A non-powered gyromagnetic device driven by magnetic lines of force

The non-powered magnetic rotation device driven by magnetic lines of force adopts a separate design of static magnetic components and mobile magnetic rotation device, which solves the problems of inconvenient maintenance and limited effect of existing magnetic rotation products, realizes a wide range of magnetic rotation functions and high reliability, and extends service life.

CN116459450BActive Publication Date: 2026-06-23NEW GREEN CONTINENT TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NEW GREEN CONTINENT TECH CO LTD
Filing Date
2023-04-26
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing gyromagnetic products cannot separate the drive structure and the gyromagnetic structure, making maintenance inconvenient and limiting their effectiveness.

Method used

The non-powered rotating magnetomechanical device driven by magnetic lines of force utilizes a separate design of a static magnetic component and a mobile rotating magnetomechanical device. Rotational motion is achieved through magnetic force transmission. The rotating magnetomechanical module of the static magnetic component is 1-10 times larger than the mobile rotating magnetomechanical module, enabling a wide range of rotating magnetomechanical functions.

Benefits of technology

It is portable, uses magnetic force for contactless transmission, generates no heat, has low noise, has a simple structure, is not easily damaged, has a long lifespan, and is easy to maintain.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a kind of unpowered gyromagnetic device driven by magnetic force line, it is related to magnetic therapy equipment technical field, including device main body, the inside of device main body is provided with driver, the side of driver is rotatably connected with first gyromagnetic module group, first gyromagnetic module group and driver are arranged in the inside of device main body, and constitute a mobile gyromagnetic device that can be used alone;The unpowered gyromagnetic device is also provided with static magnetic assembly, the inside of static magnetic assembly is provided with second gyromagnetic module group, and the side of second gyromagnetic module group is installed with transmission assembly.The unpowered gyromagnetic device driven by magnetic force line, the device main body is used alone, it is convenient to carry, since the gyromagnetic module of static magnetic assembly is much larger than the gyromagnetic module of device main body, after combination, static magnetic assembly is driven to realize wide-range gyromagnetic function, increase the range of magnetic force line, realize the reverse flip fluctuation of magnetic force line;While magnetic force transmission is non-contact, no heating, and noise is small.
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Description

Technical Field

[0001] This invention relates to the field of magnetic therapy equipment technology, specifically to a non-powered rotating magnetic device driven by magnetic lines of force. Background Technology

[0002] With the improvement of living standards, people's standards for health are also constantly rising. Among them, magnetic therapy products are very popular among middle-aged and elderly people due to their significant and stable effects. Rotating magnetic products are particularly outstanding.

[0003] In existing technologies, commercially available rotary magnet products all involve a motor driving one or more magnets to rotate. The drive structure and the rotary magnet structure of such products cannot be separated, making maintenance inconvenient. Furthermore, their effectiveness is quite limited.

[0004] To address the aforementioned issues, we propose a non-powered gyromagnetic device driven by magnetic field lines. Summary of the Invention

[0005] To address the shortcomings of existing technologies, this invention provides a non-powered rotating magnetic device driven by magnetic field lines, thereby solving the problems mentioned in the background section.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a non-powered vortex magnet device driven by magnetic lines of force, comprising a device body, an actuator disposed inside the device body, a first vortex magnet module group rotatably connected to one side of the actuator, the first vortex magnet module group and the actuator being disposed inside the device body to form a mobile vortex magnet device that can be used independently.

[0007] The non-powered magnetic rotating device is also provided with a static magnetic component. The static magnetic component has a second magnetic rotating module group inside. A transmission component is installed on one side of the second magnetic rotating module group. The second magnetic rotating module group is attracted and fixed to the first magnetic rotating module group through the transmission component. The first magnetic rotating module group and the second magnetic rotating module group rotate in opposite directions.

[0008] Both the first and second vortex module groups consist of multiple vortex components, and the transmission component has multiple magnetic conductive elements inside.

[0009] To further optimize this technical solution, a control module and a power supply module are also provided at the tail end inside the main body of the device. Both the control module and the power supply module are extended functional components.

[0010] The control module is a control circuit used to adjust the speed, frequency, and direction of the driver;

[0011] The power supply module operates either with a built-in battery or by using an external power source, and is used to power the mobile magnetic rotating device.

