US3287108A - Methods and apparatus for producing alloys - Google Patents

Methods and apparatus for producing alloys Download PDF

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US3287108A
US3287108A US249744A US24974463A US3287108A US 3287108 A US3287108 A US 3287108A US 249744 A US249744 A US 249744A US 24974463 A US24974463 A US 24974463A US 3287108 A US3287108 A US 3287108A
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heating
condensing
metals
alloy
alloys
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Hausner Johann Karl
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Hausner Enterprises Inc
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    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/22Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the process of coating
    • C23C14/24Vacuum evaporation
    • CCHEMISTRY; METALLURGY
    • C30CRYSTAL GROWTH
    • C30BSINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
    • C30B11/00Single-crystal growth by normal freezing or freezing under temperature gradient, e.g. Bridgman-Stockbarger method
    • C30B11/003Heating or cooling of the melt or the crystallised material
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S118/00Coating apparatus
    • Y10S118/90Semiconductor vapor doping
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S420/00Alloys or metallic compositions
    • Y10S420/903Semiconductive

Definitions

  • This invention relates to methods and apparatus for producing alloys and more particularly to crystallized semi-conductor alloys having an extremely high and uniform purity, such as employed in thermoelectric applications.
  • junctions may be provided wherein a donate-r element of a junction emits electrons which are absorbed by an acceptor element. By heating the junction, electricity may be generated. In the alternative, current may be passed in one direction through the junction to cause an absorption of heat or cooling, or current may be passed through the junction in the opposite direction to cause heating thereof.
  • current may be passed in one direction through the junction to cause an absorption of heat or cooling, or current may be passed through the junction in the opposite direction to cause heating thereof.
  • it is essenital that the elements have a high electric conductivity while having, a heat conductivity which is as low as possible.
  • This invention was evolved with the object of producing such semi-conductor alloys with a high degree of purity and uniformity, although various features of the invention may "be used in other applications.
  • An important feature of the invention relates to the use of a high voltage electrostatic field between a region within a vacuum chamber wherein metals are vaporized and another region wherein the metals are condensed and alloyed. With the proper application of the high voltage field, it is possible to produce particles of the alloys in exact quantities and absolute uniformity.
  • Another important feature of the invention relates to the casting of an alloy so produced into a rod and the heating and cooling of the rod while passing a current therethrongh to remove impurities and to produce a crystallized portion of extremely high purity and uniformity.
  • the current produces an electrolytic action causing impurities to move to one end or the other of the rod, leaving the central portion in a purified state.
  • FIGURE 1 is a partially diagrammatic view illustrating an alloying unit constructed according to the principles of this invention
  • FIGURE 2 is a circuit diagram of electrical apparatus for the unit of FIGURE 1;
  • FIGURE 3 is another partially diagrammatic view showing a purification and crystallization apparatus usable in conjunction with the apparatus of FIGURE 1.
  • Reference numeral- generally designates apparatus for the alloying of metals, constructed according to the principles of this invention.
  • metals to be alloyed are placed in smelting pots 11 and 12 within a vacuum chamber defined by a dome 13 on a base plate 14.
  • the metals are heated in the smelting pots 11 and 12 to be vaporized, the vaporized metals being then condensed and alloyed in a condensing 3,287,108 Patented Nov. 22, 1966 pct unit 15. Thereafter, the alloyed metals are cast into rods and treated further by the apparatus illustrated in FIGURE 3, to crystallize the same and to remove impurities.
  • the smelting pots 11 and 12 are heated by passage of electric current therethrough and are constructed of thin tungsten sheets formed into horizontal hollow cylinders having upper portions cut out for receiving the metal.
  • a first pair of vertical support and current-carrying rods 17 and 18 have upper ends mechanically and electrically connected to opposite ends of the pct 11 while a second pair of rods 19 and 20 have upper ends connected to opposite ends of the pct 12. Electrical terminals 21-24 on the lower ends of rods 17-20 are provided for connection to sources of heating current, two A.C. sources 25 and 26 being provided.
