JPS6358047B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a strip rolling mill.

(Prior Art) A strip is a metal, a non-metal, or a composite thereof, and herein refers to a rollable band-like body of these metals.

Strips are mainly manufactured by being stretched using rolling mills. When manufacturing the strip by rolling, it is desirable to use small-diameter work rolls to achieve a large rolling reduction and to reduce the number of passes. Particularly when manufacturing ultra-thin strips, the smaller the work roll diameter, the fewer passes can be made.

When using small-diameter work rolls, a back-up roll is required because the rolls are deflected by the rolling force. The conventionally known Sendzimir rolling mill is
It is the most commonly used rolling mill for ultra-thin strips, and has a complex structure in which two work rolls are supported by 18 back-up rolls.
The dimensional relationship between the work roll and the back-up rolls is subject to geometrical constraints, and in order to reduce the work roll diameter, the number of back-up rolls must be increased arithmetically.

As the number of stages of the back-up rolls increases, the amount of elastic deformation of the rolls accumulates, resulting in poor plate thickness accuracy and plate shape. In addition, the Sendzimir rolling mill has a complex structure, is expensive, and requires advanced technology to operate. U.S. Patent No. 2710550, U.S. Patent No. 2811060,
Each publication of British Patent No. 609706 shows a dual-drive planetary rolling mill, but since this rolling mill uses intermittent rolling in which the work rolls circulate, it produces significant noise and the strength of the work rolls is low. It was weak and had many breakdowns.

Japanese Patent Application Laid-open No. 58-35003 discloses a method in which one of the upper and lower work rolls is made smaller in diameter than the other work roll, and the small diameter work roll is offset in the rolling direction with respect to the other work roll.
A rolling mill is shown in which a presser roll, a dividing roll, and a horizontal bending device are arranged parallel to the small-diameter work roll on the offset side of the small-diameter work roll.

Since the purpose of this rolling mill is to control the plate thickness, the rolling mill is offset on the exit side with the intention of handling small diameter work rolls.
A rolling component force is generated toward the exit side, and this is received by the position control device on the exit side.

In such a rolling mill, the position of the small-diameter work roll fluctuates back and forth due to fluctuations in rolling load, making it difficult to make the small-diameter work roll an extremely small diameter.
In particular, in reciprocating rolling or so-called different circumferential speed rolling in which the circumferential speeds of upper and lower work rolls are different, this drawback is exacerbated and it is difficult to improve plate thickness accuracy and plate shape.

(Objective of the Invention) The present invention provides a strip rolling mill capable of obtaining the effects of one-side roll drive, rolling with different diameter rolls, rolling with different circumferential speeds, or continuous rolling.

(Structure and operation of the invention) The present invention has a structure in which a strip is spread in a zigzag pattern over non-driven small-diameter work rolls arranged in a row, and all of these work rolls are clamped by two large-diameter work rolls. In addition, this strip rolling mill is equipped with a clamping device that clamps small-diameter work rolls at both ends.

The present invention will be explained below with reference to the drawings.

FIG. 1 shows a rolling mill of the present invention in which there are two small-diameter work rolls. A drive large-diameter work roll 1, non-drive small-diameter work rolls 31, 32 for rolling the strip 2 together with the drive large-diameter work roll 1, and a drive supporting the small-diameter work rolls are housed in a roll housing substantially similar to a known double or quadruple rolling mill. The large-diameter work rolls 4 are piled up, and the small-diameter work rolls 31 and 32 are clamped from the front and rear directions by reinforcing rolls 5 and 6 and reinforcing rolls 7 and 8.

Since the two small-diameter work rolls 31 and 32 are not driven, they are freed from limitations on torsional rigidity, and because they are held under pressure by reinforcing rolls 5, 6 and 7, 8, they are free from limitations on bending rigidity. Since it is released, it is possible to significantly reduce the diameter and perform high pressure rolling. Furthermore, there is no restriction on the rolling width due to the reduction in the diameter of the small-diameter work roll.

FIG. 2 shows a case where there are three small-diameter work rolls. In this case as well, as in FIG. 1, a drive large diameter work roll 1 and a non-driven small diameter work roll 33 for rolling the strip 2 are placed in a roll housing substantially similar to a known double or quadruple rolling mill. , 34, 35 and the driven large-diameter work roll 4 supporting the small-diameter work roll are overlapped, and the small-diameter work rolls 33, 34, 35 are clamped from the front and rear directions by reinforcing rolls 5, 6.

