The present disclosure relates to a platen conveyance device.
A printer is provided with a platen and a printing portion. The platen includes a support surface able to support a cloth, and moves toward the printing portion. The printing portion performs printing on the cloth supported by the platen.
Before printing on a cloth by a printer, a pretreatment is sometimes performed on the cloth using a pretreatment device. In this case, it is necessary for an operator to set the cloth on which the pretreatment has been performed by the pretreatment device on a support surface of a platen of the printer, and this requires time and effort. Here, a mechanism is conceivable with which the platen supporting the cloth is conveyed to the pretreatment device using a first conveyance path, then the platen conveyed using the first conveyance path is transferred to a second conveyance path and is conveyed to the printer, for example. In the above-described mechanism, if the platen is transferred from the first conveyance path to the second conveyance path in a displaced state, it is possible that the platen may not be conveyed to the printer.
Embodiments of the broad principles derived herein provide a platen conveyance device capable of reducing a possibility of a platen not being conveyed to a printer.
A platen conveyance device related to one aspect of the present disclosure includes a first conveyance path, a platen supporter, a second conveyance path, and a positioner. The first conveyance path configured to convey a platen to a pretreatment device. The platen supporter configured to support the platen conveyed by the first conveyance path. The second conveyance path provided with the platen supporter, and configured to convey the platen supporter to a printer. The positioner configured to position the platen supported by the platen supporter at a prescribed printing position in a horizontal direction.
When the platen supporter is conveyed to the printer by the second conveyance path, the positioner positions the platen at the prescribed printing position in the horizontal direction. Thus, the platen conveyance device can reduce the possibility of the platen not being conveyed to the printer.
Embodiments will be described below in detail with reference to the accompanying drawings in which:
In a description of an embodiment of the present disclosure, left and right, front and rear, and up and down directions shown by arrows in the drawings are used. A print system 1 shown in
The configuration of the print system 1 will be described with reference to
To the rear of the pretreatment device 2, three of the printers 3 to 5 are aligned in the front-rear direction on the left, and three of the printers 6 to 8 are aligned in the front-rear direction on the right. The printers 3 to 8 are inkjet printers that perform printing by ejecting ink from nozzles of a print head onto the cloth P after the pretreatment that is supported by the platen 50. The post-treatment device 9 is disposed to the rear of the printers 3 to 8, and, by heating the cloth P after the printing that is supported by the platen 50 at a high temperature and drying the ink, improves the fixing of the ink to the cloth P. The platen conveyance mechanism 10 conveys the platen 50 disposed at a preparation position 100 (to be described later) in an order of the pretreatment device 2, one of the printers 3 to 8, and the post-treatment device 9, and once more returns the platen 50 to the preparation position 100.
The code reader 95 provided at the preparation position 100 (to be described later) reads identification information for identifying the cloth P, from an identification information portion (not shown in the drawings) provided on the cloth P and inputs the read identification information to the print system 1. The identification information is information to identify the cloth P, and is, for example, information of a code, such as a one-dimensional code, such as a bar code, a two-dimensional code, such as a QR code (registered trademark), or a three-dimensional code. The identification information may include information about a type, a color, a size, of the cloth P, a print color, a print size, and the like.
The configuration of the platen conveyance mechanism 10 will be explained with reference to
The dispatch line 201 is provided extending linearly in the left-right direction, at the forefront of the print system 1, and conveys the platen 50 toward the left processing line 202 and the right processing line 203 to be described later. The dispatch line 201 is provided with conveyance mechanisms 11 to 13 in that order from the left. The preparation position 100 is provided at the conveyance mechanism 11. The preparation position 100 is a position for preparation at which the cloth P is attached to the platen 50. The conveyance mechanisms 11 to 13 convey the platen 50 to the right. A front end portion of a conveyance mechanism 14 to be described later is disposed between the conveyance mechanisms 11 and 12. A front end portion of a conveyance mechanism 24 to be described later is disposed between the conveyance mechanisms 12 and 13.
The left processing line 202 and the right processing line 203 are provided side by side in the left-right direction, between the dispatch line 201 and the first return line 204 to be described later. The left processing line 202 conveys the platen 50 received from the dispatch line 201 to the pretreatment device 2, to one of the printers 3 to 5, and to the post-treatment device 9, in that order, and transfers the platen 50 to the first return line 204. The right processing line 203 conveys the platen 50 received from the dispatch line 201 to the pretreatment device 2, to one of the printers 6 to 8, and to the post-treatment device 9, in that order, and transfers the platen 50 to the first return line 204.
The left processing line 202 is provided with the conveyance mechanism 14 and conveyance mechanisms 15 to 23 and print conveyance mechanisms 41 to 43. The conveyance mechanism 14 extends to the rear from between the conveyance mechanisms 11 and 12 of the dispatch line 201, passes through the interior of the pretreatment device 2, and further extends to the rear. The conveyance mechanism 14 receives the platen 50 from the conveyance mechanism 11, passes through the pretreatment device 2, and conveys the platen 50 to the rear. The conveyance mechanism 15 extends to the left from the conveyance mechanism 14 toward the printer 3. The conveyance mechanism 15 receives the platen 50 from the conveyance mechanism 14, and conveys the platen 50 toward the printer 3. The conveyance mechanism 16 extends to the left from the printer 3. The conveyance mechanism 16 receives the platen 50 from the printer 3, and conveys the platen 50 to the left.
The conveyance mechanism 17 is disposed to the rear of the conveyance mechanism 15, and extends to the left from the conveyance mechanism 14 toward the printer 4. The conveyance mechanism 17 receives the platen 50 from the conveyance mechanism 14, and conveys the platen 50 toward the printer 4. The conveyance mechanism 18 extends to the left from the printer 4. The conveyance mechanism 18 receives the platen 50 from the printer 4, and conveys the platen 50 to the left. The conveyance mechanism 19 is disposed to the rear of the conveyance mechanism 17, and extends to the left from the conveyance mechanism 14 toward the printer 5. The conveyance mechanism 19 receives the platen 50 from the conveyance mechanism 14, and conveys the platen 50 toward the printer 5. The conveyance mechanism 20 extends to the left from the printer 5. The conveyance mechanism 20 receives the platen 50 from the printer 5, and conveys the platen 50 to the left.
The conveyance mechanism 21 extends in the front-rear direction, to the left of the printers 3 to 5, and is coupled to each of the left end portions of the conveyance mechanisms 16, 18, and 20. The conveyance mechanism 21 receives the platen 50 from each of the conveyance mechanisms 16, 18, and 20, and conveys the platen 50 to the rear. The conveyance mechanism 22 is disposed to the rear of the printer 5, and extends to the right from the rear end portion of the conveyance mechanism 21. The conveyance mechanism 22 receives the platen 50 from the conveyance mechanism 21, and conveys the platen 50 to the right. The conveyance mechanism 23 extends to the rear from the right end portion of the conveyance mechanism 22, passes through the interior of the post-treatment device 9, and further extends to the rear. The conveyance mechanism 23 receives the platen 50 from the conveyance mechanism 22, passes through the post-treatment device 9, and conveys the platen 50 to the rear. The rear end portion of the conveyance mechanism 23 is disposed between conveyance mechanisms 27 and 28 of the first return line 204 to be described later.
The print conveyance mechanism 41 is provided at the printer 3, and can convey the platen 50 in the left-right direction. The print conveyance mechanism 41 is provided with a platen supporter 60, a ball screw 3A, a pair of rails 3B, and a conveyance motor 137 (refer to
The conveyance motor 137 causes the ball screw 3A to rotate. In this way, the platen supporter 60 can move together with the nut along the ball screw 3A, as a result of the driving of the conveyance motor 137. Note that the configuration for conveying the platen supporter 60 may be a configuration other than described above, and the configuration may be provided with a pair of pulleys, an endless belt, and a motor, for example. The endless belt is stretched across the pair of pulleys. The platen supporter 60 is fixed to a part of the endless belt. As a result of the motor causing one of the pulleys to rotate in a normal and reverse direction, the endless belt moves between the pair of pulleys. In this way, the platen supporter 60 can move together with the endless belt.
The printer 4 is provided with the print conveyance mechanism 42, and the printer 5 is provided with the print conveyance mechanism 43. The print conveyance mechanisms 42 and 43 have the same configuration as the print conveyance mechanism 41, and a description thereof is thus omitted here.
The right processing line 203 has a structure that is left-right symmetrical with the left processing line 202, and a description thereof is thus omitted here. The conveyance mechanism 24 is provided at the front end of the right processing line 203, and a conveyance mechanism 25 is provided at the rear end of the right processing line 203. The conveyance mechanism 24 has the same structure as the conveyance mechanism 14 of the left processing line 202. The front end portion of the conveyance mechanism 24 is disposed between the conveyance mechanisms 12 and 13 of the dispatch line 201. The conveyance mechanism 25 has the same structure as the conveyance mechanism 23 of the left processing line 202. The rear end portion of the conveyance mechanism 25 is disposed between conveyance mechanisms 26 and 27 of the first return line 204 to be described later.
The first return line 204 is disposed at the rearmost portion of the print system 1, extends linearly in the left-right direction, and conveys the platen 50 received from the left processing line 202 and the right processing line 203 to the left. The first return line 204 is provided with the conveyance mechanisms 26 to 28 in that order from the right. The conveyance mechanisms 26 to 28 convey the platen 50 to the left. The rear end portion of the conveyance mechanism 23 of the left processing line 202 is disposed between the conveyance mechanisms 27 and 28. The rear end portion of the conveyance mechanism 25 of the right processing line 203 is disposed between the conveyance mechanisms 26 and 27.