  • the sources 25 and 26 comprise transformers 27 and 28 having primary windings 29 and 30 for connection to A.C. supply lines and secondary windings 31 and 32 having ends connected through rheostats 33 and 34 and through a-mmeters 35 and. 36 to output terminals 37 and 38, with the other ends of the secondary windings being connected to output terminals 39 and 40. Volt meters 41 and 42 may be connected between the output terminals.
  • Output terminals 37 and 3-9 are connected to the rodterminals 17 and 18 while output terminals 38 and are connected to rod terminals 19 and 20, the smelting pots 11 and 12 being heated by the currents to a temperature at which the metals are vaporized.
  • the condensing pot unit 15 comprises an outer shell 44, preferably of a ceramic'ma-terial, with an inner cup 45 therein which is preferably of copper or other heatconductive material.
  • the inner surface of the cup 45 is preferably coated or plated with a layer 46 of chromium or other hard material;
  • a cooling coil 47' of hollow tubular material is embedded in the copper cup 45. End portions 48 and 49 of the coil 47 extend downwardly through the base plate 14 and serve to support the condensing pot unit 15. Portions 48 and 49 are connected to a suitable source of recirculating cooling fluid, not shown.
  • An annular plate 51 of porcelain or the like is prefer ably supported on the rods 17-20, the outer edge thereof being adjacent the inside surface of the dome 13, and the inner edge thereof being adjacent the upper inside edge of the condensing pot unit 15.
  • a pipe 53 is connected to' a vacuum pump, not shown, and extends upwardly through the base plate with a cap 54 on the upper end thereof having screen-covered side openings 55.
  • the space within the dome is evacuated and the smelting pots are then heated by the current from sources 25 and 26 to vaporize the metals which are then condensed in the condensing pot unit 15, cooled by the cooling coil 47.
  • An important feature of the invention is in the application of a high potential electrostatic field between the smelting pots 11 and 12 and the condensing pot unit 15. With this field, an electro-vaporization operation is obtained which greatly increases the uniformity of molecular conditions of the vaporized alloys and makes it possible to produce the particles of the desired alloys in exact quantity and absolute uniformity. This is of course extremely important in the production of semi-conductor alloys for therrno-electric and similar applications.
  • a high voltage source 57 which comprises a transformer 58 having a three-legged core 59 with a primary winding 60 on one leg, a high voltage center-tapped secondary winding 61 on the second leg and a control winding 62 on the third leg.
  • the primary winding 60 is connected a r s to an A.C. supply while the control winding 62 is connected through a rheostat 63 to a D.C. source 64, the rheostat 63 being adjusted to control the degree. of saturation of the third leg of the core to thereby control the voltage across the secondary 61.
  • the ends of the high voltage secondary winding 61'- are connected through current-limiting resistors 65 and 66 to the plates of a full wave rectifier tube 67 having a filament connected to a center-tapped secondary winding 68 of :a filament transformer 69 having a primary winding 70 connected to an A.C. supply source.
  • the center taps of the windings 61 and 68 are connected to negative and positive output terminals 71 and 72, a high voltage filter capacitor 73 being connected therebetween.
  • the negative output terminal 71 is connected to the condensing pot unit through end portion 49 of the cooling coil 47 thereof, while the positive output terminal 72 is connected to the rods 17 and 19 so as to be connected to the smelting pots 11 and 12.
  • the base plate 14 is preferably of metal and insulating sleeves 75, 76, 77, 78, 79 and 80 are provided where the rods 17,18, 19 and 20 and portions 48 and 49 pass through the base plate. These sleeves 75-80 provide the necessary insulation for the application of the high voltage, and also define vacuum seals. Additional sealing members 81 and 82 are provided for the dome 13 and the pipe 53.
  • the alloy condensed in the pot unit 15 of FIGURE 1 is preferably cast in rods and then treated by apparatus generally designated by reference numeral 90 in FIG- URE 3.
  • the alloy is cast in a rod 91 within a tube 92,1 preferably a quartz tube, which is placed in a vertical position and then lowered to pass first through a smelting zone within a heating unit 93 and then through a low temperature or deep freeze zone within a cooling unit 94, the movement being controlled by a mechanism 95.
