ULTRASONE HYDROBOOSTER
Water Energy Application
Content
Curriculum Vitae
Training experience:
Installation Technique 10 years, Professional diploma CV technician.
Telecommunication 30 years, Basic, intermediate electronics, Digital technology,
Process controlled systems, Programming in Basic,
PC technology, Data communication, Video surveillance,
Professional experience:
1969 to 1979 Hulp CV mechanic
1979 to 2006 KPN Telecom
2006 to 2012 CEO: from difrend company's
2012 to 2018 Research physicists phenomena, Sun, Earth, Energy in water and its properties, water management of the earth, product development for energy saving. environment and CO2 friendly applications.
Details regarding my experience:
My experience concerns an above-average creative capacity for a wide range of problems, design and practical applications.
Through experience for spatial and technical applications I have developed a talent for visualization, which enables me to become one with the environment and matter. I can move through a switching network of a computer or become part of an atom. In this way I can observe and understand actions and reactions in complex technical systems.
Characteristic for me is that I want to understand the background of technology, in order to gain the knowledge necessary to achieve my goals. Here I deviate from the trodden path, because if I do the same as another person, I will get the same result.
I don't just take something for granted. In this way I follow my own insights. Major Out of the Box to thinking. Setbacks are precious learning moments and contribute to your success through perseverance.
My human attitude is: Problems are opportunities and challenges.
We do everything we can right away. Miracles last a little longer.
Foreword
I would like to invite you to the exciting voyage of discovery to the Ultrasonic Hydrobooster.
First of all, I would like to take this opportunity to thank the people who have helped to turn the idea into a working model.
They have made a dream come true by combining new insights and direct applications in this design. My view is partly due to the beautiful description of the torus-shaped energy field by Caspar Pompe. Energy is movement. The toroidal field - the magic donut - occurs in everything around us from subatomic level via the mitochondria in our bodies to the entire universe.
Through uncharted paths, I have become convinced that energy generation is a relationship between Action, Response and Interaction. By using the toroidal field, the Ultrasonic Hydrobooster achieves a higher efficiency than the existing thermal techniques.
Nikola Tesla and Viktor Schauberger have looked at how nature works. They are inspired by the sun, moon, earth and natural phenomena such as thunder. Why the earth rotates and how the rotation affects our water management. Our lives could never have come into being without water.
For us, water is the source of life energy, which in an incessantly reproducible cycle provides the earth with its life's need. Water Continuously goes through a natural cycle of evaporation, splitting into Hydrogen and Oxygen. Water is (according to M. Chaplin) a special material with at least 66 different properties.
For us, water is a 100% recyclable source of energy. The Ultrasonic Hydrobooster is an efficient application for turning water into an energy source. This is based on the physical principle that when a substance or element warms up, the molecules or atoms move faster.
This substance expands as a result - the ingested volume increases and thus changes. specific gravity and viscosity.
The water molecules get a higher frequency due to direct movement, kinetic Power, friction and cavitation. The higher the temperature, the higher the frequency of the molecules. You can also reverse that: the higher the frequency, the higher the temperature.
Vibrations at own frequencies of molecules and atoms form the field of resonance technology.
In the appendices you will find background information about resonance technology and the phenomenon of water. I think you will find this interesting.
I wish you a great deal of reading pleasure and look forward to your reaction.
1. Ultrasonic Hydrobooster for water energy
In this document I present the Ultrasonic Hydrobooster step by step. The Tesla Turbine forms the basis of the booster. I have added a number of processes to the Tesla Turbine in order to further increase the efficiency of the system.
The first process step takes place in a helix, which causes the spinning effect of energy/matter flows as discovered by Viktor Schauberger. The second step in the process is the adapted Tesla Turbine, which is used to heat the water.
High-quality materials in combination with resonance technology result in the operation of the Ultrasonic Hydrobooster. The Ultrasonic Hydrobooster consists of the following components:
a. Main shaft drive;
b. System energy supply by high-pressure pump;
c. Helix - water and energy concentration;
d. Adapted Tesla Turbine;
e. Internal Ultrasonic Hydrobooster with plates with ‘flutes’;
f. Output of Steam to Impeller;
g. High rotation speed due to steam acceleration - transmission to main shaft;
h. Steam production to Turbine for electricity generation;
i. Steam to heat exchanger;
j. Recirculation of electricity to pumps or electric motor;
k. Electronic process control.
