US2729190A - Apparatus for plating the interior of hollow objects - Google Patents

Apparatus for plating the interior of hollow objects Download PDF

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US2729190A
US2729190A US250306A US25030651A US2729190A US 2729190 A US2729190 A US 2729190A US 250306 A US250306 A US 250306A US 25030651 A US25030651 A US 25030651A US 2729190 A US2729190 A US 2729190A
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flanges
plating
tubular member
flange
gas
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Pawlyk Peter
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    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C16/00Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
    • C23C16/04Coating on selected surface areas, e.g. using masks
    • C23C16/045Coating cavities or hollow spaces, e.g. interior of tubes; Infiltration of porous substrates

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  • This invention relates to apparatus and methods for the coating of metallic bases with metallic coats deposited from the vapor state by the thermal decomposition of metal-bearing gases. More particularly the invention relates to the uniform coating of the interior ofhollow objects of tubular structure such as gun barrels andcylindrical bearing surfaces.
  • a primary object of the present invention is to provide improved apparatus whereby the interior platingof hollow objects may be uniformly achieved.
  • An important object of the present invention is to. provide equipment for the platingof hollow objects ona mass production basis.
  • a principal object of the invention istoprovide an improved method for the interior plating of hollow objects.
  • the invention comprises a gas plating system in which the object to be plated itself forms walls ofthe plating chamber, and which object is rotated/about a slotted tube. adapted to bear the volatilized.metaLbearingcompound to the object.
  • The. system include means for the mounting of the hollow object'- about the slotted tube for the rotation of the object, means to direct the fiow of the plating gases uniformly totheinterior walls of the object, and means to provide for the uniformity of plating gas flow through the system.
  • the invention also includes the. featu re of ready interchangeability of plating objectswhich facilitates the use of mass production methods in the gasplating of hollow objects. Substantially all materials which decompose under the influence of heat are operable in theprocess of invention, the compounds containing chromium and nickel, e. g. nickel carbonyl being most suitable.
  • Figure 1 is a schematic representation of one em bodi ment of the apparatus of invention
  • Figure 2 is an enlarged sectional view of theobject to be plated including means illustrating the mountingthereof;
  • Figure 3 is a view of the left hand end of the structure shown in Figure 2;
  • Figure 4 is a view in section of a modification of the slotted tube of Figure 2;
  • Figure 5 is an end view of the structure of Figure 4.
  • Figure 6 illustrates a modifiedform of the invention particularly adapted for the plating of long hollow objects
  • Figure 7 is a view of a modification of the structure of Figure 6;
  • Figure 8 illustrates a method of mounting a hollow object to secure plating of the entire interior surface.
  • the apparatus is shown to comprise the following general components: a source A of inert carrier gas; a substantially constant temperature source B of metal-bearing gas; a plating chamber system C; a recovery system D; and a vacuum pump system B for controlling plating gasfiow.
  • Source A may comprise a conventional cylinderl conhigh vapor pressure.
  • the cylinder is provided with a valve 3 for the control of gaseous carbon dioxide flow therefrom and a gauge 4 for indicating the flow rate.
  • the source B of metal-bearing gas includes a shell 5 containing a solid powdered metal-bearing compound, chromium carbonyl 6.
  • the shell 5 is surrounded by a hollow coil 7. and the coil and shell are submerged in oil 8 of tank 9, the whole assembly being adapted to be heated by electric heater 10 to a substantially constant temperature at which chromium carbonyl has a relatively
  • the oil 8 contacts one element 11 of a thermostatic control which is suitably connected with heater 10 in the known manner for regulation of heat input to the system.
  • a stirrer 12 driven by motor 13 may be employed.
  • the coil 7 surrounding shell 5 is connected at one end through hollow tube 14 to the valve 3 and the other end thereof is secured in an opening in the lower portion of shell 5.
  • the upper portion of shell 5 is provided with a second opening in which hollow insulated tubing 15v is secured.
  • coil 15 is of the same material as apertured tube 16 of plating chamber C, now to be described, the members 15 and 16 may be integral.
  • Plating chamber system C as more clearly shown in Figure 2, comprises a hollow, apertured tube 16 of a ceramic material and has the opposing ends thereof on the outer circumference secured in gas tight relation to cylindrical metallic bearing members 17 and 18.
  • Members 17 and 18 each extend along a sufiicient length of the circumference of tube 16 to provide adequate support therefor.