The second return line 205 extends linearly in the front-rear direction, conveys the platen 50 received from the first return line 204 to the front, and transfers the platen 50 to the conveyance mechanism 11. The second return line 205 is provided with a conveyance mechanism 29. The conveyance mechanism 29 conveys the platen 50 to the front. The platen 50 transferred to the conveyance mechanism 11 is returned to the preparation position 100 by the conveyance mechanism 11.
The conveyance mechanism 13 of the dispatch line 201 may convey the platen 50 toward another processing line (not shown in the drawings). The other processing line may have the same configuration as the left processing line 202 and the right processing line 203. The conveyance mechanism 26 of the first return line 204 may convey the platen 50 received from the other processing line (not shown in the drawings) to the left.
A belt configuration of the platen conveyance mechanism 10 will be explained with reference to
The conveyance mechanism 14 is provided with a pair of longitudinal belts 14A and pairs of lateral raising/lowering belts 14B to 14E. The pair of longitudinal belts 14A are provided at both end portions of the conveyance mechanism 14 in a direction orthogonal to the conveyance direction, in a plan view. The pair of longitudinal belts 14A convey the platen 50 to the rear. The pairs of lateral raising/lowering belts 14B to 14E are disposed between the pair of longitudinal belts 14A. The pair of lateral raising/lowering belts 14B are provided at the front end portion of the conveyance mechanism 14 such that they can be raised and lowered. The pair of lateral raising/lowering belts 14B convey the platen 50 to the right. The pair of lateral raising/lowering belts 14C can be raised and lowered on the right of the conveyance mechanism 15. The pair of lateral raising/lowering belts 14D can be raised and lowered on the right of the conveyance mechanism 17. The pair of lateral raising/lowering belts 14E can be raised and lowered on the right of the conveyance mechanism 19. The pairs of lateral raising/lowering belts 14C to 14E convey the platen 50 to the left.
The conveyance mechanisms 15 to 20 are respectively provided with pairs of lateral conveyance belts 15A to 20A. The pairs of lateral conveyance belts 15A to 20A are respectively provided at both end portions of the conveyance mechanisms 15 to 20 in a direction orthogonal to the conveyance direction, in a plan view, and are provided such that they can be raised and lowered.
The conveyance mechanism 21 is provided with a pair of longitudinal belts 21A and pairs of lateral raising/lowering belts 21B to 21E. The pair of longitudinal belts 21A are provided at both end portions of the conveyance mechanism 21 in a direction orthogonal to the conveyance direction, in a plan view. The pair of longitudinal belts 21A convey the platen 50 to the rear. The pairs of lateral raising/lowering belts 21B to 21E are disposed between the pair of longitudinal belts 21A, can be raised and lowered on the left of the conveyance mechanisms 16, 18, 20, and 22, respectively. The pairs of lateral raising/lowering belts 21B to 21D convey the platen 50 to the left, and the pair of lateral raising/lowering belts 21E convey the platen 50 to the right.
The conveyance mechanism 22 is provided with a pair of lateral belts 22A. The pair of lateral belts 22A are provided at both end portions of the conveyance mechanism 22 in a direction orthogonal to the conveyance direction, in a plan view, and convey the platen 50 to the right. The conveyance mechanism 23 is provided with a pair of longitudinal belts 23A and pairs of lateral raising/lowering belts 23B and 23C. The pair of longitudinal belts 23A are provided at both end portions of the conveyance mechanism 23 in a direction orthogonal to the conveyance direction, in a plan view. The pair of longitudinal belts 23A convey the platen 50 to the rear. The pairs of lateral raising/lowering belts 23B and 23C are disposed between the pair of longitudinal belts 23A, and can be raised and lowered on the right of the conveyance mechanisms 22 and 28, respectively. The pair of lateral raising/lowering belts 23B convey the platen 50 to the right, and the pair of lateral raising/lowering belts 23C convey the platen 50 to the left.
The conveyance mechanisms 26 to 28 are respectively provided with pairs of lateral belts 26A to 28A that extend in the conveyance direction, and convey the platen 50 in the conveyance direction in each of the conveyance mechanisms 26 to 28, that is, to the left. The conveyance mechanism 29 is provided with a pair of longitudinal belts 29A and pairs of lateral raising/lowering belts 29B and 29C. The pair of longitudinal belts 29A are provided at both end portions of the conveyance mechanism 29 in a direction orthogonal to the conveyance direction, in a plan view. The pair of longitudinal belts 29A convey the platen 50 to the front. The pairs of lateral raising/lowering belts 29B and 29C are disposed between the pair of longitudinal belts 29A, and can be raised and lowered on the left of the conveyance mechanisms 28 and 11, respectively. The pair of lateral raising/lowering belts 29B convey the platen 50 to the left, and the pair of lateral raising/lowering belts 29C convey the platen 50 to the right.
As shown in
An example of a platen conveyance operation by the platen conveyance mechanism 10 will be described with reference to
When the platen 50 reaches a position above the lateral raising/lowering belts 14C, the driving of the longitudinal belts 14A is stopped, and the upward movement of the lateral raising/lowering belts 14C is started. The lateral raising/lowering belts 14C are raised to be higher than the longitudinal belts 14A, and are stopped at the same height position as the lateral conveyance belts 15A. The lateral conveyance belts 15A and the lateral raising/lowering belts 14C are driven, and the platen 50 is transferred from the lateral raising/lowering belts 14C to the lateral conveyance belts 15A. The lateral conveyance belts 15A are driven, and convey the platen 50 toward the printer 3. The platen 50 is transferred from the lateral conveyance belts 15A to the platen supporter 60 provided inside the printer 3. Note that a specific procedure by which the platen 50 is transferred from the lateral conveyance belts 15A to the platen supporter 60 will be described later.
The platen 50 is supported by the platen supporter 60, is conveyed to the left along the pair of rails 3B, and the printing is performed inside the printer 3. When the printing is complete, the platen 50 is conveyed to the left from inside the printer 3, and is stopped at a left end position of the pair of rails 3B. Next, when the lateral conveyance belts 16A are raised, the platen 50 is lifted up by the lateral conveyance belts 16A, and separates from the platen supporter 60. Next, the lateral raising/lowering belts 21B of the conveyance mechanism 21 is raised to the same height position as the lateral conveyance belts 16A. The lateral conveyance belts 16A and the lateral raising/lowering belts 21B are driven, and the platen 50 is transferred from the lateral conveyance belts 16A to the lateral raising/lowering belts 21B. The driving of the lateral raising/lowering belts 21B is stopped and the lateral raising/lowering belts 21B are lowered. At the same time, the longitudinal belts 21A of the conveyance mechanism 21 are driven. The platen 50 is placed on the longitudinal belts 21A as a result of the lateral raising/lowering belts 21B being lowered to be lower than the longitudinal belts 21A, and the platen 50 is conveyed to the rear.
Subsequently, although not described in detail, the platen 50 is conveyed in the order of the conveyance mechanisms 21, 22, and 23 using the same transfer operation as described above, and passes through the post-treatment device 9. The platen 50 that has passed through the post-treatment device 9 is transferred from the left processing line 202 to the first return line 204, and from the first return line 204 to the second return line 205 in that order, is transferred to the conveyance mechanism 11 of the dispatch line 201, and is returned to the preparation position 100.
The structure of the platen 50 will be explained with reference to
As shown in
As shown in
As shown in
When a shirt, such as a T-shirt or the like, is attached to the attachment plate 56 as the cloth P, the neck of the shirt is positioned at the front of the platen 50, and the hem of the shirt is positioned at the rear. In order to prevent the hem of the shirt from hanging down, a hanging prevention plate 56A is provided at the rear of the platen 50. The hanging prevention plate 56A extends further to the rear than the rear end of the attachment plate 56, from the rear end of the spacer 55A, below the attachment plate 56, and then extends upward from there.
The structure of the platen supporter 60 will be described with reference to
The column 62 is provided standing in substantially the center, in the left-right direction, of the upper surface of the base 61, and is formed in a substantially cuboid shape extending upward. As shown in
As shown in
The right plate 632 extends downward from the right end portion of the upper plate 631. The left plate 633 extends downward from the left end portion of the upper plate 631. An opening 637 is provided at the front end of the left plate 633. As shown in
As shown in
The proximity sensor 90 is fixed to the front end of the lower surface of the upper plate 631 of the raising/lowering table 63, and is disposed at a hidden position further to the inside than the outer shape of the raising/lowering table 63 in a plan view. The proximity sensor 90 can detect the platen 50 placed on the raising/lowering table 63. The proximity sensor 90 and a proximity sensor 79 to be described later may be, for example, an induction type proximity sensor, an electrostatic capacity type proximity sensor, a magnetic proximity sensor, or the like.
The structure of the first positioning cylinder 70 will be described with reference to
The horizontal pin 75 is made of metal and has a substantially circular cylindrical shape extending in the left-right direction. A tapered portion 751 is provided at the leading end portion on the left side of the horizontal pin 75. The tapered portion 751 has a substantially conical shape, and the diameter thereof becomes smaller toward the left. A diameter R (refer to
The proximity sensor 79 is provided at a predetermined position inside the main body portion 71. The predetermined position is a position in proximity to the piston inside an air tube, when the horizontal pin 75 has extended to the left to its furthest extent. The proximity sensor 79 detects that the piston has come close.
