The present application claims priority from Japanese Patent Application No. 2014-242563, which was filed on Nov. 28, 2014, the disclosure of which is incorporated herein by reference in its entirety.
Field
The present disclosure relates to an ink ribbon for forming print on a recording medium, a ribbon cartridge comprising the same, and a printer that performs print formation using the ribbon cartridge.
Description of the Related Art
Techniques for printing on a recording medium (fabric tape) by the transfer of an ink of an ink ribbon (dye-containing heat transfer printing ribbon) are already known.
In print techniques that use ink ribbon, an ink melted by received heat adheres to a transfer target, forming print. To improve print quality, the melting point for melting the ink is preferably lowered to speed up melting and transfer. If the melting point is lowered too much, however, the durability of the ink ribbon may decrease during transport and the like under high ambient temperature conditions, for example. In the above prior art, striking such a balance between improving the print quality and suppressing decreases in durability was not particularly taken into consideration.
It is therefore an object of the present disclosure to provide an ink ribbon, a ribbon cartridge, and a printer capable of striking a balance between improving the print quality and suppressing decreases in durability.
In order to achieve the above-described object, according to the first aspect of the present application, there is provided an ink ribbon, comprising a ribbon base layer, a first layer that is configured to separate from the ribbon base layer and is disposed on a first surface of the ribbon base layer, and a second layer that is configured to adhere to a transfer target and is disposed on the first layer, a melting point of the second layer being 60 [° C.] or more and 90 [° C.] or less.
According to the ink ribbon of the first aspect, the melting point of the second layer that adheres to the transfer target is a relatively low 90° C. or less. With this arrangement, even if not much heat is received, the second layer melts, separates from the ribbon base layer, and quickly adheres to the transfer target, making it possible to improve the print quality. In particular, if high-speed printing is performed, the print quality improvement effect is remarkable. On the other hand, if the melting point is lowered too much, the durability of the ink ribbon may decrease during transport or the like under high ambient temperature conditions. In the present disclosure, the melting point of the second layer is set to 60° C. or more, making it possible to suppress the decreases in durability at high temperatures described above. As a result, it is possible to strike a balance between improving the print quality and suppressing decreases in durability.
In order to achieve the above-described object, according to the second aspect of the present application, there is provided a ribbon cartridge comprising an ink ribbon roll with an ink ribbon wound around an axis, and a support member that rotatably supports the ink ribbon roll, the ink ribbon comprising a ribbon base layer, a first layer that is configured to separate from the ribbon base layer and is disposed on a first surface of the ribbon base layer, and a second layer that is configured to adhere to a transfer target and is disposed on the first layer, a melting point of the second layer being 60 [° C.] or more and 90 [° C.] or less.
In order to achieve the above-described object, according to the third aspect of the present application, there is provided a printer comprising a first storage part configured to store a medium cartridge comprising a recording medium roll with a long recoding medium wound around an axis, and a first support member that rotatably supports the recording medium roll, a second storage part configured to store a ribbon cartridge comprising an ink ribbon roll with an ink ribbon wound around an axis, and a second support member that rotatably supports the ink ribbon roll, a feeder configured to feed the recording medium fed out from the recording medium roll of the medium cartridge, a printing head configured to form desired print by heat transfer printing using the ink ribbon fed out from the ink ribbon roll on the recording medium fed by the feeder to establish a long recorded medium, a winding device configured to sequentially wind the recorded medium generated by the printing head around an outer peripheral area to form a recorded medium roll, and a controller configured to control the feeder and the printing head in coordination, the ink ribbon comprising a ribbon base layer, a first layer that is configured to separate from the ribbon base layer and is disposed on a first surface of the ribbon base layer, and a second layer that is configured to adhere to a transfer target and is disposed on the first layer, a melting point of the second layer being 60 [° C.] or more and 90 [° C.] or less.
The following describes an embodiment of the present disclosure with reference to accompanying drawings. Note that, in a case where “Front,” “Rear,” “Left,” “Right,” “Up,” and “Down” are denoted in the drawings, the terms “Frontward (Front),” “Rearward (Rear),” “Leftward (Left),” “Rightward (Right),” “Upward (Up),” and “Downward (Down)” in the explanations of the description refer to the denoted directions.
