TWM632579U - Self-propelled magnetoelectric circulation ring pair - Google Patents

Abstract

The invention provides a self-driven magnetic-electric circulation ring, which includes a first ring and a second ring. The first ring includes a first conductive wire wound in a spiral shape, the first conductive wire is covered with a first insulating layer, and two ends of the first conductive wire expose the first insulating layer. The second ring includes a second conductive wire wound in a spiral shape, the second conductive wire is covered with a second insulating layer, and two ends of the second conductive wire expose the second insulating layer. The winding direction of the first conductive wire is opposite to that of the second conductive wire, and the first ring is provided with a photoelectric conversion element electrically connected to the first ring. When worn on the human body, the self-driven magnetoelectric circulation pairing ring of this creation can generate a moderately strong magnetic field through the discharge of photoelectric conversion elements and assist the flow of weak charges carried by the human body. Have good blood circulation.

Description

Self-driven magnetic and electric circulation pair ring

This work is about electromagnetic medical devices, especially a self-driven magnetic-electric circulation ring.

Existing electromagnetic medical devices use magnetic fields to stimulate specific parts of the human body. The internal organs of the human body contain trace amounts of metal ions, and proper concentration can maintain the normal operation of the internal organs of the human body; however, if the internal organs of the human body carry too much charge or static electricity, it is easy to accelerate oxidation, induce inflammation, and cause discomfort.

The development of modern physics has made trace and microcosm obvious. The research on the magnetic field of human body by superconducting quantum interferometer reveals that the biological magnetic field of the human body is derived from the biological microcurrent generated by redox reactions in the human body and the magnetic substances (metal ions) in the human body. The induced magnetic field generated and the magnetism and electricity applied by the human body (friction electricity generation...). The magnetic density of the aforementioned generated magnetic field is only between 10-7 and 10-10T (Tesla).

General electromagnetic medical devices need a power source to generate a magnetic field, so whether the power source is commercial power or batteries, the magnetic density is too high, and it is not easy to carry and use continuously for a long time.

In view of this, the author of the present invention, aiming at the above-mentioned prior art, devoted himself to the research and cooperated with the application of theories, and tried his best to solve the above-mentioned problems, which became the goal of the author's improvement.

The invention provides a self-driven magnetic-electric circulation ring, which includes a first ring and a second ring. The first ring includes a first conductive wire wound in a spiral shape, the first conductive wire is covered with a first insulating layer, and two ends of the first conductive wire expose the first insulating layer. The second ring includes a second conductive wire wound in a spiral shape, the second conductive wire is covered with a second insulating layer, and two ends of the second conductive wire expose the second insulating layer. The winding direction of the first conductive wire is opposite to that of the second conductive wire.

In the self-driven magneto-electric circulating pair ring of the invention, the end surfaces of the two ends of the first conductive wire expose the first insulating layer, and the end surfaces of the two ends of the second conductive wire expose the second insulating layer. The side surfaces of the two ends of the first conductive line expose the first insulating layer, and the side surfaces of the two ends of the second conductive line expose the second insulating layer.

In the self-driven magnetoelectric circulating pair ring of this invention, the number of winding turns of the first conductive wire is greater than three turns (at least three turns) and the diameter of the first conductive wire is greater than 0.01mm, and the winding turns of the second conductive wire The number is greater than three turns (at least three turns) and the diameter of the second conductive wire is greater than 0.01mm. The number of turns of the first conductive wire is approximately equal to the number of turns of the second conductive wire. The diameter of the first conductive wire is approximately equal to the diameter of the second conductive wire. The diameter of the inner edge of the first ring is approximately equal to the diameter of the inner edge of the second ring.

In the self-driven magneto-electric circulating ring of this invention, the two ends of the first conductive wire are located on the same side of the first ring and are roughly aligned along the direction parallel to the axis of the first ring, and the two ends of the second conductive wire are located on the same side of the first ring. The same side of the second ring is substantially aligned along a direction parallel to the axis of the second ring.

In the self-driven magnetoelectric circulating pair ring of this creation, the second ring is provided with another photoelectric conversion element electrically connected to the second ring

In the self-driven magnetoelectric circulating pair ring of the invention, the photoelectric conversion element is provided with an electric storage element.

