EP0022566B1

EP0022566B1 - Process and apparatus for electromagnetic forming of molten metals or alloys, coolant manifold for electromagnetic casting

Info

Publication number: EP0022566B1
Application number: EP80103976A
Authority: EP
Inventors: John C. Yarwood; Derek E. Tyler
Original assignee: Olin Corp
Current assignee: Olin Corp
Priority date: 1979-07-11
Filing date: 1980-07-10
Publication date: 1986-01-08
Also published as: EP0022566A1; JPS5614056A; CA1161107A; DE3071333D1

Description

Background of the Invention

The invention relates to a process according to the preambles of claims 1 and 2, to an apparatus according to the preambles of claims 3, 5 and 6, and to a coolant manifold according to the preambles of claims 9, 11 and 12. Such process, apparatus and coolant manifold are known in the art, for example as disclosed in US-A-3985179.
This invention provides a control of corner shape in continuous or semi-continuous electromagnetic casting of desired shapes, such as for example, sheet or rectangular ingots of metals and alloys. The basic electromagnetic casting process has been known and used for many years for continuously or semi-continuously casting metals and alloys.
One problem which has been presented by electromagnetic casting of sheet or rectangular ingots has been the existence of high radius of curvature corners thereon. Rounding off of corners in electromagnetic cast sheet ingots is a result of higher electromagnetic pressure at a given distance from the inductor near the ingot corners, where two proximate faces of the inductor generate a larger field. This is in contrast to lower electromagnetic pressure at the same distance from the inductor on the broad face of the ingot remote from the corner where only one inductor face acts.
There is a need to form small radius of curvature corners on sheet ingots so that during rolling cross-sectional changes at the edges of the ingot are minimized. Larger radius of curvature corners accentuate tensile stress at the ingot edges during rolling which causes edge cracking and loss of material. Thus, by reducing the radius of curvature of the ingot at the corners there is a maximizing in the production of useful material.
It has been found that rounding off of corners in electromagnetic casting can be made less severe or of smaller radius by contouring the coolant application rate or elevation (or both) in the way taught by the invention so that the rate and/or elevation is a minimum at the corners of the ingot.

