JP6659106B2 - Cutting and printing equipment - Google Patents

Description

  The present invention relates to a cutting device capable of cutting a sheet and a printing device including the same.

  Patent Literature 1 discloses a cutting device in which a cutter unit having a rotary blade can be attached to and detached from a carriage that moves in a sheet cutting direction. A user rotates the carriage by replacing the cutter unit. The blade can be replaced with a new one. When the cutter unit is coupled to the carriage, the cutter unit is provided with a hexagonal cross-section input rotary shaft on the cutter unit side connected to the rotary blade in a hexagonal cross-section hole formed on the output rotary shaft on the carriage side. It is configured to be fitted. The output rotary shaft and the input rotary shaft constitute a driving force transmission mechanism for rotating the rotary blade.

JP 2008-30168 A

  However, it is difficult to correctly position the cutter unit when the cutter unit is coupled to the carriage only by fitting the output rotation shaft and the input rotation shaft that constitute the driving force transmission mechanism.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a cutting device and a printing device capable of improving the positioning accuracy of a cutter unit and coupling the cutter unit to a carriage with high work efficiency while reducing the size of the device.

The cutting device of the present invention is provided on the carriage, a conveyance unit that conveys the sheet in the conveyance direction , a carriage that moves in a first direction that intersects the conveyance direction and a second direction that is opposite to the first direction , A drive output unit that rotates with the movement of the carriage, a cutter unit that has a rotary blade that rotates and is coupled to the carriage, and is provided on the cutter unit and is connected on an axis coaxial with the drive output unit. A drive input unit for transmitting the rotation of the drive output unit to the rotary blade, provided in the cutter unit, input to the drive input unit when the carriage moves in the first direction. Penetrating gear that transmits the rotation input to the drive input unit to the rotary blade when the carriage moves in the second direction. Characterized in that it comprises a.

  ADVANTAGE OF THE INVENTION According to this invention, the structure of the positioning mechanism of a cutter unit is collectively provided in the component part of the power transmission mechanism of a movable blade by coupling of a carriage and a cutter unit, The positioning accuracy of the unit can be improved. Therefore, the cutter unit can be efficiently connected to the carriage.

FIG. 1 is a schematic configuration diagram of a printing apparatus according to the present invention. FIG. 2 is a block diagram of a control system of the printing apparatus in FIG. 1. It is a perspective view of the cutting device in FIG. It is a top view of a cutting device. It is a perspective view of a cutting device. It is a perspective view of the carriage in a cutting device. It is a side view of a cutting device. It is the enlarged view which looked at the principal part of the cutter unit in a cutting device from the upper part. It is a front view of the cutter unit moving in the cutting direction. It is a front view of the cutter unit moving in the direction opposite to the cutting direction. It is the perspective view which looked at the cutter unit from the back side. It is the perspective view which looked at the cutter unit from the front side. It is sectional drawing of the principal part at the time of the installation start of a cutter unit. It is sectional drawing of the principal part in the middle of installation of a cutter unit. It is sectional drawing of the principal part after the attachment of a cutter unit. It is a flowchart for demonstrating the operation | movement at the time of replacement | exchange of a cutter unit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a cross-sectional view illustrating an embodiment of an inkjet printing apparatus 100 according to the present invention. The printing apparatus 100 holds a continuous sheet 1 wound in a roll shape, and the sheet 1 is sent through a conveyance path between an upper guide 6 and a lower guide 7. The sheet 1 is nipped by a nip portion between the conveying roller 8 and the pinch roller 9, conveyed in the conveying direction indicated by an arrow Y, and sent to a platen 10 provided at a print position facing the print head 2. An image is printed on the sheet 1 conveyed to the printing position by ink ejected from the print head 2. The print head 2, the carriage 3 on which the print head 2 is mounted, and the platen 10 arranged opposite to the print head 2 constitute an image printing unit. In the printing apparatus 100, a carriage shaft 4 and a guide rail (not shown) are provided in parallel with each other. Along the carriage shaft 4, the carriage 3 extends in a direction intersecting (in the present example, orthogonally) with the transport direction Y. It is guided so that it can reciprocate. The paper edge sensor 12 provided on the carriage 3 detects the position of the edge of the sheet 1 by moving together with the carriage 3. The image printing unit prints an image for one line with the forward or backward movement of the carriage 3, and then conveys the sheet 1 by a predetermined amount in the conveying direction. Print the line image. A printed portion (printed portion) of the sheet 1 on which the image is printed is conveyed toward the paper ejection guide 11.

  By repeating such operations, images can be sequentially printed on the sheet 1. The portion of the sheet 1 on which the predetermined image is printed is cut at the cutting position of the cutting device 5. The cut sheet (cut sheet) is discharged from the discharge guide 11 to the outside of the printing apparatus 100. The printing apparatus 100 is not limited to the serial scanning method as in the present embodiment, but may be a so-called full line method or a printing method other than the ink jet method.

  FIG. 2 is a block diagram for explaining a configuration of a control system of the printing apparatus 100.

  The control unit 400 included in the printing apparatus 100 controls the transport motor 51, the cutter motor 103, the carriage motor 52, and the print head 2 based on signals from the encoder 104 of the cutter motor 103, the sheet edge sensor 12, and the standby position sensor 106. Control. The control unit 400 includes a CPU, a ROM, a RAM, a motor driver, and the like (not shown), and includes a main control unit 410, a transport control unit 420, and a print control unit 430. The main control unit 410 gives a command to the transport control unit 420 and the print control unit 430. Under the control of the main control unit 410, the transport control unit 420 rotates the transport roller 8 by the transport motor 51 to transport the sheet 1, and operates the cutting device 5 by the cutter motor 103 to cut the sheet 1. The print control unit 430 prints an image on the sheet 1 by moving the carriage 3 by the carriage motor 52 and discharging ink from the print head 2.

