1. Technical Field
The present invention relates to a tape cartridge to be attached in a detachable manner to a tape printing device.
2. Background Art
Conventionally, as a tape printing device (tape writer) in which the tape cartridge of this type is used, a tape printing device including a body case that houses various mechanisms, a cartridge mounting portion for detachably mounting the tape cartridge, and five photointerrupters that are arranged on an inner wall of the cartridge mounting portion in a line is known (see Japanese Patent No. 3247585).
The tape cartridge has a specification display seal for identifying the specification of a printing tape and strange printing ink in a side surface portion. On the other hand, five photointerrupters are disposed so as to face the specification display seal. Then, the five photointerrupters detect whether or not black ink is printed in five specification display portions formed in the specification display seal and identify the specification based on a detection result.
However, in the tape printing device of this type, play on manufacturing tolerance is inevitably provided between the tape cartridge and the cartridge mounting portion. As a result, a position of the mounted tape cartridge may be positioned so as to be shifted by the tolerance. That is, the position of the tape cartridge is positioned so as to be shifted by the tolerance with respect to each photointerrupter.
Thus, in the configuration of the related art described above, a positional relationship between each photointerrupter and each specification display portion (specification display seal) provided in the tape cartridge is shifted at every time of mounting and there is a problem that the position of each specification display portion is shifted from an optimal position for performing detection by each photointerrupter. Therefore, there is a concern that detection ability by each photointerrupter is lowered and the specification described above cannot be correctly identified.
In addition, even if the positional relationship between each photointerrupter and each specification display portion becomes an optimal positional relationship when mounting is performed, the position of the tape cartridge is shifted and the optimal positional relationship cannot be maintained due to shock from the outside and forces from various driving shafts of the tape printing device.
An object of the present invention is to provide a tape cartridge which causes a positional relationship between a detecting portion on a tape printing device side and a detected portion on a tape cartridge side to be an optimal positional relationship, and maintains the optimal positional relationship.
According to the present invention, there is provided a tape cartridge that is mounted on a tape printing device including a detecting portion for reading various types of information of the tape cartridge from a detected portion by applying a detection light to the detected portion disposed in the tape cartridge in a detachable manner in a mounting direction and a removal direction, the tape cartridge including the detected portion disposed on a wall surface which is formed along the mounting direction; and an engaging portion disposed on a wall surface on a mounting direction side. The engaging portion is engaged with an engaged portion provided in a holder in which the detecting portion is disposed and performs positioning between the detecting portion and the detected portion via the holder.
In this case, it is preferable that the engaged portion is configured of a protrusion portion and the engaging portion is configured of a hole portion engaged with the protrusion portion.
According to these configurations, if the tape cartridge is mounted on the tape printing device, the engaging portion of the tape cartridge is engaged with the engaged portion of the holder in which the detecting portion is disposed. The tape cartridge and the holder are integrated, and the position of the detecting portion is positioned with respect to the position of the detected portion by the engagement. A positional relationship between the detecting portion and the detected portion can be an optimal positional relationship by positioning according to the mounting. In addition, the engaging portion and the engaged portion are engaged and thereby it is possible to prevent a position of the tape cartridge with respect to the detecting portion and an inclination (angle) of the tape cartridge with respect to the detecting portion from being shifted by shock from the outside and force from each driving shaft of the tape printing device. That is, it is possible to maintain the optimal positional relationship between the detecting portion and the detected portion. Therefore, it is possible to cause the positional relationship between the detecting portion and the detected portion to be the optimal positional relationship, and to maintain the optimal positional relationship. Thus, it is possible to improve detection ability by the detecting portion and to correctly read various types of information of the tape cartridge.
In this case, it is preferable that the tape cartridge further includes a cartridge case, the cartridge case is configured of two members of a first member on a removal direction side and a second member on the mounting direction side, the first member has a joining pin for joining the first member to the second member, the second member has a joining hole into which the joining pin is joined, and the engaging portion is disposed coaxially in the joining hole on the wall surface of the second member on the mounting direction side.
