TWM541142U - Non-power type underwater photonic vibration frequency collision device - Google Patents

Description

Non-powered underwater photon vibration frequency collision device

This creation provides information on non-powered underwater photon vibration collision devices, especially a structural technique that allows a momentum water flow with two photon beams to excite strong fluctuations after collision. When the original macromolecular group water flows in different water flow paths, the water is cut by magnetic force to form water of small molecular group traits, and at the same time, the photons in the far-infrared photonic crystal are instantaneously loaded, so that the two water streams having the photon beam collide and stimulate Momentum processing technology with strong vibration fluctuations.

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 the non-powered underwater photon vibration collision. The device will enhance the real benefits of low-carbon green energy in the world, and slow down the gap in the ozone layer and the rapid melting of ice in the polar regions.

The main purpose of this creation is to provide a non-powered underwater photon vibration pair. The collision device provides the momentum water flow that has been presented by the photon beam to the back end water demander. In order to achieve the above object, the non-powered underwater photon vibration frequency collision device comprises at least: a water inlet pipe having a water inlet water inlet and a water supply flow inlet; a water distribution pipe connected to the downstream of the water inlet pipe and having two water distribution zones, The introduced water flow is divided into two channels; the two central tubes are respectively connected to the downstream of the diversion area, one end of each central tube is a central tube inlet and the other end is a central tube outlet; and two central magnetized areas are disposed at the center a tube inlet to the central tube outlet, wherein each central magnetization zone is provided with a magnetic cutting unit corresponding to the water flow path; and the two photon supporting area has one end of the photon supporting area inlet and the other end of the photon supporting area The water inlet, the water inlet of the photon loading area is respectively connected to the central pipe outlet, and is located downstream of the two central magnetization zone, wherein each photon carrier zone is provided with a far infrared photonic crystal corresponding to the water flow path, and a far infrared ray The photonic crystal is fixed in the support zone of the photon; in the second busbar, one end of each of the busbars is a water inlet of the busbar, and the other end is a water outlet of the busbar The two-way inflow port is connected downstream of the water outlet of the photon-attached area, the two-port water outlets are oppositely arranged and maintain a pair of collision spacing; and a confluence collision area protection tube has a branching state at one end and respectively Nesting on the periphery of the two manifolds, and forming a confluence collision zone corresponding to the collision distance, and the other end is a confluence drain pipe located downstream of the confluence collision zone, so that two water flows from the two manifolds It flows to the confluence collision zone and is discharged from the confluence drain of the confluence drain after colliding with each other.

The non-powered underwater photon vibration frequency colliding device may further comprise: two outer tubes respectively sleeved outside the central tube protection tube, the central tube protection tube is opposite to the central tube to the downstream end of the photon supporting area, The outer tube is connected to the confluence zone protection tube, and is connected to the central tube protection tube near the downstream end of the photon loading area and communicates with the outer tube, so that water flows from the outer tube to the confluence tube. The outer tube and the shunt tube may be integrated into one or a segment.

Compared with the difference of traditional water resources technology, this creation provides a non-powered underwater photon vibration frequency collision device. Because the collision device adopts a non-powered momentum water flow transmission means, the user only needs to use the device. The water inlet pipe is connected to the water source supply where it is easy to obtain and has been cleaned. The use of non-powered water photon vibrating collision devices, 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

11‧‧‧Inlet pipe inlet

20‧‧‧Shunt tube

21‧‧‧Shrink pipe inlet

22‧‧‧Diversion area

30‧‧‧Center magnetization zone

31‧‧‧Central tube

32‧‧‧ center tube inlet

33‧‧‧Magnetic cutting unit

331‧‧‧ Magnet

34‧‧‧Center tube outlet

40‧‧‧ Photon loading area

41‧‧‧ Photon loading area inlet

42‧‧‧ far infrared photonic crystal

43‧‧‧ bracket

44‧‧‧ Photon loading area outlet

50‧‧‧Center tube protection

51‧‧‧External management

60‧‧‧ Confluence collision zone protection

61‧‧‧Conduit tube

62‧‧‧Conduit inlet

63‧‧‧Conduit outlet

64‧‧‧Confluence collision zone

70‧‧‧Confluence drain

71‧‧‧ Confluence outlet

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

The second drawing is a schematic cross-sectional view of the first embodiment of the present creation.

