JP4363020B2 - Tape processing unit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a tape processing apparatus that performs printing of a desired character such as a character or a figure or half-cutting of a desired cut shape on a cutting tape wound in a roll shape.
[0002]
[Prior art]
Half-cutting in a conventional tape processing apparatus is performed by cutting relatively in the X and Y directions into a cutting tape (tape piece) fed forward and backward at the position of the half-cut mechanism. In order to prevent the tape piece to be fed from interfering with the full cut mechanism or the printing mechanism, there is provided a path changing means for guiding the tape piece to be fed backward from the traveling path to the branch path on the downstream side of the full cut mechanism (for example, (See Patent Document 1).
In this case, the path changing means rotates and feeds the tape piece between the first path changing roller whose roller surface faces both the traveling path and the branch path and the first path changing roller disposed on the branch path. And a second path changing roller.
[0003]
[Patent Document 1]
JP 2002-1692 A (page 3-4, FIG. 1)
[0004]
[Problems to be solved by the invention]
In such a conventional tape processing apparatus, the branch path extends in the direction opposite to the winding direction of the cutting tape. It was difficult to be fed between the roller and the second path changing roller. Even if the tape piece is led to the branch path, there may be an error in the tape feed amount at the time of half-cut, which causes a misalignment between the printed character and the surrounding heart-shaped half cut, for example. was there
Furthermore, considering that it is possible to perform only printing on a cutting tape and only cut-out processing, which is not assumed in conventional tape processing equipment, the tape feed suitable for each of these processes in relation to each mechanism such as a printing mechanism. It is essential to do.
[0005]
The present invention can perform various processes of tape feeding, printing, half cut, and full cut on a cutting tape with a single device, and can stably change the path of the cutting tape in the half cut process. Furthermore, it is an object of the present invention to provide a tape processing apparatus capable of performing suitable tape feeding associated with each mechanism in accordance with the contents of tape processing.
[0006]
[Means for Solving the Problems]
  The tape processing apparatus of the present invention is a printing process in which a release tape and a tape main body are laminated, and a printing process for performing only printing on the tape main body with respect to a cutting tape set so as to be able to be fed out in a rolled state. In the tape processing apparatus that selectively performs the cutting process that performs only the cutting process and the combined process that performs the printing and cutting process on the tape body, the tape feeding mechanism that feeds the cutting tape and sends it along the traveling path, and the upstream side of the traveling path The printing mechanism that prints on the cutting tape in synchronization with the normal feed of the tape feeding mechanism, the full cut mechanism that cuts the cutting tape into a predetermined dimension facing the traveling path downstream of the printing mechanism, and the full cut mechanism The tape piece that was cut off in synchronization with the forward / reverse feed of the tape feed mechanism is cut out arbitrarily. Path cut to a half-cut mechanism that cuts in the shape of a tape, and a tape piece that is reversely fed in the cut-out process and the combined process to a branch path that extends in the winding direction of the cutting tape from the running path immediately downstream of the full-cut mechanism And a control means for selectively controlling the tape feeding mechanism, the printing mechanism, and the half-cut mechanism in accordance with each of the printing process, the cutting process, and the combined process.The tape feed mechanism is disposed upstream of the full cut mechanism, and feeds out the cutting tape. The tape feed mechanism is disposed downstream of the full cut mechanism and forward / reverse feed mechanism capable of feeding the cutting tape forward and backward. A clutch mechanism for cutting off the power of the tape feeding mechanism so that the tape feeding by the tape feeding mechanism and the tape feeding by the forward / reverse feeding mechanism do not overlap.It is characterized by that.
[0007]
  According to this configuration, the printing mechanism, the full cut mechanism, the path changing unit, and the half cut mechanism are faced in order from the upstream side on the travel path. Thus, when the cutting tape is unwound from the roll state, in the case of the printing process, in the order of printing and full cut, in the case of the cutting process, the combined process is performed in the order of full cut, path change, and half cut. In some cases, printing, full cut, path change, and half cut are performed in this order, and any process finally results in the form of a tape piece. In this way, by controlling the mechanism necessary for each process, various types of tape pieces can be appropriately produced with a single device.
  In the case of the cutting process and the combined process, the tape piece to be fed backward is guided to the branch path, and half cut is performed on the downstream side of the traveling path, but this branch path extends in the winding direction of the cutting tape. In the direction. As a result, the reversely fed tape piece is sent from the travel path to the branch path following the curl, while the forwardly fed tape piece is sent from the branch path to the travel path following the curl. It is possible to stably change the path of the tape piece by effectively using the winding rod. For this reason, the half cut to a tape piece can be performed stably.
  Further, since the path change is performed immediately near the downstream side of the full cut mechanism, the printing mechanism and the full cut mechanism can be disposed as close as possible, and waste of the printed cutting tape (front margin) can be prevented. In addition, since the tape piece that is fed back does not face the printing mechanism as well as the full-cut mechanism, it can prevent jamming due to interference with these mechanisms, and chips that may occur at the time of half-cutting are generated by the printing mechanism. Can be suitably avoided.
  Furthermore, the cutting tape feed control can be switched before and after the full cut mechanism, and the tape feeding mechanism feeds the cutting tape and sends it to the downstream side of the travel path of the printing mechanism, full cut mechanism, On the other hand, the forward / reverse feed mechanism allows the forward / reverse feed of the tape piece to be performed in synchronization with the half-cut mechanism. Since the clutch mechanism that cuts off the power of the tape feeding mechanism is provided, only the forward / reverse feed mechanism is driven after the tape is cut (after full cut). Thereby, a tape piece can be sent independently, without paying out a cutting tape from roll shape after a full cut. Therefore, for example, even if the tape piece is forward / reversely fed at the time of half-cutting, the unprocessed cutting tape is not fed out.
[0010]
In these cases, a process selection command means for selectively instructing a printing process, a cut-out process, and a composite process is further provided, and the control means is based on the selection command of the process selection command means, and the tape feeding mechanism, the printing mechanism, and the half cut It is preferable to selectively control the mechanism.
[0011]
According to this structure, the internal mechanism corresponding to each process can be controlled by the selection command of the selection command means.
[0014]
In this case, when performing the printing process, the control means drives the printing mechanism in synchronization with the tape feeding mechanism to perform printing on the cutting tape, and controls the full-cut mechanism after printing to separate the printed portion. It is preferable to drive the forward / reverse feed mechanism forward to pass the tape piece through the half-cut mechanism in the standby state.
[0015]
According to this configuration, in the printing process, the cutting tape is printed while being fed out by the tape feeding mechanism, the printed portion is cut, and the tape piece that is the printed portion is continuously forward fed by the forward / reverse feeding mechanism. Then, it passes through the position of the half-cut mechanism in the standby state (drive is canceled). A tape piece (printed label) can be appropriately created by such a series of control of the tape feeding mechanism, the printing mechanism, and the half-cut mechanism.
[0016]
Similarly, when performing the cut-out process, the control unit sets the printing mechanism in a standby state, controls the tape feeding mechanism to feed the cutting tape to the forward / reverse feeding mechanism, and controls the full-cut mechanism to set the cutting tape to a predetermined value. It is preferable that the half-cut mechanism is driven in synchronization with the forward / reverse feed of the tape piece by controlling the forward / reverse feed mechanism.
[0017]
According to this configuration, in the cut-out process, the cutting tape is fed out by the tape feeding mechanism, but passes through the standby printing mechanism without printing and is sent (shifted) to the forward / reverse feeding mechanism. And when it becomes a tape piece, a path | route is changed and the half cut accompanied by forward / reverse feeding is performed. By such a series of control of the tape feeding mechanism, the printing mechanism, and the half-cut mechanism, a tape piece having a cut-out shape can be appropriately created.
[0020]
Similarly, when performing complex processing, the control means drives the printing mechanism in synchronization with the tape feeding mechanism to print on the cutting tape, and controls the full-cut mechanism after printing to separate the printed portion. It is preferable to drive the half-cut mechanism in synchronization with the forward / reverse feed of the tape piece by controlling the forward / reverse feed mechanism.
[0021]
According to this configuration, in the case of composite processing, the cutting tape is printed while being fed out by the tape feeding mechanism, and then cut to become a tape piece, the path is changed, and the forward / reverse feed mechanism and the half-cut mechanism cooperate. Thus, a cut-out half cut is performed. By such a series of control of the tape feeding mechanism, the printing mechanism, and the half-cut mechanism, a tape piece in which the printed image and the cutout shape are combined can be appropriately created.
[0024]
Similarly, when performing the combined processing, the control means controls the tape feeding mechanism to feed the cutting tape into the forward / reverse feeding mechanism, and controls the clutch mechanism to cut off the power to the tape feeding mechanism. The printing mechanism is driven in synchronism with the forward feed of the reverse feed mechanism to print on the cutting tape, and after printing, the full cut mechanism is controlled to cut off the printed portion, and the forward / reverse feed mechanism is controlled to control the tape piece. It is preferable to drive the half-cut mechanism in synchronization with forward / reverse feed.
[0025]
According to this configuration, as another combined process, the cutting tape is fed to the printing mechanism by the tape feeding mechanism and then fed to the half-cut mechanism, and then the power to the tape feeding mechanism is cut off to feed the tape. Is shifted to the forward / reverse feed mechanism, and the printing mechanism is driven in synchronism with the forward feed of the forward / reverse feed mechanism for the first time. Subsequently, the half-cut mechanism is driven in synchronism with the forward / reverse feed of the forward / reverse feed mechanism for the tape piece after printing, and the printed portion and the cut-out portion are combined. In this way, printing and half-cutting on the cutting tape are performed by controlling the tape feed amount by the same forward / reverse feed mechanism, and therefore structural errors (for example, rollers) when these are fed by different feed mechanisms. Are not affected by the outer diameter error, etc.). As a result, the relative error of the tape feed amount between printing and half-cutting can be appropriately eliminated, and the printed portion and the cut-out portion can be combined with extremely high accuracy.
[0028]
In these cases, the forward / reverse feed mechanism has a grip roller made up of a drive roller and a driven roller, and a roller separation mechanism that relatively moves the drive roller and the driven roller away from each other. It is preferable to control the mechanism so that the grip roller is brought into the grip state when the cutting tape stops feeding for separation.
[0029]
According to this configuration, when the cutting tape is cut, the driven roller of the grip roller is in contact with the drive roller. Therefore, even if the full cut is performed by the slide cut method, the end surface of the cutting tape can be cut straight. . In addition, since the forward and reverse feeding of the cutting tape is performed by a roller having a grip structure, the tape feeding accuracy can be improved.
[0034]
In these cases, it is preferable that the cutting tape is housed in a tape cartridge in a state of being wound in a roll shape so that the cutting tape can be unwound and further provided with a cartridge mounting portion for detachably mounting the tape cartridge.
[0035]
According to this configuration, since the cutting tape is accommodated in the tape cartridge, management including storage of the cutting tape can be easily performed. Moreover, the setting of the cutting tape to the tape processing apparatus can be performed with a very simple specification of the tape cartridge attaching / detaching operation.
[0036]
In this case, a plurality of types of cutting tapes suitable for each of the printing process, the cutout process, and the combined process are prepared, and correspondingly, the tape cartridge has a plurality of types that accommodate each cutting tape. It is preferable that the cartridge mounting portion is composed of a single unit that can detachably mount each tape cartridge from the same direction.
[0037]
According to this configuration, since the cutting tape for various types of processing is housed in the dedicated tape cartridge, it is possible to easily manage a plurality of cutting tapes. Further, since a plurality of types of tape cartridges can be mounted on the single cartridge mounting portion from the same direction, the entire apparatus can be reduced in size. Note that the tape cartridge for printing (cutting tape) also serves as the tape cartridge for cutting combined processing (cutting tape), so that the types of tape cartridges to be prepared can be reduced.
[0064]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. The tape processing apparatus to which this embodiment is applied performs printing, full cut, half cut, and the like on this while feeding a cutting tape with release paper. Specifically, the tape processing apparatus performs a printing process for printing only a desired character such as a character or a figure on a tape main body of a cutting tape, a cutting process for only cutting a desired cut shape, printing, It is possible to select and perform combined processing for performing both cutouts, and in addition to creating cutout characters, printed labels decorated in cutout shapes can be created.
[0065]
Two types of cutting tapes with different waist strength, that is, different stiffnesses are prepared for use in the tape processing equipment. In this case, a cutting tape with high rigidity is used exclusively for the cutting process. Low cutting tape is used for printing and composite processing. Therefore, in the following explanation, the tape having high rigidity is referred to as S tape, the tape having low rigidity is referred to as P tape, and the term cutting tape is used as a general term for these. Note that, among the configurations of the tape processing apparatus, the configuration excluding mainly the one related to printing is used as the cutting device.
[0066]
FIG. 1 is an external perspective view showing the entire tape processing apparatus, and FIG. 2 is a perspective view showing a state in which an opening / closing lid of the tape processing apparatus is opened. As shown in both figures, the tape processing apparatus 1 is composed of an apparatus main body 3 having an outer shell formed by an apparatus case 2 and a tape cartridge 5 detachably attached to the apparatus main body 3. A cutting tape T with release paper Ta is housed in a roll-like state so as to be fed out.
[0067]
The device case 2 includes a lower case 7 and an upper case 8, and the upper case 8 is formed with the latter half side raised one step further. A keyboard 11 is disposed on the front upper surface of the upper case 8, and the keyboard 11 has a kana key 12, a power key 13, a process execution key 14, a mode switching key 15, and other various input keys. A display 17 for displaying input / editing results from the keyboard 11 and the like is disposed on the left front surface of the upper case 8.
[0068]
A right side portion corresponding to 2/3 of the rear half of the upper case 8 is configured as an opening / closing lid 18, and the opening / closing lid 18 is configured to be freely opened and closed by a hinge built in a rear lower portion. On the upper surface of the opening / closing lid 18, a tape discharge port 32 for leading the cutting tape T out of the apparatus main body 3 is formed in a slit shape. Inside the opening / closing lid 18 opened so that the front part is lifted up, a mechanism assembly in which the tape cartridge 5 is detachably mounted and various components are incorporated is configured.
[0069]
In the mechanism assembly, an eject mechanism is incorporated so that the tape cartridge 5 can be slid and mounted on the cartridge mounting portion 19 from an oblique side. The eject mechanism is configured such that the tiltable device frame 4 that serves as a support base for the mechanism assembly is positioned between a tilted position in which the receiving / opening side of the cartridge mounting portion 19 is tilted upward and a horizontal position in which the device main body 3 is accommodated. Tilt with. The device frame 4 incorporates an internal device 21 that performs various processes on the cutting tape T.
[0070]
As shown in the longitudinal sectional view of FIG. 3, the internal device 21 includes a tape feeding mechanism 22 that feeds the cutting tape T along the travel path A, a printing mechanism 23 that performs thermal transfer printing on the cutting tape T, and a cutting tape. A full-cut mechanism 24 that cuts T into predetermined dimensions, a half-cut mechanism 25 that half-cuts the cutting tape T (tape piece) cut in cooperation with the tape feed mechanism 22 into an arbitrary cut-out shape, and each of these mechanisms. And a controller 26 (control means) for overall control.
[0071]
The printing mechanism 23, the full cut mechanism 24, and the half cut mechanism 25 face the traveling path A on a substantially vertical line in the apparatus main body 3 from the lower side to the upper side in order. That is, the printing mechanism 23 faces the upstream side of the travel path A, and the half-cut mechanism 25 faces the downstream side of the travel path A, and the full-cut mechanism 24 is located on the travel path A between the printing mechanism 23 and the half-cut mechanism 25. Is facing. Thereby, tape processing is performed in the order of printing, full cut, and half cut.
[0072]
Further, in the apparatus main body 3, a branch path B that deviates from the traveling path A of the full cut mechanism 24 and the printing mechanism 23 and that is substantially orthogonal to the traveling path A and goes to the rear of the apparatus main body 3 is configured. The branch path B is for preventing the cutting tape T from interfering with the full cut mechanism 24 and the printing mechanism 23 when the cutting tape T is fed forward and backward during the half-cut process. The branch path B extends in the winding direction corresponding to the winding tape of the cutting tape T, and is accommodated at the downstream end so that the tail end side of the cutting tape T is fed into the apparatus main body 3. A tape storage processing unit 30 is configured.
[0073]
Therefore, the cutting tape T fed forward and backward at the position of the half-cut mechanism 25 during the half-cut process reciprocates along the reciprocating path C between the downstream side of the travel path A and the branch path B, and the tail end side as appropriate. Part of the tape enters and leaves the tape storage processing unit 30 and part of the tip end side travels back and forth while going in and out of the apparatus main body 3 from the tape discharge port 32. The processed cutting tape T is finally sent upward from the tape outlet 32 (discharge).
[0074]
In this tape processing apparatus 1, as shown in FIG. 4A, in addition to performing composite processing for both printing and cutting on the tape body Tb of the cutting tape T, as shown in FIG. A printing process for performing printing only on the main body Tb, and a cutting process for performing only cutting on the tape main body Tb as shown in FIG. That is, the tape processing apparatus 1 is configured to be able to switch between the processing modes of the composite processing, the printing processing, and the cutout processing, and is normally set to the composite processing mode.
[0075]
In the case of creating the label shown in FIG. 6A, after the user turns on the power key 13 of the tape processing apparatus 1, the user operates the key while looking at the display 17 to display a desired character (in the figure, “ ABC ") is input / edited, a desired cutout shape (" heart "in the figure) is selected, and the process execution key 14 is pushed (instructed).
