EP0001380A1 - Large volume pig-iron mixer - Google Patents

Abstract

In the case of a pig iron mixer which can be rotated or tilted and has a cylindrical mixer chamber (3) arranged horizontally and having end walls (4, 5), the mounting is carried out relative to the foundation by means of a fixed bearing (12) and a floating bearing (11, 11 '). In order to reduce the frictional force moments acting in the bearings to a fraction, approximately 1/10, of the moments that occur in pig iron mixers with conventional bearings, the mixer chamber (3) is by means of two aligned support pins (9 , 9 ', 10, 29), one of which is supported in the floating bearing (11, 11') and one in the fixed bearing (12), is supported on the foundation.

Description

The invention relates to a rotatable or tiltable mixer provided with a refractory lining, in particular a large pig iron mixer, with a horizontally arranged cylindrical mixer chamber which has end walls and is mounted on the foundation by means of a fixed and a floating bearing.

It is known Hoheisenmischer with two spaced apart on the jacket of the mixer chamber attached tracks, one of which is mounted in a movable bearing a in a fixed bearing and the other on the support undament ^f. The raceways are mounted on rollers, the rollers being guided by means of cages movable between the foundation and the raceways. In order to achieve a synchronous movement of the rollers on the fixed bearing side with those on the floating bearing side, i.e. in order to avoid tilting or moving the pig iron mixer to one side, the cages of the floating and fixed bearings must be connected to one another by cross connections that are parallel to the longitudinal axis of the vessel. A plurality of X-shaped struts were used as such connections. Despite these struts, it was not possible in practice to really synchronize the rollers of the floating bearing with those of the fixed bearing because of differences in lubrication and thermal stresses during charging and removal, as well as due to uneven friction, relative movements between the rollers of the fixed - and movable side could not be completely ruled out. There always had to be a play between the roller cages and the rollers, so that an inclination of the rollers and thus wandering and inclination of the vessel was unavoidable despite cross struts. Tilting the vessel or the rollers could lead to self-locking of the rollers, so that the vessel could no longer be moved by means of a tilt drive. As a result of the line contact between the rollers and the raceways, a vessel that had once been tilted could no longer slide back into its normal position. In fact, it happened that in the case of cast iron mixers with roller bearings, the vessel was noticeably inclined over a period of several months and had to be pushed back into the normal position with large hydraulic presses.

In order to avoid these disadvantages and difficulties, the floating bearing and the fixed bearing were designed as slide bearings according to a proposal, the raceways resting on curved slide tracks formed from a plurality of slide plates. This gives rise to the difficulty of letting the slide plates rest against the arcuate slideways with a certain pressure, i.e. to set a certain pressure distribution over the length of the slideways. Especially if the slideways deviate from the ideal shape of a circular arc - which is practically often the case due to manufacturing inaccuracies and deformations during the operation of a pig iron mixer - not all glide plates contribute to the load bearing, i.e. some glide plates are subject to premature wear and others between them Sliding plates are hardly worn. Another difficulty can be seen in the fact that even with ideally circular-arc-shaped slideways, the adjustment of the glide plates to the shape of the slideways is only laborious and time-consuming.

To further improve and design the storage of pig iron mixers, it has been proposed to hydraulically support the slide plates. The implementation of this proposal requires a correspondingly complex construction.

If one wishes to use the above-described bearing constructions for large-scale rotatable or tiltable pig iron mixers, the mixer chambers of which have a diameter of about 10 to 15 meters, it turns out that the moments caused by the frictional forces and the axis of rotation or tilting that the Counteract movement of the mixer chamber, become very large. Even with the most careful storage in accordance with the suggestions described above, it is unavoidable that a high power component has to be applied by the drive motors solely for overcoming the bearing frictional forces acting on the circumference of the mixer chamber. Large-scale pig iron mixers also experience an increase in friction because the manufacture of the roller or slideways with a large diameter can no longer be carried out with the narrow tolerances required for exact storage.

This high "friction power component" must also be taken into account when dimensioning the gearbox, so that from a certain mixer size the entire drive must be designed for a proportionally high friction power component in relation to the weight-based and inertia-related power component.

A further disadvantage of the known mixer positions is that the manufacture and control (such as, for example, the measurement) of the roller or slideways arranged on the circumference of the mixer chambers is time-consuming and costly. In addition, the slideways are directly exposed to the changes in shape caused by deformation of the mixer chamber during the operation, whereby the bearing-friction ratios, especially in the case of mixers with very large diameters, deteriorate.

