MAGNETICALLY CONTROLLED FLUID FLOW SYSTEM FOR ACTUATORS

Abstract

The present disclosure discloses a system for controlling fluid flow in an actuator, comprising a rotating magnetic assembly positioned along a flow passage, said flow passage being configured to direct a magnetized fluid. A plurality of electromagnetic elements is arranged along an inner wall of said flow passage, with said electromagnetic elements being configured to modulate the flow rate of said magnetized fluid through said flow passage. A control unit is coupled to said electromagnetic elements, said control unit being configured to adjust the magnetic field generated by said electromagnetic elements based on the operational state of said actuator. Dated 11 November 2024 Jigneshbhai Mungalpara IN/PA- 2640 Agent for the Applicant

Specification

Description:Magnetically Controlled Fluid Flow System for Actuators
Field of the Invention
[0001] The present disclosure generally relates to fluid control systems. Further, the present disclosure particularly relates to systems for controlling fluid flow in an actuator.
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] In the field of fluid control systems, various systems and techniques are employed to regulate fluid flow within mechanical components and actuators. Fluid control in such systems is often facilitated by manipulating fluid properties, flow rates, and fluidic interactions with mechanical or electronic actuators. Actuators deployed in fluid systems serve to precisely control fluid motion and pressure for various applications, including hydraulic, pneumatic, and magnetorheological (MR) systems. Conventional fluid flow control mechanisms, however, often face limitations in accuracy, response time, and adaptability to varying operational states of the actuators. Thus, new approaches for enhancing the regulation of fluid flow, particularly through the use of magnetized fluids and electromagnetic control, have been explored.
[0004] Conventional fluid flow systems in actuators commonly employ valve-based mechanisms to regulate the flow of non-magnetized fluids. Such systems generally rely on manual or automated valves that open or close to modulate flow rates. Although valve-based systems provide a basic level of control, they tend to exhibit slower response times and less precision when rapid adjustments in flow rates are required. Additionally, frequent mechanical wear associated with valve components compromises long-term reliability and operational efficiency, especially under high-pressure conditions or in environments with high particulate contamination. Consequently, valve-based systems have shown limited utility in applications demanding dynamic and precise control of fluid flow rates.
[0005] Another well-known approach for controlling fluid flow within actuators involves the use of magnetorheological (MR) fluids, which exhibit a change in viscosity upon exposure to a magnetic field. In such systems, the MR fluid flow is regulated by altering the magnetic field intensity to achieve a desired viscosity level, which in turn impacts the flow rate. While MR fluid-based systems offer enhanced control capabilities in certain applications, they are associated with significant drawbacks, particularly in terms of complex structural requirements and higher energy consumption due to the need for sustained magnetic fields. Additionally, achieving uniform field distribution across the fluid path can be challenging, resulting in uneven flow characteristics that may affect actuator performance. These limitations restrict the effectiveness of MR fluid systems in applications requiring highly consistent flow modulation.
[0006] Further, other control systems have been developed, employing arrays of electromagnetic elements positioned along the fluid flow path. Such systems generate varying magnetic fields that can interact with magnetized fluids to adjust flow rates. Although this approach offers potential advantages over purely mechanical systems, challenges arise in achieving fine-grained control of flow rates due to complex magnetic field interactions, especially when multiple electromagnetic elements are involved. Variability in the control of individual elements and interference between fields generated by adjacent elements can lead to inconsistent flow regulation and difficulties in synchronizing the control signals, resulting in suboptimal actuator performance. In addition, fluctuations in electromagnetic output contribute to operational inefficiencies and higher energy requirements.
[0007] Other techniques for fluid flow control continue to exist, but they are associated with various shortcomings, including limitations in control precision, slower response times, and excessive wear on mechanical components in the case of valve-based systems. Additionally, traditional systems lack sufficient adaptability to varying operational states of actuators, thereby impacting system reliability and efficiency under dynamic operating conditions.
[0008] In light of the above discussion, there exists an urgent need for solutions that overcome the problems associated with conventional systems and techniques for controlling fluid flow in actuators.
[0009] All references, including publications, patent applications, and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in its entirety herein.
[00010] It also shall be noted that as used herein and in the appended claims, the singular forms "a", "an", and "the" include plural referents unless the context clearly dictates otherwise. This invention can be achieved by means of hardware including several different elements or by means of a suitably programmed computer. In the unit claims that list several means, several ones among these means can be specifically embodied in the same hardware item. The use of such words as first, second, third does not represent any order, which can be simply explained as names.
Summary
[00011] 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.
[00012] The following paragraphs provide additional support for the claims of the subject application.
[00013] The present disclosure generally relates to fluid control systems. Further, the present disclosure particularly relates to systems for controlling fluid flow in an actuator.
[00014] In an aspect, the present disclosure provides a system for controlling fluid flow in an actuator, comprising a rotating magnetic assembly positioned along a flow passage, said flow passage being configured to direct a magnetized fluid. A plurality of electromagnetic elements is arranged along an inner wall of said flow passage, said electromagnetic elements being configured to modulate the flow rate of said magnetized fluid through said flow passage. A control unit is coupled to said electromagnetic elements, said control unit being configured to adjust the magnetic field generated by said electromagnetic elements based on the operational state of said actuator. The system enables precise control over the fluid flow characteristics within the actuator, contributing to enhanced responsiveness and stability under varying operational conditions.
[00015] In a further aspect, the system includes a diagonal orientation of said rotating magnetic assembly along said flow passage, with the flow passage curving at a precise angle to promote efficient magnetic alignment of said fluid particles. This arrangement enhances the precision of fluid flow control through consistent interaction between the magnetic field and the magnetized fluid.
[00016] Further, each electromagnetic element is positioned adjacently to the inner wall at alternating intervals, forming an evenly distributed electromagnetic gradient along the flow passage. This placement minimizes magnetic flux dispersion, allowing optimized modulation of the magnetized fluid, thereby improving flow rate accuracy and reducing fluctuations in fluid movement.
