PORTABLE HYDRATION SYSTEM TO ENHANCE WATER MICRO-CLUSTERING

Abstract

The present disclosure provides a portable hydration enhancement system inducing micro-clustering of water molecules. Said system includes a generator producing a specific energy field that influences hydrogen bonds among water molecules, a treatment chamber that receives water and exposes it to said energy field, a flow regulator managing the water flow rate through the treatment chamber to optimise energy field interaction, and an outlet dispensing micro-clustered water. Said system potentially improves cellular hydration by enabling the formation of smaller water clusters, facilitating more efficient absorption within the body. Dated 11 November 2024 Jigneshbhai Mungalpara IN/PA- 2640 Agent for the Applicant

Specification

Description:PORTABLE HYDRATION SYSTEM TO ENHANCE WATER MICRO-CLUSTERING
Field of the Invention
[0001] The present disclosure generally relates to hydration systems. Further, the present disclosure particularly relates to systems for inducing micro-clustering of water molecules.
Background
[0002] The background description includes information that may be useful in understanding the present invention. It is not an admission that any of the information provided herein is prior art or relevant to the presently claimed invention, or that any publication specifically or implicitly referenced is prior art.
[0003] Hydration remains a fundamental factor in sustaining cellular functions across biological systems. Water intake plays a primary role in supporting various physiological processes, influencing both cellular and organ-level functions. Conventional hydration methods focus on maintaining adequate water intake, relying on the assumption that sufficient water consumption alone meets the body's hydration needs. However, recent studies indicate that the structural arrangement of water molecules, particularly the clustering pattern of water molecules, may play a significant role in determining how efficiently water is absorbed and utilized at a cellular level. A need therefore exists to explore hydration methods that go beyond mere quantity and address the quality of water molecules in relation to bioavailability and absorption efficiency.
[0004] Several conventional approaches have sought to improve water quality and hydration benefits through water structuring techniques. A widely recognized approach in the art is the utilization of mineral-based filters, which are used to alter water properties to support better hydration. Such filters typically rely on materials like zeolite, activated charcoal, or tourmaline to modify certain physical and chemical properties of water. While mineral-based filtration is beneficial in removing impurities, such systems do not directly address water molecule clustering or significantly improve the bioavailability of water at a cellular level. Consequently, although mineral-based filtration systems improve water quality in terms of purity, such systems fall short in enhancing hydration benefits at the molecular level, leaving the bioavailability aspect largely unaddressed.
[0005] Another established method focuses on electrolysis-based water ionizers. Such ionizers split water into acidic and alkaline components, with the alkaline component believed to offer enhanced hydration benefits. Such devices typically apply an electric current through electrodes to separate ions within the water, producing a higher concentration of negatively charged ions in alkaline water. Although electrolysis-based ionizers adjust the pH levels and are claimed to provide potential benefits, they do not necessarily impact the clustering of water molecules or their structural configuration. Furthermore, studies reveal that the efficacy of ionized water in enhancing cellular hydration remains inconclusive, as pH adjustments do not inherently promote water molecule clustering or increase cellular absorption rates.
[0006] Ultrasonic or vibration-based devices represent another technique that has been explored for enhancing water properties. These systems expose water to ultrasonic waves or mechanical vibrations in an attempt to influence molecular structure. Ultrasonic-based methods aim to reduce the clustering size of water molecules, potentially promoting a more compact molecular arrangement. Despite the potential benefits of reducing molecule clusters, ultrasonic methods require high energy input and may lack consistency in cluster formation, particularly when applied in portable devices. Furthermore, such devices tend to have limited durability and may not maintain long-term effectiveness. The inconsistent clustering effect achieved through ultrasonic devices further diminishes the reliability of such devices for continuous hydration enhancement, thus limiting widespread adoption.
[0007] A further approach in the art involves magnetic water treatment systems, which expose water to magnetic fields to influence molecular alignment. Magnetic treatment methods are often employed in agricultural and industrial applications to reduce scaling and improve water absorption in plants. The basic principle underlying magnetic water treatment is the alignment of water molecules under a magnetic field, which can potentially alter intermolecular forces. However, such systems face several limitations when applied to personal hydration. Studies suggest that magnetic alignment may provide temporary molecular changes but often fails to induce stable water clusters that would be necessary for enhancing cellular absorption. Additionally, the inconsistency and transient nature of magnetic effects on water structure further reduce the practicality of magnetic systems for personal hydration purposes.
[0008] In light of the above discussion, there exists an urgent need for solutions that overcome the limitations associated with conventional systems and techniques for enhancing hydration through the restructuring of water molecules.
