1. Technical Field
The invention relates generally to the continuous casting of metals. More particularly, the invention relates to the protection of reactionary metals from reacting with the atmosphere when molten or at elevated temperatures. Specifically, the invention relates to pressurized seals which prevent the atmosphere from contacting a metal casting as it exits the melting chamber.
2. Background Information
Hearth melting processes, Electron Beam Cold Hearth Refining (EBCHR) and Plasma Arc Cold Hearth Refining (PACHR), were originally developed to improve the quality of titanium alloys used for jet engine rotating components. Quality improvements in the field are primarily related to the removal of detrimental particles such as high density inclusions (HDI) and hard alpha particles. Recent applications for both EBCHR and PACHR are more focused on cost reduction considerations. Some ways to effect cost reduction are increasing the flexible use of various forms of input materials, creating a single-step melting process (conventional melting of titanium, for instance, requires two or three melting steps) and facilitating higher product yield.
Titanium and other metals are highly reactive and therefore must be melted in a vacuum or in an inert atmosphere. In electron beam cold hearth refining (EBCHR), a high vacuum is maintained in the furnace melting and casting chambers in order to allow the electron beam guns to operate. In plasma arc cold hearth refining (PACHR), the plasma arc torches use an inert gas such as helium or argon (typically helium) to produce plasma and therefore the atmosphere in the furnace consists primarily of a partial or positive pressure of the gas used by the plasma torches. In either case, contamination of the furnace chamber with oxygen or nitrogen, which react with molten titanium, may cause hard alpha defects in the cast titanium. Thus, oxygen and nitrogen should be completely or substantially avoided within the furnace chamber throughout the casting process.
In order to permit extraction of the cast from the furnace with minimal interruption to the casting process and no contamination of the melting chamber with oxygen and nitrogen or other gases, current furnaces utilize a withdrawal chamber. During the casting process the lengthening cast moves out of the bottom of the mold through an isolation gate valve and into the withdrawal chamber. When the desired or maximum cast length is reached it is completely withdrawn out of the mold through the gate valve and into the withdrawal chamber. Then, the gate valve is closed to isolate the withdrawal chamber from the furnace melt chamber, the withdrawal chamber is moved from under the furnace and the cast is removed.
Although functional, such furnaces have several limitations. First, the maximum cast length is limited to the length of the withdrawal chamber. In addition, casting must be stopped during the process of removing a cast from the furnace. Thus, such furnaces allow continuous melting operations but do not allow continuous casting. Furthermore, the top of the cast will normally contain shrinkage cavities (pipe) that form when the cast cools. Controlled cooling of the cast top, known as a “hot top”, can reduce these cavities, but the hot top is a time-consuming process which reduces productivity. The top portion of the cast containing shrinkage or pipe cavities is unusable material which thus leads to a yield loss. Moreover, there is an additional yield loss due to the dovetail at the bottom of the cast that attaches to the withdrawal ram.
The present invention eliminates or substantially reduces these problems with a sealing apparatus which permits continuous casting of the titanium, superalloys, refractory metals, and other reactive metals whereby the cast in the form of an ingot, bar, slab or the like can move from the interior of a continuous casting furnace to the exterior without allowing the introduction of air or other external atmosphere into the furnace chamber.
The present invention provides a furnace comprising an interior chamber; a continuous casting mold within the interior chamber; a chamber wall defining a secondary chamber which communicates with the interior chamber and atmosphere external to the interior chamber; a metal casting pathway which extends from the interior chamber through the secondary chamber and is adapted to allow the metal casting to pass there through to the external atmosphere; a first seal surrounding the metal casting pathway along the secondary chamber; a first movable backing member; and a first force producing mechanism operatively connected to the backing member for forcing the backing member against the seal and the seal toward the pathway so that the first force producing mechanism and backing member are adapted to force the seal against an outer periphery of the metal casting as the metal casting is passing through the secondary chamber via the pathway.
The present invention also provides a casting furnace comprising an interior chamber; a chamber housing which is below the interior chamber and defines a secondary chamber which communicates with the interior chamber and atmosphere external to the interior chamber; a metal casting pathway which extends from the interior chamber through the secondary chamber and is adapted to allow a metal casting to pass there through to the external atmosphere; a seal which is within the secondary chamber and surrounds the pathway whereby the seal is adapted to surround the metal casting; and an inner perimeter of the seal which decreases in response to vertical compression of the secondary chamber.
The present invention also provides a method comprising the steps of forming an ingot in an interior chamber defined by a sidewall; directing the ingot from the interior chamber into a secondary chamber; and moving a backing member relative to the sidewall against a first seal to force the first seal against the ingot along the secondary chamber.