  • An important feature of the invention is in the flow of current through the alloy during the heating and cooling treatment. As soon as the alloy starts to melt, this current causes electrolysis to take place and all impurities start to move either downwardly or upwardly toward one end or the other of the tube 92, the direction of movement being determined by the chemical group of the impurity. When the alloy then reaches the cooling zone, itis crystallized into solid crystals of extremely high purity, except at the upper and lower end portions of the rod which then contain the impurities. In some cases, an improvement in results might be obtained by repeating the process. In most cases, however, only one treatment is required which is of considerable advantage over prior art systems wherein the crystallization process must be repeated many times.
  • a pair of contacts 97 and 98 are secured to the upper and lower ends of the quartz tube 92, preferably with a hermetic seal.
  • An expansion space 99 may be provided between the upper contact 97 and the alloy 91 and, to insure electrical contact, a pin 100 projects downwardly from the lower end of contact 97 into the alloy.
  • Contacts 97 and 98 are connected through suitable flexible cables to terminals 101 and 102 of a DC. source, as diagrammatically illustrated.
  • the heating unit 93 comprises a coil of wire 104, preferably Nichrome wire, surrounded by an insulating sleeve 105 of asbestos or the like, the assembly being disposed in a suitable cover or casing 106.
  • the cooling unit 94 comprises a coil 107 of hollow tubular material, embedded in a supporting sleeve 108 of heat-transmitting material, preferably sintered copper, sleeve 108 being enclosed by a sleeve 109 of insulating material such as asbestos.
  • a pair of are preferably of a ceramic material.
  • heating unit 93 to provide a shield against direct radiation from the heating unit.
  • the heating and cooling units 93 and 94 are supported in a suitable framework which also supports the; lowering machanism 95.
  • Mechanism 95 comprises a threaded rod 116 removably secured at its lower end to the upper contact member 97.
  • Rod 116 is threaded. through an internally threaded opening 117 in a .worm' gear 118 driven by a worm 119 which is driven by a suitable drive, not shown.
  • the worm gear 118 is supported through a bearing assembly 120 on a support member 121 secured to the upper end of the framework 115.
  • Support member 121 has a central opening through which the rod 116 extends and carries a key 122 extending into a keyway 123 on the rod 116 to prevent rotation of the rod 116.
  • the vertical distance from the upper end of the heating unit to the lower end of the: mechanism 95 and the distance from the lower end of the cooling unit to the base of the framework 115, should be greater than the length of the tube 92 so as to permit insertion and removal of the tube 92.
  • alloys of high purity and particularly crystallized semi-conductor alloys such as, for example, alloys of tellurium with bismuth, antimony or selenium.
  • the application of the high voltage field causes the charging of individual particles of the vaporized metals to reduce the particles of each metal .to a very small size and to then bring such particles into intimate association as they condense in the condensing pot.
  • the passage of the electric current through the alloy causes an electrolytic action and movement of impurities either in the direction of a current or in the opposite direction, depending upon the chemical group of the impurity.
  • means defining a vacuum chamber, smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for con densation of the vaporized metals therein, and means for applying a high voltage electrostatic field between said smelting means and said condensing means.
  • a tube for receiving a rod of unpurified alloy, an electrical heating coil arranged for receiving said tube and for heating the alloy to a high temperature, a cooling coil axially aligned with said heating coil for receiving said tube and cooling and crystallizing the alloy, and means for passing a current through said rod While it is disposed in said heating coil.
  • apparatus for producing alloys means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said'chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, and a high voltage source connected between said first and second conductor means.
  • means defining a vacuum chamber, a plurality of smelting pots in said chamber for receiving a plurality of metals to be alloyed, means for passing an electric current through said pots to heat the metals to vaporization temperatures, a condensing pot in said vacuum chamber, means for applying a high voltage electrostatic field between said condensing pot and said smelting pots, means for receiving alloys condensed in said condensing pots, means for heating the alloy in said receiving means, and means for passing a unidirectional electric current through the heated alloy in said receiving means to cause impurities to move in one direction by electrolytic action.
