ES1079105U - ELECTRONIC KITCHEN WITH COMPLEMENTARY CONTROL FOR VEHICLES - Google Patents

Abstract

Automatically controlled electronic horn comprising at least one exciter circuit (5), at least one electromagnetic coil (2) driven by said exciter circuit (5), and mechanical voice devices (1) operated by said coil ( 2), characterized in that it further comprises audio detectors (3) that obtain the voice signals and send the signals to at least one input terminal of an automatically controlled switching circuit (4), automatically controlled switching circuit (4). ) which automatically adjusts the frequency of the trigger signal and the loop ratio according to the environmental variations to send the input signal and the signal obtained by the combination of the original oscillation frequency signal of this input signal in the output trigger signal to said driver circuit (5). (Machine-translation by Google Translate, not legally binding)

Description

Electronic horn with complementary control for vehicles.

OBJECT OF THE INVENTION

The invention relates to electronic speakers.

The invention particularly relates to an automatically controlled electronic horn.

STATE OF THE TECHNIQUE

In the known state of the art, the voice control of the car horns is evaluated in two categories. These are; active voices and passive voices. The active voices are related to the electronic horn, so the electronic switching circuits control the coil in order to generate sound. The oscillation frequency of the switching circuit is determined artificially and the frequency must be set at the natural frequencies of the mechanical oscillation systems of the horn.

Active voices have the advantage that the electronic oscillator circuit obtains a constant frequency for the speakers. However, being under the impact of the voltage, the resistance of the circuit, the temperature, the humidity, the pressure, the oscillation diaphragm, the elasticity of the material etc. various external environmental variables can be considered an inconvenience for active voices. Constant frequency adjustment is difficult while the mechanical natural oscillation frequency changes with the external environment, and as a result, a lower voice pressure level is produced for the speakers.

Passive voices are formed by the oscillating movement of the electromagnetic coil diaphragm and with the on-off control with the energy of its own magnetic coil in order to generate sound. At this time, the frequency of the voice would automatically adjust the speaker, which would be close to the natural frequencies of the mechanical oscillation systems.

The advantage of passive voices is the opportunity to automatically adjust the horn to its natural frequency and this can be commonly used. The advantage of the type of mechanical contact, the type of Hall effect, and the loudspeakers of the optical type is the point of adjustment of the voice in the generation of voice, in which, first, the diaphragm is pulled to an appropriate position and It is then released, regardless of the external environment factors. The ideal design should include turning off the power at the lower limit and switching on the upper limit, and thus, the impact is obtained optimally in a design. Current passive speaker voices have common problems. The first of these is the problem of signal cutting, and if the switch closes or opens at an inappropriate time, this would cause a loss of energy and the difficulty of adjusting the product should also be considered. And the second of these problems is the need for excessive sensitivity of the mechanical structure for signal acquisition, which leads to deformation of the voice level or decrease of the voice level in long-term use.

As a result, the need for an electronic horn with servo control and the inadequacy of current solutions have required an improvement in the related technical field.

DESCRIPTION OF THE INVENTION

The present invention relates to the electronic horn, which meets the aforementioned requirements, eliminates all inconveniences and gives rise to some additional advantages.

The purpose of the invention is to obtain an automatically controlled technology for the speakers and eliminate all technical difficulties. In this way, the speakers are always operated at the resonance frequencies of their mechanical oscillation systems and the voice levels of the speakers are increased.

The purpose of the present invention is to provide a type of automatic electric horn comprising mechanical voice devices, electromagnetic coils, and exciter circuits. The output signal of the exciter circuit reaches the electromagnetic coil and the electromagnetic coil operates the mechanical voice devices and generates sounds. In addition, said electronic horn also comprises; Audio detectors and an automatic control switching circuit. The aforementioned audio detectors take the voice signals from the mechanical sound devices and send the signal to the input terminal of the automatic control switching circuit signal; and the input signal of the automatic control switching circuit and the original oscillation frequency signal are combined in the output trigger signal of the exciter circuit. The control switching circuit can be practical with variations in the environment and can automatically adjust the frequency of the trigger signal and the horn loop ratio.

A first operational amplifier of said aforementioned automatic control switching circuit comprises a basic oscillation circuit. The operational amplifier inversion input terminal of the operational amplifier is used to connect the voice signal input and the negative input of the operational amplifier is connected to the output terminal of said basic oscillation circuit and the output of the operational amplifier is connected to the said operation circuit.