[00017] In an additional aspect, said control unit dynamically aligns with the electromagnetic elements to establish a synchronized magnetic frequency along the flow passage. Such synchronization harmonizes the operation of the rotating magnetic assembly and contributes to precise control over fluid flow characteristics, enhancing actuator responsiveness under variable operational states.
[00018] Moreover, the flow passage incorporates an angular offset relative to the rotating magnetic assembly, enhancing the magnetic field interaction across the length of the flow passage. The angular offset optimally aligns and distributes magnetic forces, further stabilizing fluid movement within the actuator.
[00019] Additionally, each electromagnetic element includes a shielding layer interfacing with the rotating magnetic assembly, controlling magnetic flux density to prevent over-magnetization of the fluid particles. This shielding ensures stability in magnetic field strength, aiding in consistent fluid flow control and improving actuator reliability.
[00020] In another aspect, the control unit incorporates an integrated feedback module to measure the velocity of the magnetized fluid within the flow passage. Such a feedback module enables real-time adjustments to the electromagnetic elements, optimizing fluid flow rate based on environmental variations to ensure adaptive control under differing operational conditions.
[00021] Furthermore, the rotating magnetic assembly incorporates multiple magnetic poles positioned equidistantly, enhancing magnetic stability as the magnetized fluid traverses the flow passage. This arrangement minimizes fluid turbulence, promoting uniform magnetic alignment and contributing to consistent fluid motion along the flow passage.
[00022] Additionally, the control unit is configured to adjust magnetic polarity within the electromagnetic elements sequentially, allowing for gradual modulation of the magnetized fluid through the flow passage. Such a sequential adjustment maintains fluid integrity and reduces wear within the actuator system due to sudden shifts in magnetic force.
[00023] In another aspect, the electromagnetic elements incorporate a temperature-regulating layer to manage heat dissipation arising from magnetic field generation. This temperature-regulating layer ensures thermal stability within the flow passage during prolonged operation, enhancing the durability and performance of the actuator system.
[00024]
Brief Description of the Drawings
[00025] 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:
[00026] FIG. 1 illustrates an architectural diagram of a system 100 for controlling fluid flow in an actuator, in accordance with the embodiments of the present disclosure. FIG. 2 illustrates a sequence diagram of the system 100 for controlling fluid flow in an actuator, in accordance with embodiments of the present disclosure.
Detailed Description
[00027] 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.
[00028] 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.
[00029] 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.
[00030] The present disclosure generally relates to fluid control systems. Further, the present disclosure particularly relates to systems for controlling fluid flow in an actuator.
[00031] 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.
[00032] As used herein, the term "system" refers to an arrangement of components collectively configured to control fluid flow in an actuator. The system includes various elements that work in tandem to modulate the movement and characteristics of a magnetized fluid. This may include a rotating magnetic assembly that interacts with a magnetized fluid within a designated flow passage, a plurality of electromagnetic elements positioned along said flow passage to adjust the flow rate of the fluid, and a control unit capable of regulating the electromagnetic field based on actuator requirements. Additionally, the "system" as used herein is intended to encompass configurations where each component is specifically arranged to enhance the precision and stability of fluid flow control. Furthermore, the system may be adaptable to different types of actuators and operational conditions, providing a robust and reliable means of fluid modulation through electromagnetic and magnetic field interactions.
[00033] As used herein, the term "rotating magnetic assembly" is used to refer to a magnetic structure positioned along a flow passage in the system, which rotates to influence the behavior of a magnetized fluid. The rotating magnetic assembly generates a magnetic field that interacts with the magnetized fluid within the flow passage, thereby enabling control over fluid flow characteristics. Such a rotating magnetic assembly may be oriented diagonally along the flow passage to optimize the fluid's magnetic alignment, which promotes continuous motion and consistent interaction with the generated magnetic field. Additionally, the "rotating magnetic assembly" may include multiple magnetic poles positioned equidistantly to enhance magnetic stability and minimize fluid turbulence. The rotating magnetic assembly ensures uniform magnetic alignment of fluid particles, contributing to precise modulation of flow within the actuator system.
[00034] As used herein, the term "flow passage" is used to refer to a designated pathway within the system through which the magnetized fluid travels. The flow passage directs the magnetized fluid along a specific route, allowing for controlled interaction with the rotating magnetic assembly and electromagnetic elements. The flow passage may include an inner wall where the electromagnetic elements are arranged to optimize magnetic interactions with the fluid. Additionally, the flow passage may be designed with a diagonal orientation and an angular offset relative to the rotating magnetic assembly to maintain continuous motion of the fluid and enhance the magnetic field interaction. Such a configuration provides an intensified modulation effect on the magnetized fluid, ensuring efficient fluid stability and alignment, which contributes to consistent performance of the actuator.
[00035] As used herein, the term "magnetized fluid" is used to refer to a fluid containing magnetic particles or materials that respond to magnetic fields generated within the system. The magnetized fluid flows through the flow passage, where it is subjected to modulation by the rotating magnetic assembly and electromagnetic elements. Such a fluid may be continuously aligned with the magnetic field generated along the flow passage, promoting efficient flow control and alignment. The magnetized fluid's response to varying magnetic fields enables precise adjustments to its flow rate, which enhances the functionality of the actuator. Additionally, the magnetized fluid may maintain stable motion and magnetic alignment, reducing turbulence and improving the overall control over the actuator's fluid dynamics.
[00036] As used herein, the term "electromagnetic elements" is used to refer to a plurality of components arranged along the inner wall of the flow passage, which generate adjustable magnetic fields to modulate the flow rate of the magnetized fluid. These electromagnetic elements are strategically positioned at alternating intervals along the flow passage, forming an evenly distributed electromagnetic gradient that enhances control over the magnetized fluid. Each electromagnetic element may include a shielding layer to maintain controlled magnetic flux density, thereby preventing over-magnetization of the fluid particles. Additionally, the electromagnetic elements may be sequentially adjusted to modulate fluid flow gradually, preserving fluid integrity and reducing wear within the actuator. The electromagnetic elements ensure optimized fluid modulation, contributing to precise and reliable flow control.
