US2405662A - Coating - Google Patents

Coating Download PDF

Info

Publication number
US2405662A
US2405662A US409090A US40909041A US2405662A US 2405662 A US2405662 A US 2405662A US 409090 A US409090 A US 409090A US 40909041 A US40909041 A US 40909041A US 2405662 A US2405662 A US 2405662A
Authority
US
United States
Prior art keywords
metal
coating
strip
aluminum
coated
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US409090A
Inventor
Charles E Mcmanus
John D Elder
Giles B Cooke
Albert J Dornblatt
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Crown Cork and Seal Co Inc
Original Assignee
Crown Cork and Seal Co Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Crown Cork and Seal Co Inc filed Critical Crown Cork and Seal Co Inc
Priority to US409090A priority Critical patent/US2405662A/en
Application granted granted Critical
Publication of US2405662A publication Critical patent/US2405662A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F9/00Making metallic powder or suspensions thereof
    • B22F9/02Making metallic powder or suspensions thereof using physical processes
    • B22F9/12Making metallic powder or suspensions thereof using physical processes starting from gaseous 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
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/0005Separation of the coating from the substrate
    • 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
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/14Metallic material, boron or silicon
    • C23C14/16Metallic material, boron or silicon on metallic substrates or on substrates of boron or silicon
    • 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
    • C23C14/32Vacuum evaporation by explosion; by evaporation and subsequent ionisation of the vapours, e.g. ion-plating

