JP6229509B2 - Cutting device and printing device - Google Patents

Description

  The present invention relates to a cutting device and a printing device capable of cutting a tape.

  2. Description of the Related Art Conventionally, a printing apparatus having a mechanism for cutting a tape is known (see, for example, Patent Document 1). In the tape cutting device described in Patent Document 1, the rotation lever that rotates the movable blade is rotatable about the rotation axis and is urged upward by the urging force of the torsion spring. When the push button is pushed, the lower surface of the push button pushes the free end side of the rotary lever downward. As a result, the rotating lever biases the torsion spring and rotates downward, and the tape is cut between the movable blade and the fixed blade.

Japanese Utility Model Publication No. 7-23554

  In the tape cutting device described above, the force point and the action point of the torsion spring are at different axial positions of the rotation shafts. The axial direction position of the rotating shaft is a position in a direction orthogonal to the rotating direction of the rotating lever. In this case, when the rotating lever rotates downward by biasing the torsion spring, the torsion spring that is elastically deformed generates a biasing force including a vector component different from the rotation direction of the rotating lever, and the movable blade May move in the axial direction of the rotation axis. If the movable blade moves in the axial direction of the rotating shaft during cutting of the tape, it may be difficult to stably cut the tape.

  An object of this invention is to provide the cutting device and printing device which can cut | disconnect a tape stably.

  The cutting device which concerns on the 1st aspect of this invention has the cutting blade which can cut | disconnect the said tape between the fixing member provided in the position facing the tape conveyed, and the said fixing member, The said cutting blade A first movable member that is rotatable about a predetermined rotation axis and an elastic member provided on the first movable member so as to be close to or away from the fixed member, and different from each other A rotation direction of the first movable member that has a force point and an action point at a position in the axial direction of the rotation shaft, and causes the cutting blade to approach the fixed member when receiving an external force acting in a predetermined direction at the force point An elastic member that applies an urging force in the first direction to the first movable member at the point of application, and an elastic deformation of the elastic member that is provided on the axial direction side with respect to the first movable member. The axial direction of the first movable member when And a regulating member for regulating the movement of.

  According to this aspect, the 1st movable member which has a cutting blade can rotate centering | focusing on a predetermined | prescribed rotating shaft so that a cutting blade may adjoin or leave | separate with respect to a fixed member. The elastic member provided in the first movable member has a force point and an action point at different axial positions of the rotation shafts. When an external force acting in a predetermined direction is received at the force point of the elastic member, a biasing force in the first direction is applied to the first movable member at the point of action of the elastic member, and the cutting blade moves in a direction close to the fixed member. . A restricting member that restricts movement of the first movable member in the axial direction when elastic deformation of the elastic member occurs is provided on the axial direction side with respect to the first movable member. Therefore, when the tape is cut, the movement of the first movable member in the axial direction of the rotation shaft is restricted by the restriction member, so that the tape can be cut stably.

  A printing apparatus according to a second aspect of the present invention includes the cutting device, a printing unit that prints on the tape, and a supply unit that supplies the tape printed by the printing unit to the cutting device. According to this aspect, after printing the tape, the printed tape can be stably cut.

2 is a perspective view of the printing apparatus 1 and the tape cassette 30. FIG. 4 is a plan view showing a state in which the tape cassette 30 is mounted on the cassette mounting portion 8. FIG. FIG. 6 is a perspective view of the unit 70 as viewed from obliquely above. It is a front view of the cutting mechanism 80 in a standby state. It is a perspective view of the half cut mechanism 200 in which the cam board 760 exists in a reference position. It is a top view of the half cut mechanism 200 in which the cam board 760 exists in a reference position. It is a right view of the half cut mechanism 200 in which the cam plate 760 exists in a reference position. It is a front view of the half cut mechanism 200 in which the cam board 760 exists in a reference position. It is a front view of the full cut mechanism 300 and the conveyance mechanism 400 in which the cam board 760 exists in a reference position. It is a top view of the full cut mechanism 300 and the conveyance mechanism 400 in which the cam board 760 exists in a reference position. It is a perspective view of the half cut mechanism 200 in which the cam board 760 exists in a 1st rotation position. It is a top view of the half cut mechanism 200 in which the cam board 760 exists in a 1st rotation position. It is a right view of the half cut mechanism 200 in which the cam board 760 exists in a 1st rotation position. It is a front view of the half cut mechanism 200 in which the cam board 760 exists in a 2nd rotation position. It is a front view of the full cut mechanism 300 and the conveyance mechanism 400 in which the cam board 760 exists in a 3rd rotation position. It is a right side enlarged view of half cut mechanism 200 concerning a modification.

  An embodiment of the present invention will be described with reference to the drawings. In the following description, for the sake of convenience, the lower right side, upper left side, lower left side, upper right side, upper side, and lower side of FIG. 1 are respectively the front side, rear side, left side, right side, and upper side of the printing apparatus 1 and the tape cassette 30. The lower side.

  The printing apparatus 1 will be described. In FIG. 2, the top surface of the cassette case 31 is removed for easy understanding. As shown in FIG. 1, the printing apparatus 1 includes a main body cover 2 having a substantially rectangular parallelepiped shape. The printing apparatus 1 can be connected to a personal computer (not shown, hereinafter referred to as a PC) via a cable (not shown) or the like. For example, the printing apparatus 1 prints a character on a tape based on character data (letters, numbers, figures, etc.) transmitted from a PC.

  A cassette cover 6 that is opened and closed when the tape cassette 30 is replaced is provided on the upper surface of the printing apparatus 1. The main body cover 2 is provided with a cassette mounting portion 8 which is an area where the tape cassette 30 can be attached and detached. The cassette mounting portion 8 is covered when the cassette cover 6 is in the closed position, and is exposed when the cassette cover 6 is in the open position. A discharge port 111 through which the printed tape is discharged from the cassette mounting portion 8 is provided on the left side surface of the main body cover 2. Between the cassette mounting portion 8 and the discharge port 111, a tape discharge portion 110 that forms a transport path for the printed tape is provided. The tape discharge unit 110 is provided with a cutting mechanism 80 (see FIG. 3) described later.

