UA113346C2 - TURNER CONVERTER - Google Patents

Abstract

A rotary converter comprising a container (1) defining the first axis (X); a support ring (2) arranged coaxially with the receptacle (1) a certain distance from said receptacle and containing two loaded pins (3, 4) that are diametrically opposite, define a second axis (Y) perpendicular to the first axis (X), and made to allow the converter to rotate about said second axis; the first and second suspension assemblies connecting said vessel (1) to said bearing ring (2); in which at least one pair of first suspension units is made, each first suspension node having a central structure attached to the container (1); a first lateral structure disposed on the first side of said central structure and attached to the surface of the support ring (2); a second lateral structure located on the second side opposite said first lateral structure and attached to said surface of the support ring (2); wherein said first lateral structure and said second lateral structure respectively comprise two first supports (14, 15) spaced a certain distance from each other and a group of elastic beams (11) arranged adjacent and parallel to one another and supported by their ends the first two supports (14, 15) mentioned; and wherein said central structure includes a second support (12) disposed between the groups of elastic beams (11) of said first lateral structure across said first lateral structure and said second lateral structure. In one embodiment of the present invention, a third support (13) is located between the two first supports (14, 15).

Description

The field of technology

This invention relates to a rotary converter equipped with a converter container suspension system that connects said container to a support ring.

Technical level

Converters are rotary metallurgical units designed for the production or processing of liquid metals and metal alloys. The converter chamber rests on several suspension elements, which are located below or above the support ring and are attached at one end to the converter chamber and at the other end to the support ring.

The main purpose of the oxygen converter is to process pig iron produced in the blast furnace into unrefined liquid steel, which can then be refined in further stages of steel production. Converters can also be used, for example, for devanadation or dephosphorization of liquid hot metal to a state, for example, so-called semi-hot metal, which can be loaded into an oxygen converter for further processing.

The main purpose of such converters, which are referred to below as VOE converters (or basic steel melting furnaces with oxygen to the bath), is to decarbonize and remove phosphorus, vanadium, silicon, etc. from hot metal, liquid cast iron or liquid pre-molten metal and optimize the temperature of the steel so that further processing can be performed before the start of casting with minimal heating and cooling of the steel.

During the exothermic oxidation reactions that occur in the converter, a large amount of thermal energy is released - more than the energy required to reach a certain defined temperature of the steel. This excess heat is used to melt the scrap metal and/or added iron ore.

Since the VOE converter is essentially a furnace, it also undergoes significant thermal expansion. For this reason, the converter is surrounded by a support ring with a certain specified gap.

In addition to thermal loads, the connecting elements (suspension) are subject to high mechanical loads due to the weight of the equipment, and the mentioned mechanical loads vary depending on the angle of inclination of the converter chamber. This means that the elements of the suspension must be made in such a way as to ensure that these elements are not overloaded for any

From what angle of inclination.

In addition, these elements must be protected from spills of liquid steel or slag from the mouth of the converter.

There are several types of converter suspension systems available on the market today. One example of a known oxygen converter is described in OE190368582.

Said converter includes a container or chamber that defines the boundaries of the reactor, which is essentially cylindrical in shape and which rests on a support ring or a trunnion ring that surrounds the container and is located at a certain distance from it. The converter has two support axes ("pins"), which are located diametrically opposite each other, and the unit rests on two supports attached to the foundation. Control of container rotation is provided through one of these two pivots.

Said converter includes a suspension system based on plate elements to support the converter in a vertical position from within the support ring. The mentioned plate elements are located below the support ring, taking into account the vertical position of the converter with the neck facing up.

Support of the converter in a horizontal position when the converter is rotated -90 or -90 degrees relative to said vertical position is provided by rigid supports attached to the container and rigid supports attached to the support ring.

Another suspension for the converter is described in UUMO2008/092488. It includes plate elements for the suspension part and a rigid rod attached like a pendulum. This suspension is too stiff and creates problems in the dirty and hot environment where the converters operate.

MO2011/069395 describes a suspension made of locking mechanisms and pendulums. Its use is also problematic in a polluted and heated environment, and it is prone to rapid wear.

To avoid shock loads, additional contact elements between supports on the tank, as well as on the support ring, must be located and adjusted to avoid gaps.

