子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | PLANT AND METHOD FOR MELTING METAL MATERIALS | EP15708317.1 | 2015-01-30 | EP3099991A2 | 2016-12-07 | VILLEMIN, Bernard; MORSUT, Stefano; CODUTTI, Andrea; GUASTINI, Fabio |
| Plant for melting metal materials comprising at least a heating unit (11) provided with a container (13) to contain the mainly metal materials and with at least an induction heating device (22) configured to heat the mainly metal materials contained in the container (13). The plant also comprises a transfer unit (25) disposed downstream of the heating unit (11) and configured to move, substantially continuously, the mainly metal solid materials exiting from the heating unit (11) to a melting furnace (12). The container (13) is provided with an aperture (16) through which the mainly metal material, heated and in a solid state, is discharged onto the transfer unit (25), and opening/closing members (17) are associated with the aperture (16), commanded by an actuator (19) and configured to open, close and choke the aperture (16) in order to regulate the delivery of the metal materials that is discharged onto the transfer unit (25). | ||||||
| 82 | CURING SYSTEMS FOR MATERIALS THAT CONSUME CARBON DIOXIDE | EP14774291 | 2014-03-13 | EP2969439A4 | 2016-04-27 | KUPPLER JOHN P; ATAKAN VAHIT; SMITH KENNETH; HU XUDONG |
| The invention provides a curing system that is useful for curing materials that consume carbon dioxide as a reagent. The system has a curing chamber that contains the material to be cured and a gas that contains carbon dioxide. The system includes apparatus that can deliver carbon dioxide to displace ambient air upon loading the system, that can provide carbon dioxide as it is needed and as it is consumed, that can control carbon dioxide concentration, temperature and humidity in the curing chamber during the curing cycle and that can record and display to a user the variables that occur during the curing process. A method of curing a material which requires CO2 as a curing reagent is also described. | ||||||
| 83 | UMSCHMELZOFEN MIT EINER WÄGEZELLE | EP15187982.2 | 2015-10-01 | EP3002534A1 | 2016-04-06 | Popov, Ivaylov; Oehler, Ralf; Nilius, Walter |
Bei einem Umschmelzofen muss das Gewicht einer Abschmelzelektrode laufend gemessen werden, um diese entsprechend ihres Abschmelzens nachstellen zu können. Dazu befindet sich auf einer Wägezelle (2) eine Plattform (3), auf der sowohl ein Elektrodenstangenantrieb (5) mit der Elektrodenstange (7) sowie ein Haltering (18) zum Halten des Hochstromkabels (13) angeordnet sind. Obwohl beim Absenken der die Abschmelzelektrode tragende Elektrodenstange (7) die Lage des Hochstromkabels (13) sich ändert, bleibt der gemessene Gewichtsanteil des Hochstromkabels (13) gleich, so dass mit der Wägezelle (2) letztendlich die Änderung des Gewichts der Abschmelzelektrode bestimmt werden kann.