(Schematic configuration of cutting device)
FIG. 3 is a perspective view showing the entire cutting device 5, FIG. 4 is a plan view of the periphery of the cutting device 5 provided in the printing apparatus 100, and FIG. 5 is a perspective view of a main part of the cutting device 5.

  The cutting device 5 includes a guide rail 101, a toothed belt 102, a carriage 200, and a cutter unit 300. The guide rail 101 guides the carriage 200 so as to be able to reciprocate along a direction intersecting with the conveying direction of the sheet 1 (arrow Y direction). In the case of this example, the carriage 200 is guided so as to be able to reciprocate in the directions of arrows X1 and X2 orthogonal to the transport direction. The carriage 200 is connected to the belt 102. A cutter motor 103 and a motor pulley 107 are provided on one side of the guide rail 101, and a tensioner pulley 108 and a tensioner spring 109 are provided on the other side. The belt 102 is stretched between a motor pulley 107 and a tensioner pulley 108. When the tensioner pulley 108 is urged in the direction of arrow X2 by the tensioner spring 109, tension is applied to the belt 102, and jumping of the belt 102 is prevented.

  The cutter unit 300 is exchangeably coupled to the carriage 200 from a coupling direction (predetermined direction), as described later. The cutter unit 300 has a disk-shaped upper movable blade 301 and a lower movable blade 302 that can cut the sheet 1. As shown in FIG. 4, these movable blades 301 and 302 are arranged so as to intersect with the cutting direction X1 at a predetermined angle θ (intersection angle). Is disconnected. The cutter unit 300 reciprocates in the directions of the arrows X1 and X2 together with the carriage 200, and cuts the sheet 1 when moving in the direction of the arrow X1. As will be described later, the carriage 200 obtains a rotational force from the relative movement between itself and the belt 102, and rotates the lower movable blade 302 of the cutter unit 300 by the rotational force. Accordingly, when cutting the sheet 1, both the lower movable blade 302 and the upper movable blade 301 that comes into contact with the lower movable blade 302 rotate.

  During printing of an image, the cutter unit 300 is waiting at a standby position P1 outside the end 1a of the sheet 1, and moves from the standby position P1 in the cutting direction indicated by an arrow X1 when the sheet 1 is cut. After the sheet 1 is cut, the sheet 1 is inverted at the inversion position P2 corresponding to the width of the sheet 1, and returns to the standby position P1 for standby for the next cutting operation. The movement of the cutter unit 300 in the direction of the arrow X2 does not contribute to the cutting operation.

  Based on the output signal (pulse signal) of the encoder 104 provided in the cutter motor 103, the moving position of the arrow X1, X2 of the cutter unit 300 can be controlled. Since the relationship between the number of pulses of the encoder 104 and the amount of movement of the cutter unit 300 is known in advance, the amount of movement of the cutter unit 300 can be determined by counting the number of pulses of the encoder 104. A sensor holder 105 is fixed at a fixed position near the standby position P1, and the sensor holder 105 is provided with a standby position sensor 106. By detecting the sensor flag portion 305f disposed on the cutter unit 300 by the standby position sensor 106, the cutter unit 300 can be accurately stopped at the standby position P1. The standby position sensor 106 can also detect the presence or absence of the cutter unit 300 at the standby position P1.

(Structure of carriage)
FIG. 6 is a perspective view of the carriage 200, and FIG. 7 is a side view of the cutting device 5.

  The carriage 200 is disposed inside a guide rail 101 having four guide surfaces 101a, 101b, 101c, and 101d as described later. It includes a carriage chassis 201, a carriage holder 202, an upper roller holder (first holding unit) 203, and a lower roller holder (second holding unit) 204. Both ends of the belt 102 are inserted and connected to the belt insertion portion 202a of the carriage holder 202. The carriage holder 202 is fixed to the carriage chassis 201. The roller holders 203 and 204 hold rollers (rotating bodies) as guides as described later.

  When a slight gap is provided between the carriage 200 and the guide rail 101 in order to smoothly move the carriage 200 along the guide rail 101, the carriage 200 is displaced within the gap. As described above, since the movable blades 301 and 302 of the cutter unit 300 are inclined by the predetermined angle θ (intersection angle), the cutter unit 300 is displaced upstream in the transport direction during cutting of the sheet 1. Such force acts. Therefore, while the sheet 1 is being cut, the carriage 200 may be displaced upstream in the transport direction. If the position of the cutter unit 300 integrated with the carriage 200 is displaced from the start of cutting, the cut portion of the sheet 1 may bend in the transport direction. Therefore, it is necessary to arrange the carriage 200 such that there is no gap with respect to the guide rail 101 and to reduce the load during movement.

  In this example, the following guide mechanism is configured between the guide rail 101 and the carriage 200.

  The upper roller holder 203 is fixed to the carriage chassis 201, and as shown in FIG. 6, two rollers (first guide bodies) 205A rotatably supported by a roller shaft 206A are provided in the sheet 1 cutting direction. . The lower roller holder 204 is held by the carriage holder 202 so as to be slidable in the directions of arrows A1 and A2 at a position facing the upper roller holder 203. That is, the roller holders 203 and 204 are guided so as to be movable toward and away from each other. 6, two rollers (second guide bodies) 205B rotatably supported by a roller shaft 206B are provided in the lower roller holder 204 in the sheet 1 cutting direction. A pressing spring 207 for urging the upper roller holder 203 and the lower roller holder 204 in a direction to separate them from each other is provided. That is, the upper roller holder 203 is urged in the direction of the arrow A2, that is, in the direction inclining upward and in the transport direction as shown in FIG. The lower roller holder 204 is urged in the direction of arrow A1, that is, in the direction inclined in the downstream direction and downward in the transport direction as shown in FIG.