The self-driven magnetic-electric circulation pair ring of this creation can generate a magnetic field when worn on the human body and assist the magnetic field generated by the human body itself to gently discharge to slow down oxidation and stimulate the acupuncture points of the human body.

100: first ring

110: the first conductive thread

120: the first insulating layer

200: second ring

210: second conductive wire

220: second insulating layer

300/300a: photoelectric conversion element

310/310a: electric storage element

Fig. 1 is a schematic diagram of the use state of the self-driven magnetoelectric circulation ring of the preferred embodiment of the present invention.

Fig. 2 is a schematic diagram of the use state of the first ring in the self-driven magnetoelectric circular current ring of the preferred embodiment of the present invention.

Fig. 3 is a schematic diagram of the use state of the second ring in the self-driven magnetoelectric circular current pair ring of the preferred embodiment of the present invention.

Fig. 4 is the three-dimensional schematic diagram of the self-driven magnetoelectric circulation pair ring of the preferred embodiment of the present invention.

Fig. 5 to Fig. 7 are the schematic diagrams of various changes of the self-driven magnetoelectric circulation pair ring of the preferred embodiment of the present invention.

Referring to FIG. 1 to FIG. 3 , a preferred embodiment of the present invention provides a self-driven magnetoelectric ring, which includes a first ring 100 and a second ring 200 .

4 to 5, the first ring 100 includes a first conductive wire 110, the first conductive wire 110 is wound in a spiral shape, the first conductive wire 110 is covered with a first insulating layer 120, and the first conductive wire Two ends of 110 expose the first insulating layer 120 . The end surfaces of the two ends of the first conductive wire 110 expose the first insulating layer 120 . The second ring 200 includes a second conductive wire 210, the second conductive wire 210 is wound in a spiral shape, and the second conductive wire The 210 is coated with a second insulating layer 220 , and two ends of the second conductive wire 210 expose the second insulating layer 220 . Moreover, the winding direction of the first conductive wire 110 is opposite to that of the second conductive wire 210, and at least a photoelectric conversion element 300 electrically connected to the first ring 100 is provided on the first ring 100 ( Such as a solar panel), the photoelectric conversion element 300 is about the size of an ornament on a ring to provide a little potential energy. The photoelectric conversion element 300 is connected to at least a part of the first conductive wire 110 , for example, one end of the first conductive wire 110 or two ends of the first conductive wire 110 as shown in FIG. 6 . The photoelectric conversion element 300 is provided with a power storage element 310 (such as a battery or a capacitor). In this embodiment, the electricity storage element 310 is electrically connected to the photoelectric conversion element 300 and the first conductive wire 110 to buffer the current. The photoelectric conversion element 300 converts light energy into electrical energy and stores it in the electricity storage element 310 to form a stable The voltage source, and then through the power storage element 310 to supply power to the first conductive line 110 to be able to discharge smoothly. The first conductive wire 110 and the second conductive wire 210 may be copper wire, aluminum wire or steel wire, etc., and the present invention is not limited thereto. The first insulating layer 120 and the second insulating layer 220 can be an oxide insulating surface layer formed by anodizing the surface of the first conductive wire 110 and the second conductive wire 210 or an additional adhesive coating layer.

The first ring 100 of the self-driven magnetic-electric circulation pair ring of this creation is set on a part of the user's body, and the two ends of the first conductive wire 110 respectively touch the user's skin and are connected with the user's human body; the second The ring 200 is set on another part of the user's body, and the two ends of the second conductive wire 210 are in contact with the user's skin respectively to be connected with the user's body. The photoelectric conversion element 300 provides a voltage difference to the first conductive wire 110, and can further drive a current on the second conductive wire 210 through the human body, so when the current passes through the first conductive wire 110 and the second conductive wire 210 with opposite rotations, the current is in ampere The right-hand rule induces a pair of magnetic fields with opposite magnetic directions. The first ring 100 and the second ring 200 are preferably used to be worn on the fingers of the human body, and the first ring 100 and the second ring 200 are respectively worn on the fingers of the left and right hands. Therefore, the first ring 100 and the second ring 200 can respectively generate opposite magnetic fields coaxial with the limbs on the fingers of the left and right hands to stimulate the acupoints on the fingers, so they are suitable for weak and chronically ill users. The physique of the person.

