Patent Application
20230347544
The present disclosure relates to a workpiece cutting device and a workpiece cutting method used to cut a sheet-shaped or thin plate-shaped workpiece.
In the related art, devices as described in Patent Documents 1 to 3, for example, are known as devices for cutting sheet-shaped or thin plate-shaped workpieces as described above.
The device described in Patent Document 1 is a cutting device for a sheet-shaped molded article that includes a blade portion formed into a receiving shape to allow a sheet-shaped molded article to be placed thereon and a movable blade moving up and down with respect to the blade portion with the receiving shape and is adapted to cut the sheet-shaped molded article through cooperation of the blade portion and the movable blade.
The device described in Patent Document 2 is a cutting device for a sheet that cuts a sheet along a perforated line, includes a rotation shaft and a cutting shaft turning about the rotation shaft, and is adapted to cut the sheet via the perforated line by applying a tensile force caused by friction to the sheet in a state where the cutting shaft is in contact with a position of the perforated line on the sheet.
The device described in Patent Document 3 is a pressurization cutting device that cuts a flat plate-shaped workpiece along a marking-off line, includes support means for supporting the workpiece and pressurizing means including a pressurizing surface disposed to face the support means such that the pressurizing means can come into contact with and be separated from the support means, and is adapted to cut the workpiece along the marking-off line by pressurizing the workpiece supported by the support means in such a way to fold and cut the workpiece by the pressurizing surface of the pressurizing means.
Here, a process of manufacturing light-weight and high-strength carbon fiber reinforced plastics (CFRP) or glass fiber reinforced plastics (GFRP) that have widely been used as constituent materials of vehicles, aircrafts, and the like in recent years includes a step of stacking and pressing a plurality of small pieces (small pieces of CFRP or GFRP) formed into a strip shape.
At this time, a method of arranging the plurality of small pieces in parallel with each other, partially coupling adjacent small pieces to each other to obtain a sheet-shaped workpiece, and then supplying the workpiece has been employed in order to facilitate handling until the press step, and an operator's operation of tearing off the small pieces one by one from the workpiece supplied in the sheet shape and stacking them in a mold is performed in the press step.
It is a matter of course that automation of the operation of separating the small pieces from the workpiece supplied in the sheet shape has been demanded, and employing of each of the cutting devices described in Patent Documents 1 to 3 described above, for example, has been considered in order to achieve the automation of the cutting of the partially coupled small pieces.
Patent Document 1: Japanese Patent Laid-Open No. 2008-006547
Patent Document 2: Japanese Patent Laid-Open No. 2012-076381
Patent Document 3: Japanese Patent Laid-Open No. 2004-209675
In a case where the cutting device that cuts a sheet-shaped molded article through cooperation of the blade portion and the movable blade described in Patent Document 1 is employed as a device that automatically performs cutting at seams of partially coupled small pieces (small pieces of CFRP or GFRP), there is a concern that if a positioning error occurs in the small pieces due to dimensional variations or the like, the blade portion and the movable blade deviate from the position of the seams, and portions other than the seams are damaged.
Also, in a case where the device that applies a tensile force to a sheet and cuts the sheet as described in Patent Document 2 is employed to perform the aforementioned cutting at the seams of the small pieces, since tensile strength of fiber in CFRP or GFRP is high, not only the tensile force to be applied to the small pieces but also a force for gripping the small pieces are to be increased by considerable amounts, which may lead to an increase in size of the device.
Furthermore, in a case where the pressurization cutting device that folds and cuts a workpiece along a marking-off line as described in Patent Document 3 is employed to automatically perform cutting at the seams of the partially coupled small pieces, a sufficiently large folding angle is to be set. Additionally, the folding is to be repeated a plurality of times to achieve cutting even if a large folding angle is set, and the number of times the folding is to be repeated significantly differs depending on variations in physical properties caused in the process of manufacturing the small pieces. Therefore, the folding is to be repeated a number of times until each of the strip-shaped small pieces can be reliably cut, it takes long time to perform the cutting operation, and solving these problems is a task to achieve automation.
The present disclosure was made in order to solve the problems in the related art as described above, and an object thereof is to provide a workpiece cutting device capable of reliably cutting a workpiece in a short period of time without damaging portions other than seams and without leading to an increase in size of the device in a case where the device is used to cut a workpiece formed into a sheet shape by partially coupling a plurality of small pieces (small pieces of CFRP or GFRP) to each other along seams of the small pieces, for example.