  • a hollow object 19 Surrounding the gas carrying apertured tube 16 is a hollow object 19 in the form of an open ended hollow cylinder and which is to be plated on the interior wall 20. Cylinder 19 is provided on the outer circumference with a layer of heat insulating material, as asbestos, 21, on which there is superimposed a resistance heating coil 22 connected to electrical inlet and outlet 23. and 24, respectively.
  • the left hand end of cylinder 19 is provided with a ring gasket 25 which is secured in position by a novel flange member 26 recessed as at 27 for engaging the gasket and cylinder along area 28 ( Figure 3).
  • Flange 26 is provided with a central bore 29 into which extends a bearing 30 for rotating engagement with the cylindrical member 17 when the same is passed through bore 29.
  • a satisfactory gas seal between the cylindrical shaped members 17 and 30 is established by providing a neoprene gasket 31 about the member 17 in tight fitting relation with the lateral outward portion of member 26.
  • the outer circumference 32 of member 26, as at 32, is provided with a surface of friction material, as for example, rubber bonded securely to the metal of the flange member, and this surface is engaged by a second friction member 33 driven through suitable reduction gearing 34 by a motor 35.
  • a surface of friction material as for example, rubber bonded securely to the metal of the flange member
  • Flange 36 at the right end of cylinder 19 is constructed similarly to flange 26, and accordingly will not be described in detail. However flange 36 is not driven directly but is rotated with flange 26 and cylinder 19 by means of motor 35. This flange 36 also ditiers from flange 26 in that it is provided with a cylindrical member 39 having an internal bearing surface 40, the purpose of which will be described hereinafter; also flange 36 has openings as at 37 and 38 which serve as exhaust ports for the flow of waste gases to recovery system D through the member 39.
  • Line 41 may be force fitted into the system and a feature thereof is the ready removability for mass production purposes.
  • pipe line 41 having the inletend engaging bearing surface 9
  • the line 41 contains a baflle 68 for directing the flow of gases to a trap 42 which is surrounded by cooling water 43 contained in vessel 44 having inlet 46 and outlet 45 for the passage of the water.
  • Pump 47 is not an essential requirement of the system where high flow rates maybe obtained by pressure means in the earlier parts of the apparatus but is essential where it is desirable to maintain low pressures in the plating chamber.
  • the object 19 to be plated is first wound on the outer side with the layer 21 of asbestos.
  • the heating coil is then slipped over the insulating material and the gasket 25 fitted over the object end. .
  • Flange 36 and gasket 25 are then pressured onto the right hand end of object 19 and the removable exhaust line section 41 is fitted into the bearing surface 40 of hollow cylindrical member 39 to connect the same with the permanently positioned apparatus extending to the right of Figure 1.
  • This system is then swept clear of air by flushing as with carbon dioxide or other inert gas.
  • the temperature of the oil 8 in tank 9 is stabilized at approximately 240 F. and then valve 3 of tank 1 is opened to permit a measured how of carbon dioxide through line 14 and coil 7 wherein it becomes heated to substantially the temperature of the oil; the heated carbon dioxide then passes into the carburetor 5.
  • the solid chromium carbonyl having been heated to approximately the temperature of the oil has thereby attained a relatively large vapor pressure, but without the application of external pressure to the vapors very little flow thereof takes place.
  • the heated carbon dioxide gas driven by the pressure from cylinder 2 and expanding under the influence of the heat absorbed from oil 8 will sweep the carbonyl vapors with it to line thus reducing or tending to reduce the carbonyl vapor pressure in the chamber, allowing more carbonyl to vaporize.
  • the carbon dioxide carrier gas is at substantially the same pressure as the carburetor, substantially no cooling of the chromium carbonyl will be effected by contact with the carrier gas.
  • the gases passing through insulated tubing 15 enter the chamber defined by hollow object 19 through the slots in the ceramic tube 16.
  • the motor 35 which as noted is adapted to drive object 19 in rotation has meanwhile been started, and the entering carrier gases will be given a slight circular motion as they approach the wall 20.
  • the resistance heater 22 having been brought up to a temperature of about 650 F. prior to entry of the plating gas has heated the wall and upon contact of the gases with the wall the gases decompose depositing cromium thereon.
  • the uniformity of the chromium deposit is improved by rotation of the object 19 since the gases are more uniformly distributed within the object.
