FR2995121A3 - ELECTRONICALLY CONTROLLED AUDIO ALARM - Google Patents

Abstract

The invention relates to an automatically controlled sound horn comprising at least one excitation circuit (5), at least one electromagnetic coil (2) driven by said excitation circuit (5), and mechanical sound devices (1) actuated by said coil (2), and also comprising audio detectors (3) obtaining the sound signals and sending the signals to at least one input terminal of an automatically controlled switching circuit (4); and an automatically controlled switching circuit (4), which automatically adjusts the trigger signal frequency and the loop coefficient according to the environmental variations to send the input signal and the signal obtained by combining the frequency signal oscillation of origin of this input signal to the output trip signal to said excitation circuit (5).

Description

The invention relates to electronic horns 5. The invention relates in particular to an automatically controlled buzzer. In the prior art, voice control of car horns is evaluated in two categories, namely active sounds and passive sounds. The active sounds are related to the electronic horn, whereby the electronic switching circuits control the coil to generate a sound. The oscillation frequency of the switching circuit is determined artificially and the frequency must be set to the natural frequencies of the mechanical oscillation systems of the horn. The advantage of active sounds is that the electronic oscillator obtains a constant frequency for the horns. However, being under the effect of voltage, circuit resistance, temperature, humidity, pressure, oscillation diaphragm, elasticity of material, etc., various external variables Environmental considerations may be considered a disadvantage for active sounds. Constant frequency adjustment is difficult while the natural mechanical oscillation frequency changes according to the external environment, and as a result thereof, a lower sound pressure level occurs for the horns. Passive sounds are formed by the oscillation movement of the electromagnetic coil diaphragm and the on / off control with the energy of its own magnet coil to generate a sound. At that time, the sound frequency would automatically adjust the speaker, which would be close to the natural frequencies of the mechanical oscillation systems.

The advantage of passive sounds lies in the possibility of automatic tuning of the horn at its natural frequency and this can be commonly used. The advantage of mechanical-type, Hall-effect type and optical-type audible horns is the sound adjustment point during sound generation in which the diaphragm is first drawn to an appropriate position and released, regardless of external environmental factors. The ideal design should include cutting the power supply to the lower limit and switching on to the upper limit, and in this way the impact is optimally achieved in one design. The current passive sounds of horns have common problems. The first of these is the problem of signal cutoff and if the switch is closed or opened at an inappropriate time, this would result in the loss of energy and the difficulty of tuning the product should also be considered. And the second problem is the demand of excessive sensitivity of the mechanical structure for the acquisition of the signal, which leads to the deformation of the sound level or the lowering of the sound level in a long-term use. Therefore, the need for a servo-controlled buzzer and the inappropriateness of current solutions have required the improvement of the associated technical field. The present invention relates to a horn that meets the above mentioned requirements, eliminates all the disadvantages and provides some additional benefits. The object of the invention is to achieve a technology with automatic control for horns and to eliminate all technical difficulties. In this way the horns are always used with the resonance frequencies of their mechanical oscillation systems and the sound levels of the horns are increased.

The object of the present invention is to provide an electronic sound horn comprising a mechanical sound device, electromagnetic coils and excitation circuits. The output signal of the excitation circuit drives the electromagnetic coil and the electromagnetic coil operates said mechanical sound devices and generates sounds. In addition, said horn also includes: audio detectors and an automatically controlled switching circuit. Said audio detectors receive the sound signals from the mechanical sound devices and send the signal to the signal input terminal of the automatically controlled switching circuit; and the input signal of the automatically controlled switching circuit and the original oscillation frequency signal are associated with the output trigger signal of the excitation circuit. The control switching circuit can be convenient for environmental variations and can automatically adjust the frequency of the trigger signal and the loop coefficient of the horn. The subject of the present invention is therefore an automatic control electronic sound horn comprising at least one excitation circuit, at least one electromagnetic coil driven by said excitation circuit, and mechanical sound devices actuated by said coil, characterized in that it further comprises audio detectors obtaining the audible signals and sending the signals to at least one input terminal of an automatically controlled switching circuit; and an automatically controlled switching circuit which automatically adjusts the trigger signal frequency and the loop coefficient according to the environmental variations to send the input signal and the signal obtained by associating the oscillation frequency signal with origin of this input signal to the output trip signal to said driver circuit.