As shown in FIG. 7 , another photoelectric conversion element 300 a electrically connected to the second ring 200 may also be disposed on the second ring 200 , and the photoelectric conversion element 300 a is connected to at least a part of the second conductive wire 210 . Each photoelectric conversion element 300/300a provides a voltage difference to the first conductive line 110 and the second conductive line 210 respectively to drive current, and each photoelectric conversion element 300/300a can be respectively provided with a power storage element 310/310a. In this embodiment, the electricity storage element 310 of the first ring 100 is electrically connected to the photoelectric conversion element 300 of the first ring 100 and the first conductive wire 110 respectively; and the electricity storage element 310a of the second ring 200 is respectively electrically The photoelectric conversion element 300a of the second ring 200 and the second conductive wire 210 are connected to each other, so as to discharge smoothly.

Preferably, the number of turns of the first conductive wire 110 is greater than three turns, and the number of turns of the second conductive wire 210 is also greater than three turns, so that a magnetic field of sufficient strength can be induced. Furthermore, the diameter of the first conductive wire 110 is greater than 0.01mm, and the diameter of the second conductive wire 210 is also larger than 0.01mm, thereby facilitating the generation of a magnetic field by the photoelectric element releasing current and the weak static driving current carried by the human body.

Generally speaking, the first ring 100 and the second ring 200 are designed to be worn on the symmetrical acupuncture points on the human body (on the left and right fingers or toes). Therefore, the number of winding turns of the first conductive wire 110 is approximately equal to the number of winding turns of the second conductive wire 210, the diameter of the first conductive wire 110 is approximately equal to the diameter of the second conductive wire 210, and the inner ring of the first ring 100 The diameter of the rim is approximately equal to the diameter of the inner rim of the second ring 200 , so that the strength of the magnetic field generated by the first ring 100 is equal to the strength of the magnetic field generated by the second ring 200 to balance the magnetic field of the human body. However, this creation is not limited thereto. For example, when the first ring 100 and the second ring 200 are designed to be worn on the asymmetric acupuncture points on the human body, the first ring 100 and the second ring 200 are designed to have different inner edges. When the diameter (corresponding to different fingers or toes can be between 14mm and 22mm), the first conductive wire 110 and the second conductive wire 210 can be configured to have different turns or diameters correspondingly so that the first The strength of the magnetic field generated by the ring 100 is equal to the strength of the magnetic field generated by the second ring 200 .

Preferably, the two ends of the first conductive wire 110 are located on the same side of the first ring 100 and are roughly aligned along the direction parallel to the axial direction of the first ring 100 so that the two ends of the first conductive wire 110 are arranged at a minimum distance. In order to reduce the resistance suffered when the internal current passes through the human body. Similarly, the two ends of the second conductive wire 210 are located on the same side of the second ring 200 and are roughly aligned along the direction parallel to the axial direction of the second ring 200 so that the two ends of the second conductive wire 210 are arranged at a minimum distance to reduce It is the resistance suffered by the internal current passing through the human body.

In order to increase the contact area with the user's skin, the self-driven magnetic-electric circulation pair ring of the invention can also be configured as shown in Figure 5 or Figure 6, and the sides of the two ends of the first conductive wire 110 expose the first insulating layer 120 , and the side surfaces of the two ends of the second conductive line 210 expose the second insulating layer 220 .

To sum up, the self-driven magnetoelectric circulation pairing ring of this creation can generate a magnetic field when worn on the human body, which can discharge gently to slow down oxidation, and can stimulate the acupuncture points of the human body.

"Human biological microcurrent" is a modern theory. According to this theory, it can be known that excessive static electricity is harmful to the human body, and maintaining an appropriate amount of static electricity can maintain the normal operation of the human body. The magnetic field of the human body is closely related to the geomagnetism or the surrounding environment. All organs of the human body contain mobile ions (for example: iron, potassium, sodium, calcium...). The meridians and acupoints of the human body are connected, and ions move in them to generate electric current. Fingers and toes are tip discharge parts, so charges are gathered here to release excessive static electricity. The palms and soles of the feet are covered with nerve reflex areas, and each points to different organs.

