JP2012021519A

JP2012021519A - Manufacturing method for pressure using self-sustaining rotating force drawing device

Info

Publication number: JP2012021519A
Application number: JP2010175773A
Authority: JP
Inventors: Toshiharu Oishi; 利春大石
Original assignee: Individual
Current assignee: Individual
Priority date: 2010-07-16
Filing date: 2010-07-16
Publication date: 2012-02-02

Abstract

PROBLEM TO BE SOLVED: To provide a method for manufacturing an apparatus that can generate clean electric energy and use it, utilizing self-sustaining rotational force obtained with a simple device incorporating a generator, using pressure obtainable by compressing air, without using electric power and fossil fuel thereby avoiding an increase in carbon dioxide, irrespective of weather and night or daytime.SOLUTION: Utilizing a pressurizing device, which produces pressure gas based on natural energy and the like, internal pressure in an inner pressure tank 9 is increased. Pressurized water inside the tank is pushed into a (medium) pressurizing cylinder 7 through an automatic valve 59, which puts pressure also on the liquid inside a (large) cylinder 7, and then its internal pressure is raised. The pressurized water is fed into a piston actuating valve 12, which pushes up and down a (small) piston by the action of a lever. That is changed to a reciprocating motion, and then to rotational force utilizing the movement.

Description

発明の詳細な説明Detailed Description of the Invention

この考案物は化石燃料を使用せずに持続回転を得ることを目的に考案した装置でエンジン類に属するものと思われる。 This device is a device devised for the purpose of obtaining continuous rotation without using fossil fuel, and is considered to belong to engines.

化石燃料を使用する車のエンジンや、火力発電や、ウラン使用の原子力発電のような、持続回転装置や、水流利用発電装置が復数類あると思われる。これらの装置は化石燃料を使用したり大量の流水力や、落下力を利用する装置がある。 There seem to be a number of revolving types such as car engines that use fossil fuels, thermal power generation, and nuclear power generation that uses uranium, as well as continuous rotation devices and water flow power generation devices. These devices include devices that use fossil fuels, use a large amount of hydropower, and drop force.

この考案物は、化石燃料や大量の水を使用せずに、自然界に豊富あって、得ることが簡単な物で、空気を圧縮して因負いに圧力元に代えられて、その圧力を、利用して往復運動に代え、持続回転動力を得る事ができ、発電装置との組込みも因負いにできて、クリ−ンな電気エネルギ−を得ることを目的とする装置。 This device is a natural material that is easy to obtain without using fossil fuels and a large amount of water. A device intended to obtain clean electrical energy, which can be used in place of reciprocating motion to obtain continuous rotational power and can be incorporated into a power generator.

自然界に悪影響を及ぼすような二酸化炭素などを空気中に廃出せずに、持続回転動力を得られて、夜、昼に関係なく、天候に左右されずに、何時でも稼動させる事ができる装置を制作する事とを課題とする。 A device that can obtain continuous rotation power without being discarded in the air, which can adversely affect the natural world, and can be operated at any time regardless of the weather regardless of night or day. The issue is to produce.

電気を使用せずに、複数枚の回転子盤上の永久磁石に対して全変極棒の、永久磁石のＳ極とＮ極の磁極を瞬時に入れ替えることを、課題とする。 It is an object to instantaneously replace the S poles and N poles of the permanent magnets of all the variable poles with respect to the permanent magnets on a plurality of rotor disks without using electricity.

加圧装置で得られた圧力を更に高め、その圧力を利用して、往復運動に変える事を課題とする。 It is an object to further increase the pressure obtained by the pressurizing device and change the pressure into a reciprocating motion using the pressure.

化石燃料を使用せずに、太陽の熱や、穀物などの発酵時にだすガスや、海水の持つ浮力や、雑草や枯れ葉などを乾草させ、熱源を得るために考案した雑草練炭を利用して、圧力を生み出す元とすることを課題とする。 Without using fossil fuel, we use the weed briquette devised to obtain the heat source by drying the heat of the sun, gas produced during fermentation such as grains, buoyancy of seawater, weeds and dead leaves, The challenge is to create pressure.

図１は、圧力利用持続回転引き出し装置の全体形体図で、自動フイゴと、加圧装置を、組み込み見た、形体図で、図２−図７の加圧装置を利用して、空気を圧縮し、その力で持続回転動力を、生みだし利用する装置で斜視図部と、断面図と平面図を元に説明するもので外壁や、組み込み部材は磁石に反応せず、衝撃に強く、腐敗がなく強固な材質の物を利用して制作し、回転動力を得ることを課題とするものです。 FIG. 1 is an overall view of a pressure-use continuous rotation drawing device, and is a view of the built-in view of an automatic figo and a pressurizing device. Compressing air using the pressurizing device of FIGS. However, it is a device that produces and uses continuous rotational power with that force, and is explained based on a perspective view, a cross-sectional view, and a plan view. The outer wall and the built-in member do not react to the magnet, are resistant to impact, and are not subject to corruption. It is a challenge to obtain rotational power by using a strong material.

図２は、符号１の太陽熱利用自動フイゴで圧力タンクとの組み込み形体図で、円球形パネル内部に引き詰めた集熱用の銅板又はアルミ板の上を、内部に水を詰めた銅パイプに冷却用の配管を、そわし太陽の熱で温め、蒸気状態にて、ジャバラ風船と、配管で結び蒸気の力で膨張させ、加圧タンク内部の空気を、圧縮し圧力タンクに押し込み、内部の空気圧を高める。又加圧タンク内部でジャバラ風船が膨張し、センサ−と触れることによって、自動バルブが開き、冷却用のパイプ内に水を流し込み、熱交換させて、気体から液体に戻し、ジャバラ風船を縮小させる。又太陽からの熱を得ることができない曇りや、雨、夜間などの状態の時にはジャバラ風船が萎み、加圧タンク内部の内圧が下がり、逆止弁が開き、外部から新たに空気が流れ込みむ。次に太陽からの熱が得られる状態で、再度膨張して上記説明のようになり加圧作業を繰り返し課題の解決手段とする。 Fig. 2 is a built-in view of a pressure tank with a solar heat utilization automatic figo of reference number 1. On a copper plate or aluminum plate for heat collection packed inside a spherical panel, a copper pipe filled with water inside The cooling pipe is warmed by the heat of the sun, and in the vapor state, it is connected with a bellows balloon and the pipe and expanded by the power of the steam, and the air inside the pressurized tank is compressed and pushed into the pressure tank. Increase air pressure. The bellows balloon expands inside the pressurized tank and touches the sensor to open the automatic valve, allowing water to flow into the cooling pipe, heat exchange, returning from gas to liquid, and shrinking the bellows balloon. . Also, in the case of cloudy, rainy, nighttime, etc. where heat from the sun cannot be obtained, the bellows balloons are deflated, the internal pressure inside the pressurized tank decreases, the check valve opens, and new air flows from the outside. . Next, in the state where the heat from the sun is obtained, it expands again as described above, and the pressurizing operation is repeated as a solution to the problem.

