| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | 세퍼레이터 세척 기능을 갖는 폐축전지 해체 시스템 | KR1020170163028 | 2017-11-30 | KR101863333B1 | 2018-05-31 | 이영훈 |
| 본발명의세퍼레이터세척기능을갖는폐축전지해체시스템은, 폐축전지를절단하여내부의전해액을제거하는전해액제거부와, 전해액제거부의일측에설치되며, 전해액이제거된폐축전지를공급받아폐축전지의철재류를제거하는탈철부와, 탈철부의일측에설치되며, 전해액과철재류가제거된폐축전지를공급받아분쇄시키는분쇄부와, 분쇄부의일측에설치되며, 분쇄부에의해분쇄된폐축전지분쇄물을공급받아분쇄물을구성하는폴리프로필렌, 세퍼레이터및 그리드를비중을이용하여선별분리하는수력분리부와, 수력분리부의일측에설치되며, 수력분리부에의해분리회수된세퍼레이터를세척하는세퍼레이터세척부를포함할수 있다. | ||||||
| 182 | 바람직하게 선박 상에서 폐수를 정화하기 위한 장치 | KR1020117027158 | 2010-04-19 | KR1020120016096A | 2012-02-22 | 하만크누드 |
| 본 발명은, 바람직하게 선박 상에서 폐수를 정화하기 위한 장치에 있어서, 처리되지 않은 물을 위한 탱크가 해리기 및 공급 펌프를 통해 압력 탱크에 연결되어 있는, 폐수를 정화하기 위한 장치에 관한 것이다. 상기 압력 탱크는, 상기 압력 탱크 내의 처리되지 않은 물이 공기로 포화되도록, 압축 공기원에 연결되어 있다. 상기 압력 탱크는 라인을 통해 감압 탱크에 연결되어 있다. 상기 감압 탱크 내에서, 플로테이트 및 정화수가 서로로부터 분리될 수 있다. 팽창 밸브는 상기 라인 내에 삽입되어 있고, 엉김제를 위한 투약 펌프는 상기 팽창 밸브와 상기 감압 탱크 사이의 상기 라인에 연결되어 있다. | ||||||
| 183 | 생분자 제조 방법 및 장비 | KR1020107019881 | 2009-02-06 | KR1020100123859A | 2010-11-25 | 우르타레르조센; 아스체르크리스틴; 부켈리다니엘 |
| 본 발명은 생분자, 특히 약제학적 등급의 플라스미드 DNA를 제조하기 위한 확장가능한 방법 및 장비에 관한 것으로, 본 방법은 알칼리 용해 단계, 중화 단계 및 정화 단계를 포함하며, 더 확장가능하다. 용해물과 침전을 분리하기 위해 개선된 부유 방법이 개시되며, 이 방법은 침전 플록에 CO
2 방울의 부착에 기초한다. 중화 단계(산성화) 동안 또는 후에 카보네이트로부터 CO
2 가 방출된다. 본 방법은 바람직하게 자동화된 연속 모드로, 용해 및 중화 장비 및 완전히 연속적인 정화를 위한 새로운 장비(플록 및 투명 용해물의 분리)를 응용하여 수행된다.
