TWM541142U - Non-power type underwater photonic vibration frequency collision device - Google Patents
Non-power type underwater photonic vibration frequency collision device Download PDFInfo
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- TWM541142U TWM541142U TW105212346U TW105212346U TWM541142U TW M541142 U TWM541142 U TW M541142U TW 105212346 U TW105212346 U TW 105212346U TW 105212346 U TW105212346 U TW 105212346U TW M541142 U TWM541142 U TW M541142U
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Description
本創作係提供關於非動力式水中光子振頻對撞裝置,尤指一種可令具有兩個光子束的動量水流,對撞後激發強烈波動的結構技術。意使原大分子團水分流於不同水流路徑時,經磁力切割形成小分子團性狀的水,同時瞬間加載遠紅外線光子晶體中的光子,令兩個均具有光子束的水流匯流對撞,激發強烈振頻波動的動量處理技術。 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.
水是自然界之中最重要的生命泉源之一,不論在人類、動物、植物,乃至於氣候變化、溫度調節,水都扮演著相當重要的角色。然水資源科技雖廣泛運用於民生、動物、植物、醫療及各產業領域,唯現今之動量科學技術水平,仍無法完全滿足低碳綠能的標準。 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.
有鑑於此,創作人藉地震地殼變動之際所釋出的強烈縱橫頻波所引發的大海嘯原理,完成水中光子振頻對撞的實驗研究,並提出非動力式水中光子振頻對撞之裝置,俾提升全球低碳綠能的實質效益,期減緩臭氧層缺口擴大、極地急速融冰的浩劫。 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.
本創作之主要目的,係在提供一種非動力式水中光子振頻對 撞裝置,將已呈現光子束振頻對撞之動量水流提供給後端水資源需求者使用。為達上述目的,非動力式水中光子振頻對撞裝置,至少包含:一入水管,具有一入水管入水口供水流導入;一分流管,銜接於該入水管下游並具有二個分流區,該導入之水流分流為兩道;二中心管,分別銜接於該分流區下游,每一中心管之一端為一中心管入水口、另一端為中心管出水口;二中心磁化區,設置於該中心管入水口至該中心管出水口之間,該每一中心磁化區內對應於水流路徑上設有一磁切單元;二光子附載區,其一端為光子附載區入水口,另一端為光子附載區出水口,該光子附載區入水口分別銜接於中心管出水口,並位於該二中心磁化區的下游,該每一光子附載區內對應於水流路徑上設有一遠紅外線光子晶體、一將遠紅外線光子晶體固定在該光子附載區內的支架;二匯流管,每一匯流管之一端為一匯流管入水口、另一端為匯流管出水口,該二匯流入水口銜接於該光子附載區出水口的下游,該二匯流管出水口呈相對設置並保持一對撞間距;以及一匯流對撞區護管,其一端呈分岔態樣並分別套設於該二個匯流管外圍,並對應於該對撞間距形成一匯流對撞區,另一端為位於該匯流對撞區下游的匯流排水管,令該二匯流管所流出的兩道水流流至匯流對撞區,相互對撞後自該匯流排水管的匯流排水口排出。 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.
非動力式水中光子振頻對撞裝置實施時可進一步包含,二個分別套設在該中心管護管外的外管,該中心管護管相對於該中心管至該光子附載區下游端,該外管與該匯流對撞區護管銜接,又相對於光子附載區靠近下游端之該中心管護管且與該外管相通,令水流自該外管溢流至該匯流管。上述外管與該分流管可為一體而成者或分段銜接而成者。 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.
