The present invention relates to a coiled material passing device and a coiled material passing method.
A coiled material such as a steel sheet wound in a coil is used as a material in pressing machines and the like. A configuration comprising an uncoiler, a coiled material passing mechanism, and a leveler has been disclosed as a system for supplying such a coiled material to a pressing machine (see JP-A H11-169951, for example).
In JP-A H11-169951, after the coiled material is placed in the uncoiler, the starting end of the coiled material is passed through the leveler by the coiled material passing mechanism.
With the coiled material passing mechanism in JP-A H11-169951, a loop guide is raised to play out the coiled material, and a threading roll that also serves as an upper pinch roll is moved, thereby pressing in on the starting end of the coiled material. This movement of the threading roll causes the starting end of the coiled material to be clamped between the threading roll and the drive pinch roll. The drive pinch roll is then driven so that the starting end of the coiled material is fed into the leveler.
However, the following problems are encountered with the coiled material passing mechanism in the above-mentioned JP-A H11-169951.
In order to press in the starting end of the coiled material with the threading roll, it is necessary to feed the starting end of the coiled material up to a position beyond the threading roll, but the sheet cannot pass through if the starting end of the coiled material catches on the surrounding structure.
Also, when the starting end of the coiled material is pushed down toward the drive pinch roll by the threading roll, the threading roll moves while scribing an arc from the uncoiler side to the leveler side, so if only a small amount of the coiled material is played out from the uncoiler, there is a possibility that the starting end of the coiled material may come off from the threading roll. Conversely, if a large amount of the coiled material is played out, the starting end of the coiled material may be bent by the threading roll and the upper stop guide on the leveler feeder side. For this reason, the operator has to make fine adjustments to the amount of playout in order to stably pass the coiled material played out from the uncoiler to the leveler.
In view of the above problems encountered in the past, it is an object of the present invention to provide a coiled material passing device and a coiled material passing method with which the passing of a coiled material can be carried out stably.
The coiled material passing device pertaining to the first aspect is a coiled material passing device for passing a coiled material played out by an uncoiler to a leveler feeder that corrects any winding curl of the coiled material, said device comprising a damper, a moving body, and a first driver. The clamper clamps the starting end of the coiled material played out from the uncoiler. The moving body supports the clamper and is able to move between the uncoiler and the leveler feeder. The first driver moves the moving body.
Consequently, the starting end of the coiled material can be passed through the leveler feeder by moving the moving body to the leveler feeder in a state in which the starting end of the coiled material is clamped by the damper.
That is, since the clamper can be moved, the starting end of the coiled material can be clamped near the uncoiler, for example. Therefore, there are substantially no members that will interfere with the starting end of the coiled material, which reduces the possibility that the starting end of the coiled material will catch on the device components.
Also, after the starting end of the coiled material is clamped near the coiled material, the damper moves in a clamped state and the starting end of the coiled material moves to the leveler feeder, so the coiled material can be easily fed into the leveler feeder without the operator having to make fine adjustments to the amount of playout of the coiled material as in the past.
As mentioned above, it is easy to stably pass the starting end of the coiled material played out from the uncoiler to the leveler feeder.
The coiled material passing device pertaining to the second aspect is the coiled material passing device pertaining to the first aspect, wherein the clamper has a first roll, a second roll, and a second driver. The first roll is capable of moving between a clamping position at which the starting end of the coiled material played out from the uncoiler is clamped and a standby position above the center of the coiled material attached to the uncoiler. The second roll is disposed below the first roll and clamps the coiled material played out from the uncoiler, along with the first roll disposed at the clamping position. The second driver moves the first roll between the clamping position and the standby position.
Consequently, the first roll can be moved downward and the starting end of the coiled material can be clamped between the first roll and the second roll.
Also, in the standby position, since the first roll is disposed above the center of the coiled material, when the coiled material is rotated in the reverse direction, the starting end of the coiled material that has passed the first roll will be located below the first roll. Therefore, the starting end of the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
Also, since the starting end of the coiled material is positioned below the first roll merely by reverse rotation, there is no need to feed the coiled material forward before the starting end of the coiled material is clamped, and the coiled material can be clamped stably.