However, any temperature differences in these additional elements can cause additional loads on the suspension elements.

Based on this, there is a need to create a rotary converter that provides 60 the ability to overcome the above-mentioned disadvantages.

The essence of the invention

The main purpose of the invention is to create a suspension for a rotary converter container, which connects the mentioned container with a support ring and provides the possibility of avoiding both shock loads and overloads in the zones between the part of the suspension attached to the container and the parts of the suspension attached to the support ring, and also provides the ability to compensate for thermal expansion, ensuring reliable operation and reduced wear in contaminated and hot environments.

Another goal of the invention is to create a converter with a suspension system capable of absorbing vibrations caused by the melting process.

So, in this invention, the above-mentioned goals are achieved due to the creation of a rotary converter, which according to clause 1 of the claims of the invention includes: a capacity that defines the first axis (X); a support ring located coaxially with the container at a certain distance from the said container and includes two support pins that are located diametrically opposite each other, define a second axis Y, perpendicular to the first axis X, and are designed to provide the possibility of turning the converter around the mentioned the second axis; at least one pair of first suspension nodes and a plurality of second suspension nodes that connect said container to said support ring; in which said second suspension nodes are lamellar suspension elements connected as a single unit and attached from its first end to the container (1) and from its second end to the support ring, and in which each first suspension node includes - the central structure attached to the container or to the support ring, - the first side structure, located on the first side of the mentioned central structure and attached to the surface of the support ring or to the container, - the second side structure, located on the second side of the mentioned central structure, located opposite the mentioned first side, and attached to said surface of the support ring or to the container similarly to the first side structure, in which said first side structure and said second side structure, respectively, include two first supports located at a certain distance from each other, and a group of elastic elements that are located adjacent and parallel to each other and rest with their ends on the memory or two first supports, and wherein said central structure includes a second support located between groups of spring beams of said first side structure across said first side structure and said second side structure, said spring beams acting as a spring support for said second support in in case of deviation from the neutral position.

The suspensions according to the present invention are designed to support the converter in a horizontal position, that is, to accept loads when the converter assumes a horizontal position (for example, to release melting, etc.). Due to the fact that part of the horizontal loads (approximately 20-30 95) are perceived by the plate elements, which mainly perceive the load from the converter in the vertical position, the horizontal suspension can be designed with smaller component elements.

Due to the fact that the gaps between the elastic beams and the second supports, as well as the elasticity of these elastic beams can be selected by the designer of the suspension system, there are different possible load schemes: - 3 with low elasticity (very stiff beams) and also without gaps between the elastic beams and the second support - horizontal suspension units work almost like rigid supports; - with high elasticity of the elastic elements and large gaps between the elastic beams and the second supports - the suspension system is "soft", and the load is perceived mainly by the two lateral elements of the first supports.

The suspension system can be optimized so that the design thermal expansions of the second supports attached to the container casing are identical to the gaps between the elastic beams and said second supports. This means that thermal expansion is compensated by this gap to avoid overloads, and then all elements are in full contact with each other.

In addition, due to the change in elasticity of the elastic beams, the distribution of loads between the second side supports and the possible third middle support can also change. Beams can have a rectangular or square shape with appropriate dimensions. In the description and in the claims, they can be called beams or plates, without limiting the scope of the present invention. because Yes, the horizontal units of the converter suspension according to this invention have the following advantages:

- ensuring the possibility of easy absorption of thermal expansion of the capacity due to the use of the advantage, which is provided exclusively by the elasticity of the mentioned elastic elements; - enabling thermal expansions, including variables, of the structure without overloading the structural elements; - effective absorption of vibrations that occur during the supply of oxygen to the container; - effective perception of the forces that arise due to the inertia of the container during the beginning and end of its rotation; - storing the centering of the container relative to the support ring with high accuracy in all tilt conditions; - extreme ease of assembly; - suitability for converters of all sizes.

The high accuracy of the centering of the container relative to the support ring allows the thermal expansion of the container, caused by high temperatures in the conversion process, without contact between the container and the support ring.

Another advantage is that the structure of the converter, including the protrusions, is designed so that the converter is inscribed in a sphere whose radius is determined by the requirements for the structure of the equipment that includes the converter.