  • waste gases from the thermal decomposition are drawn under the influence of pump 47 which was activated just prior to starting gas flow, to the pipe 41 and are passed to trap 42 wherein any chromium carbonyl, remaining uudecomposed, is deposited, through the eflect of cooling water 43 circulating about trap 42.
  • waste gases of decomposition such as carbon monoxide thenpass. on to the pumpand the atmosphere.
  • the object 19, if assumed to be approximately 1" in internal diameter, may be thus coated with a .001 of chromium in about 15" minutes, when utilizing a carbon dioxide flow rate at valve 3 of one liters per rninuteand an oil bath temperature of 240 F., the pressure within the objector plating chamber being maintained-'at'about 12 pounds per square inch absolllt.
  • FIGS 4 to 9 Various modifications of portions of the structure of Figure :1, particularly relating to the structure of plating chamber system C, are set forth in Figures 4 to 9,- inelusive, Thus in Figures 4 and 5 there isshown a slotted tube 48 pr'ovided with fins 49 extending therefrom adjacent slots or openings 50, other fins 51 being provided between the slots.
  • the fins 49 serve to direct the flow of gases from the openings 50, while the fins 51 when used serve to prevent the formation of gas pockets at low gas flow rates.
  • fins 49 and 51 may be used together or individually as desired
  • I I 7 Figures 6 and 7 illustrate a modification of the slotted tube of Figure" l which is particularly suitable in applications where the object to be plated is relatively long.
  • the weight of the ceramic tube may cause a buckling along the length, resulting in short life of the equipment.
  • the device of Figures 6 and 7 eliminates this diflicult'y by providing the slotted; tube 52 with bearing surfaces 53 which contact in sliding engagement the bearing surface 54hr a member-55' in'the form of a U having the arm carrying; the surface '54 foreshortened.
  • the circular member'55,having internal bearing surface 54, is coupled 'by arms Matt: the flange 26.
  • Figure 7 shows a modification of Figure 6 in which a long cylindrical member 56 is secured to flange 58 (similar to flange 26) by a brace 58a to provide support for tube 52.
  • the cylindrical'member 56 and elongated bearing surface 530 are slotted as at 57 to prevent the formation of dead spots in the plating chamber.
  • This support structure may of course also be provided on a flange similar to 36 of Figure l or supports may, where required, to be extended from both flanges.
  • said flanges being rotatably supported on said tubular member, and a support extending from one said flange toward the other, said support surrounding a portion of said tubular member and slidingly engaging the same along a portion of the length thereof, and means to rotate said hollow cylinder and flanges about said tubular member.
  • Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular memher in axially spaced relation, said tubular member having a multiplicity of apertures in its wall between said flanges, means carried by said flanges adjacent their peripheries for supporting between them a hollow object to be plated, means extending from at least one of said flanges toward the other providing support for the portion of said tubular member between said flanges, and heater means coaxial with said tubular member and encompassing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member, and an exhaust port in One said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said 3.
  • Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular member in axial spaced relation, said tubular member having a multiplicity of aperturesin its wall between said flanges, means carried by said flanges adjacent their peripheries for supporting between them a hollow object to be plated, there being a central bore in each said flange and elongated bearing means within each said bore and extending beyond said flanges to engage and support said tubular -member, heater means coaxial with said tubular member and encompasing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said flanges.
  • Apparatus for gas platinghollow objects comprising a pair of rotatably journalled axially spaced flanges, there being a central bore in each said flange, bearing means within said bores, a fixed multi-apertured tubular member extending between said flanges and through said bores, said apertures being between said flanges, a support extending from one said flange along said tubular member and slidingly engaging the same along a portion of its length between said flanges, an annular recess adjacent the periphery of said flanges and a ring gasket therein adapted to support a hollow object to be plated, heater means surrounding said tubular member coaxially thereof, said heater means encompassing an object to be plated when mounted between said flanges, and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said flanges.
  • Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular member in axial spaced relation, said tubular member having a multiplicity of apertures in its wall between said flanges, a cylindrical element carried by said flanges and adjacent the periphery of said flanges adapted to support a hollow object to be plated axially spaced from said flanges, there being a central bore in each said flange and elongated bearing means within each said bore and extending beyond said flanges to engage and support said tubular member, heater means coaxial with said tubular member and encompassing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object, cylindrical element, and flanges.