  The guide rail 101 has first, second, third, and fourth guide surfaces 101a, 101b, 101c, and 101d for guiding the rollers 205A and 205B. The first and second guide surfaces 101a and 101b are located on different planes to form a first guide portion, and the third and fourth guide surfaces 101c and 101d are located on different planes and the second guide surface 101c. Construct a guide part. These first and second guide portions face each other inside the guide rail 101. In the case of this example, the first and second guide surfaces 101a and 101b are located on two planes that form a substantially right angle, and similarly, the third and fourth guide surfaces 101c and 101d are formed on two planes that make a substantially right angle. Located in. Further, the first guide surface 101a and the third guide surface 101c are substantially parallel, and the second guide surface 101b and the fourth guide surface 101d are substantially parallel. More specifically, the first guide surface 101a and the third guide surface 101c are surfaces that are orthogonal to the direction in which the sheet 1 is conveyed, and the first guide surface 101a is closer to the conveyance direction than the third guide surface 101c. Located upstream. The second guide surface 101b and the fourth guide surface 101d are surfaces orthogonal to the vertical direction, and the second guide surface 101b is located above the fourth guide surface 101d.

  The roller 205A has a tapered portion (first guided portion) 205Aa formed on one of two peripheral edges, and a tapered portion (second guided portion) 205Ab formed on the other side. The upper roller holder 203 urged in the direction of arrow A2 presses the taper portion 205Aa against the first guide surface 101a and presses the taper portion 205Ab against the second guide surface 101b. The roller 205B has a tapered portion (fourth guided portion) 205Ba formed on one of two peripheral portions, and a tapered portion (third guided portion) 205Bb formed on the other side. The lower roller holder 204 urged in the direction of arrow A1 presses the taper portion 205Ba against the fourth guide surface 101d and presses the taper portion 205Bb against the third guide surface 101c. The pressing spring 207 urges the upper roller holder 203 in the direction of arrow A2 toward the corner between the first guide surface 101a and the second guide surface 101b, so that the upper spring holder 207 is located between the third guide surface 101c and the fourth guide surface 101d. The lower roller holder 204 is urged in the direction of arrow A1 toward the corner of. Accordingly, the tapered portions of the rollers 205A and 205B are reliably pressed against the corresponding guide surfaces of the guide rails 101, and the carriage 200 is arranged so as to have no gap with respect to the guide rails 101, and maintains a stable posture. be able to. As described above, since the carriage 200 has a function of eliminating the gap with respect to the guide rail 101, it is not necessary to separately provide a configuration for eliminating the gap, and the apparatus can be downsized accordingly.

  In this example, two rollers are provided for each of the upper and lower roller holders 203 and 204, for a total of four rollers. However, the number of deployed rollers may be three or more in total. That is, by providing a plurality of rollers on one of the upper and lower roller holders 203 and 204 and providing two or more rollers on the other, the posture of the carriage 200 with respect to the guide rail 101 can be stabilized. In this example, two pressing springs 207 are provided between the upper and lower roller holders 203 and 204. However, the number of the pressing springs 207 may be one or more.

  The carriage 200 is reciprocated by the cutter motor 103 in the directions of arrows X1 and X2 via the belt 102. In accordance with the movement of the carriage 200, the rollers 205A and 205B provided on the upper and lower roller holders 203 and 204 rotate while contacting the corresponding guide surfaces 101a and 101b, guide surfaces 101c and 101d. Thus, the rollers 205A and 205B are always in contact with the guide rail 101 during the reciprocating movement of the carriage 200, and can regulate the position of the carriage 200 in the vertical and horizontal directions in FIG. As a result, the displacement of the cutter unit 300 attached to the carriage 200 from the start of cutting can be suppressed, and the occurrence of bending of the cut portion of the sheet 1 can be suppressed. In addition, by rotating the rollers 205A and 205B, the load when the carriage 200 moves can be reduced.

  In this example, the upper roller holder 203 is fixed to the carriage chassis 201, and the lower roller holder 204 is provided movably in the directions of arrows A1 and A2 with respect to the carriage holder 202 fixed to the carriage chassis 201. Therefore, the carriage 200 attached to the carriage chassis 201 does not move in the direction of the arrow A2 (upstream in the transport direction and upward) even if a force is applied thereto. Therefore, even when the cutter unit 300 receives a force on the upstream side in the transport direction due to the angle θ (crossing angle) at the time of cutting the sheet, the carriage 200 does not move in the arrow A2 direction, and the cutting position of the sheet 1 is changed. It is regulated to a regular position.

  The guide rail 101 has guide taper portions 101e and 101f for guiding the carriage 200 when the carriage 200 is assembled from the side surface. The guide taper portion 101e is formed so as to smoothly continue with the first guide surface 101a located on the upstream side in the transport direction, and is inclined toward the upstream side in the transport direction. The guide taper portion 101f is formed so as to smoothly continue with the second guide surface 101b located on the upper side, and is inclined upward. By using such guide taper portions 101e and 101f, the carriage 200 can be easily assembled from the side surface of the guide rail 101. Further, in order to improve the assemblability, a similar guide taper may be provided for the third guide surface 101c and the fourth guide surface 101d.

  The carriage chassis 201 is provided with a shaft 208 and a roller shaft 210. An output gear 209 is rotatably supported on the shaft 208, and a roller 211 is rotatably supported on the roller shaft 210. These constitute a drive mechanism for rotating the lower movable blade 302 of the cutter unit 300 in accordance with the relative movement between the carriage 200 and the belt 102. The output gear 209 is meshed with the teeth of the belt 102. The roller 211 guides the belt 102 so as to increase the amount of winding of the belt 102 around the output gear 209, thereby increasing the amount of engagement between the belt 102 and the output gear 209 and suppressing tooth jump between them. When the carriage 200 is reciprocated in the directions indicated by arrows X1 and X2 via the belt 102, the output gear 209 meshing with the belt 102 is rotated about the shaft 208. The output gear 209 forms a supply unit that supplies a driving force of the lower movable blade 302 of the cutter unit 300. The output gear 209 is provided with an output portion 209a having a polygonal cross section (in this case, a hexagonal cross section) located on the outer peripheral portion of the shaft 208, and the output portion 209a is located downstream of the sheet 1 in the conveyance direction. It protrudes to the side. The output unit 209a transmits a rotational force to the lower movable blade 302 of the cutter unit 300 as described later.