The third figure is a schematic diagram of the far infrared crystal of the first embodiment of the present creation.

The fourth drawing is a cross-sectional view of the manifold of the first embodiment of the present creation.

Figure 5 is a partial cross-sectional view of the shunt tube of the second embodiment of the present invention.

Referring to the first to fourth figures, a schematic diagram of a three-dimensional appearance of the first embodiment of the present invention, a schematic cross-sectional view, a schematic diagram of a far-infrared photonic crystal, and a cross-sectional view of a bus tube are disclosed, and the non-powered underwater photon vibration frequency pair is disclosed. The main structure of the collision device comprises an inlet pipe 10, an inlet pipe inlet 11, a shunt pipe 20, a shunt pipe inlet 21, a diverter zone 22, a center pipe 31, two center pipe inlets 32, and two central magnetizations. The area 30, the two magnetic cutting unit 33, the plurality of magnets 331, the two central tube outlets 34, the two-photon loading area 40, the two-photon loading area water inlet 41, the two far-infrared photonic crystals 42, the two brackets 43, and the two-photon supporting area The water outlet 44, the two central pipe protection pipes 50, the two outer pipes 51, a confluence collision zone protection pipe 60, two busbars 61, two busbar inlets 62, and two confluences The pipe outlet 63, a confluence collision zone 64, a confluence drain 70, and a confluence drain 71.

The water inlet pipe 10 has a water inlet port 11 for introducing water, for example, connecting to a household water supply end, an agricultural water supply end, an industrial water supply end, a fishery water supply end or a medical water supply end.

The shunt pipe 20 is connected to the downstream of the water inlet pipe 10 by the water inlet pipe 21 of the shunt pipe and has two flow streams of water introduced by the two diverting zones 22. The two central tubes 31 are respectively connected to the downstream of the flow dividing area 22, one end of each central tube 31 is a central tube water inlet 32, and the other end is a central tube water outlet 34, and the two central magnetized areas 30 are disposed at the central tube water inlet 32. Between the central tube outlets 34.

Each of the central magnetization regions 30 is provided with a magnetic cutting unit 33 corresponding to the water flow path to make the water molecular group fine. The magnetic cutting unit 33 can be composed of a plurality of equidistantly arranged magnets 331 and is provided with a central tube protection. Tube 50 isolates magnet 331 from the flow of water.

The photon supporting area 40 is respectively connected to the central tube water outlet 34 disposed downstream of the central magnetizing area 30 through the photon supporting area water inlet 41, one end of which is a photon supporting area water inlet 41, and the other end is a photon supporting area water outlet 44, each of which is a photon supporting area water outlet 44. The photon-attached region 40 is provided with a far-infrared photonic crystal 42 corresponding to the water flow path, and the far-infrared photonic crystal 42 is fixed in the bracket 43 in the photon-attached region 40, so that the water flow effectively carries the far-infrared photons.

The two manifolds 61, one end of each of the manifolds 61 is a manifold inlet 62, and the other end is a manifold outlet 63. The inlet inflow port 62 is connected downstream of the photon-attached zone outlet 44, the manifold outlet 63 is oppositely disposed and maintains a pair of collision spacing; and a confluence collision zone protection tube 60 has a branching end at one end and two sleeves respectively disposed around the two confluence tubes 61 and corresponding to the collision The spacing forms a confluence collision zone 64, and the other end is a confluence drain pipe 70 located downstream of the confluence collision zone 64, so that two water flows from the two manifolds 61 flow to the confluence collision zone. 64, after colliding with each other, is discharged from the confluence discharge port 71 of the confluence drain pipe 70.

The first embodiment of the present invention may further include two central tube protection tubes 50 respectively disposed outside the central tubes 31, and two outer tubes 51 respectively disposed outside the central tube protection tubes 50, the central tube protection tubes The photon-attached area 40 is coupled to the downstream of the central tube 31. The outer tube 51 is coupled to the confluent collision area guard 60 and the confluence tube 61, and is adjacent to the central end of the photon-attached area 40 near the downstream end. The protective tube 50 communicates with the outer tube 51 to allow water to overflow from the outer tube 51 to the manifold 61.

