JP2012125042A - Infinite power generation system rotating power generator by direct-current electric motor whose power consumption is due to protective resistance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use a direct-current electric motor as a power source of a power generator and obtain an infinite power state where a power generation amount is equal to or more the power consumption of the motor.SOLUTION: In a motor, a rotor is used as a permanent magnet to make its power consumption be 0 w. An armature by a superconduction coil is used as a stator to make the power consumption of the coil be 0 w. By connecting a protective resistance to the coil, the power consumption is due to only the power consumption of the protective resistance. By increasing the winding number of the coil, an output torque is increased. Due to a power generation system by a combination of the motor and a power generator, an infinite power (permanent rotation and self rotation) system is provided.

Description

  An infinite power generation system using a combination of a motor and a generator, a combination of a permanent magnet, or a combination of a permanent magnet and a cam.

  The conventional document JP 2000-145613 uses wind power to rotate a windmill, rotate the first generator with the power of the windmill to generate electricity, and store the electricity generated by the first generator in a storage battery. At the same time, the second generator motor is rotated, and the electric power generated by the generator is also charged to the storage battery and supplied to the second generator motor. When there is no wind, the secondary generator motor uses the power stored in the battery to rotate the second generator to generate power, and the battery is charged with the power from the second generator. The system supplies power to the motor.

  However, wind power is all the power received by the windmill, and when the motor is rotated and the second generator is rotated at the same time to generate electricity, the motor efficiency is 90% and the generator efficiency is 90%. The electric power that can be generated at 80% is 80% of the electric power supplied to the motor, resulting in a power loss of 20%. It is more efficient not to use the second generator. In addition, the second generator motor is supplied to the second generator motor while charging the battery with the electric power generated by the second generator by rotating the second generator motor with the electric power stored in the battery when there is no wind. If the motor and the electric machine are used as described above, a loss of 20% occurs. It is more efficient to supply the battery power directly to other loads.

  In the system, there is no permanent rotation (infinite power).

  As an improvement measure, the rotor has a permanent magnet, so that the power consumption of the rotor is 0 [w], and the stator is an armature with a superconducting coil, so that the specific resistance of the coil is 0 [Ω]. Assuming that the power consumption of the coil is 0 [w]. Since the superconducting coil of the stator is 0 [Ω], a short circuit accident occurs when power is supplied. In order to prevent this accident, power can be supplied in the same manner as a conventional general coil by connecting a protective resistor. The power consumption is reduced only by the power consumption for the protective resistance. For example, if the protective resistance is 0.1 [Ω] and the current is 20 [A], the power consumption will be 40 [w]. Even if the power consumption is as small as 40 [w], the coil resistance is 0 [Ω], so when the number of turns is 10,000, the strength of the magnetic field is H = NI / 2r [A / m] = 200,000 / 2r [A] / M] and a strong magnetic field can be generated. According to the conventional idea, in order to generate a strong magnetic field, a current I [A] of H = NI / 2r [A / m] is generated by using a non-resistance superconducting coil (coil resistance is 0 [ Ω], so that it becomes ∞ [A]) to strengthen the magnetic field. The strength of the magnetic field is strong even if the current I is H = NI / 2r [A / m], the number of turns is N, or the current I and the number of turns N are both increased. . A strong output torque can be obtained by using a permanent magnet having the same strength as the magnetic field of the stator. By using the DC electric motor as a power source for the generator, the amount of power generation becomes equal to or greater than the power consumption of the motor, resulting in a state of permanent rotation or infinite power.

JP 2000-145613 A JP 10-285904 A JP 2006-141189 A

  When generating electricity, carbon dioxide is generated by the thermal power generation method. Also, electronic power generation generates radioactive waste and is difficult to dispose of. .

  The present invention uses a rotor as a permanent magnet, the power consumption of the rotor as 0 [w], the stator as an electric element by a superconducting coil, and the specific resistance in the coil as 0 [Ω], thereby reducing the power consumption of the coil. Is set to 0 [w], a protective resistor (for current control) is attached in series with the coil, and a DC power supply is used as the power source, so that the induction resistance becomes 0 [Ω] and only the power consumption for the protective resistance is obtained. A DC electric motor configured to take out an output proportional to the number of turns by increasing the number of windings of the coil is a motor that can take out an output torque exceeding the power consumption. The power generation system is a combination of the motor and the generator, and the power generation system does not require an external energy supply, and is characterized by no generation of carbon dioxide or radioactive waste.

The infinite power generation system of the present invention has the following advantages.
Petroleum used in conventional generators because the motor can be rotated by the power of its own generator when the generator starts generating power by rotating the initial rotation of the motor with external power. Nuclear power is unnecessary. Moreover, since power can be generated near the consumer, power transmission equipment such as a steel tower is not necessary.

FIG. 1 is a configuration diagram of a motor and a power generation system. Example 1

  The generator is linked to the direct current electric motor of application No. 2010-271189.