  As shown in FIGS. 1 and 2, a head holder 74 is erected on the front portion of the cassette mounting portion 8. A thermal head 10 including a heating element (not shown) is provided on the front surface of the head holder 74. A ribbon take-up shaft 95 is erected on the rear side of the head holder 74. The ribbon take-up shaft 95 is a shaft that can be attached to and detached from the ribbon take-up spool 44 of the tape cassette 30. A tape drive shaft 100 is erected on the left side of the head holder 74. The tape drive shaft 100 is a shaft body that can be attached to and detached from the tape drive roller 46 of the tape cassette 30.

  On the front side of the head holder 74, the platen holder 12 that can swing around the shaft support 121 is disposed. A platen roller 15 and a movable transport roller 14 are rotatably supported at the left end portion of the platen holder 12. The platen roller 15 can contact and separate from the thermal head 10 relative to the thermal head 10. The movable conveying roller 14 can be brought into contact with and separated from the tape driving roller 46 relative to the tape driving roller 46 mounted on the tape driving shaft 100.

  The tape cassette 30 will be described. As shown in FIGS. 1 and 2, the tape cassette 30 includes a box-shaped cassette case 31. The cassette case 31 has support holes 65 to 68 for rotatably supporting spools. The support hole 65 rotatably supports the first tape spool 40 around which the first tape is wound. The support hole 67 rotatably supports the ribbon spool 42 around which the unused ink ribbon 60 is wound. The support hole 68 rotatably supports the ribbon take-up spool 44 for taking up the used ink ribbon 60. The support hole 66 rotatably supports a second tape spool (not shown) around which the second tape is wound.

  FIG. 2 illustrates a receptor type tape cassette 30. The support hole 65 supports the first tape spool 40 around which the print tape 57 as the first tape is wound. The printing tape 57 is a laminated tape in which a printing layer and a release layer are laminated with an adhesive. Since the second tape is not used in the receptor-type tape cassette 30, the support hole 66 does not support the second tape spool.

  The unit 70 will be described. The upper right side, lower left side, lower right side, upper left side, upper side, and lower side in FIG. 3 correspond to the front side, rear side, left side, right side, upper side, and lower side of the printing apparatus 1 shown in FIGS. In FIG. 3, the exterior of the platen holder 12 shown in FIG. 2 is omitted.

  As shown in FIG. 3, the unit 70 includes a first frame 701, a second frame 702, a printing mechanism 71, a cutting mechanism 80, and the like. The first frame 701 is a metal frame disposed below the cassette mounting portion 8 (see FIG. 1). The printing mechanism 71 is a mechanism for printing a character on a tape, and is disposed on the first frame 701. The printing mechanism 71 includes a head holder 74, a thermal head 10 (see FIG. 2), a platen holder 12, a platen roller 15, a movable conveying roller 14, a ribbon take-up shaft 95, a tape drive shaft 100, a tape drive motor (not shown), and a plurality of them. Including gears.

  The control unit 20 is an electric board having a CPU, a ROM, a RAM, and the like, and is disposed on the lower side of the first frame 701. The control unit 20 controls various operations of the printing apparatus 1 by the CPU executing a program stored in the ROM.

  The second frame 702 is a metal frame and is screwed to the first frame 701. The second frame 702 is disposed below the tape discharging unit 110 (see FIG. 1). The cutting mechanism 80 is a mechanism for cutting the printed tape, and is disposed on the second frame 702. The second frame 702 includes a support plate 730 that extends upward from the left end of the second frame 702. A cutter drive motor 90 described later is fixed to the upper end portion of the support plate 730.

  An outline of the operation of the printing apparatus 1 will be described. In the example shown in FIG. 2, a receptor type tape cassette 30 is mounted on the cassette mounting portion 8. When the cassette cover 6 (see FIG. 1) is closed, the platen holder 12 comes close to the cassette mounting portion 8. The platen roller 15 presses the thermal head 10 via the printing tape 57 and the ink ribbon 60. At the same time, the movable conveyance roller 14 presses the tape driving roller 46 via the printing tape 57. The control unit 20 (see FIG. 3) drives a tape drive motor (not shown) when the printing operation is executed. The ribbon drive shaft 95, the tape drive shaft 100, the movable conveyance roller 14, and the platen roller 15 are rotated by the driven tape drive motor via a plurality of gears.

  When the ribbon take-up shaft 95 rotates the ribbon take-up spool 44, the unused ink ribbon 60 is drawn from the ribbon spool 42. When the tape drive shaft 100 rotates the tape drive roller 46, the print tape 57 sandwiched between the tape drive roller 46 and the movable conveyance roller 14 is conveyed, and the unused print tape 57 is pulled out from the first tape spool 40. It is. Between the platen roller 15 and the thermal head 10, the thermal head 10 prints on the printing layer of the unused printing tape 57 using the unused ink ribbon 60. The printed printing tape 57 is conveyed to the tape discharge unit 110 and cut by a cutting mechanism 80 (see FIG. 3) as will be described later. The cut print tape 57 is discharged from the discharge port 111.

  The cutting mechanism 80 will be described. In the following description, for convenience, the upper left side, lower right side, upper right side, lower left side, upper side, and lower side of FIG. 3 are respectively referred to as the front side, rear side, left side, right side, upper side, and lower side of the cutting mechanism 80. To do. For ease of understanding, the tension spring 330 is removed from the full cut mechanism 300 in FIGS.

  As shown in FIGS. 3 and 4, the cutting mechanism 80 includes a half-cut mechanism 200, a full-cut mechanism 300, a transport mechanism 400, a cutter drive motor 90, gears 751 to 755, a drive cam 76, and the like. In the tape discharge section 110 (see FIG. 1), the full cut mechanism 300, the half cut mechanism 200, and the transport mechanism 400 are arranged in this order along the transport path of the tape. The gear 751 is attached to a drive shaft (not shown) of the cutter drive motor 90. Each of the gears 752 to 755 rotates around a shaft portion that extends forward from the support plate 730.

