WO2011031190A2 - Method for accumulating electrical energy (two variants), and electrical energy accumulator of the capacitor type for implementing said method (two variants) - Google Patents

Abstract

The invention pertains to the field of electrical engineering, and particularly relates to techniques and equipment for accumulating electrical energy in large amounts with low weight-dimension indices. The technical result consists in the production of a small-dimension, light-weight electrical energy accumulator having a high capacity. According to the invention, an anode is provided outside a vacuum chamber including a cathode, with a dielectric provided between them, and the energy is accumulated by accumulating the free electrons in the deep vacuum around the cathode. According to variant 1, the method comprises generating a volumetric negative charge in a stationary vacuum capacitor (VC) of a charging stationary device, and using the charge thereof for transferring the electrical energy to a mobile electrical energy accumulator of the capacitor type (CTEEA) for charging its VC. According to variant 2, the method comprises using two VCs in the CTEEA, wherein the first VC first receives a full charge and is then discharged through a stabilizer-converter into the second VC, whereby the charge is distributed between the two VCs. After this, an overcharge is carried out and the charge is returned from the second VC to the first VC. The main CTEEA is the VC that comprises a hot cathode with electrically insulated incandescence or a cold cathode with a micro-pico-metric surface. When charging the CTEEA and the VC, the method comprises applying a negative potential to the cathode relative to the anode, thus triggering the emission of electrons from the cathode into the vacuum where they flow towards the anode but cannot reach it due to the dielectric of the sealed tank, and remain in the vacuum into which new free electrons flow from the cathode and form a volumetric charge around the cathode until the intensity of the field of the volumetric charge becomes equal to the voltage of the charging device. The first variant of the CTEEA for implementing the first variant of the method for accumulating electrical energy comprises one vacuum capacitor. The second variant of the CTEEA for implementing the second variant of the method for accumulating electrical energy comprises an overcharging device for a CTEEA with two VCs and a CTEEA with two VCs.

Description

 The method of energy storage (two options) and a capacitor type energy storage device for implementing the method

 (two options).

Technical field

The invention relates to the field of electrical engineering, in particular to technology and equipment for the accumulation of electricity in large volumes at low mass and size indicators.

State of the art

A known electromagnetic energy battery according to the application of the Russian Federation N22006106535, comprising a housing made in the form of a toroid, the outer shell of which is a hemisphere made of diamagnet, and the inner shell is made of a ferromagnet in the form of a mirror image of the outer shell, the inner and outer shells are connected at the top through a cylindrical thermocouple, and below are fastened through a layer of a high-temperature superconductor, while the lower cavity, limited by shells and a heat insulator, is filled with refrigerant.

 There is also a known method of charging and discharging a battery according to RF patent Ns 2303841, in which the battery contains a housing, an electrolyte and two electrodes, a carbon anode and a copper cathode immersed in the electrolyte, the anode is made in the form of a felt strip made of graphite fibers, and the cathode is made in the form of a copper plate or copper cylinder. The method of charging this battery is carried out by connecting an external DC source minus to the graphite electrode and plus to the copper and the copper electrode is partially dissolved. The battery discharge is carried out by connecting an external load.

 Known technologies and equipment have significant dimensions and low energy intensity, and also have a high cost.

These shortcomings are eliminated by the claimed capacitor-type electric energy storage device (hereinafter - NECT) by creating a small-sized and a high-capacity lightweight electric battery for electric vehicles, electric boats and yachts, electric planes, etc., as well as providing the possibility of creating mini- and micro-batteries for mobile electronic and electrical equipment.

SUMMARY OF THE INVENTION

The inventive technology is based on the accumulation of charges of free electrons in a vacuum, creating a negative volumetric charge in a "vacuum capacitor" (VK).

 The method of accumulating electrical energy is that the anode is placed outside the vacuum chamber with the cathode and a dielectric is placed between them, and the energy is accumulated by the accumulation of free electrons in a deep vacuum around the cathode.

 A feature of the claimed NECT is a vacuum capacitor (VC), which contains a heated cathode with an electrically insulated filament or a cold cathode with a micropic surface donating electrons to accumulate charge - electricity in a vacuum in a dielectric tight cylinder, inside of which there is a cathode separated from the anode located on the outer surface of the dielectric sealed cylinder created by a deep vacuum.

The method of energy storage according to option 1 includes the accumulation of a charge of free electrons in a vacuum, creating a negative negative space charge in a stationary vacuum capacitor (VK) of a stationary charging device and using its charge to transfer electricity to a capacitor type mobile electric energy storage device (NECT) for charging its VK , while the power consumption of a stationary VC is 100 - 1000 times higher than the power consumption of all simultaneously charged NECTs with their VC, and the stationary VC is charged from a generator or standard rtnoy AC transformer, increasing or reducing, depending on the charging voltage and the multiplier NEKT - rectifier voltage connected to the cathode of the stationary VC, and its anode, the free end of the transformer secondary winding and a common conductor multiplier - rectifier ground; Moreover, the NECT charge received by the mobile VC is used to supply its consumers directly or through stabilizers or converters, the discharging VC creates an electric current in the stabilizer – converter, which, passing through the stabilizer – converter, gets to the cathode of the damper lamp diode, which has a constructive vacuum electric capacity and accumulates a charge in itself, if the spark gap connected to its anode to drain free electrons into the environment, air, water and the ground for a short time cannot both sinter the required discharge current. A stationary charger maintains its VC in a charged state and therefore the NECT charge rate will be limited only by the charging current, and the charge current is regulated and monitored by the NECT charge control and display control unit, with which the NECT charge value is set and the amount of charge received by it is determined.

