A system and a method for water desalination

Abstract

The present invention provides a system and a method for water desalination. In particular, the present invention provides a system and a method for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction. The system (100) includes a chamber (102) for collecting seawater and introducing it into a piezo reactor chamber (104), where micro cavitation bubbles and super vapor are generated. An electromagnetic field reactor (106), with a plurality of magnetrons, increases the electrical energy of the super vapor and charges ions in the seawater. A series of voltage-controlled carbon rods (108) separates the charged ions from the super vapor. The zero-voltage copper chamber with multiple fins (110) facilitates ion sedimentation and neutralizes the electrical charge of the super vapor. Finally, a condenser (112) cools the charged super vapor into liquid form. This innovative technology combines micro cavitation, magnetic field-enhanced ionization, and multi-layer ion extraction, followed by zero-voltage purification and efficient condensation, ensuring high purity and efficiency in converting seawater into drinkable water.

Description

[0001] A SYSTEM AND A METHOD FOR WATER DESALINATION

[0002] FIELD OF INVENTION

[0003] The present invention relates to a system and a method for water desalination. In particular, the present invention provides a system and a method for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction.

[0004] BACKGROUND ART

[0005] Water desalination is a critical process for providing potable water in regions where freshwater resources are scarce. The goal of desalination is to remove salts and other impurities from seawater or brackish water, making it safe for human consumption, agriculture, or industrial use. Desalination dates back centuries, with ancient methods involving simple solar evaporation to collect freshwater from saltwater. Modern desalination techniques began to develop in the mid-20th century, driven by technological advancements and the growing demand for clean water.

[0006] Conventionally, water desalination has relied on techniques such as reverse osmosis, RO and thermal distillation. These methods separate salts and impurities from water to produce fresh, potable water. Reverse osmosis operates by forcing water through a semipermeable membrane under high pressure, while thermal distillation involves heating water to produce vapor, which is then condensed to obtain purified water.

[0007] Some major drawbacks in using conventional desalination methods include high energy consumption, significant operational costs, and environmental concerns. Reverse osmosis membranes are prone to fouling and scaling, requiring frequent maintenance. Additionally, both RO and thermal distillation generate concentrated brine as a byproduct, which poses disposal challenges and risks to marine ecosystems.

[0008] Numerous innovations have been invented to address these challenges, including the application of novel filtration materials, such as carbon-based membranes, electrochemical systems, and magnetic desalination techniques. These approaches often involve enhanced ion extraction mechanisms or the use of advanced energy-efficient configurations. For instance, some designs incorporate charged surfaces, such as carbon rods, to facilitate ion deposition, improving desalination efficiency while reducing energy demands.

[0009] One example of a method and a system for extracting water by cavitation effect is disclosed in Chinese Patent Publication No. CN116514197 (A) (hereinafter referred to as CN 197 A1 Patent entitled “Using method of system for extracting water by cavitation effect” having a publication date of 1 August 2023, Applicant: Institute of Advanced Technology of Heilongjiang Academy of Sciences). CN 197 A1 Patent disclose a simplified method for extracting water using the cavitation effect, addressing challenges in existing seawater desalination systems that rely on cavitation technology, which are often structurally complex and difficult to install or use. The system features a cavitation water lifter equipped with a cavitation device, an electronic cooling sheet, a radiating sheet, and a water collecting tank. CN 197 A1 Patent also disclose a liquid supplementing box connects to the inlet of the cavitation water lifter via a pump, while the outlet of the cavitation water lifter is linked to a pipe that cycles back to the liquid supplementing box. Additionally, the water collecting tank is connected to a water storage tank for collecting purified water. During operation, a pressure pump introduces a liquid mixture into the cavitation water lifter. Inside, the cavitation device generates supercavitation, causing water vapor in the cavitation zone to condense into droplets, which flow out as purified water. Simultaneously, a concentrated liquid is produced as a byproduct.