According to the configuration, since the engaging portion is disposed by using a space immediately below (or immediately above) the joining hole, it is possible to dispose the engaging portion with good efficiency in space. Thus, it is possible to form the engaging portion by using a “waste hole” portion generated when forming the joining hole.
In addition, it is preferable that the engaging portion and the joining hole are configured of an integral through-hole.
According to the configuration, it is possible to easily form the engaging portion and the joining hole, and to simply configure the tape cartridge compared to a case in which the engaging portion and the joining hole are individually formed.
Hereinafter, a tape cartridge according to an embodiment of the invention will be described with reference to the drawings together with a tape printing device on which the tape cartridge is mounted. The tape printing device is provided to create a label (tape piece) by performing printing while feeding a printing tape and an ink ribbon from the mounted tape cartridge.
[Overview of Tape Printing Device]
In addition, the tape printing device 1 includes a printing mechanism portion 23 that has a printing head 21 provided uprightly in the cartridge mounting portion 5, a tape feeding mechanism 25 that is built in a rear space of the cartridge mounting portion 5, and a tape cutting mechanism 27 that is built in the vicinity of the tape discharge port 17. A user inputs printing information from the keyboard 13, recognizes the present invention in the display 11, and then executes printing with a key operation. If printing is commanded, the tape feeding mechanism 25 is driven and thereby the printing tape 102 and an ink ribbon 110 run in parallel. Furthermore, ink of the ink ribbon 110 is transferred to the printing tape 102 by heat applied from the printing mechanism portion 23 to the ink ribbon 110 and thereby printing is performed. The printing tape 102 is discharged from the tape discharge port 17 by print feeding and if printing is completed, the tape cutting mechanism 27 is driven and thereby a printed portion of the printing tape 102 is cut.
[Overview of Tape Cartridge]
As illustrated in
In addition, when the tape cartridge 100 is mounted on the tape printing device 1, an insertion opening 134 into which the printing head 21 is inserted is formed in the cartridge case 130 in the tape cartridge 100. The tape cartridge 100 includes a tape feeding port 138 which is formed in the cartridge case 130 and from which the printing tape 102 is fed. Moreover, the tape roll 106, which is described later, is rotatably supported on a cylindrical core shaft 192 protruding on the inside of the cartridge case 130.
If the platen roller 120 and the winding core 116 are driven by the tape feeding mechanism 25 described above, the printing tape 102 is fed from the tape core 104 and the ink ribbon 110 is fed from the feeding core 112. The printing tape 102 and the ink ribbon 110, which are fed, run in parallel in the platen roller 120 portion and are subjected to printing by the printing head 21. A feeding end portion (printed portion) of the printing tape 102, in which printing is performed, is fed from the tape feeding port 138 to the tape discharge port 17. On the other hand, the ink ribbon 110 rotates around a peripheral wall portion of the insertion opening 134 and is wound on the winding core 116. Moreover, a plurality of types of printing tapes having different thicknesses according to a tape width of the printing tape 102 are prepared in the tape cartridge 100.
[Details of Tape Printing Device]
As illustrated in
A positioning protrusion 41 which is positioned by fitting of the core shaft 192, the printing head 21 which is covered by a head cover 43, a platen driving shaft 45 which drives the platen roller 120 to rotate, and a winding driving shaft 47 which drives the winding core 116 to rotate are provided uprightly in the mounting base 31 of the cartridge mounting portion 5. In addition, a tape width detecting portion 51 which detects a tape width of the printing tape 102 and a core release portion 53 which releases rotation stoppers of the feeding core 112 and the winding core 116 are provided in positions in the vicinity of the winding driving shaft 47 in the mounting base 31.
Furthermore, a pair of small protrusions 55 is provided at diagonal positions in the mounting base 31. In addition, a pair of latch pieces 57 for latching a center portion of the mounted tape cartridge 100 is provided. On the other hand, the tape feeding mechanism 25 configured of a motor and a gear train (both not illustrated), and the like for rotating the platen driving shaft 45 and the winding driving shaft 47 is built into a rear space of the mounting base 31. The tape feeding mechanism 25 is power-branched in the gear train and synchronously rotates the platen driving shaft 45 and the winding driving shaft 47.
