RU2008132471A - METHOD FOR ENERGY STORAGE (2 OPTIONS) AND CONDENSER TYPE ELECTRIC ENERGY STORAGE FOR IMPLEMENTATION OF METHOD (2 OPTIONS) - Google Patents

Abstract

1. The method of electric energy storage, including the accumulation of free electron charge in vacuum, creating a negative negative volume 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, when In this case, the electric capacity of a stationary VC is 100-1000 times greater than the electric capacity of all simultaneously charged NECTs with their VC, and the stationary VC is charged from a generator or a standard network ennogo current through the transformer, increasing or reducing, depending on the charging voltage NEKT and multiplier-rectifier voltage connected to the cathode of the stationary VC, and its anode, the free end of the transformer secondary winding and the rectifier-multiplier common wire grounded; moreover, the NEKT received by the mobile VC charge is used to supply its consumers directly or through known stabilizers or converters, the discharging VC creates an electric current in the load, which, passing through the load, enters the cathode of the damper lamp diode, which has a constructive vacuum electric capacity and accumulates a charge if the arrester connected to its anode to drain free electrons into the environment, air, water and the ground for a short time cannot provide the necessary discharge current, s 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

Claims (12)

1. The method of electric energy storage, including the accumulation of free electron charge in vacuum, creating a negative negative volume 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, when In this case, the electric capacity of a stationary VC is 100-1000 times greater than the electric capacity of all simultaneously charged NECTs with their VC, and the stationary VC is charged from a generator or a standard network ennogo current through the transformer, increasing or reducing, depending on the charging voltage NEKT and multiplier-rectifier voltage connected to the cathode of the stationary VC, and its anode, the free end of the transformer secondary winding and the rectifier-multiplier common wire grounded; moreover, the NEKT received by the mobile VC charge is used to supply its consumers directly or through known stabilizers or converters, the discharging VC creates an electric current in the load, which, passing through the load, enters the cathode of the damper lamp diode, which has a constructive vacuum electric capacity and accumulates a charge if the arrester connected to its anode to drain free electrons into the environment, air, water and the ground for a short time cannot provide the necessary discharge current, s 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 controlled 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. 2. The method according to claim 1, characterized in that it is used for transport devices and use high NECT charge voltages, and the VC and the damping diode are placed in electromagnetic screens, while for obtaining high power in the load, sufficiently small currents are used, and as a spark gap use the vehicle body, on which antennas can be installed to drain free electrons, while the body is protected from corrosion (option 1). 3. The method of energy storage, including the use of two VK in the NECT, the first one first gets a full charge, and then discharged through the load 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 the process is recharged - 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 network through a transformer that increases or decreases in charge depending on the charging voltage of the NECT and containing two counter-wound output windings connected to each other and with diodes, and with a voltage rectifier multiplier so that the voltage rectifier multiplier is fed by their total voltage, and it creates a large positive potential on the anode of the first VK on the anode of the second VK there is a large negative potential for overcharging, the diodes connected to the windings provide a one-way current flow, while the output windings each work in their own half-cycle, providing switching The charge is transferred from the cathode of the second VC to the cathode of the first VC, the process is controlled by the NECT charge control, display and control unit, which turns the charge mode on and off and also reflects the charge value and the charge state of both VK. 4. The method according to claim 3, characterized in that the NECT is used for small electronic and electrical devices and for electric vehicles, and a damper lamp diode with a free electron discharge arrester and a switch connecting the second VK parallel to the first VK are added to it, and place a damping diode, this is necessary when redistributing the charge between two VK, when there is no AC source for recharging. 5. The method according to claim 3, characterized in that the NECTs are used to power small electronic or electrical devices and use low-voltage VCs with large electric capacities and stabilizers, and the electric capacities are determined from ratios that take into account the duration of continuous operation with known power consumption and permissible losses of supply voltage, and recharge device perform mobile (option 2). 6. A capacitor-type electric energy storage device (NECT) with one vacuum encoder, comprising a generator or a standard AC network 9 connected to input winding B (terminals 21 and 22) of transformer 8, a voltage rectifier 11 with input (terminal 27), common a 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 voltage rectifier (terminal 27) is connected to the output winding C ( terminal 23) of transformer 8, other the end of which (terminal 24) is connected to the ground terminal 7 and the common wire (terminal 26) of the voltage rectifier 11 is connected to this, and the control and display unit for the state of the stationary stationary VK 12, the control, display and charge control of the NECT (VK 17) 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 in the recovery mode of the charge of VK 12 from this NECT, in addition, in a stationary charging device there is a power supply unit for glow 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 by a distance L, providing a safe "step voltage", the distance L is determined from the ratio L≥U _3.6.7max [B] / 50 [B / M] = L [M], where U _3.6,7max is the maximum voltage occurring between the ground contacts 6 and 7 when the VK 12 is fully charged; 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 50V at U _3.6.7max. 7. NECT according to claim 6, 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 recharging from the stabilizer-converter 16, which ensures heating of the cathode VK 17 and the cathode of the damper lamp diode 19 in continuous mode long-term lack of recharging from the stabilizer-converter 16. 8. NECT according to claim 6, characterized in that in stand-alone mode VK 17 connected to its load (terminal 28) gives off its charge, and from the load through (terminal 29) the charge flows to the cathode of the damper foot diode 19, which also has vacuum capacity, and from it through the anode to the spark gap-stacker of free electrons 20, and from it free electrons are absorbed by the environment: air, earth or water. 9. NECT according to claim 6, characterized in that the cathode is made cold with a micropic surface providing the best return of free electrons from its surface (option 1). 10. A capacitor type electric energy storage device containing a generator or a standard AC network 9 connected to the input winding D (terminals 40 and 41) of the transformer 30, a voltage rectifier 31 with an input (terminal 48) connected to the winding E (terminal 42) , a common wire (terminal 47) connected to the winding F (terminal 45), and a positive output (terminal 46), which creates a large positive potential on the VK 17 anode, and its common wire (terminal 47) is connected to the VK 33 anode and creates a negative potential winding E and F transformer 30 p connected with their opposite ends (pins 43 and 44) to their other ends (pins 42 and 45), diodes 34 and 35 are connected with their cathodes, the anode of the diodes are connected together and through the monitoring, display and recharge control unit NEKT 32 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 of the glow 18 rechargeable VK 17 and VK 33 and the damper lamp diode 19 with self-recharging from the stabilizer-converter 16, which can be turned off for a long time disconnecting the load from the NECT, ensure heating 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 NECT control unit, display and control 32 (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), puts the NECT in offline mode. 11. NECT according to claim 10, characterized in that in stand-alone mode VK 17 connected to its load (terminal 28) gives its charge to it, and from the load through (terminal 29) the charge enters the cathode VK 33 and the process continues until the charge is 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 the cathode of the lamp damper diode 19 having also a vacuum capacity, and from it through ano d to the spark gap-stacker of free electrons 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. NECT according to claim 10 or 11, characterized in that the cathode is made cold with a micropic surface providing the best return of free electrons from its surface (option 2).