US2619433A - Method of gas plating - Google Patents

Method of gas plating Download PDF

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US2619433A
US2619433A US104754A US10475449A US2619433A US 2619433 A US2619433 A US 2619433A US 104754 A US104754 A US 104754A US 10475449 A US10475449 A US 10475449A US 2619433 A US2619433 A US 2619433A
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metal
base material
chamber
base
temperature
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US104754A
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Oliver F Davis
Hans G Belitz
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Commonwealth Engineering Company of Ohio
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Commonwealth Engineering Company of Ohio
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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
    • C23C16/00Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
    • C23C16/06Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of metallic material
    • C23C16/16Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of metallic material from metal carbonyl compounds
    • 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
    • C23C16/00Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
    • C23C16/06Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of metallic material
    • 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
    • C23C16/00Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
    • C23C16/44Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the method of coating
    • C23C16/455Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the method of coating characterised by the method used for introducing gases into reaction chamber or for modifying gas flows in reaction chamber
    • 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
    • Y10S29/00Metal working
    • Y10S29/039Spraying with other step

Definitions

  • This invention relates to, thel art of deposition of metals. More particularly it relates to coating of metal bases. Still more particularly it relates to the plating of objectsl by thel 'deposition of metal from readily decomposed volatile metal bearing compounds and apparatus for carrying out thel process.
  • Depositing of thin film of metals, such as iron, nickel, cobalt, upon metal bases has beenv accompl-ished in the past ⁇ by enclosing an object. to be plated in a chamber sealed against entry of air.
  • metals such as iron, nickel, cobalt
  • the chamber was purged with carbon dioxide and the object heated to a temperature at which volatile metal car'bonyls ⁇ decompose.
  • the deposition rate is very slow and the process requires hou-rs. to build up. an appreciable depth of metal coating.
  • the coatings are brittle andA adheredY poorly ⁇ to the base metal.
  • the object After a thin layer of metal is deposited the object is subjected to heat treatment at a temperatureof between 500 and 800 Fl to desorb the occluded gases. The object was then returned to the chamber and a second coating of the desired thickness over the rst layer deposited thereon.
  • 'Ity is ,a further object of this invention to provide a process wherein the decomposition gases are quickly removed from the plating, ⁇ area. to eliminate contamination of. the deposited metal film.
  • yIt isa still further obje-ct of this invention ⁇ to prov-ide a process for continuous and rapid deposition of bright metal coatings by directing the decomposable metal material to the met-al surface.
  • the plating composition is introduced into the deposition chamber as a liquid instead of a gas. In ⁇ this way itis possible to concentrate the stream of metal bearing materialat the heated surface.
  • the atmospherev in the neighborhood of the surface lto be coated in thus made up merely of fresh liquid propelled with force by the gas blast into the deposition zone and encountering mainly the hot gaseous decomposition products which are being removed as, for example, by suction or vacuum drawn on the chamber.
  • metal carbonyls also nitroxyl compounds, nitrosyl carbonyls, metal hydrides, metal alkyls, metal halides, metal carbonyl halogens, and the like, which are either liquids at normal temperature and pressure conditions, or gases compressible to liquid under any commercial feasible temperature conditions or solids convertible to liquids at temperatures below ⁇ the decomposition temperature of the compound, or to utilize solutions of carbonyls in volatile solvents such as petroleum ether.
  • Useful metals which may be deposited from the metallic carbonyl compounds are nickel, iron, chromium, molybdenum, tungsten, cobalt, tellurium, rhenium, and the like.
  • Illustrative compounds of the other groups are ntroxyls, such as copper nitroxyl, nitrosyl carbonyls, for example, cobalt nitrosyl carbonyl, hydrides, such as tellurium hydride, geleniurn hydride, antimony hydride, tin hydride, chromium hydride, the mixed organo-metallo hydrides such as dimethyl alumino hydride, metal alkyls such as tetraethyl lead, metal halides such as chromyl chloride, and carbonyl halogens such as rhodium carbonyl chloride, osmium carbonyl bromide, ruthenium carbonyl chloride, and the like.
  • hydrides such as tellurium hydride, geleniurn hydride, antimony hydride, tin hydride, chromium hydride
  • the mixed organo-metallo hydrides such as dimethyl a
  • Apparatus of this type usually delivers the liquid to the orifice through a central pipe.
  • the inert gas is usually fed to the mixing point through an annular chamber surrounding the central pipe.
  • the quantity of liquid atomized iF controlled by adjustment of the orifice area Commercial equipment, such as fog nozzles or fine spray nozzles, such as the DeVilbis paint spray gun, can be readily adapted for use as the spraying means.
  • Each material from which a metal may bg plated has a temperature at which decomposition is complete. However, decomposition may take place slowly at a lower temperature or while the vapors are being raised in temperature through some particular range. For example, nickel carbonyl completely decomposes at a temperature in the range of 375 F. to 400 T. However, nickel carbonyl starts to decompose slowly at about 175 F., and therefore, decomposition continues during the time of heating from 200 F. to 380 F. A large number of the metal carbonyls and hydrides may be effectively and elciently decomposed at a temperature in the range of 350 F. to 450 F. When working with most carbonyls we prefer to operate in a temperature range of 375 F. to 425 F.
  • the presentl invention is markedly superior to the processes utilized heretofore, because it accomplishes all of its decomposition quickly in close proximity to the heated surface area and because the liquid when converted to a vapor is then decomposed without delay as the carbonyl or nitrosyl or hydride compounds come in contact with the hot object to be plated.
  • the material to be decomposed is readily brought to the decomposition temperature by atomizing the liquid with hot inert gas.
  • the fine spray of liquid can thus be transformed from say 100 F. to temperatures of between 200 F. and 300 F. in a fraction of a second and the liquid converted'toagas.
  • the metal strip or object to be plated may be cleaned by employing the conventional methods used in the art, comprising electro-chemically cleaning by moving same through a bath of alkali or acid electrolyte, wherein the strip is made the cathode or anode.