相較於傳統水資源技術之差異性,本創作係提供一種非動力式水中光子振頻對撞裝置,由於對撞裝置採非動力式動量水流的輸送手段,故使用者僅需將該裝置之入水管,銜接安裝於一般取得容易且已經淨水處理手段之水源供應處即可。運用非動力式水中光子振頻對撞之裝置,除可提升人類健康的生活用水機制,更適用於農業、漁業、畜產養殖業、工業及醫學等廣大領域。 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‧‧‧入水管 10‧‧‧Water inlet
11‧‧‧入水管入水口 11‧‧‧Inlet pipe inlet
20‧‧‧分流管 20‧‧‧Shunt tube
21‧‧‧分流管入水口 21‧‧‧Shrink pipe inlet
22‧‧‧分流區 22‧‧‧Diversion area
30‧‧‧中心磁化區 30‧‧‧Center magnetization zone
31‧‧‧中心管 31‧‧‧Central tube
32‧‧‧中心管入水口 32‧‧‧ center tube inlet
33‧‧‧磁切單元 33‧‧‧Magnetic cutting unit
331‧‧‧磁鐵 331‧‧‧ Magnet
34‧‧‧中心管出水口 34‧‧‧Center tube outlet
40‧‧‧光子附載區 40‧‧‧ Photon loading area
41‧‧‧光子附載區入水口 41‧‧‧ Photon loading area inlet
42‧‧‧遠紅外線光子晶體 42‧‧‧ far infrared photonic crystal
43‧‧‧支架 43‧‧‧ bracket
44‧‧‧光子附載區出水口 44‧‧‧ Photon loading area outlet
50‧‧‧中心管護管 50‧‧‧Center tube protection
51‧‧‧外管 51‧‧‧External management
60‧‧‧匯流對撞區護管 60‧‧‧ Confluence collision zone protection
61‧‧‧匯流管 61‧‧‧Conduit tube
62‧‧‧匯流管入水口 62‧‧‧Conduit inlet
63‧‧‧匯流管出水口 63‧‧‧Conduit outlet
64‧‧‧匯流對撞區 64‧‧‧Confluence collision zone
70‧‧‧匯流排水管 70‧‧‧Confluence drain
71‧‧‧匯流排水口 71‧‧‧ Confluence outlet
第一圖係本創作第一實施例之立體外觀示意圖。 The first figure is a schematic perspective view of the first embodiment of the present creation.
第二圖係本創作第一實施例之剖視示意圖。 The second drawing is a schematic cross-sectional view of the first embodiment of the present creation.
第三圖係本創作第一實施例之遠紅外線晶體示意圖。 The third figure is a schematic diagram of the far infrared crystal of the first embodiment of the present creation.
第四圖係本創作第一實施例之匯流管剖視圖。 The fourth drawing is a cross-sectional view of the manifold of the first embodiment of the present creation.
第五圖係本創作第二實施例之分流管局部剖視圖。 Figure 5 is a partial cross-sectional view of the shunt tube of the second embodiment of the present invention.
請參閱第一圖至第四圖所示,係本創作第一實施例之立體外觀圖示意圖、剖視示意圖、遠紅外線光子晶體示意圖、匯流管剖視圖,圖中揭示非動力式水中光子振頻對撞裝置之主要結構包含一入水管10、一入水管入水口11、一分流管20、一分流管入水口21、二分流區22、一中心管31、二中心管入水口32、二中心磁化區30、二磁切單元33、複數磁鐵331、二中心管出水口34、二光子附載區40、二光子附載區入水口41、二遠紅外線光子晶體42、二支架43、二光子附載區出水口44、二中心管護管50、二外管51、一匯流對撞區護管60、二匯流管61、二匯流管入水口62、二匯流 管出水口63、一匯流對撞區64、一匯流排水管70、一匯流排水口71。 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.
入水管10具有一入水管入水口11供流水導入,例如銜接於家庭用水供應端、農業用水供應端、工業用水供應端、漁業用水供應端或醫療用水供應端。 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.
分流管20以分流管入水口21銜接於入水管10下游並具有二個分流區22導入之流水分流為二。二中心管31分別銜接於該分流區22下游,每一中心管31之一端為一中心管入水口32、另一端為中心管出水口34,二中心磁化區30設置於該中心管入水口32至該中心管出水口34之間。 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.
該每一中心磁化區30內對應於水流路徑上設有一磁切單元33,使水分子團細小化,該磁切單元33可由複數個等距排列之磁鐵331所構成,並設有中心管護管50,將磁鐵331與水流完全隔離。 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.
光子附載區40,分別透過光子附載區入水口41銜接設置於中心磁化區30下游之中心管出水口34,其一端為光子附載區入水口41,另一端為光子附載區出水口44,每一光子附載區40,對應於水流路徑上均設有一遠紅外線光子晶體42,一將遠紅外線光子晶體42固定於光子附載區40內的支架43中,使水流有效附載遠紅外線光子。 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.