Definitions

  • the present invention relates to a method of coating with metallic vapors, and is particularly concerned with a novel product such as steel sheet or black iron having a coating of aluminum bonded thereto and articles formed therefrom.
  • the method of the invention includes the coating of a base which may be a continuous strip or length of material, as well as preformed articles, to produce on the base a permanently adherent surface film which is deposited Or precipitated from an atmosphere of the vaporized coating metal.
  • This coating can be determined as being produced from the metallic vapor by metallographic examination and X ray diffraction studies.
  • the resultant laminated product exhibits characteristics which enable the coated metal to be formed and shaped, for example, (a) stamped into closure caps, particularly those of the skirted type such as crown, screw and lug caps, (22) pressed or drawn for use in the making of containers, and (c) spun to form articles which are best prepared by such operation, namely, bottles, reflectors, and goblets.
  • the coated metal repared in accordance with this invention is useful in a wide variety of applications where the base metal, if not protected, would ultimately present an objectionable appearance and in the case of containers, might affect the quality of the contents.
  • the aluminum coating produced from the vaporized metal is characterized by having a purity greater than that of customary aluminum coatings; in fact, the distillation of the aluminum enhances the purity of the coating so that it is substantially pure.
  • the coating of a base such as steel, in accordance with this invention does not result in any impairment of the properties of the steel, 1. e., the advantageous properties of the base are substantially unaffected by the coating film.
  • the coating of the steel with vaporized metal is accomplished without substantially raising the temperature of the metal or otherwise heating it in a manner which might objectionably afiect its desired properties.
  • the laminated product does not have a brittle intermediate zone or constituent, i. e., is substantially free of brittle intermetallic iron-aluminum compounds such as are frequently present where steel is coated by dipping in molten aluminum.
  • the composite product has all the ductility of uncoated steel and is substantially free of brittleness.
  • the coated metal to be employed for many forming operations.
  • the flexibility, rigidity and tensile strength of the base metal are not sacrificed and the resulting product possesses the advantageous properties or both the steel and of the metal coating.
  • a very important characteristic of the coated metal is its corrosion resistance. Not only does the aluminum coating protect the iron from corrosion, but it inherently possesses resistance to corrosion and is therefore suitable for many situations where corrosive influences would deleteriously affect the metal base.
  • Another characteristic of the laminated product 0r coated metal is the galvanic protection afforded by the direct coating of the vaporized metal such as aluminum upon the base metal such as steel or black iron.
  • the steel is rendered rustproof and is prevented from discoloring and may be employed in containers for foods and beverages.
  • coated metal Further attributes of the coated metal are the pleasing brightness and high reflectivity for radiant energy. These qualities of the coated metal make it available for walls in low-cost housing and for various applications where heat and/or light reflectivity is desirable.
  • the abrasion resistance of the coated metal is satisfactory but the coating may be oxidized and hardened to give enhanced abrasion resistance for certain purposes.
  • Another important characteristic of the laminated product is the strong and permanent adherency or bonding of the aluminum coating to the metal base which makes the product suitable for the metal working processes as above described.
  • alloying of the two constituents can be controlled, 1. e., the difiusion between the atoms of the steel base and the coating, and a substantially integral bond is thereby produced without embrittlement.
  • the aluminum coated metal may be suitably decorated, printed, dyed, or otherwise colored". It may also be subjected to well-known processes of the type used for oxidizing pure aluminum or relatively high aluminum content alloys. By such -means an oxidized film is formed on the aluminum which readily permits impregnation by various dyes and offers an excellent base upon which organic finishes may be applied. The oxidized film may be produced under conditions which give it an extraordinary degree of hardness.
  • the coated metal may be worked and possesses the desired resistant qualities and receptivity for decoration, make it ideal for the manufacture of'screw caps, crown caps, and other skirted closures.
  • the coated metal is useful for makin containers and numerous other fabricated products.
  • this aluminum coated steel for example, forms a satisfactory substitute for the customarily employed tin plate prepared by usual practice and at less cost for the coating metal due to the thinness of the coating which is commercially satisfactory.
  • Another embodiment of the invention consists in applying an organic film such as lacquer, varnish or enamel or an inorganic vitreous enamel to the metal surface, e. g., steel either of a preformed article or a continuous strip, whereby any irregularities or pores therein are effectively sealed and a smooth surface for receiving the vaporized metal coat is provided.
  • Brittle enamels should not be used on continuous sheet metal which is wound in coils.
  • the adherent vaporized coating metal is applied, for example, to the organic coating and adheres thereto and forms a film bonded to the base which is characterized by remarkable brilliance due to the uniformity, continuity and smoothness resulting from the presence of the intermediate coating.
  • This improved lustrous or mirror-like finish is comparable'to a coating produced directly upon highly polished steel sheet when vaporized aluminum is deposited thereon as a film.
  • the product above described, in which the vaporized aluminum is directly deposited upon the steel is quite satisfactory, and in either the ease of th aluminum coated steel or the aluminum coated presurfaced steel, the properties of the steel are not sacrificed and the properties of aluminum are made available. Should there be any pores or, other lack of continuity in theintermediate coating film,
  • the metallic film will afford the desired galvanic and corrosion protection.
  • suitable films I invention is a foil which may be either of pure aluminum, or comprise thin backings of iron or steel of sufiicient softness and flexibility, paper,
  • plastics such as Vinylite or other synthetic resins, chlorinated rubber, zinc foil, etc. coated with a deposit of vaporized aluminum.
  • the thin metal strip is first coated with an intermediate film such as an organic film of varnish or lacquer :upon which the thin aluminum coating or layer-is deposited.
  • the pure aluminum foil may also be produced by depositing the coating upon a suitable non-retentive surface, e. g., steel coated with Apiezon oil or stearic acid, wherefrom the foil may be readily stripped off by any suitable means.
  • a suitable non-retentive surface e. g., steel coated with Apiezon oil or stearic acid, wherefrom the foil may be readily stripped off by any suitable means.
  • Foils produced in accordance with this invention are suitable for cap spotting purposes, heat insulation and for electrical condenser foils.
  • aluminum powder and flakes may be satisfactorily produced in accordance with this invention for use as pigments, in pyrotechnics and other applications, by depositing the vaporized aluminum upon a non-retentive surface such as stearic acid, or in a non-adherent form under controlled conditions, i. e., at a reduced pressure representing a, less highly exhausted state than that which is required to produce an adherent and continuous film and/or at a temperature of the metal base conducive to production of a spongy or powdery deposit, whereby a discontinuous film or otherwise powdery deposit is formed which may be readily removed.
  • the deposit so recovered will have the necessary fineness or in any case where a greater degree of fineness is desired, the size of the particles may be reduced in any suitable maimer.
  • a further embodiment of the invention consists in producing metal coated material having flexible strip material backings of paper, plastics such as 'Vinylite or other synthetic resins, chlorinated rubber, zinc foil, etc., by a transfer process in which the coating metal such as an aluminum film is first deposited from .the vapor state upon a nonretentive surface either .as a continuous film of foil thickness or as a thin discontinuous film.
  • Such laminated material may be of foil thickness or be of greater thickness as desired.
  • the metallized laminated product or foils produced by direct coating as above described or by the transfer process just mentioned may be used as foils for cap spotting purposes, packaging, insulating walls, as well as decorative purposes.
  • An important object of the invention is to provide a method in which a permanent, uniform and coextensive adherency between the coating and the base layer is assured which persists when the metal is worked, i. e., there is no evidence of peeling, nor cracking of the laminated product, and there is an absence of any objectionable brittlizecl condition.
  • the metal should be substantially free of occluded gases, and it is highly important that before the metal sheet or strip is subjected to the coating atmosphere, it be first not only physically and chemically cleaned, but degassed as completely as possible.
  • a chamber for accomplishing the coating operation which will permit continuous movement of a continuou strip or sheet to be coated through the same and which will be thoroughly sealed whereby a substantially constant reduced pressure or vacuum is maintained and the vaporized metal in the chamber is prevented from being excessively diluted, or polluted in a manner such as would adversely affect the color or adherence of thefilm. It may not be objectionable to have, for example, a trace of air, but the presence of an appreciable amount of certain vapors as fOr instance grease hydrocarbons, may cause the deposit to be blackened and be loosely adherent, whereas a silvery white or bright metallic film is desired.
  • the relative temperature of the metal base and the metal vapor source within the coating chamber are maintained under conditions to promote rapid precipitation of the metal upon the base strip moving through the chamber to form the coating film, and While in many cases preheating or subsequent heating of the metal will be unnecessary, there are conditions where it may be desirable to either heat Or cool the metal under vacuum to a satisfactory operating temperature before deposition.
  • the method provides for suitably heating the strip under vacuum for the purpose of removing any surface accumulations and occluded gases prior to its entrance into the coating chamber, and also for assuring in certain cases, i. e., aluminum upon steel, that a more adherent coating is obtained, and one which afiords an optimum coverage of the base metal.
  • the temperature of the metal is raised where necessary after the coating operation to further assure the maximum adherency and/or to improve the continuity of the deposited coating.
  • These heating steps may be accomplished in a protective atmosphere, but are preferably carried out under vacuum.
  • a particularly advantageous consequence of this method is the efiect of introducing relatively cool metal so as to prevent the accumulation of too high a concentration of aluminum vapor which it has been found will produce a dark and non-adherent coating.
  • the aluminum vapor concentration becomes excessive there is a rise in pressure within the chamber which adversely influences the physical character of the deposit, e. g., thickness, adherency, brightness, uniformity, etc.
  • the adhesion tends to improve (a) with increasing metal source temperature; and (b) with reduced pressure.
  • the efiect of an increased rate of travel of the strip is in the direction of reducing the system pressure because of the more rapid condensation of vapor thereby obtained.
  • the effect of increasing the strip temperature is partly to reduce the rate of condensation because of the lesser temperature difierential, but on the other hand, also to improve the adhesion because of-the stress relieving and alloying tendencies.
  • the coating has been deposited, if the temperature of the laminated metal strip or sheet is so high that it would result in rapid oxidation or discoloration when introduced to the air, it is preferable to cool the coated metal preferably under vacuum, or non-oxidizing influences before it is introduced to the air.
  • the invention includes a method in which while under vacuum or reduced pressure, in a suitable chamber, the metal strip, for example, of steel is continuously discharged from a roll and passed continuously through various instrumentalities, including the coating chamber.
  • the metal strip for example, of steel
  • various instrumentalities including the coating chamber.
  • this heating step will have the further effect of de-gassing the metal herein above mentioned as one of the important preliminary treatments.
  • the cleaning and pickling operations may take place and may precede the annealing operation, if necessary, and, in some cases, a further cleaning and/or pickling may be resorted to after the anneal, if required, and before the rolls are placed in the vacuum chamber.
  • the strip metal may be sub jected while under reduced pressure in the vacuum chamber to a glow discharge just before it is presented to the vaporized metal for the purpose of removing the last traces of any physical or chemical contamination.
  • a glow discharge we mean the application of a high difference of potential between the sheet to be coated as one electrode and any suitable type of second electrode such as carbon pencil type.
  • the use of the glow discharge requires a relatively low pressure which is greater than about one micron.
  • the glow discharge method is employed for cleaning, we use somewhat higher pressures in the system than are required if the deposition is to take place at a vacuum sufiicient to make the mean free path of the metal vapor atoms reater than the distance between the source and the base to be coated.
  • the operation can be carried out in a fore-chamber maintained at a suitable pressure which may be somewhat higher than that maintained in the vaporizing chamber.
  • the metal vapor is itself ionized as indicated by the development of a luminescent glow, e. g., for aluminum a characteristic vivid or electric blue luminescence and for tin an apple green luminescence and that under these conditions when such luminescence or glow appears, it is accompanied by an immediate further drop in the pressure within the vaporizing chamber.
  • a luminescent glow e. g., for aluminum a characteristic vivid or electric blue luminescence and for tin an apple green luminescence and that under these conditions when such luminescence or glow appears, it is accompanied by an immediate further drop in the pressure within the vaporizing chamber.
  • the metal vapor is itself acting as a cleaning agent combining, for example, with oxygen and nitrogen, and probably also hydrocarbons which might be present.
  • means may be provided for travelling the strip in either direction through the system.
  • we may operate the system at a pressure suitable for the use of the glow discharge as a means of conditioning the metal base and subsequently, by reversing the direction of the strip, metallizing it under suitable conditions of vacuum while using a metal vapor source of any of the types covered by this invention.
  • we may accomplish the glow discharge cleaning in one portion of th system while following this immediately by metallization in a successive porton of the system.
  • Metallization can be accomplished at the same pressure or lower pressures than used for'eifecting the glow discharge.
  • the coating chamber may comprise a single chamber or a plurality of interconnected chambers all of which are maintained under a reduced pressure including the connections between any series of chambers.
  • the metal vapor source or a group of metal vapor sources may be disposed transversely to the direction of travel of the strip in order to produce a uniform coating of the given thickness and may also be disposed in groups arranged in the direction of travel of the stri so that successive deposits may be obtained to build up the coating to any desired thickness.
  • a differout set of conditions may be maintained in any one chamber or in each chamber of a series which will enable the formation of multiple coatings upon the metal base, i.
  • a built-up coating of acoaeca travel of the strip may be retarded with the other conditions maintained constant, or successive groups of metal sources transversely arranged in parallel may be used to successively increase the thickness of deposit; or other conditions being constant, the rate of evaporation of the metal vapor may be increased by increasing the power supply to the incandescent source, so as to assure that the particular predetermined thickness will be uniformly attained.
  • the temperature attained by the coated metal strip travelling through on chamber may not be suitable for proper deposition in a succeeding chamber, and, hence, the temperature in the said succeeding chamber may be controlled or intermediate cooling means may be introduced.
  • This intermediate cooling means may be of a positive character, as for example, suitable chilling rolls or cooling coils through which the strip passes from one chamber to the next, or the passage between the chambers may be so constructed that the sheet necessarily undergoes a drop in temperature during its travel other words, the flexibility afforded by a multiplicity of inter-communicating coating chambers or provided by a single chamber having transverse and/or successively grouped transverse series of vaporizing sources, precludes the necessityfor repeated coating steps in a single chamber of predetermined size.
  • the present method preferably embodies individual inter-communicating chambers and allows coating of a continuously moving strip.
  • the object so decorated can be removed through suitable air looks from one end of the system or stored in an evacuated chamber connected to the system.
  • the objects may be fed to the conveyor from a hopper in communication with the system through suitable air locks.
  • Conventional methods of metal coloring may, of course, be used to enhance the decorative effect. For example, by controlled heating of adecorated film in an oxidizing atmosphere comprising at least in part vaporized copper, the copper coated portions can be made to take on any desired color in a series ranging from copper red to an iridescent purple or black.
  • a jet black can be produced by heating such a coating in an atmosphere containing sulfur gases or by immersion in a solution of polysulfldes.
  • a vaporized metal coating such as copper
  • a vaporized metal coating may be colored by electrochemical means, as, for xample, the production of oxide films of controlled thickness which in turn give the copper various and controllable interference colors. This is accomplished by immersion in a bath, a suitable electrolyte under controlled conditions in accordance with established practice.
  • the various decorating methods are particularly useful for forming labels, multicolcred patterns and designs on caps, cans and other articles.
  • heating units which embody means for assuring that the metal to be vaporized will be constantly supplied and constantly vaporized at a substantially uniform and controllable rate. This is advantageous in that it enables constant conditions to be maintained in the coating chamber or chambers and assures the deposition of a continuous uniform film upon the travelling metal strip. Of particular importance, the provision of a continuous supply of the metal to be vaporized is accomplished automatically and,
  • Automatic vaporizable metal replenishing means are suitable for carrying out the invention, e. g., crucibles containing a surplus of metal will serve to automatically maintain a constant supply or continual supply of metal vapor or mechanical devices for automatically feeding predetermined amounts of metal are employed.
  • a further embodiment of the invention oomprises the use of electrostatic means within the coating chamber for directing the gaseous metal positively and definitely during the deposition of the same as a, film upon the backing.
  • the metal vapor produced by our energizing source is ionized at least in part as a consequence of thermal and/or electrical ionization and the positively charged aluminum atoms can be made to travel with great velocity and directness toward the strip or base to be coated.
  • the aluminum atoms are directed toward a negatively charged electrode or plate on the far side of the non-conductive strip; where the base is conductive, the same method may be 11 applied or, alternatively, the strip itself may be made negative with respect to the charged aluminum vapor and thus constitute a moving electrode, directing the deposition of the coating upon itself.
  • the us of such positive directional means is unnecessary in those cases where the energizing source and the container for the molten metal are placed below and open toward the surface of the strip material to be coated, which is a preferred method.
  • the vaporizing means can be used to produce an atmosphere of metal vapor under conditions permitting its diffusion in all directions.
  • the lustre of any coating formed in accordance with this invention which is not of maximum brilliance may be improved by passing the same through mirror-finish rolls such as tungsten carbide rolls.
  • steel can be coated with aluminum by our process to produce either a bright-finished product very closely resembling hot-dipped tin plate or a satin-finished product having a silver-white matter appearance resembling tin plate in which the tin coating is electro-deposited.
  • the brightfinished aluminum coated product is obtained by vapolytically depositing aluminum on steel strip which has been given a mirror-finish by means of, for example, tungsten carbide rolls.
  • the satin-finished product is similarly produced by depositing the aluminum upon steel rolled in conventional manner using cold rolls which have been ground but not polished to a mirror-finish.
  • Figure 1 is a diagrammatic sectional elevation showing the initial portion of a line or system for continuously coating metal in accordance with this invention
  • Figure 2 is a diagrammatic View of one of the vacuum chamber units
  • Figure 3 is a view similar to Figure 2 in which a single chamber is employed as distinguished from a plurality of interconnected chambers as shown in Fi ure 2;
  • Figure 4 is a view similar to Figure 2 in which the material to be coated is travelled through the coating chamber or chambers in a vertical plane as distinguished from a horizontal plane as shown in Figures 2 and 3;
  • Figure 5 is a detail view partly in section showing the crucible and associated parts for heating the coating metal by means of high frequency current
  • Figure 6 is a side view showing the manner in which preformed articles, e. g., closures, container bottoms and containers are supported while being carried through the coating system;
  • Figure '7 is a top view of the conveyor and articles thereon to be coated as shown in Figure 6;
  • Figure 8 is a sectional view showing the base metal such as steel directly coated with an adherent film of coating metal such as aluminum, deposited from aluminum vapor;
  • Figure 9 is a sectional view showing a base material such as steel coated with an adherent film of material such as lacquer, varnish or enamel over which is deposited directly a coating ,of metal such as aluminum deposited from aluminum vapor;
  • Figure 10 is a side elevation of another form of apparatus for carrying out the invention whereby continuous strip material is coated upon both sides;
  • FIG 11 is a detail sectional view of one of the housings from which the coiled strip is fed to the apparatus of Figure 10, the rewinding housing being of substantially similar construction; this view further shows the shaft upon which the coil supporting reel is mounted and the means whereby the same may be rotated while maintaining a vacuum-tight seal in the housing;
  • Figure 12 is an end elevation of the housing showing the strip guide rolls
  • Figure 13 is a detail elevational view showing the door of the housing and the sealing gasket associated therewith;
  • Figure 14 is an end elevation of the housing with the door of Figure 13 removed and showing an empty reel in position;
  • Figure 15 is a longitudinal vertical sectional view of one of the housings, taken on line 22-22 of Figure 14;
  • Figure 16 is a side elevation of another form of apparatus in which the strip is coated on both sides while travelling and wherein the strip is rotated through about its longitudinal axis after coating on one side to place the other side in proper coating position;
  • Figure 17 to 20 are elevational views of the spaced rolls for rotating or turning the strip to 180 to carry out the operation of Figure 16.
  • One method of lining the cans is to melt and vaporize the aluminum by means of an electrically heated filament centrally located in the can body in a high vacuum.
  • Tungsten wire is the most suitable material for the filament. Wire varying in'diameter from 0.015 to 0.045 inch may be used, but 0.035 inch is a preferred diameter although 0.025 inch has been satisfactorily used.
