Today, I want to talk about a form of energy harvesting that you may not have heard much about: capacitive coupling. Typically, when we discuss energy harvesting, we talk about inductive methods such as RF and power lines. However, capacitive coupling can be just as effective.
Before we dive into the specifics, let's talk about what capacitive coupling is. In short, it is a method of transferring energy from one object to another without the use of wires. It relies on the concept of capacitance, which is the ability of two objects to store an electrical charge.
Now, let's get into the nitty-gritty of how capacitive coupling works. To start, we need to calculate the capacitance of the system. This is dependent on the frequency, which in our case is 60 hertz (Hz) since we're dealing with power lines. Next, we need to figure out the capacitive reactance values, which is where things get a bit more complicated.
Assuming we're using a 25-foot strip plate of metal for the capacitive coupling, we can calculate the reactive capacitance to be 394.6 ohms. We also need to use Ohm's law to find the current value and power factor assuming we're receiving 50 volts of power to our system. Based on these calculations, we can estimate that we can receive a total of 6.33 watts of power output from the air through capacitive coupling.
Now, you might be wondering how this can be applied in real life. One potential use case is to build a conductive plate that acts as a capacitor and place it above the same length as a solar panel. Through wireless capacitive coupling, you can extract a significant amount of power that would otherwise go to waste. This power can be used to trigger circuits or charge batteries.
Of course, it's not as simple as just building a plate and calling it a day. We need to ensure that it's safe and efficient to use. Here's an example of how a system like this could be implemented:
Assuming we're roughly 75 feet away from a power line, we can place our 25-foot plate underneath it. One side of the plate should be grounded, and the other side should be connected to the capacitor. This will allow for the capacitive coupling of voltage between the plate and the power line.
One thing to note is that this method won't be as efficient as being directly plugged into the mains. However, it's still worth considering since it's essentially wasted energy in the near field. Any extra source of power we can use is better than nothing.
In conclusion, capacitive coupling is an often overlooked form of energy harvesting that has the potential to be just as effective as inductive methods. While it may seem complicated at first, it's a valuable tool that we can use to extract power from the air.
"Revolutionary Windows: Harnessing Thermal Energy for Winter Heat"
As the winter season sets in, heating costs can skyrocket, making it difficult for households to stay warm without breaking the bank. But what if there was a way to harness the power of thermal energy to keep your home warm? That's where revolutionary windows come in.
The concept behind these windows is simple yet innovative. One side of the window is designed to pull the cold air from the freezing outside, while the other side is designed to pull the heat from the inside. This thermal reaction creates or powers a heat source that can keep your home warm and cozy throughout the winter season.
To achieve this, the windows helps to transform the temperature difference into electrical energy. This electrical energy is then used to power a feedback loop between two coils, which increases the amplitude of the thermal reaction.
The result is a cost-effective and energy-efficient solution that can be used in homes, offices, and other buildings. By harnessing the power of thermal energy, these revolutionary windows can help to reduce heating costs and provide a more sustainable source of heat.
In addition to being a practical solution for winter heating, these windows also have the potential to be used in other applications. For example, they could be used in greenhouses or other agricultural settings to help regulate temperature and provide a more stable growing environment.
Overall, revolutionary windows represent an exciting development in the world of sustainable energy. With their ability to harness thermal energy for winter heat, they offer a unique and innovative solution that could have far-reaching implications for the future of energy production and consumption.
To take this concept a step further, solar power can also be incorporated into the design by using a solar diode as an oscillator instead of a traditional solar panel. This oscillator can also be used with two coils to create an additional feedback loop, which can increase output.
The combination of thermal and solar power in this way provides a sustainable and renewable source of energy, as well as a means of reducing energy costs and environmental impact. Additionally, this approach can provide an innovative and unique way to utilize windows in buildings, making them a source of green energy instead of simply a passive component of construction.
While this concept is still in the early stages of development, it holds great potential for providing an alternative energy source that is accessible, affordable, and environmentally friendly. With continued research and development, it may one day become a significant contributor to the world's energy supply, helping to mitigate climate change and reduce dependence on fossil fuels.
To construct your window, you could potentially use a thin film of bismuth telluride sandwiched between two layers of glass. The layer of bismuth telluride would be in contact with the outside air, while the layer of glass on the inside would be in contact with the warmer indoor air. As heat flows from the inside to the outside, the bismuth telluride layer would generate an electrical potential that could be used to power a heating element or to charge a battery for later use.