In addition, it also comprises an overload protection circuit, and the input terminal of the overload protection circuit is connected to the output terminal of the dynamic control switching circuit and the output terminal of the overload protection circuit is connected to the input terminal of the operating circuit.

The overload protection circuit comprises a second operational amplifier, a resistor 10 (R10), a resistor 11 (R11), a resistor 12 (R12), a capacitor (C3), and a diode (D5). The reference voltage generated in said resistance (R10) and resistance (R11) is connected to the positive input of the second operational amplifier, one terminal of the Resistance (R12) is connected to ground through the Capacitor (C3) and the other terminal is connected to the dynamic output control, the common ends of the resistor (R12) and the capacitor (C3) are connected to the negative of the second operational amplifier, and the output of the second operational amplifier is connected to the input of the exciter circuit to through the reverse driving diode (D5).

The first and the second operational amplifier are applied with a dual operational amplifier integrated circuit (IC-OPAMP).

The aforementioned audio detectors are preferably an electret microphone or a mobile coil microphone or a microphone.

The aforementioned exciter circuit comprises a resistor (R4), a field effect transistor (FET), a duplex diode (D2), and a resistor (R5), and the gate terminal (G) of the transistor (FET) is connected to the output terminal of the automatic control switching circuit through the resistor (R4). The gate terminal (G) of the FET is connected to the drain terminal (D) of said transistor through the duplex diode (D2) which is connected in series with the other resistor (R5). The source terminal (S) of the transistor is grounded.

When compared to the prior art, the present invention has the characteristics given below:

one.

 The audio detector is an individual electronic component, is mounted directly on the circuit board, is small in size, cheap, easy to install, and does not require obtaining the signal of the mechanical structure;

2.

 The dynamic control switch uses only one operational amplifier, the circuit is simple and reduces costs effectively.

3.

 The loudspeaker always operates within the resonant frequency of mechanical oscillation systems based on power reduction, and this can improve the voice pressure level of the horn.

BRIEF DESCRIPTION OF THE FIGURES

For a better understanding of the embodiment of the present invention and its advantages with its additional components, it should be evaluated together with the figures described below.

Figure 1 is the block diagram showing the operation of the horn, which is the subject of the invention.

Figure 2 is the view of the horn circuit scheme, which is the subject of the invention.

Reference numbers and abbreviations

one.

 Mechanical voice device

2.

 Electromagnetic coil

3.

 Electromagnetic audio detector

Four.

 Switching circuit automatically controlled

5.

 Exciter circuit

6.

 Overload Protection Circuit

IC-OPAMP. Dual operational amplifier integrated circuit

T1: Terminal 1 T2: Terminal 2 T3: Terminal 3 T4: Terminal 4 T5: Terminal 5 T6: Terminal 6 T7: Terminal 7 T8: Terminal 8 FET Field effect transistor D (Drainer) G (Gate) S (Source) R1 : Resistance 1 R2: Resistance 2 R3: Resistance 3 R4: Resistance 4 R5: Resistance 5 R6: Resistance 6 R7: Resistance 7 R8: Resistance 8 R9: Resistance 9 R10: Resistance 10 R11: Resistance 11 R12: Resistance 12 R13: Resistance 13 C1: Capacitor 1 C2: Capacitor 2 C3: Capacitor 3 D1: Diode 1 D2: Diode 2 D3: Diode 3 D4: Diode 4

PREFERRED EMBODIMENT OF THE INVENTION

In this detailed description, the preferred embodiments of the automatically controlled electronic horn, which is the subject of the invention, will only be disclosed for a better understanding of the subject, and will not constitute any limiting effect.

As shown in Figure 1, the invention comprises a mechanical voice device (1), an electromagnetic coil (2), an electromagnetic audio detector (3), an automatically controlled switching circuit (4), an exciter circuit ( 5), and an overload protection circuit (6). Sound wave refraction is the main source of the signals whose detection was detected by the horn's audio detector (3). The control core is the automatically controlled switching circuit (4), and the automatically controlled switching circuit (4) directly read the electromagnetic audio detectors (3) of the signal.

The basic amplifier and the resonant 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, line pressure etc.) and occupies the empty part.