General Configuration of Tape Printer
First, the general configuration of the printer related to this embodiment will be described with reference to
In
The housing 2 comprises a housing main body 2a, a first storage part 3 disposed on the rearward side of the housing main body 2a, and a second storage part 4 and a third storage part 5 disposed on the frontward side of the housing main body 2a.
The rearward-side opening/closing part 8 is connected to an upper area of the rearward side of the housing main body 2a in an openable and closeable manner. This rearward-side opening/closing part 8 is capable of opening and closing the area above the first storage part 3 by pivoting. The rearward-side opening/closing part 8 includes a first opening/closing cover 8a and a second opening/closing cover 8b.
The first opening/closing cover 8a is capable of opening and closing the area above the frontward side of the first storage part 3 by pivoting around a predetermined pivot axis K1 disposed in the upper area of the rearward side of the housing main body 2a. A head holding body 10 is disposed in the interior of the first opening/closing cover 8a (refer to
The second opening/closing cover 8b is disposed further on the rearward side than the above described first opening/closing cover 8a, and is capable of opening and closing the area above the rearward side of the first storage part 3 separately from the opening and closing of the above described first opening/closing cover 8a by pivoting around a predetermined pivot axis K2 disposed on the upper end of the rearward side of the housing main body 2a.
Then, the first opening/closing cover 8a and the second opening/closing cover 8b are configured so that, when each is closed, an outer peripheral part 18 of the first opening/closing cover 8a and an edge part 19 of the second opening/closing cover 8b substantially contact each other and cover almost the entire area above the first storage part 3.
The frontward-side opening/closing cover 9 is connected to the upper area of the frontward side of the housing main body 2a in an openable and closeable manner. The frontward-side opening/closing cover 9 is capable of opening and closing the area above the second storage part 4 by pivoting around a predetermined pivot axis K3 disposed on the upper end of the frontward side of the housing main body 2a. Specifically, the frontward-side opening/closing cover 9 is capable of pivoting from a closed position (the states in
At this time, a tape cartridge TK is detachably mounted in a first predetermined position 13 below the frontward-side opening/closing cover 9 (when closed) in the housing main body 2a. The tape cartridge TK comprises a first roll R1 formed wound around an axis O1, and a coupling arm 16 (refer to
The first roll R1 is supported on the rearward side of the tape cartridge TK by the coupling arm 16, and rotatable when the tape cartridge TK is mounted to the housing main body 2a. The first roll R1 winds a long fabric tape 153 consumed by feed-out around the axis O1 in the left-right direction in advance. Note that, in each figure of this embodiment, the above described fabric tape 153 disposed as the above described first roll R1 is suitably omitted (to avoid complexities in illustration), and only a substantially circular roll flange part disposed so as to sandwich both width-direction sides of the fabric tape 153 is shown. In this case, as a matter of convenience, the roll flange part is schematically depicted using the reference number “R1.”
Then, at this time, the first roll R1 is received from above by the mounting of the tape cartridge TK and stored with the axis O1 of the winding of the fabric tape 153 in the left-right direction in the first storage part 3. Then, the first roll R1, stored in the first storage part 3 (with the tape cartridge TK mounted), rotates in a predetermined rotating direction (a direction A in
A surface on one side (the surface on the upper side in
Further, the above described feeding roller 12 is disposed on an intermediate upward side of the first storage part 3 and the third storage part 5 of the housing main body 2a. The feeding roller 12 is driven by a feeding motor M1 disposed in the housing main body 2a via a gear mechanism (not shown), thereby feeding the fabric tape 153 fed out from the first roll R1 stored in the first storage part 3 in a tape posture in which the tape width direction is in the left-right direction.
Further, the above described head holding part 10 disposed on the first opening/closing cover 8a comprises the above described printing head 11. This printing head 11 is disposed in a position of the head holding part 10 that faces the area above the feeding roller 12, with the first opening/closing cover 8a closed, sandwiching the fabric tape 153 fed by the feeding roller 12 in coordination with the feeding roller 12. Accordingly, when the first opening/closing cover 8a is closed, the printing head 11 and the feeding roller 12 are disposed facing each other in the up-down direction. The printing head 11 comprises a plurality of heating elements (not shown). An arranged direction of the plurality of heating elements is a direction of weft threads (described later). Then, the printing head 11 forms desired print on the print-receiving surface 153A of the fabric tape 153 sandwiched between the printing head 11 and the feeding roller 12 using an ink ribbon IB of a ribbon cartridge RK described later, and the fabric tape 153 becomes a fabric tape 153′ with print.