Referring to the fifth figure, a partial cross-sectional view of the shunt tube of the second embodiment of the present invention is substantially the same as the overall technical means of the first embodiment, except that the outer tube 51 and the shunt tube 20 are divided. The segments are made after the manufacture.

According to the above embodiments, a preferred method for vibrating the photon in the water can be provided. After the water flow is split, the water flow after the splitting is sequentially passed through the magnetic cutting unit 33 to make the water flow smaller. The photons of the far-infrared photonic crystal 42 are loaded, and the momentum water that forms the photon beam in the overflow passes through the manifold 61 and reaches the confluence collision zone 64. After the collision, the momentum water with more intense vibration fluctuations is excited.

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

11‧‧‧Inlet pipe inlet

20‧‧‧Shunt tube

21‧‧‧Shrink pipe inlet

22‧‧‧Diversion area

30‧‧‧Center magnetization zone

31‧‧‧Central tube

32‧‧‧ center tube inlet

33‧‧‧Magnetic cutting unit

331‧‧‧ Magnet

34‧‧‧Center tube outlet

40‧‧‧ Photon loading area

41‧‧‧ Photon loading area inlet

42‧‧‧ far infrared photonic crystal

43‧‧‧ bracket

44‧‧‧ Photon loading area outlet

50‧‧‧Center tube protection

51‧‧‧External management

60‧‧‧ Confluence collision zone protection

61‧‧‧Conduit tube

62‧‧‧Conduit inlet

63‧‧‧Conduit outlet

64‧‧‧Confluence collision zone

70‧‧‧Confluence drain

71‧‧‧ Confluence outlet

Claims (4)

The utility model relates to a non-powered underwater photon vibration frequency collision device, which comprises at least: a water inlet pipe with a water inlet water inlet and a water supply flow introduction; a water distribution pipe connected to the downstream of the water inlet pipe and having two water distribution zones, the introduced water flow splitting Two central tubes are respectively connected to the downstream of the diversion area, one end of each central tube is a central tube inlet and the other end is a central tube outlet; and two central magnetized areas are disposed at the central tube inlet to Between the central pipe outlets, each central magnetization zone is provided with a magnetic cutting unit corresponding to the water flow path; and the two photon supporting zone has one end of the photon supporting zone water inlet and the other end of the photon supporting zone water outlet. The water inlets of the photon-attached area are respectively connected to the central tube outlet and located downstream of the two central magnetization areas, and each photon-attached area is provided with a far-infrared photonic crystal corresponding to the water flow path, and a far-infrared photonic crystal is fixed in the photon-attached area. a bracket in the photon-attached area; two busbars, one end of each manifold is a manifold inlet, and the other end is a manifold outlet, the sink flows into the water Connected to the downstream of the water outlet of the photon supporting area, the water outlet of the collecting tube is oppositely arranged and maintains a pair of collision spacing; and a protective tube of the converging collision area has a branching state at one end and is respectively sleeved on the two confluences The outer periphery of the tube forms a confluence collision zone corresponding to the collision distance, and the other end is a confluence drainage pipe located downstream of the confluence collision zone, so that two water flows from the two confluence pipes flow to the confluence collision zone. After colliding with each other, it is discharged from the confluence drain of the manifold drain. The non-powered underwater photon vibration frequency collision device according to claim 1, further comprising two central tube protection tubes respectively disposed outside the central tubes, and two respectively disposed outside the central tube protection tube An outer tube, the central tube protection tube is opposite to the central tube and the photon supporting area, the outer tube is connected with the collecting tube, and the central tube protecting tube is connected to the outer tube with respect to the photon supporting area near the downstream end, so that the water flow The outer tube overflows to the manifold. The non-powered underwater photon vibration frequency colliding device according to claim 2, wherein the outer tube and the shunt tube are integrated. The non-powered underwater photon vibration frequency colliding device according to claim 2, wherein the outer tube and the shunt tube are joined by a segment.