LT3736B - Oven with heating device of the charge in shaft form - Google Patents

Description

A similar type of melting unit is known from iS VFR model no. 8412739.

In a known melting plant, the charge is charged through a shaft-shaped charge heater located in a metal receiver in a liquid metal bath. In addition, there is the problem that the supply of electricity after the discharge and the start of a new arc is limited due to the high temperature of the bath at that time. After draining the liquid metal, the remaining bath in the furnace metal receiver is cooled down so little that only a small amount of electricity can be supplied to prevent the bath from overheating. Thus, the available melting capacity available in the initial phase cannot be utilized, which consequently increases the melting time accordingly.

In order to shorten the melting process and protect the furnace walls, it is desirable to charge the charger every time after discharge, not only from the side of the metal receiver in the furnace containing the charge heater, but evenly across or across the furnace cross-section. charging materials for the heater.

Loading the contents of the scrap tank directly into the furnace metal receiver causes space problems due to the charging shaft on one side of the furnace metal receiver and the electrode lifting and folding unit on the other side of the furnace metal receiver. In addition, such a charging process is associated with environmental pollution.

The object of the present invention is to provide a melting unit, as described in the limiting part of the definition of the invention, to which, without hindrance, the metal can be charged from the melting tank through the entire cross-section of the furnace or on the opposite side of the furnace metal receiver.

The problem is solved by the features of (i)

The most rational embodiments of the invention may be taken from the appended claims.

As a result, the charging wall of the charge heater in the lower region to the upper edge of the furnace metal receiver is formed as a part of the reservoir wall that may be supported laterally by the charging pillar and in the area above these walls. The shaft holding structure and the furnace metal receiver can move relative to one another. Ideally, the support structure has a removable tank cover. In this case, it and the shaft form a structural unit. Removing the reservoir lid can simultaneously remove the charge material heater shaft and allow enough space to charge directly into the furnace metal receiver.

the division of the charge material heater into an upper part which is secured to the shaft bearing structure and a lower part formed by a part of the tank wall at the structural connection of the shaft and the slab results in further improved charging and melting capabilities. Due to the horizontal relative displacement of the tank lid and the furnace metal receiver, the shaft itself can be used for targeted charging of the furnace metal receiver and can significantly reduce environmental pollution by covering the larger portion of the furnace metal receiver with the lid.

The relative horizontal displacement may be a rotary or linear motion of the reservoir and / or a linear displacement of the furnace metal receiver. The distance required for the relative horizontal displacement between the upper edge of the tank and the lower edge of the tank lid can be realized by raising the lid or lowering the tank.

In a particularly preferred embodiment of the invention, the furnace metal receiver is mounted to the upper frame, which rests on the support frame made in such a way that it can move. At the same time, the tank cover and shaft may not be stationary. The frame lifting device may, for example, consist of hydraulic lifting cylinders arranged in four corners of the rectangular frame and operated in pairs to allow the tank to be tilted in one direction to discharge the VA / molten metal and to be turned in the other direction so that the shoe slag removed. The movable support frame design allows for the required horizontal displacement of the tank relative to the tank lid and shaft, either allowing the furnace metal receiver to be charged from the scrap tank side outside the lid area, or allowing the charge to be charged through the shaft to the furnace metal receiver. In addition, it is best that the reciprocal horizontal displacement is parallel to the line connecting the center of the tank cover and the center line of the shaft, with

The movement to remove slag and discharge metal is perpendicular to the horizontal displacement.

Ideally, the metal receiver, viewed from above, has an oval bounded in a straight line from the sides, and the straight wall and adjacent sections of the oval form the walls of the charge material heater in its lower part.

Adjacent to the electrodes, the shaft wall may extend a certain distance below the bottom half of the lid to limit the connecting area between the inner space of the metal receiver heater and the interior of the furnace metal receiver. The charge heater in the shaft is supported by the inclined bottom of the charge heater and the inclination angle to the base of the furnace is greater than 30 ° and less than 60 in the enlarged connection zone.

In order to maintain the low weight of the shaft, the walls are preferably made of water-cooled elements.