(Structure of cutter unit)
8 is an enlarged view of the movable blades 301 and 302 of the cutter unit 300 as viewed from above, FIG. 9 is an exploded view when the cutter unit 300 is moving in the direction of the arrow X1 (cutting direction), and FIG. FIG. 4 is an exploded view when the cutter unit 300 is moving in the direction of arrow X2.

  The upper movable blade 301 is a disk-shaped round blade that can rotate integrally with the upper rotation shaft 303, and is disposed above the print surface of the sheet 1 on which an image is printed. The lower movable blade 302 is a disk-shaped round blade rotatable integrally with the lower rotation shaft 304, and is provided below a surface of the sheet 1 opposite to the print surface. The upper rotation shaft 303 is rotatably supported between the main holder 305 and the upper holder 306. The lower movable blade 302 is disposed downstream of the upper movable blade 301 in the conveying direction of the sheet 1, and has a lower rotational axis so as to form a predetermined angle θ (intersection angle) with respect to the cutting direction indicated by the arrow X <b> 1. 304 is rotatably supported between the main holder 305 and the lower holder 307. By disposing the lower holder 307 at a position shifted from the upper holder 306 by the arrow X2 by a predetermined amount, the lower rotation shaft 304 is inclined with respect to the vertical direction in FIG. 8 orthogonal to the cutting direction X1. Therefore, the lower movable blade 302 is inclined at a predetermined angle θ (intersection angle) with respect to the cutting direction indicated by the arrow X, and the intersection angle θ is set. A pressing spring 308 located around the lower rotating shaft 304 is provided between the lower movable blade 302 and the movable blade holder 305, and the lower movable blade 302 is pointed to the upper movable blade 301 by the pressing spring 308. Pressed to make contact. A contact point between the upper movable blade 301 and the lower movable blade 302 becomes a cutting point 309, and the sheet 1 is cut at the cutting point 309.

  In order to improve the cutting performance of the movable blades 302 and 301 at the start of cutting various types of sheets and to enhance the cutting performance, it is necessary to increase the intersection angle θ with respect to the cutting direction (the direction of the arrow X1). However, if the intersection angle θ is too large, the cut surface of the sheet is cut off, and if the sheet is paper, a large amount of paper dust may be generated, which may cause a reduction in cutting quality. Therefore, it is necessary to position the movable blades 302 and 301 so that the intersection angle θ is set with high accuracy. The crossing angle θ is determined by an upper movable blade 301 whose position is set by an assembling position of the upper holder 306 with respect to the main holder 305, and a lower movable blade 302 whose position is set by an assembling position of the lower holder 307 with respect to the main holder 305. It is determined. The upper holder 306 and the lower blade holder 307 can be finely adjusted in the assembly position with respect to the main holder 305, respectively, whereby the intersection angle θ can be adjusted. After the adjustment of the intersection angle θ, each of the upper holder 306 and the lower holder 307 is fixed to the main holder 305, so that the intersection angle θ is maintained.

  The cutter unit 300 has an input gear 310 for forcibly rotating the lower movable blade 302, a pendulum gear 311, and a rotating gear 312. The input gear 310 is provided with a hole-shaped input portion 310a, and the input portion 310a is formed with an inner peripheral portion having a polygonal cross section (a hexagonal cross section in this example). The output gear 209 and the input gear 310 are connected by fitting the input part 310a and the rotation output part 209a of the output gear 209 on the carriage 200 side. As described above, the output gear 209 rotates as the carriage 200 reciprocates. The rotational force of the output gear 209 is transmitted to the input gear 310. That is, the input gear 310 is rotated in the directions of the arrows B1 and B2 as the cutter unit 300 moves.

  The pendulum gear 311 transmits the rotation of the input gear 310 in one direction to the rotating gear 312. That is, when the input gear 310 rotates in the direction of the arrow B1 in FIG. 9, the pendulum gear 311 rotates in the direction of the arrow R1 around the axis of the input gear 310, and rotates to a position where it meshes with the rotary gear 312. , The rotation is transmitted to the rotating gear 312. Thereby, the rotating gear 312 is rotated in the direction of the arrow in FIG. On the other hand, when the input gear 310 rotates in the direction of the arrow B1 in FIG. 10, the pendulum gear 311 rotates in the direction of the arrow R2 around the axis of the input gear 310, and moves to the position shown in FIG. Can be stopped. Thus, the pendulum gear 311 does not mesh with the rotating gear 312, and the rotating gear 312 is not rotated. The rotating gear 312 is attached to the lower rotating shaft 304, and when the rotating gear 312 rotates, the lower movable blade 302 also rotates. Since the upper movable blade 301 is in contact with the lower movable blade 302 at the cutting point 309, when the lower movable blade 302 rotates, the upper movable blade 301 is driven to rotate.

  When the cutter unit 300 is moved in the cutting direction X1 of the arrow X1, the upper movable blade 301 and the lower movable blade 302 rotate in a direction to draw the sheet 1 to the cutting point 309 as shown in FIG. The sheet 1 can be easily cut by the cooperation of the upper movable blade 301 and the lower movable blade 302 rotating as described above. On the other hand, when the cutter unit 300 is moved in the direction of the arrow X2, as shown in FIG. 10, the rotation of the pendulum gear 311 is not transmitted to the rotary gear 312, so that the upper movable blade 301 and the lower movable blade 302 are not rotated. Thereby, wear of the upper movable blade 301 and the lower movable blade 302 can be suppressed, and as a result, their durability can be improved.