At this time, the ribbon cartridge RK is detachably mounted in a second predetermined position 14, which is below the first opening/closing cover 8a (when closed) and above the tape cartridge TK in the housing main body 2a. The ribbon cartridge RK comprises a housing RH (refer to
The ribbon supply roll R4 is rotatably supported by the housing RH on the rearward side of the ribbon cartridge RK, and winds the ink ribbon IB (refer to
The ribbon take-up roll R5 is rotatably supported by the housing RH on the frontward side of the ribbon cartridge RK, and rotates in a predetermined rotating direction (a direction E in
Further, a ribbon take-up roller (not shown) is disposed on the downstream side of the printing head 11 extended along the tape transport direction of the first opening/closing cover 8a. The ribbon take-up roller guides the used ink ribbon IB to the ribbon take-up roll R5.
That is, the ink ribbon IB fed out from the ribbon supply roll R4 is disposed further on the printing head 11 side of the fabric tape 153 sandwiched between the printing head 11 and the feeding roller 12, contacting the area below the printing head 11. Then, a portion of the layer (details described later) of the ink ribbon IB is transferred to the print-receiving surface 153A of the fabric tape 153 by the heat from the printing head 11 to execute print formation, and the used ink ribbon IB is subsequently taken up by the ribbon take-up roll R5 while guided by the ribbon take-up roller.
Further, the fabric tape 153′ with print after printing is wound on an outer peripheral side of a take-up mechanism 40, thereby forming a second roll R2. That is, the above described take-up mechanism 40 for sequentially winding the fabric tape 153′ with print is received from above and stored in the second storage part 4 so that it is supported rotatably around an axis O2, with the axis O2 of the winding of the fabric tape 153′ with print in the left-right direction. Then, the take-up mechanism 40, stored in the second storage part 4, is driven by a take-up motor M2 disposed in the housing main body 2a via a gear mechanism, and rotates in a predetermined rotating direction (a direction B in
Overview of Operation of Tape Printer
Next, an overview of the operation of the tape printer 1 will be described.
That is, when the tape cartridge TK is mounted in the first predetermined position 13, the above described first roll R1 positioned on the rearward side of the tape cartridge TK is stored in the first storage part 3, and the section on the frontward side of the tape cartridge TK is stored in the third storage part 5. Further, the take-up mechanism 40 for forming the second roll R2 is stored in the second storage part 4.
At this time, the feeding roller 12 is driven, feeding the fabric tape 153 fed out by the rotation of the first roll R1 stored in the first storage part 3 to the frontward side. Then, desired print is formed on the print-receiving surface 153A of the fed fabric tape 153 by the printing head 11, and the fabric tape 153 becomes the fabric tape 153′ with print. The fabric tape 153′ with print is further fed to the frontward side, introduced to the second storage part 4, and wound on the outer peripheral side of the take-up mechanism 40 inside the second storage part 4, thereby forming the second roll R2. At this time, a cutter mechanism 30 disposed further on the rearward side than the second roll R2, that is, on the frontward side opening/closing cover 9 on the upstream side of the second roll R2 extended along the tape transport direction, cuts the fabric tape 153′ with print. With this arrangement, it is possible to cut the fabric tape 153′ with print to be wound in the second roll R2, and remove the second roll R2 from the second storage part 4 after cutting, based on timing desired by the user.
Note that, a shoot 15 for switching the feeding path of the above described fabric tape 153′ with print between a side facing the second roll R2 and a side facing a discharging exit (not shown) may be arranged. That is, the fabric tape 153′ with print may be discharged as is from a discharging exit (not shown) disposed on the second opening/closing cover 8b side, for example, of the housing 2 to the outside of the housing 2 (without being wound inside the second storage part 4) by switching the tape path in a switch operation of the shoot 15 using a switch lever (not shown).
