DE853627C - Melting process for ferrous and non-ferrous metals and induction melting furnace for practicing the process - Google Patents

Description

Melting process for ferrous and non-ferrous metals and induction melting furnace to carry out the process The previously known induction melting process has the disadvantage that they only allow intermittent operation. the channel ovens used for this purpose must be cleaned from time to time while the inductively heated crucible furnaces are switched off and emptied anyway after each batch and need to be cleaned. In addition, there is the one carried out in a channel furnace The method still has the further disadvantage that during breaks in operation not Insignificant amounts of energy have to be expended to warm the melt channel to keep.

In contrast to the previous methods, it is with the invention to a new, particularly advantageous method, which enables the implementation of a enables continuous operation and thus considerable economic advantages brings with it. The melting process according to the invention is that the in a continuously fed shaft, the lower part of which is inductive is heated, molten metal one to increase the light liquid in addition heated holding or overheating zone and from this continuously or is withdrawn periodically. The oven used to carry out the procedure is through a bridge is divided into a melting zone and a holding zone or superheating zone. Both zones are controlled by one or more coil systems of induction heating enclosed.

The way the procedure works is as follows: A The shaft above the melting zone and its melting zone surrounded by the coil system will continuously charged with the use. That which is expediently melted on a bridge Metal collects in a warming zone. The melt is tapped through a tap hole, which can be made as desired, i.e. also on the side of the bottom of the warming part or can be arranged at a suitable height as an overflow.

The furnace itself consists of a shaft i with a melting zone 2, which are separated by a bridge 3 against a warning or overheating zone 4 is. The liquid metal can be removed from this through tap openings 5. The two heating zones 2 and 4 are surrounded by masonry 6, which in turn is encased by a slotted sheet metal jacket made of non-magnetic material. He can be used to hold thermal insulation material and / or for cooling. The induction coil 8 is arranged above the sheet metal jacket 7. You can choose from several each individually adjustable coil systems exist, so that the zones as required can be heated differently and unnecessarily for the purpose of convenient power control Energy expenditure is avoided. For more convenient melt management, it is advantageous here to the coil system or systems or parts thereof movable in the direction of the furnace axis to arrange. Such a movable arrangement of the coil systems can be approximately in the Way done that parts of the heating 'the warming zone for the power increase of the melting zone in the direction of the furnace axis. That way you can a movement of the metal mirror in the before each removal of the molten material Melting zone can be reached. Such a periodic rise in the metal level but can also by the above-mentioned, namely periodic switching of coil systems in; the melting zone can be reached, thereby not just an increase the imposed power, but at the same time an enlargement of the melting zone is achieved will. Furthermore, the periodic rise in the metal level before each removal of the melted good by increasing and decreasing the dem Coil system imposed power in the melting zone or by the periodic Reduction of the removal of the molten material can be achieved.

Depending on the material to be melted, it is instead of a ceramic one Melting zone lining advantageous, the melting zone 2 with a tubular iron core to be provided, in special cases for the purpose of improving the material passage can be made conical downwards.

To facilitate start-up after business interruptions in the top of the bridge 3 or in the bottom of the warming zone 4 an annular one Well provided, in which a closed after the oven has cooled down Metal ring remains. It is also possible to use the warming and overheating part to be built up separately and about a melting zone 2 together with one or more to operate separately and / or movably arranged warming parts 4. Such Measures prove to be particularly advantageous in terms of simplification of repairs to be carried out as well as the separation of different alloys.

Claims (7)

PATENT CLAIMS: i. Melting process for ferrous and non-ferrous metals, characterized in that the metal melted in a continuously fed shaft, which is inductively heated in its lower part, is fed to a holding or overheating zone, which is additionally heated to increase the light liquid, and fed from this or is withdrawn periodically. 2. Fusion process after Claim i, characterized in that the metal mirror periodically before each removal rises into the melting zone. 3. Induction melting furnace for performing the melting process according to claim 1 and 2, characterized in that the furnace has a melting zone (2) and a warming zone (4) which is separated from one another by a bridge (3) are. 4. Induction furnace according to claim 3, characterized in that the melting zone and in particular the warming zone or zones (4) are movably arranged. 5. Induction furnace according to claim 3, characterized in that the melting and holding zone forming masonry surrounded by a slotted jacket made of non-magnetic sheet metal is on which the coil is arranged. 6. Induction furnace according to claim 5, characterized marked that ylauerwerk and jacket are cooled. 7. induction furnace according to claim 3 or 4, characterized in that the melting zone and the holding zone are independent are heatable from each other. B. induction furnace according to claim 7, characterized in that that the zones of several coil systems or parts of such for independent Heating are surrounded. G. Induction furnace according to Claims 3 to 8, characterized in that that the coil systems are movably arranged in the longitudinal axis of the furnace. ok Induction furnace according to Claim 3, characterized in that the magnetic circuit of the induction system through the lower part of the shaft pipe and / or through the inside located fuse link is produced. ii. Induction furnace according to claim i to io, characterized in that the melting zone receives an iron core.