1851 There Really Is Free Energy Everywhere - Electrostatic Motors

Robert Murray-Smith
28 Feb 202311:07

TLDRThe video script discusses the concept of harnessing atmospheric electricity to produce power. The Earth is described as a large ball of electrons with a cloud of positive ions above, creating a significant voltage difference that can be utilized. The script introduces electrostatic motors, which operate on the principle of electrostatics, similar to magnetism. The presenter details the construction of a simple electrostatic machine using easily accessible materials like plastic and copper tape, emphasizing its low metal content and ease of assembly. The machine's operation is demonstrated using a high voltage supply, showing its potential for motion and power generation. The video also mentions advancements in the field, such as the development of the C motor and the work of individuals like Laser Hacker on the Atmos project. The presenter acknowledges the need for further refinement of the machine and the untapped potential of this free energy source.

Takeaways

  • 🌟 Atmospheric electricity is a potential source of free energy, with a voltage difference increasing by 100 volts per meter up to 52 kilometers.
  • πŸ”‹ Electrostatics is likened to the magnetism of electricity, where like forces repel and unlike forces attract, playing a role in why atoms don't disintegrate.
  • πŸ’‘ Corona Motors, atmospheric Motors, and electrostatic Motors are all terms for the same technology, which harnesses the force of electrostatics.
  • βš™οΈ A simple machine design consisting of five parts can be used to build an electrostatic motor, which can be 3D printed or constructed by hand.
  • πŸ“‘ The machine uses minimal metal, primarily plastic, and copper tape for its construction, making it suitable for 3D printing and reducing the risk of high voltage leakage.
  • πŸ”© The machine's components are assembled with nails threaded through holes in rods, creating a comb-like structure that is connected electrically.
  • πŸ”Œ A high voltage supply is used to test the machine, demonstrating that it can operate with as little as two volts, converting to around a kilowatt.
  • πŸ› οΈ Despite being historically viewed as toys or scientific curiosities, recent developments have shown that these motors can be more significant and practical.
  • πŸ”¬ Research is ongoing, with individuals like Laser Hacker and industrial developments such as the C motor, based on the work of Oleg Jefimenko, pushing the boundaries of this technology.
  • πŸ›‘οΈ The design of the motor incorporates safety measures to prevent arcing, such as spacing the nails to avoid electrical breakdown.
  • ♻️ The simplicity of the motor's construction, with minimal metal and no soldering required, makes it more accessible and potentially efficient for harnessing natural static electricity.

Q & A

  • What is the mysterious force mentioned in the video that can be harnessed to produce power?

    -The mysterious force is atmospheric electricity, which is the voltage difference created by the Earth being a ball of electrons and the cloud of positive ions above it.

  • What is the voltage difference per meter as you go up in the atmosphere?

    -The voltage difference is about a hundred volts per meter, increasing up to about 52 kilometers where it can reach hundreds of thousands of kilovolts.

  • How does electrostatics relate to the force discussed in the video?

    -Electrostatics is the static version of magnetism in electricity. It involves the interaction between like and unlike charges, which always repel and attract, respectively, and is a force that can be harnessed.

  • What are the components of the simple machine designed in the video?

    -The machine consists of five parts: four bars, twelve rods with threaded ends, twenty-four thumb screws, two plates, and one drum.

  • What material is used for the bulk of the machine, and why is it ideal for 3D printing?

    -The bulk of the machine is made from plastic, which is ideal for 3D printing because it doesn't require much metal and prevents high voltage leakage.

  • How is the connection made between the nails and the rods in the machine?

    -The connection is made by pushing the nails through the holes in the rods and using a thumb screw to secure them, creating an electrical connection without the need for soldering.

  • What is the purpose of the aluminum foil on the drum?

    -The aluminum foil on the drum serves as a conductive surface that interacts with the comb of nails to generate motion through electrostatic forces.

  • How are the nails and rods connected electrically in the machine?

    -The nails and rods are connected electrically by using a copper tape to create a path from the rods to the nails, ensuring a low resistance connection.

