| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 一种全自动尾矿绒毯回收装置 | CN201610452248.0 | 2016-06-22 | CN105921254A | 2016-09-07 | 张秋才; 左小兵; 罗斌林 |
| 一种全自动尾矿绒毯回收装置,其中,尾矿槽与收矿部分之间并排安装有多个绒毯槽,且每个绒毯槽安装时分别设置有坡度,收矿部分包括废液槽、精矿槽及接矿转换机构,接矿转换机构设置在废液槽与精矿槽交接处;同时在绒毯槽两侧分别安装有用于自动冲水跑车行走的行走轨道,并在行走轨道上安装有始端行程开关和终端行程开关;给料控制机构安装在绒毯槽与尾矿槽交接处,自动冲水跑车上安装有行走车轮和用于与供水软管连接的自动冲水机构;此外,给料控制机构、始端行程开关、终端行程开关、接矿转换机构及自动冲水机构分别与控制器连接以实现自动联锁;可实现全程自动化作业,生产效率高,有效降低了人工劳动强度,安装方便,维护简单,适应范围广。 | ||||||
| 2 | 原材料的热像块状物分离法(变量)及其实现装置(变量) | CN200480028755.7 | 2004-06-03 | CN1863603A | 2006-11-15 | V·M·沃洛世恩; V·Yu·祖布科维奇 |
| 本发明涉及用于原料的块状物分离的方法和设备,并能用于分离含铁和非铁金属矿石、矿物和化学原料的提炼、加工二次原料和工业废料。本发明的方法和设备基于:块状物包含有用组分和废物,且将这样的块状物暴露于超高频率(UHF)电磁场。该选择的频率使得电磁波穿透深度将超过块状物在电磁波最大衰减条件下时块状物的最大线性尺寸,该电磁波衰减取决于这种块状物的性质。被块状物吸收的UHF电磁辐射的能量引起块状物组分的加热。在同样时段里,具有较高导电性的组分将会比具有较低导电性的组分吸收更多UHF。结果,离开UHF场后,有价值的成分和废物将会加热到不同温度。块状物温度廓线将取决于在该块状物中具有不同性质的组分的质量比,且该温度廓线通过热像系统记录。本发明可以在同等的条件和载荷下增加有价值的成分的含量从6%-10%至18%-25%,使有用组分的重量%增加至4.5%而降低其在废弃物中的含量至3%时,并由于提炼原料中废物含量的减少而使整体能量消耗降低5%。 | ||||||
| 3 | Separation of resin by electric conductivity measurement | JP9438284 | 1984-05-11 | JPS6034745A | 1985-02-22 | IIRAI SAREMU |
| 4 | 混合物の分離方法及び分離装置 | JP2013549263 | 2012-12-11 | JPWO2013089080A1 | 2015-04-27 | 茂宏 西嶋; 史人 三島; 海磯 孝二; 孝二 海磯; 敏弘 島川 |
| 複数種類の流体を含む混合物を、粒子の種類に応じた密度と粒径の差が小さい場合でも、向流分級の手法を用いて分離できる混合物の分離方法及び分離装置を提供する。本発明では、逆錐状又は略逆錘状に構成された分離管13を用いて、第1粒子と第2粒子を含む混合物が分離される。第1粒子を形成する物質の磁化率と、第2粒子を形成する物質の磁化率は異なっている。流体が分離管13に上向きに流されて、この流体の流れを用いて混合物が分離管13内に導入される。第1粒子及び第2粒子は、混在した状態で分離管13内に保持される。分離管13内に第1粒子と第2粒子を保持した状態で、磁場生成手段23を用いて、分離管13内の領域に勾配磁場が印加される。勾配磁場の磁場勾配は鉛直方向成分を有する。 | ||||||
| 5 | 混合物の分離方法及び分離装置 | JP2013549263 | 2012-12-11 | JP5704618B2 | 2015-04-22 | 西嶋 茂宏; 三島 史人; 海磯 孝二; 島川 敏弘 |
| 6 | HYDRODYNAMISCHE SCHWERSTOFFABTRENNUNG EINER AUFSCHLÄMMUNG | EP16728658.2 | 2016-06-03 | EP3137220A1 | 2017-03-08 | CARRA, Roland; FLUCK, Patrick; ZIEGLER, Tobias |
| The invention relates to a device and to a method for the hydrodynamic removal of dense materials from a suspension, said device comprising a hydrocyclone (1), which holds the suspension, a classifying tube (2), which adjoins the hydrocyclone, and a storage chamber (3), which holds the removed dense materials, wherein a flushing water flow to the classifying tube (2) and a flushing water flow to the storage chamber (3) are provided, which can be controlled in a closed-loop or open-loop manner by means of a control element provided at the feed to the classifying tube and a control element provided at the feed to the storage chamber, respectively. | ||||||
| 7 | METHOD FOR THERMOGRAPHIC LUMP SEPARATION OF RAW MATERIAL | EP04775703.4 | 2004-06-03 | EP1666151B1 | 2010-10-27 | VOLOSHYN, Volodymyr Mykhailovich; ZUBKEVYCH, Viktor Yuriiovych |
| The interrelated group of inventions relates to methods and devices for raw material lump separation and can be used for dressing ferrous and non-ferrous metal ores, mining chemical feedstock, secondary raw material and technogenic waste. The essence of the inventive method and device lies in that a useful component containing lump and a barren rock is irradiated by an ultrahigh frequency electromagnetic field (UHF). Said radiation frequency is selected in such a way that the electromagnetic wave penetration depth dependent of lump material properties is greater than the lump maximum linear dimension at the peak attenuation of the electromagnetic wave. UHF electromagnetic radiation energy absorbed by the lump material initiates the heating of the components thereof, wherein the component exhibiting a greater electrical conductivity absorbs the greater amount of UHF energy than the component exhibiting a lower