  • the pressure used was quite low, being at least as low as 20 microns, and in many cases, as low as 0.1 micron.
  • two or more coatings of aluminum may be built up to form a lining of desired thickness. In some cases, the
  • the aluminum coating is partially oxidized to render' the lining more chemically or physically resistant, i. e., the lining is rendered harder.
  • the lining may be suitably protected by a film of wax, chlorinated rubber or polyvinyl acetal resin.
  • the galvanic protection aiforded by the aluminum lining is substantial, and moreover 'a coil of suitable backing or base material which may be steel or black iron, paper, textile fabrics, or some synthetic resinous material such as chlorinated rubber, Vinylite" resin, polyvinyl acetal resin, cellulose acetate or other organic strip material as well as glass cloth or glass ribbon and such strip is preferably directly coated, but in some cases may be provided with an intermediate film.
  • suitable backing or base material which may be steel or black iron, paper, textile fabrics, or some synthetic resinous material such as chlorinated rubber, Vinylite" resin, polyvinyl acetal resin, cellulose acetate or other organic strip material as well as glass cloth or glass ribbon and such strip is preferably directly coated, but in some cases may be provided with an intermediate film.
  • suitable backing or base material which may be steel or black iron, paper, textile fabrics, or some synthetic resinous material such as chlorinated rubber, Vinylite" resin, polyvinyl acetal resin, cellulose acetate or other
  • the steel band is led from the roll through a suitable cleaning instrumentality H in the form of a bath, for example, a pickling bath to remove surface aecumulations and scale, and the strip is conducted thence, through a suitable drier H to evaporate any liquid or moisture which may have been retained upon the surfaces. Thereafter, the steel band is continued through a bright annealing furnace is if'annealing is required, and as heretofore stated, this heating step will serve to. reduce the amount of occluded gases in the metal. From the annealing apparatus IS, the strip is preferably coiled as at i ll.
  • a coil ill of uncoated strip material is placed in the housing It at the feed end of the vacuum coating unit indicated as a whole at U, carried through the unit and coated, and then recoiled in the housing it at the delivery end of the unit.
  • Both the housings at the feed and delivery ends of the unit are under vacuum and are closed by a suitable hinged door, gasketed to insure a tight seal when the chamber is under reduced pressure, but which will allow the doors to be opened when the vacuum is broken so as to permit a coated coil to be removed and an uncoated coil to be supplied.
  • the coil Hi may b mounted on a suitable feeding shaft wholly supported within the unit and the recoiling mechanism at the delivery end for drawing the strip through the unit may include a shaft operated by a suitable motor within the unit or from outside of the unit, the shaft in the latter case being suitably packed to afford a thorough seal.
  • the housing It opens into a closed conduit of reduced cross-section through which the strip is led as shown to the heating chamber l having suitable electrical heating means l6 therein and which chamber is under vacuum.
  • the heating is carried out upon the continuously travelling strip to remove any occluded gases in the metal strip and also to vaporize any traces of volatile matter or surface accumulations.
  • the metal is continuously travelled to the coating chamber I9.
  • cooling means are provided in the restricted passage 20 if required.
  • the restricted passage itself having external walls exposed to the atmosphere, will act to dissipate the heat sufllciently so that no positive cooling means is required.
  • This connection 20 between the chambers may be elongated so that the metal to be coated enters the coating chamber at any desired temperature, for example, in the case of steel to be coated with aluminum, in the neighborhood of about room temperature. As explained, above, if the metal enters the chamber at a more elevated temperature, this is not necessarily objectionable, and in some cases promotes adherency and continuit of the deposited film.
  • the coating chamber is shown as comprising a series of chambers Illa, I91) and I90, and any desired number of chambers may be employed.
  • the chambers are connected by restricted passages 21 which may be provided with positive cooling means in the form of chilling rolls 22 or may be lined with suitable cooling coils.
  • these restricted passage-ways whose exterior surfaces are exposed to the atmosphere may be elongated if desired in order to effect cooling of the strip as it passes from one chamber to the other where this is found preferable to the provision of positive cooling means. It is believed that the provision of intermediate cooling means between the respective coating chambers of the series is conducive to good results, but a single coating chamber l9 such as shown in Figure 3 has been employed satisfactorily in lieu of the series of chambers shown in Figur 2.
  • Thesingle chamber shown in Figure 3 is connected with the housings I l and it and associated construction as described above in connection with Figure 2.
  • Figures 2 and 3 we have shown the metal as passing through the coating chamber or chambers in a horizontal plane while in Figure 4, we have shown the metal as being coated while travelling in a vertical plane, and for this purpose, after the metal leaves the coiled roll l0, it is turned through any suitable turning guides (not shown) disposed at 23. This turning operation takes place at any convenient time or place in the line after the strip Hi leaves the roll and is conducted under vacuum.
  • the feed and recoil shafts and the roll may be vertically disposed.
  • the unit including the coating chambers l9 and housings l4 and I4 are exhausted or maintained at a suitably reduced pressure by a vacuum pump or combination of pumps of any suitable construction connected to the exhaust manifold pipe 24 having leads to the individual chambers as shown in Figure 2 or to the single chamber as shown in Figure 3.
  • suitable vaporizing means which may be in the form of filaments as shown at 25 or electrical resistance or induction heated crucibles as shown at 26 or aluminum cathodes for sputtering.
  • a predetermined amount of metal to be vaporized is disposed at the energizing sources according to the area of strip to be coated and the coating thickness desired.
  • a predetermined amount of coating metal will be preferably employed where electrically heated crucibles are used to contain the coating metal or cathode sputtering is utilized. We. prefer to use an amount of coating metal slightly in excess of predetermined coating requirements.
  • cooling zone or vapor trap formed by the cooling coils 27 which surround the closed conduit leading from chamber we and which serve to trap any vapors which are discharged from the chamber I90.
  • This cooling means 21 likewise serves to lower the temperature of the travelling strip material.
  • a similar trap 29 maybe disposed at the other housing end, but this condition is generally taken care of in the chamber I where any objectionable vapors are continuously removed.
  • the coated material is drawn through the apparatus and after coating is rewound on a suitable reel in the housing I6.
  • a heating means i5 similar to the heating chamber I5 is interposed before the cooling means 21.
  • the heating and cooling in each case takes place under a vacuum.
  • One of the advantages of the method shown in Figures 2 to 4 is the ability to bring the coating chamber ii! to the best or most desired condition for coating by vaporization with a minimum of pumping effort, and therefore at a more rapid rate. That is, a. greater vacuum is required in the chambers l9a, I91) and I90 than is required in the remainder of the apparatus, namely, the housings and the chambers l5 and i5, and there are cases, for example, where a greater vacuum is desirable in one or two of the chambers Isa, Nb and Ho. Our method enables advantage to be taken of the law relating to the diffusion of gases at reduced pressure.
  • the passages from the housings I 4 and i4 and from the respective chambers l5 and i5 and "la, I92) and I90 are restricted and, for example, in the case of stri metal, are of a thinness or narrow cross section such as will just allow the metal to freel travel in order that difiusion between the housings and the respective chambers may be reduced to a minimum.
  • chilling means, heating means, or supporting or conveying means are interposed in such restricted passages, they so occupy the passage as to likewise reduce the possibility of any substantial dif-- fusion.
  • the manifold 24 is exhausted by a single line E to the exhausting means and therefore the admittance speed or evacuation speed will be greatest in the chambers i9a, Nb and I 90 which are closest to the exhaust pipe leading to the exhaust means,
  • the housings l4 and I4 and the chambers i5 and IE will exhibit a pressure gradient with respect to the chambers i9, that is, will be less exhausted. Under such conditions, operation of the exhausting apparatus will rapidly bring all of the coating chambers 19 or any one or twoof them to the desired reduced pressure, and the other chambers and housings to a satisfactory reduced pressure, and by reason of the restricted passages, between the housings and the various chambers, the amount of diffusion will be negligible in the coating operations.
  • exhausting means we mean, preferably, some multi-stage type using a suitable fore-pump for the preliminary exhaustion and higher vacuum pumps for subsequent stage or stages.
  • the passages likewise will be of a cross-sectional dimension to just clear such articles, and suitable barangs, e. g. flexible, may be disposed therein, if necessary, in order to reduce the possibility of diffusion.
  • the numeral It indicates a sealed housing from which strip material is fed continuously to and through a chamber II.
  • the chamber II may be of any suitable materials such as glass, metals, alloys, etc. and may be of any suitable size and shape in cross-section.
  • the chamber H is tubular and elongated and has an upper horizontal leg Ila, a vertical leg llb, and another horizontal leg 'Ilc which leads to a sealed housing 12 in which the strip material coated durin its passage through the tube ll is recolled.
  • the housing 10 and the housing 12 each comprises a closed box It.
  • This box is provided at one end with a strip passage 14 as shown in Figure 15 and in which is disposed a pair of guide rolls 15.
  • the housing is closed by a door I6 which may be hinged or separate as shown in Figure 13.
  • This door has a suitable packing or gasket 11 and is bolted to the housing as shown at I8 to seal the same.
  • the housing is provided with an enlarged opening 19, while at its opposite side, there is provided a recess 80 of smaller dimension than the opening 19 but concentric therewith.
  • each housing there is disposed a reel 8
  • the shaft 82 it will be noted, has a tapered end 83 which is normally disposed within the housing and within the hub of the reel 8!. At one end of the tapered portion, there is provided a squared projection 8G which engages in a similar opening 85 in the reel 8
  • a projection 86 extending into the recess 89 which acts as a guide and in some cases as a support or bearing for the shaft 82.
  • the shaft 82 is supported in a bearing 8'! which is bolted at 88 to the wall of the housing in a manner to seal the same, there being provided a suitable packing 89 between the flange of the bearing Bl and the wall of the housing.
  • the bearing 81 has a suitable packing consisting of lantern glands with stufiing indicated as a whole at 90, and the shaft may be suitably lubricated by lubricant supplied through the inlet 9i which may be removed by the outlet 92 normally maintained at the reduced pressure of the system.
  • the shaft carries a pulley 93 which is rotated by a suitable motor 94 as shown in Figare 10 for positively rotating the reel 0i in the housing 12 to draw the strip through the coating apparatus.
  • the shaft 82 is movable laterally so as to withdraw the tapered portion 83 from engagement with the reel and outside of the housing a sufficient distance to clear the reel whereby the same may be removed and another reel containing a coil of strip material to be coated replaced within the housing. This lateral movement does not afiect the sealed condition of the housing because the bearing 81 is of a length that when the shaft is withdrawn from the housing, no part of the tapered portion extends beyond the hearing surface 95.
  • the tube II is connected to the housings by Joints 96 which are preferably of the flanged type and assure complete freedom from leakage.
  • Joints 96 which are preferably of the flanged type and assure complete freedom from leakage.
  • the tube may be formed of Pyrex" glass but is preferably formed of steel having a smooth interior. In some cases, this smoothness is obtained by a suitable coating, such as tin.
  • a plurality of pairs of guide rolls 15 are disposed in the tube, and at the ends of the chambers I la and 1 lo, guide rollers 98 are employed over which the continuous strip travels from the upper le Ila to the lower reversely extending leg I I0. These rollers 98 are preferably supported by the end sealing members 99 by means of brackets 99', the sealing members 99, brackets 99 and rollers 98 being of conductive material in some cases for a purpose to be later described.
  • vaporizing means Disposed at suitable points along the length of the tube are the vaporizing means which may be of the character heretofore described and which are indicated as a whole at I00 in Figure 5.
  • crucibles IOI are illustrated and are preferably heated by a high frequency current introduced through th line I02, the line being suitably water-cooled as well known.
  • the line I03 is in the nature of a tuning tap.
  • the tubular extension I05 opening into the tube II and in which is disposed a crucible I01 and its heating means is sealed by a leak-proof joint I04 which also carries suitable insulation.
  • vaporizing means may be positioned within the tube below the undersurface of the moving strip to be coated, and they may be suitably connected so that by opening one of the ends 99, all of the vaporizing means may be removed for repair or replenishing with metal.
  • the operation is, of course, carried out under a suitably high vacuum which is produced by connecting the line I06 to an extension I05 of the tube by means of a leakproof joint I91, the line I96 being connected to a suitable vacuum pump.
  • vacuum pumps may be associated with each of the housings I0 and I2 in addition to the vacuum pump working through the line I06.
  • a strip of metal to be coated is withdrawn as a continuous length from the housing I0 and continuously travelled through the tube leg Na in which first its undersurface is coated by means of the vaporizing device or devices IIIO disposed below the unde'rsurface of the strip, whereupon the strip is turned through 180 in the leg I It and its opposite surfac is presented to and similarly coated by the vaporizing means in the leg IIc whereupon the coated strip is recoiled in the housing I2.
  • FIG 16 embodies a single longitudinal tube II in which means are provided for turning the strip after the undersurface has been coated through an angle of 180 so that its opposite surface may be similarly coated.
  • the means for accomplishing this is shown in Figures 17 to 20 and embodies guide rolls l5 and guide rolls I08 and I09 which are disposed at a suitable angle with respect to the guide rolls 15 to turn the strip as it travels through the tube 1 I. Otherwise, the construction is similar to that shown in Figure 10.
  • the shaft 82 in the case of the housing 12 is Where the crucible i used, it is located ap- 19 proximately three inches from the strip with the molten metal about four inches from the surface of the strip. This gives satisfactory results.
  • the crucible or other heating mean may be located at various distances, and we have found that the farther away the crucible is located, the greater the area of the strip which will be covered.
  • the lower the pressure in the tube H the greater the distance the crucible can be disposed away from the strip, and th thinner the coating which will be produced.
  • the lower the pressure which is maintained in the tube H the fewer the crucibles which need be employed.
  • the crucibles or resistance heating means may be disposed in various ways to obtain the desired coating, but it is preferable in the absence of any means for positively directing the vaporized metal toward the strip, to dispose the same below the travelling strip, since we find that under reduced pressure, the metal tends to diffuse upwardly and efliciently cover the lower exposed surface of the strip.
  • the vaporizing means may extend transversely of the path of movement of the strip so as to comprehend the entire transverse dimension thereof, or the vaporizing means may be disposed in staggered relation to insure complete coating. The important consideration is to obtain a uniform coating of desired thickness, and the position of the vaporizing means will, therefore, depend upon the area of the sheet to be covered.
  • the numeral H indicates a suitably insulated electrode which is sealed into one of the legs of the system
  • the numeral Ill indicates an electrical contact of opposite polarity mad through the metal plate 99 and supporting bracket and roll 98 with th strip I0.
  • a difference of potential of up to several thousand volts is established, in such manner that the electrode connected to the strip is of negative polarity.
  • This difierence of potential can be established by use of a step-up transformer in conjunction with a rectifier such as a kenotron or a mechanical rectifier operated by a. synchronous motor.
  • the vaporized aluminum ions have a positive charge and will be attracted to the negatively charged moving steel strip [0.
  • the second method involves the use of electrodes I I 2 and H3 and would be utilized in that case where the metal is to be deposited on the strip by the cathode sputtering process.
  • the electrode H2 is sealed through the crucible so as to make electrical contact with the molten metal inside. This electrode will be at a negative potential with respect to the strip which is connected to the positive side of a high voltage direct current source through the electrode or connection H3.
  • the vapor directing means described with respect to the optional methods may be interposed in the system at any convenient point and have been illustrated in Figure 10 simply for convenience. Wher the legs 1
  • the metal instead of forming the metal into a coil i0, it is introduced directly from the drier II or the annealer l3 into the coating chamber continuously passing from these instrumentalities into the unit, Also, in such cases, we some times provide at the entrance and exit ends of the unit a liquid sealing leg preferably of substantially U-shape through which the continuous strip is travelled. The seal is established by means of a suitable liquid maintained in the leg such as water, mercury, molten lead and other satisfactory liquids.
  • liquid sealing legs may be necessary to provide special means for preventing contamination of the coating metal by contact with the sealing liquid or vapor therefrom:
  • mercury will alloy with freshly deposited aluminum.
  • Capsules containing the absorbing metal can be separately vaporized by induction heating so that a film will be deposited upon the walls of the system ahead of the aluminum coating chamber i9, and this operation'will be performed after initial evacuation but before aluminizing commences.
  • the use of liquid sealing various articles are maintained in position on the belt 50 by permanent or temporary magnets and the coating may be carried out in any of the apparatus described herein.
  • a suitable means is employed to remove the coated articles from the belt 50.
  • crown caps at 52 we have illustrated crown caps at 52, screw caps at 53, lug caps at 54, can bottoms at 55 and containers at 6 6.
  • These various articles as well as containers may be coated interiorly or exteriorly, or both, in accordance with their positions on the belt.
  • the outside of an article may be coated during part of the movement of the belt whereupon the article, held in position by a temporary magnet is inverted by a suitable means (not shown) and the inside coated or lined during another period of the travel of the belt.
  • the belt 50 is provided with a multiplicity of openings to permit communication through the belt. It is preferably formed of stainless steel and the sections thereof may be hinged as shown at 51.
  • the apparatus will be suitably enlarged to permit the passage of such articles through the respective instrumentalities of the unit.
  • preformed articles may be fed thereto at the feed end Id of the unit from a suitable magazine maintained under air-tight or vacuum conditions, and discharged at the delivery end M of the unit into a suitable hopper or other collecting means, likewise maintained under vacuum or air-tight conditions.
  • the magazine and hopper may be disposed within the unit or may be disposed outside of the unit and connected thereto through suitable air-tight connections. This will be particularly the case where caps, can bottoms and containers are being coated.
  • a base of any suitable material such as steel or black iron, paper or film of organic material, directly coated with a coextensive film of aluminum Bl deposited from aluminum vapor.
  • the base 56 may be formed of paper or other flexible material, such as synthetic resins and cellulose derivatives, as well as chlorinated rubber or metal foils, i. e., of steel. In this manner, suitable materials are provided which are useful for providing center spots and overall facings for caps and closures.
  • the backing or base in the case of spotting materials is provided with a suitable adhesive coating for securing the spot or overall facing to the cushion liner of the closure.
  • Foils of this character may be used for their insulative qualities and decorating characteristics.
  • the inner member may be produced in accordance with this invention by coating the steel with a coextensive fllm of aluminum either inside or outside, or both.
  • the outer threaded member may be similarly coated.
  • the aluminum coating prepared in accordance with this invention may be provided with a coating of suitable lacquer or varnish.
  • suitable lacquer or varnish Such organic coatings are useful where chemical action between the contents and the lining or foil might be set up.
  • sufiicient metal to be vaporized as will coat a predetermined length and width of strip.
  • sufiicient metal for coating 5,000 feet of thirty inch wide strip on both sides with sufiicient aluminum to give commercially serviceable rust resistance. approximately six pounds of aluminum will be sufilcient and where several crucibles are used as in Figure 10, the total amount required is preferably equally divided among the crucibles at thestart of each run, 1. e., one and a half pounds in each crucible.
  • vapolytic aluminum films produced on steel particularly relatively thick coatings ranging from about 0.1 mil to l mil in thickness, while initially continuous and relatively adherent will separate from the steel and be readily detached as thin irregular flakes or lamellar particles when the steel is made to bend sharply.
  • Such flakes can be ball-milled to give a more uniform and smaller sized particle with or without further substantial reduction in thickness, i. e., converted to a form suitable for use in aluminum paint.
  • the power required to vaporize a pound of aluminum is so small, i. e. theoretically, it is only about 2.1 kw.-hours and with power at 1 cent per kw.-hour, it is apparent that the vapolytic method offers a much cheaper method for producing aluminum powder than the present method involving a cost of about 23 cents per pound to reduce sheet aluminum to powder, excluding metal cost.
  • thi is the only method that is explosion-proof and that can produce aluminum powder Practically free from oxide. All present methods involve powdering the aluminum under conditions where oxygen is present, and oxide and explosions may be produced.
  • both surfaces of the travelling strip [0 are simultaneously and successively coated.
  • the vapoly-tic means I 00 may be disposed in each leg Na and lib upon opposite sides of the strip travelling therethrough so as to simultaneously coat opposite sides or the strip in as it travels through the respective legs of the chamber H.
  • a method of coating a metal sheet with a vaporized metal comprising introducing the metal to be coated, prior to coating into a feeding zone and maintaining the same under reduced pressure therein, continuously advancing the metal sheet from said feeding zone in a substantially horizontal plane, while maintaining the metal sheet under reduced pressure, into a coating zone with the metal sheet at a temperature below that of the vaporized metal, maintaining that coating zone also under reduced pressure twisting the metal sheet through an angle of substantially 180 in the coating zone as it travels through the same, vaporizing the coating metal in said coating zone continuously as the metal sheet travels therethroush.
  • a method of coating a metal base with a vaporized metal comprising introducing the metal to be coated, prior to coating into a feeding zone and maintaining the same under reduced pressure therein, continuously introducing the metal from said feeding zone, while maintaining the metal under reduced pressure, into a coating zone with the metal at a temperature below that of the vaporized metal, maintaining the coating zone also under reduced pressure,

