RU2666142C1 - Method of charging batteries and device for its implementation - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to electrical engineering and can be used for charging batteries in power engineering, in particular when creating power transmission lines by means of chargers. When charging, use EMF self-inductance, which arises in closed electrical networks. Device for charging the battery is made in the form of a pulse generator of self-induction EMF with the possibility of removing from it the EMF of self-induction and structurally executed in the form of contours of primary and secondary windings of a step-up autotransformer.EFFECT: technical result consists in expanding the arsenal of funds.2 cl, 2 dwg

Description

The invention a method of charging batteries is used in the energy sector, in particular, when creating transmission lines of electricity through chargers.

The purpose of this method is to use the self-induction EMF that occurs in closed electrical networks.

Analysis of the prior art revealed the following technical solutions. Known application 2014127078, IPC Н02K 53/00 dated 02.07.2014, publ. 02/10/2016 Bull. No. 4, which describes the energy converter. It uses a method that assumes that part of the electric energy is spent on charging the battery through the charging relay (charger), and another part of the electric energy when the generator is running is used to operate the motor that rotates the generator rotor, while the electric energy is converted from the battery to excess electrical energy. However, this technical solution is not functional, since the problem of using the obtained electric energy for storage in the battery is not solved. The proposed technical solution does not take into account the energy conservation law for rotating masses. The Lenz law, according to which eddy currents in a metallic body located in a magnetic field, impede the movement of the current and slow down the body, is also not taken into account. (p. 228 Physics course, L. S. Zhdanov, V. A. Maranjyan, ed. “Science”, Moscow, 1970)

Known application 2010105326/07 of 02.16.2010, IPC Н02K 7/06, publ. 08.27.2011, “A method of converting the energy of the surrounding space into a rotation of a fuel-free engine”, according to which the motor-generator is driven by a battery, and the flywheel provides its own rotation by interacting with the energy fields of the surrounding space, and instead of the battery use an electric a capacitor, when connected to a direct current source, an electric charge is accumulated on its plates. However, when large metal masses work in a constant magnetic field, eddy currents will again appear, which prevent the flywheel from spinning.

Known Application RU 2008112129, publ. 10.10.2009, IPC H01F 17/00, “Integrated Variable Inductor Coil”, in which the coils are electromagnetically coupled, forming a closed circuit of the secondary coil, within which the secondary inductor has a variable topology, is switched in parallel to change the inductance value, output by the inductor, and the secondary inductor has a predetermined inductance. With the help of this technical solution, many inductance values are obtained, which can be derived by a multi-circuit primary inductor using a key to change the switched topology. However, they solve a different problem, namely, changing the inductance values to adjust to the powered device.

The invention is known "A device with a charging element and with a contact surface for transmitting electromagnetic energy through the contact surface to many electronic devices and method" patent RU 2 447 530, publ. 10.27.2010, IPC H01F 38/14, H01F 27/28, H01J 17/00, H01J 7/02, in which the primary winding is made as part of the resonant circuit, contains spiral elements configured to generate a complex variable magnetic field and selectively activation of this spiral element. The invention relates to a method for implementing the transfer of electromagnetic energy. However, they solve the problem of simplifying the design for transferring energy to many devices. In this case, special measures have to be taken to ensure a constant flow through the primary winding of the transformer, since the distribution of the magnetic flux over the cross section of this primary winding is not uniform for a flat spiral winding.

There are also many electric current generators in which various types of moving metal parts in a magnetic field are used, but they all have the disadvantage that they do not know how to use the Lenz law and have moving masses.

So in the invention "Electric current generator", patent RU 173750, publ. September 11, 2017, IPC Н02K 35/02, use inductors electrically connected to each other and two permanent magnets. It allows overcoming the generation of electric current using the principle of electromagnetic induction, the unwanted loss of inertia of the movable permanent magnets during their movement in the body cavity, caused by shaking and when the moving permanent magnets come closer to each other or their contact. However, these technical solutions do not use self-induction EMF.