The coiled material passing device pertaining to the third aspect is the coiled material passing device pertaining to the second aspect, wherein the standby position is a position near the outer periphery of the coiled material attached to the uncoiler in a state in which the moving body has been moved to the uncoiler side by the first driver.
Since the first roll is thus put on standby near the outer periphery of the coiled material, even if the coiled material is very stiff, the starting end of the coiled material that has passed the first roll is positioned below the first roll by reversely rotating the coiled material and protrudes on the downstream side. Therefore, the starting end of the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
The coiled material passing device pertaining to the fourth aspect is the coiled material passing device pertaining to the first aspect, wherein the moving body has a support. The support is disposed more on the uncoiler side than the second roll, and supports the played out coiled material from below. The support hits the outer periphery of the coiled material in a state of being attached to the uncoiler by the movement of the moving body to the uncoiler side with the first driver.
The support thus hits the outer periphery of the coiled material and supports the coiled material from below, which allows the coiled material unwound from its coiled state to be stably supplied between the first roll and the second roll.
This eliminates the need for a loop guide under the coiled material.
The cold material passing device pertaining to the fifth aspect is the coiled material passing device pertaining to the third aspect, wherein the moving body has a support. The support is disposed more on the uncoiler side than the second roll, and supports the played out coiled material from below. The support hits the outer periphery of the coiled material in a state of being attached to the uncoiler by the movement of the moving body to the uncoiler side with the first driver. The support is formed in a curved shape. The length along the curve from the second roll to the contact position where the support hits the coil material in a state of being attached to the uncoiler is shorter than the length around the outer periphery of the coiled material from the contact position to the outer peripheral position closest to the standby position of the coiled material in a state of being attached to the uncoiler.
Consequently, the coiled material can be rotated in the reverse direction so that the length of the portion separated from the coiled state of the coiled material that has passed the first roll at the standby position is longer than the length from the contact position to the position of the second roll, so the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
The coiled material passing method pertaining to the sixth aspect is a coiled material passing method for passing a coiled material played out by an uncoiler through a leveler feeder that corrects any winding curl of the coiled material, said method comprising a reverse rotation step, a clamping step, and a movement step. The reverse rotation step involves reversing the rotation of the uncoiler until the starting end of the coiled material passes a first roll disposed near the outer periphery and above the center of the coiled material in a state of being attached to the uncoiler. The clamping step involves moving the first roll toward a second roll disposed below the first roll so that the first roll hits the starting end of the coiled material from above, and the starting end of the coiled material is clamped between the first roll and the second roll. The movement step involves moving the first roll and the second roll to the leveler feeder in a state in which the starting end of the coiled material is clamped.
Consequently, the starting end of the coiled material can be clamped near the uncoiler. Therefore, it is less likely that the starting end of the coiled material will catch on something.
Also, after the starting end of the coiled material is clamped near the coiled material, the clamping part moves in a clamped state, and the starting end of the coiled material moves to the leveler feeder, so the coiled material can be easily fed to the leveler feeder without the operator having to make fine adjustments to the amount of playout of the coiled material as in the past.
As discussed above, it is easy to stably pass the starting end of the coiled material played out from the uncoiler to the leveler feeder.
Also, the starting end of the coiled material that has passed the first roll is positioned below the first roll by rotating the coiled material in the reverse direction, so the starting end of the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
Also, since the first roll is disposed above the center of the coiled material, the starting end of the coiled material that has passed the first roll is positioned lower than the first roll when the coiled material is rotated in reverse. Therefore, the starting end of the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
Also, since the starting end of the coiled material is positioned lower than the first roll by reverse rotation, there is no need to feed the coiled material forward before it is clamped, and the coiled material can be clamped stably.