[0076]
Then, first, the tape feeding mechanism 22 and the printing mechanism 23 are driven to feed the cutting tape T in the tape cartridge 5, and at the same time, the ink ribbon R in the tape cartridge 5 is simultaneously fed. At this time, the printing mechanism 23 is appropriately driven to generate heat, thermally transferred from the ink ribbon R to the cutting tape T, and “ABC” is printed on the tape body Tb. Even after printing, the feeding of the cutting tape T is continued. When the feeding is stopped, the slide cutter 182 of the full cut mechanism 24 moves linearly, and the printed part of the cutting tape T is cut off.
[0077]
Subsequently, the tape feeding mechanism 22 and the half-cut mechanism 25 are driven, and a “heart-shaped” half-cut is formed on the cut cutting tape T (tape piece). Half-cutting is to cut only the tape main body Tb while leaving the release paper Ta of the cutting tape T. The cutting tool 181 of the half-cut mechanism 25 is moved relative to the cutting tape T in the X and Y directions. Is done.
[0078]
Specifically, after the full cut, after the cut cutting tape T (tape piece) has been sent several steps, the route A is changed by the route change mechanism 27 (described later) located immediately downstream of the full cut mechanism 24. At the same time, the reciprocating path C is established. Here, the tape feeding mechanism 22 shifts to forward / reverse feeding of the cutting tape T, and in synchronization with this forward / reverse feeding, the cutting tool 181 moves in a direction perpendicular to the cutting tape T, and half-cut is performed. Is called.
[0079]
In this way, the cut image “heart”, which is a decorative shape surrounding the print image “ABC”, is formed on the cutting tape T by synthesizing the print image and the cut shape (FIG. 5A). Then, the cutting tape T is sent out from the tape discharge port 32, whereby a series of processes of the tape processing apparatus 1 is completed. The user separates the tape main body Tb of the discharged cutting tape T from the release paper Ta, so that it is attached to an adherend such as a file as a label having an outer shape “heart” shape having a printed image “ABC” inside. It becomes possible to stick.
[0080]
When producing the label shown in FIG. 5B, the tape feed mechanism 22, the printing mechanism 23, and the full cut mechanism 24 are driven while the half cut mechanism 25 is in a standby state. In this case, the branch path B is not used. On the other hand, in the case of FIG. 5C, the tape feeding mechanism 22, the full cut mechanism 24, and the half cut mechanism 25 are driven while the printing mechanism 23 is in a standby state.
[0081]
Further, as shown in FIG. 4D, a cutout shape such as a plurality of characters and figures can be formed on the tape body Tb, and the cutout shape is limited to a decorative outline cut surrounding the printed image. Absent. In this case, the keyboard 11 for inputting a desired print image is key-operated in the same manner as in the case of the print image, thereby inputting / editing a desired cutout shape.
[0082]
Further, when the moving range of the cutting tool 181 is set to be larger than the tape width, as shown in FIG. 5E, a transverse half cut in which the cutting tape T is half-cut linearly in the width direction, or FIG. As shown, the cutting tape T can be half-cut across the width direction and in any linear shape.
[0083]
Next, before describing the internal device 21 in detail, the device frame 4, the cartridge mounting portion 19, and the tape cartridge 5 will be described. As shown in FIG. 2, the apparatus frame 4 has a left base portion rotatably supported by the lower case 7, and is rotated between an inclined position and a horizontal position by the above-described eject mechanism, and is moved to the horizontal position. It is configured to be lockable.
[0084]
The device frame 4 includes a mounting frame 54 that constitutes the cartridge mounting portion 19, an additional frame 55 that is attached to the upper front half of the mounting frame 54 and incorporates the main part of the internal device 21, and the mounting frame 54 and the additional frame. And a base frame 56 (see FIG. 5) that supports 55, and the base frame 56 is rotatably supported by the lower case 7.
[0085]
The attachment frame 55 is integrally formed in a substantially “C” shape with a pair of left and right side frames 57 and a vertical frame 58 passed between the front portions of both side frames 57. Various shafts of the device 21 are supported (see FIGS. 5 and 6).
[0086]
As shown in FIGS. 2 and 3, the cartridge mounting unit 19 faces a printing mechanism 23, and a print head 36 (thermal head) covered with a head cover 35 protrudes. A platen drive shaft 37 and a ribbon take-up shaft 38 that face each other protrude. The platen drive shaft 37 and the ribbon take-up shaft 38 rotate using a feed drive motor 81 (described later) of the tape feed mechanism 22 as a power source (see FIG. 8), and simultaneously feed the cutting tape T and the ink ribbon R.
[0087]
The tape cartridge 5 has an outer shell formed by a cartridge case 41 having a vertically divided structure, and a cutting tape T, an ink ribbon R, and a platen roller 42 are accommodated in the cartridge case 41. The cutting tape T is wound around the tape reel 43 so as to be freely fed out, and the ink ribbon R is wound around the ribbon feeding reel 44 and the ribbon take-up reel 45. The tape reel 43, the ribbon supply reel 44, the ribbon take-up reel 45, and the platen roller 42 are rotatably accommodated in the cartridge case 41.
[0088]
The cutting tape T includes a release paper Ta (release tape) and a tape body Tb laminated on the release paper Ta, and is wound in a roll shape with the release paper Ta inside. The cutting tape T accommodated in the tape cartridge 5 is a P-tape that can perform low-strength composite processing. A printed image is formed on the tape body Tb, and the tape body Tb is half-cut by leaving the release paper Ta. A cutout shape is formed. Note that a tape cartridge that accommodates an S tape having a width of 100 mm dedicated to a highly rigid cutting process will be described later (see FIG. 21).
[0089]
The cartridge case 41 is formed with a head opening 46 facing the print head 36 and a delivery slit 47 for discharging the cutting tape T out of the cartridge case 41.
[0090]
In order to mount the tape cartridge 5 in the cartridge mounting portion 19, the opening / closing lid 18 is opened and the apparatus frame 4 is tilted upward by the eject mechanism (see FIG. 2). When the tape cartridge 5 is mounted on the cartridge mounting portion 19 in this state, the print head 36 is loosely fitted in the head opening 46, the platen driving shaft 37 is mounted on the platen roller 42, and the ribbon winding shaft is mounted on the ribbon winding reel 45. 38 is engaged, and the cutting tape T and the ink ribbon R can be fed.
[0091]
Subsequently, when the apparatus frame 4 is pushed downward and returned to its original position, a head release mechanism (not shown) is operated, and the print head 36 rotates backward about the support shaft 39. Accordingly, the print head 50 comes into contact with the platen roller 42 so as to sandwich the cutting tape T and the ink ribbon R, and printing on the cutting tape T becomes possible.
[0092]
The cutting tape T is fed out from the tape reel 43 as the platen roller 42 rotates. On the other hand, the ink ribbon R is unwound from the ribbon unwinding reel 44 by the rotation of the ribbon take-up reel 45, overlaps the cutting tape T at the print head 36 (platen roller 42), and then moves to the ribbon take-up reel 45. It will be wound up. At this time, the ink on the ink ribbon R is peeled off into a desired character shape by the thermal transfer operation of the print head 36 and transferred to the cutting tape T.
[0093]
As described above, the platen roller 42 constitutes a part of the tape feeding mechanism 22 that feeds the cutting tape T along the traveling path A, and performs printing on the cutting tape T in cooperation with the print head 36. Part of the mechanism 23 is configured. The heat-transferred cutting tape T forms a desired print image on the tape body Tb, and the printed portion passes through the feed slit 47 of the cartridge case 41 and is sent to the travel path A, which is full. It faces the cutting mechanism 24.
[0094]
By the way, in the tape cartridge 5 for composite processing, six types of tapes of 6 mm, 9 mm, 12 mm, 18 mm, 24 mm, and 36 mm are prepared as the width of the cutting tape T (P tape) to be accommodated. 5 has different thicknesses. In this case, depending on the thickness of the tape cartridge 5 and the storing form of the cutting tape T, the respective tape cartridges 5 to be mounted on the cartridge mounting portion 19 are configured such that their mounting positions coincide with each other at the center position in the mounting direction. That is, the plurality of types of cutting tapes T are set with their respective centers in the width direction matching.
[0095]
Further, a tape width detection mechanism for detecting the tape width of the cutting tape T accommodated in the tape cartridge 5 is provided on the back wall of the cartridge mounting portion 19. The tape width detection mechanism includes, for example, a tape width detection switch 370 that selectively engages an uneven portion (detected portion) formed on the bottom of the cartridge case 41 from the mounting direction (see FIG. 14). ). Based on the detection result of the tape width detection mechanism, a tape width restriction mechanism 29, which will be described later, is controlled, and the position of the traveling cutting tape T is restricted in the width direction.
[0096]
Next, the tape feeding mechanism 22 will be described in detail with reference to FIG. 3 and FIGS. As shown in FIG. 8 in particular, the tape feed mechanism 22 includes a feed drive motor 81 that can rotate forward and backward, the platen roller 42 that rotates forward by the feed drive motor 81, and a cutting tape using the feed drive motor 81 as a drive source. It has a forward / reverse feed mechanism 82 that forwards and reverses T, and a gear train power transmission portion 83 that transmits the rotational power of the feed drive motor 81 to the platen roller 42 and the forward / reverse feed mechanism 82. The feed drive motor 81 is configured by a stepping motor, and is disposed on the outer surface of the base frame 56 of the apparatus frame 4.
[0097]
The platen roller 42 rotates in the forward direction (clockwise in FIG. 3), and also serves as a feeding roller that feeds the cutting tape T from the tape cartridge 5 and feeds it to the travel path A (tape feeding mechanism, tape feeding). Mechanism, printing system feed mechanism). A platen clutch mechanism 85 is provided between the platen roller 42 and the feed drive motor 81 so as to prevent the cutting tape T from being fed out of the tape cartridge 5 during half-cut processing. Thus, the power to the platen roller 42 is interrupted (described later with reference to FIG. 8).
[0098]
As shown in FIG. 3, the forward / reverse feed mechanism 82 (main feed mechanism, cut system feed mechanism) includes a grip roller 91 disposed on a travel path A on the downstream side of the platen roller 42, and a downstream side of the grip roller 91. The first pulling roller 92 disposed in the travel path A and the second pulling roller 93 disposed in the branch path B on the upstream side of the grip roller 91 are provided. The grip roller 91 sandwiches the cutting tape T and feeds it. The first pulling roller 92 and the second pulling roller 93 are set so that the tape feed amount is slightly larger than the tape feed amount of the grip roller 91, and the cutting tape T (tape piece) is fed by slip rotation. A tension is applied to this.
[0099]
As shown in FIG. 8, the grip roller 91 is configured to be driven to rotate in forward and reverse directions by a feed drive motor 81. On the other hand, both the first and second tension rollers 92 and 93 are intermittently connected by first and second clutch mechanisms 95 and 96 interposed between the feed drive motor 81 and the cutting tape T is applied to the grip roller 91. The drive rotation is performed only in one direction of the advance feeding. That is, the forward / reverse feed mechanism 82 controls the tape feed amount by using the grip roller 91 as a main forward / reverse feed roller (main feed roller), and cooperates with the first and second pulling rollers 92 and 93 to feed the cutting tape T. Forward / reverse feed.
[0100]
Specifically, when the grip roller 91 rotates in the forward direction (forward movement feed), the forward driving power is transmitted to the first pulling roller 92 via the first clutch mechanism 95 to rotate it forward, and the first The power for forward movement to the second pulling roller 93 is cut off via the two-clutch mechanism 96 so that it can freely rotate. On the other hand, when the grip roller 91 rotates in the reverse direction (reverse feed), the power for return movement is transmitted to the second pulling roller 93 through the second clutch mechanism 96 to rotate it in the reverse direction, and the first clutch mechanism. The power for backward movement to the first pulling roller 92 is interrupted via 95 so that it can freely rotate.
[0101]
As shown in FIGS. 3, 6, 8, and 11, the grip roller 91 includes a grip drive roller 98 and a grip driven roller 99 that face each other across the travel path A, and feeds the grip drive roller 98 to a drive motor. 81 is connected.
[0102]
The grip driven roller 99 (99a, 99b, 99b) is a free roller that rotates in accordance with the rotation of the grip drive roller 98. The grip follower roller 99 is supported by a lower roller support portion 68 of the operation frame 59 extending in the left-right direction between the side frames 57, and 3 in the axial direction so as to correspond to a wide variety of cutting tapes T. The pieces are distributed.
[0103]
Each grip follower roller 99 is disposed in each mounting portion 104 formed by cutting the lower roller support portion 68 into a window shape, and is supported on both ends of the mounting portion 104 and is rotatable on the roller shaft 109. And a pair of coil springs 110 interposed between both ends of the roller shaft 109 and the bottom of the attachment portion 104 (see FIG. 11). By this coil spring 110, the grip driven roller 99 is biased toward the grip driving roller 98 via the roller shaft 109.
[0104]
In this case, of the three grip driven rollers 99, the left and right two (99b, 99b) are arranged at each mounting portion 104 in a state of slightly protruding toward the grip drive roller 98 with respect to the center grip driven roller 99a. It is installed. That is, the outer peripheral surface of the roller main body 105 of each grip driven roller 99 slightly protrudes from the attachment portion 104 (see FIG. 3), but the protrusion amounts of the two left and right (99b) compared to the center (99a) are as follows: Designed large.
[0105]
For this reason, the left and right grip driven rollers 99b and 99b (edge side rollers) are in strong rolling contact with the wide cutting tape T (S tape), and the center grip driven roller with the narrow cutting tape T (P tape). 99a (intermediate roller) is in rolling contact. Note that the grip driven roller 99 is a first grip corresponding to an S tape in which only three of the left and right sides of the gripping roller 99 are separated from each other by a roller separation mechanism described later having an operation frame 59. It is configured to be movable between the position and the second grip position corresponding to the P-tape on the back side of the first grip position where all three are in rolling contact.
[0106]
The grip drive roller 98 is composed of a roller shaft 101 rotated by a feed drive motor 81 and a roller main body 102 attached to the roller shaft 101, and both end portions of the roller shaft 101 are both rotatable to a side frame 57. Has been supported.
[0107]
The roller main body 102 corresponds to the three grip driven rollers 99, and a central roller portion 106 located in the center in the axial direction and a pair of outer roller portions 107 arranged symmetrically with a gap outside the central roller portion 106. And the roller shaft 101 is shared. The outer peripheral surfaces of the central roller portion 106 and the outer roller portions 107 where the grip driven roller 99 rolls are roughened by knurling or the like.
[0108]
The central position in the axial direction of the central roller portion 106 coincides with the intermediate position in the width direction of the cutting tape T, and an annular groove is formed in the circumferential direction. A total of five intermediate bridges 108 extending in the axial direction including the annular groove and the gaps between the central roller portion 106 and the outer roller portions 107 are disposed. The intermediate bridge 108 prevents the leading end of the cutting tape T sandwiched between the grip driven roller 99 from being bitten here. The intermediate bridge 108 is formed on a receiving plate 281 having a roller opening 283 that escapes the roller body 102 of the grip driving roller 98 (described later).
[0109]
As shown in FIGS. 3, 6, 8, and 11, the first pulling roller 92 includes a first driving roller 111 and a first driven roller 112 that face each other across the traveling path A. The first drive roller 111 includes a roller shaft 114 rotated by a feed drive motor 81 and a roller main body 115 attached to the roller shaft 114, and both end portions of the roller shaft 114 are rotatable to the side frame 57. Both ends are supported.
[0110]
The first driven roller 112 includes a roller shaft 117 that is supported at both ends by the upper roller support portion 69 of the operation frame 59, and a roller body 118 that is rotatably mounted on the roller shaft 117. Similar to the grip driven roller 99, the first driven roller 112 is urged toward the first drive roller 111 via the left and right ends of the roller shaft 117 by a pair of left and right coil springs 119 built in the upper roller support portion 69. (See FIG. 11).
[0111]
Therefore, the outer peripheral surface of the roller main body 118 is supported in a state of slightly protruding from the upper roller support portion 69, and the protrusion amount is substantially the same as the protrusion amount of the roller main body 105 of the center grip driven roller 99a. Is set to The roller body 118 has a length substantially the same as that of the roller body 105 of the center grip driven roller 99a.
[0112]
As shown in FIGS. 3, 5, 8, and 11, the second pulling roller 93 includes a second driving roller 121 and a second driven roller 122 that face each other across the branch path B (cutting tape T). ing. Similar to the first drive roller 111, the second drive roller 121 includes a roller shaft 124 that is rotated by the feed drive motor 81, and a roller body 125 that is attached to the roller shaft 124, and both end portions of the roller shaft 124. However, the side frame 57 is rotatably supported by both sides.
[0113]
The second driven roller 122 is held by a substantially “U” -shaped roller holding portion 127 fixed to the support shaft 126, and the support shaft 126 is supported by both side frames 57. In the second driven roller 122, a roller main body 129 is rotatably supported by a pair of protrusions 128 provided inwardly on the roller holding portion 127. The roller body 129 is configured to have substantially the same length as the roller body 105 of the center grip driven roller 99a. The roller main bodies (115, 118, 125, 129) of the first pulling roller 92 and the second pulling roller 93 have their axial center positions aligned with the center position of the tape width of the cutting tape T. ing.
[0114]
Although details will be described later, the first driven roller 112 moves away from and contacts the cutting tape T together with the grip driven roller 99 by the roller separating mechanism. In addition, the second driven roller 122 is moved to and away from the cutting tape T through the rotation of the support shaft 126 by the roller separating mechanism in conjunction with the movement of the grip driven roller 99 and the first driven roller 112 and the like. Moving.
