US2657457A - Continuous metal production and continuous gas plating - Google Patents
Continuous metal production and continuous gas plating Download PDFInfo
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- US2657457A US2657457A US115033A US11503349A US2657457A US 2657457 A US2657457 A US 2657457A US 115033 A US115033 A US 115033A US 11503349 A US11503349 A US 11503349A US 2657457 A US2657457 A US 2657457A
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22D—CASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
- B22D11/00—Continuous casting of metals, i.e. casting in indefinite lengths
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49789—Obtaining plural product pieces from unitary workpiece
- Y10T29/49798—Dividing sequentially from leading end, e.g., by cutting or breaking
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/4998—Combined manufacture including applying or shaping of fluent material
- Y10T29/49982—Coating
- Y10T29/49984—Coating and casting
Definitions
- This invention relates to protective metal coatings. More particularly, it relates to the coating of cast metals by deposition of protective metals through decomposition of volatile metal compounds, and apparatus for carrying out the process.
- the soaked ingots then are rolled in blooming mills into billets preparatory to further processing.
- Rough billets require more or less surface conditioning because, for example, the steel is particularly prone to form loose scale and become badly oxidized while cooling, thus necessitating the surface treatment.
- the continuous casting process eliminates several expensive steps, such as making and soaking ingots and rolling them on a blooming mill, it does not, for example, prevent scaling, oxidizing. and other surface conditions.
- Still another object of the present invention is to produce a simplified method of coating cast steel.
- a still further object of this invention is to produce a method wherein continuously cast steel is continuously plated.
- the process is carried out by casting metals and when the continuous ribbon of hot but solidified metal issues from the mold, bringing the hot metal into contact with vapors of decomposable metal compounds.
- the molten metal is poured into a shaping mold and cooled to a solid form.
- the formed cast metal progresses through an insulating sleeve. where cooling is controlled until the cast metal is reduced to a temperature in the range of approximately 300 to 600 F., depending upon the type of metal being cast and the thickness of the casting.
- This hot metal then progresses through a plating chamber where the temperature of the metal decomposes vapors of volatile metal compounds continuously fed into contact with the continuously moving cast object.
- the metal at this stage is solidified to the point where its speed of movement may be controlled by a roll drive or equivalent mechanism.
- the plated cast metal is then cut to desired length by suitable means such as saws, acetylene torches, and the like.
- the hot cast metal is brought into contact with continuously changing atmosphere which is made up of gaseous material, at least a portion of which is decomposable at the temperature of the continuously moving cast metal to deposit a metal coating.
- the leakage of inert gas into a plating chamber is limited to small quantities by having apertures in the partition walls of a configuration providing a loose sliding fit with the object passing therethrough or enlarged holes with shims encircling the moving object in close proximity to these holes and by keeping the pressure difierential small.
- the inert gas leaking into the plating chamber is not a harmful operation because the metal-bearing gases are usually diluted with an inert gaseous medium and the gas decomposing reaction in the plating chamber produces relatively inert decomposition products.
- the stream of gaseous material brought into contact with the hot cast metal may be formed by mixing an inert gas with the vapors of a volatile metal compound or by atomizing a. liquid metal compound into a blast of hot inert gas or other equivalent method.
- Carbon dioxide, helium, nitrogen, hydrogen, the gaseous product of controlled burning of hydrocarbon ases free of oxygen, and the like. have been utilized as a carrier medium or inert gas medium.
- Metals to be deposited may be introduced as gaseous metal carbonyls or vaporized solutions of certain of the metal carbonyls in readily vaporiza-ble solvents (for example, petroleum ether), also nitroxyl compounds, nitrosyl carbonyls. metal hydrides, metal alkyls, metal halides, and the like.
- Illustrative compounds of the carbonyl type are nickel, iron. chromium, molybdenum, cobalt, and mixed carbonyls.
- Illustrative compounds of other groups are the nitroxyls, such as copper nltroxyl; nitrosyl carbonyls. for example, cobalt nitrosyl carbonyl; hydrides, such as antimony hydride, tin hydride; metal alkyls, such as chromyl chloride; and carbonyls halogens, for example, osmium carbonyl bromide, ruthenium carbonyl chloride, and the like.