  • Pickling of the metal with hydrochloric, sulfuric, or nitric acid, or a combination of acids, may also be made as a part of the cleaning process and the strip thoroughly rinsed or washed and dried prior to introduction into the plating apparatus of this invention.
  • Figure 1 is a vertical sectional view showing diagrammatically one embodiment of the apparatus of this invention
  • Figure 2 is a vertical sectional view of the apparatus taken substantially on the line 2-2 of Figure 1 and looking in the direction of the arrows;
  • Figure 3 is a Vertical sectional view along the line 3-3 of Figure 1.
  • an object I0 which may be a stationary positioned object or a moving sheet or the like.
  • the object here shown is illustrated as stationary and suspended from a support I'I.
  • Adjacent the 'object is a support I2 from which is suspended suitable heating means I3, such as an electrical resistancecoil masked with a Asuitable covering I4 which prevents plating on lthe heating element.
  • Supports II and I2 are secured in the wall of an air tight chamber I5.
  • This chamber is provided with an aperture I6 for introduction and removal of objects to be plated.
  • the aperture I6 is fitted with releasable closure means II rendered air tight by a suitable gasket I8.
  • a metal jacket I9 Surrounding the chamber I5 is a metal jacket I9 having therein a closed space 20 through which a suitable medium, such as water, may be circulated.
  • the space 29 is shown in communication with an inlet 2I and an outlet 22.
  • an inert gas may be introduced by suitable means 25, such as a fan or blower.
  • Blower 25 is shown, taking' suction on a. surge tank; supplied with gas from a storage tank as indicated and introducing the gas aty the chamber inlet 21.
  • the chamber outlet pipe 26a comvmunicating with the chamber through outlet 26 may be connected at the point indicated at 25h with a vacuum pump or exhaust fan.
  • the exhausted gases which are a mixture of inert gas and carbon monoxide may, if desired, be scrubbed to remove inert gas such as carbondoxide, and the puried carbon monoxide returned to a metal carbonyl generator to conserve carbon monoxide.
  • Liquid is introduced into the chamber through the rightwardly Wall 28 of chamber I5 by suitable spray means 3B.
  • Spray means 30 consists of a central liquid tube 3I connected to a source of liquid 32.
  • the tube 3I is surrounded by a tube 33 mounted with a laterally adjustable head 34, adapted with an external gear 35.
  • Gear 35 is actuated by a gear 36 attached to a rod 31 which extends through a sealed bushing 38 to a manually oper able position outside the chamber I5.
  • Tube 33 is connected to a suitable source ci inert gas 39 through pipe 40.
  • Chamber I5 is provided with a suitable Window 42 more completely shown in Figure 3.
  • This Window comprises an ⁇ inner pane 43 of glass or clear resin joined in air tight seal to the chamber I by suitable gasket means 44. The gasketing also seals tightly to an outer glass pane 45 to form between said panes an air pocket 45.
  • This arrangement provides a clear View of the plating and spray adjustment apparatus without rdanger of carbon-monoxide leakage to the area ⁇ Where operators might be stationed.
  • thermometer 48 suitably sealed in the Wall of chamber I5 and the jacket I9 and extending outside the plating chamber for visual observation.
  • Example I Aluminum discs may be suspended from the support II.
  • the chamber may then be sealed and purged of air by passing carbon dioxide gas therethrough.
  • the discs When the chamber I5 is purged the discs may be heated by conduction due to intimate contact with resistance heater I3. At this time the Water may be started circulating in jacket I9 to maintain the chamber at a cool non-plating temperature.
  • nickel carbonyl may be introduced into the chamber by spray means 3D.
  • This lnickel carbonyl may be under a pressure of about 50 pounds per square inch and sprayed at the rate of about 2 pounds of nickel carbonyl per minute.
  • the spraying means may be carbon dioxide maintained under a pressure of about '75 pounds per square inch.
  • the decomposition of nickel carbonyl produces 4 volumes of carbon monoxide gas for each molecular Weight of liquid introduced.
  • the gasses may be removed by an exhaust fan which maintains a pressure in the chamber of between l and 2 inches of H2O vacuum.
  • the operation may be carried out in a similar manner, ⁇ using nickel carbonyl sprayed into vthe chamber at a rate of about 21/2 pounds of liquid per minute.
  • the inert atmosphere may be hydrogen gas.
  • the liquid may be sprayed using hydrogen as the blasting gas, which gas is under a pressure of ⁇ pounds per square inch and at a temperature of 200 F.
  • the lead pattern may be heated -to a temperature of approximately 375 F. and in the presence of hydrogen the nickel carbonyl vplated to a brightv metallic clean surface.
  • Example III A canbon steel'plate may be introduced into lthe chamber of Example I and the process run Aunder the following conditions:
  • the liquid supplied to the spray apparatus may be cobalt carbonyl.
  • the inert gas circulated ⁇ in the chamber may be nitrogen from a source maintained under a pressure slightly above atmospheric.
  • Temperature of the steel plate may be maintained at approximately 410 F.
  • the cobalt carbonyl may be introduced at a liquid flow rate of approximately 4 pounds of canbony-l per minute.
  • the gases are exhausted utilizing vacuum equipment capable of maintaining a pressure within the chamber of approximately 3 inches of Water vacuum.
  • a smooth coating of cobalt mayy be thus deposited on 'large plates in a matter of minutes.
  • Example IV Copper discs may be .introduced into the chamber Aexplained in conjunction with Example I and the. process operated under the following condi.- tions:
  • Copper discs may be heated to approximately 38u F.
  • the chamber may be purged with hydrogen, and hydrogen gas may be used as the spraying medium.
  • Antimony ⁇ hydride may be introduced into the chamber through the spray ap.- paratus ata rate of approximately 3 poundsvper minute.
  • These copper discs of 3 inch diameter may be plated to a depth of .025 inch with metallic antimony-in a fraction of a minute.