|
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| 184 | 정수장치 | KR1019920703083 | 1990-06-04 | KR100140192B1 | 1998-07-01 | 마일로스크로프타 |
| Water clarifying apparatus has a cylindrical tank where particulate contaminants suspended in raw water are separated using flotation techniques. A set of concentric mutually spaced, conical plates are positioned in the flotation tank. The plates rotate about the tank, preferably in unison with a (i) header that distributes equal quantities of raw water to each annular zone in the tank defined by the conical plates and (ii) a scoop for removing the contaminants which form a floated sludge layer. A screw conveyor is located in a discharge pipe of the floated sludge scoop. A infrared sludge detection array in a window in the side wall of the tank senses the sludge-water interface. Air dissolving tubes operating in parallel have common feeds and discharges coupled through three way valves operated to pressurize a closed volume of water with high pressure air in one tube while reloading and discharging the other tube. | ||||||
| 185 | 탈잉크용 부유 선별 장치 | KR1019900015350 | 1990-09-27 | KR1019960015816B1 | 1996-11-21 | 이와시게나오유끼; 에구찌마사까즈 |
| A flotation machine for de-inking waste paper stock comprises a horizontally extending flotation cell (5) defining a reservoir for a stock liquid which forms a free liquid surface in the cell. A froth receptacle (4) extends along the entire length of the cell and receives froth floating up to the liquid surface. At opposite ends of the cell are a stock inlet (1) and a stock outlet (2). Situated within the lower portion of the cell is a rotary air bubble generator (3) which extends between the two ends of the cell with its axis of rotation extending generally horizontally whereby stock liquid introduced through the inlet (1) flows along the length of the cell towards the outlet (2) in at least one spiral flow pattern (11) with a generally horizontal axis. | ||||||
| 186 | 예상치 이상의 입자를 제거하기 위한 정수장치 | KR1019890700620 | 1988-08-26 | KR1019960012553B1 | 1996-09-23 | 마일로스크로프타 |
| Apparatus adapted for use in a water clarification system which removes particles of greater than a predetermined size from the clarified water includes a screen or a pair of concentric screens positioned in a clarified water storage area between an inlet and a clarified water outlet. One or more spray heads for direct a shower of high pressure filtered clarified water at the outlet side of the screen or screens to loosen or remove particles therefrom. In addition, a rotating brush can act on the inlet side of the screen. Particles removed by the cleaning elements are recirculated through the system. Water levels are maintained by overflow control or by monitoring the water level and utilizing the output from the monitor or monitors to selectively control valves in the inlet or outlets from the system. | ||||||
| 187 | 유체 역학적 혼합 방법 및 장치 | KR1019870009109 | 1987-08-20 | KR1019920007009B1 | 1992-08-24 | 보르제이프레드릭손; 제퍼리로우엘스테펜타운싸우쓰스테펜타운로드 |
| A plurality of fluent substances are combined in a distributor (11) and caused to flow in a continuous, pressurized stream through a mixing zone (13) wherein the substances are intimately mixed by turbulent dispersion effected by a series of conically shaped surfaces (24,27) and alternate restrictions (25) and expansion chambers (28). While various fluent substances may be advantageously mixed, a typical utility is for effecting a thorough air binding of ink particles to attain efficient foaming in the deinking of reconstituted printed paper slurry. | ||||||
| 188 | A DRIVE MODULE AND ITS USES, A FLOTATION PLANT AND A METHOD OF CHANGING OF THE DRIVE MODULE | EP15891730 | 2015-05-13 | EP3295071A1 | 2018-03-21 | TAEHKIOE PEKKA; VAARNA VALTTERI; LUUKKONEN MATTI |
| A drive module (1) which is a self-supporting structure being transferable and hoistable as an integral entity. The drive module (1) comprises a self- supporting framework (2) having a shape of a rectangular parallelepiped. The self-supporting framework (2) defines an inner space (3) within the self-supporting framework. The drive module also comprises at least two drive units (4). The drive units are supported to the self-supporting framework (2) in the inner space (3) of the self-supporting framework. The drive units (4) are connectable to an external rotatable shaft (5) for the rotation of the rotatable shaft located out- side the drive module (1). | ||||||
| 189 | A FLOTATION PLANT AND ITS USES, A METHOD OF CHANGING A FLOTATION TANK IN A TANK MODULE AND A METHOD OF CHANGING A MODULE | EP15891731 | 2015-05-13 | EP3294459A1 | 2018-03-21 | TAEHKIOE PEKKA; LAKANEN JUKKA; LUUKKONEN MATTI |