Also, since the first roll stands by near the outer periphery of the coiled material, even when the coiled material is very stiff, the coiled material is rotated reversely, and the starting end of the coiled material that has passed the first roll is positioned lower than first roll and protrudes to the downstream side. Therefore, the starting end of the coiled material can be clamped between the first roll and the second roll by moving the first roll downward.
The present invention provides a coiled material passing device and a coiled material passing method with which it is easy to perform stable passing of the material.
A coil line system comprising the coiled material passing device in an embodiment of the present invention will now be described through reference to the drawings.
1. Configuration
1-1. Overview of Coil Line System 1
The leveler feeder 2 corrects winding curl and the like in the coiled material 100 supplied from a receiver port 21. The coiled material 100 is supplied from the uncoiler 3 to the receiver port 21 of the leveler feeder 2.
The uncoiler 3 unwinds the coiled material 100 (a steel sheet, etc., that is wound in a coil) while feeding it to the leveler feeder 2.
The coiled material passing device 4 is provided more or less between the leveler feeder 2 and the uncoiler 3. The coiled material passing device 4 automatically guides the starting end 100s of the coiled material 100 played out from the uncoiler 3 to the receiver port 21 of the leveler feeder 2.
The downstream side of the coiled material 100 in the transport direction is shown as X, and the upstream side is shown as Y.
The system controller 5 transmits commands to the leveler feeder 2, the uncoiler 3, and the coiled material passing device 4 on the basis of worker input from a control panel (not shown).
1-2. Leveler Feeder 2
As shown in
The receiver port 21 is formed on the uncoiler 3 side of the leveler feeder 2, and receives the coiled material 100 played out from the uncoiler 3. The receiver port 21 is formed by an upper guide plate 21a and a lower guide plate 21b that are disposed one above the other. The upper guide plate 21a and the lower guide plate 21b are formed with the uncoiler 3 side inclined so that the vertical spacing between them increases moving toward the uncoiler 3.
Any distortion or winding curl in the coiled material 100 supplied from the receiver port 21 is corrected by the upper work rolls 22 and the lower work rolls 23. The coiled material 100 is then played out from a delivery port via the upper feed roll 24 and the lower feed roll 25, and is supplied to a press die (not shown). The release drive cylinder 26 is linked to the upper work rolls 22, and separates the upper work rolls 22 from the lower work rolls 23. The upper feed roll press-down cylinder 27 adjusts the pressing of the upper feed roll 24 against the lower feed roll 25. The rotation of the leveler feeder drive motor 28 is decelerated by the leveler feeder drive speed reducer 29, and then rotates the upper feed roll 24 and the lower feed roll 25 to convey the coiled material 100.
The leveler controller 20 controls the release drive cylinder 26, the upper feed roll press-down cylinder 27, and the leveler feeder drive motor 28, as shown in
1-3. Uncoiler 3
The uncoiler 3 unwinds and plays out the required amount of the coiled material 100, which is wound in a coil shape. As shown in
The coil support 30 rotatably supports the Coiled material 100 that is wound in a coil. The coil guide 31 guides the playout of the coiled material 100. The hold-down roll 32 holds the coiled material 100 down.
The drive mechanism 33 shown in
The uncoiler controller 34 controls the drive mechanism 33, the hold-down roll 32, and the like on the basis of commands from the system controller 5.
1-4. Coiled Material Passing Device 4
The coiled material passing device 4 passes the starting end 100s of the coiled material 100 played out from the uncoiler 3 into the receiver port 21 of the leveler feeder 2. As shown in
1-4-1. Catenary Component 42
The support plates 51 are disposed across from each other, facing left and right in the X and Y directions of the coiled material 100. The support plates 51 are substantially fan shaped, with a central angle of about 90 degrees, one radius portion 51a is disposed horizontally, and the other radius portion 51b is disposed in the vertical direction. An arc portion 51c is formed on the uncoiler 3 side (the upstream direction Y side).