A structure of the second positioning cylinder 80 will be described with reference to
The supporter 81 is formed in a substantial U-shape that is open to the front in a plan view. The supporter 81 is provided with a rear plate 811, a right plate 812, and a left plate 813. The right plate 812 is disposed extending to the front from the right end portion of the rear plate 811. An opening portion 817 is provided at a position slightly to the rear of the center of the right plate 812. A shaft support hole 814 is provided, in the right plate 812, at a position to the front of and closer to the lower end of the opening portion 817. Fixing pieces 815 and 816 are provided, separated in the front-rear direction, at the upper end portion of the right plate 812. The fixing pieces 815 and 816 protrude to the right from the upper end portion of the right plate 812.
The left plate 813 is installed extending to the front from the left end portion of the rear plate 811. A shaft support hole (not shown in the drawings) is provided, in the left plate 813, at a position facing the shaft support hole 814 of the right plate 812. The support shaft 86 extends in the left-right direction, is inserted through the shaft support hole 814 of the right plate 812 and the shaft support hole of the left plate 813, and is fixed. The main body support shaft 818 also extends in the left-right direction, is inserted through a shaft support hole (not shown in the drawings) provided at a position in the vicinity of the rear of opening portion 817 of the right plate 812, through a shaft support hole (not shown in the drawings) provided at a position at the rear end of the left plate 813 and corresponding to the shaft support hole of the right plate 812, and is fixed. The fixing pieces 815 and 816 are also provided, separated in the front-rear direction, at the upper end portion of the left plate 813. The fixing pieces 815 and 816 protrude to the left from the upper end portion of the left plate 813. Each of the fixing pieces 815 and 816 of the right plate 812 and the left plate 813 is fixed to the lower surface of the upper plate 631 of the raising/lowering table 63, using screws. In this way, the supporter 81 is fixed to the lower surface of the upper plate 631.
The main body portion 82 is disposed inside the supporter 81, and is axially supported so as to be able to pivot around the main body support shaft 818. The cylinder rod 83 is provided so as to be able to advance and retract in the front-rear direction from a substantially central portion of the front surface of the main body portion 82, and is coupled to the piston inside the cylinder tube. A U-shaped portion 831 is fixed to the leading end portion of the cylinder rod 83. The U-shaped portion 831 has a substantial U shape that is open toward the front in a plan view. A support shaft 832 that extends in the left-right direction is supported inside the U-shaped portion 831.
The pin 84 is provided with a base portion 841 and a cylindrical portion 842. The base portion 841 is substantially cuboid shaped. The cylindrical portion 842 extends diagonally downward and to the front, from a side surface of the base portion 841. Note that an R portion 851 may be provided at a corner portion of the outer periphery of a leading end portion 85 of the cylindrical portion 842. The R portion 851 may be formed in a circular arc shape such that a diameter thereof becomes smaller toward the leading end. A part of the base portion 841 is disposed inside the U-shaped portion 831 of the cylinder rod 83. The base portion 841 is supported so as to be able to pivot with respect to the support shaft 86 fixed to the supporter 81. Furthermore, the base portion 841 is supported so as to be able to pivot with respect to the support shaft 832 of the U-shaped portion 831, at a position higher than the support shaft 86. Thus, inside the supporter 81, the main body portion 82 and the pin 84 are supported by the main body support shaft 818 and the support shaft 86.
The proximity sensor 89 is provided at a predetermined position inside the main body portion 82. The predetermined position is, for example, a position in proximity to the piston inside the air tube, when the cylinder rod 83 has extended to the front to its furthest extent. The proximity sensor 89 detects that the piston has come close.
An electrical configuration of the print system 1 will be described with reference to
The CPU 101 controls operations of the print system 1. The ROM 102 stores various programs. The RAM 103 is a working memory and temporarily stores various types of information. The storage portion 104 is a non-volatile flash memory, and stores various types of information. The operation portion 110 receives various inputs by an operator. The operation portion 110 may be a touch panel (not shown in the drawings), and may display various types of information, in addition to receiving the various inputs. The input/output portion 111 is provided with an SD memory card slot, a USB (registered trademark) port, a serial port of another standard, and the like.
The drive circuit 121 controls the operation of the longitudinal belt motor 131 on the basis of a control command from the CPU 101. The drive circuit 122 controls the operation of the lateral belt motor 132 on the basis of a control command from the CPU 101. The drive circuit 123 controls the operation of the lateral raising/lowering belt motor 133 on the basis of a control command from the CPU 101. The drive circuit 124 controls the operation of the lateral conveyance belt motor 134 on the basis of a control command from the CPU 101. The drive circuit 125 controls the operation of the first raising/lowering motor 135 on the basis of a control command from the CPU 101. The drive circuit 126 controls the operation of the second raising/lowering motor 136 on the basis of a control command from the CPU 101. The drive circuit 127 controls the operation of the conveyance motor 137 on the basis of a control command from the CPU 101. The drive circuit 128 controls the operation of the raising/lowering motor 69 on the basis of a control command from the CPU 101. The drive circuit 129 controls the operation of the first positioning cylinder 70 on the basis of a control command from the CPU 101. The drive circuit 130 controls the operation of the second positioning cylinder 80 on the basis of a control command from the CPU 101.
Stepping motors may be used as each of the motors configuring the platen conveyance mechanism 10. In this case, encoders are connected to each of the motors, and the CPU 101 can recognize the position of each of the motors as a result of position information of the motors being transmitted to the CPU 101 from each of the encoders.
The print processing will be described with reference to
When the platen 50 is conveyed to the front of the platen supporter 60 of the printer 3 by the lateral conveyance belts 15A of the conveyance mechanism 15, as shown in
For example, when the platen 50 on the lateral conveyance belts 15A is conveyed toward the raising/lowering table 63 in a state in which the raising/lowering table 63 is at the first position z1, the position of the raising/lowering table 63 is low with respect to the platen 50, and thus, the rear end of the lower plate 54 of the platen 50 collides with the front ends of each of the right plate 632 and the left plate 633 of the raising/lowering table 63. When these members have collided, the raising/lowering table 63 is only inserted partway into a space surrounded by the right side face plate 52, the left side face plate 53, the lower plate 54, and the upper plate 55 of the platen 50. When the positioning has been performed by the first positioning cylinder 70 and the second positioning cylinder 80 in this state, the platen 50 cannot be positioned with respect to a prescribed printing position W, and a defect occurs, such as a printing position with respect to the cloth P being displaced, and the like.
Here, as shown in
The CPU 101 determines whether the insertion of the platen 50 is complete (step S12). An insertion complete position of the platen 50 is, for example, a predetermined position on a downstream of the lateral conveyance belts 15A in the conveyance direction. A limiter switch is provided at the predetermined position, for example. An ON signal of the limiter switch is transmitted to the CPU 101 as a result of the platen 50 conveyed by the lateral conveyance belts 15A pressing the limiter switch and switching it on. As a result of receiving the ON signal, the CPU 101 determines that the insertion of the platen 50 is complete. Until the insertion of the platen 50 is complete (no at step S12), the CPU 101 returns the processing to step S12, and continues to convey the platen 50 toward the raising/lowering table 63. As shown in
As shown in
When the detection signal from the proximity sensor 90 has been received, the platen 50 is separated from the lateral conveyance belts 15A and has been placed on the raising/lowering table 63 (yes at step S15), and thus, the CPU 101 stops the driving of the second raising/lowering motor 136 of the lateral conveyance belts 15A, and stops the lowering of the lateral conveyance belts 15A (step S16). The operation is not limited to this example, and the following operation may be performed. The CPU 101 rotates the second raising/lowering motor 136 by a predetermined amount, lowers the lateral conveyance belts 15A by a predetermined amount, and stops the lowering of the lateral conveyance belts 15A. At this time, the CPU 101 determines whether the detection result from the proximity sensor 90 has been received. When it is determined that the detection result has been received, the CPU 101 determines that the platen 50 has been placed on the raising/lowering table 63. When it is determined that the detection result has not been received, the CPU 101 outputs the error. The three protrusions 634 to 636 that support the platen 50 are disposed at each of the vertices of the triangular shape in a plan view (refer to
Note that, if, for example, the protrusions 634 to 636 of the upper plate 631 of the raising/lowering table 63 are omitted and the lower surface of the upper plate 55 of the platen 50 is directly placed on the upper surface of the upper plate 631, if the lower surface of the upper plate 55 and the upper surface of the upper plate 631 are not parallel to each other, the lower surface of the upper plate 55 does not come into close contact with the upper surface of the upper plate 631, the platen 50 rattles with respect to the raising/lowering table 63, and the platen 50 is not supported at a constant height position. In contrast to this, the first embodiment can support the upper plate 55 of the platen 50 at the constant height position with respect to the upper plate 631 of the raising/lowering table 63, by placing the lower surface of the upper plate 55 of the platen 50 on the protrusions 634 to 636.
