US3300564A

US3300564A - Vacuum induction furnace

Info

Publication number: US3300564A
Application number: US375165A
Authority: US
Inventors: Junker Otto
Original assignee: Otto Junker GmbH
Current assignee: Otto Junker GmbH
Priority date: 1963-06-20
Filing date: 1964-06-15
Publication date: 1967-01-24
Anticipated expiration: 1984-01-24
Also published as: AT257185B; FR92003E; US3300565A; US3303258A; FR92004E; DE1227926C2; FR1220513A; DE1268166B; BE649556A; BE649555A; AT257186B; FR92005E; GB1067326A; DE1227926B; SE313626B; GB1067323A; FR92002E; US3303259A

Description

Jan. 24, 1967 O, JUNKER 3,300,564

VACUUM INDUCT I ON FURNACE Filed June l5, 1964 5 Sheets-Sheet 1 F/Ci/ 48 Jan. 24, 1967 o. JUNKER vVACUUM INDUCTION FURNACE .'3 Sheets-Sheet 2 Filed June l5, 1964 Jan- 24, 1967 o. JUNKER VACUUM INDUCTION FURNACE 5 Sheets-Sheet :5

Filed June l5, 1964 United States Patent Cice s claims. (ci. 13-27) The invention relates to vacuum induction furnaces, and relates more particularly to coreless induction vacuum furnaces for large capacity charges, for either melting or holding under rarefied air.

Reference is had to my Patent No. 3,056,847, dated Oct. 2, 1962.

To melt, or to hold, metal under rareed atmospheric -conditions has many advantages, among which there is the removal of gaseous substances from the surface of the metal bath.

The invention relates to melting furnaces, as well as to holding furnaces, and wherever herein below one of these types is mentioned, it will be understood that this mentioning also is meant to include the other type.

For the large scale vacuum melting of steel, the use of coreless induction furnaces, especially of line frequency induction furances, also known as net-work frequency induction furnaces, of ya network frequency of, for instance, about from 5060 cycles, is particularly attractive:

These furnaces may be installedinto the steel melting process before the .pouring of the'steel into molds; these line frequency induction lfurnaces may be connected with their induction coil directly to the existing network; the large, though controllable, bath movement that is characteristic of coreless induction furnaces offers the advantage that the de-gasing ofthe steel melt is intensied and accelerated, as the gases are constantly moved from the interior of the metal bath to the surface, where they are removed by the prevailing vacuum.

Some of the difficulties in using large capacity electric induction vacuum furna-ces prior to the advent of my aforesaid Patent No. 3,056,847 are recited in that patent. Patent No. 3,056,847 relates to a coreless vacuum induction furnace for large capacity charges. The furnace includes an upper part and a lower p-art, a crucible that extends between these parts and holds the molten metal bath, a primary induction coil, and vacuum sealing means. The vacuum sealing means include a gastight sleeve between the coil and the cru-cible and upper and lower -closures which define with the sealing means a vacuum chamber. Cooling means for the sleeve are provided which are disposed adjacent the inner surface of the sleeve.

The connection to the source of rareiied air is disposed near the upper closure.

Reference is had to my three `co-pending applications Ser. Nos. 375,163, 375,164 and 375,166, led concurrently herewith.

Experience has shown that the sealing devices or stuffing boxes of electric vacuum induction furnaces of the type of my Patent No. 3,056,847, which seal the vacuum sleeve gas tightly and vacuum tightly with the metallic parts of the furnace housing, are subject to be heated to high temperatures during the operation of the furnace. This undesirable heating is caused by electromagnetic stray fields which occur in spite of the use of magnetic yokes for the return of the flux of the field induced by the induction coil. The aforesaid stray fields primarily affect the outer, uncooled stuffing box pressure rings, so that during the operation there is generated a large amount of Joule heat and the pressure rings are heated to an elevated temperature which may cause damage not only to the gas impermeable sleeve of syn- 3,300,564 Patented Jan. 24, 1967 thetic material, but also to the sealing packings, endangering the vacuum tight sealing of the vacuum chamber of the furnace.