  • a tube for receiving a rod of unpurified alloy, heating means arranged to receive and surround said tube to heat the alloy therein, cooling means aligned with said heating means and arranged to receive and surround said tube to cool the alloy therein, means for slowly moving said tube through said heating means and thence through said cooling means, and means for passing a unidirectional electric current through said rod while disposed in said heating means.
  • means defining a vacuum chamber, a plurality of smelting pots in said chamber for receiving a plurality of metals to be alloyed, means for passing electric current through said smelting pots to heat the metals to vaporization temperatures, a condensing pot in said vacuum chamber, and means for applying a high voltage electrostatic field between said condensing pot and said smelting pots.
  • means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, a high voltage source connected between said first and second conductor means, and means for separately regulating the currents applied from said plurality of heating current sources.
  • a hollow tube of insulating material for receiving a rod of unpurified alloy, a pair of contacts on the opposite ends of said tube for making electrical contact with the unpurified alloy therein, means for heating the alloy within said tube, and means for connecting said contacts to a DO. source to pass a current longitudinally through the alloy in said rod while heating the alloy.
  • means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, a high voltage source connected between said first and second conductor means, and means for regulating the voltage of said high voltage source.
  • a tube for receiving a rod of unpurified alloy, heating means for receiving said tube and heating the alloy therein to a high temperature, and means for passing a unidirectional current longitudinally through the alloy in said rod to electrolytically cause movement of impurities to one end or the other of the rod, said tube having a greater volume than the volume of said unpurified alloy placed therein, thereby providing an expansion chamber.

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  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
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Description

Nov. 22, 1966 J. K. HAUSNER 3,287,108
METHODS AND APPARATUS FOR PRODUCING ALLOYS Filed Jan. 7, 1963 A 5 Sheets-Sheet 1 INVENTOR. (/06 0/719 Kar/ flaws/yer Mb Q W A T ()RNEYS Nov. 22, 1966 J. K. HAUSNER METHODS AND APPARATUS FOR PRODUCING ALLOYS Filed Jan. 7, 1963 5 Sheets-$heet 2 i WA E w wm 6 A MW 3 E QR.
INVENTOR. c/o/mnn Afar/Hams e/ BY Q a i s M g y I AfiMN/EYS Nov. 22, 1966 J. K. HAUSNER 3,287,108
METHODS AND APPARATUS FOR PRODUCING ALLOYS Filed Jan. '7, 1963 5 Sheets-Sheet 5 I NVENTOR. c/ob mm Az ar/fiaasner' A T' URN]; YS
United States Patent nois Filed Jan. 7, 1963, Ser. No. 249,744 14 Claims. (Cl. 75-10) This invention relates to methods and apparatus for producing alloys and more particularly to crystallized semi-conductor alloys having an extremely high and uniform purity, such as employed in thermoelectric applications.
, Quite rigid requirements are imposed in the production of alloys for thermoelectric applications. In such applications, junctions may be provided wherein a donate-r element of a junction emits electrons which are absorbed by an acceptor element. By heating the junction, electricity may be generated. In the alternative, current may be passed in one direction through the junction to cause an absorption of heat or cooling, or current may be passed through the junction in the opposite direction to cause heating thereof. To obtain high efficiency, it is essenital that the elements have a high electric conductivity while having, a heat conductivity which is as low as possible. These results can be obtained with certain crystallized semi-conductor alloy materials having a high and uniform purity, which may be doped with very small amounts of certain materials. By way of example, alloys of tellurium with bismuth, antimony or selenium are suitable for many applications.
This invention was evolved with the object of producing such semi-conductor alloys with a high degree of purity and uniformity, although various features of the invention may "be used in other applications.
An important feature of the invention relates to the use of a high voltage electrostatic field between a region within a vacuum chamber wherein metals are vaporized and another region wherein the metals are condensed and alloyed. With the proper application of the high voltage field, it is possible to produce particles of the alloys in exact quantities and absolute uniformity.