  As shown in FIGS. 3, 5, and 7, the drive cam 76 includes a gear 755, a cam plate 760, and a shaft portion 761. The cam plate 760 has a disk shape larger than the gear 755 and is fixed to the front side of the gear 755. The gear 755 and the cam plate 760 can rotate integrally around a shaft portion 761 extending in the front-rear direction.

  As shown in FIGS. 4, 6, and 8, the first drive pin 763 and the second drive pin 764 are provided on the cam plate 760. Each of the first drive pin 763 and the second drive pin 764 is a cylindrical body that protrudes forward from the cam plate 760. The first drive pin 763 is a shaft body for operating the half-cut mechanism 200. The second drive pin 764 is a shaft body for operating the full cut mechanism 300.

  The half cut mechanism 200 will be described. The half-cut mechanism 200 is a mechanism for cutting only a part of the tape in which a plurality of layers are laminated. As shown in FIGS. 5 to 8, the half-cut mechanism 200 includes a fixed part 210, a movable part 220, a tension spring 230, a pressing spring 240, and a restriction pin 250.

  The fixing portion 210 is a substantially L-shaped plate-like member in a front view, and includes a first plate portion 211, a second plate portion 212, and a cradle 213. The first plate portion 211 is a plate-like portion extending in the left-right direction, and is fixed to the second frame 702. The second plate portion 212 is a plate-like portion extending upward from the right end portion of the first plate portion 211. The cradle 213 is a surface portion that protrudes rearward from the left side portion of the second plate portion 212 and is parallel to the front-rear direction and the up-down direction. The cradle 213 has a rectangular shape that is long in the vertical direction and short in the front-back direction.

  The movable portion 220 is a substantially L-shaped plate-like member in rear view, and includes a first plate portion 221, a second plate portion 222, a cutting blade 223, and the like. The movable portion 220 is disposed so as to overlap the back surface of the fixed portion 210 and is disposed on the front side of the cam plate 760. The first plate portion 221 is a plate-like portion that extends substantially in the left-right direction, and extends from the back surface side of the fixed portion 210 to the front surface side of the cam plate 760. The second plate portion 222 is a plate-like portion that is inclined approximately 90 degrees with respect to the first plate portion 221 and extends upward from the left end portion of the first plate portion 221. The cutting blade 223 is a blade portion that extends along the right side portion of the second plate portion 222 and faces the cradle 213 from the left side.

  A support hole (not shown) penetrating the movable portion 220 is provided at a portion where the first plate portion 221 and the second plate portion 222 are connected. A rotating shaft 201 of the fixed portion 210 extends rearward from a portion where the first plate portion 211 and the second plate portion 212 are connected. A rotating shaft 201 extending in the front-rear direction is inserted through a support hole (not shown) of the movable portion 220 and rotatably supports the movable portion 220.

  The locking plates 225 and 227, the bent plate portions 229 and 235, the spring shaft portion 226, and the guide groove 233 are provided in the first plate portion 221. The spring shaft portion 226 extends forward from the first plate portion 221 between the second plate portion 212 and the cam plate 760 in a front view. The locking plates 225 and 227 and the bent plate portions 229 and 235 are all protruding pieces that protrude forward from the first plate portion 221. The locking plate 225 protrudes forward from the upper right end portion of the first plate portion 221. The locking plate 227 protrudes forward from the lower right side of the spring shaft portion 226. The bent plate portion 229 protrudes forward from the upper left side of the spring shaft portion 226 and from the right side of the second plate portion 212. The bending plate portion 235 protrudes forward from the lower side of the locking plate 225 and extends in a direction away from the spring shaft portion 226. The guide groove 233 is a groove portion that is recessed downward from the upper side portion of the first plate portion 221 and is recessed in an arc shape when viewed from the front.

  As shown in FIGS. 5 to 7, the restriction pin 250 is a shaft body standing on the second frame 702 on the front side of the movable portion 220. The restriction pin 250 includes a cylindrical portion 251 and a tapered portion 252. The column portion 251 has a column shape extending upward from the second frame 702. The peripheral surface of the cylindrical part 251 is close to the front side part of the bending plate part 235 in plan view. The tapered portion 252 is a tapered shape provided at the upper end portion of the cylindrical portion 251 and having a diameter decreasing upward.

  A gap forming portion 231 and an emboss 800 are provided on the second plate portion 222. The gap forming portion 231 slightly protrudes from the upper side of the cutting blade 223 toward the receiving base 213 rather than the cutting blade 223. The emboss 800 is provided at a position facing the fixed portion 210 in the second plate portion 222. The emboss 800 is a protruding portion that protrudes toward the fixed portion 210, and suppresses a gap (so-called looseness) between the movable portion 220 and the fixed portion 210.

  As shown in FIGS. 5 to 8, the pressing spring 240 is a torsion coil spring held by the first plate portion 221, and includes a coil portion 241 and a pair of arm portions 242 and 243. A spring shaft portion 226 is inserted through the shaft hole of the coil portion 241. The pair of arm portions 242 and 243 respectively extend from both ends of the coil portion 241 to the outside in the radial direction of the coil portion 241. That is, the pair of arm portions 242 and 243 are provided at positions in the front-rear direction that are separated from each other. The rear arm portion 242 has a larger protruding width from the coil portion 241 than the front arm portion 243. The tip of the arm portion 242 is locked to the locking plate 225 by urging the locking plate 225 from below. The tip of the arm portion 243 is locked to the locking plate 227 by urging the locking plate 227 from above.

  Both ends of the tension spring 230 are connected to the mounting portion 224 of the second plate portion 222 and the mounting portion 214 of the first plate portion 211. The second plate portion 222 is biased to the left by the elastic force of the tension spring 230. In a state where no external force is applied to the movable part 220, the movable part 220 rotates counterclockwise around the rotation shaft 201 as viewed from the front. When the bending plate portion 229 contacts the second plate portion 212, the rotation of the movable portion 220 is restricted. Thereby, the movable part 220 is held at the retracted position where the cutting blade 223 is separated from the cradle 213.

