KR100899702B1 - Device of roll having cylinder within and shifting by axis - Google Patents

Abstract

The present invention relates to a roll used in a cold rolled steelworks, bearing housings a and bearing housings b fixed to both sides of a frame on which various kinds of rolls can be installed; Spline shafts a and spline shafts b which are connected to the bearing housings a and the bearing housings b, and whose splines are formed on the surface thereof; A shell cover a and a shell cover b inserted into the spline shaft a and the spline shaft b, respectively, and engaged to rotate together with the spline shaft a and the spline shaft b; A hollow roll shell whose ends are sealed by the shell cover a and the shell cover b; A spring inserted between the distal end of the shell cover a and the distal end of the spline shaft a; It is configured to include a cylinder that is connected between each end of the shell cover a and the spline shaft b.

According to the present invention, since the frame is connected to the bearing housing fixed to the frame and the frame is moved, the meandering of the strip is efficiently controlled because its own axial movement is possible without a separate frame moving device.

In addition, it is possible to drastically reduce the overall equipment to be applied to the work, and to be applied to other ringer rolls or back-up rolls to move the roll shell, which is the coating part, in the axial direction, thereby preventing the weight of the strip edge on one part and consequently extending the roll life. Can be designed.

Description

Axial roll-in-cylinder roll device {DEVICE OF ROLL HAVING CYLINDER WITHIN AND SHIFTING BY AXIS}

1 is a schematic view of a steering roll device according to the prior art;

2 is a schematic view of a ringer roll apparatus according to the prior art;

Figure 3 is a partially cutaway perspective view of the in-cylinder roll device moved in the axial direction according to the present invention;

4 is an exploded perspective view of an in-cylinder roll device moved in the axial direction according to the present invention;

5 is a cylinder hydraulic circuit diagram of the in-cylinder roll device in the axial direction in accordance with the present invention;

6 is an installation state diagram showing a state in which the in-cylinder-type roll device that is moved in the axial direction is installed on the steering roll;

Figure 7 is an installation schematic showing a state in which the built-in cylinder roll device to be moved to the ringer roll in the axial direction according to the present invention.

Explanation of symbols on the main parts of the drawings

1: strip 2: steering roll 3: steering roll frame

4: CPC sensor 5: hydraulic cylinder 6: ringer roll                 

7 ringer roll frame 11 cylinder 12 spline shaft a

13 spline shaft b 14 spring 15 shell cover a

16 shell cover b 17 roll shell 18 bearing housing a

19: bearing housing b 20: rotary joint

The present invention relates to a roll used in a cold rolling process of a steel mill, and more specifically, a deflector roll, a steering roll, a steering roll, a ringer roll, and a backup roll according to the purpose of use. In the roll divided into (Back Up Roll), the cylinder is moved in the axial direction to simplify the installation of the roll and to extend its life by automatically mounting the cylinder in the roll itself to move in the axial direction. It relates to a built-in roll device.

The prior art will be described with reference to FIGS. 1 and 2 as follows.

In general, the steering roll 2 shown in FIG. 1 is in contact with the strip, and the strip 1 passes by. In this process, meandering of the strip 1 occurs intermittently.

Therefore, in order to correct this, when the meandering degree of the strip 1 is detected by the CPC (Center Position Control) sensor 4, the steering roll frame 3 having the roll bearing block is installed at the center thereof by driving the hydraulic cylinder 5. The meandering of the strip 1 is corrected by fine rotation in the clockwise or counterclockwise direction.

As described above, the existing sting ring (2) is prevented from meandering by eccentricity of the left and right ends thereof for this purpose, two or more hydraulic cylinders (5) are installed on the steering roll frame (3) to the steering roll (2) Only when the eccentric work is performed, and the steering roll frame 3 and the sliding surface for rotating the steering roll frame 3 should be installed, and a number of other facilities that can detect the amount of left and right deviations are additionally installed. Should be.

As a result, it is difficult to install the steering roll 2 in a narrow space, and if a fault occurs in the device, a lot of manpower and expenses are required.

In addition, the ringer roll 6 shown in FIG. 2 is made of a rubber material, and the water remaining in the strip 1 is removed while being mutually compressed by the pressure transmitted from the cylinder to the roll bearing housing. ) And back-up roll (not shown) leave strip edge marks on the rubber coating due to pressure reduction during work, and as a result, edge marks are generated on the wide width material after narrow width work. At the same time, there has been a problem that the life of the roll is shortened due to shortening of the roll replacement cycle.

The present invention was created in view of the above-described problems of the prior art as described above. When the device according to the present invention is applied to a steering roll by allowing the roll device itself to move in the axial direction without moving the frame. In addition, it is not restricted by the installation place, and its maintenance efficiency can be improved. When applied to the ringer roll and the backup roll, the rolls are moved in the axial direction automatically during the operation so that strips of the same width can be used to continuously roll the roll surface. It is an object of the present invention to provide an in-cylinder roll device which is moved in the axial direction to improve the product quality and to extend the roll life in advance to prevent the generation of edge marks that have occurred in the past.

The above object of the present invention is a bearing housing a and a bearing housing b fixedly installed at both sides of the frame on which various kinds of rolls can be installed;

Spline shafts a and spline shafts b which are connected to the bearing housings a and the bearing housings b, and whose splines are formed on the surface thereof;

A shell cover a and a shell cover b inserted into the spline shaft a and the spline shaft b, respectively, and engaged to rotate together with the spline shaft a and the spline shaft b;

A hollow roll shell whose ends are sealed by the shell cover a and the shell cover b;

A spring inserted between the distal end of the shell cover a and the distal end of the spline shaft a;

It is achieved by providing an axially moved cylinder-shaped roll device, characterized in that it comprises a cylinder connected between each end of the shell cover a and the spline shaft b.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

Figure 3 is a partially cutaway perspective view of the axially moving cylinder-integrated roll apparatus according to the present invention, Figure 4 is an exploded perspective view of the axially moving cylinder-mounted roll device according to the invention, Figure 5 is in accordance with the present invention A cylinder hydraulic circuit diagram of an in-cylinder roll device moved in the axial direction.

