caite.info 1 Bedini SG The Complete Advanced Handbook Optimizing Mechanical Recovery with a "Low-Drag" Generator Written by. Bedini SG the complete beginner's handbook (Bedini SG The Complete Beginner's Handbook Written by Peter ) Digital Format: PDF File. For anyone interested in the Bedini SG technology, please get a copy of Bedini SG - The Complete Beginner's Handbook. It will answer just about anything you need to caite.info I have read this now a couple times and.
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Bedini SG. The Complete Beginner's Handbook. Written by Digital Format: PDF File . Bedini SG is as rewarding and enriching for you as it was for us. Bedini SG Handbook Series - Download as PDF File .pdf), Text File .txt) or read online. What is the Bedini SG. Get a FREE PDF explaining the science behind FREE ENERGY! You need to know is that many of the “so-called” free energy device products.
Also, the labeled meters, switches, and connections made the demonstration easy for the Conference attendees to understand what they were looking at. You can call me or e mail at the phone and address below. I hope you will consider putting something together on that as well. What you CAN DO is study the minute details of how this process manifests itself and learn how to engineer around it! This North Pole from the Main Coil now pushes the North Pole of the magnet on the wheel away, re-enforcing its established direction of rotation. This is true of almost all mechanical systems.
By In this book.. John continued to work on his ideas.. The large model shown at the conference was built by Jim Watson. This first success did not produce the results that John was looking for. Then in John coached. John always wanted to build a self-running combination of an electric motor and an electric generator. John was "roughed-up" in his own shop and told he would "buy gasoline for the rest of his life.
Multiple working models were shown at a "Tesla Conference" in Colorado Springs. Having an interest in helping younger folks learn about his technologies. Clarke John Bedini is one of the true "living legends" of the Free Energy movement.
Introduction "The only way of finding the limits of the possible is by going beyond them into the impossible. John describes how to connect an ordinary electric motor to a specially designed "energizer" and switching circuit to produce a self-running machine that charges it's battery while running. Starting from a very young age. John published his first book on the subject titled Bedini's Free Energy Generator. Jim's machine was "confiscated" and Jim was forced to take a multi-million dollar "pay-off" to quit working on it.
Being told it was "impossible".. The energizer that Shawnee built ran on a little 9 volt battery for over a week. The machine absolutely infuriated the science teachers. News spread fast around the older internet boards and Jeane Manning. But the other teachers and students loved it. She even had a series of posters explaining why it worked. You can read this article in it's entirety. This article was called The Attractions of Magnetism. It explains the history. But it is an awful lot of material to dig through.
Unless you have built one and learned what it has to teach. The on-line forums contain a lot of experimental ideas and variations on a theme. Aaron Murakami. People getting involved for the first time now. This book is what we all wanted to have in the early days. We hope that the experience of learning about the Bedini SG is as rewarding and enriching for you as it was for us.
You can visit or join this forum for free at http: For beginners in the field. Although there is a huge data base of information on-line. Peter Lindemann.
It is quite simply THE project to start with. John consolidated several of his energizer internet discussion groups into one new forum for people to visit and learn about his technology. In the last 11 years. The Bedini SG is actually a device that operates in cooperation with the behavior of the Natural World. The most common application of the Bedini SG is to use it as a battery powered battery charger. Why You Need to Know About the Bedini SG The Bedini SG is a time-tested device that demonstrates unconventional electromagnetic and energy recycling principles that are not in the conventional textbooks.
From a learning standpoint. Or perhaps someone may wonder what the point is. Most conventional battery chargers run a lot of current through the battery. That's what the Bedini SG can do! Not only are we able to capture just about everything used. But having an energy machine that lives in symbiosis with the environment means it is working with nature instead of against it. An energy source is consumed leaving waste products in its wake.
Think about that — most energy technologies are like parasites. In addition to being able to charge these batteries. Those chargers are based on the same principles as the Bedini SG. Because of the Bedini battery charging technology. The Bedini SG actually rebuilds the chemistry of the battery from the inside.