A preferred embodiment of the invention, illustrated of the best mode in which Applicant contemplates applying the principles, is set forth in the following description and is shown in the drawings and is particularly and distinctly pointed out and set forth in the appended claims.
Similar numbers refer to similar parts throughout the drawings.
At the outset, it should be appreciated that like drawing numbers on different drawing views identify identical, or functionally similar, structural elements of the invention. While the present invention is described with respect to what is presently considered to be the preferred embodiments, it is to be understood that the invention as claimed is not limited to the disclosed aspects.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood to one of the ordinary skill in the art to which this invention belongs. Although any methods, devices or materials similar or equivalent to those described herein can be used in the practice or testing of the invention, the preferred methods, devices, and materials are now described.
The seal of the present invention is indicated generally at 10 in
Furnace 12 further includes a lift or withdrawal ram 32 for lowering a metal cast 34 (
Seal 10 is configured to prevent reactive atmosphere 44 from entering melting chamber 16 during the continuous casting of reactionary metals such as titanium and superalloys. Seal 10 is also configured to protect the heated metal cast 34 when it enters reactive atmosphere 44. Seal 10 includes a passage wall or port wall 46 having a substantially cylindrical inner surface 47 defining passage 48 therewithin which has an entrance opening 50 and an exit opening 52. Port wall 46 includes an inwardly extending annular flange 54 having an inner surface or circumference 56. Inner surface 47 of port wall 46 adjacent entrance opening 50 defines an enlarged or wider section 58 of passage 48 while flange 54 creates a narrowed section 60 of passage 48. Below annular flange 54, inner surface 47 of port wall 46 defines an enlarged exit section 61 of passage 48.
As later explained, a reservoir 62 for a molten material such as liquid glass is formed during operation of furnace 12 in enlarged section 58 of passage 48. A source 64 of particulate glass or other suitable meltable material such as fused salt or slags is in communication with a feed mechanism 66 which is in communication with reservoir 62. Seal 10 may also include a heat source 68 which may include an induction coil, a resistance heater or other suitable source of heat. In addition, insulating material 70 may be placed around seal 10 to help maintain the seal temperature.
The operation of furnace 12 and seal 10 is now described with reference to
As cast 34 continues to move downwardly as indicated in
Once cast 34 has exited furnace 12 to a sufficient degree, a portion of cast 34 may be cut off to form an ingot 80 of any desired length, as shown in
Thus, seal 10 provides a mechanism for preventing the entry of reactive atmosphere 44 into melting chamber 16 and also protects cast 34 in the form of an ingot, bar, slab or the like from reactive atmosphere 44 while cast 34 is still heated to a temperature where it is still reactive with atmosphere 44. As previously noted, inner surface 24 of mold 20 is substantially cylindrical in order to produce a substantially cylindrical cast 34. Inner surface 47 of port wall 46 is likewise substantially cylindrical in order to create sufficient space for reservoir 62 and space between cast 34 and inner surface 56 of flange 54 to create the seal and also provide a coating of appropriate thickness on cast 34 as it passes downwardly. Liquid glass 76 is nonetheless able to create a seal with a wide variety of transverse cross-sectional shapes other than cylindrical. The transverse cross-sectional shapes of the inner surface of the mold and the outer surface of the cast are preferably substantially the same as the transverse cross-sectional shape of the inner surface of the port wall, particularly the inner surface of the inwardly extending annular flange in order that the space between the cast and the flange is sufficiently small to allow liquid glass to form in the reservoir and sufficiently enlarged to provide a glass coating thick enough to prevent reaction between the hot cast and the reactive atmosphere outside of the furnace. To form a metal cast suitably sized to move through the passage, the transverse cross-sectional shape of the inner surface of the mold is smaller than that of the inner surface of the port wall.
Additional changes may be made to seal 10 and furnace 12 which are still within the scope of the present invention. For example, furnace 12 may consist of more than a melting chamber such that material 72 is melted in one chamber and transferred to a separate chamber wherein a continuous casting mold is disposed and from which the passage to the external atmosphere is disposed. In addition, passage 48 may be shortened to eliminate or substantially eliminate enlarged exit section 61 thereof. Also, a reservoir for containing the molten glass or other material may be formed externally to passage 48 and be in fluid communication therewith whereby molten material is allowed to flow into a passage similar to passage 48 in order to create the seal to prevent external atmosphere from entering the furnace and to coat the exterior surface of the metal cast as it passes through the passage. In such a case, a feed mechanism would be in communication with this alternate reservoir to allow the solid material to enter the reservoir to be melted therein. Thus, an alternate reservoir may be provided as a melting location for the solid material. However, reservoir 62 of seal 10 is simpler and makes it easier to melt the material using the heat of the metal cast as it passes through the passage.