| A flotation plant comprises a tank module (1) which includes a self-supporting framework (2) having an inner space (3). The tank module includes at least one flotation tank (4). The flotation tank is disposed in the inner space (3) of the self-supporting framework (2). The tank module is a self-supporting unit capable of being transferable and hoistable as an integral entity. The flotation plant comprises at least two drive units (5) for the rotation of drive shafts (6), each drive shaft (6) being connected to a rotor (7) for mixing and/or forming bubbles in the flotation tank (4). An overflow receptacle (8) is disposed at the level of the upper part of the tank module (1) for receiving an overflow from the flotation tanks (4). The flotation plant comprises an overflow channel (9) which is connected to the overflow receptacle (8) for receiving and conducting the overflow from the over-flow receptacle (8) to a pumping means (10). The over- flow channel (9) is disposed outside the tank module (1). | ||||||
| 190 | INJECTOR FOR FLOTATION CELL | EP08736812.2 | 2008-04-03 | EP2129828B1 | 2014-09-03 | NIEMINEN, Erkka |
| 191 | METHOD FOR SEPARATING SUSPENDED SOLIDS FROM A WASTE FLUID | EP10808441.9 | 2010-08-09 | EP2464438A1 | 2012-06-20 | BIAS, Joel; ROSS, Brian |
| The disclosure relates to a separation process. An aerated inlet mixture of fluid and solids is fed to a flotation separation vessel and is separated into an upper float layer and a lower clarified layer. The upper float layer is withdrawn from the vessel when the height of the upper float layer exceeds the height of an overflow conduit and forms a concentrated solids effluent The lower clarified layer is withdrawn from the separation vessel as a clarified fluid effluent. The separation process is performed continuously using a control process that maintains a relatively stable distribution between the lower clarified layer and the upper float layer. The control process is a closed loop process that monitors the instantaneous height of the vessel contents and computes an error function based on the instantaneous height and a set-point height. The error function is used to periodically adjust the outlet flowrate of the clarified fluid effluent. The resulting process has improved stability (e.g., being continuously operable without interruption and/or operable for extended periods between intermittent cleaning processes) and provides a concentrated solids effluent with solids concentrations higher than those previously attainable in similar separation processes. | ||||||
| 192 | Apparatus for separating impurites from coolant liquid in cutting or grinding machine | EP03008864.5 | 1997-02-12 | EP1350596B1 | 2005-04-27 | Nakai, Yoshikazu |
| A method and apparatus for feeding coolant liquid to a lathe with a nozzle (53) having a discharge port (58) of substantially rectangular cross section and a constricted curved surface portion (62) on its inner wall to produce a turbulent flow and a loosely mounted tongue piece (59) crossing the section of the discharge port and projecting outside the port. The coolant is thus discharged as a collection of particulate turbulent flows containing air bubbles drawn into the coolant liquid as it passes by the tongue piece. The coolant is caused to impinge on the rotating peripheral surface (56) which is continuous with the region of the workpiece in contact with the cutter (57). |
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| 193 | Method and apparatus for feeding coolant liquid in a lathe | EP03008863.7 | 1997-02-12 | EP1338380B1 | 2005-04-27 | Nakai, Yoshikazu |
| A method and apparatus for feeding coolant liquid to a lathe with a nozzle (53) having a discharge port (58) of substantially rectangular cross section and a constricted curved surface portion (62) on its inner wall to produce a turbulent flow and a loosely mounted tongue piece (59) crossing the section of the discharge port and projecting outside the port. The coolant is thus discharged as a collection of particulate turbulent flows containing air bubbles drawn into the coolant liquid as it passes by the tongue piece. The coolant is caused to impinge on the rotating peripheral surface (56) which is continuous with the region of the workpiece in contact with the cutter (57). |
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| 194 | METHOD AND APPARATUS FOR SUPPLYING AND SEPARATING RECOVERING LIQUID COOLANT FOR CUTTING MACHINES AND GRINDING MACHINES | EP97902667.1 | 1997-02-12 | EP0881033B1 | 2003-11-05 | NAKAI, Yoshikazu |
| A method and apparatus for feeding coolant liquid to a lathe with a nozzle (53) having a discharge port (58) of substantially rectangular cross section and a constricted curved surface portion (62) on its inner wall to produce a turbulent flow and a loosely mounted tongue piece (59) crossing the section of the discharge port and projecting outside the port. The coolant is thus discharged as a collection of particulate turbulent flows containing air bubbles drawn into the coolant liquid as it passes by the tongue piece. The coolant is caused to impinge on the rotating peripheral surface (56) which is continuous with the region of the workpiece in contact with the cutter (57). |
