JP4962154B2 - Media delivery mechanism and media processing apparatus having the same - Google Patents

Description

  The present invention relates to a media delivery mechanism for delivering a disc-shaped medium such as a CD or a DVD, and a media processing apparatus including the media delivery mechanism.

  In recent years, a disk dubbing device that writes data to a large number of media (information recording media) such as blank CDs (Compact Discs) and DVDs (Digital Versatile Discs), and media production by performing data writing and label printing Media processing devices such as CD / DVD publishers that can be issued are being used. As this type of media processing apparatus, there are known a drive that writes data to the media, a printer that prints on the label surface of the media, and a media transport mechanism that holds and transports the media to these drives and printers. ing. In addition, there is also a media receiving mechanism that receives the media transported by the media transport mechanism and transports it to a processing unit such as label printing (for example, see Patent Document 1).

International Publication No. 2002/65471 Pamphlet

  The media receiving mechanism described in Patent Document 1 holds the outer periphery of a medium from the outside in the radial direction, and is mainly used for a media transport tray of a printer. In the case of this outer periphery holding method, the method of sandwiching the media with one fixed claw and one working claw is common, but since the outer diameter size variation of the media is large, the center deviation of this variation between the media and the print result is Will occur. In addition, the outer peripheral portion of the media may swell in a circular arc shape so that the central portion in the thickness direction has a larger diameter than the vicinity of both surfaces. Therefore, as described above, if the media receiving mechanism holds the outer peripheral portion of the media from the outside in the radial direction, the position of the media after the holding is not stable, and subsequent label surface printing is performed in the unstable state. When performed, there is a possibility of adverse effects such as media misalignment and dropout.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a media delivery mechanism capable of holding a media in a stable position with high accuracy after delivery, and a media processing apparatus including the media delivery mechanism.

  In the media delivery mechanism according to the present invention that can solve the above-mentioned problems, at least three transport-side holding claws are inserted into the center hole of the medium to be held, and the transport-side holding claws are expanded in the radial direction, respectively. By pressing against the inner peripheral surface of the center hole, the media transport mechanism that holds the media and at least three receiving side holding claws are held in the transport side holding hole in the center hole of the media held by the transport side holding claws. A medium receiving mechanism for holding the medium by inserting the receiving side holding claws in a different direction from the claws and pressing the receiving side holding claws in the radial direction and pressing them against the inner peripheral surface of the center hole; .

  According to the media delivery mechanism having this configuration, the media transport mechanism inserts at least three transport-side holding claws into the center hole of the medium to be held, and widens the transport-side holding claws in the radial direction so that the inside of the center hole By pressing against the peripheral surface, the medium is transported to the media receiving mechanism while being held. Then, the media receiving mechanism inserts at least three receiving side holding claws into the center hole of the media held by the conveying side holding claws at a phase different from that of the conveying side holding claws, and receives the media. The media is held by spreading the claws in the radial direction and pressing the claws against the inner peripheral surface of the center hole. As described above, the transport side holding claw of the media transport mechanism can transport to the position where the media receiving mechanism holds the inner peripheral surface of the central hole of the media while holding the inner peripheral surface of the central hole of the media. Therefore, the medium can be held in a stable position without any center deviation after the delivery is performed reliably. Therefore, when subsequent processing is performed in the held state, the processing can be performed with high accuracy and high reliability. Moreover, the media receiving mechanism receives media by inserting at least three receiving side holding claws into the center hole of the media held by the conveying side holding claws of the media conveying mechanism at a phase different from that of the conveying side holding claws. Thus, it is possible to reliably deliver the media from the media transport mechanism to the media receiving mechanism without interference between the transport side holding claws and the receiving side holding claws.

In the media delivery mechanism according to the present invention, when the receiving side holding claw is inserted into a center hole of the media held by the transport side holding claw and receives the media, the receiving side holding claw and the transport side holding claw It is preferable that a nail | claw overlaps with the axial direction of the said center hole.
According to this configuration, since the receiving side holding claw overlaps with the conveying side holding claw, it is possible to more reliably deliver the media from the media conveying mechanism to the media receiving mechanism.

The media processing apparatus according to the present invention includes the media delivery mechanism according to the present invention and a media processing unit that performs information processing on the media, and the media receiving mechanism of the media delivery mechanism is configured to perform the media processing. Provided in the department.
According to the media processing device having this configuration, the media processing unit can stably hold the media delivered from the media transport mechanism, so that it can be a processing device with high processing reliability.

Embodiments of a media delivery mechanism and a media processing apparatus according to the present invention will be described below with reference to the drawings.
In the present embodiment, a disk publisher as a media processing apparatus will be described as an example.
FIG. 1 is an external perspective view of a publisher (media processing apparatus) with each part closed, FIG. 2 is an external perspective view of the publisher with each part open, and FIG. 3 is a front top view of the publisher with the case removed. 4 is a perspective view of a label printer portion installed in the publisher, and FIG. 5 is a perspective view of a mechanism portion of the label printer installed in the publisher.

  As shown in FIG. 1, a publisher 1 is a media processing apparatus that writes data on a disk-shaped medium (information storage medium) such as a CD or DVD and prints on the label side of the medium. A case 2 having a shape is provided. Opening and closing doors 3 and 4 that can be opened and closed to the left and right are attached to the front surface of the case 2. An operation surface 5 on which display lamps, operation buttons, and the like are arranged is provided at the upper left end portion of the case 2, and a mounting leg portion 6 is provided at the lower end of the case 2 so as to protrude downward. Are provided on both the left and right sides. A drawer mechanism 7 is provided at a position between the left and right legs 6.