[0115]
Next, the power transmission system of the tape feeding mechanism 22 will be described with reference to FIGS. The power transmission unit 83 that transmits the rotational power of the feed drive motor 81 includes an output gear 141 fixed to the output shaft of the feed drive motor 81, a print-side gear train 142 that branches and inputs power from the output gear 141, and a cut The side gear train 143 is disposed on the outer surface of the side frame 57 and the like.
[0116]
The print-side gear train 142 includes a platen gear 145 that is rotatably attached to the platen drive shaft 37, a ribbon take-up gear 146 that is rotatably attached to the ribbon take-up shaft 38, and a platen gear 145 and a ribbon take-up. Two intermediate transmission gears 147 and 147 interposed between the gear 146 and a platen switching gear 148 that meshes with the output gear 141 and selectively meshes with the platen gear 145 are provided. The platen gear 145 rotates the platen roller 42 while the ribbon take-up gear 146 rotates the ribbon take-up reel 45.
[0117]
The platen switching gear 148 is rotatably attached to the distal end portion of the clutch arm 150 that is rotatably supported by the output shaft of the feed drive motor 81, and the large gear 151 coaxially meshed with the output gear 141. 151 and a small gear 152 fixed to 151. The small gear 152 meshes with the platen gear 145 so as to be detachable, and the large gear 151 always meshes with the output gear 141, and always rotates as the feed drive motor 81 rotates.
[0118]
The platen clutch mechanism 85 is configured by the clutch arm 150, the output gear 141, the platen switching gear 148, and the switching unit 71 of the operation frame 59 described later. When the feed drive motor 81 rotates in the forward direction while the clutch arm 150 and the switching unit 71 are not engaged, the clutch arm 150 rotates with the output shaft, and the small gear 152 is connected to the platen gear 145, thereby feeding the drive motor. 81 is transmitted to the platen drive shaft 37 and the ribbon take-up shaft 38 to rotate them.
[0119]
On the contrary, during the half-cut process when the feed drive motor 81 rotates in the reverse direction, the switching unit 71 and the clutch arm 150 are engaged, and the platen clutch mechanism 85 (the small gear 152) is forcibly separated from the platen gear 145. Thus, power transmission to the printing-side gear train 142 is interrupted regardless of whether the feed drive motor 81 is forward or reverse. As a result, the platen roller 42 does not rotate clockwise in the illustrated half cut process and the cutting tape T is not fed out of the tape cartridge 5.
[0120]
Further, since the platen clutch mechanism 85 has such a structure, when a human external force is applied to pull out the tip of the cutting tape T from the tape discharge port 32 when the feed drive motor 81 is stopped, the small gear 152 is applied. Since torque is applied, the clutch arm 150 rotates in the reverse direction (FIG. 8: counterclockwise), and the small gear 152 is separated from the platen gear 145.
[0121]
Thus, since the gear train from the platen gear 145 to the ribbon take-up gear 146 is independent of the other gear trains, the cutting tape T is forced out of the tape cartridge 5 by human external force. In addition, the winding of the ink ribbon R in the tape cartridge 5 can be permitted. Accordingly, it is possible to appropriately prevent jamming of the ink ribbon R inside the tape cartridge 5 and jumping out from the feeding slit 47 to the outside of the tape cartridge 5.
[0122]
The cut-side gear train 143 includes a grip gear 161 that rotates the grip roller 91, a first tension gear 162 that rotates the first tension roller 92, a second tension gear 163 that rotates the second tension roller 93, and a grip gear. 161, a first switching gear 164 that meshes with the first tension gear 162 in a detachable manner, a second switching gear 165 that meshes with the grip gear 161 and detachably engages with the second tension gear 163, a grip gear 161, and A grip transmission gear 166 that meshes with the output gear 141 and an anti-tension gear 169 that meshes with the second tension gear 163 and rotates an anti-tension roller 131 described later.
[0123]
The grip gear 161 is fixed to the end of the roller shaft 101 of the grip drive roller 98, transmits the rotational power of the feed drive motor 81 to the grip drive roller 98, and rotates it. The grip gear 161 is always connected to the output gear 141 via the grip transmission gear 166, and always rotates in the forward and reverse directions as the feed drive motor 81 rotates in the forward and reverse directions.
[0124]
The first tension gear 162 is pivotally supported at the end of the roller shaft 114 of the first drive roller 111, transmits the rotational power of the feed drive motor 81 to the first drive roller 111, and rotates it. In this case, a first torque spring 171 is provided between the first tension gear 162 and the roller shaft 114 to rotate the roller body 115 with a constant torque when the grip roller 91 is rotated forward.
[0125]
Similarly, the second tension gear 163 is pivotally supported at the end of the roller shaft 124 of the second drive roller 121, and transmits the rotational power of the feed drive motor 81 to the second drive roller 121 to rotate it. . A second torque spring 172 is provided between the second tension gear 163 and the roller shaft 124 to rotate the roller body 125 with a constant torque when the grip roller 91 is reversely rotated.
[0126]
The first switching gear 164 is rotatably attached to the distal end portion of the first arm 167 of the carrier 160 that is rotatably supported by the roller shaft 101 that is coaxial with the grip gear 161. Similarly, the second switching gear 165 is rotatably attached to the distal end portion of the second arm 168 of the carrier 160. That is, the grip gear 161 is a sun gear, the first and second switching gears 164 and 165 are planetary gears, and the first and second arms 167 and 168 are planetary gear train-like structures. .
[0127]
Accordingly, the first arm 167, the first switching gear 164, and the grip gear 161 constitute the first clutch mechanism 95 that switches the power transmission to the first tension gear 162. Similarly, the second arm 168, the second The switching gear 165 and the grip gear 161 constitute the second clutch mechanism 96 that switches power transmission to the second tension gear 163. The first arm 167 and the second arm 168 can be separated from each other by providing a stopper on the idle side.
[0128]
When the feed drive motor 81 rotates in the forward direction (FIG. 8: clockwise rotation), the grip gear 161 rotates in the forward direction, and the carrier 160 that rotates clockwise rotates the first switching gear 164 of the first clutch mechanism 95 to the first position. The first driving roller 111 is rotated by being connected to the first pulling gear 162. In this state, the second switching gear 165 of the second clutch mechanism 96 is separated from the second tension gear 163, and the second switching gear 165 is disengaged from the second tension gear 163 and rotates idly. That is, power transmission to the second pulling roller 93 is interrupted via the second clutch mechanism 96, while the drive rollers 98 and 111 of the grip roller 91 and the first pulling roller 92 rotate in the forward direction.
[0129]
On the other hand, when the feed drive motor 81 reversely rotates (FIG. 8: rotates counterclockwise), the grip gear 161 rotates in the reverse direction, and the carrier 160 that rotates counterclockwise rotates the second switching gear of the second clutch mechanism 96. 165 is connected to the second tension gear 163 to rotate the second drive roller 121. In this state, the first switching gear 164 of the first clutch mechanism 95 is separated from the first tension gear 162, and the first switching gear 164 is disengaged from the first tension gear 162 and rotates idly. That is, power transmission to the first pulling roller 92 is interrupted via the first clutch mechanism 95, and the drive rollers 98 and 121 of the grip roller 91 and the second pulling roller 93 are rotated in reverse. At this time, the sticking prevention roller 131 rotates clockwise as shown in FIG.
[0130]
In this way, power is not transmitted to the first or second pulling rollers 92 and 93 on the downstream side in the feed direction as viewed from the grip roller 91 via the first clutch mechanism 95 and the second clutch mechanism 96. ing. Accordingly, a suitable tension can be applied to the cutting tape T in cooperation with the tension rollers 92 and 93 while controlling the forward and reverse feeding of the cutting tape T by the grip roller 91. For this reason, the half cut process of the cutting tape T by cooperation with the tape feed mechanism 22 and the half cut mechanism 25 can be performed stably.
[0131]
By the way, since the cutting resistance acts on the cutting tape T during the half-cut processing, it is preferable to forward and reverse feed the cutting tape T between the various rollers 91, 92, 93. In this case, due to the high rigidity, when the various rollers 91, 92, 93 are brought into rolling contact with the already cut portion of the tape body Tb, there is a problem that the already cut portion is easily peeled off from the release paper Ta. Therefore, the tape feeding mechanism 22 cuts the driven rollers 99, 112, and 122 that are in rolling contact with the tape body Tb side of the grip roller 91, the first pulling roller 92, and the second pulling roller 93 according to the rigidity of the cutting tape T. The roller separation / contact mechanism described above that separates from / contacts the tape T is provided.
[0132]
As described above, the roller separation / contact mechanism moves the grip follower roller 99 in three stages, and moves the first follower roller 112 and the second follower roller 122 apart from each other in conjunction with this. In this case, when the grip driven roller 99 is in the separated position, the first and second driven rollers 112 and 122 are separated from the first and second drive rollers 111 and 121, respectively, but the first corresponding to the S tape is used. In the state of the grip position, only the both ends of the S tape in the width direction are sandwiched by the grip roller 91, and the first and second driven rollers 112 and 122 are maintained in the separated state.
[0133]
On the other hand, in the state of the second grip position corresponding to the P tape, the first and second driven rollers 112 and 122 are in contact with the first and second drive rollers 111 and 121, respectively, and the grip roller 91 and the first and second rollers are in contact with each other. The P tape is held between the pulling rollers 92 and 93. As described above, since the various rollers 91, 92, 93 are separated from each other according to the rigidity of the cutting tape T, the stripped portion is prevented from being peeled from the S tape to maintain the tape running performance. With respect to the tape, it is possible to effectively prevent the skew of the tape during the half-cut process and the bending of the intermediate portion of the tape.
[0134]
As shown in FIGS. 5, 6, and 8, the operation frame 59 that constitutes the roller separation / contact mechanism includes a lower roller support portion 68 and an upper roller support portion 69 that are parallel to each other, and is laterally moved between the side frames 57. The support frame 61 and the operation lever 62 branching from one end portion of the support frame 61 and extending in the front-rear direction are integrally formed, and one end portion of the operation lever 62 is a frame operation of the interlocking mechanism 28 described later. The cam 355 is connected.
[0135]
When the operation frame 59 receives power from the interlock mechanism 28 via the operation lever 62, the grip driven roller 99 has three states: a separated position, a first grip position, and a second grip position with respect to the grip drive roller 98. As configured, it rotates in the front-rear direction.
[0136]
The support frame 61 is formed with engaging hole portions 63 serving as a rotation center portion of the operation frame 59 in the bent side plate portions 64 and 64, respectively. Further, a relief opening 67 is cut out in a substantially square shape along the extending direction of the base surface between the lower roller support portion 68 and the upper roller support portion 69 in the support frame 61. The cutting tool 181 of the cutting mechanism 25 is inserted through the roller support portions 68 and 69 so as to pass therethrough. Therefore, the support frame 61 is not contacted in the moving range of the cutting tool 181.
[0137]
The operation lever 62 has a plate-like shape extending along the left side frame 57, a switching portion 71 extending toward the feed drive motor 81, and a bending portion 72 formed at a right angle near the switching portion 71. An operation input unit 73 extending to the opposite side of the switching unit 71 and connected to the interlocking mechanism 28; a forward abutting unit 74 protruding upward from an intermediate portion between the switching unit 71 and the operation input unit 73; It is comprised integrally with.
[0138]
The switching unit 71 is configured to be freely engaged with and disengaged from the clutch arm 150, and constitutes the platen clutch mechanism 85 together with the clutch arm 150 and the like. The forward abutting portion 74 rotates the slide cutter 182 of the full cut mechanism 24 to the cutting operation position (described later with reference to FIGS. 5 and 7).
[0139]
The bending portion 72 is configured to be freely engaged with and disengaged from a rotation lever 130 fixed to the end of the support shaft 126, and the second driven roller 122 is moved away from and in contact with the second drive roller 121 via the rotation lever 130. Let That is, a part of the roller attaching / detaching mechanism for connecting / disconnecting the second pulling roller 93 from the bending portion 72, the rotating lever 130 and the support shaft 116 is configured.
[0140]
Both ends of the support shaft 126 are supported by the side frame 57 so as to freely rotate, and rotate together with the rotation lever 130. When the rotation lever 130 is disengaged from the bent portion 72, the second driven roller 122 comes into contact with the second drive roller 121 by the return spring 123 wound around the support shaft 126. On the other hand, when the operation frame 59 rotates and the bent portion 72 engages with the rotation lever 130, the rotation lever 130 rotates the support shaft 126 against the return spring 123, and the roller holding portion 127 is moved. Accordingly, the second driven roller 122 is separated from the second drive roller 121. Note that one end of the return spring 123 is hooked to a stopper 120 that regulates the position of the rotation end of the support shaft 126.
[0141]
Therefore, when power is input from the interlock mechanism 28 via the operation input unit 73, the operation frame 59 rotates around the engagement hole 63, and the grip driven roller 99 and the first first frame via the support frame 61. The driven roller 112 is moved from the separated position to the first grip position or the second grip position. At this time, the switching unit 71 cuts off the power from the feed drive motor 81 to the platen roller 42 via the clutch arm 150 at both the first and second grip positions, and the forward abutting unit 74 is connected to the slide cutter 182. It is set in a state where it can be hit. Further, the bent portion 72 is configured to be disengaged from the rotating lever 130 only at the second grip position.
[0142]
In this way, the interlock mechanism 28 causes the grip driven roller 99 and the first driven roller 112 to move away from and in contact with the drive rollers 98 and 111 via the support frame 61, and in conjunction with this, the operation lever 62 is moved. Accordingly, the second driven roller 122 moves away from and in contact with the second drive roller 121. Accordingly, an appropriate reciprocating path C corresponding to the S tape and the P tape is established, and the cutting tape T can be appropriately half-cut. Although not shown, the operation frame 59 is locked with a spring for positively rotating the operation frame 59.
[0143]
Further, as described above, the two left and right grip driven rollers 99b and 99b are spaced apart corresponding to the tape width of 100 mm of the S tape, and are configured to roll-contact with the P tape having a maximum width of 36 mm. If a wider P tape is prepared, the grip force of the grip roller 91 is larger on the left and right than the center, but the tape running performance is not hindered. In addition, as will be described later, the grip roller 91 and the first pulling roller 92 are used until the leading end of the cutting tape T sent from the upstream side of the travel path A reaches the grip roller 91 and the first pulling roller 92. In contrast, a separated state (non-grip state) is maintained.
[0144]
By the way, as described above, the operation frame 59 receives power for rotation from the operation lever 62 arranged on one side, but the grip driven roller 99 and the first driven roller 112 supported in parallel to the support frame 61 It is preferable to contact uniformly in the width direction of the cutting tape T also for tape running property. Therefore, the guide shaft 65 and the bush 66 are used in a structure in which the operation frame 59 is supported on both sides by the side frame 57 through the engagement hole 63.
[0145]
Here, the support structure around the operation frame 59 (frame member), the guide shaft 65, the bush 66, and the side frame 57 will be described in detail with reference to FIGS. The guide shaft 65 is a carriage guide shaft that guides the reciprocating motion of the carriage 184 in which the cutting tool 181 and the slide cutter 182 are mounted in the left-right direction, and is effectively used for the support structure of the operation frame 59.
[0146]
The guide shaft 65 extends in parallel with the axis of the grip follower roller 99 and the like, and has a round bar portion 75 having a circular cross section for guiding the reciprocation of the carriage 184, and the guide shaft 65 continuously from both ends of the round bar portion 75. And an anti-rotation portion 76 serving as an outer end portion of the. The anti-rotation portion 76 is formed in an oblong shape with a horizontally long cross section corresponding to the engagement hole portion 63, with both opposing ends cut into a semicircular arc shape. The guide shaft 65 is inserted into the engagement hole 63 in a loosely fitted state in a state where the both rotation stoppers 76 are aligned with the two engagement holes 63 in the horizontal direction.
[0147]
In each side frame 57, a fitting hole 77 for attaching the bush 66 from the outside is formed at a position to be a rotation center of the operation frame 59. Then, the bush 66 is fitted into the fitting hole 77, the bush 66 is attached to the engaging hole 63 of the operation frame 59 in a non-rotating state, and the anti-rotating portion 76 of the guide shaft 65 is attached to the bush 66 in a non-rotating state. Accordingly, the operation frame 59, the guide shaft 65, and the bush 66 are supported by the side frame 57 so as to be rotatable together.
[0148]
The bush 66 includes a body portion 501 having a circular outer peripheral surface, a fitting portion 502 that is located at the distal end portion of the body portion 501 and is chamfered so that the outer peripheral surface has a substantially oval shape, and the body portion 501 is provided with a predetermined shape from the front end side. A mounting portion 503 that is formed through the depth, three flange portions 504 that protrude in the radial direction from the base end portion of the body portion 501 and are mutually displaced in the circumferential direction, and three flange portions 504; It is integrally formed with three retaining portions 505 having a predetermined gap and projecting in the radial direction from the body portion 501 and displaced from each other in the circumferential direction at an equal pitch.
[0149]
The three flange portions 504 and the three retaining portions 505 are formed so as to be displaced from each other in the circumferential direction, and each flange portion 504 is formed in a slightly larger rectangle than each retaining portion 505. Has been. In other words, each retaining portion 505 is formed facing the gap between the flange portions 504. Further, the flange portion 504 and the retaining portion 505 are separated by the thickness of the side frame 57, and the side frame 57 can be sandwiched between the inner surface of the flange portion 504 and the outer surface of the retaining portion 505. ing.
[0150]
On the other hand, the fitting holes 77 have a circular annular hole 78 having an inner peripheral surface corresponding to the body 501, and project from the annular hole 78 in the radial direction and are displaced from each other in the circumferential direction at an equal pitch. The three notches 79 are formed. The diameter of the annular hole 78 and the diameter of the engagement hole 63 are formed larger than the diameter of the guide shaft 65 (round bar 75). For this reason, the guide shaft 65 can be inserted between the side frames 57 by inserting the engaging hole portion 63 into the fitting hole 77 from the outside.