In order to position the platen 50 at the prescribed printing position W (refer to
Here, as shown in
When the first positioning cylinder 70 is operated, the horizontal pin 75 extends from the cylindrical portion 73 of the first positioning cylinder 70 toward the insertion hole 59 of the left side face plate 53 of the platen 50 (refer to
When the horizontal pin 75 further extends toward the insertion hole 59, the tapered portion 751 presses one of the side edge portions 592 to the left, in a state of being in contact with the one of the pair of side edge portions 592 of the insertion hole 59. Here, both the tapered portion 751 of the horizontal pin 75 and the tapered portion 591 of the insertion hole 59 are inclined so as to widen in the up-down direction and the front-rear direction from the left toward the right. Thus, for example, even if the center of the insertion hole 59 on the platen 50 is displaced in the front-rear direction with respect to the leading end of the horizontal pin 75, as a result of the tapered portion 751 pressing the one of the side edge portions 592 of the tapered portion 591 to the left, the tapered portion 591 slides along the inclined surface of the tapered portion 751, and moves such that the center of the insertion hole 59 is aligned with the position, in the front-rear direction, of the leading end of the horizontal pin 75. At this time, the platen 50 moves in the front-rear direction using the position of the horizontal pin 75 as a reference.
Then, when both a front section and a rear section of the tapered portion 751 of the horizontal pin 75 are in contact with the front end portion and the rear end portion of the insertion hole 59, the platen 50 cannot move in the front-rear direction, and the platen 50 is firmly positioned in the front-rear direction with respect to the raising/lowering table 63.
Further, the tapered portion 751 of the horizontal pin 75 presses the tapered portion 591 of the insertion hole 59 to the left, and thus, the platen 50 moves to the left with respect to the raising/lowering table 63. As a result of this, the inner surface (left surface) of the right side face plate 52 of the platen 50 comes into contact with the outer surface (right surface) of the right plate 632 of the raising/lowering table 63. Therefore, not only in the front-rear direction, the platen 50 also cannot move in the left-right direction, and the platen 50 is thus firmly positioned in the left-right direction with respect to the raising/lowering table 63.
As described above, the tapered portion 751 of the horizontal pin 75 is in contact with and is pressed against the tapered portion 591 of the insertion hole 59, and thus, for example, even if the leading end portion of the tapered portion 751 of the horizontal pin 75 is displaced from the center of the insertion hole 59 in the front-rear direction, the tapered portion 591 slides along the inclined surface of the tapered portion 751. In this way, the horizontal pin 75 is guided toward the center of the insertion hole 59. Then, in the state of being in contact with the pair of side edge portions 592, the tapered portion 751 presses the side edge portions to the left. Thus, the platen 50 also cannot move in the front-rear direction, and at the same time as determining the position in the left-right direction, the platen 50 is also firmly positioned in the front-rear direction with respect to the raising/lowering table 63.
The CPU 101 determines whether the positioning in the left-right direction and the front-rear direction is complete (step S18). The proximity sensor 79 (refer to
As shown in
The lower surface of the upper plate 55 of the platen 50 is already in contact with the protrusions 634 to 636 of the upper plate 631 of the raising/lowering table 63. Thus, as a result of the lower plate 54 being pressed downward by the leading end portion 85 of the pin 84, the platen 50 moves downward so as to correct a displacement in the up-down direction with respect to the raising/lowering table 63. Then, a state is obtained in which the upper plate 55 of the platen 50 is being pressed from above against the protrusions 634 to 636 of the raising/lowering table 63. In this way, the platen 50 is firmly positioned in the up-down direction with respect to the raising/lowering table 63. Then, the platen 50 is positioned with respect to the raising/lowering table 63 in each of the left-right direction, the front-rear direction, and the up-down direction, and thus, the platen 50 is accurately positioned at the prescribed printing position W of the printer 3.
The CPU 101 determines whether the positioning in the up-down direction is complete (step S20). The proximity sensor 89 (refer to
When the CPU 101 has received the detection signal from the proximity sensor 89, the positioning of the platen 50 in the up-down direction is complete (yes at step S20), and thus, subsequently, in accordance with the height position of the platen 50 input by the operator using the operation portion 110, the CPU 101 lowers the raising/lowering table 63 from the second position z2 and lowers the position of the platen 50 (step S21). Depending on the thickness of the cloth P, it is sometimes necessary to lower the position of the platen 50. It is sufficient for the operator to use the operation portion 110 and input the height position of the platen 50 depending on the thickness of the cloth P. The print preparation is completed in this way, and thus, the CPU 101 uses the printer 3 to perform the printing, using the print head, on the cloth P on which the pretreatment has been performed (step S22).
Note that there are variations in the thickness of the cloth P attached to the platen 50, and wrinkles and the like are an example of this. When the foreign matter detection sensor 93 (refer to
When the print processing ends, the CPU 101 conveys the platen supporter 60 along the pair of rails 3B to a transfer position (step S23). At the transfer position, the pair of lateral conveyance belts 16A are disposed at both the left and right directions of the pair of rails 3B (refer to
The CPU 101 raises the pair of lateral conveyance belts 16A (step S27). The lower surface of the seat 51 of the platen 50 is placed on the upper surface of each of the pair of lateral conveyance belts 16A. As a result of the lateral conveyance belts 16A further rising, the upper plate 55 of the platen 50 is separated from the protrusions 634 to 636 of the upper plate 631 of the raising/lowering table 63, and the platen 50 is lifted up. The CPU 101 determines whether the platen 50 has separated from the raising/lowering table 63 (step S28). When the proximity sensor 90 fixed to the raising/lowering table 63 continues to detect the platen 50, this means that the platen 50 has not separated from the raising/lowering table 63 (no at step S28), and the CPU 101 determines whether an elapsed time from the raising of the lateral conveyance belts 16A has been exceeded (step S31).
When the elapsed time has not been exceeded (no at step S31), the CPU 101 returns the processing to step S27, and continues to raise the lateral conveyance belts 16A. When the elapsed time has been exceeded (yes at step S31), the CPU 101 outputs an error (step S32), and ends the print processing.
When the proximity sensor 90 no longer detects the platen 50, this means that the platen 50 has separated from the raising/lowering table 63 (yes at step S28), and the CPU 101 ends this processing. The platen 50 is in a state of having been transferred to the lateral conveyance belts 16A. When the platen 50 is transferred to the lateral conveyance belts 16A, the platen supporter 60 in a state of supporting the platen 50 may be rotated forward and rearward by a forward/rearward rotation device that is not shown in the drawings. The platen 50 can be transferred to the lateral conveyance belts 16A by this forward and rearward rotation. The configuration is not limited to this example, and after the printing in the printer 3, although the platen supporter 60 is conveyed to the left along the pair of rails 3B, the platen supporter 60 may transfer the platen 50 to the lateral conveyance belts 16A during that conveyance. When the platen 50 is placed, the CPU 101 moves the lateral conveyance belts 16A to be higher than the platen supporter 60, and further rotates the lateral conveyance belts 16A to the left. In this way, the platen 50 is transferred from the platen supporter 60 to the lateral conveyance belts 16A.
As described above, the print system 1 according to the first embodiment is provided with the conveyance mechanisms 14 and 15, the print conveyance mechanism 41, and the first positioning cylinder 70. The conveyance mechanism 14 conveys the platen 50 to the pretreatment device 2. The print conveyance mechanism 41 is provided with the platen supporter 60. The platen supporter 60 supports the platen 50 conveyed by the conveyance mechanism 15. The print conveyance mechanism 41 conveys the platen supporter 60 to the printer 3. The first positioning cylinder 70 positions the platen 50 at the prescribed printing position W in the left-right direction and in the front-rear direction in the printer 3. Thus, the print system 1 can reduce a possibility of the platen 50 not being conveyed to the printer 3. In this way, the platen 50 is conveyed to the printer 3 by the print conveyance mechanism 41 in the state of being positioned at the prescribed printing position W. Thus, the printer 3 can perform the printing on the cloth P on the platen 50 without any positional displacement of a target position.
The platen supporter 60 can be raised and lowered by the raising/lowering table 63. For example, the pair of rails 67 extend in the up-down direction and guide the raising/lowering table 63. The ball screw 68 is provided in parallel with the pair of rails 67 and is coupled to the raising/lowering motor 69. The nut 681 is screwed onto the ball screw 68, and is fixed to the platen supporter 60. In this way, the raising/lowering table 63 moves in the up-down direction along the pair of rails 67 by the raising/lowering motor 69 rotating the ball screw 68. The platen supporter 60 is raised and lowered in accordance with the movement in the up-down direction of the raising/lowering table 63. Thus, in the print conveyance mechanism 41, when the platen supporter 60 supports the platen 50 conveyed by the conveyance mechanism 15, the platen supporter 60 can be raised or lowered so as not to interfere with the platen 50. Thus, the print system 1 can further reduce the possibility of the platen 50 not being conveyed to the printer 3. Further, the platen supporter 60 can adjust the height of the platen 50 at the time of printing, using the raising/lowering table 63, or a height adjustment mechanism that is not shown in the drawings.
The print system 1 is provided with the proximity sensor 90. The proximity sensor 90 detects that the platen 50 is supported by the platen supporter 60. When it is detected by the proximity sensor 90 that the platen supporter 60 has supported the platen 50, the first positioning cylinder 70 positions the platen 50 at the prescribed printing position W. For example, the platen supporter 60 is provided with the horizontal pin 75. The horizontal pin 75 can come into contact with the platen 50 by moving. When it is detected by the proximity sensor 90 that the platen supporter 60 has supported the platen 50, the first positioning cylinder 70 extends the horizontal pin 75 toward the platen 50 from the cylindrical portion 73. As a result of the horizontal pin 75 coming into contact with the platen 50, the platen 50 is positioned at the prescribed printing position W. In this way, the print system 1 can reduce an erroneous operation of the first positioning cylinder 70 performing the positioning without the platen supporter 60 supporting the platen 50. Thus, the print system 1 can further reduce the possibility of the platen 50 not being conveyed to the printer 3.