Typically, the Electrode Lifting Device is placed adjacent to the furnace metal receiver on the opposite side of the Charging Material Heater to prevent interference with the electrode bending process.

Typically, the lid lifting and folding device is also located on the side of the electrode lifting device. Since, according to the invention, the center of gravity of the melting unit is close to the shaft, it

The lifting and folding device of the supporting structure of the shaft which holds the tank cover is close

Charging material on the opposite side of the furnace metal receiver than the electrode lifting device. A sliding gantry may also be provided, based on 1 rails on either side of the smelting unit, the support beams of which shall be regarded as the shaft bearing structure and, if necessary, the tank cover.

The hopper cover lifting and folding device can, in principle, be made as described in the European application no. 203339. According to this application, a pivoting portal mounted adjacent to a flank of a loading material heater is provided with a lifting device having at least one retractable retractable retaining member for lifting the lid.

If the Sis device is constructed such that the retaining member is disengaged from the lid in the lowered position, then with the tilting furnace metal receiver, it is not necessary to simultaneously rotate the lifting and folding device and this device may be mounted on a stationary base in the form of an assembly. However, it is understood that, with the appropriate selection of furnace cradle dimensions, the lifting and folding unit may be mounted on a rotating furnace platform.

In a reversible embodiment, the furnace metal receiver must rotate perpendicular to the axis relative to the center of the charge heater and the center of the furnace base.

If the retractor of the shaft-bearing structure is realized in the form of a lifting and folding device, it must lean in the same direction as the electrode lifting and folding device with respect to the furnace metal receiver. one device must lean in a mathematically positive direction and the other in a mathematically negative direction. At the same time on the other side of the e, space is available for charging.

In view of the shortening of the smelting process and the saving of electricity, it is also desirable that the charger, which is subsequently discharged from the scrap tank or through the shaft lid, be preheated by the gas used in the smelting tanks. As a result, an additional preheating chamber may be provided adjacent to the charge heater to accommodate a charged charge reservoir connected to a shaft-shaped charge heater exhaust outlet, which also allows hot gas already used during the refining phase to be used when empty. shaft-shaped charging materials for the heater. An additional preheating chamber is unnecessary if the shaft of the adequately foamed embodiment of the present invention is provided with at least one movable closure member that holds the charge material in the shaft in the closed position and provides gas passage and the preheated charge material in the open position is released or guaranteed. unobstructed charging through the shaft. From this point of view, this solution is particularly rational from an environmental point of view, since a slightly refined base charge can be charged to the furnace metal receiver without having to remove the entire tank cover completely.

The invention is illustrated by the following embodiments, which show:

FIG. 1 is a partial sectional side view of the melter, FIG. 2 is a plan view of a melting unit 2 with inserted electrodes having a lid on the furnace metal receiver, FIG. 3 - FIG. 2 with the lid open and the electrodes folded open, FIG. 4 is a side view of a second embodiment, FIG. 5 is a side view of a third embodiment with a movable furnace metal receiver and closure member in the shaft, FIG. 6-12 - Different embodiments of the fourth example:

** ν FIG. Fig. 6 is a side view of the main position, Fig. 7; 8 is a partial sectional view taken along line VIII-VIII shown in FIG. 7th

FIG. 9 is a top view of the melting unit, FIG. 10 is a top view of the support frame of the furnace metal receiver, FIG. 11 is a furnace metal receiver in an outlet position, FIG. 12 - Melting unit with tank cover removed from shaft.

FIG. The melting unit shown in i-3 consists of a tank furnace 1 and a shaft-shaped charge material heater 2.

The flexible furnace has a furnace metal receiver 3 consisting of a furnace base 4 and a reservoir wall 5. The furnace metal receiver 3 is closed by a rotating lid 6 through which

The furnace M receiver of the furnace M can be inserted into the electrodes 9 which are mounted on the brackets 7 and raised and folded sideways by the electrode lifting and folding device 8. To illustrate, FIG. only electrodes are shown.