It is accordingly among the principal objects of the invention to provide adjustable sealing devices or stufiing boxes for the aforesaid sleeve, wherein the pressure rings are practically free from any eddy currents, and the remaining parts of the stuiiing box may be composed of non-ferritic material and are either cooled and/or have low eddy current characteristics.

It is a further ob-ject of the invention to provide pressure rings of this type which are composed of nonmetaliic material, for instance of synthetic plastic material, or of thermo-setting synthetic resin with or without reinforcements.

It is another object of the invention to provide such pressure rings which may be composed of metal where necessary but have a radial slot to restrain the passage of electric current.

It is yet another object of the invention to provide such metallic slitted pressure rings that are composed of nonferritic metal.

It is still a further object of the invention to provide such sealing devices or stuliing boxes with stationary annular flanges secured to the housing of the furnace, each of which is composed of non-ferritic metal and deiines a hollow conduit for a cooling medium.

The foregoing and other objects of the invention will be best understood from the following description of an exemplication thereof, reference being had to the accompanying drawings, wherein:

FIG. 1 is a fragmentary vertical sectional view of a vacuum induction furnace in accordance with the invention;

FIG. 2 is a fragmentary large scale vertical sectional view of a detail framed at II in FIG. 1; and

FIG. 3 is a fragmentary large scale sectional view, similar to FIG. 1 but showing a detail thereof.

In carrying the invention into effect in one of the embodiments which has been selected for the illustration in the accompanying drawings and for description in this specification, and referring now particularly to FIGS. 1 and 2, there is provided an electric vacuum induction furnace which is supported on a framework 1. The framework 1 rests on a foundation 3 in a depression 2. A frame 4 is provided that is tiltable about hinges 6, and surrounds and is connected to an-d supports the furnace housing which, in turn, surrounds the crucible 7; the housing, on the other hand, is surrounded by and supports the coil and its reinforcements. Furnace tilting means are provided which include a hydraulic cylinder 5 that is supported by the foundation 3 and can be actuated to tilt the frame 4 and therewith the furnace housing including the crucible 7 and the coil 17 about the substantially horizontal axis X of the -hinges 6.

The frame 4 comprises a bottom structure that is composed of interconnected elongated steel beams and a series of six upright columns 4b which are arranged evenly distributed around a circle, furthermore of channel irons 4c that interconnect the columns 4b to each other, and lastly an outer structure 4d. The frame 4 also comprises beams 4a that support the bottom of the crucible 7. The columns 4b serve to anchor the upper part, a steel mantle 16, of the housing for the crucible 7 to the lower part of that housing, as the furnace including its housing comprises an upper part and a lower part which are gastightly sealed on the exterior.

The bottom of the crucible 7 rests on a layer of refractory bricks 8 which, in turn, are supported by a plate 9 that covers the beams 4a. The plate 9 is made of nonferritic metal and forms the lowermost closure of the Vacuum chamber of the furnace.

field (shown in broken lines' in FIG. 2, the direction of the stray currents being indicated by arrows) near the bottom of the crucible 7, and to impart instead to the stray field a desired extent and shape (shown in FIG. 2 in solid lines passing through the spring bolts 30), there are provided near the bottom additional magnetic yokes composed of laminated heat insulated transformer steel sheets.

In order to shield still further the plate 9 against the stray field of the coil 17, there is provided a layer 11 that is composed of a material having high electric conductivity characteristics. The layer 11 is disposed below the yokes 10 and below the 'bricks 8.

As best shown in FIG. 3, the outer wall section of the crucible 7 includes 4an insulating layer 12 that may be composed of mica, asbestos, or reproof felt. A cylindrical sleeve 13 is placed without play around the insulating ,layer 12. The sleeve 13 is composed of la gas impermeable material of high mechanical strength, but of low electric conductivity, such as synthetic plastic or thermo-setting synthetic material or synthetic resin with or without reinforcements; this sleeve 13 forms the lateral vacuum seal for the crucible 7.