[00037] As used herein, the term "inner wall" is used to refer to the interior surface of the flow passage along which the electromagnetic elements are arranged. The inner wall provides a structured surface that facilitates the interaction between the electromagnetic elements and the magnetized fluid. Positioning the electromagnetic elements adjacently to the inner wall at specific intervals forms a gradient that modulates the fluid's magnetic alignment and flow characteristics. The inner wall may also support the placement of temperature-regulating layers within the electromagnetic elements to manage heat dissipation during operation. By providing a controlled environment for magnetic interactions, the inner wall enables efficient modulation of fluid flow within the system, contributing to the stability and performance of the actuator.
[00038] As used herein, the term "control unit" is used to refer to an electronic or computational component coupled to the electromagnetic elements, responsible for adjusting the magnetic field generated by said elements based on the operational state of the actuator. The control unit dynamically aligns with the electromagnetic elements to establish a synchronized magnetic frequency, harmonizing the operation of the rotating magnetic assembly. The control unit may include an integrated feedback module that measures the velocity of the magnetized fluid, allowing real-time adjustments to optimize the fluid flow rate. Additionally, the control unit is configured to adjust the magnetic polarity within the electromagnetic elements in a sequential manner, enabling gradual modulation of fluid flow. The control unit ensures adaptive control, enhancing actuator responsiveness and system performance.
[00039] FIG. 1 illustrates an architectural diagram of a system 100 for controlling fluid flow in an actuator, in accordance with the embodiments of the present disclosure. The system 100 for controlling fluid flow in an actuator, which includes several key components configured to interact with a magnetized fluid to achieve precise flow modulation based on the operational state of the actuator. The system 100 comprises a rotating magnetic assembly 102 positioned along a flow passage 104. The rotating magnetic assembly 102 is designed to generate a magnetic field that interacts with a magnetized fluid 106 directed along the flow passage 104. In the described configuration, the rotating magnetic assembly 102 may incorporate multiple magnetic poles positioned at specific intervals, allowing for enhanced magnetic stability as the magnetized fluid 106 traverses the flow passage 104. The positioning of the rotating magnetic assembly 102 along the flow passage 104 enables continuous and consistent interaction between the magnetic field and the magnetized fluid 106. This configuration facilitates the alignment of magnetic particles within the fluid, which in turn affects its flow characteristics. The rotating magnetic assembly 102 may be oriented at a particular angle relative to the flow passage 104 to optimize magnetic alignment and reduce turbulence within the fluid. For example, the rotating magnetic assembly 102 may be oriented diagonally to the flow passage 104, promoting efficient magnetic interaction and ensuring a steady flow rate. This arrangement not only maintains the fluid in continuous motion but also enhances the precision of flow control within the actuator. In some embodiments, the rotating magnetic assembly 102 may incorporate a mechanism that adjusts its rotational speed or polarity, further allowing the system 100 to adapt to various operational conditions. By positioning and configuring the rotating magnetic assembly 102 along the flow passage 104, the system 100 achieves efficient fluid modulation, providing an effective solution for applications requiring dynamic control over fluid flow within an actuator.
[00040] The system 100 further includes a plurality of electromagnetic elements 108 arranged along an inner wall 110 of the flow passage 104. These electromagnetic elements 108 are configured to modulate the flow rate of the magnetized fluid 106 by generating adjustable magnetic fields within the flow passage 104. The electromagnetic elements 108 are strategically positioned at intervals along the inner wall 110 to form an evenly distributed electromagnetic gradient, which enhances control over the magnetized fluid 106 as it moves through the flow passage 104. This placement allows for a uniform modulation of the fluid, reducing instances of magnetic flux dispersion that could otherwise affect flow rate accuracy. The proximity of each electromagnetic element 108 to the inner wall 110 ensures that the generated magnetic field interacts closely with the magnetized fluid 106, enabling precise modulation. Additionally, each electromagnetic element 108 may incorporate a shielding layer to control magnetic flux density and prevent over-magnetization of the fluid particles. This shielding layer provides a stable magnetic environment within the flow passage 104, ensuring that the fluid is neither under-modulated nor over-modulated, which could otherwise disrupt flow stability. In some embodiments, the electromagnetic elements 108 may also be configured to sequentially adjust magnetic polarity, allowing the magnetized fluid 106 to be gradually modulated as it progresses through the flow passage 104. Such sequential adjustments in polarity ensure a smooth and controlled transition in fluid characteristics, reducing turbulence and wear within the actuator system. Furthermore, each electromagnetic element 108 may include a temperature-regulating layer to manage heat dissipation arising from magnetic field generation, contributing to thermal stability within the flow passage 104 and enhancing the durability of the system 100 during prolonged operation. The combination of electromagnetic elements 108 along the inner wall 110 of the flow passage 104 enables optimized modulation of the magnetized fluid 106, thereby improving flow rate accuracy and system performance.