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  • Chemical & Material Sciences (AREA)
  • General Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Engineering & Computer Science (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
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Description

P. PAWLYK Jan. 3, 1956 APPARKTUS FOR PLLTING THE INTERIOR OF HOLLOW OBJECTS 3 Sheets-Sheet 1 Filed Oct. 8, 1951 INVENTOR PETER PAWLYK BY7" 1*7" ATTORNEYS OOO P. PAWLYK Jan. 3, 1956 APPARATUS FOR PLATING THE INTERIOR OF HOLLOW OBJECTS Filed 001;. 8, 1951 3 Sheets-Sheet 2 INVENTOR PETER PAWLYK BYTYJWWh yum ATTORNEYS aiisahiaiiiaiiaai kis-siiigissaiiiisi Jan. 3, 1956 APPARATUS FOR PLATING THE INTERIOR 0F HOLLOW OBJECTS Filed 061;. 8, 1951 P. PAWLYK fi; \\T| F IG- 7 5 Sheets-Sheet 3 FIG-8 INVENTOR PETER PAWLYK BY m 2 mb ATTORNEYS United States Patent APPARATUS FOR PLATING THE norrowonrnc'rs Application October 8, 1951, Serial No. 250,306
6 Claims. (Cl. 118;-4 8) NT RI R. Q
This invention relates to apparatus and methods for the coating of metallic bases with metallic coats deposited from the vapor state by the thermal decomposition of metal-bearing gases. More particularly the invention relates to the uniform coating of the interior ofhollow objects of tubular structure such as gun barrels andcylindrical bearing surfaces.
A primary object of the present invention is to provide improved apparatus whereby the interior platingof hollow objects may be uniformly achieved.
An important object of the present invention is to. provide equipment for the platingof hollow objects ona mass production basis.
A principal object of the invention istoprovide an improved method for the interior plating of hollow objects.
The invention comprises a gas plating system in which the object to be plated itself forms walls ofthe plating chamber, and which object is rotated/about a slotted tube. adapted to bear the volatilized.metaLbearingcompound to the object. Features of the. system" include means for the mounting of the hollow object'- about the slotted tube for the rotation of the object, means to direct the fiow of the plating gases uniformly totheinterior walls of the object, and means to provide for the uniformity of plating gas flow through the system.
The invention also includes the. featu re of ready interchangeability of plating objectswhich facilitates the use of mass production methods in the gasplating of hollow objects. Substantially all materials which decompose under the influence of heat are operable in theprocess of invention, the compounds containing chromium and nickel, e. g. nickel carbonyl being most suitable.
The invention will be more fully understood by reference to the following detailed description andaccompanying drawings wherein: Y
Figure 1 is a schematic representation of one em bodi ment of the apparatus of invention;
Figure 2 is an enlarged sectional view of theobject to be plated including means illustrating the mountingthereof;
Figure 3 is a view of the left hand end of the structure shown in Figure 2;
Figure 4 is a view in section of a modification of the slotted tube of Figure 2;
Figure 5 is an end view of the structure of Figure 4;
Figure 6 illustrates a modifiedform of the invention particularly adapted for the plating of long hollow objects;
Figure 7 is a view of a modification of the structure of Figure 6; and
Figure 8 illustrates a method of mounting a hollow object to secure plating of the entire interior surface.
Referring to Figure l the apparatus is shown to comprise the following general components: a source A of inert carrier gas; a substantially constant temperature source B of metal-bearing gas; a plating chamber system C; a recovery system D; and a vacuum pump system B for controlling plating gasfiow.
Source A may comprise a conventional cylinderl conhigh vapor pressure.
taining carbon dioxide 2 under pressure. The cylinder is provided with a valve 3 for the control of gaseous carbon dioxide flow therefrom and a gauge 4 for indicating the flow rate.
The source B of metal-bearing gas includes a shell 5 containing a solid powdered metal-bearing compound, chromium carbonyl 6. The shell 5 is surrounded by a hollow coil 7. and the coil and shell are submerged in oil 8 of tank 9, the whole assembly being adapted to be heated by electric heater 10 to a substantially constant temperature at which chromium carbonyl has a relatively To assure of adequate temperature control, the oil 8 contacts one element 11 of a thermostatic control which is suitably connected with heater 10 in the known manner for regulation of heat input to the system. To avoid localized heating, a stirrer 12 driven by motor 13 may be employed.
The coil 7 surrounding shell 5 is connected at one end through hollow tube 14 to the valve 3 and the other end thereof is secured in an opening in the lower portion of shell 5. The upper portion of shell 5 is provided with a second opening in which hollow insulated tubing 15v is secured.