図３は、符号２の雑草利用練炭加圧フイゴで、木炭や竹炭、雑草や、木の葉などを乾燥させ、粉上にしたものを工業用ノリで練り、従来の練炭形体にして乾燥させ６０の縦長コンロで燃やし、熱源に利用して熱交換パネルで、小量の水を温め蒸気を発生させジャバラ風船を膨らまし、加圧タンク内の空気を圧縮し圧力タンク内に押し込む。ジャバラ風船が加圧タンク内に上下、二カ所設けた上部のセンサ−に触れる事で、熱交換パネルの中を通した冷却用の水を流すためのパイプに、自動バルブを介して、配管内に水を通して、先に温め蒸気状態にした熱交換パネル内の配管に水を流し込み内部を冷やし、液体に戻し風船部分を縮小させ加圧タンク内に新たに外気を引き込み再度、温め蒸気状態にしてジャバラ風船を膨らまし加圧タンク内の空気を９の圧力タンクに送り込み課題の解決手段とする。 FIG. 3 shows a pressure brigo using a weed briquette of reference numeral 2, which is obtained by drying charcoal, bamboo charcoal, weeds, leaves of trees, etc. It is burned with a vertical stove, and is used as a heat source to heat a small amount of water, generate steam, inflate bellows balloons, compress the air in the pressurized tank, and push it into the pressure tank. When the bellows balloon touches the upper and lower sensors in the pressurized tank, the pipe for flowing cooling water through the heat exchange panel is connected to the pipe through the automatic valve. Pour water into the pipe in the heat exchange panel that has been warmed and steamed first to cool the interior, return it to liquid, shrink the balloon part, draw fresh air into the pressurized tank, and warm it again to steam. The bellows balloon is inflated and the air in the pressurized tank is sent to the pressure tank 9 to solve the problem.

図４は、符号３の発酵加圧タンクで、穀物や、果物や、食材などの廃材品を発酵させ、その過程で出るガスを、２０連結管付逆止弁を介し、安全弁付の９の圧力タンクに押し流し込む形態にする装置で課題の解決手段とするもの。 FIG. 4 shows a fermented pressure tank denoted by reference numeral 3 for fermenting waste materials such as cereals, fruits and foods, and the gas produced in the process is passed through a check valve with 20 connecting pipes and 9 with a safety valve. A device that solves the problem with a device that is pushed into the pressure tank.

図５は、符号４の使用済み発泡材融解加圧装置で、密封状態のタンクに、柑橘類の皮を簿って取り出したリモネン液をため、その液に制作時に空気を大量に含ませた使用済み発泡材を入れて溶かすことで大量に飛び出る空気を連結管付逆止弁を介し圧力タンクに押し込み内圧を高め利用して解決手段とするもの。 FIG. 5 shows a used foaming and melting pressure device of reference number 4 in which a limonene liquid obtained by storing citrus peel in a sealed tank is used, and a large amount of air is included in the liquid during production. This is a solution by using a foamed material that is melted and pushed into a pressure tank through a check valve with a connecting pipe to increase the internal pressure.

図６は、符号５の海水浮力利用加圧装置で、海水の持つ波力を利用してジャバラ風船を膨らまし、その空気を、人力又は自動で、簡易ボンベに詰め替え、利用するもので、持続回転動力引き出し装置の設置場所に運び圧力タンクと配管で結び、詰め込んだ空気を押し込み利用して課題の解決手段とする。 FIG. 6 is a pressurizing device using seawater buoyancy number 5 which inflates bellows balloons using the wave power of seawater and refills and uses the air into a simple cylinder, either manually or automatically. It is transported to the place where the power drawer is installed, connected with a pressure tank and piping, and the packed air is used as a means to solve the problem.

図７は、符号６の人力利用フイゴで加圧タンクの内圧が低い、初期段階の時に運動不足解消にもなるように、行なうもので、圧力タンクから離れた場所にでも設置することができるものである。上記説明の装置を利用して加圧元として利用し課題を解決する手段とする。離れた場所でもタンクの内圧がわかる用にするため。 FIG. 7 is a human-powered figo of reference number 6 that is designed so that the internal pressure of the pressurized tank is low and the lack of motion is resolved at the initial stage, and can be installed at a location away from the pressure tank. It is. The above-described apparatus is used as a pressurizing source to solve the problem. In order to understand the internal pressure of the tank even at a remote location.

図１１は、符号３９の変極棒の先端にＳ極とＮ極を図の形体に並べて設け、設けた磁石の口径分のみを、変極棒の取り付け位置方行へ移動させ、回転子盤の磁石に対し反発と引き寄せを同時にして回転子盤を回転させることで盤上のＳ極とＮ極が交互に入れ代わる磁石に対して、変極棒の磁極をＳ極からＮ極へＮ極からＳ極へと、変え反発と引き寄せを同時にさせ、持続回転をさせる物で、電気を使わずに、永久磁石同志では持続回転させることが不可能と言われている事をＳ極とＮ極を同時に移動させて課題の解決手段とする。 FIG. 11 shows that a pole 39 is provided with S poles and N poles arranged side by side in the shape shown in the figure, and only the diameter of the provided magnet is moved to the direction of the mounting position of the pole changing rod, In contrast to the magnet in which the S pole and N pole on the board are alternately replaced by repelling and attracting the magnet at the same time and rotating the rotor board, the pole of the variable pole is changed from the S pole to the N pole. From S to S pole, it is a thing that changes repulsion and pulling at the same time and makes continuous rotation, and it is said that it is impossible for permanent magnets to rotate continuously without using electricity. S pole and N pole Are simultaneously moved to solve the problem.

図１８は、符号９の圧力タンク内部の内圧を、更に高め利用するためにパスカルの原理応用のシリンダ−を連結方式のシリンダ−形体にして、高圧の加圧水を産みだしその加圧水を、ピストン作動バルブに流し込み（小）ピストンを押上、ワイヤ−を介して、Ｓ極とＮ極を設けた変極棒とＮ極とＳ極を並べ設けた変極棒を同時に始動させ課題の解決手段とする。 FIG. 18 shows that, in order to further increase the internal pressure inside the pressure tank 9, the cylinder of Pascal's principle application is connected to a cylinder, and high-pressure pressurized water is produced. Then, the (small) piston is pushed up and the poles with the S and N poles and the poles with the N and S poles arranged side by side through the wire are simultaneously started to solve the problem.

