TWM543873U - Device for stabilizing water photon vibrational frequency and miniaturizing magnetic fluid characteristics - Google Patents

Description

Device for stabilizing photon vibration frequency and miniaturizing magnetic fluid property in water

This creation provides information on the stabilization of photon vibration and the properties of fine magnetic fluids in water, especially macromolecular water, which is magnetically cut to form water with fine magnetic fluid properties, while simultaneously loading photons in far-infrared photonic crystals. The overflow completes the second magnetic cutting through the cavity region to obtain the effect of stabilizing the photon vibration and miniaturizing the magnetic fluid properties.

Water is one of the most important sources of life in nature. Water plays a very important role in humans, animals, plants, climate change and temperature regulation. Although water resources technology is widely used in people's livelihood, animal, plant, medical and various industries, the current level of momentum science and technology can not fully meet the low carbon green energy standards.

In view of this, the creator completed the experimental study of the photon vibration collision in the water by the principle of the tsunami caused by the strong vertical and horizontal waves released during the earthquake crust change, and proposed to stabilize the photon vibration and fine magnetic fluid in the water. The traits of the device, to enhance the real benefits of global low-carbon green energy, to slow down the gap in the ozone layer, the rapid hurricane melting ice.

One of the purposes of this creation is to provide a device for stabilizing photon vibration and fine magnetic fluid properties in water, and to present the momentum current and fine magnetic properties of the photon beam. The fluid is provided to the back end water users. In order to achieve the above purpose, the device for stabilizing the photon vibration frequency and the fine magnetic fluid property in the water comprises at least: a water inlet pipe and a water supply flow introduction; a central pipe connected to the downstream of the water inlet pipe, and one end of the central pipe is a central pipe The water inlet and the other end are a central pipe outlet; a central magnetization zone is disposed between the central pipe inlet and the central pipe outlet, and the central magnetization zone is provided with a magnetic cutting unit corresponding to the water flow path; a photon The loading area has one end of the photon supporting area water inlet and the other end is a photon supporting area water outlet. The photon supporting area inlet is connected to the central tube outlet and located downstream of the central magnetizing area, and the photon supporting area corresponds to the water flow. A far-infrared photonic crystal module is disposed on the path; a central tube protection tube is sleeved outside the central tube and outside the photon-attached area, and the magnetic cutting unit is wrapped around the central tube protection Between the tube and the central tube; an outer tube, sleeved outside the central tube protection tube, and forming a cavity region connected downstream of the photon supporting area, one end of the cavity area is a cavity area Port, and the other end to the outlet region of the cavity, so that the water inlet, the second outlet is discharged to the cavity area cutting means after the magnetic direction toward the outlet region of the cavity along the cavity region. Thereby, the water flows through the first magnetic cutting, the photon carrying region of the photon, the second magnetic cutting, and the water outlet of the cavity region, so as to maintain the properties of the fine magnetic fluid and carry the water flow of the photon beam momentum, and provide Used by back-end water demanders.

The device for stabilizing photon vibration and miniaturizing magnetic fluid properties in water, wherein the far-infrared photonic crystal module comprises a hollow fixing sleeve with an open state at both ends, and a positioning member disposed in the fixing sleeve, at least A far-infrared photonic crystal fixed by the positioning member and mounted in the fixing sleeve, the water outlet of the supporting area is a bottom end of the fixing sleeve, so that the far-infrared photonic crystal module can exhibit the advantages of modular manufacturing and assembly.

Compared with the difference of traditional water resources technology, this creation provides a stable water The medium photon vibration frequency and the device for miniaturizing the magnetic fluid property, because the device adopts the non-powered momentum water flow conveying means, the user only needs to connect the water inlet pipe of the device, and is connected to the general easy to obtain and has been treated with water purification. The water supply is available. The use of stable photon vibration and fine magnetic fluid traits in addition to improving human health and water use mechanisms, is more suitable for agriculture, fisheries, livestock and aquaculture, industry and medicine.

10‧‧‧Water inlet

30‧‧‧Center tube

31‧‧‧ center tube inlet

32‧‧‧Center magnetization zone

33‧‧‧Magnetic cutting unit

331‧‧‧ Magnet

34‧‧‧Center tube outlet

40‧‧‧ Photon loading area

41‧‧‧ Photon loading area inlet

42‧‧‧ far infrared photonic crystal module

43‧‧‧ fixing sleeve

431‧‧‧ Positioning parts

432‧‧‧ far infrared photonic crystal

44‧‧‧ Photon loading area outlet

50‧‧‧Center tube protection

51‧‧‧External management

511‧‧‧Cavity area

512‧‧‧cavity inlet

513‧‧‧cavity outlet

The first figure is a schematic perspective view of the preferred embodiment of the present invention.

The second drawing is a schematic cross-sectional view of a preferred embodiment of the present invention.

The third figure is a schematic diagram of the far-infrared photonic crystal module of the preferred embodiment of the present invention.

Referring to the first to third figures, a schematic perspective view, a cross-sectional view, and a schematic diagram of a far-infrared photonic crystal module of the preferred embodiment of the present invention are disclosed. The photon vibration and fine magnetic fluid in the stable water are disclosed. The main structure of the device includes: a water inlet pipe 10, a central pipe 30, a central pipe inlet 31, a central magnetization zone 32, a magnetic cutting unit 33, a plurality of magnets 331, a central pipe outlet 34, and a photon. The loading area 40, a photon supporting area water inlet 41, a far infrared photonic crystal module 42, a fixing sleeve 43, a positioning member 431, a far infrared photonic crystal 432, a photon supporting area water outlet 44, and a central tube protection The tube 50, an outer tube 51, a cavity area 511, a cavity area water inlet 512, and a cavity area water outlet 513.