On the other hand, a pattern reading portion 59 for reading a type reading pattern 145 described below provided on a side surface of the tape cartridge 100 is disposed in the side plate portion 33 (front side) of the cartridge mounting portion 5. In the embodiment, the tape width detecting portion 51 detects (recognizes) the tape width of the printing tape 102 housed in the tape cartridge 100 and the pattern reading portion 59 recognizes type information (tape color and material of the housed printing tape 102, and ribbon color of the housed ink ribbon 110, and the like) of the tape cartridge 100 except the tape width. Details of the pattern reading portion 59 will be described later.
The printing mechanism portion 23 has the printing head 21 configured of a thermal head and a head support frame 61 that is rotated while supplying the printing head 21. In addition, the printing mechanism portion 23 has a head release mechanism (not illustrated) that rotates the printing head 21 between a printing position and a retracted position via the head support frame 61, and the head cover 43 that covers the printing head 21 (and the head support frame 61).
The head release mechanism is operated in conjunction with opening and closing of the opening and closing lid 7, and moves (rotates) the printing head 21 to the printing position in conjunction with a closing operation of the opening and closing lid 7. In addition, the head release mechanism causes the printing head 21 to be moved (rotated) in conjunction with an opening operation. The printing head 21 moved to the printing position abuts against the platen roller 120 via the ink ribbon 110 and the printing tape 102, and the printing head 21 moved to the retracted position is separated from the platen roller 120. Therefore, when mounting and demounting the tape cartridge 100, interference of the printing tape 102 and the ink ribbon 110 with the printing head 21 is prevented.
A plurality of heat generating elements are provided in the printing head 21 and the plurality of heat generating elements are arranged in parallel in the same direction as an axial direction of the platen roller 120. Then, printing is performed by delivery of the printing tape 102 and the ink ribbon 110, and selective driving of the plurality of heat generating elements. The head cover 43 is formed in a substantially rectangular shape in a plan view and is formed (molded) integrally with the mounting base 31 (cartridge mounting portion 5). In addition, the head cover 43 largely vertically protrudes from the mounting base 31, allows the rotation of the printing head 21 on the inside thereof, and functions as a mounting guide of the tape cartridge 100 on the outside.
The tape width detecting portion 51 is configured of a plurality of micro switches 51a, selectively engages with a detection hole group 180 of the tape cartridge 100 described below, and detects the tape width of the printing tape 102.
The core release portion 53 is configured of two release pins 53a for the feeding core 112 and the winding core 116. Although details will be described later, a rotation stopper hook 206 for latching each of the feeding core 112 and the winding core 116 is provided in the cartridge case 130 (see
The platen driving shaft 45 has a platen support shaft 48 elongated so as to pass through the platen roller 120 and a spline-shaped rotation driving shaft 49 rotatably journaled on a base portion of the platen support shaft 48 (see
Similarly, the winding driving shaft 47 has a fixed shaft 47a and a spline-shaped movable shaft 47b rotatably journaled on the fixed shaft 47a. Also, in this case, rotational power of the tape feeding mechanism 25 is transmitted to the movable shaft 47b and is further transmitted from the movable shaft 47b to the winding core 116.
If the tape cartridge 100 is mounted on the cartridge mounting portion 5, the core shaft 192 (the tape core 104) is engaged with the positioning protrusion 41, the platen roller 120 is engaged with the platen driving shaft 45, and the winding core 116 is further engaged with the winding driving shaft 47. Then, if the opening and closing lid 7 is closed, the printing head 21 is rotated and abuts against the platen roller 120 to interpose the printing tape 102 and the ink ribbon 110 therebetween, and the tape printing device 1 is in a printing standby state.
As illustrated in
The viewing window 75 is formed to be horizontally elongated and is configured of transparent (transparent to visible light) resin as a separate body from the opening and closing lid body 73. The tape cartridge 100 mounted on the cartridge mounting portion 5 is visible (type of the printing tape 102 and tape remaining amount) over the viewing window 75. In addition, the pair of journal pieces 77, the operation lever 79, the push protrusion 81, the pressing protrusion 83, and the opening and closing lid body 73 are integrally formed (molded) of resin.
