Source: http://www.google.com/patents/US5022044?dq=7,603,356
Timestamp: 2016-05-06 14:07:53
Document Index: 337021262

Matched Legal Cases: ['art.\n3', 'art 6', 'art 6', 'art 6', 'art 6', 'art 8', 'art 6', 'art 8']

Patent US5022044 - Directly heatable crucible for induction melting furnaces - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inPatentsIn a directly heatable crucible 3 for induction melting furnaces, especially for melting refractory and highly-pure metals, including an inductor coil 11 surrounding a crucible 3 and a housing 5, which at least partially encloses the inductor coil 11 and the crucible 3 and which forms together with the...http://www.google.com/patents/US5022044?utm_source=gb-gplus-sharePatent US5022044 - Directly heatable crucible for induction melting furnacesAdvanced Patent SearchPublication numberUS5022044 APublication typeGrantApplication numberUS 07/391,125Publication dateJun 4, 1991Filing dateAug 9, 1989Priority dateFeb 16, 1989Fee statusLapsedAlso published asDE3904607A1Publication number07391125, 391125, US 5022044 A, US 5022044A, US-A-5022044, US5022044 A, US5022044AInventorsFriedrich-Werner ThomasOriginal AssigneeLeybold AktiengesellschaftExport CitationBiBTeX, EndNote, RefManPatent Citations (7), Referenced by (11), Classifications (16), Legal Events (4) External Links: USPTO, USPTO Assignment, EspacenetDirectly heatable crucible for induction melting furnaces
US 5022044 AAbstract
In a directly heatable crucible 3 for induction melting furnaces, especially for melting refractory and highly-pure metals, including an inductor coil 11 surrounding a crucible 3 and a housing 5, which at least partially encloses the inductor coil 11 and the crucible 3 and which forms together with the external wall 9, 9' of the crucible a closed chamber having an annular portion 10 and a flat cylindrical base portion 10'. This chamber is passed through by a cooling agent and the crucible 3 is made of the material to be molten.
1. An induction furnace for melting a material, comprisinga crucible made of the material to be melted, a housing surrounding said crucible so that said housing and said crucible form a closed cooling chamber between said housing and said crucible, said housing having inlet means and outlet means for passing coolant through said chamber, and an induction coil surrounding said crucible in said chamber. 2. An induction furnace as in claim 1 wherein said crucible is configured as a single pot-like piece having a circumferential wall and a bottom part.
3. An induction furnace as in claim 2 wherein said cooling chamber comprises an annular portion and a flat cylindrical base portion.
4. An induction furnace as in claim 2 wherein said housing is also pot-like and comprises a circular cylindrical part and a base plate, said crucible comprising flange means extending radially outward from said circumferential wall to support said crucible on said circular cylindrical part of said housing.
5. An induction furnace as in claim 1 further comprising a support frame which fixes said induction coil in said chamber, said support frame being fixed to said housing.
6. An induction furnace as in claim 1 wherein said crucible is made of a single pure alloy.
7. A method of induction melting a material without introducing impurities therein, comprisingproviding an induction melting furnace having a crucible made of a single pure material, a housing surrounding said crucible so that said housing and said crucible form a closed chamber having inlet means and outlet means for a coolant, and an induction coil surrounding said crucible in said chamber, passing a coolant through said closed chamber, and melting in said crucible a material of the same pure material as said crucible. Description
The invention relates to a directly heatable crucible for induction melting furnaces, particularly for melting refractory and highly-pure metals. An induction coil surrounds the crucible and a housing at least partially encloses the inductor coil and the crucible and forms a closed chamber together with the external wall of the crucible.
A process is known for melting refractory metals, particularly tantalum, tungsten, thorium or alloys of these metals in a water-cooled crucible (DE 518 499); the crucible is made of materials which have a lower melting point than the material to be molten, e.g. made of quartz glass, copper or silver. The energy required for the melting process as well as for the cooling of the crucible is supplied such that the material is completely molten without causing impurities by the crucible material.
Furthermore, a replaceable, pounded crucible is known for grooveless induction melting furnaces including a metallic, non-live, basket-like frame which surrounds the crucible or which is incorporated in the external wall thereof (CH 315 944). The frame is composed of water-cooled, flat or oval pipes made of a non-magnetic material.