[00041] The system 100 also comprises a control unit 112 that is coupled to the electromagnetic elements 108. The control unit 112 is configured to dynamically adjust the magnetic field generated by the electromagnetic elements 108 based on the operational state of the actuator, thereby facilitating adaptive fluid flow control. The control unit 112 may be equipped with an integrated feedback module that continuously monitors the velocity of the magnetized fluid 106 within the flow passage 104. This feedback module is capable of relaying real-time data to the control unit 112, enabling immediate adjustments to the magnetic field strength and polarity of each electromagnetic element 108. Through such real-time feedback, the control unit 112 can respond to variations in environmental or operational conditions, ensuring that the fluid flow rate remains consistent and optimized for actuator performance. Additionally, the control unit 112 is configured to synchronize with the electromagnetic elements 108, establishing a cohesive magnetic frequency along the flow passage 104. This synchronization harmonizes the operation of the rotating magnetic assembly 102 with the electromagnetic elements 108, thereby improving the fluid flow characteristics. In some embodiments, the control unit 112 may adjust the magnetic polarity of the electromagnetic elements 108 in a sequential manner, allowing for a controlled and gradual modulation of the magnetized fluid 106 as it flows through the passage 104. This sequential polarity adjustment minimizes sudden shifts in magnetic force, FIG. 2 illustrates a sequence diagram of the system 100 for controlling fluid flow in an actuator, in accordance with embodiments of the present disclosure. The sequence begins with the rotating magnetic assembly 102 generating a magnetic field along the flow passage 104, which directs the magnetized fluid 106. The flow passage 104 channels the magnetized fluid to interact with electromagnetic elements 108 arranged along its inner wall. The control unit 112, coupled to the electromagnetic elements 108, adjusts the magnetic field intensity generated by each element based on the operational state of the actuator. This adjustment modulates the flow rate of the magnetized fluid through the flow passage 104, allowing the system to dynamically control fluid flow characteristics. The modulation by electromagnetic elements 108 enables precise alignment of magnetic particles in the fluid, ensuring consistent fluid flow within the actuator. The flow passage 104 then feeds back to the rotating magnetic assembly 102, maintaining continuous fluid alignment and stability, thus facilitating efficient and adaptive control of fluid dynamics in response to actuator demands.which could otherwise lead to fluid instability or excessive wear within the actuator. Additionally, the control unit 112 may be programmed to adjust the intensity of the magnetic field in response to temperature variations detected within the flow passage 104, thereby ensuring consistent thermal conditions and preventing overheating. Through the combination of real-time feedback, synchronization, and adaptive polarity adjustments, the control unit 112 enables precise control over fluid flow within the actuator, ensuring reliable performance and extending the operational lifespan of the system 100.
[00042] In an embodiment, the rotating magnetic assembly 102 is oriented diagonally along the flow passage 104, which directs the magnetized fluid 106 within the system 100. The flow passage 104 curves at a specified angle, promoting continuous motion of the magnetized fluid 106 and aiding magnetic alignment of fluid particles. Such diagonal orientation facilitates a consistent magnetic interaction with the magnetized fluid 106 as it traverses the flow passage 104, directly impacting the modulation of fluid flow. The specific alignment of the rotating magnetic assembly 102 relative to the flow passage 104 reduces the likelihood of turbulence and enables a controlled magnetic influence on fluid particles. This alignment is particularly beneficial in maintaining fluid stability while passing through varying magnetic fields within the system 100. As the rotating magnetic assembly 102 aligns with the flow passage 104, it generates a stable magnetic field that maintains the orientation of magnetized particles, thereby controlling flow rate and direction. The orientation and positioning of the rotating magnetic assembly 102 effectively enhance the consistency of magnetic alignment, which in turn supports continuous and stable fluid flow modulation. By orienting the rotating magnetic assembly 102 diagonally, the system 100 achieves efficient and adaptable fluid flow control suited to varied operational demands.
[00043] In an embodiment, each electromagnetic element 108 is positioned adjacently to the inner wall 110 of the flow passage 104 at alternating intervals, forming a consistent electromagnetic gradient along the flow passage 104. Such an arrangement of electromagnetic elements 108 enables a steady magnetic modulation effect on the magnetized fluid 106 as it flows through the system 100. Positioning the electromagnetic elements 108 adjacent to the inner wall 110 provides optimized proximity to the magnetized fluid 106, ensuring that the magnetic field generated by each electromagnetic element 108 directly influences the fluid flow characteristics. The alternating intervals between each electromagnetic element 108 create a gradient effect, preventing magnetic flux dispersion, which could otherwise disrupt the flow rate accuracy of the magnetized fluid 106. Additionally, the adjacent positioning of electromagnetic elements 108 allows for uniform magnetic interaction across the flow passage 104, thereby enhancing control over the modulation of fluid flow. The distributed arrangement reduces localized magnetic intensities, providing a consistent field that aligns with the magnetic orientation requirements of the magnetized fluid 106. This consistent magnetic environment within the flow passage 104 improves fluid stability and alignment while reducing instances of turbulent flow. By maintaining such a gradient, the electromagnetic elements 108 facilitate accurate modulation of the fluid flow rate, which is essential for precise actuator performance.
[00044] In an embodiment, the control unit 112 dynamically aligns with the electromagnetic elements 108 to establish a synchronized magnetic frequency along the flow passage 104. Such synchronization enables coordinated operation between the control unit 112 and the electromagnetic elements 108, creating a harmonized magnetic field that influences the movement of the magnetized fluid 106. By synchronizing with the electromagnetic elements 108,

the control unit 112 effectively modulates the fluid characteristics in response to changes in the operational state of the actuator. The dynamic alignment between the control unit 112 and the electromagnetic elements 108 enhances fluid flow control by enabling real-time adjustments to the magnetic field, ensuring that fluid movement remains stable under various operating conditions. Through this synchronized frequency, the control unit 112 prevents fluctuations in the magnetic field intensity, which might otherwise impact the stability and direction of the magnetized fluid 106. Additionally, the synchronization process improves response time, allowing the system 100 to rapidly adjust the magnetic properties along the flow passage 104 in line with actuator demands. The harmonized operation of the control unit 112 and the electromagnetic elements 108 contributes to an efficient fluid modulation system, enabling consistent alignment and stability within the actuator during dynamic operational scenarios.
