MAGNETIC ENERGY GENERATOR
A SYMBIOSIS OF PERMANENT MAGNETS AND BIFILAR COILS
The Magnetic Generator is complex system with an organized structural arrangement of permanent magnets and bifilar coils and PCB controller with a specially designed software that are used to generate and dispense electrical energy.
Initial start is performed by a battery or any other external source of energy to help motor reach needed RPM. After that the external source can be disconnected.
The device is able to operate in autonomous mode and maintain its RPM regardless of amount of useful energy being consumed.
The main components of the generator: an integrated stator; bifilar coils (mounted inside with the same and opposite poles); rotor with shaft; permanent magnets (installed with both poles to the outside); axles and bearings.
The magnetic generator MG10 consists of 60 neodymium magnets and 60 bifilar coils. The constructional feature that enables generating electrical energy is the precise angular alignment of the coils and magnets inside the drum and the switching regulations to suppress back EMF and effectively collect accumulated energy inside the electromagnets (coils). As a magnet starts approaching a coil, at a certain point the voltage of the coil increases along with the amount of charge it can transfer. Once the switching regulator detects the maximum voltage of the coil, it switches off the coil. The magnetic field of the coil that has been formed after excitation of the coil will tend to collapse generating a back EMF in the coil windings.
The designed software of the generator is able to suppress the parasitic current and transform it into usable electrical energy that can be utilized by the end user.
The drum of the Magnetic Generator consists of a rotor with neodymium rear-earth permanent magnets and a stator with copper-wired bifilar coils.
Permanent magnets are uniformly situated along the circumference of the rotor with the same-name and opposite polar poles. Bifilar coils are situated along the circumference of the stator in the same way but with a precise angular alignment to the magnets and parallel-serial connection to each other.
A neodymium magnet is the strongest type of permanent magnet commercially available today. Crystal structure of the neodymium magnet is composed of microcrystalline grains that are aligned in a powerful magnetic field during manufacture so their magnetic axes all point in the same direction. The crystal lattice of the magnet resists to turning its direction of magnetization which makes this compound highly coercive to demagnetize.
A bifilar coil is an electromagnetic coil that contains two closely spaced parallel windings and a series connection counter coil. In order to properly increase the coil power, its turns are wound in such a way to provide the greatest potential difference between adjacent turns or spirals. The energy stored in the coil is proportional to the square of the potential difference between adjacent turns. Due to the special material of the coil’s core (transformer steel), capacity for a set value of the potential difference between turns has been significantly enhanced.
The Magnetic Generator operates and is able to generate power due to interaction of permanent magnets with bifilar coils and an emerging electromagnetic force between them. The magnets and coils are directed towards each other to create torque on the rotor. This composition of the drum of the generator is designed in order for rotor to rotate indefinitely as long as energy of interaction between permanent magnets and bifilar coils is collected and dispensed rationally and effectively.
|INFINITY MG10||INFINITY MG5|
|Control system consumption||50W||50W|
|Motor consumption||Idle – 200W, full load – 3KW||Idle – 200W, full load – 1.5KW|
|Generated voltage||900 AC||900 AC|
|Effective power output||10KW||5KW|
|Effective frequency output||50/60Hz||50/60Hz|
|Effective voltage output||110V / 1 phase / 100A
220-230V / 1 phase / 50A
220-230V / 3 phase / 16A
380-440V / 3 phase / 16A
|110V / 1 phase / 50A
220-230V / 1 phase / 25A
220-230V / 3 phase / 8A
380-440V / 3 phase / 8A
|Motor rotation||1500 rpm||1500 rpm|
|Weight||80 kg||60 kg|
|Operation temperature range||-40°C ~ 70°C||-40°C ~ 70°C|
|Recommended retail price||$15,000*||$8,000*|
* This is an estimate that does not include VAT, import tax, delivery and installation fees, etc. Distributors will determine exact retail price according to their country’s laws.
Special installation is provided by your distributor
POWER TO TIME RATIO AT THE START OF THE GENERATOR
Connection (GPS navigation system)
The Magnetic Generator is equipped with a built-in GPS navigation system that is used for geographical positioning of the device. The system includes an external antenna for outside installation if the device is used underground or deep inside a building. The main function of the GPS navigation system is to locate and tie-in the device to its territory (country) in which it has been originally distributed and installed. It means that the device will operate only if the GPS navigation system is on (online) and if it is located within the authorized territory (country). In case if the GPS navigation system is off or the server cannot locate the device, the generator will automatically shut down and could not be used.
Connection (GSM, CDMA, WiFi system)
The Magnetic Generator is equipped with a GSM/CDMA/WiFi transmitter that is used for transceiving information about operational modes and condition of the device. The built-in software facilitates fastest and high-quality control over the device. Every unit has its unique individual serial number which provides this information when the server sends an enquiry signal to the transmitter. The following information can be obtained remotely:
– Generated and consumed power for a certain time period (day, week, month, etc.)
– Total operation hours of the device
– Reactive and inductive load history for a certain time period (day, week, month, etc.)