Where coil 15 is of the same material as apertured tube 16 of plating chamber C, now to be described, the members 15 and 16 may be integral.
Plating chamber system C, as more clearly shown in Figure 2, comprises a hollow, apertured tube 16 of a ceramic material and has the opposing ends thereof on the outer circumference secured in gas tight relation to cylindrical metallic bearing members 17 and 18. Members 17 and 18 each extend along a sufiicient length of the circumference of tube 16 to provide adequate support therefor.
Surrounding the gas carrying apertured tube 16 is a hollow object 19 in the form of an open ended hollow cylinder and which is to be plated on the interior wall 20. Cylinder 19 is provided on the outer circumference with a layer of heat insulating material, as asbestos, 21, on which there is superimposed a resistance heating coil 22 connected to electrical inlet and outlet 23. and 24, respectively.
The left hand end of cylinder 19 is provided with a ring gasket 25 which is secured in position by a novel flange member 26 recessed as at 27 for engaging the gasket and cylinder along area 28 (Figure 3). Flange 26 is provided with a central bore 29 into which extends a bearing 30 for rotating engagement with the cylindrical member 17 when the same is passed through bore 29. As the rate of rotation for member 19 will always be relatively slow, a satisfactory gas seal between the cylindrical shaped members 17 and 30 is established by providing a neoprene gasket 31 about the member 17 in tight fitting relation with the lateral outward portion of member 26.
The outer circumference 32 of member 26, as at 32, is provided with a surface of friction material, as for example, rubber bonded securely to the metal of the flange member, and this surface is engaged by a second friction member 33 driven through suitable reduction gearing 34 by a motor 35.
Flange 36 at the right end of cylinder 19 is constructed similarly to flange 26, and accordingly will not be described in detail. However flange 36 is not driven directly but is rotated with flange 26 and cylinder 19 by means of motor 35. This flange 36 also ditiers from flange 26 in that it is provided with a cylindrical member 39 having an internal bearing surface 40, the purpose of which will be described hereinafter; also flange 36 has openings as at 37 and 38 which serve as exhaust ports for the flow of waste gases to recovery system D through the member 39.
40 and the other end of which terminates in a trap 42 for the condensation of metal-bearing vapors. Line 41 may be force fitted into the system and a feature thereof is the ready removability for mass production purposes.
pipe line 41 having the inletend engaging bearing surface 9 The line 41 contains a baflle 68 for directing the flow of gases to a trap 42 which is surrounded by cooling water 43 contained in vessel 44 having inlet 46 and outlet 45 for the passage of the water.
The outlet end of trap 42 is secured to a vacuum pump 47. Pump 47 is not an essential requirement of the system where high flow rates maybe obtained by pressure means in the earlier parts of the apparatus but is essential where it is desirable to maintain low pressures in the plating chamber.
In the operation of the apparatus of Figures '1, 2 and 3, the object 19 to be plated, after the customary cleaning of the interior surface with acid and alcohol or any convenient means, is first wound on the outer side with the layer 21 of asbestos. The heating coil is then slipped over the insulating material and the gasket 25 fitted over the object end. .This assernblyis then pressured onto flange 26 over" the ceramic tube 16"each of which components are initially secured to the apparatus extending to the left of Figure 1. Flange 36 and gasket 25 are then pressured onto the right hand end of object 19 and the removable exhaust line section 41 is fitted into the bearing surface 40 of hollow cylindrical member 39 to connect the same with the permanently positioned apparatus extending to the right of Figure 1. This system is then swept clear of air by flushing as with carbon dioxide or other inert gas.
Where the carburetor contains, as in the present instance, chromiurn carbonyl, the temperature of the oil 8 in tank 9 is stabilized at approximately 240 F. and then valve 3 of tank 1 is opened to permit a measured how of carbon dioxide through line 14 and coil 7 wherein it becomes heated to substantially the temperature of the oil; the heated carbon dioxide then passes into the carburetor 5.
The solid chromium carbonyl having been heated to approximately the temperature of the oil has thereby attained a relatively large vapor pressure, but without the application of external pressure to the vapors very little flow thereof takes place. The heated carbon dioxide gas driven by the pressure from cylinder 2 and expanding under the influence of the heat absorbed from oil 8 will sweep the carbonyl vapors with it to line thus reducing or tending to reduce the carbonyl vapor pressure in the chamber, allowing more carbonyl to vaporize. Also since the carbon dioxide carrier gas is at substantially the same pressure as the carburetor, substantially no cooling of the chromium carbonyl will be effected by contact with the carrier gas.