The charge heater 2 is located adjacent to the furnace metal receiver 3. In the lower portion of the charge heater extending to the upper edge of the reservoir wall 5, the reservoir wall 5 forms the outer wall of the heater. Partially above it, the heater walls of the charging material comprise a shaft 10 which, like the reservoir lid 6, is secured in the supporting structure 27 and forms a unitary housing lid 6.

Αχ • 'λ * <\ x Αχ

EN 3736 Β structural unit. As shown in FIG. 3, when viewed from above, the furnace metal receiver 3 has the shape of an oval bounded by the sides in a straight line. The straight wall section 11 forms the outer shaft walls along with the adjacent oval sections 12 in the lower portion of the charge heater.

The bottom 13 of the charge material heater 2 lined with heat-resistant materials is inclined and has an inclination angle 14 of about 45 ° with respect to the heat-base material 4 of the furnace.

To reduce weight, the shaft walls 10 are made of water-cooled wall elements. The inner cross-section 15 of the shaft space 15 expands downwards to ensure unhindered flow of the charge 16

In the shaft 10.

In this case, in the view from above, the shaft 10 is almost rectangular and extends upwardly into the walls of the furnace metal receiver 3, bounded by sections 11 and 12. In this case, a connecting zone 17 is formed between the charge heater 2 and the arc furnace 1, which extends in height and width in an imaginary common plane between the charge heater and the arc furnace. It goes without saying that it is possible to choose a cross-sectional shape of a shaft that is different from a rectangle, and the shaft does not necessarily have to extend over the entire width of the furnace metal receiver or cover. In addition, the wall of the shaft 10 facing the electrodes 9 may extend downward from the lid edge inside the metal receiver of the furnace to reduce the pull of the joint.

The height of the resulting area is 17. In this case, when removing the cover, it must be raised a corresponding amount so that it can be pushed to the side.

In the upper zone, the charge heater 2 has a sealed charge port 18 as well as a gas outlet 19. The gas outlet 19 is connected to a gas pipe 20 by a gas pipe or a preheat chamber to which a charge tank or scrap metal tank can be inserted. As can be seen from FIG. 2, in the first embodiment, the electrodes 9 are in the direction of the charge material heater, the radiant heat in the arc furnace exerts a stronger effect on the charge material in the charge material heater 2 and at the same time reduces the load on the free wall areas of the dense furnace.

As can be seen from FIG. The furnace base 3 has an eccentric discharge outlet 21. As the furnace metal receiver 3 performs the discharge function, it can, as we know, be inverted, and the flip movement is perpendicular to the axis C227 connecting the center of the charge heater to the center of the furnace base. . FIG. 27th

In the melting assembly in question, the electrode lifting and unfolding device 8 is located in a shaft 10 on the opposite side of the tank cover 6 adjacent to the furnace metal receiver 3, and the lifting and unfolding device 23 of the supporting structure 27

II

A * Is the charging material heater. The lifting and folding device 23 may be made in accordance with the description set out in European application no. 203939. In this case, ant. the pivoting portal 24 is provided with a lifting cylinder 25 with a retractable and retractable retaining member 26 disengaged in a lowered position from a retaining structure 27 connected to the reservoir lid 6 and in a raised position into a retaining member 27 retained by a retaining member 27.

Lifting and folding device 23 The shaft 10 can be raised and folded to the side with the lid 6. Fig. Figure 3 illustrates the position of the side-facing cover and electrodes. It is seen that the lid and the electrodes of the furnace metal receiver may lean to the same side, i.e. y. in the illustrated case, to the discharge side such that, on the other side, in the direction of the arrows 29, it is possible to charge or dismantle the scrap tank through the open furnace metal receiver without hindrance.

Instead of a rotating portal as a moving portal, it can also be a linear scrolling portal that has a lifting device. In this case, it is best if the portal holding the lifting device can move, fig. 2 Double arrow 32 shows direction.

In the present case, the electrode lifting and unfolding device 8 is mounted on a generating furnace platform 30 whose dimensions should be selected to be sufficiently stable due to this function and the lifting and unfolding device 27 of the supporting structure 27 is in the form of a unit mounted directly on the base. This is possible due to the fact that when the support member 26 is in the lowered position, the lifting and folding device 23 is disengaged from the support structure 27 of the reservoir cover 6 so that the furnace metal receiver together with the reservoir cover can tilt unhindered.