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| 84 | WASTE MATERIAL MELTING FURNACE | EP13830075.1 | 2013-07-26 | EP2940386A1 | 2015-11-04 | KAJIYAMA Hirohisa; TODAKA Mitsumasa; MANAKO Kazutaka; NODA Kohichi; HIRAKURA Shoh |
A waste melting furnace (2) for drying, thermally decomposing, and melting waste comprises a cylindrical main part (20) extending vertically so as to form a space for containing the waste and guide the waste from upside to downside; a melt reservoir part (22), joined to a lower side of the main part along a center axis of the main part (20), for retaining melt generated from the waste; and a gas induction part (21), joined to an upper side of the main part (20) along the center axis of the main part (20), for collecting a gas generated from the waste and guiding the collected gas to an exhaust port (26). The main part (20) has a taper part (24) having an inner cross-sectional area gradually decreasing to the downside. The taper part (24) vertically occupies the largest height in all of parts constituting the main part (20). |
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| 85 | SYSTEM AND METHOD FOR THE CALCINATION OF MINERALS | EP07718671.6 | 2007-04-02 | EP2004319A1 | 2008-12-24 | HORLEY, Connor, James; SCEATS, Mark, Geoffrey |
| A system and method for the calcination of minerals. The system comprises a vertically disposed reactor segment configured to impart horizontal forces on particles passing through the reactor segment in a vertical direction; an injector unit for receiving granular feedstock, the injector unit being disposed at a top portion of the reactor segment, whereby granules of the feedstock move through the reactor segment in a granular flow under at least one of a group consisting of a force of steam, gravitational force and a centrifugal force; a reactor heat exchange unit thermally coupled to a wall of the reactor segment for providing heat to the flowing granules inside the reactor segment through heat transfer through the wall of the reactor segment; one or more inlets formed in the reactor segment for introducing a superheated gas into the reactor segment to create conditions of a gas-solid multiphase system; and one or more exhaust openings formed in the retort segment such that gas products are at least partially flushed from the reactor segment under the flow of the superheated gas from the inlets to the exhaust openings. | ||||||
| 86 | Anlage zur Herstellung von Ziegeln und/oder Dachpfannen | EP96104671.1 | 1996-03-25 | EP0735334B1 | 2001-12-12 | |
| 87 | DISPOSITIF DE TRAITEMENT ET DE VITRIFICATION DE DECHETS | EP94913653.5 | 1994-04-15 | EP0695280B1 | 1997-03-12 | LIAGRE, François; BOURDIL, Claude; BROCHOT, Jean-Marie; BOZETTO, Pierre; CABARDI, Jean; ENSUQUE, Alain |
| A device for processing waste, particularly hospital waste, comprising a gasification chamber (1) into which waste is fed so that it can be degassed and burnt, a post-combustion chamber (2) for burning gas from the gasification chamber, and a melting chamber (3) where the slag from the gasification chamber (1) is vitrified by exposure to a high temperature. | ||||||
| 88 | DEVICE FOR PROCESSING AND VITRIFYING WASTE | EP94913653.0 | 1994-04-15 | EP0695280A1 | 1996-02-07 | LIAGRE, François; BOURDIL, Claude; BROCHOT, Jean-Marie; BOZETTO, Pierre; CABARDI, Jean; ENSUQUE, Alain |
| A device for processing waste, particularly hospital waste, comprising a gasification chamber (1) into which waste is fed so that it can be degassed and burnt, a post-combustion chamber (2) for burning gas from the gasification chamber, and a melting chamber (3) where the slag from the gasification chamber (1) is vitrified by exposure to a high temperature. | ||||||
| 89 | WASTE MATERIAL MELTING FURNACE | EP13830075 | 2013-07-26 | EP2940386A4 | 2016-08-24 | KAJIYAMA HIROHISA; TODAKA MITSUMASA; MANAKO KAZUTAKA; NODA KOHICHI; HIRAKURA SHOH |
