TAPE CARTRIDGE AND TAPE PRINTING APPARATUS

TECHNICAL FIELD

The present invention relates to a tape cartridge installed in a tape printing apparatus and to the tape printing apparatus.

BACKGROUND ART

Conventionally, there has been known a cartridge including: a tag tape having a plurality of wireless tag circuit elements provided along a tape length direction and a plurality of black marks provided along the tape length direction corresponding to the plurality of wireless tag circuit elements; a cover film affixed to the tag tape after being printed; and a cartridge case in which the tag tape and the cover film are accommodated so as to be capable of being paid out, the cartridge being installed in a tag label creation apparatus that starts printing on the cover film with a print head based on the detection of the passage of the respective black marks by a mark sensor while feeding the tag tape and the cover film (see Patent Document 1).

In addition, the present applicant has proposed a sheet cartridge including: a label sheet having a plurality of label portions provided along a sheet length direction and a plurality of convex-piece tip-ends provided along the sheet length direction corresponding to the plurality of label portions; and a cartridge case in which the label sheet is accommodated so as to be capable of being paid out, the sheet cartridge being installed in a label creation apparatus that starts printing, while feeding the label sheet, on the label portions corresponding to the detected convex-piece tip-ends with a print head based on the detection of the passage of the respective convex-piece tip-ends by a light sensor (see Patent Document 2). Patent Document 2 exemplifies a configuration in which the positions of the respective convex-piece tip-ends align with the positions of label tip-ends serving as the ends of the corresponding label portions on the paying-out tip-end side of the sheet in the sheet length direction and positions detected by the light sensor align with positions printed by the print head in the sheet feeding direction.

[Patent Document 1] JP-A-2011-178147

[Patent Document 2] JP-A-2012-171079

In the above prior-art documents, consideration has not been given to rimless printing on the label portions, i.e., printing in which margins are not provided on the peripheries of the label portions. Accordingly, there is a likelihood that the rimless printing cannot be reliably performed on the respective label portions.

The present invention has an object of providing a tape cartridge allowing rimless printing to be performed on respective label portions and a tape printing apparatus.

DISCLOSURE OF THE INVENTION

According to the present invention, there is provided a tape cartridge installed in a tape printing apparatus, the tape cartridge comprising: a tape-shaped member having a plurality of label portions provided along a tape length direction and a plurality of detection convex portions provided along the tape length direction corresponding to the plurality of label portions and partially projecting from an end in a tape width direction; a cartridge case in which the tape-shaped member is accommodated; and a platen roller accommodated in the cartridge case and paying out the tape-shaped member by rotation outside the cartridge case, wherein, in the tape length direction, detection tip-ends serving as downstream-side ends of the detection convex portions are positioned downstream of label tip-ends serving as downstream-side ends of the label portions in a paying-out direction of the tape-shaped member.

According to the configuration, in the tape length direction, the detection tip-ends serving as the downstream-side ends of the detection convex portions are positioned downstream of the label tip-ends serving as the downstream-side ends of the label portions in the paying-out direction of the tape-shaped member. Therefore, printing starts at the positions between the detection tip-ends and the label tip-ends in the tape length direction. Accordingly, rimless printing can be performed on the respective label portions.

In this case, the cartridge case preferably has an exposed area in which the plurality of detection convex portions is exposed one after another as the tape-shaped member is paid out by the platen roller and a tape delivery port from which the tape-shaped member is ejected outside the cartridge case as being paid out by the platen roller, and the tape delivery port is preferably provided on a downstream side of the exposed area in the paying-out direction of the tape-shaped member.

According to the configuration, since the exposed area is provided in the cartridge case, the detection convex portions can be exposed in the exposed area. In addition, since the cartridge case has the tape delivery port, the tape-shaped member can be appropriately ejected outside the cartridge case.

In this case, the cartridge case preferably has a passage port, through which the plurality of detection convex portions passes one after another as the tape-shaped member is paid out by the platen roller, on an upstream side of the exposed area in the paying-out direction of the tape-shaped member.

According to the configuration, since the cartridge case has the passage port, the detection convex portions can appropriately pass through the passage port toward the exposed area.

In this case, the cartridge case preferably has an exposed opening that connects the tape delivery port and the passage opening to each other and causes the plurality of detection convex portions to be exposed in the exposed area.

According to the configuration, since the cartridge case has the exposed opening, the detection convex portions can be appropriately exposed in the exposed area between the passage port and the tape delivery port.

In this case, the cartridge case preferably has a platen engagement hole that pivotally supports a rotation shaft of the platen roller in the exposed area.

In this case, a detection portion provided in the tape printing apparatus is preferably positioned in the exposed area when the tape cartridge is installed in the tape printing apparatus.

According to the configuration, the detection portion positioned in the exposed area can appropriately detect the detection convex portions exposed in the exposed area.

According to the present invention, there is provided a tape printing apparatus comprising: a cartridge installation portion in which the above tape cartridge is installed; a feed portion that pays out and feeds the tape-shaped member; a light sensor that detects passage of the respective detection convex portions and has a light-emission element and a light-reception element facing each other across a feed path of the tape-shaped member and a sensor casing in which the light-emission element and the light-reception element are accommodated and a light-emission-side facing surface and a light-reception-side facing surface facing each other across the feed path are formed; and a detection target guide portion that guides feeding of the respective detection convex portions at a guide width narrower than a facing distance between the light-emission-side facing surface and the light-reception-side facing surface.

According to the configuration, since the tape printing apparatus has the detection target guide portion, the passage position of the detection convex portions in the direction in which the light-emission element and the light-reception element face each other is changed only in the range of the guide width narrower than the distance between the light-emission-side facing surface and the light-reception-side facing surface. That is, the width of the passage position of the detection convex portions in the facing direction can be made narrower than the distance between the light-emission-side facing surface and the light-reception-side facing surface. Therefore, a change in an output voltage at the passage with a change in the passage position of the detection convex portions in the facing direction can be reduced. Accordingly, the deviation of a timing for detecting the passage of the detection convex portions with the change in the output voltage at the passage can be reduced.

In this case, the tape printing apparatus preferably further comprises a casing cover portion that guides the respective detection convex portions to the feed path and covers a peripheral surface of the sensor casing that.

According to the configuration, since the tape printing apparatus has the casing cover portion, a user cannot touch the peripheral surface of the sensor casing with a finger or the like. Accordingly, it is possible to prevent the malfunction of the light sensor due to static built up on the sensor casing when touched by a user's finger or the like electrostatically charged.

In this case, the sensor casing preferably has a groove portion that constitutes the light-emission-side facing surface and the light-reception-side facing surface and serves as the feed path, the detection target guide portion preferably has an upstream-side guide portion provided so as to close some of an upstream-side opening portion of the groove portion on the upstream side in the paying-out direction of the tape-shaped member and a downstream-side guide portion provided so as to close some of a downstream-side opening portion of the groove portion on the downstream side in the paying-out direction of the tape shaped member, and each of the upstream-side guide portion and the downstream-side guide portion is preferably made of a light-shielding material.

According to the configuration, since the upstream-side guide portion that closes some of the upstream-side opening portion of the groove portion and the downstream-side guide portion that closes some of the downstream-side opening portion of the groove portion are made of a light-shielding material, light intruding into the light-reception element from the outside via the upstream-side opening portion or the downstream-side opening portion of the groove portion can be blocked. Accordingly, the malfunction of the light sensor due to the intrusion of the outside light can be prevented.

In this case, the upstream-side guide portion preferably has a light-reception-side upstream guide portion provided so as to close a side of the light-reception element of the upstream-side opening portion, the downstream-side guide portion preferably has a light-reception-side downstream guide portion provided so as to close a side to the light-reception element of the downstream-side opening portion, and each of the light-reception-side upstream guide portion and the light-reception-side downstream guide portion preferably extends to a near side of the light-reception element along the light-reception-side facing surface.

According to the configuration, since the light-reception-side upstream guide portion and the light-reception-side downstream guide portion extend to the near side of the light-reception element along the light-reception-side facing surface, the light intruding into the light-reception element from the outside can be further effectively blocked.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view showing a state in which the cover of a label creation apparatus according to an embodiment of the present invention is closed.

FIG. 2 is a perspective view showing a state in which the cover of the label creation apparatus according to the embodiment of the present invention is opened.

FIGS. 3A to 3C are views showing a label tape accommodated in the tape cartridge of the label creation apparatus.

FIG. 4 is a perspective view of the tape cartridge.

FIG. 5 is a plan view of the tape cartridge.

FIG. 6 is a perspective view of the tape cartridge with its upper casing removed.

FIG. 7 is a plan view of the tape cartridge with the upper casing removed.