図１９の形態に変極棒を外枠に間隔を定めて設け、回転子盤上の永久磁石のＳ極にはＳ極が、Ｎ極にはＮ極が反発しあい、それと共にＳ極にはＮ極がＮ極にはＳ極が、引かれ移動すると共に、最低部の回転子盤の裏に、一と間隔置きに設けた突起が、ピストン作動バルブのレバ−が押され、その直後に内部の加圧水が抜け（小）ピストンが元のいちに戻り、変極棒も元の位置に戻り回転子盤上の磁石に反応すると共に、レバ−が突起から外れバネの作用で元のいちに戻り加圧水が、注入され小ピストンが押し上げられ、上記説明の様なことが起き、持続回転へと繋げ課題を解決するための手段とする。 In the form shown in FIG. 19, poles are provided with an interval between the outer frames, and the S pole of the permanent magnet on the rotor disk is repelled by the S pole, and the N pole is repelled by the N pole. The N pole is moved to the N pole, and the S pole is pulled and moved, and at the back of the lowest rotor board, the protrusions provided at intervals are pushed by the lever of the piston operating valve. The internal pressurized water escapes (small), the piston returns to its original position, the pole changer also returns to its original position, reacts to the magnet on the rotor base, and the lever is released from the protrusion and returns to its original position by the action of the spring. Returned pressurized water is injected and the small piston is pushed up, and the above-described explanation occurs, which leads to continuous rotation and is a means for solving the problem.

前項で説明をしたようなもので構成された装置で、太陽からの熱や，海水の波力や木の葉や雑草を練炭形体にした物を熱源にし、て圧力エネルギ−を得て利用することで、化石燃料を使用せずに、持続回転エネルギ−を得られる。
発電装置と組み込み始動させクリ−ンエネルギ−を、産み出せる効果がある。A device constructed as described in the previous section, using heat from the sun, wave power of seawater, leaves and weeds in briquette form as a heat source, and obtaining pressure energy for use. Sustained rotational energy can be obtained without using fossil fuel.
There is an effect that it is possible to produce clean energy by incorporating the generator and starting.

自然界に悪影響を与える二酸化炭素放出せずにに夜、昼、また天候に左右されずに使用する事が出来る効果がある。 It has the effect of being able to be used without being affected by the night, noon, and weather without releasing carbon dioxide that adversely affects the natural world.

化石燃料を使用せずに、電気エネルギ−を得ることで，国外からの燃料に頼らずに済む事と、費用が少なくなり経済効果が出るものと思われる。 By obtaining electrical energy without using fossil fuels, it is possible to avoid the need to rely on foreign fuels and to reduce costs and achieve economic benefits.

加圧装置を設けず、図１９の形態にして私動で加圧し、漏れをなくすることで装置全体を小型化し電気自動車の発電元とすることが可能となる物と思われる。又ビニ−ルハウスや室内で、植物などを育てるための電力元にすることもでき季節を選ばずに栽培が低コストで出来る。 It is considered that it is possible to reduce the size of the entire apparatus and use it as a power generation source of an electric vehicle by not applying a pressurizing device but pressurizing in the form of FIG. In addition, it can be used as a power source for growing plants in a vinyl house or indoors, and can be cultivated at a low cost regardless of the season.

図１は、圧力利用持続回転装置全体の斜視図を、切断し見た断面図です。 Fig. 1 is a cross-sectional view of a perspective view of the entire continuous rotation device using pressure. 図２は、図１の低部に設ける加圧装置で、太陽熱利用自動フイゴと圧力タンクの、斜視図と断面図です。 Fig. 2 shows a perspective view and a cross-sectional view of the solar heat automatic huigo and the pressure tank. 図３は、雑草利用練炭フイゴの使用形体の断面図です。 Fig. 3 is a cross-sectional view of a used form of weed briquette Huigo. 図４は、密閉式発酵加圧タンクと、圧力タンクの組み込み形態図で、斜視図部と断面図です Fig. 4 is a perspective view and a cross-sectional view of a closed-type fermentation pressure tank and a built-in configuration of the pressure tank. 図５は、発泡融解加圧装置と、圧力タンクの断面図と斜視図です。 Fig. 5 is a cross-sectional view and perspective view of the foaming and melting pressure device and pressure tank. 図６は、海水の波力を利用して空気を圧縮し、簡易ボンベに詰め込む装置で、断面図です。 Fig. 6 is a cross-sectional view of a device that compresses air using the wave power of seawater and packs it into a simple cylinder. 図７は、人力で、加圧するためのフイゴで斜視図です。 Fig. 7 is a perspective view of a huigo for pressurization by human power. 図８は、フイゴ装置と圧力タンクの設置形体の平面図と連結管付逆止弁です。 Fig. 8 is a plan view of the installation form of the Huigo device and pressure tank, and a check valve with connecting pipe. 図９は、加圧タンクと加圧シリンダ−の組み込み形体図で、斜視図です。 Fig. 9 is a perspective view of the built-in form of the pressurized tank and pressurized cylinder. 図１０は、ピストン作動バルブの斜視図と平面図と組み込み形体図です。 Fig. 10 is a perspective view, plan view, and built-in view of the piston-operated valve. 図１１は、回転装置内部の、平面図です。 Fig. 11 is a plan view of the inside of the rotating device. 図１２は、（大）圧力シリンダ−内に設けるセンサ−の取り付け形体の断面図です。 Fig. 12 is a cross-sectional view of the sensor mounting form in the (large) pressure cylinder. 図１３は、変極棒に発電機を設け外壁部に取り付け、見た断面図です。 Fig. 13 is a cross-sectional view of the pole changer with a generator installed on the outer wall. 図１４は、自動三方弁の断面図です。 Fig. 14 is a cross-sectional view of an automatic three-way valve. 図１５は、加圧シリンダ−の液体注入口に、設ける浮き型逆止弁付エヤ−抜き弁です。 Fig. 15 shows an air release valve with a floating check valve installed at the liquid inlet of the pressure cylinder. 図１６は、装置全体の配置形態図で、平面図です。 Fig. 16 is a plan view of the layout of the entire device. 図１７は、発電機を、装置に組み込み見た図でＡタイプとＢタイプとＣタイプの三方法がある。Ａは、断面図Ｂは斜視図Ｃは断面図です。 FIG. 17 is a view of the generator incorporated in the apparatus, and there are three methods of A type, B type and C type. A is a sectional view. B is a perspective view. C is a sectional view. 図１８は、回転子盤と変極棒の設置形態を書き表し、見た断面図と一部斜視図。 FIG. 18 is a cross-sectional view and a partial perspective view showing the installation form of the rotor base and the variable pole. 図１９は、圧力タンクと加圧シリンダとピストン作動バルブの配置形態断面図。 FIG. 19 is a sectional view of the arrangement of a pressure tank, a pressure cylinder, and a piston operation valve. 図２０は、１２のピストン作動バルブ断面図。 FIG. 20 is a sectional view of 12 piston actuated valves. 図２１は加圧シリンダ−に、設けるためのエヤ−抜き兼逆止弁の断面図。 FIG. 21 is a cross-sectional view of an air release and check valve for providing the pressure cylinder.

