The present invention relates to a device for cooling a metallic strip. Particularly, this invention is aimed at improving the rapid cooling of an annealing process.
During its manufacture, a metallic strip undergoes several thermal treatments, notably after its cold rolling where it is annealed. Through the annealing process, the metallic product is rapidly heated at a temperature generally comprised between 700 and 850° C. and maintained at the maximal temperature for about one minute. Then the metallic product undergoes a cooling treatment where it is cooled at a controlled cooling rate. Ultimately, the overaging and the final cooling take place.
In the case of a steel strip, thanks to the thermal treatments, several phenomena occur such as the recrystallisation and the carbides precipitation. All those treatments allow a desired structure improving the resistance and the formability of the strip to be obtained.
For particular steels such as: the (TRIP) TRansformation Induced Plasticity, the multiphase steels, the high-specific strength steel; the annealing generally comprises two coolings, a first slow one and then a second rapid one.
As illustrated in
Even though a high cooling rate is achieved, greater than 1000° C., this device is not satisfactory because the cooling is not homogeneous in the strip width direction leading to flatness defects. Consequently, there is a need to improve the product flatness of the exiting metallic flat product. Thus, the cooling device 4 needs to be improved.
Moreover, sealing means 9 usually isolates the tank 2 and the cooling device 4 to limit the influence of the coolant 3 onto the cooling device 4. Furthermore, the coolant temperature in the cooling device 4 is generally inferior to the one of the tank 2 coolant. Any leakage from one space to another would create temperature gradient negatively impacting the cooling homogeneity. EP 1 300 478 B1 extensively describes a sealing means 9 and its advantages.
One purpose of this invention is to solve the aforementioned problem.
The present invention provides a cooling device (10) for a cooling operation of a flat metallic product (S), said cooling device being located in an essentially vertical, ascending or descending, path comprising:
The present invention also provides a cooling method wherein a flat metallic product moving essentially vertically, ascendingly or descendingly, is cooled in a device as described above, wherein said series of projecting devices eject a coolant flux between 250 m3 and 2,500 m3 per hour per surface of flat product.
Other characteristics and advantages of the invention will become apparent from the following detailed description of the invention.
To illustrate the invention, various embodiment of non-limiting example will be described, particularly with reference to the following figures:
As illustrated in
In the following specification, the flat metallic product S will be referred as a strip. However, said flat metallic product is not limited to a strip.
As illustrated in
The cooling device is positioned in an essentially vertical, ascending or descending, path of the flat metallic product. It means that when the flat metallic product passes through the cooling device, its moving direction is essentially vertical as represented by the arrow D.
The cooling device comprises a tank 15 containing a coolant bath 17 which defines a coolant surface 11. The primary role of the tank is to contain a coolant creating a coolant bath. The coolant is preferably a liquid and can be water. Its secondary role is to isolate the coolant bath from the exterior which permits to control the coolant parameters, such as the temperature, and the projected coolant fluxed.
Moreover, said tank comprises at least two openings, one on its upper side 16 and one on its bottom side 16′, through which said flat metallic product S can go, describing a path. The role of those openings is to let the flat metallic product pass through the cooling device 10. They should also prevent the entrance of any external liquid into the coolant bath 17. Said openings wherein the strip pass through should be essentially vertically aligned so the strip can have an essentially vertical path. The path described by said flat metallic product is essentially vertical.
Furthermore, the tank preferably comprises at least two lateral openings (21 and 21′) allowing the coolant discharge.
The opening on the bottom side is equipped with a sealing means 9 to improve the coolant bath isolation from the exterior. As illustrated in
As illustrated in
The coolant is projected through apertures 13E in said projecting devices 13. Said apertures 13 are among other possibilities: a slit, a hole or a series of holes. Said projecting devices apertures 13E are completely immersed in the coolant bath. Such an immersion permits to suppress or at least lower the gas bubble or vapor formation (and presence) in the coolant bath close to the strip compared to non-immersed apertures. Preferentially said projecting devices are completely immersed in said coolant.
