KR100881950B1 - Perfect combustion guidance apparatus - Google Patents

Abstract

A perfect combustion induction system is provided to improve fuel conversion efficiency for the perfect combustion by transmitting regular sinusoidal wave to a fuel pipe via the antenna unit. A perfect combustion induction system comprises a power input unit(10) applying DC power, a DC converter(20) converting the voltage of the DC power and supplying it as DC drive power, a regulator converting the voltage of the drive power and supplying it as operation voltage(VCC), an MPU unit(60) outputting square-wave pulse according to the internal oscillation frequency, a waveform converter(90) which receives the square-wave pulse and converts it into sinusoidal wave signal, an amplifier(40) amplifying the sinusoidal wave signal, an antenna unit(100) outputting the amplified sinusoidal wave signal to a fuel tube in which the fuel flows, and a waveform compensator(80) which is mounted between the MPU unit and the wave form converter and controls the output of square-wave signal in order to prevent signal attenuation during waveform conversion.

Description

PERFECT COMBUSTION GUIDANCE APPARATUS}

The present invention relates to a complete combustion induction apparatus, and in particular, to output a sinusoidal waveform to an duct through an antenna to change the molecular structure of the liquid fuel flowing through the duct to induce a constant sine wave output and various antenna schemes in a device that induces full combustion of fuel. The present invention relates to a complete combustion induction apparatus through which the fuel conversion efficiency can be improved.

Normally, in engines of vehicles or other power units, liquid or gaseous fuel is mixed with air at a certain ratio, flowed into the inside of a closed container and compressed, so that an explosion occurs by ignition and uses the force generated during the explosion. It is a well-known fact that it is intended to gain power.

Therefore, if oil pretreatment is performed to pre-treat fluid such as fuel to improve explosion and ignition by compression and ignition, combustion efficiency is improved and fuel economy is increased, and air pollution is also caused by incomplete combustion. Can be significantly reduced.

One way is to burn the high frequency through the antenna attached to the outside of the tube to change the molecular structure of the liquid or gaseous fuel flowing through the tube to improve the ability of hydrogen molecules to bond with oxygen molecules A fuel booster device has been developed that allows for clean and fast combustion.

Such a prior art fuel booster device is shown in FIG. 1.

Referring to FIG. 1, the input power supplied from the outside is supplied to the driving power through a transformer of the switched-mode power supply (SMPS) 1 and the SMPS controller, and the driving power 9V is a constant voltage IC 2. Is supplied to the operating power supply (Vcc) during the operation, and the timer IC supplied with the driving power is configured to output a sawtooth wave waveform from the timer IC to a signal supplied from the microprocessor via the transistor and from the timer IC. The sawtooth waveform is supplied to the microprocessor via a transistor as a square wave pulse, and the microprocessor receiving the sawtooth waveform from the timer IC in the form of a square wave pulse outputs a signal for generating a waveform. The signal of "H" or "L" generated by the inverters of the connected flashing signal generator 6 is a light emitting die. The light emitting diodes of the LED display unit 5 are turned on or blinking, and the signal of "H" or "L" output from the microprocessor is amplified by the amplification IC and the transformer of the waveform amplification unit 7 to generate high frequency. The waveform is configured to be output through the two antennas 9 and 10.

However, the fuel booster device of the prior art has a problem in that the fuel conversion efficiency for complete combustion, which is the purpose of the device, is lowered because the output waveform output through the antenna is not constant.

In addition, if the output is increased to improve it, a large amount of electromagnetic waves are generated, which is not good for the electronic parts, etc.