(Removal of the cutter unit)
The cutter unit 300 is exchangeably connected to the carriage 200. That is, the cutter unit 300 is detachable from the carriage 200. FIG. 11 is a perspective view of the cutter unit 300 as viewed from the back, and FIG. 12 is a perspective view of the cutter unit 300 as viewed from the front. FIG. 13 is a cross-sectional view of a main part at a stage when mounting of the cutter unit 300 is started, FIG. 14 is a cross-sectional view of a main part at a stage where the cutter unit 300 is being mounted, and FIG. FIG.

  The shaft 208 of the carriage 200 has a leading end 208a that protrudes downstream from the leading end of the output unit 209a in the transport direction, and the main holder 305 of the cutter unit 300 has a positioning hole A305g. The cutter unit 300 is positioned by fitting the distal end portion 208a of the shaft 208 into the positioning hole 305g. The carriage holder 202 has a cutter unit positioning hole 202b, and the main holder 305 has a positioning portion 305a. By fitting the positioning portion 305a into the positioning hole 202b, the cutter unit 300 is positioned in the direction of rotation about the output portion 209a. As described above, the cutter unit 300 is positioned with respect to the carriage 200 by the fitting between the distal end portion 208a of the shaft 208 and the positioning hole 305g and the fitting between the positioning portion 305a and the positioning hole 202b. As described above, the output unit 209a on the carriage 200 and the input unit 310a on the cutter unit 300 are fitted to each other, so that the output gear 209 and the input gear 310 are connected to each other to drive the lower movable blade 302. A transmission system is formed. That is, the output unit 209a and the input unit 310a constitute a transmission mechanism that transmits the driving force (rotation driving force) supplied from the carriage 200 to the lower movable blade 302 of the cutter unit 300. The output unit 209a, the input unit 310a, the tip 208a of the shaft 208, and the positioning hole 305g are located on the same axis O (see FIG. 13) extending along the direction in which the carriage 200 and the cutter unit 300 are joined. Has been deployed.

  As described above, the cutter unit 300 is positioned by fitting the distal end portion 208a of the shaft 208 and the positioning hole 305g, and the lower movable blade is connected by connecting the output gear 209 and the input gear 310 located on the same axis as the shaft 208. The driving force transmission system 302 is connected. In other words, the former positioning of the cutter unit 300 and the latter connection of the driving force transmission system of the lower movable blade 302 can be performed coaxially without interfering with each other. By integrating both functions coaxially, it is possible to improve the workability of mounting the cutter unit 300 and to save space, as compared to a case where a portion exhibiting those functions is set at a remote position. Can be planned. If the parts exhibiting both functions are set at separate and separated positions, separate fitting work on those parts is necessary, and when one part is fitted first, the other Is difficult to fit. Further, in this example, the length of the output unit 209a is set to be longer than the positioning unit 305a so that the positioning unit 305a is inserted into the positioning hole 202b after the output unit 209a is inserted into the input unit 310a. ing. By setting the fitting order in this way, the workability of mounting the cutter unit 300 can be further improved.

  An accommodation portion for accommodating the fixing screw 313 is formed inside the positioning portion 305a. The positioning portion 305a has a cylindrical shape extending in the coupling direction of the cutter unit 300, and is provided with a fixing screw 313 so as to be located on the center axis thereof. The cutter unit 300 is fixed to the carriage 200 by screwing the fixing screw 313 to a portion of the carriage chassis 201 located at the bottom of the positioning hole 202b. As described above, the positioning function of the cutter unit 300 by the positioning portion 305a and the positioning hole 202b and the fixing function of the cutter unit 300 by the fixing screw 313 in the positioning portion 305a are coaxially put together. Therefore, the workability of mounting the cutter unit 300 can be improved and the space can be saved, as compared with the case where the parts exhibiting these functions are set at separate and separated positions. The positioning portion 305a and the positioning hole 202b also function as a rotation preventing mechanism for stopping the relative rotation between the carriage 200 and the cutter unit 300 about the axis O.

  The main holder 305 is provided with a claw 307a that catches on the head of the fixing screw 313 in order to prevent the fixing screw 313 in the positioning portion 305a from dropping. Thus, when the cutter unit 300 is removed from the carriage 200, the fixing screw 313 can be prevented from dropping. In a state where the head of the fixing screw 313 is hooked on the claw 307a and the falling thereof is prevented, the position of the claw 307a is set such that the fixing screw 313 is accommodated in the positioning portion 305a over the entire length. When the cutter unit 300 is mounted on the carriage 200, the distal end of the fixing screw 313 fits into the positioning portion 305a, so that damage due to the distal end of the fixing screw 313 hitting near the rotation stop hole 202b is prevented. be able to. 11 and 12, the fixing screw 313 is disposed on the front side of the cutter unit 300 in the cutting direction (the direction of the arrow X1), and the input unit 310a is disposed on the rear side of the cutter unit 300 in the cutting direction. Have been. Since the fixing screw 313 is located on the front side in the cutting direction, the cutting resistance of the sheet 1 is effectively received at the portion fixed by the fixing screw 313, and the cutter unit 300 is prevented from wobbling, and the posture of the cutter unit 300 is reduced. Can be stabilized.

  When attaching the cutter unit 300 to the carriage 200, first, as shown in FIG. 13, the distal end 208a of the shaft 208 is inserted into the input unit 310a. The distal end portion 208a has a tapered shape smaller than the output portion 209a and is set sufficiently smaller than the inner diameter of the input portion 310a, and serves as a first guide portion when the cutter unit 300 is attached. That is, the position of the cutter unit 300 is roughly regulated by the fitting between the distal end portion 208a and the input portion 310a. As described above, since the distal end portion 208a is set to be longer than the positioning portion 305a, as shown in FIG. 13, when the distal end portion 208a starts to be inserted into the input portion 310a, the positioning portion 305a is not yet positioned. Not inserted into hole 202b.