Summary
[0009] The following presents a simplified summary of various aspects of this disclosure in order to provide a basic understanding of such aspects. This summary is not an extensive overview of all contemplated aspects, and is intended to neither identify key or critical elements nor delineate the scope of such aspects. Its purpose is to present some concepts of this disclosure in a simplified form as a prelude to the more detailed description that is presented later.
[00010] The following paragraphs provide additional support for the claims of the subject application.
[00011] An objective of the present disclosure is to enhance hydration efficiency by facilitating micro-clustering of water molecules, thereby promoting better cellular absorption of water. The system of the present disclosure aims to provide a portable hydration enhancement device that generates micro-clustered water by influencing hydrogen bonds among water molecules.
[00012] In an aspect, the present disclosure provides a portable hydration enhancement system inducing micro-clustering of water molecules. Said system includes a generator to produce a specific energy field impacting hydrogen bonds, a treatment chamber that receives water and exposes it to said energy field, a flow regulator to control water flow rate for optimized energy interaction, and an outlet to dispense micro-clustered water.
[00013] Further, the system enhances hydration bioavailability through electromagnetic resonance in the generator, promotes micro-cluster stability with chamber material, optimizes micro-cluster size with flow control, and optionally maintains water temperature for cluster consistency.
Brief Description of the Drawings
[00014] The features and advantages of the present disclosure would be more clearly understood from the following description taken in conjunction with the accompanying drawings in which:
[00015] FIG. 1 illustrates a portable hydration enhancement system for inducing micro-clustering of water molecules, in accordance with the embodiments of the present disclosure.
[00016] FIG. 2 illustrates a class diagram of the portable hydration enhancement system, in accordance with the embodiments of the present disclosure.
Detailed Description
[00017] In the following detailed description of the invention, reference is made to the accompanying drawings that form a part hereof, and in which is shown, by way of illustration, specific embodiments in which the invention may be practiced. In the drawings, like numerals describe substantially similar components throughout the several views. These embodiments are described in sufficient detail to claim those skilled in the art to practice the invention. Other embodiments may be utilized and structural, logical, and electrical changes may be made without departing from the scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims and equivalents thereof.
[00018] The use of the terms "a" and "an" and "the" and "at least one" and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The use of the term "at least one" followed by a list of one or more items (for example, "at least one of A and B") is to be construed to mean one item selected from the listed items (A or B) or any combination of two or more of the listed items (A and B), unless otherwise indicated herein or clearly contradicted by context. The terms "comprising," "having," "including," and "containing" are to be construed as open-ended terms (i.e., meaning "including, but not limited to,") unless otherwise noted. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., "such as") provided herein, is intended merely to better illuminate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
[00019] Pursuant to the "Detailed Description" section herein, whenever an element is explicitly associated with a specific numeral for the first time, such association shall be deemed consistent and applicable throughout the entirety of the "Detailed Description" section, unless otherwise expressly stated or contradicted by the context.
[00020] As used herein, the term "portable hydration enhancement system" refers to any device structured to increase the hydration benefits of water by altering the molecular arrangement of water molecules. Such a system induces micro-clustering within the water, potentially making the water more bioavailable for cellular absorption. A portable hydration enhancement system may be used in diverse environments, including domestic, medical, athletic, and travel applications, allowing users to access water that is more readily absorbed by the body. Said system typically incorporates a generator that produces an energy field for restructuring water, a treatment chamber where the clustering occurs, a flow regulator to control water movement through said chamber, and an outlet for dispensing water after treatment. Additionally, a portable hydration enhancement system may include supplementary features, such as filters or temperature controls, to optimize hydration quality further. Such systems are used across various sectors to promote optimal hydration benefits while maintaining a compact, portable design.
[00021] As used herein, the term "generator" refers to any device within a portable hydration enhancement system that creates an energy field intended to alter the hydrogen bonds among water molecules. Said generator influences the structural arrangement of water molecules to facilitate the formation of micro-clusters, which are smaller molecular groupings believed to enhance water absorption by cells. Such a generator may rely on various energy sources, including but not limited to electromagnetic resonance, low-frequency magnetic fields, or similar energy fields capable of impacting molecular configurations. The generator may be adjustable to emit a range of frequencies suited to different types of water sources or hydration needs. Furthermore, generators may vary in size and power based on the device's portability requirements, making them adaptable for both individual and larger scale applications. Thus, the generator serves a central role in enabling the molecular restructuring of water necessary for enhanced hydration.