The invention aims to avoid these disadvantages and difficulties and has as its object to provide a mixer of the type described in which the proportion of the drive power which is necessary to overcome the frictional forces is substantially reduced, so that one is able to also produce large-scale pig iron mixers, the drive gear and drive motors of which can primarily be dimensioned according to the weight and moment of inertia of the pig iron mixer, ie in other words, their bearing frictional torque moments to a fraction, about 1/10, which can be reduced in the case of pig iron mixers with conventional bearings.

According to the invention, this object is achieved in that the mixer chamber is supported on the foundation by means of two aligned trunnions which engage on its end walls, one of which is mounted in the floating bearing and one in the fixed bearing. This makes it possible to arrange the bearing elements which cause the friction when the mixer tilts much closer to the axis of rotation or tilting axis of the mixer, so that the moment caused by these forces is also substantially reduced. Another advantage is the fact that the bearing parts are manufactured much easier and more precisely because of the greatly reduced bearing diameter can be. Due to the arrangement of the bearings on the end walls of the mixer, deformations of the mixer walls have no significant influence on the frictional conditions of the bearing.

Preferably, the trunnions are either attached to the end walls of the mixer chamber in a rotationally fixed manner and rotatably mounted with respect to the foundation, or are rotatably fixed with respect to the foundation and rotatably supported with respect to the mixer chamber.

The axes of the support pins are advantageously arranged eccentrically to the axis of the mixer chamber.

According to a preferred embodiment, the end walls of the mixer chamber are provided with reinforcing ribs which extend radially from the supporting pins to the periphery of the mixer chamber, the mutually opposite reinforcing ribs expediently being connected by means of longitudinal ribs running parallel to the axis of the mixer chamber and resting on the jacket of the mixer vessel Force transmission of the forces into the trunnions or rings fastened to the end walls is achieved.

It has proven to be advantageous if plain bearings are provided as bearings.

An advantageous type of drive is characterized in that at least one support pin is provided with a gear wheel of a tilting drive, whereby it is possible to arrange all drive elements outside the danger zone of the mixer.

According to another advantageous embodiment, the tilt drive has at least one drive element acting on the jacket of the mixer chamber, it being expedient if two pinions are provided as the drive element, which engage in a drive shaft mounted on the jacket of the mixer chamber and can be driven via a power-branching gear.

The invention is explained in more detail with reference to the drawing of several embodiments in a schematic representation, wherein Fig. 1 is a side view, Fig. 2 a along the line II - II of Figure 1 guided sectional view. and FIG. 3 shows a detail in section, along the line III - III of FIG. 2, on an enlarged scale according to an embodiment of the invention. FIG. 4 shows a modified embodiment of the invention in the cash position analogous to FIG. 3. 5 shows a further embodiment of the invention in the same way as in FIG. 1; FIG. 6 shows a section along the line VI-VI of FIG. 5. 7 and 8 show a further embodiment of the invention, with FIG. 7 likewise in an analogous manner. 1 is a side view and FIG. 8 is an end view in the direction of arrow VIII of FIG. 7.

1 with the cylindrical jacket of a mixer chamber 3 of a large-capacity pig iron mixer, which can be rotated or tilted about the horizontal axis 2 and is provided with a refractory lining, which is closed off by end walls 4 and 5 which are cambered outwards. A filling opening 6 and a pouring spout 7 are provided on the circumference of the mixer chamber. The mixer chamber 3 can also be equipped with heating devices, which are not shown. Concentric to the tilt axis 2, which is arranged eccentrically to the cylinder axis 8 of the mixer chamber by the amount "e", supporting pins 9, 10 are provided on the end walls 4, 5, of which the supporting pin designated 9 in a floating bearing 11 and the one with 10 designated trunnion is stored in a fixed bearing 12.

According to the embodiment shown in more detail in FIG. 3, the support pins 9, 10 are rigidly attached to the end walls 4, 5 and are mounted in slide joint bearings 11, 12, each of which is inserted into a foundation support 13, 14. In Fig. 4 an embodiment is shown in which a support pin 9 'is immovably attached to the foundation support 13 and with its end facing the end wall 4 via a slide joint bearing 11' in a bearing receiving ring 15 which rigidly fastens to the end wall 4 , for example is welded, is stored. In both embodiments, one of the two sliding joint bearings is a fixed bearing and the other executed as a floating bearing. To determine the weight of the amount of pig iron present in the pig iron mixer, the bearings can be placed on load cells or the load cells can be provided within the sliding joint bearings in such a way that the sliding elements of the bearings are equipped with load cells. Instead of the slide joint bearings, other bearings, for example roller bearings, can also be provided.