electric conductivity during the same time, whereby the heating temperatures of the useful component and the barren stock measured after irradiation are different. The temperature law depends on the mass ratio of the lump components exhibiting different properties and is recorded by a thermographic system. Said invention makes it possible, under the same conditions, to increase the useful component content from 6-10 % to 18-25 %, the increment of the useful component mass ratio by 4.5 %, to reduce the useful component tailing up to 3 % and the energy consumption by 5 % by decreasing the raw material dilution during the processing thereof. | ||||||
| 8 | スラリからの高密度材料の流体力学的除去 | JP2018504951 | 2016-06-03 | JP2018526199A | 2018-09-13 | ローランド カーラ; パトリック フラック; トビアス ジーグラー |
| 【課題】懸濁液から高密度材料を流体力学的に除去するための装置および方法を提供する。 【解決手段】前記装置は、懸濁液を受け入れる液体サイクロン(1)と、液体サイクロンに付けられる分級管(2)と、除去された高密度材料を受け入れる貯留室(3)と、を備える。分級管(2)への洗浄水流と貯留室(3)への洗浄水流とが形成され、それぞれ、分級管への給送口に設けられた制御素子と貯留室への給送口に設けられた制御素子とにより、閉ループ式にあるいは開ループ式に制御され得る。 【選択図】図3 |
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| 9 | Method of separating anion and cation resin in mixed resin bed by utilizing conductivity | JP14064680 | 1980-10-09 | JPS5660649A | 1981-05-25 | REONARUDO JIYOSEFU REFUEBAA; TETSUO SATOU |
| 10 | JPS55500352A - | JP50067279 | 1979-04-16 | JPS55500352A | 1980-06-19 | |
| 11 | Mineral processing | US14792433 | 2015-07-06 | US09708688B2 | 2017-07-18 | Albert Lovshin |
| Methods and systems for processing ores by assaying the ore to determine what ore constituent has to be separated, by controlling the volume of ore processed at one time, and/or by controlling the amount of heat added to or extracted from the ore. | ||||||
| 12 | Method and apparatus for separation of mixture | US14364154 | 2012-12-11 | US09370782B2 | 2016-06-21 | Shigehiro Nishijima; Fumihito Mishima; Koji Kaiso; Toshihiro Shimakawa |
| The present invention provides a method and an apparatus for separating a mixture that are capable of separating a mixture containing a plurality types of particles, using a countercurrent classification technique, even when there is little difference in density and particle diameter depending on the types of particles. In the present invention, a mixture containing first particles and second particles is separated using a separation tube 13 having the inverted-conical or pyramidal shape or a substantially inverted-conical or pyramidal shape. The first particles and the second particles are made of substances having different magnetic susceptibilities. A fluid is caused to flow upward through the separation tube 13, and the flow of the fluid is used to introduce the mixture into the separation tube 13. The first particles and the second particles are held in the separation tube 13 in a mixed state. A gradient magnetic field is applied to a region inside the separation tube 13 using magnetic field generation means 23, in the state where the first particles and the second particles are held in the separation tube 13. The magnetic field gradient of the gradient magnetic field has a vertical component. | ||||||
| 13 | MINERAL PROCESSING | US14792433 | 2015-07-06 | US20150307954A1 | 2015-10-29 | Albert Lovshin |
| Methods and systems for processing ores by assaying the ore to determine what ore constituent has to be separated, by controlling the volume of ore processed at one time, and/or by controlling the amount of heat added to or extracted from the ore. | ||||||
| 14 | METHOD AND APPARATUS FOR SEPARATION OF MIXTURE | US14364154 | 2012-12-11 | US20140332449A1 | 2014-11-13 | Shigehiro Nishijima; Fumihito Mishima; Koji Kaiso; Toshihiro Shimakawa |