– Current operational temperature inside the device
– Noise generation of the bearings
– Effective power output values:
– Amperage (A)
– Voltage (V)
– Frequency (Hz)
– Load (inductive and reactive)
– Current (Cos Phi)
The system also has a timer function which allows to set on/off time of the generator if the demand for electricity varies throughout the day. In order to prolong lifecycle of the generator, an end user can set a limit of power generation according to their demand.
The transmitter operates just like any other remote device so the buyer can use any available network purchased from a local network provider in case if WiFi connection isn’t available.
The generator can be monitored and controlled both from a PC and a smartphone. The tremendous functionality of the software allows you to monitor the graphically represented overall process of operation with an incredible accuracy. With a single press of a button you will be offered a variety of options to change or correct operational modes of the generator, for example, its generating power. In case of a breakage or malfunction a problem can be solved remotely as the system will identify and display the problem to the user. All software upgrades of the device will be done easily and remotely just like updating software on your smartphone.
In case if larger power output is required, the generator can be connected to and synchronized with another device to produce total net power of up to 1MW. This is possible thanks to the CAN interface and special software of the device.
Each device sold within an authorized territory (country) will meet local national grid standards to main electricity, voltage, utility frequency, plug type, etc.
Available frequency: 50Hz / 60Hz
Available voltage: 110V / 120V / 220-230V / 380V / / 440V
Available plug types: NEMA 1–15 U.S. 2 pin, NEMA 5–15 U.S. 3 pin / CEE 7/16 Europlug, BS 546 5 A / BS1363 UK / SI 32 Israel / Australian AS/NZS 3112), SEV-1011 Switzerland, SRAF 1962/DB Denmark, CEI 23-50, 15 A BS 546, Brazilian NBR 14136, Thai TIS 166-2549
If the device is used in residential or recreational areas where certain level of noise must be met, the device can be covered with a special noise cancelling material which reduces noise generation of the device down to 30dB.
Start of the device is performed by a standard 12V replaceable battery (car battery) that will be automatically recharged after each launch of the generator.
Generator is capable to operate at 24/7 capacity. If the generator produces more electricity than is necessary for the consumer, external battery charge is possible. The energy in the batteries will be required in case if electricity needs exceed total capacity of generator, for example, during peak hours.
All other individual suggestions for improving features of the generator will be considered if requested. Each device can be custom made to fulfil any demands of the client.
RPM control sensor
The BLDC motor of the Magnetic Generator is designed to withstand various loads and maintain its RPM regardless of external conditions. It has a build-in RPM control sensor that is used to monitor rotation of the motor shaft and prevent it from deviating from the operational limits (± 5rpm from default). Maintaining RPM is crucial for the system to operate within necessary voltage generating limits as even slight deviation from the set limits will result in failure and burnout of the PCB components. The drum of the generator is driven by the BLDC motor through pulse-width modulation of the software driver in accordance with a specified algorithm. In case of an error of the processing algorithm and deviation from the rotation limits, the RPM control sensor will automatically shut down the whole system as it is an autonomous apparatus and is independent from the algorithm. The generator’s display will present the error and provide solution for it.
There are several temperature sensors installed inside the Magnetic Generator. Each sensor is used to measure ambient temperature around generator’s windings and coolant of the device. The generator emits heat insignificantly but truly, that is why it is equipped with a forced cooling system to deliver the generated heat from internal components to the radiator at the back of the device. Once one of the sensors detect rise of temperature the cooling system will circulate coolant through the ductwork and run the radiator fan to dispose it outside. In case if temperature of any of the components keeps rising the correspondent sensor will shut down the device and the generator’s display will present an error.
Bearing noise sensors
Annual maintenance of the generator is most of all depends on lifecycle of its bearings and other moving components. Being the main source of frictional forces between the motor and its shaft it is crucial that bearings are always greased or replaced when needed. In order to perform maintenance at the right moment, bearing noise sensors are used to detect any significant noise or vibration level deviation from the recommended by the manufacturer limits. When life of a bearing comes to an end or it needs additional grease the sensors will display a message of an upcoming maintenance to the user. If noise generation exceeds maximum limit the sensors will shut down the device to prevent other moving components from damage.
Unauthorized access sensors
The Magnetic Generator is physically protected from an unauthorized access by various methods, one of which is detection of the external case opening. Each side of the generator is equipped with several motion detection sensors which serve to prevent people from opening the device. In case if one of the sensors detects the opening it will automatically shut down the device and will not let it start until an authorized person activates it.
ADVANTAGES AND COMPARISON
EFFICIENCY RATE (kWh/year)
10kWh magnetic generator MG10
10kWh solar panel set
|$15,000 USD||$10,000–$15,000 USD|
|Garage, underground, rooftop||Number of panels up to 40. Installation on roof/land is required|
|0.6 m²||up to 65 m²|
|up to 2 years||up to 5 years|
Lifespan 20 years.