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| 195 | Apparatus for separating impurites from coolant liquid in cutting or grinding machine | EP03008864.5 | 1997-02-12 | EP1350596A1 | 2003-10-08 | Nakai, Yoshikazu |
A coolant liquid feeding method comprises feeding a coolant liquid, with air bubbles caused to form continuously therein, for cutting or grinding operation to a region under machining, expediting the splashing of air bubbles in all directions when the air bubbles impinge on the region under machining and burst, and also expediting the entry of accelerated splashed liquid particles into a cutter/workpiece pressure contact plane, thereby improving the cooling and lubrication of the region under machining, whereby the air bubbles in the coolant liquid which has failed to reach the region under machining or which, though reaching there, has left there for the recovery channel are allowed to adhere to suspended foreign matters in the liquid, thereby expediting the surfacing of the foreign matters. |
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| 196 | MOBILE SOIL TREATMENT APPARATUS AND METHOD | EP96929987.0 | 1996-09-13 | EP0961662A1 | 1999-12-08 | STEPHENSON, Robert, John; LIM, Choom, Jim; LIM, Kok-Seng |
| A mobile apparatus and method for treating contaminated soil is disclosed. The apparatus consists of three interconnected subunits, namely a fluidized bed reactor (10, 200) for segregating an aqueous soil slurry based on particle size; a metals extraction unit for removing heavy metals and other contaminants from the contaminated soil fraction; and a water treatment system utilizing a high density sludge process to remove metals from the contaminated aqueous phase. The fluidized bed reactor (10, 200) includes a relatively small first chamber (12, 202) and a relatively large second chamber (14, 204) which are partially separated by a baffle (16, 206). Pressurized gas is dispersed into the first chamber (12, 202) to create a turbulent mixture of raw soil and water, resulting in interparticle scouring of the soil surfaces to assist in the abrasion and removal of adsorbed contaminants. The soil particles are segregated into a first fraction containing relatively small, contaminated soil particles and a second fraction containing relatively large, uncontaminated soil particles. The first fraction is preferably withdrawn from an upper portion of the reactor (10, 200) as a foam. A soil slurry containing the relatively uncontaminated second fraction is continuously withdrawn from a lower portion of the reactor (10, 200). In one embodiment of the invention, the soil slurry may be circulated between the first and second chambers multiple times to increase the soil residence time in the reactor (10, 200). The soil slurry is dewatered downstream of reactor (10, 200) and the water filtrate is recycled. Gas vented from reactor (10, 200) may also be captured, cleaned and recycled. | ||||||
| 197 | Means for generating air bubbles in a liquid | EP95102747.3 | 1990-09-26 | EP0659489B1 | 1998-12-30 | Iwashige, Naoyuki; Eguchi, Masakazu |
| 198 | METHOD AND APPARATUS FOR SUPPLYING AND SEPARATING RECOVERING LIQUID COOLANT FOR CUTTING MACHINES AND GRINDING MACHINES | EP97902667.1 | 1997-02-12 | EP0881033A1 | 1998-12-02 | NAKAI, Yoshikazu |
A coolant liquid feeding method comprises feeding a coolant liquid, with air bubbles caused to form continuously therein, for cutting or grinding operation to a region under machining, expediting the splashing of air bubbles in all directions when the air bubbles impinge on the region under machining and burst, and also expediting the entry of accelerated splashed liquid particles into a cutter/workpiece pressure contact plane, thereby improving the cooling and lubrication of the region under machining, whereby the air bubbles in the coolant liquid which has failed to reach the region under machining or which, though reaching there, has left there for the recovery channel are allowed to adhere to suspended foreign matters in the liquid, thereby expediting the surfacing of the foreign matters. |
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| 199 | Flotation machine for de-inking | EP90310514.6 | 1990-09-26 | EP0428257B1 | 1996-05-29 | Iwashige, Naoyuki; Eguchi, Masakazu |
| 200 | Means for generating air bubbles in a liquid | EP95102747.3 | 1990-09-26 | EP0659489A3 | 1995-09-06 | Iwashige, Naoyuki; Eguchi, Masakazu |
A means for generating air bubbles in a liquid comprises a turbine rotor (21) which has a plurality of peripheral blades (24) and an air supply line (26) situated adjacent the outer periphery of the turbine rotor for supplying air. The air supply line (26) has at least one air supply port (26a) directed towards the turbine rotor. The rotor body (25) is in the form of a cylindrical cage and is constructed from four equispaced parallel disc-shaped ribs (23a, 23b) which have the same coaxial diameter. |
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