  • What is the significance of the nails pointing in the same direction?

    -The nails pointing in the same direction is important for the machine's operation as it ensures a consistent flow of electrostatic force, contributing to the machine's efficiency.

  • What is the conversion factor for the machine when it's running on about two volts?

    -The conversion factor is about a kilowatt, indicating the machine's efficiency in converting the electrical potential into mechanical work.

  • How have electrostatic motors evolved from being seen as scientific curiosities to more significant power sources?

    -Electrostatic motors have evolved due to advancements in materials and design, making them more efficient and accessible. They are predominantly made of plastic, require little metal, and can be easily constructed with a 3D printer and nails.

  • What are some of the practical challenges faced when building the machine as described in the video?

    -Some practical challenges include ensuring that the components do not snag on each other, which can hinder the machine's operation. The video mentions the need to adjust the design to prevent such issues.

Outlines

00:00

🌟 Harnessing Atmospheric Electricity with Simple Machines

The first paragraph introduces the concept of atmospheric electricity, which is a mysterious force that can be harnessed to produce power. The Earth is described as a large ball of electrons with a cloud of positive ions above, creating a significant voltage difference. The speaker discusses the efforts to tap into this power source, comparing it to electrostatics, which is akin to the magnetism of electricity. The forces at play are responsible for the cohesion of atoms and can be utilized through devices like Corona Motors or atmospheric electrostatic Motors. The challenge lies in the need for high voltages to produce substantial force, which can be dangerous. To address this, the speaker has designed a simple machine consisting of five parts that can be 3D printed or built by hand. The machine uses minimal metal, primarily plastic, and relies on nails threaded through holes in rods to create an electrostatic connection. The process of building the machine is detailed, including the use of copper tape and pins to establish electrical connections.

05:02

πŸ”Œ Building an Electrostatic Motor and Testing Its Efficiency

The second paragraph delves into the construction process of the electrostatic motor, emphasizing the use of specific components like combs of nails and the importance of their arrangement and direction. The assembly of the motor is described, including the use of a drum, end plates with bearings, and the connection of the nails using cables and crimps. The speaker also discusses the need for grounding the motor and providing it with a static charge for testing. A high voltage supply is used to demonstrate the motor's functionality, showing that it can operate efficiently even at low current levels. The paragraph highlights the recent advancements in the field and mentions the work of individuals like Laser Hacker and industrial developments such as the C motor. The speaker also explains the choice of using nails in the motor to prevent arcing and the significance of the motor's design, which minimizes the use of metal and allows for simple and accessible construction.

10:04

πŸ› οΈ Refining the Electrostatic Motor and Its Potential Applications

The third paragraph focuses on the practical testing and refinement of the electrostatic motor. The speaker acknowledges some design issues encountered during testing, such as snagging of handles and feet, and the need for further improvements. Despite these challenges, the motor is praised for its impressive performance and potential as a power source that utilizes the natural static electricity around us. The simplicity of the motor, enabled by 3D printing and the use of basic materials like nails, is emphasized, making it more accessible for experimentation and development. The speaker expresses optimism about the motor's growing significance and encourages viewers to engage with the content by liking and subscribing.

Mindmap

Keywords

Electrostatic Motors

Electrostatic motors are devices that convert electrostatic forces into mechanical work. In the video, the creator discusses how these motors operate on the principle of like charges repelling each other and unlike charges attracting, which is a fundamental aspect of electrostatics. They are depicted as a way to harness the atmospheric electricity present around us, which is a novel approach to generating power.

Atmospheric Electricity

Atmospheric electricity refers to the natural electrical charges found in the Earth's atmosphere. The video mentions that the Earth is essentially a large ball of electrons with a cloud of positive ions above, creating a voltage difference that increases with altitude. This concept is central to the video's theme of utilizing natural forces to generate power.

