The invention concerns a roll stand for rolling a product, especially a metal product, which has a pair of first rolls in contact with a pair of second rolls that support the first rolls, wherein the first rolls and the second rolls are provided with a radius curve (CVC cut) that is asymmetric relative to a center plane, wherein the radius curve of the first rolls is represented by a polynomial of third or fifth degree.
EP 1 307 302 B1 discloses a roll stand of this type. A polynomial curve of the specified type is provided as a radius curve in order to minimize the axial forces of the roll bearings, where suitable choice of the radius curve makes it possible to minimize horizontally acting torques without additional expense. The wedge component of the CVC work roll contour is of special importance. The configuration is carried out in such a way that the wedging of the work roll cut or work roll contour is optimized to avoid rotational torques or axial forces. The linear component of the polynomial (a1) is used as an optimization parameter for this. This makes it possible to prevent crossing of the rolls and to minimize the axial forces in the roll bearings.
In this regard, the solution according to the cited document EP 1 307 302 B1 is based on a profiling of the work rolls, which interact with cylindrical backup rolls. This is the focus of the optimization of the wedging of the work rolls. Efforts have been made to expand the adjustment range of the CVC system to further increase the strip profile-adjustment range. In this connection, in order to avoid high surface pressings between work been found, however, that to optimize the wedging of the CVC contour of the backup rolls, the same configuration as for the work rolls cannot be used if the aim is to achieve optimum conditions.
Therefore, the objective of the invention is to refine a roll stand of the aforementioned type in such a way that the wedging of a second roll supporting a first ml (usually, but not exclusively: the wedging of a backup roll that is interacting with a work roll) is realized in such a way that optimum operating conditions are established.
In a first embodiment of the invention, the solution to this problem is characterized in that in a roll stand of the aforementioned type, a radius curve of the first rolls is provided that satisfies the following equation:
R
AW(x)=a0+a1·x+a2·x2+a3·x3
where
In this connection, the following function is provided for the radius curve of the second rolls:
R
SW(x)=s0+s1·x+s2·x2+s3·x3
where
s
1
=f
1
·[R
SW
/R
AW·(b2contAW−b2contSW)·a3+b2contSW·s3]
where
The following relation preferably exists between the coefficients of the radius curve of the first rolls:
a
1
=f
1
·a
3
·b
2
contAW
where f1=− 1/20 to − 6/20
In an alternative solution in a roll stand of the aforementioned type, a radius curve of the first rolls is provided that satisfies the following equation:
R
AW(x)=a0+a1·x+a2·x2+a3·x3+a4·x4+a5·x5
where
RAW(x): radius curve of the first roll
x: coordinate in the longitudinal direction of the barrel
a0: actual radius of the first roll
a1: optimization parameter (wedge factor)
a2 to a5: coefficients (adjustment range of the CVC system)
In this connection, the following function is provided for the radius curve of the second rolls:
R
SW(x)=s0+s1·x+s2·x2+s3·x3+s4·x4+s5·x5
where
RSW(x): radius curve of the second roll
x: coordinate in the longitudinal direction of the barrel
s0: actual radius of the second roll
s1: optimization parameter (wedge factor)
s5 to s5: coefficients (adjustment range of the CVC system)
where the following relation exists between the given variables:
s
1
=f
1
·[R
SW
/R
AW·(b2contAW−b2contSW)·a3+b2contSW·s3]+f2·[RSW/RAW(b4contAW−b4contSW)·a5+b4contSW·s5]
where
In this case, the following relation preferably exists between the coefficients of the radius curve of the first rolls:
a
1
=f
1
·a
3
·b
2
contAW
+f
2
·a
5
·b
4
contAW
where f1=− 1/20 to − 6/20
f2=0 to − 9/112
The coefficients a4 and a5 of the radius curve of the first rolls can be zero. In this case, the curve of the radius of the first rolls is represented as a third-degree polynomial, while the curve of the radius of the second rolls is represented as a fifth-degree polynomial.
On the other hand, it is also possible for the coefficients s4 and s5 of the radius curve of the second rolls to be zero. Then the curve of the radius of the first rolls is represented as a fifth-degree polynomial, while the curve of the radius of the second rolls is represented as a third-degree polynomial.