Prior Art Statement

Known electromagnetic casting apparatus comprises a three part mold consisting of a water cooled inductor, a non-magnetic screen and a manifold for applying cooling water to the ingot being cast. Such apparatus are exemplified in U.S. Patent No. 3,467,166 to Getselev et al and in U.S. Patent No. 3,605,865 to Getselev. Containment of the molten metal is achieved without direct contact between the molten metal and any component of the mold. Solidification of the molten metal is achieved by direct application of water from the cooling manifold to the forming ingot shell.
In some prior art approaches the inductor is formed as part of the cooling manifold so that the cooling manifold supplies both coolant to solidify the casting and to cool the inductor. See U.S. Patent 4,004,631 to Goodrich et al.
Non-magnetic screens of the prior art are typically utilized to properly shape the magnetic field for containing the molten metal as exemplified in U.S. Patent No. 3,605,865 to Getselev. Another approach with respect to use of non-magnetic screens is exemplified as well in U.S. Patent No. 3,985,179, to Goodrich et al. Goodrich et al. '179 describes the use of a shaped inductor in conjunction with a screen to modify the electromagnetic forming field.
It is generally known that during electromagnetic casting the solidification front between the molten metal and the solidifying ingot at the ingot surface should be maintained within the zone of high magnetic field strength, i.e. the solidification front should be located within the inductor. If the solidification front extends above the inductor, cold folding is likely to occur. On the other hand, if it reaches to below the inductor, a bleed out or decantation of the liquid metal is likely to result. Getselev et al. '166 associate the coolant application manifold with the screen portion of the mold such that they are arranged for simultaneous movement relative to the inductor. In U.S. Patent No. 4,156,451 to Getselev a cooling medium is supplied upon the lateral face of the ingot in several cooling tiers arranged at various levels longitudinally of the ingot. Thus, depending on the pulling velocity of the ingot, the solidification front can be maintained within the inductor by appropriate selection of one of the tiers.
Another approach to improved ingot shape consisted of provision of more uniform fields at conductor bus connections (Canadian Patent No. 930,925 to Getselev).
In electromagnetically casting rectangular or sheet ingots, the ingots are often cast with high radius of curvature ends or corners which is indicative of the need for improved ingot shape control at the corners of such ingots.
U.S. Patent No. 3,502,133 to Carson teaches utilizing a sensor in a continuous or semi-continuous casting mold to sense temperature variations at a particular location in the mold during casting. The sensor controls application of coolant to the mold and forming ingot. Use of such a device overcomes instabilities with respect to how much extra coolant is required at start up of the casting operation and just when or at what rate this excess cooling should be reduced. The ultimate purpose of adjusting the flow of coolant is to maintain the freeze line of the casting at a substantially constant location.
Carson '133 teaches that ingots having a width to thickness ratio on the order of 3 to 1 or more possess an uneven cooling rate during casting when coolant is applied peripherally of the mold in a uniform manner. To overcome this problem, Carson '133 applies coolant to the wide faces of the ingot and/or the mold walls and not at all (or at least at a reduced rate) to the relatively narrow end faces of the ingot and/or the mold walls.
European Patent No. 15,870 relates to electromagnetic casting by using a cooling means having an annular slot between an electromagnetic screen and an insulation body, through which slot the coolant is passed. The slot has the same level, inclination and flow cross-section throughout its entire length. A deflecting body is arranged below the slot. The deflecting body deflects the coolant such that it impinges at the corners of the ingot at a lower level than between the corners. European Patent No. 15,870 has an earlier priority data and an earlier filing date than the present Patent, but the corresponding application has been published after the priority date and the filing date of the present Patent.
In contrast to the technique disclosed in European Patent No. 15,870 the invention teaches the concept to define the place of coolant impingement by the manner in which the discharge ports are provided, without the need for a deflecting body.

Summary of the Invention

Subject matter of the invention are processes for electromagnetic forming of molten metals or alloys into a casting as defined in claim 1 and 2.
A further subject matter of the invention are apparatus for electromagnetic forming of molten metals or alloys into a casting a defined in claims 3, 5 and 6.
A still further subject matter of the invention are coolant manifolds for use in electromagnetic forming of molten metals or alloys into a casting as defined in claims 9, 11 and 12.
Preferred developments of the invention are claimed in dependent claims.
Some features of the invention are also claimed in dependent claims of the European Patent application No. 80 302 291.0 having the same priority date as the present Patent being published as EP-A-0 0022 649 and designating the same States.
The invention relates particularly to electro= magnetic casting of metals and alloys into rectangular or sheet ingots and other desired elements of shape control having small radius of curvature corners or portions by application of controlled static head (through metal head or pressure modification). In particular, the invention utilizes controlled differential static head by control of cooling water application to obtain refinement of ingot shape, particularly at the corners of rectangular ingots or other desired elements of shape.
Control ingot shape may be effected by selection of the rate or location of cooling water application to the forming ingot shell within or below the containment inductor. Rounding off of corners in electromagnetic casting can be made less severe or of smaller radius by contouring the water application rate or elevation (or both) so that the rate of elevation is a minimum at the corners of the ingot. Reduction of the water application rate or lowering the application level serves to reduce the local heat extraction rate along an ingot transverse cross section line of constant height. This in turn lowers the position of the solidification front at the ingot corner and correspondingly raises the metal static head or pressure at the corner. This increased pressure results in the liquid metal approaching the inductor more closely at the corner and thus filling the corner to form a smaller radius of curvature at the corner before the increased static pressure is counterbalanced by an increased electromagnetic force.
In accordance with one embodiment of this invention a water manifold or cooling water application device is provided with drilled holes or slots of a size and/or local hole density which is modified to yield locally reduced rates of water application at the ingot or desired shape corners.
In accordance with another preferred embodiment of this invention a water manifold or cooling water application device is provided wherein the elevation of the supply holes is modified so as to apply water at the lowest elevation at the ingot or desired shape corners.
In accordance with yet another preferred embodiment of this invention the holes or slots in a water manifold or cooling water application device are modified such that the angle of the holes or slots around the corners of the ingot cause the water to impinge on the ingot surface at a lower elevation at the ingot corners.
It is of course understood that hybrids of local hole cross section, hole angle, and hole elevation can also be utilized in accordance with the concepts of this invention.
In accordance with another preferred embodiment of this invention a water manifold or cooling water application device is provided which produces a water application rate of zero over short distances at the corners of the ingot or desired shape to further accentuate the effects of reduced local cooling.
The invention will be explained in more detail by the following description of specific embodiments.