Control System
Next, the control system of the tape printer 1 will be described. In
The RAM 213 comprises an image buffer 213a that expands print data of an image data format received from the PC 217 (or generated in accordance with an operation of the operation part 216) into dot pattern data for printing on the above described fabric tape 153, and stores the dot pattern data. The CPU 212 performs printing corresponding to the print data on the above described print-receiving surface 153A by the printing head 11 via the printing head control circuit 223 in accordance with the above described print data stored in the image buffer 213a while feeding out the fabric tape 153 by the feeding roller 12, according to a suitable control program stored in the ROM 214. Note that, according to this embodiment, the feeding roller 12 and the printing head 11 are synchronized with each other and controlled in coordination by a known technique so that the printing speed for the fabric tape 153 becomes 100 [mm/sec] or higher and 200 [mm/sec] or lower by the control of the CPU 212.
Special characteristic of the embodiment In the above, according to the tape printer 1, desired printing corresponding to the above described print data is performed on the print-receiving surface 153A of the fabric tape 153 by heat transfer printing of the ink of the ink ribbon IB using the above described printing head 11, as described above. The special characteristics of this embodiment lie in the configuration of the fabric tape 153 and the ink ribbon IB for preventing inconveniences resulting from an uneven shape of the above described fabric tape 153 and ensuring high print quality during the above described printing. In the following, details on the functions will be described in order.
Unevenness of Fabric Tape
A fabric medium such as the above described fabric tape 153 is generally configured by weaving warp threads (extending along the tape longitudinal direction) and weft threads (extending along the tape width direction) and, as a result, unevenness from the weave exists on the front surface. This unevenness hinders smooth print formation by heat transfer printing using the aforementioned ink ribbon IB when large. Accordingly, to ensure high print quality, some measure is required. In particular, if high-speed printing is to be performed, a sufficient countermeasure is required since it is not possible to take a sufficient amount of time for the melting and transfer of the ink of the ink ribbon IB.
Satin Weave
As a result of repeated independent studies, the inventors and the like of this application discovered that it is possible to decrease the unevenness of the print-receiving surface 153A by making the fabric tape 153 a satin weave with more warp thread exposure on the front surface, and establishing a medium front surface on one or the other thickness-direction side of the fabric tape 153, whichever has more warp thread exposure than weft thread exposure, as the above described print-receiving surface 153A.
As shown in
In this example, the warp thread (1) is woven on the back side (the side opposite the print-receiving surface 153A; hereinafter the same) at an intersecting location with the weft thread (1), but is woven so as to be exposed on the front side (the print-receiving surface 153A side; hereinafter the same) at intersecting locations with the remaining weft threads (2)-(7). Similarly, the warp thread (2) is woven on the back side at an intersecting location with the weft thread (5), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1)-(4) and (6)-(7). Further, the warp thread (3) is woven on the back side at an intersecting location with the weft thread (2), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1) and (3)-(7). Further, the warp thread (4) is woven on the back side at an intersecting location with the weft thread (6), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1)-(5) and (7). Further, the warp thread (5) is woven on the back side at an intersecting location with the weft thread (3), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1)-(2) and (4)-(7). Further, the warp thread (6) is woven on the back side at an intersecting location with the weft thread (7), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1)-(6). Further, the warp thread (7) is woven on the back side at an intersecting location with the weft thread (4), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (1)-(3) and (5)-(7). Further, the warp thread (8) is woven on the back side at an intersecting location with the weft thread (1), but is woven so as to be exposed on the front side at intersecting locations with the remaining weft threads (2)-(7). According to this embodiment, as a result of a weave configuration such as described above, it is possible to relatively decrease the unevenness of the print-receiving surface 153A of the fabric tape 153.
Weaving Density of Warp and Weft Threads
Further, as a result of repeated simultaneous studies, the inventors and the like of this application discovered that it is possible to increase the number of warp threads to reliably increase exposure by relatively increasing the weaving density (300 [threads/inch] or more, for example) of the warp threads in the above described fabric tape 153. In particular, the inventors and the like discovered that (the number of warp and weft intersecting points can be decreased and therefore) the weaving density of the warp threads can be reliably increased by establishing at least a six-end satin in the above described satin weave. With the resulting increase in warp thread exposure, in the area of the print-receiving surface 153A shown in the above described
Further, while the warp threads may become too fine, causing decreases in durability and the occurrence of slippage in the satin weave, if the weaving density of the warp threads is made too high, the inventors and the like of this application, as a result of independent studies, discovered that it is possible to prevent the above described adverse effect by setting the weaving density of the warp threads to 540 [threads/inch] or less, for example. Note that, according to the fabric tape 153 in this embodiment, the range of the weaving density of the weft threads is set to 80 [threads/inch] or more and 540 [threads/inch] or less in order to match the aforementioned range of the weaving density of the warp threads to 300 [threads/inch] or more and 540 [threads/inch] or less, and perform smooth weaving.