 The method is used for transport devices and high NECT charge voltages are used, and the VC and the damping diode are placed in electromagnetic screens, in order to obtain high powers in the stabilizer-converter, sufficiently low currents are used, and the vehicle’s body can be used as an arrester, on which antennas to drain free electrons, while the housing is protected from corrosion.

The method of energy storage according to option 2 includes the use of two VK in the NECT, the first of them first gets a full charge, and then discharged through a stabilizer-converter into the second VK, distributing the charge between the two VK, while the electric capacity of the second VK is equal to or greater than the electric capacity of the first VK, at the end of the process, recharge is carried out - the charge is returned from the second VK to the first VK, for this they use a recharge device that is connected to a generator or a standard AC network via a transformer a mator increasing or decreasing depending on the charging voltage of the NECT and containing two counter-wound output windings connected to each other and to the diodes and to the multiplier with a voltage rectifier so that the multiplier - voltage rectifier feeds their total voltage, and it creates a large positive potential on the anode of the first VK, and a large negative potential for recharging on the anode of the second VK, the diodes connected to the windings provide current flow in one direction, while the output windings work each in its own half-cycle, providing charge transfer with the cathode of the second VK to the cathode of the first VK, the process is controlled and monitored by the control unit, display and control recharge NECT, which turns on and off the charge mode, and also reflects the amount of charge and charge state of both VK.

 The method is characterized by the fact that NECTs are used for small electronic and electrical devices and for electric transport, and a damper lamp diode with a spark gap free electron gadget and a switch connecting the second VK parallel to the first VK are added to it, and a damper diode is in its place, this is necessary when redistributing charge between two VCs when there is no AC source for recharging.

 The method is characterized by the fact that NECTs are used to power small electronic or electrical devices and use low-voltage VCs of large electric capacity and stabilizers, and the electric capacity is determined from the ratios that take into account the duration of continuous operation with known energy consumption and allowable losses of supply voltage, and the recharge device is mobile.

The method includes accumulating a charge of free electrons in a vacuum, creating a negative negative space charge in a stationary VC of a stationary charging device and using its charge to quickly transfer electricity to a mobile NECT to charge its VC (the electric capacity of a stationary VC must be at least one hundred times greater than the electric capacity NECT his VK for its quick charge). A stationary VC is charged from a generator or a standard AC network through a transformer (increasing or decreasing depending on the charging voltage of the NECT) and a multiplier - a voltage rectifier connected to the cathode of the stationary VC, and its anode is grounded. Similarly ground the free end of the secondary winding of the transformer and the common wire of the multiplier - rectifier. The NECT uses the charge received by the mobile VC to supply its consumers directly or through known stabilizers or converters, the discharging VC creates an electric current in the stabilizer - converter, which, passing through the stabilizer - converter, enters the cathode of the damper lamp diode, which, due to its design, also it has a vacuum electric capacity and can accumulate a charge in itself if a spark gap is connected to its anode to drain free electrons into its environment (air, water and earth) for some time can not provide the necessary current. A stationary charger constantly maintains its VK in a charged state and therefore the NECT charge rate will be limited only by the charging current that the supply wires and connection contacts can withstand, the charge current is regulated and monitored by the NECT charge control and display control unit, with which you can set the charge amount NECT or determine the amount of charge received by him (to determine the payment).

 NECT is convenient to use for transport devices and it is better to use high NECT charge voltages (at high voltages, it is necessary to place a VC and a damping diode in electromagnetic shields), in order to obtain high powers in the stabilizer-converter, sufficiently small currents are needed, and this is convenient for a spark gap which can use the vehicle body on which special antennas can be installed to drain free electrons, while the body will be protected from corrosion.

The first embodiment of a capacitor-type electric energy storage device for implementing the first variant of the electric energy storage method comprises one capacitor-type electric energy storage device (NECT) 50 and a stationary charger, 49 which includes a generator or a standard AC network 9, a transformer 8, a voltage rectifier 11, stationary VK 12, a unit for monitoring and displaying the state of a charged stationary VK 12, for monitoring, displaying and controlling a NECT charge (VK 17), a glow power supply 14 cathode stationary VK 12 powered by a generator or mains 9, stationary charger, spaced apart ground contacts 6 and 7.

 NECT 50 is equipped with an autonomous power supply unit for the filament 18, a charged VK 17 and a damper lamp diode 19 with self-charging from the stabilizer-converter 16, which provides heating of the VK 17 cathode and the cathode of the damper lamp diode 19 in continuous mode with a long-term absence of charging from the stabilizer-converter 16.

 In a variant design of NECT, the cathode can be made “cold” (without heating) with a micropic surface providing the best return of free electrons from its surface.