The seal of the present invention provides increased productivity because a length of the cast can be cut off outside the furnace while the casting process continues uninterrupted. In addition, yield is improved because the portion of each cast that is exposed when cut does not contain shrinkage or pipe cavities and the bottom of the cast does not have a dovetail. In addition, because the furnace is free of a withdrawal chamber, the length of the cast is not limited by such a chamber and thus the cast can have virtually any length that is feasible to produce. Further, by using an appropriate type of glass, the glass coating on the cast may provide lubrication for subsequent extrusion of the cast. Also the glass coating on the cast may provide a barrier when subsequently heating the cast prior to forging to prevent reaction of the cast with oxygen or other atmosphere.
While the preferred embodiment of the seal of the present invention has been described in use with glass particulate matter to form a glass coating, other materials may be used to form the seal and glass coating, such as fused salt or slags for instance.
The present apparatus and process is particularly useful for highly reactive metals such as titanium which is very reactive with atmosphere outside the melting chamber when the reactionary metal is in a molten state. However, the process is suitable for any class of metals, e.g. superalloys, wherein a barrier is needed to keep the external atmosphere out of the melting chamber to prevent exposure of the molten metal to the external atmosphere.
With reference to
Also within interior chamber 16 is a cooling device in the form of a water cooled tube 84 which is used for cooling conduit 66 of the feed mechanism or dispenser of the particulate material in order to prevent the particulate material from melting within conduit 66. Tube 84 is substantially an annular ring which is spaced outwardly from metal cast 34 and contacts conduit 66 in order to provide for a heat transfer between tube 84 and conduit 66 to provide the cooling described.
Furnace 12 further includes a temperature sensor in the form of an optical pyrometer 86 for sensing the heat of the outer periphery of metal cast 34 at a heat sensing location 88 disposed near induction coil 82 and above port wall 46. Furnace 12 further includes a second optical pyrometer 90 for sensing the temperature at another heat sensing location 92 of port wall 46 whereby pyrometer 90 is capable of estimating the temperature of the molten bath within reservoir 62.
External to and below the bottom wall of chamber wall 14, furnace 12 includes an ingot drive system or lift 94, a cutting mechanism 96 and a removal mechanism 98. Lift 94 is configured to lower, raise or stop movement of metal cast 34 as desired. Lift 94 includes first and second lift rollers 100 and 102 which are laterally spaced from one another and are rotatable in alternate directions as indicated by Arrows A and B to provide the various movements of metal cast 34. Rollers 100 and 102 are thus spaced from one another approximately the same distance as the diameter of the coated metal cast and contact coating 78 during operation. Cutting mechanism 96 is disposed below rollers 100 and 102 and is configured to cut metal cast 34 and coating 78. Cutting mechanism 96 is typically a cutting torch although other suitable cutting mechanisms may be used. Removal mechanism 98 includes first and second removal rollers 104 and 106 which are spaced laterally from one another in a similar fashion as rollers 100 and 102 and likewise engage coating 78 of the coated metal cast as it moves therebetween. Rollers 104 and 106 are rotatable in alternate directions as indicated at Arrows C and D.
Additional aspects of the operation of furnace 12 are described with reference to
With continued reference to
Referring to
The feed mechanism for feeding the solid particulate material of the present invention is now described in greater detail with reference to
Referring to
Referring to
Referring to
Furnace 12 is configured with a metal cast pathway which extends downwardly from the bottom of mold 20 and through the passage of reservoir wall 46. This pathway has a horizontal cross sectional shape which is the same as outer periphery 79 of cast 34, which is substantially identical to the cross sectional shape of inner surface 24 of casting mold 20. Thus, distance D1 also represents the distance from the metal cast pathway to inner surface 47 of wall 46 and the distance between said pathway and exit ends 166 of feed tubes 116.
