The invention relates to a cooling device for cooling a metallic item, in particular a metal strip, and a method for its operation.
Such cooling devices having a plurality of cooling bars arranged in parallel for applying a coolant to a metallic item are well known in the prior art; thus, for example, from European patent specification EP 0 081 132 and German patent application DE 198 54 675 A1.
Said European patent specification thus discloses a cooling device having a plurality of cooling bars which extend in the transport direction or the longitudinal direction of the metallic item to be cooled. At the same time, however, a plurality of these cooling bars are arranged in the width direction of the metallic item. A volume flow of a coolant can be applied to each cooling bar individually. In this way, different distributions of the volume flow of coolant can be implemented over the width of the metallic item to be cooled.
Published application DE 198 54 675 A1 discloses a cooling device having a plurality of cooling bars, which each extend transversely to the longitudinal direction of the metallic item to be cooled and are arranged in parallel. Each cooling bar carries, distributed over its length, i.e., distributed over the width of the metallic item, a plurality of application tubes or nozzles, which can each in turn be individually activated with respect to the coolant volume flow to be applied. In this way, a very individual distribution of the coolant volume flow over the metallic item to be cooled may also be implemented.
Finally, European patent specification EP 2 986 400 B1 discloses a cooling device. Specifically, the cooling device disclosed therein has at least one cooling bar for applying a coolant to a metallic item, wherein each cooling bar has at least one left, one middle, and one right application region in its longitudinal direction. The application regions are adjacent in pairs in the longitudinal direction of the cooling bar and the area and/or contour thereof are formed differently. Specifically, all three regions are triangular in the patent specification. Separate pumps and valves are associated with each application region for controlling or adjusting the coolant volume flow in the individual application regions.
The known cooling devices do enable a limited adjustment of the distribution of the coolant volume flow over the width of the rolled stock; however, the adjustment options for the distributions are limited. It is thus not always possible using these limited adjustment options to react adequately to strips or plates having different widths and to apply a certain coolant quantity distribution over the strip width in accordance with the strip width. With the same coolant quantity distribution in the cooling bars within a group of cooling bars, very narrow metallic items are hardly masked, while the masking of wider metallic items is much too deep. Furthermore, the similarity of application regions in the cooling bars of a group in combination with an arrangement in a row of outlet openings for the coolant in the cooling bar necessarily results in stepped coolant application over the width of the rolled item. This creates the risk of strip-shaped cooling of the metallic item.
The invention is based on the object of refining a known cooling device, a known method for its operation, and a known rolling arrangement having such a cooling device in such a way that the options for setting certain distributions of the coolant over the width of the metallic item are improved.
Accordingly, the cooling device according to the invention is characterized in that the first application region of the first cooling bar is designed differently in its contour and/or area than the first application region of the adjacent second cooling bar in the same group.
Due to the claimed different design of the same application regions in adjacent cooling bars within a group, preferably in combination with the additionally claimed individual option for adjusting the pressure or the volume flow of the coolant in each application region, a nearly arbitrary distribution of the coolant can be implemented over the width of the rolled item. By assigning multiple parallel cooling bars having individual application regions and preferably additionally individual coolant application per application region to a group, in particular technically preferred parabolic distributions of the coolant may be implemented over the width of the metallic item. Individual pressure or volume flow in each application region does not exclude equal pressure or volume flow in various application regions.
The term “area” means surface area.
In the present description, the term “group” means a plurality of cooling bars arranged in parallel, wherein the number of the cooling bars per group is determined by the ultimately desired or predetermined distribution of the coolant over the rolled material. The more members or cooling bars are assigned to a group, the more finely or precisely can a desired coolant distribution be implemented.
The term “adjacent in pairs” means that of the at least three provided application regions per cooling bar, not all three application regions are simultaneously adjacent to one another. The application regions are typically arranged in succession in the longitudinal direction in each of the cooling bars, so that typically only two at a time, i.e., one pair of application regions are always adjacent.
The terms “left, middle, and right” relate to the representation of the application regions in the figures. In a real arbitrary arrangement of the cooling bars in space, these designations are to be changed suitably.
The terms “first” and “second” cooling bar are used solely to physically differentiate the cooling bars; they do not denote the sequence or ranking of the cooling bars within the group.
The first application region of the first cooling bar and the first application region of the second cooling bar are arranged and designed in such a way that they both spray essentially an equal or common first width section of the item using coolant in spite of their differences. In these terms, the first application region of the first cooling bar and the first application region of the second cooling bar are identical or similar in terms of the present description.
This statement also applies similarly to all other application regions and all further width sections. The first and further width sections are to be distinguished from one another.
The term “equal application regions” excludes mixed combinations of application regions which each spray different width regions of the item in different cooling bars, for example, first and third, or second and third application region in different cooling bars.