The automatically operated electronic horn may include a first functional amplifier, which may include a basic oscillation circuit, which has a reversible input terminal for connecting the audio signal input, a negative input connected to the audio signal terminal. output of the basic oscillation circuit, and an output terminal connected to said excitation circuit. In addition, the automatic control electronic horn may include an overload protection circuit, the input of which is connected to the output terminal of the automatically controlled switching circuit and the output of which is connected to the input terminal of the control circuit. excitation circuit. The overload protection circuit may comprise a second functional amplifier, a resistor R10, a resistor R11, a resistor R12, a capacitor C3, and a diode D5. The overload protection circuit may comprise: the resistor R10 and the resistor R11, with the reference voltage generated across the resistors R10, R11 connected to the positive input of the second functional amplifier 1C2; resistor R12, one terminal of which is connected to ground by capacitor C3 and the other terminal is connected to the automatically controlled switching circuit; and the second functional amplifier 1C2, whose negative terminal is connected to the common terminals of said resistor R12 and the capacitor C3, and whose output is connected to the excitation circuit by at least one rear diode D5. The automatically controlled electronic horn may comprise an integrated circuit with two functional amplifiers, of which, where appropriate, the first functional amplifier and the second functional amplifier. Said audio detectors are preferably an electret microphone or a voice coil microphone or a microphone. Said excitation circuit may comprise a resistor R4, a field effect transistor (FET) T, a duplex diode D2 and resistors R5. The automatic control electronic horn may comprise at least one field effect transistor T which has a gate G connected to the output terminal of the automatically controlled switching circuit by the resistor R4, which again has a gate G connected to the drain D which is an output of the excitation circuit, by the resistor R5 and the duplex diode D2, and whose source S is connected to the ground. In comparison with the prior art, the present invention has the following characteristics: 1. The audio detector is an individual electronic component, it is mounted directly on the circuit board, is small in size, economical easy to install and does not require a signal from the mechanical structure; 2. The dynamic control switch uses only the functional amplifier, the circuit is simple and effectively reduces costs. 3. The loudspeaker still operates in the resonance frequency of mechanical oscillation systems based on power reduction, and this can improve the sound pressure level of the horn. For a better understanding of the embodiment of the present invention and its advantages with its additional components, it should be evaluated with reference to the accompanying drawings in which: - Figure 1 is a block diagram showing the operation of the horn according to the present invention; and Figure 2 is a circuit diagram of the horn according to the present invention. In this detailed description, the preferred embodiments of the automatic control buzzer, which is the subject of the invention, will only be described for a better understanding of the project, and will have no limiting effect. As shown in FIG. 1, the invention comprises a mechanical sound device 1, a magnetic coil 2, an electromagnetic audio detector 3, an automatically controlled switching circuit 4, an excitation circuit 5 and a protection circuit against overload 6. The sound wave refraction is the main source of the signals detected by the audio detector of the detection audible alarm 3. The control heart is the automatically controlled switching circuit 4 and the control switching circuit Automatic 4 directly read the electromagnetic audio sensors 3 of the signal. The base amplifier and the resonance frequency signal are simultaneous. The oscillation movement of the diaphragm becomes the trigger signal. The automatically controlled switching circuit 4 automatically changes the frequency with four environmental variables (voltage, resistance and temperature, humidity, fluid pressure, etc.) and occupies the empty portion.

The mechanical sound device 1 is formed with the diaphragm which is hooked to the upper plug. The magnetic coil 2 and the bottom plug are mounted so as to be hooked together to the body. During operation, said excitation circuit 5 switches the present magnetic coil 2. The magnetic coil 2 operates the mechanical sound device 1 to produce a sound. The audio detector 3 is formed of a microphone. The microphone used as the audio detector 3 creates at audio frequencies the oscillation movement of the diaphragm, which is called mechanical sound device 1. The electromagnetic audio detector 3 generates signals and repeatedly sends these signals to the automatically controlled switching circuit. 4, which can determine whether the movement of the diaphragm has reached the desired level or not, and the control switch of the excitation circuit 5. In this way, the dynamic control switching circuit 4 can detect the best resonance frequencies of the oscillations of the diaphragm. The overload protection circuit 6 avoids a high current which could damage said excitation circuit 5. The integrated circuit (IC) operating for the automatically controlled switching circuit 4 shown in FIG. 2 comprises: a dual functional amplifier ( LM358) and a circuit (D1, R13, D4): LM358 comprises two individual functional amplifiers having a low power and a high return.

D1 serves to avoid reverse power connection to the diodes, while resistor R13 and diode D4 are used to balance the voltage. Said integrated circuit (IC) forms the core of the automatically controlled switching circuit 4. The number 1 terminal is the output terminal, the number 2 terminal is the negative terminal, the number 3 terminal is the positive input terminal, the terminal number 4 is the earth terminal and terminal number 8 is the power connection terminal of the integrated circuit (IC). The integrated circuit of the functional amplifier can decide the basic oscillation frequencies of the resistors R1, R2, R3, R6, R7, of the diode D3, of the adjustable basic oscillation circuit of the component, the resistors R6, R7 , the diode D3, the capacitor C1, the capacitor C2 and the automatically controlled switching circuit IC1. The inverse signals of the upper limits of the lower end can be determined by changing the resistance values and cooperation can be achieved with various M indexes of sensitivity of the audio detector. The audio detector M, the resistors R8, R9, the resistor C1, the capacitors C1, C2 are responsible for the selection and operation of the audio signals. The signal and the key begin to operate with the starting oscillation frequency signal of the diaphragm group. When the signal is not present during operation with electricity, the number 3 terminal is 5 at the higher cutoff voltage while the number 2 terminal of the integrated circuit CI is low. Terminal number 1 corresponds to the high level and in this case the excitation circuit 5 operates and the diaphragm is pulled to produce a sound. In the descriptions below, the term "pin" can also be used instead of "terminal". The electromagnetic audio detector 3 obtains the appropriate signal power, increases the voltage level of the IC of the number 2 terminal, the voltage level of the number 3 pin exceeds the upper cutoff points and the excitation circuit 5 is cut off. and the voltage of pin number 3 goes to the lower cutoff point. The audio detector signals decrease, pin number 2 of the Cl2 level is at a voltage lower than the voltage of the lower cutoff point, the drive circuit 5 operates while the output pin number 1 is inverted and the output is located at the upper level, the diaphragm is pulled to produce a sound, the voltage of pin number 3 repeatedly jumps back to the lower cutoff point with the dynamic control and the switching circuit produces an alarm sound sound. To describe what is formed the excitation circuit 5: resistor R4, MOSFET (metal oxide field effect transistor) T, diode D2 and resistor R5; the resistor R4 adds an IC output control signal from the amplifier to said MOSFET T.