The proximity sensor 90 is provided at the platen supporter 60, and is disposed further to the inside than the outer shape of the platen supporter 60. In this way, the print system 1 can inhibit the cloth P from becoming caught up on the proximity sensor 90 provided at the platen supporter 60, in a state in which, for example, the cloth P is attached along the outer shape of the platen 50 and the platen 50 supports the cloth P. Thus, when the cloth P is removed from the platen 50, for example, the print system 1 can inhibit the cloth P from being damaged as a result of the cloth P being caught up on the proximity sensor 90, or inhibit the proximity sensor 90 from falling off as a result of being pulled by the cloth P. Further, since the cloth P does not become caught up on the proximity sensor 90, the print system 1 can inhibit any impact on the operation of the proximity sensor 90.
When the proximity sensor 90 does not detect the support of the platen 50 by the platen supporter 60 after the platen 50 has been conveyed by the conveyance mechanisms 14 and 15, the print system 1 outputs the error. In this way, the print system 1 can recognize, by outputting the error, that the platen supporter 60 has been conveyed to the printer 3 in a state of not supporting the platen 50.
The print system 1 is provided with the first positioning cylinder 70 and the second positioning cylinder 80. The first positioning cylinder 70 positions the platen 50 at the prescribed printing position W in the left-right direction and the front-rear direction. The second positioning cylinder 80 positions the platen 50 at the prescribed printing position W in the up-down direction. In the state of being supported by the platen supporter 60, the position of the platen 50 in the up-down direction is roughly determined by gravity. Using that characteristic, the print system 1 positions the platen 50 in the up-down direction at the prescribed printing position W after first positioning the platen 50 in the left-right direction and the front-rear direction at the prescribed printing position W. In this way, after positioning the platen 50 in the horizontal direction at the prescribed printing position W, the print system 1 can easily and rapidly determine the position, at the prescribed printing position W in the up-down direction, of the platen 50 for which the position in the up-down direction has been roughly determined. Further, in addition to being able to position the platen 50 at the prescribed printing position W in the horizontal direction, the print system 1 can position the platen 50 at the prescribed printing position W in the up-down direction. Thus, the print system 1 can support the cloth P attached to the platen 50 at the constant height position during the conveyance of the platen 50. In this way, the print system 1 can inhibit positional displacement of the printing by the printer 3.
The conveyance mechanism 14 conveys the platen 50 using the longitudinal belts 14A. The conveyance mechanism 15 conveys the platen 50 using the lateral conveyance belts 15A. The print conveyance mechanism 41 conveys the platen supporter 60 using the pair of rails 3B. The objective of the conveyance mechanism 14 is to convey the platen 50 to the pretreatment device 2, and thus, by using the longitudinal belts 14A having the relatively low positioning accuracy, the cost of equipment can be reduced. The objective of the conveyance mechanism 15 also is to convey the platen 50, and thus, by using the lateral conveyance belts 15A having the relatively low positioning accuracy, the cost of equipment can be reduced. On the other hand, it is necessary for the print conveyance mechanism 41 to convey the platen supporter 60 to the printer 3, and to position the platen 50 supported by the platen supporter 60 at the prescribed printing position W, and thus, the pair of rails 3B having the relatively high positioning accuracy are used. In this way, the print system 1 can inhibit a printing position in the printing by the printer 3 from becoming displaced.
The platen supporter 60 of the print conveyance mechanism 41 is provided with the pair of rails 67, the ball screw 68, the nut 681, and the raising/lowering motor 69. The pair of rails 67 guide the raising/lowering table 63 in the up-down direction. The ball screw 68 is provided in parallel with the pair of rails 67. The nut 681 is screwed onto the ball screw 68, and is fixed to the raising/lowering table 63. The raising/lowering motor 69 rotates the ball screw 68. In this way, the print system 1 can adjust the height position in the up-down direction of the platen 50 supported by the platen supporter 60 with a high degree of accuracy.
The first positioning cylinder 70 and the second positioning cylinder 80 are disposed further to the inside than the outer shape of the platen supporter 60. In this way, the print system 1 can inhibit the cloth P from becoming caught up on the first positioning cylinder 70 and the second positioning cylinder 80 provided at the platen supporter 60, in the state in which, for example, the cloth P is attached along the outer shape of the platen 50 and the platen 50 supports the cloth P. Thus, when the cloth P is removed from the platen 50, for example, the print system 1 can inhibit the cloth P from being damaged as a result of the cloth P being caught up on the first positioning cylinder 70 and the second positioning cylinder 80, or inhibit the first positioning cylinder 70 and the second positioning cylinder 80 from falling off as a result of being pulled by the cloth P. Further, since the cloth P does not become caught up on the first positioning cylinder 70 and the second positioning cylinder 80, the print system 1 can inhibit any impact on the operation of the first positioning cylinder 70 and the second positioning cylinder 80.
The present disclosure is not limited to the first embodiment and various modifications are possible. Various modifications described below can be combined insofar as no contradictions arise. For example, the present disclosure can also employ a type of printer other than the inkjet printer as in the first embodiment. The print system 1 of the first embodiment positions the platen 50 in the left-right direction and the front-rear direction using the first positioning cylinder 70 and positions the platen 50 in the up-down direction using the second positioning cylinder 80, but the positioning may be performed using a method other than that of the first embodiment. Here, three modified examples are described below in which the method of positioning the platen 50 is changed.
A first modified example will be described with reference to
In the processing at step S14 of the print processing shown in
A second modified example will be described with reference to
When the horizontal pin 75 of the first positioning cylinder 70 has extended to the left, the tapered portion 751 of the horizontal pin 75 comes into contact with the pair of side edge portions 592 of the tapered portion 591 of the insertion hole 59 and pushes the side edge portions 592 to the left. Then, in a similar manner to the first embodiment, the tapered portion 751 of the horizontal pin 75 and the tapered portion 591 of the insertion hole 59 are both are inclined so as to widen in the up-down direction and the front-rear direction from the left toward the right. In this way, the tapered portion 591 slides along the inclined surface of the tapered portion 751, and moves such that the center of the insertion hole 59 is aligned with the position, in the front-rear direction, of the leading end of the horizontal pin 75. At the same time, the tapered portion 751 of the horizontal pin 75 presses the pair of side edge portions 592 to the left. When all of the front end portion, the rear end portion, and the lower end portion of the tapered portion 751 of the horizontal pin 75 are in contact with the front end portion, the rear end portion, and the lower end portion of the insertion hole 59, the platen 50 cannot move in any of the front-rear direction, the left-right direction, and the up-down direction. Thus, the platen 50 is firmly positioned with respect to the raising/lowering table 63 in the front-rear direction, the left-right direction, and the up-down direction. In this way, the second modified example can position the platen 50 in the front-rear direction, the left-right direction, and the up-down direction using only the first positioning cylinder 70, without needing to use the second positioning cylinder 80.
Note that, in the second modified example, the tapered portion 751 of the horizontal pin 75 comes into contact with and presses the pair of side edge portions 592 and the lower edge portion 593, but may position the platen 50 in the left-right direction, the front-rear direction, and the up-down direction by coming into contact with and pressing the pair of side edge portions 592 and an upper edge portion.
A third modified example will be described with reference to
When the pin 84 of the second positioning cylinder 80 pivots downward, the R portion 851 of the leading end portion 85 comes into contact with the tapered portion 541 of the upper surface of the lower plate 54. The diameters of both the R portion 851 of the leading end portion 85 and the tapered portion 541 of the fitting hole 542 become wider toward the upward direction, and thus, when the pin 84 pivots further downward, the tapered portion 541 of the upper surface of the lower plate 54 slides along the inclined surface of the R portion 851 of the leading end portion 85, and, in accordance with the position of the leading end portion 85, the fitting hole 542 moves in the front-rear direction and the left-right direction. Then, as a result of the leading end portion 85 fitting into the fitting hole 542, the platen 50 is positioned in the left-right direction and the front-rear direction.
Then, by pressing the bottom plate 54 downward in a state in which the pin 84 is fitted into the engagement hole 542, the platen 50 is positioned in the up-down direction. In this way, the third modified example can position the platen 50 in the left-right direction, the front-rear direction, and the up-down direction using only the second positioning cylinder 80, without using the first positioning cylinder 70.
In addition to the three above-described modified examples of the present disclosure, various modifications are possible. The conveyance path of the platen 50 of the print system 1 shown in
The proximity sensor 90 is fixed to the upper plate 631 of the raising/lowering table 63 for detecting the platen 50, but a lever switch may be provided in place of the proximity sensor 90. In this case, when the platen 50 is placed on the raising/lowering table 63, the lever switch is pressed by the platen 50 and is switched on. As a result, the CPU 101 can detect that the platen 50 has been placed on the raising/lowering table 63.
The CPU 101 that controls the print system 1 performs the print processing shown in
In the print processing shown in
At step S30 and step S32 shown in
In the first embodiment, the identification information portion (not shown in the drawings) read by the code reader 95 is provided at the cloth P, but may be provided at the platen 50, for example.
