JP2012189071A - Seawater high pressure jet generator - Google Patents
Seawater high pressure jet generator Download PDFInfo
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- JP2012189071A JP2012189071A JP2011092453A JP2011092453A JP2012189071A JP 2012189071 A JP2012189071 A JP 2012189071A JP 2011092453 A JP2011092453 A JP 2011092453A JP 2011092453 A JP2011092453 A JP 2011092453A JP 2012189071 A JP2012189071 A JP 2012189071A
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
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Abstract
Description
本発明は無限に存在する海水圧を利用し、水深の深い処の噴出海水を利用した発電装置である。 The present invention is a power generation apparatus that uses seawater pressure that exists infinitely and that uses erupted seawater at a deep water depth.
本発明に係わる設備技術等は殆んど見受けられず全く新時代の技術である。 The equipment technology related to the present invention is hardly seen, and is a technology of a completely new era.
以下の通り図1〜図4により説明をする。
従来の発電設備より大変簡単な設備で可能である。The description will be made with reference to FIGS.
This is possible with much simpler equipment than conventional power generation equipment.
水圧を利用し、自然の海水の水面下よりの噴出と空気容器による浮力によって回転扇部分が浮き上がり回転時の軸受の摩擦等が大幅に軽減され同時に高圧海水と高圧空気の同時噴出を受け回転扇が高速回転となり強力な発電を得るものである。 Using the water pressure, the rotating fan part is lifted by the natural seawater eruption from below the surface of the water and the buoyancy of the air container, and the friction of the bearing during rotation is greatly reduced. Becomes a high-speed rotation and obtains strong power generation.
従来の火力発電・水力発電は大規模な設備が必要であり併せて大量の炭酸ガス,煤煙等の大量噴出がある。本発明は従来の発電方法にも負けない大規模発電が可能である。 Conventional thermal power generation and hydroelectric power generation require large-scale facilities, and in addition, a large amount of carbon dioxide, soot, etc. are ejected. The present invention enables large-scale power generation comparable to conventional power generation methods.
1つの課題である炭酸ガス、煤煙等の大量噴出は殆んど無くなり又1つの課題である大規模発電を解決する為に数台より数十台を連結さす事等により充分可能でありよって大容量の発電を獲得出来るものである。 One issue, carbon dioxide, soot, and so on, is almost completely eliminated, and it is possible to connect several tens to several tens of units to solve large-scale power generation, which is one issue. Capable of acquiring capacity power generation.
海に近い場所であれば殆んどの場所で発電が可能となり、且つ設備が船の造船等と比べても大変に軽い
約数tから数十tの排水量でよく大変安価な設置となりあらゆる場所に設置が可能となるものである。Power generation is possible in almost any place close to the sea, and the equipment is very light compared to shipbuilding, etc. It requires only about a few t to tens of t of drainage and is very inexpensive and can be installed anywhere. Installation is possible.
〔図1〕
海の広さは無限に在り、出来るだけ多くの発電を目指す為に本設備を数台から数十台と連結さす方法を考える事により飛躍的に大量の発電結果が得られるものである。
多くの回転扇を連ねる事により空気容器の統合、船台部分の統合等により大幅に設備投資が軽減されるものである。
〔図2〕
1)まず船体部分に於ては諸設備重量が数10t程度と思われる事と回転扇部分が丸い為に総排水量が大幅に軽減されて、想像以上に軽量の総重量となる。
2)(イ)図の通りに空気容器(A)が浮上する力を利用して回転扇全体を持ち上げる事により回転摩擦の減少を図り高速回転を行なう為の大きな役割を果たす部分である。
3)(ロ)図の通りに船上空気圧縮ポンプと海中より噴き出す高水圧海水を「高圧ジェット水流」として噴射をし回転扇(A)(B)を高速回転させて発電を行なうものである。
4)(ハ)図の通りに各空気容器は水深10m〜20mとなり、強力な水圧が掛かる為に強力な鋼鉄と防水を備えた設備となり又本発電装置で大切な浮力の調整と海水の排水と荒天時の振動の調整等が本空気容器の役目である。
当然船上部分の大きさ重量等により大きさ形状等は当然変わるものである。
又体制の変化、海流の変化度等に依り本体内の排水の為の水槽の配置も変わるものとする。
5)(ニ)図の通りに高水圧の中での放水となる為にホースの太さも出来るだけ細くし、かつ強くて固いホースとする。
6)(ホ)図の通りに空気容器Bを加える事により大型の船上部分とより深度が深くなる事により噴出圧力が強い「高水圧海水」が得られ海上発電設備がより大きく安定して来るものである。
〔図3〕
本図の通りに上部回転扇部分より海水が本空気容器内に流入して来た時に本図の様に容機内を3段階の高さとし、3番目の部屋部分には海上より高圧空気が注入されて同時に海水排出ホースを通じて外海え放出されるものである。
〔図4〕
本図の通り空気容器が浮力により浮上する力を利用して回転扇部分の芯の軸先部分を数10cm程持ち上げる事により回転が始まると「駒の回転」の如くより中心の軸先部分の一点に重量が掛かるが、その回転がだんだんと高速回転となって来ると中心のよくとれた駒の回転のように軽快な回転と同時にほぼ空中に浮いた状態の回転となりより高速回転が得られるものとなり海中での揺れが半減される大切な部分である。[Figure 1]
The area of the sea is infinite, and a large amount of power generation results can be obtained by considering a method of connecting this equipment with several to several tens of units in order to aim for as much power generation as possible.