[0151]
The three notches 79 are formed in a rectangular shape at a position corresponding to the three retaining portions 505 and in a size, and in a state where the three notched portions 79 and the three retaining portions 505 are matched. Each retaining portion 505 can be inserted through each notch 79, and the bush 66 can be attached to and detached from the fitting hole 77. When the bush 66 is fitted, the flange portion 504 functions as a stopper to the inside of the side frame 57.
[0152]
When the bush 66 is fitted and mounted, the bush 66 is allowed to rotate in the fitting hole 77 between the body 501 of the bush 66 and the annular hole 78 of the fitting hole 77. Within the rotation angle range of 120 degrees, the retaining portion 505 and the flange portion 504 sandwich the side frame 57 around the fitting hole 77. As a result, the bush 66 is rotatably supported by the side frame 57 in a state in which the bush 66 is prevented from falling off from the side frame 57 in each direction.
[0153]
The mounting portion 503 of the bush 66 is configured at the shaft center of the bush 66, and has an installation depth corresponding to the anti-rotation portion 76 of the guide shaft 65, and has a mounting depth at which the mounting portion can be mounted, and an inner peripheral surface 507 having a substantially oval cross section. It consists of The bush 66 having the rotation preventing portion 76 mounted on the mounting portion 503 has its tip end surface 508 in contact with the end surface of the round bar portion 75 of the guide shaft 65 so that it can rotate integrally with the guide shaft 65.
[0154]
The fitting portion 502 is configured at the shaft center of the bush 66, and has a substantially oval outer peripheral surface that can be fitted to the engagement hole portion 63. The bush 66 in which the engagement hole 63 is fitted in the fitting portion 502 is in contact with the end surface of the support frame 61 around the engagement hole 63 so that the inner surface of the retaining portion 505 can rotate integrally with the support frame 61. It becomes. That is, the retaining portion 505 is formed to have a thickness corresponding to the gap between the side plate portion 64 in which the engagement hole portion 63 is formed and the side frame 57. Note that the bottom of the mounting portion 503 is positioned on the proximal end side of the bush 66 beyond the mounting position by the mounting portion 502.
[0155]
Here, a procedure for assembling the guide shaft 65, the operation frame 59, and the bush 66 to the side frame 57 will be briefly described. First, the operation frame 59 is positioned at the assembly position between the side frames 57, the guide shaft 65 is introduced from the outside of the one fitting hole 77 and positioned between the side frames 57, The rotation stoppers 76 are inserted into the respective engagement holes 63. At this time, the horizontally long oval shape of the rotation stopper 76 and the engagement hole 63 of the guide shaft 65 is slightly inclined with respect to the side frame 57.
[0156]
Subsequently, the bush 66 that is inclined so as to match the direction of the substantially oval shape such as the engagement hole 63 is caused to face the fitting hole 77 from the outside of the side frame 57. Then, the bushes 66 are fitted into the fitting holes 77 so as to be pushed inside the side frames 57, and the anti-rotation portions 76 of the guide shafts 65 are attached to the attachment portions 503 and the fitting portions. Each engagement hole 63 of the operation frame 59 is fitted in 502, and each bush 66 is rotated in each fitting hole 77.
[0157]
As a result, each of the bushes 66 with the guide shaft 65 and the operation frame 59 mounted in a non-rotating state is rotated in each fitting hole 77, and each of the bushes 66 is provided between the three retaining portions 505 and the flange portions 504. Then, the side frame 57 around the fitting hole 77 is sandwiched in the circumferential direction to complete the assembling operation (see FIGS. 5 and 7).
[0158]
Therefore, the operation frame 59 to which the rotational power is input from one end side is rotated by transmitting the rotational power to the other end side via the both bushes 66 and the guide shaft 65. Accordingly, the operation frame 59 can be rotated horizontally without being twisted in the length direction regardless of its strength. Therefore, the driven roller 99 (separating member) such as the grip roller 91 is cut by the cutting tape. It is possible to make contact with T parallel to each other, and it is possible to appropriately ensure the traveling property of the cutting tape T.
[0159]
Note that the bushes 66 that support the guide shaft 65 and the operation frame 59 so as to rotate together are rotated with respect to the side frames 57 within a rotation angle range in which the driven roller 99 such as the grip roller 91 is moved away from or in contact. It is supported so that it can rotate freely without being stopped. Moreover, although the three notches 79 etc. were formed in the circumferential direction, it cannot be overemphasized that it can form by arbitrary plural numbers which is not restricted to this.
[0160]
In addition, although the workability of the assembly is deteriorated, the bush 66 may be omitted from the support structure of the operation frame 59. In this case, the guide shaft 65 passes through the both side plate portions 64 and passes between the left and right side frames 57, but each of the anti-rotation portions 76 is engaged with each of the engagement hole portions 63 in a non-rotating state. In addition, each of the fitting holes 77 is pivotally supported.
[0161]
Further, as will be described later, the separation and movement of each driven roller 99 such as the grip roller 91 is performed prior to the cutting process by the full cut mechanism 24. As a result, the cutting tape T can be cut in a state where both ends in the feeding direction are regulated (clamped) by the print head 36 and the platen roller 42 on the upstream side of the travel path A and by the grip roller 91 or the like on the downstream side. The cutting tape T can be cut stably and fully.
[0162]
Next, the tape storage processing unit 30 will be described in detail with reference to FIG. The tape storage processing unit 30 is configured adjacent to the cartridge mounting unit 19 and on the upper side thereof. The tape storage processing unit 30 prevents the cutting tape T returning (reversely feeding) from the backward feeding end of the branch path B from interfering with other mechanisms including the forward / reverse feeding mechanism 82 during the half cut process. The cutting tape T is accommodated in the inner space 134 from the tail end side (return feed end side) and accommodated.
[0163]
The internal space 134 is configured by a tape guide surface 137 a of a storage case 135 disposed in the upper rear portion of the apparatus main body 3 and an upper surface 54 a of the mounting frame 54. The tape guide surface 137a is formed of a substantially semicircular circular arc surface, and the upper surface 54a of the mounting frame 54 is formed by curving a portion connected to the tape guide surface 137a in an arc shape. That is, the inner surface constituting the internal space 134 has an arc whose cross section is close to a circle as a whole.
[0164]
The storage case 135 is provided so that the rear half of the opening / closing lid 18 can be accommodated in a widely cut-out portion, and constitutes an outline of the tape processing apparatus 1 as a part of the apparatus case 2 together with the opening / closing lid 18. Opening and closing operations are integrated (see FIG. 2). The storage case 135 is configured to be detachable from the apparatus main body 3.
[0165]
The case outer surface 136 of the storage case 135 is formed in a cross-sectional dome shape so as to rise from the rear upper surface of the opening / closing lid 18 in the closed state, and has a curved surface following the winding of the cutting tape T. The case outer surface 136 is formed on the extension of the forward feed end of the reciprocating path C. The rear surface side of the case outer surface 136 extends in the vertical direction, and the front surface side thereof faces the tape discharge port 32. Yes. As shown in FIG. 1, the tape discharge port 32 is formed between the end of the storage case 135 and the opening edge of the device case 2.
[0166]
Therefore, the portion of the cutting tape T that is fed upward from the tape discharge port 32 is appropriately guided to the case outer surface 136 on the tape main body Tb side by its curl and gravity so as to smoothly go to the rear of the storage case 135. It has become.
[0167]
The case inner surface 137 on the rear half side of the storage case 135 constitutes the tape guide surface 137a. The guide end portion 139 of the tape guide surface 137a is located at a position facing the branch path B with a slight gap between the cutting tape T and a position where the winding of the cutting tape T accommodated in the internal space 134 is completed. It is extended. In the gap between the guide terminal portion 139 and the branch path B, a sticking prevention roller 131 (auxiliary feed roller) for assisting feeding to the tail end side of the cutting tape T is disposed facing the internal space 134. ing.
[0168]
The sticking prevention roller 131 functions so as to eliminate the adhesion of the S tape to the tape guide surface 137a, and promotes the circulation of the cutting tape T in the internal space 134. That is, the sticking prevention roller 131 is rotated in the clockwise direction shown in FIG. 3 by the power transmission unit 83 (see FIG. 8), and supplementarily in the direction of winding the tail end side of the cutting tape T into the inner space 134 side. The feeding and cutting tape T is prevented from stretching on the tape guide surface 137a.
[0169]
The anti-sticking roller 131 includes a roller shaft 132 that is supported at both ends by a side frame 57 of the apparatus frame 4 so as to be rotatable, and a pair of left and right roller bodies 133 attached to the roller shaft 132. (See FIGS. 7 and 11). The sticking prevention gear 169 is fixed to the end of the roller shaft 132, and the sticking prevention roller 131 is returned to the forward / reverse feed mechanism 82 by the second clutch mechanism 96 (see FIG. 8). When the cutting tape T is rotated in synchronism with the dynamic feed (clockwise driving shown in FIG. 3) and the cutting tape T is forwardly fed, the power transmission is interrupted and free rotation is possible.
[0170]
The pair of roller main bodies 133 are spaced apart from and corresponding to the 100 mm-wide S tape, like the two left and right grips 99 (99b), and are in contact with only the S tape. Further, the outer peripheral surface of the roller body 133 is disposed so as to protrude into the internal space 134 from the vertical surface of the guide terminal portion 139. Therefore, the sticking prevention roller 131 can effectively prevent the S tape from coming into close contact with the tape guide surface 137a. In the case of P tape, the roller shaft 132 can prevent the tape tail end from jamming in the apparatus.
[0171]
As described above, the tape storage processing unit 30 effectively utilizes the curl of the cutting tape T so as to store the cutting tape T fed forward and backward in the internal space 134 of the storage case 135 on the tail end side. The leading end side is guided to the case outer surface 136 of the storage case 135. For this reason, even if it is the cutting tape T which has a long elongate hook especially, this can be appropriately half-cut by the space-saving in the apparatus main body 3. FIG. The sticking prevention roller 131 may be configured to be capable of rolling contact with a P tape.
[0172]
Next, the half-cut mechanism 25 and the full-cut mechanism 24 will be described in detail with reference to FIGS. 3, 5, and 6. The cutting tool 181 of the half-cut mechanism 25 and the slide cutter 182 of the full-cut mechanism 24 are mounted on the carriage 184. The cutting tool 181 is located on the downstream side of the grip roller 91, and the slide cutter 182 is the grip roller 91. It is located upstream. The half-cut mechanism 25 and the full-cut mechanism 24 are a reciprocating mechanism 185 (bite moving mechanism) that reciprocates the carriage 184 in a direction orthogonal to the feeding direction of the cutting tape T, and a forward / reverse mechanism that drives the reciprocating mechanism 185. A rotatable carriage motor 186 is shared.
[0173]
The reciprocating mechanism 185 includes the guide shaft 65 serving as a carriage guide shaft that guides the reciprocating motion of the carriage 184 and a carriage lead screw 187. The carriage 184 includes a carriage drive frame 195 having an internal thread portion 189 that is screwed to the carriage lead screw 187, and a carriage body 196 that engages with the carriage drive frame 195. A guide shaft 65 is inserted into the carriage body 196. A guide hole 188 having a circular cross section is formed therethrough, and a cutting tool 181 and a slide cutter 182 are mounted.
[0174]
The guide shaft 65 and the carriage lead screw 187 are positioned in parallel in the front-rear direction, and the carriage lead screw 187 is rotatably supported by both side frames 57 at both ends. The carriage motor 186 is formed of a stepping motor, similar to the feed drive motor 81, and is disposed on the outer surface of the base frame 56 adjacent to the feed drive motor 81. A carriage output gear 191 is fixed to the output shaft of the carriage motor 186, and a carriage gear 192 fixed to the end of the carriage lead screw 187 is engaged with the carriage output gear 191.
[0175]
By forward / reverse rotation of the carriage motor 186, the carriage lead screw 187 rotates forward / reversely via the carriage output gear 191 and the carriage gear 192. By forward / reverse rotation of the carriage lead screw 187, the carriage 184 reciprocates through the carriage drive frame 195 while guiding the carriage body 196 to the guide shaft 65. The reciprocating motion of the carriage 184 shown in FIGS. 5 and 6 will be described as the leftward movement on the carriage motor 186 side as “forward movement” and the rightward movement as “reverse movement”.
[0176]
The carriage drive frame 195 has the female screw portion 189 at the center portion, and a pair of upper and lower sliding contact portions 201 (see FIG. 3) whose top surface protruding in an arc shape from the top portion is in sliding contact with the inner surface of the vertical frame 58. It has an initial position detection unit 202 that bends and extends in an L shape from one sliding contact portion 201. The pair of sliding contact portions 201 function as a rotation stop for the carriage drive frame 195 that moves.
[0177]
The initial position detector 202 is used as a light shielding member for detecting the initial position of the carriage 184 by a photo interrupter (not shown) provided at the initial position on the carriage motor 186 side (forward movement side). Note that the cutout formed in one outer end portion in the extending direction of the vertical frame 58 allows for the replacement of the cutting tool 181.
[0178]
A part of the bottom of the carriage drive frame 195 is formed with an engagement recess 203 that is somewhat cut out, and the engagement protrusion 213 protruding from the carriage body 196 is inserted into the engagement recess 203. (See FIG. 10). The engaging convex portion 213 is restricted in position in the left-right direction by the engaging concave portion 203 and is allowed to tilt in the front-rear direction. Thus, when the carriage drive frame 195 moves, the engagement recess 203 moves the carriage body 196 via the engagement protrusion 213. The engagement recess 203 allows the carriage body 196 to rotate in the front-rear direction about the guide shaft 65 with respect to the carriage drive frame 195.
[0179]
As shown in FIG. 3, the carriage main body 196 has a substantially “L” -shaped cross section with a short-side thick plate portion 211 and a long-side thick plate portion 212. A guide hole 188 is formed so as to penetrate through the end of the first projection, and the engagement projection 213 is formed so as to project from the other end. In addition, a trigger portion 215 that causes the path changing member 331 of the path changing mechanism 27 to act is formed in a portion of the short piece thick plate portion 211 on the backward movement side around the guide hole 188 (described later with reference to FIG. 7). A slide cutter 182 is detachably and pivotably mounted on the end surface, which is the lower surface of the short side thick plate portion 211, while the cutting bit 181 passes through an intermediate portion of the long side thick plate portion 212. It is attached so as to be detachable.
[0180]
An up / down portion 214 is formed through the intersection of the short side thick plate portion 211 and the long side thick plate portion 212, and an up / down lever 216 having a substantially crescent-shaped cross section is inserted into the up / down portion 214. Has been. As shown in FIG. 3, the up / down lever 216 tilts the carriage main body 196 in the front-rear direction around the guide shaft 65, and constitutes an up / down mechanism 218 that separates the cutting tool 181 from the cutting tape T. is doing.
[0181]
The up / down mechanism 218 tilts the carriage main body 196 to a horizontal posture, and tilts the carriage main body 196 to an upwardly rising posture by cutting the cutting tool 181 into the cutting tape T (see FIG. 3). The carriage body 196 and the cutting tool 181 are moved between the non-cut operation position (see FIG. 23) in which the cutting tool 181 is retracted upward from the cutting tape T.
[0182]
The cutting tool 181 can be retracted from the cutting tape T (travel path A) when the slide cutter 182 is cut (full cut) by the up / down mechanism 218, and an appropriate travel path A is ensured. Can do. Further, for example, a cutout shape shown in FIG. 4D can be formed by appropriately retracting the cutting tool 181 from the cutting tape T (traveling route A) during the half-cut process.
[0183]
As shown in FIGS. 5 to 7, the up / down mechanism 218 includes the up / down lever 216 arranged in parallel to the guide shaft 65 and supported at one end by the side frame 57, and the other of the up / down lever 216. A lever frame 221 that fixes the end of the lever 221 and a drive lever 222 that engages with the lever frame 221 to operate the up / down lever 216, and the drive lever 222 is connected to the up / down cam 354 of the interlock mechanism 28. .
[0184]
Corresponding to the up / down lever 216, the up / down portion 214 of the carriage body 196 is positioned between the upper and lower cutting tools 181 and the guide shaft 65, as shown in FIG. A pair of front and rear projections 224 are formed so as to protrude toward the front. The up / down lever 216 tilts the carriage body 196 in the front-rear direction via the pair of convex portions 224.
[0185]
At both ends of the up / down lever 216, a base protrusion 227 which is the center of rotation in the front-rear direction and supported by the side frame 57, and a sliding protrusion 228 which slidably engages with the long hole 238 of the side frame 57, Are formed, and the lever frame 221 is fixed to the base projection on the forward side. Further, one end of a coil spring 226 that urges the up / down lever 216 forward is engaged with the forward-side sliding protrusion 228.
[0186]
By the coil spring 226, the up / down lever 216 constantly urges the cutting tool 181 toward the non-cut operation position via the carriage body 196 (see FIG. 23). In this state, the up / down lever 216 is in contact with the convex portion 224 on the front side of the up / down portion 214.
[0187]
The lever frame 221 is bent from the fixed position of the up / down lever 216 and extends on the back side of the operation lever 62 of the operation frame 59, and protrudes to the front side of the operation lever 62 at its extended end portion. A spring abutting portion 231 is formed. A torsion coil spring 232 wound around the cylindrical boss 239 of the drive lever 222 is abutted against the spring abutting portion 231. The drive lever 222 is formed in a circular arc shape at the tip corresponding to the spring abutting portion 231, and is attached to the device frame 4 by a shaft portion 233 that is coaxial with the cylindrical boss 239 and protrudes on the opposite side. It is rotatably supported (see FIG. 2).