Landscapes

  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Physical Vapour Deposition (AREA)

Description

Aug. 13, 1946.
C. E. M MANUS ET AL Filed Aug. 50 1941 COATING 5 Sheets-Sheet l Aug. 13, 1946. c. E. MCMANUS ET AL 2,405,662
COATING Filed Aug. 30, 1941 5 Sheets-Sheet 2 COATING Filed Aug. 30, 1941 5 Sheets-Sheet 3 Aug. 13, 1946. Q McMANUS ET AL 2,465,662
COATING Filed Aug. 30, 1941 5 Sheets-Sheet 4 an W WM? n b w%,w/
5 Sheets-Sheet 5 C. E. M MANUS ET AL COATING Filed Aug. 30 1941 Aug. 13, 1946.
HHH m Mk I vfi m m w m w 5. 8 m a M r Mi w w ai CJG WM Patented Aug. 13, 1946 cone Charles E. McManus, .lolm I). Elder, Giles B. Cooke, and Albert J. Dornblatt, Baltimore, Md, assignors to Crown Cork & Seal Qompany, Ind, Baltimore, Md a corporation oi New York Application August 30, 1941, Serial No. ddlwllll Claims. 1
The present invention relates to a method of coating with metallic vapors, and is particularly concerned with a novel product such as steel sheet or black iron having a coating of aluminum bonded thereto and articles formed therefrom.
The method of the invention includes the coating of a base which may be a continuous strip or length of material, as well as preformed articles, to produce on the base a permanently adherent surface film which is deposited Or precipitated from an atmosphere of the vaporized coating metal. This coating can be determined as being produced from the metallic vapor by metallographic examination and X ray diffraction studies.
The resultant laminated product exhibits characteristics which enable the coated metal to be formed and shaped, for example, (a) stamped into closure caps, particularly those of the skirted type such as crown, screw and lug caps, (22) pressed or drawn for use in the making of containers, and (c) spun to form articles which are best prepared by such operation, namely, bottles, reflectors, and goblets. In fact, the coated metal repared in accordance with this invention is useful in a wide variety of applications where the base metal, if not protected, would ultimately present an objectionable appearance and in the case of containers, might affect the quality of the contents.
The aluminum coating produced from the vaporized metal is characterized by having a purity greater than that of customary aluminum coatings; in fact, the distillation of the aluminum enhances the purity of the coating so that it is substantially pure.
The coating of a base such as steel, in accordance with this invention, does not result in any impairment of the properties of the steel, 1. e., the advantageous properties of the base are substantially unaffected by the coating film. In fact, the coating of the steel with vaporized metal is accomplished without substantially raising the temperature of the metal or otherwise heating it in a manner which might objectionably afiect its desired properties. In other words, not only are the temperature conditions such that the properties of the steel are not affected, but the laminated product does not have a brittle intermediate zone or constituent, i. e., is substantially free of brittle intermetallic iron-aluminum compounds such as are frequently present where steel is coated by dipping in molten aluminum. Hence, the composite product has all the ductility of uncoated steel and is substantially free of brittleness.
This allows the coated metal to be employed for many forming operations. For example, in the production of crown caps, as by stamping, there is no evidence of cracking of the coating or the base metal. This is particularly advantageous, for example, in coating cold rolled strip where it is desired to preserve the stifiness and high polish of the skin-passed steel strip. Furthermore, the flexibility, rigidity and tensile strength of the base metal are not sacrificed and the resulting product possesses the advantageous properties or both the steel and of the metal coating.
A very important characteristic of the coated metal is its corrosion resistance. Not only does the aluminum coating protect the iron from corrosion, but it inherently possesses resistance to corrosion and is therefore suitable for many situations where corrosive influences would deleteriously affect the metal base.
Another characteristic of the laminated product 0r coated metal is the galvanic protection afforded by the direct coating of the vaporized metal such as aluminum upon the base metal such as steel or black iron. The steel is rendered rustproof and is prevented from discoloring and may be employed in containers for foods and beverages.
Further attributes of the coated metal are the pleasing brightness and high reflectivity for radiant energy. These qualities of the coated metal make it available for walls in low-cost housing and for various applications where heat and/or light reflectivity is desirable.
The abrasion resistance of the coated metal is satisfactory but the coating may be oxidized and hardened to give enhanced abrasion resistance for certain purposes.
Another important characteristic of the laminated product is the strong and permanent adherency or bonding of the aluminum coating to the metal base which makes the product suitable for the metal working processes as above described. In this connection, in some cases, by regulated heating of the coated metal, alloying of the two constituents can be controlled, 1. e., the difiusion between the atoms of the steel base and the coating, and a substantially integral bond is thereby produced without embrittlement.
The aluminum coated metal may be suitably decorated, printed, dyed, or otherwise colored". It may also be subjected to well-known processes of the type used for oxidizing pure aluminum or relatively high aluminum content alloys. By such -means an oxidized film is formed on the aluminum which readily permits impregnation by various dyes and offers an excellent base upon which organic finishes may be applied. The oxidized film may be produced under conditions which give it an extraordinary degree of hardness.
It will be appreciated that the aforesaid properties, whereby the coated metal may be worked and possesses the desired resistant qualities and receptivity for decoration, make it ideal for the manufacture of'screw caps, crown caps, and other skirted closures. Likewise, the coated metal is useful for makin containers and numerous other fabricated products. In other words, this aluminum coated steel, for example, forms a satisfactory substitute for the customarily employed tin plate prepared by usual practice and at less cost for the coating metal due to the thinness of the coating which is commercially satisfactory.
Another embodiment of the invention consists in applying an organic film such as lacquer, varnish or enamel or an inorganic vitreous enamel to the metal surface, e. g., steel either of a preformed article or a continuous strip, whereby any irregularities or pores therein are effectively sealed and a smooth surface for receiving the vaporized metal coat is provided. Brittle enamels should not be used on continuous sheet metal which is wound in coils. The adherent vaporized coating metal is applied, for example, to the organic coating and adheres thereto and forms a film bonded to the base which is characterized by remarkable brilliance due to the uniformity, continuity and smoothness resulting from the presence of the intermediate coating. This improved lustrous or mirror-like finish is comparable'to a coating produced directly upon highly polished steel sheet when vaporized aluminum is deposited thereon as a film. For all usual purposes, the product above described, in which the vaporized aluminum is directly deposited upon the steel, is quite satisfactory, and in either the ease of th aluminum coated steel or the aluminum coated presurfaced steel, the properties of the steel are not sacrificed and the properties of aluminum are made available. Should there be any pores or, other lack of continuity in theintermediate coating film,
the metallic film will afford the desired galvanic and corrosion protection.
In connection with the foregoing, suitable films I invention is a foil which may be either of pure aluminum, or comprise thin backings of iron or steel of sufiicient softness and flexibility, paper,
plastics such as Vinylite or other synthetic resins, chlorinated rubber, zinc foil, etc. coated with a deposit of vaporized aluminum. In some cases where the laminated foil is produced, the thin metal strip is first coated with an intermediate film such as an organic film of varnish or lacquer :upon which the thin aluminum coating or layer-is deposited. The pure aluminum foil may also be produced by depositing the coating upon a suitable non-retentive surface, e. g., steel coated with Apiezon oil or stearic acid, wherefrom the foil may be readily stripped off by any suitable means. In general, substances used to make the surface non-retentive must not excessively dilute the metal atmosphere with their own vapors. Foils produced in accordance with this invention are suitable for cap spotting purposes, heat insulation and for electrical condenser foils.
In this connection also, aluminum powder and flakes may be satisfactorily produced in accordance with this invention for use as pigments, in pyrotechnics and other applications, by depositing the vaporized aluminum upon a non-retentive surface such as stearic acid, or in a non-adherent form under controlled conditions, i. e., at a reduced pressure representing a, less highly exhausted state than that which is required to produce an adherent and continuous film and/or at a temperature of the metal base conducive to production of a spongy or powdery deposit, whereby a discontinuous film or otherwise powdery deposit is formed which may be readily removed. In some cases the deposit so recovered will have the necessary fineness or in any case where a greater degree of fineness is desired, the size of the particles may be reduced in any suitable maimer.
In connection with the formation of foils and powder, we also accomplish this by placing strips or sheets of aluminum or other material having non-retentive surfaces on the walls of the coating chamber, whereby excess vaporized metal which would normally adhere to the wall of the chamber is caused to be collected upon the sheets or strips and may be suitably removed and the foil or powder recovered. If it is not desired to use separate sheets or strips, the walls of the coating chamber itself may be rendered non-retentive if necessary, so that the aluminum coating may be readily stripped or removed therefrom.
A further embodiment of the invention consists in producing metal coated material having flexible strip material backings of paper, plastics such as 'Vinylite or other synthetic resins, chlorinated rubber, zinc foil, etc., by a transfer process in which the coating metal such as an aluminum film is first deposited from .the vapor state upon a nonretentive surface either .as a continuous film of foil thickness or as a thin discontinuous film.
in contact with the same so as to pick up and transfer either a continuous film of aluminum to the new backing or a discontinuous film as the case may be. Such laminated material may be of foil thickness or be of greater thickness as desired. The metallized laminated product or foils produced by direct coating as above described or by the transfer process just mentioned may be used as foils for cap spotting purposes, packaging, insulating walls, as well as decorative purposes.
As will be appreciated, the products obtained in accordance with the present invention are highly valuable and their production is accomplished by novel methods which are commercially feasible.
An important object of the invention is to provide a method in which a permanent, uniform and coextensive adherency between the coating and the base layer is assured which persists when the metal is worked, i. e., there is no evidence of peeling, nor cracking of the laminated product, and there is an absence of any objectionable brittlizecl condition. We have discovered that there are several critical considerations which govern the obtaining of the integrally bonded laminated sheet. For example, it i of particular importance that the metal surface, e. g., of steel, be presented to the metal coating atmosphere in a thoroughly cleaned condition. That is to say, the metal surface should be free not only of extraneous or foreign material, but likewise of rust film. Another critical consideration which we have discovered is that for reliable adherency, the metal should be substantially free of occluded gases, and it is highly important that before the metal sheet or strip is subjected to the coating atmosphere, it be first not only physically and chemically cleaned, but degassed as completely as possible.
Equally important, with the foregoing, is the provision of a chamber for accomplishing the coating operation which will permit continuous movement of a continuou strip or sheet to be coated through the same and which will be thoroughly sealed whereby a substantially constant reduced pressure or vacuum is maintained and the vaporized metal in the chamber is prevented from being excessively diluted, or polluted in a manner such as would adversely affect the color or adherence of thefilm. It may not be objectionable to have, for example, a trace of air, but the presence of an appreciable amount of certain vapors as fOr instance grease hydrocarbons, may cause the deposit to be blackened and be loosely adherent, whereas a silvery white or bright metallic film is desired.
We use a single chamber or a plurality of interconnected chambers. The connections between the series of chambers are such that the material to be coated may be continuously travelled through the same while maintained under reduced pressure. The conditions in each chamber regarding the vacuum and the density of the vaporized metal may be modified in accordance with the product required.
A will be appreciated, the relative temperature of the metal base and the metal vapor source within the coating chamber are maintained under conditions to promote rapid precipitation of the metal upon the base strip moving through the chamber to form the coating film, and While in many cases preheating or subsequent heating of the metal will be unnecessary, there are conditions where it may be desirable to either heat Or cool the metal under vacuum to a satisfactory operating temperature before deposition.
The method provides for suitably heating the strip under vacuum for the purpose of removing any surface accumulations and occluded gases prior to its entrance into the coating chamber, and also for assuring in certain cases, i. e., aluminum upon steel, that a more adherent coating is obtained, and one which afiords an optimum coverage of the base metal. In this connection, in some cases, the temperature of the metal is raised where necessary after the coating operation to further assure the maximum adherency and/or to improve the continuity of the deposited coating. These heating steps may be accomplished in a protective atmosphere, but are preferably carried out under vacuum.
In actual operation it has been found possible to obtain very adherent coatings of aluminum on steel strip over a sustained period of operation without the strip having been at any time heated to a temperature much in excess of room temperature. In fact, the continual introduction of the uncoated strip at normal room temperature into the coating chamber acts to provide a continuous means of condensing the hot vapors of aluminum and prevent an excessive accumulation of vapor concentration in the chamber. Because of the relatively rapid rate at which the strip being coated passes adiacent to the incandescent vapor source there is insufficient opportunity for heat from the vaporizing ource or the vapors to produce any excessive temperature rise of the strip. A particularly advantageous consequence of this method is the efiect of introducing relatively cool metal so as to prevent the accumulation of too high a concentration of aluminum vapor which it has been found will produce a dark and non-adherent coating. In other words, if the aluminum vapor concentration becomes excessive there is a rise in pressure within the chamber which adversely influences the physical character of the deposit, e. g., thickness, adherency, brightness, uniformity, etc. We have found it possible by our invention to so regulate the temperature of the strip, the rate of travel of the strip, the rate of power input to the metal vapor source and the rate of exhaustion of the chamber by the pump system, to maintain an optimum condition with respect to metal vapor concentration and pressure whereby a thin, uniform, adherent and. bright metallic deposit may be continually obtained.
It may be advantageous to operate the system at a pressure, for example, somewhat higher than that which will give the desired degree of adherency of the coating deposit and subsequently increase the adhesion of thi deposit by heating the laminated product where, by virtue of alloying diffusion, an integral adherent bond is established. While we are not entirely sure, it appears that this heating step also has the effect of relieving stress resident in the aluminum coating under such conditions so that the tendency to peel is eliminated. Such stress, and in the peeling direction, may be due to the fact that the hot vapor is deposited upon the relatively cooler steel base and stresses arise owing to the coefficient of expansion differential between the aluminum and the steel. Substantially similar procedures may be employed in coating vaporized metal such as aluminum, silver or tin upon papers, e. g., varnish drab express paper to make a laminated product useful for cap spotting purposes.
With respect to the critical conditions for obtaining an optimum deposit, it has been found that, other conditions being constant, the adhesion tends to improve (a) with increasing metal source temperature; and (b) with reduced pressure. The efiect of an increased rate of travel of the strip is in the direction of reducing the system pressure because of the more rapid condensation of vapor thereby obtained. We have found that while the strip is traveling through the vaporizing chamber that the pressure is reduced as compared to the pressure existing before the strip has been set in motion and after the movement of the strip has been discontinued. The effect of increasing the strip temperature is partly to reduce the rate of condensation because of the lesser temperature difierential, but on the other hand, also to improve the adhesion because of-the stress relieving and alloying tendencies.
By virtue of the continual introduction into the system over the vaporizing sources of relatively cool metal at no time does the temperature of the metal rise to an extent which would adversely affect the desirable physical properties of the metal strip such as, for example, those imparted by a skin-pass. The effect of reducing the pressure, other conditions being constant, is to per-r aeoacee mit improved adhesion because the opportunity for collision of the vapor particles with other gaseous molecules is reduced and in the ideal case where the distance between the vapor source and the strip is less than the mean free path of the vapor molecules under the prevailing conditions, no interfering collisions can occur and the vapor particles impinge on the metal base with maximum energy, thus promoting adhesion.