[0010] Another example of a sea water desalination device is disclosed in Chinese Patent Publication No. CN116239265A (hereinafter referred to as CN 265 A1 Patent entitled “Sea water desalination device based on magnetic field Hall effect and electric field force” having a publication date of 9 June 2023, Applicant: 719th Research Institute of China State Shipbuilding Corp). CN 265 A1 Patent disclose a seawater desalination device that utilizes the magnetic Hall effect and electric field force to improve efficiency and simplify design. The system includes a seawater filter, a seawater pump, and an ion separation tube assembly. The assembly features a rectangular non-metallic flow passage with strong, uniform magnetic and electrostatic fields created by neodymium-iron-boron permanent magnets on the sides and electrode plates above and below. The magnetic and electrostatic fields are orthogonal, enabling effective ion separation. At the end of the flow passage, anion and cation separation plates divide the flow into three chambers: an anion chamber, a neutral water chamber, and a cation chamber, each with a corresponding outlet. This design enhances traditional electrodialysis by simplifying the structure, improving desalination efficiency, and adding the ability to remove neutral particles.

[0011] Another example of a treatment of saline water is disclosed in US Patent Publication No. US2021230026 (A1) (hereinafter referred to as US 026 A1 Patent entitled “Treating saline water and other solvent with magnetic and electric field” having a publication date of 29 July 2021, Applicant: Khalifa University of Science, Technology and Research, KUSTAR). US 026 A1 Patent disclose a liquid desalination system is described that includes a feed line with an inlet to receive liquid and an outlet to discharge it. The system has a magnet attached to the feed line, which creates an oscillating magnetic field that works against the flow of the liquid. By adjusting the frequency and rate of the electromagnetic waves, the system targets specific ions for removal. These waves are tuned to weaken the hydration bonds of the targeted ions, making it easier to remove them. Additionally, the system generates an electric field across the feed line, which helps desalinate the liquid. The electric field attracts sodium ions to the positive electrode and chloride ions to the negative electrode, effectively removing salt from the liquid.

[0012] As outlined above, various desalination methods have been developed to convert seawater into potable water. However, none of the prior art documents disclose the combination of principles of micro cavitation, magnetic field enhancement, and precise ion extraction for seawater salination. The present invention relates to a system and a method where seawater is passed through a piezo reactor to create super vapor. This vapor is exposed to a magnetic field through a magnetron, increasing its energy and generating ions from the minerals. The charged vapor is then directed through carbon rods to attract and remove these ions. The vapor enters a copper chamber grounded to earth, allowing minerals to settle. Finally, the vapor is cooled and condensed back into liquid form. Thus, the problem addressed by the present invention is providing clean, low-mineral water from seawater. Unlike traditional desalination methods, the present invention offers a more sustainable alternative for producing desalinated seawater. SUMMARY OF INVENTION

[0013] The present invention relates to a system and a method for water desalination. In particular, the present invention provides a system and a method for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction.

[0014] One aspect of the present invention provides a system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, the system (100) comprising a chamber (102) for collecting seawater and introducing the seawater in a piezo reactor chamber (104), the piezo reactor chamber (104) for generating micro cavitation bubbles and super vapor from the seawater, an electromagnetic field reactor (106) for increasing an electrical energy of the super vapor for a charged ion inside the seawater by a plurality of a magnetron, a plurality of voltage controlled carbon rods (108) for separating a plurality of charged ions from a charged super vapor, a zero voltage copper chamber with multiple fins (110) for facilitating sedimentation of the plurality of the charged ions extracted from the seawater and converting the super vapor to a neutral in electrical charged and a condenser (112) for cooling the charged super vapor into liquid form.

[0015] Another aspect of the present invention provides the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein the piezo reactor chamber (104) operates at a frequency between 1 MHz and 20 MHz and an amplitude range of 100 watt / hour to 600 watt / hour.

[0016] Yet another aspect of the present invention provides that the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein the plurality of a magnetrons in the electromagnetic field reactor (106) generate an electromagnetic field with a frequency range of 2 GHz to 10 GHz and an amplitude range of 250 watts / hour to 1200 / watt hour with a duration of 0 to 10 seconds.

[0017] Another aspect of the present invention provides the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein the plurality of voltage controlled carbon rods (108) directing the charged super vapor through the plurality of voltage controlled carbon rods arranged in series. Another aspect of the present invention provides the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein wherein the plurality of voltage controlled carbon rods (108) operates at a voltage from 240 volt from 0.1 amp to 1 amp.