  • the method of coating base material with a metallic coating which comprises: atomizing a llqueed heat decomposable Vgaseous metal com pound as ine droplets and propelling the samein rthe form of a spray toward the surface of the said base material to be coated, continuously maintaining lbase material and its immediate vicinity at a temperature for vaporising of said' 7 droplets, and bringing about rapid decomposition of said metal compound and rapid deposition of metal contained in said vaporous compound on said base material.
  • the method of coating base material with a metallic coating which comprises: atomizing a liquefied heat-decomposable gaseous metal compound as fine droplets and propelling the same in the form of a spray toward the base material to be coated, vaporizing the droplets in flight in the immediate vicinity of said base material, and maintaining said base material at a temperature to cause decomposition of the vaporous compound and deposition of metal thereon.
  • the method of covering metallic base material with a thin metallic coating which comprises supporting said base material in an enclosed space, purging said space of air, atomizing a liqueed heat-decomposa-ble gaseous metal compound as fine droplets and propelling the same in the form of a spray toward the metal base to be coated, converting the liquid droplets to a vapor immediately adjacent the surface of said base, and maintaining said base material heated to a temperature at which the vaporous metal compound decomposes depositing the metal constituent on said base.
  • the method of covering metallic base material with a thin metallic coating which comprises bringing a said base material into the eX- tremity of the effective throwing range of atomizing equipment, heating said base material and its immediate Vicinity, atomizing a. liqueed gaseous metal compound decomposable at the temperature of said base material as fine droplets by contacting a stream of said liqueed gaseous metal compound with a blast of inert gas, vaporizing the droplets in iiight in the said immediate vicinity of said metal base, and decomposing the vapors by the heat of said base material to cause deposition of the meta-l contained therein on said base.
  • the method of covering a base material with a metallic coating which comprises: bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its vicinity, atomizing a liquefied gaseous metal compound decomposable at the temperature of said base material as iine droplets by contacting a stream of said liquefied gaseous metal compound with a blast of inert gas maintained at a temperature eiiective to cause vaporization of said liquefied compound in flight and ineiective to cause substantial decomposition thereof, said droplets being vaporized in flight in the immediate vicinity of said base and decomposing the vapors by the heat of said base material to cause deposition of the metal contained therein on said base.
  • the method of covering metallic base material with a thin metallic coating which comprises: bringing said base material into the extremity of the eective throwing range of atomizing equipment, heating said base material and its vicinity to a temperature in the range of 250 F. to 400 F., atomizing a liqueed gaseous metal compound decomposable at the temperature of said base material as fine droplets by contacting said Fluid With a blast of inert gas maintained under a pressure in the range of 75 to 90 pounds per square inch, vaporizing said droplets in flight in the said vicinity of said base, and decomposing the resultant vapors by the heat of said base material to cause deposition of the metal contained therein on said base.
  • the method of covering metallic base material with a thin metallic coating which comprises: bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its immediate vicinity to a temperature in the range of 350 F. to 450 F., atomizing a liquefied heat-decomposable gaseous metal compound selected from the groups consisting of metal carbonyl and metal hydrides decomposable by Contact with metal maintained at a temperature in the above range, vaporizing the atomized liqueed metal compound in iiight in the said immediate vicinity of said base, and maintaining said base material heated to said temperature range to cause said vaporized metal compound to decompose and deposit the metal contained therein on said base.
  • the method of covering metallic base material with a thin metallic coating which comprises bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its immediate vicinity to a temperature in the range of 375 F. to 425 atomizing a liqueed gaseous metal compound consisting at least partially of at least one carbonyl selected from the groups consisting of nickel, iron, chromium, molybdenum, tungsten, and which is decomposable by contact with metal maintained at a temperature in the above range, vaporizing said atomized liquefied gaseous compound in iiight in the said immediate vicinity of said base, and decomposing the resultant vapors by maintaining said base material heated within said temperature range whereby said vaporized metal compound is decomposed and the metal contained therein deposited on said base.
  • the method of covering metallic base material with a thin metallic coating which comprises supporting the base in an enclosed space, purging the space of air, atomizing 2 pounds per minute of liqueed nickel carbonyl as iine droplets which are directed in the orm of a spray toward the metal base to be coated, vaporizing the droplets in iiight in the vicinity of said metal base, and maintaining the base at a temperature of about 390 F. to heat decompose said vaporized droplets and cause deposition of the metal constituent thereon on said base material.
  • the method of covering a copper base with a thin metallic coating of nickel which comp-rises: supporting the copper base in an enclosed space, purginfr the space of air, atomizing liqueiied nickel carbonyl as ne droplets which are directed in the form of a spray toward the copper base at a rate of about l pound of nickel car bonyl per minute, vaporizing the droplets in ight in the vicinity of said metal base, and maintaining said copper base heated to a temperature in the range of 375 F. to 400 F. to cause decomposition of said vaporized droplets and deposition of the metal constituent thereof on said copper base.
  • the method of covering a steel base with a thin metallic coating of cobalt which comprises: supporting the steel base in an enclosed space, purging the space of air, atomizing cobalt carbonyl as iine droplets whose flight is propelled in the form of a spray toward said base, vaporizing the droplets in flight in the vicinity of said metal base, heating the base t0 a temperature in the range of 375 F. to 425 F., and removing the decomposition products to maintain a reduced pressure in the chamber.
  • the method of covering a copper base with a thin metallic coating of r,rxtrnony hydrde which comprises supporting the copper base in an enclosed space, purging the space of air, atomizing antmony hydride as fine droplets Whose fright is propelled in the form 01"' a spray toward. said base, vaporzing the droplets in flight in the Vicinity of said metal base, heating the base to a temperature in the range of L100" F. to 450 F., and removing the decomposition products to maintain a reduced pressure in 'the Chamber.

