JPH056295Y2 - - Google Patents

Description

[Detailed description of the invention] "Industrial Application Field" This invention relates to a bridle device in a slitter line.

"Prior Art" Conventionally, in a slitter line for IC board strips in which a slitter is disposed between an uncoiler and a recoiler, sliders fixed in the direction of movement of the strip are provided on the recoiler side at the top and bottom, and the top and bottom of the top and bottom sliders are The inner surfaces of the upper and lower endless belts are brought into contact with the opposing surfaces, and the strip is sandwiched between the upper and lower endless belts, and the upper and lower sliders are pressed in opposite directions, and the frictional resistance of the front surface is greater than that of the back surface of the belt, and the belt is moved to the slider surface. It was necessary to provide a cooling device on the slider side for the frictional heat generated by the sliding motion. This is because the slider is fixed in the direction of movement with respect to the movement of the strip and belt, so the relative speed between the slider and the belt is large, which causes frictional heat to accumulate. Further, since the slider is fixed in the direction of movement, a change in speed occurs between the start of the strip and the constant speed movement of the strip, resulting in a change in frictional resistance and a change in the tension on the recoiler side. The change in tension causes the strip to oscillate laterally.

``Problems to be solved by the invention'' This invention does not use a cooling device and causes no temperature rise due to natural heat dissipation, and there is no change in frictional resistance or tension on the sliding surface between the belt and the roller, and the strip The purpose is to prevent runout.

"Means for Solving the Problem" The present invention is to provide a stripping pinch roller on the stand on the recoiler side of a slitter line in which a slitter is disposed between an uncoiler and a recoiler, and to pinch the strip on the outer circumferential surface of the roller. A pressing annular friction belt is slidably fitted to the outer circumferential surface of the belt, and a rotating drive device for the pinch roller and a sliding drive device for the pinch roller in opposite directions are provided, and the friction coefficient of the front surface of the belt is equal to that of the back surface. It consists of a bridle device in a larger slitter line.

``Operation'' Therefore, the strip 11 that has been sheared and divided by the slitter 8 passes through a U-shaped slack section suspended in the middle, and is tensioned by passing through a bridle device before being wound up by the recoiler 7. It is wound up by recoiler 7. In this bridle device, the stripping pinch rollers 2, 2 are rotated in reverse rotation by a rotary drive device 4, so that the stripping pinch rollers 2, 2 are rotated in opposite directions by a rotary drive device 4, and are moved at a speed higher than that of the annular friction belts 3, 3 and the strip 11 held between the belts 3, 3. By rotating the peripheral speed of the outer circumferential surface 2' of the rollers 2, 2 at a slightly slower speed, some frictional heat due to the speed difference between the outer circumferential surface 2' and the belt 3 is radiated and not accumulated, and the belt 3 and the roller The rise in temperature in step 2 is small and there is no need for forced cooling. Although the load due to the sliding resistance between the outer circumferential surface 2' and the belt 3 slightly increases the temperature of the rotary drive device 4, heat accumulation can be prevented by ventilation using an electric fan or the like. The belt 3 and the strip 11 move at the same speed without sliding on each other because the front surface of the belt 3 has greater frictional resistance than the back surface. The transition speed of the strip 11 and the belt 3 is the same speed as the winding peripheral speed of the recoiler 7, and the peripheral speed of the outer peripheral surface 2' of the roller 2 can be set at a constant ratio to the winding peripheral speed. Therefore, the frictional resistance between the belt 3 and the outer circumferential surface 2' of the roller 2 can be kept constant. Therefore, the pulling tension of the strip 11 is also constant.

Embodiment A slitter 8 is disposed between an uncoiler 6 and a recoiler 7 supported on the floor, and bits 9 and 9' are formed on both sides of the slitter 8 to form a slack portion of the strip. The strip plate 10 unwound from the uncoiler 6 is a copper plate plated with gold, and is divided and sheared into IC board strips 11 by a slitter 8.
The strip 11 is wound around the recoiler 7 to form a slitter line. Stands 1, 1 are provided between the bit 9 and the recoiler 7, and the pinch rollers 2, 2 of the strip 11 are installed vertically between the stands 1, 1, and the upper roller 2 has bearings 1 at both ends.
2 is supported so as to be movable up and down along the guide grooves 13 of the stands 1, 1, and a cylinder 5' is connected to the same bearing 12 to form an opposing sliding drive device 5. The rotation shafts 14, 14 of the upper and lower rollers 2, 2 are respectively connected to interlocking gears 17, 18 that mesh with each other via two universal joints 15, 15 and a spline 16, and the rotation shaft 19 of one gear 18 is By connecting to the DC motor 20, a rotational drive device 4 for the pinch rollers 2, 2 is formed. Annular friction belts 3, 3 are fitted onto the outer circumferential surfaces 2', 2' of the pinch rollers 2, 2, respectively, and the belts 3 and the outer circumferential surfaces 2' are held slidably. The frictional resistance of the surface is greater than that of the back surface. Therefore, as the strip 11 held between the belts 3, 3 moves, the belts 3, 3 rotate without sliding on the strip 11, so that the belt 3 and the outer circumferential surface 2' of the roller 2 are mutually aligned. It will slide on. The speed of transition of the strip 11 corresponds to the peripheral speed of the recoiler 7, which is kept constant by the control device. Therefore, since the speed of transition of the strip 11 is also constant, the DC motor 20
The circumferential speed of the rollers 2, 2 can also be kept constant. The difference between the speed of the strip 11 and the peripheral speed of the roller 2 can be maintained at a constant ratio,
By keeping the ratio below 10%, the speed difference and frictional resistance between the outer peripheral surface 2' of the roller 2 and the belt 3 and the tension of the strip 11 can be kept constant. Strip 11 speed is 100
m/min, the circumferential speed of rollers 2 and 2 is 90 m/min.
min or 90m/min or higher.

"Effects" Since the present invention is constructed as described above, firstly, there is no need to provide a forced cooling device in the bridle device for the recoiler 7 of the slitter line, and the tension of the strip 11 can be maintained constant to prevent lateral vibration. This can prevent damage caused by lateral vibration.

[Brief explanation of the drawing]

Figure 1 is a side view showing the bridle device in the slitter line of the present invention, and Figure 2 is Figure 1 A-A.
FIG. 3 is a partially enlarged view of FIG. 1; DESCRIPTION OF SYMBOLS 1...Stand, 2...Pinch roller for the strip, 2'...Outer peripheral surface, 3...Annular friction belt for strip pinching, 4...Rotary drive device, 5...Sliding drive device in opposing directions.

Claims (1)

[Scope of utility model registration request] On the recoiler side of a slitter line in which a slitter is arranged between an uncoiler and a recoiler, a pinch roller for stripping is provided on the stand, and an annular friction belt for pinching the strip is slidably attached to the outer circumferential surface of the roller. mated to,
and a rotational drive device for the pinch roller and a sliding drive device for the pinch roller in opposite directions,
A bridle device for a slitter line in which the friction coefficient of the front surface of the belt is larger than that of the back surface.