In the first embodiment, the platen 50 is conveyed from the lateral conveyance belts 15A to the printer 3, and after the printing has ended, is transferred to the lateral conveyance belts 16A and conveyed, but after the printing has ended, the platen 50 may be returned to the lateral conveyance belts 15A. The platen supporter 60 moves inside the printer 3 and supports the platen 50 during the printing, and it is thus preferable that the position thereof in the up-down direction, the left-right direction, and the front-rear direction does not become displaced. Thus, when the platen 50 is transferred from the lateral conveyance belts 15A to the platen supporter 60, and when the platen 50 is transferred from the platen supporter 60 to the lateral conveyance belts 16A, it is preferable for the lateral conveyance belts 15A and the lateral conveyance belts 16A to move in the up-down direction rather than the platen supporter 60 moving in the up-down direction. However, the platen supporter 60 may move in the up-down direction without the lateral conveyance belts 15A and the lateral conveyance belts 16A moving in the up-down direction.
In the first embodiment, the first positioning cylinder 70, the second positioning cylinder 80, and the proximity sensor 90 are disposed further inside than the outer shape of the platen supporter 60. An example of this arrangement format will be described. In the state in which the raising/lowering table 63 is inserted inside the platen 50, as shown in
In the first embodiment, when the second positioning cylinder 80 (refer to
Hereinafter, the second embodiment will be described with reference to
In the second embodiment, for the printer 3, the conveyance mechanisms 14, 15, 17, and 19, and the print conveyance mechanisms 41, 42, and 43, the same devices and mechanisms (refer to
A detailed configuration of the platen supporter 60A will be described with reference to
A hole 637A is provided at the center, in the left-right direction, of the upper plate 631A, and further to the front than the center in the front-rear direction. The hole 637A penetrates the upper plate 631A in the up-down direction. The hole 637A is larger than a movement range, in the front-rear direction, of a rear roller 72A to be described later. Protrusions 634A and 635A are provided, respectively, at the front left corner portion and the front right corner portion of the upper plate 631A. A protrusion 636A is provided to the rear of the hole 637A, of the upper plate 631A. The protrusions 634A, 635A, and 636A protrude upward from the upper surface of the upper plate 631A. In the second embodiment, the proximity sensor 90 is provided to the rear of the protrusion 636A. In other words, the proximity sensor 90 is disposed further to the inside than the outer shape of the upper plate 631A in a plan view.
A plate 638A is provided at the front end portion of the hole 637A. The plate 638A extends upward from the upper plate 631A. A hole 639A is provided in the plate 638A. The hole 639A penetrates the plate 638A in the left-right direction. A rotation restricting member 91A to be described later and shown in
A positioner 70A for determining the position of the platen 50A shown in
As shown in
A plate 736A is fixed to the front end of the cylinder rod 732A. The plate 736A extends in the left-right direction. The roller support portion 737A is provided at the center, in the left-right direction, of the plate 736A. As shown in
According to the above-described configuration, the plate 736A moves in the front-rear direction as a result of the cylinder rod 732A advancing and retracting with respect to the main body portion 731A by the driving of the positioning cylinder 73A. In this way, the rear roller 72A moves in the front-rear direction with respect to the platen supporter 60A. When the cylinder rod 732A is retracted with respect to the main body portion 731A, the roller support portion 737A is disposed at the rear end of the hole 637A. At this time, the rear roller 72A is disposed at the rear end of the movable range of the rear roller 72A.
The configuration of the platen 50A will be described in detail with reference to
A block 500A is provided at the lower surface of the upper plate 155A. The block 500A has a cuboid shape, and is fixed at a central portion of the upper plate 155A. As shown in
The left block 510A and the right block 520A are arranged side by side in the left-right direction and extend in the front-rear direction. Holes 511A and 521A are formed in central portions, in the front-rear direction, of each of the left block 510A and the right block 520A. The hole 511A extends in the left-right direction from the left surface of the left block 510A to the groove 501A. The hole 521A extends in the left-right direction from the right surface of the right block 520A to the groove 501A. The holes 511A and 521A are aligned on a single straight line in the left-right direction. The rotation restricting member 91A to be described later and shown in
A rear engaging portion 560A is provided at the rear end portions of the left block 510A and the right block 520A. The rear engaging portion 560A is configured by inclined surfaces 561A and 562A. The inclined surface 561A is formed at a rear right corner portion of the left block 510A, and, in a bottom view, extends to the left the further from the front side toward the rear side. The inclined surface 562A is formed at a rear left corner portion of the right block 520A, and, in a bottom view, extends to the right the further from the front side toward the rear side. Thus, when the rear engaging portion 560A is cut in a horizontal plane, a cross-sectional shape thereof widens in both the left and right directions the further from the front toward the rear, namely, the further from the rear engaging portion 560A toward the rear roller 72A (refer to
In a back view, the inclined surface 561A extends to the left the further from the lower side to the upper side thereof. In a back view, the inclined surface 562A extends to the right the further from the lower side to the upper side thereof. In a side view, the inclined surface 561A extends to the front the further from the lower side to the upper side thereof (refer to
A front engaging portion 550A is provided at the front end portions of the left block 510A and the right block 520A. Since both the left block 510A and the right block 520A are fixed to the upper plate 155A, the position of the front engaging portion 550A with respect to the rear engaging portion 560A in the front-rear direction is fixed.
The front engaging portion 550A is configuration by inclined surfaces 551A and 552A. The inclined surface 551A is formed at a front right corner portion of the left block 510A, and, in a bottom view, extends to the left the further from the rear side toward the front side. The inclined surface 552A is formed at a front left corner portion of the right block 520A, and, in a bottom view, extends to the right the further from the rear side toward the front side. Thus, when the front engaging portion 550A is cut in a horizontal plane, a cross-sectional shape thereof widens in both the left and right directions the further from the rear toward the front, namely, the further from the front engaging portion 550A toward the front roller 71A (refer to
In a front view, the inclined surface 551A extends to the left the further from the lower side to the upper side thereof. In a front view, the inclined surface 552A extends to the right the further from the lower side to the upper side thereof. In a side view, the inclined surface 551A extends to the rear the further from the lower side to the upper side thereof (refer to
The electrical configuration of the print system 1 according to the second embodiment will be described. The electrical configuration of the print system 1 according to the second embodiment is the same as the electrical configuration of the print system 1 according to the first embodiment (refer to
At the same time as describing the print processing according to the second embodiment with reference to
As shown in
When the processing at step S14 shown in
In the second embodiment, as described above, the encoder (not shown in the drawings) is provided at the conveyance motor 137. In the processing at step S13 shown in
As shown in
As shown in
When the platen 50A is placed on the raising/lowering table 63 (yes at step S15), the CPU 101 stops the driving of the second raising/lowering motor 136, and stops the lowering of the lateral conveyance belts 15A (step S16). In this state, as shown in
As shown in
When the rear roller 72A presses the rear engaging portion 560A to the front, when the rear roller 72A is displaced toward the inclined surface 561A (the left) or toward the inclined surface 562A (the right) with respect to the center, in the left-right direction, between the inclined surface 561A and the inclined surface 562A, the rear roller 72A moves to the front relative to the rear engaging portion 560A while rotating along the inclined surface 561A or the inclined surface 562A. If, for example, the rear roller 72A does not rotate, a larger friction is more easily generated between the rear roller 72A and the inclined surfaces 561A and 562A than when the rear roller 72A rotates. In the second embodiment, the rear roller 72A rotates, and thus, the large friction between the rear roller 72A and the inclined surfaces 561A and 562A is less likely to be generated. As a result, the print system 1 can suppress wear due to the friction between the rear roller 72A and the inclined surfaces 561A and 562A.
The rear engaging portion 560A is engaged with the rear roller 72A, and thus, the rear engaging portion 560A moves to the front with respect to the platen supporter 60A in accordance with the movement to the front of the rear roller 72A. In this way, the platen 50A moves to the front with respect to the platen supporter 60A. The front engaging portion 550A moves to the front toward the front roller 71A while maintaining the distance, in the front-rear direction, between the front engaging portion 550A and the rear engaging portion 560A to be constant. In this case, when the front roller 71A has become displaced toward the inclined surface 551A (the left) or toward the inclined surface 552A (the right) with respect to the center in the left-right direction between the inclined surface 551A and the inclined surface 552A, the front roller 71A moves to the rear relative to the inclined surfaces 551A and 552A while rotating along the inclined surface 551A or the inclined surface 552A. In the second embodiment, the front roller 71A rotates, and thus, in a similar manner as with the rear roller 72A and the inclined surfaces 561A and 562A, the print system 1 can suppress wear due to the friction between the front roller 71A and the inclined surfaces 551A and 552A.
As a result of the front engaging portion 550A engaging with the front roller 71A, the movement to the front of the platen 50A with respect to the platen supporter 60A is restricted. In other words, the position of the front roller 71A in the front-rear direction is a reference position in the front-rear direction of the platen 50A with respect to the platen supporter 60A. The rear roller 72A is urged to the front toward the front roller 71A by the positioning cylinder 73A, and thus, the movement of the rear roller 72A to the rear is restricted. Thus, as a result of the rear roller 72A moving to the front with respect to the platen supporter 60A in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the platen 50A is positioned at the prescribed printing position W in the front-rear direction by the positioner 70A.