We have found that while a filament coated with the metal to be vaporized emanates the metal vapor in all directions substantially uniformly, that the emanation of vapor from an incandescent crucible is in the general form of an expanding cone-shaped beam of small angle with respect to the axis of the beam. For example, a crucible heated by induction placed beneath a steel strip will deposit a layer of the incandescent metal vapor in a circular pattern substantially directly above the vertical axis of th crucible. The diameter of this pattern in creases with the distance of the crucible from the strip. While it is desirable to have the distance between the strip to be coated and the metal vapor source less than the mean free path of the metal vapor atoms or particles, this is not essential. We have found that commercially satisfactory adherent deposits can be obtained when the distance just referred to is greater by a limited extent than the mean free path.
It may be advantageous, in some cases, in order to promote a better adhesion and continuity, to subject the laminated material to elevated temperature for a predetermined time period and in a non-oxidizing atmosphere preferably under vacuum, followed by a cooling step in a non-oxidizing atmosphere or preferably under vacuum to eliminate the possibility of oxidation.
Also, after the coating has been deposited, if the temperature of the laminated metal strip or sheet is so high that it would result in rapid oxidation or discoloration when introduced to the air, it is preferable to cool the coated metal preferably under vacuum, or non-oxidizing influences before it is introduced to the air.
The invention includes a method in which while under vacuum or reduced pressure, in a suitable chamber, the metal strip, for example, of steel is continuously discharged from a roll and passed continuously through various instrumentalities, including the coating chamber. In this connection, in some cases before being introduced to the vacuum chamber, it is preferred to anneal the strip and a continuous annealer may be incorporated in the line, and in addition to accomplishing its accepted function, this heating step will have the further effect of de-gassing the metal herein above mentioned as one of the important preliminary treatments. Likewise, before the strip is introduced as a roll to the vacuum chamher, the cleaning and pickling operations may take place and may precede the annealing operation, if necessary, and, in some cases, a further cleaning and/or pickling may be resorted to after the anneal, if required, and before the rolls are placed in the vacuum chamber. With relation to the cleaning step, the strip metal may be sub jected while under reduced pressure in the vacuum chamber to a glow discharge just before it is presented to the vaporized metal for the purpose of removing the last traces of any physical or chemical contamination. By a glow discharge, we mean the application of a high difference of potential between the sheet to be coated as one electrode and any suitable type of second electrode such as carbon pencil type. The use of the glow discharge requires a relatively low pressure which is greater than about one micron. Where the glow discharge method is employed for cleaning, we use somewhat higher pressures in the system than are required if the deposition is to take place at a vacuum sufiicient to make the mean free path of the metal vapor atoms reater than the distance between the source and the base to be coated. Wherei-t is desired to use this method for cleaning, the operation can be carried out in a fore-chamber maintained at a suitable pressure which may be somewhat higher than that maintained in the vaporizing chamber.
In the practical operation of the invention usin a high frequency induction-heated crucible type of metal source, it has been observed that the metal vapor is itself ionized as indicated by the development of a luminescent glow, e. g., for aluminum a characteristic vivid or electric blue luminescence and for tin an apple green luminescence and that under these conditions when such luminescence or glow appears, it is accompanied by an immediate further drop in the pressure within the vaporizing chamber. This indicates that the metal vapor is itself acting as a cleaning agent combining, for example, with oxygen and nitrogen, and probably also hydrocarbons which might be present.
If desired, according to our invention, means may be provided for travelling the strip in either direction through the system. Using such means, we may operate the system at a pressure suitable for the use of the glow discharge as a means of conditioning the metal base and subsequently, by reversing the direction of the strip, metallizing it under suitable conditions of vacuum while using a metal vapor source of any of the types covered by this invention. Alternatively, we may accomplish the glow discharge cleaning in one portion of th system while following this immediately by metallization in a successive porton of the system. Metallization can be accomplished at the same pressure or lower pressures than used for'eifecting the glow discharge.
As explained above, the coating chamber may comprise a single chamber or a plurality of interconnected chambers all of which are maintained under a reduced pressure including the connections between any series of chambers. In any given chamber, the metal vapor source or a group of metal vapor sources may be disposed transversely to the direction of travel of the strip in order to produce a uniform coating of the given thickness and may also be disposed in groups arranged in the direction of travel of the stri so that successive deposits may be obtained to build up the coating to any desired thickness. A differout set of conditions may be maintained in any one chamber or in each chamber of a series which will enable the formation of multiple coatings upon the metal base, i. e., a built-up coating of acoaeca travel of the strip may be retarded with the other conditions maintained constant, or successive groups of metal sources transversely arranged in parallel may be used to successively increase the thickness of deposit; or other conditions being constant, the rate of evaporation of the metal vapor may be increased by increasing the power supply to the incandescent source, so as to assure that the particular predetermined thickness will be uniformly attained. In other cases, the temperature attained by the coated metal strip travelling through on chamber may not be suitable for proper deposition in a succeeding chamber, and, hence, the temperature in the said succeeding chamber may be controlled or intermediate cooling means may be introduced. This intermediate cooling means may be of a positive character, as for example, suitable chilling rolls or cooling coils through which the strip passes from one chamber to the next, or the passage between the chambers may be so constructed that the sheet necessarily undergoes a drop in temperature during its travel other words, the flexibility afforded by a multiplicity of inter-communicating coating chambers or provided by a single chamber having transverse and/or successively grouped transverse series of vaporizing sources, precludes the necessityfor repeated coating steps in a single chamber of predetermined size. The present method preferably embodies individual inter-communicating chambers and allows coating of a continuously moving strip.
In addition to the aforesaid advantages accruing from the flexibility of the process, there is the further desirable factor that different metals may be vaporized in the several chambers or from succeeding groups of vaporizing sources in a single chamber, and, therefore, built-up coatings of different compositions may be produced on the base metal. For example, aluminum, silver, copper or tin may constitute the first coat upon a base of steel or other material followed by a deposition of a different metal or metals either selected from those just mentioned or any other metal which it may be desired to use. By subsequent heating of such built-up coatings, a surface layer composed of a true alloy, e. g., aluminum-silver, aluminumcopper or copper-tin and many other combinations may be produced with resultant advantageous properties such as increased hardness, resistance to wear or corrosion.
It is apparent that by alternating adjacent transversely grouped metal vapor sources so that the groups, for example, contain different metals, parallel deposits of dissimilar metals may be applied to the surface of the strip. For instance, we may alternate stripes of aluminum with stripes of copper or we may deposit stripes of vaporized aluminum on a copper strip or a strip having a vaporized copper coating or vice versa. particularly useful in the case of foils; the method may be carried out with any combination of metals. Laminated products produced by this method are suitable for various decorative applications. Designs may be applied to the travelling strip by the use of an endless belt suitably perforated and disposed in close proximity to one side of the travelling strip between the strip and the vapor source. The suitably perforated endless belt or stenciltravelling at the same rate of speed as the strip being coated permits the continuous marking of the strip with designs in ac- This is cordance with the nature of the perforations in the stencil In a similar fashion, designs may be continuously applied to formed objects, for
example, cans and caps mounted on a saddle-like endless conveyor having the saddle perforated in accordance with the stencil design to be applied. The object so decorated can be removed through suitable air looks from one end of the system or stored in an evacuated chamber connected to the system. The objects may be fed to the conveyor from a hopper in communication with the system through suitable air locks. Conventional methods of metal coloring may, of course, be used to enhance the decorative effect. For example, by controlled heating of adecorated film in an oxidizing atmosphere comprising at least in part vaporized copper, the copper coated portions can be made to take on any desired color in a series ranging from copper red to an iridescent purple or black. Similarly, a jet black can be produced by heating such a coating in an atmosphere containing sulfur gases or by immersion in a solution of polysulfldes. Furthermore, a vaporized metal coating, such as copper, may be colored by electrochemical means, as, for xample, the production of oxide films of controlled thickness which in turn give the copper various and controllable interference colors. This is accomplished by immersion in a bath, a suitable electrolyte under controlled conditions in accordance with established practice. The various decorating methods are particularly useful for forming labels, multicolcred patterns and designs on caps, cans and other articles.
In addition to the foregoing features of the invention, we provide heating units which embody means for assuring that the metal to be vaporized will be constantly supplied and constantly vaporized at a substantially uniform and controllable rate. This is advantageous in that it enables constant conditions to be maintained in the coating chamber or chambers and assures the deposition of a continuous uniform film upon the travelling metal strip. Of particular importance, the provision of a continuous supply of the metal to be vaporized is accomplished automatically and,
therefore, in such a manner as to not necessitate any loss or interruption of vacuum. Automatic vaporizable metal replenishing means are suitable for carrying out the invention, e. g., crucibles containing a surplus of metal will serve to automatically maintain a constant supply or continual supply of metal vapor or mechanical devices for automatically feeding predetermined amounts of metal are employed.
A further embodiment of the invention oomprises the use of electrostatic means within the coating chamber for directing the gaseous metal positively and definitely during the deposition of the same as a, film upon the backing. In this connection, equipment such as is embodied in the Cottrell precipitator may be advantageously used for this purpose, with the metal backing strip acting as the electrode upon which precipi= tation occurs. For example, we have found that the metal vapor produced by our energizing source is ionized at least in part as a consequence of thermal and/or electrical ionization and the positively charged aluminum atoms can be made to travel with great velocity and directness toward the strip or base to be coated. Where the base is non-conductive, the aluminum atoms are directed toward a negatively charged electrode or plate on the far side of the non-conductive strip; where the base is conductive, the same method may be 11 applied or, alternatively, the strip itself may be made negative with respect to the charged aluminum vapor and thus constitute a moving electrode, directing the deposition of the coating upon itself. On the other hand, the us of such positive directional means is unnecessary in those cases where the energizing source and the container for the molten metal are placed below and open toward the surface of the strip material to be coated, which is a preferred method.
Furthermore, the vaporizing means can be used to produce an atmosphere of metal vapor under conditions permitting its diffusion in all directions.
While the metal coating film in many cases will present a satisfactory highly polished surface, the lustre of any coating formed in accordance with this invention which is not of maximum brilliance may be improved by passing the same through mirror-finish rolls such as tungsten carbide rolls. on the other hand, it has been found that steel can be coated with aluminum by our process to produce either a bright-finished product very closely resembling hot-dipped tin plate or a satin-finished product having a silver-white matter appearance resembling tin plate in which the tin coating is electro-deposited. The brightfinished aluminum coated product is obtained by vapolytically depositing aluminum on steel strip which has been given a mirror-finish by means of, for example, tungsten carbide rolls. The satin-finished product is similarly produced by depositing the aluminum upon steel rolled in conventional manner using cold rolls which have been ground but not polished to a mirror-finish.
In the drawings,
Figure 1 is a diagrammatic sectional elevation showing the initial portion of a line or system for continuously coating metal in accordance with this invention;
Figure 2 is a diagrammatic View of one of the vacuum chamber units;
Figure 3 is a view similar to Figure 2 in which a single chamber is employed as distinguished from a plurality of interconnected chambers as shown in Fi ure 2;
Figure 4 is a view similar to Figure 2 in which the material to be coated is travelled through the coating chamber or chambers in a vertical plane as distinguished from a horizontal plane as shown in Figures 2 and 3;
Figure 5 is a detail view partly in section showing the crucible and associated parts for heating the coating metal by means of high frequency current;
Figure 6 is a side view showing the manner in which preformed articles, e. g., closures, container bottoms and containers are supported while being carried through the coating system;
Figure '7 is a top view of the conveyor and articles thereon to be coated as shown in Figure 6;
Figure 8 is a sectional view showing the base metal such as steel directly coated with an adherent film of coating metal such as aluminum, deposited from aluminum vapor;
Figure 9 is a sectional view showing a base material such as steel coated with an adherent film of material such as lacquer, varnish or enamel over which is deposited directly a coating ,of metal such as aluminum deposited from aluminum vapor;
Figure 10 is a side elevation of another form of apparatus for carrying out the invention whereby continuous strip material is coated upon both sides;
Figure 11 is a detail sectional view of one of the housings from which the coiled strip is fed to the apparatus of Figure 10, the rewinding housing being of substantially similar construction; this view further shows the shaft upon which the coil supporting reel is mounted and the means whereby the same may be rotated while maintaining a vacuum-tight seal in the housing; I
Figure 12 is an end elevation of the housing showing the strip guide rolls;
Figure 13 is a detail elevational view showing the door of the housing and the sealing gasket associated therewith;
Figure 14 is an end elevation of the housing with the door of Figure 13 removed and showing an empty reel in position;
Figure 15 is a longitudinal vertical sectional view of one of the housings, taken on line 22-22 of Figure 14;
Figure 16 is a side elevation of another form of apparatus in which the strip is coated on both sides while travelling and wherein the strip is rotated through about its longitudinal axis after coating on one side to place the other side in proper coating position; and
Figure 17 to 20 are elevational views of the spaced rolls for rotating or turning the strip to 180 to carry out the operation of Figure 16.
While the invention will be described in connection with the coating of vaporized aluminum upon a steel strip or sheet, it is to be understood that other vaporizable metals may be used exemplified by magnesium, silver, tin, zinc, chromium, nickel, etc. Moreover, alloys of which those composed of aluminum and silver, silver and zinc, aluminum and manganese, nickel and chromium are examples, may be employed. In referring to a "pure metallic coating, and vaporized meta we intend to include by these and similar expressions, elements as well as alloys.
With respect to the use of metal alloys for the coating atmosphere, in some cases we employ separate sources for the elements which are to make up the alloy, so situated that their vapors intermingle, and control the heating so that each vaporizes at the desired rate to properly proportion the vapor mixture and hence deposit as an alloy of any desired composition upon the base. The sources are, of course, situated in the same coating chamber.
' One method of lining the cans is to melt and vaporize the aluminum by means of an electrically heated filament centrally located in the can body in a high vacuum. Tungsten wire is the most suitable material for the filament. Wire varying in'diameter from 0.015 to 0.045 inch may be used, but 0.035 inch is a preferred diameter although 0.025 inch has been satisfactorily used. We have used 12 to 20 amperes, 6 to 10 volts. The pressure used was quite low, being at least as low as 20 microns, and in many cases, as low as 0.1 micron. For some purposes, two or more coatings of aluminum may be built up to form a lining of desired thickness. In some cases, the