The dependent clauses correspond to preferred embodiments of the present invention.

Brief description of figures

The features and advantages of the present invention will become clear from the detailed description of the oxygen converter embodiments, which are preferred, but which are not exclusive, and which are illustrated only as non-limiting examples with the help of the accompanying drawings, in which in fig. 1a shows a side view of the first embodiment of the converter according to this invention in a vertical melting position; in fig. 165 shows a top view with a local section of the converter shown in fig. And; in fig. 2a shows a side view of the second embodiment of the converter according to the present invention in a vertical melting position; in fig. 25 shows a top view with a local section of the converter shown in fig. Ha;

From in fig. C shows a local section of a part of the converter, made in the plane marked B-

In fig. 16 and fig. 20; in fig. 4 shows a local side view of a portion of the converter shown in FIG. 26; in fig. 5 shows a top view with a local section of a part of the converter shown in fig. 4;

The same elements or nodes are marked on the figures with the same item numbers.

A detailed description of preferred embodiments of the present invention

The figures show preferred versions of the oxygen converter.

Said converter includes: - a container 1, or chamber that defines the X-axis, has a loading nozzle 7 for scrap metal and liquid hot metal, liquid cast iron or liquid pre-molten metal, and also has a side flap (not shown) for liquid steel, obtained at the end of the conversion process; - the support ring 2, designed to support the container 1, and the said ring 2 is located coaxially with the container 1 at a certain proper distance from it; - two support trunnions 3, 4, or pivot axes, of the mentioned support ring 2, or "trunnions", which are located diametrically opposite each other and define the Y-axis, perpendicular to the X-axis, and at least one of the mentioned support trunnions is connected to the turning mechanism (not shown); - the first and second nodes of the suspension, which connect the container 1 with the support ring 2, and also perform the centering function between the container and the ring.

The first suspension nodes are designed to form a horizontal support of the converter when the container is turned at an angle of up to 90 or -90 degrees relative to the position shown in fig. and or 2a.

The second suspension nodes are designed to form a support that receives the loads that act on the converter in a vertical position, that is, in a position when the neck 7 of the container is turned up (Fig. 1a or Fig. 2a). Due to their design and location, the second suspension nodes take part of the load from the converter when it is turned at an angle of 90 or -90 degrees relative to the position shown in fig. 1a or fig. 2a, which allows to reduce the size of the first nodes of the suspension. because if we define the additional axis 24 as an axis that is perpendicular to the X-X plane and passes through the point of intersection of the X and MU axes, then the formed plane U-7, which can be considered the "equatorial" plane of the converter, and the formed plane X-7 are planes , perpendicular to the X-Y plane.

The container 1 has a cylindrical central part and two parts made in the form of a truncated cone, and both parts made in the form of a truncated cone are located on both sides of said cylindrical central part. The first part, made in the form of a truncated cone, is welded or otherwise immovably attached to the mentioned cylindrical central part on one end, and on the other end it has a loading neck 7 of the container. The second part, made in the form of a truncated cone, is welded at one end or fixedly attached in another way to the mentioned cylindrical central part on the opposite side relative to the first part, made in the form of a truncated cone, and the bottom of the container 1 is located on the other end. According to other examples, the container can have said second part of another shape different from the shape of a truncated cone, for example, a spherical cup-shaped or other suitable geometric shape.

The support ring 2, located in the central part of the container 1, is hollow and preferably has a rectangular cross-section. The ring 2 has the first surface 20 facing the part of the container in which the loading neck 7 is located; the second surface 21, opposite to the first surface 20, facing the part of the container 1 in which its bottom is located; the third inner surface facing the central part of the container; and a fourth outer surface opposite the inner surface.

According to an option that provides certain advantages, the converter includes at least two first suspension nodes designed to form a horizontal support of the converter. The mentioned first suspension units are located essentially parallel to the U-2 plane, essentially perpendicular to the U-X plane, and are located essentially symmetrically relative to the X-2 plane below (Fig. 1a) or above (Fig. 2a) the support ring 2. In one from the execution options (not shown), the converter includes two pairs of first suspension nodes: the first pair of first suspension nodes is located on the first side of the U-7 plane, and the second pair of first suspension nodes is located on the second side of the U-7 plane.