図１が、装置の全体図で、下部に画いた図２から図７の加圧装置で、中央の圧力タンクの内圧を高め、配管を介しての自動バルブまで送りのセンサ−を介してバルブの開閉をさせ、パスカルの原理を応用した加圧シリンダ−で内圧を高めピストン作動バルブに送り込み、往復運動を得手、変極棒を作動させ回転子盤の永久磁石に反応させ、回転子盤の回転力に変えて、発電機と組み込み、実施するものである。 FIG. 1 is an overall view of the apparatus. In the pressurizing apparatus shown in FIGS. 2 to 7, the internal pressure of the central pressure tank is increased, and the valve is connected to the automatic valve via the pipe through the sensor. The pressure cylinder that applies Pascal's principle is used to increase the internal pressure and feed it to the piston operating valve, gaining reciprocating motion, operating the diverting rod and reacting with the permanent magnet of the rotor disk, Instead of turning force, it is built with a generator.

考案物の実施の形態を実施例にもとづき図面を参照して、あらましを説明する。図１は、圧力利用持続回転動力引き出し装置の斜視図と、一部を切断し，見た断面図です。この装置の特徴は、外装材や組み込み部材は、磁力に反応せず、衝撃に強く腐敗がなく強固な材質の物を利用するもので構成され、図２から図７の加圧装置の何れかの装置を、設置場所に合わせ利用して、９の圧力タンクの内圧を高め、１２のピストン作動バルブに送り込み往復運動に変え利用する装置で、テコとバネと滑車とベヤ−リングと歯車と永久磁石などを複数利用して持続回転装置とするもの。 An outline of an embodiment of the invention will be described based on an example with reference to the drawings. Fig. 1 shows a perspective view of a pressure-driven continuous rotating power drawer and a cross-sectional view of a part cut away. The feature of this device is that the exterior material and the built-in member are made of a material that does not react to magnetic force, is strong against impact and does not rot, and uses a strong material. This device is used in accordance with the installation location to increase the internal pressure of the pressure tank 9 and send it to the 12 piston actuating valve to convert it into reciprocating movement. The lever, spring, pulley, bearing ring, gear and permanent A rotating device that uses multiple magnets.

図２の、符号１の円球型太陽熱利用フイゴで、少量の水を渦巻き形体にしたパイプに水を溜め加圧用の３３のジャバラ風船に配管で結び、太陽で温められて、できる蒸気でジャバラ風船を膨らまし、加圧タンク内の空気を、９の圧力タンクに押し込む形態になり、太陽が陰ることで蒸気が水に戻り風船が小さくなり９の圧力タンクに押し込まれた分だけ、８の加圧タンクに設けた２０の逆止弁の作用で外気が流れ込み太陽からの熱が得られると、また３３のジャバラ風船が膨らみ前記で述べた事が複数回繰りかいされることで９の圧力タンクの内圧を高めることになる。８の加圧タンク内部に設けたセンサ−働きを介して冷却を可能とすることもできる。 In Fig. 2, a circular solar-powered figo 1, a small amount of water is stored in a spiral pipe, and water is connected to a 33 bellows balloon for pressurization, heated by the sun, and bellows produced by steam. The balloon is inflated, and the air in the pressurized tank is pushed into the 9 pressure tank. Steam is returned to the water due to the sun's shadow, and the balloon becomes smaller and is pushed into the 9 pressure tank. When the outside air flows and heat from the sun is obtained by the action of the 20 check valves provided in the pressure tank, the 33 bellows balloons are inflated and the above-described operations are repeated a number of times so that 9 pressure tanks are obtained. Will increase the internal pressure. Cooling can also be made possible via a sensor function provided inside the pressurized tank.

図３は、符号５の海水浮力と波の持つエネルギ−を利用して、６１の詰め替えジャバラ風船を膨らまし４９の簡易ボンベに詰め込み内圧を高め、圧力利用持続回転動力引き出し装置の設置場所に運び９の圧力タンクに６２の配管で結び空気を流し込み内圧を高め利用する。 FIG. 3 shows the seawater buoyancy of 5 and the energy of the waves, inflating 61 refillable bellows balloons into a simple cylinder of 49, increasing the internal pressure, and carrying it to the place where the pressure-utilizing continuous rotating power drawer is installed. The pressure tank is connected with 62 pipes and air is poured to increase the internal pressure.

図４は、符号３の密閉式発酵加圧タンクで、穀物や果物など食材の残り物を、加圧タンク内で、人力で空気を送り込み発酵させ、その過程で、出る二酸化炭素を９の圧力タンクに押し込む状態にして内圧を高め利用する。 FIG. 4 shows a closed fermentation pressurization tank denoted by reference numeral 3, and the remaining food ingredients such as cereals and fruits are fermented by manually feeding air into the pressurization tank, and in the process, the carbon dioxide that exits is sent to 9 pressure tanks. The internal pressure is increased and used by pushing it into

図５は、符号２の雑草利用練炭フイゴで、雑草や木の葉などを乾燥させ粉末状にして、木炭や竹炭などは、粒條にして、工業用のノリと混ぜ、練炭形態にして乾燥させ燃料として、燃やし熱源にして２の雑草利用練炭フイゴの３７の熱交換パネルを熱し、蒸気状態にして、送り込んで３３のジャバラ風船を膨らまし８の加圧タンク内の空気を、９の圧力タンクに押し込む、一定の大きさになる事で、タンク内部に設けた１８のセンサ−を介して３７の熱交換パネル内の冷却用の配管の途中の４２（小）自動バルブを開き熱しられた湯を冷やし温度を下げる事で気体から液体に戻し３３のジャバラ風船を元の大きさに戻すことで、加圧タンク内部の内圧が下がり、外気を引き込むようになり、それと同時に低部に設けたセンサ−の働きで４２の（小）自動バルブが締まりふたたび３７の熱交換パネルを温め、前記説明のようなことを繰り介し、圧力タンクの内圧を高め一定にする。 Fig. 5 shows a weed briquette figo with reference numeral 2 in which weeds and leaves are dried and powdered, and charcoal and bamboo charcoal are granulated, mixed with industrial paste, dried into briquetted form, and dried. As a burning heat source, heat the heat exchange panel 37 of the weed briquette fiigo 2 of 2 weeds, make it into a steam state, send inflating 33 bellows balloons, and push the air in the pressurized tank 8 into the pressure tank 9 By making the size constant, open the 42 (small) automatic valve in the middle of the cooling pipe in the 37 heat exchange panel via the 18 sensors provided inside the tank to cool the heated hot water. By returning the temperature from the gas to the liquid by lowering the temperature and returning the 33 bellows balloons to their original size, the internal pressure inside the pressurized tank is lowered and the outside air is drawn in. 42 in work Small) warmed heat exchange panel of the automatic valve is tight again 37, through repeated things like the description, a constant increase the internal pressure of the pressure tank.

