| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | Method and device for treating noncondensable gas from geothermal well | JP26055886 | 1986-10-31 | JPS62117983A | 1987-05-29 | JIEEMUZU TEII KUWADA |
| 42 | Formation injection tool for down-bore in-situ disposal | KR19967003635 | 1996-07-05 | KR977000278A | 1997-01-08 | HAMMEKE MICHAEL N; HENDERSON BILL II; MICHAEL CLARENCE |
| 43 | CBM 산출수 처리시스템 | KR1020140054102 | 2014-05-07 | KR1020150127897A | 2015-11-18 | 남양원; 강민준 |
| 본발명은, 석탄층메탄가스(coal bed methane)(이하, CBM이라한다.)를생산하는과정에서 CBM 생산정으로부터산출되는물인 CBM 산출수가저장되는원수저류장치, 원수저류장치로부터의 CBM 산출수에대하여응집제를이용하여고액분리를하는고액분리장치, 고액분리장치로부터의처리수에대하여고도처리를하는고도처리수단을포함하는 CBM 산출수처리시스템을제공한다. | ||||||
| 44 | 연소배기가스중의 이산화탄소의 제거방법 | KR1019930000490 | 1993-01-15 | KR1019970011311B1 | 1997-07-09 | 후지이마스미; 수다타이이찌로; 홋타요시쯔구; 코바야시켄지; 요시다쿠니히꼬; 시모죠시게루; 카라사끼무쯔노리; 이이지마마사끼; 세또토오루; 미쯔오까시게아키 |
| A process for removing carbon dioxide (CO2) from a combustion exhaust gas of a boiler which generates steam for driving high, intermediate, and low pressure turbines. The process comprises the steps of removing CO2 in the combustion exhaust gas by absorption with a CO2-absorbing liquid, liquefying the removed CO2 by compression and cooling, storing the CO2, and regenerating the CO2-absorbing liquid by a CO2-absorbing liquid regeneration column equipped with a reboiler. In the process, a part of steam discharged from the high pressure turbine is used to drive turbines for compressors that compress and cool the CO2, and steam discharged from the compressor turbines is supplied as a heating source to the reboiler for the regeneration of the CO2-absorbing liquid. A decrease in the overall power plant efficiency due to the removal of carbon dioxide from the exhaust gas can be reduced. |
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| 45 | 압력 모니터링에 의한 지중 가스 저장층에서의 가스유출 탐지방법 및 지중 가스 저장시스템 | KR1020100076979 | 2010-08-10 | KR100999030B1 | 2010-12-10 | 박용찬; 허대기 |
| PURPOSE: A method for detecting gas leakage in an underground gas storage layer and an underground gas storage system are provided to deal with gas leakage in real time by transmitting the pressure value measured by a pressure sensor in real time. CONSTITUTION: A storage layer(10) is made of permeable rocks under the ground. A cover rock layer(20) is formed on the upper side of the storage layer and is made of impermeable rocks. An upper permeable layer(30) is made of permeable rocks on the upper side of a cover rock layer. A hollow casing(50) is fitted into the inner wall of a gas injection well from the surface to the storage layer. A plurality of gas injection holes are formed. A pressure sensor(60) is arranged with the same depth as the upper permeable layer and detects the upper permeable layer. The pressure of the upper permeable layer is detected. | ||||||
| 46 | 생고형물 처리 및 메탄 생성 방법 | KR1020047001189 | 2001-10-02 | KR100550149B1 | 2006-02-08 | 브루노,마이클,에스.; 뒤세올트,모리스,비.; 비락,로만 |
| A method for the disposal of biosolids, the method comprising a) providing a supply of biosolids; creating a slurry of the biosolids suitable for injecting; selecting an injection formation below a ground surface, the injection formation comprising a natural gas formation in a gas accumulation zone; injecting the biosolids slurry into the injection formation at a pressure sufficient to create and maintain fractures within the selected injection formation; and allowing degradation of the injected biosolids slurry. | ||||||
| 47 | 생고형물 처리 및 메탄 생성 방법 | KR1020047001189 | 2001-10-02 | KR1020040035694A | 2004-04-29 | 브루노,마이클,에스.; 뒤세올트,모리스,비.; 비락,로만 |
| 본 발명은 생고형물(A3)을 지면 아래 주입층(A4)으로 주입시킴을 포함하는 도시 하수 폐기물과 같은 생고형물(A3)의 처리 방법에 관한 것이다. 당해 방법은 생고형물(A3)의 분해로부터 생성된 메탄을 회수하는 단계를 포함할 수 있다. | ||||||
| 48 | HIGH PRESSURE GAS STORAGE | EP15795036.1 | 2015-06-12 | EP3155212B1 | 2018-08-15 | STRYBOS, Ronald |
