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Motionless Switching Magnetosphere Electric Generator
Switching the flux flow of 128 permanent magnets or more by powering one electromagnet
This invention is the greatest new technology I know of in theory because it produces a lot more electrical energy than it needs to operate it. It does this by creating a smaller flux flow in one coil through electrical stimulation to control the Flux rerouting of several other permanent magnets in the generator. This rerouting of flux from several permanent magnets is routed through adjacent coils to each of these magnets. The flux rerouting through all of these coils in the generator are used to generate electrical energy. The electrical energy it takes to control the switching coil is a lot less than the electrical energy that is generated from the accumulation of all of the output coils in this generator.
Let’s go through each word of the generator to give you an introduction to this new technology.
Motionless: There are no physical moving parts in this generator. There are several moving flux paths in this generator, but that movement does not cause physical wear on the components of the generator. The maintenance of this generator will be minimal. Fuses can be added into the generator to protect the hardware of this generator.
Magnetosphere: The generator operates like one large magnetosphere in one mode and several magnetospheres in the second mode. The two different modes each has different flux routes from each of the magnets in the generator. This is unique from any other generator that I have seen.
Switching: The Switching is done by one coil by alternating the operation of the generator between the two magnetosphere modes. Mode one is operating with all the permanent magnets in the generator operating collectively in one magnetosphere. The flux goes from magnet to magnet in this mode. Mode two is each permanent magnet operating with the closest coil to it to form individual magnetospheres in the generator. Each coil adjacent to a permanent magnet provides an easy flux return path for each magnet, creating several smaller self-sustaining magnetospheres in the generator.
Electric: The world is changing into an all-electrical energy world. So having a generator that does not need external power to operate it is the best invention in today’s world that will help the world to move from having the need to use up its fossil fuels. This is an open energy system because it harvests energy using the permanent magnets to move flux into and out of several output coils in the generator.
Generator: Having this generator that produces free electrical energy will reduce the need to quickly change the technology of less efficient electrical devices. This is because all you need to do is to build a bigger generator to operate them.
Note: Now over the long run, you will want to build more efficient devices like electric motors so that you do not have to purchase the higher power generators. This will reduce the consumer cost in the overall cost of their living expenses. So, the best approach is to develop the generator first, then the other devices I have written about in my other books.
Motionless Switching Magnetosphere Electric Generator Drawing .png
Figure one shows one example of what the Motionless Switching Magnetosphere Electric Generator looks like. Here the generator is built up with 16 fin assemblies all sharing the same core assembly. All of these put together form a magnetosphere. I call it a magnetosphere because the magnetic flux moves around and through this generator like a magnetosphere. Each fin has 8 permanent magnets colored in red and blue to show their polarity. The red color is the north pole of the magnet and blue to represents the south pole of the magnet. The fins also have 8 coils in them. The light green color is the core of the coil, and the dark green is the wire around the core material. These coils are used as output coils in this generator. The first drawing has the output coils in grey because no flux is in them at this point of the generator’s operation.
The generator has one core that is shared with all the fin assemblies. The permanent magnets and the coil being operated like an electromagnet are larger in the core assembly to handle the sum of flux through them from the 16 fin assemblies.
Motionless Switching Magnetosphere Electric Generator Drawing Config 2 .png
Figure two shows one of the two configurations for this generator. The Coil or Electromagnet in the middle of the generator controls the two modes of the generator. When the switching coil does not have any power going through it, then the flux in the core will move from one permanent magnet to another one. Then it moves through the core of the switching coil. Then through the other side of the generator’s core through the other permanent magnets of the core assembly. Then the flux flows through each of the fin assemblies to the other side of the core again in order to complete one large ring of travel for each fin assembly. It keeps repeating this loop over and over again. If the current through the coil is in one direction, then it will produce a flux in it that supports the flux flow through the permanent magnets and the core of the coil of the magnetosphere. When either of these two coil conditions occurs then the magnetosphere is active of having one large flux ring through each fin assembly moving through the common sphere core assembly. This condition will keep most of the flux movement away from the fin coil assemblies. If the magnetosphere stays in this condition, then no electrical energy will be generated. Electrical energy is generated when a magnetic field is moving into or out of the output coils. Therefore, we need a second condition for the generator to go into, so that changing flux pathing can occur. The second generator configuration is shown in the next drawing. The length of the permanent magnet needs to be longer than the distance from one permanent magnet to the next permanent magnet. If it is not, then there will be a lot of flux returning to the other side of the individual magnet because it is a better route than going to the next permanent magnet in the fin assembly.
Motionless Switching Magnetosphere Electric Generator Drawing Config 1 .png
Figure 3 shows the second condition of the generator. The coil is used like an electromagnet in the core assembly. It is powered to produce a magnetic field that opposes the permanent magnets in the core assembly. This action will stop continual flux flow through the core assembly. This action destroys the generator from operating as one large magnetosphere. When this happens, the permanent magnets seek the next easy path to move its flux. This path for each of the magnets in the fin assemblies become the coils that are parallel with them. These coils have cores in them. Flux moves easier through core material, so most of the flux will now flow through the coils rather than the air pathways. Now if the coil in the core assembly stays in this state, the flux will be constant in this state.