図６は、発泡融解加圧装置で柑橘類の皮を絞った液などの中に使用済みの発泡材を入れて溶かす事で、発泡材を制作するときに取り込まれた大量の空気が排出されてタンク内部の内圧を上げ圧力タンクに流れ込みタンクの内圧を上げる事になる。 Fig. 6 shows that a large amount of air taken when producing a foam material is discharged by putting the used foam material into a solution that has been squeezed with citrus peel with a foaming and melting pressure device. The internal pressure inside the tank is increased and flows into the pressure tank, and the internal pressure of the tank is increased.

図７は、この装置の設置場所から、はなれた場所でも圧力タンクの内圧がわかようにするもので、室内などに設け利用するもので人力を利用して、運動不足解消にも繋げようとするもの、遊び心にもつながるもの。 FIG. 7 shows the internal pressure of the pressure tank even in a place away from the installation location of this device. It is used indoors and is used to try to solve the lack of exercise by using human power. Things that lead to playfulness.

上記説明の図２−図７のような加圧装置を、設置場所や区域に合わせ利用して圧力を得手９の圧力タンクから６２の配管を介して５９の（大）自動バルブに４２の加圧水を送り、７の（大）加圧シリンダ−内に、複数設けた１８センサ−を介して（大）５９の自動バルブを同時開閉させ、パスカルの原理を利用した、７の（大）加圧シリンダ−内の液体に圧力をかけ、その加圧水を、１２のピストン作動バルブに送り込み、２５の小ピストンの上部に設けた誘導パイプの中間部に設けた４４のワイヤ−取り付け金具に３２のワイヤ−を取り付け２３の滑車と１５の（大）テコ棒を介して、１１の永久磁石をＳ極とＮ極を並べて設けその端に発電装置を設けた複数の３９の変極棒を同時に引き、同じ大きさの永久磁石を、同位置、円周線上に、同間隔にＳ極とＮ極を、交互に取り付け、歯車を設けた複数枚の１０の回転子盤の磁石に反応させ、５６の軸を中心に同時回転させ、その回転力を利用して、クリ−ンな電気エネルギ−を得ようとする装置で、１２のピストン作動バルブの開閉を、１０の回転子盤の回転力を利用して行なうもので、複数枚設けた回転子盤の、最低部の裏面に、表面の永久磁石の取り付け位置の中心の円周線上で同じ位置に、一間隔置きに４５の突起を設けピストン作動バルブの６５のレバ−に接触して押されて、ドレン側が開き、加圧水が抜け２５の小ピストンが、元の位置に戻り注入側の４２加圧水が止められると同時に、１０の回転子盤が回転していることで裏側の４５の突起から４５のレバ−が外れ４５のレバ−に設けた４３のバネの作用で元の位置に戻り１２のピストン作動バルブの開閉も変わり加圧水の流れも変わって持続回転につながるものです。また７（大）加圧シリンダ−内の液体（加圧水）と９の圧力タンク内の液体（加圧水）は循環利用させるもので、７の大シリンダ−内いの４２の加圧水は、１２のピストン作動バルブの働ききで排出された分が７の（大）シリンダ−内の２５の（大）ピストンの、押し込み側の裏側に戻り、１８のセンサ−の働きで切り替わったときには、加圧水に変わり再度１２のピストン作動バルブに送り込まれ、２５の（小）ピストンを押上た後に、循環利用される用になる。また９の圧力タンク内の液体（加圧水）は、５９の（大）自動バルブに押し込まれ、７の大加圧シリンダ−内に複数設けた１８のセンサ−を、介して開閉され、それと同時に、押し込み側と相対する、（Ａ）か（Ｂ）のどちらかの１３のポンプが始動して、９の圧力タンクに引き戻す状態になり、再度利用されると同時に、押し込み側の反対の、７の（中）シリンダ−に送り込まれていた４２の加圧水を、９の圧力タンクに戻し、内圧を保って循環利用させ、実施するものである。 2 to 7 in the above description are used in accordance with the installation location and area to obtain pressure from the pressure tank of the user 9 through the piping of 62 to the (large) automatic valve of the 42 pressurized water of 42 7 (large) pressurization using the Pascal principle by simultaneously opening and closing (large) 59 automatic valves via a plurality of 18 sensors in the (large) pressurization cylinder of 7 Pressure is applied to the liquid in the cylinder, the pressurized water is sent to 12 piston operating valves, and 44 wires are attached to an intermediate portion of a guide pipe provided on the top of 25 small pistons. At the same time, a plurality of 39 poles with 11 generator magnets arranged side by side and a power generator at the end are drawn through 23 pulleys and 15 (large) lever rods. A permanent magnet of the same size, on the circumference, at the same position S poles and N poles are alternately mounted at intervals, and reacted with the magnets of a plurality of 10 rotor bases provided with gears. Simultaneously rotating around 56 axes, using the rotational force, -A device for obtaining a large amount of electrical energy, which opens and closes 12 piston operating valves by utilizing the rotational force of 10 rotor bases. On the back surface of the magnet, 45 projections are provided at regular intervals at the same position on the circumference of the center of the permanent magnet mounting position on the front surface, and the drain side is opened by being pressed against the 65 levers of the piston operating valve. The small piston of the pressurized water 25 is returned to its original position, the 42 pressurized water on the injection side is stopped, and at the same time, the 10 levers are rotated, so that the 45 lever is released from the 45 projections on the back side. The original position by the action of 43 springs provided on the 45 levers Flow opening also changes pressurized piston-actuated valve of the return 12 is what leads to sustained rotation changes. Also, the liquid in the 7 (large) pressure cylinder (pressurized water) and the liquid in the 9 pressure tank (pressurized water) are circulated, and 42 pressurized water in the 7 large cylinders are operated by 12 pistons. When the valve is activated, the amount discharged by the operation of the valve returns to the back side of the 25 (large) piston in the 7 (large) cylinder and is switched by the operation of the 18 sensor. It is sent to the piston actuating valve, and after 25 (small) pistons are pushed up, it is used for circulation. The liquid (pressurized water) in the pressure tank 9 is pushed into the (large) automatic valve 59 and opened and closed through 18 sensors provided in the large pressure cylinder 7, and at the same time, The 13 pumps of either (A) or (B), which are opposite to the pushing side, are started and pulled back to the 9 pressure tank and are reused at the same time. (Medium) The 42 pressurized water that has been fed into the cylinder is returned to the 9 pressure tank, and the internal pressure is maintained and circulated for use.