aluminum coating is partially oxidized to render' the lining more chemically or physically resistant, i. e., the lining is rendered harder. In those cases where the contents of the container will attack the aluminum lining, the lining may be suitably protected by a film of wax, chlorinated rubber or polyvinyl acetal resin. As will be appreciated, the galvanic protection aiforded by the aluminum lining is substantial, and moreover 'a coil of suitable backing or base material which may be steel or black iron, paper, textile fabrics, or some synthetic resinous material such as chlorinated rubber, Vinylite" resin, polyvinyl acetal resin, cellulose acetate or other organic strip material as well as glass cloth or glass ribbon and such strip is preferably directly coated, but in some cases may be provided with an intermediate film. The invention as stated is particularly concerned and will be described in connection with strip steel or black iron. The steel band is led from the roll through a suitable cleaning instrumentality H in the form of a bath, for example, a pickling bath to remove surface aecumulations and scale, and the strip is conducted thence, through a suitable drier H to evaporate any liquid or moisture which may have been retained upon the surfaces. Thereafter, the steel band is continued through a bright annealing furnace is if'annealing is required, and as heretofore stated, this heating step will serve to. reduce the amount of occluded gases in the metal. From the annealing apparatus IS, the strip is preferably coiled as at i ll.
Referring to Figure 2, a coil ill of uncoated strip material is placed in the housing It at the feed end of the vacuum coating unit indicated as a whole at U, carried through the unit and coated, and then recoiled in the housing it at the delivery end of the unit. Both the housings at the feed and delivery ends of the unit are under vacuum and are closed by a suitable hinged door, gasketed to insure a tight seal when the chamber is under reduced pressure, but which will allow the doors to be opened when the vacuum is broken so as to permit a coated coil to be removed and an uncoated coil to be supplied. The coil Hi may b mounted on a suitable feeding shaft wholly supported within the unit and the recoiling mechanism at the delivery end for drawing the strip through the unit may include a shaft operated by a suitable motor within the unit or from outside of the unit, the shaft in the latter case being suitably packed to afford a thorough seal.
The housing It opens into a closed conduit of reduced cross-section through which the strip is led as shown to the heating chamber l having suitable electrical heating means l6 therein and which chamber is under vacuum. In this heating chamber, the heating is carried out upon the continuously travelling strip to remove any occluded gases in the metal strip and also to vaporize any traces of volatile matter or surface accumulations. By this treatment and through the provision of a glow discharg means having electrodes il, a perfectly clean metal surface is presented to the coating chamber and the heating chamber I5 is provided with means such as an exhaust pump l 8 for positively exhausting any gases driven off in that chamber so that there is no possibility of polluting the metal atmosphere in the coating chamber. From the heating or outgassing chamber l5, the metal is continuously travelled to the coating chamber I9. Between the chamber l5 and the chamber I9, cooling means are provided in the restricted passage 20 if required. In some cases, the restricted passage itself having external walls exposed to the atmosphere, will act to dissipate the heat sufllciently so that no positive cooling means is required. This connection 20 between the chambers may be elongated so that the metal to be coated enters the coating chamber at any desired temperature, for example, in the case of steel to be coated with aluminum, in the neighborhood of about room temperature. As explained, above, if the metal enters the chamber at a more elevated temperature, this is not necessarily objectionable, and in some cases promotes adherency and continuit of the deposited film.
In the construction shown in Figure 2, the coating chamber is shown as comprising a series of chambers Illa, I91) and I90, and any desired number of chambers may be employed. The chambers are connected by restricted passages 21 which may be provided with positive cooling means in the form of chilling rolls 22 or may be lined with suitable cooling coils. As heretofore explained, these restricted passage-ways whose exterior surfaces are exposed to the atmosphere may be elongated if desired in order to effect cooling of the strip as it passes from one chamber to the other where this is found preferable to the provision of positive cooling means. It is believed that the provision of intermediate cooling means between the respective coating chambers of the series is conducive to good results, but a single coating chamber l9 such as shown in Figure 3 has been employed satisfactorily in lieu of the series of chambers shown in Figur 2.
Thesingle chamber shown in Figure 3 is connected with the housings I l and it and associated construction as described above in connection with Figure 2. In Figures 2 and 3, we have shown the metal as passing through the coating chamber or chambers in a horizontal plane while in Figure 4, we have shown the metal as being coated while travelling in a vertical plane, and for this purpose, after the metal leaves the coiled roll l0, it is turned through any suitable turning guides (not shown) disposed at 23. This turning operation takes place at any convenient time or place in the line after the strip Hi leaves the roll and is conducted under vacuum. Instead of the turning mechanism, the feed and recoil shafts and the roll may be vertically disposed.
The unit including the coating chambers l9 and housings l4 and I4 are exhausted or maintained at a suitably reduced pressure by a vacuum pump or combination of pumps of any suitable construction connected to the exhaust manifold pipe 24 having leads to the individual chambers as shown in Figure 2 or to the single chamber as shown in Figure 3. Within the coating chambers are disposed suitable vaporizing means which may be in the form of filaments as shown at 25 or electrical resistance or induction heated crucibles as shown at 26 or aluminum cathodes for sputtering.
By reason of the vaporizing devices, a constant supply of the gaseous coating metal is maintained in the chamber l9, and as will be later explained,
- automatic means are provided to insure that the supply of metal to be vaporized iscontinuously replenished as needed. In lieu of such automatic means, a predetermined amount of metal to be vaporized is disposed at the energizing sources according to the area of strip to be coated and the coating thickness desired. Such a predetermined amount of coating metal will be preferably employed where electrically heated crucibles are used to contain the coating metal or cathode sputtering is utilized. We. prefer to use an amount of coating metal slightly in excess of predetermined coating requirements. After the metal strip has travelled through the coating chamber, it is continuously led while maintained under vacuum through a cooling zone or vapor trap formed by the cooling coils 27 which surround the closed conduit leading from chamber we and which serve to trap any vapors which are discharged from the chamber I90. This cooling means 21 likewise serves to lower the temperature of the travelling strip material. A similar trap 29 maybe disposed at the other housing end, but this condition is generally taken care of in the chamber I where any objectionable vapors are continuously removed.
The coated material is drawn through the apparatus and after coating is rewound on a suitable reel in the housing I6. Where it is desired to heat the coated strip before it is rewound, a heating means i5 similar to the heating chamber I5 is interposed before the cooling means 21. As will be noted, the heating and cooling in each case takes place under a vacuum.
Referring to Figure 2, it will be observed that separate exhaust connections 28 having adjustable valves are provided for each chamber of the series. This permits selective variation of the reduced pressures maintained in each chamber so that the coating operation is rendered flexible.
One of the advantages of the method shown in Figures 2 to 4 is the ability to bring the coating chamber ii! to the best or most desired condition for coating by vaporization with a minimum of pumping effort, and therefore at a more rapid rate. That is, a. greater vacuum is required in the chambers l9a, I91) and I90 than is required in the remainder of the apparatus, namely, the housings and the chambers l5 and i5, and there are cases, for example, where a greater vacuum is desirable in one or two of the chambers Isa, Nb and Ho. Our method enables advantage to be taken of the law relating to the diffusion of gases at reduced pressure. in that we are able, with a minimum of pumping effort, to rapidly bring the chambers I So, I Qb and I90 to the required reduced pressure, and at the same time produce a. reduced pressure in the other chambers which is sufiicient for their respective particular purposes. In other-words, in our apparatus we are able to operate with a pressure gradient existing in the system with a minimum pressure or the highest vacuum existing in the vaporization chamber l9.
This method and the advantageous results thereof may .be achieved in several ways. For instance, the passages from the housings I 4 and i4 and from the respective chambers l5 and i5 and "la, I92) and I90 are restricted and, for example, in the case of stri metal, are of a thinness or narrow cross section such as will just allow the metal to freel travel in order that difiusion between the housings and the respective chambers may be reduced to a minimum. Where chilling means, heating means, or supporting or conveying means are interposed in such restricted passages, they so occupy the passage as to likewise reduce the possibility of any substantial dif-- fusion. Again, as shown in Figure 2, the manifold 24 is exhausted by a single line E to the exhausting means and therefore the admittance speed or evacuation speed will be greatest in the chambers i9a, Nb and I 90 which are closest to the exhaust pipe leading to the exhaust means,
whereas the housings l4 and I4 and the chambers i5 and IE will exhibit a pressure gradient with respect to the chambers i9, that is, will be less exhausted. Under such conditions, operation of the exhausting apparatus will rapidly bring all of the coating chambers 19 or any one or twoof them to the desired reduced pressure, and the other chambers and housings to a satisfactory reduced pressure, and by reason of the restricted passages, between the housings and the various chambers, the amount of diffusion will be negligible in the coating operations.
While we have illustrated in Figure 2 a single exhaust line E connected to the manifold, there may be several such lines connecting to a single exhaust means or to independent means. In such cases, the restricted passages between the housings-and respective chambers will likewise act to preclude any substantial diiiusion and the valves in the lines leading from the housings i4-I4' or the housings and chambers l5 and IE to the manifold (where the latter are connected to the manifold), for example, may be closed when a suitable vacuum has been established therein so that all of the further exhausting may be accomplished with respect to the coating chambers H or any one or two of them where a higher degree of vacuum is required.
Furthermore, we provide in some cases a separate exhausting means for each of the housings and chambers. With this method and construction the restricted passages between the housings and chambers again act to prevent any substantial difiusion, and the exhausting means may be discontinued when a reduced pressure has been established in any housing or any chamber in the required degree.
In the methods just described above, less pumping efiort is necessary, and the coating chambers are brought to the desired reduced pressure in a minimum of time.
In referring to exhausting means we mean, preferably, some multi-stage type using a suitable fore-pump for the preliminary exhaustion and higher vacuum pumps for subsequent stage or stages.
By reason of the restricted passages, the possibility of any substantial difi'usion occurring is so reduced to a minimum that the method will operate satisfactorily, notwithstanding there may be slight leaks, for example, in the housings M or M.
In this connection, and as herein explained, where articles of greater dimension than steel strip are being coated, the passages likewise will be of a cross-sectional dimension to just clear such articles, and suitable baiiles, e. g. flexible, may be disposed therein, if necessary, in order to reduce the possibility of diffusion.
In the construction shown in Figures 2, 3, 4, 10 and 16, provision is made for applying a film to each side of the strip material ill, but, if desired, the positioning of the vaporizing devices may be such that a coating is produced only upon one side of the strip.
In the various apparatus illustrated, we have shown both filament and crucible vaporizing means within the chambers. It is to be understood that in any one single chamber, all of the devices should be the same. Where a series of chambers are used, however, each chamber may have a different type of energizing source.
Referring to Figure 10, we have illustrated a further form of apparatus and methods which have proved highly satisfactory. The numeral It indicates a sealed housing from which strip material is fed continuously to and through a chamber II. The chamber II may be of any suitable materials such as glass, metals, alloys, etc. and may be of any suitable size and shape in cross-section. Preferably, the chamber H is tubular and elongated and has an upper horizontal leg Ila, a vertical leg llb, and another horizontal leg 'Ilc which leads to a sealed housing 12 in which the strip material coated durin its passage through the tube ll is recolled.
Referring to Figure 11, the housing 10 and the housing 12 each comprises a closed box It. This box is provided at one end with a strip passage 14 as shown in Figure 15 and in which is disposed a pair of guide rolls 15. At the opposite ends, the housing is closed by a door I6 which may be hinged or separate as shown in Figure 13. This door has a suitable packing or gasket 11 and is bolted to the housing as shown at I8 to seal the same. 3 At one side, the housing is provided with an enlarged opening 19, while at its opposite side, there is provided a recess 80 of smaller dimension than the opening 19 but concentric therewith. In each housing, there is disposed a reel 8| as shown in Figure 11 which is rotatable upon a shaft 82 in the case of the feed housing I and is positively rotated by the shaft 82 in the recoil housing I2 for withdrawing strip material from the coil in the housing I0 and continuously drawing the same through the tube I I. The shaft 82, it will be noted, has a tapered end 83 which is normally disposed within the housing and within the hub of the reel 8!. At one end of the tapered portion, there is provided a squared projection 8G which engages in a similar opening 85 in the reel 8|. From the projection Be there extends longitudinally a projection 86 extending into the recess 89 which acts as a guide and in some cases as a support or bearing for the shaft 82. The shaft 82 is supported in a bearing 8'! which is bolted at 88 to the wall of the housing in a manner to seal the same, there being provided a suitable packing 89 between the flange of the bearing Bl and the wall of the housing. The bearing 81 has a suitable packing consisting of lantern glands with stufiing indicated as a whole at 90, and the shaft may be suitably lubricated by lubricant supplied through the inlet 9i which may be removed by the outlet 92 normally maintained at the reduced pressure of the system. At its free end, the shaft carries a pulley 93 which is rotated by a suitable motor 94 as shown in Figare 10 for positively rotating the reel 0i in the housing 12 to draw the strip through the coating apparatus. In addition to its movement of rotation, the shaft 82 is movable laterally so as to withdraw the tapered portion 83 from engagement with the reel and outside of the housing a sufficient distance to clear the reel whereby the same may be removed and another reel containing a coil of strip material to be coated replaced within the housing. This lateral movement does not afiect the sealed condition of the housing because the bearing 81 is of a length that when the shaft is withdrawn from the housing, no part of the tapered portion extends beyond the hearing surface 95. When a reel has been positioned in the housing, the shaft is moved in to the position shown in Figure 18. and the apparatus is ready to be operated. The housings are in all respects similar, the only exception being that 18 positively driven and, therefore, carries the pulley 83.
' The tube II is connected to the housings by Joints 96 which are preferably of the flanged type and assure complete freedom from leakage. At 91, we have shown flanged joints for connecting sections of the tube, but these may be eliminated by welding, the ends of the sections together. The tube may be formed of Pyrex" glass but is preferably formed of steel having a smooth interior. In some cases, this smoothness is obtained by a suitable coating, such as tin. A plurality of pairs of guide rolls 15 are disposed in the tube, and at the ends of the chambers I la and 1 lo, guide rollers 98 are employed over which the continuous strip travels from the upper le Ila to the lower reversely extending leg I I0. These rollers 98 are preferably supported by the end sealing members 99 by means of brackets 99', the sealing members 99, brackets 99 and rollers 98 being of conductive material in some cases for a purpose to be later described.
Disposed at suitable points along the length of the tube are the vaporizing means which may be of the character heretofore described and which are indicated as a whole at I00 in Figure 5. In the present instance, crucibles IOI are illustrated and are preferably heated by a high frequency current introduced through th line I02, the line being suitably water-cooled as well known. The line I03 is in the nature of a tuning tap. The tubular extension I05 opening into the tube II and in which is disposed a crucible I01 and its heating means is sealed by a leak-proof joint I04 which also carries suitable insulation. Instead of having the vaporizing means disposed in suitable extensions I05, they may be positioned within the tube below the undersurface of the moving strip to be coated, and they may be suitably connected so that by opening one of the ends 99, all of the vaporizing means may be removed for repair or replenishing with metal.
