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Publication numberUS3086856 A
Publication typeGrant
Publication dateApr 23, 1963
Filing dateFeb 10, 1954
Priority dateFeb 14, 1953
Also published asDE1061527B, DE1210415B, US2876147, US3030194, US3216805, US3234012
Publication numberUS 3086856 A, US 3086856A, US-A-3086856, US3086856 A, US3086856A
InventorsSiebertz Karl
Original AssigneeSiemens Ag
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Method and device for the successive zone melting and resolidifying of extremely pure substances
US 3086856 A
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Description  (OCR text may contain errors)

Apnl 23, 1963 K. SIEBERTZ 3,086,856

METHOD AND DEVICE FOR THE SUCCESSIVE ZONE MELTING AND RESOLIDIFYING OF EXTREMELY PURE SUBSTANCES Filed Feb. 10, 1954 FIG.4

FIG.I

FIG.3

United States Patent 3,086,856 METHQD AND DEVlCE FGR THE SUCCESSKVE ZONE MEL'HNG AND RESULIDIFYING 0F EX- TREMELY PURE SUBSTANQES Karl Siebertz, Munich, Germany, assignor to Siemens & li-lalske Aktiengesellschaft, Berlin and Munich, Germany, a German corporation Filed Feb. 10, 1954, Ser. No. 469,420 Qlaims priority, application Germany Feb. 14, 1953 6 (Ilaims. (Cl. 75-10) -It is known to liberate last traces of impurities from generally pure materials by successively melting a zone of an elongated body or rod of the material in such a manner that the molten zone travels gradually from one end of the body to the other. Due to the concentration jump of the dissolved impurities in the border surface between the liquid and solid portions of the rod, the molten zone becomes enriched in impurities while a depletion occurs in the resolidifying material, or vice versa. Due to the fact that the melting zone is gradually displaced from one to the other end of the rod, the impurities also migrate toward one of these ends. If necessary, the process can be repeated for obtaining maximum degrees of purity. At the same time, the process may serve to produce a single crystal from an originally amorphous or polycrystalline material, which may be sintered or otherwise produced. This requires placing into the melting zone, at the point where it commences its travel along the body, a single crystal of the proper orientation to serve as a crystal germ.

The zone-melting process as heretofore known requires placing the material to be melted into a crucible or boat of refractory material. The results of the process, therefore, are affected by the fact that the material being processed can take up new impurities from the surface of the crucible walls.

It is an object of my invention to avoid this deficiency and to improve the zone-melting method toward achieving a higher degree of purity of the material being treated and toward a reduction in the processing time needed for securing a given degree of purity.

To this end, and in accordance with a feature of my invention, the body to be successively zone melted is mechanically supported at only a few places so that the melting zones are only in the slightest degree, if at all, in contact with the means holding or containing the body. To prevent the molten material from running off due to its gravity, the melting zone is kept so narrow that the surface tension suffices for retaining it between the adjacent solid parts of the material. To achieve this result, and according to another feature of my invention, the elongated and preferably rod-shaped body is arranged vertically, in contrast to the horizontal arrangement heretofore customary.

According to another feature of my invention, the running-off of the molten material is prevented by continuously revolving the body during the zone-melting operation.

According to still another feature of the invention, the body may be given a horizontal or inclined arrangement and is heated only from above so that the melting zone does not extend through the entire diameter of the rod but forms only a molten segment or cone-shaped zone comprising only about the upper half of the rod, while the lower part of the rod remains solid and carries the melting zone.

According to a further feature of the invention, the liquid material in the melting zone, which in this case may traverse the entire cross section of the rod, is kept freely floating by electromagnetic or pneumatic means. To this end, an electric field may be produced which, at

ice

the place of the melting zone, produces potential surfaces of a corresponding shape, for instance saddle shape, to

magnetically support the material, the material being electrically conductive at least when in its molten condition. The same effect can be obtained by the coaction of correspondingly arranged streams of gas. The gas to be used for this purpose is the same protective or inert gas that forms the atmosphere within which the entire zone-melting operation is to be performed.