What's more. What if the power goes out and you only have a battery as your source of power? With the global economy and energy markets in a shambles. Many people are starting battery rejuvenation businesses all around the world using these Bedini SG energizers or the solid state battery chargers available from http: Many companies claim they have battery rejuvenation technology.
All of this is documented and explained in detail. It could save your life someday. And like the first handbook.
The book also clearly describes how the circuit operations produce not only a "power gain" but an actual "energy gain" due to special behaviors in the capacitors and the batteries. It starts with a complete discussion about circuit optimization and "fine tuning" so you can "wring every ounce" of energy possible from the system. The first change is to switch from the little 9 volt battery to a more powerful 12 volt, rechargeable battery.
The next change is to ADD a component that protects the transistor, as a safety precaution, in case the voltage spike is not directed to the proper place. You see, batteries don't really perform very well when they are being "charged" and "discharged" rapidly and repeatedly. By adding a second battery to the circuit, one battery can now Run the system and the second battery can now be CHARGED by the system at the same time. This allows both batteries to operate at their highest levels of efficiency.
The first diode in the circuit is needed to conduct currents in the trigger coil loop around the transistor when they were produced in the reverse direction. The new Diode must block currents from the second battery from discharging through the Main Coil. It works extremely well, but it also demonstrates an unusual phenomenon. Most Physicists and Electrical Engineers believe that all electricity is the same, and that electricity does NOT exhibit "quality" differences, only differences in quantity.
In order to charge the second battery with a "quality" of electricity that is compatible with other methods of charging, one last modification must be made. Here, we ADD a capacitor and a switch. Now, the voltage spikes from the Main Coil can be collected in the capacitor when the switch is open and periodically delivered to the battery when the switch is temporarily closed. When all of these changes are made, it brings us to the quintessential Bedini Mono-Pole Energizer circuit that is extremely similar to the diagram shown in US Patent 6,,, issued in April of So this is the fundamental method of operating the self- rotating energizer and recovering as much of the electricity as possible.
So this covers the section on the recovery of Electrical Energy in the machine. When the circuit is tuned properly, the CHARGE Battery is charging at about the same rate as the RUN Battery is discharging, so the system can run for a long time if the batteries are periodically switched.
But there is more! The rotor of the machine is spinning, and producing some mechanical energy, as well. It is the combined electrical and mechanical energy outputs that exceed the electrical energy input. So, what can be done to the machine to enhance its ability to make even more mechanical energy? As it turns out, there are a number of design features that can be changed to accomplish this. For this Beginner's Manual, I'd like to focus on just two primary features, one is "rotor wheel diameter" and the other is "timing.
When I worked at John's shop in , I tested every model he had with a dynamometer, to measure how much mechanical energy each model produced.
Without fail, machines with the same electrical circuits produced more mechanical energy as the rotor wheel's got larger. The best one in the shop at the time was the model with the "bicycle wheel" rotor. The other feature is the "timing. This process will be discussed in detail in Chapter 6. Chapter Four Electronics for the Bedini SG You may have noticed that the electronic circuits that are a part of this project are expressed in symbolic form. This chapter of the book is for you beginners who are not familiar with the symbols used to produce a representation of the circuit, which is called a "schematic diagram.
This chapter will cover just the bare necessities for you to work with this project. If you would like to learn more about electronics, at a beginner's level, I highly recommend the book: Getting Started in Electronics, by Forrest Mims, which you can purchase from this website: Forrest Mims or by going to Amazon.
OK, let's get started. There are nine different electronic parts that have been used in the circuits discussed in the preceding chapters. They are: The Battery is the source of electric power used by the circuit. While the original Bedini SG built by Shawnee Baughman used a small 9 volt alkaline battery, all of the models you will be working with will use a rechargeable lead-acid type of battery.
These can be sealed, like a "gel-cell" battery, or the more typical type of openable cell batteries, like you may use in your automobile. We recommend that you use the lead-acid type of battery that has openable cells like the one illustrated here.
The reason for choosing a battery like this is that they are more difficult to damage when you are learning experimental charging methods.
They are also relatively inexpensive and can run your experimental energizer for between 12 and 24 hours at a time. The symbol shown here is how a battery is indicated in a schematic diagram. The parallel lines indicate the battery plates.
