KR200218164Y1 - Electronic Horn with Automatic Stop Function - Google Patents

Abstract

The present invention relates to an electric horn (HORN) used in a car or a motorcycle, and the horn may operate by itself regardless of the switch operation due to a failure of the horn operation switch installed in the vehicle or an electric wiring of the horn system. This situation can occur and cause damage to the unspecified number of people around by the noise. When such a situation occurs, the time when the horn switch is detected (turn on) is measured and the time is longer than the time set arbitrarily. The electronic horn is designed to stop the operation of the horn by judging it as a failure when the horn switch is detected.

Description

Electron Horn with Automatic Stop Function {.}

The present invention is a noise when the horn acts by itself regardless of the switch operation due to the failure of the horn operation switch installed in the vehicle or the electric wiring of the horn system installed in the vehicle. It is designed to prevent damage.

In the case of the conventional electronic horn, the pulse oscillation circuit for each sound generation is composed of the high sound generation and the low sound generation, and the sound is generated by the signal of the operation switch of the horn. There are products that produce various sounds with one CPU using a microprocessor (CPU) that is programmed beforehand without using IC.

This invention basically uses a microprocessor (CPU), but by putting the sensing part of the horn operation switch in the peripheral circuit to monitor the operation time of the switch, if it is operated for longer time than necessary, it can reduce the noise damage. In order to stop the generation of the pulse and to stop the operation of the transistor which receives the pulse signal and drive the operation coil of the horn, it prevents noise pollution and prevents the failure of the electromagnetic horn due to the heat generated during continuous operation. It is intended to construct an electron horn that can also prevent the discharge of the battery.

1 is a circuit diagram of the present invention

2 is a schematic diagram of the present invention 〈Description of the symbols for the main parts of the drawings〉 1: Switch detection unit 2 Power supply unit 3 Sound generation unit 4 Processor automatic control unit 5 Low coil drive unit 6 High sound coil drive unit 7 Power separation Diode 8: Low Coil 9: High Coil CPU: Microprocessor VDD: Constant Voltage Power Supply B +: Battery + Power Supply

Hereinafter, the configuration of the present invention will be described with reference to FIG. 1 of the accompanying drawings. In the circuit of the electronic horn, the power supply unit 2 supplies a stable voltage to the microprocessor (CPU), and the power separation diode 7 is a coil ( 8, 9) In order to operate the microprocessor (CPU) stably from the surge voltage and noise signal generated during operation, the ground between the high current drive circuit and the low current drive circuit is separated so as not to affect the circuit. The switch detection unit (1) in the center of the Q10 detects whether the horn switch is operated (+ voltage or-voltage when the horn switch of the handle is pressed) and transmits the signal to the microprocessor (CPU) through the resistor R4. Each time, the oscillating output of the high and low sound is output for 7 seconds for a certain period of time (longer than the discharge time of the excitation capacitor C2 (3)). And terminal 6, and at the same time, the output of terminal 5 of the microprocessor (CPU) operates transistor Q2 through resistor R21, and Q3 is operated by Q2 to charge the capacitor C2 for sound generation through resistor R5. In addition, the low-coil driving transistors Q7 and Q6 are operated through R7 and R8, and the high-coil driving transistors Q9 and Q4 are operated through the resistors R6 and R9 to flow current through the coils 8 and 9 for sound generation. The coil is excited to make an electromagnet. At this time, transistors Q5 and Q8 are repeatedly turned on and off according to the oscillation output of terminals 6 and 7 of the microprocessor (CPU), and in response to this, resistors R7 and transistor Q5 and resistors R6 and Q8 are connected. By repeating driving (ON / OFF), the coil driving transistors Q7, Q6, Q9, and Q4 are repeatedly operated to interrupt the excitation current of the coil according to the oscillation period of the microprocessor (CPU).

