| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | Electrostatic dust collector for use in vacuum system | EP89113192.2 | 1989-07-19 | EP0356684A3 | 1990-04-04 | Saeki, Hiroshi; Ikeda, Junji; Ishimaru, Hajime |
An electrostatic dust collector (K1, K2) including a wall (1) enclosing a vacuum chamber (C) in which a target face (9a) to be subjected to dust removal is provided, an electron beam emitting device (2) for emitting electron beams to dust (13) on the target face (9a) so as to charge the dust (13) negatively, a dielectric member (10) which is provided in the vacuum chamber (C) and has a collecting face (10a) confronting the target face (9a) and a member (11, 12) for imparting positive potential to the collecting face (10a) such that the dust (13) charged negatively is attracted to the collecting face (10a). |
||||||
| 102 | A vacuum chamber assembly for degassing particulate material | EP82306054.6 | 1982-11-12 | EP0079783A2 | 1983-05-25 | Rozmus, Walter J.; Rozmus, Walter J., Jr. |
A vacuum chamber assembly defined by a glass tube having metal end cap members and including a vacuum outlet midway the length of the tube with the assembly being symmetrical about the middle of the tube whereby the assembly may be turned end-for-end to pass particulate material bach and forth through the chamber. In each of two disclosed embodiments there is a funnel-shaped member within each metal cap member for receiving particulate material which flows through the metal cap member into the vacuum chamber. A glass tubular member is suspended in the vacuum chamber with the ends thereof disposed in spaced relationship to the small outlet openings of the respective funnel members for isolating the flow of particulate material from the vacuum chamber in the central portion thereof. There is a conical-shaped dispersing member associated with each funnel so that material exiting the upper funnel is dispersed outwardly in a circular curtain surrounding the small outlet opening of the lower funnel which is closed by its dispersing member so that particulate material flowing into the vacuum chamber into the uppermost funnel is dispersed outwardly and exits the lower end of the tubular member to pass over the exterior of the bottom funnel member to be dispersed thereover. The periphery of the large inlet opening of each funnel member is spaced from the end cap so that the particulate material dispersed over the lower funnel member will exit over the lip of the periphery thereof and out the adjacent end cap. An electric field-field producing means is positioned within the vacuum outlet to charge the gaseous contaminants and cause separation of the gaseous contaminants from that particulate material. A valve member is disposed in the flow passage in each end cap member for controlling the flow of particulate material into and out of the vacuum chamber. The assembly may also include members for grounding each end cap member. |
||||||
| 103 | An assembly and method for electrically degassing particulate material | EP82305989.4 | 1982-11-10 | EP0079756A2 | 1983-05-25 | Rozmus, Walter J. |
Gas-contaminated particulate material is passed through a vacuum chamber wherein it is subjected to an electric field to charge the gaseous contaminants to cause the gaseous contaminants to separate from the particulate material and enter a gas flow path through the vacuum outlet to the vacuum source. A series of electrical potentials are established in the vacuum outlet by a series of electrodes spaced from one another. Adjacent potentials or electrodes are of opposite polarity and the distance between adjacent potentials or electrodes decreases in the direction of the gas flow path out the vacuum outlet whereby the vacuum and the electrodes move the gases from the vacuum chamber. |
||||||
| 104 | SYSTEM AND METHOD FOR LOCKING A WEIGHT ASSEMBLY | PCT/US2020/045190 | 2020-08-06 | WO2021040995A1 | 2021-03-04 | AHMED, Muneeb; LUNNEMANN, Robert; MCCOY, James |