FIG. 8 is a perspective view of an opening/closing cover in a closed state when seen from its left lateral side.

FIG. 9 is a bottom view of the opening/closing cover in the vicinity of a light sensor.

FIG. 10 is a horizontal cross-sectional view of the label creation apparatus in the vicinity of the light sensor.

FIG. 11 is a vertical cross-sectional view of the label creation apparatus in the vicinity of the light sensor.

FIGS. 12A to 12E are views showing a print/cut operation in the label creation apparatus.

FIG. 13A is a view for describing the vicinities of a platen roller and a drawing prevention portion, and FIG. 13B is a view for describing a modified example of FIG. 13A.

FIGS. 14A and 14C are views for describing a state in which a light sensor detects a detection tip-end in a related art, and FIG. 14B is a view for describing a state in which the light sensor detects a tip end in the embodiment.

FIG. 15A is a view for describing a label tape when seen from the exit side of a tape delivery port in the related art, and FIG. 15B is a view for describing a label tape when seen from the exit side of a tape delivery port in the embodiment.

FIG. 16A is a plan view of the label tape according to the related art, and FIG. 16B is a cross-sectional view of FIG. 16A.

FIG. 17 is a perspective view of a tape cartridge according to the related art with its upper casing removed.

FIG. 18 is a plan view of the tape cartridge according to the related art with the upper casing removed.

FIGS. 19A to 19C are views for describing a change in the output of the light sensor with a change in the passage positions of detection convex portions.

FIG. 20 is a graph for describing the occurrence of the deviation of a timing for detecting the passage of the detection convex portions with a change in an output voltage at passage.

FIG. 21 is a view of a lower surface in the vicinity of the light sensor of the opening/closing cover, showing a modified example of a light-emission-side convex portion and a light-reception-side convex portion covering the peripheral surface of a sensor casing.

FIG. 22 is a view showing a modified example of the label tape.

BEST MODES FOR CARRYING OUT THE INVENTION

Hereinafter, a description will be given of a label creation apparatus according to an embodiment of the present invention with reference to the accompanying drawings. The label creation apparatus of the embodiment is used in a state of being connected to a print data creation apparatus constituted by, for example, a personal computer in a wired or wireless fashion, acquires print data created and edited by the print data creation apparatus, and performs printing on the respective label portions of a label tape based on the acquired print data.

As shown in FIGS. 1 and 2, a label creation apparatus 1 has a tape cartridge 100 and an apparatus main body 200 in which the tape cartridge 100 is attachably/detachably installed. The tape cartridge 100 has a label tape 101, an ink ribbon 102, a platen roller 103, and a cartridge case 104 in which the label tape 101, the ink ribbon 102, the platen roller 103 are accommodated (see FIG. 6).

The label tape 101 has a plurality of label portions 105 provided along its length direction (see FIGS. 3A to 3C).

Note that the apparatus main body 200 is an example of a “tape printing apparatus” in the claims. In addition, the label tape 101 is an example of a “tape-shaped member” in the claims.

The label creation apparatus 1 performs printing on the respective label portions 105 based on print data acquired from a print data creation apparatus not shown while paying out and feeding the label tape 101 from the installed tape cartridge 100 and separates the printed respective label portions 105 to create labels printed as desired.

A description will be given of the label tape 101 with reference to FIGS. 3A to 3C and FIG. 15B. Note that the width direction of the tape will also be called a “top and bottom direction” in the following description. Of course, the direction is only for illustration purpose, and the present invention is not limited to the direction for its implementation.

The label tape 101 has a backing tape 107 as a release tape, a print tape 106 releasably affixed to a backing surface 107a of the backing tape 107, and a backing-surface exposed portion 153 at which the backing surface 107a is exposed like substantially the “rim of glasses.”

The backing tape 107 has a plurality of backing convex portions 108 partially projecting from one end, i.e., an upper end in the width direction of the tape. On the other hand, the print tape 106 has the plurality of label portions 105 provided along its length direction and has two non-label portions 120 in the top and bottom direction.

The plurality of label portions 105 is releasably affixed to the backing surface 107a of the backing tape 107 excluding the plurality of backing convex portions 108. On the peripheries of the respective label portions 105, annular exposed portions 154 at which the backing surface 107a is exposed are provided. The above backing-surface exposed portion 153 is constituted by the plurality of annular exposed portions 154 and a plurality of connection exposed portions 155 that connects the annular exposed portions to each other. The non-label portions 120 are releasably affixed to the backing surface 107a of the backing tape 107. The non-label portions 120 on a top side in the figures are affixed to the backing surface 107a so as to cover the plurality of backing convex portions 108 and constitute a plurality of detection convex portions 109 with the plurality of backing convex portions 108.

As shown in FIGS. 3A to 3C, the label tape 101 has the plurality of label portions 105 at an even pitch along its length direction. In addition, the label tape 101 has a first lateral portion 151 and a second lateral portion 152 on both lateral sides in its width direction, and the first lateral portion 151 on the top side is formed into a concavo-convex shape in the width direction. That is, the label tape 101 has the above convex detection convex portions 109 and concave non-detection concave portions 110 alternately provided in the length direction.

The detection convex portions 109 are obtained by making the first lateral portion 151 partially projected to a lateral side, i.e., a top side in the width direction of the tape so as to be formed into a substantially rectangular shape. The plurality of detection convex portions 109 is provided along the length direction of the tape at the same pitch as that of the plurality of label portions 105 so as to individually correspond to the plurality of label portions 105.

In the length direction of the tape, the tape paying-out tip-end sides of the respective detection convex portions 109, i.e., detection tip-ends 109a serving as downstream-side ends in the paying-out direction of the label tape 101 are positioned downstream of the tape paying-out tip-end sides of the respective label portions 105, i.e., label tip-ends 105a serving as downstream-side ends in the paying-out direction of the label tape.

On the other hand, in the length direction of the tape, paying-out terminal-end sides of the respective detection convex portions 109, i.e., detection rear-ends 109b serving as upstream-side ends in the paying-out direction are arranged at the same positions as those of the paying-out terminal-end sides of the respective label portions 105, i.e., label rear-ends 105b serving as upstream-side ends in the paying-out direction.

The label tape 101 is constituted by the backing tape 107 and the print tape 106 releasably affixed to one of the front and rear surfaces of the backing tape 107, i.e., the backing surface 107a (see FIGS. 15A and 15B) via an adhesive. The backing surface 107a is, for example, siliconized to make the print tape 106 easily released. The materials of the backing tape 107 and the print tape 106 are not particularly limited, and a paper, a resin, or the like can, for example, be used as such. The print tape 106 is lower in translucency than the backing tape 107.

As described above, the backing-surface exposed portion 153 has the plurality of annular exposed portions 154 provided along the length direction of the tape and the plurality of connection exposed portions 155 that connects the annular exposed portions 154 to each other. The plurality of annular exposed portions 154 is provided so as to leave margins on both the lateral sides in the width direction of the tape.

The print tape 106 provided inside the respective annular exposed portions 154 serves as the above label portions 105. In addition, the print tape 106 provided on both the lateral sides of the plurality of annular exposed portions 154 in the width direction serves as the non-label portions 120. That is, the print tape 106 has the plurality of label portions 105 and the two non-label portions 120.

The shape of the respective label portions 105 is not particularly limited, and the respective label portions 105 may have various shapes such as a circular shape having a long axis (see FIG. 3A), a corner-round rectangular shape (see FIG. 3B), and circular shape (see FIG. 3C).

The non-label portions 120 are provided on both the sides of the first lateral portion 151 and the second lateral portion 152 of the label tape 101. In addition, the respective non-label portions 120 are continuously provided in the length direction of the tape.

The backing-surface exposed portion 153 is formed in such a way that die-cutting is performed to cut out the print tape 106 into the shape of the backing-surface exposed portion 153 and the die-cut portions of the print tape 106 are removed from the backing tape 107, i.e., unnecessary portions are removed. Note that since the annular exposed portions 154 are connected to each other by the connection exposed portions 155, the unnecessary portions can be removed from the print tape 106 one after another.

Although the sizes of the respective portions of the label tape 101 configured as described above are not particularly limited, examples thereof will be shown below.

- The tape width of the label tape 101 including the detection convex portions 109 (hereinafter also called a first tape width W1): 42 mm
- The tape width of the label tape 101 excluding the detection convex portions 109 (hereinafter also called a “second tape width W2”): 36 mm

The distance between the detection tip-end 109a and the label tip-end 105a when a distance to the upstream side in the paying-out direction is positive in the length direction of the tape (hereinafter also called a “first distance S1”): 2.5 mm

The size A of the label portion 105 in the width direction of the tape: 25 mm

- The size B between the lower end of the label portion 105 and the lower end of the label tape 101: 5.5 mm
- The size G of the non-detection concave portion 110 in the length direction of the tape: 16.7 mm
- The exposed width M1 of the annular exposed portion 154: 2 mm
- The exposed width M2 of the connection exposed portion 155: 5 mm

Note that the size C of the label portion 105 in the length direction of the tape is different depending on the shape of the label portion 105. Accordingly, the size E of the detection convex portion 109 in the length direction of the tape is different depending on the shape of the label portion 105.