The mechanical voice device (1) is formed with the diaphragm that is secured with the upper pin. The magnetic coil (2) and the lower pin are mounted in a way that they are secured to the body together. While it is operating, said exciter circuit (5) switches the present magnetic coil (2). The magnetic coil (2) operates the mechanical voice device (1) to make it produce voice. The audio detector (3) is formed by a microphone.

The microphone used as the audio detector (3) audibly performs the oscillation movement of the diaphragm, which is called a mechanical voice device (1). The electromagnetic audio detector (3) produces 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 to the control switch of the exciter circuit ( 5). In this way, the dynamic control switching circuit (4) can detect the best resonance frequencies of the diaphragm oscillations. The overload protection circuit (6) prevents the high current that could damage said exciter circuit (5).

The circuit that operates for the automatically controlled switching circuit (4) shown in Figure 2 comprises; a double operational amplifier (LM358) as an integrated operational amplifier circuit (IC-OPAMP) and a circuit (D1, R13, D4): the LM358 comprises two individual operational amplifiers that have low power and high performance.

Diode 1 (D1) is to prevent reverse electrical connection to the diodes, while resistor 13 (R13) and diode 4 (D4) are used to balance the voltage.

Said operational amplifier integrated circuit (IC-OPAMP) forms the core of the automatically controlled switching circuit (4). Terminal 1 (T1) is the output terminal, terminal 2 (T2) is the negative terminal, terminal 3 (T3) is the positive input terminal, terminal 4 (T4) is the ground terminal, and the terminal 8 (T8) is the electrical connection terminal of the operational amplifier integrated circuit (IC-OPAMP).

The first operational amplifier, resistors 1, 2, 3, 6 and 7 (R1, R2, R3, R6, R7) and diode 3 (D3) form the basic amplifier. The values of resistors 1, 2, 3 (R1, R2, R3) set the upper and lower limits for the actions of pulling the diaphragm and releasing the diaphragm, respectively.

During ignition, resistance 7 (R7) and capacitor 2 (C2) determine the ignition time, and during shutdown, the parallel values of resistors 6, 7 (R6, R7) and capacitor 2 (C2) determine The shutdown time. Resistor 8 (R8) is used to derive the acoustic sensor, resistor 9 (R9) and capacitor 1 (C1) are responsible for extracting and processing the acoustic signal.

The diaphragm can decide the natural oscillation frequencies of resistors 1, 2, 3, 7 (R1, R2, R3, R7), of diode 3 (D3), of the basic oscillation circuit, of capacitor 1 (C1), of Capacitor 2 (C2) and automatic control switching circuit. Natural oscillation frequencies are established by the diaphragm and simply the thickness of the diaphragm affects these frequencies.

When the signal is not present during operation with electricity, terminal 3 (T3) is at the voltage of the upper disconnection point while terminal 2 (T2) of the amplifier integrated circuit operates (IC-OPAMP) is at a low level Terminal 1 (T1) corresponds to a high level and in this case, the exciter circuit (5) operates and the diaphragm is pulled to produce sound. In the descriptions set forth below in this document, the term leg may also be used instead of "terminal."

The electromagnetic audio detector (3) gains the appropriate signal power, increases the voltage level of terminal 2 (T2) of the first operational amplifier, the voltage level of terminal 3 (T3), exceeds the upper disconnection points and the exciter circuit (5) is disconnected and the voltage of terminal 3 (T3) jumps to the lower disconnection point.

The audio detector signals decrease, the level of terminal 2 (T2) of (IC2) drops more than the lower disconnection point voltage, the operation circuit (5) operates while output terminal 1 (T1) (1 ) is opposite and the output is at a high level, the diaphragm is pulled to produce sound, the voltage of terminal 3 (T3) again repeatedly jumps to the lower disconnection point with the dynamic control and the switching circuit produces a sound of horn.

In order to describe that the exciter circuit (5) is formed by; a resistor 4 (R4), a MOSFET (FET), a diode 2 (D2), and a resistor 5 (R5); resistor 4 (R4) adds the output control signal of the operational amplifier integrated circuit (IC-OPAMP) to said Mosfet (FET).

