JPS63235004A - Rolling mill - Google Patents

Abstract

PURPOSE:To easily and quickly charge interval between housings by pushing a flange of tension bar and also a spacer to be possible to fitting/detaching to the other housing by working a hydraulic cylinder and fixing to the other housing. CONSTITUTION:In the case of a narrowing interval between the housings, a solenoid valve 40 is turned to T side and a clamp cylinder 24 is retreated and the spacer 23 is made to open-state by working a cylinder. Next, by working a shift cylinder, the shifting side housing 1 is shifted to the fixed side housing 2. Successively, after the spacer 23 is closed by working the cylinder, the solenoid valve 40 is turned to P side and the clamp cylinder 24 is worked, and by pressing the flange part of the tension bar 19 and the spacer 23 to the fixed side housing, the tension bar 19 is fixed to the fixed side housing 2. In this way the shifting side housing 1 is safely fixed to the fixed side housing 2 through the tension bar 19 in a short time without any handworking or crane- operation.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a multi-purpose, versatile rolling mill, in particular a rolling mill for rolling shaped steel and sheet steel.

[Conventional technology]

As described in Japanese Patent Application Laid-Open No. 139866/1986, a conventional rolling mill has a fixed side housing and a movable side housing facing each other on the upper surface of a housing shell fixed on a foundation so that the interval between them can be adjusted. The rollers are arranged in parallel with the roll axis and are fixed to the housing shell with a predetermined housing spacing, fixed to the cylinder via a wedge, and are rotatably supported between the housings. Both housings are fixed at a predetermined distance by four tension bars via spacers.

When changing the housing spacing to rearrange the rolls, it is necessary to replace the tension bar and spacer, and this replacement work requires crane work and manual intervention, which makes the work dangerous. In addition, due to restrictions on the use of cranes, it takes a long time to reassemble the rolls, resulting in a reduction in production.

[Problem that the invention seeks to solve]

In the above-mentioned conventional technology, when changing the housing interval during roll rearranging, manual intervention is required, which poses a risk to the work and takes a long time to rearrange the rolls.

An object of the present invention is to provide a rolling mill that eliminates the above-mentioned problems and does not require manual handling when changing the housing spacing.

[Means for solving problems]

The above object is to provide a rolling mill in which the interval between both housings that rotatably support a roll shaft is adjustable, in which one end of a tension bar is fixed to one housing in a direction parallel to the roll shaft;
The other end of the tension bar passes through the other housing, and the other end is provided with a flange, and is fixed to the other housing and is actuated by a hydraulic cylinder that is movable in a direction parallel to the roll axis, This is achieved by providing a rolling mill characterized in that the tension bar is fixed to the other housing by pressing both the flange of the tension bar and a removable spacer against the other housing.

[Effect]

In the rolling mill according to the present invention configured in this manner, the spacer is detachable, so the hydraulic cylinder presses the tension bar flange and the spacer against the other housing by changing the order of the flange and the spacer, or changing the order of the spacer and the tension bar flange. Since the tension bar is fixed by adjusting the distance between the two housings, the distance between the two housings is adjusted and the two housings are fixed.

〔Example〕

Embodiments of the present invention will be described with reference to the drawings. Figure 1 shows the engineering mold steel.
This is an overall side view of a rolling mill in a state where the housings are fixed with a wide spacing when rolling L-shaped steel and plate steel with double rolls, etc., and one housing 1, that is, the movable side housing has bolts 36, It is disposed on the upper surface of the housing shoe 4 fixed to the foundation with a nut 27 so as to be movable in a direction parallel to the roll axis. The other housing 2, that is, the stationary housing, is mounted on the housing shoe 4, facing the movable housing 1, with bolts 34. It is fixed by a nut 35.

These housings are equipped with a lowering device 30 for horizontal rolls.
is installed in the upper part, and a lowering device ei31 is installed in the lower part.

To fix the movable housing 1, see FIG.

As shown in FIG. 5, in the legs of the moving housing 1, the cylinder 1 attached to the moving housing
7 is activated to bring the sloped surface a of the block 43 connected to the tip of the cylinder 17 into contact with the sloped surface a of the housing shoe 4, thereby fixing the movable housing 1. Further, in the center of the movable housing 1, a tension bar 19 fixed to the movable housing 1 with a nut 20 passes through the fixed housing 2, and is fixed to a frame 22 fixed to the fixed housing 2. Hydraulic cylinder 24. That is, by the operation of the clamp cylinder,
The tension bar 19 and the spacer 23 are pressed against and fixed to the stationary housing 2, and the tension bar 19 is fixed to the stationary housing 2.

In the rolling state, pressure oil passes through the P side of the solenoid valve 40 and acts on the clamp cylinder 24, pushing the tension bar 19 and spacer 23, thereby fixing the movable housing 1 to the stationary housing 2.

During rolling, the roll tends to expand and contract in the direction of the roll axis 3, and a method of restraining this will be explained with reference to FIGS. 5 and 9. When the roll shaft 3 tries to push in its axial direction, the roll shaft 3 acts on the moving side housing 1 via the chock clamp 42 fixed to the moving side housing 1, and tries to widen the housing interval. Although the force is applied, the tension bar 19 fixes both housings by the nut 20 and the flange of the tension bar 19, and the tension bar 1
9 is in a state where a tensile force is applied.