- nitroxyls such as copper nltroxyl
- nitrosyl carbonyls for example, cobalt nitrosyl carbonyl
- hydrides such as antimony hydride, tin hydride
- metal alkyls such as chromyl chloride
- carbonyls halogens for example, osmium carbonyl bromide, ruthenium carbonyl chloride, and the like.
- Each material from which a metal may be plated has a temperature at which decomposition is complete. However, decomposition may take place slowly at a lower temperature or while the vapors are being raised in temperature through some particular range. For example, nickel carbonyl completely decomposes at a temperature in the range of 375 F. to 400 F. However, nickel carbonyl starts to decompose slowly at about 175 F. and therefore decomposition continues during the time of heating from 200 F. to 380 F.
- a large number of the metal carbonyls and hydrldes may be effectively and efiiciently decomposed at a temperature in the range of 350 F. to 450 F.
- a temperature range of 375 F. to 425 F When working with most metal carbonyls we prefer to operate in a temperature range of 375 F. to 425 F.
- the process is illustrated without provision for annealing the deposited coating in order to increase their adhesion and ductility. If such an operation is desired provision can be made for an anneal in the inert gas filled annular space, as will be more definitely explained.
- Annealing temperatures are higher than plating temperatures and generally in the range of 800 to 1200 F.
- An anneal may be carried out, for example, by induction heating.
- Figure l is a diagrammatic elevational view of a complete unit for continuously casting and plating metals.
- Figure 2 is an enlarged sectional view of the plating equipment.
- FIG. 1 there is shown the supporting framework I0 of a multi-story building.
- On the top floor of said building framework I0 supports tracks II for a movable overhead crane I2.
- a ladle I3 is suspended from crane I2 by suitable cables I I.
- Ladle I3 is shown suspended over a, heated holding ladle I5.
- Ladle I5 is actuated for tipping and pouring by suitable means I6 such as pulleys 0r levers.
- Adjacent the ladle I5 is a liquid-cooled mold il in which ladle I5 is adapted to empty.
- a cast steel tube IB is shown issuing from the mold I1 and moving downward through an insulating sleeve I9 within which there is generally maintained an atmosphere of hydrogen.
- Steel tube I8 moves downward from the sleeve I9 through a unit 20 designed to accurately maintain and control the temperature of the steel tube.
- Steel tube I8 passes on downward through a plating unit 2I which will be described in more detail.
- Plated steel tube is drawn downward at a predetermined rate, generally in the range of 3 to 7 feet per minute for a tube of about 3 inch radius, by squeeze rolls 22.
- the coated steel tube is cut into predetermined lengths by an acetylene torch 23 and the tubular units lowered to the horizontal by suitable cradle means 24.
- consists of an inner wall member 30 and outer wall members 3
- Each of the wall members is provided with two aligned ports indicated as a and b, respectively, of size adapted for close sliding fit with the steel tube I8 passing vertically downward therethrough,
- the closure of each chamber may be tightened by use of shims indicated as c and d.
- the inner chamber is provided with gas inlet and outlet means 35 and 36, respectively.
- Chamber 33 is provided with gas inlet and outlet means 31 and 38, respectively.
- Chamber 34 is provided with inlet and outlet means 39 and 40, respectively.
- Outlet means 40 is adapted with an exhaust means 4
- Hot molten metal is poured at a temperature in excess of 2000 F. In the primary mold the temperature is reduced to that necessary to set the cast metal, for carbon steel this is in a temperature range of 1200" F. to 1600 F.
- the temperature is reduced to a temperature in the range of approximately 300 to 600 F. and preferably to 350 to 450 F. in an atmosphere of hydrogen.
- the inner chamber is the plating chamber, where the hot metal contacts an atmosphere, preferably of carbon dioxide and vapors of a volatile metal compound. These vapors may be maintained under a variety of pressures,
- inert gas In the outer annular space there is maintained an atmosphere of inert gas.
- the gas is maintained under a pressure generally slightly under atmospheric in order that all gas, either that inert introduced or atmospheric air leaking into this annular space 34, will be removed by the exhaust tan and there will be no tendency for gas to leak out, contaminating the atmosphere which must be frequented by workmen.
- the intermediate annular space 33 there is maintained an inert gas atmosphere under a pressure generally higher than is maintained in either the inner chamber or the outer annular space. While other arrangements could be used. the high pressure is preferred for the intermediate annular space because gas flow is then inward into the plating chamber through the free space around the traveling rod.