[0018] Another aspect of the present invention provides the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein the condenser (112) converts the charged super vapor into fresh water, free from dissolved salts, minerals and other impurities.

[0019] Another aspect of the present invention provides the system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, wherein the zero voltage copper chamber with multiple fins (110) are strategically placed to maximize contact with the super vapor, ensuring thorough purification before the final stage.

[0020] One aspect of the present invention provides a method for converting seawater into fresh water using micro cavitation, magnetic field and ion extraction, the method comprising steps of (200) feeding seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202), feeding the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated a plurality of multiple magnetrons (204), directing a charged super vapor through a plurality of voltage controlled carbon rods (108) arranged in series for attracting a plurality of charged ions from the charged super vapor (206), passing the charged super vapor into a zero voltage copper chamber (110) with multiple fins that is grounded to earth zero voltage for facilitating sedimentation of charged ions extracted from the super vapor (208) and condensing the charged super vapor into liquid form by cooling the charged super vapor (210).

[0021] Another aspect of the present invention provides the method for converting seawater into fresh water using micro cavitation, magnetic field and ion extraction, wherein feeding the seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202) further comprising steps of (300) operating the piezo reactor chamber (104) at frequencies ranging from 1 MHz to 20 MHz (302), forming and collapsing a plurality of tiny bubbles within the seawater through a micro cavitation (304), bursting the plurality of tiny bubbles at a surface reaching extremely high temperatures and pressures 5000 K and 1000 atm respectively (306); and ionizing the super vapor and initiating desalination process (308). Yet another aspect of the present invention provides the method for converting seawater into fresh water using micro cavitation, magnetic field and ion extraction, wherein feeding the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated by multiple magnetrons (204) further comprising steps of (400) amplifying ionization as the super vapor travels through a magnetic field tube (402), increasing an electrical charge of the super vapor (404) and enhancing efficiency of subsequent ion extraction and creating charged ions inside the super vapor (406).

[0022] Yet another aspect of the present invention provides the method for converting seawater into fresh water using micro cavitation, magnetic field and ion extraction, wherein directing the charged super vapor through a series of voltage controlled carbon rods (108) for attracting a plurality of charged ions from the charged super vapor (206) further comprising steps of (500) passing the charged super vapor through a series of three layers, each consisting of 10 charged carbon rods (502) and depositing charged ions, particularly those of salts and minerals, on a surface of the carbon rods to ensures that the super vapor becomes increasingly purified as it moves through each layer (504) and separating the charged ions from the super vapor (506).

[0023] The present invention consists of features and a combination of parts hereinafter fully described and illustrated in the accompanying drawings, it being understood that various changes in the details may be made without departing from the scope of the invention or sacrificing any of the advantages of the present invention. BRIEF DESCRIPTION OF ACCOMPANYING DRAWINGS

[0024] To further clarify various aspects of some embodiments of the present invention, a more particular description of the invention will be rendered by references to specific embodiments thereof, which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the accompanying drawings in which:

[0025] Figure 1 illustrates a system for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction of the present invention.

[0026] Figure 2 is a flowchart illustrating method for converting seawater into fresh water using micro cavitation, magnetic field enhancement and precise ion extraction of the present invention.

[0027] Figure 3 is a flowchart illustrating method of feeding seawater into a piezo reactor chamber and transforming the seawater into a super vapor.

[0028] Figure 4 is a flowchart illustrating method of feeding the super vapor into an electromagnetic field reactor and exposing the super vapor to a magnetic field tube generated a plurality of multiple magnetrons.

[0029] Figure 5 is a flowchart illustrating a method for directing the charged super vapor through a series of voltage controlled carbon rods for attracting a plurality of charged ions from the charged super vapor. DETAILED DESCRIPTION OF THE DRAWINGS

[0030] The present invention relates to a system and a method for water desalination. In particular, the present invention provides a system and a method for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction.

[0031] Hereinafter, this specification will describe the present invention according to the preferred embodiments. It is to be understood that limiting the description to the preferred embodiments of the invention is merely to facilitate discussion of the present invention and it is envisioned without departing from the scope of the appended claims.

[0032] Reference is first made to Figure 1. Figure 1 illustrates a system for converting seawater into less salty or mineralized water, making it suitable for diverse uses combining the principles of micro cavitation, magnetic fields, and ion extraction of the present invention.