The particulate coating material is shown as substantially spherical particles 74 which are fed along the feed path from hopper 110 to reservoir 62. It has been found that a soda-lime glass works well as the coating material due in part to the availability of such glass in substantially spherical form. Due to the relatively long pathway along which particles 74 must travel while maintaining control of their flow downstream toward reservoir 62, the use of spherical particles 74 has been found to greatly facilitate the feeding process through conduits 116 which are positioned at an angle suitable to maintain this controlled flow. The segments 142 of feed tubes 116 are disposed along a generally constant angle in spite of the diagrammatic view shown in
The operation of the feed system is now described with reference to
Particles 74 complete their travel along the feed path (arrows M) as they reach ends 166 and exit feed tubes 116 therefrom, as shown in
Another aspect of the present invention is illustrated in
The operation of furnace 12 during initial startup is now described with reference to
The cross sectional transverse shapes of passages 200 of O-rings 190 and 192 are, prior to insertion of starter stub 224, substantially the same as and slightly smaller than that of starter stub 224. The resilient compressible characteristics of the O-rings 190 and 192 allow them to expand slightly as starter stub 224 is inserted in order to match the cross sectional size of stub 224 and provide the gas tight seal previously noted. O-rings 190 and 192 are formed of a material which is impermeable to the inert gas. The cross sectional shape of sleeve 194 is very nearly the same as that of starter stub 224 and although it does not provide a gas tight seal, it does generally eliminate the vast majority of gas which may move from one side to the other of sleeve 194. Thus, it substantially minimizes the inert gas which would otherwise flow from segment 208 of passage 184 into the external atmosphere. Sleeve 194 is formed of a material which is permeable to the inert gas. Thus, inert gas may be exhausted from the annular portion of space 208 to the other side of sleeve 194 by passing through the pores of the material forming sleeve 194, between the inner periphery of sleeve 194 and outer periphery of starter stub 224, and also between the outer periphery of sleeve 194 and inner periphery 189 of the passage wall.
Once the gas tight seal is formed between starter stub 224 and O-rings 190 and 192, vacuum mechanism 220 is operated in order to evacuate the air from melting chamber 16. Typically, melting chamber 16 is evacuated to a base level below 100 millitorr and a leak rate of less than 30 millitorr within three minutes. The seal provided by the O-rings allows this to occur. Even though O-rings 190 and 192 are configured to provide a gas tight seal, or a substantially gas tight seal when the atmosphere within chamber 16 is at atmospheric pressure or under vacuum, the substantial reduction of pressure within chamber 16 may allow some leakage of gas into chamber 16 between starter stub 224 and O-rings 190 and 192 or between inner periphery 189 and said O-rings. Thus, the inert gas supplied to passage 184 is intended to allow only inert gas to enter melting chamber 16 via this potential leakage location, and thus not allow any air from the external atmosphere to enter melting chamber 16 around starter stub 224. After the melting chamber is evacuated and checked to ensure that the leak rate is limited to an acceptable level, the furnace is then back filled with inert gas from supply 214 via conduit 218. Melting chamber 16 is monitored to insure oxygen and moisture concentrations are sufficiently low to prevent contamination.
If these concentrations meet quality control standards, melting hearth plasma torch 28 is lit or ignited to form a plasma plume 226 to begin heating and melting the solid feed material within melting hearth 18 which is to be used for forming the metal ingot. Induction coils 68 and 82 are then powered for respectively inductively heating passage wall 46 and starter stub 224. Heat sensors 86 and 90 are used to respectively to monitor and control the temperature to which starter stub 224 and passage wall 48 are preheated. Although the exact temperature may vary with the specific circumstances, in the exemplary embodiment, starter stub 224 is preheated to approximately 2000° F. while reservoir passage wall 46 is preheated to a temperature of about 1700° F. to 1800° F. The mold plasma torch 30 is also lit or ignited to form its plasma plume 226 for heating the top of starter stub 224. Torch 30 may be used in the preheating process of starter stub 224. In addition, torch 30 is used to melt the top portion of starter stub 224 after which molten metal 72 is poured from hearth 18 into mold 20 to begin casting metal cast 34 so that stub 224 and cast 34 together form an ingot.
As shown in
As shown in
When the starter stub and metal cast 34 is initially withdrawn after this stopping period, the withdrawal rate is relatively slow, and typically less than 1.0 inch per minute. The lowering of the ingot at this slower rate typically occurs for about ten minutes. The use of this slower withdrawal rate is related to the above noted need to maintain sufficient heat energy from the metal cast to melt particles 74 and keep them in a molten state. Once the molten seal is formed, there is no longer a need for the O-rings 190 and 192 to provide a seal to prevent external atmosphere from entering melting chamber 16, and thus no longer a need to provide inert gas into passage 184. Thus, movement of inert gas into passage 184 is stopped once the molten seal is formed. Once the slower ingot withdrawal is over, the ingot withdrawal rate is then accelerated to a rate typically greater than 1.0 inch per minute with a typical maximum rate of about 3.0 inches per minute.