Completely independent from all environmental factors
|Solar system generates 44 units per day. However, how much power 10kW system generates depends on two key factors – your geographic location and the orientation and tilt angle of your solar panel array. It generates more power in summer than in winter, and sunnier locations yield better results than those experiencing higher cloud levels. In average 6,5 hours at daylight, at night time it doesn’t work. Panels will never run at 100% efficiency. Shading or dirt on just one of the cells in a solar panel causes a loss of power from many cells, not just the one that is covered.|
LIFESPAN AND DEGRADATION RATE
MAGNETIC GENERATOR MG10
In the absence of external influences, neodymium magnets remain magnetic for hundreds of years. Demagnetization of generator’s magnets is extremely small if the device is used properly with a rate of 1% every 10 years. If maintenance is performed regularly and duly, the generator may serve indefinitely longer than its 20 year lifespan.
SOLAR PANEL SET 10KW
Photovoltaic (PV) modules of solar panels manufactured today offer a much longer lifespan of 20 years of use. However, degradation of crystalline silicon modules located in extreme climates (heavy wind, snow load, high levels of UV exposure) exhibits high rates of approximately 1% per year which leads to 20% of efficiency loss at the end of solar panel lifespan.
(average US, EU household consumption)
MAGNETIC GENERATOR MG10
Electricity price: 1kW = $0.2 (EU average)
Total consumption: 10,000kW
Annual savings: 10,000 x 0.2 = $2,000
Selling remaining electricity back to the grid:
77,360 x 0.1 = $7,736
(1kW = $0,1 (EU average NEM tariff)
Payback: 15,000 / (2,000 + 7,736) = 1,5 years
SOLAR PANEL SET 10KW
Electricity price: 1kW = $0.2 (EU average)
Total consumption: 9,000kW
Annual savings: 9,000 x 0.2 = $1,800
Selling remaining electricity back to the grid: $0
Payback: 15,000/1,800 = 8,3 years
CONNECTION DIAGRAM OPTIONS
This option enables direct connection of the generator to the three-phase relay of the central electrical service panel. This connection type can be used to provide electricity for a house, apartment, office or industrial building as a main power supply or a standby power supply.
Low energy consumption:
During the night the house consumes a normal amount of energy, usually the load of the generator is small. The magnetic generator is able to provide the necessary amount of energy for entire house with. Non-consumable load for the house can be accumulated by batteries, charging them, which are connected to the generator.
This option allows to store generated energy in batteries that can be consumed at later hours when demand is 2-3 times higher from the nominal capacity of the generator.
High energy consumption:
When a lot of devices are used in the house and the energy consumption increases, so the magnetic generator starts working at full load, the batteries that have accumulated charge during low electricity consumption turn on and this system powers the house.
This connection type serves best bigger families when at certain rush hours (morning, evening) demand for energy is much greater than at regular hours. This method is also beneficial for prolonging life cycle of the device as at full charge of batteries the generator can go to standby mode until batteries are discharged.
This option is intended for a combined electricity consumption through a grid tied inverter.
At night, when the house consumes a normal amount of energy, usually the load is small. The magnetic generator is able to provide the house with the necessary amount of energy. The non-consumable load for the house can be given to the National Network. The energy supplied back to the Network through the grid tied inverter can be exchanged for monetary compensation in some countries.
It allows the end user to utilize energy from the grid when generator’s energy insufficient and return surplus of unused energy from the generator back to the grid.
Each installation is controlled by a control unit with special software that provides synchronization of several generators. All generators are connected and synchronized via CAN cable.
The software simultaneously monitors the network load and the load of a group of generators, and also allows synchronizing the frequency wave for the current sine and summing up the power of 2 or more devices connected in this way with a total net output of up to 1MW.
Operation algorithm: the control unit monitors the required load of the consumer and sends a signal to start additional generators. Installations are synchronized and power generation begins depending on the needs of the load. Installations adapt to the load, can be started and stopped depending on changes in demand.
In this option, it is possible to apply a grid inverter to return non-consumed energy by the consumer to the National Network.
Schemes of connection
Connection with grid inverter
Connection with Batteries
Connection of several MG
Research & Development
Our invention consists of two parts; an electric motor and white magnetic generator. The motor is used to run the magnetic generator up to 1500 RPM and then motor is disconnected from the power.
After the motor is disconnected from the power, the magnetic generator produces all the energy and powers the electric motor, lights, a space heater etc.
The magnetic generator has coils of bifilar of copper wire in the stator and neodymium magnets in the rotor inside. When a magnet approaches a coil of copper wire, it induces a like polarity in the coil.
For example: A magnets North pole will induce a North polarity in the coil and North repels North and that creates the motive force for the generator. This is known as the Lorentz Force. Permanent Magnets are Permanent: Permanent magnets only lose 1% of their power in 10 years.
The generator is powered by permanent magnets and coils of copper wire using the Lorentz force. When a magnet approaches a coil of copper wire, it induces a like polarity in the coil (North induces North and North repels North). This repulsive force causes the generator rotor to spin and create electricity.
Physicists have no theory to explain where the energy that creates electron spin in permanent magnets comes from. Unexplained observations absolutely always precede theory.