The operation lever 79 largely protrudes from the rear surface of the opening and closing lid body 73 and is inserted into a slit opening 87 provided on the side surface of the cartridge mounting portion 5 in accordance with closing of the opening and closing lid 7. The operation lever 79 inserted into the slit opening 87 operates the head release mechanism and rotates the printing head 21. Similarly, the pressing protrusion 83 is inserted into a rectangular opening 91 adjacent to the slit opening 87 and operates (ON) the lid closing detection switch in accordance with the closure of the opening and closing lid 7. The push protrusion 81 corresponds to a position in the vicinity of the platen roller 120 of the tape cartridge 100 and presses the tape cartridge 100 so that the tape cartridge 100 sits on the mounting base 31 of the cartridge mounting portion 5 in accordance with closing of the opening and closing lid 7.
[Details of Tape Cartridge]
Next, the tape cartridge 100 will be described in detail with reference to
As described above, the tape cartridge 100 includes the cartridge case 130, the tape roll 106 housed therein, the ribbon roll 114, the winding core 116, and the platen roller 120. In addition, the tape cartridge 100 includes the insertion opening 134 formed in the cartridge case 130 and the tape feeding port 138 formed on the left side surface in the vicinity of the platen roller 120.
Furthermore, the tape cartridge 100 includes a type display seal 141 (see
On the other hand, the type reading pattern (detected portion) 145 indicating type information (tape color and a material of the housed printing tape 102, and the ribbon color of the housed ink ribbon 110, and the like) of the tape cartridge 100 is formed in the type reading seal 143 (see
The cartridge case 130 configures an outer shell of the tape cartridge 100 (shell structure) and has an appearance of an “L” shape in a plan view of which the base end side of the right side surface protrudes somewhat. The cartridge case 130 in a front and rear direction is configured of two members of a lower case 150 (second member) that becomes the rear side (mounting direction side) and an upper case 152 (first member) that becomes the front side (removal direction side) when being mounted on the cartridge mounting portion 5. The cartridge case 130 of the embodiment is configured such that the upper case 152 is formed of molding of transparent resin and the lower case 150 is formed of molding of opaque resin.
The upper case 152 is formed (molded) integrally with a top wall portion 156 configuring the surface of the cartridge case 130 and an upper periphery wall portion 158 provided uprightly in a periphery portion of the top wall portion 156. In addition, the lower case 150 is formed (molded) integrally with a bottom wall portion 160 configuring the rear surface of the cartridge case 130, a lower periphery wall 162 provided uprightly in the periphery portion of the bottom wall portion 160, and an opening periphery wall portion 164 vertically provided in the bottom wall portion 160 in order to form the insertion opening 134.
A plurality of joining pins 170 are provided on the lower end surface of the upper periphery wall portion 158 at appropriate intervals in the upper case 152 and a plurality of joining holes 172, which correspond to the plurality of joining pins 170 and to which the plurality of joining pins 170 are respectively joined, are provided in the lower periphery wall 162 of the lower case 150 (see
On the other hand, a pair of latch receiving portions 174 that are latched to the pair of latch pieces 57 of the cartridge mounting portion 5 are provided on the left side surface and the right side surface of the lower case 150 (see
In addition, as illustrated in
Furthermore, fitting small holes 176 into which the pair of small protrusions 55 are fitted with clearance somewhat are provided on the rear surface of the lower case 150. The pair of small protrusions 55 on the cartridge mounting portion 5 side are fitted into a pair of fitting small holes 176 of the mounted tape cartridge 100 and thereby simple positioning of the tape cartridge 100 is performed on the mounting base 31.
In addition, the detection hole group 180, which is positioned in a left corner portion (right corner portion viewed on the front surface side) on the base end surface side and corresponds to the tape width detecting portion 51, is provided on the rear surface of the lower case 150 (see
In addition, a positioning hole portion 182 (engaging portion) engaged with a positioning pin 326 (described below) provided in the pattern reading portion 59 is disposed in the vicinity of the detection hole group 180. Details of the positioning hole portion 182 will be described later.