[0188]
The tail end portion of the drive lever 222 extends toward the interlocking motor 351 and is in contact with the up / down cam 354 of the interlocking mechanism 28. Then, when the drive lever 222 rotates about the shaft portion 233 via the up / down cam 354, the torsion coil spring 232 functions to push the spring abutting portion 231 to act the lever frame 221. . As a result, the up / down lever 216 comes into contact with the convex portion 224 on the rear side of the carriage body 196 against the coil spring 226, and moves the cutting tool 181 to the cutting operation position (see FIG. 3). That is, the cutting edge of the cutting tool 181 elastically hits the cutting tape T.
[0189]
When the drive lever 222 is rotated in the reverse direction via the up / down cam 354, the lever frame 221 is rotated and returned by the coil spring 226. The torsion coil spring 232 is cushioned with respect to the spring abutting portion 231. As a result, the cutting tool 181 moves to the non-cut operation position (see FIG. 23).
[0190]
Next, the structure around the slide cutter 182 will be described in detail with reference to FIG. 5 and FIG. The slide cutter 182 has a cutter blade 241 at the tip and is detachably mounted on the carriage body 196, and cuts the cutting tape T when the carriage body 196 moves backward. The slide cutter 182 is rotatably attached to the carriage body 196, and is rotated by a cutter attaching / detaching mechanism 219 using reciprocating motion of the carriage 184 (see FIG. 7).
[0191]
The slide cutter 182 has a blade insert member 246 that rotates the cutter blade 241 from the non-cutting position to the cutting position at the forward end, and a blade member that rotates the cutter blade 241 from the cutting position to the non-cutting position at the return end. 247. On the other hand, the cutter attaching / detaching mechanism 219 includes the reciprocating mechanism 185, the forward abutting portion 74 formed on the operating lever 62 of the operating frame 59, and the backward abutting portion 251 provided on the side frame 57. It is configured.
[0192]
Therefore, when the carriage 184 moved forward by the reciprocating mechanism 185 reaches the vicinity of the end of the forward movement, the blade insert member 246 of the slide cutter 182 hits the forward abutting portion 74, and the cutter blade 241 cuts the slide cutter 182. It rotates to the cutting operation position which becomes a posture (see FIG. 5). On the other hand, when the carriage 184 that moves backward reaches the vicinity of the end of the backward movement, the blade protruding member 247 of the slide cutter 182 hits the backward movement abutting portion 251, and the cutter blade 241 is in the non-cutting posture in the slide cutter 182. It rotates to the non-cutting operation position (see FIG. 7).
[0193]
The slide cutter 182 includes an oblique cutter blade 241, a cutter holder 242 that holds the cutter blade 241 and is rotatably supported by the carriage body 196, and the cutting tape T that is attached to the cutter holder 242 and is cut at a flat tip surface. And a tape pressing member 243 for pressing the portion.
[0194]
The tape pressing member 243 is formed so as to penetrate the central surface, covers the cutter holder 242 and rotates integrally with the cutter holder 242. In addition, a presser spring (torsion coil spring) 244 that biases the tape presser member 243 in the press direction is interposed between the tape presser member 243 and the cutter holder 242, and the tape presser member 243 presses against the cutter holder 242. It is slidably mounted in the direction (front-rear direction). For this reason, the tape pressing member 243 can elastically press the cutting tape T during the cutting operation.
[0195]
The tape pressing member 243 constitutes a tip surface of the tape pressing member 243, and includes a flat portion 255 having a slit hole surrounding the cutting edge of the cutter blade 241, a gently inclined portion 257 continuous from the flat portion 255 to the forward side, and a flat portion 255. It comprises a steeply inclined portion 256 that continues to the return side, and the blade member 247 that continues to the steeply inclined portion 256 and protrudes to the return side.
[0196]
The cutter holder 242 abuts against a bearing 249 that is rotatably supported by the shaft protrusion 197 of the carriage body 196 and a part of the tape pressing member 243 that penetrates, and resists the pressing spring 244 so that the tape pressing member 243 A stopper 245 that regulates the slide end position (presser end position), a spring latch pin 248 that protrudes from the tape presser member 243 side and is fitted with a presser spring 244, and a forward side of the spring latch pin 248 are adjacent to each other. And the above-described blade insert member 246.
[0197]
The bearing portion 249 is formed so as to be slightly displaced toward the forward movement side with respect to the axis of the cutter blade 241, and the cutter holder 242 has a cutting posture and a non-cutting posture with respect to the carriage body 196. It is attached so that it can rotate freely. Further, in the vicinity of the cutter blade 241 of the cutter holder 242, a rotation preventing portion (not shown) that maintains the cutting posture of the cutter blade 241 during the cutting operation is formed. A rotation blocking receiving portion 250 with which the blocking portion is click-engaged is formed.
[0198]
The rotation preventing portion is a thin belt-like portion having a pair of left and right springs with the cutter blade 241 interposed therebetween, and the rotation preventing receiving portion 250 is configured by a pair of protrusions formed on the left and right of the shaft protrusion 197. ing. Therefore, when the slide cutter 182 is rotated to the cutting posture at the forward movement end, the rotation blocking portion is engaged with the rotation blocking receiving portion 250. In this state, when the slide cutter 182 performs a cutting operation in the backward movement direction, a cutting resistance acts on the cutter blade 241 and tries to rotate the cutter holder 242 counterclockwise as shown in FIG. The cutting operation position of the slide cutter 182 during the cutting operation is maintained by the engagement with the rotation prevention receiving portion 250.
[0199]
In addition, when the slide cutter 182 at the cutting operation position rotates to the non-cutting operation position via the blade member 247 at the return end, the engagement between the rotation prevention unit and the rotation prevention receiving unit 250 is released. It is like that. Note that the non-cutting operation position of the slide cutter 182 maintains the non-cutting posture of the cutter blade 241 by the weak friction force interposed between the cutter holder 242 and the carriage body 196 (see FIG. 7).
[0200]
As shown in FIG. 3, the apparatus main body 3 is provided with a cutter receiving portion 252 (tape receiving portion) corresponding to the movement locus of the slide cutter 182. The cutter receiving portion 252 is provided integrally with a part of the mounting frame 54.
[0201]
As shown in FIG. 27, the cutter receiving portion 252 is formed with a linear cutter receiving groove 253 whose cutting edge faces along the movement locus of the cutter blade 241 and tape along the movement locus of the cutter blade 241. A holding cam portion 260 that faces the distal end portion of the pressing member 243 is formed. The reciprocating slide cutter 182 relatively protrudes and retracts the cutter blade 241 from the slit hole of the tape pressing member 243 by the holding cam portion 260. The cutter blade 241 is regulated by the stopper 245 at a position where the cutter blade 241 sinks relative to the tape pressing member 243.
[0202]
The pressing cam portion 260 (sliding contact portion) is composed of a running portion 261 having an upward slope on the forward end side, and a straight portion 262 extending to the backward movement side connected to the running portion 261. The straight portion 262 receives the cutter. A groove 253 is formed. When the slide cutter 182 at the cutting operation position moves backward from the forward movement end, the steeply inclined portion 256 that is the tip of the slide cutter 182 comes into contact with the running portion 261 of the pressing cam portion 260 with priority. Then, the slide cutter 182 moves backward while the tape pressing member 243 resists the pressing spring 244 such that the steeply inclined portion 256 runs up the running portion 261.
[0203]
When the slide cutter 182 reaches the linear portion 262 of the pressing cam portion 260, the sliding contact portion of the tape pressing member 243 with respect to the pressing cam portion 260 shifts from the steeply inclined portion 256 to the flat portion 255. At this time, the flat portion 255 and the straight portion 262 are parallel, and the cutting edge of the cutter blade 241 is exposed from the slit hole of the flat portion 255 and faces the cutter receiving groove 253.
[0204]
As a result, the slide cutter 182 cuts the cutting portion of the cutting tape T while sandwiching and pressing the cutting portion of the cutting tape T so as not to move between the straight portion 262 and the front end surface of the flat portion 255. For this reason, the end face of the cutting tape T can be cut straight. On the other hand, in the reciprocating motion of the slide cutter 182 in the non-cutting operation position, the gently inclined portion 257 of the tape pressing member 243 is substantially parallel to the travel path A, and the slide cutter 182 is cut by the tape pressing member 243 as well as the cutter blade 241. Separate from the tape T.
[0205]
The range of forward and backward movement of the carriage 184 for cutting the slide cutter 182 is set outside the range of reciprocation of the carriage 184 when the cutting tool 181 is cut. When the cutting operation (reciprocating motion) is performed, the slide cutter 182 does not hit the backward abutting portion 251 and the forward abutting portion 74. Further, the trigger 215 of the carriage 184 strikes the lever 337 of the path changing member 331 of the path changing mechanism 27 at the same time as the slide cutter 182 hits the backward abutting section 251 and rotates to the non-cutting operation position. (See FIG. 7).
[0206]
Next, the structure around the cutting tool 181 will be described in detail with reference to FIGS. The cutting tool 181 includes a tool 271, a shaft-shaped tool holder 272 that holds the tool 271 at its tip, a tool holder frame 273 that rotatably supports the tool holder 272, and is supported by the carriage body 196. It consists of The tip of the cutting tool holder frame 273 extends so as to surround the tip half of the cutting tool holding member 272 and the cutting tool 271, and the cutting edge of the cutting tool 271 protrudes from the flat tip surface. The tip end portion of the cutting tool holder frame 273 protrudes from the escape opening 67 of the support frame 61, and the cut portion of the cutting tape T corresponding to the periphery of the cutting tool 271 is pressed by the flat tip end surface.
[0207]
A bearing 275 that rotatably supports the base side of the bite holding member 272 is built in an intermediate portion of the bite holder frame 273, and both ends thereof are hooked to the base end of the bite holder frame 273 ( A bit holder member 276 with an adjusting screw attached by snap-in is mounted, and the bit holder member 276 presses the base portion of the bit holder member 272 toward the distal end side.
[0208]
A receiving plate 281 supported by both side frames 57 is disposed at a portion where the cutting tool 181 is opposed to the cutting tape T, and the receiving plate 281 is cut as shown in FIGS. A cutting tool receiving groove 282 that escapes the cutting edge of the cutting tool 271 along the movement path of the cutting tool 181 is formed.
[0209]
The receiving plate 281 includes a roller opening 283 for escaping the grip driving roller 98, the plurality of intermediate bridges 108 formed in the axial direction so as to straddle the grip driving roller 98, and a moving guide portion 284 bent upward. A branch guide B 285 that is curved from the grip drive roller 98 to the second drive roller 121 is formed.
[0210]
The cutting tool 181 moved to the cutting operation position by the up / down mechanism 218 has the cutting tool T cut between the cutting tool T between the cutting tool 271 facing the cutting tool receiving groove 282 and the tip of the cutting tool holder frame 273 between the receiving plate 281. The cutting operation is performed while holding down (see FIG. 3). Thereby, the cutting tool 271 can stably perform a half cut in which only the tape body Tb is cut.
[0211]
Further, the tool receiving groove 282 extends longer than the tape width (maximum tape width) of the cutting tape T having a width of 100 mm corresponding to the set movement range of the cutting tool 181. Thereby, since the cutting operation can be started from the front side in the width direction of the cutting tape T, the cutting tape T of each width can be appropriately half-cut across the width direction (FIG. 4 (e) and (Refer to (f)).
[0212]
Note that rubber-like precut members may be provided in the bite receiving grooves 282 at both end positions (forward end position and / or reverse end position) of the reciprocating range of the carriage 184 during the cutting operation. According to this, since the initial cutting posture of the cutting tool 181 is oriented, in particular, the transverse half cut of the cutting tape T can be performed satisfactorily.
[0213]
In addition, another cutting tool setting mechanism for controlling the initial cutting attitude of the cutting tool 181 to the cutting tape T may be provided. For example, the bite setting mechanism is provided with magnets at a part of the bite holding member 272 and at one end position (side frame 57) of the reciprocating range of the carriage 184 corresponding to the bite holding member 272. The member 272 is rotated so that the cutting tool 271 is oriented in an appropriate initial cutting position.
[0214]
Alternatively, a flexible magnet is provided at one end position of the reciprocating range of the carriage 184, and the cutting edge of the cutting tool 271 moved to this position is brought into contact with the flexible magnet to actually start the cutting movement. When turning, the bite 271 is rotated 180 degrees by the reaction force.
[0215]
As another configuration, a spring that is provided at the end position of the reciprocating range of the carriage 184 so that the tip ends of the pair of posture control members are opposed to each other with the cutting tool 271 interposed therebetween, and is locked to the base portion of the posture control member, The posture control members are configured to be rotatable so that the tip portions thereof are in contact with each other. For example, when the carriage 184 reaches the forward movement end position, the cutting tool 271 passes between the tip portions of the pair of posture control members. However, when the carriage 184 moves backward, the cutting tool 271 causes both posture control members to resist the spring. Rotate to open. As a result, the cutting tool 271 that comes into contact with the position of the tip portion of both attitude control members is in an appropriate initial cutting attitude.
[0216]
By the way, as described above, the cutting operation of the cutting tool 181 is performed in synchronization with frequent forward / reverse feeding of the cutting tape T guided to the branch path B, but this is stable when the rigidity of the cutting tape T is low. Need to be done. In order to prevent the cutting tape T from being skewed, a tape width regulating mechanism 29 for regulating the position of the cutting tape T on the traveling path A and the branch path B in the width direction is disposed in the apparatus main body 3.
[0217]
The tape width regulating mechanism 29 will be described with reference to FIGS. 3 and 5 mainly with reference to FIG. The tape width regulating mechanism 29 has a pair of left and right width regulating guides 301 that regulate the position of the cutting tape T in the width direction, and a guide moving mechanism 302 that moves the pair of width regulating guides 301 at the same time. Based on the detection result of the width detection mechanism, the guide moving mechanism 302 moves each width regulation guide 301 to fit the tape width.
[0218]
The guide moving mechanism 302 includes a guide lead screw 304 and a width regulating motor 305 that rotates the guide lead screw 304 forward and backward via a gear train (worm / worm wheel). The width restricting motor 305 is a DC motor with a commutator and a brush, and is disposed on the upper inner surface of the base frame 56. A worm gear 306 is fixed to the output shaft of the width restricting motor 305. The worm gear 306 meshes with a worm wheel 307 provided at the end of the guide lead screw 304, and rotates the guide lead screw 304.
[0219]
Both ends of the guide lead screw 304 are rotatably supported by the side frame 57 and screwed into the guide female screw portion 308 of each width regulating guide 301. As described above, the cutting tape T having a plurality of widths is fed so that the center position in the width direction coincides with the center position in the left-right direction. A right male screw portion 312 is formed with a right screw threaded on one side and a left male screw portion 313 screwed with a left screw having the same lead as the right male screw portion 312 is formed on the other side with the direction center portion 311 as a boundary. Is formed. One of the pair of width regulation guides 301 has a right guide female screw portion 308 that is screwed into the right male screw portion 312, and the other has a left guide female screw portion 308 that is screwed into the left male screw portion 313.
[0220]
When the guide lead screw 304 is rotated forward, the pair of width regulating guides 301 are moved equidistant from the center portion 311 of the guide lead screw 304 so as to be separated from each other. When the guide lead screw 304 is reversed, the pair of width regulating guides 301 are moved equidistant toward the center portion 311 of the guide lead screw 304 so as to approach each other. As a result, the set of the width regulation guides 301 can be easily controlled by the width regulation motor 305 and can be made simultaneously. Moreover, after setting, the set state of each width regulation guide 301 can be appropriately maintained with respect to the cutting resistance by the cutting tool 181.
[0221]
Each width regulation guide 301 straddles the forward / reverse feed mechanism 82, a lower guide portion 321 (first guide portion, tape guide portion) located on the downstream side of the branch path B, and an upper position located on the downstream side of the travel path A. The lower guide portion 321 and the upper guide portion 322 are integrally formed in a substantially “Z” cross section. The guide portion 322 includes a guide portion 322 (second guide portion, discharge port side tape guide portion). The guide female thread portion 308 is formed at a substantially intermediate portion between the lower guide portion 321 and the upper guide portion 322.
[0222]
Further, in the vicinity of each guide female screw portion 308, a guide guide portion 324 that slidably engages with the moving guide portion 284 of the receiving plate 281 is formed to protrude. The guide guide portion 324 constitutes a rotation stop of the guide female screw portion 308. When the guide lead screw 304 rotates, the guide guide portion 324 is guided by the moving guide portion 284, and each width regulating guide 301 reciprocates.
[0223]
As shown in FIGS. 3 and 5, each lower guide portion 321 has a space-side guide portion 323 extending deeply in the internal space 134 so as to escape the second pulling roller 93, etc. It has two guide pieces 325a and 325b that face a branch portion with the path B and face each other with a gap. The space-side guide portion 323 has a lower surface curved along the upper surface 54a of the mounting frame 54, and the upper surface extends horizontally from the guide start end 138 to the guide end portion 139 of the tape guide surface 137a. Yes.
[0224]
The two guide pieces 325a and 325b are formed so as to protrude from the inner surface of the lower guide portion 321 and are positioned above and below (with a gap) through the slit that becomes the reciprocating path C, and at the corner of the branch portion The arcuate curved surfaces along the lines face each other (see FIG. 28). The two guide pieces 325a and 325b are in contact with the cutting tape T so as to sandwich the edge of the cutting tape T in the width direction, and the folding of the both ends of the cutting tape T is suppressed. In addition, it is more preferable that the front end side of the two guide pieces 325a and 325b faces the straight portion of the travel route A.