[00022] As used herein, the term "treatment chamber" refers to an enclosed area within a portable hydration enhancement system where water is exposed to an energy field generated by the generator. Said treatment chamber is structured to receive water, allowing the energy field to act upon the water molecules to facilitate micro-cluster formation. Such treatment chambers are constructed from materials that may enhance energy field absorption by water molecules, thereby promoting the stability of the resultant micro-clusters. The design of the treatment chamber may include specific internal geometries, which aid in the even distribution of the energy field across water molecules. Additionally, the treatment chamber may vary in size and configuration to optimize the flow and exposure time of water within, which can further support the formation and stabilization of smaller water clusters. Treatment chambers are used within the system to perform the essential function of creating micro-clustered water.
[00023] As used herein, the term "flow regulator" refers to any component within a portable hydration enhancement system that manages the flow rate of water through the treatment chamber. Said flow regulator is operable to control the rate at which water enters and moves through the chamber, ensuring that water molecules receive adequate exposure to the energy field for effective micro-cluster formation. Such a flow regulator may be mechanical or electronic, capable of adjusting the water flow to suit the system's requirements. The flow regulator may be set to maintain a specific residence time within the treatment chamber, where the duration supports the stability of the micro-clusters produced. Flow regulators are particularly valuable in optimizing hydration quality by providing consistent control over water exposure to the energy field, contributing to the efficient functioning of the hydration enhancement system.
[00024] As used herein, the term "outlet" refers to any component within a portable hydration enhancement system that dispenses micro-clustered water from the device after treatment within the chamber. Said outlet serves as the point of exit for water that has undergone the micro-clustering process, making it available for consumption. Such an outlet may include a filtration mechanism, which removes particulate matter or other impurities, ensuring that only purified, micro-clustered water is dispensed. Outlets may be equipped to control the flow of water being dispensed, allowing users to access treated water at a preferred rate. Outlets are essential within the hydration system, serving as the final stage in delivering micro-clustered water for effective hydration.
[00025] FIG. 1 illustrates a portable hydration enhancement system for inducing micro-clustering of water molecules, in accordance with the embodiments of the present disclosure. In an embodiment, a generator within the portable hydration enhancement system produces a specified energy field directed toward influencing hydrogen bonds present among water molecules. Said generator may comprise an electromagnetic resonance device, which emits frequencies that interact with the water molecules. The generated energy field can alter the spatial orientation of water molecules, creating a shift in hydrogen bond structures that encourages the formation of smaller clusters. The generator may be configured to vary the emitted frequency based on specific hydration requirements or types of water sources. For instance, electromagnetic resonance frequencies may range from low to mid-range, depending on the extent of molecular reconfiguration desired. In one embodiment, the generator may incorporate control circuits allowing manual or automatic adjustments to the energy field, thereby modifying the intensity or frequency in response to environmental variables. To ensure effective application of the energy field, the generator may be coupled with materials that promote targeted energy dispersion, thus maximizing the impact on hydrogen bonds. In some configurations, said generator may operate in tandem with temperature control mechanisms to support consistent energy transmission. The generator's position within the system can be selected to optimize the exposure of incoming water, thereby increasing the probability of achieving the desired micro-clustered water structure.
[00026] In an embodiment, a treatment chamber is structured to receive water and facilitate exposure to the energy field generated by the generator, thereby promoting micro-cluster formation among water molecules. Said treatment chamber may be constructed of materials conducive to absorbing and transmitting the energy field, such as certain polymers or metal alloys that amplify or sustain energy interaction with the water molecules. The internal geometry of the treatment chamber may be designed to guide water along a predetermined path, maximizing contact with the energy field. Such geometry may include specific angles, curves, or surfaces that influence the molecular flow, ensuring even distribution of the energy field across the water molecules. The treatment chamber may also include insulation to maintain an optimal temperature, supporting the stabilization of the micro-clustered molecular structure. In another embodiment, the treatment chamber may incorporate multiple compartments or flow channels, each dedicated to specific phases of the clustering process. Such a structure allows for prolonged exposure to the energy field, promoting consistency in the clustering effect achieved. Materials within the treatment chamber may be selected for compatibility with water, preventing any interaction that could alter the chemical composition of the treated water. Additionally, the chamber may contain sensors that monitor temperature, flow rate, or other variables to support the reliable operation of the micro-clustering process.