The foregoing and other features of the invention will be more fully understood from the following description of the embodiments of devices according to the invention illustrated on the drawing, in which- FIG. 1 illustrates an arrangement for heat-treating a vertically held elongated body of material according to the invention wherein the melted zone is prevented from running off by means of a plurality of inclined blowers;

FIG. 2 illustrates an alternative method of practicing the invention wherein the material being treated is horizontally or slantingly disposed;

FIG. 3 is a transverse cross-sectional view of FIG. 2

taken through the melted zone; and

FIG. 4 shows an apparatus for performing the method according to the invention with an arrangement as shown in PEG. 1.

According to FIG. 1, a rod 1, of aluminum for example, to be processed is held in vertical position by clamping devices 2 and 3 engaging the two ends of the rod. A directly or indirectly heated ring 4 of small axial width in comparison with the length of the rod 1 surrounds a zone 5 of the rod in concentric relation thereto. The whole device is located in a vacuum or within a protective inert gaseous medium. A number of nozzles 6 are distributed around the rod below the heater 4. Their blowing direction is such that the melting zone 5 is impinged on all sides from below so that the molten material cannot drop off. The gas supplied to the nozzle 6 is preheated by a heating device (not shown) to prevent marginal cooling of the melting zone. The clamps 2 and 3 together with the rod 1 are displaceable in the direction of the arrow 7 relative to the stationarily mounted heating and blowing devices 4, 6. The mechanism for moving the holders together with the rod may comprise a motor driven worm screw, a guide device for allowing simultaneous translatory motion of the two holders, and gear mechanism carried by the holders and in meshing engagement with the worm screw. During the operation, therefore, the melting zone 5 travels from the bottom upwardly along the rod.

In the embodiment shown in FIGS. 2 and 3, the rod 1 of the material to be purified is arranged horizontally. An arc lamp 8 serves as a source of heat. is concentrated upon the surface of rod 1 by means of a hollow mirror 9 and produces a trough or cone-shaped melting zone 10. This melting zone is carried by the underlying solid portion of the rod. A blowing device 11 directs a cooling stream of protective gas against the bottom side of rod 1 to prevent the melting zone from breaking through the solid area. The rod 1 is continuously kept in revolution in the direction of the arrow 12 by means of a motor (not illustrated) adapted to turn a holding device at one end of the rod being processed.

In addition, the radiation source 8, 9 is displaced relative and cooling means in relation to a cross section of rod' Its radiation 1 through the melting zone 10. As apparent from FIG. 3, the heat source 8, 9 is given a somewhat slanting arrangement while the cooling effect of the nozzle arrangement 11 extends over a larger peripheral range of the rod and is effective not only from below but also from the side of the rod.

In the device according to FIG. 4, the rod 1 to be processed is mounted at both ends in respective holders 2,3 and is surrounded by a ring-shaped heater 4 for melting an axially narrow cross-sectional zone as described above with reference to FIG. 1. Holder 3 is mounted on a support 21 which is slidably connected with a base plate 22 *and can be displaced in the axial direction of rod 1 by means of a screw spindle 23. A bell-shaped housing 24 sealed against the base plate 22 encloses the rod 1 to permit operating in vacuum or m a protective atmosphere. The holder 2 is mounted on a shaft 25 that passes through the housing to the outside and carries a gear 26 to be driven from a motor 27. The heater ring 4 is mounted on an axially displaceable rod 28 that extends to the outside of the housing 24 where it is connected by a rope 29 with a reel 30.

Operating the reel, for instance by means of another motor, causes the rod 28 and the heater 4 to progress along the rod 1, for instance, in the direction of the arrow 7 for zone-melting the rod in the manner described. During the processing, the spacing between the holders 2 and 3 can be varied for controlling the cross section of the processed portion of material. Also during the zone-melting, the motor 27 may be operated to keep the upper portion of rod 1 in revolution. If desired, another motor may be provided for also revolving the holder 3 with the lower portion of rod 1.

A magnet coil 31 is mounted on rod 28 in concentric relation to heater ring operation a magnetic fielo to counteract the tendency of the molten material to run Oil. For the same purpose the device is also equipped with the above-described nozzles 6 that, when in use, blow a stream of gas up wardly against the molten zone. The gas may be identical with the one used as a protective atmosphere. The nozzles are preferably mounted together with the heater so that they maintain, during the travel motion, their proper spacing from the molten zone.

