System for reducing fuel consumption and increasing output of internal combustion engine using output-wave

Abstract

There is provided a system for reducing fuel consumption and increasing output of an internal combustion engine using an output-wave, the system comprising: an output-wave generation and amplification device configured to generated an amplified output-wave; an output-wave transmitter connected to the output-wave generation and amplification device for transmitting an output-wave to an air intake channel of an internal combustion engine, wherein the output-wave transmitter is inserted into the channel; an output-wave adjuster configured to adjust the output-wave from the output-wave generation and amplification device, wherein the output-wave adjuster is disposed between the output-wave transmission terminal and the output-wave transmitter.

Claims

1. A system for reducing fuel consumption and increasing output of an internal combustion engine using an output-wave, the system comprising: an output-wave generation and amplification device 100 configured to generated an amplified output-wave; an output-wave transmitter 200 connected to the output-wave generation and amplification device 100 for transmitting an output-wave to an air intake channel 710 of an internal combustion engine 700, wherein the output-wave transmitter 200 is inserted into the channel 710; an output-wave adjuster 300 configured to adjust the output-wave from the output-wave generation and amplification device 100, wherein the output-wave adjuster 300 is disposed between the output-wave transmission terminal 160 and the output-wave transmitter 200, wherein the output-wave generation and amplification device 100 includes: a power-supply terminal 110 configured to supply external power; a power supply 120 configured to supply the external power supplied through the power-supply terminal 110 to a frequency generation module 130; the frequency generation module 130 configured to be driven by the power supplied from the power supply 120 to generate a frequency having a waveform; a waveform-shaping module 140 configured to shape the waveform of the frequency generated by the frequency generation module 130; a power amplification module 150 configured to amplify the frequency shaped through the waveform-shaping module 140; and an output-wave transmission terminal 160 configured to transmit the output-wave to the output-wave transmitter 200, wherein the output-wave transmitter includes an emission coil, wherein when the output-wave transmitter 200 emits the output-wave into the air intake channel 710, the output wave vibrates moisture in air sucked through the air intake channel 710 to decompose the moisture into oxygen and hydrogen.

2. The system of claim 1, further comprising an output-wave amplifier 400 between the output-wave adjuster 300 and the output-wave transmitter 200, wherein the output-wave amplifier 400 is configured to further amplify the wavelength of the output-wave to be transmitted to the output-wave transmitter 200.

3. The system of claim 1, further comprising an output-wave distributor 500 between the output-wave adjuster 300 and the output-wave transmitter 200, wherein the output-wave transmitter 200 includes a plurality of output-wave sub-transmitters 200 installed along a longitudinal direction of the air intake channel 710, wherein the output-wave distributor 500 is configured to distribute the output-wave between and to the plurality of output-wave sub-transmitters 200.

4. The system of claim 1, further comprising: an output-wave distributor 500 between the output-wave adjuster 300 and the output-wave transmitter 200, wherein the output-wave transmitter 200 includes a plurality of output-wave sub-transmitters 200 installed along a longitudinal direction of the air intake channel 710, wherein the output-wave distributor 500 is configured to distribute the output-wave between and to the plurality of output-wave sub-transmitters 200; and a plurality of output-wave sub-amplifiers 400 disposed between the distributor 500 and the output-wave sub-transmitters 200 respectively, wherein the output-wave sub-amplifier 400 are respectively configured to further amplify the wavelengths of the output-waves to be transmitted to the output-wave sub-transmitter 200.

5. The system of claim 1, further comprising a humidifier 600 coupled to the air intake channel 710, wherein the humidifier is configured to further supply moisture into air sucked through the air intake channel 710, whereby decomposed oxygen and hydrogen via water decomposition using the output wave from the output-wave transmitter 200 are supplied more into the engine 700.

6. The system of claim 1, wherein the output-wave transmitter 200 includes at least one emission coil 220, wherein the shape of the coil include a circular annular shape or a rod shape.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a basic block diagram of a system for reducing fuel consumption and increasing output of an internal combustion engine according to the present disclosure.

(2) FIG. 2 is a circuit diagram of an output-wave generation and amplification device in a system for reducing fuel consumption and increasing output of an internal combustion engine according to the present disclosure.

(3) FIG. 3 is a circuit diagram of an output-wave adjuster in a system for reducing fuel consumption and increasing output of an internal combustion engine according to the present disclosure.

(4) FIG. 4 is a block diagram illustrating a system for reducing fuel consumption and increasing output of an internal combustion engine according to a first embodiment of the present disclosure.

(5) FIG. 5 is a block diagram showing a system for reducing fuel consumption and increasing output of an internal combustion engine according to a second embodiment of the present disclosure.

(6) FIG. 6 is a block diagram of a system for reducing fuel consumption and increasing output of an internal combustion engine according to a third embodiment of the present disclosure.

(7) FIG. 7 is an illustration of a first embodiment of an output-wave transmitter in a system for reducing fuel consumption and increasing output of an internal combustion engine according to the present disclosure.

