EP0761347A1 - Process for operating an inductor and inductor for carrying out this process - Google Patents

Abstract

In an inductor operating method, during one working phase, the fluid cooled inductor is inductively coupled to an electrically conductive shaped part or is coupled directly to an electrically conductive melt in an electrically non-conductive shaped part and, opt. during another working phase, the fluid cooled inductor is electromagnetically decoupled. The inductor may be operated to (a) heat or cool melts in tapping equipment (e.g. open nozzles, channels or stopper, sliding and tube closures), in transport runners and/or in vessels or (b) to melt or solidify metals or non-metals (esp. non-metallic slags and/or glasses). Also claimed is an inductor for carrying out the above method, the inductor (2) having one or more cooling fluid supply (8) and return (9) lines.

Description

The invention relates to a method for operating an inductor and an inductor for performing the method.

According to the prior art, the inductor is water-cooled during operation. For this purpose, the induction coil has a hollow cross section that forms a cooling channel (cf. EP 0 291 289 B1, EP 0 339 837 B1). Water cooling serves to protect the inductor against overheating. Water cooling, however, has the disadvantage that any leaks lead to a possibly harmful, in any case undesirable development of water vapor when it emerges into a melt.

DE 41 36 066 A1 describes a pouring device for a metallurgical vessel and a method for opening and closing a pouring sleeve. The inductor is to be brought into different displacement positions relative to the pouring sleeve in order to influence the heat conduction between the inductor and the pouring sleeve. In a first shift position, a gap between the The inductor and the pouring sleeve have thermal insulation, and the electrically switched on, cooled inductor inductively melts a metal plug existing in the pouring sleeve.

In the second shift position there is a heat-conducting connection between the inductor and the pouring sleeve. The inductor through which the cooling medium flows is electrically switched off. The resulting cooling of the pouring sleeve freezes the molten metal in the pouring sleeve. In order to be able to operate the inductor in these two working phases (shift positions), it must be moved mechanically. This requires a corresponding actuation and control device.

Patent application P 44 28 297 describes an inductor in an outlet member of a melt vessel, which is installed directly in the bottom of the melt vessel or in a perforated brick in the bottom of the melt vessel. This inductor cannot be operated in accordance with DE 41 36 066 A1 because it cannot be displaceable relative to the pouring sleeve.

The object of the invention is to propose a variable operating method for an inductor.

According to the invention, the above object is achieved by the features of the characterizing part of claim 1.

The operating method described has the advantage that it can be adapted to operating conditions in a variety of ways. By appropriately matching the heating output and the cooling output, the inductor can be used to heat or cool melts in tapping devices, such as free-running nozzles, channels, stopper, slide and pipe closures or in transport channels and / or vessels. It can also be used to melt or solidify metals or non-metals, in particular non-metallic slags and / or glasses. It can also be used to heat components, containers or transport elements that come into contact with melts.

It is also advantageous that the inductor does not have to be moved in the working phases. It can therefore be built into the tapping device or rigidly connected to it.

In the process described, different fluids, such as liquid gas, dry ice, water or gas, in particular compressed air, can be used in the working phases. Water is preferably not used. The use of liquid gas or dry ice as a coolant in the work phase, in which a high cooling capacity is desired, is favorable because it does not lead to dangerous water vapor or oxyhydrogen gas development in contact with a melt when escaping and any leaks in the liquid gas or dry ice guide can come.

In the other work phase, in which a lower cooling capacity is sufficient, compressed air can be used as the coolant. The use of compressed air is cheap because it is simple and cheap to use and also does not lead to the problems associated with water cooling.

In an exemplary operating method, the melt is heated by the inductor in at least one tapping device of a melt vessel in a first working phase. The inductor can be inductively coupled to the tapping device or in connection with an electrically non-conductive molded part directly to the electrically conductive melt in the molded part. The first working phase thus serves to heat the melt or the tapping device. If necessary, a melt plug solidified in the tapping device can also melt. In the first phase of work, the inductor works with very high electrical power, so that a melted edge zone is created on the plug before the thermal expansion of the plug comes into effect, so that it explodes the refractory material surrounding it. The liquid peripheral zone layer is displaced as the plug gradually expands. Even with these high starting powers, a fluid, for example liquid gas or dry ice and in particular also compressed air, has proven to be sufficient coolant for the inductor.

