The present invention relates to a knife folding machine for folding a sheet with a knife blade.
A conventional knife folding machine generally comprises a frame having a support surface to support a lower surface of a sheet, and a feed means attached to the frame to sequentially feed the sheet to a fold position on the support surface. The feed means comprises a drive roller and an idle roller which are parallel spaced from each other, and a conveyer belt extending between the drive roller and the idle roller. A part of the support surface is formed by a feed surface of the conveyer belt. A stopper is attached to the frame to position the sheet at the fold position by a front end of the sheet abutting the stopper.
The knife folding machine comprises a knife blade, a pair of folding rollers opposed to the knife blade at the folding position with the support surface therebetween; and a slider crank mechanism. The knife blade and the folding rollers extend in parallel to a feed path of the sheet. The slider crank mechanism reciprocates the knife blade between first and second positions via an opening through which the knife blade passes. The opening is formed on the support surface. The first position is opposite to the folding rollers with the support surface therebetween and spaced from the support surface. The second position is adjacent a gap between the folding rollers.
The knife blade has one end fixed to a rod which is connected with a crank of the slider crank mechanism. The crank makes one revolution every time the sheet is set at the fold position. During one revolution of the crank, the knife blade reciprocates between the first position (upper dead point) and the second position (lower dead point) so as to effect a folding operation. While the knife blade moves from the first position to the second position, the sheet on the support surface is folded in two by the knife blade, then an edge of the folded portion thereof is pushed out of the opening and inserted into the gap between the folding rollers so that the sheet can be folded by the folding rollers.
The conventional knife folding machine feeds the sheet to the fold position at a constant speed and sets the sheet at the fold position by a front end of the sheet abutting the stopper. It is preferable to feed the sheet at high-speed so as to increase a processing efficiency. However if the feed speed of the sheet becomes high, the sheet cannot be accurately set at the fold position because of the sheet rebounding from the stopper, and the sheet may be damaged or wrinkle by the sheet colliding with the stopper.
In order to solve the problems, in the conventional knife folding machine, a brush is attached opposite to the feed surface of the conveyer belt to contact the upper surface of the feed sheet to decelerate the sheet (see, for example, Patent Document 1), or a deceleration belt is arranged opposite to the conveyer belt to contact the upper surface of the sheet conveyed by the conveyer belt to decelerate the sheet (see, for example, Patent Document 2). The deceleration means disposed on the feed path of the sheet contacts the sheet to keep the speed of the sheet at a constant high-speed during feeding the sheet but reduce the speed of the sheet before the sheet abutting the stopper.
However these deceleration means decelerate the sheet conveyed by the conveyer belt by applying dynamic friction to the sheet and slipping the sheet on the feed surface of the conveyer belt. The deceleration means cannot always accurately stop the sheet at the fold position since it is difficult to control the position of the sheet on the way of decelerating. As a result, a position of the fold line on the sheet may be misaligned, which leads to the reduction of accuracy of the folding and a poor finish in the subsequent processes such as a sewing process and so on.
Patent Document 1: JP 2004-331402 A
Patent Document 2: JP 11-180635 A
It is an object of the present invention to provide a knife folding machine which can achieve an accurate folding operation without damage and wrinkle of the sheet while keeping the processing speed high.
In order to achieve the objects, the present invention provides a knife folding machine, comprising:
According to a preferred embodiment of the present invention,
According to further preferred embodiment of the present invention,
According to further preferred embodiment of the present invention,
According to further preferred embodiment of the present invention,
According to further preferred embodiment of the present invention,
According to further preferred embodiment of the present invention,
According to the present invention, the conveyer belt is driven by the servomotor whose rotation is controlled so that the sheet is decelerated at a constant acceleration before its abutment against the stopper without its rebounding from the stopper. And thereby it is possible to decelerate the sheet without the deceleration means contacting the upper surface of the sheet conveyed by the conveyer belt while keeping the processing speed high. Consequently the position of the sheet can be easily controlled while the sheet decelerated, and the sheet can accurately stop at a preset fold position at all times. And a high accuracy of the sheet folding is achieved.
According to the present invention, it is possible to prevent the sheet from rebounding against the stopper and accurately stop the sheet at the preset fold position by correcting a default start position of the deceleration of the sheet and shifting the start position of the deceleration in a direction toward and away from the stopper in the case that the sheet conveyed by the conveyer belt slips on the feed surface of the conveyer belt.