A lock assembly for a vibratory separator includes a latch. The latch includes a first inner protrusion and a first outer protrusion. The first outer protrusion defines a first outer protrusion opening. The lock assembly also includes a first spacer. The first spacer includes a first fastener that is configured to be inserted into the first outer protrusion opening. |
||||||
| 105 | GAS OIL SEPARATION PLANT SYSTEMS AND METHODS FOR RAG LAYER TREATMENT | PCT/US2019/012639 | 2019-01-08 | WO2019139880A1 | 2019-07-18 | SOLIMAN, Mohamed; ALANAZI, Khalid; SALU, Samusideen; AL-ZAHRANI, Talai |
Systems and methods for treating a rag layer in a gas oil separation plant. The method includes withdrawing the rag layer from a vessel proximate an oil water interface; conveying the rag layer to a separation device, the separation device operable to effect electrostatic coalescence on the rag layer to separate oil and water; and recycling separated oil from the separation device back to the gas oil separation plant process. |
||||||
| 106 | 실외용 미세먼지 제거장치, 제거방법 및 미세먼지 흡착 제어 시스템 | PCT/KR2018/005649 | 2018-05-17 | WO2018221877A1 | 2018-12-06 | 허일정; 장태선; 박지훈; 서정권; 김범식 |
본 발명은 통전성 하전망, 상기 하전망과 대향하며 미세먼지를 포집하는 포집체를 포함하는 집진부가 형성된 미세먼지 제거장치 및 이를 구동하기 위한 미세먼지 제어 시스템에 관한 것으로, 본 발명에 의한 미세먼지 제거장치 및 미세먼지 제어장치는 높은 효율로 대기중에 분포하는 미세먼지의 제거가 가능한 장점이 있다. |
||||||
| 107 | SYRUP PURIFICATION BY CAPACITIVE DEIONIZATION | PCT/US2014020564 | 2014-03-05 | WO2014138171A3 | 2014-11-06 | KETSMAN JOOST; VERCAUTEREN RONNY LEONTINA MARCEL |
| The invention relates to a process for purifying syrups. The process comprises removing charged components from the syrup by passing said syrup through a capacitive deionization cell. The present invention further relates to the use of capacitive deionization to recover charged components from syrups. In particular the syrups are mannose, fructose and sorbitol containing syrups. | ||||||
| 108 | METHOD FOR SORTING NANOOBJECTS AND AN APPARATUS FABRICATED THEREBY | PCT/RU2010000030 | 2010-01-27 | WO2010090552A3 | 2010-10-07 | BUTKO VLADIMIR YURYEVICH |
| A method for sorting nanoobjects from the mixture comprising nanoobjects such as semiconducting and metallic carbon nanotubes and an apparatus fabricated thereby. An embodiment comprises an energy transfer to the mixture in a way that the degree in which nanoonobjects are heated and bonded to the surface of a substance depends on their electrical conductivities. The next embodiment comprises an electrolytic deposition of a material on the mixture in a way that the degree in which nanoanobjects are bonded to the surface of the substance by the deposited layer depends on their electrical conductivities. The above nanoobjects are sorted by selectively separating mostly the weaker bonded nanoobjects from the surface. Another embodiment comprises an energy transfer in a low pressure reactive gas medium to the mixture in a way that the degree in which nanoonobjects are heated and chemically modified depends on their conductivities. | ||||||
| 109 | LOW-MAGNETIC MATERIAL SEPARATION METHOD ASSOCIATED WITH A MAGNETIC PRODUCT ELECTRICAL REMOVAL AND A DEVICE FOR CARRYING OUT SAID METHOD | PCT/UA2005000026 | 2005-06-13 | WO2006112803A8 | 2007-04-19 | TURKENICH ALEXANDR MIHAILOVICH |
| The invention can be used for processing low-magnetic materials according to magnetic properties thereof, in particular in the mining industry. The aim of said invention is to remove magnetic grains from a magnetic roller in which a magnetic field is formed along the entire circumference of the surface thereof. The inventive method for a dry magnetic separation of low-magnetic materials consists in supplying a processable material to the magnetic roller rotatable about a horizontal axis, in holding said magnetic grains on the roller by the magnetic force action, in removing the non-magnetic grains towards a non-magnetic product by