[0225]
Each upper guide portion 322 is integrally formed with an upper guide piece 326 that extends along the travel route A and contacts the edge portion in the width direction of the cutting tape T to guide it. The upper guide piece 326 is located between the first pulling roller 92 and the tape discharge port 32, and is formed in an arc shape on the inner surface of the upper guide portion 322 so as to follow the curl of the cutting tape T. The surface of the upper guide piece 326, that is, the feed guide surface constituting the reciprocating path C is disposed so as to be flush with the case outer surface 136 of the storage case 135, and both ends in the feed direction are chamfered. Yes.
[0226]
Each upper guide portion 322 has a free-rotating star roller 327 that faces the upper guide piece 326 across the traveling route A and is in rolling contact with the edge in the width direction of the cutting tape T. The star roller 327 includes a thin star roller main body 328 whose outer peripheral surface is formed in a jagged star shape, and a coil spring-like star roller shaft 329 that rotatably supports the star roller main body 328. As a result, the star roller 327 rolls in contact with the cutting tape T while pressing the cutting tape T against the upper guide piece 326. For this reason, even if it is the cutting tape T with especially low rigidity, folding of both ends is suppressed effectively.
[0227]
As described above, the two guide pieces 325a and 325b are arranged on one side of the reciprocating path C, and the upper guide piece 326 and the star roller 327 are arranged on the other side. The forward / reverse feed can be stably performed along the reciprocating path C without lifting both ends in the width direction. At this time, the cutting tape T can be regulated in position in the width direction by sliding both side ends in the width direction on the inner surfaces (position regulating surfaces) of the upper and lower guide parts 321 and 322, and by the lower guide part. The cutting tape T can be stably fed into the internal space 134.
[0228]
In some cases, the positional relationship between the two guide pieces 325a and 325b of the lower guide portion 321 and the second pulling roller 93 and the positional relationship between the upper guide piece 326 and the first pulling roller 92 may be reversed. Good. Further, instead of the two guide pieces 325a and 325b, a star roller 327 may be provided in the lower guide portion 321 in the same manner as the upper guide portion 322.
[0229]
Although details will be described later, the tape width regulating mechanism 29 starts driving and sets each width regulating guide 301 at the same time as the power is turned on. Further, prior to the cutting operation of the half-cut process, the cut cutting tape T (tape piece) after being cut is fed forward and backward a plurality of times by the tape feeding mechanism 22 so as to be fed in an appropriate manner to each width regulation guide 301. I have to.
[0230]
Next, the path changing mechanism 27 will be described with reference to FIGS. 3, 7 and 11. The path changing mechanism 27 switches to the branch path B by blocking the travel path A on the downstream side of the full cut mechanism 24. The cutting tape T (tape piece) fed backward is changed from the tail end to the branch path B. It has a route changing member 331 for guiding, and a moving mechanism 332 for moving the route changing member 331 between a change position projecting into the travel route A and a retreat position retracting from the travel route A. Note that the route change member 331 at the retracted position is in a non-projecting state on the branch route B and opens both the travel route A and the branch route B.
[0231]
The route changing member 331 is interposed between the slide cutter 182 and the cutting tool 181, that is, disposed at the branch portion between the travel route A and the branch route B. The path changing member 331 has an upward wedge-shaped cross section having parallel surfaces along the traveling path A, and extends in the width direction of the cutting tape T. Both ends of the path changing member 331 are rotatably supported by the cutter receiver 252, and at one end, a return spring 334 that biases the path changing member 331 toward the retracted position, and a return spring One end of 334 is locked and has a stopper 335 for restricting the path changing member 331 to the retracted position. As described above, the route changing member 331 moves to the changed position by blocking the traveling route A by rotating so that the tip end portion thereof is tilted forward by the moving mechanism 332 against the return spring 334. .
[0232]
In addition, a lever portion 337 (an interlocking member) is provided at the other end of the path changing member 331 so that the trigger portion 215 of the carriage 184 moved to the return end position is engaged. The carriage 184 rotates the path changing member 331 to protrude to the change position. At this time, in the slide cutter 182, the blade member 247 comes into contact with the backward abutting portion 251 and rotates to the non-cutting posture. Further, when the carriage 184 moves out of the return end position (moves to the forward movement side), the trigger portion 215 and the lever portion 337 of the carriage 184 are disengaged, and the path changing member 331 is moved by the return spring 334. It returns to the retracted position.
[0233]
As described above, the moving mechanism 332 includes the lever portion 337 provided on the route changing member 331 and the carriage 184 that moves the route changing member 331 between the change position and the retracted position via the lever portion 337. The trigger unit 215 and the reciprocating mechanism 185 are configured.
[0234]
Although the details will be described later, the change timing between the change position and the retracted position of the path changing member 331 is that the tail end of the cutting tape T (tape piece) after cutting is the path changing member 331 from the retracted position to the changed position. On the other hand, from the change position to the retracted position, it is performed when the cutting tape T is first sent to the branch path B.
[0235]
As shown in FIGS. 3 and 5, a route guide portion 285 of the receiving plate 281 faces the branch route B side facing the route changing member 331. The route guide portion 285 is formed in a curved surface shape following the curl direction of the cutting tape T, and together with the wedge-shaped tip of the route change member 331, the route change member 331 is essentially rotated. Even if not, the cutting tape T can be guided to the branch path B. Therefore, although the moving mechanism 332 can be omitted, the cutting tape T that is fed back is moved from the travel path A to the branch path B by appropriately moving the path changing member 331 between the change position and the retracted position. Can lead to sure. As shown in FIG. 5, the route guide portion 285 is formed at a total of three locations, that is, an intermediate portion and both end portions in the extending direction of the receiving plate 281 in order to ensure the movement of the width regulation guide 301.
[0236]
Next, with reference to FIGS. 5, 6, and 7, the interlocking mechanism 28 mainly composed of a cam mechanism will be described. As described above, the interlocking mechanism 28 uses the interlocking motor 351 capable of rotating in the forward and reverse directions, (1) the power switching operation for intermittently transmitting power to the printing side gear train 142, (2) the grip roller 91, and the first The second pulling rollers 92 and 93 perform the roller separating operation of the driven rollers 98, 112, and 122 and the up and down operation of the cutting tool 181. The power switching operation of “1” The roller separation / contact operation of “(2)” is synchronized. Further, as described above, in the roller separation / contact operation of “(2)”, three-stage operations are performed: the separation position of the grip driven roller 99 and the like, the first grip position, and the second grip position.
[0237]
Similarly to the width regulating motor 305, the interlocking motor 351 is a DC motor with a commutator and a brush, and is disposed on the inner surface of the base frame 56. A worm gear 352 is fixed to the output shaft of the interlocking motor 351, and a worm wheel 353 is engaged with the worm gear 352. On the same axis as the worm wheel 353, an up / down cam 354 (first plate cam) that operates the drive lever 222 to perform the operation “3” and an operation input unit 73 of the operation frame 59 are operated. The frame operation cam 355 (second plate cam) that performs the operation (1) and the operation (2) is disposed so as to overlap.
[0238]
As shown in FIG. 7, the up / down cam 354 is fixed to the back side of the worm wheel 353, and is fixed to the lever operating cam 361 that contacts and operates the tail end portion of the drive lever 222 and the back side of the lever operating cam 361. The lever operation cam 361 and the up / down detection cam 362 are constituted by plate cams arranged on the same axis. That is, when the worm wheel 353 rotates, the lever operation cam 361 and the up / down detection cam 362 rotate simultaneously on the same axis.
[0239]
On the other hand, the frame operation cam 355 is pivotally supported so as to be freely rotatable, and is disposed between the up / down cam 354 and the base frame 56 as shown in FIG. The frame operation cam 355 includes a frame operation cam 364 that contacts and operates the operation input portion 73 of the operation frame 59, and a frame detection cam 365 fixed to the back side of the frame operation cam 364. The cam 364 and the frame detection cam 365 are constituted by plate cams arranged coaxially.
[0240]
The frame action cam 364 has a three-stage operation of “(2)”, an all-separation cam portion 371 corresponding to the separation position of the grip driven roller 98 and the like, and a first grip corresponding to the first grip position. The cam portion 372, the second grip cam portion 373 corresponding to the second grip position, and three transition cam portions for continuously connecting the cam portions are integrally configured. Note that the reference numerals of the transition cam portion are omitted.
[0241]
The frame detection cam 365 protrudes in the radial direction, and a first grip position detection cam portion 375 for detecting the first grip position and a second grip position detection cam portion 376 for detecting the second grip position. And have. The first grip position detection cam portion 375 and the second grip position detection cam portion 376 are displaced in the axial direction (thickness direction) and are formed at point symmetry positions in the circumferential direction.
[0242]
Reference numeral 368 in FIG. 5 is a frame position detection switch disposed facing the frame detection cam 365, while reference numeral 369 in FIG. 7 is disposed facing the up / down detection cam 362. These are up / down detection switches that control the driving of the interlock motor 351.
[0243]
The frame position detection switch 368 detects both the results of “1” and “2” through the frame detection cam 365, and the first grip position detection cam of the frame detection cam 365. The first grip position detection switch 368a corresponding to 375 and the second grip position detection switch 368b corresponding to the second grip position detection cam 376 are configured. Then, based on the detection results (1 or 0) of the first grip position detection switch 368a and the second grip position detection switch 368b, the driving of the interlock motor 351 is stopped. In the following description, it is assumed that the switch detection signal “1” is ON and the switch detection signal “0” is OFF.
[0244]
On the other hand, the up / down detection switch 369 detects the operation result of “(3)” via the up / down detection cam 362. Based on this detection result (1 or 0), the up / down detection switch 369 moves the interlock motor 351 from the normal rotation. The direction of rotation to be driven is switched from reverse rotation to reverse rotation to normal rotation. That is, when the up / down detection switch 369 is appropriately turned ON / OFF (1 or 0), the forward / reverse rotation of the interlocking motor 351 is appropriately switched.
[0245]
The frame operation cam 355 and the up / down cam 354 face each other in a non-contact state, and a projecting pin 366 is integrally provided on the opposite end surface (surface) of the frame action cam 364, and the up / down detection cam An idling groove 367 with which the projecting pin 366 is engaged is provided on the opposite end surface (back surface) of 362. As a result, the output of the interlocking motor 351 is transmitted from the worm / worm wheel 352, 353 via the up / down cam 354 to the projecting pin 366 abutting against the end of the idling groove 367, so that the frame operation cam 355 is transmitted. Communicated.
[0246]
In this case, the idling groove 367 is a half-moon-shaped (arc-shaped) long groove, and the projecting pin 366 is engaged with the idling groove 367 with play in a predetermined rotation range. Only the up / down cam 354 can be rotated forward and backward. That is, in the idling groove 367, only the operation “3” can be performed without performing both the operations “1” and “2”.
[0247]
Here, the relationship between the operations of “1” to “3” and the switches 368 and 369 will be described with reference to FIGS. Both figures are a table showing the sequence of the interlocking motor 351 in relation to the frame position detection switch 368 and the up / down detection switch 369. As shown in both figures, the up / down cam 354 and the frame operation cam 355 are in an initial state in a state where the interlocking motor 351 rotates normally by turning on the power and the various switches 368 and 369 become “0”.
[0248]
In this state, the motion input portion 73 of the motion frame 59 is in contact with the all-separation cam portion 371 and is “(2) separation position”, “(1) power transmission is possible”, and (3) non-cut operation position. Is. On the other hand, the projecting pin 366 is in contact with one end of the idling groove 367. In this state, in the case of a P tape, printing processing is usually performed.
[0249]
When cutting the cutting tape T, the interlocking motor 351 is further rotated in the forward direction, and the up / down cam 354 and the frame operation cam 355 are rotated in the forward direction so as to perform the operation “(2)”. In this case, in the case of the S tape in FIG. 13, the driving of the interlocking motor 351 stops when the first grip position detection switch 368a becomes “1”. The operation “to 1 grip position” and the operation “(1) power interruption” are performed in synchronization therewith. At this time, the contact state of the projecting pin 366 with the idling groove 367 is maintained, and the contact end of the operation frame 59 is transferred to the first grip cam portion 372.
[0250]
On the other hand, in the case of the P tape in FIG. 12, the interlocking motor 351 continues to rotate normally until the second grip position detection switch 368b becomes “1”. The operation "(2) To the first grip position" is performed, and subsequently, the operation "(2) From the first grip position to the second grip position" is performed. At this time, the contact end of the operation frame 59 moves to the second grip cam portion 373, but the contact state of the projecting pin 366 with respect to the idling groove 367 is still maintained.
[0251]
As described above, when cutting the cutting tape T, the up / down cam 354 rotates normally in both the S tape and the P tape, but the up / down detection switch 369 maintains “0”. , “(3)” is not performed.
[0252]
In order to perform the operation “(3)” at the time of the half cut after cutting the cutting tape T, first, the interlocking motor 351 is reversed. At this time, the projecting pin 366 relatively moves in the idling groove 367, and only the up / down cam 354 rotates. Thereby, since the frame detection switch 368 is not switched, the “(1) power cutoff” and “(2) first grip position (or second grip position)” do not change.
[0253]
Until the up / down detection switch 369 becomes “1”, the operation “(3) to the cutting operation position” is performed, and the cutting tool 181 can perform the half-cut processing. Subsequently, when the switch 369 is set to “1”, the interlocking motor 351 is switched to the forward rotation, and until this becomes “0” and the interlocking motor 351 is switched to the reverse rotation again, “(3) non-cut operation position”. The operation “to” is performed. Also in this case, since the projecting pin 366 moves relatively in the idling groove 367, the frame detection switch 368 is not switched.
[0254]
In this way, the worm wheel 353, the up / down cam 354, and the frame operation cam 355 transmit the rotational output of the interlocking motor 351 in both the forward and reverse directions to the bite up / down mechanism 218 and the rotational output to the bite up / down mechanism 218. In the shut-off state, power transmission means is configured to transmit the rotation output in the forward and reverse directions to the tape feeding power shut-off mechanism that operates as “1” and the roller separation mechanism that operates as “2”. Thus, the single motor 351 can repeatedly perform only the operation (3) without performing the operations (1) and (2).
[0255]
Next, a main control system constituted by the controller 26 will be described. As shown in the block diagram of FIG. 14, the control system of the tape processing apparatus 1 includes an input unit 380 having a keyboard 11, a display unit 381 having a display 17, and a printing mechanism 23. A printing unit 382 that performs printing, a cutting unit 383 that includes the half-cut mechanism 25 and the full-cut mechanism 24 and performs a cutting operation on the cutting tape T, and a conveyance unit 384 that includes the tape feeding mechanism 22 and feeds the cutting tape T. And a width restricting portion 385 that has the tape width restricting mechanism 29 and restricts the width of the cutting tape T, an interlocking portion 386 that has the interlocking mechanism 28 and interlocks each mechanism, and various drivers that drive each portion. The drive unit 387 and the detection switch (tape width detection switch 370, up / down detection) of the tape width detection mechanism and the interlock mechanism 28. A detection unit 388 for performing various detections a switch 369 and a frame position detecting switch 368), and a control unit 389 for controlling each of the tape processing apparatus 1 (the controller 26).
[0256]
The control unit 389 includes a CPU 391, ROM 392, RAM 393, CG-ROM 394, and P-CON 395, which are connected to each other via a bus 396. The ROM 392 has an area for storing a control program processed by the CPU 391 and control data. The CG-ROM 394 stores font data such as characters, symbols, and figures prepared in the tape processing apparatus 1 and font data for cutout shapes (for example, heart shape), and code data for specifying characters and the like is stored in the CG-ROM 394. When given, output the corresponding font data. The RAM 393 is used as various work areas for control processing.
[0257]
The P-CON 395 incorporates a logic circuit for supplementing the functions of the CPU 391 and handling interface signals with peripheral circuits. Various commands and font data from the input unit 380 are processed as they are or processed into the bus 396. In conjunction with the CPU 391, the data and control signals output from the CPU 391 or the like to the bus 396 are output to the drive unit 387 as they are or after being processed.
[0258]
The CPU 391 then inputs various detection signals, various commands, various data, etc. via the P-CON 395 according to the control program in the ROM 392, and the font data from the CG-ROM 394 and the various data in the RAM 393. Then, a control signal is output to the drive unit 387 via the P-CON 395.
[0259]
Thus, display control of the display 17 is performed via various drivers, and the print head 36 is controlled to print on the cutting tape T under predetermined printing conditions. The feed driving motor 81, the carriage motor 186, the width regulating motor 305, and The entire tape processing apparatus 1 is controlled by controlling the interlocking motor 351 and the like to perform half-cutting and full-cutting on the cutting tape T under predetermined feeding conditions and cutting conditions.
[0260]
Next, with reference to FIGS. 15 to 18, the tape processing method by the tape processing apparatus 1 will be briefly described step by step with respect to the control by the controller 26 in the composite processing mode. When the power key 13 of the tape processing apparatus 1 with the tape cartridge 5 is pressed, various mechanisms are initialized (FIG. 15: S1 to S3).
[0261]
By this initial setting (FIG. 15: S4), the interlocking motor 351 of the interlocking mechanism 28 rotates in the forward direction, and the grip roller 91 and the driven rollers 99, 112, 122 of the first and second pulling rollers 92, 93 are separated from each other. Then, the power can be transmitted to the platen roller 42, and the cutting tool 181 is moved to the non-cut operation position (see FIGS. 12 and 13). Further, the carriage 184 is moved to the initial position side, the path changing member 331 is moved to the retracted position, and the slide cutter 182 is moved to the non-cutting operation position. Further, the width regulating guide 301 is moved and set so as to match the tape width upon receiving the tape width detection.