The label creation apparatus 1 can perform rimless printing on the respective label portions 105, i.e., it can perform printing so as not to leave margins on the peripheries of the label portions 105 (see FIGS. 12A to 12E). Therefore, ranges protruding to both sides in the length direction and both sides in the width direction of the tape by a prescribed size, for example, 1 mm from the respective label portions 105 are print ranges 156.

In addition, as will be described in later, the apparatus main body 200 controls the feeding of the label tape 101 based on whether the respective detection convex portions 109, i.e., the detection tip-ends 109a and the detection rear-ends 109b have passed. After having detected the passage of the detection tip-ends 109a, the apparatus main body 200 feeds the label tape 101 by a print margin width N and then starts printing on the respective label portions 105. In addition, after having detected the passage of the detection rear-ends 109b, the apparatus main body 200 feeds the label tape 101 by a cut margin width Q and then cuts off the label tape 101. That is, the label tape 101 has print start spots 111 at positions upstream of the detection tip-ends 109a by the print margin width N in the paying-out direction and has cut spots 112 upstream of the detection rear-ends 109b by the cut margin width Q in the paying-out direction. The print margin width N is, for example, 1.5 mm, and the cut margin width Q is, for example, 2.5 mm. In addition, the values of the print margin width N and the cut margin width Q are adjusted at the shipment of the apparatus main body 200 or the like. Moreover, a user is also allowed to operate the print data creation apparatus to adjust the values of the print margin width N and the cut margin width Q.

Note that with the non-detection concave portions 110 provided at the positions of the detection convex portions 109 and the detection convex portions 109 provided at the positions of the non-detection concave portions 110 in the embodiment, the apparatus main body 200 may start printing on the respective label portions 105 based on whether the detection rear-ends 109 have passed and may separate the respective label portions 105 based on whether the detection tip-ends 109a have passed.

A description will be given of the tape cartridge 100 with reference to FIGS. 4 to 7. Note that in the following description, the thickness direction of the tape cartridge 100 will also be called a “top and bottom” direction, the width direction thereof will also be called a “right and left” direction, and the depth direction thereof will also be called a “front and rear” direction. Of course, these directions are for illustration purpose, and the present invention is not limited to these directions for its implementation.

As shown in FIGS. 4 to 7, the cartridge case 104 is joined such that an upper casing 113 and a lower casing 114 are abutted against each other so as to be separable. The upper casing 113 has a top wall portion 115 and an upper peripheral wall portion 116 projecting from the periphery of the top wall portion 115. The lower casing 114 has a bottom wall portion 117 and a lower peripheral wall portion 118 projecting from the periphery of the bottom wall portion 117. The top wall portion 115 and the bottom wall portion 117 face each other. Note that the upper casing 113 is made of a semi-transparent resin and the lower casing 114 is made of a light-shielding (for example, black and non-transparent) resin.

In the cartridge case 104, a tape roll 157 is accommodated on a rear side, a ribbon paying-out reel 122 and a ribbon winding-up reel 123 are accommodated on a right front side, and a platen roller 103 is accommodated at a left end.

The tape roll 157 is wound on a tape core 121 in a roll shape so as to be capable of being paid out with the side of the print tape 106 of the label tape 101 directed outward. The tape roll 157 is accommodated in the cartridge case 104 so as to make the first lateral portion 151 having the detection convex portions 109 positioned on the side of the top wall portion 115 and make the second lateral portion 152 positioned on the side of the bottom wall portion 117. That is, the end surface on the side of the first lateral portion 151 of the label tape 101 is covered with the top wall portion 115 of the upper casing 113, and the end surface on the side of the second lateral portion 152 of the label tape 101 is covered with the bottom wall portion 117 of the lower casing 114.

On the other hand, the ink ribbon 102 is wound on the ribbon paying-out reel 122 so as to be capable of being paid out, and the ink ribbon 102 paid out from the ribbon paying-out reel 122 is wound up by the ribbon winding-up reel 123.

On the left side surface of the cartridge case 104, i.e., on the left side surfaces of the upper peripheral wall portion 116 and the lower peripheral wall portion 118, a slit-shaped tape delivery port 124 that is long in the top and bottom direction is formed to eject the label tape 101 to the outside of the cartridge case 104. In addition, at the left front corner portion of the cartridge case 104, a head opening 125 allowing the insertion of a print head 225 that will be describe later is formed so as to penetrate in the top and bottom direction.

The top wall portion 115 of the upper casing 113 is constituted by a high wall portion 126, a low wall portion 127, and a vertical wall portion 128. In a plan view, the high wall portion 126 is formed in a region in which the tape roll 157 and the ribbon paying-out reel 122 are positioned. The low wall portion 127 is formed so as to be lower than the high wall portion 126 i.e., formed so as to be closer to the bottom wall portion 117 in a region in which the ribbon winding-up reel 123 and the platen roller 103 are positioned. The vertical wall portion 128 extends like a substantially lying “Γ”-shape and connects the high wall portion 126 and the low wall portion 127 to each other.

The low wall portion 127 has a reel wall portion 158 at which the ribbon winding-up reel 123 is provided and a roller wall portion 159 at which the platen roller 103 is provided. The upper regions of the reel wall portion 158 and the head opening 125 are surrounded by the upper ends of the upper peripheral wall portion 116 and the vertical wall portion 128 on their peripheries and formed into concave space 131 having a substantially rectangular shape in a plan view. The roller wall portion 159 connects a substantially middle portion in the front and rear direction on the left side of the upper peripheral wall portion 116 and the left end of the vertical wall portion 128 to each other. In addition, the roller wall portion 159 faces a light sensor 206 at a position lower than the light sensor 206 that will be described later (see FIG. 11). Since the roller wall portion 159 connects the upper peripheral wall portion 116 and the vertical wall portion 128 to each other, the strength between the upper peripheral wall portion 116 and the vertical wall portion 128 can be enhanced.

The tape cartridge 100 has a thickness corresponding to the first tape width W1 in the region in which the high wall portion 126 is formed. Note that a remaining amount of the label tape 101 wound on the tape core 121 can be visually checked via the semi-transparent high wall portion 126.

On the other hand, the tape cartridge 100 has a thickness corresponding to the second tape width W2 in the region in which the low wall portion 127 is formed. Therefore, the roller wall portion 159 of the low wall portion 127 has a slit-shaped exposed opening 133 to make the plurality of detection convex portions 109 exposed upward one after another as the label tape 101 is paid out. The roller wall portion 159 has a print-tape-side wall portion 161 on the side of the print tape 106 of the label tape 101 and a backing-tape-side wall portion 162 on the side of the backing tape 107 across the exposed opening 133.

Since the roller wall portion 159 has the exposed opening 133, the roller wall portion 159, i.e., the print-tape-side wall portion 161 and the backing-tape-side wall portion 162 can be provided on both front and rear surface sides of the label tape 101. Therefore, compared with a case in which the roller wall portion 159 is provided on only one of the front and rear sides of the label tape 101, the area of the roller wall portion 159 is increased, whereby the strength between the upper peripheral wall portion 116 and the vertical wall portion 128 can be further enhanced.

The vertical wall portion 128 has a passage port 132 through which the plurality of detection convex portions 109 passes one after another as the label tape 101 is paid out. The exposed opening 133 of the roller wall portion 159 connects the passage port 132 and the tape delivery port 124 to each other. The exposed opening 133 is formed to be wider on the side of the passage port 132, i.e., on the upstream side in the paying-out direction so as to correspond to a remaining amount of the label tape 101, i.e., a change in a feed path corresponding to a winding amount of the label tape 101 on the tape core 121.

Moreover, a pair of front and rear tape cover portions 134 is formed at an end on an upstream side in the paying-out direction of the exposed opening 133 so as to extend in a rib shape from the edge portion of the passage port 132 to a downstream side in the paying-out direction. That is, the pair of tape cover portions 134 projects upward from the edge portion of the print-tape-side wall portion 161 and the edge portion of the backing-tape-side wall portion 162 at the end on the upstream side in the paying-out direction of the exposed opening 133. The pair of tape cover portions 134 is slightly lower than the vertical wall portion 128. Therefore, the upper ends of the pair of tape cover portions 134 are positioned to be lower than the upper end of the high wall portion 126.