Brief Description of the Drawings

Figure 1 is a schematic cross-sectional representation of a prior art electromagnetic casting apparatus utilizing a slot type coolant manifold for discharging water onto the faces of a forming ingot.
Figure 2 is a schematic cross-sectional representation of an electromagnetic casting apparatus showing an inductor having drilled holes for supplying water to an ingot in accordance with this invention.
Figure 3 is a schematic cross-sectional representation of an electromagnetic casting apparatus showing a modified slot type manifold for supplying water to an ingot in accordance with this invention.
Figure 4 is a schematic cross-sectional representation of an electromagnetic casting apparatus showing another embodiment of a modified slot type manifold for supplying coolant to an ingot in accordance with this invention.
Figure 5 is a partial bottom plan view looking up into the manifold discharge slot of a manifold showing corners possessing different slot modifications in accordance with this invention.

Detailed Description of Preferred Embodiments In all drawing Figures alike parts are designated by alike numerals.
Referring now to FIGURE 1 there is shown therein a prior art electromagnetic casting apparatus in accordance with U.S. Patent 4,158,379.
The electromagnetic casting mold 10 is comprised of an inductor 11 which is water cooled; a coolant manifold 12 for applying cooling water to the peripheral surface 13 of the metal being cast C; and a non-magnetic screen 14. Molten metal is continuously introduced into the mold 10 during a casting run, in the normal manner using a trough 15 and down spout 16 and conventional molten metal head control. The inductor 11 is excited by an alternating current from a suitable power source (not shown).
The alternating current in the inductor 11 produces a magnetic field which interacts with the molten metal head 19 to produce eddy currents therein. These eddy currents in turn interact with the magnetic field and produce forces which apply a magnetic pressure to the molten metal head 19 to contain it so that it solidifies in a desired ingot cross section.
An air gap exists during casting, between the molten metal head 19 and the inductor 11. The molten metal head 19 is formed or molded into the same general shape as the inductor 11 thereby providing the desired ingot cross section. The inductor may have any desired shape including circular or rectangular as required to obtain the desired ingot C cross section.
The purpose of the non-magnetic screen 14 is to fine tune and balance the magnetic pressure with the hydrostatic pressure of the molten metal head 19. The non-magnetic screen 14 comprises a separate element as shown, and is not a part of the manifold 12 for applying the coolant.
Initially, a conventional ram 21 and bottom block 22 is held in the magnetic containment zone of the mold 10 to allow the molten metal to be poured into the mold at the start of the casting run. The ram 21 and bottom block 22 are then uniformly withdrawn at a desired casting rate.
Solidification of the molten metal which is magnetically contained in the mold 10 is achieved by direct application of water from the cooling manifold 12 to the ingot surface 13. The water is shown applied to the ingot surface 13 within the confines of the inductor 11. The water may be applied, however, to the ingot surface 13 from above, within or below the inductor 11 as desired.
The solidification front 25 of the casting comprises the boundary between the molten metal head 19 and the solidified ingot C. The location of the solidification front 25 at the ingot surface 13 results from a balance of the heat input from the superheated liquid metal 19 and the resistance heating from the induced currents in the ingot surface layer, with the longitudinal heat extraction from the cooling water application.
Coolant manifold 12 is arranged above the inductor 11 and includes at least one discharge port 28 at the end of extended portion 30 for directing the coolant against the surface 13 of the ingot or casting. The discharge port 28 can comprise a slot or a plurality of individual orifices for directing the coolant against the surface 13 of the ingot C about the entire periphery of that surface.
Coolant manifold 12 is arranged for movement along vertically extending rails 38 and 39 axially of the ingot C such that extended portion 30 and discharge port28 can be moved between the non-magnetic screen 14 and the inductor 11. Axial adjustment of the discharge port 28 position is provided by means of cranks 40 mounted to screws 41.