The closest technical solution taken as a prototype is the application for the invention "Inductively - static method of generating electrical energy and a device for its implementation", application RU 2004124018, published January 27, 2006, IPC H01F 1/00, in which primary and secondary windings forming an inductor with the transition of free magnetic energy into an inductively dependent state and induce induction EMF and obtain magnetic flux densification proportional to the increase in electric power. Due to this, an increase in electrical power is proportional to the compaction. However, it also fights static and mechanical counteractions of fixed coils to ampere forces, and does not use them.

In the proposed technical solution there are no moving metal masses in a constant magnetic field, which gives a great advantage. The essence of the proposed method is that they initiate the EMF pulse of induction from the battery, and back through the positive feedback already the EMF of self-induction plus the EMF of induction, which was stored in the coil. Thus, they use EMF of self-induction - counter - EMF, which is defined in the Lenz rule. Due to this, they achieve the fact that we spend the induction emf, and return the self-induction emf to the battery.

Thus, as a solvable inventive task, in accordance with which it is required to use the emf of self-induction, charging the batteries (battery) is carried out not only by the emf of the source, but also by the generated emf of self-induction, which is many times more powerful than the emf of induction, and which used in the proposed method for its generation.

In all known technical solutions, the EMF of self-induction is always considered a negative factor, they have been fought with as a counter-EMF, and to date they have not been used at all.

Thus, the inventive task is to use pulsed voltages from the secondary winding of the pulsed EMF generator of self-induction, which would make it possible to directly take the EMF of self-induction of the emerging pulsed voltage of the EMF of self-induction in order to recover it by positive feedback through a diode rectifier back to the battery as an EMF energy source to the primary capacitor or directly into the network.

Achievable technical result is the use of dual functional purpose of the secondary winding of a pulse generator of self-induction EMF for removal and efficient use of the resulting self-induction EMF, in particular, for charging batteries.

The technical result is achieved due to the fact that the method consists in charging a battery (battery) due to the generated EMF of self-induction in a pulse generator of EMF of self-induction. The proposed method differs in that a pulse voltage is used for charging from the secondary winding of the pulse generator of self-induction EMF, the resulting pulse voltage of self-induction EMF is generated in the primary winding of the pulse generator of self-induction EMF by positive feedback from the secondary winding, and the pulse voltage of self-induction EMF plus induction EMF is removed form of DC voltage from the primary winding and sent to the primary battery, which serves as a source of energy for imp lsnogo self-induction electromotive force generator to fully charge and / or pulse voltage recovery is performed self-induced EMF and send it directly to the battery of rechargeable batteries.

Thus, the battery is charged not only due to the emf of the source (primary battery), but also due to the generated emf of self-induction, which is many times more powerful than the emf of induction, which is used to generate it.

The claimed technical result is provided due to the fact that the pulsed EMF generator of self-induction, structurally executed in the form of primary and secondary windings, is a single-phase step-up autotransformer. In a step-up autotransformer, the secondary winding is simultaneously functionally an electric conductor and a magnetic circuit. It is proposed to consider the presented method as a practical application of the known phenomena of self-induction when a circuit is closed and its circuit is opened. This method is implemented through the use of a device in which the phenomenon of self-induction, i.e. a phenomenon in which an alternating magnetic field created by a current in a circuit excites an emf of induction in the same circuit, and an electromotive force arises, which is called the emf of self-induction. At the same time, the self-induction current arising in the circuit at the moment of its opening, i.e. extracurrents of breaking.

What is new is that up to now, the magnetic energy stored in the circuit, and hence the self-induction currents and extra opening currents arising from the self-induction EMF, has been spent on increasing the power of the opening current (short circuit). The breaking current power was spent on a spark discharge in the circuit contacts, which could lead to an arc discharge at high powers. At high power pulse voltage, the electric arc can reach up to a meter or more. The absorption or prevention of such a discharge required additional complex technological measures, as can be seen from the disassembled analogues. The proposed method is implemented using a pulsed EMF generator, the design of which is presented as a single-phase step-up autotransformer in the form of a simple induction coil with a core made in the form of a spiral coil with the ability to remove self-induction EMF and the coil is equipped with two or more conductors that are separated by a dielectric, and each the conductor has conclusions.