[0012] To further optimize this technical solution, the first gyromagnetic module group is an active gyromagnetic module, and the second gyromagnetic module group is a load gyromagnetic module. The first gyromagnetic module group acts as an active gyromagnetic module to drive the second gyromagnetic module group to rotate as a load gyromagnetic module.

[0013] To further optimize this technical solution, the movable magnetic rotating device is placed on a functional product, which includes, but is not limited to, mattresses, pillows, clothing, lumbar supports, knee supports, neck supports, and hats; the static magnetic component is placed inside the functional product, and the movable magnetic rotating device is attracted and fixed to the corresponding position of the static magnetic component.

[0014] To further optimize this technical solution, the gyromagnetic components in the first gyromagnetic module group and the gyromagnetic components in the second gyromagnetic module group are assembled in proportion, and the ratio of the number of gyromagnetic components in the first gyromagnetic module group to the number of gyromagnetic components in the second gyromagnetic module group includes, but is not limited to, 2:1, 2:2, 2:4, 2:6, and 2:8.

[0015] To further optimize this technical solution, the magnetic component in the second magnetic module group is 1-10 times larger than the magnetic component in the first magnetic module group. The first magnetic module group drives the second magnetic module group to rotate through the transmission component. The rotation speed is inversely proportional to the size of the magnetic component. When the first and second magnetic module groups are placed horizontally, the same-direction dual-axis magnetic / reverse dual-axis magnetic functions are realized. At this time, the range of magnetic field lines will be multiplied, and the reverse reversal and fluctuation of the magnetic field lines will be realized.

[0016] To further optimize this technical solution, the gyromagnetic components in both the first and second gyromagnetic module groups are arranged with N / S intervals.

[0017] To further optimize this technical solution, the magnetic conductive element in the transmission component is made of magnetic material and is arranged perpendicular to the rotation surface of the vortex module. The number of vortex modules in the first or second vortex module group is even, and the number of magnetic conductive elements in the transmission component is the sum of the number of the first and second vortex module groups divided by 2.

[0018] Compared with the prior art, the present invention provides a powerless gyromagnetic device driven by magnetic lines of force, which has the following advantages:

[0019] This is a non-powered magnetic rotation device driven by magnetic field lines. When used alone, the main body of the device is easy to carry. Because the magnetic rotation module of the static magnetic component is much larger (1-10 times) than the magnetic rotation module of the main body, when combined, it can drive the static magnetic component to achieve a wide range of magnetic rotation functions, increase the range of action of the magnetic field lines, and realize the reverse reversal and fluctuation of the magnetic field lines. At the same time, the magnetic force transmission is contactless, generates no heat, and has low noise. The structure is simple, not easily damaged, highly reliable, and has a long service life. The device adopts a split design, which facilitates later maintenance. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the moving gyromagnetic device in a non-powered gyromagnetic device driven by magnetic lines of force proposed in this invention.

[0021] Figure 2 This is a schematic diagram of a structural variant of the first and second vortex module groups in a non-powered vortex device driven by magnetic lines of force proposed in this invention.

[0022] Figure 3 This is a schematic diagram of a structural variant of a non-powered gyromagnetic device driven by magnetic lines of force proposed in this invention, which combines a movable gyromagnetic device and a static magnetic component.

[0023] Figure 4 This is a schematic diagram of a right-angled structure in a non-powered gyromagnetic device driven by magnetic lines of force proposed in this invention.

[0024] Figure 5 This is a schematic diagram of an embodiment of a non-powered rotating magnetic device driven by magnetic lines of force proposed in this invention.

[0025] In the diagram: 1. Main body of the device; 2. Driver; 3. First magnetic module group; 4. Second magnetic module group; 5. Transmission component; 6. Power supply module; 7. Control module; 8. Magnetic conductor. Detailed Implementation

[0026] The technical solutions of the present invention will be clearly and completely described below with reference to the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0027] Example:

[0028] Please see Figure 1A non-powered magnetic rotating device driven by magnetic lines of force includes a device body 1. A driver 2 is disposed inside the device body 1. A first magnetic rotating module group 3 is rotatably connected to one side of the driver 2. The first magnetic rotating module group 3 and the driver 2 are disposed inside the device body 1 to form a mobile magnetic rotating device that can be used independently.