In another working phase, in which the melt flows freely with little or no reheating, a lower cooling capacity with reduced or switched off electrical power or electrical decoupling of the inductor is sufficient. It is cooled by means of the fluid, preferably compressed air. If several tapping devices are provided next to one another on the melt vessel and a reduced melt flow occurs on one or more of the tapping devices as a result of a lower temperature, these tapping devices can be reheated by increased electrical power or a reduction in the cooling capacity so that the same melt flow occurs at all tapping devices. Different heat emissions can also be compensated for.

The melt can be cooled in a further working phase. The inductor is switched off electrically. The cooling of the inductor continues to be operated and is preferably carried out with a high cooling capacity by means of water, liquid gas, dry ice or compressed air. This working phase serves in particular to freeze the melt in the tapping device in order to specifically interrupt the melt flow.

By appropriate selection of the cooling capacity, it is also possible to freeze any melt that has penetrated into any cracks in the tapping device, so that the cracks are closed.

It is also possible to freeze part of the melt as a layer on the wall of the molded part.

Figur 1

eine Vorrichtung zur Durchführung des Verfahrens, schematisch

Figur 2 bis Figur 6

verschiedene Möglichkeiten der Zuführung und Abführung des Kühlfluids bei einem wendelförmigen Induktor,

Figur 7

einen spiralförmigen, plattenförmigen Induktor mit Zu- und Abführungen des Kühlfluids,

Figur 8

einen Induktor aus einem wendelförmigen, schraubenförmigen und einem spiralförmigen, plattenförmigen Induktorteil, und

Figur 9

eine abgewandelte Ausführung des Induktors.

Further advantageous embodiments of the invention result from the subclaims and the following description. The drawing shows:

Figure 1

an apparatus for performing the method, schematically

Figure 2 to Figure 6

different ways of supplying and removing the cooling fluid in a helical inductor,

Figure 7

a spiral, plate-shaped inductor with supply and discharge of the cooling fluid,

Figure 8

an inductor from a helical, helical and a spiral, plate-shaped inductor part, and

Figure 9

a modified version of the inductor.

An inductor (2) is installed in the bottom (1) of a melt vessel. This consists of an electrically conductive induction coil with a hollow cross section, which forms a cooling channel (3) for a cooling fluid. The inductor (2) is connected to an electrical energy source by means of electrical connections (4, 5).

The inductor (2) encloses a free-running nozzle (6) made of refractory ceramic material (molded part) which is used as a tapping device in the bottom (1). This forms a channel (7) for the melt flow.

On the one hand an inlet line (8) and on the other hand an outlet line (9) are connected to the cooling channel (3). The inlet line (8) is via a 3-way valve (10) on a pressure container (11) for liquid gas or a dry ice container and on a compressed air source (12). The dry ice can also be introduced into the inlet line in the form of bars or cartridges.

The functioning of the described device is, for example, as follows:

If one assumes that the melt flow is interrupted by a melt plug deliberately frozen in the channel (7) and the melt flow is to be started, then in a first working phase the inductor (2) is switched to high electrical power and the 3-way valve (10) is set so that liquid gas from the pressure vessel (11) changes to the gaseous state and flows through the cooling channel (3). The liquid gas can be liquid nitrogen, for example. Solidified CO ₂ (dry ice) and especially compressed air are also conceivable. The heating inductor (2) is cooled by the liquid gas. Either it couples inductively to the freewheel nozzle (6) or to a susceptor surrounding the freewheel nozzle, which then melts the metal plug in the channel (7) by heat conduction; or it couples inductively directly to the melt or the metal plug, so that it also melts.