| A waste melting furnace (2) for drying, thermally decomposing, and melting waste comprises a cylindrical main part (20) extending vertically so as to form a space for containing the waste and guide the waste from upside to downside; a melt reservoir part (22), joined to a lower side of the main part along a center axis of the main part (20), for retaining melt generated from the waste; and a gas induction part (21), joined to an upper side of the main part (20) along the center axis of the main part (20), for collecting a gas generated from the waste and guiding the collected gas to an exhaust port (26). The main part (20) has a taper part (24) having an inner cross-sectional area gradually decreasing to the downside. The taper part (24) vertically occupies the largest height in all of parts constituting the main part (20). | ||||||
| 90 | SYSTEM AND METHOD FOR THE CALCINATION OF MINERALS | EP07718671.6 | 2007-04-02 | EP2004319B1 | 2015-06-10 | HORLEY, Connor, James; SCEATS, Mark, Geoffrey |
| 91 | VERFAHREN ZUM GESCHLOSSENZELLIGEN BLÄHEN VON MINERALISCHEM MATERIAL | EP12777880.1 | 2012-10-04 | EP2697181A1 | 2014-02-19 | BRUNNMAIR, Ernst Erwin |
| The invention relates to a method for producing an expanded granulate from sand grain-shaped material (1) using a propellant; the material (1) is fed into an upright furnace (2) and falls along a drop section (4) though multiple heating zones (5) in an furnace shaft (3) of the furnace (2), each said heating zone (5) being heatable using at least one independently controllable heating element (6); and the material (1) is heated to a critical temperature at which the surfaces (7) of the sand grains (15) plasticize and the sand grains are expanded on the basis of the propellant. According to the invention, if a first temperature drop of the material (1) is detected between two successive positions (9) along the drop section (4), the heating elements (6) along the remaining drop section (4) are regulated dependent on the critical temperature in order to adjust a closed surface of the expanded granulate in a controlled manner. | ||||||
| 92 | SYSTEM AND METHOD FOR THE CALCINATION OF MINERALS | EP07718671 | 2007-04-02 | EP2004319A4 | 2011-07-20 | HORLEY CONNOR JAMES; SCEATS MARK GEOFFREY |
| 93 | METHOD AND APPARATUS FOR CONTROLING TEMPERATURE UNIFORMITY OF THE BURDEN IN A DIRECT REDUCTION SHAFT FURNACE | EP02792357.2 | 2002-12-12 | EP1604373A1 | 2005-12-14 | METIUS, Gary, E.; MONTAGUE, Stephen, C.; BAILEY, Russell; KAKALEY, Russell; VOELKER, Brian, W. |
| A method and apparatus for increasing hydrocarbon input to a direct reduction shaft furnace (12) while controlling the temperature uniformity of the center portion (26) of the burden within the furnace (12) wherein the hydrocarbon gases used in the direct reduction may be preheated, which increases the temperature of the hydrocarbon gases, and therefore increases the resultant temperature of the upflowing gas as it rises from the lower section (66) of the furnace (12) into the center (26) of the burden. Alternatively, a portion of the upflowing gas may be removed before it enters the reduction zone of the furnace. The removed upflowing gas, known as hot bleed gas, may be ducted to the top gas scrubber (32) of the furnace or may be mixed with the main reducing gas stream of the furnace for reintroduction to the furnace. Alternatively, hot reducing gas may be directly injected into the center portion (26) of the burden, offsetting the cooling effect of the upflowing gas. The centrally injected hot reducing gas may be split off from the main reducing gas stream or may be generated by a partial oxidation reactor. | ||||||
| 94 | Schachtofen und Verfahren zum Einspeisen von Sauerstoff in einen derartigen Schachtofen | EP81104201.9 | 1981-06-02 | EP0043442B1 | 1986-12-03 | Hakenberg, Walther, Dipl.-Ing.; Seitz, Holger, Dr.-Ing.; Krüger, Benno, Ing. grad. |
| 95 | Verfahren zum Herstellen einer Gesteinsmaterialschmelze in einem Kupolofen | EP81100891.1 | 1981-02-09 | EP0034319B1 | 1983-08-10 | Jensen, Leif |
| 96 | 이산화탄소를 소비하는 물질에 대한 경화 시스템 및 이의 사용 방법 | KR1020157029506 | 2014-03-13 | KR101695746B1 | 2017-01-12 | 쿠플러,존,피.; 아타칸,바히트; 스미스,케네트; 후,수동 |
| 본발명은시약으로서이산화탄소를소비하는물질을경화시키기에유용한경화시스템을제공한다. 그러한시스템은이산화탄소를함유하는가스및 경화되는물질을함유하는챔버를지닌다. 그러한시스템은, 시스템을로딩시키면이산화탄소를전달하여주위공기를대체시킬수 있고, 필요에따라서그리고소비됨에따라서이산화탄소를공급할수 있고, 경화사이클동안에경화챔버내의이산화탄소농도, 온도및 습도를제어할수 있고, 경화공정동안에발생하는변수를기록하고사용자에게보여줄수 있는장치를포함한다. | ||||||