[00027] In an embodiment, a flow regulator is operable to control the rate at which water flows through the treatment chamber, thereby optimizing the interaction between water molecules and the energy field. The flow regulator may be configured to maintain a specific flow rate that maximizes the residence time of water within the treatment chamber. Said flow rate can be adjusted based on requirements for micro-cluster size, which may vary depending on the intended application. In one configuration, the flow regulator may be mechanical, using adjustable valves or pistons to set the water movement speed through the chamber. In another configuration, the flow regulator may incorporate electronic controls, allowing for automated flow adjustments that respond to feedback from sensors monitoring conditions within the chamber. Such controls may be programmed to adjust flow rate in response to environmental factors, such as temperature or pressure fluctuations. The flow regulator may also support manual adjustment, enabling users to customize the hydration properties of the dispensed water. In certain embodiments, the flow regulator may work in tandem with sensors within the treatment chamber to monitor real-time data on flow dynamics, ensuring that water maintains an optimal flow rate conducive to effective micro-clustering. The structure of the flow regulator may be integrated into the treatment chamber or positioned externally, depending on space and design considerations of the portable hydration system.
[00028] In an embodiment, an outlet is provided to dispense micro-clustered water for consumption after treatment within the chamber. Said outlet may include a filtering mechanism designed to remove particulate matter or impurities from the water, ensuring that only purified, micro-clustered water is dispensed. The outlet may further include a flow control valve that regulates the rate of dispensed water, allowing users to select a preferred dispensing speed. In one configuration, the outlet may include antimicrobial materials to prevent contamination, thereby maintaining water purity throughout the dispensing process. In another configuration, the outlet may comprise a detachable nozzle that facilitates easy cleaning and maintenance, ensuring continued system hygiene. Said outlet may be located at the base of the treatment chamber or another accessible area of the system for user convenience. The outlet may be manually operable or electronically controlled, providing additional customization for dispensing needs. In certain embodiments, the outlet may include temperature regulation features, maintaining water at a stable temperature until dispensing, which may be particularly beneficial in environments where temperature fluctuations could affect water quality.
[00029] In an embodiment, the generator comprises an electromagnetic resonance device that emits frequencies specifically selected to alter hydrogen bond structures within water molecules. Said electromagnetic resonance device is structured to apply an energy field that interacts directly with the hydrogen bonds, causing them to rearrange and form smaller clusters. The frequency emitted by the electromagnetic resonance device is optimized to create a stable effect on hydrogen bonds, promoting efficient micro-cluster formation. The frequency range may be chosen based on the molecular structure of water and the desired characteristics of the clustered water. The electromagnetic resonance device may include controls for adjusting frequency output to maintain stable resonance with the hydrogen bonds within the water molecules, ensuring that each molecule's hydrogen bonds are uniformly influenced. The structure of the electromagnetic resonance device may allow for emission of single or multiple frequencies depending on the requirements of the hydration process. The electromagnetic resonance device may be constructed with materials that enhance resonance effects, allowing it to produce precise frequencies that align with the natural oscillation patterns of water molecules. Placement of the electromagnetic resonance device within the system may be optimized to ensure full exposure of water molecules to the emitted energy field. Additionally, the electromagnetic resonance device may include shielding to contain the emitted energy field within the treatment chamber, minimizing external interference with the clustering process.
[00030] In an embodiment, the treatment chamber is constructed from a material selected specifically to enhance the absorption of the energy field emitted by the generator, thereby promoting stable formation of micro-clusters among water molecules. Said material may possess high permeability to the energy field, allowing efficient transmission through the chamber walls to support molecular restructuring within the chamber. Examples of suitable materials may include specific polymers, alloys, or composites that have been shown to facilitate energy absorption without altering the chemical composition of water. The treatment chamber material may also be chosen for its resistance to corrosion and durability under varied temperature and pressure conditions, ensuring consistent operation. In one configuration, the material may have surface treatments or coatings that further enhance its energy absorption capabilities. The treatment chamber may incorporate multiple layers or coatings of said material, with each layer providing additional benefits, such as energy field intensification, molecular alignment, or thermal stability. The structural design of the treatment chamber, coupled with the chosen material, may ensure that the water molecules receive optimal exposure to the energy field, which is essential for effective micro-clustering. Additionally, the material of the treatment chamber may also be selected to have minimal interaction with impurities within water, preserving the purity of the water throughout the clustering process.
[00031] In an embodiment, the flow regulator maintains a controlled rate of water flow through the treatment chamber, ensuring sufficient residence time for effective micro-cluster formation among water molecules. The flow regulator may operate to adjust water flow depending on parameters such as water temperature, chamber pressure, and the specific energy field emitted within the treatment chamber. The flow regulator can include mechanical components, such as adjustable valves, which control the rate of water flow entering and exiting the treatment chamber. In other configurations, the flow regulator may be electronically controlled, utilizing a microprocessor or controller to maintain a steady flow rate based on pre-set criteria or real-time feedback from sensors within the chamber. The ability to adjust the flow rate allows the system to optimize residence time, as certain flow rates may be more conducive to maintaining smaller, stable clusters within the water. In some embodiments, the flow regulator may be synchronized with other components, such as the generator or temperature control unit, to maintain consistency in water treatment regardless of environmental factors. The flow regulator may be integrated directly into the chamber inlet or outlet or may be positioned externally with piping connecting it to the chamber. Furthermore, the flow regulator's structure may be chosen to prevent any backflow or leakage, ensuring the flow remains uniform throughout the treatment process.