[0262]
From this state (FIG. 17A), when the user inputs a desired print image and cutout shape and the process execution key 14 is pressed (FIG. 15: S8 to S9), the feed drive motor 81 is turned on. Rotate forward. As a result, the grip roller 91, the first pulling roller 92, and the platen roller 42 start normal rotation, and the cutting tape T is fed from the tape cartridge 5 to the traveling path A.
[0263]
At this time, a print image is printed on the cutting tape T by the print head 36 that generates heat in synchronization with the normal rotation of the platen roller 42 (FIG. 16: S7, FIG. 17B). When printing is finished (FIG. 16: S8), the feed drive motor 81 rotates somewhat forward, and when the cutting tape T is fed forward by the distance between the print head 36 and the slide cutter 182, the feed drive motor 81 is moved forward. A voltage is applied to and the stop state is held (FIG. 16: S9 to S10).
[0264]
Here, the interlocking motor 351 is rotated forward until the second grip position detection switch 368b of the frame position detection switch 368 is turned on (see FIG. 12), and the power transmission to the platen roller 42 is interrupted, and the grip roller 91 and The driven rollers 99, 112, 122 of the first and second pulling rollers 92, 93 are moved to the second grip position (FIG. 16: S11, FIG. 17 (c)). At the next timing, the slide cutter 182 moves forward, rotates to the cutting operation position, and then reverses and moves backward to detach the cutting tape T (FIG. 16: S12, FIG. 18 (a)).
[0265]
Subsequently, a “half-cut process” is performed on the cut cutting tape T (printed tape piece) (FIG. 16: P10 subroutine). That is, first, the feed drive motor 81 is rotated forward again to feed the cutting tape T along the travel route A until the tail end of the cutting tape T passes the route changing member 331 (FIG. 16: S14). Next, the slide cutter 182 further moves backward, and the slide cutter 182 is rotated to the non-cutting operation position at the return end position. At the same time, the path changing member 331 is rotated to the change position via the carriage 184, and the reciprocating path C is established (FIG. 16: S15, FIG. 18B).
[0266]
Here, when the feed drive motor 81 is reversed and the grip roller 91 and the second pulling roller 93 are reversed, the cutting tape T is fed backward, and its tail end comes into contact with the path changing member 331, and the branch path B And is sent to the upper guide portion 322 of the width regulation guide 301 (FIG. 16: S16, FIG. 18C). When the carriage 184 moves forward and the path changing member 331 returns to the retracted position, the feed drive motor 81 is rotated backward and forward a plurality of times, and the cutting tape T is reciprocated forward and backward. And adjust to the width regulation guide 301 in the set state (FIG. 16: S17 to S18, FIG. 19A).
[0267]
Subsequently, forward and reverse feeding of the cutting tape T by the grip roller 91 and the first and second pulling rollers 92 and 93, reciprocation of the cutting tool 181 by the reciprocating mechanism 185, and up and down of the cutting tool 181 by the interlocking mechanism 28. In synchronization with the operation, the cutting tape T is half-cut (FIG. 16: S19, FIG. 19B). When the half cut is completed, finally, the feed drive motor 81 is rotated forward to feed the cutting tape T out of the apparatus from the tape discharge port 32 (FIG. 16: S20 to S21, FIG. 19 (c)).
[0268]
As described above, according to the tape processing apparatus 1 of the present embodiment, a series of operations on the cutting tape T is automatically performed by driving each mechanism housed in the apparatus case 2 to create a printed image and a cutout shape. be able to. In addition, when the cut shape is not input in Step 5 of FIG. 15, the driving of the half-cut mechanism 25 is canceled, and the process proceeds from Step 13 to the Step 21 from the determination branch. Thereby, the cutting tape T (printed tape piece) passes through the half-cut mechanism 25 in the standby state, and is sent out from the tape discharge port 32 to the outside of the apparatus.
[0269]
A plurality of colors are prepared for the cutting tape T and the ink ribbon R accommodated in the tape cartridge 5, and a color print image and a color cutout shape can be formed on the cutting tape T. . For this reason, various forms of tapes can be created.
[0270]
The tape processing apparatus 1 may be connected to an external device such as a personal computer with a cable or the like. According to this, data created by input / editing or selection created by an external device can be processed on the cutting tape T by the tape processing apparatus 1. The setting of the width regulation guide 301 may be left to a user's manual operation.
[0271]
FIG. 20 shows another processing flow of the tape processing apparatus 1 that synthesizes the print image and the cutout shape formed on the cutting tape T with high accuracy in structure in the combined processing mode. Specifically, the processing flow between S7 to S12 in FIG. 16 is different, and the print head 36 is driven to generate heat and cutting tape in synchronism with the forward rotation of the grip roller 91 instead of the platen roller 42. It prints on T.
[0272]
As shown in the figure, after the print image and the cutout shape are input, when the processing execution key 14 is pressed (see FIG. 15), the cutting tape T is moved from the tape cartridge 5 to the travel path A by the forward rotation of the platen roller 42. (Fig. S6). In this case, the print head 36 is fed until the leading end of the cutting tape T reaches the position of the grip roller 91 without driving the heat generation (FIG. 20: S31). Strictly speaking, the cutting tape T is fed until the tip of the cutting tape T reaches the position of the first pulling roller 92. Here, the interlocking motor 351 is rotated forward to interrupt the power transmission to the platen roller 42, and each driven roller 99 such as the grip roller 91 is moved to the second grip position (FIG. 20: S32).
[0273]
In this state, the cutting tape T is further fed out of the tape cartridge 5 by the normal rotation of the grip roller 91, and the heat generation drive of the print head 36 is started in synchronism with the feeding and feeding to print an image on the cutting tape T. Start (S33). Then, after the cutting tape T sent somewhat forward after the printing is completed (S34 to S37 in the figure), the gripping roller 91 applies the tape to the cut cutting tape T (tape piece). The forward / reverse feed in which the feed amount is controlled and the reciprocating motion of the cutting tool 181 are performed in synchronism, and the cutting tape T is subjected to a cut-out half-cut process (FIG. P10).
[0274]
As described above, according to this processing flow, printing on the cutting tape T and half-cutting are both performed by controlling the feed amount of the tape by the grip roller 91. As a result, it is possible to eliminate a relative error based on the tape-feed amount between printing and half-cut that may occur when printing is performed by the platen roller 42 and half-cutting is individually controlled by the grip roller 91. The printed image and the cutout shape can be satisfactorily synthesized.
[0275]
Next, with reference to FIG. 21 to FIG. 23, the case where the tape cartridge 401 dedicated to the cutting process that forms only the cut shape is used will be described. The cutting tape T (S tape) dedicated to the cutting process is composed of the release paper Ta and the tape body Tb as in the above embodiment, and has a large rigidity for the cutting process, and the above embodiment. The tape body Tb has elasticity. For this reason, when the tape body Tb is cut out, the already cut out portion is easily peeled off from the release paper Ta. For this reason, the processing operation of the tape processing apparatus 1 is partially different from the above embodiment.
[0276]
As shown in these drawings, the tape cartridge 401 dedicated to the cutting process is formed with a larger thickness than the above-described tape cartridge 5 for printing / composite processing, and accommodates a cutting tape T having a width of 100 mm. . The tape cartridge 401 includes a tape roll 403 obtained by winding a cutting tape T around a cylindrical core, and a cartridge case 404 that detachably accommodates the tape roll 403.
[0277]
The cartridge case 404 includes a main body case 406 that houses the tape roll 403, a lid 407 that closes the main body case 406, and a tape roll 403 that is rotatably supported and supported at both ends by both side plates 411 of the main body case 407. And a rolled shaft 408.
[0278]
The body case 406 is integrally formed with both side plates 411 and a vertical plate 412 passed between both side plates 411, and the both side plates 411 support the roll shaft 408 so that it can be pulled out in the axial direction. For this reason, the tape cartridge 401 has a lock mechanism 413 that locks the roll shaft 408 to the main body case 406 in a retaining state.
[0279]
The lock mechanism 413 is formed on a lock piece 414 formed at one end of the roll shaft 408 and extending in the radial direction, and one side plate 411 corresponding to the lock piece 414 (upper side plate 411a in FIG. 21). The roll piece 414 has a notch opening 415 from which the lock piece 414 can be pulled out, and the roll shaft 408 has a lock position where the lock piece 414 is removed from the notch opening 415 inside the side plate 411, and an unlock position where the roll piece 414 faces the notch opening 415. It is comprised so that rotation operation is possible between.
[0280]
The lock piece 414 has a spring property, and a rotation stop protrusion 419 that protrudes toward the side plate 411 is provided at the tip of the lock piece 414. Corresponding to the rotation protrusion 419, the side plate 411 is formed with a rotation hole 420 into which the rotation protrusion of the lock piece 414 is fitted in a state where the roll shaft 408 is rotated to the lock position.
[0281]
The lid 407 opens and closes around the base supported inside the both side plates 411 and closes the main body case 406 so as to fit inside the both side plates 411. An engagement portion 418 that protrudes somewhat in the extending direction as compared with the other side surface portions and that prevents the lid 407 from being removed in the closed state is formed on the tip side 417 of the lid 407. Corresponding to the engaging portion 418, on both side plates 411 of the main body case 406, an engaging receiving portion 421 is formed on which the engaging portion 418 is engaged and disengaged as the lid 407 is opened and closed.
[0282]
Further, the closed lid 407 is prevented from being opened with respect to the roll shaft 408. In other words, both ends of the roll shaft 408 are provided with latching portions 422 for latching the lid 407 in a closed state, and correspondingly, the lid 407 has a lock position and an unlock position of the roll shaft 408. A latch receiving portion 423 to which the latch portion 422 is engaged and disengaged with the rotation operation is provided. As described above, the lock for locking itself by the rotation operation of the roll shaft 408 and the opening / closing lock (opening prevention) of the lid 407 are performed, so that the closed state of the lid 407 with respect to the main body case 406 can be appropriately maintained. In addition, the tape roll 403 can be exchanged easily by opening it.
[0283]
A cutting tape T is fed from the tape roll 403 and sent out of the case between the front end side 417 of the lid body 407 in the closed state and the end side of the main body case 406 facing the front end side 417 of the cover body 407. A tape delivery port 424 is configured. Further, in the vicinity of the tape delivery port 424, the cartridge case 404 incorporates a feeding roller 425 that feeds the cutting tape T from the tape roll 403 and guides it to the tape delivery port 424.
[0284]
The feeding roller 425 is rotatably supported by a roller support portion 426 formed inwardly projecting from both side plates 411, and faces the center position of the thickness of the tape cartridge 401, that is, the center position of the tape width of the cutting tape T. . The platen drive shaft 37 of the cartridge mounting portion 19 is engaged with the proximal end side of the feeding roller 425, and the feeding roller 425 is a tape feeding mechanism 22 that feeds the cutting tape T along the traveling path A. Part of it.
[0285]
A head escape opening 427 that is cut out in a square shape is formed in the side surface portion of the lid 407 facing the feeding roller 425. When the tape cartridge 401 is attached to the cartridge attachment portion 19, the relief opening 427 is formed in the relief opening 427. The print head 36 faces. Similar to the tape cartridge 5 described above, the tape cartridge 401 can be attached to and detached from the cartridge mounting portion 19 from the same direction. The tape cartridge 401 is mounted at a position close to the rear half of the cartridge mounting unit 19. In this mounted state, the platen drive shaft 37 engages with the feeding roller 425 and rotates through the head release mechanism. The head 36 comes into contact with the feeding roller 425 with the cutting tape T interposed between the head relief opening 427 and the ribbon take-up shaft 38 is detached from the tape cartridge 401 and stands upright.
[0286]
With reference to FIG. 23 and FIG. 24, the process flow of the clipping process in the tape processing apparatus 1 will be briefly described. When the power key 13 of the tape processing apparatus 1 is turned on, various initial settings are performed as in the case of the composite processing (FIG. 24: S41 to S44). Here, the mode switch key 15 is pressed (input) to switch the tape processing apparatus 1 from the composite processing mode to the cut-out processing mode (FIG. 24: S45). By this mode switching, the heat generation driving of the printing mechanism 23 is automatically canceled (FIG. 24: S46).
[0287]
The user inputs, edits or selects a desired cutout shape by operating the keys while looking at the display 17, and pushes the process execution key 14 (FIG. 24: S47 to S48). Then, first, the tape feeding mechanism 22 is driven, and the feeding roller 425 is fed out from the tape cartridge 401 while pressing the cutting tape T against the print head 36 in the non-heat generation driving state (standby state), and this is run along the traveling path. A predetermined length is sent along A.
[0288]
Also in this case, when the leading end of the cutting tape T is fed to the position of the grip roller 91, the power to the feeding roller 425 is cut off, and the subsequent feeding of the cutting tape T is performed including feeding from the tape cartridge 5. The gripping roller 91 is used (FIG. 24: S49). That is, when the tip of the cutting tape T reaches the grip roller 91, the interlocking motor 351 rotates in the forward direction, interrupts power transmission to the feeding roller 425, and moves the driven roller 99 of the grip roller 91 to the first grip position. (FIG. 24: S50).
[0289]
As described above, the first grip position is such that only the left and right rollers 99b and 99b of the grip driven roller 99 of the grip roller 91 sandwich the cutting tape T with the grip drive roller 98, and the grip driven The roller 99a at the center of the roller and the first and second driven rollers 112 and 122 are maintained apart from the cutting tape T (see FIGS. 23 and 13). As a result, appropriate running performance of the cutting tape T is ensured.
[0290]
Then, when the grip roller 91 is rotated forward, the cutting tape T is fed out from the tape cartridge 5 and sent to the other side by the length necessary for forming the cutout shape (FIG. 22: S51). Stop feeding for cutting. At the next timing, the cutting tape T is cut by the slide cutter 182 (FIG. 22: S52 to S53), and the subsequent half-cut processing (FIG. 22: P10) is started.
[0291]
As described above, the sticking prevention roller 131 is in rolling contact with both ends in the width direction of the cutting tape T guided to the tape storage processing unit 30 in the half-cut processing. Thereby, since the cutting tape T is prevented from sticking to the case inner surface 137 of the storage case 135, the forward and reverse feeding of the cutting tape T at the time of half-cutting is performed smoothly. Finally, the cutting tape T is discharged from the tape discharge port 32 to the outside of the apparatus.
[0292]
Thus, when the cutting tape T with high rigidity dedicated to the cutting process is cut out, the grip driven roller 99a located at the center position in the width direction of the cutting tape T, and the first and second tension rollers 92 and 93. The driven rollers 112 and 122 are separated from the cutting tape T, and are rotated and fed while the cutting tape T is sandwiched between the left and right rollers 99b and 99b of the grip driven roller and the grip driving roller 99. As a result, it is possible to perform feed control while holding the cutting tape T without peeling off the already cut-out shape portion in a state in which the traveling property of the cutting tape T forward-reversely fed is satisfactorily secured.
[0293]
The mode switching from the composite processing mode to the cut-out processing mode may be performed by an input operation of the keyboard 11 as described above. However, the tape width detection mechanism provided in the cartridge mounting unit 19 uses the tape cartridge type. You may make it carry out by detecting.
[0294]
In other words, the tape width detection mechanism also serves as a tape detection mechanism (cartridge detection means) for detecting the type of each tape cartridge of the composite process, the print process, and the cut process, and the tape detection mechanism has detected the tape cartridge 401 for the cut process. Sometimes, the heat generation drive of the printing mechanism 23 may be canceled. Accordingly, it is possible to automatically cancel the driving of the printing mechanism 23 by mounting the tape cartridge 401 for the cutting process without switching the mode by key operation.
[0295]
Note that the cutting tape T dedicated to the cutting process of the present embodiment is a roll-shaped cutting tape, but may be a fixed length cutting tape T having a specific length. In this case, the cutting tape T is manually inserted into the tape processing apparatus 1 using the tape discharge port 32 as an introduction port. 25 and 26 show a processing flow of the tape processing apparatus 1 in this case. In addition, the tape width of the manual cutting tape T is 100 mm as described above, and the tape processing apparatus 1 is in a state where the tape cartridges 5 and 401 for composite processing or cut-out processing are mounted on the cartridge mounting portion 19. Also, the manual cutting tape T is configured to be capable of half-cut processing.
[0296]
As shown in FIG. 25, when the power key 13 of the tape processing apparatus 1 is turned on, initialization is performed in the same manner as described above (FIG. 25: S61 to S63). When the mode switching key 15 is pressed (input) twice and the tape processing apparatus 1 is switched from the composite processing mode to the automatic cutting process mode (see FIG. 24) to the manual cutting mode, the same as described above. Then, the heat generation driving of the printing mechanism 23 is canceled (FIG. 25: S64 to S65).
[0297]
Further, the path changing member 331 is set at the change position via the carriage 184 (FIG. 25: S66No to S69). When the tape cartridge is mounted (FIG. 25: S66 Yes), the process proceeds to the decision branch of Step 67 to determine which tape cartridge 5 (or 401) is mounted. At this time, when the composite processing tape cartridge 5 is mounted (FIG. 25: S67 No), the width regulation guide 301 set to the P tape specification is reset to the manual cutting tape T specification. Later (FIG. 25: S68), the process proceeds to Step 69. If the manual cutting tape T has been introduced into the tape processing apparatus 1 in advance, a comment to that effect is displayed on the display 17 (FIG. 26: S70 Yes to S71).
[0298]
Subsequently, the cutting tape T is set in the tape discharge port 32, a desired cutout shape is input by a key operation, and the processing execution key 14 is pushed (FIG. 26: S72 to S73). Then, the grip follower roller 99 and the like of the grip roller 91 move to the first grip position and the power transmission to the platen roller 42 and the like is interrupted, and then the cutting tape T is conditioned and reciprocated (FIG. 26: S75). ).