At a downstream end in the paying-out direction of the tape cover portions 134 in the exposed opening 133, i.e., on a side upstream of a cover-portion downstream end 134a (see FIG. 12A), the respective detection convex portions 109 projecting upward from the exposed opening 133 are covered with the pair of tape cover portions 134 on the side of the print tape 106 and the side of the backing tape 107. On the other hand, on a side downstream of the cover-portion downstream end 134a in the exposed opening 133, the respective detection convex portions 109 projecting upward from the exposed opening 133 are exposed so as to be capable of being detected by the light sensor 206 when passing through the light sensor 206. That is, the area between the cover-portion downstream end 134a and the tape delivery port 124 serves as an exposed area 135 at which the respective detection convex portions 109 are exposed upward to allow the passage of the respective detection convex portions 109 to be detected by the light sensor 206. The exposed area 135 is provided at a position overlapping with the platen roller 103 in the paying-out direction. The above passage port 132 is provided on an upstream side in the paying-out direction of the exposed area 135, and the above tape delivery port 124 is provided on a downstream side in the paying-out direction thereof.

Note that as will be described in detail later, the upper ends of the respective detection convex portions 109, i.e., convex lateral ends 109c serving as lateral ends in the width direction of the tape of the detection convex portions 109 are positioned to be higher than the roller wall portion 159 in the tape cartridge 100. In addition, the upper ends of the respective non-detection concave portions 110, i.e., non-detection lateral ends 110c serving as lateral ends in the width direction of the tape of the non-detection concave portions 110 are positioned to be lower than the roller wall portion 159 (see FIG. 13A).

On the other hand, a guide wall 136 projects from the bottom wall portion 117 of the lower casing 114 so as to surround the periphery of the head opening 125 except for a portion at which the platen roller 103 faces the print head 225. At the plurality of the places of the upper end surface of the guide wall 136, guide engagement holes 137 with which the engagement pins (not shown) of the upper casing 113 engage are formed. The ink ribbon 102 paid out from the ribbon paying-out reel 122 goes around the outer peripheral surface of the guide wall 136 and is then wound up by the ribbon winding-up reel 123. Note that the ink ribbon 102 has substantially the same width as the second tape width W2.

Moreover, a slender plate-shaped drawing prevention portion 138 projects on a side upstream of the platen roller 103 in the paying-out direction so as to be positioned on the side of the print tape 106 of the label tape 101. The drawing prevention portion 138 projects from a position overlapping with the platen roller 103 in a traverse direction traversing the feed path of the label tape 101, i.e., in a direction orthogonal to the feed path (see FIG. 7). As will be described in detail later, the drawing prevention portion 138 prevents the label tape 101 from being drawn in the cartridge case 104 in cooperation with the platen roller 103.

A tape position restriction portion 163 projects from a base end on the upstream side in the paying-out direction of the drawing prevention portion 138 (see FIGS. 13A and 13B). When the lower end surface of the label tape 101 contacts the upper surface of the tape position restriction portion 163, the position of the label tape 101 can be restricted in the top and bottom direction.

The drawing prevention portion 138 does not contact the detection convex portions 109 and contacts the label tape 101 from an end on the side of the second lateral portion 152 of the label tape 101 to the midstream of the second tape width W2. A length F of the drawing prevention portion 138 is shorter than a length R of the platen roller 103 in the width direction of the tape. Here, the length F of the drawing prevention portion 138 is a length from the upper surface of the tape position restriction portion 163 to the tip end of the drawing prevention portion 138. In addition, the length R of the platen roller 103 is a length of a platen rubber 142 contacting the label tape 101. The drawing prevention portion 138 contacts an area from the lower end of the label tape 101 to a position above the second tape width W2 by a%. That is, the length F of the drawing prevention portion 138 is a% of the second tape width W2. For example, a is a value greater than equal to 50 and less than or equal to 100 and preferably a value greater than or equal to 60 and less than or equal to 80.

The tip end of the drawing prevention portion 138 does not contact the top wall portion 115 of the upper casing 113. In addition, the drawing prevention portion 138 is formed to be thin in the front and rear direction of the label tape 101, i.e., in the traverse direction traversing the feed path of the label tape 101. Therefore, the tip end of the drawing prevention portion 138 is capable of elastically tilting to a direction away from the label tape 101, i.e., to a side opposite to the platen roller 103 in the traverse direction.

The rear surface of the drawing prevention portion 138 is formed into a gentle arc shape and contacts the side of the print tape 106 of the label tape 101. On the other hand, the front surface of the drawing prevention portion 138 contacts the ink ribbon 102. That is, the print tape 106 is fed while being brought into slide-contact with the rear surface of the drawing prevention portion 138, and the ink ribbon 102 is fed while being brought into slide-contact with the front surface of the drawing prevention portion 138. The print tape 106 and the ink ribbon 102 merge with each other near the downstream side of the drawing prevention portion 138 and then is held between the platen roller 103 and the print head 225.

The tape delivery port 124 is formed to be slightly longer than the first tape width W1, formed to have substantially the same width over its whole length, and formed to be slightly wider than the thickness of the label tape 101. The upper end of the tape delivery port 124 is constituted by the upper end of the upper peripheral wall portion 116 of the upper casing 113 and serves as a convex-portion passage 124a through which the respective detection convex portions 109 pass. Chamfering portions 139 are formed at corners on the inner surface side of the cartridge case 104 of both front and rear edges of the convex-portion passage 124a (see FIG. 10).

The platen roller 103 is provided so as to face the print head 225 inserted in the head opening 125, is rotated by the apparatus main body 200, and feeds by rotation the label tape 101 and the ink ribbon 102 held between the platen roller 103 and the print head 225.

The platen roller 103 has a roller main body 141 having a cylindrical shape and a platen rubber 142 wound on the roller main body 141. The platen rubber 142 is brought into rolling-contact with the side of the backing tape 107 of the label tape 101. The platen rubber 142 has substantially the same length as the second tape width W2 like the ink ribbon 102.

The backing-tape-side wall portion 162 of the upper casing 113 has an upper platen engagement hole 143 with which the upper end of the roller main body 141 engages. Similarly, the bottom wall portion 117 of the lower casing 114 has a lower platen engagement hole (not shown) with which the lower end of the roller main body 141 engages. That is, the upper platen engagement hole 143 is formed in the backing-tape-side wall portion 162 in the exposed area 135.

The upper platen engagement hole 143 and the lower platen engagement hole pivotally support the rotation shaft of the platen roller 103. In addition, each of the upper platen engagement hole 143 and the lower platen engagement hole is formed to be long in the paying-out direction. Thus, the platen roller 103 is rotatably accommodated in the cartridge case 104 and moves within a prescribed range in the paying-out direction as the label tape 101 is paid out and drawn. Therefore, even if the label tape 101 is drawn, for example, when the tape core 121 is rotated due to vibrations in a state in which the tape cartridge 100 is not installed in the apparatus main body 200, the platen roller 103 moves to the upstream side in the paying-out direction as the label tape 101 is drawn, whereby the label tape 101 is held between the platen roller 103 and the above drawing prevention portion 138. Thus, the label tape 101 is not further drawn, and the tip end of the label tape 101 is prevented from getting in the cartridge case 104.

A description will be given of the apparatus main body 200 with reference to FIG. 1, FIG. 2, and FIGS. 8 to 11. Note that in the following description, the height direction of the apparatus main body 200 will also be called a “top and bottom” direction, the width direction thereof will also be called a “right and left” direction, and the depth direction thereof will also be called a “front and rear” direction. Of course, these directions are for illustration purpose, and the present invention is not limited to these directions for its implementation.

As shown in FIGS. 1 and 2, the outer shell of the apparatus main body 200 is formed by an apparatus casing 201 having a substantially cubic shape. An opening/closing cover 202 is provided at the upper surface of the apparatus casing 201. The opening/closing cover 202 opens/closes a cartridge installation portion 210 in which the tape cartridge 100 is installed. A cover opening button 203 for opening the opening/closing cover 202 is provided at the left-front corner portion of the apparatus main body 200. When the user presses the cover opening button 203, the opening/closing cover 202 rotates upward about a hinge portion 204 provided at a right end.

The tape cartridge 100 is installed in the cartridge installation portion 210 with the upper casing 113 directed upward and the lower casing 114 directed downward. Therefore, when the tape cartridge 100 is installed in the cartridge installation portion 210, the respective detection convex portions 109 exposed upward from the exposed opening 133 formed in the roller wall portion 159 of the upper casing 113 face the rear side of the closed opening/closing cover 202.