To generate electrical energy in this generator, you will need to have changing flux flow through the fin coils. This change in flux flow can occur in two ways. It can occur in the amount of flux increasing through the coils or the amount of flux leaving the coil assemblies. This is done in the generator in one of two ways. The first way is to frequently cycle the power in the coil from producing a repulsive magnetic field with turning the power off to the switching coil. The second way is to frequently cycle the power in one direction to reverse the magnetic field of that of the permanent magnetics to that of powering the switching coil in the direction to support the direction of the magnets in the core assembly.
The length of the permanent magnets in the fin assembly needs to be longer than the distance of the output coils to those magnets. This is needed for proper flux rerouting between the two generator mode configurations of the generator. Some testing of this positioning will be needed to optimize this distance for the greatest electrical energy output from the generator.
Motionless Switching Magnetosphere Electric Generator Option 2 Drawing .png
The grey areas between the fin coils and permanent magnets are a metal material that allow flux to flow through easily at the same time will not hold magnetism very long once the magnetic field is removed from the metal. This will reduce the flux that moves through the air. This will cause more flux to move in and out of the fin coil assemblies. This in turn will produce more electrical output from the generator. One optional core material will likely be the better laminated core materials and design of high efficiency transformers. I have heard of a crystalline material that is being used in some applications. The core design will have a lot to do with the most efficient frequency to operate the generator at. The shape and routing of the core materials will have a lot of influence of the flux that is rerouted between the two operational modes of the generator. The object of the added core material is to have the largest flux flowing into and out of the output coils. The more this is achieved, the more energy is available for electrical power generation. Testing and optimizing the performance of one fin assembly through the common core assembly will prove valuable before building and assembling all 16 fins into the generator.
Motionless Switching Magnetosphere Electric Generator Drawing Option 3 .png
The core could have coils in it to generate electrical power from the rerouting of flux pathing as the electromagnet changes state during the generator operation. The biggest caution of doing this is that you do not want to take too much flux switching away from the fin coils. It would be best to evaluate the generator without the core pickup coils and then cautiously bring in the coils into the core area making sure that this design change adds to the power output of the generator.
Motionless Switching Magnetosphere Electric Generator Option 3 Drawing .png
Figure six is an option that uses several of the optional addons to the generator all added at the same time.
Lunkster
Switching the flux flow of 128 permanent magnets or more by powering one electromagnet
This invention is the greatest new technology I know of in theory because it produces a lot more electrical energy than it needs to operate it. It does this by creating a smaller flux flow in one coil through electrical stimulation to control the Flux rerouting of several other permanent magnets in the generator. This rerouting of flux from several permanent magnets is routed through adjacent coils to each of these magnets. The flux rerouting through all of these coils in the generator are used to generate electrical energy. The electrical energy it takes to control the switching coil is a lot less than the electrical energy that is generated from the accumulation of all of the output coils in this generator.
Let’s go through each word of the generator to give you an introduction to this new technology.
Motionless: There are no physical moving parts in this generator. There are several moving flux paths in this generator, but that movement does not cause physical wear on the components of the generator. The maintenance of this generator will be minimal. Fuses can be added into the generator to protect the hardware of this generator.
Magnetosphere: The generator operates like one large magnetosphere in one mode and several magnetospheres in the second mode. The two different modes each has different flux routes from each of the magnets in the generator. This is unique from any other generator that I have seen.
Switching: The Switching is done by one coil by alternating the operation of the generator between the two magnetosphere modes. Mode one is operating with all the permanent magnets in the generator operating collectively in one magnetosphere. The flux goes from magnet to magnet in this mode. Mode two is each permanent magnet operating with the closest coil to it to form individual magnetospheres in the generator. Each coil adjacent to a permanent magnet provides an easy flux return path for each magnet, creating several smaller self-sustaining magnetospheres in the generator.
Electric: The world is changing into an all-electrical energy world. So having a generator that does not need external power to operate it is the best invention in today’s world that will help the world to move from having the need to use up its fossil fuels. This is an open energy system because it harvests energy using the permanent magnets to move flux into and out of several output coils in the generator.
Generator: Having this generator that produces free electrical energy will reduce the need to quickly change the technology of less efficient electrical devices. This is because all you need to do is to build a bigger generator to operate them.
Note: Now over the long run, you will want to build more efficient devices like electric motors so that you do not have to purchase the higher power generators. This will reduce the consumer cost in the overall cost of their living expenses. So, the best approach is to develop the generator first, then the other devices I have written about in my other books.
