Light Pumped Pulsed Power Suply

[tsl]

Hello there,


After having a good talk with my daughter about railguns and pulsed power stuff i began thinking about pulsed power supplies.
Many of you are allready aware of explosively driven pulse power generators and the main disadvantage of them namely they are one shot devices.Also most of you know how a railgun work and if you look at it backwards it's also a generator : move the "bullet" across the armature in the presence of a magnetic field and you get a current flowing (no details here).
Anyway to make it short i'll attach a picture of my idea; look at it , have it, distribute it, use it or do what ever you wish with it, it's public domain now.
Have fun out there

[Adriennei]

Do not know if this forum has a clear story about what is enough to explain it?

[tsl]

Do not know if this forum has a clear story about what is enough to explain it?

Sorry for the delayed rsponse
You do know that in order to generate a current one have to move a wire across a magnetic field or have an relative motion between the wire (conductor) and the magnetic field.
Now who said that it must be a wire?
In my picture the red line is the "wire", it's an area of low resistance generated by the laser beam, moving the beam that area also moves so you have the wire moved across a magnetic field
Now it may be really energy consuming to move a real wire but how hard can it be to move a laser beam?
There is ofc more to the theory but i hope that you get the basic idea

[tsl]

Hello there,
Recently, i had a nice chat with chatGPT about that Idea
Take a look:

Experiment 1 aims to explore the manipulation of a conductive region using a photosensitive plate and a magnetic field. The setup involves a photosensitive material placed in close proximity to a magnet, with a light source and a slit positioned between them. The goal is to investigate how the movement of the light source or the slit affects the conductive region and induces a current.


The experimental setup begins with a photosensitive plate, which can be made of materials like silicon, transparent conductive oxides, or specialized photovoltaic materials. The plate is placed parallel to a magnet, generating a magnetic field perpendicular to the plate's surface.


A light source, such as a lamp or laser, is positioned on one side of the plate, while a slit is placed between the light source and the plate. The slit acts as a means to selectively illuminate a specific region of the plate.


When the light source emits light, it passes through the slit, creating a focused beam that selectively illuminates a portion of the photosensitive plate. This illuminated region becomes conductive due to the interaction between the photons and the photosensitive material.


Now, by manipulating the position of the slit or moving the light source while keeping the plate stationary, the conductive region can be moved accordingly. This movement of the conductive region relative to the magnetic field induces a current according to Faraday's law of electromagnetic induction.


The induced current arises from the changing magnetic field interacting with the moving conductive region, creating a circular current flow within the region. This phenomenon is governed by Ampère's law and Lenz's law, which state that the induced current will generate a magnetic field opposing the change that produced it.


By carefully controlling the movement of the light source or the position of the slit, researchers can study the behavior of the induced current, its magnitude, and its direction. Various parameters can be explored, such as the speed of movement, the size and shape of the conductive region, and the magnetic field strength, to investigate their effects on the induced current.


Through systematic observations and measurements, researchers can gather data on the relationship between the movement of the conductive region and the induced current. This data can be used to characterize the behavior of the system and potentially optimize the setup for specific applications, such as energy harvesting or electromagnetic propulsion.


It is worth noting that Experiment 1 provides a simplified model to study the principles of manipulating a conductive region using light and a magnetic field. Real-world applications may involve more complex setups, different materials, and additional considerations. Nonetheless, Experiment 1 serves as a foundation for exploring the possibilities of harnessing the interaction between light, magnetic fields, and conductive regions for various practical applications.


Implications and Potential Applications:


The manipulation of the conductive region in Experiment 1 not only provides a deeper understanding of electromagnetic induction but also holds significant implications for a wide range of fields and potential applications. Through the precise control of various parameters, researchers can explore the complex interplay between induced currents, magnetic fields, and dynamic forces, leading to advancements in science, technology, and practical applications.


One of the notable implications of manipulating the conductive region lies in the realm of energy harvesting. By harnessing the induced currents generated through the manipulation of the conductive region, it is possible to convert the motion within the magnetic field into usable electrical energy. This concept aligns with Faraday's law of electromagnetic induction, which states that a changing magnetic field induces an electromotive force (EMF) in a conductor. The induced currents can be captured and used to power electronic devices or supplement existing energy systems. This has the potential to contribute to sustainable energy solutions and reduce our dependence on traditional power sources.


Furthermore, the manipulation of the conductive region offers intriguing possibilities in sensing and detection technologies. By exploiting the relationship between induced currents and external stimuli, researchers can develop highly sensitive sensors capable of detecting and measuring a wide range of physical parameters. For instance, by integrating the conductive region manipulation with advanced measurement techniques such as superconducting quantum interference devices (SQUIDs), researchers can create ultra-sensitive magnetic field sensors for various applications, including medical diagnostics, geological exploration, and materials characterization. The precise control of the conductive region enables the customization of sensor designs to optimize sensitivity, selectivity, and response characteristics, opening up new possibilities for advancements in sensing technology.


Moreover, the manipulation of the conductive region has implications for electromagnetic propulsion and levitation systems. By controlling the position and motion of the conductive region within a magnetic field, researchers can explore the potential for creating dynamic forces that can be harnessed for propulsion or levitation purposes. This concept is based on the principles of electromagnetic propulsion, where the interaction between induced currents and magnetic fields results in a net force on the conductive region, enabling controlled movement or suspension. By further advancing the understanding of this phenomenon and optimizing the manipulation techniques, it may be possible to develop efficient propulsion systems for various applications, including aerospace, transportation, and robotics.