The present invention relates to a complete combustion induction apparatus, comprising: a power input unit for applying direct current power; A DC converter unit for supplying a DC driving power by transforming the DC power applied from the power input unit; A regulator unit for transforming driving power applied from the DC converter unit to supply an operating power VCC; An MPU unit configured to output a square wave pulse according to an internal oscillation frequency; A waveform converter which receives the square wave pulse output from the MPU unit and converts the square wave pulse into a sine wave signal; An amplifier for amplifying the sine wave signal output from the waveform converter; And an antenna unit configured to output the amplified sinusoidal signal output from the amplifier to a pipe through which fuel flows. A waveform compensator is connected between the MPU unit and the waveform convertor, and the waveform compensator selectively depends on a frequency output from the MPU unit to prevent signal attenuation generated during the waveform converting process of the waveform convertor. And controlling a square wave signal output applied to the waveform converter.

Preferably, the waveform compensator receives an input of a square wave output from the MPU unit to the base terminal of the seventh transistor Q7 and receives an operating power supply VCC of the regulator unit to a collector terminal to operate according to the input of the square wave. Switching power is supplied to the waveform conversion unit 90, the operating power switched in accordance with the input of the square wave is input to the base terminal of the sixth transistor (Q6) and according to the switching frequency of the sixth transistor (Q6) The operating power connected to the collector stage is charged and discharged to the capacitor C23, and the fifth transistor Q5 is turned on according to the state of charge of the capacitor C23. When a low frequency is input from the MPU unit, the capacitor C23 is charged. Applied to the base terminal of the fifth transistor Q5 to operate the fifth transistor Q5 to supply a square wave to the waveform converter. When the high frequency is inputted from the MPU unit and the high frequency is inputted through the collector stage, the capacitor C23 is not charged so that the fifth transistor Q5 is not operated, thereby passing the square wave signal supplied to the waveform converter as it is. It is characterized by.

More preferably, the antenna unit is composed of a first antenna wire and a second antenna wire wound in a flow pipe through which liquid fuel flows, and the first antenna wire and the second antenna wire are formed as a single line that meets each other during winding. It is done.

More preferably, the antenna unit is composed of a first antenna wire and a second antenna wire wound around the flow pipe through which liquid fuel flows, and the first antenna wire and the second antenna wire are wound in opposite directions to each other and the ends thereof are opened. Characterized in that formed in two lines.

More preferably, the antenna unit is composed of a first antenna wire and a second antenna wire wound around the flow pipe through which liquid fuel flows, and the first antenna wire and the second antenna wire are wound in opposite directions and wound on both sides of the wound bundle. It is characterized by being formed in a single line that is wound at a central portion between and meets each other during winding of the central portion.

More preferably, the antenna unit is formed in two lines comprising a first antenna wire connected to the inner conductor plate of the milk pipe and a second antenna wire connected to the outer surface of the milk pipe through the milk pipe.

According to the present invention, the fuel conversion efficiency can be improved through a constant sinusoidal output and various antenna schemes in a device that induces complete combustion of fuel by outputting a sinusoidal waveform to an duct through an antenna and changing the molecular structure of the liquid fuel flowing through the duct. It is effective to be.

That is, even when the variable frequency is used by the waveform compensator, the corresponding waveform converter can output a constant sinusoidal wave, so that a constant sinusoidal wave without distortion is transmitted to the associated pipe through the antenna unit to increase fuel conversion efficiency for complete combustion. Will be.

In addition, it is possible to increase the fuel conversion efficiency for complete combustion by applying the optimized antenna method according to the material of the pipe.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

Hereinafter, the present invention outputs a sinusoidal waveform through a wound antenna to change the molecular structure of the liquid fuel flowing through the canal by inducing a complete combustion of the fuel in the device to induce fuel combustion through a constant sinusoidal output and various antenna winding methods Full combustion induction apparatus that can increase the will be described as a preferred embodiment, but the technical idea of the present invention is not limited or limited to this can be variously modified by those skilled in the art.

2 is an overall block diagram for explaining a complete combustion induction apparatus according to an embodiment of the present invention, Figures 3 and 4 is an overall circuit diagram for explaining a complete combustion induction apparatus according to an embodiment of the present invention.