The support 52 is disposed between the pair of support plates 51 and curves along the arc portions 51c. The support 52 has a plurality of free rolls 61, a catenary side guide 62, and a guide plate 63. In
In
1-4-2. Clamper 41
As shown in
The lower pinch roll 71 and the threading roll 73 clamp the coiled material 100. The threading roll driver 76 moves the threading roll 73 between a standby position Pw (see
Lower Pinch Roll 71
As shown in
Pinch Roll Drive Motor 72
As shown in
Threading Roll 73
As shown in
Link 74
As shown in
The first link members 81 are rotatably provided on the outside of the support plates 51. The first link members 81 are connected to each other at connecting parts 85 at one end thereof by the rod-shaped connecting member 84 that passes perpendicularly through the pair of support plates 51. The connecting member 84 is disposed at the end of the support plates 51 on the upstream direction Y side (near the edge of the arc portions 51c).
One end of a second link member 82 is disposed rotatably with the other end of a first link member 81 at a connecting part 86. The threading roll 73 is rotatably disposed at the ends 82a of the second link members 82 on the opposite side from the connecting parts 86. The third link members 83 are rotatably supported at one end 83a thereof by the support plates 51. The ends 83a are attached on the upstream direction Y side of the lower pinch roll 71, on the outside of the support plates 51. The third link members 83 are rotatably linked at their other end to the second link members 82 at connecting parts 87. The connecting parts 87 are provided between the connecting parts 86 and the ends 82a.
Link Driver 75
As shown in
The linking lever 92 is fixed to the connecting member 84, and its distal end is connected to the distal end of the rod 91a so as to be rotatable in the XY direction.
In the state shown in
On the other hand, when the rod 91a is contracted in the downstream direction X from the state shown in
Consequently, the threading roll 73 moves downward toward the lower pinch roll 71 (see the arrow Q).
1-4-3. Driver 43
The driver 43 moves the catenary component 42 between the leveler feeder 2 and the uncoiler 3. As shown in
As shown in
The encoder 113 is disposed at an end of the catenary drive ball screw 112 in the upstream direction Y. Rotation of the catenary drive ball screw 112 can be detected by the encoder 113, and the position of the catenary component 42 in the XY direction can also be detected. As shown in
1-4-4. Passing Controller 44
The passing controller 44 controls the pinch roll drive motor 72, the threading roll drive cylinder 91, the catenary drive motor 111, and the catenary side guide 62 on the basis of a command from the system controller 5. The passing controller 44 controls the catenary drive motor 111 on the basis of the value detected by the encoder 113 to control the position of the catenary component 42 in the XY direction. Also, the passing controller 44 controls the catenary side guide 62 to match the position of the opposing pair of side guides 62b to the width of the coiled material 100.
2. Operation
The operation of the coil line system 1 in an embodiment of the present invention will now be described, and an example of the coiled material passing method of the present invention will also be discussed at the same time.
2-1. Coiled Material Passing Operation
First, in step S11, the threading roll 73 is in the standby position (see
Next, in step S12, the uncoiler controller 34 controls the drive mechanism 33 to rotate the coiled material 100 reversely (see the arrow T1 in
When the coiled material 100 is rotated reversely and the starting end 100s of the coiled material 100 goes past the threading roll 73, in step S13 the uncoiler controller 34 controls the drive mechanism 33 to stop the rotation of the coiled material 100. An encoder or the like provided in the drive mechanism 33 detects that the starting end 100s has passed the threading roll 73.
When the starting end 100s of the coiled material 100 passes the threading roll 73, the starting end 100s is separated from the outer periphery 100e of the coiled material 100 under its own weight, by its rigidity, etc., as shown in
The starting end 100s of the coiled material 100 protrudes more on the downstream direction X side than the threading roll 73, as shown in
Next, in step S14, the passing controller 44 lowers the threading roll 73 from the standby position Pw to the clamping position Ps at which the threading roll 73 presses on the lower pinch roll 71. More precisely, the passing controller 44 drives the threading roll drive cylinder 91 to contract the rod 91a in the downstream direction X. Consequently, as shown in
That is, as shown in
When the threading roll 73 moves to the clamping position Ps where the threading roll 73 presses on the lower pinch roll 71, as shown in
Next, in step S15, the passing controller 44 drives the catenary drive motor 111 to move the catenary component 42 to the leveler feeder 2 in a state in which the starting end 100s is clamped. Since the lower pinch roll 71 and the threading roll 73 mesh with each other at the gears 71a and 73a at both ends of the rolls, the clamped state of the starting end 100s of the coiled material 100 is maintained even during movement. The passing controller 44 stops the catenary component 42 in front of the leveler feeder 2 on the basis of the detected value from the encoder 113.