  The full cut mechanism 300 will be described. The full cut mechanism 300 is a mechanism for cutting all layers of a tape in which a plurality of layers are laminated. As shown in FIGS. 9 and 10, the full cut mechanism 300 includes a fixed portion 310, a movable portion 320, and a tension spring 330 (see FIG. 4).

  The fixed portion 310 is a substantially L-shaped plate member in a front view, and includes a first plate portion 311, a second plate portion 312, and a fixed blade 314. The 1st board part 311 is a plate-shaped part extended in the left-right direction, and is being fixed to the 2nd flame | frame 702 (refer FIG. 3). The second plate portion 312 is a plate-like portion extending upward from the right end portion of the first plate portion 311. The fixed blade 314 is a blade portion provided in the left side portion of the second plate portion 312 and extending in the vertical direction.

  The movable portion 320 is a substantially L-shaped plate-like member in rear view, and includes a first plate portion 321, a second plate portion 322, a movable blade 324, and the like. The movable portion 320 is disposed so as to overlap the back surface of the fixed portion 310 and is disposed on the front side of the cam plate 760. The first plate portion 321 is a plate-like portion that extends substantially in the left-right direction, and extends from the back surface side of the fixed portion 310 to the front surface side of the cam plate 760. The second plate portion 322 is a plate-like portion extending from the left end portion of the first plate portion 321 to the upper side with an inclination of approximately 90 degrees with respect to the first plate portion 321. The movable blade 324 is a blade portion that extends along the right side portion of the second plate portion 322 and faces the fixed blade 314 from the left side.

  A support hole (not shown) penetrating the fixing portion 310 is provided at a portion where the first plate portion 311 and the second plate portion 312 are connected. A support hole (not shown) penetrating the movable portion 320 is provided at a site where the first plate portion 321 and the second plate portion 322 are connected. A rotating shaft 301 extending in the front-rear direction is inserted into each support hole of the fixed portion 310 and the movable portion 320. The rotation shaft 301 is rotatably supported in a state where the fixed portion 310 and the movable portion 320 are overlapped with each other.

  A guide groove 323 and a guide hole 325 are provided in the first plate portion 321. The guide groove 323 is a groove portion that is provided on the distal end side of the first plate portion 321 and is recessed downward from the upper side portion of the first plate portion 321. The guide hole 325 is a hole that is provided substantially at the longitudinal center of the first plate portion 321 and penetrates the first plate portion 321. The guide hole 325 is a long hole extending in parallel with the longitudinal direction of the first plate portion 321. The vicinity of the left end portion of the first plate portion 321 is inclined obliquely forward toward the back surface of the fixed portion 310 (see FIG. 10).

  Both ends of the tension spring 330 (see FIG. 4) are connected to the mounting portion 313 of the first plate portion 311 and the mounting portion 329 of the second plate portion 322. The second plate portion 322 is urged to the left by the elastic force of the tension spring 330. In a state where no external force is applied to the movable part 320, the movable part 320 rotates counterclockwise around the rotation shaft 301 in a front view. As a result, the movable portion 320 is held at the retracted position where the movable blade 324 is separated from the fixed blade 314.

  The transport mechanism 400 will be described. The transport mechanism 400 is a mechanism for transporting the tape cut by the full cut mechanism 300 toward the discharge port 111 (see FIG. 1). As shown in FIGS. 9 and 10, the transport mechanism 400 includes a first link 410, a second link 420, a movable roller 430, a fixed roller 440, and the like.

  A guide member 770 (see FIG. 3) is provided along the tape transport path in the tape discharge section 110 (see FIG. 1). The guide member 770 is provided in the fixing unit 210 and has a guide surface that guides the printed tape conveyed by the tape discharge unit 110 toward the discharge port 111. The fixed roller 440 is a rotating body that is provided on the guide member 770 and is rotatable about an axis extending in the vertical direction. The fixed roller 440 is provided behind the fixed blade 314. Below the fixed roller 440, the plate-like first link 410 and the second link 420 are axially supported by the rotating shaft 401 side by side.

  A locking pin 411 that protrudes forward from the first link 410 is provided at the right end of the first link 410. An operating mechanism 412 that rotates the movable roller 430 is provided at the upper left end of the first link 410. The second link 420 is connected to the first link 410 via a connection spring 402 provided on the rotation shaft 401. A roller holder 414 is provided at the upper left end of the second link 420. The roller holder 414 rotatably supports the movable roller 430 that is a rotating body. The roller holder 414 is disposed on the right side of the operation mechanism 412. The movable roller 430 faces the fixed roller 440 from the left side. Since the structure and operation of the operation mechanism 412 and the roller holder 414 are known as described in, for example, Japanese Patent Laid-Open No. 2000-71523, description thereof is omitted.

  As the movable part 320 of the full cut mechanism 300 rotates, the locking pin 411 moves along the guide hole 325. As the locking pin 411 moves, the first link 410 rotates around the rotation shaft 401. As the first link 410 rotates, the second link 420 also rotates through the connection spring 402. As shown in FIGS. 9 and 10, when the movable portion 320 moves toward the retracted position, the locking pin 411 moves toward the left end portion of the guide hole 325. The first link 410 and the second link 420 rotate counterclockwise when viewed from the front. As a result, the second link 420 is held at the retracted position where the movable roller 430 is separated from the fixed roller 440.

  A connection structure of the cutting mechanism 80 will be described. As shown in FIG. 4, the movable part 220 of the half-cut mechanism 200 extends in the left-right direction across the movable part 320 of the full-cut mechanism 300. As shown in FIGS. 4, 6, and 10, in the left portion of the cutting mechanism 80, the fixed blade 314 of the full-cut mechanism 300, the receiving base 213 of the half-cut mechanism 200, and the fixed roller 440 of the transport mechanism 400 in this order. Line up from the back. The movable blade 324 of the full cut mechanism 300, the cutting blade 223 of the half cut mechanism 200, and the movable roller 430 of the transport mechanism 400 are arranged from the front side to the rear side.