Of course, there would be many design considerations and challenges to overcome in creating a functional window like this, including the need to maintain a seal between the inside and outside environments, optimizing the materials used for maximum efficiency, and dealing with the variability of outdoor temperatures. But with careful planning and experimentation, it could be possible to create a window that helps regulate indoor temperatures using the power of thermoelectricity.
Posted by: JoeLag - 03-29-2023, 02:32 AM - Forum: Files
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From the Cejka Files:
Cejka - A German Cancer Therapy
The article discusses a new type of cancer therapy called the German New Medicine, which was developed by Dr. Ryke Geerd Hamer in the 1980s. According to Hamer, cancer is not a disease caused by mutations or genetic defects, but rather the result of a shock or trauma that affects the psyche and the brain. He believed that cancer is the body's natural response to a traumatic experience, and that it serves as a means of healing and self-repair.
The German New Medicine is based on five biological laws that explain the biological significance of disease, including cancer. These laws describe the stages of healing that the body goes through in response to a traumatic experience, and the symptoms that can manifest during each stage.
The therapy involves identifying and resolving the traumatic experience that triggered the cancer, and supporting the body's natural healing process through diet, lifestyle changes, and natural remedies. The therapy also includes emotional healing and addressing any psychological issues that may have contributed to the traumatic experience.
While the German New Medicine has been controversial and has not been widely accepted by the medical community, some patients and practitioners have reported positive outcomes from using this therapy. However, it is important to note that the therapy should not be used as a substitute for conventional cancer treatment, and patients should always consult with their healthcare provider before starting any new treatment.
Posted by: JoeLag - 03-29-2023, 02:04 AM - Forum: Files
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From the Cejka Files
Cejka - A Dynamic Model of Cell Membranes Capald
Artificial Membranes: A Revolution in Science and Technology
Membranes are thin, flexible barriers that separate different environments. In biology, membranes are essential components of cells, organelles, and tissues, and they control the flow of molecules and ions across them. In engineering, membranes are used for filtration, separation, purification, and other processes that involve the transport of fluids and solutes.
For decades, scientists and engineers have been interested in creating artificial membranes that mimic or surpass the properties of natural membranes. Such membranes could have many applications in medicine, biotechnology, energy, and environmental fields. However, designing and synthesizing artificial membranes is a complex and challenging task that requires multidisciplinary approaches and cutting-edge technologies.
One of the main strategies for creating artificial membranes is to use synthetic polymers that can self-assemble into thin films or vesicles. These polymers can be engineered to have specific chemical, physical, and mechanical properties that enable them to mimic or improve upon natural membranes. For example, some polymers can form ion channels or pores that allow selective transport of ions or molecules, while others can form bilayers or monolayers that have high stability and permeability.
Another approach to creating artificial membranes is to use biological or biomimetic materials that can integrate with natural membranes or mimic their functions. For example, liposomes are vesicles made of phospholipids, which are the main building blocks of cell membranes. Liposomes can be used for drug delivery, gene therapy, or tissue engineering, as they can protect and target their cargo while avoiding immune or toxic responses. Similarly, some proteins or peptides can form channels or pumps that mimic the functions of ion channels or pumps in natural membranes.
Artificial membranes have many potential benefits and challenges. On the one hand, they could enable new therapies, diagnostics, and sensors that are more precise, selective, and efficient than current technologies. For example, artificial membranes could be used to create artificial organs, prosthetics, or implants that can integrate with the body's tissues and functions. On the other hand, artificial membranes could raise ethical, social, and environmental concerns, as they could alter the natural boundaries and interactions of living systems. For example, artificial membranes could be used for genetic engineering, synthetic biology, or geoengineering, which could have unpredictable or irreversible consequences.
In conclusion, artificial membranes are a fascinating and rapidly advancing field of science and technology that offers many opportunities and challenges. By combining the principles of biology, chemistry, physics, and engineering, researchers and innovators can create new materials, devices, and systems that could transform many aspects of our lives. However, it is crucial to ensure that the development and use of artificial membranes are guided by ethical, legal, and societal principles that prioritize safety, transparency, and equity.
Posted by: JoeLag - 03-29-2023, 01:50 AM - Forum: Files
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From the Cejka Files:
Cejka - Atomic Transmutations - Michio Kushi
The article discusses the concept of transmutation, which is the process of transforming one thing into another. The author explains how transmutation can occur in various forms, including chemical reactions, spiritual practices, and personal development. The article then focuses on personal transmutation, describing how individuals can transform negative emotions and experiences into positive growth and change. The author provides several examples of personal transmutation, such as turning fear into courage, transforming anger into compassion, and changing disappointment into motivation. The article concludes by emphasizing the importance of embracing the process of personal transmutation as a means of personal and spiritual growth.