The configuration and operation of Example 1 are illustrated in FIG.
Referring to FIG. 1, FIG. 1 is a diagram showing a configuration of an infinite power generator system using a combination of a DC electric motor and a generator according to the present invention.
100 is a motor. Reference numeral 100 denotes a casing, which is cylindrical and fixes internal components.
Reference numeral 101 denotes a lid at the top of the casing, which is a part of the casing. The lid 101 has a disk shape and is fixed to the housing 100, and has a circular hole for attaching a bearing at the center. The purpose is to fix the rotation shaft 300 to the center of the housing 100 in a rotatable manner.
Reference numeral 102 denotes a hole formed in the lid 101. The purpose is to keep the inside of the cooling tank at the same pressure as the atmospheric pressure. Another purpose is to draw out the lead wires of the coils in the cooling bath.
Reference numeral 103 denotes a lid at the bottom of the casing, which is a part of the casing. The lid 103 has a disc shape and is fixed to the housing, and has a circular hole for attaching a bearing at the center. The role is to fix the rotation shaft 300 to be rotatable at the center of the housing 100.
Reference numeral 300 denotes a rotating shaft, and a rotor 600 made of a permanent magnet is fixed substantially at the center of the rotating shaft 300.
Reference numeral 401 denotes a motor pulley, which is a portion of the rotating shaft 30 protruding outside from the lid 101 of the housing.
It is fixed at 0. The purpose is to transmit the rotational output of the rotary shaft 300 to the outside.
A generator pulley 402 serves to transmit the rotational force of the motor to the generator.
Reference numeral 500 denotes a bearing, which is press-fitted into a bearing hole in the center of the upper and lower lids 101 and 103 of the housing. The function reduces friction between the hole of the lid of the housing and the rotating shaft 300.
Reference numeral 600 denotes a rotor made of a permanent magnet, which is magnetized in the north and south poles. It is the shape which cut off both sides of a cylinder. A hole through which the rotary shaft 300 passes is opened at the center. Rotor 60
A rotating body having a pair of 0 and a rotating shaft 300 is housed inside the housing, and the rotating shaft 300 is fixed to the housing lids 101 and 103 via bearings 500 at the center of the housing. The function is to generate a rotational force by repulsion and attraction with the electromagnetic pole 800 of the stator.
Reference numeral 700 denotes a cooling tank that is tightly fixed to the inside of the housing 100 and has an upper portion that is in close contact with the lid 101 of the housing. The shape is a shape in which U-shaped grooves are arranged in a circle, and is integrally molded. Both the inner diameter and the outer diameter are circular, and the center overlaps the center of the housing 100.
Reference numeral 800 denotes a stator that is inserted inside the cooling tank 700 and is fixed to the casing 100 together with the cooling tank 700. The center of the stator 800 is overlapped with the center of the housing 100 together with the center of the cooling tank.
900 is a coil. A coil is a wire (conductive wire) wound several times. The material of the coil 900 is a material that causes a superconducting phenomenon near 273.15 degrees Celsius of absolute zero. High-temperature superconductivity is a material that causes a superconducting phenomenon at minus 173 degrees Celsius or less.
When the superconducting phenomenon occurs, the resistance becomes 0 [Ω], so that the wire (conductor) can be made thin.
If the wire is 0 [Ω], no power is consumed even if the coil is wound tens of thousands of turns.
Reference numeral 1000 denotes a frame for attaching the fixed sensor 1100, which has a cylindrical shape and a collar for attaching the main body. The center of the cylinder overlaps with the center of the rotation shaft 300. The frame 1000 is attached to the lid 103 at the lower part of the housing so that it can be rotated clockwise or counterclockwise within 40 degrees about the shaft 300. The function is to support the fixed sensor and adjust the rotation speed.
Reference numeral 1100 denotes a fixed sensor. The fixed sensor 1100 is configured to include a light projecting unit and a light receiving unit, and sends a signal to the outside when it repeatedly receives and blocks light.
1101 to 1118 include 18 (a plurality) of each fixed sensor, and the mounting frame 1000
Are fixed at equal intervals every 20 degrees.
1200 is a rotation sensor. Disk-shaped, center is the same as the center of the rotary shaft 300, and the rotary shaft 3
It is fixed at 00, and there is a cut on the outer periphery (the inner arc cut at an angle of 23 degrees is smaller than the tip of the fixed sensor), and the rotary shaft 300 passes through the center. Rotation sensor 120
When 0 rotates in the clockwise direction, the leading portion of the cut is fixed to the rotating shaft 300 so as to overlap the center line of the rotor 600.
Reference numeral 1300 denotes a control box. It is installed outside the motor. The (+) pole and the (-) pole are output to the connection point of the coil determined by the signal output when the fixed sensor detects the cut portion of the rotation sensor 1200. The circuit accommodates a circuit that rectifies input power, a circuit that converts the input power into a light for control, and a circuit that sends power to a coil that matches the rotational position of the rotor 600.
Reference numeral 1400 denotes a generator.
Reference numeral 1401 denotes a load other than the power generation system.
Reference numeral 1500 denotes a driving belt that connects the motor and the generator and transmits the rotational force of the motor to the generator.