The complete combustion induction device to which the present invention is applied includes a power input unit 10, a DC converter unit 20, a regulator unit 30, an amplifier unit 40, a reference oscillator unit 50, and a microprocessor unit (MPU) unit 60. , A display unit 70, a waveform compensator 80, a waveform converter 90, and an antenna unit 100.

The power input unit 10 receives a DC 9V ~ 30V through the input terminal, the varistor (C6) for protecting the circuit from the transient voltage generated from the input power and a common mode noise filter for removing noise of the input power ( T3), the reverse voltage prevention diode (D2) and the filter circuit (C9, C10) and serves to stabilize the input DC power.

The DC converter 20 receives the DC power stabilized through the power input unit 10 through the input terminal VCC of the internal converter IC U2 and converts the DC power into DC driving power required for the circuit. Here, the DC driving power that is transformed and output through the DC converter unit 20 is determined by the resistance ratios of the distribution resistors R8 and R9 connected to the output terminal COMP_IN of the converter IC U2, and the eighth resistor. The 8V DC driving power is output through R8 and applied to the regulator 30, the amplifier 40, and the display 70.

The regulator unit 30 receives the 8V DC driving power applied from the DC converter unit 20 and outputs the DC 5V stabilized operating power VCC through the internal regulator IC U3. Here, filter circuits C14 and C15 are connected to the output terminal for stabilizing the power supply.

On the other hand, the reference oscillator 50 generates an 8 MHz reference waveform from the internal oscillator X1 and inputs the oscillation input terminals XTAL1 and XTAL2 of the MPU IC U1 of the MPU unit 60.

The MPU unit 60 receives an operating power supply VCC applied from the regulator unit 30 and outputs a square wave pulse through the output terminal P1.4, and also outputs P1.0, P1.1, The light emitting diodes LED1, LED2, LED3, LED4, and LED5 of the display unit 70 may be turned on through P1.2 and P1.3.

That is, an 8V DC driving power source from the DC converter unit 20 is applied to the corresponding display unit 70 via the first resistor R1 and the signal from the output terminal P1.0 from the MPU unit 60. When the supply is applied to the base end of the first transistor Q1, the first transistor Q1 is turned on to light the first and second light emitting diodes LED1 and LED2, thereby powering the device externally. You can confirm that you are authorized.

Similarly, the base terminal of the other transistors Q2, Q3, and Q5 is also connected to the output terminals P1.1, P1.2, and P1.3 of the corresponding MPU IC U1, so that the operation state of the corresponding MPU IC U1 can be maintained. Accordingly, by selectively lighting the light emitting diodes LED3, LED4, and LED5 using a driving power source, the MPU IC U1 is notified to the outside.

Meanwhile, the waveform converter 90 receives a square wave pulse output from the MPU unit 60 and converts the square wave pulse into a sinusoidal wave through an internal waveform converter IC U4A. Amplified by the amplifying IC (U5) to output a sine wave through the antenna unit (100). In this case, the output transformer TRANS is connected to an end of the amplifier 40 adjacent to the antenna unit 100 to insulate and separate the external and internal circuits.

At this time, looking at the sinusoidal wave output waveform of the antenna unit 100, the output waveform of the sinusoidal wave is not constant, as shown in FIG.

This is because a large attenuation occurs at a high frequency due to the reactance of the capacitor C20 in the process of converting the square wave to the sinusoid by the waveform conversion IC U4A of the waveform converter 90 in an environment using a variable frequency. to be.

To compensate for this, if the amplification gain is set according to the high frequency by connecting the frequency adjusting resistor R10, the distortion occurs at the low frequency.

Accordingly, the MPU unit 60 outputs a square wave pulse by the waveform compensation unit 80 to reduce the square wave input signal to the waveform conversion IC U4A at a low frequency by adjusting the amplification gain of the waveform conversion IC U4A to a high frequency. ) And the waveform conversion unit 90 for sine wave conversion of the square wave.