An aspect of the present disclosure is directed to a workpiece cutting device that cuts a sheet-shaped or thin plate-shaped workpiece into a first-side workpiece and a second-side workpiece including a securing mechanism that secures the first-side workpiece, a gripping mechanism that grips the second-side workpiece, a turning mechanism that turns the second-side workpiece gripped by the gripping mechanism around a boundary with the first-side workpiece as an axis, and separating mechanism that separates the first-side workpiece and the second-side workpiece at a vulnerable portion formed at the boundary through a turning operation of the second-side workpiece performed by the turning mechanism.
The workpiece cutting device according to the present disclosure has a significantly excellent effect that it is possible to reliably cut small pieces in a short period of time without damaging portions other than seams and without leading to an increase in size of the device in a case where the device is used to cut the small pieces of a workpiece formed into a sheet shape by partially coupling the plurality of small pieces (small pieces of CFRP or GFRP) to each other, for example.
Hereinafter, embodiments of the present disclosure will be described on the basis of the drawings.
In this embodiment, a case where a workpiece cutting device according to the present disclosure is used to automatically cut a sheet-shaped workpiece W illustrated in
As illustrated in
The workpiece cutting device 1 according to the present embodiment includes a feeding mechanism 2, a securing mechanism 3, a gripping and turning mechanism 4, a separating piece insertion mechanism (separating mechanism) 5, and a transferring mechanism 8.
The feeding mechanism 2 includes a guide plate 21 on which the sheet-shaped workpiece W is placed, a pressing plate 22 for preventing buckling of the workpiece that is disposed on the guide plate 21 in an overlapping manner at substantially the same gap as the thickness of the workpiece W, a rail 23 disposed from a workpiece transport-in end portion side (the right end portion side in
The guide plate 21 and the pressing plate 22 includes grooves 21a and 22a formed therein along the rail 23 such that the pin 25 penetrates through the grooves 21a and 22a as illustrated in
Note that in the feeding mechanism 2, a suctioning hole may be disposed in the guide plate 21 instead of the pressing plate 22, for example, and the workpiece W may be pressed through vacuum adsorption. Also, a belt conveyor or the like may be employed instead of the feeding mechanism 2.
The securing mechanism 3 includes an air cylinder 31 disposed along a vertical direction above the workpiece cutting end portion of the guide plate 21, an upper pressurizing portion 32 that is provided at a distal end of a cylinder rod 31a of the air cylinder 31 and moves up and down, and a workpiece cutting end portion 21b of the guide plate 21 configuring a clamp along with the upper pressurizing portion 32. In this embodiment, two sets of air cylinders 31 and upper pressurizing portions 32 are disposed in a width direction of the workpiece W (the up-down direction in
The gripping and turning mechanism 4 includes an air cylinder 41 disposed along a vertical direction on the side further downstream of the workpiece feeding (the left side in
Additionally, the gripping and turning mechanism 4 includes a shaft 44 disposed in the width direction of the workpiece W along the workpiece cutting end portion 21b of the guide plate 21 and a rotary air cylinder 45 disposed at an upper end portion in
At this time, a turning center O of the two sets of receiving portions 42 and upper pressurizing portions 43 integrated with the shaft 44 that also serving as a rotation center of the second-side workpiece WL is preferably located at substantially the center of a clearance with a width w between the securing mechanism 3 and the gripping and turning mechanism 4 as illustrated in
The separating piece insertion mechanism 5 includes an air cylinder 51 disposed along the vertical direction above the workpiece cutting end portion of the guide plate 21, a holder 52 provided at a distal end of a cylinder rod 51a of the air cylinder 51, and a separating piece 53 having a thin plate shape with a sharp distal end, supported by the holder 52, and moving up and down along with the holder 52. The separating piece insertion mechanism 5 is adapted to separate the second-side workpiece WL (small piece Wp) from the first-side workpiece WR by inserting, through a rod pushing-out operation of the air cylinder 51, the separating piece 53 into a vulnerable portion formed at the seam Wa through the folding operation (turning operation) of the second-side workpiece WL performed by the gripping and turning mechanism 4. Note that although not illustrated, the air cylinder 51 is provided with an automatic switch such that it is possible to detect whether or not the separating piece 53 has passed through the seam Wa of the workpiece W.
Note that the separating piece 53 is not limited to one with a sharp distal end in the separating piece insertion mechanism 5. Also, a guide or a spring that guides the separating piece 53 to the seam Wa of the workpiece W may be provided between the holder 52 and the separating piece 53.
The transferring mechanism 8 is a robot arm disposed in the vicinity of the gripping and turning mechanism 4 as illustrated in
Next, how to cut the sheet-shaped workpiece W and take the cut second-side workpiece WL (small piece Wp) by using the workpiece cutting device 1 according to the embodiment will be described.