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Description

NOV. 25, 1952 Q F DAVlS ET AL 2,619,433
METHOD OF GAS PLATIN@ Filed July 14, 1949 2 SHEETS--SHEET l ATTORNEYS Nov. 25, 1952 o. E. lDAVIS ET AL 2,619,433
METHOD oF GAS PLATIN@ Filed July 14, 1949 l2 SHEETS-SHEET 2 OLIVER F. D AVIS HANS G. BELITZ @Mem ATTORNEYS Y Patented Nov. 25, 1952 METHODr OF GAS PLATING Oliver F. Davis, Troy, and Hans G. Belitz, Dayton,
Ohio,4 assignors to The Commonwealth Engineering Company of Ohio, Dayton, Ohio, a
corporation of Ohio Application July'14, 1949, Serial No. 104,754
12 Claims.
This invention relates to, thel art of deposition of metals. More particularly it relates to coating of metal bases. Still more particularly it relates to the plating of objectsl by thel 'deposition of metal from readily decomposed volatile metal bearing compounds and apparatus for carrying out thel process.
Depositing of thin film of metals, such as iron, nickel, cobalt, upon metal bases has beenv accompl-ished in the past` by enclosing an object. to be plated in a chamber sealed against entry of air.
The chamber was purged with carbon dioxide and the object heated to a temperature at which volatile metal car'bonyls` decompose.
Following this a metal carbonyl gas was carbureted into a stream of carbon dioxide to form a dilute carbonyl mediuml which was metered into the chamber. Upon coming in contact with the hot metal the carbonyl was decomposed and the metal component deposited.
This process has many ydisadvantages which limit its usefulness. While the chamber is lled with a -mixture of inert gas and metal carbonyl vapors, plating only occurs when the carbonyl vapor ycontacts the hot object and general decomposition mayV take place, with the result that powdered metal accumulates in the bott-omof, the chamber.
Further, the deposition rate is very slow and the process requires hou-rs. to build up. an appreciable depth of metal coating. In addition', the coatings are brittle andA adheredY poorly` to the base metal.
In another process,y utilizing quite similar equipment, the brittleness and D001- adhesion has been largely overcome. In this process the metal deposition is carried out in two stages.
After a thin layer of metal is deposited the object is subjected to heat treatment at a temperatureof between 500 and 800 Fl to desorb the occluded gases. The object was then returned to the chamber and a second coating of the desired thickness over the rst layer deposited thereon.
This process, while producingadhering metal coatings, is still a time consumi-ng one. It also requires that the plating cycle be interrupted with consequent loss of materials due to purging the equipment to avoid formation of explosive mixtures of carbonyl gases with air.
It is anv object of this invention to overcome the limitations and disadvantages of the above described processes.
It is another object of this invention to provide a process in which the time for ldepositing any thickness of coating is markedly shorter than heretofore.
yIt -is another object of this invention to produce thicker adhering coatings than have lbeen produced heretofore.
It is another object of this invention to provide a process wherein the metal carbonyl is not brought into the reaction zone in a dilute weak plating vapor state.
It is another object to provide a process which may be operated under eitherpositive or negative pressure conditions.
'Ity is ,a further object of this invention to provide a process wherein the decomposition gases are quickly removed from the plating,` area. to eliminate contamination of. the deposited metal film.
yIt isa still further obje-ct of this invention` to prov-ide a process for continuous and rapid deposition of bright metal coatings by directing the decomposable metal material to the met-al surface.
It is still a further object of this invention to provide a simplified method 4and apparatus for depositing metal froma volatile metal compound by continuously decomposing the compound and conducting the gaseous product resultantl from the decomposition away from contact: with hot metal in order to avoid decontamination and dulling of the bright deposit.
It is sti-ll another object of thisinvention to provide a process; wherein the dec.omposable,n1a terial is not brought up to a decomposition temperat-ure before it isv in the direct plating zone..
Other and morev specific objects and advantages will be apparent to one. skilled in the art as the following description proceeds:
In this new process the plating composition is introduced into the deposition chamber as a liquid instead of a gas. In` this way itis possible to concentrate the stream of metal bearing materialat the heated surface.
The atmospherev in the neighborhood of the surface lto be coated in thus made up merely of fresh liquid propelled with force by the gas blast into the deposition zone and encountering mainly the hot gaseous decomposition products which are being removed as, for example, by suction or vacuum drawn on the chamber.
This invention makes it possible to utilize metal carbonyls, also nitroxyl compounds, nitrosyl carbonyls, metal hydrides, metal alkyls, metal halides, metal carbonyl halogens, and the like, which are either liquids at normal temperature and pressure conditions, or gases compressible to liquid under any commercial feasible temperature conditions or solids convertible to liquids at temperatures below` the decomposition temperature of the compound, or to utilize solutions of carbonyls in volatile solvents such as petroleum ether.
Useful metals which may be deposited from the metallic carbonyl compounds are nickel, iron, chromium, molybdenum, tungsten, cobalt, tellurium, rhenium, and the like.
Illustrative compounds of the other groups are ntroxyls, such as copper nitroxyl, nitrosyl carbonyls, for example, cobalt nitrosyl carbonyl, hydrides, such as tellurium hydride, geleniurn hydride, antimony hydride, tin hydride, chromium hydride, the mixed organo-metallo hydrides such as dimethyl alumino hydride, metal alkyls such as tetraethyl lead, metal halides such as chromyl chloride, and carbonyl halogens such as rhodium carbonyl chloride, osmium carbonyl bromide, ruthenium carbonyl chloride, and the like.
When introducing the liquid products into the closed chamber, the liquid is broken up into a fine spray by a blast of inert gas. Apparatus of this type usually delivers the liquid to the orifice through a central pipe.
The inert gas is usually fed to the mixing point through an annular chamber surrounding the central pipe. The quantity of liquid atomized iF controlled by adjustment of the orifice area Commercial equipment, such as fog nozzles or fine spray nozzles, such as the DeVilbis paint spray gun, can be readily adapted for use as the spraying means.