As shown in FIG. 2, the open / close door 3 on the right side of the front view opens and closes the opening 8 on the front side of the publisher 1. Alternatively, it is a door that opens and closes when the created medium M is taken out through the opening 8.
The opening / closing door 4 on the left side when viewed from the front is for opening and closing when the ink cartridge 12 of the label printer 11 shown in FIG. 3 is replaced. When the opening / closing door 4 is opened, a plurality of cartridges arranged in the vertical direction are opened. The cartridge mounting portion 14 having the holder 13 is exposed.

  As shown in FIG. 2 and FIG. 3, inside the case 2 of the publisher 1 is a media storage unit capable of stacking a plurality of unused media M (for example, 50) that have not been subjected to data write processing. The central axis of the media M that stores the media stacker 21 and the media stacker 22 as a media storage unit that stores a plurality of unused media M (for example, 50) or created media M is the same. Are arranged above and below. Each of the media stacker 21 and the media stacker 22 is detachable from a predetermined position.

  The upper media stacker 21 is provided with a pair of left and right arc-shaped frame plates 24 and 25, thereby allowing the media M to be received from the upper side and accommodated in a coaxially stacked state. The operation of accommodating or replenishing the media M in the media stacker 21 can be easily performed by opening the door 3 and taking out the media stacker 21.

  The lower media stacker 22 has the same structure as the media stacker 21 and includes a pair of left and right arc-shaped frame plates 27 and 28. This allows the media M to be received from above and accommodated in a coaxially stacked state. A simple stacker is configured.

  As shown in FIG. 3, a media transport mechanism 31 is disposed behind the media stacker 21 and the media stacker 22. The media transport mechanism 31 has a vertical guide shaft 35 that is vertically spanned between the main body frame 30 and the top plate 33 of the chassis 32. A transport arm 36 is supported on the vertical guide shaft 35 in a state where it can be raised and lowered and turned. The transport arm 36 can be moved up and down along the vertical guide shaft 35 by a drive motor 37 and can be swung left and right about the vertical guide shaft 35.

Two media drives 41 stacked one above the other are disposed in the rear side of the upper and lower stackers 21 and 22 and the media transport mechanism 31, and a carriage (described later) of the label printer 11 is disposed below these media drives 41. 62 is movably arranged.
The media drive 41 has media trays 41a that can move between a data writing position on the media M and a media delivery position for receiving and delivering the media M, respectively.

  Further, the label printer 11 has a media tray 45 that is movable between a print position where label printing can be performed on the label surface of the medium M and a medium delivery position where the medium M is received and delivered.

  FIG. 3 shows a state in which the media tray 41a of the upper and lower media drives 41 is pulled out to the front and is in the media delivery position, and a state in which the media tray 45 of the lower label printer 11 is in the media delivery position on the front side. Yes. The label printer 11 is an ink jet printer, and ink cartridges 12 of various colors (black, cyan, magenta, yellow, light cyan, and light magenta in this embodiment) are used as the ink supply mechanism 60, and these ink cartridges. 12 is mounted on each cartridge holder 13 of the cartridge mounting section 14 from the front.

  Here, a gap is formed between the pair of left and right frame plates 24 and 25 of the media stacker 21 and between the pair of left and right frame plates 27 and 28 of the media stacker 22 so that the transport arm 36 of the media transport mechanism 31 can move up and down. Has been. Further, a gap is opened between the upper and lower media stackers 21 and the media stacker 22 so that the transport arm 36 of the media transport mechanism 31 pivots horizontally and can be positioned directly above the media stacker 22. Further, when both the media trays 41a are pushed into the media drive 41, the transport arm 36 of the media transport mechanism 31 is lowered to access the media tray 45 at the media delivery position.

  The transport arm 36 of the media transport mechanism 31 is further below the height position of the media tray 45 with both media trays 41a positioned at the data writing position and the media tray 45 positioned at the back printing position. It is possible to descend to. Below the media delivery position of the media tray 45, there is a guide hole 65 (see FIG. 2) through which the media M released by the transport arm 36 descending to this position passes. A guide hole 65 in which the stacker is mounted is formed.

  As shown in FIGS. 2 and 3, the drawer mechanism 7 has a drawer tray 70 that can be pulled out of the main body frame 30 to be opened and housed and closed under the main body frame 30. . The drawer tray 70 is provided with a stacker portion 71 that is recessed downward. When the drawer tray 70 is in the storage position (closed position), the stacker unit 71 is positioned below the guide hole 65, and the center of the stacker unit 71 is the center of the media tray 41a and the media tray 45 at the delivery position. The axes are positioned so as to be the same. The stacker unit 71 receives the medium M inserted through the guide hole 65 and accommodates the medium M in a relatively small amount (for example, about 5 to 10 sheets). The stacker unit 71 can receive the medium M from above and can be accommodated in a state of being stacked coaxially.

  A media stacker (separate stacker) 72 having a larger amount of media M than the stacker unit 71 is detachable from the stacker unit 71 and the guide hole 65 of the drawer tray 70 in the stored state (see FIG. 3). . The media stacker 72 also includes a pair of arc-shaped frame plates 73 and 74, which allows the media M to be received from above and accommodate a plurality of sheets (for example, 50 sheets) in a coaxially stacked state. . A gap is formed between the pair of arcuate frame plates 73 and 74 so that the transport arm 36 of the media transport mechanism 31 can be moved up and down. In addition, a handle 75 that is gripped by the user at the time of attachment / detachment is provided on the upper portion of one frame plate 74.

If the media stacker 72 is attached, the unused media M is taken out from the lower media stacker 22, recorded and printed by the media drive 41 and the label printer 11, and then stored in the media stacker 72. can do.
Also, for example, the upper media stacker 21 and the lower media stacker 22 are loaded with the maximum number of unused media M (50 sheets + 50 sheets), respectively, and the total number of lower media stackers 22 (50 sheets). ) Media M are sequentially processed and accommodated in the media stacker 72. Next, the entire media stacker 21 of the upper media stacker 21 (50 sheets) is sequentially processed to form an empty lower media stacker 22 To house. In this way, the maximum number of sheets (50 + 50 sheets) of media M in the upper media stacker 21 and the lower media stacker 22 is processed at once (batch processing mode).