First, the pin 25 moves by a predetermined stroke in response to an output from a drive source, which is not illustrated, of the feeding mechanism 2, the workpiece W set between the guide plate 21 and the pressing plate 22 for preventing buckling of the workpiece is pressurized on the side of the workpiece cutting end portion of the guide plate 21 by a predetermined amount, and the first-side workpiece WR and the second-side workpiece WL are caused to be located at the locations of the securing mechanism 3 and the gripping and turning mechanism 4, as illustrated in
In this state, the air cylinder 31 of the securing mechanism 3 operates to clamp and secure the first-side workpiece WR, and the air cylinder 41 of the gripping and turning mechanism 4 then operates to clamp and secure the second-side workpiece WL as illustrated in
Once the securing mechanism 3 and the gripping and turning mechanism 4 secure the workpiece W, the rotary air cylinder 45 of the gripping and turning mechanism 4 operates to successively turn the receiving portions 42 and the upper pressurizing portions 43 in forward and backward directions as illustrated in
Then, the receiving portions 42 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 are turned to original positions before the operation, and the air cylinder 51 of the separating piece insertion mechanism 5 operates on the vulnerable portion formed at the seam Wa through the folding performed by the gripping and turning mechanism 4 to pierce the separated piece 53 (separating step) as illustrated in
In a case where cutting is determined to have been completed, the second-side workpiece WL pinched between and secured by the receiving portions 42 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 is folded downward by 90°, and the robot arm that is the transferring mechanism 8 then operates to cause the vacuum adsorption portions 8b of the hand 8a to adsorb the second-side workpiece WL (strip-shaped small piece Wp) separated from the first-side workpiece WR as illustrated in
After the adsorption of the second-side workpiece WL achieved by the vacuum adsorption portions 8b of the hand 8a is completed, the pinching and the securing of the second-side workpiece WL achieved by the receiving portions 42 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 are released, and the robot arm that is the transferring mechanism 8 takes the second-side workpiece WL out between the receiving portions 42 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 as illustrated in
Thereafter, the receiving portions 42 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 are returned to the original positions before the operation, and the feeding mechanism 2 restarts the operation to cut the next second-side workpiece WL (the second small piece Wp from the left end in
At this time, the robot arm that is the transferring mechanism 8 transports the second-side workpiece WL (strip-shaped small piece Wp) adsorbed by the vacuum adsorption portions 8b of the hand 8a to the vicinity of the image sensor 9, and the position of the hole Wh pierced in the small piece Wp is detected by the image sensor 9. Then, the teaching point of the robot arm is corrected on the basis of the detection result, and the adsorption achieved by the vacuum adsorption portions 8b is released by causing the positioning pin 12 to pass through the hole Wh inside the guide block 11 of the workpiece stacking jig 10.
As described above, the workpiece cutting device 1 according to the embodiment is adapted such that the gripping and turning mechanism 4 is caused to perform the folding operation on the second-side workpiece WL of the workpiece W at the seam (boundary) Wa between the first-side workpiece WR and the second-side workpiece WL and the separating piece 53 of the separating piece insertion mechanism 5 is then pierced to the vulnerable portion formed at the seam Wa through the folding operation.
In other words, even if a small left portion (uncut fiber) remains at the vulnerable portion after the folding operation of the second-side workpiece WL of the workpiece W, the part corresponding to the left portion is removed by the insertion of the separating piece 53, and it is thus possible to reliably cut the second-side workpiece WL of the workpiece W by inserting the separating piece 53 of the separating piece insertion mechanism 5 into the vulnerable portion after the folding operation regardless of whether there is such a left portion.
Therefore, the workpiece cutting device 1 according to the embodiment can minimize the number of times the folding operation of the second-side workpiece WL of the workpiece W is to be performed and shorten the time to perform the cutting.
Also, since the workpiece cutting device 1 according to the present embodiment employs the air cylinder 51 as an operation source of the separating piece insertion mechanism 5, the separating piece 53 is inserted between the upper pressurizing portions 32 of the securing mechanism 3 and the upper pressurizing portions 43 of the gripping and turning mechanism 4 by following the seam Wa due to backlash that the air cylinder 51 of the separating piece insertion mechanism 5 has and deflection of the separating piece 53 itself that is a thin plate as illustrated in
Additionally, since the workpiece cutting device 1 according to the embodiment is adapted such that the gripping and turning mechanism 4 is caused to perform the folding operation on the second-side workpiece WL of the workpiece W and the separating piece 53 of the separating piece insertion mechanism 5 is inserted into the vulnerable portion formed at the seam Wa through the folding operation, there is no need to pull the workpiece W with a stronger force or to grip the workpiece W with a larger force as compared with the cutting devices in the related art. Therefore, it is possible to use small-sized air cylinders as operation sources for gripping and cutting and thereby to realize a decrease in entire size of the device as well.