Motionless Switching Magnetosphere Electric Generator Drawing .png
Figure one shows one example of what the Motionless Switching Magnetosphere Electric Generator looks like. Here the generator is built up with 16 fin assemblies all sharing the same core assembly. All of these put together form a magnetosphere. I call it a magnetosphere because the magnetic flux moves around and through this generator like a magnetosphere. Each fin has 8 permanent magnets colored in red and blue to show their polarity. The red color is the north pole of the magnet and blue to represents the south pole of the magnet. The fins also have 8 coils in them. The light green color is the core of the coil, and the dark green is the wire around the core material. These coils are used as output coils in this generator. The first drawing has the output coils in grey because no flux is in them at this point of the generator’s operation.
The generator has one core that is shared with all the fin assemblies. The permanent magnets and the coil being operated like an electromagnet are larger in the core assembly to handle the sum of flux through them from the 16 fin assemblies.
Motionless Switching Magnetosphere Electric Generator Drawing Config 2 .png
Figure two shows one of the two configurations for this generator. The Coil or Electromagnet in the middle of the generator controls the two modes of the generator. When the switching coil does not have any power going through it, then the flux in the core will move from one permanent magnet to another one. Then it moves through the core of the switching coil. Then through the other side of the generator’s core through the other permanent magnets of the core assembly. Then the flux flows through each of the fin assemblies to the other side of the core again in order to complete one large ring of travel for each fin assembly. It keeps repeating this loop over and over again. If the current through the coil is in one direction, then it will produce a flux in it that supports the flux flow through the permanent magnets and the core of the coil of the magnetosphere. When either of these two coil conditions occurs then the magnetosphere is active of having one large flux ring through each fin assembly moving through the common sphere core assembly. This condition will keep most of the flux movement away from the fin coil assemblies. If the magnetosphere stays in this condition, then no electrical energy will be generated. Electrical energy is generated when a magnetic field is moving into or out of the output coils. Therefore, we need a second condition for the generator to go into, so that changing flux pathing can occur. The second generator configuration is shown in the next drawing. The length of the permanent magnet needs to be longer than the distance from one permanent magnet to the next permanent magnet. If it is not, then there will be a lot of flux returning to the other side of the individual magnet because it is a better route than going to the next permanent magnet in the fin assembly.
Motionless Switching Magnetosphere Electric Generator Drawing Config 1 .png
Figure 3 shows the second condition of the generator. The coil is used like an electromagnet in the core assembly. It is powered to produce a magnetic field that opposes the permanent magnets in the core assembly. This action will stop continual flux flow through the core assembly. This action destroys the generator from operating as one large magnetosphere. When this happens, the permanent magnets seek the next easy path to move its flux. This path for each of the magnets in the fin assemblies become the coils that are parallel with them. These coils have cores in them. Flux moves easier through core material, so most of the flux will now flow through the coils rather than the air pathways. Now if the coil in the core assembly stays in this state, the flux will be constant in this state.
To generate electrical energy in this generator, you will need to have changing flux flow through the fin coils. This change in flux flow can occur in two ways. It can occur in the amount of flux increasing through the coils or the amount of flux leaving the coil assemblies. This is done in the generator in one of two ways. The first way is to frequently cycle the power in the coil from producing a repulsive magnetic field with turning the power off to the switching coil. The second way is to frequently cycle the power in one direction to reverse the magnetic field of that of the permanent magnetics to that of powering the switching coil in the direction to support the direction of the magnets in the core assembly.
The length of the permanent magnets in the fin assembly needs to be longer than the distance of the output coils to those magnets. This is needed for proper flux rerouting between the two generator mode configurations of the generator. Some testing of this positioning will be needed to optimize this distance for the greatest electrical energy output from the generator.
Motionless Switching Magnetosphere Electric Generator Option 2 Drawing .png
The grey areas between the fin coils and permanent magnets are a metal material that allow flux to flow through easily at the same time will not hold magnetism very long once the magnetic field is removed from the metal. This will reduce the flux that moves through the air. This will cause more flux to move in and out of the fin coil assemblies. This in turn will produce more electrical output from the generator. One optional core material will likely be the better laminated core materials and design of high efficiency transformers. I have heard of a crystalline material that is being used in some applications. The core design will have a lot to do with the most efficient frequency to operate the generator at. The shape and routing of the core materials will have a lot of influence of the flux that is rerouted between the two operational modes of the generator. The object of the added core material is to have the largest flux flowing into and out of the output coils. The more this is achieved, the more energy is available for electrical power generation. Testing and optimizing the performance of one fin assembly through the common core assembly will prove valuable before building and assembling all 16 fins into the generator.
Motionless Switching Magnetosphere Electric Generator Drawing Option 3 .png
The core could have coils in it to generate electrical power from the rerouting of flux pathing as the electromagnet changes state during the generator operation. The biggest caution of doing this is that you do not want to take too much flux switching away from the fin coils. It would be best to evaluate the generator without the core pickup coils and then cautiously bring in the coils into the core area making sure that this design change adds to the power output of the generator.
Motionless Switching Magnetosphere Electric Generator Option 3 Drawing .png
Figure six is an option that uses several of the optional addons to the generator all added at the same time.
Lunkster
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