Vacuum sealing means are provided which comprise the cylindrical sleeve 13 that is composed of gas impermeable material having low electric and magnetic conductivity characteristics, such as synthetic plastic, plastic impregnated paper, or the like. The lower edge of the sleeve 13, as best shown in FIG. 2, is inserted into an annular groove that is formed by an annular flange 14 that is welded to the plate 9 and projects upwardly therefrom. The flange 14 may be hollow to provide a conduit for a cooling fluid, :and is provided with connections for the entrance and exit of the cooling fluid.

The sealing of the sleeve 13 in the laforesaid annular groove is carried out lby means of a packing 14a that is cooled by the `aforesaid cooling conduit. The packing 14a is pressed downwardly by a pressure ring 15 that is'forced down by screws 15a that connect the ring 15 with the stationary annular ange 14 adjustably in the manner of a s'tufng box. The pressure ring 15 is composed of material free from eddy currents, and the remaining parts of the stutlng box of material having low eddy current characteristics, such as non-ferritic material. The pressure ring 15 is composed of lan electrically non-conducting material, such as plastic, self-hardening resin, or non-ferritic metal; when it is made of non-ferritic metal, the pressure ring 15 is provided with at least one radial slot to prevent the passage of electric current.

The sleeve 13 extends downwardly beyond the coil 17, and extends upwardly beyond the electric range of iniluence of the coil 17. The upper end of the sleeve 13 is vacuum sealed in a manner similar to that of the lower end of the sleeve 13.

The packing 14a is received in a hollow groove that is formed by an annular flange 14 that has an internal conduit for a coolant. The annular flange 14 of the upper part of the sleeve 13 is, however, connected to the steel mantle 16 that forms part of the housing of the furnace, and also, like the sleeve 13, forms lpart of the vacuum sealing means, and surrounds the upper part of the crucible 7 and surrounds the spout 7a.

The crucible 7 and the spout 7a are formed of rammed refractory material.

At the height of the alternating eld that emanates from the coil 17, there are provided cooling means to cool the sleeve 13. These cooling means are provided inside the sleeve 13 and include a series of hair-pin shaped tubes 18. As best shown in FIG. 2, each tube 18 is bent back upon itself and is preferably composed of austenitic, heat resistant steel.

The tubes 18 are embedded into the rammed mass of the crucible 7, and are disposed inwardly of an insulating layer 12 that is interposed between the tubes 18 and the sleeve 13. The tubes 18 are surrounded by a particularly fine ramming mass 19 composed of highly refractory material.

Each t-ube 18 is shaped like an inverted U and has both open ends 18a and 1gb directed downwardly. Each tube 118 has a circular cross section at the entrance end 18a and the lower exit end 18b, while throughout the remainder of its length throughout which including its .bend it is embedded in the mass, it has a at cross section, narrow in the radial plane of the sleeve 13. This ilat squeezed shape serves the purpose to increase the cooling surface of the tubes 18 for the sleeve 13.

Crossbraces 18C are provided that interconnect the long sidewalls inside the tubes 18, and extend throughout the tube length, which serve to compensate for the reduced static strength in the aforesaid radial plane; these cross braces 18e preferably also are composed of austenitic, heat resistant steel.

In order to make the walls of the tube-s 18 as thin as possible, sheets 20 are provided to take up pressures thatare exerted by the molten metal radially outwardly, and between the sheets 20 and that side of the tubes 18 which faces the center of the crucible, there is provided an additional insulating layer 21. Each sheet 20 is preferably also made of austenitic steel, while the layer 21 is composed of material that has poor electric and heat conductivity characteristics.

As best shown in FIG. l, the shorter entrance ends of the tufbes 18a terminate in an annular channel 22 that forms a part of the bottom support structure for the crucible 7. The annular channel 22 is provided with an entrance pipe for the connection to a blower for the cooling fluid (not shown).