The Ultrasonic Hydrobooster produces steam. Because steam has a broad field of applications, I will only give a brief overview of the possibilities in chapter 2. In chapter 3 I will discuss different paths from concept to product. For the readers who want to go deeper into the theory, I have added three appendices.
1.1. Main shaft drive
The system can be driven in two different ways.
1. With a large power circulation pump, where at start-up less forces are released on the water Impeller. Advantage, the speed of the drive shaft, will gradually increase and will reach higher rpm than with an electric motor.
The drive pump will deliver more than 420,000 litres per hour, which will serve 11.67 litres of 1.8 bar of thrust per second for the main axis. Disadvantage, higher production costs compared to an electric motor without frequency control and transmission ratio to achieve a higher speed. The choice of the solution also depends on the application of the Ultrasonic Hydrobooster.
2. Drive with an electric motor is more economical. Direct power transmission and speed are adjustable. However, a pulley transfer, or frequency control can cancel out the benefit of the cost savings. Here, too, the application of the ultrasonic Hydrobooster must determine the choice.
The prototype will be made in such a way that both a water impeller and an electric motor can be used as a drive. A small model can be equipped with a Dynamotor, which acts as a dynamo when it does not need to drive the system itself. The tension can be transformed upwards and directed evenly. This solution is interesting for the automotive industry to charge battery powered cars while driving.
This saves space, space and the cost of making the unit, reducing the need for a pump and impeller (impeller wheel) to drive the unit.
1.2. Energy generation by water
Energy is generated by the helixling current of the water through the Ultrasonic Hydrobooster. Where this energy comes from is a question that I would like to put to physicists. The water is pumped through the system with an adjustable pump (4000 Liter per hour) at an adjustable pressure up to 8 Bar. This pump feeds into a closed circuit of:
1. Heat exchanger;
2. Pump;
3. Helix;
4. Custom Tesla Turbine;
5. Ultrasonic Hydrobooster.
The choice of application determines how many cockles and improved Tesla Turbine per Ultrasonic Hydrobooster will be used up to a maximum of 4 per system. The improved Tesla Turbine has two different internal versions.
1.3. Helix – water energy concentration (Schauberger)
First, water is divided into seperate supply streams, in which the water flow rotates through a copper helix. This helix is located in a copper tube. The fixed left-hand turning helix itself is a fixed component (without rotating parts).
The water stream rotates and is also concentrated according to the discovered methods of Viktor Schauberger. This is where the first acceleration, overpressure, underpressure (Cavitation) occur at the entrance of the adapted Tesla Turbine.
An example is an outboard motor screw. One sees acceleration on the outside and under pressure in the centre of the water flow.
1.4. Adapted Tesla-turbine
A Tesla turbine consists of a housing with an inner work of round plates with a spacing of 0.5 to 1 mm. A connection has been made in the outer wall for the water supply. The water enters the turbine tangentially, so that the disk pack rotates.
The water flows from the outside to the holes in the middle of the discs and has to overcome two forces. First force is the friction of the water flow against the discs. The second force is the centrifugal force due to the high rotation speed of the package. The resistance to these forces heats the water.
This process repeats itself on the next level of disks, which then start running. The water flows through several disc layers until it finally reaches the exit via a funnel in the centre of the system.
The water flow between the disks, towards the center, has an equal flow rate. Each time a shorter path is taken to the city centre. This results in a difference in ‘confrontation speed’ on both sides of a disc, despite the equal supply.
In this game of under- and overpressure cavitation bubbles develop, which are locked up in between the discs. The bubbles are made up of steam. Steam has 1600 times the volume of the water from which it originates.
This steam is drawn to the direction of the holes in the center of the discs by the under pressure at the output relative to the overpressure of the input. However, a large number of bubbles will implode with high vibration frequencies being introduced into the water.
The cavitation causes a turbulence that is 90° at right angles to the rotation speed of the water supply between the discs, causing more cavitation towards the exit. This phenomenon results in a steam water mixture that leaves the turbine.
The volume and power of the water that flows into the adapted Tesla Turbine ensures a very fast rotation of the disk package. The stacked vane wheels at the exit are mounted on the same shaft with three fixings and a lock ensures more under pressure inside the Tesla Turbine.
In the Ultrasonic Hydrobooster, the construction of the Tesla turbine has been adapted. The disks packets have a different spacing between the disks. On the drive side of the Ultrasonic Hydrobooster, spacing is 1 mm while the discs are centered at 0.5 mm from each other.