| The present invention provides a method and an apparatus for separating a mixture that are capable of separating a mixture containing a plurality types of particles, using a countercurrent classification technique, even when there is little difference in density and particle diameter depending on the types of particles. In the present invention, a mixture containing first particles and second particles is separated using a separation tube 13 having the inverted-conical or pyramidal shape or a substantially inverted-conical or pyramidal shape. The first particles and the second particles are made of substances having different magnetic susceptibilities. A fluid is caused to flow upward through the separation tube 13, and the flow of the fluid is used to introduce the mixture into the separation tube 13. The first particles and the second particles are held in the separation tube 13 in a mixed state. A gradient magnetic field is applied to a region inside the separation tube 13 using magnetic field generation means 23, in the state where the first particles and the second particles are held in the separation tube 13. The magnetic field gradient of the gradient magnetic field has a vertical component. | ||||||
| 15 | Method for thermographic lump separation of raw material (variants) and device for carrying out said method (variants) | US10561891 | 2004-06-03 | US20060175232A1 | 2006-08-10 | Volodymur Voloshyn; Viktor Zubkevych |
| The present interdependent group of inventions pertains to methods of and devices for lump separation of raw material and may be used in ferrous and non-ferrous metal ore dressing, concentration of mining and chemical raw materials, processing secondary raw materials and technological wastes. The method and the device are based on the idea that a lump comprises a useful component and refuse, and such lump is exposed to ultrahigh frequency (UHF) electromagnetic field. The frequency selected is such that electromagnetic wave penetration depth will exceed the maximum linear size of a lump under conditions of maximum damping of electromagnetic wave, which depends upon characteristics of such lump material. The energy of UHF electromagnetic radiation absorbed by a lump material causes heating of the lump components. A component with higher electric conductivity will absorb UHF energy higher than UHF energy absorbed by a component with lower electric conductivity during the same period of time. As a result, after removing the UHF field the useful component and the refuse will be heated to different temperatures. A lump temperature profile will depend on mass ratio of components with different properties within such lump, and said temperature profile is registered by a thermographic system. The invention implementation will make possible to increase the useful component content from 6˜10% to 18˜25% under conditions and loads unchanged, increase weight % of the useful component to 4.5% while decreasing its content in tails to 3%, decrease the total electric energy consumption by 5% due to decrease of refuse content in the raw material being concentrated. | ||||||
| 16 | Method controlling a process by impedance analysis | US351647 | 1989-06-06 | US5108495A | 1992-04-28 | Seppo O. Heimala; Kaarlo M. J. Saari |