According to the drawings, the bearing housing a (18) and the bearing housing (b) 19 are fixedly installed on both sides of the conventional frame in which various kinds of rolls are installed.

The shell cover a (15) and the shell cover (b) are formed so that the spline shaft a (12) and the spline shaft (13) are connected to the bearing housing a (18) and the bearing housing b (19), respectively. (16) is inserted into and connected to the spline shaft a (12) and the spline shaft (b).

The shell cover a (15) and the shell cover b (16) are provided with a hollow roll shell (17) in which both ends thereof are hermetically sealed to be engaged with the spline shaft (a) 12 and the spline shaft (b) 13, respectively. Each protrusion of the shell cover a 15 and the shell cover b 16 is located inside the roll shell 17.

Inside the shell cover a (15) is inserted a spring (14) contacting the distal end and the distal end of the spline shaft (a) 12.

A cylinder 11 is installed between each end portion of the shell cover a 15 and the spline shaft b 13, and a rod of the cylinder 11 is connected to the shell cover a 15 side and toward the spline shaft b 13. The cylinder 11 body is connected.

In addition, the cylinder 11 preferably uses a hydraulic cylinder. At this time, the spline shaft b 13 is formed in a hollow shape so that hydraulic pressure is supplied to the hydraulic cylinder, and the rotary joint 20 is connected to the distal end thereof.                     

For reference, FIG. 5 illustrates a hydraulic circuit diagram for supplying hydraulic pressure to the hydraulic cylinder so that the roll shell 17 moves in the axial direction.

Referring to Figures 3 to 7 the operational relationship of the present invention made of such a configuration as follows.

According to the figure, the roll shell 17 is moved in the axial direction according to the equilibrium relationship between the force of the spring 14 and the hydraulic cylinder embedded therein.

In more detail, during the initial roll installation, the hydraulic cylinder is set to have the same force generated by the hydraulic pressure as the spring 14 is compressed by x displacement.

Then, as described in the following equation, the force generated in the spring 14 is determined by the spring constant k and the displacement x. The spring constant is fixed so that the force of the spring 5 is determined by the compressed displacement x. do.

In addition, the force generated by the hydraulic cylinder is determined by the cylinder cross-sectional area A and the pressure P. Since the cross-sectional area A of the hydraulic cylinder is fixed at the time of cylinder selection, the force of the hydraulic cylinder is determined by the pressure P supplied. As follows.

F _Spring = k × x

F _Cylinder = P × A

F _Spring <F _Cylinder- → Move toward bearing housing a (18)

F _Spring > F _Cylinder- → Move in the direction of the bearing housing b (19)

That is, when the force applied to the hydraulic cylinder is lowered and less force is generated than the force generated in the spring 14, the roll shell 17 is moved in the direction toward the bearing housing b 19, and when the pressure applied to the hydraulic cylinder is increased. A force greater than that generated by the spring 14 is generated such that the roll shell 17 is moved in a direction toward the bearing housing a 18.

In addition, the extent to which the strip 1 meanders is received by the CPC sensor 4 or the sensor shown in FIG. 5 as shown in FIG. 6 or through other strip production information.

At this time, the information is transmitted to the controller shown in FIG. 5 to operate the servovalve, and thus the hydraulic cylinder is moved to the left side of the shaft. When the rightward movement is necessary, the servovalve is operated by the force of the spring 14. Is moved.

6 and 7 illustrate a state in which an in-cylinder roll device in the axial direction according to the present invention is applied to the steering roll 2 and the ringer roll 6.

In addition, while the apparatus according to the present invention has been described through the specific embodiments shown in the drawings, the apparatus according to the present invention may be variously modified and modified without departing from the spirit or the scope of the present invention provided by the claims below. Note that it can be changed.

As described in detail above, according to the present invention is connected to the bearing housing fixed to the frame and the frame is moved so that its own axial movement is possible without a separate frame moving device compared to the conventional roll moved with it Meandering is effectively controlled.

In addition, to move the entire frame in the axial direction, excessive equipment should be administered, but when the apparatus according to the present invention is applied to the roll itself is moved in the axial direction, no additional equipment administration is required, and applied to other ringer rolls or backup rolls, etc. Moving the roll shell in the axial direction prevents the strip edge from being weighted in one portion, resulting in an extension of the roll life.

Claims (1)

A bearing housing a 18 and a bearing housing b 19 fixed to both sides of the frame on which various kinds of rolls can be installed; A spline shaft a and a hollow spline shaft b which are connected to the bearing housing a 18 and the bearing housing b 19, respectively, and having a spline formed thereon; A shell cover a (15) and a shell cover (16) inserted into the spline shaft (a) and the spline shaft (13), respectively, and engaged with the spline shaft (a) and the spline shaft (b); A hollow roll shell 17 whose both ends are hermetically sealed by the shell cover a 15 and the shell cover b 16; A spring (14) inserted between the distal end of the shell cover a (15) and the distal end of the spline shaft a (12) inside the shell cover a (15); An axially moving cylinder-integrated roll, characterized in that it comprises a cylinder (11) connected between each end of the shell cover a (15) and the spline shaft (13) inside the roll shell (17) Device.

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