Voltage Difference

Voltage difference is the measure of an electric potential between two points. The script describes how every meter increase in altitude results in a voltage difference of about a hundred volts, reaching hundreds of thousands of kilovolts at higher altitudes. This voltage difference is a key factor in the potential for harnessing atmospheric electricity.

Electrostatics

Electrostatics is a branch of physics that deals with stationary electric charges. The video likens electrostatics to the magnetism of electricity, highlighting how it's responsible for the forces that keep particles together and is omnipresent in our environment. It's the underlying principle behind the operation of the electrostatic motors discussed.

Corona Motors

Corona motors are a type of electrostatic motor. The video script mentions them as being synonymous with atmospheric and electrostatic motors, all performing the same function of converting electrostatic forces into motion. They are part of the broader discussion on innovative power generation methods.

High Voltage

High voltage refers to an electric potential that is significantly greater than the standard voltage levels. In the context of the video, high voltage is necessary to generate substantial force from low-voltage sources like atmospheric electricity. The creator demonstrates the motor's operation using a high-voltage supply to simulate the natural static electricity.

3D Printing

3D printing is a process of making three-dimensional solid objects from a digital file. The video script describes how the electrostatic motor components, primarily made of plastic, can be 3D printed, which is beneficial due to the minimal use of metal in the construction of these machines. This method allows for easier and more accessible creation of the motors.

Copper Tape

Copper tape is a thin, flexible material used for electrical connections. In the script, it is used to create an electrical path on the motor's components. The copper tape is an essential part of the electrostatic motor's construction, as it facilitates the flow of electric charge.

Aluminum Foil

Aluminum foil is a thin sheet of aluminum and is used in the video to cover the drum of the motor. It serves as a reflective surface that can help in the conduction of electricity. In the context of the electrostatic motor, it is used to enhance the motor's interaction with the surrounding electrical charges.

Static Charge

Static charge is an imbalance of electric charges within or on the surface of a material. The video discusses how static electricity, which is a buildup of static charges, can be harnessed to power the motor. The demonstration involves giving the motor a ground and a static charge to observe its operation.

Microamps

Microamps refer to a unit of electric current, with one microamp being one millionth of an ampere. The video mentions that the motor operates in the microamp range, indicating that it requires a very small amount of electric current to function, which is significant for the efficiency and practicality of the device.

Highlights

The Earth is essentially a giant ball of electrons with a cloud of positive ions above, creating a voltage difference that increases with altitude.

Atmospheric electricity can potentially be harnessed to produce power, with efforts being made to utilize this natural resource.

Electrostatics, likened to the magnetism of electricity, is a force that can be harnessed and is responsible for the cohesion of atoms.

High voltages are required for significant electrostatic force, which can be dangerous but also powerful for generating energy.

Corona Motors, atmospheric Motors, and electrostatic Motors are all terms for technology that does the same thing: harnessing electrostatic forces.

A simple machine design consisting of five parts can be used to build an electrostatic motor, which can be 3D printed or handmade.

The machine uses minimal metal, primarily plastic, making it ideal for 3D printing and reducing the risk of high voltage leakage.

Copper tape and nails are used to create a comb-like structure that serves as a key component of the electrostatic motor.

The motor's drum is prepared with an aluminum foil covering and connected to the comb structure via electrical connections.

The use of color-coded combs and directionally aligned nails is crucial for the motor's operation and efficiency.

The motor can be tested with a high voltage supply to observe its functionality and the speed at which it operates.

Recent developments have shown that these motors are more than just toys; they are becoming significant in their capabilities.

Laser hacker's Atmos is an example of independent development in the field of electrostatic motors.

The C motor is an industrial example that builds on the principles of capacitance and the work of Oleg Jeffy Manco.

The design of the motor allows for easy assembly with minimal tools and no soldering, making it accessible to a wider audience.

Despite the simplicity of the motor, there are practical challenges such as snagging and the need for further refinement in design.

The motor operates using natural static electricity, showcasing a previously ignored power source that is gaining interest.

The video concludes with a call to action for viewers to like and subscribe for more content on electrostatic motors and their applications.