This will result in a higher temperature in the middle of the Ultrasonic Hydrobooster compared to the drive side. Lower tones are produced there. In the prototype there are two improved Tesla Turbines on both sides of the Hydrobooster.
1.5. The Ultrasonic Hydrobooster
The Hydrobooster is made up of different components and different techniques.
It can be built in different sizes or connected in parallel depending on the application. The question is whether a lot of heat, or more electricity is needed, can be set by means of control technology. The parameters influence the test results of the prototype to make optimal settings for different applications visible.
The Ultrasonic Hydrobooster transmits direct movement through various forces to the water. Energy generation will provide more efficiency by reducing losses in direct confrontation as well as in convection, radiation or combustion.
The efficiency of the Hydrobooster is very high. It seems that the Law of Conservation of Energy is not applicable here. But that is not possible. Considering the various characteristics of the Hydrobooster, external factors must play a role here. We therefore conclude that other types of energy are induced by the Ultrasonic Hydrobooster.
When drawing up the energy balance, the system boundaries must be extended. Do gravity or geomagnetism play a role? Therefore, we are not talking about the efficiency of the Ultrasonic Hydrocarrier, but about Coefficient of Production (COP), which is mostly used in the Geothermics.
We therefore advocate additional external scientific research into the functioning of the Hydrocarbons and the mysterious energies that apparently play a role here.
https://www.youtube.com/watch?v=U-uUYCFDTrc
The Ultrasonic Hydrobooster is an improved version of the Ultrasonic Hydropump an invention from 2006
https://www.youtube.com/watch?v=UBxpn6odtcA
https://www.youtube.com/watch?v=wAHNpCeGmDw&t=28s.
This version shows the operation of the Ultrasonic Hydrobooster. This version has been improved on several points, so that the Ultrasonic Hydrobooster will maintain itself (self-running).
https://www.youtube.com/watch?v=zbd50_hOy0U&t=65s
The construction with different plates - alternating with a blind plate and a slotted plate - creates so-called 'whistles'. This is also shown in the previous video. The version of the Ultrasonic Hydrobooster is more compact than the Hydropump, has many more flutes that increase in pitch towards the steam output.
The number of pan flutes varies depending on the size of the model.
These flute plates are mounted on an axis, whereby each flute can be seen as a tooth of a saw blade, whereby an overpressure and underpressure is created with each of the teeth.
The multiple overpressure and underpressure moments cause more noise.
The prototype has 8498 flutes, which add 80 different tones to the water. The pitch is determined by the circumference of the plates times the number of whistles per plate and rotation speed of the plates.
The axle with plates also has a flywheel function and gives self-propulsion. The density, specific gravity and volume of the water are changed considerably.
The small drops of mist turn into steam by kinetic confrontation with the sound of the flute and thus energy saturation.
The water is beaten approximately 5,000,000 times smaller in 3 to 5 seconds, at a speed of 160 Km/h and above, rising above the sound velocity. This depends on the maximum speed to be achieved, the circumference of the plates, the 80 different added frequencies.
The kinetic confrontation of more than ca. 1,690,000 per second gives a much higher peak frequency than the tones through the pan flutes. The Ultrasonic Hydrobooster can be fed with water or Honeywell's R-245Fa for better energy conversion.
The propagation of sound in water is 5 times the speed of sound in air (1500 metres per second). The water supply varies from 0.1 to 1.6 litres per second from small to large model Hydrobooster.
The higher the tones and number of whistles, the more kinetic force + sound will be added to heat the water. A smaller flute produces higher tones.
More steam increases the velocity of rotation.
These frequencies increase the energy and temperature of water molecules. The different frequencies come from the flute plates, the inside wall of housing and the implosion of the steam bubbles.
1.6. Impeller
The impeller function is reversed as the operation of a pump impeller in this design.
The impeller therefore provides a driving function for water or steam.
The steam generated goes through the outputs (twice 1") to the Impeller output, propelling the shaft with plates. It accelerates in its already moving direction of rotation, causing self-provoked propulsion.
As a result, the Ultrasonic Hydrobooster requires less or no more thrust at the input of the system. The Ultrasonic Hydrobooster is more or less self-sustaining and can be controlled via the supply of water or R-245Fa, which already evaporates at 82°C.
When leaving the impeller drive, the steam will go to the next impeller, which drives an axle for an electric generator. The speed and force is reduced, so that the force increases as a result of the transmission ratio.
The increased pressure and volume (1:1600) due to the transition from water to steam and other natural properties of water play a role in this.