問題視されている二酸化炭素による環境破壊を、化石燃料からの脱却で食い止める事とができればと思い考案したもので、これが可能になれば化石燃料に依存せずにクリ−ンな電気エネルギ−を、安価な装置で得られ、産業に寄与するものと思われる。又この装置の、加圧タンクを除き、圧力タンクのみにして、加圧用の液体を循環利用形体にし、小型化し、電気自動車の発電装置にも利用することも可能と思われる。このようなことが可能になることで、エネルギ−コストが下がり、経済的に見ても産業上での利用価値があるものと思われる。 It was devised if the environmental destruction caused by carbon dioxide, which is regarded as a problem, can be stopped by moving away from fossil fuels. If this is possible, clean electric energy will not be dependent on fossil fuels. It can be obtained with inexpensive equipment and contributes to the industry. It is also possible to use only the pressure tank, except for the pressurized tank of this device, to make the pressurized liquid into a circulation-use form, miniaturize it, and use it for a power generator of an electric vehicle. By making this possible, the energy cost is reduced, and it is considered that there is an industrial utility value even from an economical viewpoint.

１太陽熱利用フイゴ２雑草利用練炭フイゴ
３発酵加圧タンク４廃棄発泡材融解加圧タンク
５海水浮力利用加圧装置６人力利用フイゴ
７加圧シリンダ−（大）（中）（小）８加圧タンク
９圧力タンク１０回転子盤
１１永久磁石１２ピストン作動バルブ
１３ポンプ（Ａ）（Ｂ）１４ストレ−ナ−
１５テコ棒（大）（小）１６安全弁
１７圧力ゲ−ジ１８センサ−
１９逆止弁２０連結管付逆止弁
２１エヤ−抜き献逆止弁２２ベヤ−リング
２３滑車２４支持金具
２５ピストン（大）（中）（小）２６防水用ゴムカバ−
２７実管シリ−ブ管２８発電機
２９使用済み発泡材３０バルブ
３１海水３２ワイヤ−
３３ジャバラ風船３４リモネン液
３５ガイド溝３６給水管
３７熱交換パネル３８冷却水用自動バルブ
３９変極棒４０雑草練炭
４１防水ゴムカバ− ４２加圧水
４３バネ４４ワイヤ−取り付け金具
４５突起４６踏台
４７外壁４８円球型太陽熱パネル
４９簡易ボンベ５０私動式足踏みエヤ−ポンプ
５１ドレン用バルブ５２煙突
５３蛇口５４固定板
５５バイパス用パイプ５６軸
５７押し出し用バルブ５８渦巻き型銅パイプ
５９自動バルブ６０縦長コンロ
６１詰め替えジャバラ風船６２配管
６３押さえ込み棒６４液体注入口
６５レバ− ６６酸素注入口
６７グリス注入口６８循環水
６９ピストン取り付け心棒７０蛇口
７１外部空気引き込み逆止弁７２心棒DESCRIPTION OF SYMBOLS 1 Solar heat utilization Huigo 2 Weed utilization briquette Huigo 3 Fermentation pressurization tank 4 Waste foam melting pressurization tank 5 Seawater buoyancy pressurization device 6 Human power utilization Huigo 7 Pressure cylinder-(Large) (Medium) (Small) 8 Pressurization Tank 9 Pressure tank 10 Rotor base 11 Permanent magnet 12 Piston actuation valve 13 Pump (A) (B) 14 Strainer
15 lever (large) (small) 16 safety valve 17 pressure gauge 18 sensor
DESCRIPTION OF SYMBOLS 19 Check valve 20 Check valve with connection pipe 21 Air-excluding dedicated check valve 22 Bearer ring 23 Pulley 24 Support metal fitting 25 Piston (Large) (Medium) (Small) 26 Waterproof rubber cover
27 Actual pipe sleeve 28 Generator 29 Used foam material 30 Valve 31 Seawater 32 Wire
33 Bellows Balloon 34 Limonene Liquid 35 Guide Groove 36 Water Supply Pipe 37 Heat Exchange Panel 38 Cooling Water Automatic Valve 39 Polarizing Bar 40 Weed Briquette 41 Waterproof Rubber Cover 42 Pressurized Water 43 Spring 44 Wire-Mounting Bracket 45 Protrusion 46 Step 47 Outer Wall 48 Circle Spherical solar panel 49 Simple cylinder 50 Private stepping air pump 51 Drain valve 52 Chimney 53 Faucet 54 Fixed plate 55 Pipe for bypass 56 Shaft 57 Extrusion valve 58 Spiral copper pipe 59 Automatic valve 60 Vertical stove 61 Refillable bellows Balloon 62 Piping 63 Holding rod 64 Liquid inlet 65 Lever 66 Oxygen inlet 67 Grease inlet 68 Circulating water 69 Piston mounting mandrel 70 Faucet 71 External air intake check valve 72 Mandrel

Claims

自然界で、容易に得ることのできる、太陽の熱や、海水の持つ波力や、果物や穀物の発酵時に出す、二酸化炭素を外部に排出せずに利用し（９）の圧力タンクの内圧を高めたり、自然界に豊富にあて、二酸化炭素の排出の量が増える事が少ない木の葉や雑草などを，練炭状態にしたものを、燃やして熱を利用したりして、加圧装置内の（３３）のジャバラ風船を、膨らまし、（８）の加圧タンク内部の、空気を圧縮し（２０）の連結管付逆止弁を介して（９）の圧力タンク内部の内圧を高め、利用し、（７）の加圧シリンダ−内の循環水にも圧力をかけ、高めて利用して、（１２）のピストン作動バルブに送り込み往復運動を生み出し利用する方法。 The internal pressure of the pressure tank (9) can be easily obtained in the natural world without using the carbon dioxide emitted outside during the fermentation of the heat of the sun, seawater, and fruits and grains. Increase the amount of carbon dioxide emissions that increase or abundantly in the natural world, such as leaves and weeds in a briquette state, burn them and use heat to (33 ) Inflating the bellows balloon in (8), compressing the air inside the pressurized tank in (8) and increasing the internal pressure in the pressure tank in (9) via the check valve with the connecting pipe in (20), (7) A method of applying pressure to the circulating water in the pressurizing cylinder of (7) and increasing the pressure to feed it to the piston operating valve of (12) to generate and use the reciprocating motion.

