61 |
compressor |
JP25012993 |
1993-09-10 |
JP3629592B2 |
2005-03-16 |
泰生 佐藤; 泰彦 糸永; 睦郎 西村 |
|
62 |
Driving mechanism using a fluid control mechanism and fluid |
JP7191192 |
1992-03-30 |
JP3274488B2 |
2002-04-15 |
知己 加藤; 俊一 安藤; 元美 尾崎; 康之 岡田; 充 新行内; 武 竹本 |
|
63 |
Heat-driven pump |
JP9489390 |
1990-09-10 |
JPH0754640Y2 |
1995-12-18 |
謙治 岡安 |
|
64 |
Fluid transfer pressure generating method due to the movement of the phase-change region |
JP20721192 |
1992-07-10 |
JPH0765599B2 |
1995-07-19 |
OZAKI KOICHI |
|
65 |
Compressor |
JP25012993 |
1993-09-10 |
JPH0783200A |
1995-03-28 |
SATO YASUO; ITONAGA YASUHIKO; NISHIMURA MUTSURO |
PURPOSE:To provide a compressor without any generation of abrasion, vibration and noise, which does not have any effect such as a flicker on a power source system by eliminating a mechanically operating unit. CONSTITUTION:A compressor comprises a confluence tube 1, a magnetic valve 2, a cylinder 3, stators 4a, 4b, a compressed air tank 5 and a recirculator 6. The magnetic valve 2 makes magnetic fluid 7 intermittently flow in the confluence tube 1 for combining air with the magnetic fluid 7. The cylinder 3 is formed into a spiral shape, to make the magnetic fluid 7 and air pass from the confluence tube 1. The circular stators 4a, 4b are disposed above and below the cylinder 3, respectively, in such a manner as to hold the cylinder 3 therebetween. The magnetic fluid 7 discharged from an outlet of the cylinder 3 flows into the compressed air tank 5 through a check valve 40. The magnetic fluid 7 staying inside the compressed air tank 5 is supplied to the magnetic valve 2 via the recirculator 6. |
66 |
Dynamic pressure machine |
JP7164793 |
1993-03-30 |
JPH0642500A |
1994-02-15 |
RORUFU ARUTOHAUSU; YAUUPIN CHIYOU; ERUBUIN TSUAUNAA |
PURPOSE: To obtain a dynamic pressure machine having a simple structure and reducing a high cost needed by controlled ignition means. CONSTITUTION: A cell wall 23 is provided with means for automatic ignition and combustion of a new inflow gas mixture. This means is, for example, a high-temperature gas pocket 24 disposed at the wall 23 of a cell 11. |
67 |
Gradual moving apparatus of liquid |
JP11032091 |
1991-11-13 |
JPH0547500U |
1993-06-25 |
暎朔 田中 |
(57)【要約】 【目的】 容器の中の液体を、必要な量だけ、他の容器又は場所に、連続かつ自動的に移動するものである。 【構成】 繊維質の含液物質(5)を充填した、管状の吸上筒部(1)と流下筒部(2)、および、液を流す流導部(3)から構成される装置である。 【効果】 緩やかな液体の移動を、外部から、他の動力を加える事なく行なう事が出来る。 |
68 |
JPH021500U - |
JP7839188 |
1988-06-14 |
JPH021500U |
1990-01-08 |
|
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69 |
JPS5710481U - |
JP8484780 |
1980-06-19 |
JPS5710481U |
1982-01-20 |
|
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70 |
JPS56111300U - |
JP845380 |
1980-01-29 |
JPS56111300U |
1981-08-28 |
|
|
71 |
JPS54142810U - |
JP4118578 |
1978-03-29 |
JPS54142810U |
1979-10-03 |
|
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72 |
JPS5290710U - |
JP17846575 |
1975-12-29 |
JPS5290710U |
1977-07-06 |
|
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73 |
JPS5290709U - |
JP17648175 |
1975-12-29 |
JPS5290709U |
1977-07-06 |
|
|
74 |
Fluid drive equipment, chemical analysis apparatus and a fluid driving method |
JP13023594 |
1994-06-13 |
JP3595883B2 |
2004-12-02 |
亮 三宅; 弘 三巻; 功夫 山崎; 英雄 榎; 雅治 石井 |
PURPOSE:To enable the generation of flow to a fluid without inserting any external object in the fluid in a passage or a tank. CONSTITUTION:A fluid 12 is stored between a flat plate 10 and a flat plate 11, and the flat plate 10 is placed on plural supports 14 provided on a stationary base 13. A driving plate 15 is fixed to the bottom face of the flat plate 10, and a fixed plate 16 is fixed to the stationary base 13. A piezoelectric element 17 is provided between the driving plate 15 and the fixed plate 16. When sawtooth voltage with steep rise and easy fall is applied to the piezoelectric element 17 from a driver 18, the piezoelectric element 17 repeats expansion and contraction, and the driving plate 15 is vibrated with speed vectors 20, 21 different in size by the expansion and contraction, and flow can be generated to the fluid 12 by this vibration. |
75 |
Liquid jet generation method by ehd pumping and liquid jet generation device by ehd pumping |
JP2000314474 |
2000-09-06 |
JP2002081400A |
2002-03-22 |
HANAOKA RYOICHI; TAKADA SHINZO |
PROBLEM TO BE SOLVED: To inhibit a deterioration of an electrical characteristic of an insulative liquid used by generating a liquid jet having a high directivity even to the insulative liquid having a constant temperature thermally insulated and accompanying with no charge pouring from the electrode to the insulative liquid regarding the case where the liquid jet is generated by EHD pumping.