After the steam is used for electricity generation, it will pass through a heat exchanger for heat transfer. This can be cooling or heating for industrial applications.
1.7. Recirculation of electricity
A connected electrical generator will generate more energy than is necessary for the system to function. The generated electrical voltage will be fed back to the input in order to maintain itself. The excess electric power generated can be used for other purposes or discharged to the mains.
Experimentally it will have to be determined which application will be optimal for each configuration.
2. Testing & Electronic Process Control
The most important measurement is the temperature difference between incoming and outgoing water/steam and its volume. To apply the existing formula calculation to this, to recoup it with the added power to energy, which will create a difference factor.
It is preferable to carry out the first tests with water. Where we can vary output by management of the intake of water.
The offered temperature of this water and the energy extracted via a heat exchanger to store in a supply vessel / boiler must be measured.
By influencing the ∆T we can choose between applications for generating electricity or more heat will be preferred.
After the test phase with water, these tests can be performed again with a replacement for water, by Honeywell's R-245Fa.
These R-245Fa Not frozen until -24°C can easily reach our target temperature of between 82°C and 125°C. It must also be possible to set this for every application. Because of his characteristic new possibilities offers, after being filled once, this compound is a reusable source for energy production. The advantage of this is that there is no oxygen in this solution so the metal cannot and will not rust (corrode). This can lead to significantly lower production costs.
This entire system will be controlled and managed by electronics that have yet to be developed and will be influenced by the test results.
The following process properties and measurements and security are then brought together in a design, displayed and measured via a display:
1. Total energy used such as current, voltage, power of the drive pump or motor.
2. The water flow of the total system and drive pump.
3. The water flow that is offered to the Hydrobooster for heat generation.
4. The input pressure that the drive pump delivers.
5. The temperature of the water offered at the entrance.
6. The output temperature of the steam emitted from the output.
7. The steam pressure that comes from the Ultrasonic Hydrobooster.
8. A pressure protection via water supply control at the input.
9. A volume control of the water offered for heat generation.
10. Bluetooth web interface for operation and reading.
11. Reading out of outgoing energy from heat according to the energy formula.
12. Reading out of self-generated energy by the steam.
13. Reading out of the generated voltage and current by the generator of the system.
14. Displaying the total energy generated Heat and Power.
15. A conversion factor of energy input and energy output.
16. Feedback of generated current to the input of drive pump.
17. Storage of excess energy you generate or dump it back into the grid.
18. Calculate how much energy savings this system will generate on an annual basis.
19. Logging functions e.g. for energy flow rate and number of operating hours.
I have already developed the electronics for reheating the generated steam.
Where water is split into hydrogen and oxygen, this is immediately ignited to produce a plasma flame. This plasma technique can be used for different purposes.
This electronics also ensures that the power is adjustable by controlling the time of positive and zero. The duty cycle which is generally 50% positive and 50% zero, so a distribution of 25% positive and 75% zero can come. As a result of which the power consumption will decrease by 50%, this can be thermally controlled by incorporating an NTC resistor in the circuit.
Display of desired output signal
This circuit is controlled by two source signals. The lowest control signal available on port 14 of the 4017 divides the signal into 9 outputs.
The high signal first goes to an EN port to get more fan (load) out. The high signal is distributed over 9 inputs of 9 EN ports. The output signal of the 4017 IC is connected to the second inputs of the EN ports.
Each output of the EN ports will give a 1 if both inputs are 1, this will give the signal from the previous image. The IC LM311 and IC 555 provide the duty cycle and duration setting, the output goes through a NOF port from a 7408 to the Reset input of the 4017 IC.
The still free NOF ports of 7408 can be used for security in the control system. This can be a pressure protection or maximum temperature protection or a room thermostat or dry cooker protection.
I have chosen to control the 4017 IC for approx 450 KHz, which in this case will make a fundamental of 50 KHz, which is above the hearing limit of humans and animals.
Out of 9 control signal outputs via the 7408 IC, 9 FET drivers are used to control 9 signals in turn to control limit switches.
The load output is switched via the FET circuit to ground. With an overvoltage protection in the joint output, this is spaced with one diode per output for feedback to other outputs.
3. Applications
The Ultrasonic Hydrobooster initially produces steam. When the central axis is coupled with a generator, the booster also delivers electricity. In combination with the customer's wishes and needs with this environmentally friendly application. One only needs water! The production of heat and/or electricity will therefore become significantly cheaper and the production costs of other products can be significantly reduced.