The gases passing through insulated tubing 15 enter the chamber defined by hollow object 19 through the slots in the ceramic tube 16. The motor 35 which as noted is adapted to drive object 19 in rotation has meanwhile been started, and the entering carrier gases will be given a slight circular motion as they approach the wall 20. The resistance heater 22 having been brought up to a temperature of about 650 F. prior to entry of the plating gas has heated the wall and upon contact of the gases with the wall the gases decompose depositing cromium thereon.
The uniformity of the chromium deposit is improved by rotation of the object 19 since the gases are more uniformly distributed within the object.
The waste gases from the thermal decomposition are drawn under the influence of pump 47 which was activated just prior to starting gas flow, to the pipe 41 and are passed to trap 42 wherein any chromium carbonyl, remaining uudecomposed, is deposited, through the eflect of cooling water 43 circulating about trap 42.
The waste gases of decomposition such as carbon monoxide thenpass. on to the pumpand the atmosphere.
The object 19, if assumed to be approximately 1" in internal diameter, may be thus coated with a .001 of chromium in about 15" minutes, when utilizing a carbon dioxide flow rate at valve 3 of one liters per rninuteand an oil bath temperature of 240 F., the pressure within the objector plating chamber being maintained-'at'about 12 pounds per square inch absolllt.
Various modifications of portions of the structure of Figure :1, particularly relating to the structure of plating chamber system C, are set forth in Figures 4 to 9,- inelusive, Thus in Figures 4 and 5 there isshown a slotted tube 48 pr'ovided with fins 49 extending therefrom adjacent slots or openings 50, other fins 51 being provided between the slots. The fins 49 serve to direct the flow of gases from the openings 50, while the fins 51 when used serve to prevent the formation of gas pockets at low gas flow rates. It will be apparent that fins 49 and 51 may be used together or individually as desired I I 7 Figures 6 and 7 illustrate a modification of the slotted tube of Figure" l which is particularly suitable in applications where the object to be plated is relatively long. Since the gas carrying tube of ceramic or other material 'must be substantially coextensive with the object in order to provide for uniform deposition of metal the weight of the ceramic tube may cause a buckling along the length, resulting in short life of the equipment. The device of Figures 6 and 7 eliminates this diflicult'y by providing the slotted; tube 52 with bearing surfaces 53 which contact in sliding engagement the bearing surface 54hr a member-55' in'the form of a U having the arm carrying; the surface '54 foreshortened. The circular member'55,having internal bearing surface 54, is coupled 'by arms Matt: the flange 26. Figure 7 shows a modification of Figure 6 in which a long cylindrical member 56 is secured to flange 58 (similar to flange 26) by a brace 58a to provide support for tube 52. The cylindrical'member 56 and elongated bearing surface 530 are slotted as at 57 to prevent the formation of dead spots in the plating chamber. This support structure may of course also be provided on a flange similar to 36 of Figure l or supports may, where required, to be extended from both flanges.
It will be noted that in Figure 1 the ends of the object 19 are covered to a slight extent by the gaskets and flanges, thus preventing deposition of metal to the very end of the structure. The apparatus of Figure 8 overcomes this objection by providing cylindrical elements 59 and 60 which are secured over the object 61 at opposing ends. Attachment of gaskets 62 and 63 and flanges 64 and 65 is then made over elements 59 and 60 and the interior of the object may then be completely plated. Elements 59 and 60 must be heat conductive in order to insure that the wall portions of object 61 opposite the elements are completely heated.
This application is related to copending applications, Serial Nos. 250,301; 250,302; 250,303; 250,304; 250,305; and 250,307; all filed October 8, 1951, and all by the same inventor as the present application.
'saidbores, said flanges being rotatably supported on said tubular member, and a support extending from one said flange toward the other, said support surrounding a portion of said tubular member and slidingly engaging the same along a portion of the length thereof, and means to rotate said hollow cylinder and flanges about said tubular member.
2. Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular memher in axially spaced relation, said tubular member having a multiplicity of apertures in its wall between said flanges, means carried by said flanges adjacent their peripheries for supporting between them a hollow object to be plated, means extending from at least one of said flanges toward the other providing support for the portion of said tubular member between said flanges, and heater means coaxial with said tubular member and encompassing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member, and an exhaust port in One said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said 3. Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular member in axial spaced relation, said tubular member having a multiplicity of aperturesin its wall between said flanges, means carried by said flanges adjacent their peripheries for supporting between them a hollow object to be plated, there being a central bore in each said flange and elongated bearing means within each said bore and extending beyond said flanges to engage and support said tubular -member, heater means coaxial with said tubular member and encompasing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said flanges.
4. Apparatus for gas platinghollow objects comprising a pair of rotatably journalled axially spaced flanges, there being a central bore in each said flange, bearing means within said bores, a fixed multi-apertured tubular member extending between said flanges and through said bores, said apertures being between said flanges, a support extending from one said flange along said tubular member and slidingly engaging the same along a portion of its length between said flanges, an annular recess adjacent the periphery of said flanges and a ring gasket therein adapted to support a hollow object to be plated, heater means surrounding said tubular member coaxially thereof, said heater means encompassing an object to be plated when mounted between said flanges, and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object and said flanges.
5. Apparatus for gas plating hollow objects comprising a fixed tubular member, a pair of flanges journalled for rotation on and about the axis of said tubular member in axial spaced relation, said tubular member having a multiplicity of apertures in its wall between said flanges, a cylindrical element carried by said flanges and adjacent the periphery of said flanges adapted to support a hollow object to be plated axially spaced from said flanges, there being a central bore in each said flange and elongated bearing means within each said bore and extending beyond said flanges to engage and support said tubular member, heater means coaxial with said tubular member and encompassing an object to be plated when mounted between said flanges, means to conduct plating gases to said tubular member and an exhaust port in one said flange to allow escape of products of decomposition of said gas from a chamber formed by said object, cylindrical element, and flanges.
6. The apparatus according to claim 5 in which a support extends from one said flange along said tubular member and slidingly engaging the same along a portion of its length between said flanges.
References Cited in the file of this patent UNITED STATES PATENTS 15,836 Wallace Sept, 20, 1856 1,089,334 Dickerson Mar. 3, 1914 1,164,619 Jefferson Dec. 14, 1915 1,711,643 Marshall May 7, 1929 1,784,611 Polyani Dec. 9, 1930 2,161,950 Christensen June 13, 1939 2,233,070 Atwell et al Feb. 25, 1941 2,336,946 Marden Dec. 14, 1943 2,516,058 Lander July 18, 1950

Claims (1)

1. IN APPARATUS FR GAS PLATING, THE STRUCTURE COMPRISING OPPOSED END FLANGES ADAPTED TO SUPPORT A TUBULAR OBJECT THEREBETWEEN, SAID FLANGES BEING PROVIDED WITH BORES, MEANS TO HEAT SAID OBJECT, A LONG MULTI-APERTURED TUBULAR MEMBER HAVING OPPOSED ENDS EXTENDING THROUGH SAID BORES, SAID FLANGES BEING ROTATABLY SUPPORTED ON SAID TUBULAR MEMBER, AND A SUPPORT EXTENDING FROM ONE SAID FLANGE TOWARD THE OTHER, SAID SUPPORT SURROUNDING A PORTION OF SAID TUBULAR MEMBER AND SLIDINGLY ENGAGING THE SAME ALONG A PORTION OF THE LENGTH THEREOF, AND MEANS TO ROTATE SAID HOLLOW CYLINDER AND FLANGES ABOOUT SAID TUBULAR MEMBER.
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Cited By (9)

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Publication number Priority date Publication date Assignee Title
US2898227A (en) * 1957-02-01 1959-08-04 Ohio Commw Eng Co Zinc gas plating
US2906803A (en) * 1955-08-22 1959-09-29 Yardney International Corp Process for making porous electrodes and the like
US2913357A (en) * 1956-09-20 1959-11-17 Union Carbide Corp Transistor and method of making a transistor
US3077444A (en) * 1956-06-13 1963-02-12 Siegfried R Hoh Laminated magnetic materials and methods
US3131049A (en) * 1963-01-24 1964-04-28 Union Carbide Corp Production of chromium lamella on a molten supporting vehicle
US3294059A (en) * 1963-04-15 1966-12-27 Charles R Barnes Deposition of nickel films on the interior surface of polytetrafluoroethylene tubing
US3314833A (en) * 1963-09-28 1967-04-18 Siemens Ag Process of open-type diffusion in semiconductor by gaseous phase
US5445973A (en) * 1991-04-24 1995-08-29 Im Institute For Mikroelektronik Method for manufacturing solar cells
FR2834713A1 (en) * 2002-01-15 2003-07-18 Snecma Moteurs PROCESS AND PLANT FOR DENSIFICATION OF SUBSTRATES BY CHEMICAL STEAM INFILTRATION

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US15836A (en) * 1856-09-30 Jambs wallace
US1089334A (en) * 1913-04-19 1914-03-03 Joseph Richard Dickerson Steam washing-machine.