By connecting many rotating fans, the equipment investment can be greatly reduced by integrating the air container and the stern part.
[Figure 2]
1) First, in the hull part, the weight of various facilities seems to be about several tens of t, and the total amount of drainage is greatly reduced because the rotating fan part is round, resulting in a lighter weight than expected.
2) (A) As shown in the figure, this is a part that plays a major role in performing high-speed rotation by reducing the rotational friction by lifting the entire rotating fan using the force that the air container (A) rises.
3) As shown in (b), high-pressure seawater spouted from the ship's air compression pump and the sea is injected as a “high-pressure jet water flow”, and the rotating fans (A) and (B) are rotated at high speed to generate power.
4) (c) As shown in the figure, each air container has a water depth of 10m to 20m, and it is a facility equipped with strong steel and water proofing because of strong water pressure. The adjustment of vibration during stormy weather is the role of this air container.
Of course, the size, shape, etc. of course vary depending on the size, weight, etc. of the onboard part.
In addition, the arrangement of the water tank for drainage in the main body will change depending on the change of the system and the change of the ocean current.
5) (D) As shown in the figure, make the hose as thin as possible to make it discharge under high water pressure, and make it a strong and hard hose.
6) (e) By adding air container B as shown in the figure, a large shipboard part and deeper depth will result in a “high water pressure seawater” with a higher jet pressure, resulting in a larger and more stable offshore power generation facility. Is.
[Figure 3]
As shown in this figure, when seawater flows into the air container from the upper rotating fan part, the inside of the container is made up to three levels as shown in the figure, and high pressure air is injected into the third room part from the sea. At the same time, the seawater is discharged through the seawater discharge hose.
[Fig. 4]
As shown in this figure, when the rotation starts by lifting the axial tip of the core of the rotating fan part by several tens of centimeters using the force that the air container floats due to buoyancy, one point of the central axial tip part such as “Rotation of the piece” However, when the rotation gradually becomes high-speed rotation, it becomes a rotation that floats in the air at the same time as light rotation like the rotation of a good piece at the center, and high-speed rotation can be obtained. This is an important part where shaking in the sea is halved.
海上に於て船底部分に回転扇部分を設け船底部分より噴出される高水圧海水を船上からの高圧空気と混合させて「ジェット海水」として回転扇部分に直接噴出させて回転力を得る発電装置であって発生する海水を船外に排出さす為に空気容器船を数室に仕切り最後の室に船上より高圧空気を注入し、海水の排水を行ない排水後は高圧空気を逃しながら順次排水を行なう発電装置である。 A power generator that obtains rotational force by mixing high-pressure seawater ejected from the bottom of the ship with high-pressure air from the ship, and directly jetting it as "jet seawater" to the rotational fan part at sea. In order to discharge the generated seawater to the outside of the ship, the air vessel ship is divided into several chambers, high pressure air is injected into the last chamber from the ship, and the seawater is drained. It is a power generator to be performed.