To reinforce the walls of the mixer chamber 3, reinforcing ribs 16, 17 are provided on the end walls 4, 5 of the support pins 9, 10 and extend radially to the periphery of the mixer chamber, the mutually opposite reinforcing ribs 17 of the two end faces, which are directed toward the underside of the mixer chamber , are connected by means of longitudinal ribs 18 which are parallel to the axis 8 of the mixer chamber 3 and support the cylindrical jacket 1 of the mixer chamber. This forms a type of support cage that reinforces the mixer chamber walls.

According to the embodiments shown in FIGS. 1 to 4, a rack mechanism is provided for the tilt drive of the pig iron mixer, wherein the drive blocks 19 are mounted concentrically to the tilt axis 2 on flanges 20 fixed centrally on the cylindrical jacket 1. The drive motor, together with the reduction gear, is combined to form a structural unit 21 located below the mixer chamber 3 and thereby protected by the mixer chamber 3. The reduction gear is designed as a power-branching gear for driving two pinions 22, 23 which mesh with the drive sticks and which are arranged at a distance from one another in the circumferential direction of the mixer chamber. The drive has an emergency drive motor, not shown.

The embodiment shown in FIGS. 5 and 6 differs from the embodiment shown in FIG. 1 with regard to the design of the drive. A power-branching gear 24 is provided as the drive, by means of which two pinions 25, 26, which engage in two drive rods 27, 28 arranged in the region of the end walls 4, 5 on the casing 1 of the mixer chamber, are driven.

With this arrangement of the drive rods 27, 28 and the pinion 25, 26, it is possible to introduce the forces which are necessary for the tilting of the vessel near the bearings of the mixer chamber 3, thereby reducing the risk of the mixer chamber tilting during the tilting is reduced compared to a drive acting closer to the center of the mixer chamber. Here, too, the drive is arranged below the mixer chamber to save space.

7 and 8 show a further possibility of a particularly expedient embodiment of a drive for a mixer according to the invention. After that, one of the. Support pin, preferably the support pin 29 mounted in the fixed bearing 12, which is connected to the end wall 4 in a rotationally fixed manner, extends beyond the foundation support 13 and is connected in a rotationally fixed manner to a large gear wheel 30. Four large pinions 31 arranged around the circumference thereof engage in the large gear 30, each of which can be driven by its own drive motor. The gear housing 33 is overhung on the trunnion 29 and is supported with respect to the foundation 34 by a torque support, which is designated by 35. This configuration of the mixer drive offers the advantage that the drive parts can be accommodated outside the "hot zone" and thus outside the danger area of the mixer.

The mixer vessel according to the invention can also be used with other drives e.g. be provided by a rack acting on the jacket of the mixer chamber.

Claims (10)

1. With a fireproof lining, rotatable or tiltable mixer, in particular large pig iron mixer, with a horizontal end wall with cylindrical mixer chamber, which is mounted on the foundation by means of a fixed and a floating bearing, characterized in that the mixer chamber (3 ) by means of two aligned trunnions (9, 9 ', 10, 29) engaging on their end walls (4, 5), one of which is mounted in the floating bearing (11, 11') and one in the fixed bearing (12), on Foundation is supported. 2. Mixer according to claim 1, characterized in that the support pins (9, 10) on the end walls (4, 5) of the mixer chamber (3) are rotatably mounted and rotatably mounted relative to the foundation (Fig. 3). 3. Mixer according to claim 1, characterized in that the supporting pins (9 ') are fixed in terms of rotation relative to the foundation and are rotatably mounted with respect to the mixer chamber (Fig. 4). 4. Mixer according to claims 1 to 3, characterized in that the axes (2) of the support pins (9, 9 ', 10, 29) to the axis (8) of the mixer chamber (3) are arranged extremly. 5. Mixer according to claims 1 to 4, characterized in that the end walls (4, 5) of the mixer chamber (3) are provided with reinforcing ribs (16, 17) extending radially from the support pins to the periphery of the mixer chamber. 6. Mixer according to claim 5, characterized in that the mutually opposite reinforcing ribs (17) by means of parallel to the axis (8) of the mixer chamber, connected to the jacket of the mixer vessel longitudinal ribs (18) are connected. 7. Mixer according to claims 1 to 6, characterized in that slide bearings (11, 11 ', 12) are provided as bearings. 8. Mixer according to one of claims 1 to 7, characterized in that at least one support pin (29) with a gear wheel (30) of a tilt drive (31 to 34) is provided (Fig. 7, 8). 9. Mixer according to one of claims 1 to 7, characterized in that the tilt drive has at least one on the jacket (1) of the mixer chamber engaging drive element (Fig. 1, 2, 5, 6). 10. Mixer according to claim 9, characterized in that two pinions (22, 23; 25, 26) are provided as the drive element, which engage in a drive shaft (19; 27, 28) mounted on the casing (1) of the mixer chamber (3) and can be driven via a power-branching gear (21, 24).

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