[0033] The system for converting seawater comprising a chamber (102) for collecting seawater and introducing the seawater in a piezo reactor chamber (104); the piezo reactor chamber (104) for generating micro cavitation bubbles and super vapor from the seawater. The piezo reactor chamber (104) forces seawater to undergo cavitation, transitioning it into a super vapor stage. The piezo reactor chamber (104) operates at a frequency between 1 MHz and 20 MHz and an amplitude range of 100 watt / hour to 600 watt / hour. This vapor phase is crucial because chemical bonds, such as those holding dissolved salts and minerals in water, are much easier to break or manipulate in the vapor state. The reduced intermolecular forces and increased energy in the super vapor phase facilitate more efficient separation of ions, improving the overall desalination process.

[0034] An electromagnetic field reactor (106) for increasing an electrical energy of the super vapor for a charged ion inside the seawater by a plurality of a magnetron so that the charged ion inside seawater can be attracted to the carbon rod. The plurality of a magnetrons in the electromagnetic field reactor (106) generate an electromagnetic field with a frequency range of 2 GHz to 10 GHz and an amplitude range of 250 watts / hour to 1200 / watt hour with a duration of 0 to 10 seconds.

[0035] A plurality of voltage controlled carbon rods (108) for separating a plurality of charged ions from a charged super vapor. The plurality of voltage controlled carbon rods (108) directing the charged super vapor through the plurality of voltage controlled carbon rods arranged in series. The plurality of voltage controlled carbon rods (108) operates at a voltage from 240 volt from 0.1 amp to 1 amp. A plurality of voltage controlled carbon rods (108) are designed to attract and capture charged ions, particularly the minerals dissolved in seawater. The applied voltage creates an electric field that draws these ions toward the rods, where they become embedded or deposited on the surface. This method is highly effective in removing heavy metals and other unwanted ions, ensuring that the remaining water is purified. Additionally, the use of voltage control allows precise tuning to target specific ions, enhancing the efficiency of the desalination process.

[0036] A zero-voltage copper chamber with multiple fins (110) is utilized to facilitate the sedimentation of charged ions extracted from seawater and neutralize the electrical charge of the super vapor. The plurality of voltage controlled carbon rods (108) are specifically designed to attract and capture salt ions and other impurities from the super vapor efficiently. The zero-voltage copper chamber with multiple fins (110), equipped with multiple fins, creates a stable zero-voltage environment that not only neutralizes the remaining electrical charge in the vapor but also captures residual ionized heavy metals. The fins increase the surface area, promoting effective heat dissipation and enhancing the condensation of the super vapor into liquid form. This design ensures that sedimented impurities are collected in an organized manner, simplifying maintenance and cleaning processes. Additionally, the chamber's grounded environment prevents any re-ionization of the purified vapor, ensuring the production of high-quality desalinated water with minimal energy consumption.

[0037] A condenser (112) for cooling the charged super vapor into liquid form. The result is pure, drinkable water free from salts, minerals, and other impurities. The condensation process is carefully controlled to maintain the purity of the water, ensuring that it is suitable for human consumption. The system operates within a precisely controlled environment, where the temperature is maintained just above freezing at 0°C, promoting efficient condensation without compromising the quality of the water. To further enhance the purity, the system is equipped with voltage earthing to prevent any static interference, which could potentially affect the integrity of the condensation process. Additionally, the condenser is designed with advanced filtration and temperature regulation mechanisms, ensuring that only the purest super vapor is condensed. The process is energy-efficient, minimizing waste while maximizing the production of clean water. Finally, the collected pure water undergoes additional monitoring for quality assurance, ensuring that the final output meets the highest standards for human consumption. Reference is now made to Figure 2, 3, 4 and 5 respectively. Figure 2 is a flowchart illustrating method for converting seawater into fresh water using micro cavitation, magnetic field enhancement and precise ion extraction of the present invention. Figure 3 is a flowchart illustrating method of feeding seawater into a piezo reactor chamber and transforming the seawater into a super vapor. Figure 4 is a flowchart illustrating method of feeding the super vapor into an electromagnetic field reactor and exposing the super vapor to a magnetic field tube generated a plurality of multiple magnetrons. Figure 5 is a flowchart illustrating a method for directing the charged super vapor through a series of voltage controlled carbon rods for attracting a plurality of charged ions from the charged super vapor.

