The present invention concerns improvements in and relating to electromagnetic stirring of molten metals, particularly apparatus for stirring and methods of stirring.
It is known to use electromagnets to generate moving magnetic fields within molten metal and as a consequence generate motion within the molten metal. The movement causes stirring of the molten metal within its container, with beneficial effects on heat transfer, material dispersion and the like.
In general, planar electromagnetic stirrers are deployed close to a planar wall of the container in which the molten metal is to be stirrer.
Whilst planar walls for containers are commonplace, there are situations in which such planar walls are not present or are not readily accessible for deployment of an electromagnetic stirrer.
The present invention has amongst its potential aims to provide apparatus for stirring and methods of stirring which are more optimised for deployment relative to non-planar walls of containers, particularly larger containers. The present invention has amongst its potential aims to provide apparatus for stirring and methods of stirring which provide better stirring effects within rotary furnaces or other containers with a curved profile to one or more walls of the container. The present invention has amongst its potential aims to provide apparatus for stirring and methods of stirring which provides a stronger magnetic field and/or optimised magnetic field configuration within molten metal.
According to a first aspect of the invention there is provided apparatus for stirring a molten metal, the apparatus comprising:
an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils;
connections for applying a current to the electrically conducting coils;
wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth.
According to a second aspect of the invention there is provided a method of manufacturing apparatus for stirring a molten metal, the method comprising:
measurement of the non-planar characteristics of the wall for the container for the molten metal at the location at which stirring is to be provided;
providing an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils;
providing connections for applying a current to the electrically conducting coils;
wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face, the tooth end face for at least one of the teeth not being aligned with the tooth end face for at least one of the other teeth; and wherein the extent of non-alignment of the tooth end faces is determined from the measurement of the non-planar characteristics of the wall.
According to a third aspect of the invention there is provided a method of stirring molten metal within a container, the method including:
providing an electromagnetic stirrer, the electromagnetic stirrer including a core, the core being provided with two or more teeth, the core being provided with two or more electrically conducting coils;
applying a current to at least one of the electrically conducting coils at a first time to generate a first magnetic field configuration;
applying a current to at least one of the other electrically conducting coils at a second time to generate a second magnetic field configuration, such that the changes in magnetic field configuration cause movement of the molten metal within the container;
wherein the two or more teeth have an end proximal the core and an end distal the core, the end distal the core defining a tooth end face with a tooth edge around that tooth end face, a tooth end face plane being defined as the plane passing through three points on the tooth edge of the tooth end face, the tooth end face plane for at least one of the teeth not being aligned with the tooth end face plane for at least one of the other teeth.
The first, second and third aspects of the invention may include any of the following features, options and possibilities.
The core may include a base connector upon which one or more or all of the teeth are provided. The core may include a base connector which connects one or more of the teeth together. The core may provide a magnetic circuit between one tooth and one or more other teeth. The base connector may have a face from which the one or more teeth extend. The base connector may have a face opposing the face from which the teeth extend. One or both faces may be planar.
The tooth end face for at least one of the teeth may be considered not aligned with the tooth end face for at least one of the other teeth when one or more or all of the following apply:
One or more or each of the tooth end faces may have a tooth edge around that tooth end face. The tooth edge may be defined by the boundary between the tooth end face and the side surface or surfaces of the tooth. A tooth end face plane may be defined for one or more of the tooth end faces. The tooth end plane may be defined as a plane passing through three points on the tooth edge of the tooth end face.
The tooth end face for at least one of the teeth may be considered not aligned with the tooth end face for at least one of the other teeth when the tooth end face plane for at least one of the teeth is not aligned with the tooth end face place for at least one of the other teeth. The tooth end faces may be considered not to be aligned when one or more or all of the following apply:
One or more or all of the teeth may extend perpendicular to the base connection. Each tooth may have an extent away from the base connection. One or more of the teeth may have a greater extent that one or more of the other teeth. The tooth end face or a part thereof may represent the maximum extent of the tooth away from the base connection.
The outermost tooth on one side of the set of teeth, preferably the outermost tooth on both sides of the set of teeth, may be have a greater extent and/or be longer than one or more and preferably all of the other teeth. Preferably the extent and/or length of the outermost teeth is the same. The inner most tooth for an odd number of teeth and the innermost pair of teeth for an even number of teeth may have a lesser extent and/or be shorter than one or more or preferably all of the other teeth.