means of a gravitation force action, in taking out the magnetic grains beyond the non-magnetic grain removal area during the roller rotation, in forming an electric field which is located outside of the non-magnetic grain discharge area between the magnetic roller and a non-magnetic electrode and whose intensity is such that the electrical force removing the magnetic grains from the roller surface is greater than the magnetic force pressing said grains thereto in order to transfer the magnetic grains removed from the magnetic roller by said electrical force to the magnetic product. | ||||||
| 110 | CARBON DIOXIDE TREATMENT SYSTEM AND CARBON DIOXIDE TREATMENT METHOD | PCT/JP2022025300 | 2022-06-24 | WO2023282089A1 | 2023-01-12 | MIYAZAKI HIDETAKA |
| Provided are a system and a method for treating carbon dioxide that make it possible to continuously decompose CO2 using as simple a configuration as possible. The system comprises: a carbon dioxide decomposition unit for taking in a carbon-dioxide-containing fluid and ionizing the carbon dioxide into positively charged carbon atoms and negatively charged oxygen atoms through contact with atmospheric-pressure low-temperature plasma; and a separation unit located downstream of the carbon dioxide decomposition unit along the flow direction of a fluid including the ionized carbon atoms and oxygen atoms, the separation unit being equipped with an upstream electrode positioned upstream of the flow and a downstream electrode positioned downstream of the flow and being configured such that the upstream electrode and the downstream electrode alternately have a positive potential and a negative potential, and the separation unit decelerating the positively charged carbon atoms using the electrode having the positive potential among the upstream electrode and the downstream electrode and collecting the carbon atoms as solid carbon using a collection means provided near the upstream electrode and the downstream electrode. | ||||||
| 111 | DISPOSITIF DE DÉPOUSSIÉRAGE D'OBTURATEURS PAR IONISATION | PCT/FR2021/050054 | 2021-01-13 | WO2021144532A1 | 2021-07-22 | STAELENS, Laurent |
Dispositif de dépoussiérage d'obturateurs (5) aptes à circuler dans une goulotte (4) s'étendant selon un axe longitudinal (y-y'), comprenant des moyens d'aspiration disposés autour de la goulotte (4) et aptes à aspirer les poussières dissociées des obturateurs, caractérisé en ce qu'il comprend au moins une barre d'ionisation (51, 52) s'étendant longitudinalement autour de la goulotte (4). |
||||||
| 112 | CATEGORY SPECIFIC INDUSTRIAL BATTERY OPTIMIZATION AND RESTORATION DEVICE, WITH BATTERY DIAGNOSTICS, BATTERY LIFE PROGNOSTICATION, AND AN ARTIFICIAL INTELLIGENCE MEANS | PCT/US2019/037193 | 2019-06-14 | WO2019245901A1 | 2019-12-26 | ZEIER, Bruce, Eric |
Improvements in a battery optimization and restoration device that uses a means of varying the regulator voltage as a function of time and discharge event timing and depth in order to establish a consistent power level for the charging of the capacitor. The device models the power supply regulation voltage as a first order factor as a function of time. The regulation voltage is modeled as a function of time so as to maintain an acceptable charging current at all times by charging a large capacitive load which is periodically discharged in a rapid pulse-like manner requires a modeled regulation voltage that is synchronized to the discharge frequency of the capacitor. The modeled charging is a function of the discharge depth and the charging height in initial capacitor voltage before the discharge and the final capacitor voltage after the discharge. |
||||||
| 113 | ENERGY STORAGE, HYDROGEN AND OXYGEN PRODUCTION USING ION SEPARATORS | PCT/US2018/043209 | 2018-07-22 | WO2019023085A3 | 2019-01-31 | ABLEDU, Kodzo Obed |