  Further, if the media stacker 72 is removed, the unused media M is taken out from the upper media stacker 21 or the lower media stacker 22, and data recording and printing are performed by the media drive 41 and the label printer 11. It can be accommodated in the stacker portion 71 of the drawer tray 70 in the accommodated state.

  As a result, the completed medium M can be taken out of the stacker unit 71 by pulling out the drawer tray 70. That is, even during processing on the medium M, it is possible to take out one sheet or a plurality of sheets at a time from the completed medium M with the open / close door 3 closed (external discharge mode).

  Here, by the combined operation of raising and lowering the transport arm 36 of the media transport mechanism 31 and turning to the left and right, the media M includes the media stacker 21, the media stacker 22, the stacker unit 71 (or the media stacker 72) of the drawer tray 70, It is appropriately conveyed between the media tray 41a of the media drive 41 and the media tray 45 of the label printer 11.

  As shown in FIG. 4, the label printer 11 is provided with a carriage 62 having an ink jet head 61 provided with ink ejection nozzles (not shown). The carriage 62 is moved to the carriage guide shaft by the driving force of the carriage motor. And reciprocates horizontally (not shown).

  The label printer 11 includes an ink supply mechanism 60 having a cartridge mounting portion 14 in which the ink cartridge 12 is mounted. The ink supply mechanism 60 has a vertical structure and is erected on the main body frame 30 of the publisher 1 and arranged in the vertical direction. One end of a flexible ink supply tube 63 is connected to the ink supply mechanism 60, and the other end of the ink supply tube 63 is connected to a carriage 62.

The ink in the ink cartridge 12 mounted on the ink supply mechanism 60 is supplied to the carriage 62 via the ink supply tube 63, and passes through a damper unit and a back pressure adjustment unit (not shown) provided on the carriage 62. The ink is supplied to the inkjet head 61 and discharged from an ink nozzle (not shown).
The ink supply mechanism 60 is provided with a pressurizing mechanism 64 so as to dispose a main portion on the upper portion thereof. The pressurizing mechanism 64 pressurizes the inside of the ink cartridge 12 by sending out compressed air so that the ink is supplied. The ink stored in the ink pack in the cartridge 12 is sent out.

A head maintenance mechanism 81 is provided on the lower side of the carriage 62 at the home position (position shown in FIG. 4).
The head maintenance mechanism 81 includes a head cap 82 that covers the ink nozzles of the inkjet head 61 exposed on the lower surface of the carriage 62 disposed at the home position, and is discharged to the head cap 82 by a head cleaning operation and an ink filling operation of the inkjet head 61. And a waste ink suction pump 83 for sucking the discharged ink.

The ink sucked by the waste ink suction pump 83 of the head maintenance mechanism 81 is sent to the waste ink absorption tank 85 through the tube 84.
The waste ink absorption tank 85 has an absorbent material (not shown) disposed in a case 86, and the upper surface thereof is covered with a cover 88 having a plurality of vent holes 87.
Below the head maintenance mechanism 81, a waste ink receiving portion 89, which is a part of the waste ink absorption tank 85, is provided to receive the ink dropped from the head maintenance mechanism 81 and absorb it by the absorbent material. Yes.

  As shown in FIG. 5, the inkjet head 61 mounted on the carriage 62 has a nozzle surface facing downward, and the media tray 45 can reciprocate horizontally in the front-rear direction at the lower position of the inkjet head 61. It has become. The media tray 45 has a right end supported by a guide shaft 302 extending horizontally in the front-rear direction, and a left end supported by a guide rail 303 extending horizontally in the front-rear direction in a slidable state. . The drive mechanism of the media tray 45 is also configured to include a timing belt 304 that extends horizontally in the front-rear direction and a tray motor 305 for driving the timing belt 304. The media tray 45 includes, on the upper surface of a rectangular plate, a low circular convex portion 45a that is in contact with the outer peripheral end surface of the media and restricts the movement of the media.

Next, a belt driving mechanism that moves the media tray 51 will be described.
FIG. 6 is a schematic plan view of the belt drive mechanism.
The media tray 45 moved by the belt driving mechanism 310 has a guide shaft 302 extending horizontally in the front-rear direction of the apparatus passing through a slide bearing 311 provided on one side thereof, and provided on the other side. A slide piece 313 is slidably mounted on a guide rail 303 extending in the front-rear direction of the apparatus. Thereby, the media tray 45 is supported by the guide shaft 302 and the guide rail 303 so as to be slidable in the front-rear direction of the apparatus.

The guide shaft 302 is disposed at intervals along a frame 315 disposed in the front-rear direction of the apparatus, and both ends thereof are fixed to fixing plates 316 provided at both ends of the frame 315.
In the frame 315, a drive pulley 321 is rotatably provided in the vicinity of the end portion on the rear side of the apparatus, and a driven pulley 322 is rotatably provided in the vicinity of the end portion on the front side of the apparatus. A timing belt 304 is wound around the driving pulley 321 and the driven pulley 322, and one side portion of the media tray 45 is fixed to the timing belt 304 by a belt clamp 324. As a result, the media tray 45 is slid in the running direction when the timing belt 304 is run.

  An encode plate 332 and a transmission pulley 333 are fixed to the rotation shaft 331 of the drive pulley 321. A tray motor 305 is provided below the frame 315, and a rotation pulley 336 is provided on the drive shaft 335 of the tray motor 305. A transmission belt 327 is wound around the transmission pulley 333 and the rotary pulley 336.

  A plurality of position detection slits are formed at equal intervals along the periphery of the encode plate 332, and a position detector (not shown) detects the position detection slits of the encode plate 332. . The position of the media tray 45 can be detected based on the detection signal from the position detector.