海上に浮かせた船と、船の下に接続される容器とを具備し、前記船の船底部分に回転扇を設置し、前記回転扇に、船底部分に噴出する高圧な海水と船内から導入される高圧な空気とを混合させた「ジェット海水」を直接衝突させることにより、回転扇を回転させて発電する発電装置であって、前記容器は仕切り壁により複数の室に仕切り、回転扇に衝突させた後の海水を前記容器の前記複数の室に順次導入し貯留させ、前記回転扇に衝突させた後の海水を排出する際には、前記複数の室の最も下流側に位置する室に船内から導入される高圧な空気を注入することにより、前記回転扇に衝突させた後の海水を容器外に排出し、海水を排出しない際には、前記最も下流側に位置する室に充満した高圧な空気を逃がすことを繰り返す発電装置である。 It has a ship floated on the sea and a container connected to the bottom of the ship. A rotary fan is installed on the bottom of the ship, and the high-pressure seawater ejected to the bottom of the rotary fan is introduced from the ship. This is a power generation device that rotates a rotating fan to generate power by directly colliding with "jet seawater" mixed with high-pressure air, and the container is partitioned into a plurality of chambers by partition walls and collides with the rotating fan. When the seawater after being introduced and stored sequentially in the plurality of chambers of the container and discharging the seawater after colliding with the rotary fan is placed in a chamber located on the most downstream side of the plurality of chambers. By injecting high-pressure air introduced from the ship, the seawater after colliding with the rotary fan is discharged out of the container, and when the seawater is not discharged, the chamber located on the most downstream side is filled. It is a power generator that repeatedly releases high-pressure air
Claims (3)
同時に本空気容器安定船は本発電施設全体の海上での安定と波動等にも対応するものであるIn order to discharge the generated seawater to the outside of the ship, the air vessel stable ship is divided into several chambers, and in the last chamber, seawater is discharged with a tough hose that can withstand high water pressure simultaneously by injecting high pressure air from the ship. This air vessel stable ship is also compatible with the stability and wave motion of the entire power generation facility at sea.
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JP2011092453A JP5030007B1 (en) | 2011-03-10 | 2011-03-10 | Seawater pressure high-pressure jet generator |
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JP2011092453A JP5030007B1 (en) | 2011-03-10 | 2011-03-10 | Seawater pressure high-pressure jet generator |
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Publication number | Priority date | Publication date | Assignee | Title |
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JP2014137062A (en) * | 2013-01-17 | 2014-07-28 | Seiyu Shima | Large capacity drain due to double layer undersea space installation |
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JP2015020734A (en) * | 2013-07-22 | 2015-02-02 | 晴勇 島 | Whole concentration of high-capacity rotary fan power generation based on combination of power generation reinforcement by inner and outer rotary fan operation with negative pressure utilization on rough weather |
JP5622132B1 (en) * | 2013-12-03 | 2014-11-12 | 晴勇 島 | Rotating fan power generator equipment utilizing two-stage maritime draft line |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS61145374A (en) * | 1984-12-19 | 1986-07-03 | Masatoshi Toyoda | Sinking type generating device utilizing water pressure |
JPH03124974A (en) * | 1989-10-06 | 1991-05-28 | Hisao Fushiba | Atmospheric pressure-applied power generating device |
JP2004124866A (en) * | 2002-10-04 | 2004-04-22 | Tetsuji Tatsuoka | Submerged generator |
JP2005023799A (en) * | 2003-06-30 | 2005-01-27 | Tetsuji Tatsuoka | Submerged power generating device |
JP2007023780A (en) * | 2005-07-12 | 2007-02-01 | Shinko Jigyo Yugenkoshi | Pressure accumulating power generation system |
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2011
- 2011-03-10 JP JP2011092453A patent/JP5030007B1/en not_active Expired - Fee Related
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS61145374A (en) * | 1984-12-19 | 1986-07-03 | Masatoshi Toyoda | Sinking type generating device utilizing water pressure |
JPH03124974A (en) * | 1989-10-06 | 1991-05-28 | Hisao Fushiba | Atmospheric pressure-applied power generating device |
JP2004124866A (en) * | 2002-10-04 | 2004-04-22 | Tetsuji Tatsuoka | Submerged generator |
JP2005023799A (en) * | 2003-06-30 | 2005-01-27 | Tetsuji Tatsuoka | Submerged power generating device |
JP2007023780A (en) * | 2005-07-12 | 2007-02-01 | Shinko Jigyo Yugenkoshi | Pressure accumulating power generation system |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2014137062A (en) * | 2013-01-17 | 2014-07-28 | Seiyu Shima | Large capacity drain due to double layer undersea space installation |
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