[0038] The method comprising steps of feeding seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202), feeding the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated a plurality of multiple magnetrons (204), directing a charged super vapor through a plurality of voltage controlled carbon rods (108) arranged in series for attracting a plurality of charged ions from the charged super vapor (206), passing the charged super vapor into a zero voltage copper chamber (110) with multiple fins that is grounded to earth zero voltage for facilitating sedimentation of charged ions extracted from the super vapor (208) and condensing the charged super vapor into liquid form by cooling the charged super vapor (210). Feeding of the seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202) further comprising steps of (300) operating the piezo reactor chamber (104) at frequencies ranging from 1 MHz to 20 MHz (302), forming and collapsing a plurality of tiny bubbles within the seawater through a micro cavitation (304), bursting the plurality of tiny bubbles at a surface reaching extremely high temperatures and pressures 5000 K and 1000 atm respectively (306); and ionizing the super vapor and initiating desalination process (308). Feeding of the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated by multiple magnetrons (204) further comprising steps of (400) amplifying ionization as the super vapor travels through a magnetic field tube (402), increasing an electrical charge of the super vapor (404) and enhancing efficiency of subsequent ion extraction and creating charged ions inside the super vapor (406). Directing the charged super vapor through a series of voltage controlled carbon rods (108) for attracting a plurality of charged ions from the charged super vapor (206) further comprising steps of (500) passing the charged super vapor through a series of three layers, each consisting of 10 charged carbon rods (502) and depositing charged ions, particularly those of salts and minerals, on a surface of the carbon rods to ensures that the super vapor becomes increasingly purified as it moves through each layer (504) and separating the charged ions from the super vapor (506).

[0039] Results

[0040] Table 1 shows the test result of seawater from Pantai Morib with a salt level of 2.48%, which has been converted into water with a salt level of 0.06%.

[0041] No.

[0042]

[0043] 2.48% from Pantai Morib

[0044] initial salt percentage (highest sea salt level 3.5%)

[0045]

[0046] Desalination Proof of concept 700 watt / hour

[0047] system energy

[0048]

[0049] Desalinated water salt percentage

[0050]

[0051] Water tab water standard 0.02%

[0052]

[0053] Next step of process for Oasis Water can be domestically, for Dynamics drink need further membrane and UV treatment

[0054]

[0055] Table 1

[0056] Heavy metal content after salinity process.

[0057] The lab results showed that the system is able to achieve the parameter set by world health organization, WHO as shown in Table 2. Further optimisation can produce water of required qualities. Metal Raw sea water WHO / EPA limit (ppm) 1st test 2nd test after (ppm):

[0058] (ppm) optimise EMW

[0059] tppro}

[0060] As (arsenic) ND ND ND 0.01

[0061] Al (aluminium) ND ND ND 0.1 - 0.2

[0062] K (potassium) 968.0 0.44 0.017 1 – 5

[0063] Cu (copper) 0.0054 0.0055 0.0072 2

[0064] Ca(calcium) 558 0.12 0.55 30 – 100

[0065] Cd(cadmium) 0.0076 0.0068 ND 0.003

[0066] Fe(iron) 0.079 ND ND 0.3

[0067] Hg(mercury) ND ND ND 0.006

[0068] 1388 1J0S 10-50 Mnfmangane&&) 0.0088 0,0077 ND 0.4 (WHO W 0.05

[0069] (EPA) j JMrtral _ 9077 215 "53 Less 200

[0070] Zn (zinc) 0.0055 0.005 ND 3 – 5

[0071] Pb (lead) 0.0043 0.0031 ND 0.01

[0072]

[0073] Ni (nickel) 0.0075 0.005 ND 0.07

[0074] WHO = World Health Organisation

[0075] EPA = Environment Protection Agency USA

[0076]

[0077] EMW “ HcoSrotnagnetic

[0078] Table 2

[0079] Throughout this specification, unless the context requires otherwise, the word “comprise”, or variations such as “comprises” or “comprising”, will be understood to imply the inclusion of a stated step or element or integer or group of steps or elements or integers, but not the exclusion of any other step or element or integer or group of steps, elements or integers. Thus, in the context of this specification, the term “comprising” is used in an inclusive sense and thus should be understood as meaning “including principally, but not necessarily solely”.