I claim:

1. The process of successively zone-melting and resolidifying a rod of fusible material which comprises sup 4 to produce during the melting' the molten zone moving in a helical path in and along said body.

2. The process of claim 1, the molten segmental zone extending not more than half Way across the cross section of said rod.

3. The process of successively zone-melting and resolidifying a rod of fusible material which comprises supporting said rod at opposite end portions, applying heat to establish a molten segmental zone extending only part Way across the cross section of the rod, the axial Width and cross-sectional area of said molten zone being such that the amount of molten material is limited to that which is supportable solely by virtue of cohesive and in a helical path in and along said body.

4. The process of claim 3, the molten segmental zone extending not more than half way across the cross section of said rod.

5. The method of processing an elongated rod-shaped body of melta-ble material of delimited length, comprising clampingly supporting the body at opposite end portions, heating a segmental zone of said body to molten temperature, said zone extending only part way across said body, and advancing said heating along said body, the axial length and cross-sectional area of said molten zone being small enough so that surface tension serves to contain said molten zone in position along said body.

6. The crucible-free method of zone-melting an elongated rod-shaped body of meltable material, comprising supporting the body at its end regions, heating a transshaped body, while directing a blast of preheated inert gas so that it impinges against the molten zone, serving to counteract gravitational force acting on the molten material by preventing the dropping off of molten material, and also serving to prevent marginal cooling of the melting zone.

References Cited in the file of this patent UNITED STATES PATENTS OTHER REFERENCES Keck and Golay: Phys. Rev. 89, 1297 (1953).

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2254306 *Mar 18, 1939Sep 2, 1941Nat Cylinder Gas CoApparatus for flame hardening
US2683676 *Jan 13, 1950Jul 13, 1954Bell Telephone Labor IncProduction of germanium rods having longitudinal crystal boundaries
US2686864 *Jan 17, 1951Aug 17, 1954Westinghouse Electric CorpMagnetic levitation and heating of conductive materials
US2739088 *Nov 16, 1951Mar 20, 1956Bell Telephone Labor IncProcess for controlling solute segregation by zone-melting
US3030194 *Feb 11, 1954Apr 17, 1962Siemens AgProcessing of semiconductor devices
FR1065523A * Title not available
FR1087946A * Title not available
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3226193 *Jun 21, 1962Dec 28, 1965Union Carbide CorpMethod for growing crystals
US3231430 *Dec 28, 1964Jan 25, 1966Titanium Metals CorpConditioning ingots
US3943324 *Dec 27, 1972Mar 9, 1976Arthur D. Little, Inc.Apparatus for forming refractory tubing
US4218282 *Jun 15, 1978Aug 19, 1980Kabushiki Kaisha Suwa SeikoshaMethod of preparation of chrysoberyl and beryl single crystals
US4609402 *Oct 28, 1985Sep 2, 1986Iowa State University Research Foundation, Inc.Melts, hollow tube molds, inert gas
US4615760 *Jan 10, 1985Oct 7, 1986Dressler Robert FSuppression or control of liquid convection in float zones in a zero-gravity environment by viscous gas shear
US4828608 *May 14, 1987May 9, 1989Indium Corporation Of AmericaSmall diameter stream of liquefied metal, high vacuum heating to vaporize volatiles
US5258092 *Mar 23, 1992Nov 2, 1993Shin-Etsu Handotai Co., Ltd.Method of growing silicon monocrystalline rod
US6039802 *Mar 5, 1998Mar 21, 2000Murata Manufacturing Co., Ltd.Single crystal growth method
US7332030 *Jan 15, 2003Feb 19, 2008Michel BruelMethod of treating a part in order to alter at least one of the properties thereof
Classifications
U.S. Classification117/44, 75/10.11, 23/295.00R, 117/933, 23/301
International ClassificationC30B15/02, C30B13/28, C30B13/32, C30B15/00, C30B13/26, C30B13/16, C30B15/30
Cooperative ClassificationC30B13/26, C30B15/002, Y10S117/901, Y10S117/91, C30B13/16, Y10S117/917, C30B13/32, C30B15/02, C30B15/30, C30B13/28
European ClassificationC30B13/16, C30B13/28, C30B15/30, C30B13/26, C30B15/00B, C30B13/32, C30B15/02