Another important feature of the invention relates to the casting of an alloy so produced into a rod and the heating and cooling of the rod while passing a current therethrongh to remove impurities and to produce a crystallized portion of extremely high purity and uniformity. The current produces an electrolytic action causing impurities to move to one end or the other of the rod, leaving the central portion in a purified state.
This invention contemplates other and more specific objects, features and advantages which will become more fully apparent from the following detailed description taken in conjunction with the accompanying drawings which illustrate preferred embodiments and in which:
FIGURE 1 is a partially diagrammatic view illustrating an alloying unit constructed according to the principles of this invention;
FIGURE 2 is a circuit diagram of electrical apparatus for the unit of FIGURE 1; and
FIGURE 3 is another partially diagrammatic view showing a purification and crystallization apparatus usable in conjunction with the apparatus of FIGURE 1.
Reference numeral- (generally designates apparatus for the alloying of metals, constructed according to the principles of this invention. In the general operation of the apparatus 10, metals to be alloyed are placed in smelting pots 11 and 12 within a vacuum chamber defined by a dome 13 on a base plate 14. The metals are heated in the smelting pots 11 and 12 to be vaporized, the vaporized metals being then condensed and alloyed in a condensing 3,287,108 Patented Nov. 22, 1966 pct unit 15. Thereafter, the alloyed metals are cast into rods and treated further by the apparatus illustrated in FIGURE 3, to crystallize the same and to remove impurities.
The smelting pots 11 and 12 are heated by passage of electric current therethrough and are constructed of thin tungsten sheets formed into horizontal hollow cylinders having upper portions cut out for receiving the metal.
A first pair of vertical support and current-carrying rods 17 and 18 have upper ends mechanically and electrically connected to opposite ends of the pct 11 while a second pair of rods 19 and 20 have upper ends connected to opposite ends of the pct 12. Electrical terminals 21-24 on the lower ends of rods 17-20 are provided for connection to sources of heating current, two A.C. sources 25 and 26 being provided.
The sources 25 and 26 comprise transformers 27 and 28 having primary windings 29 and 30 for connection to A.C. supply lines and secondary windings 31 and 32 having ends connected through rheostats 33 and 34 and through a-mmeters 35 and. 36 to output terminals 37 and 38, with the other ends of the secondary windings being connected to output terminals 39 and 40. Volt meters 41 and 42 may be connected between the output terminals.
Output terminals 37 and 3-9 are connected to the rodterminals 17 and 18 while output terminals 38 and are connected to rod terminals 19 and 20, the smelting pots 11 and 12 being heated by the currents to a temperature at which the metals are vaporized.
The condensing pot unit 15 comprises an outer shell 44, preferably of a ceramic'ma-terial, with an inner cup 45 therein which is preferably of copper or other heatconductive material. The inner surface of the cup 45 is preferably coated or plated with a layer 46 of chromium or other hard material; A cooling coil 47' of hollow tubular material is embedded in the copper cup 45. End portions 48 and 49 of the coil 47 extend downwardly through the base plate 14 and serve to support the condensing pot unit 15. Portions 48 and 49 are connected to a suitable source of recirculating cooling fluid, not shown.
An annular plate 51 of porcelain or the like is prefer ably supported on the rods 17-20, the outer edge thereof being adjacent the inside surface of the dome 13, and the inner edge thereof being adjacent the upper inside edge of the condensing pot unit 15.
For evacuation of the space within the dome 13, a pipe 53 is connected to' a vacuum pump, not shown, and extends upwardly through the base plate with a cap 54 on the upper end thereof having screen-covered side openings 55.
After placing the metals to be alloyed in the smelting pots 11 and 12, the space within the dome is evacuated and the smelting pots are then heated by the current from sources 25 and 26 to vaporize the metals which are then condensed in the condensing pot unit 15, cooled by the cooling coil 47.