| A storage wellhead allowing on-line system maintenance and testing is provided. Including at least two fluidically parallel gas passages adapted to allow testing or maintenance of one gas passage, while the other gas passage remains in service. The gas may be hydrogen. Also including at least two fluidically parallel liquid passages adapted to allow testing or maintenance of one liquid passage, while the other liquid passage remains in service. The liquid may be brine. | ||||||
| 49 | VERFAHREN ZUR HYDROGENOTROPHEN METHANOGENESE VON H2 UND CO2 ZU CH4 | EP16713366.9 | 2016-03-24 | EP3280807A1 | 2018-02-14 | MITTEREGGER, Markus; BAUER, Stephan; LOIBNER, Andreas P.; SCHRITTER, Johanna; GUBIK, Alexander; BACKES, Diana; PICHLER, Markus; KOMM, Robert; BRANDSTÄTTER-SCHERR, Kerstin |
| The invention relates to a method for the hydrogenotrophic methanogenesis of H 2 and CO 2 into CH 4, characterized in that a gas mixture comprising natural gas, hydrogen, and CO 2 and having a minimum concentration of natural gas of 10% and preferably a ratio between hydrogen and CO 2 that is stoichiometric for the formation of CH 4 is introduced into an underground store comprising a gas zone and is stored there in the presence of methanogenic microorganisms. The invention further relates to the use of such a method to control the content of CO 2 and/or hydrogen in a natural gas. | ||||||
| 50 | METHOD OF USING PRESSURE SIGNATURES TO PREDICT INJECTION WELL ANOMALIES | EP08799094.1 | 2008-09-03 | EP2198115B1 | 2017-08-02 | SHOKANOV, Talgat, A.; NOLTE, Kenneth, G.; FRAGACHAN, Francisco; OVALLE, Adriana, P. |
| 51 | METHOD FOR DETECTING GAS OUTFLOW FROM AN UNDERGROUND GAS STORAGE LAYER BY MEANS OF PRESSURE MONITORING, AND AN UNDERGROUND GAS STORAGE SYSTEM | EP10855958 | 2010-12-23 | EP2605049A4 | 2017-04-19 | PARK YONG-CHAN; HUH DAE-GEE |
| 52 | TUNNELED GAS STORAGE | EP13820602 | 2013-07-17 | EP2874917A4 | 2016-02-10 | RAM YOSEF |
| A system for high-pressure natural gas storage includes at least one underground bored tunnel, suitable for holding natural gas under pressure and a process for storing natural gas under pressure. | ||||||
| 53 | AN INTEGRATED SYSTEM FOR OFFSHORE INDUSTRIAL ACTIVITIES WITH FUME INJECTION | EP12830562 | 2012-12-19 | EP2795055A4 | 2015-11-04 | MYHR GUNNAR |
| This invention is related to integrated systems for offshore or land based industrial activities which use for feedstock or produce gas, crude oil and/or refined petroleum products/components, and provide reservoir injection of fume gases, can receive and store CO2 or flue gases from other offshore or onshore industrial processes or hydrocarbon producing installations, and can provide industrial products, the generation and transmission of electric power and communications between the various elements or units within a defined network or grid. The at least one industrial activity is represented by combinations of at least one hydrocarbon producing installation, at least one distillation unit, at least one upgrading unit, oil refinery, combined cycle electric power plant, production of heat, production of steam, production of at least one fertilizer, production of at least one petrochemical product. A most favorable integrated system can detect and measure the demand, include applying and the control of fogging of the at least one gas turbine (5) and provide and control wet compression (7), generate electric power accordingly by a combined cycle gas combustion process, and provide the optimization (minimization) of O2, enabling the reinjection of the fume gases (CO2 + N2) into producing HC reservoirs, thus provide pressure support for enhanced HC recovery. Associated or integrated heat and/or steam production ( from the at least one steam or boiler unit) can facilitate other activities on the at least one installation or distributed to the network (10). The integrated system will control the supply of electric power to the grid or network in question. The control of the system is integrated, coordinated and operated in real time. | ||||||