A preferred embodiment of the present invention will be explained below with reference to the accompanying drawings.
A pair of folding rollers 6a, 6b are opposed to a knife blade 5 with the support surface 4 therebetween at the fold position on the support surface 4. In this embodiment, the knife blade 5 is disposed above the center plate 2a (the support surface 4) and the folding rollers 6a, 6b are disposed below the center plate 2a. In another embodiment, the knife blade 5 may be disposed below the center plate 2a and the folding rollers 6a, 6b may be disposed above the center plate 2a.
The folding rollers 6a, 6b are attached to the frame 1. The knife blade 5 and the folding rollers 6a, 6b are disposed in parallel to each other and the center plate 2a. An opening 3 through which the knife blade 5 passes is formed on the center plate 2a and extends longitudinally thereof. One end of the knife blade 5 is opposed to a gap between the folding rollers 6a, 6b.
The knife folding machine comprises a knife drive unit 7. The knife drive unit 7 reciprocates the knife blade 5 between first and second positions through the opening 3 in a direction perpendicular to the support surface 4. The first position is arranged above the support surface 4 with spacing. The second position is disposed adjacent the gap between the folding rollers 6a, 6b. The knife drive unit 7 is supported by a support arm 8 attached to the frame 1.
The knife folding machine further comprises a feed means attached to the frame 1 to sequentially feed the sheet S to the fold position in a direction parallel to the knife blade 5 on the support surface 4.
The feed means comprises a drive roller 9 and an idle roller 10 which are attached to the frame 1 and respectively disposed on opposite ends of the frame 1 below the support surface 4 (plates 2, 2a). Each of rotation shafts of the drive roller 9 and the idle roller 10 is disposed in parallel to each other and extends in a direction perpendicular to the knife blade 5. The drive roller 9 is driven by a first servomotor 11 fixed to the frame 1. The first servomotor 11 is controlled by the control unit 12.
A plurality of conveyer belts 13 extends between the drive roller 9 and the idle roller 10. The conveyer belts 13 circulate and a feed surface thereof forms a feed path of the sheet S. Two conveyer belts 13 are arranged for each of the plates 2, 2a and spaced from each other. Each of upper portions of the conveyer belts 13 is disposed above the plates 2, 2a so that the feed surface of the conveyer belts 13 forms a part of the support surface 4.
The knife folding machine further comprises a stopper 14 attached to the frame 1 to position the sheet S at the fold position on the support surface 4. The stopper 14 is disposed at a downstream of the knife blade 5 and extends in a direction perpendicular to the feed path of the sheet S on the support surface 4. The stopper 14 positions the sheet S at the fold position by its abutment of the front end of the sheet S against the stopper 14.
A horizontal support bar 15 is attached to the frame 1 at its opposed ends and extends in a direction perpendicular to the feed path of the sheet S at an upstream of the opening 3 of the plate 2a. A sensor 16 is attached to the center of the support bar 15 to detect a passage of the sheet S.
The stopper 14 is movable along the feed path of the sheet S in a direction toward and away from the sensor 16.
The control unit 12 decelerates the first servomotor 11 to a predetermined rotary speed during the period from the passage of the sheet S through the sensor 16 to its abutment against the stopper 14. The rotary speed is set in such a way that the sheet S cannot rebound from the stopper 14 when the sheet S abuts the stopper 14. And then the control unit 12 accelerates the first servomotor 11 to a rotary speed before the deceleration during the period from the start of the folding operation to the start of the feed of the next sheet S. Thus the feed speed of the sheet S reduces during the period from the passage of the sheet S through the sensor 16 to its abutment against the stopper 14 so that the sheet S accurately stops at the fold position without rebounding against the stopper 14, and after finishing the folding operation of the sheet S the next sheet S is conveyed to the fold position at a feed speed before reducing.
It is possible to decelerate and accelerate the first servomotor 11 at a constant acceleration, or it is possible to decelerate and accelerate the first servomotor 11 with changing the acceleration. In the embodiment, the first servomotor 11 decelerates and accelerates at a predetermined constant acceleration α.
The first servomotor 11 may start to decelerate at any point in a path from point where the sheet S passes through the sensor 16 to point where the sheet S abuts the stopper 14. The first servomotor 11 may start to accelerate at any time in time from when the folding operation of the sheet S starts till when the next sheet S starts to be conveyed.