[0029] The movable magnetic rotating device is placed on the functional product, which includes, but is not limited to, mattresses, pillows, clothing, lumbar supports, knee supports, neck supports, and hats; the static magnetic component is placed inside the functional product, and the movable magnetic rotating device is attracted and fixed to the corresponding position of the static magnetic component.

[0030] The device body 1 is also equipped with a control module 7 and a power supply module 6 at its rear end. Both the control module 7 and the power supply module 6 are extended functional components.

[0031] The control module 7 is a control circuit used to adjust the speed, frequency, and direction of the driver 2.

[0032] The power supply module 6 is powered by a built-in battery or by an external power source, and is used to power the mobile magnetic rotating device.

[0033] The non-powered magnetic rotating device is also provided with a static magnetic component. The static magnetic component has a second magnetic rotating module group 4 inside. A transmission component 5 is installed on one side of the second magnetic rotating module group 4. The second magnetic rotating module group 4 is attracted and fixed to the first magnetic rotating module group 3 through the transmission component 5. The rotation directions of the first magnetic rotating module group 3 and the second magnetic rotating module group 4 are opposite.

[0034] like Figure 2 As shown, the gyromagnetic components in both the first gyromagnetic module group 3 and the second gyromagnetic module group 4 are arranged with N / S intervals. The installation options for the gyromagnetic components can be... Figure 2 One of the four installation methods.

[0035] like Figure 3 As shown, the magnetic conductor 8 in the transmission component 5 is made of magnetic material and is arranged perpendicular to the rotation surface of the magnetic module. The number of magnetic modules in the first magnetic module group 3 or the second magnetic module group 4 is even, and the number of magnetic conductors 8 in the transmission component 5 is the sum of the number of the first magnetic module group 3 and the second magnetic module group 4 divided by 2.

[0036] The first gyromagnetic module group 3 is an active gyromagnet, and the second gyromagnetic module group 4 is a load gyromagnet. The first gyromagnetic module group 3 acts as an active gyromagnet to drive the second gyromagnetic module group 4 to rotate the load gyromagnet.

[0037] The first vortex module group 3 and the second vortex module group 4 are each composed of multiple vortex components, and the transmission component 5 is internally provided with multiple magnetic conductive elements 8.

[0038] The device body 1 is also equipped with a control module 7 and a power supply module 6 at its rear end. Both the control module 7 and the power supply module 6 are extended functional components.

[0039] The control module 7 is a control circuit used to adjust the speed, frequency and direction of the driver 2;

[0040] The power supply module 6 is a built-in battery used to power the mobile magnetic rotating device.

[0041] By incorporating a mobile magnetic rotating device and a static magnetic component, it is easy to carry. When combined, it can drive a large magnetic rotating component to achieve a wide range of magnetic rotating functions, increasing the range of magnetic field lines and enabling the reverse reversal and fluctuation of magnetic field lines. At the same time, the magnetic force transmission is contactless, generates no heat, and produces low noise. The structure is simple, not easily damaged, highly reliable, and has a long lifespan. The decoration adopts a split design, which facilitates later maintenance.

[0042] Furthermore, the magnetic components in the first magnetic module group 3 are assembled in proportion to the magnetic components in the second magnetic module group 4, and the ratio of the number of magnetic components in the first magnetic module group 3 to the number of magnetic components in the second magnetic module group 4 includes, but is not limited to, 2:1, 2:2, 2:4, 2:6, and 2:8.

[0043] Furthermore, the magnetic components in the second magnetic module group 4 are 1-10 times larger than those in the first magnetic module group 3. The first magnetic module group 3 drives the second magnetic module group 4 to rotate via the transmission component 5, with the rotation speed inversely proportional to the size of the magnetic components. Figure 5 As shown, when the first magnetic flux module group 3 and the second magnetic flux module group 4 are placed horizontally, the function of co-directional dual-axis magnetic flux / reverse dual-axis magnetic flux is realized. At this time, the range of magnetic field lines will be multiplied, and the reverse reversal fluctuation of magnetic field lines will be realized.