As illustrated in
That is, a tape delivery path 196 from the tape roll 106 as a starting point to the tape feeding port 138 through the tape guide 194 and the platen roller 120 is configured within the cartridge case 130. The printing tape 102 fed from the tape roll 106 is guided to the platen roller 120 via the tape guide 194, is subjected to printing in the platen roller 120, and is further guided from the platen roller 120 to the tape feeding port 138.
The tape roll 106 has the printing tape 102 and the tape core 104, and also has two films 198 adhered on both end surfaces of the printing tape 102 of a roll shape. The two films 198 prevent loosening of the printing tape 102 wound around the tape core 104. In addition, although not illustrated, a reverse rotation stop mechanism is incorporated in the tape core 104. When carrying the tape cartridge 100, the reverse rotation of the printing tape 102 is prevented by the reverse rotation stop mechanism. On the other hand, if the tape cartridge 100 is mounted on the cartridge mounting portion 5 of the tape printing device 1, the reverse rotation stop of the reverse rotation stop mechanism is released by the positioning protrusion 41 and delivery of the printing tape 102 may be performed.
A ribbon housing area 200 is configured adjacent to the insertion opening 134 on the right side of the base portion on the inside of the cartridge case 130. A feeding-side bearing portion 202 rotatably supporting the ribbon roll 114 (the feeding core 112) is formed integrally with the cartridge case 130 on the right side of the ribbon housing area 200 and a winding-side bearing portion 204 rotatably supporting the winding core 116 is formed integrally with the cartridge case 130 on the left side thereof. That is, the feeding-side bearing portion 202 and the winding-side bearing portion 204 are respectively formed in the upper case 152 and the lower case 150.
The rotation stopper hooks 206 of which leading end portions face the feeding-side bearing portion 202 and the winding-side bearing portion 204 are respectively and integrally formed in cutout portions of the feeding-side bearing portion 202 and the winding-side bearing portion 204 formed in the lower case 150. Then, one rotation stopper hook 206 is engaged with the feeding core 112 and the other rotation stopper hook 206 is engaged with the winding core 116 respectively in a rotation stop state.
A first ribbon guide 210, which is positioned in the vicinity of the feeding-side bearing portion 202 and guides the fed ink ribbon 110 to the platen roller 120 is provided uprightly and integrally with the lower case 150 in the ribbon housing area 200. In addition, a plurality of second ribbon guides 212, which guide circulation of the ink ribbon 110, are integrally formed on an outer periphery side of the opening periphery wall portion 164.
That is, a ribbon delivery path 214 from the ribbon roll 114 as a starting point to the winding core 116 through the first ribbon guide 210, the platen roller 120 and the plurality of second ribbon guides 212 is configured on the inside of the cartridge case 130. The ink ribbon 110 fed from the ribbon roll 114 is guided to the platen roller 120 via the first ribbon guide 210, where it is subjected to printing, and is wound around the winding core 116 by circulating the opening periphery wall portion 164 (plurality of second ribbon guides 212) from the platen roller 120.
The ribbon roll 114 has the ink ribbon 110 and the feeding core 112, and also has an annular leaf spring 220 applying a braking load to the feeding core 112 (see
The feeding core 112 is formed in a cylindrical shape and a plurality of cutouts 222 is formed in an end portion on the lower case 150 side in the circumferential direction (see
Similarly, the winding core 116 is formed in a cylindrical shape and a plurality of cutouts 224 are formed in an end portion on the lower case 150 side in the circumferential direction. Then, the rotation stopper hooks 206 are engaged and disengaged with the plurality of cutouts 224. In addition, spline grooves 226 are formed on an inner peripheral surface of the winding core 116 and are splined to the winding driving shaft 47. Therefore, the rotational force of the winding driving shaft 47 is transmitted to the winding core 116 and the ink ribbon 110 is wound.