An ion separating device comprising a stator cylinder with input and output ports, end caps, a rotor core, homopolar north poles, and homopolar south poles, is used to separate positive and negative ions in electrolyte introduced into the device. The resulting charged ionic solutions are stored in separate tanks. Energy recovery from the charged ionic solutions is accompanied by the release of gases thereby providing another process of producing hydrogen and oxygen. |
||||||
| 114 | ENERGY STORAGE, HYDROGEN AND OXYGEN PRODUCTION USING ION SEPARATORS | PCT/US2018/043209 | 2018-07-22 | WO2019023085A2 | 2019-01-31 | ABLEDU, Kodzo Obed |
An ion separating device comprising a stator cylinder with input and output ports, end caps, a rotor core, homopolar north poles, and homopolar south poles, is used to separate positive and negative ions in electrolyte introduced into the device. The resulting charged ionic solutions are stored in separate tanks. Energy recovery from the charged ionic solutions is accompanied by the release of gases thereby providing another process of producing hydrogen and oxygen. |
||||||
| 115 | METHOD AND SYSTEM FOR REMOVING CONTAMINANTS FROM A FLUID | PCT/US2009/041608 | 2009-04-24 | WO2009140040A1 | 2009-11-19 | PRUET, Randall Boyd |
A method and system for removing contaminants from a fluid are provided. The method can generally include providing microstructures in the fluid. At least some of the contaminants in the fluid are attracted to the microstructures and adhered to the microstructures. With the contaminants attached to the microstructures, the microstructures can be separated from the fluid so that the contaminants are thereby removed from the fluid. |
||||||
| 116 | СПОСОБ СУХОЙ МАГНИТНОЙ СЕПАРАЦИИ СЛАБОМАГНИТНЫХ МАТЕРИАЛОВ С ЭЛЕКТРИЧЕСКИМ СЪЕМОМ МАГНИТНОГО ПРОДУКТА И УСТРОЙСТВО ДЛЯ ЕГО ОСУЩЕСТВЛЕНИЯ | PCT/UA2005/000026 | 2005-06-13 | WO2006112803A1 | 2006-10-26 | ТУРКЕНИЧ Александр Михайлович |
Использование: при обогащении слабомагнитных материалов по магнитным свойствам, в частности, в горнорудной промышленности. Техническая задача: съем магнитных зерен с магнитного ролика, в котором магнитное поле создается по всей длине окружности его поверхности. Сущность изобретения: способ сухой магнитной сепарации слабомагнитных материалов включает подачу обогащаемого материала на магнитный ролик, вращающийся вокруг горизонтальной оси, удержание магнитных зерен на ролике под действием магнитной силы, удаление немагнитных зерен под действием силы тяжести в немагнитный продукт, вывод магнитных зерен при вращении магнитного ролика за пределы зоны удаления немагнитных зерен, создание за пределами зоны разгрузки немагнитных зерен между магнитным роликом и немагнитным электродом электрического поля с напряженностью, при которой электрическая сила, отрывающая магнитные зерна от поверхности ролика, больше магнитной силы, прижимающей эти зерна к поверхности ролика, удаление магнитных зерен, оторванных от магнитного ролика с помощью электрической силы, в магнитный продукт. |
||||||
| 117 | APPARATUS AND PROCESS FOR MEASURING CHARACTERISTICS OF PARTICLE FLOW | EP16861673.8 | 2016-11-02 | EP3371582B1 | 2025-05-14 | JANKA, Kauko; SAUKKO, Erkka |
| 118 | GAS OIL SEPARATION PLANT SYSTEMS AND METHODS FOR RAG LAYER TREATMENT | EP19705424.0 | 2019-01-08 | EP3737733A1 | 2020-11-18 | SOLIMAN, Mohamed; ALANAZI, Khalid; SALU, Samusideen; AL-ZAHRANI, Talai |
| 119 | APPARATUS AND PROCESS FOR MEASURING CHARACTERISTICS OF PARTICLE FLOW | EP16861673.8 | 2016-11-02 | EP3371582A4 | 2020-02-12 | JANKA, Kauko; SAUKKO, Erkka |
| The present invention relates to an apparatus (1) and process for measuring characteristics of a particle flow. The measuring is done with two different cut-off diameters of a particle trap (13) of which one cut-off diameter is adjusted based on the measured particle characteristics. | ||||||
| 120 | ELECTROSTATIC COALESCER WITH RESONANCE TRACKING CIRCUIT | EP09748677.3 | 2009-11-05 | EP2346613B1 | 2019-03-20 | AKDIM, Mohamed, Reda; KRUIJTZER, Govert, L.; ANTSIFEROV, Pavel |