  In the belt drive mechanism 310, when the drive current having the current value determined based on the PID control by the control means is output to the tray motor 305, the tray motor 305 is driven and the drive shaft 335 is rotated. Is done. Then, the rotational force of the drive shaft 335 is transmitted to the rotation shaft 331 of the drive pulley 321 by the transmission belt 327 wound around the rotation pulley 336 and the transmission pulley 333, and the drive pulley 321 is rotated. When the drive pulley 321 is rotated in this manner, the timing belt 304 wound around the drive pulley 321 and the driven pulley 322 travels, whereby the media tray 45 fixed to the timing belt 304 is moved in the front-rear direction of the apparatus. Moved to.

(Media transport mechanism)
FIG. 7 is a perspective view showing a media transport mechanism constituting the media delivery mechanism. As shown in FIG. 7, the media transport mechanism 31 includes a chassis 32 that is vertically attached, and a vertical guide is provided between a horizontal support plate portion 34 attached to the base 72 and the top plate 33 of the chassis 32. A shaft 35 is attached. The transfer arm 36 is supported on the vertical guide shaft 35 in a state where it can be raised and lowered and turned.

The raising / lowering mechanism of the transfer arm 36 includes a raising / lowering drive motor 37 that is a drive source, and the drive side that drives the timing belt 104 over which the rotation of the drive motor 37 extends over the chassis 32. It is transmitted to the pulley. A base 110 (see FIG. 8) of the transport arm 36 is connected to a part of the timing belt 104.
Therefore, when the drive motor 37 is driven, the timing belt 104 moves in the vertical direction, and the transport arm 36 attached thereto moves up and down along the vertical guide shaft 35. The drive motor 37 is a stepping motor, and the vertical position of the transfer arm 36 can be controlled by the number of steps.

  As shown in FIG. 7, the turning mechanism of the transfer arm 36 includes a turning drive motor 105 as a drive source, and a pinion (not shown) is attached to the output shaft of the drive motor 105. The rotation of the pinion is transmitted to the fan-shaped final gear 109 through a reduction gear train having a transmission gear 107. The fan-shaped final gear 109 can turn left and right about the vertical guide shaft 35. The final stage gear 109 is mounted with a chassis 32 in which components of the lifting mechanism of the transfer arm 36 are assembled. When the drive motor 105 is driven, the fan-shaped final stage gear 109 pivots left and right, so that the chassis 32 mounted here pivots left and right around the vertical guide shaft 35 as a unit. As a result, the transfer arm 36 held by the elevating mechanism mounted on the chassis 32 turns left and right around the vertical guide shaft 35.

Next, each mechanism provided in the transfer arm 36 will be described.
8 is a plan view of an arm base for explaining the gripping mechanism, FIG. 9 is a perspective view of a holding claw portion of the gripping mechanism, FIG. 10 is an enlarged plan view of the gripping mechanism, and FIGS. FIG.

  As shown in FIG. 8, the transfer arm 36 includes an elongated arm base 125a having a rectangular shape in plan view, and an arm case (not shown) having the same contour shape that is placed on the arm base 125a. Further, the transport arm 36 is provided with a gripping mechanism 130 for holding the medium M.

  The gripping mechanism 130 includes three columnar holding claws (conveying side holding claws) 141 to 143 arranged at equal angles (120 °) on the same circle, and these holding claws 141 to 143 are , Projecting vertically downward from a circular hole 125c formed at the tip of the arm base 125a, inserting it into the center hole of the medium M, spreading outward in the radial direction, and hitting the inner peripheral surface of the center hole of the medium M The medium M is held in contact.

  As shown in FIGS. 8 and 9, the holding claws 141 to 143 are attached to the lower ends of the support pins 151 to 153. Each of the support pins 151 to 153 passes through the circular hole 125c of the arm base 125a, extends upward, and is fixed to three swivel plates 161 to 163 arranged on the upper surface of the arm base 125a. The pivot base shafts 171 to 173 are vertically fixed at equal angular intervals on the same circle in a state of surrounding the circular hole 125c in the arm base 125a, and each of the pivot plates 161 to 163 is supported by the pivot center shaft 171. It is supported in a pivotable state about ˜173.

  As shown in FIGS. 8 to 10, each of the swiveling plates 161 to 163 extends forward along the arm base 125 a toward the front side (counterclockwise in the top view) along the substantially circumferential direction of the circular hole 125 c. Arm portions 161a to 163a, rear arm portions 161b to 163b extending rearward (clockwise in the top view clockwise direction) side substantially along the circumferential direction of the circular hole 125c, and a support protruding from the turning center to the inner side of the circular hole 125c Arms 161c to 163c are provided. Support pins 151 to 153 are vertically fixed to the back surfaces of the tips of the support arms 161c to 163c, respectively.

A long hole 161d is formed in the rear arm portion 161b of the swivel plate 161 along the substantially radial direction of the circular hole 125c, and the long hole 161d is downward at the rear end of the front arm portion 163a of the swivel plate 163. The projecting slide pin 163f is slidably inserted.
Further, a slide surface 163e is formed at the tip of the rear arm portion 163b of the swivel plate 163 along the substantially radial direction of the circular hole 125c, and the front end of the front arm portion 162a of the swivel plate 162 is formed on the slide surface 163e. It is set so that the parts do not touch. Further, a slide surface 162e is formed at the tip of the rear arm 162b of the swivel plate 162 along the substantially radial direction of the circular hole 125c, and the front end of the front arm 161a of the swivel plate 161 is formed on the slide surface 162e. The part can be slidably contacted. Here, the long hole 161d of the swivel plate 161 and the slide surfaces 162e and 163e of the swivel plates 162 and 163 are formed in a concave curved shape set so that the respective swivel plates 161 to 163 swirl in the same direction. .