The waveform compensation unit 80 will be described in more detail. The waveform compensation unit 80 receives a square wave pulse output from the MPU unit 60 and applies it to the base terminal of the seventh transistor Q7 used as a buffer. do. Accordingly, the seventh transistor Q7 switches the operating voltage VCC of the collector stage according to the input of the square wave pulse to output the square wave through the resistor R14, and sets the frequency gain through the line of the resistor R19. Done.

That is, the sixth transistor Q6 receives the square wave output from the seventh transistor Q7 through the base end to switch the operating power supply VCC. When the square wave is applied to the sixth transistor Q6, the collector The charge / discharge capacitor C23 connected to the stage is periodically charged and discharged.

The fifth transistor Q5 is operated by using the charge / discharge voltage of the capacitor C23. When a low frequency square wave is input to the circuit, the charge / discharge capacitor C23 converts the charged voltage to the fifth transistor Q5. By applying the fifth transistor (Q5) to the base terminal of the () to reduce the square wave signal applied to the waveform converter 90 through the resistor (R14).

On the contrary, when the square wave of high frequency is input to the circuit, the corresponding charge / discharge capacitor C23 is not charged properly, and thus the fifth transistor Q5 cannot be operated. Thus, the waveform converter 90 The square wave signal applied by) is passed as it is.

By the operation of the waveform compensator 80, even in an environment using a variable frequency, as shown in FIG. 6, the waveform converting unit 90 can output a constant sine wave, thereby causing distortion through the antenna unit 100. Constant sinusoidal waves are transmitted to the canal to increase fuel conversion efficiency for complete combustion.

Meanwhile, an example of the antenna unit 100 is illustrated in FIG. 7.

The two output antenna wires 110 and 120 of the antenna unit 100 are wound (about 10 to 15 turns) around the oil pipe P1 through which the liquid fuel flows. In this case, the first antenna wire 110 and the first antenna wire 110 are formed. The two antenna wires 120 are single lines that meet each other during winding, as shown in FIG.

As such, the winding method in which the first antenna wire 110 and the second antenna wire 120 are formed in a single line is preferable when the related pipe P1 is made of a metal material.

In addition, another example of the antenna unit 100 is illustrated in FIG. 8.

The two-stranded output antenna wires 110 and 120 of the antenna unit 100 are wound around the oil pipe P2 through which liquid fuel flows. In this case, the first antenna wire 110 and the second antenna wire 120 are As illustrated in FIG. 8, two ends are wound to be wound in opposite directions to open ends. In this case, winding directions of the first antenna wire 110 and the second antenna wire 120 are opposite to each other.

As such, the winding method in which the first antenna wire 110 and the second antenna wire 120 are formed in two lines is preferable when the oil pipe P2 is made of a non-metallic material (eg, a rubber pipe).

In addition, another example of the antenna unit 100 is illustrated in FIG. 9.

The two output antenna wires 110 and 120 of the antenna unit 100 are wound around the oil pipe P3 through which liquid fuel flows. In this case, the first antenna wire 110 and the second antenna wire 120 are As shown in FIG. 9, it is a single line wound in the opposite direction to each other and wound again in the center portion between the two wound turns bundles thus wound and meeting each other during the winding of the center portion.

As described above, the winding method in which the first antenna wire 110 and the second antenna wire 120 are formed in a single line and winding in three portions is preferable when the related pipe P3 is made of a mixture of a non-metallic material and a metal material. .

In addition, another example of the antenna unit 100 is illustrated in FIG. 10.

The two output antenna wires 110 and 120 of the antenna unit 100 are connected to the oil pipe P4 through which the liquid fuel flows. In this case, as shown in FIG. 10, the first antenna wire 110 penetrates through the oil pipe P4 and is connected to the inner conductor plate 111 of the oil pipe P4, and the second antenna wire 120 is connected to the oil pipe P4. Will be connected to the outer surface.

