WO2014045082A1

WO2014045082A1 - Lead-out energy at special resonance conditions

Info

Publication number: WO2014045082A1
Application number: PCT/IB2012/054956
Authority: WO
Inventors: Lawrence Chun Ning TSEUNG; Siu Lai YUNG; Geoffrey Yau Leok SUN; Apache Cheong ONG; Roberts ROBERT; Raymond Wang
Original assignee: Bsi Energy Holdings Limited; G-Led Usa Inc.; CORUM, Steven
Priority date: 2012-09-19
Filing date: 2012-09-19
Publication date: 2014-03-27

Abstract

The Invention leads-out or brings-in Electron Motion Energy under special resonance conditions. !n example electrical circuit consisting of an Inductor (L), a Capacitor (C) and a Resistor (R) will exhibit the property of oscillation. If this oscillation circuit is appropriately tuned with another oscillation entity such a switching transistor, electron motion energy can be lead-out or brought-in. This lead-out or bring-in energy can be used to power the load. The load can be light bulbs, Light Emitting Diodes (LEDs), motors, or other electrical appliances.

Description

Background: This invention relates to energy, specifically related to lead-out or bring-in Electron Motion Energy under special resonance conditions. Scientists know about oscillating systems and that two or more such systems can be in resonance for a long time. For example, a Signal Generator can produce a sound with a particular frequency via a speaker. The loudness or the amplitude can be very low as detected by the human ear or by scientific instruments. When a cup of the correct height matching one-quarter of the wavelength of the sound is placed on top of the speaker, the loudness or the amplitude can be much higher. The standard textbook explanation is that the louder sound is due to a more efficiency use of the energy from the speaker at resonance. No additional energy was lead-out or brought-in from the surrounding.

However, another plausible explanation for the louder sound is that the kinetic energy of air molecules can be lead-out or brought-in. This explanation will not violate the Law of Conservation of Energy.

If the kinetic energy of air molecules can be brought-in at sound resonance, the logical question is - can electron motion energy be brought-in at electromagnetic resonance?

The first experiment to answer the above question is done via the resonance of two oscillating or vibrating electronic systems. The first system consists of an Inductor (L), a Capacitor (C), a Resistor(R) and one or more LEDs as load or indicator. The second system consists of a Transistor. The Inductor can be in the form of a ring with the wires wounded throughout the circumference (such a configuration is commonly known as a toroid). The parameters that go into the tuning process include:

1. The supplied voltage - either from a battery or a DC Power Supply.

2. The type of transistors used.

3. The toroid (type of ferrite or just air, diameter, number of windings, winding

techniques).

4. The capacitor (type, voltage rating, Farad value).

5. The resistors (type, value).

6. The load (different loads require different tuning).

7. If the circuit is done on a breadboard, the position of the electronic components and the length of the connecting wire will have an effect.

8. The external surrounding. This can be demonstrated by the simple act of putting the hand over the circuit and the brightness of the LEDs may change.

With proper tuning, the resulting circuit can continue to light LEDs for many minutes even with the battery removed. This long lights-on time cannot be explained by charges stored in the capacitor. A more scientific measurement to help in the explanation can be done via the oscilloscope.

With an oscilloscope, the Instantaneous Voltage and the Instantaneous Current (voltage across a one ohm resistor) can be measured and stored for analysis. The Instantaneous Power can be calculated from the product of the Instantaneous Voltage and the

Instantaneous Current. This Instantaneous Power Curve can be plotted and analyzed using a computer program such as Microsoft Excel. In particular, the Instantaneous Power Curve may take the shape of a standing wave. A standing wave is a characteristic of resonance. The average Input Power and/or the average Output Power may even be negative. The negative value implies a feedback circuit. In a feedback circuit, more energy goes back to the source than supplied from the source.

In addition, the numerical value of the average Output Power can be many times more than the average Input Power. The Law of Conservation of Energy states that Energy cannot be created from nothing, the only plausible explanation is that some energy come in from the surrounding environment. This energy is referred to as the lead-out or bring-in energy.

The more detailed scientific question is - what is the nature of this lead-out or bring-in energy. A plausible explanation or hypothesis is that the lead-out energy is from the electron motion energy. There are electrons orbiting around the nucleus. They must have energy for such motion. Chemical energy comes from the different distribution of the electron cloud between different compounds. This invention shows that it is possible to extract and use such energy related to electron motion without actual chemical reactions.