The water inlet pipe 10 is used for water supply, for example, connecting to the domestic water supply end, agricultural use Water supply end, industrial water supply end, fishery water supply end or medical water supply end.

A central pipe 30 is connected to the downstream of the water inlet pipe 10. One end of the central pipe 30 is a central pipe water inlet 31, and the other end is a central pipe water outlet 34. A central magnetization zone 32 is disposed at the center pipe inlet 31 to the center. Between the tube outlets 34.

A magnetic cutting unit 33 is disposed in the central magnetizing region 32 corresponding to the water flow path to make the fluid magnetic and fine. The magnetic cutting unit 33 can be composed of a plurality of equidistantly arranged magnets 331 and is provided with a central tube protective tube. 50. The magnet 331 is completely isolated from the water flow.

The photon-attached area 40 has a photon-attached area water inlet 41 at one end and a photon-attached area water outlet 44 at the other end. The photon-attached area water inlet 41 is connected to the central tube outlet 34 and located downstream of the central magnetization area 32. A far-infrared photonic crystal module 42 is disposed in the photon-attached area 40 corresponding to the water flow path, and the far-infrared photonic crystal module 42 includes a hollow fixing sleeve 43 having an open state at both ends, and a set in the fixed sleeve. The positioning member 431, the at least one far-infrared photonic crystal 432 fixed in the fixing sleeve 43 by the positioning member 431, the water outlet 44 of the supporting area is the bottom end of the fixing sleeve 43, so that the far-infrared photonic crystal module 42 can The advantages of modular manufacturing and assembly are presented. When implementing, the far-infrared photonic crystal module 42, the fixing sleeve 43 and the positioning member 431 can be implemented according to different use requirements or different sizing according to different size and size specifications. .

The central tube protection tube 50 is sleeved outside the central tube 30 and outside the photon attachment area 40, and the magnetic cutting unit 33 is wrapped between the central tube protection tube 50 and the central tube 30. The outer tube 51 is sleeved outside the central tube protection tube 50, and forms a cavity region 511 that is connected downstream of the photon-attached region 40. One end of the cavity region 511 is a cavity inlet 512 and the other end is empty. The chamber water outlet 513 causes the water flow to pass through the water inlet 512 of the cavity area toward the cavity outlet 513 for the second time. The unit 33 is cut to complete the second magnetic cutting.

According to the above embodiments, a method for stabilizing the photon vibration and the fine magnetic fluid property in the water can be provided, and the water flow is sequentially subjected to the first magnetic cutting through the central magnetization region 32 to form a fine magnetic fluid by magnetic cutting. After the water of the trait is loaded with the photons of the far-infrared photonic crystal 432, the water of the magnetic fluid is again flowed through the cavity 511 at the periphery of the central magnetization region 32 to complete the second magnetic cutting, thereby finally miniaturizing the magnetic fluid having the photon beam. The water flows to the cavity outlet 513 to obtain the effect of stabilizing the photon vibration and finening the magnetic fluid properties in the water.

The above implementation descriptions, the best examples of the series of creations, are not limited to the scope of the patents of this creation. Anyone who uses the same technology and means of the same technology and means to change the same purpose and function should belong to this book. The scope of application for protection.

10‧‧‧Water inlet

30‧‧‧Center tube

31‧‧‧ center tube inlet

32‧‧‧Center magnetization zone

33‧‧‧Magnetic cutting unit

331‧‧‧ Magnet

34‧‧‧Center tube outlet

40‧‧‧ Photon loading area

41‧‧‧ Photon loading area inlet

42‧‧‧ far infrared photonic crystal module

43‧‧‧ fixing sleeve

431‧‧‧ Positioning parts

432‧‧‧ far infrared photonic crystal

44‧‧‧ Photon loading area outlet

50‧‧‧Center tube protection

51‧‧‧External management

511‧‧‧Cavity area

512‧‧‧cavity inlet

513‧‧‧cavity outlet

Claims (2)

The utility model relates to a device for stabilizing photon vibration frequency and miniaturizing magnetic fluid properties in water, comprising at least: a water inlet pipe and a water supply flow introduction; a central pipe connected to the downstream of the water inlet pipe, one end of the central pipe being a central pipe inlet, and the other One end is a central pipe outlet; a central magnetization zone is disposed between the central pipe inlet and the central pipe outlet, the central magnetization zone is provided with a magnetic cutting unit corresponding to the water flow path; and a photon supporting zone One end is the water inlet of the photon supporting area, and the other end is the water outlet of the photon supporting area. The inlet of the photon supporting area is connected to the central tube outlet and located downstream of the central magnetizing area, and the photon supporting area is provided with a corresponding water flow path. a far-infrared photonic crystal module; a central tube protection tube, the central tube protection tube sleeve is disposed outside the central tube and outside the photon-attached area, and the magnetic cutting unit is wrapped around the central tube protection tube and the center Between the tubes; an outer tube, sleeved outside the central tube protection tube, and forming a cavity region that is connected downstream of the photon-attached region, one end of the cavity region is a cavity inlet and the other end of the cavity region The outlet direction of the cavity region, the flow of water along the cavity toward the inlet region of the cavity region of the secondary outlet means after the magnetic cut, the outlet from the discharge region of the cavity. The apparatus for stabilizing photon vibration and miniaturizing magnetic fluid properties in water according to claim 1, wherein the far-infrared photonic crystal module comprises a hollow fixing sleeve having an open state at both ends, and a hollow fixing sleeve disposed in the fixing sleeve. The positioning member, the at least one far-infrared photonic crystal fixed by the positioning member and disposed in the fixing sleeve, the water outlet of the supporting area is a bottom end of the fixing sleeve.