Low Print Quality Based on Comparison Example
The inventors and the like of this application fabricated the fabric tape 153 based on a 5-end satin weave as a comparison example to confirm the study results described above. At this time, the weaving density of the warp threads was set to less than 300 [threads/inch], and the weaving density of the weft threads was set to less than 80 [threads/inch]. Then, the inventors and the like fabricated the fabric tape 153′ with print by performing so-called high-speed printing that is a printing speed of 100 [mm/sec] on the fabric tape 153 in this comparison example, in the tape printer 1 with the above described configuration. The print formation results are shown in
High Print Quality by Manufacturing Conditions in Line with Study Results
In response to the above described comparison example, the inventors and the like of this application fabricated the above described fabric tape 153 based on a satin weave of 6-end satin or more and 10-end satin or less (7-end satin, for example), in line with the above described study results. At this time, the weaving density of the warp threads was set to 300 [threads/inch] or more and 540 [threads/inch] or less (360 [threads/inch], for example) and the weaving density of the weft threads was set to 80 [threads/inch] or more and 540 [threads/inch] or less (106 [threads/inch], for example). Then, the inventors and the like fabricated the fabric tape 153′ with print by performing high-speed printing that is a printing speed of 100 [mm/sec] in the same way as the above described comparison example on the fabric tape 153, in the tape printer 1 with the above described configuration. The print formation results are shown in
Calender Processing
Further, according to the above described fabric tape 153 in this embodiment, known calender processing is performed on the print-receiving surface 153A side in order to improve the above described print quality. The following describes the details using
The calender processing device 210, in this example, comprises heatable rotating drums 210A, 210A, rotating drums 210B, 210B, and rotating drums 210C, 210C. Then, the introduced above described raw fabric 153-0 is heated and pressed by the respective pairs of rotating drums 210A, 210B, 210C while fed at a predetermined speed. With this arrangement, the above described raw fabric 153-0 becomes a shiny fabric 153-1 wherein at least the side that becomes the print-receiving surface A (both sides in this example) is smoothened and given a lustrous shine (refer to the enlarged view). Note that this calender processing is performed under the conditions of a heating temperature of 160 [° C.] or more, the above described feeding speed of 10 [m/min] or lower, and a pressure of the above described pressing of 7 [MPa] or more, for example.
The shiny fabric 153-1 derived from the calender process device 210 is supplied to a heat cutting processing device 220 via a guide roll 204. The heat cutting processing device 220 comprises heatable cutter parts 221, 221 on both width-direction sides of the feeding path of the shiny fabric 153-1. According to this embodiment, the raw fabric 153-0 (that is, the shiny fabric 153-1) includes a hot melt fiber, and both width-direction ends of the shiny fabric 153-1 are cut (heat cutting processing) by the above described cutter parts 221, 221, thereby becoming the above described fabric tape 153. Note that the heating conditions of the above described cutter part 221 is 525 [° C.], for example. As a result of this processing, the print-receiving surface 153A of the fabric tape 153 comprises relatively thick ear parts 153a, 153a positioned on edges of both width-direction sides, and print area 153b on which print is formed by the aforementioned printing head 11, positioned between these ear parts 153a, 153a in a width-direction intermediate area. Note that each figure other than this
The fabric tape 153 thus formed is wound inside an original winding roll 206 via a guide roll 205. Note that, as a result of the above processing, the thickness of above described warp threads and the thickness of the weft threads of the fabric tape 153 become 30 [deniers] or more and 90 [deniers] or less (specifically, 48 [deniers], for example), and 30 [deniers] or more and 90 [deniers] or less (specifically, 75 [deniers], for example), respectively. Further, the above described first roll R1 need only use the above described original winding roll 206 as is or a roll with the fabric tape 153 fed out once again from the original winding roll 206 wound around a suitable winding core (so that the print-receiving surface 153A is on the outer peripheral side).