- the steel may be poured at the rate of approximately 400 pounds per minute, which rate will supply continuously cooled rod traveling at a rate of approximately 5 feet per minute.
- the temperature of the rod entering the plating chamber may be controlled to be approximately 425 F.
- the rate of flow of gaseous medium to the plating chamber may be approximately 20 cubic feet per hour per cubic foot of chamber space, with nickel carbonyl vapors being present in the ratio of approximately ounces of carbonyl per cubic foot oi carbon dioxide gas passed through the plating chamber.
- the rate of flow of carbon dioxide gas through the intermediate annular space 33 may be maintained at approximately 30 cubic feet of gas per hour per cubic foot of chamber space.
- the rate of flow of gas in the outer annular space 34 may be at the rate of 5 cubic feet per hour per cubic foot of chamber space, and the actual pressure maintained on the space by the exhaust equipment being 2 inches of water vacuum.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature in the range of 300 to 600 F., thereafter subjecting said cast a: eta] while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
- a process of casting and plating ferrous metals simultaneously and continuously comprising the steps of pouring molten ferrous metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a. heat-decomposable metal vapor compound, thereafter subjecting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast ferrous metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, thereafter subjeeting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, frictionally controlling the speed of movement of said continuously cast metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature in the range of 350 to 450 R, thereafter subjecting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into desired length.
- a process of casting and plating copper simultaneously and continuously which comprises the steps of pouring molten copper into a mold and continuously withdrawing hot congealed copper from the mold in a downwardly direction, cooling said continuously cast copper to a temperature within the range for decomposing a heat-decomposable metal vapor compound, there after subjecting said cast copper while continuously moving along to heat-decomposable copper vapors, at least a portion of said vapors decomposing at said temperature range whereby copper metal is deposited on said continuously moving cast copper, and severing said continuously cast and gaseous metal plated copper into predetermined lengths.
- a process of casting and plating ferrous metals simultaneously and continuously which comprises the steps of pouring molten ferrous metal into a mold and continuously withdrawing hot congealed ferrous metal from the mold in a downwardly direction, cooling said continuously cast ferrous metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound. thereafter subjecting said cast ferrous metal to heat-decomposable metal vapors, at least a portion of said vapors decomposing at said temperature range whereby metal is deposited on said continuously moving cast ferrous metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing gaseous nickel carbonyl when brought in contact therewith, thereafter subjecting said cast metal while moving along to gaseous nickel carbonyl vapors, at least a portion of said vapors decomposing at said temperature range whereby nickel metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a predetermined length.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing gaseous chromium carbonyl when said gaseous carbonyl is brought in contact therewith, thereafter subjecting said cast metal while moving along to a gaseous chromium carbonyl, at least a portion of said carbonyl decomposing at said temperature range whereby chromium metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, thereaiter sub- .iecting said cast metal while moving along and hot to a mixture of gases comprising an inert gas and a heat-decomposable metal vapor compound, causing decomposition of said metal vapor com-- pound whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
- a process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said cast metal to a gaseous medium composed of carbon. dioxide gas and a heat-decomposable metal carbonyl, said metal carbonyl being heat-decomposed whereby metal is deposited on said continuously cast metal upon contacting the hot cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
- a process of casting and plating metal simultaneously and continuously which comprises continuously withdrawing hotcongealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said hot cast metal to a gaseous medium composed of hydrogen and a heat-decomposable gaseous metal hydride causing decomposition of said metal hydride whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
- the method of plating continuously cast copper base alloys which comprises: continuously passing molten alloys to a molded form, cooling the molded alloy to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot cast material through a chamber where its surface is contacted by a gaseous medium including a heat decomposable metal bearing compound, at least a portion of which is decomposed whereby metal is deposited on the said cast molded metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
- the method of plating continuously cast ferrous metals which comprises: continuously passing cast ferrous molten metal to a molded form, cooling the molded metal to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot metal through a chamber where its surface is contacted by a gaseous medium including a heat decomposable metal bearing compound, at least a portion of which is a gaseous chromium carbonyl which decomposes whereby chromium metal is deposited on the said cast molded metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
- the method of plating continuously cast metals which comprises: continuously passing cast molten metal to a molded form, cooling the molded metal to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot cast material through a chamber sealed against escape of toxic gases by maintaining an atmosphere of hydrogen in the annular spaces surrounding the plating chamber, contacting the hot metal within said chamber with a gaseous medium composed of hydrogen and heat decomposable metal hydrides causing decomposition of said metal hydrides whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
Description
Nov. 3, 1953 H. A. TOULMIN, JR ,4
CONTINUOUS METAL PRGDUCTION AND CONTINUOUS GAS PLATINC Filed Sept. 10, 1949 INVENTOR TOULMIN JR.
