PL26475B1 - Induction furnace. - Google Patents

Description

There are known furnaces in which the cylindrical coil surrounding the melting point of the crucible shape has a spiral extension under the bottom of the brickwork in order to ensure that the crucible is as completely covered with the coil turns. Systems with disc coils above the cover and below the bottom are also known, as well as on the sides of the side walls of the square brickwork. It is also known for a long time in the construction of furnaces to use several layers of winding in both disc and cylindrical coils. In the above-mentioned devices, all the coils were supplied with the current of the same frequency. Finally, it was proposed to lay between the shell-shaped induction furnaces, equipped with centrally and symmetrically arranged disc coils and possibly powered by a medium or low frequency current, in a spiral to the top of the no-current cooling tube bundle. These types of furnaces, operating at a low frequency, are distinguished by a very vigorous circulation of the molten metal, which is often excessive. In order to prevent excessive circulation of liquid metal, or to better regulate the circulation, which at the same time at least in certain periods of motion it should be replaced entirely by a single, quieter eddy motion, it can be done in such a way that some parts of the winding are electrically insulated from each other, energizing them with currents of various frequencies where the greatest possible vortices are desired, the major part of the energy must be fed at a low frequency and a smaller part at a higher frequency. In periods when it is desirable to circulate calmly in the bath, it is necessary to do the opposite. It turned out that the independent coils had an inductive effect on each other, which had a detrimental effect. The harmful interaction of the coils, supplied with currents of different frequencies, could be removed by properly arranging these coils, namely the winding elements currents of different frequencies, create spatial angles between each other, the size of which is approximately 90 °. It turned out that it was more likely to energize the internal coil with a higher frequency current than the external one, and at the same time, the magnetic axes so that the axis of the coil fed with a higher frequency current is perpendicular to the mirror of molten metal, and the axis of the coils fed with a low frequency current (one or more) has a large component in the horizontal direction. As the elements of the coils are cut almost the entire length of the winding approximately perpendicularly, there is no harmful mutual induction in these new coils. However, care must be taken that those parts of the outer coils (most conveniently arranged symmetrically about the vertical axis of the system) which extend horizontally and are therefore parallel to the turns of the inner coil are as short as possible. When making the outer coil, care must be taken that the upper, usually horizontally extending parts of the coils are as short as possible. It is also convenient to divide the inner coil into a number of parallel, electrically insulated branches. ; the new arrangement of the coils achieves the hitherto unattainable subtlety of regulating the mixing of the liquid metal, uniform across the entire surface, while weighing the high frequency. The new system also makes it possible to adjust the depth of penetration of the working magnetic field in any way. The figure shows an example of the invention in a vertical projection. frequency and is made most conveniently hollow inside the spiral which flows the coolant. Outside this coil 2 are positioned coils 4 with axis 5 approximately perpendicular to the plane of the paper. A number of these coils 4 are disposed symmetrically around the periphery of the wall. However, they are not shown in the drawing, so as not to lose its clarity; a current of lower frequency flows with them according to the conditions of motion. The number of coils with a horizontal magnetic axis can be three or a multiple of three, then these coils can be connected to the three phases of a three-phase current. The latter arrangement also eliminates the influence of those parts of the coils that run horizontally (evenly). ¬ legle to the plane of the winding of the second coil), because the total induction of three phases on the horizontal winding of the second coil is zero in total. PL

Claims (6)

Patent claims. 1. An induction furnace, characterized in that it has two primary winding systems - 2 - (2, 4), the magnetic axes (3, 5) of which cross in space and that both of these systems are supplied with currents of different frequencies, the energy ratio supplied to them varies. 2. The induction furnace according to claim According to claim 1, characterized in that the magnetic axes (3, 5) of the coils are approximately perpendicular to each other, 3. Induction furnace as per preset. A method according to claim 1, 2, characterized in that the axis (3) of the inner winding system (2), fed by a higher frequency current, is perpendicular to the surface of the molten metal, while the axes (15) of the outer disc coils (4), fed with a lower current frequencies are substantially parallel to this surface. 4. Induction furnace as per preset. A method according to any one of claims 1 to 3, characterized in that in the triangular-shaped disc outer tubules (4), the top horizontally extending parts of the coils are as short as possible. 5. Induction furnace according to claim 1 - 4, characterized in that its internal coil is divided into several electrically parallel, insulated branches. 6. An induction furnace according to claims 1-5, characterized in that the number of the disc coils is a thesis or a multiple of three and that the coils or groups of coils are connected to the phases of a three-phase current. Heraeus Vacuum s chmelze Aktiengesellschaft. Deputy: Inz. S. Glowacki, patent attorney. s? Printing by L. Boguslawski and Ski, Warsaw. PL