Next, in step S16, the passing controller 44 drives the pinch roll drive motor 72 to rotationally drive the lower pinch roll 71 and the threading roll 73.
The rotation of the lower pinch roll 71 and the threading roll 73 causes the starting end 100s of the coiled material 100 to be supplied to the receiver port 21 formed by the upper guide plate 21a and the lower guide plate 21b.
The coiled material 100 can be passed to the leveler feeder 2 by the above operation.
2-2 Winding of Coiled Material
Next, the operation for winding the coiled material will be described.
When the pressing operation ends, if there is still some coiled material 100, this coiled material 100 is wound up and stored.
After the pressing operation ends and the coiled material 100 has been cut, the uncoiler controller 34 controls the drive mechanism 33 to rotate the coiled material 100 backward to perform the winding operation of the coiled material 100. Then, any slack in the coiled material 100 produced in the pressing operation is wound up to put the coiled material 100 in a taut state.
From this taut state, the uncoiler controller 34 rotates the coiled material 100 backward to wind up the coiled material 100, and along with this winding, the passing controller 44 moves the catenary component 42 toward the uncoiler 3 in a state in which the coiled material 100 is clamped by the damper 41.
By thus moving the catenary component 42 to near the coiled material 100, it is possible to wind up the coiled material 100 into a tight coil, with as little slack as possible. That is, since the back tension produced by the threading roll 73 and the lower pinch roll 71 can be loaded near the outer periphery 100e of the coiled material 100, the coiled material 100 can be wound without loosening.
Also, the catenary component 42 moves to a position where the threading roll 73 hits the coiled material 100, the support 52 (the free rolls 61, etc.) of the catenary component 42 is pressed against the coiled material 100, and the end of the unwound coiled material 100 is guided by the catenary side guide 62 to near the outer periphery 100e, so offset in the width direction of the coiled material 100 can also be reduced.
3. Features
(3-1)
The coiled material passing device 4 in this embodiment is a coiled material passing device for passing a coiled material 100 played out by an uncoiler 3 to a leveler feeder 2 that corrects any winding curl in the coiled material, and comprises the clamper 41, the catenary component 42 (an example of a moving body), and the driver 43 (an example of a first driver). The clamper 41 clamps the starting end 100s of the coiled material 100 played out from the uncoiler 3. The catenary component 42 supports the clamper 41 and is able to move between the uncoiler 3 and the leveler feeder 2. The driver 43 moves the catenary component 42. Therefore, the starting end 100s of the coiled material 100 can be passed through the leveler feeder 2 by moving the catenary component 42 to the leveler feeder 2 in a state in which the starting end 100s of the coiled material 100 is clamped by the clamper 41.
That is, since the clamper 41 can be moved, the starting end 100s of the coiled material 100 can be clamped near the uncoiler 3, for example. Therefore, there are substantially no members that will interfere with the starting end 100s of the coiled material 100, which reduces the possibility that the starting end 100s of the coiled material 100 will catch on the device components.
Also, after the starting end 100s of the coiled material 100 has been clamped near the coiled material 100, the damper 41 moves in this clamped state, and the starting end 100s of the coiled material 100 is moved to the leveler feeder 2, so the operator does not have to make fine adjustments to the amount of playout of the coiled material as in the past, and the coiled material 100 can be easily fed into the leveler feeder 2.
As described above, the starting end 100s of the coiled material 100 played out from the uncoiler 3 can be easily and stably passed through the leveler feeder 2.