Ink Ribbon
On the other hand, print that utilizes the heat transfer printing of ink in the same way as the above described ink ribbon IK is formed by the adherence of ink drops, which melted due to received heat, to the transfer target. To improve the print quality, the melting point for melting the ink ribbon is preferably lowered to speed up melting and transfer. If the melting point is lowered too much, however, the durability of the ink ribbon may decrease during transport and the like under high ambient temperature conditions, for example. Thus, to strike a balance between improving the print quality and suppressing decreases in durability, some measure is required in relation to the layer structure of the ink ribbon, the physical properties of each layer, and the like.
Details of Layered Structure of Ink Ribbon
As a result of independent studies, the inventors and the like of this application discovered that, in the layered structure of the ink ribbon IB, it is possible to strike the above described balance between improving the print quality and decreasing the durability by setting the melting point of the layer to be adhered to the fabric tape 153 in a predetermined range (described later).
As shown in
Films that may be used for the ribbon base layer 155a include, for example, polyester films such as polyethylene naphthalate film (PEN), polyarylate film (PAR), and polybutylene terephthalate film (PBT) in addition to the above described polyethylene terephthalate film (PET), and various other films generally used as a base film of ink ribbon.
The undercoat layer 155b and the overcoat layer 155a include a resin component and a wax component, and the ink layer 155c includes a resin component, a pigment component, and a wax component (details described later).
In the ink ribbon IB with the above described configuration, the above described undercoat layer 155b is melted by heat reception resulting from the heat from the printing head 11, thereby separating the transfer layer 155A made of the undercoat layer 155b, the ink layer 155c, and the overcoat layer 155d from the above described ribbon base layer 155a. Then, the overcoat layer 155d side of the transfer layer 155A is transferred and adheres to the print-receiving surface 153A of the fabric tape 153 serving as the transfer target (refer to
Setting the Melting Point
As a result of repeated studies, the inventors and the like of this application discovered that it is possible to strike the above described balance between improving the print quality and decreasing the durability by setting the melting point of the above described overcoat layer 155a to 60° C. or more and 90° C. or less. That is, the melting point of the overcoat layer 155a is set to a relatively low 90° C. or less, thereby causing the layer to melt, separate from the ribbon base layer 155a, and quickly adhere to the fabric tape 153 serving as the transfer target, even if there is not much heat reception. As a result, it is possible to improve the print quality. In particular, if high-speed printing that is 100 [mm/sec] or higher is performed, for example, the above described print quality improvement effect is remarkable, as described above. On the other hand, if the melting point is lowered too much, the durability of the overall ink ribbon IB may decrease during transport or the like under high ambient temperature conditions. In this embodiment, the melting point of the overcoat layer 155a is set to 60° C. or more, making it possible to suppress the above described decreases in durability at high temperatures. As a result, it is possible to strike a balance between improving the print quality and suppressing decreases in durability.
Low Print Quality Based on Comparison Example
The inventors and the like of this application fabricated the fabric tape 153′ with print by performing so-called high-speed printing that is a printing speed of 100 [mm/sec] on the above described fabric tape 153 by the tape printer 1 with the above described configuration, using the ink ribbon IB with a melting point of the above described overcoat layer 155a set to less than 90° C., as a comparison example for confirming the study results described above. The print formation results are shown in
High Print Quality by Manufacturing Conditions in Line with Study Results
In response to the above described comparison example, the inventors and the like of this application fabricated the fabric tape 153′ with print by performing high-speed printing that is a printing speed of 100 [mm/sec] in the same way as the above described comparison example on the above described fabric tape 153 by the tape printer 1 with the above described configuration, using the ink ribbon IB comprising the overcoat layer 155a having a melting point of 60° C. or more and 90° C. or less (80° C., for example), in line with the above described study results. The print formation results are shown in
Note that, in the ink ribbon IB with the above described configuration, according to this embodiment, the resin to wax component ratio (weight ratio) in the overcoat layer 155a is resin:wax=5:5, for example. Further, the resin to wax component ratio (weight ratio) in the undercoat layer 155b is resin:wax=1:9, for example, and the melting point of the overall undercoat layer 155b is approximately 95° C., for example, as a result. Further, the resin to pigment to wax component ratio (weight ratio) in the ink layer 155c is resin:pigment:wax=4:5:1, for example, and the melting point of the overall ink layer 155c is approximately 85° C., for example, as a result. Note that, as a result of further studies on the weight ratio of the wax component in relation to the overcoat layer 155a, the inventors and the like of this application discovered that it is possible to reliably improve the adherence to the transfer target by setting the weight ratio of the wax component to 50 [%] or more. Further, the inventors and the like discovered that it is possible to suppress decreases in abrasion resistance by setting the weight ratio of the wax component to 70 [%] or less.