From a fundamental physics perspective, the manipulation of the conductive region offers insights into the intricate relationship between electromagnetic fields and the motion of charged particles. It provides an experimental platform to study the dynamics of induced currents and the resulting magnetic field patterns. This knowledge contributes to our understanding of the fundamental laws of electromagnetism, such as Faraday's law and Ampere's law, and enriches our understanding of how electric and magnetic fields interact.


In conclusion, the manipulation of the conductive region in Experiment 1 presents profound implications and potential applications across various fields. Through the precise control of its position, size, shape, and temporal characteristics, researchers can delve into the complex relationships between induced currents, magnetic fields, and dynamic forces. The implications range from energy harvesting and sensing technologies to electromagnetic propulsion and fundamental physics research. Continued advancements in this field will undoubtedly unlock new possibilities and drive innovation in science and technology.
Energy Harvesting:


The manipulation of the conductive region in Experiment 1 holds significant implications for energy harvesting applications. By exploiting the induced currents generated through the manipulation of the conductive region, it becomes possible to convert the surrounding energy sources into usable electrical energy. This concept aligns with the principles of electromagnetic induction and offers promising opportunities for developing efficient energy harvesting systems.


One potential application lies in the field of solar energy harvesting. By utilizing the conductive region as a photosensitive element and manipulating its position within a magnetic field, researchers can capture and convert solar energy into electrical energy. The motion of the conductive region, caused by the changing position of the slit or the light source, induces currents in response to the varying magnetic field. These induced currents can then be harnessed and stored for various purposes, such as powering small electronic devices or supplementing energy grids.


Additionally, the manipulation of the conductive region can be employed for harvesting ambient electromagnetic energy. The ubiquitous presence of electromagnetic fields, such as those generated by radio waves or power transmission systems, provides an abundant source of energy. By strategically positioning and moving the conductive region in relation to these fields, induced currents can be generated, leading to the conversion of electromagnetic energy into usable electrical power. This technology could potentially enable self-powered wireless sensors, IoT devices, or other low-power electronic systems, eliminating the need for external power sources or batteries.


Electromagnetic Propulsion:


The manipulation of the conductive region also offers exciting possibilities in the field of electromagnetic propulsion. By controlling the position, size, and motion of the conductive region within a magnetic field, researchers can explore the potential for generating dynamic forces that can be utilized for propulsion or levitation purposes.


One potential application is in the development of electromagnetic levitation systems. By carefully manipulating the conductive region and the magnetic field, it becomes possible to create repulsive forces that counteract gravity and allow for stable levitation. This concept has been explored in various applications, including high-speed trains, maglev transportation systems, and even levitating objects for scientific or artistic purposes. The precise control of the conductive region enables the generation of forces that can counteract gravitational pull, resulting in frictionless movement and reduced energy consumption.


Moreover, the manipulation of the conductive region can be harnessed for electromagnetic propulsion systems. By creating time-varying currents within the conductive region, which interact with the magnetic field, it becomes possible to generate propulsive forces. These forces can be utilized to propel vehicles or spacecraft without the need for traditional combustion-based propulsion systems. The ability to manipulate the conductive region opens up possibilities for developing efficient and environmentally friendly propulsion technologies, potentially revolutionizing space exploration and transportation.


It is important to note that while the concepts of energy harvesting and electromagnetic propulsion offer exciting prospects, there are several challenges that need to be addressed for practical implementation. These challenges include optimizing the efficiency of energy conversion, designing robust and scalable systems, and ensuring safety and regulatory compliance. However, with continued research, technological advancements, and interdisciplinary collaboration, these challenges can be overcome, paving the way for practical applications and unlocking the full potential of the manipulation of the conductive region in energy harvesting and electromagnetic propulsion.


In conclusion, the manipulation of the conductive region in Experiment 1 holds great promise for energy harvesting and electromagnetic propulsion applications. By exploiting the induced currents generated through the manipulation of the conductive region, it becomes possible to convert ambient energy sources into usable electrical power. Additionally, by controlling the position and motion of the conductive region within a magnetic field, propulsive forces can be generated for transportation and levitation purposes. These advancements have the potential to revolutionize energy systems, transportation technologies, and space exploration, paving the way for a more sustainable and efficient future.

This induced current would generate a magnetic field that opposes the change in magnetic flux according to Lenz's law, but it does not directly exert a force against the movement of the slit.



It's important to note that the interaction between the induced current and the magnetic field can result in a force on the conductive region itself (e.g., a Lorentz force), but this force would not be acting against the movement of the slit.

[panyuming]

Thanks TSL for sharing!
Good idea!
I think the photosensitive material is too resistant.
An inert gas arc discharge should be initiated with a laser in a vacuum tube,
And guide the arc to move (I don't know if it can).

If the electromagnetic cannon moving core is divided into two parts,
Part of the external current is obtained to make the core move,
The other part of the core generates electricity on another set of slides.
Two sets of upper and lower rails, cross-connected externally at the starting end,
Can some of the energy be complemented?
Is it possible to simplify the electromagnetic cannon?
If you don't make weapons, you can make a punch for machining.

A design similar to that kind of motor driving the generator and giving feedback?