In this case, the pulse voltage of the EMF of self-induction in the primary winding of the pulse generator of the EMF of self-induction is removed by positive feedback from the secondary winding in the form of a pulse voltage of the EMF of self-induction plus EMF of induction. The pulse current arising on the secondary winding in the form of a DC voltage is transmitted to the primary and / or external battery. If the primary battery turned out to be fully charged, then this pulse voltage can be removed to the battery of external batteries. When voltage is removed, an electrical bypass can also be used for voltage converters. Bypass can be used for external batteries using, for example, voltage stabilizers and uninterruptible power supplies (UPS), which convert the AC network current into direct current. In addition, a conventional rectifier, such as a diode, can be used.

In the context of this application, positive feedback is considered such a positive feedback, in which a change in the output current of the self-induction of the secondary winding leads to a change in the input current on the primary winding, which contributes to a further increase in the output current of the self-induction from the original value. It is characterized by the following parameters: voltage and current in the input and output circuits of the windings. In the proposed method, positive feedback operates as a self-oscillator, which generates electrical (electromagnetic) vibrations, supported by the supply of a part of the positive feedback of an alternating voltage from the output of the self-oscillator to its input.

The entire circuit acts as a single-phase boost autotransformer. The principle of operation of the autotransformer in the context of this method is that when a field winding is connected, the primary winding to an alternating current network, a longitudinal magnetic flux arises in the circuit, which pulsates in time with the network frequency. In the primary and secondary windings, this flow induces an emf of induction and self-induction, the frequency of which is equal to the frequency of the network, and the effective value depends on the position of the windings relative to each other. [Goldberg O.D., Gurin Y.S., Seiridenko I.S. Design of electrical machines. M., 1982].

EMF of self-induction depends on the flux linkage of the magnetic field with the circuit, in turn, the stored energy in the magnetic field depends on the current strength in the circuit and on the nature of the circuit itself. Therefore, the shape of the contour of the windings also affects the emf generated by self-induction.

The industrial applicability of the proposed method is confirmed by examples of devices for implementing this method, which are not exhaustive and are described below.

A device for implementing the method of charging batteries relates to electrical engineering, in particular, to designs of pulsed induction current generators.

The purpose of the proposed invention is the use of a charger to provide pulsed power to the network or to charge batteries using a pulsed self-induction EMF generator and a diode rectifier.

The prior art invention is known "Mobile communications and method of charging a battery of a mobile communications", Patent RU 2582651, publ. 04/27/2016, Bull. No. 12, IPC H02J 7/32, Н02K 35/02, which is made on the basis of electromagnetic induction and contains cells whose walls are formed by inductive coils in which permanent magnets are placed. The invention improves the reliability and resource of the communication means by preventing the rapid destruction of the permanent magnets of the generator. However, it is used in mobile devices and permanent magnets are mobile and are installed in the cells with a gap, which leads to impacts on the side walls of the cells. The invention solves another problem, namely, improve the shape of the cells to soften the shock.

The invention is known "The ignition system of an internal combustion engine", application RU 95105608, publ. 01/10/1997, IPC F02P 3/05, in which an element with one-sided conductivity, a primary winding and an element that reduces the emf are used self-induction. EMF step-down circuit installed in the power circuit of the winding parallel to the power source is designed to combat EMF self-induction. The invention allows the inclusion in the circuit of the ignition system of the EMF of the lowering circuit to significantly increase the energy of the spark discharge. However, it does not solve the problem of the proposed technical solution, namely, the creation of a pulsed self-induction EMF generator for charging the battery or removing the voltage to the network.