HARRY ATTOR EYS Patented Nov. 3, 1953 CONTINUOUS METAL PRODUCTION AND CONTINUOUS GAS PLATING Harry A. Toulmin, Jr., Dayton, Ohio, assignor to The Commonwealth Engineering Company of Ohio, Dayton, Ohio, a corporation of Ohio Application September 10, 1949, Serial No. 115,033
14 Claims. 1
This invention relates to protective metal coatings. More particularly, it relates to the coating of cast metals by deposition of protective metals through decomposition of volatile metal compounds, and apparatus for carrying out the process.
Special types of carbon and alloy steel and non-ferrous alloys have been manufactured heretofore by pouring the molten metal into ingot molds.
Large size ingots while still hot are removed from the molds and shipped to the soaking pits where they are held until the internal and external ingot temperatures equalize.
The soaked ingots then are rolled in blooming mills into billets preparatory to further processing.
Rough billets require more or less surface conditioning because, for example, the steel is particularly prone to form loose scale and become badly oxidized while cooling, thus necessitating the surface treatment.
This process has now been at least partially superseded by the so-called continuous casting process. Continuous casting has been successfully performed upon a commercial scale, both in conjunction with ferrous and non-ferrous alloys.
While the continuous casting process eliminates several expensive steps, such as making and soaking ingots and rolling them on a blooming mill, it does not, for example, prevent scaling, oxidizing. and other surface conditions.
It is an object of the present invention to overcome the limitations and disadvantages of the processes known heretofore.
It is also an object of the present invention to prepare cast metal objects having a protective coating of a non-oxidizing metal.
It is another object of this invention to prepare cast steel of reduced scaling character.
It is still a further object of this invention to prepare cast steel with ductile protective metal coatings which do not interfere with further processing such as rolling.
It is still another object of this invention to prepare cast metals having protective coatings not depositable by electrolytic methods.
Still another object of the present invention is to produce a simplified method of coating cast steel.
A still further object of this invention is to produce a method wherein continuously cast steel is continuously plated.
It is still another object of this invention to produce a method wherein cast steel is plated while hot and a protective layer deposited.
It is also another object of the present invention to provide a method of increased efficiency clue to the utilization of heat normally dissipated in the cooling operation.
Other and more specific objects and advantages will be apparent to one skilled in the art as the following description proceeds.
In brief, the process is carried out by casting metals and when the continuous ribbon of hot but solidified metal issues from the mold, bringing the hot metal into contact with vapors of decomposable metal compounds.
In this way at least a portion of the heat in the molded material instead of being wasted is utilized to decompose volatile metal compounds and deposit a protective coating.
In sequence the molten metal is poured into a shaping mold and cooled to a solid form. The formed cast metal progresses through an insulating sleeve. where cooling is controlled until the cast metal is reduced to a temperature in the range of approximately 300 to 600 F., depending upon the type of metal being cast and the thickness of the casting.
This hot metal then progresses through a plating chamber where the temperature of the metal decomposes vapors of volatile metal compounds continuously fed into contact with the continuously moving cast object.
The metal at this stage is solidified to the point where its speed of movement may be controlled by a roll drive or equivalent mechanism.
The plated cast metal is then cut to desired length by suitable means such as saws, acetylene torches, and the like.
In the plating step the hot cast metal is brought into contact with continuously changing atmosphere which is made up of gaseous material, at least a portion of which is decomposable at the temperature of the continuously moving cast metal to deposit a metal coating.
Inasmuch as the cast metal is progressing continuously through this chamber, one of the factors important to the successful operation is control of gas pressure not only within the plating chamber itself, but in each of the surrounding annular spaces, of design which will be hereafter explained.
In order to insure against leakage of plating gases which are toxic from the plating chamber and still have openings in the partition walls for the continuous passage of the cast metal, it is necessary to maintain a metal-vapor free gas atmosphere at a slightly higher gas pressure in the annular spaces surrounding the plating chamber.