[00045] In an embodiment, the flow passage 104 integrates an angular offset relative to the rotating magnetic assembly 102, aligning such an offset to enhance magnetic field interaction across the entire length of the flow passage 104. The angular offset in the flow passage 104 is configured to facilitate a more intensified magnetic modulation effect on the magnetized fluid 106 as it flows through the system 100. Such a configuration allows the magnetic field generated by the rotating magnetic assembly 102 to have a sustained and uniform influence on the magnetized fluid 106, ensuring that fluid particles remain aligned as they traverse the passage. The alignment provided by the angular offset prevents disruptions in fluid flow, contributing to a smooth and controlled fluid path within the actuator. Additionally, the angular offset optimally distributes magnetic forces throughout the flow passage 104, reducing potential areas of flux imbalance that might otherwise create turbulence or affect flow rate precision. By incorporating an angular offset, the flow passage 104 promotes the consistent modulation of fluid flow and enhances the distribution of magnetic forces, supporting stable fluid movement within the actuator. The angular offset, therefore, contributes significantly to maintaining fluid stability and optimal magnetic alignment, benefiting the performance of the entire fluid control system.
[00046] In an embodiment, each electromagnetic element 108 incorporates a shielding layer that interfaces with the rotating magnetic assembly 102 to manage magnetic flux density and prevent over-magnetization of fluid particles within the flow passage 104. The shielding layer serves as a buffer, controlling the intensity of the magnetic field generated by each electromagnetic element 108, thereby avoiding excessive magnetization that could disrupt fluid flow and stability. The controlled magnetic environment provided by the shielding layer ensures that the magnetized fluid 106 is modulated to the required extent without causing saturation or other adverse effects in the actuator system. The shielding layer between each electromagnetic element 108 and the rotating magnetic assembly 102 also aids in maintaining a uniform magnetic influence along the flow passage 104, preventing sudden variations in magnetic field strength. By providing this level of control, the shielding layer allows each electromagnetic element 108 to contribute to a stable magnetic field distribution within the flow passage 104, which is essential for precise fluid flow control. Furthermore, the shielding layer reduces magnetic flux leakage, enhancing the efficiency of magnetic field application across the magnetized fluid 106. Such controlled flux density benefits actuator performance by maintaining a consistent and reliable fluid flow rate.
[00047] In an embodiment, the control unit 112 operates with an integrated feedback mechanism that continually measures the velocity of the magnetized fluid 106 within the flow passage 104. The feedback mechanism collects real-time data on the fluid's velocity, transmitting this information to the control unit 112, which in turn adjusts the electromagnetic elements 108 to maintain optimal fluid flow rate. The feedback process allows the control unit 112 to account for variations in environmental conditions or operational states that may impact fluid dynamics within the actuator. Through continuous monitoring, the control unit 112 dynamically alters the magnetic field strength, enabling adaptive control over fluid flow based on real-time conditions. This adaptive modulation prevents disruptions in the fluid's velocity and ensures that the flow rate remains within desired parameters, which is essential for actuator stability. By responding to real-time measurements, the control unit 112 mitigates potential issues such as turbulence or unintended flow rate changes that could impact actuator performance. Such a feedback mechanism provides accurate and responsive control, aligning the system 100 with varying operational demands.
[00048] In an embodiment, the rotating magnetic assembly 102 incorporates multiple magnetic poles positioned equidistantly along its structure. Such positioning enhances magnetic stability as the magnetized fluid 106 flows through the flow passage 104, creating a consistent magnetic alignment across the length of the passage. The arrangement of equidistant magnetic poles within the rotating magnetic assembly 102 minimizes turbulence and provides a steady magnetic environment, allowing for uniform orientation of fluid particles within the magnetized fluid 106. By reducing magnetic intensity fluctuations, the multiple magnetic poles support stable and smooth fluid movement through the flow passage 104, contributing to precise control over the fluid's direction and speed. This arrangement also prevents concentrated magnetic fields that might otherwise induce unwanted disturbances within the flow passage 104. Additionally, the equidistant placement of magnetic poles optimizes the magnetic alignment of fluid particles throughout the passage, enhancing the modulation of fluid flow rate. Such a design in the rotating magnetic assembly 102 aligns with the overall fluid control objectives of the system 100, supporting continuous and stable fluid movement within the actuator.
[00049] In an embodiment, the control unit 112 adjusts the magnetic polarity within each electromagnetic element 108 in a sequential manner, allowing gradual modulation of the magnetized fluid 106 as it flows through the flow passage 104. This sequential polarity adjustment within the electromagnetic elements 108 prevents sudden changes in magnetic force that could disrupt fluid integrity or create turbulence. The gradual modulation facilitated by sequential polarity changes provides a smooth transition in the magnetic field along the flow passage 104, reducing the impact of magnetic flux shifts on the fluid's flow rate. By maintaining a controlled progression of polarity adjustments, the control unit 112 supports a stable flow environment within the actuator. The controlled modulation achieved through sequential polarity adjustments reduces wear on actuator components, as abrupt magnetic shifts are minimized. Such an approach enables the system 100 to sustain fluid stability and maintain consistent flow characteristics.
[00050] In an embodiment, each electromagnetic element 108 includes a temperature-regulating layer to manage heat dissipation that arises from magnetic field generation during prolonged operation. The temperature-regulating layer within each electromagnetic element 108 ensures thermal stability within the flow passage 104, preventing overheating that could affect the performance and durability of the system 100. The temperature-regulating layer absorbs and dissipates excess heat generated by the electromagnetic elements 108, maintaining a consistent thermal environment. This controlled temperature regulation prevents fluctuations that could disrupt fluid flow characteristics or compromise actuator reliability. Furthermore, the temperature-regulating layer supports the longevity of electromagnetic elements 108 by reducing thermal stress on magnetic components. Such heat management contributes to stable fluid flow modulation and maintains the efficiency of the magnetic field, essential for sustained and reliable actuator performance. The integration of a temperature-regulating layer enhances the durability and performance of each electromagnetic element 108, ensuring that the system 100 operates effectively under various conditions.