A recharging device 51 combined with NECT 52 (for NECT 52 with two VK 17 and VK 33) connected to a standard network or alternator 9, input winding D (terminals 40 and 41) of transformer 30, a multiplier - voltage rectifier 31 with input (contact 48) connected to the winding E (pin 42), a common wire (pin 47), connected to the winding F (pin 45), and a positive output (pin 46), which creates a large positive potential on the anode of VK 17, and its common wire (pin 47) is connected to the anode of VK 33 and creates a negative potential, windings E and F transformer 30 are connected by their opposite ends (pins 43 and 44) to their other ends (pins 42 and 45) by their cathodes are connected diodes 34 and 35 anode of the diodes are connected together and through the control unit, display and control recharge NEKT 32, connected to the cathode (K ) VK 17, and contacts 43,44 through block 32 to the cathode (K) VK 33, and the stand-alone power supply for the filament 18 rechargeable VK 17 and VK 33, and a damper lamp diode 19, with auto-charging from the stabilizer-converter 16, which can be off during long-term disconnection of loads from NECT, provides heating of the cathode VK 17, VK 33 and the cathode of the damper lamp diode 19 in continuous mode even with a long-term absence of recharging from the stabilizer-converter 16, in turn, the block 32 for monitoring, displaying and controlling the recharge of NECT (VK 17 and VK 33 ) issuing the command to switch the contact group 36 after a full recharge of NECT (VK 17 and VC 33), and puts the NECT in offline mode.

 NEKT 52 is characterized by the fact that in stand-alone mode VK 17 is connected to the stabilizer - converter 16 (pin 28) and gives its charge to it, and from the stabilizer - converter 16 through (pin 29) the charge goes to the VK 33 cathode and the process continues until complete redistribution charge between VK 17 and VK 33, if there is no AC source 9 for recharging them, the switch 37 connects VK 33 in parallel to VK 17, and in its place connect the cathode of the damper diode 19, the charge will go to the cathode of the damper diode 19, which also has vacuo capacitance, and from it through the anode to the spark gap there is a free electron stacker 20, and from it free electrons are absorbed by the environment: air, earth and water, and contacts 38 and 39 are designed for primary charging of NEKT 52 (VK 17) from a stationary charger and its recharging, if during operation its charge was partially lost through the arrester 20.

 NECT is characterized by the fact that the cathode is made cold with a micropic surface providing the best return of free electrons from its surface.

NECT includes a vacuum capacitor (VC), which contains a heated cathode with an electrically insulated filament or a cold cathode with a micropic surface that gives off electrons to accumulate charge - electricity in a vacuum in a dielectric sealed container, inside of which there is a cathode separated from the anode located on the outer surface dielectric sealed cylinder created by a deep vacuum. The VC is charged as follows, to the cathode relative to the anode, using a special charger such as a voltage multiplier for the cathode ray tube generating free electrons, a negative potential is applied, which causes the emission of electrons from the cathode into vacuum, where they rush to the anode, but cannot reach it due to the dielectric of the sealed balloon, they remain in a vacuum, where new free electrons continue to flow from the cathode, forming a space charge around the cathode, and this process will continue until the field charge of the space charge becomes equal to the voltage of the charger. Charging NECT and VK completed.

 NECT is convenient to use for transport devices and it is better to use high NECT charge voltages (at high voltages, it is necessary to place a VC and a damping diode in electromagnetic shields) at the same time to obtain high power in the load, sufficiently small currents are needed, and this is convenient for a spark gap which can be used as a housing vehicle on which special antennas can be installed to drain free electrons, while the body will be protected from corrosion.

The method according to option 2 is characterized in that two VCs are used in the NECT, the first of them, as in the first method, first receives a full charge, and then discharges through a stabilizer - a converter in the second VC distributing its charge between the two VCs (the electric capacity of the second VC should be equal to or greater than the electric capacity of the first VK), when the process is over, recharging is required, that is, the charge is returned from the second VK to the first VK, for this a recharging device is used, which must be connected to a generator or a standard network alternating current through a transformer (increasing or decreasing depending on the charging voltage of the NECT) and containing two counter-wound output windings connected to each other and with diodes, and to the multiplier with a voltage rectifier so that the multiplier - voltage rectifier is powered by their total voltage, and he creates a significant positive potential on the anode of the first VK, and a significant negative potential on the anode of the second VK to facilitate their overcharging, diodes connected to the windings provide prote current flow in one direction, while the output windings work each in its own half-cycle providing charge transfer from the cathode of the second VK to the cathode of the first VK, the process is controlled and monitored by the monitoring, display and control unit for recharging the NECT, which turns the charge mode on and off, and also displays the amount of recharge and the state of charge of both VCs. If the recharging device is carried out separately from the NECT with two VK, then such NECT is most convenient to use for small electronic and electrical devices. NECT with two VCs can be used for electric transport, but then you need to add a damper lamp diode with a spark gap to the free electron beam and a switch connecting the second VC in parallel to the first VC, and in its place a damping diode, this is necessary if the charge redistribution between the two VCs has already happened, and there is no AC source for recharging nearby. After switching, you need to get to the AC source or charging station, switch the NECT to its original state, fully recharge it, and then recharge it, compensating for the electron charge lost through the arrester using a stationary charger. When using this NECT for powering small electronic or electrical devices, it is better to use low-voltage VC of large electric capacity and the well-known simplest stabilizers in the NECT, the electric intensity is determined from the known formulas, taking into account the duration of continuous operation with a known power consumption and allowable voltage drops.

