RU2368057C1 - Method of generating electrical energy using electromechanically actuated contra-rotating generator and device to this end - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electrical engineering and is meant for generating electrical energy using an electromechanically actuated contra-rotating generator. A rotor and the contra-rotating generator are connected by two oppositely rotating disc rotors larger than the radius of a high-speed linear motor. Two oppositely rotating steps in form of double blocks are formed, lying coaxially and with a common axis of rotation. The inductor of the high-speed linear motor is immovably attached to the housing of the device and transmits counterrotation with angular acceleration to secondary elements through steps. As a result of this opposite rotation, two velocities and two moments are combined. The method is safe and cheap. The device is distinguished by high reliability, high power at low weight, low price, easier manufacture and operation.

EFFECT: increased power and efficiency.

2 cl, 1 dwg

Description

The invention relates to the field of electrical engineering and is intended to produce electricity in a fuel-free, harmless and economical way.

Closest to the invention is a method of generating electricity by a counter-rotor unit, proposed by M. Kasparov. and Simonov V.V. in 1950, consisting in the fact that the rotor and the counter-rotor (stator) of the generator are rotated by a coaxial hydraulic turbine in different directions, while a higher rotor speed relative to the counter-rotor is achieved, which allows to increase power, reduce the number of generator poles, therefore its dimensions and weight (Simonov VV Direct-flow turbines of high and ultra-high speed. M.-L.: Gosenergoizdat, 1951).

The disadvantage of this method is that in the manufacture of the unit for its implementation requires a high level of calculation of the profiles of the blades of the turbine, their optimal spatial location between the working blades of the rotating stages and the presence of a powerful water stream.

The problem to which the invention is directed, is to simplify and reduce the cost of the method of generating electricity by a counter-rotor generator.

The technical result is a high coefficient of performance.

The specified technical result is achieved in that the rotation of the rotor and the counter-rotor towards each other is carried out by connecting the latter with a high-speed linear motor with two large-diameter counter-rotating disk rotors, and as a result of this counter-rotation, two angular velocities and two angular forces reinforced by double blocks are added, which leads to power gains and increased efficiency.

The drawing shows a structural diagram of a device that implements this method, with a horizontal (possible options with a vertical) arrangement of the axis of rotation.

The proposed device is an open inertial-torsion, electromechanical system of two counter-rotating stages with an inertial reference system, consists of a coaxial counter-rotor generator 1 with a counter-rotor 2 and rotor 3, from a high-speed linear motor with an inductor 6 and with two counter-rotating disk rotors 4 and 5 of a large the diameter, along the edge of the circle of which the secondary elements 7 and 8 are fixed perpendicular to it, while the hub 9 of the disk rotor 4 is attached to the flange of the shaft of the rotor 3, forming a per the second rotation stage in the form of a double block of a disk rotor 4 with a radius Rn and a rotor 3 with a radius R, where Rn is n times larger than R, located on the same shaft with sliding on bearings 11, and the hub 10 of the disk rotor 5 is attached to the body of the counter-rotor 2 , forming the second stage of rotation from the disk rotor 5 and the counter-rotor 2 in the form of another double block with a difference of radii also n times located coaxial to the shaft of the rotor 3 with sliding bearings 12, also consists of an electronic control unit (not shown) and a system forced cooled an inductor with channels for circulation of a cooler (not shown). The inductor 6 and the housing of the device (not shown) combine the components of this design into a single mechanism.

The method of producing electric energy in this way is that the counter-rotor generator 1 is rotated by connecting it to a high-speed linear motor with two large-diameter counter-rotating disk rotors 4 and 5, in the inductor 6 of which the generated electricity is divided into two parts, each of which form a mechanical force and distributed between the two secondary elements 7 and 8, which, under the action of the applied forces, do the work, giving angular acceleration to two anti-rotating stupas Thus, they are double blocks, thus amplifying and supplying both parts of the mechanical energy to the generator 1, where they are combined again, as a result of which the two moments of forces and two angular velocities are added together, while the power of the incoming energy is converted, which is converted into electrical energy, sent to the consumer and do it as follows.

When the inductor 6 of the linear motor is connected to an alternating current main, two magnetic fields are formed in it, which move in the longitudinal halves of the magnetic circuit in different directions at a certain speed and induce currents in the secondary elements 7 and 8. As a result of the interaction of the magnetic fields and the currents induced by them, electromagnetic forces under the action of which the secondary elements 7 and 8 begin to shift relative to the motionlessly fixed inductor 6 in opposite directions with a speed equal to the speed moved I have a magnetic field along the magnetic circuit. The mechanical traction forces created by the secondary elements 7 and 8 are equal to the electromagnetic forces acting on them and are distributed equally between the secondary elements,