  In the right side portion of the cutting mechanism 80, the first plate portion 221 of the half cut mechanism 200 is disposed on the front side of the first plate portion 321 of the full cut mechanism 300 and extends to the right side of the first plate portion 321. The locking pin 411 of the transport mechanism 400 is connected to the guide hole 325 of the full cut mechanism 300 on the left side of the drive cam 76.

  When the cutter drive motor 90 is not driven, the cutting mechanism 80 is in a standby state (see FIGS. 4 to 10). In the cutting mechanism 80 in the standby state, the movable parts 220 and 320 and the second link 420 are all in the retracted position. A gap between the fixed blade 314 and the movable blade 324, a gap between the cradle 213 and the cutting blade 223, and a gap between the fixed roller 440 and the movable roller 430 communicate with each other in the front-rear direction. The tape transport path in the tape discharge unit 110 (see FIG. 1) passes through these gaps communicating in the front-rear direction. The printed tape is conveyed along the fixed blade 314, the cradle 213, and the fixed roller 440.

  As shown in FIGS. 4, 6, and 10, when the cutting mechanism 80 is in the standby state, the cam plate 760 is in the reference position. When the cam plate 760 is at the reference position, the first drive pin 763 is located above the shaft portion 761. The second drive pin 764 is located on the left side of the shaft portion 761. As shown in FIGS. 5 and 6, the first drive pin 763 contacts the arm portion 242 of the pressing spring 240 locked to the locking plate 225 from above. As shown in FIGS. 9 and 10, the second drive pin 764 contacts the guide groove 323 of the first plate portion 321 from above.

  The operation mode of the cutting mechanism 80 will be described. In the following description, a case where a printed tape is cut will be exemplified. The cutting mechanism 80 starts the cutting operation from the standby state (see FIGS. 4 to 10).

  The operation mode of the half-cut mechanism 200 will be described. As shown in FIGS. 11 to 13, when the control unit 20 (see FIG. 3) causes the half-cut mechanism 200 to cut the tape, the control unit 20 rotates the cutter drive motor 90 in the forward direction (hereinafter referred to as forward rotation). When the cutter drive motor 90 rotates in the forward direction, the cam plate 760 rotates in the clockwise direction through the gears 751 to 755 (see FIGS. 3 to 5). As the cam plate 760 rotates, the first drive pin 763 rotates about the shaft portion 761 in the first operation direction (in the present embodiment, the clockwise direction when viewed from the front).

  The first drive pin 763 that rotates in the first operation direction urges the arm portion 242 downward. The arm portion 243 biases the locking plate 227 downward according to the external force applied to the arm portion 242. The movable part 220 rotates in the first operation direction about the rotation shaft 201 against the elastic force of the tension spring 230. The cutting blade 223 provided on the second plate portion 222 moves to the right side. That is, the arm portion 242 functions as a power point that receives an external force for rotating the movable portion 220. The arm portion 243 functions as an action point that urges the movable portion 220 in accordance with the external force received by the arm portion 242.

  When the cam plate 760 rotates approximately 90 degrees in the first operation direction from the reference position, the movable part 220 moves from the retracted position to the cutting position. The cutting position is a position where the cutting blade 223 is close to the cradle 213. When the movable part 220 is in the cutting position, the gap forming part 231 contacts the cradle 213 and the rotation of the movable part 220 is restricted. A gap narrower than the thickness of the tape (specifically, a gap substantially equal to the thickness of the print layer) is formed between the cutting blade 223 and the cradle 213. The rotational position of the cam plate 760 that moves the movable part 220 to the cutting position is referred to as a first rotational position.

  When the movable part 220 moves from the retracted position to the cutting position, the bending plate part 235 moves downward through the rear side of the regulation pin 250. At this time, the movable portion 220 may be inclined from an appropriate posture due to a gap (so-called looseness) between the fixed portion 210 and the movable portion 220. In this case, the bending plate portion 235 contacts the tapered portion 252 and is guided toward the cylindrical portion 251 along the inclined surface of the tapered portion 252. Thereby, since the movable part 220 rotates to a cutting position with a proper attitude | position, the cutting blade 223 adjoins perpendicularly with respect to the receiving stand 213. FIG.

  When the cam plate 760 rotates to the first rotation position, the control unit 20 further rotates the cutter drive motor 90 forward by a predetermined amount. The first drive pin 763 that rotates in the first operation direction further biases the arm portion 242 downward. Since the rotation of the movable portion 220 is restricted, the pressing spring 240 is elastically deformed by the urging force applied to the arm portion 242. The arm portion 242 bends downward and is separated from the locking plate 225.

  In the present embodiment, the force point (arm portion 242) and the action point (arm portion 243) of the pressing spring 240 are at different positions in the front-rear direction. The pressing spring 240 that is elastically deformed as described above generates a biasing force that includes a vector component different from the first operating direction. For example, the vector component different from the first operation direction acts in the direction from the arm portion 242 toward the arm portion 243 (in the present embodiment, the lower front side). Due to this vector component, the movable part 220 at the cutting position may move forward along the spring shaft part 226. That is, the posture and position of the cutting blade 223 at a position close to the cradle 213 may change.

  When the movable part 220 is in the cutting position, the cylindrical part 251 of the restriction pin 250 faces the bending plate part 235. When the movable part 220 moves in the forward direction due to the elastic deformation of the pressing spring 240, the bending plate part 235 comes into contact with the cylindrical part 251, so that the forward movement of the movable part 220 is restricted. Accordingly, even when the pressing spring 240 is elastically deformed, the cutting blade 223 located in the vicinity of the cradle 213 is maintained in an appropriate posture and position.

  The distance from the rotation shaft 201 to the first drive pin 763 is substantially equal to the distance from the rotation shaft 201 to the restriction pin 250. When the movable part 220 is in the cutting position, the first drive pin 763 and the regulation pin 250 are arranged in the front-rear direction in plan view (see line Q in FIG. 12). That is, the restriction pin 250 faces the front side of the first drive pin 763 that presses the arm portion 242. Thereby, the regulation pin 250 can reliably regulate the movement of the movable part 220 in the forward direction on the vector direction side in which the movable part 220 is moved in the forward direction.