As the ingot is lowered, particles 74 are fed at a sufficient rate to maintain the molten seal within reservoir 62 at a suitable level. The particle 74 feed rate is tied to the linear velocity of withdrawing cast 34 in order to maintain the volume of the molten material forming the molten seal at approximately the same level throughout the process although there is some room for variation as long the molten seal is maintained. More particularly, a faster withdrawal rate of metal cast 34 uses molten material from the molten seal more quickly in forming the coating around the metal cast and thus requires a relatively faster feed rate of particles 74 while a relatively slower withdrawal rate uses molten material from the molten seal less rapidly and thus requires a less rapid feed rate of particles 74 to maintain the molten seal. The rest of the casting process also continues at a controlled rate, and thus solid feed material is fed as needed into melting hearth 18 and melted therein to pour molten material into the continuous casting mold at the desired rate. The casting of metal cast 34 and the application of the coating material to the outer periphery of the metal cast via the molten seal continues as previously described.
When an entire campaign of casting is completed (which can easily last for six or seven days or more) O-rings 190 and 192 and ceramic braided sleeve 194 are removed and replaced in order to set up the furnace for a new campaign of continuous casting. Although the O-rings of the present invention are intended for temporary operation under the high temperatures involved during the start up process to provide the needed seal until the molten seal is formed, they nonetheless are not suitable for a long term continuous casting campaign, and thus will have deteriorated to a degree that they need to be replaced for initial startup of subsequent casting. Indeed, the sealing rings 190 and 192 typically will only provide the needed seal for less than one hour, most typically about ½ hour or so. While the ceramic braided sleeve 194 is configured for even higher temperature use, (for example, over 2000° F.) for longer periods it nonetheless needs to be replaced prior to setting up for a new campaign of casting. Although ceramic braided sleeve 194 might otherwise last longer, the interaction with the coating applied to the outer periphery of metal cast 34 degrades ceramic braided sleeve 194 to the degree that it needs to be replaced.
It is noted that the volume of molten material in the molten seal is relatively small and typically no more than can be melted during the previously noted stopping period in which the ingot is stopped in order to feed particles 74 into reservoir 62 and melt them to form the molten seal. One reason for keeping the volume of the molten material and molten seal to a relative minimum is to limit the amount of energy used to provide the necessary temperature for this melting process. In addition, the minimal volume is advantageous when the furnace needs to be shut down in a controlled manner. The shutdown of the furnace involves shutting off the flow of particles 74 along the particle feed pathway to reservoir 62. Ceasing the flow of particles 74 into reservoir 62 may be achieved almost immediately or within a relatively few seconds in order to quickly reach a state in which the volume of molten material in reservoir 62 is not increased. The shutdown of the furnace obviously also includes cessation of pouring additional molten material into mold 22. The metal cast 34 is lowered relatively quickly in order to ensure that the molten material forming the molten seal within reservoir 62 does not solidify prior to complete removal of the ingot therefrom. Thus, the temperature of the portion of metal cast 34 passing through reservoir 62 during this shutdown process should not decrease to below the melting temperature of particles 74. In the exemplary embodiment this temperature is about 1400° F., which is the approximate melting temperature of the glass particles which are typically used in making up particles 74. However, this temperature will obviously vary depending upon what material is used to form particles 74. When this portion of metal cast 34 does decrease below said melting temperature, the metal cast will become stuck and effectively weld itself to passage wall 46 along the annular flange forming the bottom of reservoir 62. The furnace would thus require a substantial amount of time for repair and removal of the ingot therefrom.
It is noted that alternate start up assemblies may be used in order to prevent external atmosphere from entering the melting chamber prior to the formation of the molten seal. However, such a start up assembly is more complicated than the one described above and creates its own problems. More particularly, a lower sealed chamber may be formed below the melting chamber which includes a rigid wall or door which may be closed to form the sealed condition of the lower chamber and opened or removed to open communication between the lower chamber and the external atmosphere. Such a configuration would require a larger annular sealing member which would not contact the outer periphery of the ingot but rather contact and form an airtight seal between the door and other rigid walls such as the bottom wall of the melting chamber or a rigid structure extending downwardly therefrom. Such a start up assembly would thus require that the melting chamber and the lower chamber both be evacuated and then back filled with inert gas prior to formation of the molten seal. Once the molten seal used with such a start up apparatus is formed, the sealed chamber can be opened to the external atmosphere by opening of the door to break the initial seal. In order to proceed with the continuous casting of the ingot using the molten seal, the door would thus have to be moved out of the metal cast pathway extending below the melting chamber. While the use of such a start up assembly is possible, it is relatively cumbersome and requires a substantial amount of additional structure compared to the use of vacuum seal assembly 180. The use of such a lower chamber may tend to cause the process to slow down, which can be problematic in keeping the metal cast at a desired temperature for melting the particles of coating material as previously discussed. While the lower chamber could be made substantially larger in order to minimize the problems related to slowing down the withdrawal of the ingot, doing so would add to the length of the lower chamber required. In addition, the size of the lower chamber would need to be large enough to accommodate the lowering mechanism such as rollers 100 and 102 in order to control the insertion of the starter stub as well as the withdrawal of the ingot. The use of vacuum seal assembly 180 eliminates these problems and the various structures and the lower chamber which would be required in order to create such a start up assembly.