  Between the rear arm portion 161b of the turning plate 161 and the rear arm portion 162b of the turning plate 162, between the rear arm portion 162b of the turning plate 162 and the rear arm portion 163b of the turning plate 163, and the rear arm portion 163b of the turning plate 163. A tension coil spring (biasing member) 174 is bridged between the rear arm 161b of the revolving plate 161 and the rear arm 161b. Then, the tension plates 161 to 163 are held without rattling by the tensile force of the tension coil springs 174, and the directions indicated by the arrows R1 in FIG. 10 (holding claws 141 to 143) with respect to each of the rotation plates 161 to 163. (In the direction of spreading)).

In the state of FIG. 10, the circumscribed circle of the holding claws 141 to 143 attached to the tips of the support arms 161 c to 163 c of the swivel plates 161 to 163 has a larger diameter than the inner diameter of the center hole of the medium M. In this state, when one swivel plate 161 is swung in the direction indicated by the arrow R2, the other two swivel plates 162, 163 are also swung in the same direction. As a result, the support arms 161c to 163c of the swivel plates 161 to 163 move toward the center of the circular hole 125c, and the holding claws 141 to 143 attached to these tip portions can be inserted into the center hole of the medium M. It is narrowed to the state.
In this state, the holding claws 141 to 143 are inserted into the center hole of the medium M, and then the turning plates 161 to 163 are turned in the reverse direction R1, so that the holding claws 141 to 143 are pushed outward in the radial direction. As a result, the holding claws 141 to 143 are pressed against the inner peripheral surface of the center hole of the medium M, and the medium M is held.

  The swivel plate 161 is formed with an operating arm 161g extending from the side opposite to the support arm 161c. The tip of one arm 175a of the link 175 is connected to the tip of the operation arm 161g in a rotatable state. The link 175 is rotatably supported by the arm base 125a with the middle part thereof as the center, and the tip of the arm part 175b on the opposite side is connected to the operating rod 176a of the electromagnetic solenoid 176. When the electromagnetic solenoid 176 is in an off state, the operating rod 176a is projected by the spring force of a built-in spring.

  When the electromagnetic solenoid 176 is switched on in this state, the operating rod 176a is retracted against the built-in spring force, the link 175 is turned, and the turning plate 161 is turned in the R2 direction. Then, as shown in FIG. 11, the slide surface 162e of the rear arm portion 162b of the swivel plate 162 is in sliding contact with the tip of the front arm portion 161a of the swivel plate 161, and the slot 161d of the rear arm portion 161b of the swivel plate 161 is in contact. The inner surface is in sliding contact with the slide pin 163f of the front arm 163a of the swivel plate 163. As a result, the slide surface 162e of the swivel plate 162 slides on the tip of the front arm portion 161a of the swivel plate 161 and slides radially outward of the circular hole 125c, thereby turning the swivel plate 162 in the R2 direction. The inner surface of the long hole 161d of the rear arm 161b of the swivel plate 161 is in sliding contact with the slide pin 163f of the front arm 163a of the swivel plate 163, and the front arm 163a of the swivel plate 163 slides toward the center of the circular hole 125c. As a result, the turning plate 163 also turns in the R2 direction.

  Thus, when the turning plate 161 turns in the R2 direction, the turning force of the turning plate 161 in the R2 direction is transmitted to the other turning plates 162 and 163. As shown in FIG. The holding claws 141 to 143 that turn in the R2 direction and are provided on the support arms 161c to 163c of the turning plates 161 to 163 are arranged in a circumscribed circle that is sufficiently smaller than the center hole of the medium M. It is narrowed to an insertable state.

  In this state, when the electromagnetic solenoid 176 is switched off, the operating rod 176a is protruded by the spring force of the built-in spring, and the link 175 rotates. Then, the turning motion of the link 175 is transmitted to the turning plate 161, and the turning plate 161 turns in the R1 direction. In conjunction with this, the other two swiveling plates 162 and 163 are pulled toward the center of the circular hole 125c by the rear arm portions 162b and 163b by the pulling force of the tension coil spring 174. The plates 162 and 163 also turn in the R1 direction in the same manner as the turning plate 161. As a result, as shown in FIG. 13, the holding claws 141 to 143 are spread and the holding claws 141 to 143 are pressed against the inner peripheral surface of the center hole of the medium M, and the medium M is held.

  At this time, the swiveling plates 162 and 163 are independently swung in the R1 direction by the pulling force of the pulling coil spring 174 with respect to the swiveling plate 161, so that the holding claws 141 to 143 are also independently separated from each other in the radial direction. And is pressed against the inner peripheral surface of the center hole of the medium M.

  As shown in FIG. 14, the three holding claws 141 to 143 include cylindrical pins 141 a to 143 a that protrude from the lower ends of the support pins 151 to 153, and rubber that surrounds the pins 141 a to 143 a in a concentric state. Elastic cylinders 141b to 143b made of The three holding claws 141 to 143 have a downward protruding length l that is equal to or smaller than the thickness t1 of the medium M to be held. The protrusion length l is preferably not less than the thickness t1 of the inner periphery Mb of the center hole Ma of the medium M and not more than the thickness t1 of the medium M including the height of the annular protrusion Mc. As a result, when holding the stacked media M in the thickness direction, the holding claws 141 to 143 do not come into contact with the inner peripheral surface Mb of the second media M, and the first media that is the uppermost portion. Only M is held.

(Media receipt mechanism)
15 and 16 are transparent plan views showing the media receiving mechanism, FIG. 17 is a transparent plan view showing the relationship between the holding claw of the media receiving mechanism and the holding claw of the media transport mechanism at the time of media delivery, and FIG. 18 is at the time of media delivery. FIG. 6 is a side view schematically showing a relationship between a holding claw of the media receiving mechanism and a holding claw of the media transport mechanism and the medium.
A media receiving mechanism 300 shown in FIG. 15 constitutes the media delivery mechanism 301 together with the media transport mechanism 31 described above, and includes the media tray 45 of the label printer 11 and the belt drive mechanism 310 described above. A reciprocating slide is performed between the home position and the media delivery position including the print area along the axis 302.