  When the cutter unit 300 is detached from the carriage 200, the input gear 310 is allowed to swing and slide in the insertion direction of the shaft 208 by the gap G as shown in FIG. That is, the input gear 310 on which the input portion 310a is formed can be displaced in a direction intersecting with the direction in which the cutter unit 300 is coupled to the carriage 200. This gap G may allow only the swing of the input gear 310 or only the sliding. The gap G is set so as to allow the input gear 310 to be tilted at least in a range where the input gear 310 and the pendulum gear 311 do not contact the tooth bottom. The input gear 310 may be slightly tilted with respect to the cutter unit 300. it can.

  Therefore, when the cutter unit 300 is coupled to the carriage 200, even if the position of the cutter unit 300 with respect to the carriage 200 is slightly shifted, the input unit 310a guides the output unit 209a while tilting. As a result, the workability of mounting the cutter unit 300 can be improved. Further, the user can attach the cutter unit 300 at an angle so as to secure a visual field.

  Here, the input unit 310a and the output unit 209a have the same color (in the present specification, the same color or a similar color) and have the same color different from the colors of other peripheral components. This allows the user to visually recognize the relationship between the input unit 310a and the output unit 209a even when attaching for the first time, and easily fit them together.

  As shown in FIG. 14, when the cutter unit 300 is further inserted, the positioning portion 305a is inserted into the positioning hole 202b. At this time, the output unit 209a has not been inserted into the input unit 310a. Therefore, the cutter unit 300 can move within the range of restriction by the input section 310a and the tip section 208a, and the positioning section 305a can be easily inserted into the positioning hole 202b.

Thereafter, by further inserting the cutter unit 300, as shown in FIG. 15, the output unit 209a is inserted into the input unit 310a, and they are connected. Further, the insertion of the distal end portion 208 a into the positioning hole A 305 g positions the cutter unit 300 with respect to the carriage 200. Therefore, after the positioning section 305a is inserted into the positioning hole 202b as shown in FIG. 14, the output section 209a and the tip section 208a are inserted into the input section 310a and the positioning hole 305g as shown in FIG. In this way, by shifting the insertion timing, the workability of the attachment can be improved as compared with the case where they are inserted at the same time.

  As described above, the shaft (shaft) 208, the positioning hole 305 g fitted with the shaft 208, the output unit 209 a, and the input unit 310 a fitted with the shaft 208 are provided at positions facing the carriage 200 and the cutter unit 300. A first set of fitting portions is configured. The convex shaft 208 and the output portion 209a constitute a carriage-side convex portion, and the concave positioning hole 305g and the input portion 310a constitute a cutter unit-side concave portion. Further, the positioning hole 202b and the positioning portion 305a constitute a second set of fitting portions provided at positions where the carriage 200 and the cutter unit 300 face each other. The concave positioning hole 202b forms a carriage-side concave portion, and the convex positioning portion 305a forms a cutter unit-side convex portion. Therefore, the coupling of the first set of fitting parts is started before the second set of fitting parts. More specifically, after loose fitting between the shaft 208 and the input portion 310a is started, fitting between the output portion (transmission convex portion) 209a and the input portion (transmission concave portion) 310a is started, The fitting of the positioning hole 208 and the positioning hole 305g is started. Further, as shown in FIG. 14, between the time when the loose fitting of the shaft 208 and the input portion 310a is started and the time when the fitting of the output portion 209a and the input portion 310a are started, as shown in FIG. The fitting with the part 305a is started. In this way, by shifting the start timing of the fitting at each fitting portion, the workability of the connection of the cutter unit 300 can be improved.

  The distal end 208a of the shaft 208 has a sufficient length, and the length can be adjusted even if the user releases the cutter unit 300 after the cutter unit 300 is positioned as shown in FIG. It is a length that does not drop from 200. For example, when the cutter unit 300 is positioned on the carriage 200 as shown in FIG. 15, the tip of the tip portion 208a (the left end in FIG. 15) is located on the left side in FIG. 15 of the center of gravity of the cutter unit 300. The length of the tip 208a is set. As described above, since the cutter unit 300 is prevented from dropping due to gravity, the user positions the cutter unit 300 as shown in FIG. 15 and then releases his / her hand to fix the cutter unit 300 with the fixing screw 313. Can be. As a result, the workability of mounting the cutter unit 300 is improved.

  If the cutter unit 300 is not located at a correct position during the mounting operation, the distal end portion 208a of the shaft 208 may come into contact with the upper movable blade 301 and the lower movable blade 302. That is, when the distal end portion 208a faces the movable blades 301 and 302 during the coupling of the cutter unit 300, it may come into contact with the movable blades 301 and 302. Therefore, in this example, the guide rail 101 is provided with an abutting portion 101g (see FIG. 7). The abutting portion 101g contacts the positioning portion 305a of the cutter unit 300 so as to prevent occurrence of the contact before the tip portion 208a of the shaft 208 contacts the upper movable blade 301 and the lower movable blade 302. The position at which the portion such as the abutting portion 101g that comes into contact with the positioning portion 305a is not limited to the guide rail 101, and may be provided at a part constituting the carriage 200 or a part other than the cutting device 5. The positioning portion 305a and the abutting portion 101g constitute a pair of opposing portions that can come into contact with each other when the distal end portion 208a opposes the movable blades 301 and 302 when the cutter unit 300 is connected.

  In order to allow a user to stably hold the cutter unit 300 by hand when attaching and detaching the cutter unit 300, a cue portion 305b (see FIG. 9) is provided on both side surfaces of the main holder 305. As shown in FIG. 9, the cue unit 305b, the input unit 310a, the positioning unit 305a, and the fixing screw 313 are arranged on substantially the same straight line along the directions of the arrows X1 and X2. Retention and operability at the time of attachment and detachment can be ensured. In addition, the cutter unit 300 has a small surface other than the cue portion 305b and has a shape that is difficult to hold, so that even when the user attaches and detaches for the first time, the user can easily recognize the portion as having the cue portion 305b. it can.