As shown in FIGS. 8 to 11, the opening/closing cover 202 has a check window 205, which is long in the right and left direction and has a rectangular shape with round corners, at a substantially central portion, and the rear side of the opening/closing cover 202 is provided with the light sensor 206 that is positioned in front of the check window 205 and detects the passage of the respective detection convex portions 109. Note that the light sensor 206 is an example of a “detection portion” in the claims.

The check window 205 is made of a translucent resin, and the installation/uninstallation of the tape cartridge 100 in/from the cartridge installation portion 210 can be visually checked via the check window 205. Note that except for the check window 205, the apparatus casing 201 with the opening/closing cover 202 is made of a light-shielding resin. On the rear side of the opening/closing cover 202, a rib-shaped annular convex portion 207 projects from the peripheral edge portion of the check window 205. The annular convex portion 207 is also made of a light-shielding resin. The annular convex portion 207 is formed to have a height at which a slight gap is generated between the annular convex portion 207 and the upper surface of the tape cartridge 100 installed in the cartridge installation portion 210 in a state in which the opening/closing cover 202 is closed.

The light sensor 206 is constituted by a transmission-type photo interrupter and has a light-emission element 216 and a light-reception element 217 facing each other, a sensor casing 208 in which the light-emission element 216 and the light-reception element 217 are accommodated, and a sensor substrate 209 on which a circuit element is mounted. The light-emission element 216 is constituted by, for example, an infrared light-emission diode, and the light-reception element 217 is constituted by, for example, an infrared photo transistor. The sensor substrate 209 is accommodated in a substrate accommodation portion 211 slightly projecting from the rear surface of the opening/closing cover 202 in a lying “L”-shape in a bottom view.

The light sensor 206 detects the passage of the detection tip-ends 109a when an output voltage changes with the passage of the detection tip-ends 109a of the detection convex portions 109 between the light-emission element 216 and the light-reception element 217. In addition, the light sensor 206 detects the passage of the detection rear-ends 109 when the output voltage changes with the passage of the detection rear-ends 109b of the detection convex portions 109 between the light-emission element 216 and the light-reception element 217.

In a state in which the cover is closed, the light sensor 206 is positioned in the exposed area 135 provided at the upper surface of the cartridge case 104. In addition, when the opening/closing cover 202 is closed, the substrate accommodation portion 211 is accommodated in the concave space 131 formed in the tape cartridge 100 and prevented from interfering with the top wall portion 115 of the tape cartridge 100 (see FIG. 10).

The sensor casing 208 has a substantially reverse “U”-shape in a side view. In the sensor casing 208, a light-reception-side accommodation portion 214 in which the light-reception element 217 is accommodated and a light-emission-side accommodation portion 213 in which the light-emission element 216 is accommodated are disposed in the front and rear direction across a groove portion 212 serving as a feed path. That is, in a state in which the opening/closing cover 202 is closed, the light sensor 206 is attached to the opening/closing cover 202 with the light-emission-side accommodation portion 213 positioned on a front side and the light-reception-side accommodation portion 214 positioned on a rear side, i.e., on the side of the check window 205. That is, the light-reception element 217 turns its back to the check window 205.

Moreover, as shown in FIG. 10, the position of the light axis of detection light from the light sensor 206 aligns with the position of the shaft of the platen roller 103 in the paying-out direction. That is, a position P1 detected by the light sensor 206 aligns with a print position P2 by the print head 225 in the paying-out direction (see FIGS. 12A to 12E). Therefore, a second distance S2 between the position P1 detected by the light sensor 206 and the print position P2 by the print head 225 is substantially 0 mm when a distance to the upstream side in the paying-out direction is positive.

The light-emission-side accommodation portion 213 and the light-reception-side accommodation portion 214, respectively, have a light-emission-side facing surface 213a and a light-reception-side facing surface 214a facing each other. The respective detection convex portions 109 pass through the area between the light-emission-side facing surface 213a and the light-reception-side facing surface 214, i.e., the groove portion 212. A facing distance D1 (see FIG. 9) that is the distance between the light-emission-side facing surface 213a and the light-reception-side facing surface 214a, i.e., the width of the groove portion 212 is, for example, about 4 mm. In addition, each of the light-emission-side facing surface 213a and the light-reception-side facing surface 214a has a slit to allow detection light emitted from the light-emission element 216 to pass through.

Moreover, a light-emission-side convex portion 218 having a reverse “U”-shape in a bottom view and a light-reception-side convex portion 219 having a lying “C”-shape in a bottom view project from the lower surface of the substrate accommodation portion 211. Each of the light-emission-side convex portion 218 and the light-reception-side convex portion 219 is made of a light-shielding resin. Note that the upstream-side corner portion of the light-emission-side convex portion 218 and the upstream-side corner portion of the light-reception-side convex portion 219 are chamfered to prevent the detection tip-ends 109a of the respective fed detection convex portions 109 from getting stuck on the corner portions.

The light-emission-side convex portion 218 covers the peripheral surface of the light-emission-side accommodation portion 213 excluding a light-emission-side facing surface 213a. On the other hand, the light-reception-side convex portion 219 is integrally constituted by a light-reception-side upstream guide portion 221, a light-reception-side downstream guide portion 222, and a light-reception-side cover portion 223. The light-reception-side upstream guide portion 221 is formed at one tip end so as to close the light-reception side of the upstream-side opening portion of the groove portion 212. The light-reception-side downstream guide portion 222 is formed at the other tip end so as to close the light-reception side of the downstream-side opening portion of the groove portion 212. The light-reception-side cover portion 223 covers the peripheral surface of the light-reception-side accommodation portion 214 excluding a light-reception-side facing surface 214a.

Each of the light-reception-side upstream guide portion 221 and light-reception-side downstream guide portion 222 internally extends to the near side of the light-reception element 217 along the light-reception-side facing surface 214a. The respective detection convex portions 109 pass through the groove portion 212 while being guided by the front surfaces of the light-reception-side upstream guide portion 221 and the light-reception-side downstream guide portion 222 and the light-emission-side facing surface 213a. That is, the respective detection convex portions 109 are fed between the light-reception-side upstream guide portion 221 and the light-reception-side downstream guide portion 222 and the light-emission-side facing surface 213a at a guide width D2 narrower than the above facing distance D1 (see FIG. 9).

As shown in FIG. 2, the print head 225 of a thermal type projects from the left-front corner of the cartridge installation portion 210. The tape cartridge 100 is installed in the cartridge installation portion 210 so as to make the print head 225 inserted in the head opening 125. Moreover, a platen driving shaft 226 that faces the print head 225 and engages with and rotates the platen roller 103 inside the tape cartridge 100 is provided to stand in the cartridge installation portion 210. Note that a guide projection that guides the installation of the tape cartridge 100 projects from the substantially central portion of the cartridge installation portion 210 and a ribbon winding-up driving shaft that engages with and rotates the ribbon winding-up reel 123 is provided to stand on the right side of the print head 225.

Moreover, a feed portion 231 that rotates the platen driving shaft 226 and the ribbon winding-up driving shaft is provided on the rear side of the cartridge installation portion 210. The feed portion 231 has a feed motor 232 serving as a power source and a feed-power transmission mechanism (not shown) constituted by a gear train or the like that divides and transmits the power of the feed motor 232 to the platen driving shaft 226 and the ribbon winding-up driving shaft (see FIG. 12A). When the feed portion 231 rotates the platen driving shaft 226 and the ribbon winding-up driving shaft, the platen roller 103 and the ribbon winding-up reel 123 rotate to feed the label tape 101 and the ink ribbon 102.

A slit-shaped tape ejection port 234 long in the top and bottom direction is formed at the left side portion of the apparatus casing 201. The tape ejection port 234 communicates with the cartridge installation portion 210, and the label tape 101 fed from the tape cartridge 100 installed in the cartridge installation portion 210 is ejected to the outside of the apparatus via the tape ejection port 234.

A cutting portion 241 that cuts off the label tape 101 is provided between the cartridge installation portion 210 and the tape ejection port 234. The cutting portion 241 has a fixed blade 242 and a movable blade 243 with the feed path of the label tape 101 held therebetween and is constituted by a cutter 244 that cuts off the label tape 101 like scissors, a cutter motor 245 that serves as the power source of the movable blade 243, a cutter power transmission mechanism (not shown) that transmits the power of the cutter motor 245 to the movable blade 243, or the like (see FIG. 12A).

In the paying-out direction, a position at which the respective blade edges (blade lines) of the fixed blade 242 and the movable blade 243 are scraped is a cut position P3 at which the label tape 101 is cut off. Further, in the paying-out direction, a distance L1 between the cut position P3 and the above cover-portion downstream end 134a, i.e., the upstream end of the exposed area 135 is shorter than a distance L2 (L1<L2) between the detection tip-end 109a of the detection convex portion 109 corresponding to the n-th label portion 105 from the downstream side in the paying-out direction and the cut spot 112 of the n−1-th label portion 105 (see FIG. 12A).