(8) FIG. 8 is an illustration of a second embodiment of the out-wave transmitter in a system for reducing fuel consumption and increasing output of an internal combustion engine according to the present disclosure.

DETAILED DESCRIPTION

(9) Hereinafter, preferred embodiments of the present disclosure will be described in detail with reference to the accompanying drawings so that those skilled in the art can readily implement the present disclosure.

(10) As shown in FIGS. 1 to 3, the system for reducing fuel consumption and increasing output of an internal combustion engine using an output-wave according to the present disclosure basically includes an output-wave generation and amplification device 100 configured to generated an amplified output-wave, and an output-wave transmitter 200 connected to the output-wave generation and amplification device 100 for transmitting an output-wave to an air intake channel 710 of an internal combustion engine 700.

(11) In this connection, the output-wave generation and amplification device 100 includes a power-supply terminal 110 for supplying external power as an input terminal and includes an output-wave transmission terminal 160 configured to transmit the output-wave to the output-wave transmitter 200 as an output terminal.

(12) The output-wave generation and amplification device 100 includes a power supply 120, a frequency generation module 130, a waveform-shaping module 140, and a power amplification module 150 in sequence between the power-supply terminal 110 and the output-wave transmission terminal 160. Thus, the output-wave generation and amplification device 100 generates, shapes, and amplifies a frequency to generate an amplified output wave.

(13) As a result, the output-wave is a type of a frequency of a few kHz to a few megahertz. The frequency may vary between an audible band and a non-audible band. In particular, the output wave may decompose moisture in the air into oxygen and hydrogen by vibrating the air. Therefore, it is preferable that the output wave is formed of a square wave having excellent resonance.

(14) In this connection, the power supply 120 converts the external power supplied through the power-supply terminal 110 into an appropriate utility power that can be driven by the frequency generation module 130.

(15) The power supply 120 supplies the converted power to the frequency generation module 130.

(16) Next, the frequency generation module 130 is driven by the utility power supplied from the power supply 120 to generate a frequency having a waveform.

(17) Subsequently, the waveform-shaping module 140 shapes the waveform of the frequency generated by the frequency generation module 130.

(18) For example, the waveform-shaping module 140 adjusts the length of the AM frequency to form a square wave approximate to the FM frequency.

(19) The power amplification module 150 amplifies the wavelength of the formed frequency through the waveform-shaping module 140. The amplified frequency is supplied to the output-wave transmission terminal 160. The output-wave transmission terminal 160 provides the output frequency to the output-wave transmitter 200, which, in turn, uses the output frequency to implement an output-wave.

(20) In this connection, the output-wave generation and amplification device 100 preferably has all components from the power-supply terminal 110 to the output-wave transmission terminal 160 integrally formed on the PCB.

(21) The output-wave transmitter 200 is connected to the output-wave transmission terminal 160 of the output-wave generation and amplification device 100. The output-wave transmitter 200 outputs an output-wave into the air intake channel 710. The output wave may vibrate the moisture in the air sucked through the air intake channel 710 to decompose the moisture into oxygen and hydrogen. To this end, the output-wave transmitter 200 is inserted into the air intake channel 710 for supplying external air to the internal combustion engine 700. The output-wave transmitter 200 has a plurality of emission coils 220 in the channel 710.

(22) In this connection, the output-wave transmitter 200 generally transmits the output-wave using the emission coil 220. To both ends of the emission coil 220, conductive plates 210 are connected respectively. That is, the output-wave transmission terminal 160 is connected to the conductive plates 210, whereby the emission coil 220 emits the output-wave having resonance.

(23) Eventually, while, on the one hand, the fuel gas is supplied into the internal combustion engine 700 through the fuel supply line of the internal combustion engine 700, on the other hand, through the air intake channel 710, air is supplied into the internal combustion engine 700. At the same time, the output-wave transmitter 200 emits an output-wave from the output-wave generation and amplification device 100 into the air intake channel 710 to vibrate the moisture in the supplied air therein, thereby decomposing the moisture into oxygen and hydrogen. The decomposed oxygen and hydrogen is fed to the internal combustion engine 700. As a result, the oxygen and hydrogen may be completely burned together with the fuel gas thereto.

(24) In one embodiment, an output-wave adjuster 300 configured to adjust the output-wave from the output-wave generation and amplification device 100 may be disposed between the output-wave transmission terminal 160 and the output-wave transmitter 200.

(25) In this connection, the output-wave adjuster 300 may typically have an LED lamp or display that allows the frequency band to be identified according to various colors.

(26) In one embodiment, the present system may further comprise a humidifier 600. The humidifier further supplies moisture to the air sucked through the air intake channel 710. Thus, the decomposed oxygen and hydrogen via the water decomposition operation by the output-wave transmitter 200 connected to the output-wave generation and amplification device 100 may be supplied more into the engine 700.

(27) In other words, this intends to maximize the supply of oxygen and hydrogen by increasing the amount of decomposition at the time of decomposing water into oxygen and hydrogen through the output-wave.

(28) The system for reducing fuel consumption and increasing output of the internal combustion engine described above may be implemented into various embodiments in terms of their functional aspects.