The leakage of inert gas into a plating chamber is limited to small quantities by having apertures in the partition walls of a configuration providing a loose sliding fit with the object passing therethrough or enlarged holes with shims encircling the moving object in close proximity to these holes and by keeping the pressure difierential small.
It will be recognized that the inert gas leaking into the plating chamber is not a harmful operation because the metal-bearing gases are usually diluted with an inert gaseous medium and the gas decomposing reaction in the plating chamber produces relatively inert decomposition products.
The stream of gaseous material brought into contact with the hot cast metal may be formed by mixing an inert gas with the vapors of a volatile metal compound or by atomizing a. liquid metal compound into a blast of hot inert gas or other equivalent method.
Carbon dioxide, helium, nitrogen, hydrogen, the gaseous product of controlled burning of hydrocarbon ases free of oxygen, and the like. have been utilized as a carrier medium or inert gas medium.
Metals to be deposited may be introduced as gaseous metal carbonyls or vaporized solutions of certain of the metal carbonyls in readily vaporiza-ble solvents (for example, petroleum ether), also nitroxyl compounds, nitrosyl carbonyls. metal hydrides, metal alkyls, metal halides, and the like.
Illustrative compounds of the carbonyl type are nickel, iron. chromium, molybdenum, cobalt, and mixed carbonyls.
Illustrative compounds of other groups are the nitroxyls, such as copper nltroxyl; nitrosyl carbonyls. for example, cobalt nitrosyl carbonyl; hydrides, such as antimony hydride, tin hydride; metal alkyls, such as chromyl chloride; and carbonyls halogens, for example, osmium carbonyl bromide, ruthenium carbonyl chloride, and the like.
Each material from which a metal may be plated has a temperature at which decomposition is complete. However, decomposition may take place slowly at a lower temperature or while the vapors are being raised in temperature through some particular range. For example, nickel carbonyl completely decomposes at a temperature in the range of 375 F. to 400 F. However, nickel carbonyl starts to decompose slowly at about 175 F. and therefore decomposition continues during the time of heating from 200 F. to 380 F.
A large number of the metal carbonyls and hydrldes may be effectively and efiiciently decomposed at a temperature in the range of 350 F. to 450 F. When working with most metal carbonyls we prefer to operate in a temperature range of 375 F. to 425 F.
The process is illustrated without provision for annealing the deposited coating in order to increase their adhesion and ductility. If such an operation is desired provision can be made for an anneal in the inert gas filled annular space, as will be more definitely explained.
Annealing temperatures are higher than plating temperatures and generally in the range of 800 to 1200 F. An anneal may be carried out, for example, by induction heating.
The invention will be more clearly understood from the following description taken in connection with the drawing which:
Figure l is a diagrammatic elevational view of a complete unit for continuously casting and plating metals; and
Figure 2 is an enlarged sectional view of the plating equipment.
Referring to the drawings, there is illustrated a continuous method of casting and plating as utilized in connection with steel manufacture without any intention that the invention be limited thereto.
In Figure 1 there is shown the supporting framework I0 of a multi-story building. On the top floor of said building framework I0 supports tracks II for a movable overhead crane I2.
A ladle I3 is suspended from crane I2 by suitable cables I I. Ladle I3 is shown suspended over a, heated holding ladle I5. Ladle I5 is actuated for tipping and pouring by suitable means I6 such as pulleys 0r levers.
Adjacent the ladle I5 is a liquid-cooled mold il in which ladle I5 is adapted to empty. A cast steel tube IB is shown issuing from the mold I1 and moving downward through an insulating sleeve I9 within which there is generally maintained an atmosphere of hydrogen.
Steel tube I8 moves downward from the sleeve I9 through a unit 20 designed to accurately maintain and control the temperature of the steel tube. Steel tube I8 passes on downward through a plating unit 2I which will be described in more detail.
Plated steel tube is drawn downward at a predetermined rate, generally in the range of 3 to 7 feet per minute for a tube of about 3 inch radius, by squeeze rolls 22.
The coated steel tube is cut into predetermined lengths by an acetylene torch 23 and the tubular units lowered to the horizontal by suitable cradle means 24.