A platen housing area 230 is configured adjacent to the insertion opening 134 on the left side of the base portion within the cartridge case 130. A lower bearing portion 234 (see
Meanwhile, the tape cartridge 100 carries the feeding end portion of the printing tape 102 in a state of slightly protruding from the tape feeding port 138 to the outside (see
The platen roller 120 has a cylindrical roller base body 240 and a rubber roller 242 mounted on an outer peripheral surface of the roller base body 240. The rubber roller 242 has a length corresponding to the printing head 21 in the axial direction and the printing head 21 moved to the printed position comes into contact with the rubber roller 242 by sandwiching the printing tape 102 and the ink ribbon 110. In addition, spline grooves 244 are formed on an inner peripheral surface of the roller base body 240 and the rotation driving shaft 49 of the platen driving shaft 45 is splined into the spline grooves 244. Therefore, the rotational force of the platen driving shaft 45 is transmitted to the platen roller 120 and print feeding of the printing tape 102 (and the ink ribbon 110) is performed.
[Details of Pattern Reading Portion and Positioning Hole Portion]
Next, the pattern reading portion 59 and the positioning hole portion 182 will be described with reference to
The unit support portion 302 is provided in an opening portion 33a opened to the side plate portion 33 of the cartridge mounting portion 5 and supports the sensor unit 300 to be movable to the inside and the outside of the cartridge mounting portion 5.
The unit biasing portion 304 has a pair of right and left coil springs 306 and biases a pair of spring receiving portions 324 (described below) provided in the sensor unit 300 by the pair of coil springs 306. That is, the unit biasing portion 304 biases the sensor unit 300 into the cartridge mounting portion 5 via the pair of spring receiving portions 324 by the pair of right and left coil springs 306. In a state where the tape cartridge 100 is not mounted, the sensor unit 300 is in a state of protruding toward the cartridge mounting portion 5 by the bias. In addition, in a state where the tape cartridge 100 is mounted, the sensor unit 300 is biased on the tape cartridge 100 side and the sensor unit 300 is in a state of being pressed against the base end surface of the tape cartridge 100.
As illustrated in
The plurality of optical sensors 309 are arranged on the sensor substrate 308 in a matrix shape of two rows and four columns similar to the bit configuration portion 147 (see
The sensor holder 312 includes a holder body 320 having a trapezoidal shape in a side view, a pair of upper and lower substrate mounting hooks 322 protruding from the holder body 320 on the base end side, a pair of right and left spring receiving portions 324 protruding from the base end portion of the holder body 320 on right and left sides, the positioning pin 326 (engaged portion) provided on a right front side of the holder body 320, and a connection portion 328 connecting the positioning pin 326 and the holder body 320. Moreover, the holder body 320, the pair of substrate mounting hooks 322, the pair of spring receiving portions 324, the positioning pin 326, and the connection portion 328 are integrally formed (molded) of resin and the like.
The pair of substrate mounting hooks 322 mount the sensor substrate 308 on the sensor holder 312. That is, the sensor substrate 308 is mounted on the sensor holder 312 by the pair of substrate mounting hook 322.
The pair of spring receiving portions 324 are portions against which one end of the pair of right and left coil springs 306 abut and which receive a biasing force of the pair of right and left coil springs 306. The pair of spring receiving portions 324 abut against the side plate portion 33 of the cartridge mounting portion 5 and also function as a front end regulation portion for performing regulation of the front end in the movement of the sensor unit 300.
The holder body 320 is configured of a holder cover 330 that covers an entirety of the plurality of optical sensors 309 and partition members 332 that individually surround each optical sensor 309. A plurality of sensor holes 334 corresponding to the plurality of optical sensors 309 are formed in a leading end portion of the holder cover 330. Each optical sensor 309 applies the detection light from each sensor hole 334 and receives the reflection light from each bit configuration portion 147 from each sensor hole 334.
The holder cover 330 functions as an external light shielding portion for shielding external light toward each optical sensor 309. On the other hand, the partition member 332 functions as an interference preventing portion for shielding the detection light from the adjacent optical sensors 309 and preventing interference between the optical sensors 309.
