JP2002511340A - Rolling stand with roll that can move in the axial direction - Google Patents

Abstract

(57) Abstract: The present invention is directed to cold rolling or hot rolling rolling strips of different materials, consisting of working rolls arranged in pairs, a supporting roll and optionally an intermediate roll. Roll stand. At least one pair of rolls (6) is axially movable to both sides and has a suitable profile to compensate for rolling defects. A disadvantage of the rolls which are moved axially by the movable roll chocks is that each movable roll (6) has at least one hydrodynamic oil film bearing (3), which oil film bearing This is avoided because the hydraulic unit (17), which can respond to perform axial movement, is integrated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001] The present invention provides a roll arrangement wherein at least one roll pair is axially movable to both sides and has a profile suitable for compensating for roll defects. The present invention relates to a rolling stand for hot or cold rolling of rolled strips of various materials by means of a working roll, a supporting roll and possibly an intermediate roll.

[0002] EP 91540 describes a rolling stand of this kind which is designed as a fourth or sixth rolling stand. In the case of the fourth rolling stand, the support roll can also be moved in the axial direction beside the work roll, and the support roll can be moved by the work roll
Done independently of the rolls or with the work rolls. In the case of the sixth rolling stand, a work roll is provided, supports the intermediate roll supported by the support roll, and
The rolls and / or the supporting rolls and / or the intermediate rolls can be moved axially with respect to each other and the rolls have at least two roll pairs with a curved profile extending over the entire bale length. The profile is composed of a convex area and a concave area, and the bales profile supplements the oppositely supported or co-operating rolls only supplementally at predetermined relative axial locations of the rolls. The chocks are provided with sliding surfaces, which can slide on each other or on the beam of the rolling stand and can be moved axially by push rods. The installation costs required for this structure are considerable.

An object of the present invention is to simplify the axial movement of the rolls of a rolling stand compared to a solution with a movable chock.

This problem is solved in that each movable roll has at least one hydrodynamic oil film bearing, which is integrated with a hydraulic unit for effecting axial movement. . Since the rolls in the hydrodynamic oil film bearing float on the hydrodynamic oil film outside the case of the sliding surface of the chock, friction is also small in the axial direction. The roll can thereby be positioned axially with little effort and without hindrance and without transition. The integrated hydraulic unit can be installed smaller than conventional ordinary push rods and is a component of the roll bearing.

Due to the low bearing friction, axial adjustment can be performed under load. Due to the small space requirement, the hydraulic unit can be used for all roll types (work roll, support roll and intermediate roll).

[0006] The support roll is provided with an n-th finish in the case of hot rolling. At the front stand of the rolling strip path, in particular in the case of endless rolling, the support roll is moved in order to compensate for the thermal crown of the work roll. The presetting is performed by a CVC (continuously variable crown) work roll.

[0007] In the rear stand, the work roll movement helps to reduce and reduce wear and thermal crown. The adjustment of the shape of the roll gap is performed by bending the roll. The work roll movement of the rear stand extends the adjustment area for adjusting the roll gap shape, which is particularly useful for narrow soft strips as well as wide hard strips.

[0008] The support roll is provided with a CVC finish to compensate for x2 defects in the case of cold rolling in order to compensate for smoothness defects. The work roll or intermediate roll at the sixth stand has a CVC finish to compensate for xn defects.

In the case of the sixth stand, the support roll has a CVC finish to compensate for the x2 defect and the intermediate roll and the work roll to compensate for the xn defect are "edge drop" (board edge). Means for compensating for the phenomenon.

The hydraulic unit has an annular cylinder fixed to the rolling stand, in which an annular piston fixed to the roll is air-tightly guided by an integrated ring, so that the hydraulic unit is a hydrodynamic oil film bearing. It is particularly well adapted to the shape of It is not important that the diameter be larger than the diameter of the bearing sleeve of the hydrodynamic oil film bearing.

The movement of the roll in both directions is possible by the pressure action on both sides of the ring of the annular piston. The two hydraulic connections of the annular piston selectively supply hydraulic oil for both directions of movement to the annular piston.

The position detector serves to determine the axial position of each of the axially movable rolls. This position is controlled by the hydraulic unit via the adjustment circuit of the rolling stand using the signals of the position detector.

A particular advantage of the present invention is that the hydrodynamic oil film bearing is used as a replacement part with the hydraulic unit. This allows existing roll chocks to be used when replacing old equipment. Thus, only the hydrodynamic oil film bearing needs to be replaced. A moving mechanism requiring space in the rolling stand column can be omitted.

