FR2518436A1 - Electromagnetic forming of molten metal - by opposed alternating currents in parallel conductors - Google Patents

Abstract

A moving stream of molten metal, e.g. steel, Al, Cu, etc., is formed, close to its eventual finished shape, by an alternating magnetic field, This sets up induced currents in the periphery of the metal, producing compressive centripetal forces. The field is produced by pairs of lengthwise conductors, set approximately parallel around the stream. Each one of a pair carries alternating currents opposed in phase. The axis of symmetry of the field coincides with the axis of rotation of the stream. The frequency of the a.c. is such that the thickness of the periphery is much less than the radius of the stream. Getting close to the finished shape in the molten state saves effort and energy by comparison with conventional forming of a cast billet etc.

Description

"Method and device, of electromagnetic type, for
metal forming "
The present invention relates to the forming of metals. It relates more particularly, but not exclusively, the forming of ingots or metal billets of specific sections.

 In the conventional metal forming technique, the molten metal is cast in a mold to form, after cooling, a solid ingot which is then brought to its final form of smaller section billet by repeated passages in a succession of rolling mills, of progressively decreasing passage sections, the metal part being generally reheated one or more times between certain passages. Such a succession of passes through rolling mills involves a considerable expenditure of mechanical and thermal energy and expensive equipment.

 The invention aims to considerably reduce the expenditure of energy and material by making it possible to give the liquid metal a form as close as possible to the desired final shape, for example the shape of a billet of desired section. Indeed the forces required to deform a mass of liquid metal are significantly lower than those required to deform a solid state metal, more or less pasty, hence reduction of mechanical energy expenditure, and it is not It is no longer necessary to carry out reheating, hence the abolition of thermal energy expenditure. Once the metal has been brought to a first form (close to the final shape to be imparted to it) by the very economical process according to the present invention, the will bring to its final form in the conventional manner, but it will then be to subject the solid metal a very small deformation that will not require a lot of mechanical energy and possibly thermal.

 Finally, the liquid metal is given a first form as close as possible to the final form, it is frozen by cooling in this first form and is brought, in the solid state, to the definitive form, for example by a number very few passes in one or more rolling mills.

 The method according to the invention for forming the metals consists in applying, to a moving liquid metal mass, an alternating magnetic field capable of creating, at the periphery of said metal mass, induced currents which generate in this mass of forces centripetal tending to compress it.

 The device for carrying out this method comprises in combination, on the one hand, an inductor comprising at least two elongated substantially parallel conductors and electrical means for passing alternating currents through the conductors and, alternatively, secondly, means for circulating inside the inductor, between the conductors thereof, the liquid metal mass to be conformed.

 Preferably the inductor comprises at least one pair of substantially parallel elongated conductors, said electrical means passing opposing instantaneous alternating direction currents through the conductors of the same pair.

We know that we are showing forces! in a metal field when subjecting it to an alternating magnetic field. Indeed any electroconductive field, placed in the vicinity of a conductor traversed by an alternating current I, is subject to variations in flux produced by the pulsating magnetic field, induction B, generated by the driver; to combat these variations in flux, the metal reacts by creating its own induced currents J, in opposition to the current in the inductor; these currents are situated at the periphery of the metal domain in a skin of thickness d, which is thinner as the electrical conductivity of the medium is greater or the frequency of the inductor currents is higher. (oF)
The direction of these currents J, perpendicular in every respect to that of the magnetic field which gives them birth, is optimal for generating Laplace's force.
F = J, B, always directed towards the inside of the metal domain. There is therefore a repulsive force between the inductor and the metal domain. The exploitation of this force makes it possible to impose a given shape on a liquid metal medium, without any contact between the metal and a wall or an electrode.

The invention will be better understood in the light of a number of explanations and several nonlimiting embodiments described below with reference to the accompanying drawings in which:
FIG. 1 illustrates the creation of centripetal forces in the frame of the invention, in a metal mass by means of a conductor traversed by an alternating current;
- Figure 2 shows the deformation of a liquid metal vein, in the context of the invention, by means of two pairs of conductors traversed by alternating currents;
FIGS. 3 to 7 illustrate various forms that can be imposed on a liquid metal vein by the process according to the invention;
- Figure 8 shows in perspective an inductor according to the invention for forming the metal;
FIGS. 9 and 10 are sections through IX-IX and
XX respectively, of Figure 8;
FIG. 11 represents a screen for the inductor of FIG. 8;
- Figure 12 is a section through XII-XII of Figure 11;
FIG. 13, finally, represents two screens, according to FIGS. 11 and 12, mounted on the inductor of FIG.