| The invention relates to a method for controlling a process operating by means of the electrochemical potential, in which process complex ores and/or concentrates are treated in order to arrange the valuable components in the materials in a form appropriate for further processing and in which method electrodes made of material essentially similar to the materials to be treated in the process. According to the invention an impedance analysis in connection with the measurement of the electrochemical potential is carried out for the material to be treated in process in order to analyze the state of the solid surface and/or the state between the solid material and the intermediary material. The measured values are utilized in the adjustment of the process parameters. In order to carry out the impedance analysis voltage pulses are conducted into the material in at least one frequency and in at least one value of the electrochemical potential of the material. | ||||||
| 17 | Process for separating oil shale waste material | US36637 | 1979-05-07 | US4326950A | 1982-04-27 | Brij M. Moudgil; David F. Messenger |
| A method is disclosed for the separation of oil shale from run of mine (ROM) oil shale containing particles of oil shale and refuse, which comprises conditioning the ROM oil shale with a coupling agent capable of selectively coating the kerogen hydrocarbons in the particulate oil shale to the substantial exclusion of coating the non-hydrocarbonaceous refuse, which coupling agent is one or more compounds selected from the group consisting of an alcohol, at least one carboxylic acid, preferably containing from about 5 to about 28 carbon atoms and a ketone. Combined with said coupling agent is a fluorescent dye in a quantity to make the coated particles of oil shale fluoresce upon excitation to a degree sufficient to distinguish the coated oil shale particles from the substantially non-coated refuse. Exciting (e.g. as with ultraviolet light) the fluorescent dye coupled to the oil shale particles induces fluorescence and enables separating the fluorescing, coated oil shale particles from substantially non-fluorescing, non-coated refuse particles. | ||||||
| 18 | Separation of anion and cation exchange resins in a mixed resin bed | US83150 | 1979-10-09 | US4264439A | 1981-04-28 | Leonard J. Lefevre; Tetsuo Sato |
| A mixture of anion and cation exchange resins is separated into their respective resin types by classifying the resin mixture, using a fluid such as water, in the presence of a solid, inert material (e.g., copolymer beads of styrene, divinylbenzene and methyl methacrylate) which, upon classification, forms a layer intermediate between the layers of the anion and cation resins. The degree of resin separation and the location of the layers of the classified anion resin and cation resin are determined by measuring a conductivity property of the resulting classified resin bed. | ||||||
| 19 | Mineral processing | US14792403 | 2015-07-06 | US09708687B2 | 2017-07-18 | Albert Lovshin |
| Methods and systems for processing ores by assaying the ore to determine what ore constituent has to be separated, by controlling the volume of ore processed at one time, and/or by controlling the amount of heat added to or extracted from the ore. | ||||||
| 20 | BEACH DETECTION SENSORS FOR VIBRATORY SEPARATOR | US14317903 | 2014-06-27 | US20150377020A1 | 2015-12-31 | Ed Kronenberger; Kasi Amaravadi |
| An apparatus including a screen capable of separating solids from a liquid-solid mixture and a first probe disposed beneath the screen. The first probe is provided to determine a position of a beach between the liquid-solid mixture and separated solids. The apparatus may measure a property of a local volume of a probe disposed beneath a first separator deck. The probe may then send a first signal to database. Based on the signal a location of a beach may be determined. | ||||||
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