ROLLER FOR DEFLECTING OR GUIDING A METAL STRIP TO BE COATED IN A METAL MELT BATH

Abstract

A roller may be used to deflect or guide a metal strip to be coated in a metal melt bath. The roller may comprise a steel roller shell and steel bearing journals that are connected to the roller shell and arranged coaxially to each other for a rotary supporting of the roller. Disposed on each bearing journal may be a substantially cylindrical or circular disk-shaped connection portion that is made of steel and that extends radially in a direction of the roller shell. At least one of the connection portions may have at least one through opening that emerges at an end face of the roller shell. Further, a filling made of one or more filling elements that have at least one closed cavity may be arranged in the roller shell. The filling may have a structure that is symmetrical about an axis of rotation of the roller.

Claims

1.-9. (canceled)

10. A roller for deflecting or guiding a metal strip to be coated in a metal melt bath, the roller comprising: a steel roller shell; steel bearing journals that are connected to the steel roller shell and are disposed coaxially to each other for a rotary supporting of the roller; a connection portion disposed on each of the steel bearing journals, each connection portion being substantially cylindrical or circular disk shaped and being comprised of steel, wherein each connection portion extends radially in a direction of the roller shell, wherein at least one of the connection portions includes a through opening that emerges at an end face of the steel roller shell; and a filling comprised of one or more filling elements that have a closed cavity, the filling being disposed in the steel roller shell, wherein the filling comprises a structure that is symmetrical about an axis of rotation of the roller.

11. The roller of claim 10 wherein the one or more filling elements comprise one or more longitudinal profiles that contain at least one hollow profile that is closed at both ends.

12. The roller of claim 10 wherein the one or more filling elements comprise longitudinal profiles that contain at least one hollow profile that is closed at both ends, wherein the longitudinal profiles have different cross sections.

13. The roller of claim 10 wherein the one or more filling elements comprise longitudinal profiles that contain at least one hollow profile that is closed at both ends, wherein the longitudinal profiles have different wall thicknesses.

14. The roller of claim 10 wherein the one or more filling elements comprise longitudinal profiles that contain at least one hollow profile that is closed at both ends, wherein the longitudinal profiles have cross sections that are the same.

15. The roller of claim 10 wherein the one or more filling elements comprise longitudinal profiles that contain at least one hollow profile that is closed at both ends, wherein the longitudinal profiles have wall thicknesses that are the same.

16. The roller of claim 10 wherein at least one of the one or more filling elements is configured as a tube bundle comprised of multiple interconnected tubes, wherein at least some of the multiple interconnected tubes are closed at both ends.

17. The roller of claim 10 wherein the multiple interconnected tubes have different cross sections.

18. The roller of claim 10 wherein the multiple interconnected tubes have different wall thicknesses.

19. The roller of claim 10 wherein the multiple interconnected tubes have cross sections that are the same.

20. The roller of claim 10 wherein the multiple interconnected tubes have wall thicknesses that are the same.

21. The roller of claim 10 wherein an overall density of the roller is in a range of 0.8 to 1.2 times a density of a metal melt of the metal melt bath.

22. The roller of claim 10 wherein the closed cavity of at least one of the one or more filling elements is at least partially filled with a filling material.

23. The roller of claim 18 wherein the filling material is configured as powder, granules, or fleece.

24. The roller of claim 10 wherein the filling is detachably connected to at least one of an interior of the steel roller shell or the connection portions.

25. The roller of claim 10 wherein the filling is detachably connected to an interior of the steel roller shell.

26. The roller of claim 10 wherein the filling is detachably connected to at least one of the connection portions.

27. A hot-dip coating plant with at least one roller as recited in claim 10.

Description

[0019] The invention shall be explained more closely below with the aid of a drawing showing several sample embodiments. There are shown:

[0020] FIG. 1 a hot-dip coating device in schematic representation;

[0021] FIG. 2 one embodiment of the roller according to the invention for arrangement in a melt bath of a hot-dip coating plant, in an axial cross section;

[0022] FIG. 3 a bearing journal of the roller in an embodiment corresponding to FIG. 2 in an axial cross section;

[0023] FIG. 4 one embodiment of a longitudinal profile according to the invention in cross section representation;

[0024] FIG. 5 one embodiment of a filling element in another embodiment;

[0025] FIG. 6 a cross section of a roller according to the invention in one embodiment;

[0026] FIG. 7 a cross section of another embodiment of the roller according to the invention;

[0027] FIG. 8 a cross section of another embodiment of the roller according to the invention;

[0028] FIG. 9 a cross section of another embodiment of the roller according to the invention.