The short lines represent the Negative Plates and the long lines represent the Positive Plates of the battery. The Coil is the component in the circuit that produces a magnetic field when electricity flows through it. It consists of a plastic coil frame, sometimes called a "spool", one or more lengths of wire wrapped around this frame, and a material in the center of the frame to channel the magnetic field.
The coil frame is quite often in the shape of a "spool" with an open center section. This way, wire may be wound around the outside of the spool and held together by the plastic disks on each end, while the open center may be filled with a material that will channel the magnetic field.
Here we see an image of a coil illustrating these features. Here is the symbol for the Coil element in a schematic diagram. You can see the three features, including the Frame, the Core in the center, and the Wires, which show the turns symbolically as little squiggles. The dots near the top of the coils indicate that these are the same "ends" of the coil for two separate windings. The Transistor is a "semi-conductor" device that has a complex function to regulate the circuit.
Actually, it connects two parts of a circuit so that one part can regulate what the other part is doing. In this case, we are using the Transistor as a "switch" that has no moving parts, something that can turn the electricity ON and OFF when we want it to. As you can see, it has a square "case" with a mounting hole near one end. It also has three connections coming out that all must connect to the circuit.
The symbol to the right shows these three connections, and labels them B, C, and E. These letters stand for the Base, Collector, and Emitter. There are thousands of different types of transistors that perform hundreds of different kinds of functions in different circuits. The Emitter is connected to the Negative of the Battery, the Collector is connected to the Main Coil, and the Base is connected to the part of the circuit that tells the transistor when to turn ON and when to turn OFF.
Exactly "how" the transistor performs these functions is beyond the scope of this tutorial. You may find that information in the Getting Started in Electronics manual recommended earlier.
The Resistor is a passive component that regulates how much electric current moves through that part of the circuit. It has two connections fitted to either end of a cylindrical body. It can be hooked up to the circuit in either direction. Resistors come in hundreds of sizes and are rated for the amount power flowing through them, as well as for their resistance to current flow, which is rated in units called Ohms.
The symbol for the resistor is shown as a wavy line that resembles the teeth of a saw blade. You may be able to see some colored stripes on them. These stripes represent a code which reveals the resistance value of the component.
The larger blue resistor is a typical 2 watt device. Its color code, starting from the right side is blue-yellow-brown-gold.
Many electronic components have these tolerances ratings, because it is impossible to mass produce components that have exactly the same values. It acts like a valve that is open to electricity flowing in one direction, but if it tries to go backwards, the valve shuts and prevents the electricity from coming back. Because the diode passes electricity in one direction and blocks it in the other direction, it is very important to install diodes in a circuit correctly. Whereas Resistors operate the same in both directions, Diodes do not!
Diodes usually appear as a small cylinder with a wire coming out of each end. Diodes will usually show the symbol, or a single stripe at one end of the cylinder, as the examples in the picture shows.
One end of the diode is called the "Cathode" C and the other end is called the "Anode" A. Electricity will flow through the device when the Cathode is "more negative" than the Anode, OR if the Anode is "more positive" than the Cathode. The stripe indicates the Cathode end of the Diode. The symbol for the Diode looks like an arrow pointing at a solid line.
Remarkably, the direction of flow of electricity through the Diode is in the opposite direction of this arrow. The reason for this is that the symbol for the Diode was invented when it was believed that electricity flowed from Positive to Negative. After it was discovered that electrons have a Negative charge, and their flow was really from Negative to Positive, it was too late to change the symbol. So, electron currents flow through the Diode in the opposite direction of the way the arrow is pointing.
The Capacitor is a component that stores electricity. Whereas a battery stores electricity in a chemical form, the capacitor stores the electricity as an electrical stress across a material called the "dielectric. Capacitors come in many shapes and sizes, from as small as a little resistor, all the way up to the size of a garbage can.
These two capacitors are about one inch in diameter. The symbol for a Capacitor is two parallel lines facing each other, with wires coming out. These parallel lines represent the "plates" of the capacitor and the space between the lines represents the dielectric material that separates them.