[00051] In an embodiment, rotating magnetic assembly (102) positioned along flow passage (104) applies a continuous magnetic field to magnetized fluid (106), controlling the fluid flow rate within actuator system (100). Positioning rotating magnetic assembly (102) along flow passage (104) enables stable magnetic alignment of fluid particles, which minimizes turbulence and promotes steady fluid movement. The diagonal orientation of rotating magnetic assembly (102) relative to flow passage (104) ensures constant particle alignment with the magnetic field, reducing fluid disruptions and optimizing flow modulation. This orientation, combined with the angled curvature of flow passage (104), enhances fluid stability by maintaining continuous magnetic influence over magnetized fluid (106) as it travels. By aligning magnetized particles with the direction of flow, rotating magnetic assembly (102) enables fluid rate consistency across diverse actuator demands. Such positioning is beneficial for applications requiring adaptable fluid control and stability within actuator systems.
[00052] In an embodiment, electromagnetic elements (108) arranged along inner wall (110) at alternating intervals create a continuous electromagnetic gradient within flow passage (104), enabling consistent modulation of magnetized fluid (106). Placing electromagnetic elements (108) adjacent to inner wall (110) optimizes magnetic field interaction with magnetized fluid (106), reducing instances of magnetic flux dispersion and improving control over flow rate. The alternating interval arrangement of electromagnetic elements (108) forms an electromagnetic gradient that aligns with the direction of fluid flow, minimizing fluctuations in fluid rate. The proximity of electromagnetic elements (108) to inner wall (110) enables precise magnetic influence across each segment of flow passage (104), facilitating real-time modulation adjustments. Such distribution along flow passage (104) mitigates variations in magnetic field strength, stabilizing fluid movement and reducing turbulence. This configuration also enables electromagnetic elements (108) to respond efficiently to control adjustments, supporting uniform fluid characteristics throughout the actuator system.
[00053] In an embodiment, control unit (112) dynamically aligns with electromagnetic elements (108) to establish a synchronized magnetic frequency along flow passage (104), creating a unified magnetic field effect that modulates magnetized fluid (106) in response to actuator demands. This synchronization enables control unit (112) to harmonize the operation of electromagnetic elements (108) with the rotating magnetic assembly (102), resulting in consistent fluid characteristics throughout the actuator system. The synchronized alignment across electromagnetic elements (108) prevents desynchronization between magnetic influences, which could otherwise disrupt flow stability. This alignment allows for rapid adjustments to the magnetic field, ensuring stability under changing operational conditions. The coordination between control unit (112) and electromagnetic elements (108) also reduces response lag, supporting steady and adaptable fluid flow modulation that aligns with actuator requirements. This synchronized operation enhances fluid consistency within flow passage (104), providing stable flow dynamics across a range of applications.
[00054] In an embodiment, flow passage (104) incorporates an angular offset relative to rotating magnetic assembly (102), enhancing magnetic field distribution along flow passage (104) by aligning the field with the direction of magnetized fluid (106) flow. The angular offset intensifies magnetic interaction along flow passage (104), promoting efficient modulation of fluid flow rate. This offset provides uniform distribution of magnetic forces across magnetized fluid (106), reducing localized disturbances and ensuring smooth particle alignment. The angular offset prevents disruptions in fluid stability by guiding the magnetic field along the flow path, minimizing potential areas of flux imbalance within the actuator system. By positioning flow passage (104) with an angular offset, the system optimizes particle alignment and reduces turbulence, enabling consistent flow rate modulation. This configuration also enhances fluid stability during transitions between magnetic zones, supporting continuous fluid flow control across varying operational conditions.
[00055] In an embodiment, each electromagnetic element (108) incorporates a shielding layer that interacts with rotating magnetic assembly (102) to regulate magnetic flux density, preventing over-magnetization of fluid particles within flow passage (104). This shielding layer controls the intensity of the magnetic field generated by electromagnetic elements (108), reducing the risk of excessive magnetization that may destabilize fluid movement. By maintaining a controlled magnetic environment, the shielding layer enables stable alignment of magnetized fluid (106) with the magnetic field, ensuring consistent flow characteristics within flow passage (104). The shielding layer also minimizes magnetic flux leakage, allowing each electromagnetic element (108) to generate a focused field that directly influences fluid rate without unnecessary dispersion. This stable magnetic field distribution enhances the reliability of fluid modulation and contributes to the durability of actuator system (100), supporting long-term operational consistency and efficiency.
[00056] In an embodiment, control unit (112) incorporates a feedback mechanism that continuously monitors the velocity of magnetized fluid (106) within flow passage (104), providing real-time data to support adaptive adjustments to electromagnetic elements (108). This feedback mechanism enables control unit (112) to maintain optimal flow characteristics by dynamically modifying the magnetic field based on fluid velocity measurements. Continuous monitoring of fluid velocity helps control unit (112) address variations in environmental or operational conditions, ensuring consistent fluid stability within actuator system (100). Real-time data allows immediate modulation adjustments to compensate for any disruptions in flow rate, enhancing the reliability of fluid characteristics within flow passage (104). The feedback mechanism within control unit (112) provides continuous oversight of fluid dynamics, supporting adaptable fluid control under changing demands, and preventing fluctuations that could otherwise impact actuator performance.
[00057] In an embodiment, rotating magnetic assembly (102) integrates multiple magnetic poles positioned equidistantly to enhance magnetic stability as magnetized fluid (106) flows through flow passage (104). The equidistant positioning of magnetic poles minimizes turbulence by providing a steady magnetic influence that maintains fluid alignment along the length of flow passage (104). This design reduces fluctuations in magnetic field strength, ensuring uniform fluid modulation and reducing disruptions in fluid rate and direction. By preventing concentration of magnetic fields in specific areas, the configuration of rotating magnetic assembly (102) contributes to smooth fluid flow with consistent particle alignment. This arrangement supports stable magnetic alignment across the entire flow passage (104), providing a controlled environment for magnetized fluid (106) that enhances fluid consistency and stability within actuator system (100).