 When working at large reactive capacities of the VK and the release of a large amount of heat, standard VK cooling systems, air or oil type, are provided.

 At a VC operating voltage of more than 28 kV, x-ray radiation may occur, which requires shielding.

The second variant of the capacitor type electric energy storage device for implementing the second variant of the electric energy storage method is a recharging device for NECT with two VK 51 and NECT with two VK 52. The precharging device for NECT with two VC contains a generator or a standard AC network 9, a multiplier is a voltage rectifier , transformer, control unit, display and management of recharge NEKT, stand-alone power supply unit 18 rechargeable VK 17 and VK 33, and a damper lamp diode 19, with automatic recharging from tabilizatora - 16 converter. In the embodiment of the second embodiment, the capacitor-type electric energy storage device can be “cold” (without heating) with a micropic surface providing the best return of free electrons from its surface.

To confirm the theoretical assumptions about the possibility of creating a vacuum capacitor and determine the electrical intensity of the vacuum, an experiment was set up where a 6D6A type electric vacuum diode with an approximate internal vacuum volume of 2.3 cm ³ was used as a VC. For this purpose, a 6D6A diode for isolation of its own anode was placed in a metal glass filled with transformer oil, the glass itself became the VK anode. The cathode was heated using a filament transformer with an effective voltage of 6.3V. The charge was carried out by a rectified mains voltage (i.e. ^ 310V), through a current-limiting variable resistor and ammeter, with which a constant charge current of 10 mA was maintained for 8 hours of charge. For 8 hours of charge, the voltage between the metal cup (anode) and the cathode of the 6D6A diode reached 28 V.

 From the obtained measurements, the calculation of the vacuum capacity created by VC was made.

It is known that q _BK = l ₃ ^x t ₃ = C _BK xU _3i where l ₃ = 0.01 A, t ₃ = 8 hours = 28800 sec, U ₃ = 28B, hence q _BK = 0.01 x28800 = 288 coulomb , which means the capacity is

With _VK = t, tfgg ⁼ ^ 28 = 10.2857 farads, where Ι ₃ is the VK charge, is the VK charge time, and _{3 is the} voltage between the anode and the VK cathode obtained at the end of the charge, q _BK is the VK charge after its charge , with _VC - VC calculated capacity.

 The result showed a large capacity of VC and, as a consequence, the expediency of its use in energy storage systems and other energy devices. The electrical intensity of one cubic centimeter of vacuum thus measured is more than 5 farads, and the operating voltages are tens of kilovolts, known capacitors cannot solve this problem.

Vacuum capacitor, contains a heated cathode with an electrically insulated glow, placed in a dielectric a sealed container with a deep vacuum, and an anode located on the outer surface of the dielectric sealed container.

 In a vacuum capacitor, the cathode can be made cold with a micropic surface providing free electron transfer from its surface without heating.

 The vacuum capacitor allows you to solve the following technical problems: to accumulate a large electric charge at high voltages, which corresponds to high energy at its own small size, this allows you to use it in energy storage devices for various purposes, as an electric battery that can quickly charge electricity, and then give it in any mode .

Blueprints

The invention is illustrated by drawings, where: in FIG. 1 - shows a General view in section of a vacuum capacitor with a heated cathode; in FIG. 2 - the same with a cold cathode; in FIG. 3 is a block diagram for implementing the method and accumulating electric energy of a capacitor type (NECT) on one VK and a stationary charger to it; in FIG. 4 is a block diagram for implementing the method and the storage of electric energy of a capacitor type (NECT) on two VK, combined with a recharge device.

In the drawings, the positions indicated: 1 - cathode; 2 - dielectric sealed container; 3 - deep vacuum; 4 - anode; 5 - electrically insulated glow of the cathode (see Fig. 1 or 2); 6, 7 (see Fig. 3) - grounding contacts (in addition to standard grounding, metal plates electrodes immersed in water can be used as grounding contacts); 8 - transformer (increasing or decreasing depending on the charging voltage of NECT); 9 - alternating current generator (any known alternating current generator or any standard power supply network); 10 - land or water; 11 - multiplier - voltage rectifier; 12 - rechargeable VK stationary charger for NECT; 13 - disconnecting contact group; 14 - glow power supply unit of a charged VK stationary charger for NECT with power from generator or network; 15 is a unit for monitoring and displaying the state of a charged stationary VC, monitoring, displaying and managing a NECT charge, and for controlling a trip contact group 13; 16 - load element NECT, made in the form of stabilizers - converters of known types, linear or pulsed, or alternating current, depending on the consuming payload; 17 - rechargeable VK in NECT; 18 - an autonomous power supply unit for the glow of a charged VK 17 in NECT and a damper lamp diode 19 with self-charging from a stabilizer-converter 16, which can be turned off when the load is disconnected from the NECT for a long time; 19 - damper lamp diode with a heated or cold cathode; 20 - discharge device for the flow of free electrons; 30 - a transformer (increasing or decreasing depending on the charging voltage of the NECT) containing two counter-wound output windings; 31 - multiplier - voltage rectifier; 32 - control unit and display the status of the charged VK 17 and discharged VK 33, control, display and management of reloading NECT, and control the contact group switching 36; 33 - the second VK in NECT, designed to receive charge from the first VK 17 through the consumer 16; 34, 35 - rectifier diodes; 36, 37 - switching contact groups; 38, 39 - contact group for connecting a stationary charger (Fig. 3 and 4); 49 - stationary charger for NECT; 50 - NECT with one VK; 51 - recharge device for NECT with two VK; 52 - NECT with two VK.