The field of application is therefore almost infinite. That is why I shall confine myself here to a brief overview of the possibilities.
3.1. Glasshouse horticulture
Greenhouse horticulture consumes lots of energy. In the Netherlands alone, there are approximately 250,000 hectares of greenhouses. The energy consumption is approximately 1 MW per hectare. Hot water is mainly used to heat the greenhouses in winter. A heat exchanger is therefore required for heating. The electricity from the turbine can be used to provide the lighting. It is possible to operate completely self sustained.
3.2. Process industry
Process industry uses a lot of steam to heat conversion processes into autoclaves. For example, in the sand-lime industry, where the stones harden in an autoclave at high temperature and humidity. Or in the food industry where steam is used.
Petrochemical industry, heat dissipating processes for various applications, energy storage for an indefinite period of time by a This makes new inventions possible.
It is also possible to use heat exchangers to heat air, such as industrial buildings. By combining the Hydrobooster with the air purification products of Swentibold BV, this is a possible market for their existing customers.
3.3. District heating
An increasing number of municipalities are switching to district heating via heat networks. Steam is used as the medium. The heat generated can be used to heat space and potable water. For example, between Arnhem and Nijmegen, the company is busy expanding its heat grid.
By using heat exchangers in the form of boilers, these can be linked to increase the storage capacity.
Swimming pools can be heated via the heat network, or a small Hydrobooster can be installed, another heat exchanger will be installed that can be used universally by linking these as required.
3.4. Residual waste disposal with plasma technology
The steam produced can further be processed into a very hot water plasma (more than 7000 oC). With this heat all matter can be gasified. At present, plasma gasification is increasingly being used for the removal of old waste dumps. In this way, residual waste becomes a source of energy.
3.5. Automotive sector
A small version of the Hydrobooster can be installed in an electric car. The steam drives a small turbine to charge the car electrically while driving.
Charge in standby mode when parked.
This will extend the range for hybrid vehicles. If facilities to keep a car frost-free can be combined with solar cells on the roof of the car, possibly incorporated in the panoramic roof.
The ability to keep the temperature inside the car stable even when it is not in motion.
By achieving a lower boiling point with Honeywell's R245Fa, there are new applications that can be used in the automotive industry.
This enables the new generation of fuel cells to be brought up to operating temperature quickly, from 15 minutes to approx. 30 seconds. For better and more powerful performance of the fuel cells.
Energy-consuming processes for various applications, energy storage for an indefinite period of time by a This makes it possible to create new inventions.
4. From Prototype to Product
The expectation is that the Hydrobooster is so revolutionary that it will quickly conquer the market through its broad applicability. By working together on the basis of confidentiality further developments can take place. It is very important to find the right partners on the path from prototype to product.
For the whole project, there will be a definition schedule of the steps to be followed to realize the development of the Ultrasonic Hydrobooster. This includes fundraising and business vision, and marketing as an important part of the process to be completed.
When generating and with this system a CO2 reduction of more than 80% is expected.
According to a calculation, this will yield 502.8 Kw/h of heat if the 1 litre per second of water is heated 120 degrees, at only 4.8 Kw of electric power added, by pump and drive motor.
Without using oil or gas to generate this form of 100% clean recyclable energy from water.
The development will take place with the cooperation of various factories in Europe, each of which will make different parts throughout Europe.
After development, the production will be set up, the aim being to let production follow demand.
There will be a production line to be set up in each country, for assembly by country.
For example, jobs will be created in each country for the manufacture, installation, transport and supply of various ancillary products developed by other manufacturers.
The first concept designs are currently being converted into the final size of the prototype of this modified Ultrasonic Hydrobooster.
Converting the design into a prototype will take place in several steps, in order to make the adjustments for each part in relation to each other. By doing so, I want to avoid double work pay and unnecessary material wastage.
The company that participates in the development of the Hydrobooster contributes both resources and competences. The development is carried out by a company to be founded, in which both the inventor and the business partner participate.
When applying for a patent, it is desirable to take equal action, to apply for subsidies. This is, after all, part of the investment, so that we will also be able to pay for part of the production at the time of the introduction.
The shortest route is an application where steam produced can be delivered directly to the customer, thus preventing transport losses. Industry is the largest consumer of energy for 80% of heat (steam and hot water).
This new technique can be combined with existing solutions.
By working together with Hogeschool Zuyd in Heerlen this concept of my idea, two students have worked it out in direct cooperation with me.