[00058] In an embodiment, control unit (112) sequentially adjusts the magnetic polarity within each electromagnetic element (108), facilitating gradual modulation of magnetized fluid (106) as it progresses through flow passage (104). This sequential polarity adjustment prevents abrupt shifts in magnetic force, which could otherwise disrupt fluid integrity or cause wear within actuator components. By modulating fluid characteristics in a gradual manner, control unit (112) minimizes fluctuations in flow rate and maintains stability within the flow passage (104). The sequential polarity adjustment process supports smooth transitions between magnetic zones, enabling consistent fluid characteristics and reducing potential wear within the system. This approach preserves fluid alignment, promoting stable and reliable fluid control throughout actuator system (100) under varying operational demands.
[00059] In an embodiment, electromagnetic elements (108) incorporate a temperature-regulating layer that manages heat dissipation resulting from magnetic field generation during extended operation. This temperature-regulating layer maintains thermal stability within flow passage (104), preventing excessive heat buildup that could disrupt fluid characteristics or reduce system reliability. By absorbing and dissipating excess heat, the temperature-regulating layer allows electromagnetic elements (108) to function consistently without thermal stress impacting magnetic modulation. Consistent temperature regulation prevents fluctuations in fluid characteristics and supports the longevity of electromagnetic elements (108), enhancing the durability of actuator system (100). This thermal management ensures stable fluid modulation and consistent performance over prolonged use, making actuator system (100) suitable for varied and extended operational conditions.
[00060]
[00061] 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.
[00062] Throughout the present disclosure, the term 'Artificial intelligence (AI)' as used herein relates to any mechanism or computationally intelligent system that combines knowledge, techniques, and methodologies for controlling a bot or other element within a computing environment. Furthermore, the artificial intelligence (AI) is configured to apply knowledge and that can adapt it-self and learn to do better in changing environments. Additionally, employing any computationally intelligent technique, the artificial intelligence (AI) is operable to adapt to unknown or changing environment for better performance. The artificial intelligence (AI) includes fuzzy logic engines, decision-making engines, preset targeting accuracy levels, and/or programmatically intelligent software.
[00063] Throughout the present disclosure, the term 'processing means' or 'microprocessor' or 'processor' or 'processors' includes, but is not limited to, a general purpose processor (such as, for example, a complex instruction set computing (CISC) microprocessor, a reduced instruction set computing (RISC) microprocessor, a very long instruction word (VLIW) microprocessor, a microprocessor implementing other types of instruction sets, or a microprocessor implementing a combination of types of instruction sets) or a specialized processor (such as, for example, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA), a digital signal processor (DSP), or a network processor).
[00064] The term "non-transitory storage device" or "storage" or "memory," as used herein relates to a random access memory, read only memory and variants thereof, in which a computer can store data or software for any duration.
[00065] 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.
[00066] 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 system (100) for controlling fluid flow in an actuator, comprising:
a rotating magnetic assembly (102) positioned along a flow passage (104), said flow passage (104) being configured to direct a magnetized fluid (106);
a plurality of electromagnetic elements (108) arranged along an inner wall (110) of said flow passage (104), said electromagnetic elements (108) being configured to modulate the flow rate of said magnetized fluid (106) through said flow passage (104); and
a control unit (112) coupled to said electromagnetic elements (108), said control unit (112) being configured to adjust the magnetic field generated by said electromagnetic elements (108) based on the operational state of said actuator.
Claim 2:
The system (100) as recited in claim 1, wherein said rotating magnetic assembly (102) is oriented diagonally along said flow passage (104), with said flow passage (104) curving at a precise angle to maintain said magnetized fluid (106) in continuous motion, promoting efficient magnetic alignment of said fluid particles. The diagonal orientation of said rotating magnetic assembly (102) relative to said flow passage (104) ensures a consistent interaction between said magnetic field and said magnetized fluid (106), enhancing the precision of flow control.
Claim 3:
The system (100) as recited in claim 2, wherein each of said electromagnetic elements (108) is positioned adjacently to said inner wall (110) at alternating intervals, forming an evenly distributed electromagnetic gradient along said flow passage (104). The adjacency of said electromagnetic elements (108) to said inner wall (110) allows for optimized modulation of said magnetized fluid (106) within said flow passage (104), reducing magnetic flux dispersion and improving flow rate accuracy.
Claim 4:
The system (100) as recited in claim 3, wherein said control unit (112) dynamically aligns with said electromagnetic elements (108) in a manner that establishes a synchronized magnetic frequency along said flow passage (104), effectively harmonizing the operation of said rotating magnetic assembly (102). The synchronization of said control unit (112) with said electromagnetic elements (108) facilitates precise control over fluid flow characteristics, enhancing actuator responsiveness under variable operational states.
Claim 5:
The system (100) as recited in claim 4, wherein said flow passage (104) integrates an angular offset in relation to said rotating magnetic assembly (102), said angular offset being aligned such that it enhances the magnetic field interaction across said flow passage (104) length, providing an intensified modulation effect on said magnetized fluid (106). Said angular offset contributes to optimal alignment and distribution of magnetic forces, improving fluid stability within said actuator.
Claim 6:
The system (100) as recited in claim 5, wherein each of said electromagnetic elements (108) incorporates a shielding layer that interfaces with said rotating magnetic assembly (102), such shielding layer maintaining controlled magnetic flux density to prevent over-magnetization of said fluid particles. The interface between said shielding layer and said rotating magnetic assembly (102) ensures stability in magnetic field strength, aiding in consistent fluid flow control and actuator reliability.
Claim 7:
The system (100) as recited in claim 1, wherein said control unit (112) operates with an integrated feedback module that continually measures the velocity of said magnetized fluid (106) within said flow passage (104), such feedback module relaying real-time adjustments to said electromagnetic elements (108) to optimize fluid flow rate based on environmental variations, ensuring accurate and adaptive control under differing operational conditions.
