolution of the control signal (CO). 3) Device according to claim 2, wherein the means (MOD) for modulating the carrier frequency (F) comprise means (MOC) for forming the control signal (CO) from at least one rectangular signal of single frequency and less than the carrier frequency. 4) Device according to claim 3, wherein the means (MOC) for forming the control signal (CO) comprise another oscillator (01), intended to generate a rectangular signal (Si), said first rectangular signal, of frequency ( F1) unique and inferior to the carrier frequency (F). 5) Device according to claim 4, wherein the control signal (CO) is equal to the first rectangular signal (Sl). 6) Device according to claim 4, wherein the means (MOC) for forming the control signal (CO) comprise a plurality of other oscillators (02, O3, ... Oi) each intended to generate a rectangular signal (S2 , S3, ..., Si) of single frequency and less than the carrier frequency and means (ML) for forming a resultant signal (R) by mixing together these rectangular signals, the control signal (CO) then being obtained by mixing the first rectangular signal with the resulting signal (R). 7) Device according to claim 6, wherein the means (N1, N2, ... Ni) for mixing together these rectangular signals are two-input type NAND gates. 8) Device according to claim 7, wherein the means (MOC) for forming the control signal (CO) comprises: - four other oscillators (02, 03, 04 and 05), said second, third, fourth and fifth, intended each of them generating a rectangular signal (S2, S3, S4 S5) and - the means (ML) for forming the resulting signal (R) by mixing together these rectangular signals comprise: - three NAND type logic gates (N1, N2 , N3) with two inputs, said first and second, - the output of the second oscillator (02) is connected to one of the inputs of the first gate (N1) and the output of the third oscillator (03) is connected to the another input of the first gate (N1), the output of the fourth oscillator (04) is connected to one of the inputs of the second gate (N2) and the output of the first gate (N1) is connected to the other gate of the second gate (N2), the output of the fifth oscillator (05) is connected to one of the inputs of the third door (N3) and the output of the second door (N2) is connected to the other input of the third door (N3), - the resulting signal (R), which is then present on the output of the third door (N3), is mixed with the first rectangular signal (Sl). 9) Device according to one of claims 1 to 8, wherein the frequency of at least one oscillator is adjustable. 10) Device according to one of claims 8 or 9, wherein the carrier frequency is equal to 37 KHz, 50 Khz or 100 Khz, the frequency of the first rectangular signal is equal to 1 Hz and the frequency from the second, third Fourth and fifth oscillators are equal to 0.5 Hz, 25 Hz, 2500 Hz and 0.2 Hz.