Carbon dioxide, helium, nitrogen, hydrogen, the gaseous product of controlled burning of hydrocarbon gases free of oxygen, mixtures of these gases, and the like, have been utilized as the gas i surface is somewhat critical in order to convert f the liquid to a gas at a point in close proximity to the plating surface. What this distance may be is readily determinable for any particular combination of liquid, temperatureof the blasting gas and temperature of the plating object, I.
iineness' of the spray, and so forth. However, in View of the many ways in which the conditions may be varied, it will be seen that an exact number of inches would only apply to specific conditions, and that the critical thing really is that the liquid not impinge on the plating surface as a strong liquid spray.
Each material from which a metal may bg plated has a temperature at which decomposition is complete. However, decomposition may take place slowly at a lower temperature or while the vapors are being raised in temperature through some particular range. For example, nickel carbonyl completely decomposes at a temperature in the range of 375 F. to 400 T. However, nickel carbonyl starts to decompose slowly at about 175 F., and therefore, decomposition continues during the time of heating from 200 F. to 380 F. A large number of the metal carbonyls and hydrides may be effectively and elciently decomposed at a temperature in the range of 350 F. to 450 F. When working with most carbonyls we prefer to operate in a temperature range of 375 F. to 425 F.
It will be seen thus that the presentl invention is markedly superior to the processes utilized heretofore, because it accomplishes all of its decomposition quickly in close proximity to the heated surface area and because the liquid when converted to a vapor is then decomposed without delay as the carbonyl or nitrosyl or hydride compounds come in contact with the hot object to be plated.
Maintenance of the metal objects at temperatures in the general operating range is easily accomplished with numerous heating means, such as radiant heating, electrical resistance heating, induction heating, and the like.
The material to be decomposed is readily brought to the decomposition temperature by atomizing the liquid with hot inert gas. The fine spray of liquid can thus be transformed from say 100 F. to temperatures of between 200 F. and 300 F. in a fraction of a second and the liquid converted'toagas.
This transformation to a gas takes place in the vicinity of the hot object to be plated, giving the process excellent integration for obtaining efficient operation.
Preparatory to coating base material the metal strip or object to be plated may be cleaned by employing the conventional methods used in the art, comprising electro-chemically cleaning by moving same through a bath of alkali or acid electrolyte, wherein the strip is made the cathode or anode.
Pickling of the metal with hydrochloric, sulfuric, or nitric acid, or a combination of acids, may also be made as a part of the cleaning process and the strip thoroughly rinsed or washed and dried prior to introduction into the plating apparatus of this invention.
The process will be more readily understood from a description of the process with reference to the apparatus and the specific examples.
In the drawings:
Figure 1 is a vertical sectional view showing diagrammatically one embodiment of the apparatus of this invention;
Figure 2 is a vertical sectional view of the apparatus taken substantially on the line 2-2 of Figure 1 and looking in the direction of the arrows; and
Figure 3 is a Vertical sectional view along the line 3-3 of Figure 1.
Referring to the drawings in detail, there is shown an object I0 which may be a stationary positioned object or a moving sheet or the like. The object here shown is illustrated as stationary and suspended from a support I'I. Adjacent the 'object is a support I2 from which is suspended suitable heating means I3, such as an electrical resistancecoil masked with a Asuitable covering I4 which prevents plating on lthe heating element.
Supports II and I2 are secured in the wall of an air tight chamber I5. This chamber is provided with an aperture I6 for introduction and removal of objects to be plated. The aperture I6 is fitted with releasable closure means II rendered air tight by a suitable gasket I8.
Surrounding the chamber I5 is a metal jacket I9 having therein a closed space 20 through which a suitable medium, such as water, may be circulated. The space 29 is shown in communication with an inlet 2I and an outlet 22.
If pressure above atmospheric pressure is to be maintained in the chamber I5, an inert gas may be introduced by suitable means 25, such as a fan or blower.
Blower 25. is shown, taking' suction on a. surge tank; supplied with gas from a storage tank as indicated and introducing the gas aty the chamber inlet 21.
If pressures below atmospheric are to be maintained the chamber outlet pipe 26a comvmunicating with the chamber through outlet 26 may be connected at the point indicated at 25h with a vacuum pump or exhaust fan. The exhausted gases which are a mixture of inert gas and carbon monoxide may, if desired, be scrubbed to remove inert gas such as carbondoxide, and the puried carbon monoxide returned to a metal carbonyl generator to conserve carbon monoxide. Liquid is introduced into the chamber through the rightwardly Wall 28 of chamber I5 by suitable spray means 3B. Spray means 30 consists of a central liquid tube 3I connected to a source of liquid 32.
The tube 3I is surrounded by a tube 33 mounted with a laterally adjustable head 34, adapted with an external gear 35. Gear 35 is actuated by a gear 36 attached to a rod 31 which extends through a sealed bushing 38 to a manually oper able position outside the chamber I5.
Tube 33 is connected to a suitable source ci inert gas 39 through pipe 40. Chamber I5 is provided with a suitable Window 42 more completely shown in Figure 3. This Windowcomprises an `inner pane 43 of glass or clear resin joined in air tight seal to the chamber I by suitable gasket means 44. The gasketing also seals tightly to an outer glass pane 45 to form between said panes an air pocket 45.
This arrangement provides a clear View of the plating and spray adjustment apparatus without rdanger of carbon-monoxide leakage to the area `Where operators might be stationed.
In Figure 2 there is also shown a thermometer 48 suitably sealed in the Wall of chamber I5 and the jacket I9 and extending outside the plating chamber for visual observation.
Conditions of operation of the process With relation to speoic plating operations carried out in the above described apparatus will be set forth in the following examples:
Example I Aluminum discs may be suspended from the support II. The chamber may then be sealed and purged of air by passing carbon dioxide gas therethrough. When the chamber I5 is purged the discs may be heated by conduction due to intimate contact with resistance heater I3. At this time the Water may be started circulating in jacket I9 to maintain the chamber at a cool non-plating temperature.
When the thermometer 48 records temperature in the vicinity of the discs at approximately 390 F., nickel carbonyl may be introduced into the chamber by spray means 3D. This lnickel carbonyl may be under a pressure of about 50 pounds per square inch and sprayed at the rate of about 2 pounds of nickel carbonyl per minute.