FIG. In the embodiment shown in Fig. 4, when the tank cover is pulled open, it does not lean to the side and, after lifting, leans to the side. As a result, a two-rail 4i moving portal 42 is provided. The rails 41 are mounted on a base on either side of the melting unit. A moving portal 42 with two supporting beams 43, one of which according to FIG. 4, is located in front of the shaft 10, and the other behind it clamps the melting unit. in this case, the moving portal also holds the electrode lifting and unfolding device 8. 'The supporting beams 43 with the detachable lifting devices not shown are in some places connected to the reservoir lid 6 or the shaft 10 support structure so that the reservoir lid can be raised if necessary. or turn it sideways. On the other hand, tilting motion should not be obstructed by removal

Slag and drain furnace metal receiver 3.

The arc furnace may be constructed as a direct or alternating current arc furnace and may have a single electrode or several electrodes inserted through the reservoir lid.

FIG. The arc furnace 1 shown in Fig. 5 has, in horizontal direction, wheels 57 on two parallel rails 58 C, only the front} movable metal receiver 3 is visible here.

The shaft 10 of the heater 2 has a closure member, all of which is marked 5i-a. The closure member 51 consists of two rollers 52 disposed opposite each other in a common horizontal plane, for example water-cooled, one of which is respectively in the row plane of the cantilever holders 53. Accordingly, the holders 53 are made identical, and in the same way as the rollers 52 can be cooled by water.

The rollers 52 may be rotated accordingly in the base members 54. However, the attachment assembly shown may be elastic, for example, manufactured using mechanical elastic members or hydraulic dampers.

The rollers can start to rotate, not shown in the drawing, gear mechanisms, ό stop brakes in the required angular position. The base members 54 are accordingly made to correspond to the extended area of the charge heater 2, and the corresponding wall wall area of the shaft 10 is protruding outwardly so that the rollers 52 with the respective holding members 53 are hermetically mounted inside the shaft 10.

Both rollers 52 may be actuated to move synchronously so that the retaining members may be in position, FIG. 5 shown in solid, dotted, and striated lines. In addition, there are some outstanding issues

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s 55 half e equipment 5.6, of the two, purpose is vi r these circle nk

the cover 6 and the shaft 10 respectively show the free position of the respective support members 53, in which the rows of the support members are inside the respective base element 54. In this position, the closure member 51 or the retaining members 53 are fully retracted, and the charging column can then be loaded. The charging pillar rests on the underside of the bottom or metal receiver wall 3 area.

The support structure of the shaft 10 and the reservoir cover 6 is fixed so that it can be rotated by a rotating support 55 located on the electrode lifting and folding

In the area of the unit 8 opposite the charge heater. In the opposite direction, the supporting structure of the rotating abutment is operated by a lifting unit consisting of one or more, preferably two, units, which are folded into the rotating abutment 55 and at the same time in relation to the furnace metal receiver 3. As the hunger actuates the lifting device 56, the shaft 10 and the lid 6 may lean out of the position in which they fit against the upper edge of the furnace metal receiver 3, closing the reservoir. When the supporting structure 27 is raised, the furnace metal receiver 3 can move the wheels 58 back and forth on the rails 58. At this famine, the furnace metal receiver 3 from the base position I, which in FIG. 5, shown in solid lines, can move to dotted position II on the left, and dotted lines to position III to the right of * \? Λ / base position. Correspondingly, the position of the metal receiver changes with respect to the shaft 10 as well. At the same time, various zones 3 of the furnace metal receiver may be intentionally connected to the shaft 10. When the furnace metal receiver 3 is in the home position, the heater 2 of the charging shaft 10 is positioned so that a charging column can be charged therein above the first zone of the furnace metal receiver. From this position, the furnace metal receiver may be displaced such that the shaft 10 is connected to a second zone of the furnace metal receiver 3 remote from the distance 6, in which position the furnace metal receiver 3 will be in position II. Due to the displacement of the furnace metal receiver resulting from the arrangement of the shaft 10 and the furnace metal receiver, the arc furnace charge material can be loaded directly into the furnace metal receiver, regardless of the respective technological mode or operating state.

