DISCOVERING THE METHOD OF EXTRACTING HYDROGEN GAS FROM WATER AND SAVING HYDROGEN GAS WITH HIGH ENERGY EFFICIENCY

Abstract

The discovery of the method of extracting hydrogen gas from water and saving the high-energy hydrogen gas is a system used by acid-lead batteries and their electrolyte replacement, which removes hydrogen from the water during charging, and then the electricity consumed for this purpose. The battery float charge mode is stored in the battery by chemical reactions. Also, by reversible reactions, a little more than the hydrogen gas is released into the normal amount of gas from the battery houses. By this method, the practical steps are to finalize the sample during the Gaseous hydrogen is recommended for industry and industry.

Claims

1. System for extracting hydrogen gas from water and saving high-energy hydrogen gas, has two or more lead acid batteries, the required electrolyte, ie, concentrated potassium hydroxide, an electrical system for the flow of acid batteries, a drop-down battery, and an extraction system Gas.

2. As claimed in clause 1, this system requires at least two lead acid batteries, which should be at least 45 amps in order for the charge current to exceed 5 amperes to enter the required gas. Hydrogen gas is collected from the houses of these batteries. The electrolyte is brought to the tank and the gas is transferred to the reservoir. The electrolyte of these batteries is exchanged and produced by chemical reactions simultaneously with the supply of hydrogen gas.

3. According to claim 1, this system requires potassium hydroxide instead of sulfuric acid to react with the desired chemical reactions. The concentration of electrolyte can be exactly as acid concentration and add to h2o and the overall reaction to The charge and discharge face is as follows: Discharge:pbo2+2koh+2k++pb+oh−−k2o+k2pbo2+h2o+pb(oh)+e− Charge:pb(ohh+k2pbo2+2k+k20+h20+0h 2koh+pbo2+Pb+4koh+o2+h2+2e

4. As stated in clause 1 of the electric system, charging the battery between the batteries has the function of charging the batteries in order to extract the hydrogen gas charge in practice. This system is placed between the batteries and each battery adds a voltage augmentation circuit which is tasked This operation circuit is similar to the charger of a battery that is the source of this other battery. At the output of the circuits, the applied voltage and maximum flow through the potentiometers can be adjusted. (FIG. 2)

5. As claimed in clause 4, the relay is used in the output of the amplifier circuits, which are connected to the timer by the timer. The timer are used to activate the relay for a few minutes and the electric current from the battery to the battery The second is established and at another time, the current of this relay is interrupted and another relay is connected and the current from the second battery is connected to the first battery.

6. As claimed in clause 5, a timer connected to the charge-compensated battery has the function of disconnecting the relays. This time can be set by the timer to get the most gas from the batteries (FIG. 3-number 3).

7. According to claim 1, this system has a drop-down battery, which uses the battery to disconnect and connect circuits, help other batteries to reduce electrical current in augmentation circuits, establish electrical current for the pump to pump the gas in the reservoir (FIG. 4-number 11} (FIG. 3-number 7)

8. According to claim 1, this system has a gas extraction unit that is closed on a container battery house that has the ability to open and close it for the purpose of controlling the houses of the battery and closes on this hollow box until the gas Put the pump into the reservoir (FIG. 1-number 2).

9. According to claim 8, the gas extraction system must be flash-driven before and after the tank to prevent gas or spark leaking into the reservoir and pump.

10. According to claim 8, the gas extraction system should have strong, principled and durable connections to prevent leakage and explosion of hydrogen gas.

Description

DESCRIPTION OF DRAWINGS

[0014] FIG. 1 shows the battery and gas collection point and shows three parts that contain [0015] No. 1: Acidic Lead Battery with Potassium Hydroxide Electrolyte [0016] No. 2: Closed enclosure on battery houses [0017] No. 3: Outlet hose from the chamber to transport hydrogen gas

[0018] FIG. 2—Map 2 illustrates the performance of the voltage-increasing voltage circuits between the batteries, which includes: [0019] No. 1: The first battery [0020] No. 2: The second battery [0021] No. 3: Input wires of the first voltage augmentation circuit [0022] No. 4: The first voltage augmentation circuit [0023] No. 5: Output wires of the first voltage augmentation circuit [0024] No. 6: Output wires of the second voltage augmentation circuit [0025] No. 7: Input wires of the second voltage augmentation circuit [0026] No. 8: Secondary voltage augmentation circuit

[0027] FIG. 3—In Map 3, the relay placement and timer are displayed in the system, which includes: [0028] No. 1: Second voltage voltage augmentation relay [0029] No. 2: Connect the relay to the battery [0030] No. 3: Timer [0031] No. 4: First voltage boosting relay [0032] No. 5: Output Timer Timer to disconnect relays [0033] No. 6: Connect the relay to the battery [0034] No. 7: Battery Drop Down

[0035] FIG. 4 shows the gas extraction system on the map 4 of the batteries. In this map, the electrical system is not shown for better understanding of this system. [0036] No. 1: The first battery [0037] No. 2: The second battery [0038] No. 3: The hose of the first battery outlet [0039] No. 4: Secondary Battery Outlet Hose [0040] No. 5: suction and blow pump [0041] No. 6: Expansion tank or gas collection [0042] No. 7: Gas Outlet [0043] No. 8: Flashback after the tank [0044] No. 9: Flashback before the tank [0045] No. 10: Hose for transferring hydrogen gas from pump to reservoir [0046] No. 11: Drop Down Battery [0047] No. 12: Battery connector for charging the pump to the battery

EXECUTION METHODS

[0048] The invention is based on the method used to extract hydrogen from water, and can sell hydrogen at lower prices, use hydrogen from production in the place of consumption, as well as in other energy-consuming systems such as urban gas in homes, automobiles Generators. It should be explained how the circuits between the batteries can be changed, or other electrical methods for charging electricity can be used that increase gas production. The best part is the use of this system in cars, the dynamo is fully responsible for the circuits and is extracted continuously from the battery of hydrogen gas and the fuel is supplied to the car. If there is a problem in any part of the design, the same part can be repaired or replaced.