| 54 | Bohrlochkomplettierung einer Speicherbohrung | EP14170623.4 | 2014-05-30 | EP2821586A2 | 2015-01-07 | Klafki, Michael; Bannach, Andreas |
Die Erfindung betrifft eine Bohrlochkomplettierung einer Speicherbohrung (1) einer Druckluftkaverne, umfassend eine Standrohrtour (4), eine Ankerrohrtour (5), eine Futterrohrtour (6) aus einem ersten Werkstoff und eine sich in die Druckluftkaverne (2) erstreckende Förderrohrtour (3). Bei der Bohrlochkomplettierung gemäß der Erfindung ist vorgesehen, dass die Futterrohrtour (6) als Futterrohrschuh (10) an ihrem in der Speicherbohrung (1) führenden Ende wenigstens eine Futterrohrsektion aus einem zweiten korrosionsbeständigen Werkstoff umfasst, der von dem ersten Werkstoff verschieden ist, dass der Futterrohrschuh (10) über eine Rohrmuffe aus einem dritten Werkstoff an die Futterrohrtour (6) angeschlossen ist und dass der dritte Werkstoff von dem ersten und zweiten Werkstoff verschieden ist.
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| 55 | AN INTEGRATED SYSTEM FOR OFFSHORE INDUSTRIAL ACTIVITIES WITH FUME INJECTION | EP12830562.0 | 2012-12-19 | EP2795055A2 | 2014-10-29 | MYHR, Gunnar |
| This invention is related to integrated systems for offshore or land based industrial activities which use for feedstock or produce gas, crude oil and/or refined petroleum products/components, and provide reservoir injection of fume gases, can receive and store CO 2 or flue gases from other offshore or onshore industrial processes or hydrocarbon producing installations, and can provide industrial products, the generation and transmission of electric power and communications between the various elements or units within a defined network or grid. The at least one industrial activity is represented by combinations of at least one hydrocarbon producing installation, at least one distillation unit, at least one upgrading unit, oil refinery, combined cycle electric power plant, production of heat, production of steam, production of at least one fertilizer, production of at least one petrochemical product. A most favorable integrated system can detect and measure the demand, include applying and the control of fogging of the at least one gas turbine (5) and provide and control wet compression (7), generate electric power accordingly by a combined cycle gas combustion process, and provide the optimization (minimization) of O 2, enabling the reinjection of the fume gases (CO 2 + N 2) into producing HC reservoirs, thus provide pressure support for enhanced HC recovery. Associated or integrated heat and/or steam production ( from the at least one steam or boiler unit) can facilitate other activities on the at least one installation or distributed to the network (10). The integrated system will control the supply of electric power to the grid or network in question. The control of the system is integrated, coordinated and operated in real time. | ||||||
| 56 | Procédé pour maintenir un volume de gaz dans un réservoir géologique souterrain par injection d'azote | EP12290209.1 | 2012-06-26 | EP2565371A1 | 2013-03-06 | Barroux, Claire |
On sélectionne un gaz de traitement ayant les propriétés suivantes : - le gaz de traitement est plus léger que le gaz à maintenir ; - le gaz de traitement engendre des tensions interfaciales avec des liquides aqueux ou hydrocarbonés plus importantes que le gaz à maintenir ; - le gaz de traitement mouille moins la roche de couverture que le gaz à maintenir. Puis, on détermine le volume de gaz de traitement à injecter en fonction des caractéristiques géologiques du réservoir et du volume de gaz à maintenir. On injecte le volume de gaz de traitement dans le réservoir.