(29) <First Embodiment>

(30) Referring to FIG. 4, the system for reducing fuel consumption and increasing output of the internal combustion engine further includes an output-wave amplifier 400 between the output-wave adjuster 300 and the output-wave transmitter 200. The output-wave amplifier 400 may be configured to further amplify the wavelength of the output-wave to be transmitted to the output-wave transmitter 200.

(31) Thus, when the output-wave output from the output-wave generation and amplification device 100 is initially weak, the output-wave amplifier 400 is activated via the output-wave adjuster 300. Thus, the output of the output-wave transmitted to the output-wave transmitter 200 may be further increased.

(32) <Second Embodiment>

(33) Referring to FIG. 5, the system for reducing fuel consumption and increasing output of the internal combustion engine further includes a output-wave distributor 500 between the output-wave adjuster 300 and the output-wave transmitter 200. In this connection, a plurality of output-wave transmitters 200 are installed along the longitudinal direction of the air intake channel 710. Thus, the output-wave distributor is configured to distribute the output-wave between and to the plurality of output-wave transmitters 200.

(34) That is, together with increasing the number of the output-wave transmitters 200 to facilitate the decomposition of moisture in the air into oxygen and hydrogen, the output-wave of the same magnitude is fed to the plurality of output-wave transmitters 200 via the output-wave distributor 500.

(35) <Third Embodiment>

(36) Referring to FIG. 6, the system for reducing fuel consumption and increasing output of the internal combustion engine further includes an output-wave amplifier 400 between the output-wave adjuster 300 and the output-wave transmitter 200. The output-wave amplifier 400 may be configured to further amplify the wavelength of the output-wave to be transmitted to the output-wave transmitter 200. Further, the system for reducing fuel consumption and increasing output of the internal combustion engine further includes an output-wave distributor 500 between the output-wave adjuster 300 and the output-wave amplifier 400. In this connection, a plurality of output-wave transmitters 200 are installed along the longitudinal direction of the air intake channel 710. Thus, the output-wave distributor 500 is configured to distribute the output-wave between and to the plurality of output-wave transmitters 200.

(37) In this way, when the output-wave output from the output-wave generation and amplification device 100 is initially weak, the output-wave amplifier 400 is activated via the output-wave adjuster 300. Thus, the output of the output-wave transmitted to the output-wave transmitter 200 may be further increased. Further, together with increasing the number of the output-wave transmitters 200 to facilitate the decomposition of moisture in the air into oxygen and hydrogen, the output-wave of the same magnitude is fed to the plurality of output-wave transmitters 200 via the output-wave distributor 500.

(38) Referring to FIG. 7, the output-wave transmitter 200 includes the emission coil 220 and the conductive plates 210. The emission coil 220 may be efficiently installed while being disposed in the air intake channel 710. The emission coil 220 may be formed in a shape capable of aggressively performing the moisture decomposition operation. For example, the shape may include a circular annular or rod shape.

(39) FIG. 7a shows a circular annular shape of the coil. In this case, the emission coil 220 is formed in a C shape, and the conductive plates 210 are connected to both ends of the coil respectively. FIG. 7b shows the rod shape of the coil. In this case, the conductive plates 210 are elongated in a bar shape so as to be easily inserted into the air intake channel 710. The emission coil 220 is connected and extended to and between the conductive plates 210 facing each other.

(40) FIG. 8a shows an output-wave transmitter 200 having two opposing conductive plates 210, which are similarly folded, and an emission coil 220 connecting them. As shown in FIG. 8b, a plurality of pins 230 are vertically protruded from one surface of each of the conductive plates 210. This can increase the heat generating area of the conductive plates 210.

(41) According to the present disclosure, by decomposing the moisture in the air sucked into the air intake channel into oxygen and hydrogen, the hydrogen and oxygen can be completely burned in the internal combustion engine. As a result, compared with the prior art, the fuel consumption efficiency increases and the output increase can be maximized. Further, by decomposing the water into hydrogen and oxygen, corrosion of the internal combustion engine can be prevented by removing moisture from the air.

(42) In the above description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. The present disclosure may be practiced without some or all of these specific details. In other instances, well-known process structures and/or processes have not been described in detail in order not to unnecessarily obscure the present disclosure. Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this inventive concept belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

(43) Examples of various embodiments are illustrated and described above. It will be understood that the description herein is not intended to limit the claims to the specific embodiments described. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the present disclosure as defined by the appended claims.

REFERENCE NUMERALS

(44) 100: output-wave generation and amplification device

(45) 110: power-supply terminal

(46) 120: power supply

(47) 130: frequency generation module

(48) 140: waveform-shaping module

(49) 150: power amplification module

(50) 160: output-wave transmission terminal

(51) 200: output-wave transmitter

(52) 210: conductive plate

(53) 220: emission coil

(54) 300: output-wave adjuster

(55) 400: output-wave amplifier

(56) 500: output-wave distributor

(57) 600: humidifier

(58) 700: an internal combustion engine

(59) 710: air intake channel