[00032] In an embodiment, a reservoir is coupled to the treatment chamber, capable of holding a specified volume of water before treatment. The reservoir may be constructed from materials compatible with long-term water storage, including stainless steel, BPA-free plastics, or glass, ensuring that stored water remains uncontaminated before entering the treatment chamber. Said reservoir may include a cover or cap to prevent contaminants or debris from entering the water supply. Additionally, the reservoir may be designed to maintain a constant water supply to the treatment chamber, allowing for uninterrupted operation of the hydration enhancement system. In some embodiments, the reservoir may include a built-in filtration system to remove impurities or particulates from water prior to its entry into the treatment chamber. The size of the reservoir may be adjustable or selected based on user requirements, allowing the system to be used in various applications from personal hydration to larger-scale uses. The reservoir may include a gauge or indicator to display water levels, ensuring that users can monitor and refill the reservoir as needed. Additionally, the reservoir may feature an inlet valve that regulates water input, preventing overflow or excessive pressure build-up within the reservoir. Positioning of the reservoir relative to the treatment chamber may be designed to promote consistent water flow, enabling efficient operation of the entire system.
[00033] In an embodiment, the internal geometry of the treatment chamber is structured to facilitate even distribution of the energy field across water molecules within the chamber. The chamber may incorporate specific angles, curves, or flow paths to direct water uniformly through the energy field generated by the electromagnetic resonance device. The geometry of the treatment chamber may include multiple channels or compartments, each designed to expose water molecules to the energy field in an organized manner that promotes consistent micro-cluster formation. The arrangement of the chamber's internal geometry can support optimal residence time, preventing water from flowing too quickly or unevenly through the field. Such internal configurations can reduce the likelihood of flow stagnation or uneven clustering, which may affect the hydration benefits of the treated water. Materials within the chamber may be selected to complement this geometry, enhancing water movement along the desired path. In some embodiments, the internal geometry may also support heat dissipation or prevent energy concentration in specific areas, preserving the stability of the micro-clusters formed within the chamber.
[00034] In an embodiment, the electromagnetic resonance device within the generator may be adjustable to alter the frequency range of emitted energy for specific hydration applications or water sources. The adjustment capability allows the electromagnetic resonance device to optimize the frequency for different types of water, accounting for variables such as mineral content or temperature that may affect the hydrogen bond structure. Said adjustment may be controlled manually, allowing users to select the desired frequency range, or it may be automatically regulated by a control circuit that senses water properties and adjusts frequency accordingly. The adjustment mechanism may also permit switching between single and multi-frequency emission modes, depending on the treatment requirements. The electromagnetic resonance device may incorporate a display or indicator showing the current frequency settings, providing feedback on the treatment process. Such adjustability can support customized water treatment solutions, enhancing versatility for various user preferences.
[00035] In an embodiment, the system includes a temperature control unit operable to maintain a stable temperature within the treatment chamber during exposure to the energy field, supporting consistent micro-cluster formation in water molecules. The temperature control unit may comprise heating or cooling elements that respond to environmental conditions, ensuring that water within the treatment chamber remains within an optimal temperature range. Temperature stabilization can impact the stability of hydrogen bond alterations, facilitating micro-clustering by ensuring molecular movement and energy absorption remain consistent. The temperature control unit may also include sensors to monitor chamber temperature, providing real-time data to adjust heating or cooling as required. The control unit may feature insulation around the treatment chamber to preserve thermal conditions, enabling energy efficiency during operation. The temperature control unit may be configured to respond automatically based on pre-set parameters or real-time feedback, promoting an uninterrupted micro-clustering process.
[00036] In an embodiment, an outlet within the hydration enhancement system dispenses micro-clustered water for consumption, and may include a filter to remove particulate matter from the treated water prior to dispensing. Said filter may be constructed of materials compatible with the purified water, such as activated carbon, ceramic, or high-density polyethylene, which can trap particulates or impurities without interfering with water composition. The filter may be designed with a specific pore size to remove contaminants while allowing micro-clustered water to pass through. In some configurations, the outlet may also feature a flow control valve that regulates dispensing speed, enabling users to draw treated water at a preferred rate. The outlet may be positioned at a convenient location on the system, facilitating ease of access for users. The outlet may also be detachable, allowing for periodic cleaning or replacement of the filter as necessary.