In this embodiment the initial setting of the first servomotor 11 is conducted in such a way that the first servomotor 11 starts to decelerate when the front end of the sheet S arrives at the start position of the deceleration after the passage of the sheet S through the sensor 16, the start position of the deceleration being preset between the sensor 16 and the stopper 14.
The control unit 12 comprises a first input portion 17 for receiving input of a coordinate correction amount to correct the start position of the deceleration in a direction of the feed path, and a first memory 18 for storing the coordinate correction amount inputted through the first input portion 17.
In this embodiment, as shown in
The reason why the coordinate correction amount can be inputted to correct the start position of the deceleration will be explained below. The start position of the deceleration is preset in the assumption that the sheet S conveyed by the conveyer belt 13 does not slip on the feed surface of the conveyer belt 13. However there are generally two types of the sheet S, that is, one of which slips and the other of which does not slip while the sheet S conveyed despite the same feed speed, because of the weight of the sheet and the friction coefficient between the sheet S and the conveyer belt 13 and so on. In the case that the sheet S is apt to slip while the sheet S conveyed, it is possible to prevent the sheet S from rebounding against the stopper 14 by shifting the default start position of the deceleration in a direction toward and away from the stopper 14 along the feed path.
Therefore the correction of the start position is conducted if necessary, and generally the coordinate correction amount is preset to zero.
As shown in
In this embodiment the control unit 12 detects an arrival of the front end P of the sheet S at the start position of the deceleration based on the pulse from the encoder installed in the first servomotor 11, but in another embodiment the control unit 12 comprises a timer for measuring a time elapsed from the passage of the front end P of the sheet S through the sensor 16, and the control unit 12 starts to decelerate the first servomotor 11 when detecting an arrival of the front end P of the sheet S at the start position of the deceleration based on a measurement value of the timer.
According to the present invention, the conveyer belt 13 is driven by the first servomotor 11 whose rotation is controlled so that the sheet S is decelerated at a constant acceleration before its abutment against the stopper 14 without its rebounding against the stopper 14. And thereby it is possible to decelerate the sheet S without the deceleration means contacting the upper surface of the sheet S conveyed by the conveyer belt 13 while keeping the processing speed high. Consequently the position of the sheet S can be easily controlled while the sheet S decelerated, and the sheet S can accurately stop at a preset fold position at all times. And a high accuracy of the sheet folding is achieved.
According to the present invention, it is possible to prevent the sheet from rebounding against the stopper and accurately stop the sheet at the preset fold position by correcting a default start position of the deceleration of the sheet to shift the preset start position of the deceleration in a direction toward and away from the stopper in the case that the sheet conveyed by the conveyer belt slips on the feed surface of the conveyer belt.
As shown in
A feed screw 22 is attached to rotate around an axis thereof and extends in parallel to the rod 20 between the upper and lower support walls 19a, 19b of the holder 19. The block 21 has a through hole which provided with thread grooves corresponding to the feed screw 22. The feed screw 22 is engaged with the through hole. While the feed screw 22 rotates, the rod 20 reciprocates in a direction perpendicular to the support surface 4 through the block 11.
The knife drive unit 7 further comprises a first pulley 23 attached to an upper end of the feed screw 22, a second servomotor 24 attached to the holder 19 and having a drive shaft 24a in parallel to the feed screw 22, a second pulley 25 attached to the drive shaft 24a of the second servomotor 24, and a timing belt 26 extended between the first and second pulleys 23, 25.
In this embodiment, the first pulley 23 is attached to the upper end of the feed screw 22 and driven by the second servomotor 24, but the first pulley 23 may be attached to the lower end of the feed screw 22 and driven by the second servomotor 24.
The second servomotor 24 is controlled by a control unit 12.
The control unit 12 comprises a second input portion 27 for receiving input of both data of a distance d1 (see
In this embodiment, as shown in
At the right side of the numerical display columns 34a, 34b, there are a “+” button for increasing the corrected value, a “−” button for decreasing the corrected value, and a “D” button for setting the corrected value to zero. Each of the corrected values can easily be inputted by touching these buttons.