An important feature of the invention is in the application of a high potential electrostatic field between the smelting pots 11 and 12 and the condensing pot unit 15. With this field, an electro-vaporization operation is obtained which greatly increases the uniformity of molecular conditions of the vaporized alloys and makes it possible to produce the particles of the desired alloys in exact quantity and absolute uniformity. This is of course extremely important in the production of semi-conductor alloys for therrno-electric and similar applications.
To produce the high potential field, a high voltage source 57 is provided which comprises a transformer 58 having a three-legged core 59 with a primary winding 60 on one leg, a high voltage center-tapped secondary winding 61 on the second leg and a control winding 62 on the third leg. The primary winding 60 is connected a r s to an A.C. supply while the control winding 62 is connected through a rheostat 63 to a D.C. source 64, the rheostat 63 being adjusted to control the degree. of saturation of the third leg of the core to thereby control the voltage across the secondary 61.
The ends of the high voltage secondary winding 61'- are connected through current-limiting resistors 65 and 66 to the plates of a full wave rectifier tube 67 having a filament connected to a center-tapped secondary winding 68 of :a filament transformer 69 having a primary winding 70 connected to an A.C. supply source.
The center taps of the windings 61 and 68 are connected to negative and positive output terminals 71 and 72, a high voltage filter capacitor 73 being connected therebetween. The negative output terminal 71 is connected to the condensing pot unit through end portion 49 of the cooling coil 47 thereof, while the positive output terminal 72 is connected to the rods 17 and 19 so as to be connected to the smelting pots 11 and 12.
The base plate 14 is preferably of metal and insulating sleeves 75, 76, 77, 78, 79 and 80 are provided where the rods 17,18, 19 and 20 and portions 48 and 49 pass through the base plate. These sleeves 75-80 provide the necessary insulation for the application of the high voltage, and also define vacuum seals. Additional sealing members 81 and 82 are provided for the dome 13 and the pipe 53.
The alloy condensed in the pot unit 15 of FIGURE 1 is preferably cast in rods and then treated by apparatus generally designated by reference numeral 90 in FIG- URE 3.
In particular, the alloy is cast in a rod 91 within a tube 92,1 preferably a quartz tube, which is placed in a vertical position and then lowered to pass first through a smelting zone within a heating unit 93 and then through a low temperature or deep freeze zone within a cooling unit 94, the movement being controlled by a mechanism 95.
An important feature of the invention is in the flow of current through the alloy during the heating and cooling treatment. As soon as the alloy starts to melt, this current causes electrolysis to take place and all impurities start to move either downwardly or upwardly toward one end or the other of the tube 92, the direction of movement being determined by the chemical group of the impurity. When the alloy then reaches the cooling zone, itis crystallized into solid crystals of extremely high purity, except at the upper and lower end portions of the rod which then contain the impurities. In some cases, an improvement in results might be obtained by repeating the process. In most cases, however, only one treatment is required which is of considerable advantage over prior art systems wherein the crystallization process must be repeated many times.
To apply the current through the rod 91, a pair of contacts 97 and 98 are secured to the upper and lower ends of the quartz tube 92, preferably with a hermetic seal. An expansion space 99 may be provided between the upper contact 97 and the alloy 91 and, to insure electrical contact, a pin 100 projects downwardly from the lower end of contact 97 into the alloy.
Contacts 97 and 98 are connected through suitable flexible cables to terminals 101 and 102 of a DC. source, as diagrammatically illustrated.
The heating unit 93 comprises a coil of wire 104, preferably Nichrome wire, surrounded by an insulating sleeve 105 of asbestos or the like, the assembly being disposed in a suitable cover or casing 106.
The cooling unit 94 comprises a coil 107 of hollow tubular material, embedded in a supporting sleeve 108 of heat-transmitting material, preferably sintered copper, sleeve 108 being enclosed by a sleeve 109 of insulating material such as asbestos.
To oppose flow of heat to the cooling unit 94 from the heating unit 93 and from the external space, a pair of are preferably of a ceramic material.
heating unit 93, to provide a shield against direct radiation from the heating unit.