F _EM1 = F ₁ ; F _EM2 = F ₂ ; F ₁ = F ₂ . Closed into rings, the secondary elements 7 and 8 convert their linear displacements into rotational movements of the disk rotors 4 and 5 to which they are attached. The force takes the definition of the moment of force, and the speed becomes angular velocity. Under the influence of these moments, the counter-rotating steps of the device acquire angular acceleration. The use of a double block device in operation allows you to locate the point of application of the acting force on a block of large radius, thereby increasing the moment of force and angular acceleration of the rotating stage, and placing the working body of the mechanism on the block of small radius, reduce the moment of reaction and the moment of inertia. The moment of force acting on one disk rotor at point A of a block of large radius will be M ₁ = FRn, and at point B of a block of small radius will be M = FnR, M ₁ = M. Now we apply the force of equal magnitude at point B and trace the reverse order of action. The moment of opposing force on one disk rotor at point B of the block of small radius will be M _EM = FR, and at point A on the block of large radius will be M _EM1 = FR / n. The rule of equal moments of the large and small blocks is satisfied only if the force is applied from the side of the block with a large radius, if on the contrary, this rule does not work. The value of M is greater than M _{EM by} n times, and M _{EM is} greater than M _{EM1 by} n times, this proves that the double block n times increases the moment of action and n times decreases the moment of reaction force. If the double block rotates with acceleration, then the “golden rule” (equilibrium rule) does not work. Subject to this condition, this device, consisting of two double blocks, performs the work of rotating the rotor 3 and the counter-rotor 2, and the sum of these works allows the generator to convert the incoming mechanical energy into electrical energy. Counter rotation allows the field windings and the armature to intersect twice in one revolution, which doubles the frequency of formation of the electromotive force, and the resulting field created by the combined actions of the armature currents and the field windings will remain stationary. Therefore, in the generator, two angular velocities ω + ω = 2ω and two moments reinforced by double blocks are added, n M + n M = 2n M, and the product of these indicators gives a definition of the power received by the generator,

2n М 2ω = 4n Мω = 4n Р = Р _ОГ . From this power, the power of the total _GHG losses R that is inevitable during the conversion is subtracted, and the remaining part is the useful power R of the _EG generator. R _OG- R _PG = R _EG .

Supply and removal of voltage from the generator windings is carried out using slip rings and slip rings (not shown in the diagram).

The electronic control unit monitors the performance of the internal and external circuits of the device, regulates and stabilizes the parameters, includes, if necessary, protection against short circuit and overload, converts the frequency to the required value to obtain a certain speed of the secondary elements, switches the power of the inductor from an external source to stand-alone mode and vice versa.

The cooling of the linear motor inductor is carried out depending on the purpose and operating conditions. If the device is used on vehicles, blow air is used. When the device is operating at rated loads, heat is removed by blowing fans. For devices operating at near-limit loads and in poorly ventilated spaces, the best effect is achieved when using liquid gas circulating through the channels inside the magnetic circuit.

Closest to the proposed device is an electromechanical drive, consisting of a generator and two high-speed linear motors with large-diameter disk rotors, mounted with the possibility of rotation towards each other to rotate two working bodies of one mechanism, and two-sided inductors of high-speed linear motors are fixed motionless in the case opposite to each other friend, while the hub of one disk rotor has a spline connection with the generator shaft, and the hub of another disk mouth Dr. planted on the generator shaft without any fixation (RU 2301489 C2, on June 20, 2007, BI number 17).

The disadvantage of this drive is that it consists of two high-speed linear motors with two inductors, since similar work can be performed by one inductor, the second inductor is additional materials, extra weight. The disadvantage is that the secondary elements located on the plane of the disk rotors do not allow you to use all the potential of a large circle due to the fact that the point of application of the acting force is located at a certain distance from the edge of the circle, and this reduces the moment of force. Flywheels located on disk rotors are also considered a disadvantage because they increase the moment of inertia and reduce angular acceleration.

In the proposed device, these shortcomings are absent. It consists of a coaxial counter-rotor generator 1 with an elongated strong shaft of the rotor 3, on which a core with an anchor winding, a blower fan, slip rings and a flange are rigidly fixed, there are two bearings 11 for rotating the shaft itself and the entire anti-rotation system in the device body and two bearings 12 for coaxial rotation of the counter-rotor 2 along it, to the casing of which the core with the field winding, an exhaust fan and slip rings are rigidly fixed, the casing has windows for the flow of ventilated air; from a high-speed linear motor with two disk rotors of large radius 4 and 5, made of composite materials for devices of small and medium power and welded, metal for devices of high power, on which secondary elements 7 and 8 of aluminum are fixed at the edge of the circles, perpendicular to them tires in the form of shells, the hub 9 of the disk rotor 4 is bolted to the flange of the shaft of the rotor 3, and the hub 10 of the disk rotor 5 is bolted to the housing of the counter-rotor 2, thus forming two counter-rotating steps in the form of double blocks, and in the immediate vicinity of the secondary elements, with a minimum air gap, a single-sided inductor 6 in the form of a segment, the magnetic circuit of which consists of two longitudinal cores, with an antiferrite gasket between them, and with a common winding laid special way; from an electronic control unit including a unit for starting and stopping the device, a unit for monitoring and automatically adjusting the parameters of the incoming and generated electricity, a thyristor frequency converter unit, a short circuit protection unit for internal and external circuits, as well as a switch and connection unit; from a forced induction cooling system including a fan with an air duct and a radiator with a pump for circulating a liquid cooler through special channels inside the magnetic circuit.