図２の、円球形太陽熱利用自動フイゴで、（９）の圧力タンクと（２０）のバルブと逆止弁付パイプで結んだ状態を書き表した図で、（４８）の円球型パネル内部にアルミ又は銅板を敷きつめその上に、渦巻き形態の蒸気用の配管に、冷却用のパイプを沿わし、蒸気用のパイプに水を詰め込み配管を這わし蒸気漏れのないようにして、加圧タンク内の（３３）のジャバラ風船と結び太陽からの熱で、得た蒸気で膨張させ、加圧タンク内部の、空気を圧縮し、（１６）の安全弁付の圧力タンクに送り込み（７）の加圧シリンダ−の始動圧力元として利用する方法。 Fig. 2 is a diagram showing the state of the spherical solar heat automatic huigo, which is connected to the pressure tank of (9), the valve of (20), and a pipe with a check valve. Place an aluminum or copper plate on top of it, place a cooling pipe on the spiral steam pipe, stuff water into the steam pipe, squeeze the pipe, and prevent steam leakage. It is connected to the bellows balloon of (33) and expanded with the steam obtained by the heat from the sun, and the air inside the pressurized tank is compressed and sent to the pressure tank with a safety valve of (16) (7) pressurization Method used as starting pressure source for cylinder.

図３の雑草利用練炭フイゴで燃料とする雑草や木きの葉などを、乾草させ、粉状にしたものと木炭を粉状にした物を工業用ノリで、練り合わせ、従来の練炭状態にして、乾草させ、装置の低部に設けた縦長形体の（６０）の縦長コンロで燃やし熱源にして、少量の水の入った（７）の熱交換パネルを温め蒸気を発生させ、タンク内部に設けた（３３）のジャバラ風船を膨張させ、タンク内部の空気を圧縮し、逆止弁付パイプを介して（９）の圧力タンクに、送り込んで利用する方法。 Weeds and wood leaves used as a fuel in the weed briquette figs shown in Fig. 3 are hayed and pulverized with charcoal pulverized material, and then kneaded with an industrial paste to obtain a conventional briquette state. Heat the heat exchange panel of (7) with a small amount of water to generate steam by using a vertically long (60) stove that is installed in the lower part of the device, and heat it up. A method of inflating the bellows balloon of (33), compressing the air inside the tank, and sending it to the pressure tank of (9) through a pipe with a check valve.

図４の海水浮力利用フイゴで、海水の波の力によって押し上げられた海水をパイプ内に押し込みパイプ内部の空気を（６１）の詰め替えジャバラ風船に送り込み膨らました空気を、（５７）の押し出しバルブで、（４９）の簡易ボンベに、バルブの切り替えと共に私動式で詰め込み利用する方法。 With the seawater buoyancy-use figo of Fig. 4, the seawater pushed up by the wave force of seawater was pushed into the pipe, the air inside the pipe was sent to the refilled bellows balloon of (61), and the air was inflated with the extrusion valve of (57) (49) A method of using a simple cylinder packed in a private manner along with valve switching.

図５の人力利用フイゴで（４６）の踏台に乗り足の力で一方を踏み込み空気を排出し、それと同時にもう一方は引き上げられ、ジャバラホ−ス部分に外気を取り込み、次に踏み込んで排出口から噴き出し、（９）の圧力タンクに押し込む状態で利用するフイゴで、タンク内部の内圧を知るために設ける。 With the human-powered fig in FIG. 5, step on one of the steps (46) with the power of the foot and exhaust the air, and at the same time, the other is lifted, and outside air is taken into the bellows hose part, and then stepped on from the outlet It is a figo that is used in a state of being ejected and pushed into the pressure tank of (9), and is provided to know the internal pressure inside the tank.

図６の、発酵加圧タンクで、穀物や、果物や、食材などの廃材品を発酵させた時出る二酸化炭素を、９の圧力タンクへ、送り込み利用する方法。 The carbon dioxide produced when fermenting waste materials such as cereals, fruits and foods in the fermentation pressure tank shown in FIG.

図７の発泡融解加圧装置で、柑橘類の皮を絞り出たした液体を、融解漕（加圧タンク）に貯めた、（３４）のリモネン液に（５７）の発泡材押し出しバルブ内に（２９）の発泡材を入れ、（５７）のバルブ操作で押し出し（６３）の押さえ込み棒で、発泡材を押し下げ、リモネン液で溶かし、発泡材の制作時に大量に含まれた空気を排出させ、融解層の内圧を高め、（９）の圧力タンクに送り込み利用する方法。 The liquid obtained by squeezing the citrus peel with the foaming and melting pressure device of FIG. 7 is stored in a melting trough (pressure tank), into the limonene liquid of (34) into the foaming material extrusion valve of (57) ( 29) Put the foam material, push the valve by (57) valve operation, push down the foam material with the push-in stick of (63), melt with limonene liquid, discharge the air contained in large quantities when producing the foam material, melt Method to increase the internal pressure of the layer and send it to the pressure tank of (9).

図９の圧力タンクと、加圧シリンダ−との組み込み形体図で（９）の圧力タンクからの液体を（６２）の配管を介して（５９）の自動バルブに送り込み、（７）の（大）加圧シリンダ−内に複数設けた、（１８）のセンサ−を介して開閉させ、（７）の（中）シリンダ−内の（２５）の（中）ピストンと共に、大シリンダ−内の大ピストンも、同時に始動させ、内部の、液体に圧力をかけ、加圧水とする方法。 In the figure of the built-in configuration of the pressure tank of FIG. 9 and the pressure cylinder, the liquid from the pressure tank of (9) is sent to the automatic valve of (59) through the pipe of (62), and ( ) Open and close via a sensor (18) provided in a plurality of pressure cylinders, together with (25) (medium) pistons in (7) (medium) cylinders, The piston is also started at the same time, and pressure is applied to the liquid inside to produce pressurized water.

図１０は、往復運動を生み出しための、（１２）のピストン作動バルブのレバ−の開閉を、することで挿入口側が開いたとき排出口側は閉じられ（２５）（小）ピストンが、加圧水の圧力で押し上げられ（１５）のテコ棒や滑車やワイヤ−やバネの作用で、（３９）の全変極棒を始動させ、（５６）の中心軸の上下に（２２）のベヤ−リングを設け、同位置で、同間隔に複数の（１０）の回転子盤を、同時回転させその回転力を利用するもの方法。 FIG. 10 shows the opening and closing of the lever of the piston actuating valve of (12) for generating reciprocating motion, so that the discharge port side is closed when the insertion port side is opened. (25) (Small) (39) The lever poles, pulleys, wires, and springs act to actuate all the poles (39), and (22) the bearing ring above and below the central axis of (56) A method in which a plurality of (10) rotor discs are simultaneously rotated at the same position at the same position and the rotational force is used.