In addition, when the front engaging portion 550A is cut in the horizontal plane, the cross-sectional shape thereof opens while widening in both the left and right directions from the rear toward the front. As a result, in a state in which the platen 50A is positioned in the front-rear direction, the front roller 71A presses the front engaging portion 550A in both the left and right directions due to the urging force of the positioning cylinder 73A. When the rear engaging portion 560A is cut in the horizontal plane, the cross-sectional shape thereof opens while widening in both the left and right directions from the front toward the rear. As a result, in the state in which the platen 50A is positioned in the front-rear direction, the rear roller 72A presses the rear engaging portion 560A in both the left and right directions due to the urging force of the positioning cylinder 73A. In this way, due to the engagement of the front engaging portion 550A and the front roller 71A, and the engagement of the rear engaging portion 560A and the rear roller 72A, the movement in the left-right direction of the platen 50A with respect to the front roller 71A and the rear roller 72A is restricted. Thus, as a result of the rear roller 72A moving to the front with respect to the platen supporter 60A in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the platen 50A is positioned at the prescribed printing position W in the left-right direction by the positioner 70A.
Furthermore, when the front engaging portion 550A is cut in a plane extending in the up-down direction and the left-right direction, the cross-sectional shape thereof opens while widening in both the left and right directions from the lower side toward the upper side. As a result, in the state in which the platen 50A is positioned in the front-rear direction, the front roller 71A presses the front engaging portion 550A downward due to the urging force of the positioning cylinder 73A. When the rear engaging portion 560A is cut in a plane extending in the up-down direction and the left-right direction, the cross-sectional shape thereof opens while widening in both the left and right directions from the lower side toward the upper side. As a result, in the state in which the platen 50A is positioned in the front-rear direction, the rear roller 72A presses the rear engaging portion 560A downward due to the urging force of the positioning cylinder 73A. In this way, due to the engagement of the front engaging portion 550A and the front roller 71A, and the engagement of the rear engaging portion 560A and the rear roller 72A, the lower surface of the platen 50A is pressed against the protrusions 634A, 635A, and 636A. As a result, the platen 50A is restricted from lifting up from the protrusions 634A, 635A, and 636A. Thus, as a result of the rear roller 72A moving to the front with respect to the platen supporter 60A in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the platen 50A is positioned at the prescribed printing position W in the up-down direction.
As described above, the platen 50A is positioned at the prescribed printing position W in the front-rear direction, the left-right direction, and the up-down direction, by the positioner 70A. In this state, a state is maintained, by the positioning cylinder 73A, in which the rear roller 72A is urged to the front toward the front roller 71A. Thus, due to the urging force of the positioning cylinder 73A, the engagement between the front roller 71A and the front engaging portion 550A, and the engagement between the rear engaging portion 560A and the rear roller 72A are not easily released. As a result, the print system 1 can suppress the platen 50A from becoming displaced from the prescribed printing position W.
As shown in
Furthermore, the platen 50A is positioned at the prescribed printing position W with respect to the platen supporter 60A, at the two locations of the front roller 71A and the front engaging portion 550A, and the rear roller 72A and the rear engaging portion 560A. Thus, the platen 50A is restricted from rotation in the horizontal direction around the front engaging portion 550A, and the platen 50A is restricted from rotating in the horizontal direction around rear engaging portion 560A. Furthermore, the platen 50A is restricted from lifting up to the rear end with the front engaging portion 550A as a fulcrum, and the platen 50A is restricted from lifting up to the front end with the rear engaging portion 560A as a fulcrum.
When the platen 50A is positioned at the prescribed printing position W as a result of the platen 50A moving to the front with respect to the platen supporter 60A, the plate 638A is disposed at a central portion, in the front-rear direction, of the groove 501A. In this way, in the state in which the platen 50A is positioned at the prescribed printing position W, the holes 511A, 639A, and 521A are aligned on the straight line in the left-right direction. In this state, a user inserts the rotation restricting member 91A into the holes 521A, 639A, and 511A.
The rotation restricting member 91A is a pin for restricting the platen 50A from rotating in the horizontal direction with respect to the platen supporter 60A, and extends from the right end of the right block 520A to the left end of the left block 510A. In this case, if the platen 50A tries to rotate in the horizontal direction with respect to the platen supporter 60A, the rotation restricting member 91A engages with the walls of the holes 511A, 639A, and 521A. In this way, the platen 50A is further restricted from rotating in the horizontal direction with respect to the platen supporter 60A. The flow from transferring the platen 50A to the platen supporter 60A up to determining the position of the platen 50A at the prescribed printing position W ends in this way.
The description will return to
As described above, the print system 1 according to the second embodiment is provided with the conveyance mechanisms 14 and 15, the print conveyance mechanism 41, and the positioner 70A. The conveyance mechanism 14 conveys the platen 50A to the pretreatment device 2. The print conveyance mechanism 41 is provided with the platen supporter 60A. The platen supporter 60A supports the platen 50A conveyed by the conveyance mechanism 15. The print conveyance mechanism 41 conveys the platen supporter 60A to the printer 3. Thus, the positioner 70A positions the platen 50A supported by the platen supporter 60A at the prescribed printing position W in the horizontal direction. As a result, the print system 1 can reduce the possibility of the platen 50A not being conveyed to the printer 3. The platen 50A is conveyed to the printers 3, 4, and 5 in the state of being positioned at the prescribed printing position W, and thus, the printers 3, 4, and 5 can perform the printing on the cloth P on the conveyed platen 50A without any positional displacement of a target position. Note that, in a similar manner, the printers 6, 7 and 8 can perform the printing without any positional displacement. In addition, the print system 1 according to the second embodiment can achieve the same effects as those of the first embodiment.
The rear engaging portion 560A is provided at the platen 50A. The positioner 70A is provided with the rear roller 72A. The rear roller 72A is provided at the platen supporter 60A, and can move in the front-rear direction with respect to the platen supporter 60A. When the platen 50A is positioned at the prescribed printing position W by the positioner 70A, the rear engaging portion 560A engages with the rear roller 72A. Thus, the print system 1 can even more accurately position the platen 50A at the prescribed printing position W.
As a result of the rear roller 72A moving in the front-rear direction in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the positioner 70A positions the platen 50A at the prescribed printing position W. The positioner 70A is provided with the front roller 71A. The front roller 71A is provided at the platen supporter 60A. For example, the rear roller 72A can move between a first position and a second position. The first position and the second position are different from each other in the front-rear direction. When the rear roller 72A is at the first position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A engages with the rear roller 72A from the front, and the front engaging portion 550A engages with the front roller 71A from the rear. When the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, or the front engaging portion 550A separates from the front roller 71A to the rear. Alternatively, when the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, and the front engaging portion 550A separates from the front roller 71A to the rear. When the platen 50A is positioned at the prescribed printing position W by the positioner 70A, the rear engaging portion 560A engages with the rear roller 72A, and the front engaging portion 550A engages with the front roller 71A. In this way, the platen 50A engages with the platen supporter 60A in the two locations in the front-rear direction. Thus, the print system 1 can suppress the platen 50A from rotating in the horizontal direction with respect to the platen supporter 60A.
The positioner 70A is provided with the positioning cylinder 73A. The positioning cylinder 73A urges the rear roller 72A toward the front roller 71A. Thus, due to the urging force of the positioning cylinder 73A, the rear engaging portion 560A reliably engages with the rear roller 72A. As a result, the print system 1 can even more accurately position the platen 50A at the prescribed printing position W. In the state in which the platen 50A is positioned at the prescribed printing position W, the urging force of the positioning cylinder 73A is maintained. Thus, the print system 1 can suppress the platen 50A from becoming displaced from the prescribed printing position W.
The rear roller 72A is provided so as to be able to move in a direction approaching the front roller 71A in the front-rear direction. The print system 1 is provided with the proximity sensor 90 and the CPU 101. The proximity sensor 90 detects that the platen 50A is supported by the platen supporter 60A. When it is detected by the proximity sensor 90 that the platen 50A is supported by the platen supporter 60A, the CPU 101 urges the rear roller 72A toward the front roller 71A by controlling the positioning cylinder 73A. In the state in which the platen 50A is separated from the platen supporter 60A, the distance L2 between the rear roller 72A and the front roller 71A in the front-rear direction is larger than the distance L1 between the rear engaging portion 560A and the front engaging portion 550A in the front-rear direction. Thus, when the platen 50A is transferred to the platen supporter 60A, the print system 1 can suppress the front engaging portion 550A and the rear engaging portion 560A from interfering with the front roller 71A and the rear roller 72A from above. When it is detected by the proximity sensor 90 that the platen 50A is supported by the platen supporter 60A, the positioning cylinder 73A is controlled, and the rear roller 72A is urged toward the front roller 71A. Thus, the print system 1 can suppress the rear roller 72A from being urged toward the front roller 71A by the positioning cylinder 73A in the state in which the platen 50A is not supported by the platen supporter 60A.
As a result of moving the rear roller 72A to the front in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the positioner 70A positions the platen 50A at the prescribed printing position W in the left-right direction. For example, the rear roller 72A can move between the first position and the second position. The first position and the second position are different from each other in the front-rear direction. When the rear roller 72A is at the first position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A engages with the rear roller 72A from the front and from the left and right directions, and the front engaging portion 550A engages with the front roller 71A from the rear and from the left and right directions. When the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, or the front engaging portion 550A separates from the front roller 71A to the rear. Alternatively, when the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, and the front engaging portion 550A separates from the front roller 71A to the rear. Thus, in addition to positioning the platen 50A at the prescribed printing position W in the front-rear direction, the print system 1 can position the platen 50A at the prescribed printing position W in the left-right direction.
The rear engaging portion 560A is open while widening in both the left and right directions the further from the rear engaging portion 560A toward the rear roller 72A, that is, the further from the front toward the rear. Thus, it is not necessary to separately provide a mechanism for positioning the platen 50A at the prescribed printing position W in the front-rear direction, and a mechanism for positioning the platen 50A at the prescribed printing position W in the left-right direction. As a result, the print system 1 can position the platen 50A at the prescribed printing position W in the front-rear direction and the left-right direction using a simple mechanism.