The operation is, of course, carried out under a suitably high vacuum which is produced by connecting the line I06 to an extension I05 of the tube by means of a leakproof joint I91, the line I96 being connected to a suitable vacuum pump. In this connection, vacuum pumps may be associated with each of the housings I0 and I2 in addition to the vacuum pump working through the line I06.
It will be observed that a strip of metal to be coated is withdrawn as a continuous length from the housing I0 and continuously travelled through the tube leg Na in which first its undersurface is coated by means of the vaporizing device or devices IIIO disposed below the unde'rsurface of the strip, whereupon the strip is turned through 180 in the leg I It and its opposite surfac is presented to and similarly coated by the vaporizing means in the leg IIc whereupon the coated strip is recoiled in the housing I2.
The construction shown in Figure 16 embodies a single longitudinal tube II in which means are provided for turning the strip after the undersurface has been coated through an angle of 180 so that its opposite surface may be similarly coated. The means for accomplishing this is shown in Figures 17 to 20 and embodies guide rolls l5 and guide rolls I08 and I09 which are disposed at a suitable angle with respect to the guide rolls 15 to turn the strip as it travels through the tube 1 I. Otherwise, the construction is similar to that shown in Figure 10.
the shaft 82 in the case of the housing 12 is Where the crucible i used, it is located ap- 19 proximately three inches from the strip with the molten metal about four inches from the surface of the strip. This gives satisfactory results. However, the crucible or other heating mean may be located at various distances, and we have found that the farther away the crucible is located, the greater the area of the strip which will be covered. Moreover, the lower the pressure in the tube H, the greater the distance the crucible can be disposed away from the strip, and th thinner the coating which will be produced. Also, the lower the pressure which is maintained in the tube H, the fewer the crucibles which need be employed.
In carrying out the invention with a strip three inches wide, we moved the strip at the rate of twenty-three feet per minute and maintained a pressure of one micron in the tube 1 I Using aluminum as the coating metal, we obtained a satisfactorily coated strip having a coating of about seven millionths of an inch thick. -The power emplcyed depends on the width of the strip being covered.
The crucibles or resistance heating means may be disposed in various ways to obtain the desired coating, but it is preferable in the absence of any means for positively directing the vaporized metal toward the strip, to dispose the same below the travelling strip, since we find that under reduced pressure, the metal tends to diffuse upwardly and efliciently cover the lower exposed surface of the strip. In this connection, the vaporizing means may extend transversely of the path of movement of the strip so as to comprehend the entire transverse dimension thereof, or the vaporizing means may be disposed in staggered relation to insure complete coating. The important consideration is to obtain a uniform coating of desired thickness, and the position of the vaporizing means will, therefore, depend upon the area of the sheet to be covered.
Referring to Figure 10, we have indicated two optional means for directing the vapor in any of the methods herein set forth, one or the other of which may be satisfactorily employed. The numeral H indicates a suitably insulated electrode which is sealed into one of the legs of the system, and the numeral Ill indicates an electrical contact of opposite polarity mad through the metal plate 99 and supporting bracket and roll 98 with th strip I0. Between the electrodes H0 and III, a difference of potential of up to several thousand volts is established, in such manner that the electrode connected to the strip is of negative polarity. This difierence of potential can be established by use of a step-up transformer in conjunction with a rectifier such as a kenotron or a mechanical rectifier operated by a. synchronous motor. The vaporized aluminum ions have a positive charge and will be attracted to the negatively charged moving steel strip [0. The second method involves the use of electrodes I I 2 and H3 and would be utilized in that case where the metal is to be deposited on the strip by the cathode sputtering process. The electrode H2 is sealed through the crucible so as to make electrical contact with the molten metal inside. This electrode will be at a negative potential with respect to the strip which is connected to the positive side of a high voltage direct current source through the electrode or connection H3. The vapor directing means described with respect to the optional methods may be interposed in the system at any convenient point and have been illustrated in Figure 10 simply for convenience. Wher the legs 1| etc. are metallic, to avoid directing the deposition of metal vapor upon the metallic walls, adjacent to the strip in the vicinity of the vapor source, these walls will be electrically insulated from the mov. ing strip in any suitable manner a by winding and unwinding the strip upon non-conducting mandrels iii. In this connection, we may take advantage of this high voltag direct current to effect cleaning of the strip by means of a glow discharge. 1
It is to be understood that while we have illustrated a continuous strip of material being coated, individual strips of any desired length may be suitably fed through the coating system while carried at upon a conveyor or suspended there.- from. In this connection, also, one or both sides of a flat material such as strips or sheets may be coated, depending upon the position of the metal vaporizing means. Likewise, where the metal is coated upon both sides and it is desired to use an intermediate organic film, this will be applied to both sides of the strip or sheet.
In some cases, instead of forming the metal into a coil i0, it is introduced directly from the drier II or the annealer l3 into the coating chamber continuously passing from these instrumentalities into the unit, Also, in such cases, we some times provide at the entrance and exit ends of the unit a liquid sealing leg preferably of substantially U-shape through which the continuous strip is travelled. The seal is established by means of a suitable liquid maintained in the leg such as water, mercury, molten lead and other satisfactory liquids.
Where liquid sealing legs are employed it may be necessary to provide special means for preventing contamination of the coating metal by contact with the sealing liquid or vapor therefrom: For example, mercury will alloy with freshly deposited aluminum. We overcome this objection in that the coated steel emerging from the vacuum coating apparatus is first led through a layer of oil of low vapor pressure floating on top of the mercury of the exit sealing leg, whereby the oil film thus applied to the aluminum coated sheet will prevent contact between the mercury and the aluminum coating.
In the event that objectionable amounts of mercury vapors from the sealing leg at the entrance to the evacuated system are not removed by the trap 29 or from the de-gassing chamber l5, or by means of refrigerating coils or condensing surfaces within the evacuated system adjacent to the end of the aforesaid sealing leg in advance of the coating chamber l9, then these traces of mercury vapor are removed by an agent having a strong afiinity for mercury such as metallic sodium, potassium or other alkali metal disposed between the sealing leg and said coating chamber. Capsules containing the absorbing metal can be separately vaporized by induction heating so that a film will be deposited upon the walls of the system ahead of the aluminum coating chamber i9, and this operation'will be performed after initial evacuation but before aluminizing commences.
As explained above, the use of liquid sealing various articles are maintained in position on the belt 50 by permanent or temporary magnets and the coating may be carried out in any of the apparatus described herein. At the conclusion of the final step of the coating operation, 1. e., when the conveyor reaches housing I4, a suitable means is employed to remove the coated articles from the belt 50.
In Figures 6 and '7, we have illustrated crown caps at 52, screw caps at 53, lug caps at 54, can bottoms at 55 and containers at 6 6. These various articles as well as containers, may be coated interiorly or exteriorly, or both, in accordance with their positions on the belt. Thus the outside of an article may be coated during part of the movement of the belt whereupon the article, held in position by a temporary magnet is inverted by a suitable means (not shown) and the inside coated or lined during another period of the travel of the belt. It is to be noted that the belt 50 is provided with a multiplicity of openings to permit communication through the belt. It is preferably formed of stainless steel and the sections thereof may be hinged as shown at 51.
In the case where articles of greater dimension than relatively thin strip material are being coated in accordance with the apparatus and methods herein described, the apparatus will be suitably enlarged to permit the passage of such articles through the respective instrumentalities of the unit. In this connection, where preformed articles are carried by the conveyor 50, they may be fed thereto at the feed end Id of the unit from a suitable magazine maintained under air-tight or vacuum conditions, and discharged at the delivery end M of the unit into a suitable hopper or other collecting means, likewise maintained under vacuum or air-tight conditions. The magazine and hopper may be disposed within the unit or may be disposed outside of the unit and connected thereto through suitable air-tight connections. This will be particularly the case where caps, can bottoms and containers are being coated.
Referring to Figure 8, we have shown at 66 a base of any suitable material, such as steel or black iron, paper or film of organic material, directly coated with a coextensive film of aluminum Bl deposited from aluminum vapor.
In Figure 9, we have shown a similar base 66 provided with a coextensive intermediate film 68, such as lacquer, varnish or enamel upon which is deposited a coextensive coating 61 of aluminum deposited from aluminum vapor.
As explained above, the base 56 may be formed of paper or other flexible material, such as synthetic resins and cellulose derivatives, as well as chlorinated rubber or metal foils, i. e., of steel. In this manner, suitable materials are provided which are useful for providing center spots and overall facings for caps and closures. As understood, the backing or base in the case of spotting materials is provided with a suitable adhesive coating for securing the spot or overall facing to the cushion liner of the closure.
Foils of this character, of course, may be used for their insulative qualities and decorating characteristics.
Also, in the case of two-part caps, particularly those of the screw cap type, the inner member may be produced in accordance with this invention by coating the steel with a coextensive fllm of aluminum either inside or outside, or both. Likewise, the outer threaded member may be similarly coated.
Wherever desirable, the aluminum coating prepared in accordance with this invention, whether for spotting materials or as for linings for closures and containers, may be provided with a coating of suitable lacquer or varnish. Such organic coatings are useful where chemical action between the contents and the lining or foil might be set up.-
While we have referred herein to steel band or strip, the invention is equally applicable to the coating of other material in continuous lengths, for example, wire and wire screening.
When the vacuum i broken with any of the methods described herein, as by cutting oil the pump and allowing air to enter the system, we prefer that such air be dehydrated before it enters the system. This we find substantially reduces the time required to pump down the system to the desired reduced pressure for the next operation.
Also in the various methods recited, we prefer to introduce to the crucibles or other vaporizing means sufiicient metal to be vaporized as will coat a predetermined length and width of strip. For example, for coating 5,000 feet of thirty inch wide strip on both sides with sufiicient aluminum to give commercially serviceable rust resistance. approximately six pounds of aluminum will be sufilcient and where several crucibles are used as in Figure 10, the total amount required is preferably equally divided among the crucibles at thestart of each run, 1. e., one and a half pounds in each crucible.
With further reference to the making of metal powder in accordance with this invention, it has been found that vapolytic aluminum films produced on steel, particularly relatively thick coatings ranging from about 0.1 mil to l mil in thickness, while initially continuous and relatively adherent will separate from the steel and be readily detached as thin irregular flakes or lamellar particles when the steel is made to bend sharply. Such flakes can be ball-milled to give a more uniform and smaller sized particle with or without further substantial reduction in thickness, i. e., converted to a form suitable for use in aluminum paint.
The power required to vaporize a pound of aluminum is so small, i. e. theoretically, it is only about 2.1 kw.-hours and with power at 1 cent per kw.-hour, it is apparent that the vapolytic method offers a much cheaper method for producing aluminum powder than the present method involving a cost of about 23 cents per pound to reduce sheet aluminum to powder, excluding metal cost. Furthermore, thi is the only method that is explosion-proof and that can produce aluminum powder Practically free from oxide. All present methods involve powdering the aluminum under conditions where oxygen is present, and oxide and explosions may be produced. We produce aluminum powder by condensing aluminum vapor on an endless belt, or by using a strip which can be operated first in one direction and then another, much as is the method followed in the vapolytic unit disclosed in Figure 10, except that the speed of travel of the belt will be so slow that a relatively heavy aluminum film will be formed and means will be provided for detaching this film by sharply bending the steel belt or strip or by a suitable doctor blade for example. The fragmented aluminum flakes thus obtained are ultimately withdrawn from the vacuum system and ball-milled and screened to give aluminum powder suitable for paint, etc. We may ballmill in vacuum or according to conventional practice; in the latter case, a substantial part of the time normally required to produce the desired fineness is saved, and the explosion hazard, while not eliminated, has been somewhat reduced. Alternatively, we carry out the ball-milling operation under an inert atmosphere, and have an aluminum powder lower in oxide content than conventionally produced.
In connection with the operations shown in Figures 10 and 16, both surfaces of the travelling strip [0 are simultaneously and successively coated. Also, referring to Figures 10 and 16, it is to be understood that as with other forms of the invention, the vapoly-tic means I 00 may be disposed in each leg Na and lib upon opposite sides of the strip travelling therethrough so as to simultaneously coat opposite sides or the strip in as it travels through the respective legs of the chamber H.
No claim is made in this application to the sub- .iect-matter which is the Joint invention of the inventors in copending application Serial'No. 349,646, flied August 2, 1940, now U. S. Patent 2,382,432, granted August 14, 1945.
We claim:
1. A method of coating a metal sheet with a vaporized metal comprising introducing the metal to be coated, prior to coating into a feeding zone and maintaining the same under reduced pressure therein, continuously advancing the metal sheet from said feeding zone in a substantially horizontal plane, while maintaining the metal sheet under reduced pressure, into a coating zone with the metal sheet at a temperature below that of the vaporized metal, maintaining that coating zone also under reduced pressure twisting the metal sheet through an angle of substantially 180 in the coating zone as it travels through the same, vaporizing the coating metal in said coating zone continuously as the metal sheet travels therethroush. maintaining a difference in potential between the continuously traveling metal sheet and the vaporized metal ions to thereby direct the vaporized metal to the metal sheet and to deposit the vaporized metal upon successively exposed longitudinally as spaced opposite surfaces 01 the continuously traveling metal sheet presented by said twisting while the metal sheet is moving through the coating zone, and continuously collecting the coated metal sheet from said coating zone in a zonemaintained under reduced pressure.
2. A method of coating a metal base with a vaporized metal comprising introducing the metal to be coated, prior to coating into a feeding zone and maintaining the same under reduced pressure therein, continuously introducing the metal from said feeding zone, while maintaining the metal under reduced pressure, into a coating zone with the metal at a temperature below that of the vaporized metal, maintaining the coating zone also under reduced pressure,
- coating the metal surface on one side as it travels through said zone by vaporizing the coating metal in said coating zone continuously as the metal base travels therethrough and by maintaining a (Inference in potential between the continuously traveling metal base and the vaporized metal ions to thereby direct the vaporized metal to the metal base and to deposit the vaporized metal upon said side, coating another side of said metal base as it continuously travels from said first zone through a second zone and in the same manner as in said first zone, the second coating zone also being maintained under reduced pressure, and continuously collecting the coated metal from said second coating zone in a zone maintained under reduced pressure.
3. The method according to claim 1 wherein the metal base is steel and the vaporized metal for producing the coating on the steel is aluminum.
4. The method in accordance with claim 2 wherein the metal base is steel and the vaporized metal for producing the coating on the steel isaluminum.
5. The method in accordance with claim 2 wherein. the metal being coated is sheet metal and the same is continuously advanced from the feeding zone in a substantially horizontal plane.
. CHARLES E. MCMANUS.
JOHN D. ELDER. GILES B. COOKE. ALBERT J. DORNBLA'IT.
US409090A 1941-08-30 1941-08-30 Coating Expired - Lifetime US2405662A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US409090A US2405662A (en) 1941-08-30 1941-08-30 Coating