[00037] In an embodiment, the generator comprises a low-frequency magnetic field generator operable to produce a magnetic field that interacts with hydrogen bonds in water molecules, altering molecular structures within the treatment chamber. Said magnetic field generator may emit low-frequency magnetic waves that align or rearrange the orientation of hydrogen bonds, supporting the formation of micro-clusters. The magnetic field generator

may include coils or magnets positioned strategically to produce an even magnetic effect across the water within the chamber.
[00038] FIG. 2 illustrates a class diagram of the portable hydration enhancement system, in accordance with the embodiments of the present disclosure. The portable hydration enhancement system diagram illustrates four main components within the system: the generator, treatment chamber, flow regulator, and outlet. The system centralizes around the purpose of inducing micro-clustering in water molecules to enhance hydration bioavailability. The generator produces a specific energy field that targets hydrogen bonds in water molecules. This energy field is applied within the treatment chamber, where water is received and exposed to the field, facilitating the formation of micro-clusters. The flow regulator maintains a controlled rate of water flow through the treatment chamber, ensuring that water molecules interact with the energy field for optimal clustering. Finally, the outlet dispenses the micro-clustered water for consumption. Each component is represented as a class with specific operations: the generator generates the energy field, the treatment chamber receives and exposes water, the flow regulator controls flow rate, and the outlet dispenses the processed water. Together, they contribute to the system's hydration enhancement functionality.
[00039] In an embodiment, a portable hydration enhancement system induces micro-clustering of water molecules, potentially improving hydration bioavailability when consumed. The generator within the system produces a specified energy field targeted at the hydrogen bonds in water molecules, facilitating a rearrangement that encourages smaller molecular clusters. The treatment chamber houses water, exposing it directly to this energy field generated by the generator, allowing optimal molecular clustering. The flow regulator maintains a specific water flow rate through the chamber, ensuring an appropriate residence time for consistent interaction between water molecules and the energy field. Finally, the outlet dispenses treated, micro-clustered water, making it available for user consumption. Each component operates synergistically to support the structural transformation of water, potentially resulting in enhanced absorption characteristics.
[00040] In an embodiment, the generator incorporates an electromagnetic resonance device to produce a frequency targeted at altering hydrogen bonds within water molecules. This frequency specifically resonates with the molecular structure of water, encouraging a stable transformation into smaller clusters by aligning with natural molecular oscillations. By applying a controlled frequency, the electromagnetic resonance device supports a highly stable clustering effect, fostering a consistent molecular restructuring process. The resonance frequency emitted by the device is optimized to ensure that energy is effectively absorbed by the water, providing a reliable basis for hydrogen bond reformation. The ability of the resonance device to deliver energy in a uniform and stable frequency range promotes more predictable clustering, making it suitable for hydration purposes that benefit from enhanced water bioavailability.
[00041] In an embodiment, the treatment chamber material is selected to enhance energy absorption within water molecules, thereby promoting stable formation of micro-clusters. Said material provides high permeability to the energy field emitted by the generator, ensuring that energy reaches water molecules efficiently. Enhanced energy absorption facilitates a more intense interaction between the energy field and water molecules, preventing dissipation and enabling more uniform clustering throughout the chamber. The selected material promotes molecular stability by supporting prolonged contact with the energy field, helping water molecules maintain a smaller, stable cluster structure. By enhancing the energy field's impact on water, the chamber material contributes to the reliable formation of molecular clusters that could potentially enhance hydration.
[00042] In an embodiment, the flow regulator controls water flow within the treatment chamber, thereby optimizing the residence time of water exposed to the energy field for consistent micro-clustering. The flow regulator enables precise control over water speed, allowing water molecules ample time to interact fully with the generated energy field. By maintaining a controlled flow rate, the regulator prevents water from moving too quickly through the chamber, which could result in incomplete clustering and diminish the desired hydration properties. The flow regulator's ability to adapt flow rates based on system parameters promotes more effective and consistent micro-cluster formation by balancing water residence time with energy exposure. This flow regulation supports uniform cluster size, potentially contributing to improved hydration characteristics.
[00043] In an embodiment, a reservoir is coupled to the treatment chamber, holding a specified volume of water before treatment and ensuring a continuous supply to the hydration enhancement system. The reservoir's compatibility with water storage helps maintain purity prior to exposure in the treatment chamber, as the structure is typically resistant to contaminants. By holding an adequate volume of water, the reservoir supports steady flow into the chamber, ensuring the treatment process remains uninterrupted. The reservoir structure minimizes unnecessary turbulence within stored water, maintaining its molecular integrity until it is treated. The stable water supply provided by the reservoir contributes to more consistent treatment operations, allowing the system to deliver a continuous output of micro-clustered water.