Moreover, the apparatus main body 200 has a CPU (Central Processing Unit) and a control unit 250 (see FIGS. 12A to 12E) constituted by various storage elements or the like. As will be described later, the control unit 250 drives and controls the feed motor 232 and the cutter motor 245 based on the passage detection of the detection tip-ends 109a and the detection rear-ends 109b of the various detection convex portions 109 by the light sensor 206.

A description will be given of a print/cut operation in the label creation apparatus 1 with reference to FIGS. 12A to 12E. Note that in FIGS. 12A to 12E, the platen roller 103, the print head 225, and the movable blade 243 are shown in black at a driving time and shown in white at a non-driving time. In addition, the light sensor 206 is shown in black when the passage of the detection tip-ends 109a and the detection rear-ends 109b of the respective detection convex portions 109 is detected and shown in white when the passage is not detected.

First, it is assumed that the n−1-th label portion 105 from the downstream side in the paying-out direction is separated at the cut spot 112 in a previous print/cut operation. At this time, the tip end of the label tape 101 aligns with the cut position P3 until a print/cut operation with respect to the label tape 101 starts. In addition, the detection tip-end 109a of the detection convex portion 109 corresponding to the n-th label portion 105 is positioned slightly upstream (for example, 4 mm) of the detection position P1 of the light sensor 206 in the paying-out direction (see FIG. 12A).

When the user inputs a print start in this state, the control unit 250 drives the feed motor 232 and the platen roller 103 rotates to start feeding the label tape 101 and the ink ribbon 102. Then, when the detection tip end 109a of the detection convex portion 109 corresponding to the n-th label portion 105 reaches the detection position P1, the light sensor 206 detects the passage of the detection tip end 109a and outputs the detection result to the control unit 250 (see FIG. 12B).

Upon receiving the detection result showing the passage of the detection tip-end 109a, the control unit 250 feeds the label tape 101 by the print margin width N (see FIGS. 3A to 3C) such that the print start spot 111 of the n-th label portion 105 reaches the print position P2. Then, the control unit 250 drives the print head 225 to start printing with respect to the n-th label portion 105 from the print start spot 111, i.e., the downstream-side end in the paying-out direction of the print range 156 (see FIG. 12C).

Then, when the detection rear-end 109b of the detection convex portion 109 corresponding to the n-th label portion 105 reaches the detection position P1, the light sensor 206 detects the passage of the detection rear-end 109b and outputs the detection result to the control unit 250 (see FIG. 12D).

Upon receiving the detection result of the passage of the detection rear end 109b, the control unit 250 feeds the label tape 101 by the cut margin width Q (see FIGS. 3A to 3C) such that the cut spot 112 of the n-th label portion 105 reaches the cut position P3. Moreover, the control unit 250 drives the movable blade 243 to cut off the label tape 101 at the cut spot 112 and separate the n-th label portion 105 (see FIG. 12E).

In the way described above, the label with a desired print can be created by the label creation apparatus 1. Note that the above description refers to a case in which one of the label portions 105 is printed and separated. However, it may also be possible to perform printing on the plurality of label portions 105 one after another and cut off the label tape 101 at the cut spot 112 of the rear most one of the label portions 105 to separate the plurality of label portions 105 in a lump.

The overview of the label creation apparatus 1 of the embodiment is described above. Next, a description will be given in further detail of (1) the positional relationship between the label tape 101 and the exposed area 135 in the tape cartridge 100, (2) the positional relationship between the detection convex portions 109 and the label portion 105 in the label tape 101, (3) the detection convex portions 109 of the label tape 101, and (4) the drawing prevention portion 138.

(1) Positional Relationship Between Label Tape 101 and Exposed Area 135 in Tape Cartridge 100

As shown in FIG. 13A, in the tape cartridge 100 of the embodiment, the label tape 101 is not exposed in the exposed area except for the detection convex portions 109. More specifically, the non-detection lateral ends 110c of the respective non-detection concave portions 110 are positioned to be lower than the roller wall portion 159. Therefore, the respective non-detection concave portions 110 are not positioned to be higher than the upper surface of the roller wall portion 159. Accordingly, the respective non-detection concave portions 110 can be prevented from being falsely detected by the light sensor 206 facing the roller wall portion 159 at a position higher than the roller wall portion 159. Therefore, the label creation apparatus 1 can perform a printing operation and a cutting operation with respect to the respective label portions 105 at an appropriate position.

As shown in FIG. 13B, the non-detection lateral ends 110c of the respective non-detection concave portions 110 may be at the same position as the roller wall portion 159 in the top and bottom direction. Even with this configuration, the respective non-detection concave portions 110 are not positioned to be higher than the upper surface of the roller wall portion 159. Accordingly, the respective non-detection concave portions 110 can be prevented from being falsely detected by the light sensor 206.

(2) Positional Relationship Between Detection Convex Portions 109 and Label Portions 105 in Label Tape 101

As described above, in the length direction of the tape, the detection tip-ends 109a of the detection convex portions 109 are positioned downstream of the label tip-ends 105a of the corresponding label portions in the paying-out direction. Further, printing starts at the print start spots 111 that are the positions between the detection tip-ends 109a and the label tip-ends 105a in the length direction of the tape. That is, the detection convex portions 109 and the label portions 105 are disposed such that printing starts at the print start spots 111 that are the positions between the detection tip-ends 109a and the label tip-ends 105a in the length direction of the tape. Thus, rimless printing is reliably performed on the respective label portions.

Note that as shown in FIG. 14A, when the first distance S1 between the detection tip-end 109a and the label tip-end 105a is the same (for example, 0 mm) as the second distance S2 between the detection position P1 and the print position P2 unlike the label tape 101 of the embodiment, the label tip-end 105a of the corresponding label portion 105 reaches the print position P2 at a timing at which the light sensor 206 detects the detection tip-end 109a. Therefore, if the light sensor 206 is provided at a position slightly deviating from a setting value on the downstream side in the paying-out direction with respect to the print head 225, the label tip-end 105a is positioned downstream of the print position P2 in the paying-out direction at the timing at which the light sensor 206 detects the detection tip-end 109a. Accordingly, rimless printing cannot be performed on the respective label portions 105.

On the other hand, as shown in FIG. 14B, the label tape 101 of the embodiment is such that the first distance S1 (2.5 mm) between the detection tip-end 109a and the label tip-end 105a is greater than the second distance S2 (0 mm) between the detection position P1 and the print position P2. Therefore, at the timing at which the light sensor 206 detects the detection tip-end 109a, the label tip-end 105a of the corresponding label portion 105 is positioned upstream of the print position P2 by the difference (2.5 mm) between the first distance S1 and the second distance S2 in the paying-out direction. Accordingly, even if the light sensor 206 is provided at a position deviating from a setting value within the difference between the first distance S1 and the second distance S2 on the downstream side in the paying-out direction with respect to the print head 225, printing can start at a position deviating to downstream side of the label tip-end 105a in the paying-out direction with respect to the label portion 105, whereby rimless printing can be reliably performed on the respective label portions 105.

In this case, the first distance S1 may be appropriately set according to a maximum value of the positional deviation amount of the light sensor 206 with respect to the print head 225, a deviation width at rimless printing, or the like. In addition, the print margin width N is preferably adjusted according to a positional deviation amount of the light sensor 206 with respect to the print head 225 at the shipment of the apparatus main body 200, user's usage, or the like.

Note that even if the first distance is zero and the second distance S2 has a negative value, the label tip-end 105a of the corresponding label portion 105 is positioned upstream of the print position P2 in the paying-out direction at the timing at which the light sensor 206 detects the detection tip-end 109a. Therefore, the same effects as those of the embodiment can be obtained.

(3) Detection Convex Portions 109 of Label Tape 101

In the label tape 101, the detection convex portions 109 are constituted by the backing convex portion 108 and the non-label portions 120 affixed to the backing convex portion 108 as described above. Therefore, compared with a case in which the detection convex portions 109 are constituted only by the backing convex portion 108, the strength of the detection convex portions 109 can be further enhanced. Thus, the detection convex portions 109 are prevented from being folded. Accordingly, the detection convex portions 109 can favorably pass through the passage port 132 and the tape delivery port 124 formed in the cartridge case 104 and the groove portion 212 of the light sensor 206.

Moreover, since the detection convex portions 109 are constituted by the backing convex portion 108 and the non-label portions 120, the light-shielding performance of the detection convex portions 109 can be further enhanced compared with the case in which the detection convex portions 109 are constituted only by the backing convex portion 108. Therefore, a rate at which detection light from the light sensor 206 is shielded by the detection convex portions 109, i.e., a light-shielding rate can be increased. Accordingly, the passage of the detection convex portions 109 can be reliably detected by the light sensor 206.