Also known is an induction melting furnace including a replaceable crucible (U.S. Pat. No. 3,162,710) which has an insert made of refractory material and can be inserted into an external sleeve of sheet metal. This external sleeve is surrounded by an inductor coil which, at the same time, serves as a cooling element. The inductor coil, in turn, is supported by a rack which is configured as a hollow cylinder.
Further, a device for melting and casting titanium has been suggested (U.S. Pat. No. 3,383,840) wherein the crucible is a sleeve made of graphite which is surrounded by a pot-like jacket made of a relatively thin-walled ceramic material. The inductor coil which, in turn, encloses the graphite jacket is surrounded by a hood which rests on a base plate as does the crucible.
Finally, a device is known for melting reactive metals and metal alloys (EP 0 276 544), to which U.S. Pat. No. 4,738,713 corresponds wherein the crucible is made of stave-like metal rods which are provided with vertically running pocket holes in which end thin-walled pipes. These pipes are used to feed cooling water into the pocket holes. The metal rods which form narrow, vertically extending gaps between two adjacent rods are connected to one another as one piece via the base plate under which the feed lines are disposed for supplying the cooling agent to the thin-walled pipes.
These known induction melting furnaces have the particular disadvantage that a large portion of the electric energy which is necessary for the melting process is already lost in the crucible.
It is an object of the present invention to provide an induction melting furnace in which only a small portion of the electric energy necessary for the melting process is lost in the crucible, and which is suitable for obtaining a highly-pure melt.
The object is achieved in that a cooling agent passes through the chamber and in that the crucible is made of the material to be molten.
Preferably, the crucible is pot-like, of pure metal or a highly pure metal alloy and as one piece.
Advantageously, the housing which surrounds the external wall of the crucible forms together with the bottom part of the pot-like crucible an annular chamber portion and an approximately cylindrical, flat portion passed though by a cooling agent.
At its top circumferential rim, the approximately pot-like crucible advantageously has arms which radially extend toward the exterior or has a flange-like enlargement or an edge with which it rests or is supported on the top edge of the external housing; the housing itself is also pot-like, and the bottom part of the housing is supported spaced-apart from the bottom part of the crucible.
In order to ensure a cooling of the crucible and the inductor coil, the inductor coil is fixed in a certain distance to the crucible by means of a supporting frame which, in turn, is supported on the base plate and/or the housing flange and prevents the inductor coil from contacting the crucible or the housing.
The sole FIGURE is a diagrammatic cross-section.
The crucible 3 has a pot-like shape and is made of the metal which is also to be melted, for example, pure titanium in case a pure titanium charge is to be molten. The top, circumferential rim 4 of the crucible 3 is provided with a flange-like edge 5 with which the latter rests on the top edge or the flange 16 of the circular cylindrical housing part 6. The housing part 6, in turn, is supported on a base plate 7 and rigidly attached thereto, by means of welding, for example. The housing part 6 and the base plate 7 collectively form the housing. The height of the housing part 6 is selected such that the bottom part 8 of the crucible 3 is supported in a spaced-apart relationship to the base plate 7. The housing and the crucible form a closed chamber having an annular portion 10 between the part 6 and the circumferential wall 9 of the crucible, and a flat cylindrical base portion 10' between the bottom part 8 of the crucible and the base plate 7.
The inductor coil 11 is disposed in the annular portion 10 of the chamber 10, 10' where it is supported by a special support frame 12, 12'. As it is commonly known, the crucible assumes during the melting process the function of a short-circuited secondary coil when transferring the voltage according to the transformer principle.
While the material 13 is molten, a liquid coolant agent is continuously pumped from the inlet 14 via chamber 10, 10' to the outlet 15. 0n the one hand, the inductor coil 11 is thus cooled and, on the other hand, the wall of the crucible 3 is protected from overheating, and the mechanical stability of the crucible 3 is ensured. This can even be further supported by correspondingly selecting the operational frequency. Due to the overlapping of inductive heating and simultaneous intensive cooling a stable crucible wall thickness is created in the area of the crucible wall 3 during this process. In this area the temperature drops from the melting point in the interior of the cooled crucible 3 to the temperature of the cooled crucible wall. It is significant that the melt is not contaminated since the crucible itself is made of a highly-pure material or of the same alloy as the material to be molten. Depending on the material to be molten, the entire device can be operated under atmospheric conditions or, if correspondingly configured, in a vacuum.