Figure 1 shows schematically a conductor 1 traversed by an alternating current of instantaneous intensity t and thus creating an induction ss around him. The metal domain is illustrated in 2; its "skin" 2a of thickness d is the domain of induced currents J and thus of Laplace F forces directed inwards (centripetal forces): F = J Bx
These preliminary explanations having been provided with reference to FIG. 1, reference will now be made to FIG. 2 to explain how the centripetal forces such as F of FIG. 1 make it possible to form a liquid metal flow.

en appelant la perméabilité magnétique du milieu métal- lique de la veine 3 et a sa-conductivité électrique. En effet les forces utiles au formage qu'il faut induire dans le métal liquide sont des forces de pression qui doivent etre normales à l'interface 3b séparant le milieu métallique de l'atmosphere ambiante, condition qui est d'autant mieux réalisée que l'épaisseur de peau d est plus faible.Or, by way of non-limiting example, a free vein 3 of liquid metal, initially circular, flowing vertically perpendicular to the plane of FIG. 2, and of revolution about the axis 4 of the assembly. Four parallel elongate conductors 5a, 5b, 5c, 5d are arranged along the edges of a right square base prism. The AC power supply of these conductors is realized in such a way that at each moment the directions of the current are opposite in two adjacent conductors (such as b'a, bb or 5b, 5c). AC power supply of the electrical conductors 5a, 5b, 5c, 5d must be such that the thickness d of the skin-3a is small in front of the radius
R of vein 3 of metal before it has undergone electromagnetic effects
d / R <<1, with

calling the magnetic permeability of the metal medium of vein 3 and its electrical conductivity. Indeed, the forces useful for forming which must be induced in the liquid metal are pressure forces which must be normal at the interface 3b separating the metallic medium from the ambient atmosphere, a condition which is all the better achieved by the fact that the d skin thickness is lower.

 In the near vicinity of the conductors 5a, 5b, 5c, 5d, the repulsion force F is very intense because of the high intensity of the induction magnetic field B and induced currents J, which result therein in these registers On the other hand, in the regions situated at equal distances, successive pairs of conductors 5a-5b, 5b-5c, 5c-5d, 5d-5e, traversed by instantaneous currents of opposite directions (as can be seen in FIG. 2), for the magnetic field B and the associated induced currents J are weak, just as the repulsion force which they create. Thus the vein 3 of liquid metal has a tendency to move away from the conductors and to extend along the median planes 6 between these pairs of conductors. The equilibrium shape of the vein resulting from the distribution of forces F, non-uniform along the circular free surface, is therefore close to that of a four-pointed star, with rounded edges, referenced 7, resulting from a balance between the magnetic pressure (force j and the surface tension in each point along the periphery of vein 3.

 FIG. 3 illustrates in solid lines, in interrupted lines and in broken lines three shapes 8, 9 and 10, respectively, which can be presented on the periphery of a liquid metallic vein, originally circular in shape around the 4 and running perpendicular to the plane of Figure 3, when subjected to an alternating magnetic field produced by the AC current passage in parallel elongated conductors 11a, 11b, lic, 11d, also arranged perpendicular to the plane of Figure 3, the direction of instantaneous currents being opposite in two adjacent conductors, as in the case of Figure 2 (the current directions are shown in the usual manner in Figures 2 and 3).

The greater the intensity of the alternating current is increased in the conductors 11a, 11b, 11c, 11d, the more the equilibrium form of the vein deviates from the circular form, that is to say the more the ratio, between the largest dimension (along the YY, Y'Y 'axes) and the smallest dimension (along the axis ZZ and Z'Z' bisectors)
XX and YY) deviates from unity.

 The alternation of the instantaneous senses of the current in the conductors 11a to 11d makes it possible to reveal very large magnetic field gradients outside the liquid metal casing and subjects the formed metal vein to restoring forces. which ensure the perfect stability of the equilibrium form obtained. This stability ensures the constancy in time and space of the shape and the area of the cross-section of the metal vein 8, 9, 10.

 A theoretical analysis makes it possible to predict the equilibrium shape of the metal domain for an intensity of the alternating current in the conductors 11a, 11b, 11b, 11d.

 Tests with mercury confirmed the calculated values.

 FIGS. 4 to 7 show, in section, different forms 12, 13, 14, 15 of liquid vein obtained from a circular vein, by means of pairs of conductors (referenced all 16 in these figures), traversed by alternating currents of opposite instantaneous senses.