In addition, since the non-label portions 120 are affixed to the backing tape 107, the strength of the whole label tape 101 can be further enhanced compared with a case in which only the plurality of label portions 105 is affixed to the backing tape 107. Therefore, even if a tensional force is applied in the length direction of the tape, for example, when the label tape 101 is wound on the tape core 121, the label tape 101 can be prevented from being torn.

Unlike the tape cartridge 100 of the embodiment, FIG. 15A assumes a case in which the label tape 101, where only the plurality of label portions 105 is affixed to the backing surface 107a of the backing tape 107, is accommodated in the cartridge case 104. In this case, there is a likelihood that the label portion 105 overlaps with the edge portion of the tape delivery port 124 when seen from the exit side of the tape delivery port 124 at a timing at which the spots between the label portions 105 pass through the tape delivery port 124. If the label tape 101 is paid out in this state, the label tip-ends 105a are likely to get stuck on the edge portion of the tape delivery port 124 when the label portions 105 pass through the tape delivery port 124.

On the other hand, as shown in FIG. 15B, the print tape 106 has the non-label portions 120 provided on both the lateral sides with respect to the plurality of annular exposed portions 154 in the width direction of the tape in the tape cartridge 100 of the embodiment. Thus, the label portions 105 are prevented from overlapping with the edge portion of the tape delivery port 124 when seen from the exit side of the tape delivery port 124 at the timing at which the spots between the label portions 105 pass through the tape delivery port 124 after the label tape 101 is paid out. Therefore, the label tip-ends 105a hardly get stuck on the edge portion of the tape delivery port 124 at the timing at which the respective label portions 105 pass through the tape delivery port 124. Accordingly, the label tape 101 having the plurality of label portions 105 is smoothly delivered from the tape delivery port 124.

Note that in the embodiment, the non-label portions 120 are provided on both the side of the first lateral portion 151 and the side of the second lateral portion 152 with respect to the plurality of annular exposed portions 154. However, the same effects can be obtained in a case in which the non-label portions 120 are provided on only one of the side of the first lateral portion 151 and the side of the second lateral portion 152.

Note that when the print tape 106 does not have the annular exposed portions 154 and the non-label portions 120 are provided in contact with the label portions 105, the upper and lower ends of the label portions 105 may run onto the inner peripheral edge portions 120a of the non-label portions 120. That is, in a case in which the shape of the label portions 105 is, for example, a circle, the label portions 105 hardly deform when a tensional force in the length direction of the tape is applied to wind the label tape 101 on the tape core 121. In this regard, the non-label portions 120 expand in the length direction of the tape as a whole, and the respective inner peripheral edge portions 120a deform from a circular shape to a substantially elliptic shape long in the length direction of the tape. Therefore, the upper and lower ends of the label portions 105 run onto the inner peripheral edge portions 120a (see FIGS. 16A and 16B). In this case, ink is not satisfactorily transferred to the upper and lower ends of the label portions 105 run onto the non-label portions 120, whereby rimless printing cannot be appropriately performed. On the other hand, in the label tape 101 of the embodiment, the print tape 106 has the annular exposed portions 154. Therefore, even if a tensional force in the length direction of the tape is applied, the upper and lower ends of the label portions 105 do not run onto the inner peripheral edge portions 120a of the non-label portions 120. As a result, rimless printing can be appropriately performed.

(4) Drawing Prevention Portion 138

As described above, the tape cartridge 100 has the platen roller 103 contacting the side of the backing tape 107 of the label tape 101 and the drawing prevention portion 138 provided upstream of the platen roller 103 in the paying-out direction and contacting the side of the print tape 106 of the label tape 101. Moreover, in a conventional tape cartridge 100 in which a normal label tape 101 without a plurality of detection convex portions 109 is accommodated, a drawing prevention portion 138 has a length engaging with a top wall portion 115 of an upper casing 113 and contacts the label tape 101 over the whole tape width (see FIG. 17). Therefore, in the conventional tape cartridge 100, the label tape 101 is curved like an “S”-shape in a front and rear direction over the whole tape width on a feed path from the drawing prevention portion 138 to a platen roller 103 (see FIG. 18).

In the tape cartridge 100 in which the label tape 101 of the embodiment is accommodated, the respective detection convex portions 109 enter the light sensor 206 in a state of being curved like an “S”-shape in the front and rear direction if the drawing prevention portion 138 contacts the respective detection convex portions 109. Therefore, compared with a case in which the respective detection convex portions 109 enter the light sensor 206 in a state of being formed into a linear shape, there is a likelihood that the respective detection convex portions 109 cannot appropriately enter the area between the light-emission element 216 and the light-reception element 217.

In this regard, in the tape cartridge 100 of the embodiment, the portion of the label tape 101 contacting the drawing prevention portion 138, i.e., the side of the second lateral portion 152 of the label tape 101 is curved like an “S”-shape in the front and rear direction, while the respective detection convex portions 109 do not contact the drawing prevention portion 138 and are formed into a substantially linear shape, for example, a gentle arc shape (see FIG. 7).

Accordingly, the respective detection convex portions 109 enter the light sensor 206 in a state of being formed into a substantially linear shape. Thus, compared with a case in which the respective detection convex portions 109 enter the light sensor 206 in a state of being curved like an “S”-shape, the respective detection convex portions 109 can appropriately enter the area between the light-emission element 216 and the light-reception element 217 without changing their entering path for each time. Therefore, since the passage position of the detection convex portions 109 in the direction in which the light-emission element 216 and the light-reception element 217 of the light sensor 206 face each other is secured, a change in output voltage at the passage due to a change in the passage position is prevented, whereby the light sensor 206 can appropriately detect the passage of the detection convex portions 109. In addition, in this case as well, since the side of the second lateral portion 152 of the label tape 101 is held between the platen roller 103 and the drawing prevention portion 138 when the platen roller 103 moves to the upstream side in the paying-out direction as the label tape 101 is drawn, the tip end of the label tape 101 can be prevented from getting in the cartridge case 104. Therefore, the light sensor 206 can appropriately detect the passage of the detection convex portions 109, while the tip end of the label tape 101 is prevented from getting in the cartridge case 104.

Note that in the embodiment, the drawing prevention portion 138 contacts the label tape 101 from the end of the side of the second lateral portion 152 of the label tape 101 to the midstream of the second tape width W2.

Moreover, the tip end of the drawing prevention portion 138 projecting from the bottom wall portion 117 is configured to be capable of elastically tilting in the direction away from the label tape 101. Therefore, when the label tape 101 is fed, the drawing prevention portion 138 is pressed by the label tape 101 fed in its tensed state and the tip end tilts in the direction away from the label tape 101. Accordingly, with this configuration, the side of the second lateral portion 152 of the label tape 101 corresponding to the base-end side of the drawing prevention portion 138 is curved like an “S”-shape but the side of the first lateral portion 151 of the label tape 101 corresponding to the tip-end side of the drawing prevention portion 138 is formed into a substantially linear shape, for example, a gentle arc shape on the feed path from the drawing prevention portion 138 to the platen roller 103. Therefore, the upper side of the label tape 101 can be further linearly shaped. Accordingly, the respective detection convex portions 109 can further appropriately enter the area between the light-emission element 216 and the light-reception element 217 of the light sensor 206.

In addition, as described above, in the tape cartridge 100 of the embodiment, the side of the second lateral portion 152 of the label tape 101 contacting the drawing prevention portion 138 is curved like an “S”-shape, but the side of the first lateral portion 151 of the label tape 101 having the plurality of detection convex portions 109 is formed into a substantially linear shape, for example, a gentle arc shape. Thus, compared with a case in which the label tape 101 is curved like an “S”-shape over the whole tape width, the print tape 106 hardly partially falls off from the backing tape 107 and thus is prevented from becoming wrinkled on the feed path from the drawing prevention portion 138 to the platen roller 103.

As described above, according to the tape cartridge 100 of the embodiment, rimless printing can be reliably performed on the respective label portions 105.