Referring to Figure 2, it will be seen that the plating unit 2| consists of an inner wall member 30 and outer wall members 3| and 32, which enclose annular spaces or chambers 33 and 34, respectively.
Each of the wall members is provided with two aligned ports indicated as a and b, respectively, of size adapted for close sliding fit with the steel tube I8 passing vertically downward therethrough, The closure of each chamber may be tightened by use of shims indicated as c and d.
The inner chamber is provided with gas inlet and outlet means 35 and 36, respectively. Chamber 33 is provided with gas inlet and outlet means 31 and 38, respectively. Chamber 34 is provided with inlet and outlet means 39 and 40, respectively. Outlet means 40 is adapted with an exhaust means 4|, such as a fan, for maintaining less than atmospheric pressure in annular space 34.
Operation of the equipment is as follows:
Hot molten metal is poured at a temperature in excess of 2000 F. In the primary mold the temperature is reduced to that necessary to set the cast metal, for carbon steel this is in a temperature range of 1200" F. to 1600 F.
In the insulating sleeve or after cooler the temperature is reduced to a temperature in the range of approximately 300 to 600 F. and preferably to 350 to 450 F. in an atmosphere of hydrogen.
The hot metal then travels through the plating unit. In this unit, the inner chamber is the plating chamber, where the hot metal contacts an atmosphere, preferably of carbon dioxide and vapors of a volatile metal compound. These vapors may be maintained under a variety of pressures,
ranging from a pressure below to pressures above atmospheric pressures and generally in the range of 6 inches of water vacuum to 6 inches or water positive pressure.
In the outer annular space there is maintained an atmosphere of inert gas. The gas is maintained under a pressure generally slightly under atmospheric in order that all gas, either that inert introduced or atmospheric air leaking into this annular space 34, will be removed by the exhaust tan and there will be no tendency for gas to leak out, contaminating the atmosphere which must be frequented by workmen.
In the intermediate annular space 33 there is maintained an inert gas atmosphere under a pressure generally higher than is maintained in either the inner chamber or the outer annular space. While other arrangements could be used. the high pressure is preferred for the intermediate annular space because gas flow is then inward into the plating chamber through the free space around the traveling rod.
In the plating of nickel, by way of specific example, upon a 3 inch diameter rod of cast steel, the following conditions may be maintained:
The steel may be poured at the rate of approximately 400 pounds per minute, which rate will supply continuously cooled rod traveling at a rate of approximately 5 feet per minute.
The temperature of the rod entering the plating chamber may be controlled to be approximately 425 F.
The rate of flow of gaseous medium to the plating chamber may be approximately 20 cubic feet per hour per cubic foot of chamber space, with nickel carbonyl vapors being present in the ratio of approximately ounces of carbonyl per cubic foot oi carbon dioxide gas passed through the plating chamber.
The rate of flow of carbon dioxide gas through the intermediate annular space 33 may be maintained at approximately 30 cubic feet of gas per hour per cubic foot of chamber space.
The rate of flow of gas in the outer annular space 34 may be at the rate of 5 cubic feet per hour per cubic foot of chamber space, and the actual pressure maintained on the space by the exhaust equipment being 2 inches of water vacuum.
It will be understood that while the method and apparatus disclosed and described herein illustrate a preferred form of the invention, modification can be made without departing from the spirit of the invention, and that all modifications that fall Within the scope of the appended claims are intended to be included herein.
I claim:
1. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature in the range of 300 to 600 F., thereafter subjecting said cast a: eta] while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
2. A process of casting and plating ferrous metals simultaneously and continuously comprising the steps of pouring molten ferrous metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a. heat-decomposable metal vapor compound, thereafter subjecting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast ferrous metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
3. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, thereafter subjeeting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, frictionally controlling the speed of movement of said continuously cast metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
4. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature in the range of 350 to 450 R, thereafter subjecting said cast metal while continuously moving along to a heat-decomposable metal vapor compound, at least a portion of said vapor decomposing at said temperature range whereby metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into desired length.
5. A process of casting and plating copper simultaneously and continuously which comprises the steps of pouring molten copper into a mold and continuously withdrawing hot congealed copper from the mold in a downwardly direction, cooling said continuously cast copper to a temperature within the range for decomposing a heat-decomposable metal vapor compound, there after subjecting said cast copper while continuously moving along to heat-decomposable copper vapors, at least a portion of said vapors decomposing at said temperature range whereby copper metal is deposited on said continuously moving cast copper, and severing said continuously cast and gaseous metal plated copper into predetermined lengths.