(External shape of cutter unit)
As shown in FIGS. 11 and 12, the main holder 305 has a support portion 305c1, a support portion 305c2, an extruding portion 305d, and a guide portion 305e, and the upper holder 306 has a guide portion 306a. When the sheet 1 having a short cutting length is cut by the cutter unit 300, the behavior of the cut sheet becomes unstable, and the sheet may enter the guide rail 101. In such a state, when the cutter holder 300 after the cutting operation is moved in the direction X2, the cutter holder 300 may come into contact with the sheet that has entered the guide rail 101 and malfunction may occur. Therefore, in this example, the back surface of the cut sheet is supported by the support portions 305c1 and 305c2. That is, the support portion 305c1 extends from near the cutting point 309 (see FIG. 9) between the upper movable blade 301 and the lower movable blade 302 toward the upstream side in the cutting direction (the direction of the arrow X1), and It is located downstream in the transport direction. The support portion 305c2 extends from the vicinity of the cutting point 309 toward the downstream side in the cutting direction, and is located downstream of the sheet 1 in the transport direction. Thus, when the sheet 1 is cut, the portion of the sheet 1 before cutting is supported by the support portion 305c1, and the portion after cutting is supported by the support portion 305c2. As a result, the sheet 1 can be cut in a stable posture, and the cut sheet can be reliably discharged.

  When the cutter unit 300 returns in the arrow X2 direction after the cutting of the sheet 1 and the rear end of the cut sheet enters the cutting point 309 between the upper movable blade 301 and the lower movable blade 302, The rear end of the cut sheet 1 may be cut again. Therefore, in this example, the rear end of the cut sheet 1 is extruded by the extruding unit 305d. That is, the extruding unit 305d protrudes downstream of the cutting point 309 in the transport direction of the sheet 1, and pushes the cut sheet downstream in the transport direction when the cutter unit 300 returns in the direction of arrow X2. This can prevent the trailing end of the cut sheet from being cut again.

  When the cutter unit 300 returns in the arrow X2 direction after the cutting of the sheet 1 and the end of the sheet 1 on the uncut side contacts the main holder 305 and the upper holder 306, the sheet on the uncut side is cut off. The printed surface of the image in 1 may be damaged. Therefore, in this example, the guide portion 305e and the guide portion 306a are provided. These guide portions 305e and 306a are located on the side facing the print surface of the image on the sheet 1 and on the upstream side in the transport direction, and have a tapered shape that is inclined upward toward the upstream side in the transport direction. . These guide portions 305e and 306a guide the end of the sheet 1 on the uncut side when the cutter unit 300 returns in the arrow X2 direction. Thereby, contact of the main holder 305 and the upper holder 306 with the end of the sheet 1 is avoided, or the contact area is limited only to the end of the end of the sheet 1, thereby suppressing damage to the print surface of the image. it can.

(Replace the cutter unit)
FIG. 16 is a flowchart for explaining the operation when the cutter unit 300 is replaced.

  First, the cutter unit 300 is moved to a predetermined replacement position together with the carriage 200 by selecting the replacement mode of the cutter unit 300 on the operation unit (not shown) of the printing apparatus 100 (step S1). The replacement position is a work position where the user can easily replace the cutter unit 300, and is set to, for example, a substantially central position of a movement area of the cutter unit 300 in the directions of the arrows X1 and X2. Next, the cutter unit 300 is removed by removing the fixing screw 313, and the new cutter unit 300 in place of the cutter unit 300 is positioned on the carriage 200 and fixed by the fixing screw 313 as described above (step S2). After the replacement of the cutter unit 300 in this manner, the completion of the replacement of the cutter unit 300 is confirmed after waiting for an input indicating that the replacement has been completed from the operation unit of the printing apparatus 100 (step S3). Thereafter, the carriage 200 is moved in the direction of the arrow X1 (step S4), and a part of the carriage 200 abuts against a stopper (not shown) on the cutter motor 103 side. By detecting a load variation of the cutter motor 103 at the time of the collision, the collision position is confirmed (step S5).

  At the time of such abutting, tooth skipping of the belt 102 is unlikely to occur for the following reason, so that the load variation of the cutter motor 103 can be reliably detected and the abutting position can be accurately recognized. As described above, both ends of the belt 102, that is, one end on the motor pulley 107 side and the other end on the tensioner pulley 108 side are connected to the belt insertion portion 202 a of the carriage holder 202, respectively. Belt 102 has a relatively short length between one end and motor pulley 107 and a relatively short length between the other end and motor pulley 107 because it is folded back through tensioner pulley 108. long. When the carriage 200 is moved in the direction of the arrow X1 to hit the stopper, the former short portion of the belt 102 pulls the cutter unit 300, so that the extension amount of the portion is small, and tooth jump between the motor pulley 107 and the motor pulley 107 may occur. Hard to occur. If the carriage 200 is moved in the direction of arrow X2 and hits a stopper (not shown) on the tensioner pulley 108 side, the latter longer portion of the belt 102 pulls the cutter unit 300. Therefore, the long portion has a large amount of elongation, and tooth skipping between the motor pulley 107 and the motor pulley 107 is likely to occur.

  After confirming the striking position in step S5, the carriage 200 is moved in the direction of arrow X2 by position control based on the output signal (pulse signal) of the encoder 104 based on the striking position, and is moved to the standby position P1. (Step S6). Then, it is determined whether or not the sensor flag unit 305f of the cutter unit 300 is detected by the standby position sensor 106 provided at the standby position P1 (Step S7). If this is detected, it is determined that the cutter unit 300 has been correctly replaced, and the series of processing ends. On the other hand, if it is not detected, it is determined that the cutter unit 300 is not properly mounted or the movement of the carriage 200 is not normal, and an error such as notifying the user of the determination is made. Processing is performed (step S8).