Meanwhile, in the light sensor 206, an output voltage at the passage of the detection convex portions 109 changes simultaneously with a change in the passage position of the detection convex portions 109 in a direction in which the light-emission element 216 and the light-reception element 217 face each other. That is, as shown in FIGS. 19A and 19B, when the detection convex portions 109 get close to the side of the light-emission element 216 or the side of the light-reception element 217 during the passage, detection light emitted from the light-emission element 216 is blocked by the detection convex portions 109 and not incident on the light-reception element 217. On the other hand, as shown in FIG. 19C, when the detection convex portions 109 pass through the intermediate area between the light-emission element 216 and the light-reception element 217, most of the detection light is blocked by the detection convex portions 109 but some of the detection light are reflected by the sensor casing 208 (the groove bottom surface of the groove portion 212 or the like) and incident on the light-reception element 217. Therefore, the difference between an output voltage at the non-passage and an output voltage at the passage is reduced. Further, since time required to reach the threshold of an output voltage at which the passage/non-passage is determined changes with the change in the output voltage at the passage, a timing for detecting the passage of the detection convex portions 109 is deviated (see FIG. 20).

In this regard, in the embodiment, the respective detection convex portions 109 are fed by the light-reception-side upstream guide portion 221 and the light-reception-side downstream guide portion 222 at the guide width D2 narrower than the facing distance D1 between the light-emission-side facing surface 213a and the light-reception-side facing surface 214a as described above (see FIG. 9). Thus, the passage position of the detection convex portions 109 in the direction in which the light-emission element 216 and the light-reception element 217 face each other is changed only in the range of the guide width D2 narrower than the facing distance D1. That is, the width of the passage position of the detection convex portions 109 in the facing direction can be made narrower than the facing distance D1. Therefore, the change in the output voltage at the passage with the change in the passage position of the detection convex portions 109 in the facing direction can be reduced. Accordingly, the deviation of the timing for detecting the passage of the detection convex portions 109 with the change in the output voltage at the passage can be reduced.

Moreover, with the light-emission-side convex portion 218 and the light-reception-side convex portion 219 covering the peripheral surface of the sensor casing 208, the user cannot touch the peripheral surface of the sensor casing 208 with a finger or the like. Accordingly, it is possible to prevent the malfunction of the light sensor 206 due to static built up on the sensor casing 208 when touched by a user's finger or the like electrostatically charged. Note that the lower surface of the sensor casing 208 (the surface on the side of the cartridge case 104) may also be covered unless the cartridge case 104 is interfered.

In addition, the light-reception-side upstream guide portion 221 provided so as to close some of the upstream-side opening portion of the groove portion 212 and the light-reception-side downstream guide portion 222 provided so as to close some of the downstream-side opening portion of the groove portion 212 are made of a light-shielding material. Thus, light intruding into the light-reception element 217 from the outside via the upstream-side opening portion or the downstream-side opening portion of the groove portion 212 can be blocked. Accordingly, the malfunction of the light sensor 206 due to the intrusion of the outside light can be prevented. In addition, the light-reception-side upstream guide portion 221 and the light-reception-side downstream guide portion 222 extend to the near side of the light-reception element 217 along the light-reception-side facing surface 214a. Thus, the light intruding into the light-reception element 217 from the outside can be further effectively blocked.

As described above, according to the label creation apparatus 1 of the embodiment, the deviation of the timing for detecting the passage of the detection convex portions 109 can be reduced. Note that although the above embodiment describes an example in which the one end in the tape width direction of the label tape 101 projects in the tape width direction, the present invention is not limited to this. For example, the detection convex portions 109 may be, for example, opening portions formed in the label tape 101. In addition, the label tape 101 may not be accommodated in the cartridge case 104. Moreover, the present invention is also applicable to, besides the label creation apparatus 1, a tape feeding apparatus such as a cutting plotter that does not have a print function.

A description will be given, with reference to FIG. 21, of a modified example of the light-emission-side convex portion 218 and the light-reception-side convex portion 219 focusing on the difference between the light-emission-side convex portion 218 and the light-reception-side convex portion 219 of the modified example and the light-emission-side convex portion 218 and the light-reception-side convex portion 219 of the above embodiment. The light-emission-side convex portion 218 is formed into a reverse “U”-shape in a bottom view and integrally constituted by a light-emission-side upstream guide portion 251, a light-emission-side downstream guide portion 252, and a light-emission-side covering portion 253. The light-emission-side upstream guide portion 251 is formed at one tip-end so as to close some (light-emission side) of the upstream-side opening portion of the groove portion 212. The light-emission-side downstream guide portion 252 is formed at the other tip end so as to close some (light-emission side) of the downstream-side opening portion of the groove portion 212. The light-emission-side covering portion 253 covers the peripheral surface of the light-emission-side accommodation portion 213 excluding the light-emission-side facing surface 213a.

Similarly, the light-reception-side convex portion 219 is formed into a “U”-shape in a bottom view and integrally constituted by a light-reception-side upstream guide portion 221, a light-reception-side downstream guide portion 222, and a light-reception-side covering portion 223. The light-reception-side upstream guide portion 221 is formed at one tip-end so as to close some (light-reception side) of the upstream-side opening portion of the groove portion 212. The light-reception-side downstream guide portion 222 is formed at the other tip end so as to close some (light-reception side) of the downstream-side opening portion of the groove portion 212. The light-reception-side covering portion 223 covers the peripheral surface of the light-reception-side accommodation portion 214 excluding the light-reception-side facing surface 214a. In the modified example, both the light-reception-side upstream guide portion 221 and the light-reception-side downstream guide portion 222 do not inwardly extend to the near side of the light-reception element 217.

The respective detection convex portions 109 are fed while being guided between the light-emission-side upstream guide portion 251 and the light-reception-side upstream guide portion 221 on the upstream side in the paying-out direction of the groove portion 212 and fed while being guided between the light-emission-side downstream guide portion 252 and the light-reception-side downstream guide portion 222 on the downstream side in the paying-out direction of the groove portion 212. That is, the respective detection convex portions 109 are fed at the guide width D2 narrower than the above facing distance D1 between the light-emission-side upstream guide portion 251 and the light-reception-side upstream guide portion 221 and between the light-emission-side downstream guide portion 252 and the light-reception-side downstream guide portion 222.

Accordingly, in the modified example as well, the change in the output voltage at the passage with the change in the passage position of the detection convex portions 109 in the facing direction can be reduced like the above embodiment. Thus, the deviation of the timing for detecting the passage of the detection convex portions 109 with the change in the output voltage at the passage can be reduced. In addition, with the light-emission-side convex portion 218 and the light-reception-side convex portion 219 covering the peripheral surface of the sensor casing 208, the user cannot touch the peripheral surface of the sensor casing 208 with a finger or the like. Moreover, the light-emission-side upstream guide portion 251 and the light-reception-side upstream guide portion 221 provided so as to close some of the upstream-side opening portion of the groove portion 212 and the light-emission-side downstream guide portion 252 and the light-reception-side downstream guide portion 222 provided so as to close some of the downstream-side opening portion of the groove portion 212 are made of a light-shielding material. Thus, the light intruding into the light-reception element 217 from the outside via the upstream-side opening portion or the downstream-side opening portion of the groove portion 212 can be blocked.

A description will be give of a modified example of the label tape 101.

As shown in FIG. 22, a label tape 101 according to the modified example is so-called a die-cut label and has, for example, corner-round rectangular label portions 105 or the like at an even pitch in its length direction. The label tape 101 is constituted by a print tape 106 and a backing tape 107 affixed to the rear side of the print tape 106 via an adhesive, and only the print tape 106 is cut out (half-cut) into a corner-round rectangular shape to form the respective label portions 105. Note that the label tape 101 may be such that other portions (frame portions) of the print tape 106 are released in advance with the respective label portions 105 remain intact.

The label tape 101 has a plurality of detection convex portions 109 projecting in a rectangular shape in its width direction at one end (upper side in FIG. 22) in the width direction. The plurality of detection convex portions 109 are provided along the length direction of the tape at the same pitch as those of the plurality of label portions 105 so as to individually correspond to the plurality of label portions 105. That is, ends (detection tip-ends 109a) on the paying-out tip-end side of the respective detection convex portions 109 are positioned ahead of ends (label tip-ends 105a) on the paying-out tip-end side (on a downstream side in the paying-out direction) of the respective label portions 105 in a paying-out direction by a prescribed distance, while ends (detection rear ends 109b) on the paying-out terminal-end side of the respective detection convex portions 109 align with ends (label rear-ends 105b) on the paying-out terminal-end side (on an upstream side in the paying-out direction) of the respective label portions 105. Of course, the positional relationship between the respective label portions 105 and the respective detection convex portions 109 in the length direction of the tape is not limited to this, but the respective label portions 105 and the respective detection convex portions 109 may only be required to have a prescribed positional relationship each other.

EXPLANATION OF REFERENCE SYMBOLS

1: label creation apparatus

100: tape cartridge

200: apparatus main body

Number	Date	Country	Kind
2013-058869	Mar 2013	JP	national
2013-209711	Oct 2013	JP	national

TAPE CARTRIDGE AND TAPE PRINTING APPARATUS

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