The control unit 12 calculates an amount of the rotation of the second servomotor 24 corresponding to the distance from the first position to the second position based on the data of the distances d1, d2 stored in the second memory 28 and controls the second servomotor 24.
The second servomotor 24 rotates the feed screw 22 to reciprocate the rod 20 or the knife blade 5 between the first position (see
The reciprocal movement of the knife blade 5 between the first and second positions effects a folding operation. While the knife blade 5 moves from the first position to the second position, the sheet S on the support surface 4 is folded in two by the knife blade 5, and an edge of the folded portion thereof is pushed out of the opening 3 and inserted into the gap between the folding rollers 6a, 6b so that the sheet S can be folded by the folding rollers 6a, 6b.
According to the present invention, the second servomotor 24 rotates the feed screw 22 to reciprocate the rod 20 or the knife blade 5 between the first and second positions. Thus the stroke of reciprocal movement of the knife blade 5 can easily be adjusted so that the first and second positions of the knife blade 5 can separately be adjusted by controlling the amount of rotation of the second servomotor 24.
Further in the present invention, the rod 20 is not subjected to the offset load in a direction away from the axis thereof during the folding operation because the rod 20 and the feed screw 22 are disposed in parallel to each other, so that the durability of the knife folding machine can be improved. Since the rod 20 or the knife blade 5 is reciprocated by the feed screw 22 which is rotated by the second servomotor 24, the overload applied to the knife blade 5 is detected by the second servomotor 24. As a result, when each sheet S is sequentially fed to the fold position every time the folding operation is finished, the paper jam between the folding rollers 6a, 6b can be avoided by stopping the knife blade 5 in the course of its folding operation even if a plurality of sheets S are accidentally fed at one time.
In this embodiment the knife drive unit comprises the rod arranged to reciprocate in a direction perpendicular to the support surface of the sheet, the feed screw disposed in parallel to the rod, the block operatively connected with the rod and the feed screw, and the servomotor for rotating the feed screw. However the structure of the knife drive unit is not limited to this embodiment, and for example the knife drive mechanism can be composed of a known slider clank mechanism.
The control unit 12 comprises a third input portion 29 for receiving input of a time correction value to correct a default time from the passage of the front end P of the sheet S through the sensor 16 to the start of the folding operation of the knife blade 5, and a third memory 30 for storing the time correction value inputted through the third input portion 29.
The default time is determined as follows. First, as shown in
The default time (t), or a time elapsed from the passage of the front end P of the sheet S through the sensor 16 to the arrival of the sheet S at the fold position, can be calculated by the equation as follows:
t=(L−a)/v+a/α
Wherein, a character (v) designates the feed speed of the sheet S, and the character (α) designates the deceleration while decelerating the sheet S.
In this embodiment, as shown in
The control unit 12 starts the folding operation when a time summed up in both the default time and the time correction value is elapsed after the front end P of the sheet S passes through the sensor 16.
Thus it is possible to adjust a start time of the folding operation and accurately achieve the folding operation by inputting the time correction value for correcting the default time in the case that the sheet S rebounds against the stopper 14 after its abutment without stopping at the fold position at default time because of the weight of the sheet S and the friction coefficient between the sheet S and the conveyer belt 13 and so on. Therefore the correction of the time is conducted if necessary, and generally the time correction value is preset to zero.
Thus the knife blade 5 moves to the first position based on the set value of the distance (d1) so as to be kept in a standby condition before the start of the operation of the knife folding machine.
Then the first sheet S is conveyed to the folding position by the conveyer belt 13 after the start of the operation of the knife folding machine. When the sensor 16 detects the passage of the front end P of the sheet S, the control unit 12 measures a time elapsed from the passage of the front end P of the sheet S through the sensor 16. And then the sheet S abuts the stopper 14 to stop at the folding position (see also
During the movement, the sheet S on the support surface 4 is folded in two by the knife blade 5, and the edge of the folded portion of the sheet S is pushed out of the opening 3 and inserted into the gap between the folding rollers 6a, 6b so that the sheet S can be folded by the folding rollers 6a, 6b. Then the knife blade 5 returns from the second position to the first position. During the reciprocal movement of the knife blade 5 between the first and second positions, the folding operation is effected. The next sheet S is conveyed to the fold position by the conveyer belts 20 every time the folding operation is completed.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2010/050501 | 1/18/2010 | WO | 00 | 7/10/2012 |