The coolant is discharged against the surface of the casting in the direction indicated by arrows 43 to define the place of coolant application.
Figure 2 is a schematic cross-sectional representation of one embodiment of a system for application of a coolant in accordance with this invention. Line 29 divides Figure 2 into two sides (A) and (B). Side (A) shows a section through a face of rectangular ingot 20 and inductor 11' while side (B) shows a section through the corner of the same elements. Coolant, typically water, is supplied to the peripheral surface 13 of ingot 20 via holes 17 in inductor 11'.
Rounding off of corners in electromagnetic casting results from higher electromagnetic pressure at a given distance from the inductor near the corner (where two proximate faces of the single turn inductor generate field) and from excess cooling or higher heat extraction rates at the corners because of geometric and higher heat transfer characteristics. Referring to Figure 2, dotted line 23 exemplifies the location of the solidification front at the corner of an ingot (side (B)) which is cooled by known uniform rate and height peripheral coolant flow directed to the surface 13 of rectangular ingot 20. As can be seen, excess cooling at the corners of the ingot 20 cause the solidification front to rise in comparison to the elevation of the solidification front along the faces of the ingot 20 (side (A)), denoted by dashed line 24. Thus, b, the height of the solidification front from the point of coolant impingement at the corners of the ingot 20 is greater than a, the height of the solidification front from the point of coolant impingement along the faces of the ingot 20. This combination of higher solidification front (lower head) and increased magnetic pressure at the corners causes the pushing of molten metal away from the corners thereby producing a highly undesirable rounding off of the ingot corners.
In accordance with this invention coolant application devices are modified to produce controlled differential static head leading to refinement of ingot shapes at the corners, and in particular to form smaller radius of curvatures at ingot corners.
Control of ingot shape is effected in accordance with the present invention by selection of the rate and/or location of cooling water impingement upon the surface of forming ingot shells. Rounding off of corners in electromagnetic casting can be made less severe or of smaller radius by contouring the water application rate and/or elevation so that the rate and/or elevation is a minimum at the corner of the ingot. Reduction of the water application rate and/or lowering of the application level serves to reduce the local heat extraction rate along an ingot transverse cross section line of constant height. This in turn lowers the position of the solidification front at the ingot corners and correspondingly raises the metal static head or pressure at the corners. This increased pressure results in the liquid metal approaching the inductor more closely at the corners and thereby filling the corner to form a smaller radius of curvature before the increased static pressure is counterbalanced by the increased electromagnetic force.
As can be seen from Figure 2, the elevation of the water impingement at the side (B) (the corner of ingot 20) in accordance with this invention is lower than the elevation at side (A) (along the face of the ingot 20) by virtue of the modification in elevation and angle of holes 17 in inductor 11'. The solidification front 25 forms as a result at a height b above the point of water impingement (point 26) but at a level lower than the point 27 where the solidification front 25 forms along the faces of ingot 20.
As an alternative to alterring the angle and/or elevation of holes 17 in inductor 11' it would be possible to obtain a lowering of the solidification front at the corners of ingot 20 by reducing the diameter of holes 17 and/or by blocking one or more holes locally of the corners thereby partially reducing or reducing to zero the rate of water application at the ingot corners. Of course hybrids of hole size, density, elevation, angle and blockage could be devised to obtain the results desired with respect to cooling rate at the corners in accordance with this invention.

