Practical Guide to Free-Energy Devices
A wonderful resource for anyone interested in this field. Patrick J. Kelly has kept a immense collection online for years despite attempts to have it removed. Read more by clicking on the link below.
The purpose of this web site is to provide you with an introduction to a series of devices which have been shown to have very interesting properties and some are (incorrectly) described as ‘perpetual motion’ machines.
What’s that you say – perpetual motion is impossible? My, you’re a difficult one to please. The electrons in the molecules of rock formations have been spinning steadily for millions of years without stopping – at what point will you agree that they are in perpetual motion?
So, why don’t electrons run out of energy and just slow down to a standstill? The universe is a seething cauldron of energy with particles popping into existence and then dropping out again. If the equation E = mC2 is correct, then we can see that a tremendous amount of energy is needed to create any form of matter. Scientists remark that if we could tap even a small part of that energy, then we would have free energy for our lifetime.
The Law of Conservation of Energy is generally thought to be correct when it states that more energy cannot be taken out of any system than is put into that system. However, that does not mean that wecannot get more energy out of a system than we put into it. A crude example is a solar panel in sunlight. We get electrical power out of the panel but we do not put the sunlight into the panel – the sunlight arrives on its own. This example is simple as we can see the sunlight reaching the solar panel. In passing, it might be remarked that the “Law” of Conservation of Energy has recently been proved to be wrong, however, it wouldn’t bother me at all if it were actually right as it assumes a “closed system” which is something that does not exist anywhere in the universe.
If, instead of the solar panel, we had a device which absorbs some of the energy which the universe contains and gives out, say, electrical power, would that be so different? Most people say “yes! – it is impossible!” but this reaction is based on the fact that we cannot see this sea of energy. Should we say that a TV set cannot possibly work because we cannot see a television transmission signal?
Many people have produced devices and ideas for tapping this energy. The energy is often called “Zero-Point Energy” because it is the energy which would remain if a system has it’s temperature lowered to absolute zero. This presentation is introductory information on what has already been achieved in this field: devices which output more power than they require to run. This looks as if they contradict the Law of Conservation of Energy, but they don’t, and you can see this when you take the zero-point energy field into account.
The material on this web site describes many different devices, with diagrams, photographs, explanations, pointers to web sites, etc. As some of the devices need an understanding of electronic circuitry, a simple, step-by-step instruction course in electronics is also provided in Chapter 12. This can take someone with no previous knowledge of electronics, to the level where they can read, understand, design and build the type of circuits used with these devices.
This is a very interesting field and the topic is quite absorbing once you get past the “it has to be impossible” attitude. We were once told that it would be impossible to cycle at more than 15 mph as the wind pressure would prevent the cyclist from breathing. Do you want to stay with that type of ‘scientific’ expert? Have some fun – discover the facts.
There are many, many interesting devices and ideas already on the web. This site does not mention them all by any means. What it does, is take some of what are in my opinion, the most promising and interesting items, group them by category, and attempt to describe them clearly and without too many technical terms. If you are not familiar with electronics, then some items may be difficult to understand. In that case, I suggest that you start with Chapter 12 and go through it in order, moving at whatever speed suits you, before examining the other sections. I hope you enjoy what you read