The spraying means may be carbon dioxide maintained under a pressure of about '75 pounds per square inch. The decomposition of nickel carbonyl produces 4 volumes of carbon monoxide gas for each molecular Weight of liquid introduced. The gasses may be removed by an exhaust fan which maintains a pressure in the chamber of between l and 2 inches of H2O vacuum.
Under these conditions small discs may be plated to a thickness of many hundredths of an inch in ai matter off seconds with a smooth. .coatcing. V- Example II A lead pattern may be introduced into' the apparatus of Example I in place of the aluminum disc.
The operation may be carried out in a similar manner,` using nickel carbonyl sprayed into vthe chamber at a rate of about 21/2 pounds of liquid per minute.
In this operation the inert atmosphere may be hydrogen gas. The liquid may be sprayed using hydrogen as the blasting gas, which gas is under a pressure of` pounds per square inch and at a temperature of 200 F.
The lead pattern may be heated -to a temperature of approximately 375 F. and in the presence of hydrogen the nickel carbonyl vplated to a brightv metallic clean surface.
Example III A canbon steel'plate may be introduced into lthe chamber of Example I and the process run Aunder the following conditions:
The liquid supplied to the spray apparatus may be cobalt carbonyl. The inert gas circulated `in the chamber may be nitrogen from a source maintained under a pressure slightly above atmospheric.
Temperature of the steel plate may be maintained at approximately 410 F. The cobalt carbonyl may be introduced at a liquid flow rate of approximately 4 pounds of canbony-l per minute.
In order to remove the decomposition products and the circulating nitrogen, the gases are exhausted utilizing vacuum equipment capable of maintaining a pressure within the chamber of approximately 3 inches of Water vacuum.
A smooth coating of cobalt mayy be thus deposited on 'large plates in a matter of minutes.
Example IV Copper discs may be .introduced into the chamber Aexplained in conjunction with Example I and the. process operated under the following condi.- tions:
Copper discs may be heated to approximately 38u F. The chamber may be purged with hydrogen, and hydrogen gas may be used as the spraying medium. Antimony `hydride may be introduced into the chamber through the spray ap.- paratus ata rate of approximately 3 poundsvper minute. These copper discs of 3 inch diameter may be plated to a depth of .025 inch with metallic antimony-in a fraction of a minute.
It will I be understood that While there have been given herein certain specic examples of the practice of this invention, it is not intended thereby to have this invention limited to or circumscribed by the specic details herein specified, in view of the fact that this invention may be modifled according to individual preference or conditions Without necessarily departing from the spirit of this disclosure and the scope of the appended claims.
We claim:
1. The method of coating base material with a metallic coating which comprises: atomizing a llqueed heat decomposable Vgaseous metal com pound as ine droplets and propelling the samein rthe form of a spray toward the surface of the said base material to be coated, continuously maintaining lbase material and its immediate vicinity at a temperature for vaporising of said' 7 droplets, and bringing about rapid decomposition of said metal compound and rapid deposition of metal contained in said vaporous compound on said base material.
2. The method of coating base material with a metallic coating which comprises: atomizing a liquefied heat-decomposable gaseous metal compound as fine droplets and propelling the same in the form of a spray toward the base material to be coated, vaporizing the droplets in flight in the immediate vicinity of said base material, and maintaining said base material at a temperature to cause decomposition of the vaporous compound and deposition of metal thereon.
3. The method of covering metallic base material with a thin metallic coating which comprises supporting said base material in an enclosed space, purging said space of air, atomizing a liqueed heat-decomposa-ble gaseous metal compound as fine droplets and propelling the same in the form of a spray toward the metal base to be coated, converting the liquid droplets to a vapor immediately adjacent the surface of said base, and maintaining said base material heated to a temperature at which the vaporous metal compound decomposes depositing the metal constituent on said base.
4 The method of covering metallic base material with a thin metallic coating which comprises bringing a said base material into the eX- tremity of the effective throwing range of atomizing equipment, heating said base material and its immediate Vicinity, atomizing a. liqueed gaseous metal compound decomposable at the temperature of said base material as fine droplets by contacting a stream of said liqueed gaseous metal compound with a blast of inert gas, vaporizing the droplets in iiight in the said immediate vicinity of said metal base, and decomposing the vapors by the heat of said base material to cause deposition of the meta-l contained therein on said base.
5. The method of covering a base material with a metallic coating which comprises: bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its vicinity, atomizing a liquefied gaseous metal compound decomposable at the temperature of said base material as iine droplets by contacting a stream of said liquefied gaseous metal compound with a blast of inert gas maintained at a temperature eiiective to cause vaporization of said liquefied compound in flight and ineiective to cause substantial decomposition thereof, said droplets being vaporized in flight in the immediate vicinity of said base and decomposing the vapors by the heat of said base material to cause deposition of the metal contained therein on said base.
6. The method of covering metallic base material with a thin metallic coating which comprises: bringing said base material into the extremity of the eective throwing range of atomizing equipment, heating said base material and its vicinity to a temperature in the range of 250 F. to 400 F., atomizing a liqueed gaseous metal compound decomposable at the temperature of said base material as fine droplets by contacting said Fluid With a blast of inert gas maintained under a pressure in the range of 75 to 90 pounds per square inch, vaporizing said droplets in flight in the said vicinity of said base, and decomposing the resultant vapors by the heat of said base material to cause deposition of the metal contained therein on said base.
7. The method of covering metallic base material with a thin metallic coating which comprises: bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its immediate vicinity to a temperature in the range of 350 F. to 450 F., atomizing a liquefied heat-decomposable gaseous metal compound selected from the groups consisting of metal carbonyl and metal hydrides decomposable by Contact with metal maintained at a temperature in the above range, vaporizing the atomized liqueed metal compound in iiight in the said immediate vicinity of said base, and maintaining said base material heated to said temperature range to cause said vaporized metal compound to decompose and deposit the metal contained therein on said base.