Figure 3 shows a partial schematic cross-sectional representation of the electromagnetic casting apparatus of Figure 1 with a modified coolant manifold 12' in accordance with another embodiment of this invention.
Figure 3 shows extended portion 30 to have a discharge port 28' (Side (B)) naving a modified slot discharge angle causing impingement of coolant water at a lower elevation at the corners of ingot 20. Side (A) shows a standard or unmodified discharge port 28 which impinges water at a higher level along the faces of ingot 20. Solidification front 25 is seen to be at a higher level as designated by point 27 along the faces of the ingot than at or near the corners of ingot 20, designated by point 26.
Figure 4 shows a partial schematic cross-sectional representation of the electromagnetic casting apparatus of Figures 1 and 3 with a modified coolant manifold 12" in accordance with yet another embodiment of this invention.

In Figure 4, extended portion 30 of modified coolant manifold 12" is constructed with discharge port 28 completely blocked off at or near the corners of ingot 20 (Side (B)) by portion 31 of coolant manifold 12". Thus there is zero local cooling in the immediate corners of ingot 20 causing solidification front 2J to drop to the point26 at the corners of ingot 20. Side (A) shows that the solidification front 25 stays at point 27 along the faces of the ingot.
Where slot type coolant manifold such as depicted in Figures 1, and 4 are used, the slot cross section can be accurately contoured to produce a smoothly varying water flow rate with a minimum or zero flow rate at or near the ingot corner positions.
In addition to alterring the angle of slot discharge, it is contemplated to alter the extended portion 30 at the areas of the corners of the ingot 20 to modify the elevation of the slot discharge ports so as to be lowest at the ingot corners. Thus the elevation of the impinging water can be alter- red by alterring the angle and/or the actual elevation of the discharge slots. Again, hybrids of contoured slot cross section, elevation and angle could be devised to carry out the process of this invention.
Figure 5 is a bottom plan view looking up into an extended portion 30 of a manifold and shows corners possessing different slot modifications in accordance with this invention. Extended portion 30 comprises an inner wall 32, an outer wall 34 and a discharge port 28. Corner C shows an unmodified full slot discharge port 28 with a slot width equal to that along the four faces of extended portion 30. Corner D shows a contoured slot discharge port 28 with zero slot width (closed) at the exact corner 62 of extended portion 30. Corner E shows a countoured slot discharge port 28 with zero slot width over about half the corner radius 64 of extended portion 30 and corner F shows zero slot width over about virtually the whole corner radius 66 of extended portion 30.
The aforedescribed variants in coolant applying equipment are typically designed so as to modify the coolant application rate and/or impact point within about three inches on either side of a corner while the maximum extent of the modifications in coolant application is to result in substantial absence of coolant application over about one inch or less of the ingot surface about the corner.
The novel method and apparatus of the present invention find applicability in the electromagnetic casting of any shapes wherein it is desired to form portions thereon of low radius of curvature.
It is apparent that there has been provided with this invention a novel process and means for utilizing controlled differential static head by control of coolant application to obtain refinement of ingot shape during electromagnetic casting which fully satisfy the objects, means and advantages set forth herein before. While the invention has been described in combination with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, it is intended to embrace all such alternatives, modifications and variations as fall within the scope of the appended claims.

Claims

1. A process for electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one first portion of small radius of curvature relative to an adjacent second portion thereof, by pouring the molten metal or alloy (19) downwardly into a shaping electromagnetic force field and applying coolant to the peripheral casting surface (13) through one or more coolant discharge ports (17; 28), characterized in that the coolant is applied at the said first portion of the peripheral casting surface (13) through one or more discharge ports (17; 28) being arranged at a lower level and/or being directed downwardly with a larger inclination and/or being modified to provide (together) a locally smaller coolant application rate than at the said second portion.