Patent CitationsCited PatentFiling datePublication dateApplicantTitleUS1707294 *Feb 14, 1928Apr 2, 1929Westinghouse Electric & Mfg CoHeat-treating furnaceUS3162710 *Jul 24, 1962Dec 22, 1964Jay Anderson DonaldInduction furnace with removable crucibleUS3383840 *May 10, 1966May 21, 1968Cottrell Res IncDust collecting systemUS3935412 *May 22, 1974Jan 27, 1976Applied Materials, Inc.Induction heated vapor sourceUS4738713 *Dec 4, 1986Apr 19, 1988The Duriron Company, Inc.Method for induction melting reactive metals and alloysCH315944A * Title not availableDE518499C *Nov 2, 1926Feb 16, 1931Siemens AgVerfahren zum Schmelzen schwerschmelzbarer Metalle, insbesondere von Tantal, Wolfram, Thorium oder Legierungen dieser Metalle in einem wassergekuehlten Behaelter* Cited by examinerReferenced byCiting PatentFiling datePublication dateApplicantTitleUS5301299 *Feb 16, 1993Apr 5, 1994Intel CorporationOptimized write protocol for memory accesses utilizing row and column strobesUS6014403 *Jul 1, 1998Jan 11, 2000Cselt- Centro Studi E Laboratori Telecomunicazioni S.P.A.Induction furnaces for the synthesis of glassesUS6793894 *Jan 22, 2002Sep 21, 2004Japan Nuclear Cycle Development InstitutePyrochemical reprocessing method for spent nuclear fuel and induction heating system to be used in pyrochemical reprocessing methodUS7323032Jun 1, 2004Jan 29, 2008Japan Nuclear Cycle Development InstitutePyrochemical reprocessing method for spent nuclear fuelUS7323668 *Mar 15, 2005Jan 29, 2008Sgl Carbon AgWorkpiece carrier for the inductive heating of workpieces, process for producing a ceramic material for the workpiece carrier and process for the inductive heating or hardening of workpiecesUS20020192134 *Jan 22, 2002Dec 19, 2002Japan Nuclear Cycle Development InstitutePyrochemical reprocessing method for spent nuclear fuel and induction heating system to be used in pyrochemical reprocessing methodUS20050211702 *Mar 29, 2004Sep 29, 2005Dennis Tool CompanyCrucibles for a microwave sintering furnaceUS20050242089 *Mar 15, 2005Nov 3, 2005Sgl Carbon AgWorkpiece carrier for the inductive heating of workpieces, process for producing a ceramic material for the workpiece carrier and process for the inductive heating or hardening of workpiecesUS20070163386 *Jun 1, 2004Jul 19, 2007Japan Nuclear Cycle Development InstitutePyrochemical reprocessing method for spent nuclear fuelUS20070272156 *May 14, 2007Nov 29, 2007Semes Co., Ltd.Linear evaporator for manufacturing organic light emitting device using numerous cruciblesEP0894771A2 *Jul 28, 1998Feb 3, 1999CSELT Centro Studi e Laboratori Telecomunicazioni S.p.A.Improvements to induction furnaces for the synthesis of glasses* Cited by examinerClassifications U.S. Classification373/151, 219/649, 219/632, 373/156International ClassificationF27D9/00, F27B14/10, F27B14/06, H05B6/24Cooperative ClassificationF27B14/061, F27B14/10, F27D9/00, H05B6/24European ClassificationF27B14/10, F27B14/06D, F27D9/00, H05B6/24Legal EventsDateCodeEventDescriptionOct 24, 1989ASAssignmentOwner name: LEYBOLD AKTIENGESELLSCHAFT, GERMANYFree format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:THOMAS, FRIEDRICH-WERNER;REEL/FRAME:005174/0907Effective date: 19890609Jan 10, 1995REMIMaintenance fee reminder mailedJun 4, 1995LAPSLapse for failure to pay maintenance feesAug 15, 1995FPExpired due to failure to pay maintenance feeEffective date: 19950607RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services