In the opposite direction, we move C position III} so that the charge pole is drawn closer to the electrodes 9 on the left side of the metal receiver and quenches faster.

The typical process is described below. With the holding members 53 in the open position and when the shaft 10 is located above zone 3 of the first furnace metal receiver, a charging column may be charged through the shaft 10 during the melting phase. This arrangement corresponds to the basic arrangement 3 of the furnace 1 metal receiver. At the end of the melting phase, the charge column is molten and the charge heater is almost empty. Due to the junctions in the shaft 10, the jammed parts of the charging material column can be easily transported to the furnace metal receiver 3 by rotation of the support members 53 and consequent pressure on the charging material. To accelerate the melting process, the metal receiver 3 may move during charging of the charge column or later, in such a way that the charge of the charge column relative to the electrodes is reduced. This may, for example, cause the furnace metal receiver 3 to move to position III. In this way, the energy of the electric arcs can be purposefully used to melt the charge column.

Immediately after the melting of the charge column during the direct refining phase, no charge is added to the molten metal to obtain the molten metal having the required properties. According to FIG. In the melting unit 5, the charging material can be loaded into the shaft 10 when the holding members 53 are in the closed position. This charge is slightly heated during the refining phase from the furnace metal receiver to the shaft 10 with hot gas. The charge in the display can only be charged after the contents of the furnace metal receiver 3 have been released. In order to be able, FIG. Protect the furnace metal receiver 3 wall area shown in left-hand side 5 from overheating of the electrodes 9,

The charge of the shaft 10 is charged to the furnace metal receiver 3 when the furnace metal receiver 3 is displaced relative to the fixed shaft 10 which is connected to the left zone of the furnace metal receiver. This arrangement corresponds to FIG. 5, II. In addition, the heated charge material may bCtti be charged to the left area of the furnace metal receiver.

After being recharged to the left zone 3 of the furnace metal receiver, it is returned again, to FIG. 5, the holding members 53 are moved into the free position, whereby they do not prevent the continuous loading of the material through the shaft 10.

In this way, the charge inside the shaft can be heated during the refining phase. Because the lid 6 only needs to be lifted slightly during heating and charging to allow the furnace metal receiver to be pushed in, this guarantees no environmental contamination.

FIG. 6-12, in various embodiments of the invention and operating positions, the supporting structure of the shaft 10, to which the reservoir lid is removably attached, is fixed by brackets 59 on the fundamental posts 60 and on the electrode lifting and lowering device Cf. FIG. 8 and 93. The furnace metal receiver 3 is secured to the upper frame 61, which rests on the support frame 63 by the frame lifting device 62.

The support frame may move parallel to the connecting line between the centerline of the shaft and the centerline of the furnace base, i. y. parallel to the axis 22 93. For this purpose, the invention according to FIG. The wheels 6 are mounted on the left and right sides of the 6 supporting frames and run on rails

58.

As in the above embodiments, the furnace metal receiver may rotate about a transverse axis 22 connecting the middle line of the charge heater 2 to the center of the furnace base, namely to rotate the molten metal to one side near the furnace base flange 4. the opening 2i> o is turned to the other side where it is mounted, closed by a sliding door, a working opening 64 having a removable plate 65. To leave room for the bucket 66 during loading of the contents of the furnace metal receiver 3. 113, on this side the upper frame 61 is curved upwards to align the dotted line of FIG. 63. On the opposite side, due to the space occupied by the working opening 64, the upper frame 61 is inclined downwardly Align the dotted line of FIG. 63.

In order to leave space for the bucket 66 and the removable plate below, the support frame 63 of the slag conveyor, not shown in the drawing, also has a certain shape. As can be seen from FIG. 10, it has two parallel transverse beams 68 and 67 and an approximately median longitudinal beams 69 connecting them. The support rollers 57 are respectively mounted in the rear zones of the transverse support beams 68, two spaced apart support rollers 57 being provided. the rails for the rollers 57 of the transverse support beam 68 are also mounted in the middle so as not to interfere with either the bucket on one side or the slag transporter on the other. In the drawing shown, the frame lifting device 62 is comprised of lifting members 70, 71 arranged along the perimeter of the frame 61, namely a rectangular top view? in the corner corners of the frame.