The annular channel 22 is supported on the beams 4a of the tiltable frame 4, Iand serves on one hand to support the bottom plate 9, and on the other hand serves to be connected to the columns 4b. The longer leg of eac-h tube l18 has its exit end 18b projecting axially through the -annular channel 22 into the atmosphere, for the discharge of the cooling fluid.

The sleeve 13 is surrounded, along a portion of its height, by the coil 17. A series of twelve C-yokes 24 are arranged evenly spaced from each other circularly about the coil 17 to the exterior thereof. Each yoke 24 is composed of lamellae of transformer sheet metal.

As best shown in FIG. 1, a terminal 25 is provided for the electric current for interconnecting the coil 17 with the network; and a connection 26 is provided for interconnecting the coil 17 with a cooling liquid that courses, in a well-know manner, in the interior of the hollow coil 17. The conduits 14 for cooling the sealing devices heretofore described are also connected to the connection 26. The cooling conduits for the sealing devices hereafter described are 'also connected to the connection 26.

As bestl shown in FIG. 2, the space between the inner surface of the coil 17 and the outer surface lof the sleeve 13 is filled with a layer 27 of liquid self-hardening resin, in order to take up the radially outwardly directed pressures of the ceramic material of the crucible 7, and to transfer it to the frame of the furnace.

An insulation 28 composed of mica, asbestos or fireproof felt is provided between the coil 17 and the yokes 24 that surround the coil 17.

As best shown in FIG. 2, the coil 17 is supported at its lower end by the inner leg of the yokes 24 and an insulating layer 29 thereon. To take up the electromechanical forces which occur in the windings of the coil 17 during the operation ofthe furnace, there are provided lingers 30a and a spring loaded anchor bolt 30. The fingers 30a-press, -by means of van insulating layer 29 against tlhe upper portion of the coil 17. `Each spring loaded anchorbolt 30 is connected to Ia yoke 24. f

Reference is had to my Patent No. 2,852,587, .dated September 16, 1958.

The crucible 7 is open on top and is covered, except for that part which leads into the spout 7a, by an inner cover 33. The cover 33 is vaulted and is composed of refractory bricks which are held together by a metal frame 33a. When the furnace is in operation, a stopper 34, which is also composed of refractory material, closes the open channel that leads to the spout 7a,

A bell-shaped outer lid 35 is provided that surmounts the crucible 7, the inner cover 33, as well as the spout 7a. The outer lid 35 is composed of steel sheet, and is lined on the interior with a fireproof insulation layer 35a.

The lower rim of the outer lid 35 has an inverted annular groove 36 which is filled with a deformable sealant 36a. On the exterior, the lid 35 has near the groove 36 an annular cooling conduit 37 which is provided with fittings `57a to be connected to the cooling connection 26.

The lid 35 rests with the sealant 36a on the apex of an annular wedge-shaped upright sealing ridge 38 that is formed on an annular carrying flange 39. The carrying flange 39 is hollow and has an internal conduit for a cooling fluid including a fitting 39a to be connected to the cooling connection 26. The carrying flange 39, by means of connecting struts 40, is welded to said steel mantle 16, `and therefore is united therewith.

The inner cover 33 has a central aperture or opening 33h and the outer lid 35 has an opening 3517 in register therewith. These openings 33b and 35b serve for the sampling of the lmolten metal mass or the adding of alloying material. Both openings may be closed. The opening 35b may gastightly be closed by a stopper 46 and, in connection with Ia superstructure 47, be sealed with a cap 43 which Works according to the same principle as the lid 35 itself in connection with the sealing device that comprises the deformable sealant 36a, the ridge 38 and the cooling conduits 37 in the flange 39, as previously described. An objective 49 is provided that is sealed to the outer lid 35 and which permits viewing through the aperture 33h of the Crucible 7 during operation of the furnace. The 'aperture 33b of the inner cover 33 may be closed by a ap 50 that is composed of refractory material and is manipulated from the exterior at 52 and is pivoted at 51.