[0014] Other features of the invention will be apparent from the following description and from the drawings, in which embodiments of the invention are schematically illustrated.

The only figure shows a longitudinal section through a hydrodynamic oil film bearing with a hydraulic unit in the rightmost position. The figure shows a rolling stand column (1) (or roll chock) in which a bearing bush (2) of a hydrodynamic oil film bearing (3) is arranged. The journal bush (4) associated with the bearing is located on the roll journal (5) of the roll (6) by means of a clamping cone.

An annular cylinder (7) is fixed to the rolling stand column (1), and an annular piston (8) is air-tightly guided in the cylinder. This piston is connected to a roll journal (5) via a tapered roller bearing (9). The annular piston (8) has on its periphery a ring (10) which can be moved axially with the annular piston (8) in a groove (11) of the annular cylinder (7).

The groove (11) together with the annular piston (8) forms an annular space (12), which is divided by a ring (10). The part of the annular space (12) is connected to the control hydraulic means of the rolling stand via a separate hydraulic connection (13).

The free end of the roll journal (5) is oil-tightly covered by a cover (14). A fixed position detector (15) is fixed to the cover and is connected to the free end of the roll journal (5) via a connecting rod (16).
The annular cylinder (7), the annular piston (8) and the position detector (15) form a hydraulic unit (17).

The arrangement of the invention works as follows: in the case of the required axial movement of the roll (6), the right or left hydraulic connection acts on the pressure oil based on the desired adjustment direction Is done. This pressure oil acts, inter alia, on the annular surface of the ring (10) and thereby exerts an axial force, which is transmitted via the tapered roller bearing (9) to the roll jar of the roll (6). It is transmitted to the null (5) without friction. The axial movement of the roll journal (5) is transmitted via a connecting rod (16) to a position detector (15), which further pressurizes the oil flow to achieve the desired rolling position. Control.

The arrangement of the invention provides a simple, reliable and space-saving axial displacement device, which requires no precautions for its complete encapsulation. Due to this property, the axial displacement device is also suitable for the subsequent installation of existing rolling stands on roll chocks.

[Brief description of the drawings]

FIG. 1 shows a longitudinal section through a hydrodynamic oil film bearing with a hydraulic unit in a rightmost position.

[Explanation of symbols]

 1. . . . . Rolling stand column 2. . . . . Bearing bush 3. . . . . 3. Hydrodynamic oil film bearing . . . . Journal bush5. . . . . Journal 6. . . . . Roll 7. . . . . Annular cylinder 8. . . . . Annular piston 9. . . . . Tapered roller bearing 10. . . . Ring 11. . . . Groove 12. . . . Annular space 13. . . . 13. hydraulic connection . . . Cover 15. . . . Position detector 16. . . . Connecting rod

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Laying Konrad, Germany 57271 Hirchenbach, Auf der Heide, 1 (72) Inventor Müller Karl-Friedrich Germany, 57338 Erntebrück, Im・ Strite Platts, 3

Claims (8)

[Claims] The rolls (6) are capable of axially moving at least one roll pair to both sides and having a profile suitable for compensating for roll defects. In a rolling stand for hot or cold rolling of rolled strips of various materials by means of an arranged work roll, a support roll and possibly an intermediate roll, each movable roll (6) has at least one roll. A rolling stand comprising one hydrodynamic oil film bearing (3), wherein a hydraulic unit (17) for effecting axial movement is integrated with the oil film bearing. 2. The hydraulic unit (17) includes an annular cylinder (17) fixed to a rolling stand.
Rolling according to claim 1, characterized in that the annular cylinder (7) has an annular piston (8) fixed to a roll guided hermetically by an integrated ring (10). stand. 3. The rolling stand according to claim 2, wherein the ring (10) of the annular piston (8) can exert pressure on both sides. 4. The rolling stand according to claim 2, wherein the annular cylinder (7) has two hydraulic connections (13). 5. The method according to claim 1, wherein a position detector (15) is provided for each movable roll (6). Rolling stand as described. 6. The position of the movable roll (6) in the axial direction can be controlled by a hydraulic unit (17) using a signal from a position detector (15) via an adjustment circuit of a rolling stand. The rolling stand according to claim 5. 7. The rolling stand according to claim 1, wherein the hydrodynamic oil film bearing (3) can be used as a replacement part together with the hydraulic unit (17). 8. The hydrodynamic oil film bearing (3) can be mounted together with the hydraulic unit (17) on a front stand and / or a rear stand of a hot rolling mill and / or a cold rolling mill. A rolling stand according to claim 7.