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| 57 | METHOD OF USING PRESSURE SIGNATURES TO PREDICT INJECTION WELL ANOMALIES | EP08799094.1 | 2008-09-03 | EP2198115A1 | 2010-06-23 | SHOKANOV, Talgat, A.; NOLTE, Kenneth, G.; FRAGACHAN, Francisco; OVALLE, Adriana, P. |
| A method of designing a response to a fracture behavior of a formation during re-injection of cuttings into a formation, the method including obtaining a pressure signature for a time period, interpreting the pressure signature for the time period to determine a fracture behavior of the formation, determining a solution based on the fracture behavior of the formation, and implementing the solution is disclosed. A method of assessing a subsurface risk of a cuttings re-injection operation, the method including obtaining a pressure signature for a time period, interpreting the pressure signature to determine a fracture behavior of the formation, characterizing a risk associated with the determined fracture behavior of the formation, and implementing a solution based on the characterized risk is also disclosed. | ||||||
| 58 | APPARATUS AND METHOD TO MONITOR SLURRIES FOR WASTE RE-INJECTION | EP06788847.9 | 2006-07-28 | EP1910642A1 | 2008-04-16 | ROGERS, Brian; ALBA, Andrea; PERI, Shrinivas; STOCKS, Shannon; CHANG, Lingo |
| A method to inject a slurry into a subterranean formation includes measuring characteristic data from a well in communication with the subterranean formation, estimating downhole properties of the slurry using the measured characteristic data, measuring surface properties of the slurry with a measurement apparatus, determining optimal surface properties for the slurry from the estimated downliole properties, comparing the measured surface properties with the determined optimal surface properties, modifying the slurry until the measured surface properties are within tolerance values of the determined optimal surface properties, and injecting the modified slurry into the subterranean formation through the well. | ||||||
| 59 | METHOD FOR CONSTRUCTION AND COMPLETION OF INJECTION WELLS | EP03734441.3 | 2003-06-06 | EP1509675B1 | 2007-09-19 | JOHNSON, Michael H. |
| A method for well construction and completion is disclosed. Generally the method comprises the steps of 1) drilling through an injection zone, 2) positioning an extendable permeable element on the casing capable of stopping formation material from entering the well bore, 3) positioning the casing such that the extendable elements are aligned with the injection zone, 4) extending the member such that they come into direct contact with the injection zone formation, 5) running tubing/completion equipment, and 6) begin injecting the desired fluids into the well. Thus eliminating the need to perforate and gravel pack the well while improving reliability of the injection well completion. | ||||||
| 60 | Méthode de détermination des capacitiés de stockage de gaz acides d'un milieu géologique à l'aide d'un modèle de transport réactif multiphasique | EP06291894.1 | 2006-12-07 | EP1795699A1 | 2007-06-13 | Michel, Anthony; Trenty, Laurent |
On découpe le milieu géologique en un ensemble de sous volumes pour lesquels on définit des liaisons. On définit ensuite un modèle de transport réactif multiphasique, en réalisant, selon un principe de taux de transfert, un découpage des phénomènes intervenant dans le comportement dudit milieu géologique en deux parties. Une première partie est traitée par un premier sous modèle de type « réservoir multiphasique compositionnel » permettant de déterminer les taux de transfert liés à la phase gazeuse. Une seconde partie est traitée par un modèle de type « transport réactif monophasique » permettant de déterminer les taux de transfert liés à l'eau et au solide. On initialise le modèle à l'aide de données acquises sur le terrain ou en laboratoire. On détermine, à partir du modèle de transport réactif, les capacités de stockage en gaz acides du milieu. Application au stockage de gaz acides dans un réservoir naturel.
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