The invention is known "Power supply device for a vehicle", patent RU 2413352, publ. 02/27/2011 Bull. No. 6, IPC Н02J 7/00, Н02М 3/155, B60L 11/00, in which the battery charger is connected to the energy storage device, power converters are made to divide the part of the current received from the battery charger to work as another battery a charger charging a second energy storage device. A power supply device for a vehicle having a plurality of installed energy storage devices is provided, wherein a charge / discharge imbalance for a plurality of energy storage devices is reduced. In this case, one of the high voltage batteries is used to supply power to the auxiliary load. However, it is necessary to solve the problem of balanced charging of many high voltage batteries. In this case, an external source is used for charging, and not the self-induction EMF, which is integrated in the system itself.

The closest technical solution adopted for the prototype is the invention "Pulse generator EMF self-induction", patent RU 2524387, publ. 06/10/2013 Bull. No. 16, IPC H01F 19/08, H01F 27/28, in which the primary and secondary windings are equipped with two or more conductors that are separated by a dielectric, and the conductor has leads. Moreover, the low-voltage primary winding is electrically connected to the low-voltage battery through a circuit breaker with the formation of a closed electrical circuit, the high-voltage secondary winding is simultaneously an electrically conductive winding and a magnetic circuit, while the turns of the primary winding are located outside the turns of the secondary winding so that both windings form a step-up transformer in which the secondary winding is an induction coil of a step-up transformer. This generator uses pulsed power generation and conversion. However, the self-induction emf obtained and used is not stored, if necessary, or is not replenished with it the initial charge of the low-voltage battery.

The inventive task of the proposed technical solution is to create a pulsed self-induction EMF generator for charging the battery or removing the voltage to the network in the manner described above.

The technical result, which is achieved at the same time, is a significant expansion of the arsenal of tools for pulsed generation and conversion of electricity for charging batteries.

The technical result is achieved due to the fact that the device for charging the battery according to the above method is made in the form of a pulsed self-induction EMF generator with the ability to remove self-induction EMF from it, and structurally made in the form of primary and secondary winding circuits in which the secondary winding is simultaneously an electrical conductor and magnetic circuit, and is equipped with two or more conductors separated by a dielectric, each of which has leads, and the primary circuit has an output to primary battery. The device is new and differs from the prototype in that in the device for charging the battery, the primary and secondary windings are structurally formed by a step-up autotransformer, for which the primary winding of the pulsed self-induction EMF generator is electrically connected to the battery through a breaker, with the formation of a closed electrical circuit, and, at the same time, a rectifier is connected electrically via a diode, connected in parallel to the breaker key, with a battery serving as the primary source energy for self-induction EMF pulse generator and a secondary winding having two terminals, one of which is internally free, and is electrically connected to the second primary winding conductor to form a positive feedback connection.

The device has the following design.

In the device for implementing the method of charging the battery, the pulsed self-induction EMF generator is structurally made in the form of primary (1) and secondary (2) windings of a single-phase boosting autotransformer, in which the secondary (2) winding is both functionally an electric conductor and a magnetic circuit. It is proposed to consider the presented design as the simplest induction coil with a core structurally executed in the form of a spiral coil with the possibility of removing the self-induction EMF from it. The windings (1,2) are equipped with two or more conductors (3) and (4), respectively, which are separated by a dielectric and each conductor has terminals “A” and “B”. In a pulsed self-induction EMF generator, the primary (1) low-voltage winding (conductor) is made of spiral-ribbon and has at least 2 turns wound tightly or with a small gap, turn to turn, the winding tape is made from a width of 120 to 200 mm and a thickness of 1 to 2 mm. The secondary (2) high-voltage winding (conductor) is also made of a spiral tape, the winding tape is made of electrical steel coated with electrical insulation, and has at least 100 turns wound tightly or with a small gap, turn to turn, the tape is made from a width of 120 up to 200 mm, and a thickness of not more than 0.1 mm. The primary (1) winding is electrically connected to the low-voltage storage battery (5) in two ways: through a breaker (6), with the formation of a closed electrical circuit and a rectifier diode (7) for positive feedback from the secondary (2) winding.