2. A process for electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one first portion of small radius of curvature relative to an adjacent second portion thereof, by pouring the molten metal or alloy (19) downwardly into a shaping electromagnetic force field and applying coolant to the peripheral casting surface (13) through one or more coolant discharge ports (17; 18), characterized in that no coolant is applied at the said first portion.

3. An apparatus for electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius of curvature relative to an adjacent second portion thereof,

comprising means (11; 11') for generating an electromagnetic force field which shapes the downwardly poured molten metal or alloy (19), and means (12; 12'; 12") for applying coolant to the peripheral casting surface (13) through one or more coolant discharge ports (17; 28),

characterized in that the means (12; 12'; 12") for applying coolant comprises opposite the said first portion of the peripheral casting surface (13) one or more discharge ports (17; 28) being arranged at a lower level and/or being directed downwardly with a larger inclination and/or being modified to provide (together) a locally smaller coolant application rate than opposite the said second portion.

4. An apparatus as in claim 3, characterized in that the density of discharge ports (17; 28) is smaller opposite the said first portion than opposite the said second portion.

5. An apparatus for electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius or curvature relative to an adjacent second portion thereof,

comprising means (11; 11') for generating an electromagnetic force field which shapes the downward poured molten metal or alloy (19), and means (12; 12'; 12") for applying coolant to the peripheral casting surface (13) through one or more coolant discharge ports (17; 28),

characterized in that the means (12; 12'; 12") for applying coolant has no operating discharge port (17; 28) opposite the said first portion.

6. An apparatus for electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius of curvature relative to an adjacent second portion thereof,

characterized in that, opposite the said first portion, discharge port(s) (17; 28) or a portion of a slot-shaped discharge port (28) is (are) blocked.

7. An apparatus as in any one of claims 3 to 6, characterized in that the means (12; 12'; 12") for applying coolant is unified with the means (11; 11') for generating an electromagnetic force field.

8. An apparatus as in any one of claims 3 to 7, characterized in that the discharge port(s) (17; 28) is (are) provided in a coolant manifold.

9. A coolant manifold for use in electromagnetic forming of molten metal or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius of curvature relative to a second portion thereof, the loop- shaped manifold (12; 12'; 12") comprising one or more coolant discharge ports (17; 28) for applying coolant to the peripheral casting surface (13), characterized in that in at least one corner area of the manifold (12; 12'; 12") associated with the said first portion of the peripheral casting surface (13) the discharge port(s) (17; 28) is (are) arranged at a lower level and/or is (are) directed downwardly with a larger inclination and/or is (are) modified to provide (together) a locally smaller coolant flow cross section than in an adjacent area of the manifold (12; 12'; 12").

10. A coolant manifold as in claim 9, characterized in that the density of discharge ports (17; 28) is smaller in the corner area than in the adjacent area.

11. A coolant manifold for use in electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius of curvature. relative to a second portion thereof, the loop- shapped manifold (12; 12'; 12") comprising one or more coolant discharge ports (17; 28) for applying coolant to the peripheral casting surface (13), characterized in that no operating discharge port (17; 28) is provided in the corner area associated with the said at least one portion for discharge onto said at least one portion.

12. A coolant manifold for use in electromagnetic forming of molten metals or alloys (19) into a casting (20) with a transverse cross section having at the peripheral casting surface (13) at least one portion of small radius of curvature relative to a second portion thereof, the loop- shaped manifold (12; 12'; 12") comprising one or more coolant discharge ports (17; 28) for applying coolant to the peripheral casting surface (13), characterized in that discharge port(s) (17; 28) or a portion of a slot-shaped discharge port (28) is (are) blocked in the corner area.