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US409090A US2405662A (en) 1941-08-30 1941-08-30 Coating

Publications (1)

Publication Number Publication Date
US2405662A true US2405662A (en) 1946-08-13

Family

ID=23619009

Family Applications (1)

Application Number Title Priority Date Filing Date
US409090A Expired - Lifetime US2405662A (en) 1941-08-30 1941-08-30 Coating

Country Status (1)

Country Link
US (1) US2405662A (en)

Cited By (44)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2638428A (en) * 1948-02-23 1953-05-12 Gordon James Edward Method of producing a metal facing on hardenable material
US2638423A (en) * 1949-08-25 1953-05-12 Ohio Commw Eng Co Method and apparatus for continuously plating irregularly shaped objects
US2656283A (en) * 1949-08-31 1953-10-20 Ohio Commw Eng Co Method of plating wire
US2656284A (en) * 1949-09-07 1953-10-20 Ohio Commw Eng Co Method of plating rolled sheet metal
US2658006A (en) * 1949-05-11 1953-11-03 Keuffel & Esser Co Measuring tape
US2680699A (en) * 1952-04-21 1954-06-08 Milton D Rubin Method of manufacturing a conductive coated sheet and said sheet
DE1009883B (en) * 1953-05-15 1957-06-06 Heraeus Gmbh W C High vacuum evaporation system
US2812272A (en) * 1954-08-02 1957-11-05 Ohio Commw Eng Co Apparatus and method for the production of metallized materials
US2820722A (en) * 1953-09-04 1958-01-21 Richard J Fletcher Method of preparing titanium, zirconium and tantalum
US2839378A (en) * 1955-04-15 1958-06-17 American Marietta Co Method of making metal flakes
US2865787A (en) * 1955-03-09 1958-12-23 Heberlein Patent Corp Process for producing color effects on textile and other sheet-like material and products therefrom
US2867552A (en) * 1954-06-01 1959-01-06 Ohio Commw Eng Co Metallized filamentary materials
US2906641A (en) * 1958-04-18 1959-09-29 Nat Res Corp Process for producing aluminum-coated black iron strip
US2920981A (en) * 1954-03-30 1960-01-12 Owens Corning Fiberglass Corp Metal coated fibers and treatments therefor
US2940873A (en) * 1957-07-18 1960-06-14 Itt Method of increasing the thickness of fine mesh metal screens
US2958899A (en) * 1953-10-09 1960-11-08 Int Resistance Co Apparatus for deposition of solids from vapors
US2986115A (en) * 1958-03-14 1961-05-30 Union Carbide Corp Gas plating of synthetic fibers
US3004866A (en) * 1957-11-04 1961-10-17 Union Carbide Corp Method and apparatus for gas plating nickel films with uniformity of resistance
US3012904A (en) * 1957-11-22 1961-12-12 Nat Res Corp Oxidizable oxide-free metal coated with metal
US3019515A (en) * 1953-11-10 1962-02-06 Owens Corning Fiberglass Corp Metal coated glass fibers
US3043715A (en) * 1958-08-13 1962-07-10 Nat Res Corp Method and apparatus for vacuum coating metallic substrates
US3075385A (en) * 1960-12-15 1963-01-29 Clifford M Stover Hygrometer
US3081485A (en) * 1958-11-20 1963-03-19 Steigerwald Karl Heinz Process and apparatus for treating synthetic plastic materials
US3086879A (en) * 1958-03-05 1963-04-23 Frederic H Lassiter Metallized products and foils and method of forming the same
US3117065A (en) * 1959-09-02 1964-01-07 Magnetic Film And Tape Company Method and apparatus for making magnetic recording tape
US3123489A (en) * 1961-02-06 1964-03-03 Method for preparing nacreous pigments
US3181209A (en) * 1961-08-18 1965-05-04 Temescal Metallurgical Corp Foil production
US3201275A (en) * 1961-12-21 1965-08-17 Gen Electric Method and apparatus for meniscus coating
US3223552A (en) * 1960-01-14 1965-12-14 Nippon Telegraph & Telephone Method for producing thin titano-ceramic film
US3268422A (en) * 1960-06-09 1966-08-23 Nat Steel Corp Electroplating bath containing aluminum and manganese-bearing materials and method of forming aluminummanganese alloy coatings on metallic bases
US3270381A (en) * 1965-08-04 1966-09-06 Temescal Metallurgical Corp Production of ductile foil
US3278331A (en) * 1965-07-26 1966-10-11 Pennsalt Chemicals Corp Process for coating steel with zinc
US3326177A (en) * 1963-09-12 1967-06-20 Pennsalt Chemicals Corp Metal vapor coating apparatus
US3410636A (en) * 1963-10-01 1968-11-12 Gen Electric Optically smooth reflector construction
US3438754A (en) * 1965-02-18 1969-04-15 Republic Steel Corp Zinc-coated steel with vapor-deposited aluminum overlay and method of producing same
US3660146A (en) * 1969-09-29 1972-05-02 Nat Res Corp Method of coating stiff materials onto fragile, heat vulnerable substrate webs
US3957608A (en) * 1974-01-15 1976-05-18 Cockerill-Ougree-Providence Et Esperance-Longdoz, En Abrege "Cockerill" Process for the surface oxidisation of aluminum
US3985917A (en) * 1972-03-02 1976-10-12 Avco Corporation Method of depositing material on a heated substrate
US4911810A (en) * 1988-06-21 1990-03-27 Brown University Modular sputtering apparatus
US5198033A (en) * 1991-10-31 1993-03-30 Medtronic, Inc. Continuous plasma surface treatment apparatus for running length polymeric tubing
US20120064201A1 (en) * 2010-09-15 2012-03-15 Del Monte Corporation Galvanic package for fruits and vegetables and preservation method
US20120164344A1 (en) * 2009-09-03 2012-06-28 Industrie De Nora S.P.A. Activation of Electrode Surfaces by Means of Vacuum Deposition Techniques in a Continuous Process
US20130183793A1 (en) * 2012-01-04 2013-07-18 Colorado State University Research Foundation Process and hardware for deposition of complex thin-film alloys over large areas
US20150158048A1 (en) * 2013-12-10 2015-06-11 Applied Materials, Inc. Substrate spreading device for vacuum processing apparatus, vacuum processing apparatus with substrate spreading device and method for operating same

Cited By (51)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2638428A (en) * 1948-02-23 1953-05-12 Gordon James Edward Method of producing a metal facing on hardenable material
US2658006A (en) * 1949-05-11 1953-11-03 Keuffel & Esser Co Measuring tape
US2638423A (en) * 1949-08-25 1953-05-12 Ohio Commw Eng Co Method and apparatus for continuously plating irregularly shaped objects
US2656283A (en) * 1949-08-31 1953-10-20 Ohio Commw Eng Co Method of plating wire
US2656284A (en) * 1949-09-07 1953-10-20 Ohio Commw Eng Co Method of plating rolled sheet metal
US2680699A (en) * 1952-04-21 1954-06-08 Milton D Rubin Method of manufacturing a conductive coated sheet and said sheet
DE1009883B (en) * 1953-05-15 1957-06-06 Heraeus Gmbh W C High vacuum evaporation system
US2820722A (en) * 1953-09-04 1958-01-21 Richard J Fletcher Method of preparing titanium, zirconium and tantalum
US2958899A (en) * 1953-10-09 1960-11-08 Int Resistance Co Apparatus for deposition of solids from vapors
US3019515A (en) * 1953-11-10 1962-02-06 Owens Corning Fiberglass Corp Metal coated glass fibers
US2920981A (en) * 1954-03-30 1960-01-12 Owens Corning Fiberglass Corp Metal coated fibers and treatments therefor
US2867552A (en) * 1954-06-01 1959-01-06 Ohio Commw Eng Co Metallized filamentary materials
US2812272A (en) * 1954-08-02 1957-11-05 Ohio Commw Eng Co Apparatus and method for the production of metallized materials
US2865787A (en) * 1955-03-09 1958-12-23 Heberlein Patent Corp Process for producing color effects on textile and other sheet-like material and products therefrom
US2839378A (en) * 1955-04-15 1958-06-17 American Marietta Co Method of making metal flakes
US2940873A (en) * 1957-07-18 1960-06-14 Itt Method of increasing the thickness of fine mesh metal screens
US3004866A (en) * 1957-11-04 1961-10-17 Union Carbide Corp Method and apparatus for gas plating nickel films with uniformity of resistance
US3012904A (en) * 1957-11-22 1961-12-12 Nat Res Corp Oxidizable oxide-free metal coated with metal
US3086879A (en) * 1958-03-05 1963-04-23 Frederic H Lassiter Metallized products and foils and method of forming the same
US2986115A (en) * 1958-03-14 1961-05-30 Union Carbide Corp Gas plating of synthetic fibers
US2906641A (en) * 1958-04-18 1959-09-29 Nat Res Corp Process for producing aluminum-coated black iron strip
US3043715A (en) * 1958-08-13 1962-07-10 Nat Res Corp Method and apparatus for vacuum coating metallic substrates
US3081485A (en) * 1958-11-20 1963-03-19 Steigerwald Karl Heinz Process and apparatus for treating synthetic plastic materials
US3117065A (en) * 1959-09-02 1964-01-07 Magnetic Film And Tape Company Method and apparatus for making magnetic recording tape
US3223552A (en) * 1960-01-14 1965-12-14 Nippon Telegraph & Telephone Method for producing thin titano-ceramic film
US3268422A (en) * 1960-06-09 1966-08-23 Nat Steel Corp Electroplating bath containing aluminum and manganese-bearing materials and method of forming aluminummanganese alloy coatings on metallic bases
US3075385A (en) * 1960-12-15 1963-01-29 Clifford M Stover Hygrometer
US3123489A (en) * 1961-02-06 1964-03-03 Method for preparing nacreous pigments
US3181209A (en) * 1961-08-18 1965-05-04 Temescal Metallurgical Corp Foil production
US3201275A (en) * 1961-12-21 1965-08-17 Gen Electric Method and apparatus for meniscus coating
US3326177A (en) * 1963-09-12 1967-06-20 Pennsalt Chemicals Corp Metal vapor coating apparatus
DE1295959B (en) * 1963-09-12 1969-05-22 Pennsalt Chemicals Corp Device for applying a metallic coating to a metal strip by vacuum vapor deposition
US3410636A (en) * 1963-10-01 1968-11-12 Gen Electric Optically smooth reflector construction
US3438754A (en) * 1965-02-18 1969-04-15 Republic Steel Corp Zinc-coated steel with vapor-deposited aluminum overlay and method of producing same
US3278331A (en) * 1965-07-26 1966-10-11 Pennsalt Chemicals Corp Process for coating steel with zinc
US3270381A (en) * 1965-08-04 1966-09-06 Temescal Metallurgical Corp Production of ductile foil
US3660146A (en) * 1969-09-29 1972-05-02 Nat Res Corp Method of coating stiff materials onto fragile, heat vulnerable substrate webs
US3985917A (en) * 1972-03-02 1976-10-12 Avco Corporation Method of depositing material on a heated substrate
US3957608A (en) * 1974-01-15 1976-05-18 Cockerill-Ougree-Providence Et Esperance-Longdoz, En Abrege "Cockerill" Process for the surface oxidisation of aluminum
US4911810A (en) * 1988-06-21 1990-03-27 Brown University Modular sputtering apparatus
US5198033A (en) * 1991-10-31 1993-03-30 Medtronic, Inc. Continuous plasma surface treatment apparatus for running length polymeric tubing
US5277753A (en) * 1991-10-31 1994-01-11 Medtronic, Inc. Continuous plasma surface treatment method for elongated, flexible, clear polymeric tubing
US20120164344A1 (en) * 2009-09-03 2012-06-28 Industrie De Nora S.P.A. Activation of Electrode Surfaces by Means of Vacuum Deposition Techniques in a Continuous Process
US20120064201A1 (en) * 2010-09-15 2012-03-15 Del Monte Corporation Galvanic package for fruits and vegetables and preservation method
US8420140B2 (en) * 2010-09-15 2013-04-16 Del Monte Corporation Galvanic package for fruits and vegetables and preservation method
US9422103B2 (en) 2010-09-15 2016-08-23 Del Monte Foods, Inc. Galvanic package for food products
US20130183793A1 (en) * 2012-01-04 2013-07-18 Colorado State University Research Foundation Process and hardware for deposition of complex thin-film alloys over large areas
US8778081B2 (en) * 2012-01-04 2014-07-15 Colorado State University Research Foundation Process and hardware for deposition of complex thin-film alloys over large areas
US8956698B2 (en) 2012-01-04 2015-02-17 Colorado State University Research Foundation Process and hardware for deposition of complex thin-film alloys over large areas
US20150158048A1 (en) * 2013-12-10 2015-06-11 Applied Materials, Inc. Substrate spreading device for vacuum processing apparatus, vacuum processing apparatus with substrate spreading device and method for operating same
US9333525B2 (en) * 2013-12-10 2016-05-10 Applied Materials, Inc. Substrate spreading device for vacuum processing apparatus, vacuum processing apparatus with substrate spreading device and method for operating same

Similar Documents

Publication Publication Date Title
US2405662A (en) Coating
US2382432A (en) Method and apparatus for depositing vaporized metal coatings
US2384500A (en) Apparatus and method of coating
US2671739A (en) Plating with sulfides, selenides, and tellurides of chromium, molybdenum, and tungsten
US3326177A (en) Metal vapor coating apparatus
US4183975A (en) Vacuum metallizing process
US3123493A (en) Art of bonding of vacuum metallized coatings
US3205086A (en) Method and apparatus for continuous vacuum metal coating of metal strip
KR890002742B1 (en) A combined continuous plating apparatus for hot-dip plating and vacuum deposition plating
US3700486A (en) Method for coating filaments
Schiller et al. Vacuum coating of large areas
US2046036A (en) Method of coating ferrous bodies with other metals
US3957608A (en) Process for the surface oxidisation of aluminum
JPH02194162A (en) Production of zn-mg alloy plated metallic material
US3447951A (en) Cyclone separation of particles in vapor coating
US2023364A (en) Metal coated ferrous article and process of making it
US20060096674A1 (en) Method for coating the surface of a metallic material, device for carrying out said method
JPH08134632A (en) Production of zinc-magnesium alloy plated steel sheet
CN2934268Y (en) Metal plate belt vacuum film coating equipment
US3281262A (en) Art of bonding of vacuum metallized coatings to metal substrates
JPS634057A (en) Production of alloyed galvanized steel strip by vapor deposition
US3761302A (en) Reducing re evaporation of vacuum vapor deposited coatings
JPS6157905B2 (en)
JPS61253382A (en) Plating method for forming two layers of zn and al
JPH0617232A (en) Si/zn two-layer galvanized steel sheet excellent in corrosion resistance and having beautiful appearance and its production