8. The method of covering metallic base material with a thin metallic coating which comprises bringing said base material into the extremity of the effective throwing range of atomizing equipment, heating said base and its immediate vicinity to a temperature in the range of 375 F. to 425 atomizing a liqueed gaseous metal compound consisting at least partially of at least one carbonyl selected from the groups consisting of nickel, iron, chromium, molybdenum, tungsten, and which is decomposable by contact with metal maintained at a temperature in the above range, vaporizing said atomized liquefied gaseous compound in iiight in the said immediate vicinity of said base, and decomposing the resultant vapors by maintaining said base material heated within said temperature range whereby said vaporized metal compound is decomposed and the metal contained therein deposited on said base.
9. The method of covering metallic base material with a thin metallic coating which comprises supporting the base in an enclosed space, purging the space of air, atomizing 2 pounds per minute of liqueed nickel carbonyl as iine droplets which are directed in the orm of a spray toward the metal base to be coated, vaporizing the droplets in iiight in the vicinity of said metal base, and maintaining the base at a temperature of about 390 F. to heat decompose said vaporized droplets and cause deposition of the metal constituent thereon on said base material.
10. The method of covering a copper base with a thin metallic coating of nickel which comp-rises: supporting the copper base in an enclosed space, purginfr the space of air, atomizing liqueiied nickel carbonyl as ne droplets which are directed in the form of a spray toward the copper base at a rate of about l pound of nickel car bonyl per minute, vaporizing the droplets in ight in the vicinity of said metal base, and maintaining said copper base heated to a temperature in the range of 375 F. to 400 F. to cause decomposition of said vaporized droplets and deposition of the metal constituent thereof on said copper base.
ll. The method of covering a steel base with a thin metallic coating of cobalt which comprises: supporting the steel base in an enclosed space, purging the space of air, atomizing cobalt carbonyl as iine droplets whose flight is propelled in the form of a spray toward said base, vaporizing the droplets in flight in the vicinity of said metal base, heating the base t0 a temperature in the range of 375 F. to 425 F., and removing the decomposition products to maintain a reduced pressure in the chamber.
12. The method of covering a copper base with a thin metallic coating of r,rxtrnony hydrde which comprises supporting the copper base in an enclosed space, purging the space of air, atomizing antmony hydride as fine droplets Whose fright is propelled in the form 01"' a spray toward. said base, vaporzing the droplets in flight in the Vicinity of said metal base, heating the base to a temperature in the range of L100" F. to 450 F., and removing the decomposition products to maintain a reduced pressure in 'the Chamber.
OLIVER, F. DAVIS.
HANS G. BELITZ.
CES CTED The following references are of record in the e of this patent:
Number Number 10 UNITED STATES PA'IENTS Name Date Sohoop May 13, 1930 Lang Mar. 27, 1934 Beck Oct. 8, 1940 Germer et al. May 23, 1950 FOREIGN PATENTS Country Date Great Britain June 20, 1930

Claims (1)

1. THE METHOD OF COATING BASE MATERIAL WITH A METALLIC COATING WHICH COMPRISES: ATOMIZING A LIQUEFIED HEAT DECOMPOSABLE GASEOUS METAL COMPOUND AS FINE DROPLETS AND PROPELLING THE SAME IN THE FORM OF A SPRAY TOWARD THE SURFACE OF THE SAID BASE MATERIAL TO BE COATED, CONTINUOUSLY MAINTAINING BASE MATERIAL AND ITS IMMEDIATE VICINITY AT A TEMPERATURE FOR VAPORIZING OF SAID DROPLETS, AND BRINGING ABOUT RAPID DECOMPOSITION OF SAID METAL COMPOUND AND RAPID DEPOSITION OF METAL CONTAINED IN SAID VAPOROUS COMPOUND ON SAID BASE MATERIAL.
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US313738A US2728321A (en) 1949-07-14 1952-10-08 Apparatus for gas plating

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Cited By (28)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2694377A (en) * 1951-10-08 1954-11-16 Ohio Commw Eng Co System of gas plating
US2698812A (en) * 1949-10-21 1955-01-04 Schladitz Hermann Metal deposition process
US2728321A (en) * 1949-07-14 1955-12-27 Ohio Commw Eng Co Apparatus for gas plating
US2746134A (en) * 1953-05-22 1956-05-22 Ohio Commw Eng Co Duplex metal sheet or article
US2753800A (en) * 1952-03-24 1956-07-10 Ohio Commw Eng Co Production of printing plates
US2793140A (en) * 1953-10-20 1957-05-21 Ohio Commw Eng Co Method of gas plating with a chromium compound and products of the method
US2813803A (en) * 1955-06-22 1957-11-19 Ohio Commw Eng Co Method for the production of composite metallic material
US2824828A (en) * 1955-05-12 1958-02-25 Ohio Commw Eng Co Colored glass fibers and method of producing the same
US2881518A (en) * 1956-11-23 1959-04-14 Ohio Commw Eng Co Continuous gas plated metal article
US2887089A (en) * 1955-06-22 1959-05-19 Ohio Commw Eng Co Gas plating apparatus
US2898230A (en) * 1954-04-08 1959-08-04 Ohio Commw Eng Co Process of cleaning and coating aluminum
US2898234A (en) * 1953-08-14 1959-08-04 Ohio Commw Eng Co Method of producing composite metallic bodies
US2905573A (en) * 1957-12-10 1959-09-22 Union Carbide Corp Method of gas plating
US2916400A (en) * 1957-02-25 1959-12-08 Union Carbide Corp Gas plating with tin