Also efficient use of the possible construction with composite solution will be a major material saving and cost saving. As development progresses, more opportunities will emerge and opportunities will arise for this unique form of energy generation for the future.
After the test phase with water, these tests can be performed again with a replacement for water, by Honeywell's R-245Fa.
Between 82°C and 125°C or higher, it must also be possible to set this for each application, taking into account the self-igniting characteristic of 412°C or higher. Because of his characteristic new possibilities offers, after being filled once, a reusable source for energy production.
The advantage of this is that there is no oxygen in this solution so the metal cannot and will not rust (corrode). This can significantly reduce the choice of production.
As development progresses, more opportunities will emerge and opportunities will arise for this unique form of energy generation for the future.
If we compare the Ultrasonic Hydrobooster technology with other alternative clean applications such as solar collectors, wind turbines, heat pumps and ground heat, the Ultrasonic Hydrobooster will have a higher energy generation at lower purchase and operating costs.
At 80% CO2 savings at named percentages see list below. However, as the generated voltage will be coupled back, the CO2 emissions will decrease by approximately 99% or more. The market share mentioned here is a long-term forecast.
This calculation is based on the Ultrasonic Hydrobooster Model 125+, at startup the savings will be much lower, as the numbers will be much lower.
The actual market price depends in part on the other combined products. These are: Pumps, Heat exchangers, Heat storage vessels and boilers, Hot air Heaters, Separate Electric Motors, Type of electrical generator.
Annex 1: Resonance technology
NOTE: THIS SECTION IS TRANSLATED FROM DUTCH BY COMPUTER – PLEASE BE AWARE THAT WEIRD SENTENCES MAY OCCUR.
Current techniques in the field of heating make use of convection heat, combustion, electric coils or infrared radiation heat. With combustion as a chemical process, an energy development takes place that can be observed, in which the flames consist of several different colours.
The volume of combustible dust (mass) inlet velocity through a certain opening and mix with air that determines the amount of energy by a factor.
The rate of discharge at lightning, 150,000 Km/s equal to the half speed of lightning.
And, in turn, causes different chemical reactions through the combination of air, water and the heat of the discharges.
The different colours represent different Frequencies, where Frequencies are related to the time of a period of time:
Speed versus time is comparable to the timeline, the flying of circumference of a circle. The first figure shows a circle with the angles expressed in degrees. Figure two shows the progression in time of a period.
It is not yet possible to go from point 180° via 270° to 0° in time, which would mean that we would go back in time in this period. We express a period in time in terms of the number of Hertz per second.
The colours of the gas flame show where most of the energy intensity takes place.
Higher frequency, according to the colour spectrum and the corresponding frequency table, also play a role in this. Otherwise, it would never be possible to achieve the required temperature with a flame: see the corresponding frequencies in the colour spectrum table.
The gas flame transfers energy by means of vibrations to the metal.
The propagation rate of air, water and metal or ceramic substances for vibrations differ considerably from each other.
These range from low to very high, including frequencies that are not visible, from before and after the colour spectrum:
Think Steel can be Dust by to high frequenty 911
Think Steel can be Dust by to high frequenty 911
In case of heat transfer of different temperatures and substances, nature will have to increase in order to find a balance. Where these two want to come into balance and harmony with each other.
This is called resonance when the balance is reached where the frequencies are equal because the source and other object have the same rhythm.
The gas flame transmits its vibrations, whether or not visibly, in the metal an equilibrium is created. This transfer of energy can melt metals and materials, by energy saturation or even by evaporation.
Combustion of watergas has very special properties compared to other combustible gases, because it consists of two different elements...
Where released temperature is also determined by the hardness of the material with which it is confronted and tries to come into resonance (frequency balance).
Watergas consists of 66.6% hydrogen and 33.3% oxygen. Watergas has a higher optimal combustion rate of 3000 m/sec = 10,800,000 Km/h.
The frequency of this flame has a higher speed transfer, also due to frequencies outside the visible colour spectrum its ignition velocity of 3000 m/s.
Even these 3000 m/s is not only frequency determining, this frequency is much higher. What happens in nature, when discharged during a thunderstorm a mass of energy is released in this 1/3000 sec. If I want to make this visible with figures, I will have to make an estimate and assumption because it is impossible to measure.
Calculations show that up to 1 litre of water contains 12.92 Kw of energy, let me suppose up to 1000 liters when discharged 12,920 Kw r
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