As a result of moving the rear roller 72A to the front in the state in which the rear engaging portion 560A is engaged with the rear roller 72A, the positioner 70A positions the platen 50A at the prescribed printing position W in the up-down direction. For example, the rear roller 72A can move between the first position and the second position. The first position and the second position are different from each other in the front-rear direction. When the rear roller 72A is at the first position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A engages with the rear roller 72A from the front and from below, and the front engaging portion 550A engages with the front roller 71A from the rear and from below. When the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, or the front engaging portion 550A separates from the front roller 71A to the rear. Alternatively, when the rear roller 72A is at the second position in the state in which the platen 50A is supported, from below, by the platen supporter 60A, the rear engaging portion 560A separates from the rear roller 72A to the front, and the front engaging portion 550A separates from the front roller 71A to the rear. Thus, in addition to positioning the platen 50A at the prescribed printing position W in the front-rear direction, the print system 1 can position the platen 50A at the prescribed printing position W in the up-down direction.
The print system 1 is provided with the rotation restricting member 91A. Thus, using the rotation restricting member 91A, the print system 1 can suppress the platen 50A from rotating in the horizontal direction with respect to the platen supporter 60A. If, for example, an upward force acts on the platen 50A, the rotation restricting member 91A engages with the walls of the holes 521A, 639A, and 511A. Thus, using the rotation restricting member 91A, the print system 1 can suppress the platen 50A from being removed upward from the platen supporter 60A.
In the processing at step S13, the print system 1 controls the conveyance motor 137 using the CPU 101. In this way, the platen supporter 60A is suppressed from moving in the front-rear direction while the platen 50A is being transferred to the platen supporter 60A. As a result, the print system 1 can suppress the transfer of the platen 50A to the platen supporter 60A from becoming difficult.
The present disclosure is not limited to the second embodiment and various modifications are possible. For example, in the second embodiment, the rear roller 72A may be fixed with respect to the platen supporter 60A, and the front roller 71A may be movable with respect to the platen supporter 60A in the front-rear direction. In the second embodiment, the rear roller 72A may be movable in the left-right direction, for example, rather than in the front-rear direction. In this case, the front roller 71A may be provided on the left or on the right of the rear roller 72A, and the block 500A may be fixed to the platen 50A at an orientation obtained by rotating the block 500A by 90° in the horizontal direction, centered on itself, from the orientation of the second embodiment.
In the second embodiment, a configuration may be adopted in which one or both the front roller 71A and the rear roller 72A are not able to rotate. For example, a wall may be provided in place of the front roller 71A. In the second embodiment, the front roller 71A and the rear roller 72A are cylindrically shaped. In contrast to this, the front roller 71A and the rear roller 72A may be another shape, such as a conical shape, for example. The front roller 71A and the rear roller 72A may have a polygonal shape in a plan view, or may have the shape of the front engaging portion 550A and the rear engaging portion 560A in a plan view, for example. The front roller 71A and the rear roller 72A may have mutually different shapes.
One or both of the front engaging portion 550A and the rear engaging portion 560A may have a shape that is different from the above-described embodiment. For example, the front engaging portion 550A and the rear engaging portion 560A may have flat surfaces that extend in the up-down direction and the left-right direction, or may have a curved shape. When the front engaging portion 550A is cut in a horizontal plane, the shape thereof may be a tapered shape that is inclined to the inside in both the left and right directions the further from the rear to the front. In this case, the shape of the front roller 71A in a horizontal plane may correspond to the tapered shape of the front engaging portion 550A, and may be a shape that is open while widening in both the left and right directions the further from the front toward the rear.
In the second embodiment, the front engaging portion 550A and the rear engaging portion 560A are configured by the block 500A. In contrast to this, the front engaging portion 550A and the rear engaging portion 560A may be configured by a plurality of divided blocks. For example, four blocks, namely, a block on which the inclined surface 551A is formed, a block on which the inclined surface 552A is formed, a block on which the inclined surface 561A is formed, and a block on which the inclined surface 562A is formed may be fixed to the lower surface of the platen 50A. Alternatively, two blocks, namely a block on which the inclined surfaces 551A and 552A are formed, and a block on which the inclined surfaces 561A and 562A are formed, may be fixed to the lower surface of the platen 50A. In the above-described embodiment, the respective rear ends of the inclined surfaces 551A and 552A are separated from each other in the left-right direction. In contrast to this, the respective rear ends of the inclined surfaces 551A and 552A may be connected to each other. Similarly, the respective front ends of the inclined surfaces 561A and 562A may be connected to each other.
In the second embodiment, an elastic member, such as a spring, a rubber, a sponge, or the like, may be provided in place of the positioning cylinder 73A. In other words, the rear roller 72A may be urged toward the front roller 71A by an elastic force of the elastic member.
In the second embodiment, the positioning cylinder 73A urges the rear roller 72A toward the front roller 71A by pressing the rear roller 72A from the rear. In contrast to this, the positioning cylinder 73A may urge the rear roller 72A toward the front roller 71A by pulling the rear roller 72A from the front. The positioning cylinder 73A may urge the front roller 71A toward the rear roller 72A.
In the second embodiment, the user inserts the rotation restricting member 91A into each of the holes 521A, 639A, and 511A. In contrast to this, the print system 1 may be provided with a restricting pin drive portion (a robot, for example) for moving between a position at which the rotation restricting member 91A is inserted into each of the holes 521A, 639A, and 511A, and a position at which the rotation restricting member 91A is removed from each of the holes 521A, 639A, and 511A. In this case, the CPU 101 may control the restricting pin drive portion and may perform an operation to remove the rotation restricting member 91A from or insert the rotation restricting member 91A into each of the holes 521A, 639A, and 511A.
In the second embodiment, the platen 50A is restricted from rotating in the horizontal direction with respect to the platen supporter 60A by the rotation restricting member 91A being inserted into each of the holes 521A, 639A, and 511A. A member other than the pin, such as a plate, or a block, may be employed as the rotation restricting member 91A. The print system 1 may adopt another rotation restricting mechanism and restrict the platen 50A from rotating in the horizontal direction with respect to the platen supporter 60A. The print system 1 need not necessarily be provided with the rotation restricting member 91A.
In the second embodiment, the print system 1 may be provided with a sensor for detecting the removal and insertion of the rotation restricting member 91A into and from the holes 521A, 639A, and 511A. In this case, the CPU 101 may move to subsequent processing when it is detected by the sensor that the rotation restricting member 91A has been inserted into the holes 521A, 639A, and 511A, or that the rotation restricting member 91A has been removed from the holes 521A, 639A, and 511A.
In the second embodiment, by the restriction control, the print system 1 restricts the platen supporter 60A from being conveyed in the front-rear direction by the print conveyance mechanisms 41, 42, and 43. In contrast to this, the print system 1 may configured to be able to structurally restrict the platen supporter 60A from being conveyed in the front-rear direction by the print conveyance mechanism 41. For example, a movement restricting hole may be provided in the platen supporter 60A, and a movement restricting pin may be engaged with the print conveyance mechanism 41 by inserting the movement restricting pin into the movement restricting hole. In this case, since the movement restricting pin is engaged with both the movement restricting hole and the print conveyance mechanism 41, the print system 1 can structurally restrict the platen supporter 60A from being conveyed in the front-rear direction by the print conveyance mechanism 41. The user may insert the movement restricting pin into the movement restricting hole before attaching the platen 50A to the platen supporter 60A, and may remove the movement restricting pin from the movement restricting hole after the attachment of the platen 50A to the platen supporter 60A is complete. The print system 1 may be provided with a movement restricting pin drive portion (a robot, for example) for moving the movement restricting pin to a position at which the movement restricting pin is inserted into the movement restricting hole and to a position at which the movement restricting pin is removed from the movement restricting hole. In this case, the CPU 101 may control the movement restricting pin drive portion and remove the rotation restricting pin from or insert the rotation restricting pin into the movement restricting hole.
In the second embodiment, some or all of the contact portions T1 to T4 may be disposed outside the triangular region C in a plan view. The number of the protrusions 634A, 635A, and 636A may be two or less, or may be four or more. The print system 1 need not necessarily be provided with the protrusions 634A, 635A, and 636A. In this case, the lower surface of the upper plate 155A may be in contact with the upper surface of the upper plate 631A. The protrusions 634A, 635A, and 636A may be provided on the lower surface of the upper plate 155A.
The apparatus and methods described above with reference to the various embodiments are merely examples. It goes without saying that they are not confined to the depicted embodiments. While various features have been described in conjunction with the examples outlined above, various alternatives, modifications, variations, and/or improvements of those features and/or examples may be possible. Accordingly, the examples, as set forth above, are intended to be illustrative. Various changes may be made without departing from the broad spirit and scope of the underlying principles.
Number | Date | Country | Kind |
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2019-233946 | Dec 2019 | JP | national |
This application is a continuation application of International Application No. PCT/JP2020/048398, filed Dec. 24, 2020, which claims priority from Japanese Patent Application No. 2019-233946, filed on Dec. 25, 2019. The disclosure of the foregoing application is hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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20220324667 A1 | Oct 2022 | US |
Number | Date | Country | |
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Parent | PCT/JP2020/048398 | Dec 2020 | WO |
Child | 17846562 | US |