US1164619A (en) * 1914-08-07 1915-12-14 Herbert P Jefferson Vacuo-centrifugal fiber and fabric treating machine.
US1711643A (en) * 1924-02-26 1929-05-07 Remington Arms Co Inc Method and apparatus for impregnating paper tubes or other porous articles
US1784611A (en) * 1927-07-07 1930-12-09 Polanyi Michael Method of producing bodies consisting of a plurality of thin alternately conducting and insulating layers
US2161950A (en) * 1936-05-27 1939-06-13 Bell Telephone Labor Inc Deposition furnace
US2233070A (en) * 1938-03-09 1941-02-25 Atlantic Rayon Corp Holder for hollow articles
US2336946A (en) * 1941-12-10 1943-12-14 Westinghouse Electric & Mfg Co Method and apparatus for coating envelopes for electric lamps
US2516058A (en) * 1943-09-30 1950-07-18 Bell Telephone Labor Inc Apparatus for plating of metals

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Publication number Priority date Publication date Assignee Title
US15836A (en) * 1856-09-30 Jambs wallace
US1089334A (en) * 1913-04-19 1914-03-03 Joseph Richard Dickerson Steam washing-machine.
US1164619A (en) * 1914-08-07 1915-12-14 Herbert P Jefferson Vacuo-centrifugal fiber and fabric treating machine.
US1711643A (en) * 1924-02-26 1929-05-07 Remington Arms Co Inc Method and apparatus for impregnating paper tubes or other porous articles
US1784611A (en) * 1927-07-07 1930-12-09 Polanyi Michael Method of producing bodies consisting of a plurality of thin alternately conducting and insulating layers
US2161950A (en) * 1936-05-27 1939-06-13 Bell Telephone Labor Inc Deposition furnace
US2233070A (en) * 1938-03-09 1941-02-25 Atlantic Rayon Corp Holder for hollow articles
US2336946A (en) * 1941-12-10 1943-12-14 Westinghouse Electric & Mfg Co Method and apparatus for coating envelopes for electric lamps
US2516058A (en) * 1943-09-30 1950-07-18 Bell Telephone Labor Inc Apparatus for plating of metals

Cited By (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2906803A (en) * 1955-08-22 1959-09-29 Yardney International Corp Process for making porous electrodes and the like
US3077444A (en) * 1956-06-13 1963-02-12 Siegfried R Hoh Laminated magnetic materials and methods
US2913357A (en) * 1956-09-20 1959-11-17 Union Carbide Corp Transistor and method of making a transistor
US2898227A (en) * 1957-02-01 1959-08-04 Ohio Commw Eng Co Zinc gas plating
US3131049A (en) * 1963-01-24 1964-04-28 Union Carbide Corp Production of chromium lamella on a molten supporting vehicle
US3294059A (en) * 1963-04-15 1966-12-27 Charles R Barnes Deposition of nickel films on the interior surface of polytetrafluoroethylene tubing
US3314833A (en) * 1963-09-28 1967-04-18 Siemens Ag Process of open-type diffusion in semiconductor by gaseous phase
US5445973A (en) * 1991-04-24 1995-08-29 Im Institute For Mikroelektronik Method for manufacturing solar cells
FR2834713A1 (en) * 2002-01-15 2003-07-18 Snecma Moteurs PROCESS AND PLANT FOR DENSIFICATION OF SUBSTRATES BY CHEMICAL STEAM INFILTRATION
WO2003060183A1 (en) * 2002-01-15 2003-07-24 SNECMA PROPULSION SOLIDE Société Anonyme Method and installation for the densification of substrates by means of chemical vapour infiltration
US20040237898A1 (en) * 2002-01-15 2004-12-02 Bruno Bernard Method and installation for the densification of substrates by means of chemical bapour infiltration
US7691440B2 (en) 2002-01-15 2010-04-06 Snecma Propulsion Solide Method and installation for the densification of substrates by means of chemical vapor infiltration

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