  An irregular hole 45c is formed in the center of the placement plate 45b on which the medium M is placed in the media tray 45. The irregularly shaped hole 45c has a shape in which circular holes are formed at equal intervals in a portion protruding in a triangular shape from the inner peripheral surface to the center side. Three holding claws (receiving side holding claws) 241 to 243, which will be described later, of the gripping mechanism 230 of the media receiving mechanism 300 protrude through the deformed holes 45c.

  The gripping mechanism 230 includes three columnar holding claws 241 to 243 arranged at equal angles (120 °) on the same circle, and these holding claws 241 to 243 are formed on the media tray 45. It protrudes vertically upward from the deformed hole 45c. These three holding claws 241 to 243 are inserted into the center hole of the medium M and pushed outward in the radial direction, thereby contacting the inner peripheral surface of the center hole of the medium M to hold the medium M.

  The holding claws 241 to 243 are fixed to three swiveling plates 261 to 263 arranged on the lower surface of the mounting plate 45b of the media tray 45, respectively. In the media tray 45, the turning center shafts 271 to 273 are fixed vertically at equal angular intervals on the same circle so as to surround the deformed hole 45c, and the turning plates 261 to 263 are respectively connected to the turning center shafts 271. It is supported in a pivotable state about ˜273.

  Each of the swiveling plates 261 to 263 includes a front arm portion 261a to 263a extending along the media tray 45 along the substantially circumferential direction of the deformed hole 45c toward the front side (counterclockwise in the top view), and a deformed hole 45c. Are provided with rear arm portions 261b to 263b extending rearwardly (clockwise in the top view) along the substantially circumferential direction, and support arms 261c to 263c projecting from the turning center to the inside of the deformed hole 45c. Holding claws 241 to 243 are vertically fixed to the distal ends of the support arms 261c to 263c, respectively.

  A slide surface 263d is formed at the tip of the rear arm portion 263b of the swivel plate 263 along the substantially radial direction of the deformed hole 45c, and the front end of the front arm portion 262a of the adjacent swivel plate 262 is formed on this slide surface 263d. The part can be slidably contacted. Further, a slide surface 262d is formed at the tip of the rear arm portion 262b of the swivel plate 262 along the substantially radial direction of the deformed hole 45c, and the front arm portion 261a of the adjacent swivel plate 261 is formed on the slide surface 262d. The front end of the slidable contact is possible. Further, a slide surface 261d is formed at the tip of the rear arm portion 261b of the swivel plate 261 along the substantially radial direction of the deformed hole 45c, and the front arm portion 263a of the adjacent swivel plate 263 is formed on this slide surface 261d. The front end of the slidable contact is possible.

  A tension coil spring 274 is bridged between the front end side of the front arm portion 261a of the turning plate 261 and the mounting plate 45b. Then, by the pulling force of the tension coil spring 274, the swiveling plates 261 to 263 are held without rattling, and the direction indicated by the arrow R7 (holding claws 241 to 243) in FIG. (In the direction of spreading)).

In the state of FIG. 15, the circumscribed circle of the holding claws 241 to 243 attached to the tips of the support arms 261 c to 263 c of the revolving plates 261 to 263 is larger than the inner diameter of the center hole of the medium M. In this state, when one swivel plate 261 is swung in the direction indicated by the arrow R8 shown in FIG. 16, the other two swivel plates 262 and 263 are also swung in the same direction. As a result, the support arms 261c to 263c of the swivel plates 261 to 263 move toward the center of the deformed hole 45c, and the holding claws 241 to 243 attached to these tip portions can be inserted into the center hole of the medium M. It is narrowed to the state.
In this state, the holding claws 241 to 243 are inserted into the center hole of the medium M, and then the turning plates 261 to 263 are turned in the reverse direction R7, whereby the holding claws 241 to 243 are pushed outward in the radial direction. As a result, the holding claws 241 to 243 are pressed against the inner peripheral surface of the center hole of the medium M, and the medium M is held.

  The swivel plate 261 is formed with an operation arm 261e extending from the side opposite to the support arm 261c. The tip of one arm 275a of the link 275 is connected to the tip of the operating arm 261e in a rotatable state. The link 275 is rotatably supported by the media tray 45 around a rotation shaft 275b on the proximal end side of the arm portion 275a. The link 275 is opposite to the intermediate orthogonal part 275c extending perpendicularly to the arm part 275a from the base end side of the arm part 275a and the arm part 275a of the intermediate orthogonal part 275c from the side opposite to the arm part 275a. And an arm portion 275d extending in the direction. An arc-shaped contact portion 275e is formed at the tip of the arm portion 275d.

  The frame 315 is formed with a cam 211 on which the contact portion 275e of the link 275 rides when the media tray 45 moves to the media delivery position (the state shown in FIG. 16). The link 275 is configured such that when the media tray 45 moves to the printing area (the state shown in FIG. 15), the contact portion 275e cancels the riding on the cam 211 and does not contact the frame 315. In this state, the link 275 does not pull the operating arm 261e of the turning plate 261, the turning plates 261 to 263 turn in the R7 direction by the pulling force of the tension coil spring 274, and the holding claws 241 to 243 move in the radial direction. It is pushed outward.

  On the other hand, in the link 275, when the media tray 45 moves to the media delivery position, the contact portion 275e rides on the cam 211. In this state, the link 275 turns against the tensile force of the tension coil spring 174, and the turning plate 261 turns in the R8 direction. Then, the slide surface 262d of the rear arm 262b of the swivel plate 262 slides in contact with the tip of the front arm 261a of the swivel plate 261 and slides outward in the radial direction of the deformed hole 45c, so that the swivel plate 262 turns in the R8 direction. To do. At the same time, the slide surface 263d of the rear arm portion 263b of the swivel plate 263 slides in contact with the tip of the front arm portion 262a of the swivel plate 262 and slides radially outward of the deformed hole 45c, so that the swivel plate 263 is moved in the R8 direction. Turn. As a result, the support arms 261c to 263c of the swivel plates 261 to 263 move toward the center of the deformed hole 45c, and the holding claws 241 to 243 attached to these tip portions can be inserted into the center hole Ma of the medium M. It is narrowed to the state.