 It can thus be seen that, by means of pairs of conductors traversed by opposite instantaneous alternating directions of direction, it is possible to form a liquid metal vein, of circular initial section, into a metal vein having a desired section (such sections are illustrated at 7, 8, 9, 10, 12, 13, 14 and 15 in FIGS. 2-7).

 With reference to FIGS. 8 to 13, an embodiment, given in a non-limiting manner, of the structure of an inductor (set of pairs of conductors) suitable for carrying out the method according to the invention will now be described. which has been discussed with reference to Figures 2 to 7.

 Considering firstly Figures 8 to 10, we see that the inductor itself comprises four conductors 17a, 17b, 17c. and 17d. These conductors consist of electrically connected square section copper tubes. In order to eliminate the heat generated by the passage of the current in these tubes 17a to 17d, a coolant is circulated inside these pipes via a tubing 18, also of square section, which is connected by tubings 18a and 18b, also of square section, at the top of the tubes 17a and 17d by arcuate tubular sections 19a and 19d, also of square section.The cooling fluid exits through the pipes 19b and 19c connected to the upper ends of the tubes of square section 17b and 17c respectively by arcuate tubular sections 21a and 21b respectively, the pipes 21a and 21b connecting the lower ends of the hollow conductors 17a-17b and 17c-17d respectively to ensure the continuity of the circulation of the cooling fluid.

 A slight downward taper is preferably given to the figure formed by the four tubular conductors 17a, 17b, 17c and 17d, as can be seen by comparing the central portions of FIGS. 9 and 10, the distance a between two opposing conductors. at the level of the IX-IX section being greater than the distance b between two opposite conductors at the level of the section XX of FIG. 8, in order to compensate for the decrease in section of the liquid metal vein in its vertical descent under the effect acceleration by gravity.

 Electrical connections (not shown) make it possible to bring the electric current.

 An inductor as shown in FIGS. 8 to 10 makes it possible to obtain profile blanks having a four-star shaped section of the type shown in FIGS. 2 and 3.

 To obtain metal sections whose cross section is constant in the vertical direction of the casting, it is necessary to eliminate any disturbance of electromagnetic origin which tends to appear in particular at the entrance of the inductor. The magnetic field to be produced must be purely two-dimensional, shaped, which is disturbed by the presence of the electrical connections connecting two adjacent conductors as well as the conductors to the AC supply circuit.

 To eliminate these harmful parasitic effects, magnetic screens illustrated in FIGS. 11 to 13 are provided to cancel the magnetic field resulting from the presence of the electrical connections.

 FIG. 13 shows two screens, namely an upper screen 22a and a lower screen 22b made of copper plates whose thickness is greater than 11 skin thickness in the copper at the frequency f chosen to obtain the forming . The skin thickness is determined by the prior formula 1, but this time denoted by the letters v and a respectively the magnetic permeability and the electrical conductivity of the copper. The copper plates are also hollow, as seen in section in Figure 12, so as to eliminate the calories produced in their mass Joule effect, by circulating a cooling fluid.

 The lower plate 22b has at its center a rectangular opening 23 to allow the passage of the connection of the arcuate tubular sections 19a, 19b, 19c-19d with the tubes liat 17b, 17c, 17d; des-rbndelles rubber 24 separate the part upper section of the aforementioned sections 22a and 22b. The upper plate 22a also has a type 23 opening to allow passage of the liquid vein within the inductor, but for this upper plate, a circular section can be advantageously provided for the passage opening. . The holes 25 serve to pass the fastening screws of the plates 22a, 22b and washers 24.

 Because of induction phenomena whose screens are the seat of electric currents flowing through the connections, induced currents appear which are in opposition to the currents in the connections. As a result, at the top of the inductor, the magnetic field is zero and the parasitic effect of the connections is annihilated. Such screens can also be used at the lower end of the inductor.

 In one embodiment used to carry out laboratory experiments on a mercury vein initially of circular section which was brought to a shape of the type illustrated in FIG. 2, an inductor according to FIGS. 8 to 13 consisting of Copper tubes of rectangular section (4 mm x 8 mm with a thickness of 1 mm) run through with water to eliminate the calories produced by Joule effect. The conductors are placed radially around the axis of the metal vein. Two diametrically opposed conductors are separated by 10 mm. The length of the inductor is 200 mm. The notches consist of two copper plates, placed on either side of the connections, 50 mm x 50 mm and 1.5 mm thick. The intensity of the electric current in the conductors can reach 2500 A for a voltage of the order of 600 V. The frequency f used is i75 KHz, which corresponds to a skin depth of 1.2 mm. The casting speed of the metal vein formed is 1 m / s. The aspect ratio between the largest and the smallest dimension of the profile blank can reach 6 under the conditions defined above.