二匯流管61,每一匯流管61之一端為一匯流管入水口62、另一端為匯流管出水口63,該匯流入水口62銜接於該光子附載區出水口44下游,該匯流管出水口63呈相對設置並保持一對撞間距;以及一匯流對撞區護管60,其一端呈分岔態樣並為二個分別套設於該二個匯流管61外圍,並對應於該對撞間距形成一匯流對撞區64,另一端為位於該匯流對撞區64下游的匯流排水管70,令該二匯流管61所流出的兩道水流流至匯流對撞區 64,相互對撞後自該匯流排水管70的匯流排水口71排出。 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.
本創作第一實施例可進一步包含二個分別套設在各中心管31外的中心管護管50、二個分別套設在該中心管護管50外的外管51,該中心管護管50相對於該中心管31之下游,銜接該光子附載區40,該外管51與該匯流對撞區護管60及匯流管61銜接,又相對於光子附載區40靠近下游端之該中心管護管50與該外管51相通,令水流自該外管51溢流至該匯流管61。 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.
請參閱第五圖所示,為本創作第二實施例之分流管局部剖視圖,本實施例與第一實施例之整體技術手段大致相同,不同之處在於外管51與該分流管20為分段製造後銜接而成。 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.
藉由上述各實施例,可提供一種較佳的水中光子振頻對撞之方法,係將水流分流後,令分流後之水流分別依序經過磁切單元33、使水分子團細小化之水流附載遠紅外線光子晶體42之光子,再令溢流中形成光子束之動量水流通過匯流管61,並直至匯流對撞區64,對撞後激化出更強烈振頻波動的動量水流。 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.
以上實施說明,係列舉本創作之最佳實施例,並非以此侷限本創作之專利範圍,舉凡與本創作採相同技術、手段之簡易均等置換變化而達相同目的、功效者,均應屬本創作之申請保護範疇。 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‧‧‧入水管 10‧‧‧Water inlet
11‧‧‧入水管入水口 11‧‧‧Inlet pipe inlet
20‧‧‧分流管 20‧‧‧Shunt tube
21‧‧‧分流管入水口 21‧‧‧Shrink pipe inlet
22‧‧‧分流區 22‧‧‧Diversion area
30‧‧‧中心磁化區 30‧‧‧Center magnetization zone
31‧‧‧中心管 31‧‧‧Central tube
32‧‧‧中心管入水口 32‧‧‧ center tube inlet
33‧‧‧磁切單元 33‧‧‧Magnetic cutting unit
331‧‧‧磁鐵 331‧‧‧ Magnet
34‧‧‧中心管出水口 34‧‧‧Center tube outlet
40‧‧‧光子附載區 40‧‧‧ Photon loading area
41‧‧‧光子附載區入水口 41‧‧‧ Photon loading area inlet
42‧‧‧遠紅外線光子晶體 42‧‧‧ far infrared photonic crystal
43‧‧‧支架 43‧‧‧ bracket
44‧‧‧光子附載區出水口 44‧‧‧ Photon loading area outlet
50‧‧‧中心管護管 50‧‧‧Center tube protection
51‧‧‧外管 51‧‧‧External management
60‧‧‧匯流對撞區護管 60‧‧‧ Confluence collision zone protection
61‧‧‧匯流管 61‧‧‧Conduit tube
62‧‧‧匯流管入水口 62‧‧‧Conduit inlet
63‧‧‧匯流管出水口 63‧‧‧Conduit outlet
64‧‧‧匯流對撞區 64‧‧‧Confluence collision zone
70‧‧‧匯流排水管 70‧‧‧Confluence drain
71‧‧‧匯流排水口 71‧‧‧ Confluence outlet
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TW105212346U TWM541142U (en) | 2016-08-15 | 2016-08-15 | Non-power type underwater photonic vibration frequency collision device |
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TW105212346U TWM541142U (en) | 2016-08-15 | 2016-08-15 | Non-power type underwater photonic vibration frequency collision device |
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