  As shown in FIG. 14, the first drive pin 763 that rotates in the first operation direction slides from the right end portion to the left end portion of the guide groove 233 while bending the arm portion 242 downward. The rotational position of the cam plate 760 that slides the first drive pin 763 to the left end of the guide groove 233 is referred to as a second rotational position. When the cam plate 760 rotates to the second rotation position, the first drive pin 763 contacts the wall portion 233A that forms the left end portion of the guide groove 233. When the cam plate 760 rotates to the second rotation position, the control unit 20 stops driving the cutter drive motor 90 for a predetermined time.

  When the cam plate 760 is in the second rotation position, the urging force of the arm portion 242 acts upward. The direction in which the urging force of the arm portion 242 acts is substantially parallel to the perpendicular P extending from the first drive pin 763 to the arm portion 242. The action of rotating the first drive pin 763 in the first operation direction is exerted by the urging force of the arm portion 242. The first drive pin 763 is restricted from moving in the first operation direction by the wall portion 233A. As a result, the arm portion 242 biases the first drive pin 763 toward the wall portion 233A, so that the movement of the first drive pin 763 (that is, rotation of the cam plate 760) is restricted. Even when the drive of the cutter drive motor 90 is stopped, the state where the cutting blade 223 is close to the cradle 213 is maintained.

  With the above operation, the printed tape is cut as follows. The cutting blade 223 approaches the cradle 213 as the cam plate 760 rotates from the reference position to the first rotation position. The tape transported to the tape discharge unit 110 (see FIG. 1) is pressed against the cradle 213 by the cutting blade 223, and is disposed in the gap between the cutting blade 223 and the cradle 213. While the cam plate 760 rotates from the first rotation position to the second rotation position and while the cam plate 760 is held at the second rotation position, the cutting blade 223 strongly biases the tape toward the cradle 213. A part of the tape (specifically, a release layer) is cut by the cutting blade 223.

  Thereafter, the control unit 20 rotates the cutter driving motor 90 in the reverse direction (hereinafter, reversed). When the cutter drive motor 90 is reversed, the cam plate 760 is rotated in the second operation direction through the gears 751 to 755 in the front view (in the present embodiment, the counterclockwise direction in the front view). As the cam plate 760 rotates, the first drive pin 763 rotates about the shaft portion 761 in the second operation direction. The first drive pin 763 slides from the left end portion of the guide groove 233 toward the right end portion. The arm portion 242 moves elastically so as to lift the first drive pin 763 and is locked to the locking plate 225. That is, the cam plate 760 rotates from the second rotation position (see FIG. 14) to the first rotation position (see FIGS. 11 to 13).

  Further, the control unit 20 reverses the cutter drive motor 90 until the cam plate 760 rotates from the first rotation position (see FIGS. 11 to 13) to the reference position (see FIGS. 4, 6, and 10). The movable portion 220 rotates in the second operation direction about the rotation shaft 201 by the elastic force of the tension spring 230. The cutting blade 223 provided on the second plate portion 222 moves to the left side. The movable part 220 moves from the cutting position to the retracted position. With the above operation, the cutting mechanism 80 returns to the standby state. Thereafter, the control unit 20 drives a tape drive motor (not shown) by a predetermined amount. Thereby, the tape from which the release layer has been cut is conveyed toward the discharge port 111.

  The operation modes of the full cut mechanism 300 and the transport mechanism 400 will be described. When the full cut mechanism 300 cuts the tape, the control unit 20 reverses the cutter drive motor 90 and rotates the cam plate 760 from the reference position in the second operation direction.

  As shown in FIG. 15, the second drive pin 764 that rotates in the second operation direction urges the first plate portion 321 downward in the guide groove 323. As the first plate portion 321 moves downward, the movable portion 320 rotates in the first operation direction about the rotation shaft 301 against the elastic force of the tension spring 330. When the cam plate 760 rotates approximately 45 degrees from the reference position in the second operation direction, the movable portion 320 moves from the retracted position to the cutting position. The cutting position is a position where the movable blade 324 intersects the fixed blade 314. The rotational position of the cam plate 760 that moves the movable part 320 to the cutting position is referred to as a third rotational position.

  As the cam plate 760 rotates from the reference position to the third rotation position, the locking pin 411 of the first link 410 moves toward the right end of the guide hole 325. As the locking pin 411 moves, the first link 410 rotates about the rotation shaft 401 in the first operation direction. The second link 420 also rotates in conjunction with the first link 410 via the connection spring 402 (see FIG. 10). As a result, the second link 420 moves from the retracted position to the transport position. When the second link 420 is in the transport position, the movable roller 430 is urged against the fixed roller 440 (see FIG. 9). As the first link 410 rotates, the operating mechanism 412 rotates the movable roller 430 half a turn.

  With the above operation, the printed tape is cut as follows. As the cam plate 760 rotates from the reference position to the third rotation position, the movable roller 430 presses the tape conveyed to the tape discharge unit 110 (see FIG. 1) against the fixed roller 440. All layers of the tape sandwiched between the movable roller 430 and the fixed roller 440 are cut between the movable blade 324 and the fixed blade 314. At this time, the operating mechanism 412 adjacent to the movable roller 430 causes the movable roller 430 to rotate half a turn. The cut tape is conveyed toward the discharge port 111 by a distance corresponding to a half rotation of the movable roller 430.

  Thereafter, the control unit 20 rotates the cutter drive motor 90 in the forward direction to rotate the cam plate 760 from the third rotation position to the reference position. Due to the elastic force of the tension spring 330, the movable part 320 rotates around the rotation shaft 301 in the second operation direction. The movable part 320 moves from the cutting position to the retracted position. With the rotation of the movable portion 320, the locking pin 411 moves toward the left end portion of the guide hole 325, and the first link 410 and the second link 420 rotate about the rotation shaft 401 in the second operation direction. . The second link 420 moves from the transport position to the retracted position.