Teeth intermediate the outermost and the innermost teeth or pair of teeth may have an intermediate extent and/or length.
Where four teeth are provided, then outermost tooth on both sides of the set of teeth may have a greater extent and/or be longer than one or both inner teeth. Preferably the extent and/or length of the outermost teeth is the same. The inner pair of teeth may have a lesser extent and/or be shorter than one or both outer teeth. Preferably the extent and/or length of the innermost pair of teeth is the same.
Where three teeth are provided, then outermost tooth on both sides of the set of teeth may have a greater extent and/or be longer than innermost tooth. Preferably the extent and/or length of the outermost teeth is the same. The innermost tooth may have a lesser extent and/or be shorter than one or both outer teeth.
Where two teeth are provided preferably the outermost portion of the tooth end face has a greater extent and/or is longer than one or more and preferably all of the other portions of the tooth end face, particularly the innermost portion of the tooth end face. The innermost portion of the tooth end face may have a lesser extent and/or be shorter than one or more or preferably all of the other portions of the tooth end face.
One or more or all of the tooth end faces may be provided such that the air gap between the end face and the outer wall of the opposing part of the container for the molten metal is less than 10 cm, preferably less than 5 cm, more preferably less than 4 cm, still more preferably less than 3 cm, yet more preferably less than 2 cm and ideally less than 1 cm. One or more of the tooth end faces may be inclined and/or orientated and/or profiled so as to provide all of the tooth end face within a maximum air gap value. The maximum air gap value may be less than 10 cm, preferably less than 5 cm, more preferably less than 4 cm, still more preferably less than 3 cm, yet more preferably less than 2 cm and ideally less than 1 cm.
One or more or all of the tooth end faces may be aligned with the opposing part of the container for the molten metal. A tooth end face may be so aligned when one or more or all of the following apply:
The opposing part of the container may preferably be a metal plate, such as a stainless steel plate.
The opposing part of the container may be a side wall for the container, for instance with the apparatus to the side of the container.
The opposing part of the container may be a base of the container, for instance with the apparatus under the container.
The casing for the apparatus may pass through the air gap between the tooth end faces and the opposing part of the container.
The casing for the apparatus may be a metal skin or barrier to protect the apparatus from factors in the environment such as molten metal or metal.
The casing may include a container opposition section. The container opposing section of the casing may pass through the air gap between the tooth end faces and the opposing part of the container. The container opposing section may be profiled to provide a consistent separation between the section and the opposing part of the container. The consistent separation may be provided if the separation varies by less than 2 cm, more preferably less than cm across different parts of the container opposing section. The container opposing section may be profiled to provide a consistent maximum separation between the section and the closest part of the tooth end faces. The consistent separation may be provided if the separation varies by less than 2 cm, more preferably less than 1 cm, ideally less than 0.5 cm across different parts of the container opposing section.
The apparatus may have an extent relative to the container, particularly an opposing part of the container. The extent may be an arc extent. The extent may be less than 20% of the perimeter of the container, preferably less than 15% of the perimeter and more preferably less than 10% of the perimeter and potentially less than 5% of the perimeter.
The measurement of the non-planar characteristics of the wall for the container for the molten metal at the location at which stirring is to be provided may be made with reference to the opposing part of the container to the apparatus and/or may include one or more of: the curvature of the wall; the variation in radial extent of the wall; the shape of the profile, for instance arc, within that part of the wall.
The first, second and third aspects of the invention may include any of the following features, options and possibilities, together with those set out in the specific description and elsewhere within the application.
The method of stirring may be a method of stirring molten metal. The method of stirring may be a method of stirring aluminium.
The method of stirring may be a method of stirring a furnace. The method of stirring may be a method of stirring a ladle, storage vessel, transport vessel, holding furnace.
The method of stirring may be a method of stirring using a side mounted stirrer.
A apparatus may further include one or more of: a casing for the apparatus; a support frame; one or more cooling spaces; a control system. The support frame may support the core and/or one or more or all of the coils of electrical conductor and/or the control system.