Furthermore, since the workpiece cutting device 1 according to the embodiment is formed to include the feeding mechanism 2 that moves the first-side workpiece WR in a state where securing by the securing mechanism 3 has been released toward the gripping and turning mechanism 4 by the predetermined amount, it is possible to continuously and smoothly cut the plurality of small pieces Wp in the cutting of the workpiece W formed into a sheet shape by partially coupling the plurality of small pieces (small pieces of CFRP or GFRP) Wp to each other at the seam Wa.
As illustrated in
The drive mechanism 6 serving as a separating mechanism of the workpiece cutting device 1A according to the embodiment includes lifting and lowering cylinders 61 and 61 secured to the gripping and turning mechanism 4 of the workpiece cutting device 1 according to the previous embodiment on the side of the rotary air cylinder 45 and the side of the bearing 46, respectively, via a holder 62 and adaptors 63 and 63 disposed at distal ends of rods 61a and 61a of the lifting and lowering cylinders 61 and 61.
In this embodiment, a shaft 44 is bridged between the adaptors 63 and 63 of the drive mechanism 6, and it is possible to achieve cutting by causing the entire clamp part of the gripping and turning mechanism 4 to move upward through operations of the lifting and lowering cylinders 61 and 61 after the folding operation of the second-side workpiece WL performed by the gripping and turning mechanism 4 and tearing off the second-side workpiece WL at the seam Wa.
In this case, there is a concern that positional deviation may occur in the second-side workpiece WL or a first-side workpiece WR if the gripping force of the clamp portion of the gripping and turning mechanism 4 is small, and attention is thus to be paid to set the gripping force.
In this embodiment, a structure for determining cutting of the second-side workpiece WL through an operation stroke of the lifting and lowering cylinder 61 may be added.
The configuration of the workpiece cutting device according to the present disclosure is not limited to the aforementioned embodiments and can be modified in various manners without departing from the scope of the present disclosure.
Also, although the case where the workpiece cutting device according to the present disclosure is employed to cut a sheet-shaped workpiece has been described in the aforementioned embodiments, it is also possible to employ the workpiece cutting device according to the present disclosure to cut a thin plate-shaped workpiece.
A first aspect of the present disclosure is a workpiece cutting device that cuts a sheet-shaped or thin plate-shaped workpiece into a first-side workpiece and a second-side workpiece, the device is formed to include: a securing mechanism that secures the first-side workpiece; a gripping mechanism that grips the second-side workpiece; a turning mechanism that turns the second-side workpiece gripped by the gripping mechanism about a boundary with the first-side workpiece as an axis; and a separating mechanism that separates the first-side workpiece and the second-side workpiece at a vulnerable portion formed at the boundary through a turning operation of the second-side workpiece performed by the turning mechanism.
Also, a second aspect of the present disclosure is formed to include a feeding mechanism that moves the first-side workpiece in a state where securing by the securing mechanism has been released toward the turning mechanism by a predetermined amount.
Furthermore, a third aspect of the present disclosure is configured such that the separating mechanism is a separating piece insertion mechanism that inserts a thin plate-shaped separating piece into the vulnerable portion to separate the first-side workpiece and the second-side workpiece.
Moreover, a fourth aspect of the present disclosure is configured such that the separating mechanism is a drive mechanism that moves the second-side workpiece in a direction separating from the first-side workpiece to separate the second-side workpiece from the first-side workpiece at the vulnerable portion.
Furthermore, a fifth aspect of the present disclosure is formed to include a transferring mechanism that transfers the second-side workpiece to a stacking jig for stacking the second-side workpiece separated from the workpiece and stacks the second-side workpiece.
A sixth aspect of the present disclosure is formed to include, when a sheet-shaped or thin plate-shaped workpiece is cut into a first-side workpiece and a second-side workpiece by the workpiece cutting device according to any one of the above first to fourth aspects: a securing step of securing the first-side workpiece by the securing mechanism; a gripping step of gripping the second-side workpiece by the gripping mechanism; a folding step of turning the second-side workpiece gripped by the gripping mechanism about a boundary with the first-side workpiece as an axis by the turning mechanism; and a separating step of separating the first-side workpiece and the second-side workpiece by the separating mechanism at a vulnerable portion formed at the boundary in the folding step.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-032505 | Mar 2021 | JP | national |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2022/008561 | Mar 2022 | US |
| Child | 18348474 | US |