  Thus, when the turning plate 261 turns in the R8 direction, the turning force of the turning plate 261 in the R8 direction is transmitted to the other turning plates 262 and 263, and the turning plates 262 and 263 also turn in the R8 direction and turn. The holding claws 241 to 243 provided on the support arms 261c to 263c of the plates 261 to 263 are arranged in a circumscribed circle sufficiently smaller than the center hole of the medium M, and are narrowed to a state where they can be inserted into the center hole of the medium M. .

  From this state, when the media tray 45 moves to the printing area and the contact portion 275e of the link 275 descends from the cam 211, the swiveling plate 261 rotates the link 275 by the pulling force of the pulling coil spring 174, and the R7 direction. Turn to. Then, in conjunction with this, the other two swiveling plates 262, 263 are respectively pulled by the rear arm portions 262b, 263b toward the center of the circular hole 45c, so that the swiveling plates 262, 263 are also swiveled. As in H.261, turn in the R7 direction. As a result, the holding claws 241 to 243 are spread and the holding claws 241 to 243 are pressed against the inner peripheral surface of the center hole of the medium M, and the medium M is held.

Next, delivery of the media M between the media transport mechanism 31 and the media receiving mechanism 300 will be described.
The transport arm 36 that holds the medium M descends from vertically above the media tray 45 at the delivery position and delivers the medium M. At this time, the media transport mechanism 31 descends with the center of the circular hole 125c of the transport arm 36 disposed coaxially with the center of the deformed hole 45c of the media receiving mechanism 300.

  Then, the medium M held by the holding claws 141 to 143 of the media transport mechanism 31 is brought close to the holding claws 241 to 243 in the narrowed state of the media receiving mechanism 300, and as shown in FIG. The holding claws 241 to 243 in a narrowed state are inserted into the center hole Ma of M.

Here, in a state where the center of the media guide 133 and the center of the deformed hole 45c are arranged coaxially, the holding of the media receiving mechanism 300 is held with respect to the holding claws 141 to 143 of the media transport mechanism 31 as shown in FIG. The claws 241 to 243 have a phase difference of 60 degrees. The movable range A241 to A2 shown by the two-dot chain lines of the holding claws 241 to 243 of the media receiving mechanism 300 with respect to the entire movable range A141 to A143 of the holding claws 141 to 143 of the media transport mechanism 31. The entire range of A243 is arranged so as not to interfere with each other.
Therefore, the holding claws 241 to 243 enter the center hole Ma of the medium M without interfering with a phase different from that of the holding claws 141 to 143.

  Then, as schematically shown in FIG. 18, when the holding claws 141 to 143 enter the holding claws 241 to 243 to a position where they overlap in the direction of the axis L of the center hole Ma, the transport arm 36 is stopped. If the electromagnetic solenoid 176 of the media transport mechanism 31 is switched on in this state, the operating rod 176a is pulled against the built-in spring force, the link 175 is turned, and the turning plate 161 is turned in the R2 direction. Then, the turning force of the turning plate 161 in the R2 direction is transmitted to the other turning plates 162 and 163, and the turning plates 162 and 163 also turn in the R2 direction and are provided on the support arms 161c to 163c of the turning plates 161 to 163. The holding claws 141 to 143 are arranged in a circumscribed circle that is sufficiently smaller than the center hole Ma of the medium M, and are narrowed to a state where the holding of the center hole Ma of the medium M is released. As a result, the media M is delivered from the media transport mechanism 31 to the media receiving mechanism 300. At this time, the medium M has the holding claws 241 to 243 in the narrowed state of the medium receiving mechanism 300 inserted in the center hole Ma, and is placed on the placement plate 45b in this state.

  Next, the transport arm 36 of the media transport mechanism 31 is raised, and the holding claws 141 to 143 are taken out from the center hole Ma of the medium M. Thereafter, the belt driving mechanism 310 moves the media tray 45 to the printing area side. Then, at the initial stage, the abutting portion 275e of the link 275 that moves together with the media tray 45 descends from the cam 211, and the revolving plate 261 rotates the link 275 by the pulling force of the pulling coil spring 174, and the direction R7 shown in FIG. Turn to. Then, in conjunction with this, the other two swiveling plates 262 and 263 also turn in the R7 direction in the same manner as the swiveling plate 261. As a result, the holding claws 241 to 243 are spread and the holding claws 241 to 243 are pressed against the inner peripheral surface Mb of the center hole Ma of the medium M, and the medium M is held. In this state, the label printer 11 performs a label printing process on the medium M in a state where the center hole Ma side is held.

  When the label printing process ends, the label printer 11 moves the media tray 45 to the media delivery position in order to deliver the media M. Then, the contact portion 275e rides on the cam 211 at the delivery position, and the turning plates 261 to 263 turn in the R8 direction. Then, the support arms 261c to 263c of the swivel plates 261 to 263 move toward the center of the deformed hole 45c, and the holding claws 241 to 243 attached to these tip portions release the holding of the center hole Ma of the medium M. It is narrowed to the state to do. Therefore, the holding claws 241 to 243 of the medium M are in the center hole Ma of the medium M and release the holding of the medium M.

  In this state, the transport arm 36 of the media transport mechanism 31 is lowered again so that the holding claws 141 to 143 enter the center hole Ma of the medium M. Also at this time, the holding claws 141 to 143 enter the center hole Ma of the medium M without interfering with a phase different from that of the holding claws 241 to 243.