US2919207A (en) * 1956-01-24 1959-12-29 Max Braun Method of applying a ferromagnetic surface to a base utilizing iron carbonyl and oxygen
US2929739A (en) * 1958-11-07 1960-03-22 Union Carbide Corp Aluminum plating
US2934820A (en) * 1954-04-15 1960-05-03 Union Carbide Corp Metal-to-metal adhesive bonding
US2970068A (en) * 1955-03-07 1961-01-31 Union Carbide Corp Method of making a composite stock
US2982016A (en) * 1955-04-12 1961-05-02 Union Carbide Corp Method of gas plating an alloy of aluminum and magnesium
US2989421A (en) * 1957-06-18 1961-06-20 Union Carbide Corp Gas plating of inert compounds on quartz crucibles
US3055087A (en) * 1954-06-07 1962-09-25 Union Carbide Corp Carbonyl metal plated product
US3109228A (en) * 1959-08-10 1963-11-05 Thermway Ind Inc Manufacture of electric radiant heating panels
US3111731A (en) * 1958-10-17 1963-11-26 Union Carbide Corp Die construction
US3119710A (en) * 1961-05-31 1964-01-28 Standard Oil Co Process of applying an aluminum oxide coating from a hydrocarbon aluminum compound
US3121925A (en) * 1960-08-16 1964-02-25 Jr Harry A Toulmin Method and apparatus for making honeycomb structures
US3214288A (en) * 1961-12-14 1965-10-26 Nat Steel Corp Process for the deposition of metallic aluminum
US3305386A (en) * 1955-10-05 1967-02-21 Union Carbide Corp Metal plating process utilizing bis (arene) metal compounds
US3464844A (en) * 1967-03-02 1969-09-02 Continental Oil Co Aluminum plating of surfaces

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GB306902A (en) * 1928-02-27 1930-06-20 Siemens Ag A process for the metallisation of thermally unstable substances, more particularly of organic electrically insulating substances
US1952760A (en) * 1929-04-10 1934-03-27 Lang Niels Metallic coating apparatus
US2217039A (en) * 1938-06-02 1940-10-08 Mark F Beck Printing and reproduction plate
US2508590A (en) * 1944-07-14 1950-05-23 Acrojet Engineering Corp Jet motor with cooling system

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Publication number Priority date Publication date Assignee Title
US1758473A (en) * 1924-06-30 1930-05-13 Schoop Max Ulrich Coating articles, particularly with metals
GB306902A (en) * 1928-02-27 1930-06-20 Siemens Ag A process for the metallisation of thermally unstable substances, more particularly of organic electrically insulating substances
US1952760A (en) * 1929-04-10 1934-03-27 Lang Niels Metallic coating apparatus
US2217039A (en) * 1938-06-02 1940-10-08 Mark F Beck Printing and reproduction plate
US2508590A (en) * 1944-07-14 1950-05-23 Acrojet Engineering Corp Jet motor with cooling system

Cited By (28)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2728321A (en) * 1949-07-14 1955-12-27 Ohio Commw Eng Co Apparatus for gas plating
US2698812A (en) * 1949-10-21 1955-01-04 Schladitz Hermann Metal deposition process
US2694377A (en) * 1951-10-08 1954-11-16 Ohio Commw Eng Co System of gas plating
US2753800A (en) * 1952-03-24 1956-07-10 Ohio Commw Eng Co Production of printing plates
US2746134A (en) * 1953-05-22 1956-05-22 Ohio Commw Eng Co Duplex metal sheet or article
US2898234A (en) * 1953-08-14 1959-08-04 Ohio Commw Eng Co Method of producing composite metallic bodies
US2793140A (en) * 1953-10-20 1957-05-21 Ohio Commw Eng Co Method of gas plating with a chromium compound and products of the method
US2898230A (en) * 1954-04-08 1959-08-04 Ohio Commw Eng Co Process of cleaning and coating aluminum
US2934820A (en) * 1954-04-15 1960-05-03 Union Carbide Corp Metal-to-metal adhesive bonding
US3055087A (en) * 1954-06-07 1962-09-25 Union Carbide Corp Carbonyl metal plated product
US2970068A (en) * 1955-03-07 1961-01-31 Union Carbide Corp Method of making a composite stock
US2982016A (en) * 1955-04-12 1961-05-02 Union Carbide Corp Method of gas plating an alloy of aluminum and magnesium
US2824828A (en) * 1955-05-12 1958-02-25 Ohio Commw Eng Co Colored glass fibers and method of producing the same
US2887089A (en) * 1955-06-22 1959-05-19 Ohio Commw Eng Co Gas plating apparatus
US2813803A (en) * 1955-06-22 1957-11-19 Ohio Commw Eng Co Method for the production of composite metallic material
US3305386A (en) * 1955-10-05 1967-02-21 Union Carbide Corp Metal plating process utilizing bis (arene) metal compounds
US2919207A (en) * 1956-01-24 1959-12-29 Max Braun Method of applying a ferromagnetic surface to a base utilizing iron carbonyl and oxygen
US2881518A (en) * 1956-11-23 1959-04-14 Ohio Commw Eng Co Continuous gas plated metal article
US2916400A (en) * 1957-02-25 1959-12-08 Union Carbide Corp Gas plating with tin
US2989421A (en) * 1957-06-18 1961-06-20 Union Carbide Corp Gas plating of inert compounds on quartz crucibles
US2905573A (en) * 1957-12-10 1959-09-22 Union Carbide Corp Method of gas plating
US3111731A (en) * 1958-10-17 1963-11-26 Union Carbide Corp Die construction
US2929739A (en) * 1958-11-07 1960-03-22 Union Carbide Corp Aluminum plating
US3109228A (en) * 1959-08-10 1963-11-05 Thermway Ind Inc Manufacture of electric radiant heating panels
US3121925A (en) * 1960-08-16 1964-02-25 Jr Harry A Toulmin Method and apparatus for making honeycomb structures
US3119710A (en) * 1961-05-31 1964-01-28 Standard Oil Co Process of applying an aluminum oxide coating from a hydrocarbon aluminum compound
US3214288A (en) * 1961-12-14 1965-10-26 Nat Steel Corp Process for the deposition of metallic aluminum
US3464844A (en) * 1967-03-02 1969-09-02 Continental Oil Co Aluminum plating of surfaces

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