Said first suspension assemblies include (as shown in particular in Fig. 4 and Fig. 5):

Zo - the central structure, attached, for example, by welding to the capacity 1 of the converter; - the first side structure, located on the first side of the mentioned central structure and attached, for example, by welding to the surface 20 or the surface 21 (fig. Ta or fig. ha) of the support ring 2 of the container 1; - the second side structure, located on the second side of the mentioned central structure opposite the mentioned first side structure and attached, for example, by welding to the mentioned surface 20 (fig. 2a) or to the mentioned surface 21 (fig. Ta) of the support ring 2.

The first and second side structures are located essentially symmetrically with respect to the central structure.

According to a variant that provides certain advantages, each side structure includes two first supports 14, 15, located at a certain distance from each other, and a group of elastic beams 11, which are located adjacent and parallel to each other and rest with their ends on the mentioned two first supports 14, 15. In addition, the central structure includes a second support 12 located between two groups of elastic beams 11 of the mentioned side structures, in the transverse direction, and the elastic beams 11 act as an elastic support or shock absorber for the second support 12 in case of deflection from the neutral position, which is considered to be the position of the converter with the neck turned up (Fig. and Fig. 2a). If necessary, elastic beams can be made in the form of plates, for example, rectangular, the thickness of which is much less than the other two dimensions.

All the first suspension nodes, or horizontal suspension nodes, are located on the corresponding loaded trunnion 3, 4 in the transverse direction to the X-Y plane.

The second support 12 of each first suspension unit is essentially parallel to the surfaces 20, 21 of the support ring 2 and essentially perpendicular to the corresponding groups of elastic beams 11. Therefore, the beams 11 are located perpendicular to the surfaces 20, 21 of the support ring 2. In an embodiment of the present invention, which is preferred, elastic beams 11 are made in the form of metal plates.

The elastic beams 11 of each group are located next to each other and are freely installed between the first supports 14, 15 and the mechanical stops 16 and 17. The mechanical stops 16 and 17 are located, for example, near the ends and/"or on top of the elastic beams 11 and partially overlap the outer surfaces supports 14 and 15. because Beams 11 are located more or less freely, providing the possibility of any deformation.

Therefore, the beams 11 are not rigidly fixed, but only held in place by mechanical stops 16 and 17. This feature provides maximum elasticity and avoidance of additional stresses caused by the limitation of thermal expansion. This feature also provides an additional advantage, which is that these elastic beams 11 can be replaced or adjusted after a certain period of operation to change or adjust the mechanical characteristics of the shock absorber.

The said elastic beams 11 of each group in the position of the converter with the neck 7 turned upwards are located with a gap relative to the corresponding second support 12 or are located in direct contact with the corresponding mentioned second support 12. In both cases, the thermal expansion of the supports 12 attached to the outer shell of the container, is compensated by the elastic deformation of the mentioned elastic beams 11.

According to the variant, which provides certain advantages, and which is shown in detail in fig. 5, the second supports 12 have a base 22, adjacent to the converter casing, and a head 23, the shape of which ensures its location in the space between two groups of elastic beams 11.

The second supports 12 have side surfaces 24 of the head 23, which have a convex shape and are made in such a way as to ensure the possibility of entering into contact with at least one of the corresponding groups of elastic beams 11. To ensure the movement of the supports 12 attached to the converter chamber in three directions under the conditions operation, the contact zone of the mentioned support surface 12 with the beams 11 has a spherical shape, and according to the preferred option, a spherical cup-shaped shape. Therefore, supports 12 can move in directions parallel to three axes: X, Y and 2.

The support on the support ring 2 of the converter is made in the form of two supports 14, 15 - one from each end of the elastic beams 11 - which are constantly in contact with the mentioned elastic beams 11.

In the embodiments shown in fig. 4 and fig. 5, the third support 13 is made in both side structures and is located between the two first supports 14, 15. According to the preferred variant, the third support 13 is located parallel and in the middle relative to the two corresponding first supports 14, 15.

Every third support 13 in the position of the converter with the neck 7 turned upwards is, according to the preferred option, located with a gap relative to the corresponding group

From the elastic beams 11. When the elastic beams 11 are deformed by the load from the converter capacity during tilting, the middle support 13 comes into contact with the elastic beams 11 at a certain defined angle of inclination, limiting the deformation of the elastic beams 11 and taking over part of this load.