In addition, the holder cover 330 also functions as a spacer that abuts against the base end surface of the tape cartridge 100 and causes clearance between the sensor portion 310 (each optical sensor 309) and the type reading pattern 145 to be a predetermined clearance in addition to the function of the external light shielding portion. That is, a leading end surface 330a of the holder cover 330 becomes an abutting surface against the base end surface of the tape cartridge 100. Then, if the holder cover 330 is pressed by the tape cartridge 100 via the pair of spring receiving portions 324 by bias of the unit biasing portion 304 (pair of right and left coil springs 306), the leading end surface 330a abuts against the base end surface of the tape cartridge 100 to come into close contact with the base end surface. Therefore, the predetermined clearance is formed between the sensor portion 310 and the type reading pattern 145. Moreover, the leading end surface 330a of the holder cover 330 is formed to be inclined slightly downward so as to follow the base end surface of the tape cartridge 100.
In addition, a leading inclined surface 330b inclined downward on the front side is formed in an upper end portion of the holder cover 330 on the front side. The leading inclined surface 330b abuts against an end portion of the tape cartridge 100 on the rear surface side and causes a part (component force) of a force for mounting the tape cartridge 100 to act as a force for pushing the sensor unit 300 back on the outside of the cartridge mounting portion 5 when mounting the tape cartridge 100. The sensor unit 300 is pushed back against the unit biasing portion 304 by the leading inclined surface 330b in accordance with the mounting of the tape cartridge 100. Therefore, when the mounting of the tape cartridge 100 is completed, the sensor unit 300 is in a state of being pressed against the tape cartridge 100.
The positioning pin 326 is formed in a cylindrical shape which rises upward, tapered, and upright. That is, the leading end portion of the positioning pin 326 is formed in a frustoconical shape and an upper bottom surface portion thereof has a rounded dome shape. The positioning pin 326 becomes the engaged portion of the sensor holder 312 engaged with the positioning hole portion 182.
Next, the positioning hole portion 182 of the tape cartridge 100 will be described with reference to
Next, a mounting operation of the tape cartridge 100 on the cartridge mounting portion 5 will be described with reference to
Thereafter, if the insertion is further advanced, the tape cartridge 100 continues to advance on the rear side in the mounting direction while sliding to the sensor unit 300. The positioning hole portion 182 provided on the rear surface of the tape cartridge 100 is engaged with (positioning) the positioning pin 326 of the sensor unit 300 while positioning of the sensor unit 300 is performed by the frustoconical shape (tapered surface) of the leading end surface of the positioning pin 326 (see
According to the configuration described above, if the tape cartridge 100 is mounted on the tape printing device 1, the positioning hole portion 182 of the tape cartridge 100 is engaged with the positioning pin 326 of the sensor holder 312. The tape cartridge 100 and the sensor holder 312 are integrated and the position of the sensor portion 310 is positioned with respect to the position of the type reading pattern 145 by the engagement. The positional relationship between the sensor portion 310 and the type reading pattern 145 can be the optimal positional relationship by positioning in accordance with mounting. In addition, the positioning hole portion 182 and the positioning pin 326 are engaged and thereby it is possible to prevent the position and the inclination (angle) of the tape cartridge 100 with respect to the sensor portion 310 from being shifted by shock from the outside and force from each of the driving shafts 45 and 47 of the tape printing device 1. That is, it is possible to maintain the optimal positional relationship between the sensor portion 310 and the type reading pattern 145. As described above, it is possible to make the positional relationship between the sensor portion 310 and the type reading pattern 145 the optimal positional relationship and to maintain the optimal positional relationship. Therefore, it is possible to improve a detection ability by the sensor portion 310 (each of the optical sensor 309) and to accurately read the type information of the tape cartridge 100.
In addition, in the lower case 150, the positioning hole portion 182 is formed coaxially with one of the joining holes 172 and thereby the positioning hole portion 182 is disposed by using the space immediately below the joining hole 172. Therefore, it is possible to dispose the positioning hole portion 182 with good efficiency in space. Thus, it is possible to form the positioning hole portion 182 by using a “waste hole” generated when forming the joining hole 172.
Furthermore, the joining hole 172 and the positioning hole portion 182 are configured by the integral through-hole 172a and thereby it is possible to easily form the joining hole 172 and the positioning hole portion 182. In addition, it is possible to simply configure the tape cartridge 100.