[0299]
Then, the path changing member 331 returns to the retracted position, and the cut-out half-cut process is started (FIG. 26: S76 to S78). Similarly to the above, after the half cut mechanism 25 and the tape feed mechanism 22 (the forward / reverse feed mechanism 82) cooperate to store the cutting tape T in the tape storage processing unit 30, the half cut process is performed. The cutting tape T is finally discharged from the tape discharge port 32 to the outside of the apparatus (FIG. 26: S79 to S80).
[0300]
Next, another embodiment of the tape width regulating mechanism 29 will be described with reference to FIGS. 29 and 30. FIG. Unlike the above embodiment, in the tape width regulating mechanism 29 of this embodiment, the guide moving mechanism 302 is provided with a lead shaft 531 having a cylindrical cam groove 533 instead of the guide lead screw 304, and correspondingly. The width regulating guide 301 is provided with a cam projection 534 that engages with the cylindrical cam groove 533 instead of the guide female thread portion 308. Each upper guide portion 322 is provided with a lower guide piece 550 that faces the upper guide piece 326 across the travel path A, instead of the star roller 327, and two guide pieces 325a formed on the lower guide portion 321. 325b.
[0301]
Similarly to the guide lead screw 304, the lead shaft 531 is supported at both ends on both sides of the side frame 57 so as to be rotatable, and is connected to the width regulating motor 305 via gear trains 306 and 307. A detection cam 532 for detecting one rotation of the lead shaft 531 is formed at the end of the lead shaft 531 on the gear (worm wheel 307) side. The number of rotations of the lead shaft 531 is detected by a detection switch (not shown) via the detection cam 532, and the movement of the width regulating guide 301 is controlled by the number of steps. Note that the configuration of the rotation speed detection mechanism including the detection cam 532 and the detection switch can also be applied to the tape width restriction mechanism of the first embodiment.
[0302]
The lead shaft 531 has a cylindrical cam groove 533 corresponding to each tape width of a plurality of types of cutting tapes T with a laterally extending center portion 536 as a boundary. , One side is formed in a right-handed screw shape, and the other side is formed in a left-handed screw shape. On the other hand, the left and right width restricting guides 301 are configured to be separated from each other when the width restricting motor 305 rotates in the forward direction and approach each other when the width restricting motor 305 rotates in the reverse direction by cam protrusions 534 engaged with the left and right cylindrical cam grooves 533. Yes.
[0303]
Each cylindrical cam groove 533 connects a plurality of position restricting groove portions 537 in which each width restricting guide 301 is set and a plurality of position restricting groove portions 537, and a plurality of feed groove portions 538 having a predetermined pitch corresponding to each tape width. It consists of and. The outermost end position restricting groove portion 537a is formed of an annular groove having a zero pitch, and the plurality of position restricting groove portions 537b excluding the outermost end are formed of substantially semicircular grooves. When the cam protrusion 534 is engaged with the intermediate predetermined position restricting groove portion 537b, the width restricting guide 301 is set at the guide position of the cutting tape T.
[0304]
The guide moving mechanism 302 includes two coil springs 540 that are attached to the lead shaft 531 in a loosely-fitted state corresponding to the width regulation guides 301. Each coil spring 540 is configured such that one end is fixed to the outer surface on the separation side (outside) of each width regulating guide 301 and the other end can be brought into contact with the side frame 57. That is, each coil spring 540 is moved integrally with each width regulating guide 301 in the axial direction of the lead shaft 531, and the width regulating guide 301 moved to the outer end portion of the lead shaft 531 is moved between the side frames 57. Press to reverse.
[0305]
Accordingly, when the width regulating motor 305 rotates in the forward direction, the width regulating guide 301 moves to the outer end portion of the lead shaft 531, and the cam projection 534 moves to the outermost end position regulating groove portion 537a, the width regulating guide 301 is moved. Will be stopped at that position without being sent any further. In this idle feed state, the width regulation guide 301 hits the side frame 57 via the coil spring 540, and the cam projection 534 slides on the outermost end position regulation groove 537a against the urging force of the coil spring 540. .
[0306]
Conversely, when the width restricting motor 305 is reversed in this state, the width restricting guide 301 takes advantage of the urging force of the coil spring 540 so that the cam protrusion 534 extends from the position restricting groove 537a at the outermost end to the feed groove 538 continuous thereto. To be migrated. As a result, the idle feed state is released and the width regulating guide 301 moves to the inside of the lead shaft 531 so as to approach. Based on the detection result of the detection mechanism, each width restriction guide 301 that moves according to each feed groove 538 is set at a predetermined guide position by reversing the width restriction motor 305 by the number of rotations corresponding to the tape width. Can do.
[0307]
As described above, also by the tape width regulating mechanism 29 of the present embodiment, the set of each width regulating guide 301 can be easily adjusted by the width regulating motor 305 and the position of the cutting tape T can be appropriately regulated in the width direction. . In particular, each width regulation guide 301 can be quickly moved corresponding to each tape width, and the accuracy of the stop position of the width regulation guide 301 can be sufficiently increased. This is particularly effective when the introduction center in the width direction of the plurality of types of cutting tapes T varies depending on the tape width.
[0308]
Specifically, for example, due to the structure of the tape cartridge (5, 401), even if any one cutting tape T is not set in alignment with the center in the width direction, the left and right feed groove portions 538 are respectively set to the tape width. Therefore, the left and right width regulating guides 301 can be moved with different stroke amounts. For this reason, the width of the cutting tape T that can be processed by the tape processing apparatus 1 is widened as compared with the screw type moving structure of the above embodiment. Further, the set movement of the width regulation guide 301 can be performed quickly, and the accuracy of the set position (stop position) can be increased.
[0309]
The configuration of the width regulation guide 301 including the tape width regulation mechanism 29 of other embodiments is formed by integrally forming the lower guide part 321 and the upper guide part 322, and the lower guide part 321 and the upper guide part 322 are simultaneously formed. Although they are moved in the same width, they may be configured separately, that is, in two sets, and individually moved in the tape width direction.
[0310]
This will be described by taking another embodiment as an example. Another lead shaft 531 is provided separately, and a pair of left and right upstream guide portions and a pair of left and right downstream guide portions can be individually guided on the two lead shafts 531, respectively. . In such a configuration, it is preferable that the upstream guide portion and the downstream guide portion are appropriately moved in synchronism with the forward and reverse feeding of the cutting tape T during half-cutting.
[0311]
Specifically, one pair of guide portions positioned on the upstream side in the feeding direction of the cutting tape T is individually moved to a position matching the tape width, and the other pair of guide portions is slightly wider than the tape width. It is preferable to move them individually to positions. According to this, the guide portion that faces the downstream side of the cutting tape T in the feeding direction is made to properly regulate the width of the cutting tape T by matching the tape width, while the guide that the upstream side of the cutting tape T faces in the feeding direction. The part has a clearance with respect to the cutting tape T.
[0312]
As a result, even if the cutting tape is obliquely fed to the pair of guide portions facing from now on during forward and reverse feeding, the cutting tape T can be appropriately guided to the inside of the pair of guide portions. For this reason, the width of the cutting tape T can be appropriately regulated without hindering forward / reverse feeding of the cutting tape T.
[0313]
【The invention's effect】
According to the tape processing apparatus of the present invention, a printing mechanism, a full cut mechanism, a path changing means, and a half cut mechanism are faced in order from the upstream side in the traveling path, and the half cut of the cutting tape is performed in the winding direction of the tape. A half-cut is performed by leading to a branching path extending to. As a result, the cutting tape can be sent between the travel route and the branch route following the winding, so that the half-cut process with the route change can be stably performed. Also, suitable tape feeding associated with each mechanism can be performed according to the contents of tape processing.
[Brief description of the drawings]
FIG. 1 is an external perspective view of a tape processing apparatus according to an embodiment of the present invention.
FIG. 2 is an external perspective view showing a state in which an opening / closing lid of the tape processing apparatus is opened.
FIG. 3 is a longitudinal sectional view showing the internal structure of the tape processing apparatus.
FIGS. 4A and 4B illustrate the results of formation on a tape main body by various processes formed on a cutting tape by a tape processing apparatus, where FIG. 4A is a composite process, FIG. 4B is a print process, and FIGS. Is a cut-out process, and (e) and (f) are those subjected to a transverse half-cut process.
FIG. 5 is a perspective view showing main mechanisms of the tape processing apparatus.
FIG. 6 is a perspective view showing main mechanisms of the tape processing apparatus.
FIG. 7 is a perspective view showing a main mechanism portion of the tape processing apparatus.
FIG. 8 is a plan view showing a train wheel of the tape processing apparatus.
FIG. 9 is a partially exploded perspective view showing the full cut mechanism and bushes in the tape processing apparatus.
FIG. 10 is a cross-sectional view showing the area around the bush in the tape processing apparatus.
FIG. 11 is a perspective view showing a main mechanism portion of the tape processing apparatus.
FIG. 12 is a table showing a sequence of an interlocking mechanism when executing composite processing.
FIG. 13 is a table showing a sequence of an interlocking mechanism when a cutout process is executed.
FIG. 14 is a block diagram showing a control configuration of the tape processing apparatus.
FIG. 15 is a flowchart showing a control processing flow by the tape processing apparatus, and particularly shows a processing flow of printing processing and composite processing.
FIG. 16 is a flowchart showing a similar processing flow subsequent to FIG. 15;
FIG. 17 is an operation explanatory diagram illustrating a procedure (1) for creating a tape process (particularly a composite process) by the tape processing apparatus;
FIG. 18 is an operation explanatory diagram showing a procedure (2) for creating tape processing (particularly composite processing) by the tape processing apparatus.
FIG. 19 is an operation explanatory view showing a creation procedure (3) of tape processing (particularly composite processing) by the tape processing apparatus.
FIG. 20 is a flowchart showing another processing flow in the composite processing in the processing flow by the tape processing apparatus.
FIG. 21 is an external perspective view showing a tape cartridge dedicated to cutout processing.
FIG. 22 is an external perspective view showing a state in which the lid of the tape cartridge dedicated to the cutting process is opened.
FIG. 23 is a longitudinal sectional view showing an internal structure of a tape processing apparatus in which a tape cartridge for clipping processing is mounted.
FIG. 24 is a flowchart showing a cut-out process flow in the process flow of the tape processing apparatus.
FIG. 25 is a flowchart showing a process flow of a cutting process for a fixed length cutting tape in the process flow of the tape processing apparatus.
FIG. 26 is a flowchart illustrating a similar processing flow subsequent to FIG. 25;
FIG. 27 is a cross-sectional view showing around the full cut mechanism in the tape processing apparatus.
FIG. 28 is a cross-sectional view showing the periphery of the tape width regulating mechanism in the tape processing apparatus.
FIG. 29 is a perspective view showing a tape width regulating mechanism according to another embodiment.
FIG. 30 is a cross-sectional view showing a tape width regulating mechanism according to another embodiment.
[Explanation of symbols]
1 Tape processing device 2 Device case
3 Device body 4 Device frame
5 Tape cartridge 19 Cartridge mounting part
22 Tape feeding mechanism 23 Printing mechanism
24 Full cut mechanism 25 Half cut mechanism
26 Controller 27 Path change mechanism
29 Tape width regulating mechanism 30 Tape storage processing section
32 Tape outlet 36 Print head
42 Platen roller 57 Side frame
59 Operation frame 61 Support frame
63 Engagement hole 65 Guide shaft
66 Bush 67 Escape opening
68 Lower roller support part 69 Upper roller support part
77 Fitting hole 78 Annular hole
79 Notch 81 Feed drive motor
82 Forward / reverse feed mechanism 85 Platen clutch mechanism
91 Grip roller 92 First tension roller
93 Second tension roller 95 First clutch mechanism
96 Second clutch mechanism 131 Anti-sticking roller
134 Internal space 135 Storage case
136 Case outer surface 137 Case inner surface
139 End 181 Cutting Bit
182 Slide cutter 184 Carriage
185 Reciprocating mechanism 187 Carriage lead screw
218 Up-down mechanism 219 Cutter separation mechanism
241 Cutter blade 242 Cutter holder
243 Tape pressing member 244 Pressing spring
245 Stopper 246 Blade insert member
247 Blade member 250 Rotation prevention receiving part
252 Cutter receiving part 253 Cutter receiving groove
271 Bite 281 Receiving plate
282 Bite receiving groove 301 Width regulation guide
302 Guide moving mechanism 304 Guide lead screw
305 Width regulating motor 308 Guide female thread
311 Center 312 Right male thread
313 Left male screw part 321 Upper guide part
322 Lower guide part 325 Upper guide piece
326 Lower guide piece 327 Star roller
331 Route changing member 332 moving mechanism
351 Interlocking motor 353 Worm wheel
354 Up / down cam 355 Frame motion cam
366 Pin 367 idling groove
401 Tape cartridge 501 Annular hole
502 fitting part 503 mounting part
504 Flange 505 Stopper
531 Lead shaft 533 Cylindrical cam groove
534 Cam projection 536 Center part
537 Position regulating groove 538 Feed groove
A Travel route B Branch route
C Reciprocating path T Cutting tape
Ta peeling tape Tb tape body
R ink ribbon

Claims (9)

For the cutting tape that is made by laminating the peeling tape and the tape body,
In a tape processing apparatus that selectively performs a printing process that performs printing only on the tape body, a clipping process that performs only clipping on the tape body, and a combined process that performs printing and clipping on the tape body,
A tape feed mechanism that feeds the cutting tape and sends it along a travel path;
A printing mechanism that faces the upstream side of the traveling path and performs printing on the cutting tape in synchronization with the forward feeding of the tape feeding mechanism;
A full-cut mechanism that faces the travel path downstream of the printing mechanism and separates the cutting tape into a predetermined dimension;
A half-cut mechanism that faces the travel path on the downstream side of the full-cut mechanism and cuts the tape piece separated in synchronization with the forward / reverse feed of the tape feed mechanism into an arbitrary cut shape,
Path changing means for guiding the tape piece fed back in the cutting process and the combined process to a branch path extending in the winding direction of the cutting tape from the traveling path in the immediate vicinity of the downstream side of the full cut mechanism;
Control means for selectively controlling the tape feeding mechanism, the printing mechanism, and the half-cut mechanism according to each of the printing process, the cut-out process, and the combined process ,
The tape feeding mechanism is
A tape feeding mechanism disposed on the upstream side of the full-cut mechanism and feeding out the cutting tape;
A forward / reverse feed mechanism disposed downstream of the full cut mechanism and capable of forward / reverse feed of the cutting tape;
A tape processing apparatus , comprising: a clutch mechanism that cuts off the power of the tape feeding mechanism so that the tape feeding by the tape feeding mechanism and the tape feeding by the forward / reverse feeding mechanism do not overlap . A process selection command means for selectively commanding the printing process, the cutout process, and the combined process;
2. The tape processing apparatus according to claim 1, wherein the control unit selectively controls the tape feeding mechanism, the printing mechanism, and the half-cut mechanism based on a selection command of the processing selection command unit. . The control means, when performing the printing process, drives the printing mechanism in synchronization with the tape feeding mechanism to perform printing on the cutting tape, and controls the full-cut mechanism after printing to print the printed part. 3. The tape processing apparatus according to claim 1 , wherein the tape processing apparatus is configured to allow the tape piece to pass through the half-cut mechanism in a standby state by driving the forward / reverse feed mechanism forward. The control means, when performing the cut-out process, sets the printing mechanism in a standby state, controls the tape feeding mechanism to send the cutting tape to the forward / reverse feeding mechanism, and controls the full-cut mechanism. 3. The tape according to claim 1, wherein the cutting tape is cut into a predetermined size, and the half-cut mechanism is driven in synchronization with the forward-reverse feed of the tape piece by controlling the forward-reverse feed mechanism. Processing equipment. The control means drives the printing mechanism in synchronization with the tape feeding mechanism to perform printing on the cutting tape when performing the combined processing, and controls the full-cut mechanism after printing to control the printed portion. 3. The tape processing apparatus according to claim 1, wherein the half-cut mechanism is driven in synchronization with forward / reverse feed of the tape piece by controlling the forward / reverse feed mechanism. The control means controls the tape feeding mechanism to feed the cutting tape to the forward / reverse feeding mechanism, and controls the clutch mechanism to shut off the power to the tape feeding mechanism when performing the combined processing. Thereafter, the printing mechanism is driven in synchronization with the forward feed of the forward / reverse feed mechanism to perform printing on the cutting tape, and after printing, the full cut mechanism is controlled to separate the printed portion, and the forward / reverse 3. The tape processing apparatus according to claim 1, wherein the half-cut mechanism is driven in synchronization with forward / reverse feed of the tape piece by controlling a feed mechanism. The forward / reverse feed mechanism includes a grip roller including a driving roller and a driven roller, and a roller separation mechanism that relatively moves the driving roller and the driven roller.
Wherein the control means controls the roller disjunction mechanism, when the cutting tape is stopped feeding for disconnecting, in any one of claims 1 to 6, characterized in that the gripping roller and the gripping state The tape processing apparatus as described. The cutting tape is housed in a tape cartridge in a state of being wound into a roll so as to be freely fed out.
8. The tape processing apparatus according to claim 1 , further comprising a cartridge mounting portion for detachably mounting the tape cartridge. The cutting tape is prepared with a plurality of types suitable for each of the printing process, the cutting process and the combined process,
Correspondingly, the tape cartridge is prepared with a plurality of types for accommodating the cutting tapes,
9. The tape processing apparatus according to claim 8 , wherein the cartridge mounting unit is configured as a single unit that can detachably mount the tape cartridges from the same direction.

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