An embodiment of the invention

In FIG. 1 shows a VK containing a heated cathode 1 with an electrically insulated filament 5, placed in a dielectric sealed container 2 with a deep vacuum 3, and an anode 4 located on the outer surface of the dielectric sealed container 2.

In FIG. 2 shows a VC containing a cold cathode with a micropic surface 1, placed in a dielectric sealed cylinder 2 s deep vacuum 3, and the anode 4 located on the outer surface of the dielectric sealed container 2.

 The block diagram (Fig. 3) shows the first variant of a stationary charger for NECT 49 and NECT with one VK 50 for implementing the first variant of the method of electric energy storage. The stationary charger for NECT includes a generator or a standard AC network 9 connected to the input winding B (terminals 21 and 22) of the transformer 8, a multiplier - a voltage rectifier 11 with an input (terminal 27), a common wire (terminal 26) and a negative output ( terminal 25) charging the stationary VK 12 through the cathode (K), and its anode (A) is connected to the ground terminal 6, the input of the multiplier - voltage rectifier (terminal 27) is connected to the output winding C (terminal 23) of the transformer 8, the other end of which (terminal 24) connected to contact grounding 7 to it is connected the common wire (pin 26) of the multiplier - voltage rectifier 11, the control unit and display the status of a charged stationary VK 12, control, display and charge control NEKT (VK 17) 15, issuing a command to disconnect the contact group 13 after full or a predetermined NECT charging (VK 17), which transfers the NECT to stand-alone operation, and the stationary charger to the VK 12 charge recovery mode of the given NECT, the stationary charger also has a glow power supply unit 14 of the stationary VK 12 cathode powered by a generator or power supply 9 provides continuous heating of the VK 12 cathode and can be turned off or on only with a stationary charger (when using VK 12 with a cold cathode, block 14 is not needed).

A stand-alone power supply for the glow 18 of a charged VK 17 and a damper lamp diode 19 with automatic recharging from the stabilizer-converter 16, which can be turned off when it is disconnected from the NECT for a long time, provides heating of the VK 17 cathode and the cathode of the damper lamp diode 19 in continuous mode even in the long-term absence recharging from 16 (when using VK 17 and diode 19 with a cold cathode, block 18 is not needed). . In stand-alone mode, VK 17 connected to the stabilizer - converter 16 (contact 28) gives its charge to it, and from the stabilizer - converter 16 (contact 29) the charge goes to the cathode of the damper diode 19 also having a vacuum capacity, and from it through the anode to the spark gap - free electron stacker 20 with it free electrons are absorbed by the environment: air, earth and water, flowing in this way through the stabilizer - converter 16, the electric current does useful work.

 Grounding contacts 6 and 7 are spaced apart at a distance L, which ensures a safe "step voltage", the distance L is determined by the formula:

L> U ₃ .6,7 _m ax [B] / 50 [B / M] = L [M], where

 U3.67 ma is the maximum voltage occurring between the ground contacts 6 and 7 with a full charge of VK 12;

L is the distance between the ground contacts 6 and 7 at which the potential difference is provided on the connection line between the ground contacts (6 and 7) on any meter of this segment, the potential difference is not more than 50 V at and ₃ . _b , 7 tach -

The cathode is made with glow (heating) or “cold” (without heating) with a micropic surface providing the best return of free electrons from its surface.

 The block diagram (Fig. 4) shows a second embodiment of a recharging device for NECT with two VK 51 and NECT with two VK 52 for implementing the second variant of the method of electric energy storage.

The block diagram shows a recharging device for NECT with two VCs contains a generator or a standard AC network 9 connected to the input winding D (pins 40 and 41) of the transformer 30, a multiplier - a voltage rectifier 31 with an input (pin 48) connected to the winding E ( pin 42), a common wire (pin 47) connected to the winding F (pin 45), and a positive output (pin 46) creating a large positive potential on the VK 17 anode, and its common wire (contact 47) creates a large negative on the VK 33 anode potential winding E and F trans ormatora 30 are connected at their ends oppositely (pins 43 and 44) to their other ends (pins 42 and 45) diodes 34 and 35 are connected by their cathodes; diode anodes are connected together and through the NECT 32 monitoring, display and recharge control unit, connected to the cathode (K) VK 17, and the contacts 43,44 through the block 32 to the cathode (K) VK 33. A stand-alone power supply of the glow 18 rechargeable VK 17 and VK 33, and a damper lamp diode 19, with auto-charging from the stabilizer-converter 16, which can be turned off when the stabilizer-converter is turned off for a long time 16 from NECT, provides heating of the cathode VK 17, VK 33 damper diode cathode tube 19 in a continuous manner even during long-term absence of charge of 16 (using VK 12 of the cold cathode unit 14 is not needed).