The heating and cooling units 93 and 94 are supported in a suitable framework which also supports the; lowering machanism 95. Mechanism 95 comprises a threaded rod 116 removably secured at its lower end to the upper contact member 97. Rod 116 is threaded. through an internally threaded opening 117 in a .worm' gear 118 driven by a worm 119 which is driven by a suitable drive, not shown. The worm gear 118 is supported through a bearing assembly 120 on a support member 121 secured to the upper end of the framework 115. Support member 121 has a central opening through which the rod 116 extends and carries a key 122 extending into a keyway 123 on the rod 116 to prevent rotation of the rod 116.
It may benoted that the vertical distance from the upper end of the heating unit to the lower end of the: mechanism 95 and the distance from the lower end of the cooling unit to the base of the framework 115, should be greater than the length of the tube 92 so as to permit insertion and removal of the tube 92..
With the methods and apparatus as above described, it is possible to produce alloys of high purity and particularly crystallized semi-conductor alloys such as, for example, alloys of tellurium with bismuth, antimony or selenium. It may be noted that although the exact reasons for the improved results are not known with absolute certainty, it is believed that in the vaporization and condensing step of the process, the application of the high voltage field causes the charging of individual particles of the vaporized metals to reduce the particles of each metal .to a very small size and to then bring such particles into intimate association as they condense in the condensing pot. Then in the purification and crystallization steps of the process, the passage of the electric current through the alloy causes an electrolytic action and movement of impurities either in the direction of a current or in the opposite direction, depending upon the chemical group of the impurity.
It will be understood that modifications and variations may be effected without departing from the spirit and scope of the novel concepts of this invention.
I claim as my invention:
1. In a method of producing alloys, the steps of separately heating and vaporizing a plurality of metals to be alloyed within a common vacuum chamber, and condensing and alloying the vaporized metals in a cooled condensing region while applying a high voltage electrostatic field between the vaporization and condensing regions.
2. In a method of producing crystallized semi-conductor alloys, the steps of separately heating and vaporizing a pluralityof metals to be alloyed within a common,
vacuum chamber, condensing and alloying the vaporized metals in a cooled condensing region while applying a high voltage electrostatic field between the vaporization and condensing regions, casting the condensed alloy into rods, heating and then cooling the rods while passing an electric current longitudinally through the rods to cause impurities to move to one end or the other while leaving the central portion in a crystallized purified state.
3. In apparatus for producing alloys, means defining a vacuum chamber, smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for con densation of the vaporized metals therein, and means for applying a high voltage electrostatic field between said smelting means and said condensing means.
4. In a method of producing crystallized alloys, the steps of separately heating and vaporizing a plurality of metals to be alloyed within a common vacuum chamber, condensing and alloying the vaporized metal in a cooled condensing region while applying a high voltage electrostatic field between the vaporization and condensing regions, subsequently heating the condensed alloy, and then cooling and crystallizing the alloy.
5. In apparatus for purifying and crystallizing alloys, a tube for receiving a rod of unpurified alloy, an electrical heating coil arranged for receiving said tube and for heating the alloy to a high temperature, a cooling coil axially aligned with said heating coil for receiving said tube and cooling and crystallizing the alloy, and means for passing a current through said rod While it is disposed in said heating coil.
6. In a method of producing crystallized semi-conductor alloys, the steps of separately heating and vaporizing a plurality of metals to be alloyed within a common vacuum chamber, condensing and alloying the vaporized metals in a cooled condensing region, casting the condensed alloy into rods, heating and then cooling the rods while passing an electric current longitudinally through the rods to cause impurities to move to one end or the other while leaving the central portion in a crystallized purified state.
7. In apparatus for producing alloys, means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said'chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, and a high voltage source connected between said first and second conductor means.
8. In apparatus for producing alloys, means defining a vacuum chamber, a plurality of smelting pots in said chamber for receiving a plurality of metals to be alloyed, means for passing an electric current through said pots to heat the metals to vaporization temperatures, a condensing pot in said vacuum chamber, means for applying a high voltage electrostatic field between said condensing pot and said smelting pots, means for receiving alloys condensed in said condensing pots, means for heating the alloy in said receiving means, and means for passing a unidirectional electric current through the heated alloy in said receiving means to cause impurities to move in one direction by electrolytic action.