Conversely, when the roll shaft 3 tries to contract in its axial direction, a force acts on the moving side housing 1 through the flange of the roll shaft 3 to narrow the distance between the housings, but the tension bar 19 The movable housing 1 is pushed outward at one end, and the clamp cylinder 24 attached to the fixed housing 2 is pushed at the other end to generate a compressive force on the tension bar 19, thereby fixing both housings.

Therefore, the clamp cylinder 24 has a capacity large enough to not be pushed back by the applied load.

The mechanism by which the spacer 23 opens and closes around the tension bar 19 is as shown in FIG.

The spacer 23, which is divided into two parts in the longitudinal direction, is rotatably attached around a pin 29 attached to a frame 22 fixed to the stationary housing 2, and opens and closes around the tension bar 19. .

To open and close the spacer 23, a pin 27 is attached to the frame 22, a pin 26 is attached to each of the two halves of the spacer 23, and each end of the cylinder 25 is attached to the pin 27, respectively. Pin 18. A lever 41 is connected to the spacer 23, the frame 22, and the cylinder 25 via the block 28, and when the cylinder 25 is opened,
The lever 41 rotates about the pin 27, causing each of the two halves of the spacer 23 to pivot in opposite directions around the pin 29, resulting in a closed state.

In FIG. 8, the cylinder 25 is operated to the closing side.

The spacer 23 is shown in an open state, and in this state, the flange portion of the tension bar 19 can work in a direction parallel to the roll axis without hitting the spacer 23.

Next, a case will be described in which the housing interval is narrowed for H-type adjustment rolling.

As shown in FIG. 6, the solenoid valve 40 is moved to the T side to move the clamp cylinder 24 backward, and then the spacer 23 is opened by operating the cylinder 25 as shown in FIG. .

Next, as shown in FIG. 4, the sloped surface a of the block 43 is separated from the sloped surface of the housing shoe 4 by the operation of the cylinder 17, and the bolt 38. The shift cylinder 5 held on the bracket 6 fixed to the foundation with a nut 39 is operated to move the movable housing 1 toward the stationary housing 2.

Next, the spacer 23 is moved by the operation of the cylinder 25.
After closing as shown in FIG. 7, as shown in FIG. 6, switch the solenoid valve 40 to the P side, operate the clamp cylinder 24, and press the flange of the tension bar 19 and the spacer 23 against the fixed housing. This fixes the tension bar 19 to the stationary housing.

Next, the cylinder 17 pushes the block 43 to bring the sloped surface a into contact with the sloped surface a of the housing shoe 4, thereby fixing the legs of the movable housing 1 to the housing shoe 4.

FIG. 2 shows an overall side view of the rolling mill in which the horizontal rolls 7 and hard rolls 8 have been assembled after the above operations have been completed. The installed state of the rigid roll is shown in FIG. 3. Even in this state, the movable housing 1 can be safely and quickly attached to the stationary housing 2 via the tension bar 19 without manual work or crane work. is fixed.

〔Effect of the invention〕

According to the present invention, when changing the housing spacing in order to rearrange the rolls of a rolling mill, there is no need for manual intervention or crane work, so there is no danger in the work, and there are no restrictions on the use of the crane. Since this eliminates the need for damage, the housing spacing can be changed easily and quickly, and production can therefore be increased.

Furthermore, since the output direction of the hydraulic cylinder 24 is the same as the fixing direction of the tension bar 19 that fixes the two housings, even if the tension bar 19, the spacer 23, and the contact surfaces between the two housings wear out.

The moving housing 1 can be reliably fixed by pushing the hydraulic cylinder 24 using its extra stroke. Therefore, the effect of ensuring and maintaining the rolling accuracy of the rolled material can be expected.

[Brief explanation of the drawing]

Fig. 1 is an overall side view showing sheet steel rolling, Fig. 2 is an overall side view showing H-shaped adjustment rolling, Fig. 3 is a cross-sectional view taken along the line I-I in Fig. 2, and Fig. 4 is a view of Fig. 1. ■-■ cross-sectional view of
Figure 6 is a cross-sectional view taken along line IX-IK in Figure 2, Figure 7 is a cross-sectional view taken along line x-X in Figure 6, and Figure 8 is a cross-sectional view viewed from Figure 7. , when viewed from the cross-sectional arrow showing the open state of the spacer 1. FIG. 9 shows a cross-sectional view along the arrow X in FIG. 1. 1... One housing, 2... The other housing. 3... Roll axis, 19... Tension bar, 23...
...Spacer, 24...Hydraulic cylinder, 50...
・Rolling machine.

Claims (1)

[Claims] 1. In a rolling mill in which the distance between both housings that rotatably support a roll shaft can be adjusted, one end of a tension bar is fixed to one housing in a direction parallel to the roll shaft, and the other end of the tension bar is fixed to the other housing. The flange of the tension bar, a removable spacer and A rolling mill characterized in that the tension bar is fixed to the other housing by pressing both of the tension bars against the other housing.