Alternatively, every third support 13 is in direct contact with the corresponding group of elastic beams 11 also in the neutral position. In this case, it is possible to obtain a more or less rigid structure or a non-rigid structure depending on the specific structure.

According to another variant of the implementation of the present invention (not shown in detail), acceptable, for example, in converters of reduced size, the need for the third supports 13 is eliminated, and therefore the mentioned supports 13 are not provided.

In all embodiments of the invention shown in the figures, the formed groups of vertical nodes of the suspension are located essentially at the same distance from each other around the circumference of the support ring 2 and include plate elements 9 of the suspension, in which the plates 10 are connected as a single unit and attached from its first end to container 1, and from its second end to support ring 2.

Alternatively, the mentioned groups of vertical suspension nodes include elastic rods (not shown), and said rods are inseparably connected at the first end to the container 1, and at the second end - to the support ring 2.

Each horizontal suspension node is located between two corresponding groups of vertical suspension nodes directly under the support ring 2 (fig. 1a, fig. 15) or is located between two corresponding groups of vertical suspension nodes in the projection zone above the support ring 2 (fig. 2a, fig. 25 ).

Two support pins 3, 4, which actuate at least one turning mechanism, provide the ability to turn the converter around the U axis.

The converter, as a rule, is turned from the first position, in which it is vertical with the loading neck 7 turned upwards (Fig. 1a or Fig. 2a), to the second position, inclined at an angle of about 30" relative to the vertical axis, by turning the support pins 3 , 4 in the first direction of rotation. In this second position, liquid iron and scrap metal are loaded through the opening 7. After loading, the converter is returned to the first position shown in Fig. Ta. One or more oxygen jets introduced into the container through the opening 7, provide(s) a supply of oxygen for a predetermined period of time, significantly reducing the carbon content and reducing the concentration of undesirable impurities such as sulfur and phosphorus.

After the conversion to unrefined liquid steel is complete, the converter is moved from the first position shown in FIG. 1a, to the third position, inclined at an angle of up to 90" or -907 relative to the vertical axis, by turning the support pins 3, 4 in the second direction of rotation, opposite to the first. In this third position, through the discharge hole (fly) in the converter tank, liquid is usually released became

In all embodiments of the present invention, the load determined by the sum of the weight of the container 1, the weight of liquid cast iron and scrap metal is transferred to the foundation by means of the support ring 2, horizontal and vertical suspension nodes, pivot axes 3, 4 and the corresponding supports.

In particular, the structure of the horizontal and vertical nodes of the suspension provides the possibility of perceiving the mentioned weight at any inclination of the container 1.

Vertical suspension assemblies act essentially as, for example, connecting rods at an angle of inclination of the converter relative to the vertical axis equal to 0". On the other hand, they act exclusively as struts at an angle of inclination equal to 180", and partially act as , such as connecting rods, and as struts at angles other than 0" or 1807.

The position in which the angle of inclination is equal to 180", that is, with the neck 7 turned downwards, is provided for draining the slag, cleaning the container after discharge or for other purposes (for example, storing the hot state of the converter).

Horizontal suspension units provide optimal support, stability and rigidity of the container. The aforementioned horizontal suspension nodes serve in principle to accept the weight of the container in the direction that crosses the Y axis when it is tilted at an angle of 90 or -90" (release position), as well as to accept the component of the load perpendicular to the X axis of the converter in any - in any other state.

So, in general, the load on the vertical suspension nodes gradually changes from a certain maximum value when the converter is in a vertical position to a certain minimum value when the converter is in a horizontal position. At the same time

The load on the horizontal nodes of the suspension gradually changes essentially from zero to a certain maximum value when the converter moves from a horizontal position to a vertical position.

The moments generated during the rotation of the converter around the Y axis are perfectly perceived by the described horizontal and vertical suspension nodes.

In an alternative embodiment of the present invention (not shown), the only difference compared to the above-mentioned embodiments is that the first suspension nodes include: - a central structure attached, for example, by welding, to the surface 20 or the surface 21 of the support ring 2 containers 1; - the first side structure, located on the first side of the mentioned central structure and attached, for example, by welding, to the capacity 1 of the converter; - the second side structure located on the second side of the mentioned central structure opposite the mentioned first side structure and attached, for example by welding, to the mentioned container 1.