The second experiment is designed to demonstrate that lead-out energy at resonance is responsible for the lighting of many (38 in the experiment) LEDs. The circuit is deliberately tuned so that the 38 LEDs dimmed for about two minutes and get bright again at around the three minute mark with the battery removed. The reason why the LEDs get bright again is that the circuit passes through a resonance peak. At this resonance peak, more lead-out energy is brought into the system. The occurrence of the resonance peak can be confirmed via the displays and measurements from the oscilloscope.

The third experiment is designed to demonstrate that the amount of lead-out energy can be much higher than the supplied input power. The Input Power is from a DC Power Supply. The Voltage and the Current can be displayed digitally. The load is 1,000 LEDs rated at 1 watt each using a voltage of 24 volts. This means that under normal conditions, 1,000 watts at 24 volts DC is required to light up these LEDs to full brightness. With the said invention, the Input can be at 12 Volts drawing a current of 3.6 Amps. This means the new Input of 43.2 (3.6 x 12) watts is needed to drive the same 1,000 LEDs to full brightness. This means a saving of 97.5% (1000- 43.2/1000). Since the addition energy cannot come from the DC Power Supply, it must have come from the lead-out energy.

The fourth experiment is designed to check the effect of resonance on power consumption. Thirty LEDs is used. With the said invention, a circuit of 30 LEDs is appropriately tuned. These 30 LEDs have the same brightness at the end of two minutes as at the beginning. A timer can then be added so that current is supplied for 15 seconds and then turned off for 2 minutes. The 30 LEDs have the same brightness throughout. The effective power supplied is 11% (15/135).

The fifth experiment is designed to confirm that lead-out energy must be responsible for the observed effects. Two rechargeable batteries are used. The first one is connected to drive the circuit in the said invention fashion. Thirty-eight LEDs are lighted continuously. The second one is connected so that it can be recharged by the first. At the beginning of the next day, the two batteries are swapped. This process can be repeated many times. The 38 LEDs will remain ON continuously even during the period of swapping batteries. The voltages of the batteries remain almost the same after many weeks.

To be more exact, the use of the Input Power Source is to bring and keep the load in the special resonance condition. At this special resonance condition, electron motion energy is lead-out. Under normal conditions, the circuit will drift away from this special resonance condition. This can be observed with the oscilloscope. With the said invention, the Input Power Source is NOT to drive the load but to keep the circuit at the special resonance condition. This new discovery will change our understanding of electrical power and its application to all known electrical appliances.

The sixth experiment is designed to show that lead-out energy can be much more than the supplied input energy using DC power comparisons. The output power from the said invention is normally pulsing and can be at any frequency. This output power can be rectified or changed into DC and smoothed. The Input can be an AA battery at 1.5V DC drawing current at 1 Amp. The output DC voltage using the said invention can be 15V drawing a current of 0.8 Amp. The output can be used to light LEDs or drive motors. With this example, the Input power is 1.5 (1.5 x 1) watts, the lead-out energy converted into DC power is 12 (15 x 0.8) watts. Since the comparison is DC to DC, there is no need to worry about complications of frequency or phase angles.

One important experiment is to replace the capacitor with an electrolysis system. The two plates comprising the anode and cathode can be regarded as the two plates in a capacitor. With appropriate tuning, the decomposition of water into hydrogen and oxygen can be achieved with lead-out energy. The resulting hydrogen and oxygen gases can be used as fuel to power cars, ships or planes. Thus running cars using water as fuel will be a reality.

Another important point to note is that in some circuits, there are implicit values of resistance, capacitance or inductance. There may not be real resistors, capacitors or inductors in the circuit. For example, a circuit has only a capacitor and an inductor. Even if there is no actual resistor, the circuit with its wires and connection points will have some resistance. In the case of the breadboard, many connecting wires are placed next to each other, there will be significant capacitance. These connecting wires may also form loops, which will give rise to inductance.

Summary: This invention is based on a new scientific discovery. Electron Motion Energy can be lead-out or brought-in into a system at special resonance conditions such as the interaction of two or more oscillating systems. The various parameters need to be matched for this to happen. After starting, the input energy source can be removed. The device using the said invention can lead-out electron motion energy to sustain its operations. In some cases, the input energy source is retained and used to keep the device in the special resonance condition.