[0029] The hot-dip coating device represented schematically in FIG. 1 comprises a melt bath vessel 1, which is filled with a metal melt 2, such as one based on aluminum or zinc. Through a trunk 3 dipping into the metal melt 2, a steel strip 4 being coated is guided into the metal melt 2. In the melt bath vessel 1 there is arranged a deflecting roller (so-called dipping or pot roller) 5, by means of which the steel strip 4 is deflected from the downward slanting direction of travel into an upward, preferably substantially vertical direction of travel. Furthermore, there are arranged in the melt bath vessel 1 one or two guiding rollers (so-called stabilization rollers) 6, which serve to suppress vibrations of the steel strip 4 and thereby ensure the most accurate possible running of the strip 4 in relation to a stripping device 7. The stripping device removes excess coating material from the surface of the coated steel strip 4, for which it typically has stripping nozzles 7 operating with pressurized air or inert gas in the form of flat-jet nozzles.

[0030] The deflecting roller 5 and/or at least one guiding roller 6 have a structure which is represented for example in FIGS. 2 to 9. The roller 5 or 6 comprises a roller shell 8 made of steel, such as chromium-molybdenum steel. The roller shell 8 is tubular. The lateral surface 8.1 of the roller may be convex bulging, so that the outer diameter of the roller 5 or 6 diminishes from the middle toward the ends of the roller.

[0031] At the ends of the roller shell 8 there are arranged bearing journals 9 which are coaxially arranged with respect to each other, which are likewise made of steel, such as chromium-molybdenum steel. The respective bearing journal 9 has a substantially cylindrical or circular disk-shaped connection portion 9.1. The connection portion 9.1 is preferably formed as a single piece with the journal portion 9.2 protruding axially at the end face of the roller shell 8. The connection portion 9.1 extends from the journal portion 9.2 or the axis of rotation of the roller 5 or 6 radially in the direction of the roller shell 8. The roller shell 8 has at its ends increased-diameter internal surfaces 8.2, each of which defines an encircling internal shoulder 8.3. The connection portions 9.1 of the bearing journals 9 are shoved by form fit into the increased-diameter interior sections of the roller shell 8 and firmly connected to it, for example, by annular welded seams.

[0032] The outer diameter of the journal portion 9.2 of the bearing journal 9 is smaller by a factor in the range of 3.0 to 7.0, preferably 4.0 to 5.0, than the outer diameter of the roller shell 8. The use of a bearing journal 9 with a correspondingly small journal diameter (diameter of the journal portion 9.2) is preferred, since the journal portion 9.2 then presents less rolling resistance and thus the roller 5 or 6 can be turned more easily.

[0033] The connection portion 9.1 of the respective bearing journal 9 has at least one or, as represented in FIG. 3, several through openings 9.3, which emerge at the end face of the roller shell 8 and also on the interior side of the connection portion 9.1 or bearing journal 9. In the sample embodiment shown, for example, four through openings 9.3 are provided in the respective connection portion 9.1 or bearing journal 9, which run substantially parallel to each other and are arranged equally spaced apart on a common partial circle. As a modification of this sample embodiment, the connection portion 9.1 or bearing journal 9 may also have fewer than or more than four through openings 9.3.

[0034] The respective through opening 9.3 is preferably fashioned as a borehole. In other embodiments, however, other shapes or also a spoke-like design of the connection portion 9.1 are also possible.

[0035] According to the invention, as is also shown for example in FIG. 2 and FIGS. 6 to 9, the cavity of the roller 5 or 6 bounded by the roller shell 8 and the connection portions 9.1 of the bearing journals 9 is filled with one or more filling elements 11, the filling element 11 containing at least one closed cavity.

[0036] As shown in FIG. 4, a cavity in one embodiment according to the invention may be formed by a longitudinal profile 10 which is closed at both ends by a closure element 12.1. Such a closed hollow profile 10, 10.1, 10.3, 10.4 constitutes a filling element 11 according to the invention. In one preferred embodiment, however, several longitudinal profiles 10 are combined to form one filling element 11 and joined firmly to each other, especially preferably being welded together.

[0037] FIG. 5 shows another embodiment of a filling element 11, in which several longitudinal profiles 10 are joined together by a common closure element 12.2 and this closure element 12.2 at the same time closes the cavities lying in or between the profiles. The connection between the longitudinal profiles 10 and the closure element 12.2 is preferably done by means of welding.