Referring to
Casting furnace 12 also includes an inert gas supply 322 and a gas pump 324. Gas pump 324 forces the inert gas through input line 326 and the plasma torches to fill melting chamber 16. Used gas exits chamber 16 via output line 328 and re-enters inert gas supply 322 to be recycled through the continuous feedback or recirculation loop formed of chamber 16, line 328, supply 322, pump 324 and line 326. While the feedback loop is generally a closed system, if gas loss sensors 316 detect that an excessive amount of inert gas has been lost from interior chamber 16, sensor 316 sends a gas loss signal to the inert gas controller 318, which directs the gas pump 324 to increase the supply of the inert gas within the melting chamber 16. Further, a gas loss sensor may be located within the melting chamber to detect a low gas condition where additional inert gas can be pumped into the chamber. Such a gas loss sensor may be a pressure sensor which determines the internal pressure of chamber 16 such that a sufficient pressure change indicates a loss of inert gas.
Referring primarily to
A compressible annular seal 338 with a cylindrical inner surface 340 and a cylindrical outer surface 342 is secured between the upper ring and the lower ring radially inward of rods 337. Seal 338 is preferably composed of a ceramic braid, but may also be composed of a fiberglass, Kevlar, or any other suitable refractory sealing material. In particular, upper ring 334 includes a top surface 344 and a bottom surface 346, while lower ring 336 includes a top surface 348 and a bottom surface 350. An annular seal-receiving space 335 is defined between upper ring 334 and lower ring 336 and particularly bottom surface 346 and top surface 348. Seal 338 is secured within the annular receiving space. A rigid sensor collar 358 is rigidly secured to and extends downwardly from bottom surface 350 of lower ring 336 of first assembly 302 to a rigid connection with the top of upper ring 334 of second assembly 304. The sensor collar preferably includes an aperture 360 adapted to receive and secure inert gas sensors 316 below or downstream of the respective seals 338. Secondary chamber 330 is thus defined by the circular inner perimeters or surfaces of collar 332, seals 338 and each of the upper and lower rings 334 and 336 of the various seal assemblies 302, 304, 306 and 308, and each of sensor collars 358. Thus, the annular spaces between the respective pairs of upper and lower rings 334 and 336, including the respective annular seal-receiving space 335, extend radially outwardly from chamber 330.
Seal 338 is surrounded by four rigid backing members or plates 352 at seal outer surface 342. Force producing mechanisms 312 include the backing plate 352, a rod or piston 354, and a housing or cylinder 356 in which piston 354 is slidably received and driven by pressurized hydraulic fluid or air. As shown in
Each backing plate 352 preferably includes an inner surface 362 that is concavely curved as viewed from above and complementary shaped to the convexly curved seal outer surface 342. Each inner surface 362 forms or lies along an arc of a circle which is concentric about longitudinal axis 333 and has a radius of curvature which is substantially the same as that of outer surface 342. Force producing mechanisms 312 are thus configured to compress the seal about its periphery and force the seal inner surface 340 into contact with the outer surface 79 of the ingot and the starter stub. Outer surface 79 also serves to define or is coincident with the portion of the outer periphery of the metal casting pathway in secondary chamber 330 through which the ingot passes from chamber 16 to the external atmosphere. Each of seal assemblies 304 through 308 are structurally and functionally equivalent to assembly 302, with the only exception being that seal assemblies 304 through 308 are located below seal assembly 302 and secured to the adjacent seal assembly.
The operation of the furnace utilizing the present seal assemblies is now described.