(3-2)
With the coiled material passing device 4 in this embodiment, the damper 41 has the threading roll 73 (an example of a first roll), the lower pinch roll 71 (an example of a second roll), and the threading roll driver 76 (an example of a second driver). The threading roll 73 is able to move between the clamping position Ps at which the starting end 100s of the coiled material 100 played out from the uncoiler 3 is clamped, and the standby position Pw above the center 100a of the coiling material 100 in a state of being attached to the uncoiler. The lower pinch roll 71 is disposed below the threading roll 73, and, along with the threading roll 73 disposed in the clamping position Ps, clamps the coiled material 100 played out from the uncoiler 3. The threading roll driver 76 moves the threading roll 73 between the clamping position Ps and the standby position Pw.
As a result, the threading roll 73 can be moved downward and the starting end 100s of the coiled material 100 can be clamped between the threading roll 73 and the lower pinch roll 71. Also, since the threading roll 73 is disposed above the center 100a of the coiled material 100, the starting end 100s of the coiled material 100 which has passed the threading roll 73 by reverse rotation of the coiled material 100 is positioned lower than the threading roll 73. Therefore, the starting end 100s of the coiled material 100 can be clamped between the threading roll 73 and the lower pinch roll 71 by moving the threading roll 73 downward.
Also, since the starting end 100s of the coiled material 100 is positioned lower than the threading roll 73 merely by rotating the coiled material 100 reversely, the coiled material 100 can be stably clamped, without having to rotate and feed the coiled material 100 forward before the starting end 100s of the coiled material 100 has been clamped.
(3-3)
With the coiled material passing device 4 in this embodiment, in a state in which the catenary component 42 has been moved to the uncoiler 3 side by the driver 43, the standby position Pw is a position near the outer periphery 100e of the coiled material 100 in a state of being attached to the uncoiler 3.
Since the threading roll 73 is thus put on standby near the outer periphery 100e of the coiled material 100, even if the coiled material 100 is very stiff, the starting end 100s of the coiled material 100 that has passed the threading roll 73 is positioned below the threading roll 73 by reversely rotating the coiled material 100 and protrudes on the downstream direction X side. Therefore, the starting end 100s of the coiled material 100 can be clamped between the threading roll 73 and the lower pinch roll 71 by moving the threading roll 73 downward.
(3-4)
With the coiled material passing device 4 in this embodiment, the catenary component 42 has the support 52. The support 52 is disposed more on the uncoiler 3 side than the lower pinch roll 71, and supports the played-out coiled material 100 from below. The support 52 hits the outer periphery 100e of the coiled material 100 attached to the uncoiler 3 as a result of the movement of the catenary component 42 to the uncoiler 3 side by the driver 43.
Thus, the support 52 hits the outer periphery 100e of the coiled material 100 and supports the coiled material 100 from below, allowing the coiled material 100 unwound from a coiled state to be stably supplied between the threading roll 73 and the lower pinch roll 71.
This eliminates the need for a loop guide below the coiled material.
(3-5)
With the coiled material passing device 4 in this embodiment, the support 52 is disposed in a curved shape. The length L2 along the curve from the contact position P2 between the support 52 and the coiled material 100 attached to the uncoiler 3, to the lower pinch roll 71 is shorter than the length L1 along the outer periphery 100e of the coiled material 100 from the outer peripheral position P1 closest to the standby position Pw of the coiled material 100 attached to the uncoiler 3, to the contact position P2.
As a result, the length of the portion of the coiled material 100 separated from its coiled state, which has passed the threading roll 73 as a result of the reverse rotation of the coiled material 100, is approximately L1. Since this length L1 is longer than the length L2 from the contact position P2 to the position of the lower pinch roll 71, the threading roll 73 is moved downward and the coiled material 100 can be clamped between the threading roll 73 and the lower pinch roll 71.