As described above, the first antenna wire 110 and the second antenna wire 120 are formed in two lines, but the first line is connected to the inner conductor plate 111 of the oil pipe P4. It is preferred for large large diameter canals.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited to the drawings shown.

1 is a block diagram showing a fuel booster device according to the prior art;

Figure 2 is an overall block diagram for explaining the complete combustion induction apparatus according to an embodiment of the present invention.

3 and 4 is an overall circuit diagram for explaining a complete combustion induction apparatus according to an embodiment of the present invention.

5 is a view showing a sine wave output waveform of the antenna according to the prior art.

6 is a view showing a sinusoidal wave output waveform of an antenna according to the present invention;

7 is a view showing an example of an antenna unit according to the present invention.

8 is a view showing another example of an antenna unit according to the present invention.

9 is a view showing another example of an antenna unit according to the present invention.

10 is a view showing another example of an antenna unit according to the present invention.

Claims (6)

A power input unit for applying a DC power supply; A DC converter unit for supplying a DC driving power by transforming a DC power applied from the power input unit; A regulator unit for transforming driving power applied from the DC converter unit to supply an operating power VCC; An MPU unit for outputting square wave pulses according to an internal oscillation frequency; A waveform converter which receives the square wave pulse output from the MPU unit and converts the square wave pulse into a sine wave signal; An amplifier for amplifying the sine wave signal output from the waveform converter; And An antenna unit for outputting an amplified sine wave signal output from the amplifier to a pipe through which fuel flows; Including, A waveform compensator is connected between the MPU unit and the waveform converting unit, and the waveform compensating unit is selectively connected to the waveform converting unit according to the frequency output from the MPU unit so as to prevent signal attenuation generated during the waveform converting process of the waveform converting unit. Full combustion induction apparatus, characterized in that for controlling the applied square wave signal output. The method of claim 1, The waveform compensator receives an input of a square wave output from the MPU unit to the base terminal of the seventh transistor Q7 and receives an operating power supply (VCC) of the regulator unit to a collector terminal, thereby operating power according to the input of the square wave. Switch to supply to the waveform conversion unit 90, The operating power switched according to the square wave input is input to the base terminal of the sixth transistor Q6 to charge and discharge the operating power connected to the collector terminal of the sixth transistor Q6 to the capacitor C23 according to the corresponding switching frequency. The fifth transistor Q5 is turned on according to the state of charge of the capacitor C23, When the low frequency is input from the MPU unit, the voltage charged in the corresponding capacitor C23 is applied to the base terminal of the fifth transistor Q5 to operate the fifth transistor Q5 to supply the square wave signal supplied to the waveform converter. Guided through the collector stage and removed, When the high frequency is input from the MPU unit, the corresponding capacitor (C23) is not charged, so that the fifth transistor (Q5) is not operated to pass the square wave signal supplied to the waveform converter as it is. The method according to claim 1 or 2, The antenna unit is composed of a first antenna wire and a second antenna wire wound in a conduit through which liquid fuel flows, and the first antenna wire and the second antenna wire are formed as a single line that meets each other during winding. Complete combustion induction device. The method according to claim 1 or 2, The antenna unit is composed of a first antenna wire and a second antenna wire wound around the flow pipe of the liquid fuel, the first antenna wire and the second antenna wire is wound in the opposite direction to each other two ends to be opened Complete combustion induction apparatus, characterized in that formed by the line of. The method according to claim 1 or 2, The antenna unit is composed of a first antenna wire and a second antenna wire wound around the flow pipe through which liquid fuel flows, and the first antenna wire and the second antenna wire are wound in opposite directions to each other, and both sides are thus wound up. And the ends of the rolled bundles are formed in a single line which is wound again at a central portion between the two rolled bundles to meet each other. The method according to claim 1 or 2, The antenna unit is a complete combustion induction apparatus, characterized in that formed through two lines consisting of a first antenna wire connected to the inner conductor plate of the tube and the second antenna wire connected to the outer surface of the tube.

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