The lifting elements consist of hydraulically operated piston-cylinder assemblies. However, they could also include other elements, such as a drive gear and a toothed belt or helical gear interacting with it. The lifting elements are provided on both sides of the axis 22 connecting the inner line of the charge material heater to the center of the furnace base, and in the example shown the lifting elements 71 on the discharge side may pivot about pivot axes 22 parallel to frame 61 and support frame 63. and at that time the lifting members 70 on the side of the slag removal Ckair fig. Side 8? has a vertical guide, and only the upper frame 61 is mounted to rotate on a pivot axis parallel to axis 22. The lifting elements 71 and the lifting elements 70 can operate synchronously. Due to the lowering of the synchronous lifting elements 71, the furnace metal receiver may be turned to one side and the synchronous lifting elements 70 to remove the slag may be turned to the other side. If all the lifting elements are lowered synchronously, the furnace metal receiver 3 will lower without turning. In the example shown, the lifting members 70 may be vertically raised due to the fact that the hydraulic cylinders are mounted in the pipes 72 rigidly connected to the support frame 63.

The following technological operations can be performed with the melting unit described.

After the release of the molten metal, Cfig. iID, this causes the lifting members 71 to be lowered and the furnace metal receiver 3 to be tilted about the stationary upper axis of rotation of the lifting members 70. The lifting members 71 are again raised to a position at a sufficient distance from the lower edge of the tank cover 6 to allow the furnace metal receiver 3 to move horizontally. In this position, the support frame from the position shown in FIG. 6, moves to the left until the entire reservoir is located either outside the shaft area 10 to allow direct loading of the charge from the scrap metal reservoir, or to FIG. 7 illustrates the positioning of the charge material from the charge material reservoir 73 through the shaft to the right, i.e. to the side of the metal receiver on the side of the electrode lifting device. This position of FIG. 9 is a dotted line. In this position, the environment is not polluted by the furnace gas flowing from the left side of the tank, here in the horizontal extension Cfig of the tank lid. 7 on the left} may be provided with a protective cover, not shown in the drawing, such as a cover mounted on the lower edge of the lid, cantilevered or otherwise

Λ / Λ / of sheet material. The furnace metal receiver then drills again in FIG. The starting position shown in Fig. 6 and Rise up enough to guarantee the desired closure between the furnace metal receiver and the tank cover. In this position, another Charger is fed through Shaft 10, and therefore

The shaft forms a scrap pillar that rests on the bottom of tank 1 in the left area of the tank wall. After

The shaft of the cross section shown in FIG. 6, has an aperture u shape, and which can move horizontally along rails 75, the lid closure is melted by another furnace charge.

and the resulting furnace gas warms up the scrap pillar. If the shaft 10 is provided with closing bulkheads as described in FIG. 5, including the Charged substance heated during the refining phase and retained in the Shaft 10 can be recharged at any desired location below the furnace metal receiver *

content release.

It goes without saying that the horizontal movement of the furnace metal receiver also allows the arc furnace electrodes to be brought closer to the arc during the melting process.

A column of charge material to accelerate the melting process. The resulting partial opening of the reservoir can be avoided because here too, the horizontal extension of the reservoir wick is provided with a guard Cfig. 7 on the left}.

Exhaust gas discharge during discharge Czr. FIG. 113 may be retarded, for example, by means of a circuit shield 76. However, the gas exiting during the inversion may also be suctioned by a suction hood.

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The structural position of the shaft 10 relative to the tank lid 6 does not mean that the shaft must be permanently fixed to the tank lid. In addition, it is desirable that the cover can be replaced if the cover fails. For this reason, the embodiment shown in FIG. 6-12, the reservoir lid 6 is detachably secured to the posts 60 of the shaft bearing structure 27 which rest on the base such that, after this fastening, the reservoir lid as shown in FIG. 12, may be lowered due to the synchronous lowering of the lifting elements, fitting to the upper edge of the reservoir, and protruding outside the shaft zone 10 together with the furnace metal receiver Cat.

on the left ?, and be removed or replaced with a crane.