SOLUTION: One end of a suspected donut-like electrode in which a liquid circulation hole is penetrated to a direction of a center axis and of which both end surfaces are molded to an arc-like shape is opposed to a flat plate electrode at an interval to constitute an electrode system. This electrode system is placed in an insulative liquid and a liquid jet of the insulative liquid is injected from an end surface of the suspected donut-like electrode through the liquid circulation hole of the suspected donut-like electrode by applying a D.C. high voltage to a space between the suspected donut-like electrode and the flat plate electrode.
COPYRIGHT: (C)2002,JPO |
76 |
Electrical momentum transport pump |
JP50040897 |
1995-11-09 |
JPH11506183A |
1999-06-02 |
ザンズチ,ピーター,ジェイ.; デマーズ,ロバート; バートン,シャーロット,エー.; マクブライド,スターリング,イー. |
(57)【要約】 本発明は電極ベース・ポンプ(803)およびこのようなポンプを操作する方法を提供する。 ある実施形態では、本発明は、第1の電極(801A)および第2の電極(801B)からなる流路中に置かれた電極ベース・ポンプであり、前記第1(801A)および第2(801B)の電極が約25〜約100ミクロンの直径を持ち約100〜約2,500ミクロンの間隔をおいて配置されるポンプを提供する。 別の実施形態では、本発明は、第1の電極(801A)、第2の電極(801B)および第3の電極(801C)を有する電極ベース・ポンプを提供する。 |
77 |
Fluid transfer pressure generating method due to the phase change |
JP32955391 |
1991-11-18 |
JP2673977B2 |
1997-11-05 |
崎 浩 一 尾; 中 章 浩 田 |
|
78 |
Pumping machine |
JP5117088 |
1988-03-03 |
JP2664922B2 |
1997-10-22 |
健二 丸本; 全 土井 |
PURPOSE:To make a pump in the configuration without a driving apparatus and improve its reliability by providing a water absorbing section whose aqueous solution touches outside water such that a penetrating membrane interfaces them, an evaporation section where the water is evaporated and a cooling plate which liquefies the water. CONSTITUTION:Located in a lower position is a water absorbing section 10 which contains aqueous solution 6 touching water such that a penetrating membrane 5 interfaces them. An evaporation section 9 is located in a higher position where the water is evaporated from the aqueous solution 6. A cooling plate 7 cools the evaporated water and liquefies it. The water 1 is absorbed through the membrane 5 due to the osmotic pressure generated by concentration difference of the water 1 and the aqueous solution 6. Due to absorption, the volume of the aqueous solution 6 increases so that its upper face rises and its concentration is diluted. Accordingly, A pump does not need a driving apparatus so that its reliability is improved and demineralized water is obtained. |
79 |
Fluid transfer method of phase-change use in fluid transport network |
JP22463192 |
1992-07-31 |
JPH0765600B2 |
1995-07-19 |
崎 浩 一 尾 |
|
80 |
Fluid transfer pressure generating method by phase change area movement |
JP20721192 |
1992-07-10 |
JPH074400A |
1995-01-10 |
OZAKI KOICHI |
PURPOSE:To provide a fluid transfer pressure generating method effectively used for the pumping, sealing, or the like of a fluid through the easy control of pressure at the time of generating the pressure for the flow of the fluid from a low pressure side container to a high pressure side container making use of phase change (evaporation-condensation) by the heating-cooling of the fluid. CONSTITUTION:A low pressure side container 1 stored with a fluid to be transferred, and a high pressure side container 2 to which the fluid is transferred are communicated through a narrow clearance passage 3. A heating part 4 for evaporating the fluid in the passage 3 from the low pressure side to the high pressure side is moved in relation to the passage 3, along the flow direction of the fluid, and the required pressure toward a high pressure side fluid storage area from a low pressure side fluid storage area is generated to the fluid in the passage 3 by controlling the moving speed of the heating part 4. |