  At this time, with the rotation of the first link 410, the operating mechanism 412 rotates the movable roller 430 by half. As a result, before the movable roller 430 moves away from the fixed roller 440, the movable roller 430 rotates halfway while energizing the fixed roller 440. The cut tape is conveyed toward the discharge port 111 by a distance corresponding to a half rotation of the movable roller 430. With the above operation, the cutting mechanism 80 returns to the standby state.

  As described above, according to the cutting mechanism 80 of the present embodiment, the movable part 220 having the cutting blade 223 is centered on the rotation shaft 201 so that the cutting blade 223 is close to or separated from the cradle 213. It can be rotated. The pressing spring 240 provided on the movable portion 220 has a force point (arm portion 242) and an action point (arm portion 243) at different positions in the axial direction of the rotating shafts 201 (in this embodiment, the front-rear direction position). . When the arm portion 242 receives an external force acting in a predetermined direction (downward in the present embodiment), the arm portion 243 applies an urging force in the first operation direction to the movable portion 220, and the cutting blade 223 receives the cradle. Move in the direction closer to 213. A restriction pin 250 that restricts the movement of the movable portion 220 in the axial direction (front side in the present embodiment) when elastic deformation of the pressing spring 240 occurs is provided on the axial direction side with respect to the movable portion 220.

  Therefore, when the tape is cut, the movement of the movable portion 220 in the axial direction of the rotation shaft 201 is restricted by the restriction pin 250. Since the posture and position of the cutting blade 223 close to the cradle 213 are stable, the tape can be cut stably. Since the cutting blade 223 is suppressed from being pressed against the tape in a direction different from an appropriate cutting direction, wear deterioration of the cutting blade 223 can be suppressed. Since the posture and position of the cutting blade 223 are stabilized, the gap between the cutting blade 223 and the cradle 213 at the time of cutting the tape can be made constant, so that the tape can be cut accurately.

  When the elastic deformation of the pressing spring 240 occurs, the arm part 242 moves away from the locking plate 225 of the movable part 220. Thereby, since the urging | biasing force to the axial direction side produced at the time of the elastic deformation of the press spring 240 is suppressed, the load which the movable part 220 provides to the regulation pin 250 can be suppressed. Since the arm portion 242 can be easily attached to and detached from the locking plate 225, the manufacturing operation for assembling the pressing spring 240 to the movable portion 220 is facilitated.

  At least a part of the restriction pin 250 is a cylindrical portion 251 that contacts the movable portion 220 when the elastic deformation of the pressing spring 240 occurs. When the pressing spring 240 is elastically deformed, the movable portion 220 contacts the outer peripheral surface of the cylindrical portion 251 at a single point in plan view, so that the contact area between the cylindrical portion 251 and the movable portion 220 is small. Therefore, when the pressing spring 240 is elastically deformed, the movement of the movable portion 220 is restricted with a smaller contact area, and therefore the movable portion 220 can be held in an accurate posture and position.

  An end portion (upper end portion in this embodiment) of the restriction pin 250 in the second operation direction is a tapered portion 252 whose diameter gradually decreases in the upward direction. When the movable portion 220 rotates in the first operation direction, the tapered portion 252 faces the movable portion 220 before the elastic deformation of the pressing spring 240 occurs. Thereby, before the elastic deformation of the pressing spring 240 occurs, the movable part 220 rotating in the first operation direction can be guided toward the cylindrical part 251.

  The fixed portion 210 is a member provided with a cradle 213 and is fixed to the movable portion 220 side by side in the axial direction of the rotation shaft 201. The emboss 800 is provided at a position facing the fixed portion 210 in the movable portion 220 and protrudes toward the fixed portion 210. Thereby, the gap (so-called looseness) between the movable part 220 and the fixed part 210 can be suppressed, and the posture and position of the movable part 220 rotating in the first operation direction can be stabilized.

  The first drive pin 763 applies an external force acting in a predetermined direction to the movable portion 220 by pressing the pressing spring 240. When the movable part 220 rotates in the first operation direction to the second rotation position, the pressing spring 240 is elastically deformed according to the external force. The distance from the rotation shaft 201 to the first drive pin 763 is substantially equal to the distance from the rotation shaft 201 to the restriction pin 250. Thereby, the restriction pin 250 can reliably restrict the movement of the movable part 220 on the vector direction side in which the movable part 220 is moved in the axial direction side.

  When the cutting blade 223 comes close to the cradle 213, the gap forming portion 231 forms a gap between the cutting blade 223 and the cradle 213 that is substantially equal to the thickness of some layers included in the tape. The pressing spring 240 holds the position of the first drive pin 763 in a state where a gap is formed by the gap forming portion 231. Thereby, even if the drive of the cutter drive motor 90 stops, the state where the cutting blade 223 is close to the cradle 213 can be maintained.

  The first drive pin 763 presses the pressing spring 240 in conjunction with the forward rotation of the cutter drive motor 90. Thus, the tape can be cut by driving the cutter drive motor 90 so that the cutting blade 223 comes close to the cradle 213.

  The second drive pin 764 presses the movable portion 320 in conjunction with the reversal of the cutter drive motor 90, thereby applying an urging force that acts in the direction in which the movable blade 324 is brought close to the fixed blade 314 to the movable portion 320. Thereby, the tape half cut and full cut can be selectively executed by the drive control of one cutter driving motor 90.

  In the printing apparatus 1 of the present embodiment, the tape is printed by the printing mechanism 71 and supplied to the cutting mechanism 80. Therefore, the printed tape can be stably cut after the tape is printed.

  In the above embodiment, the cutting mechanism 80 is an example of the “cutting device” of the present invention. The cradle 213 is an example of the “fixing member” in the present invention. The cutting blade 223 is an example of the “cutting blade” in the present invention. The movable portion 220 is an example of the “first movable member” in the present invention. The pressing spring 240 is an example of the “elastic member” in the present invention. The regulation pin 250 is an example of the “regulation member” in the present invention. The fixing portion 210 is an example of the “installation member” in the present invention. The embossing 800 is an example of the “projection” in the present invention. The first drive pin 763 is an example of the “first pressing member” in the present invention. The gap forming portion 231 is an example of the “gap forming means” in the present invention. The cutter drive motor 90 is an example of the “rotation drive unit” in the present invention. The movable part 320 is an example of the “second movable member” in the present invention. The second drive pin 764 is an example of the “second pressing member” in the present invention. The printing mechanism 71 is an example of the “printing unit” and the “supply unit” in the present invention.