The support frame may support the core and/or teeth and/or electrically conducting coils and/or casing for the apparatus and/or cooling system and/or control system. The support frame preferably maintains a consistent position for the support the core and/or teeth and/or electrically conducting coils and/or casing for the apparatus during the application of and removal of current to one or more or all of the electrically conducting coils.
The one or more cooling spaces may be provided within the apparatus and be in fluid communication with a source of coolant.
The control system may control the current and/or voltage and/or timing thereof and/or duration thereof for one or more and preferably all of the electrically conductive coils. The control system may control the phases and/or phasing of activation and/or deactivation of the magnetic field and/or current to the electrically conductive coils. The control system may apply a current to at least one of the electrically conducting coils at a first time to generate a first magnetic field configuration and/or applying a current to at least one of the other electrically conducting coils at a second time to generate a second magnetic field configuration, such that the changes in magnetic field configuration cause movement of the molten metal within the container.
The core is preferably formed of a ferromagnetic material, such as iron or steel. The core preferably integrally provides the connection base and the teeth extending therefrom.
The connections preferably provide for the separate application of current to the separate electrically conducting coils. The connections preferably allow a single power supply to provide the current to the separate electrically conducting coils.
Various embodiments of the invention will not be described, with reference to the accompanying drawings by way of example only, in which:
As illustrated in
The core 7 is generally of a ferromagnetic or ferromagnetic material, such as iron, and is crucial to concentrating the magnetic flux and hence the generation of a more powerful magnetic field than would be achieved without the core 7. Typically a thousand time increase in the strength of the magnetic field is possible through the use of the core 7.
The magnetic field arises which a current passes through the conductor 3 and disappears when the current is removed. This occurs quickly and so makes the use of electromagnets beneficial where a changing magnetic field is required.
As shown in
In the
In effect, the core 7 and the molten metal 21 form a magnetic circuit with relatively low reluctance. The air gap AG has a higher reluctance but is kept small by the relative deployment of the electromagnetic stirrer 1 and the container 23.
As shown, the electromagnetic stirrer 1 is provided in proximity with a planar wall 31 of the container 23. The casing 33 provided around the electromagnetic stirrer 1 has a planar wall 35 facing the planar wall 33 of the container 23. The end faces 37a, 37b and 37c of the three poles are also aligned in a common plane (extending left to right in the illustration) and the connecting base 25 of the core 7 also means that the connecting base 25 and the ends 35a, 35b and 35c of the three poles distal to the planar wall 35 also occupy a separate common plane (extending left to right in the illustration).
In very many cases, the container 23 in which molten metal 21 is to be stirred features a planar wall 31, for instance as a side wall or a base wall, for the container 23 and so the planar wall 35 of the casing 33 can be placed close to the planar wall 31 of the container. This means that the total air gap AG is kept low.
As illustrated in
As shown in
In the embodiment of the invention illustrated in
The profile of the casing 133 is modified to be generally concentric with the perimeter wall 131a of the container 123. As a consequence, the air gap AG1 between the outside of the perimeter wall 131a and the outside of the casing 133 is kept similar and low for all three poles.
As seen in the detailed view of
As shown in
Other non-planar arrangements for the combination of the end faces 137a, 137b, 137c of the first tooth 105, second tooth 113 and third tooth 117 are possible.
As shown in
As shown in
Whilst the modification to the casing and to the poles is shown with reference to a three tooth electromagnetic stirrer, the same principles can be applied to a two stirrer or a stirrer with more than three poles.
In the above illustrations, the invention has been shown with reference to a curved container wall, however, other non-planar container walls can be accommodated by the principle of the invention.
When considering the alignment of the end faces relative to each other and/or the connecting base at its plane, it can be beneficial to consider that alignment in the context of a tooth end face plane. The tooth end face plane can be established by the approach shown in
Number | Date | Country | Kind |
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1620024.8 | Nov 2016 | GB | national |
This application is a continuation of U.S. application Ser. No. 16/462,026, filed May 17, 2019, which is a national phase under 35 U.S.C. § 371 of International Application No. PCT/GB2017/053565, filed Nov. 27, 2017, which claims the benefit of priority to United Kingdom Patent Application No. 1620024.8, filed Nov. 26, 2016, the entire contents of each of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | 16462026 | May 2019 | US |
Child | 17935845 | US |