The boundary between two adjacent application regions of a cooling bar is marked by a boundary line in each case. The boundary line does not have to extend linearly, but rather can also extend curved or stepped between individual application tubes or nozzles of the respective cooling bar. If it is mentioned in the following description that the boundary line is inclined at an angle α with respect to the longitudinal axis of the respective cooling bar, then a real or virtual straight boundary line is assumed. If the boundary line is actually not straight, but rather stepped or wavy, a virtual straight boundary line through the actually non-straight boundary line is assumed for the definition of the angle α. The virtual straight boundary line is then used as a representation or center line through the actually non-straight boundary line.
According to a first exemplary embodiment of the cooling device according to the invention, the different configuration between the same application regions in two adjacent cooling bars of the same group can be achieved in that the boundary lines in the two cooling bars to be compared are either inclined at different angles angles α in relation to the longitudinal axis of the respective cooling bar and/or the boundary lines are positioned differently along the longitudinal axis of the cooling bars in the x direction, i.e., are displaced in relation to one another in the x direction. Both alternatives actually effectuate an expansion of the possibility for setting a desired distribution of the coolant over the width of the metallic item.
The above-mentioned object of the invention is furthermore achieved by a rolling mill having at least one rolling stand for rolling the metallic item and having a cooling device according to the present invention, which is typically connected downstream of the rolling stand. A first group of cooling bars according to the invention can be arranged to apply the coolant to the upper side of the metallic item and at least one second group of cooling bars can be provided to apply the coolant to the lower side of the metallic item.
Finally, the above-mentioned object of the invention is also achieved by a method for operating the cooling device according to the invention. According to this method, the pressure or the volume flow of the coolant in the individual application regions of at least one cooling bar within the group is adjusted in each case as a function of at least one of the following parameters of the rolled item: width of the metallic item, temperature distribution of the rolled item to be cooled over its width, and/or chemical composition. Said parameters can be measured or calculated at the input or at the output of the cooling device, depending on this one refers to a pilot control or a regulation.
The advantages of the claimed rolling mill and the claimed method correspond to the advantages mentioned above with reference to the claimed cooling device.
Finally, it is also possible to individually change the distribution of the pressure or the volume flow of the coolant over the length of the individual cooling bars during the passage of the metallic items through the cooling device as a function of the parameters.
Further advantageous designs of the devices according to the invention and the method according to the invention are the subject matter of the disclosure.
Five figures are appended to the description, wherein
The invention is described in detail hereinafter with reference to the mentioned figures in the form of exemplary embodiments. In all exemplary embodiments, the same technical elements are designated by the same reference numerals.
In a more detailed variant, the respective similar application regions I, II, III are not each connected in parallel with respect to the coolant supply, but rather alternatively a separate valve can also be assigned to each application region of each cooling bar. In the exemplary embodiment shown in
In this way, in particular, the pressures or the volume flows of the coolant in the individual application regions I, II, III can be set individually at least in groups, here for the one group G shown.
All valves 130 and all pumps 160 are connected to a control unit 120 and are activated individually by this control unit.
In the first exemplary embodiment shown in
It can furthermore be seen that in the cooling bars 110-1 . . . -4, all application regions are always trapezoidal, while in the fifth cooling bar 110-5, the two outer application regions I and III are each triangular and only the middle cooling region II is trapezoidal.
Each of the cooling bars has at least one, but typically a plurality of application tubes or nozzles 150 in each application region, wherein these application tubes or nozzles can also solely be formed in the form of simple openings in the cooling bar.
The cooling bars 110-n extend with their longitudinal axis transversely to the transport direction T of the rolled item 200.
In contrast to what is shown in
A group G of cooling bars 110-n is defined via a desired distribution of the coolant 300 over the width of the metallic item 200. The desired distribution function results from superimposing the individual distribution functions of the individual cooling bars within the group G. The more cooling bars having differently formed application regions I, II, III are combined in a group, the more precisely a desired overall distribution function for the coolant can be implemented. In particular, a technically preferred fine parabolic application of coolant 300 to the metallic item 200 may then be implemented.
Overall,
The cooling device 100 according to the invention is typically connected downstream of the last rolling stand of a rolling mill. At least one first group G of cooling bars 110 is arranged in the cooling device to apply the coolant to the upper side of the metallic item and/or at least one second group is arranged to apply the coolant to the lower side of the metallic item.
The pressure or the volume flow of the coolant 300 in the individual applications I, II, and III of at least one cooling bar 110 within the group G can be adjusted in each case as a function of at least one of the following parameters: The width of the metallic item, the temperature distribution of the metallic item to be cooled over its width, or as a function of the chemical composition of the material or the material properties of the metallic item.
These mentioned parameters can be measured and/or calculated either at the input and/or at the output of the cooling device. If they are detected at the input of the cooling device, this is thus referred to as a public control; if the parameters are detected at the output of the cooling device, it can thus be a regulation.
While the design of the individual application regions I, II, and III shown by way of example in
Number | Date | Country | Kind |
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10 2018 205 685.4 | Apr 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/058452 | 4/4/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/197255 | 10/17/2019 | WO | A |
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Number | Date | Country | |
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20210162478 A1 | Jun 2021 | US |