The present invention relates to a thermal head and a thermal transfer printer in which the thermal head is used. In particular, the present invention can reduce friction force to be generated between the thermal head and an ink ribbon.
In a conventional thermal transfer printer, an ink ribbon and printing paper are sandwiched between a thermal head and a platen roller to melt ink on the ink ribbon with heat generated by the thermal head. Then, by transferring and fixing the molten ink onto the printing paper, the thermal transfer can print predetermined information on the printing paper.
An example of an existing thermal transfer printer will be described in detail with reference to
The printing paper supply unit 3 has a supply shaft 7, and a rolled printing paper 8 is held by the supply shaft 7. The printing unit 4 includes a thermal head 9, a platen roller 10 that is located to oppose the thermal head 9, an ink ribbon supply unit 11, and an ink ribbon take-up unit 12. An ink ribbon 13 is guided from the ink ribbon supply unit 11 to the ink ribbon take-up unit 12 by guide rollers 14 to stretch along a lower portion of the thermal head 9.
The printing paper 8 that is supplied from the printing paper supply unit 3 is transported by a transport roller 15 toward the printing unit 4 located downstream from the printing paper supply unit 3. The transported printing paper 8 is sandwiched, together with the ink ribbon 13, between the thermal head 9 and the platen roller 10. At this point, ink on the ink ribbon 13 melts with heat generated in the thermal head 9, and predetermined information is printed on the printing paper 8. After printing, the printing paper 8 is cut by the printing paper cutting unit 5 in a desired length and discharged to the outside of the thermal transfer printer 1 through the discharge port 6.
Subsequently, the thermal head 9 to be used in the thermal transfer printer 1 will be described with reference to
The thermal head 9 includes a head body 20 that is configured of a heatsink, a heat generator 21, a connector unit 22 which transmits a signal to control an amount of heat in the heat generator 21 through a control unit in a body (printer body) of the thermal transfer printer 1, and an engaging unit 23 which supports the thermal head 9 onto an unillustrated bracket of the body.
The heat generator 21 includes a plurality of heating elements arrayed intermittently extending parallel in a widthwise direction of the thermal head 9. The heating elements emit heat to melt the ink on the ink ribbon 13. The predetermined information is printed as the molten ink is transferred and fixed onto the printing paper 8.
In the thermal transfer printer 1 configured as described above, circumstances that lead to printing failure have been observed. The circumstances include the ink ribbon 13 sagging, being wrinkled, or traveling obliquely. As a method of retaining constant tension of the ink ribbon 13 in order to prevent wrinkles or the like from being generated in the ink ribbon 13, a method exists in which a speed at which the ink ribbon 13 is taken up is controlled in an unillustrated control unit such that the speed at which the ink ribbon 13 is taken up exceeds a speed at which printing paper is transported, or a method in which a guide member is provided to guide the ink ribbon 13 at a position where the ink ribbon 13 is separated from the printing paper 8 in the thermal head 9 and redirected toward the ink ribbon take-up unit 12 (see, for example, PTL 1).
However, in the thermal transfer printer 1 having the above-described configuration, when, for example, black and white are reversed in printing or printing density is increased, thermal energy is concentrated at a part of the ink ribbon 13. Then, a wave-like warp is generated partially in the ink ribbon 13 due to the heat. There is a possibility that wrinkles are generated due to the warp and uniform tension is not given to the ink ribbon 13, which results in printing failure or oblique traveling of the ink ribbon 13.
A detailed description will be given using
The printing paper 8 is transported in accordance with a rotary drive (a direction illustrated by an arrow in
The ink ribbon 13 includes a film layer 24 and an ink layer 25 that is applied on the film layer 24. The thickness of the ink ribbon 13 is 6 μm to 8 μm. The ink in the ink layer 25 is heated with heat generated by the heat generator 21 that is located to the side of the film layer 24. The ink ribbon 13 is separated from the printing paper 8 after the ink is cooled to be transferred and fixed onto the printing paper 8. When printing in this way, the ink on the ink ribbon 13 is made molten by the thermal head 9 and remains in a molten state until the ink ribbon 13 is separated from the printing paper 8 at a downstream side of the thermal head.