Note that the above described wax component used in the above described undercoat layer 155b, overcoat layer 155a, and ink layer 155c need only be, for example, one type (or two or more types mixed together) from among natural waxes, such as beeswax (animal wax), carnauba wax, candelilla wax, Japan wax, rice wax (vegetable wax), montan wax, ozocerite wax, and ceresin wax (mineral wax); petroleum waxes such as paraffin wax and microcrystalline wax; and synthetic waxes such as Fischer-Tropsch wax, polyethylene wax (hydrocarbon synthetic wax), higher fatty acid ester, fatty acid amide, ketone, amines, and hydrogen hardened oil.
Further, the above described resin (hot melt resin) component used in the above described undercoat layer 155b, overcoat layer 155a, and ink layer 155c need only be, for example, one type (or two or more types mixed together) from among olefinic-based copolymer resins such as ethylene-vinyl acetate copolymer and ethylene-acrylate copolymer; elastomers such as polyamide resin, polyester resin, epoxy resin, polyurethane reins, acrylic resin, vinyl chloride resin, cellulose resin, vinyl alcohol resin, petroleum resin, phenolic resin, styrene resin, vinyl acetate resin, natural rubber, styrene-butadiene rubber, isoprene rubber, and chloroprene resin; polyisobutylene; and polybutene.
Advantages of this Embodiment
As described above, in this embodiment, the fabric tape 153 is made into a satin weave with more warp thread exposure on the front surface, and the side with more warp thread exposure is established as the print-receiving surface 153A, making it possible to decrease the unevenness of the print-receiving surface 153A. In particular, the weaving density of the warp threads is set to 300 [threads/inch] or more, making it possible to increase the number of warp threads and reliably increase exposure. In particular, the satin is established as at least a 6-end satin, making it possible to decrease the number of warp and weft intersecting points and reliably increase the weaving density of the warp threads. Further, calender processing is performed on the above described print-receiving surface 153A, making it possible to give a lustrous shine to the front surface of the print-receiving surface 153A. As a result, it is possible to achieve the print-receiving surface 153A with small unevenness, high warp thread exposure, and lustrous shine, making it possible to improve the print quality when forming print by the transfer of ink drops (the above described transfer layer 155A in this example) using the above described ink ribbon IB. In particular, the quality improvement effect is significant when high-speed printing that is 100 [mm/sec] or higher is executed, for example.
Further, in particular, according to this embodiment, the thickness of the warp thread of the fabric tape 153 is set to 30 [deniers] or more, making it possible to reliably suppress decreases in durability and the occurrence of slippage in the satin weave caused by the warp thread becoming too fine. Further, the thickness of the warp threads is set to 90 [deniers] or less, making it possible to reliably suppress decreases in print quality caused by a decrease in weaving density and loose weaves. Then, in correspondence with the above described thickness range of the warp threads, the thickness of the weft threads is set to 30 [deniers] or more and 90 [deniers] or less, making it possible to obtain the fabric tape 153 that is appropriately combined with warp threads that achieve the advantage described above.
Further, in particular, according to this embodiment, both width-direction sides of the fabric tape 153 are subjected to heat cutting processing. With this arrangement, it is possible to suppress the occurrence of fray on the edges of both sides.
Further, in particular, according to this embodiment, it is possible to strikingly achieve the above described print quality effect in particular during high-speed printing that is a printing speed of 100 [mm/sec] or higher, as described above. At this time, the upper limit of the printing speed is suppressed to 200 [mm/sec] or lower, making it possible to ensure favorable meltability and favorable adherence to the transfer target of the ink drops (the above described transfer layer 155A in this example) of the ink ribbon IB, and reliably improve the print quality.