  Then, the media transport mechanism 31 turns off the electromagnetic solenoid 176, whereby the link 175 turns and the turning plates 161-163 turn in the R1 direction. As a result, the holding claws 141 to 143 are spread, the holding claws 141 to 143 are pressed against the inner peripheral surface Mb of the center hole Ma of the medium M, and the medium M is held on the lower surface side of the transport arm 36. . In this state, the media transport mechanism 31 lifts the transport arm 36 and transports the medium M.

  As described above, in the media delivery mechanism 301 according to the above embodiment, the media transport mechanism 31 inserts the three holding claws 141 to 143 into the center hole Ma of the medium M to be held, and the holding claws 141 to 143. Are spread in the radial direction and pressed against the inner peripheral surface Mb of the center hole Ma, so that the medium M is conveyed to the media receiving mechanism 300 while being held. Then, the media receiving mechanism 300 inserts the three holding claws 241 to 243 into the center hole Ma of the medium M held by the holding claws 141 to 143 at a phase different from that of the holding claws 141 to 143. At the same time, the holding claws 241 to 243 are expanded in the radial direction and pressed against the inner peripheral surface Mb of the center hole Ma, thereby holding the medium M. In this way, in the state where the media transport mechanism 31 holds the media M, the media receiving mechanism 300 transports the media M to the position where the media M is held, so that the delivery is performed reliably and at a stable position after delivery. Media can be held. Therefore, the label printing process to be executed thereafter can be performed with high accuracy and high reliability while the medium M is stably held.

  In addition, the media receiving mechanism 300 inserts the holding claws 241 to 243 into the center hole Ma of the medium M held by the holding claws 141 to 143 of the media transport mechanism 31 with a phase different from that of the holding claws 141 to 143. Since M is received, the medium M can be reliably delivered from the media transport mechanism 31 to the media receiving mechanism 300.

  Further, when the holding claws 241 to 243 are inserted into the center hole Ma of the medium M held by the holding claws 141 to 143 and the medium M is received, the holding claws 241 to 243 and the holding claws 141 to 143 are center holes. Since they overlap in the axial direction of Ma, it is possible to more reliably deliver the medium M from the media transport mechanism 31 to the media receiving mechanism 300.

  According to the publisher 1 having the media delivery mechanism 301 described above, the media M can be delivered stably between the media tray 45 of the label printer 11 and the media transport mechanism 31. A processing apparatus with high processing reliability can be obtained.

In the above embodiment, the present invention is applied to the delivery position of the media M to the media tray 45 of the label printer 11. However, the present invention is not limited to the label printer 11, but the media M to the media tray 41a in the media drive 41 to which data is written. You may apply to a delivery location.
The medium used in the present invention is not limited to a disk-shaped medium such as the medium M of the above embodiment, and can be applied to a polygonal or elliptical medium such as a rectangular shape. Also, the recording method is not limited at all, such as an optical recording method and a magneto-optical recording method.

It is an external appearance perspective view of a publisher (media processing apparatus). It is an external appearance perspective view of the publisher which opened each part. It is the perspective view seen from the front upper side of the state which removed the case of the publisher. It is a perspective view of the label printer part installed in the publisher. It is a perspective view of the recording device part installed in the publisher. It is a schematic plan view of a belt drive mechanism. It is a perspective view which shows a media conveyance mechanism. It is a top view of the arm base explaining a gripping mechanism. It is a perspective view of the holding nail | claw part of a gripping mechanism. It is an enlarged plan view of a holding claw part. It is each a top view explaining the movement of a turning board and a holding claw. It is each a top view explaining the movement of a turning board and a holding claw. It is each a top view explaining the movement of a turning board and a holding claw. It is sectional drawing of a holding nail explaining a holding nail. It is a permeation | transmission top view which shows a media receiving mechanism. It is a permeation | transmission top view which shows a media receiving mechanism. FIG. 6 is a transparent plan view showing a relationship between a holding claw of a media receiving mechanism and a holding claw of a media transport mechanism during media delivery. It is a side view which shows notionally the relationship between the holding claw of a media receiving mechanism at the time of media delivery, the holding claw of a media conveyance mechanism, and a medium.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Publisher (media processing apparatus), 31 ... Media conveyance mechanism, 141-143 ... Holding claw (carrying side holding claw), 300 ... Media receiving mechanism, 301 ... Media delivery mechanism, 241-243 ... Holding claw (receiving side holding) Nail), M ... media, Ma ... center hole, Mb ... inner peripheral surface.

Claims (4)

A medium for holding the medium by inserting at least three transport side holding claws into the center hole of the medium to be held, spreading each of the transport side holding claws in the radial direction, and pressing it against the inner peripheral surface of the center hole. A transport mechanism;
At least three receiving side holding claws are inserted into a central hole of the medium held by the conveying side holding claws at a phase different from that of the conveying side holding claws to receive the medium, and the receiving side holding claws are by pressing the inner peripheral surface of the central hole respectively radially widened, have a media receiving mechanism for holding the medium;
The media delivery mechanism includes a media tray that is movable between a printing position where label printing can be performed on a label surface of the media and a media delivery position for receiving and delivering the media. The media delivery mechanism according to claim 1,
When the receiving side holding claw is inserted into the center hole of the medium held by the transport side holding claw to receive the medium, the receiving side holding claw and the transport side holding claw are in the axial direction of the center hole. Media delivery mechanism that overlaps The media delivery mechanism according to claim 2,
  The receiving side holding claw releases the holding of the medium when the media tray moves to the media delivery position and the receiving side holding claw and the transport side holding claw overlap in the axial direction of the center hole. And a media delivery mechanism for holding the media when the media tray moves to the printing position. The media delivery mechanism according to any one of claims 1 to 3,
  A media processing unit that performs information processing on the media,
  A media processing apparatus in which the media receiving mechanism of the media delivery mechanism is provided in the media processing unit.

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