  The present invention is not limited to the above embodiment, and various modifications can be made. The cutting mechanism 80 does not need to be provided in the printing apparatus 1. The cutting mechanism 80 may be a device that can be used alone, or may be a part of another device that uses a tape in which a plurality of layers are laminated. The cutting mechanism 80 is not limited to a mode driven by the cutter drive motor 90, and may be a mode in which the tape is cut by a user's manual operation.

  The pressing spring 240 may be another elastic member (for example, a leaf spring, elastic rubber, etc.). The full cut mechanism 300 may be provided with a pressing spring 240 and a restriction pin 250. Thereby, like the half-cut mechanism 200 of the said embodiment, the movement of the movable part 320 is controlled at the time of a full cut of a tape, and a tape can be stably fully cut.

  As shown in FIG. 16, the modified locking plate 225 is a wall portion that is in contact with the power point (arm portion 242) of the pressing spring 240 and extends in the vertical direction. The modified locking plate 225 is a guide wall that guides the force point (arm portion 242) that moves in accordance with the elastic deformation of the pressing spring 240 downward. According to this, according to the elastic deformation of the pressing spring 240, the movable part 220 can be rotated in an appropriate posture. By the pressing spring 240 that is elastically deformed when the tape is cut, a vector component as designed in advance is applied to the movable portion 220. Therefore, the cutting mechanism 80 can be easily designed and manufactured.

  The shape, total length, diameter, position, and the like of the restriction pin 250 can be changed. For example, the cylindrical portion 251 of the restriction pin 250 may be provided at a position facing the movable portion 220 at least when the pressing spring 240 is elastically deformed. Instead of the cylindrical portion 251, a prismatic portion or a conical portion may be provided.

DESCRIPTION OF SYMBOLS 1 Printing apparatus 57 Printing tape 71 Printing mechanism 80 Cutting mechanism 90 Cutter drive motor 200 Half cut mechanism 201 Rotating shaft 210 Fixed part 213 Receiving base 220 Movable part 223 Cutting blade 231 Gap formation part 240 Pressing spring 242 Arm part 243 Arm part 250 Restriction Pin 251 Cylindrical portion 252 Tapered portion 300 Full cut mechanism 301 Rotating shaft 314 Fixed blade 320 Movable portion 324 Movable blade 763 First drive pin 764 Second drive pin 800 Emboss

Claims (11)

A fixing member provided at a position facing the conveyed tape;
A first movable member having a cutting blade capable of cutting the tape between the fixed member and rotatable about a predetermined rotation axis so that the cutting blade is close to or separated from the fixed member When,
The elastic member provided in the first movable member, having a force point and an action point at different axial positions of the rotation shaft, and receiving an external force acting in a predetermined direction at the force point In addition, an elastic member that applies a biasing force in a first direction, which is a rotation direction of the first movable member, that brings the cutting blade close to the fixed member to the first movable member at the point of action;
A restriction member provided on the axial direction side with respect to the first movable member, and restricting movement of the first movable member in the axial direction when elastic deformation of the elastic member occurs. Cutting device characterized.   The cutting apparatus according to claim 1, wherein the elastic member is separated from the first movable member when the elastic member is elastically deformed.   The said 1st movable member is a wall part which contacts the said power point, Comprising: The guide wall which guides the said power point which moves according to the elastic deformation of the said elastic member is provided. Cutting device.   4. The cutting device according to claim 1, wherein at least a part of the restricting member is a columnar portion that contacts the first movable member when elastic deformation of the elastic member occurs. . In the regulating member, the end in the second direction, which is the rotational direction of the first movable member that separates the cutting blade from the fixed member, is a tapered portion whose diameter gradually decreases in the second direction,
The taper portion faces the first movable member before elastic deformation of the elastic member occurs when the first movable member rotates in the first direction. A cutting device according to any of the above. A member provided with the fixing member, and an installation member fixed side by side in the axial direction with respect to the first movable member;
The cutting apparatus according to any one of claims 1 to 5, further comprising: a protruding portion that is provided at a position facing the installation member in the first movable member and protrudes toward the installation member. A first pressing member that applies the external force to the first movable member by pressing the elastic member;
The elastic member is elastically deformed according to the external force when the first movable member rotates in the first direction to a predetermined position,
The cutting device according to any one of claims 1 to 6, wherein a distance from the rotation shaft to the first pressing member is substantially equal to a distance from the rotation shaft to a regulating member. When the cutting blade is close to the fixing member, the cutting blade includes a gap forming means for forming a gap substantially equal to the thickness of a part of the layers included in the tape between the cutting blade and the fixing member,
The cutting apparatus according to claim 7, wherein the elastic member holds a position of the first pressing member in a state where the gap is formed by the gap forming unit. A rotation drive means rotatable in the first rotation direction;
The cutting apparatus according to claim 7 or 8, wherein the first pressing member presses the elastic member in conjunction with the rotation of the rotation driving unit in the first rotation direction. A fixed blade,
A second movable member having a movable blade capable of cutting the tape between the fixed blade and being rotatable about a rotation axis so that the movable blade is close to or spaced from the fixed blade;
A second pressing member that applies an urging force acting on the second movable member in a direction in which the movable blade is brought close to the fixed blade by pressing the second movable member;
The rotation driving means is rotatable in a second rotation direction which is opposite to the first rotation direction;
The cutting apparatus according to claim 9, wherein the second pressing member presses the second movable member in conjunction with rotation of the rotation driving unit in the second rotation direction. A cutting device according to any one of claims 1 to 10,
Printing means for printing on the tape;
A printing device comprising: a supply device that supplies the tape printed by the printing device to the cutting device.

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