Note that, while the weaving density of the warp threads is set to 300 [threads/inch] or more from the viewpoint of increasing warp thread exposure and decreasing unevenness in the above, the weaving density may be determined taking into account the resolution of the printing head 11 as well (the fabric tape 153 with a weaving density greater than or equal to the resolution of the printing head 11). That is, for example, if the value of the weaving density of the fabric tape 153 is lower (less than 300 [threads/inch]; approximately 200 [threads/inch], for example) than the resolution of the printing head 11 when the resolution is relatively high (300 dpi, for example), adherence of the ink drops generated at the fine resolution is hindered by the unevenness of the loose weaving density, making adherence and thus dot formation impossible. Accordingly, if the resolution of the printing head 11 is set to approximately 300 dpi, for example, as described above, it is best to set the weaving density of the fabric tape 153 to a value that is at least equivalent to the resolution or to 300 [threads/inch] or more, which is higher than the resolution, preferably to approximately 360 [threads/inch], which is approximately 20% higher. With this arrangement, it is possible to reliably achieve high print quality.
Further, as described above, in this embodiment, the melting point of the overcoat layer 155a included in the ink ribbon IB is set to 60° C. or more and 90° C. or less, making it possible to strike a balance between improving the print quality and suppressing decreases in durability.
Further, in particular, according to this embodiment, the weight ratio of the wax component included in the overcoat layer 155a of the ink ribbon IB is set to 50 [%] or more and 70 [%] or less (50% in the aforementioned example), making it possible to reliably improve the adherence to the transfer target and suppress decreases in abrasion resistance, thereby reliably maintaining the integrity of the ink ribbon.
Further, in particular, according to this embodiment, both width-direction sides of the fabric tape 153 become the ear parts 153a subjected to heat cutting processing, making it possible to suppress the occurrence of fray on the edges of both sides. Further, print formation is avoided on the ear parts 153a with a larger thickness and performed in the print area 153b with a smaller thickness, thereby making it possible to reliably suppress the occurrence of faint print and the like.
Note that the present disclosure is not limited to the above aspects, and various modifications may be further made without deviating from the spirit and scope of the disclosure. The following describes various modifications that satisfy such conditions, one by one. Note that components identical to those in the above described embodiment are denoted using the same reference numbers, and descriptions thereof will be omitted or simplified as appropriate.
(1) When the Ink Layer of the Ink Ribbon Also Serves as the Adhering Function
In the ink ribbon IB with the above described configuration, the above described undercoat layer 155b is melted by heat reception resulting from the heat from the printing head 11, thereby separating the transfer layer 155A of this modification that is made of the undercoat layer 155b and the ink layer 155c′ from the above described ribbon base layer 155a. Then, the transfer layer 155A is transferred and adheres to the print-receiving surface 153A of the fabric tape 153 serving as the transfer target (refer to
The inventors and the like of this application discovered that, in the configuration of this modification, it is possible to strike the above described balance between improving the print quality and decreasing the durability by setting the melting point of the overall ink layer 155c′ to 60° C. or more and 90° C. or less (80° C. in this modification, for example) in the same way as the overcoat layer 155a in the above described embodiment. In particular, similar to the above described embodiment, if high-speed printing that is 100 [mm/sec] or higher is performed, for example, the above described print quality improvement effect is remarkable.
Further, similar to the above described embodiment, as a result of further studies on the weight ratio of the wax component included in the ink layer 155c′, the inventors and the like of this application confirmed that it is possible to reliably improve the adherence to the transfer target while suppressing decreases in abrasion resistance by setting the weight ratio of the wax component to 50 [%] or more and 70 [%] or less.
(2) Other
Note that, in the above, the arrows shown in
Further, other than that already stated above, techniques based on the above described embodiments and each of the modifications may be suitably utilized in combination as well.
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Entry |
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Sep. 20, 2016—(EP) Extended Search Report—App 15185726.5. |
Jul. 8, 2016—(EP) Partial Search Report—App 15185726.5. |
Number | Date | Country | |
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20160152056 A1 | Jun 2016 | US |