Diet and medicine, healing or regulation, are all aimed at bringing the chemical changes in the body into proper balance. If the electrostatic potential of the human body is too high, it will easily cause excessive oxidation and cause diseases. If the human body is not charged enough, the cells will lack activity and cause necrosis. The self-driven magnetoelectric circulation pairing ring created by this invention can moderately adjust the surplus and deficiency of the human body's magnetism and electricity, so as to keep the body in the best condition. Moreover, the self-driven magnetic-electric circulation pair ring of the present creation is convenient to wear and use for a long time.

The principle of the self-driven magnetoelectric circulation pair ring of the present invention is simple and obvious, and the effect is obvious, and it can be driven by the slight potential energy generated by the photoelectric conversion element 300 . The ring conductor is grounded by its own human body so that the current in it changes the magnetic force line to point outward or inward. The first ring 100 and the second ring 200 rotate clockwise and counterclockwise respectively so that the magnetic field lines of the human body and the external magnetic field form a circulation. When the fingers of the first ring 100 and the second ring 200 are close together, the magnetic fields of the two rings can be connected to facilitate the electric charge circulation of the human body.

The above descriptions are only preferred embodiments of this creation, and are not intended to limit the patent scope of this creation. Other equivalent changes that use the patent spirit of this creation should all fall within the patent scope of this creation.

100: first ring

110: the first conductive thread

120: the first insulating layer

200: second ring

210: second conductive wire

220: second insulating layer

300/300a: photoelectric conversion element

310/310a: electric storage element

Claims (10)

A self-driven magnetoelectric circulating ring, comprising: a first ring, including a first conductive wire, the first conductive wire is wound in a spiral shape, the first conductive wire is covered with a first insulating layer, and the Two ends of the first conductive wire expose the first insulating layer; and a second ring includes a second conductive wire wound in a spiral shape, and the second conductive wire is covered with a second insulating layer. layer, and the two ends of the second conductive wire expose the second insulating layer, wherein the winding direction of the first conductive wire is opposite to the winding direction of the second conductive wire, and the first ring is provided with an electrical A photoelectric conversion element connected to the first ring. The self-driven magnetoelectric circulating ring as described in Claim 1, wherein the end surfaces of the two ends of the first conductive wire expose the first insulating layer, and the end surfaces of the two ends of the second conductive wire expose the second insulating layer. In the self-driven magnetoelectric circular pair ring as claimed in claim 2, the side surfaces of the two ends of the first conductive wire expose the first insulating layer, and the side surfaces of the two ends of the second conductive wire expose the second insulating layer. The self-driven magnetoelectric circulating ring as described in Claim 1, wherein the number of winding turns of the first conductive wire is greater than three turns and the diameter of the first conductive wire is greater than 0.01mm, and the winding turns of the second conductive wire The number of turns is greater than three turns and the diameter of the second conductive wire is greater than 0.01mm. The self-driven magnetoelectric circulating pair ring according to claim 1, wherein the number of winding turns of the first conductive wire is approximately equal to the number of winding turns of the second conductive wire. The self-driven magnetoelectric circular current pair ring according to claim 1, wherein the inner diameter of the first conductive wire is approximately equal to the inner diameter of the second conductive wire. The self-driven magnetoelectric circular current pair ring as claimed in item 1, wherein the diameter of the inner edge of the first ring is approximately equal to the diameter of the inner edge of the second ring. The self-driven magnetoelectric circular current pair ring according to claim 1, wherein the two ends of the first conductive wire are located on the same side of the first ring and are roughly aligned along a direction parallel to the axial direction of the first ring, the Two ends of the second conductive wire are located on the same side of the second ring and are substantially aligned along a direction parallel to the axis of the second ring. The self-driven magnetoelectric circulating pair ring according to claim 1, wherein the second ring is provided with another photoelectric conversion element electrically connected to the second ring and the second ring. The self-driven magnetoelectric circulating pair ring according to claim 1, wherein the photoelectric conversion element is provided with an electric storage element.

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