The secondary (2) winding is simultaneously an electrically conductive winding and a magnetic circuit. In this case, the turns of the primary (1) winding are located outside the turns of the secondary (2) winding so that both windings form a step-up autotransformer, in which the secondary (2) winding is an induction coil of a high voltage transformer, providing electrical conductivity due to the tape made of electrical steel insulated external layer of insulation and, at the same time, performs the function of the core for the primary (1) winding. The self-induction EMF is removed through, for example, a bypass line (8) of the primary (1) winding with a diode rectifier (7). EMF of self-induction is obtained due to the periodic operation of the interrupt key (6). (p. 229-232, textbook: Physics course, part two. "Science" Moscow 1970. Authors: L. S. Zhdanov, V. A. Maranjan.).

At the same time, due to the response frequency of the interrupter key (6), the calculated pulse voltage and current occurring in the secondary (2) winding are provided according to the formula

where - where L is the inductance of the circuit or the proportionality coefficient between the rate of change of the current strength in the circuit and the resulting self-induction EMF,

- скорость изменения силы тока в электрической цепи

- rate of change of current in an electric circuit

In special cases, the primary (1) winding can be made of copper or aluminum conductor, and can have 3 turns or more, the number of turns is limited by the transformer ratio: the ratio of the number of turns of the secondary (2) winding to the number of turns of the primary (1) winding, which determines transformation ratio, i.e. how much voltage in the secondary winding is greater than in the primary. For example, a low-voltage battery (5) can be designed for 12-24 volts and it is a source of direct current. In particular, the intermittent key interrupter (6) is periodically operated at an industrial frequency of 50 Hz AC. In this case, the frequencies can be any technically feasible for implementation, but better than 50 Hz: since it is easier to convert, or to consume using existing standard converters or electrical appliances. The calculated self-induction EMF in the secondary (2) winding is provided, in particular, by the geometry of the circuit and the magnetic properties of the core for the primary winding. So it can be made with a contour shape that is made round with a diameter of 150 mm or more, which depends on the transformation coefficient, which will determine the diameter of the secondary (2) winding depending on the thickness of the electrical steel used, or a round spiral shape. Since the secondary (2) winding is a high voltage winding and is made of electrical steel, this means that its magnetic properties are determined by the material itself (those proper magnetic properties of electrical steel).

The invention in the most generalized form is illustrated by drawings. A specific embodiment is not limited to the embodiments shown in the drawings.

In FIG. 1 - shows the layout of the primary and secondary windings, a rechargeable battery with a breaker key and a diode current rectifier on an additional bypass line of the primary winding.

In FIG. 2 - section AA is shown along the connected secondary and primary windings.

The drawings do not cover all possible design options for connecting the presented circuit.

A device for charging a battery, including a pulsed self-induction EMF generator, as shown in FIG. 1 and FIG. 2, structurally executed in the form of a single-phase step-up autotransformer (and also structurally is the simplest induction coil), which consists of a primary (1) spiral-ribbon winding (copper or aluminum conductor) 2-3 turns 1-2 mm thick, 120 mm wide, connected to the battery (5) low voltage 12-24 V, a DC source through a key-chopper (7), forming a closed electrical circuit.

Secondary (2) high voltage spiral tape winding made of electrical steel coated with electrical insulation has a number of turns of 100 or more, tape thickness 0.1 mm, width 120 mm. The secondary (2) winding made of electrical steel performs two functions in the design simultaneously: an electrically conductive winding and a magnetic circuit.

As an electrical conductor, the secondary winding (2) is a high voltage induction coil of a step-up autotransformer.

As a magnetic circuit, the secondary winding (2) is the core for the primary winding (1) of a classic induction coil.

A single-phase step-up autotransformer has a primary (1) and secondary (2) winding, the ends of the secondary (2) spiral winding have two terminals “B”, one of which is internally free, and the other end is connected to the conductor (3) of the primary (1) winding, thus constructively constructing an autotransformer. The self-induction EMF is removed from the primary (1) winding through positive feedback through a diode rectifier (7) in the form of a DC voltage to the battery (5).