A gap 19 separates two vertically successive projecting devices (e.g. 13A and 13B) of a series (18 and 18′) of projecting devices. As illustrated in
The closest projecting device, of each series, to the coolant bath surface 11 comprised in the tank 15 is referred as the uppermost projecting device (20 and 20′). As illustrated in
The use of such a claimed cooling device 10 is not limit to only one positioned at the strip exit from the cooling device as illustrated in
wherein the fast cooling takes place in the claimed cooling device and the slow cooling is in a tank containing boiling water.
In the prior art, it seems that no solution permits to avoid the formation of turmoi leading to a heterogeneous cooling along the strip width. On the contrary, with the equipment according to the present invention, the cooling homogeneity is improved along the strip width.
Advantageously, both series (18 and 18′) have the same number of projecting devices (13) downwardly inclined of an angle of 20° to 40° compared to the horizontal. In order to obtain a homogeneous in the strip width, the inclined projecting device of each series should be facing each other.
Advantageously, the two uppermost projecting devices of both series (18 and 18′) are downwardly inclined of an angle of 20° to 40° compared to the horizontal. The two uppermost projecting devices (20 and 20A or 20′ and 20′A) of a series correspond to the two immersed projecting devices being the closer to the surface, as illustrated in
Advantageously, the three uppermost projecting devices on both series (18 and 18′) are downwardly inclined of an angle of 20° to 40° compared to the horizontal.
Advantageously, the four uppermost projecting devices on both series (18 and 18′) are downwardly inclined of an angle of 20° to 40° compared to the horizontal.
Advantageously, all projecting devices located up to a depth of 50 cm from the coolant surface are downwardly inclined of an angle of 20° to 40° compared to the horizontal. Such an arrangement permits to increase even further the cooling homogeneity in the strip width because the formation of gas bubble is reduced even more. Preferably, all projecting devices located up to a depth of 1 meter or 2 meters or 3 meters from the coolant surface are downwardly inclined of an angle of 20° to 40° compared to the horizontal.
Advantageously, said series of projecting devices comprises 10 to 40 devices. Such a quantity of devices permits to ensure a sufficient cooling capacity of the cooling device. More advantageously, each projecting device can spray at least 250 m3·h−1 of coolant per m2 of strip.
Advantageously, said projecting devices are tubes 14. Preferably, as illustrated in
Advantageously, said projecting device apertures 13E (See
Advantageously, the cooling device does not comprise rolls, such as restraining rolls, between said two openings.
The invention also relates to a cooling method wherein a flat metallic product moving essentially vertically, ascendingly or descendingly, is cooled in a device as described previously, said series of projecting devices eject a coolant flux between 250 m3 and 2,500 m3 per hour per surface of flat product. A coolant flux in that range is sufficient to obtain a cooling speed desired to achieve the desired product properties.
Preferably, said series of projecting devices eject a coolant having a speed between 0.25 m·s−1 and 20 m·s−1. Such a speed permits to the ejected coolant to reach the strip surface and being reflected horizontally in the gap between the projecting devices which improves the coolant renewal and thus the cooling homogeneity.
Preferably, said series of projecting devices eject a coolant being at a temperature between 10 and 100° C.
Preferably, said cooling device permits to cool said flat metallic product of at least 200° C.·s−1. More preferably, said cooling device permits to cool said flat metallic product of at least 500° C.·s−1. Even more preferably, said cooling device permits to cool said flat metallic product of at least 1000° C.·s−1.
The invention has been described above as to the embodiment which is supposed to be practical as well as preferable at present. However, it should be understood that the invention is not limited to the embodiment disclosed in the specification and can be appropriately modified within the range that does not depart from the gist or spirit of the invention, which can be read from the appended claims and the overall specification.
Number | Date | Country | Kind |
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PCT/IB2019/056684 | Aug 2019 | IB | international |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/057132 | 7/29/2020 | WO | 00 |