So, a typical capacitor has two contacts and connects to a circuit in two places. Capacitors are rated both for how high a voltage they can store, but also for how much energy they can store, which is called "capacity.
Others are not polarized and can be connected to a circuit in either direction. Polarized Capacitors are usually marked with a stripe on the negative terminal or on the side of the label. Actually, most semi-conductor junctions produce some light when they operate, but LEDs are designed to maximize the light producing function.
The symbol for the LED is the same as for a Diode, except that it also has two little squiggly lines next to it, indicating that light is coming out of the diode. Like all other Diodes, the LED only allows electricity to move through it in one direction.
And, like all other Diodes, the LED has a Cathode and an Anode and must be connected to the circuit correctly to operate. The Neon Light is a specialty lighting device where two electrodes are placed near each other in an enclosed space that contains a small amount of Neon gas at very low pressure.
It usually takes about volts to make a neon bulb light up. The symbol for the Neon Light mimics its internal structure, where two parallel electrodes are surrounded by an enclosure. Neon Lights can run on either AC or DC and are rated for both the voltage needed to light them up, as well as for how much power they use, measured in milliwatts.
The Switch is any device that allows a temporary contact between two sections of a circuit. Most of us use switches everyday, to turn ON appliances, lights, fans, stove elements and other things. We even have many automatic switches that turn things ON and OFF based on pre-set conditions, like the thermostat in our house, or the refrigerator and freezer.
In the Bedini SG Project, the Switch is used to discharge the Capacitor into the Battery after it has been charged to a certain level by the discharges of the Main Coil. The generic symbol for a switch is the one shown here, where a wire is interrupted with a section connected to one end and the other end is hovering over the wire. This represents a break in the wire that can be closed to complete the connection. It shows the same roller wheel and two brush contacts in symbolic form as the top picture shows as a real model.
So, anything that works to make a momentary contact, periodically, will discharge the Capacitor into the Battery and keep the system operating.
Reading a Schematic Diagram is pretty easy, once you understand how circuits are laid out. In general, circuits usually have at least three parts. They are best described as Power, Control, and Output. The Power section of the circuit consists of a "power supply", and the part of the circuit that power is being supplied to.
The Control section of the circuit is the part that tells the power section "what to do" and "when to do it. An example of a circuit is a home music system. The Power comes from the wall plug and is converted into the power needed by the circuit.
The Control function starts with the music signal stored in the recording and transfers it to the power section. The Output is the speaker system where you can listen to the music at a controllable volume. So here is the schematic diagram of the simplest form of our project. Notice, I have used the symbols I talked about earlier in this chapter and labeled each component with a simple letter, or letter and number designation.
All of the lines that connect between the labeled components represent wires. So, let's review the components of this circuit.
B1 is the "first battery" or the battery the system runs on. It is the beginning of the circuit, and functions as the "primary power supply. B2 is the "second battery" or the battery the system charges. Since this is the end result of the circuit, B2 also represents the Output, and in this case, the actual end of the circuit.
Let's look at the Power Section of this circuit. We have already identified B1 as the power supply, and the beginning of the circuit. So, what does the "power supply" supply power to? In the diagram below, I have highlighted this section of the circuit in RED. Tracing the flow of electron current from the Battery B1 we see that it flows out of the Negative terminal, follows the wire to the Emitter of Transistor T , comes out the Collector of Transistor T , follows the wire up to the bottom of Main Coil MC , flows through Main Coil MC and comes out the top, then follows the wire back to the Positive Terminal of Battery B1.
Read the paragraph above and look at the drawing of the circuit diagram to the right until you understand that they represent exactly the same set of ideas. If you are having trouble with this, please refer back to the earlier descriptions of the battery and the transistor.
This is the power section of the circuit for this project. When this function happens, the Main Coil MC is being magnetized, and the magnet on the rotor wheel is being pushed away. It is the only time when electricity is coming out of Battery B1 and the only time when the system is consuming any energy that counts as an "input.
Even though this is the Power Section of the circuit, it too has the three main functions of Power, Control and Output. The power comes from the Battery B1. The Control is provided by Transistor T , and the Output, or the end effect, is the production of a magnetic field when the electric current flows through Main Coil MC. Next, let's look at the Control Section of this circuit.