In the present invention, the large diameter work rolls 1 and 4 are driven in opposite directions, and the strip 2 is introduced into the large diameter work roll 1 and the small diameter work roll 31 in FIG.
and the large diameter work roll 4. Hereinafter, in the present invention, the strips are said to run in a zigzag pattern. Also in FIG. 2, the strip is passed in a zigzag pattern between the small diameter work rolls 33, 34, 35 and the large diameter work rolls 1, 4.

Since the small-diameter work rolls 33, 34, and 35 are not driven, they are freed from limitations on torsional rigidity, and because they are held under pressure by reinforcing rolls 5 and 6, they are freed from limitations on bending rigidity. The diameter can be significantly reduced and rolling under high pressure is possible. Furthermore, the rolling width is not restricted by reducing the diameter of the small-diameter work roll.

In the present invention, the small-diameter work roll cooperates with the driving large-diameter work roll on the side where the strip is rolled, and rotates in the direction of advancing the strip, and the small-diameter work roll is different from the other driving large-diameter work roll. They move in opposite directions while touching each other. This means that regardless of the presence or absence of lubricant, the friction coefficient of small diameter work rolls is
That is, the side in contact with the strip is larger than the side in contact with the large diameter work roll.

In the present invention, the strip can be passed from arrow A to arrow B or from arrow A to arrow C in FIG. In the latter case, the strip will be clamped between a small diameter work roll 32 and a reinforcing roll 6.

(Effects of the Invention) As described above, the present invention can significantly reduce the diameter of the small-diameter work roll by holding the small-diameter work roll under pressure with the reinforcing rolls. In general, the influence of work roll diameter on rolling characteristics is determined by changing the work roll diameters on both sides of the material to be rolled.
Let D ₁ and D ₂ be the equivalent roll diameter (=
2D ₁ D ₂ / (D ₁ + D ₂ )) is discussed as an index, and by reducing the diameter of one work roll, the equivalent roll diameter can be significantly reduced, and the rolling load and rolling torque can be reduced. This makes it possible to operate under high pressure.

For example, if D ₂ is set to 1/5 or 1/10 of D ₁ , the equivalent roll diameter becomes as small as 0.33D ₁ or 0.18D ₁ , respectively. The small diameter work roll clamping device can be easily added to a conventional double or quadruple rolling mill. In addition, since the small-diameter work rolls of the roll set shown in FIGS. 1 and 2 are not driven, they can be easily accommodated in the housing of a conventional double rolling mill or quadruple rolling mill. Since the machine can be reused, it becomes an inexpensive rolling mill.

In addition, since the small diameter work roll is supported by the large diameter work roll from the direction opposite to the rolling force,
The rigidity can be significantly increased, and unlike the Sendzimir rolling mill, elastic deformation of the rolls does not accumulate and the plate thickness accuracy and plate shape deteriorate. Furthermore, small-diameter work rolls are not limited by geometrical size and are freed from limitations on torsional and bending rigidity, so they can be significantly smaller in diameter and can be operated under high pressure.

This rolling mill can obtain effects such as one-side roll drive, rolling with different diameter rolls, and rolling with different circumferential speeds, and can also obtain effects of continuous rolling by using a plurality of small diameter work rolls.

Furthermore, the present invention has great industrial effects, such as being able to use the housing of a conventional double rolling mill or a quadruple rolling mill, and enabling high-reduction rolling in a high-rigidity rolling mill by holding small-diameter work rolls in both directions. be.

[Brief explanation of the drawing]

1 and 2 are side views of the rolling mill of the present invention. 1, 4: Large diameter work roll, 2: Strip,
9, 10: Clamping device, 31, 32, 33, 34,
35: Small diameter work roll.

Claims (1)

[Claims] 1. The strip is passed in a zigzag pattern over non-driven small-diameter work rolls arranged in a row, and all of these work rolls are sandwiched between two large-diameter work rolls, and the small-diameter work rolls at both ends are A strip rolling machine characterized by being equipped with a clamping device for clamping the strip.