6. A process of casting and plating ferrous metals simultaneously and continuously which comprises the steps of pouring molten ferrous metal into a mold and continuously withdrawing hot congealed ferrous metal from the mold in a downwardly direction, cooling said continuously cast ferrous metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound. thereafter subjecting said cast ferrous metal to heat-decomposable metal vapors, at least a portion of said vapors decomposing at said temperature range whereby metal is deposited on said continuously moving cast ferrous metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
7. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing gaseous nickel carbonyl when brought in contact therewith, thereafter subjecting said cast metal while moving along to gaseous nickel carbonyl vapors, at least a portion of said vapors decomposing at said temperature range whereby nickel metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a predetermined length.
8. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing gaseous chromium carbonyl when said gaseous carbonyl is brought in contact therewith, thereafter subjecting said cast metal while moving along to a gaseous chromium carbonyl, at least a portion of said carbonyl decomposing at said temperature range whereby chromium metal is deposited on said continuously moving cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
9. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, thereaiter sub- .iecting said cast metal while moving along and hot to a mixture of gases comprising an inert gas and a heat-decomposable metal vapor compound, causing decomposition of said metal vapor com-- pound whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
10. A process of casting and plating metal simultaneously and continuously which comprises the steps of pouring molten metal into a mold and continuously withdrawing hot congealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said cast metal to a gaseous medium composed of carbon. dioxide gas and a heat-decomposable metal carbonyl, said metal carbonyl being heat-decomposed whereby metal is deposited on said continuously cast metal upon contacting the hot cast metal, and severing the resultant continuously cast and gaseous metal plated product into a desired length.
11. A process of casting and plating metal simultaneously and continuously which comprises continuously withdrawing hotcongealed metal from the mold in a downwardly direction, cooling said continuously cast metal to a temperature within the range for decomposing a heat-decomposable metal vapor compound, subjecting said hot cast metal to a gaseous medium composed of hydrogen and a heat-decomposable gaseous metal hydride causing decomposition of said metal hydride whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
12. The method of plating continuously cast copper base alloys which comprises: continuously passing molten alloys to a molded form, cooling the molded alloy to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot cast material through a chamber where its surface is contacted by a gaseous medium including a heat decomposable metal bearing compound, at least a portion of which is decomposed whereby metal is deposited on the said cast molded metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
13. The method of plating continuously cast ferrous metals which comprises: continuously passing cast ferrous molten metal to a molded form, cooling the molded metal to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot metal through a chamber where its surface is contacted by a gaseous medium including a heat decomposable metal bearing compound, at least a portion of which is a gaseous chromium carbonyl which decomposes whereby chromium metal is deposited on the said cast molded metal, and severing the resultant continuously cast and gaseous metal plated product into predetermined lengths.
14. The method of plating continuously cast metals which comprises: continuously passing cast molten metal to a molded form, cooling the molded metal to a temperature in the decomposing range for volatile metal bearing compounds, thereafter guiding the hot cast material through a chamber sealed against escape of toxic gases by maintaining an atmosphere of hydrogen in the annular spaces surrounding the plating chamber, contacting the hot metal within said chamber with a gaseous medium composed of hydrogen and heat decomposable metal hydrides causing decomposition of said metal hydrides whereby metal is deposited on said continuously cast metal, and severing the same into predetermined lengths.
HARRY A. TOULMIN. J's.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 2,118,701 Field May I938 2,219,004 Daeves et al Oct. 22, 1940 2,290,083 Webster July 14, lit-i2 2,332,309 Drummond Get. 19, 1943 2,344,138 Drummond Mar. 14, 1944 2,363,695 Ruppik Nov. 28, 1944 2,382,432 McManus et al Aug. 14, 1945 2,442,485 Cook June 1, 1943 OTHER REFERENCES Iron Age, vol. 162, No. 8, August 15!, 1948, pages '76 and 77.