The melt flow is set in motion by the melting of the metal plug. The electrical power of the inductor (2) can now be reduced or switched off because there is little or no need for post-heating. The cooling capacity can also be reduced accordingly. This is done by switching the 3-way valve (10) to the compressed air source (12) at the latest now. In the standby phase, cooling is carried out with air, which limits the consumption of liquid gas.

If several freewheeling nozzles with inductors are provided next to each other on the floor (1), the inductors can be controlled individually so that the same melt flow rates emerge through the freewheeling nozzles.

If cracks are formed in the freewheel nozzle (6) into which the melt enters, the cooling can be controlled in such a way that the melt which has penetrated into the cracks freezes in the cracks, but the main stream of the melt continues to run through the channel (7).

If the melt flow is to be interrupted, the inductor (2) is switched off electrically and the 3-way valve (10) is switched back to the pressure vessel (11) or the compressed air throughput is increased. The inductor (2) is now cooled with a high cooling capacity, the free-running nozzle (6) correspondingly being cooled by heat conduction and the melt freezing in the channel (7) to form a plug which interrupts the melt flow.

In the working phases described, the coolant emerges from the outlet line (9). It can be released directly into the environment without damage. During the working phases, the liquid gas evaporating in the inductor (2) or the heated compressed air escapes.

If necessary, the liquid gas can also be conducted in a closed circuit. A device for this is shown in dashed lines in the figure. A further 3-way valve (13) is then provided on the outlet line (9), which leads on the one hand to a gas outlet (14) and on the other hand to a liquefied gas recovery apparatus (15), for example a compressor, which connects to the 3-way valve (10). connected.

The device described can also be used in other tapping devices of a melt vessel, for example the inductor (2) is then not installed in the bottom (1) of a melt vessel, but in a slide closure device or another component.

According to Figure 2, outlet lines (9, 9 ') (cooling fluid discharges) are connected to both ends of the inductor (2). In an area lying between the outlet lines (9, 9 '), an inlet line (8) (cooling fluid supply) is connected to the cooling duct (3) of the inductor (3). The inlet line (8) is connected to a point on the inductor (2) which corresponds to the desired cooling conditions. For example, it lies in the middle of its length. The coolant entering through the inlet line (8) thus flows on the one hand to the outlet line (9) and on the other hand to the outlet line (9 '). It improves the cooling effect. The most cooled point of the inductor (2) can be placed in a desired area of the inductor (2).

In the embodiment according to FIG. 3, two inlet lines (8, 8 ') are provided between the two outlet lines (9, 9'). This allows the coolant flow to be increased and thus the cooling effect to be improved.

A partition (16) can be provided between the inlet lines (8, 8 ') in the cooling channel (3) of the inductor (2) (cf. FIG. 4). This ensures that the cooling fluid flowing in through the inlet line (8) only reaches the outlet line (9) and the cooling fluid flowing in through the inlet line (8 ') only reaches the outlet line (9'). Depending on requirements, the inductor (2) can thus be cooled in its upper region with a different cooling fluid than in its lower region, or else the two regions can be cooled differently with the same cooling fluid with more or less exposure.

In the embodiment according to FIG. 5, inlet lines (8, 8 ') are arranged at the two ends of the helical inductor (2). One or two outlet lines (9, 9 ') are provided approximately in the middle of the inductor (2). This can also improve the cooling effect.

It is also possible to provide an inlet line (8) at one end of the inductor (2) and an outlet line (9 ') at the other end. In the central region of the inductor (2) there is then, separated by the partition (16), an outlet line (9) and an inlet line (8 '). This is shown in Figure 6. In other versions, more than two inlet lines and / or outlet lines can also be provided on the inductor (2).

Figure 7 shows a spiral, plate-shaped inductor (2). In this case too, an outlet line (9, 9 ') can be provided at each end, the inlet line (8) then being connected between the outlet lines (9, 9') and the inductor (2). The alternatives described above can also be implemented in the spiral inductor (2) according to FIG.