[0038] FIGS. 6 to 9 show various embodiments for the filling element 11. All sample embodiments shown are shown with the roller shell 8 and in a cross section plane situated perpendicular to the axis of rotation. The cavity of the roller 5 or 6 between the connection portions 9.1 is preferably substantially entirely filled with the filling elements 11. Thanks to the enclosed cavities in the filling elements 11, the roller 5, 6 has reduced overall density as compared to the material of the roller shell 8. The diameter ratio between the outer diameter and the inner diameter of the roller shell 8 lies for example in the range of 1.2 to 2.0, preferably in the range of 1.4 to 1.6. The overall density of the roller 5 or 6 lies for example in the range of 0.8 to 1.2, preferably 1.0 to 1.1 times the density of the metal melt 2 used, which may be in particular a metal melt based on aluminum or zinc.

[0039] In the embodiment shown in FIG. 6, the filling element or elements 11 are formed by tubes 10.1 as the longitudinal profiles 10. The embodiment with tubes 10.1 is especially preferred, since these are especially advantageous in regard to the stresses occurring due to the internal pressure in the cavities and at the same time a good filling can be achieved.

[0040] FIG. 7 represents an embodiment in which solid profiles 10.2, here square profiles, are used as the longitudinal profiles, these being joined together in the longitudinal direction. The cavities are formed by the interstices occurring between the profiles and closure elements 12.1, 12.2 arranged at both ends.

[0041] Another embodiment is shown in FIG. 8. Here, regular longitudinal profiles 10 are likewise used, in this configuration with hexagonal hollow profiles 10.3. In general for a configuration according to the invention it is preferable to use longitudinal profiles 10 with a cross section having several planes of symmetry including the longitudinal axis, since these are favorable for a uniform density distribution, enable a good filling of the roller 5, 6, and are relatively economical.

[0042] FIG. 9 shows another embodiment in which a filling element 11 consists of several circular segment shaped sections 10.4.

[0043] Furthermore, FIG. 9 shows that at least some of the cavities are filled at least partly with a filling material 13. In the example shown, a fibrous filling material 13 such as steel or mineral wool is used, since these afford the advantage of being resistant to the operating temperature and have position stability inside the cavity. Alternatively, silicon powder can be used for example.

[0044] The embodiment of the invention is not confined to the sample embodiments represented in the drawing. Instead, further variants are conceivable, which also make use of the invention as indicated in the claims, albeit in modified configuration. Thus, for example, the longitudinal profiles 10 used in a filling element 11 may have different cross sections, diameters, and/or wall thicknesses in order to achieve the most uniform possible and/or favorable weight distribution inside the roller for the rotational properties.

[0045] In terms of the operating temperature and the internal pressure in the cavities caused by this, filling elements 11 preferably consist at least for the most part of steel. Especially in embodiments of filling elements having parts not under pressure load, or under less pressure load, these may also consist of other temperature-resistant materials preferably having less density, such as ceramic materials.

[0046] In order to prevent a relative movement especially about the axis of rotation between roller shell 8 and the filling element or elements 11, these comprise positioning means in a further embodiment, by which the filling elements 11 are connected to the roller shell (8) and/or connection portion 9.1 and also optionally to each other, preferably in detachable manner. Especially suitable for this are plug-in connections in the form of pins or protrusions.

LIST OF REFERENCE SYMBOLS

[0047] 1 Melt bath vessel [0048] 2 Metal melt [0049] 3 Trunk [0050] 4 Steel strip being coated [0051] 5 Deflecting roller (so-called dipping roller or pot roller) [0052] 6 Guiding roller (so-called stabilization rollers) [0053] 7 Stripping device [0054] 8 Roller shell [0055] 8.1 Lateral surface [0056] 8.2 Internal surface [0057] 8.3 Internal shoulder [0058] 9 Bearing journals [0059] 9.1 Connection portion [0060] 9.2 Journal portion [0061] 9.3 Through opening [0062] 10 Longitudinal profile [0063] 10.1 Hollow profile (tube) [0064] 10.2 Solid profile (square) [0065] 10.3 Hollow profile (hexagon) [0066] 10.4 Cavity (circular ring segment) [0067] 11 Filling element [0068] 12 Closure element [0069] 12.1 Closure element (plug) [0070] 12.2 Closure element (plate) [0071] 13 Filling material