 Finally, with an inductor of the type illustrated in FIGS. 8 to 13, it is possible to produce a profile in the liquid state, having a section of the type illustrated in FIGS. 2, 3 or 4. With inductors comprising more than two pairs of conductors, it is possible to produce profiles according to FIGS. 5, 6 or 7.

 The inductor construction rules, deduced from theoretical and experimental considerations, are the following: to obtain a plane free surface it suffices to create a uniform repulsion force by placing several parallel conductors traversed by currents of the same direction; to show an outgrowth (profiled wing, for example) it suffices to place two series of parallel conductors in the neighborhood of the initial free surface traversed by currents of opposite directions: the plane of symmetry of these two rows of conductors is an area where the weak repulsion force allows the liquid to expand.

 In the case where the initial casting geometry of the metal vein is very far from the desired shape, a preforming transition zone may be provided immediately upstream of the forming inductor proper. In this zone the conductors providing the forming are used but they flare out in order to surround the metal vein to be formed. The transition between the starting geometry and the final geometry is therefore ensured.

 Once a profile blank obtained by the method and the device according to the invention, it is sufficient to let the metal settle by cooling, then; by means of one or more passages in conventional rolling mills, bring the profile to the desired final shape.

Since most of the deformation has been carried out in the liquid state, the energy required by the total deformation to obtain the definitive shape is considerably reduced, which is the essential advantage of the invention. .

 The invention applies to the forming of different metals such as steel, aluminum, copper and their alloys, without this enumeration being limiting.

 It goes without saying and as it follows already from the foregoing, the invention is in no way limited to those of its modes of application and of realization which have been more especially envisaged; it embraces, on the contrary, all variants.

Claims (12)

 1. A method for forming metals, characterized in that it consists in applying, to a moving liquid metal mass, an alternating magnetic field capable of creating, at the periphery of said metal mass, induced currents which extend into this mass of centripetal forces tending to compress it.  2. Method according to claim 1, characterized in that the alternating magnetic field is generated by at least two elongated substantially parallel electrical conductors traversed by alternating currents.  3. Method according to claim 2, characterized in that the magnetic field is generated by at least one pair of substantially parallel elongated conductors, the two conductors of each pair being traversed by alternating currents having opposite instantaneous directions.  4. Method according to claim 1, 2 or 3, wherein the liquid metal mass in motion has the shape of a cylinder of circular section and therefore has an axis of revolution, characterized in that the configuration of the magnetic field, which determines the shape imposed on the liquid metal mass, has an axis of symmetry coincident with the axis of revolution of the moving metal mass.  5. Apparatus for forming metals by the implementation of the method according to all of claims 1 and 2, characterized in that it comprises in combination, on the one hand, an inductor having at least two elongated conductors substantially parallel and. electrical means for passing alternating currents through the conductors and, secondly, means for circulating the liquid metal mass to be circulated inside the inductor between the conductors thereof; .  6. Device according to claim 5 for carrying out the method according to claim 3, characterized in that the inductor comprises at least one pair of substantially parallel elongated conductors, said electrical means passing instantaneous alternating currents of direction. opposites through the drivers of the same pair.  7. Device according to claim 6, wherein the moving liquid metal mass has the shape of a cylinder of circular section and therefore has an axis of revolution, characterized in that the inductor has an axis of symmetry around which are the pairs of conductors, this axis of symmetry coinciding with the axis of revolution of the moving metallic mass.  8. Device according to any one of claims 5 to 7, characterized in that the frequency of the alternating currents is such that the ratio d / R is much smaller than 1, by calling R the mean radius of the metal mass moving liquid and penetrating skin thickness of the currents induced in this mass, d being determined by the formula,

 wherein 1 is the magnetic permeability of the moving metallic medium, has the electrical conductivity of this metallic medium and f said frequency.  9. Device according to any one of claims 6 to 8, characterized in that the inductor consists essentially of two pairs of elongated substantially vertical conductors whose overall figure has a slight taper towards the bottom, mass metal moving up and down between the two pairs of conductors.  10. Device - according to any one of claims 5-9, characterized in that the conductors are hollow tubes through which is circulated a cooling fluid.  11. Device according to any one of claims 5 to 10, characterized in that the inductor has at its input portion, for the liquid metal mesh in motion, at least one screen to eliminate the parasitic effects of electrical connections. .  12. Device according to claim 11, characterized in that the screens are made by copper plates whose thickness is greater than the skin thickness d in the copper at the frequency of the alternating current, given by the formula

 wherein is the magnetic permeability of copper, the electrical conductivity of copper and the frequency.