Claim 8:
The system (100) as recited in claim 1, wherein said rotating magnetic assembly (102) is constructed to incorporate multiple magnetic poles positioned equidistantly, thereby enhancing magnetic stability as said magnetized fluid (106) traverses said flow passage (104). Such construction of said rotating magnetic assembly (102) minimizes fluid turbulence, contributing to uniform magnetic alignment throughout the length of said flow passage (104).
Claim 9:
The system (100) as recited in claim 1, wherein said control unit (112) is configured to adjust magnetic polarity within said electromagnetic elements (108) in a sequential manner, allowing for gradual modulation of said magnetized fluid (106) through said flow passage (104), thereby maintaining fluid integrity and reducing wear within the actuator system due to sudden shifts in magnetic force.
Claim 10:
The system (100) as recited in claim 1, wherein said electromagnetic elements (108) include a temperature-regulating layer to manage heat dissipation arising from magnetic field generation, said temperature-regulating layer ensuring consistent thermal stability within said flow passage (104) during prolonged operation, thus enhancing the overall durability and performance of said actuator system.





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



Magnetically Controlled Fluid Flow System for Actuators
Abstract
The present disclosure discloses a system for controlling fluid flow in an actuator, comprising a rotating magnetic assembly positioned along a flow passage, said flow passage being configured to direct a magnetized fluid. A plurality of electromagnetic elements is arranged along an inner wall of said flow passage, with said electromagnetic elements being configured to modulate the flow rate of said magnetized fluid through said flow passage. A control unit is coupled to said electromagnetic elements, said control unit being configured to adjust the magnetic field generated by said electromagnetic elements based on the operational state of said actuator.



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



, Claims:Claims
I/We Claim:
1. A system (100) for controlling fluid flow in an actuator, comprising:
a rotating magnetic assembly (102) positioned along a flow passage (104), said flow passage (104) being configured to direct a magnetized fluid (106);
a plurality of electromagnetic elements (108) arranged along an inner wall (110) of said flow passage (104), said electromagnetic elements (108) being configured to modulate the flow rate of said magnetized fluid (106) through said flow passage (104); and
a control unit (112) coupled to said electromagnetic elements (108), said control unit (112) being configured to adjust the magnetic field generated by said electromagnetic elements (108) based on the operational state of said actuator.
Claim 2:
The system (100) as recited in claim 1, wherein said rotating magnetic assembly (102) is oriented diagonally along said flow passage (104), with said flow passage (104) curving at a precise angle to maintain said magnetized fluid (106) in continuous motion, promoting efficient magnetic alignment of said fluid particles. The diagonal orientation of said rotating magnetic assembly (102) relative to said flow passage (104) ensures a consistent interaction between said magnetic field and said magnetized fluid (106), enhancing the precision of flow control.
Claim 3:
The system (100) as recited in claim 2, wherein each of said electromagnetic elements (108) is positioned adjacently to said inner wall (110) at alternating intervals, forming an evenly distributed electromagnetic gradient along said flow passage (104). The adjacency of said electromagnetic elements (108) to said inner wall (110) allows for optimized modulation of said magnetized fluid (106) within said flow passage (104), reducing magnetic flux dispersion and improving flow rate accuracy.
Claim 4:
The system (100) as recited in claim 3, wherein said control unit (112) dynamically aligns with said electromagnetic elements (108) in a manner that establishes a synchronized magnetic frequency along said flow passage (104), effectively harmonizing the operation of said rotating magnetic assembly (102). The synchronization of said control unit (112) with said electromagnetic elements (108) facilitates precise control over fluid flow characteristics, enhancing actuator responsiveness under variable operational states.
Claim 5:
The system (100) as recited in claim 4, wherein said flow passage (104) integrates an angular offset in relation to said rotating magnetic assembly (102), said angular offset being aligned such that it enhances the magnetic field interaction across said flow passage (104) length, providing an intensified modulation effect on said magnetized fluid (106). Said angular offset contributes to optimal alignment and distribution of magnetic forces, improving fluid stability within said actuator.
Claim 6:
The system (100) as recited in claim 5, wherein each of said electromagnetic elements (108) incorporates a shielding layer that interfaces with said rotating magnetic assembly (102), such shielding layer maintaining controlled magnetic flux density to prevent over-magnetization of said fluid particles. The interface between said shielding layer and said rotating magnetic assembly (102) ensures stability in magnetic field strength, aiding in consistent fluid flow control and actuator reliability.
Claim 7:
The system (100) as recited in claim 1, wherein said control unit (112) operates with an integrated feedback module that continually measures the velocity of said magnetized fluid (106) within said flow passage (104), such feedback module relaying real-time adjustments to said electromagnetic elements (108) to optimize fluid flow rate based on environmental variations, ensuring accurate and adaptive control under differing operational conditions.
Claim 8:
The system (100) as recited in claim 1, wherein said rotating magnetic assembly (102) is constructed to incorporate multiple magnetic poles positioned equidistantly, thereby enhancing magnetic stability as said magnetized fluid (106) traverses said flow passage (104). Such construction of said rotating magnetic assembly (102) minimizes fluid turbulence, contributing to uniform magnetic alignment throughout the length of said flow passage (104).
Claim 9:
The system (100) as recited in claim 1, wherein said control unit (112) is configured to adjust magnetic polarity within said electromagnetic elements (108) in a sequential manner, allowing for gradual modulation of said magnetized fluid (106) through said flow passage (104), thereby maintaining fluid integrity and reducing wear within the actuator system due to sudden shifts in magnetic force.
Claim 10:
The system (100) as recited in claim 1, wherein said electromagnetic elements (108) include a temperature-regulating layer to manage heat dissipation arising from magnetic field generation, said temperature-regulating layer ensuring consistent thermal stability within said flow passage (104) during prolonged operation, thus enhancing the overall durability and performance of said actuator system.





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

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