The Mosfet (FET) is responsible for switching the magnetic coil (2) and cutting the power of the magnetic coil (2). The Mosfet (FETT) provides a self-induction fem discharge, the self-induction fem has to reach the peak at a higher voltage, resistance 5 (R5) and provisional resistance prevent the voltage carrying diode 2 (D2) Duplex makes an impact on the circuit, and the Mosfet (FET) provides the discharge of electromagnetic power energy to the spiral coils.

Since there is a very low energy loss, the energy function inside the coil (2) can barely change the sound of the present high energy function.

The overload protection circuit (6) forms the core overload protection circuit. Resistors 10, 11 (R11, R10) form the pressure circuit, while the input is positive for terminal 5 (T5), the input is negative for terminal 6 (T6), and terminal 7 (T7) is the exit.

The signal switch of terminal 6 (T6) determines the position according to the signals coming from terminal 5 (T5).

The amplifier (IC2) decides whether or not there is an excessive load, and if the output of terminal 7 (T7) is at a low level and the diode (D5), the display of the Mosfet (T) is open at a high level, for example, the decision of the amplifier (IC2) is excessive load, and the power of the electromagnetic coil (2) is gone in order to protect the coil (2) from excessive load.

Claims (9)

one.

 Automatically controlled electronic horn comprising at least one exciter circuit (5), at least one electromagnetic coil (2) driven by said exciter circuit (5), and mechanical voice devices (1) operated by said coil (2) , characterized in that it also comprises audio detectors (3) that obtain the voice signals and that send the signals to at least one input terminal of an automatically controlled switching circuit (4), automatically controlled switching circuit (4) that Automatically adjusts the frequency of the trip signal and the loop ratio according to environmental variations to send the input signal and the signal obtained by combining the original oscillation frequency signal of this input signal into the signal of output trip to said exciter circuit (5).

2.

 Automatically controlled electronic horn according to claim 1 characterized in that it further comprises a first operational amplifier, which has an inverting input terminal used to connect the input of the audio signal; which has a negative input connected to the output terminal of a basic oscillation circuit, and an output terminal connected to the exciter circuit (5).

3.

 Automatically controlled electronic horn according to claim 1 characterized in that it further comprises an overload protection circuit (6), whose input is connected to an output terminal of the automatically controlled switching circuit (4), and whose output is connected to a input terminal of said exciter circuit (5).

Four.

 Automatic controlled electronic horn according to claim 3 characterized in that the overload protection circuit (6) comprises a second operational amplifier, a resistor 10 (R10), a resistor 11 (R11), a resistor2 (R12), a capacitor 3 (C3) and a diode 5 (D5).

5.

 Automatic controlled electronic horn according to claim 4 characterized in that the resistor 10 (R10) and the resistor 11 (R11) have a generated reference voltage that is connected to the positive input of the second operational amplifier; resistor 12 (R12) comprises a first terminal that is grounded through capacitor 3 (C3) and a second terminal that connects to the automatically controlled switching circuit (4), where the negative terminal of the second operational amplifier is connected with the common ends of resistor 12 (R12) and capacitor 3 (C3), and whose output is connected to the exciter circuit

(5) through at least diode 5 (D5), which is preferably reverse conduction.

6.

 Electronic vehicle horn automatically controlled according to claims 2 and 4 characterized in that it further comprises an operable amplifier integrated circuit (IC-OPAMP) with dual operational amplifiers that integrate the first operational amplifier and the second operational amplifier.

7.

 Electronic vehicle horn automatically controlled according to any of the preceding claims, and is characterized in that the audio detectors (3) are an electret microphone or a mobile coil microphone or a microphone.

8.

Electronic vehicle horn automatically controlled according to any of the preceding claims characterized in that the exciter circuit (5) comprises a resistor 4 (R4), a field effect transistor (FET), a duplex diode 2 (D2), and resistors 5 (R5).

9.

 Automatically controlled electronic horn according to claims 3 and 8 characterized in that the field effect transistor (FET) comprises a gate terminal (G) connected to the output terminal of the automatically controlled switching circuit (4) through resistor 4 (R4), where the gate terminal (G) is connected to a drain terminal (D) of the FET (T) which is the output of the exciter circuit (5), through one of the resistors 5 (R5) and diode 2 (D2), and where the field effect transistor (FET) further comprises a source terminal (S) that is grounded.

 FIG. one   FIG. 2