Furthermore, in the example corresponding to FIG. i ~ 3, it is not necessary for the tank cover 6 to lean sideways with the shaft

10. It is sufficient if the shaft is secured to the supporting structure 27 and the reservoir cover 6 is secured by its own device, such as an electrode lifting device, which may be a folding device 8 and is pulled aside.

In addition, it is not necessary that, as shown in FIG. 6, the left wall of the shaft is in line with the tank wall below it. It may be slightly pulled in the middle of the lid. It is also important that, when charged through the shaft 10, the charging material may rest on the wall of the furnace metal receiver 5.

Claims (35)

DEFINITION OF INVENTION A melting unit with a tank furnace C 13 consisting of a furnace metal heater (3) consisting of a furnace base C 443 and a tank wall C53, as well as a tank cap C 63 and a furnace metal receiver in the form of a shaft-type charge heater On the side C 23, the inner cavity C 153, which in the area adjacent to the bottom C 133 joining zone C 173 is connected to the inner cavity of the arc furnace C 13, which also has a sealed charging port C 183 in the upper area for charging the substance; gas outlet C 193, also in view of the charge heater C23 in its lower zone up to the height of the upper edge of the metal receiver C33 of the furnace is made up of part C 153 of the reservoir wall and fixed in the zone above it to the supporting structure of shaft C 103 C 273, and that the bearing structure C 273 and the furnace metal receiver C33 can move relative to one another. 2. The melting assembly according to claim 1. , in addition to the fact that the support structure C 273 has a detachable tank cap C 63. 3. The melting assembly according to claim 1 or 2, characterized in that the bearing structure C273 lifting device Αχ Α » Αχ Ar C 23, 26, 563 may rise relative to the furnace metal receiver. 4. The melting assembly according to claim 1 or 2. , characterized in that the oven receiver C33 may be lowered relative to the supporting structure. The melting assembly according to one of claims i-4. , characterized in that the bearing structure C273 and the furnace metal receiver C 33 can move horizontally relative to each other. 6. The melting assembly according to claim 5. , also considering that the direction of horizontal displacement between each other is parallel to the line joining between the center of the tank cap C 63 and the center of the shaft C 103. 7. The melting assembly according to one of claims 1-6. characterized in that the shaft C 103 is fitted with at least one closure member C 513 such that it can move from the closed position where it forms a support for the charge to the open position or the unload position to the furnace metal receiver free passage of the charge through the shaft, it would be possible to charge the charge. 8. The melting assembly according to p. characterized in that the closing element C513 consists of at least one water-cooled roller C523 which is rotatably mounted and can start to rotate at least to one side and stop in a predetermined angular position; from this roller extends at least one row of commonly mounted cantilever bearing members C 533, in addition, the closed members C533 are arranged in a predetermined angular position where their free ends C53b protrude into the inner cavity of shaft C 103 and the open members are positioned in a prime position below the closed position, in a position such that the charge material can pass. 9. The melting assembly according to claim 8. , also considering that the bearing elements C 533 are water-cooled. 10. The melting assembly according to one of the claims 7-9, characterized in that, on the opposite sides of the shaft C 103, the rollers C 523 with supporting members C533 are mounted at the same height and their free ends C 53b are aligned in one line. some distance away from each other. 11. The melting assembly according to one of claims 1-10. characterized in that the top view3 of the metal receiver C33 C is made in the form of an oval bounded on one side by a straight line, and its straight wall section C i 13 together with the adjacent oval section C 123 form the outer walls of the charging material heater C 23 in the lower dal yj e. 12. The melting assembly according to claim 11. , also considering that the straight line delimits the oval between 3/4 and 9/10 of its length. 13. The melting assembly according to one of claims 1-12. This includes the fact that the walls of the shaft C 103 are made of water-cooled wall elements. 14. A melting assembly according to one of 1-13 Λ / * \ / Do Ar Characterized in that the cross-section of the inner cavity C153 of the shaft C 103 is downwardly expanding. 