Claims

CLAIMS1. A system for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, the system (100) comprising;a chamber (102) for collecting seawater and introducing the seawater in a piezo reactor chamber (104); the piezo reactor chamber (104) for generating micro cavitation bubbles and super vapor from the seawater;an electromagnetic field reactor (106) for increasing an electrical energy of the super vapor for a charged ion inside the seawater by a plurality of a magnetron;a plurality of voltage controlled carbon rods (108) for separating a plurality of charged ions from a charged super vapor;a zero voltage copper chamber with multiple fins (110) for facilitating sedimentation of the plurality of the charged ions extracted from the seawater and converting the super vapor to a neutral in electrical charged; anda condenser (112) for cooling the charged super vapor into liquid form.

2. The system as claimed in claim 1, wherein the piezo reactor chamber (104) operates at a frequency between 1 MHz and 20 MHz and an amplitude range of 100 watt / hour to 600 watt / hour.

3. The system as claimed in claim 1, wherein the plurality of a magnetrons in the electromagnetic field reactor (106) generates an electromagnetic field with a frequency range of 2 GHz to 10 GHz and an amplitude range of 250 watts / hour to 1200 / watt hour with a duration of 0 to 10 seconds.

4. The system as claimed in claim 1, wherein the plurality of voltage controlled carbon rods (108) directing the charged super vapor through the plurality of voltage controlled carbon rods arranged in series.

5. The system as claimed in claim 5, wherein the plurality of voltage controlled carbon rods (108) operates at a voltage from 240 volt from 0.1 amp to 1 amp.

6. The system as claimed in claim 1, wherein the condenser (112) converts the charged super vapor into fresh water, free from dissolved salts, minerals and other impurities.

7. The system as claimed in claim 1, wherein the zero voltage copper chamber with multiple fins (110) are strategically placed to maximize contact with the super vapor, ensuring thorough purification before the final stage.

8. A method for converting seawater into fresh water using micro cavitation, magnetic fields and ion extraction, the method comprising steps of (200):feeding seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202);feeding the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated a plurality of multiple magnetrons (204);directing a charged super vapor through a plurality of voltage controlled carbon rods (108) arranged in series for attracting a plurality of charged ions from the charged super vapor (206);passing the charged super vapor into a zero voltage copper chamber (110) with multiple fins that is grounded to earth zero voltage for facilitating sedimentation of charged ions extracted from the super vapor (208); and condensing the charged super vapor into liquid form by cooling the charged super vapor (210).

9. The method as claimed in claim 8, wherein feeding the seawater into a piezo reactor chamber (104) and transforming the seawater into a super vapor (202) further comprising steps of (300);operating the piezo reactor chamber (104) at frequencies ranging from 1 MHz to 20 MHz (302);forming and collapsing a plurality of tiny bubbles within the seawater through a micro cavitation (304);bursting the plurality of tiny bubbles at a surface reaching extremely high temperatures and pressures 5000 K and 1000 atm respectively (306); and ionizing the super vapor and initiating desalination process (308).

10. The method as claimed in claim 8, wherein feeding the super vapor into an electromagnetic field reactor (106) and exposing the super vapor to a magnetic field tube generated by multiple magnetrons (204) further comprising steps of (400);amplifying ionization as the super vapor travels through a magnetic field tube (402);increasing an electrical charge of the super vapor (404); andenhancing efficiency of subsequent ion extraction and creating charged ions inside the super vapor (406).

11. The method as claimed in claim 8, wherein directing the charged super vapor through a series of voltage controlled carbon rods (108) for attracting a plurality of charged ions from the charged super vapor (206) further comprising steps of (500);passing the charged super vapor through a series of three layers, each consisting of 10 charged carbon rods (502); anddepositing charged ions, particularly those of salts and minerals, on a surface of the carbon rods to ensures that the super vapor becomes increasingly purified as it moves through each layer (504); andseparating the charged ions from the super vapor (506).

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