[00044] In an embodiment, the treatment chamber's internal geometry is structured to facilitate even distribution of the energy field across water molecules, encouraging consistent micro-clustering. Features such as angles, curves, and channels direct the flow of water through the chamber, exposing it uniformly to the energy field. The carefully designed geometry supports a controlled flow path, allowing energy to interact with each water molecule at similar levels. This design prevents areas of stagnant flow or uneven energy distribution that could interfere with clustering, ensuring that water molecules maintain consistent exposure and uniform molecular transformation. The internal geometry contributes to the stability of micro-cluster formation, which can improve the hydration potential of the treated water.
[00045] In an embodiment, the electromagnetic resonance device within the generator can be adjusted to alter the frequency range for different hydration applications or water sources. This adjustable frequency allows the device to optimize resonance with various molecular compositions, accommodating water sources with distinct mineral contents or other properties. Users may select or preset the frequency range to tailor the micro-clustering effect to specific hydration needs. By allowing a range of frequency adjustments, the resonance device can adapt to environmental factors or treatment preferences, promoting reliable hydrogen bond restructuring. The adjustable resonance supports customized hydration treatments by providing the flexibility to align with distinct hydration properties across various water types.
[00046] In an embodiment, a temperature control unit within the system maintains a stable temperature during exposure to the energy field in the treatment chamber, supporting consistent micro-cluster formation. Temperature stability is essential to maintaining hydrogen bond structures, as temperature fluctuations could disrupt the clustering process. The temperature control unit keeps water within an ideal range for molecular realignment, preventing energy losses that could interfere with the clustering effect. Real-time temperature monitoring may allow the control unit to make necessary adjustments, stabilizing molecular interactions and enabling predictable cluster formation. Consistent temperature control contributes to a reliable hydration enhancement by promoting a stable environment for the molecular transformation of water.
[00047] In an embodiment, the outlet within the hydration system incorporates a filter to remove particulate matter from the micro-clustered water before dispensing, delivering purified water for consumption. The filter, made of materials such as activated carbon or ceramic, captures impurities that could interfere with water quality. Filtering out particulates helps maintain the micro-clustered structure created in the treatment chamber, preserving its hydration properties. Positioned directly before dispensing, the filter ensures that treated water is clear of contaminants, promoting cleanliness and safety. The filter's presence supports the delivery of water that retains its structured form, providing a purified hydration source that may benefit the body's absorption processes.
[00048] In an embodiment, the generator includes a low-frequency magnetic field generator that emits a magnetic field to influence water's molecular structure within the treatment chamber. The low-frequency magnetic waves interact with hydrogen bonds, promoting alignment and potentially forming smaller clusters. By using low frequencies, the magnetic field generator provides a stable magnetic effect across water molecules without causing disruption to other chemical components. The application of a magnetic field supports controlled alignment in hydrogen bonds, creating a micro-clustered arrangement that may increase water's bioavailability. The magnetic field generator allows consistent structuring of water molecules, enhancing the hydration characteristics of water treated by the hydration enhancement system.
[00049] Example embodiments herein have been described above with reference to block diagrams and flowchart illustrations of methods and apparatuses. It will be understood that each block of the block diagrams and flowchart illustrations, and combinations of blocks in the block diagrams and flowchart illustrations, respectively, can be implemented by various means including hardware, software, firmware, and a combination thereof. For example, in one embodiment, each block of the block diagrams and flowchart illustrations, and combinations of blocks in the block diagrams and flowchart illustrations can be implemented by computer program instructions. These computer program instructions may be loaded onto a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions which execute on the computer or other programmable data processing apparatus create means for implementing the functions specified in the flowchart block or blocks.
[00050] Operations in accordance with a variety of aspects of the disclosure is described above would not have to be performed in the precise order described. Rather, various steps can be handled in reverse order or simultaneously or not at all.
[00051] While several implementations have been described and illustrated herein, a variety of other means and/or structures for performing the function and/or obtaining the results and/or one or more of the advantages described herein may be utilized, and each of such variations and/or modifications is deemed to be within the scope of the implementations described herein. More generally, all parameters, dimensions, materials, and configurations described herein are meant to be exemplary and that the actual parameters, dimensions, materials, and/or configurations will depend upon the specific application or applications for which the teachings is/are used. Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents to the specific implementations described herein. It is, therefore, to be understood that the foregoing implementations are presented by way of example only and that, within the scope of the appended claims and equivalents thereto, implementations may be practiced otherwise than as specifically described and claimed. Implementations of the present disclosure are directed to each individual feature, system, article, material, kit, and/or method described herein. In addition, any combination of two or more such features, systems, articles, materials, kits, and/or methods, if such features, systems, articles, materials, kits, and/or methods are not mutually inconsistent, is included within the scope of the present disclosure.