 Block 32 monitoring, display and management of reloading NECT (VK 17 and VK 33), issuing a command to switch the contact group 36 after a full recharge of NECT (VK 17 and VK 33), which puts the NECT in stand-alone operation. In stand-alone mode, VK 17 connected to the stabilizer - converter 16 (pin 28) gives its charge to it, and from the stabilizer - converter 16 through (pin 29) the charge goes to the VK 33 cathode and this process will continue until the charge is redistributed between VK 17 and VK 33, if this happened when there is no AC source 9 nearby to recharge them, you can connect VK 33 to VK 17 with a switch 37 and connect the cathode of damper diode 19 in its place, the charge will go to the cathode of damper diode 19 with e vacuum capacity, and from it through the anode to the spark gap - free electron stacker 20 from it free electrons are absorbed by the environment: air, earth and water, flowing in this way through the stabilizer-converter 16, the electric current does useful work. Contacts 38 and 39 are intended for primary charging of NECT (VK 17) from a stationary charger and its recharging if during operation its charge was partially lost through the spark gap 20.

The cathode is made with heat (heating) or can be made “cold” (without heating) with a micropic surface providing the best return of free electrons from its surface. A capacitor-type energy storage device with one vacuum capacitor 50 contains a generator or a standard AC network 9 connected to the input winding B (terminals 21 and 22) of the transformer 8, a multiplier - a voltage rectifier 11 with an input (terminal 27), a common wire (terminal 26) and a negative output (terminal 25), charging the stationary VK 12 through the cathode (K), and its anode (A) is connected to the ground terminal 6, the input of the multiplier - voltage rectifier (terminal 27) is connected to the output winding C (terminal 23) of the transformer 8 another horse which (terminal 24) is connected to ground terminal 7 and the common wire (terminal 26) of the multiplier - voltage rectifier 11 is connected to this, while the control and display unit for the state of the stationary stationary VK 12, the control, display and charge control of NECT (VK 17) 15, issuing a command to disconnect the contact group 13 after full or predetermined charging of the NECT (VK 17), puts the NECT in stand-alone operation, and the stationary charger 49 in the recovery mode of the charge VK 12 given NECT, in addition to the stationary charging device e there is a power supply unit 14 of the cathode of stationary VK 12 powered by a generator or power supply 9, which provides heating of the cathode VK 12 in continuous mode and can be turned off or on only with the stationary charger, in turn, the ground contacts 6 and 7 are spaced between themselves at a distance L, providing a safe "step voltage", the distance L is determined from the ratio:

L ^ U ₃ .6,7 max [B] / 50 [B / M] = L [M], where

 U3.67 max - the maximum voltage occurring between the ground contacts 6 and 7 with a full charge of VK 12;

 L is the distance between the ground contacts 6 and 7 at which the potential difference is ensured on the connection line between the ground contacts (6 and 7) on any meter of this segment, the potential difference is not more than 50 V at U3.6J max

NECT is characterized by the fact that it is equipped with an autonomous power supply unit for filament 18, a charged VK 17 and a damper lamp diode 19 with automatic charging from a stabilizer - converter 16, which provides heating of the cathode VK 17 and the cathode of the damper lamp diode 19 v continuous mode with a long-term lack of recharging from the stabilizer-converter 16.

 NECT is characterized by the fact that in stand-alone mode VK 17 is connected to the stabilizer - converter 16 (pin 28) and gives its charge to it, and from the stabilizer - converter 16 through (pin 29) the charge goes to the cathode of the damper diode 19, which also has a vacuum capacity, and from it through the anode to the discharger - a stack of free electrons 20 from it free electrons are absorbed by the environment: air, earth or water.

 NECT is characterized by the fact that the cathode is made “cold” (without heating) with a micropic surface providing the best return of free electrons from its surface.

The stationary charger 49 (for NECT with one VK 50) contains a generator or a standard AC network 9 connected to the input winding D (terminals 40 and 41) of the transformer 30, a multiplier - a voltage rectifier 31 with an input (terminal 48) connected to the winding E (pin 42), a common wire (pin 47) connected to the winding F (pin 45), and a positive output (pin 46), which creates a large positive potential on the VK 17 anode, and its common wire (pin 47) is connected to the VK anode 33 and creates negative potential, windings E and F transformer and 30 are connected by their opposite ends (pins 43 and 44) to their other ends (pins 42 and 45) with their cathodes diodes 34 and 35 are connected, the diode anodes are connected together and connected to the cathode via the NECT 32 recharge control, display and control unit, are connected to the cathode (K ) VK 17, and contacts 43,44 through block 32 to the cathode (K) VK 33, and the stand-alone power supply for the filament 18 rechargeable VK 17 and VK 33, and a damper lamp diode 19, with auto-charging from the stabilizer-converter 16, which can be off during long-term shutdown of the stabilizer - pre of the developer 16 from the NECT, provides heating of the cathode VK 17, VK 33 and the cathode of the damper lamp diode 19 in continuous mode even with a long-term absence of recharging from the stabilizer-converter 16, in turn, the block 32 for monitoring, displaying and controlling the recharge of NECT (VK 17 and VK 33) issuing the command to switch the contact group 36 after a full recharge of NECT (VK 17 and VC 33), and puts the NECT in offline mode.