As previously described with regard to the use of vacuum seal assembly 180 of the previous embodiment illustrated in
At this point, torches 28 and 30 are ignited in order to melt the metal to form molten material 72 within hearth 18 and to control the temperature within mold 20, as seen in
During operation, the first or uppermost seal assembly 302 provides sealing until at least the upper inert gas sensor 316 detects an excessive inert gas leak condition. Once this inert gas leak or loss is sensed, sensor 316 sends an inert gas loss signal to control valve 314 via controller 318, which in response actuates the four force producing mechanisms 312 of the second seal assembly 304 to force the seal 338 thereof against the outer periphery of the metal cast 34 to provide a suitable seal which either replaces or is in addition to the seal provided by seal 338 of first assembly 302. At this point, sensor 316 which is downstream of first assembly 302 and upstream of assembly 304 is deactivated and the sensor 316 downstream of second assembly 304 and upstream of third assembly 306 is activated in order to detect inert gas loss downstream of the seal 338 of the second assembly. In the same manner as noted above, an excessive gas leak detected by this second sensor 316 signals control valve 314 via controller 318 to activate mechanism 312 of the third assembly 306 to force seal 338 against the outer perimeter of metal cast 334 to add to or provide the sole seal between interior chamber 16 and the external atmosphere. The activation and radially inward movement of the rods, backing members and seal 338 of assembly 306 is illustrated in
The seal assemblies are thus typically activated in a sequential manner such that the uppermost or most upstream seal assembly 302 is activated to provide a seal against the ingot, followed by activation of the next downstream seal assembly 304, followed by seal assembly 306 and subsequently by seal assembly 308. However, as noted above, more than one of the seal assemblies may be activated simultaneously or during the same time duration. It is also noted that inasmuch as each of the seal assemblies includes four force producing mechanisms 312 in the exemplary embodiment, the controller 318 and control valve 314 are typically configured to operate the four mechanisms 312 of a given seal assembly in unison from the inactivated position to the activated position and vice versa. Although each set of force producing mechanisms of a given seal assembly may operate in unison, system 300 is configured such that each set of mechanisms 312 of a given seal assembly operates independently of each other set such that they may be activated or inactivated sequentially or otherwise.
This operation and process continues until all of the seals are exhausted. Preferably, continuous casting operations will last for a full work week of five to seven days before all the seals are worn out. Casting is then discontinued with at least one seal still functioning so that the inert gas may be removed from chamber 16 and backfilled with air. The ingot is then completely removed from chamber 330, which provides the operator with the ability to change all of the seals at one time in order to set up for subsequent casting process. Although the preferred embodiment is illustrated with four seals, it is within the spirit and scope of the present invention to provide any number of seals and to locate the inert gas sensors at any position within the secondary chamber.
While rings 372 and 376 of the upper collar are rigidly secured to side wall 14 and are thus stationary, the remainder of chamber housing 388 serves as a rigid backing member which is moveable relative to side wall 14 and rings 372 and 376. More particularly, the remainder chamber housing 388 includes a lower annular member or ring 390, and an annular side wall which is rigidly secured to and extends upwardly from the outer perimeter of annular ring 390. The annular sidewall includes lower and upper annular members or rings 392 and an annular member or flange 394 which is rigidly secured between rings 392 and extends radially outwardly therefrom beyond their outer perimeters. The side wall 392, 394 has an inner surface or perimeter which is defined by the inner surfaces or perimeters of rings 392 and flange 394 and which in the exemplary embodiment has a diameter which is the same as diameter 378 of the outer perimeter of the seals 380. Thus, the outer diameter of ring 376 is nearly the same as and slightly smaller than the inner diameter of the side wall formed by members 392 and 394. In addition, outer surfaces 384 of seals 380 contact the inner perimeter of side wall 392, 394. Each of rings 376 and 390 have inner perimeters which are disposed radially inwardly of the inner perimeter of the side wall 392, 394. Six holes 396 are formed in flange 394 radially outward of the outer perimeter of rings 390, 392 and 376 and have disposed therein respective bushings 398 which themselves define respective openings 400 vertically aligned with threaded holes 374. Respective externally threaded members in the form of bolts 402 have shafts which extend through holes or openings 400 such that the externally threaded section of the bolt threadably engages the respective threaded hole 374. Each bolt 402 has an enlarged head 404 disposed below and spaced downwardly from flange 394.
A force producing mechanism 406, shown here in the form of a spring, is secured between a bottom surface 408 of flange 394 and the top of head 404. Spring 406 provides a constant vertically upward force or pressure (arrows 416) on flange bottom surface 408 and forces or biases flange 394 and seals 382 upward. Springs 406 thus bias the backing member formed of members 390, 392 and 394 vertically upwardly in the upstream direction relative to the stationary members 372, 376 and side wall 14 and thus parallel to the metal cast pathway and the direction of movement of the ingot during casting. The upward movement of the backing member illustrated at arrows 416 is translated to and compresses the seals 380 between the top surface of ring 390 and the bottom surface of ring 376 such that each seal 380 applies a radially outward force (arrows 417) against the inner perimeter of the side wall 392, 394 and a radially inward force (arrows 418) toward the metal casting pathway which during the casting process is also against the outer periphery of the metal casting. Outer sidewall 392 includes a top surface 410 arranged to contact a bottom surface 412 of upper ring 372 when the seals are worn to the degree that they should be replaced although seals 380 may be replaced before this occurs. As noted with the previous embodiment, seals 380 are typically formed of a ceramic braided material or the materials noted in the previous embodiment.