The film layer 24 of the ink ribbon 13 immediately after being heated by the heat from the thermal head 9 warps in a wave-like shape if the amount of received heat is high. And, the ink in the ink layer 25 that is in a molten state deforms in accordance with a shape of the warped film layer 24. Therefore, simply adjusting the speed at which the ink ribbon 13 is taken up or only providing the guide member to guide the ink ribbon 13 toward the ink ribbon take-up unit 12 after the ink ribbon 13 and the printing paper 8 are separated from each other as described in PTL 1 does not allow uniform tension to be given to the ink ribbon 13 that has warped in a wave-like shape in a state where the ink is molten immediately after being heated by the thermal head 9.
Further, since printing is carried out in a state where the ink ribbon 13 and the printing paper 8 are pressed against the thermal head 9 by the platen roller 10, a constant friction force is continuously generated between the thermal head 9 and the ink ribbon 13. Then, the friction force is enhanced at a location where the ink ribbon 13 is warped due to the heat compared to a location where the ink ribbon 13 is not warped. Accordingly, the speed at which the ink ribbon 13 is taken up is reduced from a preset speed. On the other hand, since the printing paper 8 is transported by the platen roller 10, a difference in speed of the ink ribbon 13 and the printing paper 8 is increased from a preset difference. Then, the ink in a molten state is pulled toward the direction in which the printing paper 8 is transported, and the ink ribbon 13, on the contrary, is braked between the printing paper 8 and the thermal head 9 toward the direction opposite to the transport direction of the printing paper 8. Thus, there has been a possibility that the ink is separated within the ink layer 25 (refer to an intra-layer separation part 26). When an intra-layer separation occurs, a shade of printed information partially varies, and the information is prevented from being displayed appropriately.
As one of the methods to solve the above-described problem, a method in which the redirecting member 27 that is located downstream from the thermal head 9 is adjusted toward a direction intersecting with the ink ribbon 13 to adjust the ink ribbon 13 to be pressed toward a direction away from the thermal head 9 can be contemplated. However, this adjustment requires a highly skilled operation and could not easily be carried out by a typical user.
The present invention has been made in view of the above-described problem, and it is an object of the present invention to provide a thermal head and a thermal transfer printer in which tension is given to an ink ribbon that has warped as being heated by the thermal head to reduce friction force to be generated between the thermal head and the ink ribbon without requiring a highly skilled operation.
A first aspect of the present invention provides a thermal head that includes a head body; a heat generator including a plurality of heat generators aligned on the head body, wherein the thermal head allows a printing paper and an ink ribbon to be transported between the thermal head and a platen roller opposed to the thermal head and allows necessary and possible printing information to be transferred onto the printing paper using the ink ribbon; and a ribbon transport direction changing member which is provided to be parallel to the heat generator in a vicinity of the heat generator of the head body, wherein the ribbon transport direction changing member protrudes toward the platen roller than the heat generator.
Further, the ribbon transport direction changing member includes projections which are intermittently provided.
Further, the ribbon transport direction changing member is provided downstream side with respect to the heat generator.
Further, the projections are formed by intermittently applying a non-volatile resin to bulge portions to which the resins are applied.
Further, the projections are formed so that tips of the projections are circular-arc-shaped.
Further, a second aspect of the present invention provides a thermal transfer printer that includes a thermal head; and a platen roller which is arranged to oppose the thermal head, wherein the thermal transfer printer carries out a printing operation with printing paper and an ink ribbon which is capable of being transferred to print on the printing paper which are sandwiched between the thermal head and the platen roller, and wherein the thermal head includes a heat generator including a plurality of heating elements extending parallel and in a widthwise direction of the printing paper and includes a ribbon transport direction changing member in a vicinity of the heat generator, and a tip of the ribbon transport direction changing member protrudes toward the platen roller to a position to make contact with the ink ribbon.
According to the first aspect of the present invention, by providing the ribbon transport direction changing member in the vicinity of the heat generator of the thermal head, a transport path of the ink ribbon can be moved toward the platen roller to give a tension to the ink ribbon. Thus, a friction force to be generated between the ink ribbon and the thermal head can be reduced, and a separation within the ink layer can be prevented with ease.