(3-6)
The coiled material passing method in this embodiment is a coiled material passing method in which the coiled material 100 played out by the uncoiler 3 is passed through a leveler feeder 2 that corrects any winding curl in the coiled material 100, comprising steps S12 and S13 (examples of a reverse rotation step), step S14 (an example of a clamping step), and step S15 (an example of a movement step). Steps S12 and S13 (examples of reverse rotation step) involve rotating the uncoiler 3 backward until the starting end 100s of the coiled material 100 passes the threading roll 73 disposed near the outer periphery 100e and above the center 100a of the coiled material 100 attached to the uncoiler 3. Step S14 (an example of a clamping step) involves moving the threading roll 73 toward the lower pinch roll 71 disposed below the threading roll 73, so that the threading roll 73 hits the starting end 100s of the coiled material 100 from above, and the starting end 100s of the coiled material 100 is clamped by the threading roll 73 and the lower pinch roll 71. Step S15 (an example of a movement step) involves moving the threading roll 73 and the lower pinch roll 71 to the leveler feeder 2 in a state in which the starting end 100s of the coiled material 100 is clamped.
Consequently, the starting end 100s of the coiled material 100 can be passed through the leveler feeder 2 by moving the catenary component 42 to the leveler feeder 2 in a state in which the starting end 100s of the coiled material 100 is clamped by the clamper 41.
Specifically, since the damper 41 can be moved, the starting end 100s of the coiled material 100 can be clamped near the uncoiler 3, for example. Therefore, the risk that the starting end 100s will catch on any of the device components when the coiled material 100 is played out can be reduced.
Also, after the starting end 100s of the coiled material 100 has been clamped near the coiled material 100, the damper 41 moves in this clamped state, and the starting end 100s of the coiled material 100 is moved to the leveler feeder 2, so the operator does not have to make fine adjustments to the amount of playout of the coiled material as in the past, and the coiled material 100 can be easily fed into the leveler feeder 2.
As described above, the starting end 100s of the coiled material 100 played out from the uncoiler 3 can be easily and stably passed through the leveler feeder 2.
4. Other Embodiments
An embodiment of the present invention was described above, but the present invention is not limited to or by the above embodiment, and various modifications are possible without departing from the gist of the invention.
(A)
In the above embodiment, the threading roll 73 was moved from the standby position Pw to the clamping position Ps by the link 74 and the link driver 75, but this configuration is not the only option. For example, the threading roll 73 may be moved by a cylinder. In other words, any configuration may be used as long as the threading roll 73 can be moved.
(B)
In the above embodiment, the driver 43 for moving the catenary component 42 had the catenary drive motor 111, the catenary drive ball screw 112, and so forth, but this configuration is not the only option. For example, the catenary component 42 may be moved by a rack and pinion or the like. In other words, any configuration may be used as long as the catenary component 42 can be moved.
(C)
In the above embodiment, it was stated that when the catenary component 42 was moved to the uncoiler 3 side, the support 52 of the catenary component 42 hit the outer periphery 100e of the coiled material 100, but the support 52 of the catenary component 42 may be disposed near the outer periphery 100e of the coiled material 100. In this case, the position P2 shown in
(D)
In the above embodiment, the system controller 5, the leveler controller 20, the uncoiler controller 34, and the passing controller 44 were described separately, but the system controller 5, the leveler controller 20, the uncoiler controller 34, and the passing controller 44 may all be combined into a single control device.
(E)
Steps S11 to S16 in the flowchart in
The coiled material passing device and the coiled material passing method of the present invention allow material to be simply and stably passed, and are useful in a coil line system or the like for supplying a coiled material to a pressing machine.
Number | Date | Country | Kind |
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2016-008226 | Jan 2016 | JP | national |
This application is a U.S. National stage application of International Application No. PCT/JP2016/088627, filed on Dec. 26, 2016. This U.S. National stage application claims priority under 35 U.S.C. § 119(a) to Japanese Patent Application No. 2016-008226, filed in Japan on Jan. 19, 2016, the entire contents of which are hereby incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/088627 | 12/26/2016 | WO | 00 |