FIG. 8 shows an inductor which consists of the combination of a helical inductor part (2 ') and a spiral inductor part (2' '). This inductor is suitable, for example, for an immersion spout (10) which forms a refractory, ceramic molded part, the helical, screw-shaped inductor part (2 '') being introduced into a cylindrical region of the immersion spout and the spiral, plate-shaped inductor part (2 '') of an upper one Extension (10 ') of the immersion nozzle (10) is assigned. Electrically, the inductor parts (2 ', 2' ') can be connected as a unit. Their cooling can be carried out separately by appropriate inlet and outlet lines.

In the embodiment according to FIG. 9, the helical, helical, cylindrical inductor part (2 ') is connected or combined with a second helical inductor part (2' ''). The second inductor part (2 '' ') widens conically, the individual turns merging into one another in different or changing radii. The inductor part (2 ') is used as an internal inductor for a melt outlet (11) formed by a refractory ceramic molded part. The inner inductor part (2 '' ') is used as an outer inductor for a plug (12) assigned to the melt outlet (11), which is also a refractory ceramic molded part. The inlet lines and outlet lines described with reference to FIGS. 2 to 6 can also be provided here.

Claims (15)

Method for operating an inductor
characterized,
that the inductor is inductively coupled to an electrically conductive molded part during one working phase and is cooled by means of a fluid and, if necessary, is electromagnetically decoupled during another working phase and is cooled by means of a fluid. Method according to claim 1,
characterized,
that the fluid is liquid gas or dry ice or water or water vapor or gas, especially compressed air. Method according to claims 1 and 2,
characterized,
that the electromagnetic decoupling takes place by electrical shutdown or by reducing the electrical power of the inductor. Method for operating an inductor for heating or cooling an electrically conductive molded part according to claim 1 or 2,
characterized,
that the inductor is used to heat or cool melts in tapping devices such as freewheel nozzles, channels, stopper, slide and pipe closures. Method for operating an inductor for heating or cooling an electrically conductive molded part according to claim 1 or 2,
characterized,
that the inductor is used to heat or cool melts in transport channels and / or in vessels. Method for operating an inductor according to one of the preceding claims 1 to 5,
characterized,
that the inductor is used for melting or solidifying metals or non-metals, in particular non-metallic slags and / or glasses. Method for operating an inductor
characterized,
that the inductor is coupled directly to an electrically conductive melt in the molded part during a work phase in connection with a non-electrically conductive molded part and is cooled by means of a fluid and, if appropriate, is decoupled electromagnetically in another work phase and is cooled by means of a fluid. Method according to one of the preceding claims,
characterized,
that the melt is cooled in another working phase, the inductor being electrically switched off and the cooling of the inductor being continued. A method according to claim 8,
characterized,
that part of the melt is frozen as a layer on the wall of the molded part. Method according to one of the preceding claims,
characterized,
that several inductor parts (2 ', 2''), in particular of different shape, such as helical shape or spiral shape, are arranged as an inductor on the molded part and are designed as an internal and / or external inductor. Inductor for the method according to one of the preceding claims,
characterized,
that the inductor (2) has one or more inlets (8, 8 ') and one or more outlets (9, 9') for the cooling fluid. Inductor according to claim 11,
characterized,
that the helical or spiral inductor (2) each has an outlet (9, 9 ') at the ends of the helix or spiral and between these outlets (9, 9') one or more inlets (8). Inductor according to claim 11,
characterized,
that the helical or spiral inductor (2) each has a feed (8, 8 ') at the ends of the helix or spiral and between these feeds (8, 8') at least one discharge (9). Inductor according to claim 11,
characterized,
that the inductor (2) has an inlet and an outlet at its ends and between an outlet and an inlet or has several outlets and several inlets. Inductor according to claims 11 to 14,
characterized,
that the plurality of inlets (8, 8 ') or outlets (9, 9') lying between the inductor ends are separated from one another with respect to the flow of the fluid by a partition (16) in the cooling duct of the inductor (2).

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