The MOSFET T is responsible for the switching of the magnetic coil 2 and the power cutoff from the magnetic coil 2. The MOSFET T discharges the electromotive force of self-induction, the electromotive force of self induction must reach a peak at a higher voltage, R5 and the temporary resistance prevents the diode D2 diode traversed by a voltage from causing an impact on the circuit, and the MOSFET T provides the electromagnetic power to discharge the spiral coils. Since there is a very low energy loss, the energy function in coil 2 can hardly change the sound of the high energy function present. The overload protection circuit 6 forms the main circuit for overload protection. The resistors R11, R10 form the pressure circuit, while the input is positive for pin number 5, the input is negative for pin number 6 and pin number 7 is the output.

The signal switch of the overload protection circuit 6 determines the position according to the signals from the pin number 5. The amplifier IC2 decides whether there is an excessive load or not, and if the output pin number 7 is at a low level and if the diode D5, the screen of the MOSFET T are open at a high level, for example, the decision of the amplifier IC2 is an excessive load, and the power of the electromagnetic coil 2 is discharged to protect the coil 2 from excessive load. 30

Claims (9)

CLAIMS1 - Automatically controlled electronic horn comprising at least one excitation circuit (5), at least one electromagnetic coil (2) driven by said excitation circuit (5), and mechanical sound devices (1) actuated by said coil (2), characterized in that it further comprises audio detectors (3) obtaining the audible signals and sending the signals to at least one input terminal of an automatically controlled switching circuit (4); and an automatically controlled switching circuit (4), which automatically adjusts the trigger signal frequency and the loop coefficient according to the environmental variations to send the input signal and the signal obtained by combining the frequency signal oscillation of origin of this input signal to the output trip signal to said excitation circuit (5). 2 - automatic control electronic horn according to claim 1, characterized in that it comprises a first functional amplifier (IC1) which has a reversible input terminal for connecting the input of the audio signal, a negative input connected to the output terminal of the basic oscillation circuit, and an output terminal connected to said excitation circuit (5). 3 - Automatically controlled electronic horn according to claim 1, characterized in that it comprises an overload protection circuit (6), the input of which is connected to the output terminal of the automatically controlled switching circuit (4) and whose output is connected to said input terminal of the excitation circuit (5). 4 - Automatically controlled electronic horn according to claim 3, characterized in that the overload protection circuit (6) comprises: a second functional amplifier (IC2), a resistor (R10), a resistor (R11), a resistor (R12), a capacitor (C3), and a diode (D5). 5 - Automatically controlled electronic horn according to claim 4, characterized in that the overload protection circuit (6) comprises: the resistor (R10) and the resistor (R11), with the reference voltage generated at the terminals resistors (R10, R11) connected to the positive input of the second functional amplifier (IC2); the resistor (R12), one terminal of which is connected to earth by the capacitor (C3) and the other terminal is connected to the automatically controlled switching circuit (4); and the second functional amplifier (IC2), whose negative terminal is connected to the common terminals of said resistor (R12) and the capacitor (C3), and whose output is connected to the excitation circuit (5) by at least one diode rear (D5). 6 - automatic control electronic horn according to any one of the preceding claims, characterized in that it comprises an integrated circuit (IC) with two functional amplifiers including, where appropriate, the first functional amplifier (IC1) and the second functional amplifier (IC2). 7 - automatic control electronic horn according to any one of the preceding claims, characterized in that the audio detectors (3) are an electret microphone or a voice coil microphone or a microphone. 8 - automatic control electronic horn according to any one of the preceding claims, characterized in that said excitation circuit (5) comprises a resistor (R4), a field effect transistor (T), a duplex diode (D2) and resistors (R5). 9 - electronic audible alarm with automatic control according to claim 8, characterized in that it comprises at least one field effect transistor (T) which has a gate (G) connected to the output terminal of the switching circuit to automatic control (4) by the resistor (R4), which again has a gate (G) connected to the drain (D) which is an output of the excitation circuit, by the resistor (R5) and the duplex diode (D2) , and whose source (S) is connected to the earth.