15. The melting assembly according to one of claims 1-14. , characterized in that, on the side of the tank cap C63 opposite the charge heater C 23, there is an electrode lifting device C 83 adjacent to the furnace metal receiver C 33. 16. The melting assembly according to one of claims 1 to 15, characterized in that on the side of the charge material heater C 23 there is a retractor C233 of the bearing structure C 273 of the shaft C 103 adjacent to the metal receiver C33 of the furnace. 17. The melting assembly according to one of claims 15-16. , also considering that the C273 retractor for the supporting structure is a lifting and folding device In the form of C233, this unit and the electrode lifting and folding unit may lean to the same side relative to the furnace metal receiver C33. 18. A melting assembly according to one of claims i-17. characterized in that a lifting device C 253 is mounted on the movable portal C 243 adjacent to the charge heater and which has at least one lifting and lowering support member C263 acting on the supporting structure C 273 or if the reservoir lid C 63 is attached to the edge of the cover C 273 of the supporting structure. 19. The smelting assembly according to claim 18; in that the support member C 263, when in the down position and disengaged from the toothed edge C 60 or the support structure C 270 and raised and inclined with the spring C280 in the shape of the support member, acts on the edge of the lid or bearing structure C 270. 20. The melting assembly according to one of claims 18-19. , also considering that the moving portal is in the form of a rotating portal C 240. 21. The melting assembly according to one of claims 1-20. , characterized in that the furnace metal receiver C 30 can be turned perpendicular to axis C 220, which connects the middle line of the charge material heater C 20 to the middle of the furnace base C 40. 22. Melting unit.-According to one of the claims 18-21. , characterized in that the retaining portal C240 is mounted on a stationary base. 23. The melting assembly according to one of claims 1-16. , characterized in that the mobile portal C240 has at least one reservoir lid C 60, a retaining support beam C 430 and lifting devices which can be detachably connected to the supporting structure C 270 or to the tank cover C60. 24. The smelting assembly according to claim 23; , also considering that the moving portal C 240 holds the electrode lifting and unfolding device C 80. 25. The melting assembly according to one of claims 1-24. This is due to the fact that the metal receiver C30 is attached to the upper frame C610 which rests on the support frame C 637 with the frame lifting device C620. 26. The melting assembly according to p. , and with that in mind so that the support frame C 637 can move. 27. The melting assembly according to claim 25 or 26. In particular, the frame lifting device C627 comprises at least two lifting members C 70,7 17 arranged along the perimeter of the frame C 617. 28. Melting unit according to p. , including that the lifting members' C70,717 are hydraulically or pneumatically actuated piston-ci1 open units. 29. The melting assembly according to one of claims 25 ~ 28. together with 24 p. In particular, the lifting members are disposed on both sides of the axis C 227 connecting the center line of the charge heater C 27 to the center line of the furnace base C 47, such that the lifting member or members are mounted on both sides of the frame C617. , as well as in the supporting frame C 637 and can rotate about its rotational axes parallel to the axis C 227 when the lifting element or the elements on the other side have a vertical bending C 727. 30. The melting assembly according to one of claims 25 to 29. characterized in that the support frame C637 has two parallel transverse support beams C 67, 687 and a longitudinal beam C 697 connecting them in the middle. 31. The melting assembly according to p. along with 21 p. , also considering that the longitudinal beam C697 is parallel to the axis C 227. 32. The melting assembly according to one of claims 27-31. , which is based on the fact that the frame C613 is made of a rectangular top and the lifting elements from above The C70, 717 are respectively fitted in the old corners of this frame. 33. The melting assembly according to one of claims 30-32. , characterized in that the support frame <633 has corresponding pivoting supports C573 with one transverse support beam C 673 in the end zones. and in another transverse support beam C 683 is in the middle zone. 34. The melting assembly according to one of claims 30-33. , characterized in that the frame on the outlet side of the C613 furnace metal receiver is curved upward and on the side of the opening for slag removal downwards. 35. A smelting assembly according to one of claims 25-34. , characterized in that the bearing structure C273 is stationary.