 NECT is characterized by the fact that in stand-alone mode, VK 17 is connected to the stabilizer - converter 16 (pin 28) and gives its charge to it, and from the stabilizer - converter 16 through (pin 29), the charge goes to the VK 33 cathode and the process continues until complete redistribution charge between VK 17 and VK 33, if there is no AC source 9 for recharging them, the switch 37 connects VK 33 in parallel to VK 17, and in its place connect the cathode of the damper diode 19, the charge will go to the cathode of the damper diode 19, which also has vacuo capacity, and from it through the anode to the spark gap there is a free electron stacker 20, and from it free electrons are absorbed by the environment: air, earth and water, and contacts 38 and 39 are designed for primary charging of NECT (VK 17) from a stationary charger and its recharging, if during operation its charge was partially lost through the arrester 20.

 NECT includes a vacuum capacitor (VC), which contains a heated cathode with an electrically insulated filament or a cold cathode with a micropic surface that gives off electrons to accumulate charge - electricity in a vacuum in a dielectric sealed container, inside of which there is a cathode separated from the anode located on the outer surface of the dielectric hermetic a cylinder created by a deep vacuum.

Industrial applicability

This technical solution is industrially applicable, since it can be manufactured industrially in electrical engineering, and its purpose is indicated in the description of the application and title of the invention. These distinctive features of the invention allow to obtain a given technical result, i.e. are significant.

The invention, as described in each of the claims, can be carried out using means and methods, described in the prototype, which became public until the priority date of the invention.

 The VC is charged as follows, to the cathode relative to the anode, using a special charger such as a voltage multiplier for the cathode ray tube generating free electrons, a negative potential is applied, which causes the emission of electrons from the cathode into vacuum, where they rush to the anode, but cannot reach it due to the dielectric of the sealed balloon, they remain in a vacuum, where new free electrons continue to flow from the cathode, forming a space charge around the cathode, and this process will continue I until the field strength of the space charge becomes equal to the voltage of the charger. Charging NE T and VK completed.

Claims

Claim

1. The method of energy storage, option 1, which includes the accumulation of a charge of free electrons in a vacuum, creating a negative volumetric charge in a stationary vacuum capacitor (VK) of a stationary charging device and using its charge to transfer electricity to a capacitor type mobile electric energy storage device (NECT) for its VC charge, while the electric capacity of the stationary VC is 100 - 1000 times higher than the electric capacities of all simultaneously charged NECTs with their VC, and the stationary VC is charged from the generator or standard AC network through a transformer, increasing or decreasing depending on the charging voltage of the NECT and the multiplier - rectifier connected to the cathode of the stationary VC, the free end of the secondary winding of the transformer and the common wire of the multiplier - rectifier are grounded, and the NECT received by the mobile VC is used for power their consumers directly or through stabilizers or converters, by means of a discharging VK, create an electric current in the load, which, passing through the stabilizer - the converter enters the cathode of the damper lamp diode, which has a constructive vacuum electric capacity and accumulates a charge if the discharger connected to its anode to drain free electrons into the environment, air, water and the ground for a short time can not provide the necessary discharge current, while the stationary charger maintains its VC in a charged state, which limits the NECT charge rate only to the charging current, and the charge current is regulated and monitored by the control unit Ia and display NEKT charge with which set value NEKT charge and determining the amount of charge received.

2. The method of energy storage, option 1 according to claim 1, characterized in that vehicles are used as a consumer, for which high charge voltages are applied, NECT, and the VK and damper diode are placed in electromagnetic screens, and the vehicle body is used as an arrester which may be antennas are installed to drain free electrons, while the housing protects against corrosion.

 3. A capacitor-type electric energy storage device, option 1 for implementing option 1 of the method, comprising one vacuum capacitor, a generator or a standard AC network 9 connected to input winding B (terminals 21 and 22) of transformer 8, a multiplier - a voltage rectifier 11 with an input ( terminal 27), a common wire (terminal 26) and a negative output (terminal 25) charging the stationary VK 12 through the cathode (K), and its anode (A) is connected to ground terminal 6, the input of the multiplier - voltage rectifier (terminal 27) is connected to output winding C (terminal 23) of the transformer 8, the other end of which (terminal 24) is connected to the ground terminal 7 and the common wire (terminal 26) of the multiplier - voltage rectifier 11 is connected to this, while the control unit and display the status of the charged stationary VK 12, control, display and charge control NECT (VK 17) 15, issuing a command to disconnect the contact group 13 after a full or predetermined charging NECT (VK 17), is configured to transfer NECT to offline mode, and a stationary charger to charge recovery mode VK 12 delivered by NECT, and the stationary charger is equipped with a power supply unit 14 of the cathode of stationary VK 12 powered by a generator or power supply 9, with the possibility of heating the cathode VK 12 in continuous mode and turning it off or on only with the stationary charger, grounding contacts 6 and 7 are spaced apart at a distance L, providing a safe "step voltage", while the distance L is determined from the ratio:

L> U ₃ . ₆ .7 max [B] / 50 [B / M] = L [M], where

 from 6.7 max - the maximum voltage arising between the grounding contacts and when the VK is fully charged;

L is the distance between the grounding contacts and at which the potential difference is provided on the connection line between the grounding contacts on any meter of this segment, the potential difference is not more than 50V at 6.7 max

4. A capacitor-type electric energy storage device, option 1 according to claim 3, characterized in that it is equipped with an autonomous power supply unit for filament 18, a charged VK 17 and a damper lamp diode 19 with automatic charging from a stabilizer-converter 16, with the possibility of heating the VK 17 cathode and cathode damper lamp diode 19 in continuous mode with a long-term lack of recharging from the stabilizer-Converter 16.