The power to operate this part of the circuit comes from changes in the magnetic field in the coil core and its ability to generate electricity in the Trigger Coil TC. The control section of this circuit consists of both the Resistor R and the Diode D1. The output of this section of the circuit is the proper set of conditions to activate the Base of Transistor T so that it turns ON and OFF at the right time to run the Power Section properly.
The Output Section of the circuit is next. When this happens, the magnetic field must collapse. In doing so, it induces a burst of electrical energy in Main Coil MC that can be collected. Capturing this energy is one of the main reasons for learning about this project. Diode D2 is the control component in this section of the circuit. It allows the discharge of the energy in Main Coil MC to divert around the Transistor T and also facilitates the charge in Capacitor C to build up without discharging.
The charging of Capacitor C is the desired, end result of this section of the circuit. In this section, Capacitor C is the power source, Switch S is the control device, and the charging of Battery B2 is the end result, the final Output, and the last operation of the circuit.
In Summary, the circuit works like this. That magnetic field is used to create a mechanical action upon the magnet on the wheel. After this operation is finished, the energy in the magnetic field is discharged.
The electricity produced by the discharge of the magnetic field is then captured in the Capacitor C. As multiple discharges of the Main Coil MC accumulate, the voltage in Capacitor C rises high enough so that the excess electricity can be transferred to Battery B2. This sequence of events produces what Nikola Tesla referred to as a "shuttle circuit" where electricity is transferred from location to location, but never allowed to "ground out", dissipate, or be lost entirely.
This method represents the true meaning of "Energy Conservation. If, for any reason, it is prevented from discharging through Diode D2 as shown on the previous page, a secondary path must be available to dissipate this energy, or Transistor T will be damaged.
MC through Battery B1. While this is not the preferred way to collect this energy, it does allow the energy to be safely dissipated without damaging Transistor T by subjecting it to a very high voltage spike. Hopefully, by now, you have a pretty good idea about how this circuit works, and how to read a schematic diagram. You'll need to know all of this stuff as you move into the next chapter, where you will find complete instructions on how to build your very own model of the Bedini SG.
But before we do that, there is one more, minor detail about reading schematic diagrams that I would like to bring to your attention. That issue relates to how best to symbolically represent when "wires cross each other and connect" and "when wires cross each other and DO NOT connect.
The first method is the method I have Not Connected Connected been using in the schematic diagrams Not Connected Connected in this book. As shown in this first drawing, the image on the left that looks like the horizontal line is looping over the vertical line, represents where the two wires cross each other in the diagram, but ARE NOT electrically connected. The image on the right that looks like the lines form a cross represent where the two wires come together in the diagram and ARE electrically connected.
The second method is used in some of the patents in the back of the book and looks like this. The image on the left, where the lines cross, represents where two wires cross over each other in the diagram, but ARE NOT electrically connected. The image on the right, where the lines cross with a www. So, when reading a schematic diagram, it is helpful to quickly determine which method is being used, or you may misinterpret the circuit. Which Way does Electricity Flow?
People have been doing practical things with electricity since Ben Franklin invented the "Lightning Rod" back in His concept was that the earth ground was Negative and the stormy sky had a Positive quantity of electricity.
It appeared that when lightning struck, it moved from the sky towards the ground. So, the convention developed that electricity flowed like heat, from the location that had an excess Positive to the location that had less Negative.
When the Electron was discovered by Joseph J. Thomson in , it was found to hold a "negative charge. This explanation assumes that electricity flows from Negative to Positive. For the last years, people have believed both explanations. Regardless of which theory may be right or wrong, all of the circuit explanations in this book use the Electron Current model and assume that the electric currents are flowing from Negative to Positive in the circuit.
If you were taught Conventional Theory, please realize that all of the explanations in this book are not "wrong. Magnetic fields also flow between the poles of the magnet.
Some people www. Some people believe they flow from the South Pole to the North Pole. And still others believe that energy flows from both poles and re-enters the magnet in the center, at the so-called "neutral line. One thing that we do know about magnetic fields is how to make either a North Pole or a South Pole appear where we want in an electric coil.