The casting process using system 370 is now described. As discussed in the previous embodiment, a starter stub is first inserted upwardly through the secondary chamber along the metal casting pathway such that its upright end is inserted into the continuous casting mold 20. To facilitate the upward insertion of the starter stub, the bolts 402 would be unthreaded or backed off by rotation in one direction in order to decompress springs 406 completely or sufficiently so that seals 380 would not unduly hinder the upward movement of the starter stub into position. The inner perimeter or surfaces 382 of seals 380 may be disengaged or spaced outwardly from the outer surface of the stub at this point. Once the starter stub has been inserted, the bolts 402 may be tightened by threading them into holes 374 by rotation in the opposite direction in order to compress springs 406 to the desired degree in order that seals 380 provide a sufficient seal between the chamber wall and the starter stub. More particularly, the tightening of bolts 402 causes the compression of springs 406 such that the tightening and the spring bias of springs 406 applies the vertically upward force on the backing member of housing 388 to compress seals 380, whereby the inner perimeters 382 thereof move radially inwardly such that the respective inner perimeter is decreased as is the corresponding inner diameter such that the inner perimeters form a seal against the outer periphery of the ingot. It is noted that the bolts may be tightened in order to force the backing member upwardly without the use of springs 406 although springs 406 when sufficiently compressed are able to provide a continuous upward force or pressure on the backing member over an extended time duration as the seals begin to wear and thus eliminate the subsequent additional tightening of the bolts in order to continue to provide the seal against the ingots.
Once this seal is formed, the melting chamber 16 is evacuated and backfilled with inert gas as discussed in the previous embodiment. As shown in
Referring to
During operation, heads 430 are frictionally engaged with metal casting 34 and cylindrical outer surface 430 such that heads 430 are forced downward in the direction associated with arrow 364 and force arm 432 to bend in the same direction. Although the tadpole seals 420 provide some radially inward bias against the outer periphery of the ingot during the casting process, this force is typically insufficient to allow a single seal 420 to provide the necessary seal against the ingot to provide the separation between the inert gas atmosphere and the external atmosphere. Thus, a plurality of seals 420 is typically used in order to provide the degree of seal necessary. Once the seals are no longer effective, individual seals 420 may be replaced, or the entire assembly may be removed and replaced to provide continuous casting.
Thus, furnace 12 and the seals provide a simple apparatus for continuously casting and protecting metal castings which are reactionary with external atmosphere when hot so that the rate of production is substantially increased and the quality of the end product is substantially improved.
Accordingly, the continuous casting sealing method is an effective, safe, inexpensive, and efficient device that achieves all the enumerated objectives of the invention, provides for eliminating difficulties encountered with prior art devices, systems, and methods, and solves problems and obtains new results in the art.
In the foregoing description, certain terms have been used for brevity, clearness, and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes and are intended to be broadly construed.
Moreover, the description and illustration of the invention is an example and the invention is not limited to the exact details shown or described.
Having now described the features discoveries, and principles of the invention, the manner in which the continuous casting sealing method is construed and used, the characteristics of the construction, and the advantageous new and useful results obtained; the new and useful structures, devices, elements, arrangement, parts, and combinations are set forth in the appended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 12/283,226, filed Sep. 10, 2008, now U.S. Pat. No. 7,926,548 , which is a continuation-in-part of U.S. patent application Ser. No. 11/799,574, filed May 2, 2007, now U.S. Pat. No. 7,484,549, which is a continuation-in-part of U.S. patent application Ser. No. 11/433,107, filed May 12, 2006, now U.S. Pat. No. 7,484,548, which is a continuation-in-part of U.S. patent application Ser. No. 10/989,563, filed Nov. 16, 2004, now U.S. Pat. No. 7,322,397; the contents of the applications are entirely incorporated herein by reference.
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Number | Date | Country | |
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20100282427 A1 | Nov 2010 | US |
Number | Date | Country | |
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Parent | 12283226 | Sep 2008 | US |
Child | 12828782 | US | |
Parent | 11799574 | May 2007 | US |
Child | 12283226 | US | |
Parent | 11433107 | May 2006 | US |
Child | 11799574 | US | |
Parent | 10989563 | Nov 2004 | US |
Child | 11433107 | US |