 5. A capacitor-type electric energy storage device, option 1 according to claim 3, characterized in that in stand-alone mode, the VK 17 is connected to a stabilizer-converter 16 (contact 28) with the possibility of transferring its charge to it and transferring charge from the stabilizer-converter 16 through (contact 29) to the cathode of the damper foot diode 19 with a vacuum capacitance, and from it through the anode to the spark gap there is a free electron stacker 20 with the possibility of subsequent absorption of free electrons by the environment: air, earth or water.

 6. A capacitor-type electric energy storage device, option 1 according to claim 3, characterized in that the cathode is made “cold” with a micropic surface.

7. The method of energy storage, option 2, which includes the use of two VK in the NECT, first charge the first one with a full charge, and then discharge it through the stabilizer-converter to the second VK, distributing the charge between the two VK, while the electric capacity of the second VK equal to or greater than the electric capacity of the first VK, at the end of the process, recharging is carried out - the charge is returned from the second VK to the first VK, for this a recharging device is used that is connected to a generator or a standard AC mains without a transformer, increasing or decreasing depending on the charging voltage of the NECT and containing two counter-wound output windings connected to each other and to the diodes, and to the voltage rectifier multiplier so that the voltage rectifier multiplier is fed by their total voltage, and it creates the first VK has a large positive potential, and on the anode of the second VK there is a large negative potential for their recharging, The diodes connected to the windings provide a one-way current flow, while each output winding is connected in its own half-cycle, providing charge transfer from the cathode of the second VC to the cathode of the first VC by controlling the process of monitoring, displaying and controlling the recharge of NECT, which turns on and off the charge it, and also reflects the magnitude of the charge and the state of charge of both VCs.

 8. The method of energy storage, option 2 according to claim 7, characterized in that small-sized devices of electronic and electrical devices and electric vehicles are used as a consumer of NECT, for which a damping lamp diode with a spark gap free electron gadget and a switch connecting the second VK are added to the NECT parallel to the first VC, and in its place a damper diode is installed, with the possibility of redistributing the charge between two VCs in the absence of an AC source for recharging.

 9. The method of energy storage, option 2 according to claim 7, characterized in that NECT are used to power small electronic or electrical devices and use low-voltage VCs of large electric capacity and stabilizers, the electric capacity is determined from ratios that take into account the duration of continuous operation with known energy consumption and allowable losses supply voltage, and the recharge device is mobile.

10. The capacitor-type electric energy storage device, option 2 for implementing the method option 2, comprising two vacuum capacitors, a generator or a standard AC network 9 connected to the input winding D (terminals 40 and 41) of the transformer 30, the multiplier is a voltage rectifier 31 with an input ( pin 48) connected to winding E (pin 42), a common wire (pin 47), connected to winding F (pin 45), and a positive output (pin 46), which creates a large positive potential on the anode of VK 17, and its common wire ( pin 47) connected to the anode m VC 33 and creates a negative potential, E and F of the winding of the transformer 30 are connected at their oppositely directed ends (contacts 43 and 44) to their other ends (contacts 42 and 45) with their cathodes connected to diodes 34 and 35 diodes anodes are connected together and through the block monitoring, display and management of recharge NEKT 32, connected to the cathode (K) VK 17, and contacts 43,44 through the block 32 to the cathode (K) VK 33, and the stand-alone power supply glow 18 rechargeable VK 17 and VK 33, and a damper lamp diode 19, with auto-charging from the stabilizer-converter 16, which can be turned off when the stabilizer-converter 16 is turned off for a long time from the NECT, provides heating of the cathode VK 17, VK 33 and the cathode of the damper lamp diode 19 in continuous mode even with a long-term absence of charging from the stabilizer mash - Converter 16, in turn, block 32 monitoring, display and management of reloading NECT (VK 17 and VK 33), issuing a command to switch the contact group 36 after a full recharge of NECT (VK 17 and VK 33), and transfers the NECT offline mode of operation.

 11. The capacitor-type energy storage device, option 2 of claim 10, characterized in that in the stand-alone mode, the VK 17 connected to the stabilizer-converter 16 (contact 28) gives it its charge, and then through (contact 29) the charge goes to the cathode VK 33 and the process continues until the charge is completely redistributed between VK 17 and VK 33, if there is no AC source 9 for recharging them, the switch 37 connects VK 33 in parallel to VK 17, and in its place connect the cathode of the damper diode 19, the charge goes to lamp damper cathode iodine 19, which also has a vacuum capacitance, and from it through the anode to the spark gap there is a free electron stacker 20, and from it free electrons are absorbed by the environment: air, earth and water, and contacts 38 and 39 are designed for primary charging of NECT (VK 17) from a stationary charger and its recharging.

 12. A capacitor type electric energy storage device, variant 2 according to claim 10 or 11, characterized in that the cathode is made cold with a micropic surface.