In addition, in the embodiment described above, the positioning hole portion 182 and the joining hole 172 are configured by the integral through-hole 172a, but the positioning hole portion 182 and the joining hole 172 may be individually formed.
In addition, in the embodiment described above, the positioning hole portion 182 and the positioning pin 326 are provided in only one set, but they may be provided in two sets or more.
Furthermore, in the embodiment described above, the shape of the positioning hole portion 182 is circular, but the shape is not limited to the embodiment. For example, the shape of the positioning hole portion 182 may be rectangular and other polygons.
In addition, in the embodiment described above, the engaging portion (positioning hole portion 182) on the tape cartridge 100 side is the hole portion and the engaged portion (positioning pin 326) on the sensor unit 300 side is the protrusion portion, which are used for positioning between the sensor portion 310 and the type reading pattern 145, but the portions are not limited to the embodiment. For example, the former may be the protrusion portion and the latter may be the hole portion.
In addition, in the embodiment described above, each of the bit configuration portion 147 and the detection sensor 309 includes eight of two rows and four columns, but the number and arrangement (the number of rows and the number of columns) thereof are not limited to the embodiment. For example, each of the bit configuration portion 147 and the detection sensor 309 may be horizontally arranged side by side as six of one row and six columns or may be vertically arranged side by side as six of six rows and one column. In addition, the number of rows and the number of columns may be the same as each other as sixteen of four rows and four columns.
In addition, in the embodiment described above, the bit configuration portion 147 displays the bit information of one bit by whether or not black ink is printed (solid printing) in a white printing region, but the color of the printing region and the color of ink to be printed are not limited to the embodiment if the bit information can be detected by the detection sensor 309 (if presence or absence and intensity of the reflection light can be detected when applying the detection light). For example, bit information of one bit may be displayed by whether or not white ink is printed in a black printing region. In addition, for example, one of the color of the printing region and the color of ink may be a color of blue, navy blue, and a greenish color, and the other may be red, yellow, and orange.
Furthermore, in the embodiment described above, the type reading seal 143 on which the type reading pattern 145 is formed is adhered to the side surface of the tape cartridge 100 and the type reading pattern 145 is provided on the side surface of the tape cartridge 100, but the type reading pattern 145 may be directly formed on the side surface of the tape cartridge 100. In such a case, the type reading pattern 145 may be printed on the side surface or the type reading pattern 145 may be engraved on the side surface by a laser and the like. Furthermore, an opening is selectively formed with respect to each bit configuration portion 147 and thereby the type reading pattern 145 may be formed.
Number | Date | Country | Kind |
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2014-201784 | Sep 2014 | JP | national |
The present application is a continuation application of U.S. patent application Ser. No. 15/166,302 filed on May 27, 2016, which is a continuation of PCT application No. PCT/JP2015/071889 filed on Jul. 31, 2015, which claims priority to Japanese Patent Application No. 2014-201784 filed Sep. 30, 2014, the contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
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5959652 | Privin | Sep 1999 | A |
6042280 | Yamaguchi et al. | Mar 2000 | A |
6196740 | Yamaguchi et al. | Mar 2001 | B1 |
6650351 | Yamamoto et al. | Nov 2003 | B2 |
20110293350 | Noda et al. | Dec 2011 | A1 |
20150343821 | Sakano | Dec 2015 | A1 |
Number | Date | Country |
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A1-0333375 | Sep 1989 | EP |
3247585 | Jan 2002 | JP |
2002053272 | Feb 2002 | JP |
A-2012-006209 | Jan 2012 | JP |
2013-141749 | Jul 2013 | JP |
Entry |
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Notice of Allowance and Notice of Allowability received in U.S. Appl. No. 15/166,302, dated Sep. 13, 2016. |
Number | Date | Country | |
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20170087901 A1 | Mar 2017 | US |
Number | Date | Country | |
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Parent | 15166302 | May 2016 | US |
Child | 15374296 | US | |
Parent | PCT/JP2015/071889 | Jul 2015 | US |
Child | 15166302 | US |