In the circuit operating as described above in more detail, the operation signal of the horn switch in the switch detection unit 1 is a-signal when the transistor Q1 conducts through the diode D5, zener diode D1, resistor R20 Then, the microprocessor (CPU) terminal 4 is reached through the emitter, the collector terminal, and the resistor R4 of Q1. When the operation signal of the horn switch is the + signal, the transistor Q10 is turned on through the zener diode D4, and the resistors R1 and R20 are connected. Since the base current of transistor Q1 flows through the collector and emitter terminals of transistor Q10, transistor Q1 also conducts, and this signal reaches terminal 4 of the microprocessor (CPU) through resistor R4 to sense this signal voltage. To output the oscillation signal from terminals 6 and 7 of the microprocessor (CPU) Giving a signal to the sound generating unit 3, the coil driving unit (5, 6) is operated to give a sound. At this time, when the horn switch operation signal reaching the microprocessor terminal 4 is detected for a longer time than the predetermined time set in the program of the automatic control unit 4, the microprocessor (CPU) generates a noise generator (terminal 5). 3) The operation output is stopped, and the oscillation output is immediately stopped at the terminals 6 and 7 and the continuous voltage is output so that the transistors Q8 and Q5 are turned on through the resistors R14 and R15 so that the coil driving transistors Q7, The drive current for operating Q6, Q9 and Q4 flows to ground through the collector and emitter terminals of transistor Q5, and to the ground through the collector and emitter terminals of transistor Q8. Q9 and Q4 are disabled so that the sound generating coils 8 and 9 are not excited.

Electromagnetic horn without this function causes the excitation current to continue to flow in the coil for electromagnet when the horn switch is kept pressed, so that each coil generates heat like a heater and burns out, and the coil driving transistor Q6 and Q4 are continuously energized. It is damaged by the heat generated by the electric horn as well as the problem that can lead to vehicle fire if you have a problem, since the generator does not operate when the engine is stopped, it has a problem that causes the discharge of the battery is essentially a coil drive transistor Q7 , Q6, Q9, and Q4 are disabled.

If the horn continues to operate due to a malfunction (short circuit) of the vehicle's horn switch or if the switch-related electrical wiring is damaged by sharp metal parts of the body and the electronic horn continues to operate beyond the contact with the vehicle body, the noise pollution Of course, due to the coil current of several amperes [A] flowing when operated, there is a problem that the coil and the coil driving transistor are excessively heated to lead to failure and lead to a vehicle fire.

Even if the above fault occurs, the present invention detects the operation time of the horn switch and stops the oscillation output when the horn switch is detected for more than a certain time (the time set in the microprocessor). It stops the coil current to stop and prevents noise pollution, prevents the breakdown of the electronic horn, and also prevents battery discharge of the vehicle.When the switch fault (short circuit) condition is canceled, it returns to normal use from then on. There is a number.

Claims (2)

The switch sensing unit 1, the power supply unit 2, the sound generating unit 3, the programmed processor automatic control unit 4, and the high and low coil driving units 5 and 6 are included. With the switch input terminal, when there is a switch input, the voltage output is transmitted to the automatic control unit 4 to operate the sound generator 3 to charge the capacitor C2 for sound generation, and to drive the coils 5 and 6 for the high and low sound, respectively. A pair of horns to output the pre-programmed high and low oscillation pulses and to excite the high and low coils (8, 9) in conjunction with these oscillation pulses. The oscillation output is output from the automatic control section 4 only when there is an output from the switch sensing section 1, and the output time of the oscillation output is greater than the maximum discharge time of the capacitor C2 of the sound generating section 3. If the output time is longer and the operating time of the switch detected by the switch detection unit 1 is detected by the automatic control unit 4 longer than the time set in the program, the oscillation output is stopped immediately and the sound generating coil ( (8) and (9) to stop the operation of the transistor, so that even if the switch signal is sensed indefinitely, the electronic horn characterized in that the sound generation automatically stops after a set time in the program.