I wish it to beunderstood that I do not desire to be limited to the exact details of construction shown and described, for obvious modifications will occur to a person skilled in the art.

Having thus described the invention, what I claim as new and desire to be secured by Letters Patent is as follows:

1. In a coreless induction furnace for large capacity charges, the combination of, a Crucible, a primary induction coil adapted to be fed from an electric source surrounding said crucible, vacuum sealing means comprising a furnace housing, a sleeve including gas impermeable material having low electric and magnetic conductivity characteristics disposed between said coil and said cruci'ble, land gastight upper and lower closure means operable for airtightly closing the upper and, respectively, the lower ends of said vacuum sealing means and defining a vacuum chamber housing said Crucible, and cooling means for said sleeve disposed `adjacent the inner surface of at least a portion of said sleeve, said sealing means comprising upper and lower sealing devices between the furnace housing and said sleeve each sealing device comprising an adjustable stufllng box including a packing, and a pressure ring surrounding a portion of said sleeve and exerting pressure on said packing for sealing said sleeve portion and being free from eddy currents, the remaining parts of the stuffing box for the packing being composed of material having low eddy current characteristics.

2. In a coreless induction furnace, as claimed in claim 1, said remaining parts being composed of non-ferritic material.

3. In a coreless induction furnace, as claimed in claim 1, said remaining parts including means establishing a conduit for a cooling fluid.

4. In a coreless induction furnace, as claimed in claim 1, each lpressure ring being composed of metal and having at least one radial slot,

5. In a coreless induction furnace, as claimed in claim 1, each pressure ring being composed of non-ferritic metal.

6. In a coreless induction furnace, as claimed in claim 1, each pressure ring being composed of non-metallic synthetic material.

7. In a coreless induction furnace, as claimed in claim 1, each sealing device comprising a stationary annular flange operable to receive the packing and the end portion of the sleeve and being composed of non-ferritic metal.

3. In a coreless induction furnace, as claimed in claim 7, each stationary annular flange defining a conduit for a cooling fluid, and including means for delivering cooling fluid to said cond-uit.

Claims

1. IN A CORELESS INDUCTION FURNACE FOR LARGE CAPACITY CHARGES, THE COMBINATION OF, A CRUCIBLE, A PRIMARY INDUCTION COIL ADAPTED TO BE FED FROM AN ELECTRIC SOURCE SURROUNDING SAID CRUCIBLE, VACUUM SEALING MEANS COMPRISING A FURNACE HOUSING, A SLEEVE INCLUDING GAS IMPERMEABLE MATERIAL HAVING LOW ELECTRIC AND MAGNETIC CONDUCTIVITY CHARACTERISTICS DISPOSED BETWEEN SAID COIL AND SAID CRUCIBLE, AND GASTIGHT UPPER AND LOWER CLOSURE MEANS OPERABLE FOR AIRTIGHTLY CLOSING THE UPPER AND, RESPECTIVELY, THE LOWER ENDS OF SAID VACUUM SEALING MEANS AND DEFINING A VACUUM CHAMBER HOUSING SAID CRUCIBLE, AND COOLING MEANS FOR SAID SLEEVE DISPOSED ADJACENT THE INNER SURFACE OF AT LEAST A PORTION OF SAID SLEEVE, SAID SEALING MEANS COMPRISING UPPER AND LOWER SEALING DEVICES BETWEEN THE FURNACE HOUSING AND SAID SLEEVE EACH SEALING DEVICE COMPRISING AN ADJUSTABLE STUFFING BOX INCLUDING A PACKING, AND A PRESSURE RING SURROUNDING A PORTION OF SAID SLEEVE AND EXERTING PRESSURE ON SAID PACKING FOR SEALING SAID SLEEVE PORTION AND BEING FREE FROM EDDY CURRENTS, THE REMAINING PARTS OF THE STUFFING BOX FOR THE PACKING BEING COMPOSED OF MATERIAL HAVING LOW EDDY CURRENT CHARACTERISTICS.