Also in this case, the first and second side structures are located essentially symmetrically with respect to the central structure.

Claims (12)

FORMULA OF THE INVENTION 1. A rotary converter, which includes: a container (1) that defines the first axis (X), a support ring (2), located coaxially with the container (1) at a certain distance from said container, and which includes two loaded trunnions (3, 4) which are diametrically opposite and define a second axis (Y) perpendicular to the first axis (X) and are designed to allow the converter to rotate around said second axis, at least one pair of first suspension nodes and a plurality of second nodes suspensions that connect said container (1) to said support ring (2), in which said second suspension units are suspension plate elements (9) connected as a single unit and attached at its first end to the container (1 ), and from its other end - to the supporting ring (2), (c; in which each first suspension unit includes: - a central structure attached to the container (1) or to the support ring (2), - a first side structure located on the first side of said central structure and attached to the surface of the support ring (2) or to the container (1), - a second side structure located on the second side of the mentioned central structure, located opposite the mentioned first side, and attached to the mentioned surface of the support ring (2) or to the container (1) similarly to the first side structure, in which the first mentioned the lateral structure and the mentioned second lateral structure respectively include two first supports (14, 15) located at a certain distance from each other and a group of elastic elements (11) which are located adjacent and parallel to each other and rest with their ends on the mentioned two first supports (14, 15), in which said central structure includes a second support (12) located between groups of elastic elements (11) of said first side o structure across said first side structure and said second side structure, in which the elastic elements (11) of each group are located next to each other and are freely installed between the two first supports (14, 15) and the mechanical stops (16, 17), and in position of the converter with the neck turned upwards, are located with a gap relative to the corresponding second support (12), and said elastic elements (11) act as an elastic support for the second support (12) in case of deviation from the neutral position. 2. Rotary converter according to claim 1, which differs in that all mentioned first suspension nodes are located near the corresponding loaded trunnion (3, 4) transversely to the first plane X- IN. 3. Rotary converter according to claim 2, which is characterized in that the elastic elements are elastic beams (11), and the second support (12) of each first suspension unit is essentially parallel to the mentioned surface of the support ring (2) and essentially perpendicular to the corresponding groups of elastic beams (11). 4. A rotary converter according to any of the previous items, characterized in that in said first side structure and in said second side structure, a third support (13) is provided, which is located between the two first supports (14, 15). 5. Rotary converter according to claim 4, which is characterized by the fact that the third support (13) is located parallel and in the middle relative to the mentioned two first supports (14, 15). 6. Rotary converter according to claim 5, characterized in that the third support (13), in the position of the converter with the neck facing up, is located with a gap relative to the corresponding group of elastic beams (11) or is in direct contact with said corresponding group of elastic beams (11). 7. A rotary converter according to any of the previous points, characterized in that each of the second supports (12) has side surfaces that have a convex shape and are designed to be brought into contact with at least one of the corresponding groups of beams (11). 8. Rotary converter according to claim 7, which is characterized by the fact that the contact zone of the mentioned side surfaces with elastic beams (11) has a spherical cup-shaped shape. 9. A rotary converter according to any of the previous points, which is characterized by the fact that the mentioned first suspension nodes are located symmetrically with respect to the third plane X-7 below or above the support ring (2) and are located parallel to the second plane U-7, perpendicular to the first axis X , where 7 is an axis perpendicular to the first X-Y plane and passes through the point of intersection between the first X axis and the second Y axis. 10. Rotary converter according to claim 9, which is characterized by the fact that in this rotary converter two pairs of first suspension nodes are made, and the first pair of first suspension nodes is located on the first side of the second plane of MU-7, and the second pair of first suspension nodes is located on the second side of the second plane U-7. 11. The rotary converter according to any of the previous items, which is characterized by the fact that said second suspension units are installed in groups located essentially at the same distance from each other around the circumference of the support ring (2). 12. Rotary converter according to claim 11, which is characterized by the fact that each first suspension node is located between two corresponding groups of second suspension nodes directly under the support ring (2) or in the projection zone above the support ring (2).