Further, according to the second aspect of the present invention, by using the thermal head which is provided with the ribbon transport direction changing member in the vicinity of the heat generator in the thermal transfer printer, a favorable printing quality can be obtained by reducing the friction force to be generated between the ink ribbon and the thermal head even when high thermal energy is concentrated on the ink ribbon as in a case where black and white are reversed in printing or the like.
A thermal transfer printer 28 and a thermal head 29 according to an embodiment of the present invention will be described using
Here, configurations that are similar to those of the existing technique in
The thermal head 29 includes the heat generator 21 that is arranged in a widthwise direction thereof, and the heat generator 21 includes heating elements intermittently aligned. Ink on the ink ribbon 13 is molten as the heating elements emit heat, and the predetermined information is printed as the molten ink is fixed onto the printing paper 8. The ribbon transport direction changing member 30 extends in a widthwise direction of the thermal head 29 and is downstream from the vicinity of the heat generator 21 in the direction of the printing paper. The vicinity referred to herein is, for example, in a range of 1.0 mm to 1.5 mm downstream from the heat generator 21.
The ribbon transport direction changing member 30 includes a plurality of projections 31, which serve as projecting members, provided intermittently in a widthwise direction of the thermal head 29, and downstream in the direction of the printing paper from the heat generator 21. The projection 31 has a length X in a widthwise direction of the thermal head 29 of 2.2 mm to 3.1 mm, and the length X can preferably be 3.0 mm. Further, the projection 31 has a length Y in a paper transport direction in the thermal head 29 of 1.0 mm to 1.2 mm, and the length Y can preferably be 1.0 mm. Further, the projection 31 protrudes toward a platen by a thickness H of 0.1 mm to 0.12 mm, and the thickness H can preferably be 0.1 mm. Furthermore, a pitch P between a center point Q of a projection 31 and a center point Q of an adjacent projection 31 is 7.0 mm to 9.0 mm, and the pitch P can preferably be 8.0 mm.
Further, the projections 31 can be formed by applying a non-volatile resin, and a shape of a tip of the projection 31 that comes in contact with the ink ribbon 13 can be formed into a circular arc.
A relationship between the ink ribbon 13 and the printing paper 8 in a case where predetermined information is printed on the printing paper 8 by the thermal transfer printer 28 that includes the thermal head 29 will be described based on
Note that although the ribbon transport direction changing member 30 includes the projections 31 which are intermittently provided downstream from the heat generator 21 in the above-described embodiment, the projections 31 do not need to be provided intermittently. The ribbon transport direction changing member 30 may be provided continuously at a position parallel to the heat generator 21 as long as it falls within a range that can solve the problem of the present invention.
According to the above-described configuration, even if the ribbon transport direction changing member 30 pushes the ink ribbon 13 away from the heat generator 21, the printing operation can be carried out normally. Further, since the ink ribbon 13 and the printing paper 8 are pressed against the heat generator 21 by the platen roller 10, tension can be given to the ink ribbon 13 between the heat generator 21 and the redirecting member 27. Thus, even if the film layer 24 is warped due to heat, the friction force to be generated between a downstream portion of the heat generator 21 of the thermal head 29 and the film layer 24 can be reduced to a level at which a take-up speed of the ink ribbon 13 is not affected.
Further, since the ribbon transport direction changing member 30 is provided in the thermal head 29 in advance, a highly skilled operation for separating the ink ribbon 13 becomes unnecessary.
Further, forming the tip of the projection 31 in a curved shape reduces a surface thereof to come into contact with the ink ribbon 13, and thus the friction force to be generated between the thermal head 29 and the ink ribbon 13 can be reduced.
Number | Date | Country | Kind |
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2010-276075 | Dec 2010 | JP | national |
The present application is a 35 U.S.C. §§371 national phase conversion of PCT/JP2011/004072, filed Jul. 19, 2011, which claims priority of Japanese Patent Application No. 2010-276075, filed Dec. 10, 2010, the contents of which are incorporated by reference herein. The PCT International Application was published in the Japanese language.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/004072 | 7/19/2011 | WO | 00 | 6/6/2013 |