| 97 | Vertical type firing apparatus | KR20120025497 | 2012-03-13 | KR101173514B1 | 2012-08-14 | LEE SANG CHUL; CHOI JONG DAE |
| PURPOSE: A vertical firing device is provided to smooth quicklime cofiring process through raw material and fuel flying inlet, combustive air provider, and an external air gate blocking tool. CONSTITUTION: A vertical firing device comprises a main furnace(10), a feeder(20), a discharger(30) and a combustion air feeder(40). The Novon processes a quicklime cofiring process while accepting the limestone and coal. The feeder inputs the limestone and coal into inside the Novon. The discharger discharges the quicklime which is inside the Novon. The combustive air provider provides the combustive air to inside the Novon. The feeder comprises an outer tube, an inner shell and a feeding guide. The feeding guide comprises a fixing guide part, a rotation guide and a rotation angle control part. The discharger comprises an exhaust hopper(31), an evacuated chamber, a push part and a damper part. | ||||||
| 98 | 가공칩 재활용 장치 | KR1020070059278 | 2007-06-18 | KR100872659B1 | 2008-12-09 | 배철홍 |
| A processed chip recycling apparatus is provided to shorten the recycling process, and to reduce costs compared as regenerated ingots are procured and used. A processed chip recycling apparatus comprises: a collection room(20) which is connected to a processing apparatus through a pipeline(11), and on which a plurality of heating wires are mounted; a filter(12) mounted on a drain formed in a rear end portion of the pipeline; a moving unit(30) which has a screw(31) mounted on an inner part thereof, a plurality of injection nozzles(32) mounted on a front end portion thereof, and a plurality of heating wires installed therein, and which is connected to the collection room; a dust collecting unit(35) connected to the rear end portion of the moving unit; and a melting furnace(38) connected to the moving unit through a corrugated pipe. | ||||||
| 99 | HOT MELT ADHESIVE SUPPLY AND METHODS ASSOCIATED THEREWITH | EP16709851.6 | 2016-02-12 | EP3256263A2 | 2017-12-20 | VARGA, Leslie, J.; CHASTINE, Christopher, R.; CLARK, Justin, A.; ESTELLE, Peter, W.; EVAN, Howard, B.; GANZER, Charles, P.; GUERREO, Manuel, A.; RAMOSEVAC, Enes; RINEY, John, M.; SHIN, Sang, Hyub |
| A flexible bag system can dispense particulate hot melt adhesive. The flexible bag system includes an articulation device in contact with the flexible bag body and manipulates the flexible bag body to maintain fluidity of the particulate hot melt adhesive out of the outlet. A system for supplying particulate hot melt adhesive is also disclosed. The system includes an outer housing, a flexible inner housing disposed inside the outer housing that receives the particulate hot melt adhesive, a transfer opening disposed inside the flexible inner housing and through which the particulate hot melt adhesive is transferred, and an agitator in contact with the flexible inner housing, where the agitator applies a lateral force to a surface of the flexible inner housing. | ||||||
| 100 | PLANT AND METHOD FOR MELTING METAL MATERIALS | EP15708317.1 | 2015-01-30 | EP3099991B1 | 2017-12-13 | VILLEMIN, Bernard; MORSUT, Stefano; CODUTTI, Andrea; GUASTINI, Fabio |
| Plant for melting metal materials comprising at least a heating unit (11) provided with a container (13) to contain the mainly metal materials and with at least an induction heating device (22) configured to heat the mainly metal materials contained in the container (13). The plant also comprises a transfer unit (25) disposed downstream of the heating unit (11) and configured to move, substantially continuously, the mainly metal solid materials exiting from the heating unit (11) to a melting furnace (12). The container (13) is provided with an aperture (16) through which the mainly metal material, heated and in a solid state, is discharged onto the transfer unit (25), and opening/closing members (17) are associated with the aperture (16), commanded by an actuator (19) and configured to open, close and choke the aperture (16) in order to regulate the delivery of the metal materials that is discharged onto the transfer unit (25). | ||||||
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