図１１は、装置内部の軸と回転子盤と、相対する変極棒の設置状態を、上から見た図で往復運動を、回転力に変えるために、回転子盤上の歯車より内側に、取り付ける丸型の永久磁石の外周が、歯車の歯の部分より内側になって、同位置の円周線上に、Ｓ極とＮ極を交互に設けた複数枚の回転子盤を回転軸に、縦長にＳ極とＮ極が、それぞれ同列に、縦長になる状態し、変極棒の先端に並べて設けた厚みを見て、回転子盤に取り付けた磁石と、変極棒に取り付けた磁石が、ふれあうことの無いように間隔隔を考慮して取り付け固定し、その回転軸の上下に（２２）のベヤ−リングを設け、捩れ回転のないようにして、垂直にし、固定板に確じつに固定する。その後（４７）の円形の外壁に、（２８）の発電機を組み込んだ（３９）の変極棒を、図１８の状態に、回転子盤の永久磁石の取り付け位置の中心線定の位置で、回転子盤と回転子盤の上下の中心になるように高さを合わせ固定しワイヤ−をしっかり張り、弛みのないようにして利用する方法。 FIG. 11 shows the installation state of the shaft inside the device, the rotor disk, and the opposite poles, as viewed from above, in order to change the reciprocating motion into a rotational force, inside the gear on the rotor disk. The outer periphery of the round permanent magnet to be attached is inside the gear teeth, and a plurality of rotor discs having S poles and N poles alternately arranged on the same circumferential line are used as the rotating shaft. The magnets attached to the rotor disk and the magnets attached to the pole changer are as follows. However, in order to prevent contact with each other, the mounting is fixed in consideration of the interval, and the (22) bearer ring is provided above and below the rotating shaft so that it does not twist and is vertical, and is securely attached to the fixing plate. Fix it. After that, the variable pole of (39) incorporating the generator of (28) on the circular outer wall of (47), in the state shown in FIG. 18, at the center line fixed position of the rotor magnet permanent magnet mounting position. A method of using the rotor board and the rotor board so that the height is aligned and fixed so that the wire is firmly attached and the wire is not loosened.

図１２は、センサ−の取り付け形体図で（７）の大加圧シリンダ−内の相対する位置に複数設け、細いワイヤ−で（２５）の大ピストンとつながれ、一方が押されて、ＯＮとＯＦが同時にされると、同時に反対側の同位置の（１８）のセンサ−側は、ＯＦとＯＮ状態になり互いにＡ側の自動バルブが開くときには、Ｂ側の加圧ポンプが始動して（Ｂ）側の自動バルブが開くときは、（Ａ）Ａ側のポンプが始動する形体になって（中）ピストンが加圧水によって、押し込まれる事によって、センサ−と離れると同時にバネの作用でＯＦ状態になると同時に、押し込み方向も変わって、ピストン作動用の加圧水が利用済みとなって、圧力が無くなり、元の大加圧シリンダ−内の（２５）の（大）ピストンの押し込み方向の裏側に流れ込み溜まって次のセンサ−が切り変わると同時に加圧水となって循環使用が可能となるようにするセンサ−の取り付け方法。 FIG. 12 is a diagram showing the mounting structure of the sensor. A plurality of sensors are provided at opposite positions in the large pressure cylinder (7), connected to the large piston (25) by a thin wire, and one of them is pushed and turned ON. When OF is performed at the same time, the sensor side (18) at the same position on the opposite side is simultaneously turned on with the OF, and when the automatic valve on the A side opens, the B side pressure pump is started ( (B) When the automatic valve on the side opens, (A) The pump on the A side starts (middle) When the piston is pushed in by pressurized water, it is separated from the sensor, and at the same time, it is in the OF state by the action of the spring At the same time, the pushing direction changes, the pressurized water for operating the piston is already used, the pressure disappears, and it flows into the back side of the pushing direction of the (25) (large) piston in the original large pressure cylinder. Accumulated Sensor - mounting method - is cut changes when sensor it will be possible to recycling becomes pressurized water at the same time.

図２１は、逆止弁で、ピストン作動バルブで小ピストンを、押し上げる為に利用した加圧水を、排出した後に（７）の大加圧シリンダ−に流し込ませるための流入口に取り付けタンク内の空気を抜く事と、加圧水に変わったときの逆流を防ぐために設ける浮き型式の逆止弁を利用する方法。 FIG. 21 is a check valve, which is attached to an inlet for discharging the pressurized water used to push up the small piston with the piston operating valve to the large pressure cylinder in (7), and then the air in the tank. And using a floating type check valve provided to prevent backflow when changing to pressurized water.

図１９は装置を縮小し、狭い場所にも設置が可能に成る用にするもので、前記で延べてきた加圧タンクを、設けずに、図１９の形体の圧力タンクに私動で、（６４）の液体注入口から液体と、エヤ−を押し込み配出口から配管を介して自動バルブへと流し込み前記で述べたように加圧シリンダ−で利用しる。又利用ごは、前記で述べたように（１３）のポンプの働きで（９）の圧力タンクへ戻るようになる。このことによって（８）の加圧タンクを設けないことで、装置を縮小して利用する方法。 FIG. 19 is for reducing the size of the device so that it can be installed in a narrow space. The pressure tank extended as described above is not provided, and the pressure tank of the configuration of FIG. 64) The liquid and the air are pushed in from the liquid inlet, and are poured into the automatic valve through the piping from the outlet and used in the pressurizing cylinder as described above. As described above, the user returns to the pressure tank (9) by the action of the pump (13). By this, the apparatus is reduced and used by not providing the pressurized tank of (8).

図１９の符号（４１）は、ジャバラ式の防水ゴムカバ−で、（６９）のピストン取り付け心棒の、左右の移動時に２７の実管シリ−ブパイプの回りからの液体の漏れを無くする事と、（７２）心棒の移動をスムウズにするために設けるもの。請求項１から請求項１４までを、特許請求の範囲とする。 Reference numeral (41) in FIG. 19 is a bellows type waterproof rubber cover, which eliminates liquid leakage from around the 27 real pipes when the piston mounting mandrel of (69) moves left and right. (72) Provided for smooth movement of the mandrel. Claims 1 to 14 are claimed.