Priority Applications (3)
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US115033A US2657457A (en) | 1949-09-10 | 1949-09-10 | Continuous metal production and continuous gas plating |
US270920A US2741216A (en) | 1949-09-10 | 1952-02-11 | Apparatus for continuous metal production and continuous gas plating |
US348726A US2743700A (en) | 1949-09-10 | 1953-04-14 | Continuous metal production and continuous gas plating |
Applications Claiming Priority (1)
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US115033A US2657457A (en) | 1949-09-10 | 1949-09-10 | Continuous metal production and continuous gas plating |
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US115033A Expired - Lifetime US2657457A (en) | 1949-09-10 | 1949-09-10 | Continuous metal production and continuous gas plating |
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US2743700A (en) * | 1949-09-10 | 1956-05-01 | Ohio Commw Eng Co | Continuous metal production and continuous gas plating |
US2771669A (en) * | 1952-07-07 | 1956-11-27 | Gen Motors Corp | Method of coating interior of tubing with zinc |
US2853970A (en) * | 1956-03-09 | 1958-09-30 | Ohio Commw Eng Co | Continuous gas plating apparatus under vacuum seal |
US2854363A (en) * | 1953-04-02 | 1958-09-30 | Int Standard Electric Corp | Method of producing semiconductor crystals containing p-n junctions |
US2862783A (en) * | 1954-02-04 | 1958-12-02 | Ohio Commw Eng Co | Method of making metallized fibers |
US2881094A (en) * | 1953-07-16 | 1959-04-07 | Thomas B Hoover | Process of coating with nickel by the decomposition of nickel carbonyl |
US2881518A (en) * | 1956-11-23 | 1959-04-14 | Ohio Commw Eng Co | Continuous gas plated metal article |
US2886468A (en) * | 1953-07-16 | 1959-05-12 | Thomas B Hoover | Nickel plating process |
US2898234A (en) * | 1953-08-14 | 1959-08-04 | Ohio Commw Eng Co | Method of producing composite metallic bodies |
US2913354A (en) * | 1954-06-08 | 1959-11-17 | Northwestern Steel & Wire Co | Continuous method for conditioning wire |
US2934820A (en) * | 1954-04-15 | 1960-05-03 | Union Carbide Corp | Metal-to-metal adhesive bonding |
US2958899A (en) * | 1953-10-09 | 1960-11-08 | Int Resistance Co | Apparatus for deposition of solids from vapors |
US3191251A (en) * | 1962-08-16 | 1965-06-29 | Olsson Erik Allan | Process for treating continuously cast material |
US3394679A (en) * | 1966-12-05 | 1968-07-30 | Dresser Ind | Vacuum coating apparatus |
US3505974A (en) * | 1967-11-14 | 1970-04-14 | Edwards High Vacuum Int Ltd | Vacuum deposition apparatus |
US3602192A (en) * | 1969-05-19 | 1971-08-31 | Ibm | Semiconductor wafer processing |
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US2771669A (en) * | 1952-07-07 | 1956-11-27 | Gen Motors Corp | Method of coating interior of tubing with zinc |
US2854363A (en) * | 1953-04-02 | 1958-09-30 | Int Standard Electric Corp | Method of producing semiconductor crystals containing p-n junctions |
US2886468A (en) * | 1953-07-16 | 1959-05-12 | Thomas B Hoover | Nickel plating process |
US2881094A (en) * | 1953-07-16 | 1959-04-07 | Thomas B Hoover | Process of coating with nickel by the decomposition of nickel carbonyl |
US2898234A (en) * | 1953-08-14 | 1959-08-04 | Ohio Commw Eng Co | Method of producing composite metallic bodies |
US2958899A (en) * | 1953-10-09 | 1960-11-08 | Int Resistance Co | Apparatus for deposition of solids from vapors |
US2862783A (en) * | 1954-02-04 | 1958-12-02 | Ohio Commw Eng Co | Method of making metallized fibers |
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US2913354A (en) * | 1954-06-08 | 1959-11-17 | Northwestern Steel & Wire Co | Continuous method for conditioning wire |
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US3191251A (en) * | 1962-08-16 | 1965-06-29 | Olsson Erik Allan | Process for treating continuously cast material |
US3394679A (en) * | 1966-12-05 | 1968-07-30 | Dresser Ind | Vacuum coating apparatus |
US3505974A (en) * | 1967-11-14 | 1970-04-14 | Edwards High Vacuum Int Ltd | Vacuum deposition apparatus |
US3602192A (en) * | 1969-05-19 | 1971-08-31 | Ibm | Semiconductor wafer processing |
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