Claims
I/We Claim:
1. A portable hydration enhancement system for inducing micro-clustering of water molecules, said system comprising:
a generator configured to produce a specified energy field to influence hydrogen bonds between water molecules;
a treatment chamber structured to receive water and expose said water to said energy field generated by said generator, thereby facilitating micro-cluster formation in said water;
a flow regulator operable to control the flow rate of water through said treatment chamber to optimize interaction with said energy field; and
an outlet configured to dispense micro-clustered water for consumption.
2. The system of claim 1, wherein said generator comprises an electromagnetic resonance device, configured to emit a frequency optimized for altering hydrogen bond structures among water molecules.
3. The system of claim 1, wherein said treatment chamber comprises a material selected to enhance energy absorption by water molecules, promoting the stability of formed micro-clusters.
4. The system of claim 1, wherein said flow regulator is configured to maintain a residence time for water within said treatment chamber sufficient to achieve a predetermined micro-cluster size.
5. The system of claim 1, further comprising a reservoir coupled to said treatment chamber, said reservoir operable to hold a specified volume of water before treatment.
6. The system of claim 1, wherein said treatment chamber comprises an internal geometry that facilitates even distribution of said energy field across water molecules.
7. The system of claim 2, wherein said electromagnetic resonance device is adjustable to alter the frequency range for specific hydration applications or water sources.
8. The system of claim 1, further comprising a temperature control unit configured to maintain said water at a stable temperature during exposure to said energy field, thereby optimizing micro-cluster formation.
9. The system of claim 1, wherein said outlet comprises a filter configured to remove particulate matter from said micro-clustered water before dispensing.
10. The system of claim 1, wherein said generator comprises a low-frequency magnetic field generator, operable to generate a magnetic field to alter water structure within said treatment chamber.






Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant



PORTABLE HYDRATION SYSTEM TO ENHANCE WATER MICRO-CLUSTERING
Abstract
The present disclosure provides a portable hydration enhancement system inducing micro-clustering of water molecules. Said system includes a generator producing a specific energy field that influences hydrogen bonds among water molecules, a treatment chamber that receives water and exposes it to said energy field, a flow regulator managing the water flow rate through the treatment chamber to optimise energy field interaction, and an outlet dispensing micro-clustered water. Said system potentially improves cellular hydration by enabling the formation of smaller water clusters, facilitating more efficient absorption within the body.





Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant , Claims:Claims
I/We Claim:
1. A portable hydration enhancement system for inducing micro-clustering of water molecules, said system comprising:
a generator configured to produce a specified energy field to influence hydrogen bonds between water molecules;
a treatment chamber structured to receive water and expose said water to said energy field generated by said generator, thereby facilitating micro-cluster formation in said water;
a flow regulator operable to control the flow rate of water through said treatment chamber to optimize interaction with said energy field; and
an outlet configured to dispense micro-clustered water for consumption.
2. The system of claim 1, wherein said generator comprises an electromagnetic resonance device, configured to emit a frequency optimized for altering hydrogen bond structures among water molecules.
3. The system of claim 1, wherein said treatment chamber comprises a material selected to enhance energy absorption by water molecules, promoting the stability of formed micro-clusters.
4. The system of claim 1, wherein said flow regulator is configured to maintain a residence time for water within said treatment chamber sufficient to achieve a predetermined micro-cluster size.
5. The system of claim 1, further comprising a reservoir coupled to said treatment chamber, said reservoir operable to hold a specified volume of water before treatment.
6. The system of claim 1, wherein said treatment chamber comprises an internal geometry that facilitates even distribution of said energy field across water molecules.
7. The system of claim 2, wherein said electromagnetic resonance device is adjustable to alter the frequency range for specific hydration applications or water sources.
8. The system of claim 1, further comprising a temperature control unit configured to maintain said water at a stable temperature during exposure to said energy field, thereby optimizing micro-cluster formation.
9. The system of claim 1, wherein said outlet comprises a filter configured to remove particulate matter from said micro-clustered water before dispensing.
10. The system of claim 1, wherein said generator comprises a low-frequency magnetic field generator, operable to generate a magnetic field to alter water structure within said treatment chamber.






Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant

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