The device can operate continuously for a long time, stopping is necessary for prevention and for replacing brushes. It is distinguished by the simplicity of manufacture, operation and maintenance, high reliability and efficiency, low cost. But the main difference is that its efficiency is greater than one.

Set the numerical values for this device. The radii of the disk rotors are 1 m each, the radii of the rotor and counter-rotor (along the radius of the air gap of the generator) are 0.1 m, the difference in radii is 10, the length of the secondary elements is 6.28 m, the width is 0.1 m, the thickness is 0.005 m, the inductor receives a three-phase current with a voltage of 380 V, a frequency of 1308 Hz from the electronic unit, has a pole division of 0.06 m, provides a speed of movement of secondary elements in opposite directions at 157 m / s or 565.2 km / h, creates a pulling force per square centimeter of the active surface of the inductor 0.2 N, and 500 square centimeters - 100 N, having spent 15700 W of usable power, and taking into account losses during conversion with an efficiency of 0.6 of the inductor, there will be 26166 W of total electric power, the force acting on one disk rotor is 50 N, and the moment of force on the generator rotor it will be 10 times larger and equal to 500 Nm, the angular velocity is 157 rad / s, the same moment of force and the same speed is given to the counter rotor by the second disk rotor, two amplified moments of forces are added in the generator and their sum is 1000 Nm and two angular velocities with the sum of 314 rad / s, their product it consumes 314,000 W of power supplied to the generator, taking into account losses at a generator efficiency of 0.95, there will be 298,300 W of useful power, the generator has one pair of poles, with a rotor and counter-rotor speed of 1,500 rpm or 25 rpm, the generator generates electricity with frequency of 50 Hz. We determine the reaction force of electromagnetic forces on the inductor of a linear motor with one secondary element. We determine the total moment of counteracting forces by dividing the total generator power of 314000 W by twice the angular velocity of 314 rad / s, and we get 1000 Nm, it is distributed between two disk rotors of 500 Nm, when transmitted to the secondary element it will decrease by 10 times and will be equal to 50 Nm , dividing by the radius of the disk rotor, we find the reaction force equal to 50 N. Received the equality of the forces of action and reaction in order to upset this balance, it will be enough to increase the power consumed by the inductor of the linear motor to 28000 W and lower the ceiling by boron generator power to 280,000 watts. In this interval, the device will operate in nominal mode. The efficiency of the device is 10. With this indicator, having received energy to start, in the future the device can provide power to its engine with its own electricity, and give the rest of the power.

Such a device will find application in all spheres of human activity and will get rid of the use of internal combustion engines, thermal and nuclear power plants.

Information sources

1. Direct-flow turbines of high and ultra-high speed. Semenov V.V. M.-L.: Gosenergoizdat, 1951

2. Elementary physics. Landsberg G.S., Volume 1.

3. Electric cars. Tokarev B.F., Energoatomizdat, 1990

4. Linear induction motors. Veselovsky O.N., Konyaev A.Yu., Sarapulov F.N., Energoatomizdat, 1991

5. RU 2301489 C2, dated June 20, 2007, BI No. 17.

Claims (2)

1. A method of generating electric energy by a counter-rotor generator, based on the counter-rotation of the rotor and the counter-rotor by a coaxial hydraulic turbine, characterized in that the counter-rotor generator is rotated by connecting it to a high-speed linear motor with two large-diameter counter-rotating disk rotors, in the inductor of which the received electricity is divided into two parts of each form a mechanical force and distributed between two secondary elements, which under the action of the attached silt do work, giving angular acceleration to two counter-rotating steps, which are double blocks, thus amplify and bring both parts of the mechanical energy to the generator, where they are combined again, as a result of which the addition of two moments of forces and two angular velocities, while increasing the power the incoming energy, which is converted into electrical energy and, at a new quantitative level, is sent to the consumer. 2. A device for generating electricity, containing a generator and two high-speed linear motors with large-diameter disk rotors mounted for rotation against each other to rotate two working bodies of one mechanism, and two-sided inductors of high-speed linear motors are fixedly mounted in the housing opposite each other, when the hub of one rotor has a spline connection to the generator shaft, and the hub of the other disk rotor is mounted on the generator shaft without any fixation characterized in that it includes a coaxial counter-rotor generator, a high-speed linear motor with an inductor fixedly mounted in the casing and with two counter-rotating large-diameter disk rotors, along the edge of the circle of which secondary elements are fixed perpendicular to it, while the hub of one disk rotor is attached to the flange of the generator shaft forming the first stage of rotation in the form of a double block of a large-radius disk rotor and a small-radius generator rotor located on the same shaft, and the second Single stage formed when attaching other disc rotor with a large radius kontrrotoru generator of small radius disposed coaxially generator shaft, the electronic control unit and a system of forced cooling of the inductor with channels for circulation of coolant.