Moreover, the currents arising in the secondary (2) winding are calculated by the formula where - where L is the inductance of the circuit or the proportionality coefficient between the rate of change of the current strength in the primary winding (1) and the resulting self-induction EMF in the secondary winding (2),

- скорость изменения силы тока в электрической цепи первичной обмотки (1) за счет ключа-прерывателя (6).

- the rate of change of the current strength in the electrical circuit of the primary winding (1) due to the interrupt key (6).

Periodic operation of the key interrupter (6) is carried out with an industrial AC frequency of 50 Hz. The calculated self-induction EMF in the secondary winding (2) is provided by the geometry of the secondary winding circuit (4) and the magnetic properties of the core for the primary winding (1)

The shape of the circuit (3) obtained by the primary (1) and secondary (2) windings, in the presented embodiment, is made of a round diameter of 150 mm or more.

The device operates as follows.

When the electric circuit of the primary winding (1) is closed with a key (6), a magnetic field arises, the energy of which is stored in the magnetic field of the secondary winding (2).

Opening the key (6) of the primary winding circuit (1) forms a decreasing current, which, according to the Lenz rule, seeks to support the EMF of the induced induction of the secondary winding (2).

As a result, the energy stored in the magnetic field of the secondary winding (2) is converted into additional energy of the self-induction current transmitted to the primary winding (1), which feeds the electrical circuit of the secondary winding (4), both by inductive coupling and directly by electric.

Depending on the amount of magnetic energy stored in the secondary winding circuit (2), the self-induction current power can be different and is determined by the well-known formula:

In practice, the voltage pulses of the self-induction EMF obtained in the presented electrical circuit exceed the induction EMF voltage by no more than 2-5 volts. In our case, if the initial voltage at the battery terminals is 12 volts, then after closing and opening the electric circuit, the self-inductance EMF voltage is from 14 to 17 volts. This voltage is enough to charge the battery with an EMF pulse of self-induction. In each specific wiring diagram of a pulsed EMF generator, it is possible to select a diode rectifier (7) with such characteristics as to ensure that the voltage is transmitted by voltage in a given interval, for example: 14-17 volts, (pp. 229-232, textbook: Physics course, part two ed. " Science, Moscow, 1970. Authors: L. S. Zhdanov, V. A. Maranjan.)

Thus, this invention achieves the technical result - consisting in the fact that the design, material and dual functionality of the secondary winding of the device allows you to remove and effectively use the resulting self-induction EMF to charge the battery.

Claims (2)

1. The method consisting in the fact that they charge the battery (battery) due to the generated EMF self-induction in a pulse generator EMF self-induction, characterized in that for charging using pulse voltage from the secondary winding of a pulse generator EMF self-induction, receive the resulting pulse voltage EMF self-induction in the primary winding of the pulsed EMF generator of self-induction by means of positive feedback from the secondary winding, the pulse voltage of the EMF of self-induction plus E is removed With the induction of DC voltage to the primary winding and is directed to the primary battery serving as the energy source for the pulse generator of the self-induction electromotive force, to its full charge and / or pulse voltage recovery is performed self-induced EMF and send it directly to the battery of rechargeable batteries. 2. The device for charging the battery according to claim 1 is made in the form of a pulsed self-induction EMF generator with the possibility of removing self-induction EMF from it, and structurally made in the form of primary and secondary winding circuits, in which the secondary winding is simultaneously an electric conductor and a magnetic circuit and is equipped with two or more conductors separated by a dielectric, each of which has conclusions, and the primary winding circuit has an output to the primary battery, characterized in that in the device for charging a the primary and secondary windings form a step-up autotransformer constructively, for which the primary winding of the self-induction EMF pulse generator is electrically connected to the battery through a breaker with the formation of a closed electrical circuit and simultaneously electrically connected through a diode rectifier, parallel to the breaker, is connected to the battery a battery serving as the primary source of energy for the pulsed EMF generator of self-induction, and the secondary winding has two outputs yes, one of which is internally free, and the second is electrically connected to the primary conductor to form a positive feedback.

Images