Detailed Description : In Figure 1, there are LEDs 1 arranged in the letters BSI. The LEDs are rated at 3V and normally will not be lighted by an AA battery 2. However, in this invention, there are Capacitor 4, Resistor 5 and Inductor 7 making up an oscillating circuit. If this oscillating circuit is tuned with the pulse switching Transistor 5, the LEDs 1 will light up. Additional tuning can be achieved via the Variable Resistor 6 and an ON/OFF Switch 8. After appropriate tuning, the battery 2 can be removed and the LEDs 1 remain ON for many minutes. The average no-battery time is around 20 minutes and some prototypes can achieve no-battery time greater than 50 minutes. The energy providing the lighting during the no-battery time comes mainly from the Lead-out Electron Motion Energy.

In Figure 2, there are two curves comparing the Output Power 11 with the Input Power 12. The ratio of Average Output Power over Average Input Power from this particular curve is 9.8. This means that for one unit of energy coming from the Battery 2, nine units of energy are detected across the LEDs 1. The extra energy is accounted for by the Lead-out Electron Motion Energy.

In Figure 3, the detailed circuit diagram is shown. The positive end 30 of the Battery 32 is connected to the two jointed wires 35 and 36 of the Toroid 37. One other wire of the Toroid 37 is joined through an one kilo-ohm Resistor 34 to the base of the Transistor 38. Another wire of the Toroid 37 is jointed to the connector of the Transistor 38. The emitter end of the Transistor 38 is connected to a one ohm Resistor 41 before the common ground. The one ohm Resistor 41 is used to help the measurement of the input current. The load in this circuit diagram is the LEDs 43. Another one ohm Resistor 46 is used to help the

measurement of the output current.

The choice of the various electronic components is not totally random. In this specific case, the Battery 2 is an AA battery. The Transistor 5 is a 2n2222. The Resistor 4 is one Kilo-ohms. The Toroid 7 is 2.5cm in diameter wound with 20 gauge copper wire with 28 turns. The Capacitor 3 is rated at 2.3V 10 Farads.

Conclusion, ramification and scope: The invention shows how to use a new form of energy. This energy is clean, abundant, available everywhere. It can be compared with the invention of the light bulb. Thomas Edison tried many thousand materials before he could demonstrate the lighting of the light bulb. Once it was demonstrated, the scientific community found it elementary - a battery, some connecting wires, an on/off switch and a filament. This invention is similar. It took the inventors many years and thousands of experiments. Once understood and demonstrated, it is a matter of matching some electronic components to get into special resonance conditions. The confirmation is done via the oscilloscopes. This new source of energy is likely to replace all fossil fuel just like the electric light bulb replaced the candles and oil lamps.

This invention is not only limited to the above example circuits. Almost all known electrical appliances can be tuned to use the lead-out electron motion energy.

Claims

Claims: What is claimed is:

1. A method of leading-out or bringing-in electron motion energy to supply energy to a load in an electrical circuit, comprising the steps of:

a. providing an oscillating circuit and

b. tuning it with another oscillating circuit so that a resonance condition is

established.

2. A method as in claim 1 wherein the said oscillating circuit in step a comprises of inductor, capacitor and resistor.

3. A method as in claim 1 wherein the said another oscillating circuit in step b

comprises of transistors or switches.

4. A method as in claim 1 wherein the said tuning in step b comprises the steps of: a. selecting the appropriate electrical components,

b. observing and analyzing the output and input waveforms on an oscilloscope, c. changing the electrical components until the average output power is greater than the input power.

5. A method as in claim 1 wherein one portion of the said load is a rechargeable

battery. This rechargeable battery can be swapped with the original battery periodically. The recharging energy comes from the lead-out energy of the said invention. Such a two rechargeable battery system can continue to power the remainder of the load without any other power source.

6. A method as in claim 1 wherein the said resonance condition in step b is shown by removing the power source.

7. A method as in claim 6 wherein the removal of the power source is periodic so that much less power is required.

8. A method as in claim 1 wherein one of the electrical components in the said

oscillating circuit in step a is the two plates in an electrolysis system. The lead-out energy is used to decompose water into hydrogen and oxygen gases.