As is already known in itself, it is preferably provided that the radius curve of the first rolls is designed in such a way that the tangents that touch an end diameter and the convex part of the roll and the tangents that touch the other end diameter and the concave part of the roll are parallel to each other and are inclined to the roll axes by a wedge angle. The same applies to the radius curve RSW(x) of the second roll.
The first rolls are preferably work rolls, and the second rolls are preferably backup roils.
However, it is also possible for the roll stand to be a six-high stand and for the first rolls to be intermediate rolls and the second rolls backup rolls.
In general, the given linear component (wedge component), the contact length, and the diameter of the corresponding adjacent roll are taken into consideration.
An embodiment of the invention is illustrated in the drawings.
The drawings show the conditions already known from EP 1 307 302 B2, to which reference is explicitly made in this respect.
Both the work rolls 2 and the backup rolls 3 have a so-called CVC cut, i.e., the profile is asymmetric with respect to a center plane 4. Details of this are described in EP 1 307 302 B2, which was cited earlier. Accordingly, the rolls 2, 3 have a functional curve over the coordinate x in the longitudinal direction of the barrel that results from polynomials of the nth degree, with polynomials of the third or fifth degree being preferred or at least sufficient.
If the work rolls 2 are shifted axially relative to each other, the roll gap can be influenced correspondingly. The load between the work rolls 2 and the backup rolls 3 is unevenly distributed over the contact region bcont (see
As
EP 1 307 302 B2 describes the optimization of the so-called wedge factor, i.e., the coefficient of the linear term of the polynomial, for which suitable equations are proposed.
As can be seen from
Accordingly, the present concept can be summarized again as follows:
The rule for the configuration of the work roll contour and the determination of the wedge component (linear coefficient of the polynomial function) is obtained according to or very similarly to the previously known EP 1 307 302 B2. The coefficients a2, a3, a4, and a5 (in the case of a fifth-degree polynomial) result from the desired adjustment range or effect in the roll gap. The contact length between the work roll and backup roll or, alternatively, the length of the work roll is to be set as the contact width for the configuration of the CVC work rolls and especially for the wedge component (a1), as described in EP 1 307 302 B2. If these rules are followed, the work roll contours and especially the a1 coefficient (wedge component) are optimally configured.
For the wedge component s1 of the backup roll contour, which can also be described by a polynomial function, similar equations apply (which can be iteratively computed offline). The values for the wedge component s1 vary as a function of the associated work roll contour and length. The shape of the backup roll thus must be adapted to the shape of the work roll. The coefficients s2, s3, s4, and s5 (in the case of representation of the backup roll contour by a fifth-degree polynomial) result from the desired adjustment range or adaptation to the S shape of the work rolls. The procedure specified above for the configuration of the backup roll contour applies here for the linear component.
For the special case that—in a representation of the radius curve as a third-degree polynomial—the backup roll does not have a CVC contour, the coefficient s3 is equal to zero.
The above relationships also apply to contours that are similar to an S-shaped contour, e.g., to a so-called SmartCrown function (sine function), or to contours that are preassigned by a point sequence and can be approximated with one of the polynomial functions specified above.
In the case of a six-high stand, the procedure can be carried out in similar fashion. In this case, the work roll is analogously configured. The configuration of the wedging of the intermediate roll is carried out as for the backup roll. After the intermediate roll is determined, the col on of the backup roll of the six-high stand is carried out analogously to the configuration of the backup roll of the four-high stand. Generally speaking, in this regard, the given linear component, the contact length, and the diameter of the corresponding adjacent roll are taken into consideration.
In special cases, it is possible, for example, for the work roll contour to be realized by a fifth-degree polynomial function and the backup roll or intermediate roll by a third-degree polynomial function or vice versa. The mathematical relationships outlined above apply to the work rolls. For the backup rolls and intermediate rolls, the wedgings are likewise optimized by the above procedure.
The above details apply in one case for the approximation of the radius profile by a third-degree polynomial and in one case by a fifth-degree polynomial. Naturally, however, it is also basically possible to provide polynomials of higher degree, but polynomials of a degree higher than five are rarely used.
Number | Date | Country | Kind |
---|---|---|---|
10 2008 062 402.0 | Dec 2008 | DE | national |
10 2009 021 414.3 | May 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2009/008989 | 12/15/2009 | WO | 00 | 6/16/2011 |