The description about the infinite motive power generation system by the combination of the DC electric motor and generator of this invention.
The direct current electric motor which is a power source of the infinite power system of the present invention uses a permanent magnet for the rotor and a superconducting coil for the stator, thereby reducing the power consumption of the rotor and the stator to 0 [ w]. Since the resistance of the coil where the superconducting phenomenon occurs is 0 [Ω], a short circuit accident will occur if the power supply is connected. To prevent this accident, attach a protective resistor in series with the coil. For example, if the protective resistance is 0.1 [Ω] and the current is 20 [A], E = I * R = 20 [A] × 0.1 [Ω] = 2 [v] according to Ohm's law. The power is P = E * I = 2 [v] × 20 [A] = 40 [w], and the power consumption of this motor is 40 [w]. Since the resistance of a superconducting wire is 0 [Ω], the resistance is 0 [Ω] even if the constant length of the wire is almost infinite. In addition, the number of turns of the coil can be greatly increased by setting the wire cross-sectional area to the minimum diameter that can be applied. Since the magnetic strength is H = NI / 2r, the magnetic strength increases as the number of turns N increases. The conventional idea for the superconducting coil is that the coil resistance is 0 [Ω] from H = NI / 2r, so that the current can flow to ∞. When the current (I) flows to ∞, the magnetic field increases to ∞. However, H = NI / 2r This formula says that if the number of turns (N) is increased to ∞, the magnetic field will also increase to ∞. From this, for example, even if the power consumption is 40 [w] for the protective resistance, it is possible to make the motor have the same output torque as the 50 [kw] motor of the conventional output calculation method. If the generator is used to rotate the generator (power generation efficiency 90%), 90% of the motor output torque can be generated. The amount of power generation is 45 [kW]. Since the power consumption of the motor is 40 [w], the amount of power that can be used externally is minus 40 [w], and 44.96 [kw] can be supplied to the outside. If the amount of power generation exceeds the power consumption of the generator motor, self-rotation (infinite power, permanent rotation) is possible.

The configuration and operation of Example 2 are illustrated in FIG.
Example 2 is a case where the rotor of the DC electric motor, which is the power source of the infinite power system of the present invention, is a permanent magnet, and the stator coil is not a superconducting wire. The wire (conductive wire) used for the coil is a commercially available wire (conductive wire) that does not cause superconductivity, such as polyester copper wire (PEW). It is the protective resistance to prevent short circuit accidents when voltage is applied to leave the specific resistance in the conductor. To reduce the specific resistance, increase the cross section of the wire. For example, if the coil has a diameter of 10 cm and the wire cross-sectional area is doubled, the electrical resistance will not change even if the constant length is doubled. If the coil wire is replaced with a coil with a diameter of 10 cm, the number of turns will double. When the number of turns of the coil is doubled, the magnetic field strength is doubled from H = NI / 2r. When the strength of the magnetic field is doubled, the output torque is also doubled. According to the above explanation, if the specific resistance (protection resistance) is constant and the voltage used is the same, the power consumption is also constant. The output torque increases in proportion to the number of windings by increasing the number of windings by increasing the cross-sectional area of the wire (conductor) and increasing the constant length. It is an infinite motive power generation system using a DC electric motor with a protective resistance (specific resistance) with a current value of 25 [A] / square millimeter or less as a power source.

Provision of systems to power plants. Providing systems for private generators.

100 is a motor.
101 is a lid at the top of the housing.
102 is a hole formed in the lid 101.
Reference numeral 103 denotes a lid at the bottom of the housing.
300 is a rotating shaft.
401 is a motor pulley.
Reference numeral 402 denotes a generator pulley.
500 is a bearing.
600 is a rotor made of permanent magnets.
700 is a cooling tank.
800 is a stator.
900 is a coil.
1000 is a frame for mounting a fixed sensor.
1100 is a fixed sensor.
1101 to 1118 are 18 for each fixed sensor.
1200 is a rotation sensor.
1300 is a control box.
1400 is a generator.
1401 is a load other than the power generation system.
1500 is a driving belt.

Claims (2)

A permanent magnet magnetized in the N and S poles is used as a rotor with a power consumption of 0 [w], a superconducting coil is used for the stator, and a power consumption of the stator is an armature of 0 [w]. An infinite motive power generation system using a DC electric motor as a power source, with a protective resistor attached and power consumption limited to the protective resistance.
A coil wire having an internal resistance is used, a resistance value with a current value per square millimeter of wire area of 15 [A] or less is defined as a protective resistance, power consumption is defined as a protective resistance, A permanent rotation power generation system using a DC electric motor as a power source for the generator, characterized by taking out output torque proportional to the number of turns.

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