[0044] When the moving vortex generator on the non-powered vortex generator adopts Figure 1 When the structure shown is used, the static magnetic component needs to be in the form of... Figure 4 The right-angled structures shown are assembled and placed.

[0045] The beneficial effects of this invention are:

[0046] This is a non-powered magnetic rotation device driven by magnetic field lines. When used alone, the main body of the device is easy to carry. Because the magnetic rotation module of the static magnetic component is much larger (1-10 times) than the magnetic rotation module of the main body, when combined, it can drive the static magnetic component to achieve a wide range of magnetic rotation functions, increase the range of action of the magnetic field lines, and realize the reverse reversal and fluctuation of the magnetic field lines. At the same time, the magnetic force transmission is contactless, generates no heat, and has low noise. The structure is simple, not easily damaged, highly reliable, and has a long service life. The device adopts a split design, which facilitates later maintenance.

[0047] In the description of this specification, the references to terms such as "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of different embodiments or examples.

[0048] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A non-powered gyromagnetic device driven by magnetic field lines, comprising a device body (1), characterized in that, The device body (1) is equipped with a driver (2) inside. A first magnetic module group (3) is rotatably connected to one side of the driver (2). The first magnetic module group (3) and the driver (2) are arranged inside the device body (1) to form a mobile magnetic device that can be used independently. The non-powered magnetic rotating device is also provided with a static magnetic component. The static magnetic component is provided with a second magnetic rotating module group (4). A transmission component (5) is installed on one side of the second magnetic rotating module group (4). The second magnetic rotating module group (4) is attracted and fixed to the first magnetic rotating module group (3) through the transmission component (5). The rotation directions of the first magnetic rotating module group (3) and the second magnetic rotating module group (4) are opposite. Both the first and second vortex module groups (3 and 4) are composed of multiple vortex components. The transmission component (5) is internally equipped with multiple magnetic conductors (8). The first vortex module group (3) is an active vortex, and the second vortex module group (4) is a load vortex. The first vortex module group (3) drives the second vortex module group (4) to rotate as a load vortex. The vortex components in the second vortex module group (4) are 1-10 times larger than the vortex components in the first vortex module group (3). The first vortex module group (3) drives the second vortex module group (4) to rotate through the transmission component (5). The rotation speed is inversely proportional to the size of the vortex components. When the first vortex module group (3) and the second vortex module group (4) are placed horizontally, the same-direction dual-axis vortex / reverse dual-axis vortex function is realized. At this time, the range of action of the magnetic lines of force will be The magnetic field lines are doubled and reversed, and the magnetic field components in the first magnetic module group (3) and the second magnetic module group (4) are assembled in proportion. The ratio of the number of magnetic field components in the first magnetic module group (3) to the number of magnetic field components in the second magnetic module group (4) includes, but is not limited to, 2:1, 2:2, 2:4, 2:6, and 2:

8. The magnetic field components in the first magnetic module group (3) and the second magnetic module group (4) are N / S intervals. The magnetic conductor (8) in the transmission component (5) is made of magnetic material and is arranged perpendicular to the rotation surface of the magnetic field module. The number of magnetic field modules in the first magnetic module group (3) or the second magnetic module group (4) is even. The number of magnetic conductors (8) in the transmission component (5) is the sum of the number of the first magnetic module group (3) and the second magnetic module group (4) divided by 2.

2. The unpowered rotating magnetic device driven by magnetic lines of force according to claim 1, characterized in that, The device body (1) is also equipped with a control module (7) and a power supply module (6) at its tail end. The control module (7) and the power supply module (6) are both extended functional elements. The control module (7) is a control circuit used to adjust the speed, frequency and direction of the driver (2); The power supply module (6) is either powered by a built-in battery or by an external power source, and is used to power the mobile magnetic rotating device.

3. The unpowered gyromagnetic device driven by magnetic lines of force according to claim 1, characterized in that, The movable magnetic rotating device is placed on the functional product, which includes, but is not limited to, mattresses, pillows, clothing, lumbar supports, knee supports, neck supports, and hats; the static magnetic component is placed inside the functional product, and the movable magnetic rotating device is attracted and fixed to the corresponding position of the static magnetic component.