9. In apparatus for purifying alloys, a tube for receiving a rod of unpurified alloy, heating means arranged to receive and surround said tube to heat the alloy therein, cooling means aligned with said heating means and arranged to receive and surround said tube to cool the alloy therein, means for slowly moving said tube through said heating means and thence through said cooling means, and means for passing a unidirectional electric current through said rod while disposed in said heating means.
10. In apparatus for producing alloys, means defining a vacuum chamber, a plurality of smelting pots in said chamber for receiving a plurality of metals to be alloyed, means for passing electric current through said smelting pots to heat the metals to vaporization temperatures, a condensing pot in said vacuum chamber, and means for applying a high voltage electrostatic field between said condensing pot and said smelting pots.
11. In apparatus for producing alloys, means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, a high voltage source connected between said first and second conductor means, and means for separately regulating the currents applied from said plurality of heating current sources.
12. In apparatus for purifying and crystallizing alloys, a hollow tube of insulating material for receiving a rod of unpurified alloy, a pair of contacts on the opposite ends of said tube for making electrical contact with the unpurified alloy therein, means for heating the alloy within said tube, and means for connecting said contacts to a DO. source to pass a current longitudinally through the alloy in said rod while heating the alloy.
13. In apparatus for producing alloys, means defining a vacuum chamber, electrically heated smelting means in said chamber for heating a plurality of metals to vaporization temperatures, condensing means within said chamber for condensing the vaporized metals therein, a plurality of heating current sources, first conductor means extending from said current sources into said vacuum chamber and connected to said smelting means, second conductor means extending from said condensing means to a point outside said chamber, means insulating said first and second conductor means from each other, a high voltage source connected between said first and second conductor means, and means for regulating the voltage of said high voltage source.
14. In apparatus for purifying alloys, a tube for receiving a rod of unpurified alloy, heating means for receiving said tube and heating the alloy therein to a high temperature, and means for passing a unidirectional current longitudinally through the alloy in said rod to electrolytically cause movement of impurities to one end or the other of the rod, said tube having a greater volume than the volume of said unpurified alloy placed therein, thereby providing an expansion chamber.
References Cited by the Examiner UNITED STATES PATENTS 2,711,379 6/1955 Rothstein l48--l.5
DAVID L. RECK, Primary Examiner.
H. F. SAITO, Assistant Examiner.

Claims (1)

  1. 2. IN A METHOD OF PRODUCING CRYSTALLIZED SEMI-CONDUCTOR ALLOYS, THE STEPS OF SEPARATELY HEATING AND VAPORIZING A PLURALITY OF METALS TO ALLOYED WITHIN A COMMON VACUUM CHAMBER, CONDENSING AND ALLOYING THE VAPORIZED METALS IN A COOLED CONDENSING REGION WHILE APPLYING A HIGH VOLTAGE ELECTOSTATIC FIELD BETWEEN THE VAPORIZATION AND CONDENSING REGIONS, CASTING THE CONDENSED ALLOY INTO RODS, HEATING AND THEN COOLING THE RODS WHILE PASSING AN ELECTRIC CURRENT HONGITUDINALLY THROUGH THE RODS TO CAUSE
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3519498A (en) * 1966-07-14 1970-07-07 Ibm Ferromagnetic film
US3522087A (en) * 1966-02-16 1970-07-28 Philips Corp Semiconductor device contact layers

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2711379A (en) * 1952-08-04 1955-06-21 Rothstein Jerome Method of controlling the concentration of impurities in semi-conducting materials

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2711379A (en) * 1952-08-04 1955-06-21 Rothstein Jerome Method of controlling the concentration of impurities in semi-conducting materials

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3522087A (en) * 1966-02-16 1970-07-28 Philips Corp Semiconductor device contact layers
US3519498A (en) * 1966-07-14 1970-07-07 Ibm Ferromagnetic film

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