(Unit configuration)
The carriage 200 and the cutter unit 300 in the cutting device 5 are unitized and detachable from each other. Since the movable blades 301 and 302 are provided in the unitized cutter unit 300, if the movable blades 301 and 302 need to be replaced due to wear or the like, the cutter unit 300 is simply replaced. Good. If the carriage 200 and the cutter unit 300 are not unitized and the movable blades 301 and 302 are assembled to the cutting device 5, the movable blades 301 and 302 are replaced unless the cutting device 5 is disassembled. Can't do that, which is extremely troublesome. In particular, when the cutting device 5 is incorporated in a device such as the printing device 100, replacement of the movable blades 301 and 302 becomes extremely troublesome.

  As described above, the output unit 209a on the carriage 200 side for outputting the rotational force and the input unit 310a on the cutter unit 300 side for inputting the rotational force have the function of transmitting the rotational force of the lower movable blade 302 and the function of the cutter unit. And 300 positioning functions. Thereby, the carriage 200 and the cutter unit 300 can be reduced in size. In particular, the downsizing of the cutter unit 300 makes it easier to handle and greatly improves the workability when replacing it.

(Other embodiments)
The configuration of the blade of the cutting apparatus that cuts the sheet is not limited to the configuration using two rotating movable blades (rotary blades), but may be any configuration that can cut the sheet with relative movement with the sheet. . For example, a configuration using a movable blade that moves up and down, a fixed blade, and a combination of a movable blade and a fixed blade may be used, and the number of blades may be one. Further, the cutting device can be incorporated in various devices that handle sheets in addition to the printing device.

  In the guide mechanism that movably guides the carriage 200 to the guide rail 101, rotatable rollers 205A and 205B are provided as guide members that contact the guide surface of the guide rail 101. The guide member may slide without contacting the guide surface of the guide rail 101 without rotating. In this case, at least two guided surfaces that contact the guide rail 101 can be formed on the guide member, similarly to the rotatable rollers 205A and 205B, and the number of the guide members provided is one or more. Should be fine. Such a guide mechanism can be widely applied as a guide mechanism for movably guiding various carriages. For example, it can be used as a guide mechanism for a carriage 3 on which a print head 2 is mounted or a carriage on which an image reading head is mounted.

Reference Signs List 1 sheet 5 cutting device 200 carriage 202b positioning hole (positioning recess)
208 Shaft 208a Tip (positioning projection)
209a Output part (transmission convex part)
300 Cutter unit 301, 302 Movable blade (rotary blade)
305a Positioning part (positioning convex part)
305g positioning hole (positioning recess)
310a Input part (transmission concave part)
O axis

Claims (10)

Conveying means for conveying the sheet in the conveying direction ,
A carriage that moves in a first direction that intersects the transport direction and a second direction that is opposite to the first direction ;
A drive output unit that is provided on the carriage and rotates with the movement of the carriage;
A cutter unit having a rotating blade, which is coupled to the carriage ,
A drive input unit that is provided on the cutter unit and that is connected on an axis coaxial with the drive output unit and transmits the rotation of the drive output unit to the rotary blade .
When the carriage moves in the first direction, the rotation input to the drive input unit is transmitted to the rotary blade, and when the carriage moves in the second direction, the rotation input to the drive input unit is provided to the cutter unit. A pendulum gear that does not transmit the performed rotation to the rotary blade . The drive output unit and the drive input portion, one is a transmitting convex portion provided with the positioning convex portion, the cutting device according to claim 1 in which the other is characterized in that the transfer recess formed positioning recess.   The cutting according to claim 2, wherein one of the positioning protrusion or the transmission protrusion is displaceable in a direction intersecting the transport direction with respect to one of the positioning recess or the transmission recess. apparatus. The carriage and the cutter unit, provided with a detent means including a detent projection provided on one side and a detent recess provided on the other,
The detent means is configured such that the detent protrusion and the detent recess are fitted by coupling the carriage and the cutter unit, so that the carriage and the cutter unit are positioned relative to the axis in the transport direction. cutting device according to any one of claims 1 to 3, characterized in that does not rotate. The cutting device according to claim 4 , wherein the detent means is located on the side in the first direction relative to the rotary blade. Conveying means for conveying the sheet in the conveying direction,
A carriage that moves in a direction that intersects the transport direction;
A drive output unit that is provided on the carriage and rotates with the movement of the carriage;
A cutter unit having a rotating blade, which is coupled to the carriage,
A drive input unit that is provided on the cutter unit and that is connected on an axis coaxial with the drive output unit and transmits rotation of the drive output unit to the rotary blade;
A positioning projection provided to extend to the drive output unit,
A positioning concave portion provided to extend to the drive input portion and into which the positioning convex portion is inserted;
A detent recess provided in the carriage,
A cutting device provided on the cutter unit, comprising: a rotation-stop projection that fits into the rotation-stop recess.
When the positioning protrusion faces the rotary blade, the detent protrusion contacts the opposing portion of the carriage first before the positioning protrusion contacts the rotary blade, whereby the positioning protrusion is formed. A cutting device characterized in that a part does not contact the rotary blade . 7. The cutter unit according to claim 6 , wherein when one of the positioning convex portion and the positioning concave portion or the rotation preventing convex portion and the rotation preventing concave portion is fitted, the cutter unit is prevented from dropping due to gravity. 8. Cutting device. A screw that is screwed from the transport direction of the carriage and the cutter unit so as to couple the detent convex portion and the detent concave portion,
The cutting device according to claim 6 , wherein the rotation-preventing convex portion has an accommodation portion having a length that accommodates the screw. The cutting device according to claim 8 , wherein the housing includes a claw that regulates a position of a head of the screw. A cutting device according to any one of claims 1 to 9, the printing apparatus characterized by comprising a printable printing means an image on a sheet, a.

Images