JP4848713B2 - Printing device - Google Patents

Description

  The present invention relates to a printing apparatus for printing on a recording medium by sandwiching an ink ribbon and a recording medium by a thermal head and a platen roller and controlling the heat generation of the thermal head, and relates to an untransferred portion caused by wrinkles of the ink ribbon. The present invention relates to a printing apparatus that prevents generation.

2. Description of the Related Art Conventionally, there is a printing apparatus that uses an ink ribbon on which heat transferable ink is arranged and heats the ink ribbon to a recording medium by heating the ink ribbon with a thermal head.
For example, in a printing apparatus having a paper cassette containing paper as a recording medium and a ribbon cassette containing ink ribbon, the paper fed from the paper cassette is conveyed and an unused ink ribbon is wound. The ink ribbon is transported while being pulled out from the rotated ribbon spool. The ink ribbon and the paper are sandwiched between the thermal head and the platen roller, and the ink applied to the ink ribbon is thermally transferred to the paper by controlling the heat generation mode of the thermal head in this state.
In this case, the paper and the ink ribbon are individually transported, but the transport path of the recording medium and the transport path of the ink ribbon are around the portion where printing is performed between the thermal head and the platen roller. Overlapping parts occur.
Then, on the upstream side in the transport direction of the recording medium with respect to the thermal head and the platen roller, the ink ribbon is pressed against another member such as a guide piece that is guided when the ink ribbon is transported due to the rigidity of the paper. The ink ribbon may be sandwiched between other members and the paper.

In addition, because the ink is thermally transferred to the paper by heating the ink ribbon with the thermal head, the base of the heated ink ribbon is stretched in the vicinity of the thermal head. The sheet and the ink ribbon are conveyed to the thermal head and the platen roller as they are.
In this respect, the rotational load of the ribbon spool around which the unused ink ribbon is wound acts as a back tension for the conveyance of the ink ribbon, so that it functions to absorb the elongation of the ink ribbon caused by the heating by the thermal head. .
However, in this case, the ink ribbon is sandwiched with the recording medium on the one hand by the thermal head and the platen roller, and is sandwiched while being pressed by the recording medium on the other hand. It cannot be absorbed by tension.

Therefore, when printing is continued using the ink ribbon, the more the printing is performed, the more the elongation of the ink ribbon based on heating is accumulated near the thermal head. When the accumulated elongation increases to some extent, the ink ribbon is conveyed to the thermal head in a slack state. As a result, the slack portion of the ink ribbon is sandwiched between the thermal head and the platen roller, and wrinkles are formed in which the ink ribbon is bent. When printing is performed in a state where wrinkles are formed on the ink ribbon, the wrinkled portion has a thickness equivalent to a plurality of ink ribbons, so that the ink cannot be transferred without the heat of the thermal head being transmitted. It will be.
That is, the wrinkle generated in the ink ribbon causes an untransferred portion in the printed product, resulting in a problem that the quality of the printed result is deteriorated.

A printing apparatus described in Patent Document 1 is known as a printing apparatus that takes measures against wrinkles generated on the ink ribbon.
As described above, the cause of the wrinkles in the ink ribbon is that the ink ribbon is pressed by another member such as a ribbon guide and pinched due to the rigidity of the paper.
Here, in the printing apparatus described in Patent Document 1, the shape of the ribbon guide that sandwiches the ink ribbon together with the paper is improved, so that the back tension by the ribbon spool is effectively applied to the ink ribbon. Is prevented. Specifically, by forming a plurality of protrusions on the surface that contacts the ink ribbon, the area where the ink ribbon and the ribbon guide contact is reduced, and the frictional force generated between the ink ribbon and the ribbon guide is reduced. . Thereby, the back tension by the ribbon spool can be effectively applied to the ink ribbon, and the elongation of the ink ribbon which is a cause of wrinkles can be absorbed.
JP-A-8-99421

However, in the printing apparatus described in Patent Document 1, by forming protrusions on the contact surface of the ribbon guide with the ink ribbon, the frictional force acting on the ink ribbon is reduced, and the back tension by the ribbon spool is reduced. Although effective, it is not possible to prevent the ink ribbon from wrinkling when a sheet having a large rigidity is used. In other words, when the paper is stiff and the ink ribbon is pressed more strongly, the frictional force generated between the ink ribbon and the ribbon guide becomes larger at the protrusions, and the ribbon spool back tension is effective as before. It becomes impossible to act on.
In other words, in the printing apparatus described in Patent Document 1, papers that can be printed without causing wrinkles on the ink ribbon are limited, and papers that can be printed with high quality are limited. there were.

  The present invention has been made in view of the above-described problems. A printing apparatus that prints on a recording medium by sandwiching an ink ribbon and a recording medium by a thermal head and a platen roller and controlling the heat generation of the thermal head. In view of the above, an object of the present invention is to provide a printing apparatus capable of preventing the occurrence of an untransferred portion caused by wrinkles of an ink ribbon regardless of the strength of the paper.

The printing apparatus according to claim 1, which is made to solve the above-described problem, is a recording medium, a thermal head in which a plurality of heating elements are arranged, and an ink to which ink to be thermally transferred to the recording medium is applied. A ribbon, a sheet conveying unit that conveys the recording medium, a ribbon conveying unit that can convey the ink ribbon, a platen roller that presses the recording medium and the ink ribbon by the thermal head, and during printing on the upstream side in the conveying direction of the recording medium, wherein while separating the recording medium from an ink ribbon, have a sheet guide member for guiding, the thermal head is pressed to press the recording medium and the ink ribbon to the platen roller The sheet guide member is movably disposed between a position and an open position for opening the recording medium and the ink ribbon. Following the movement of the head, on the basis of the thermal head is moved to the pressing position, characterized in that to separate the recording medium from an ink ribbon.

In other words, the printing apparatus of the invention according to claim 1 presses and holds the recording medium conveyed by the sheet conveying means and the ink ribbon conveyed by the ribbon conveying means between the thermal head and the platen roller, Ink is thermally transferred to the recording medium by heating the ink ribbon by the heat generating elements arranged in a row.
At this time, when the ink ribbon is heated by the thermal head, the ink ribbon is stretched. However, the recording medium is guided to the upstream side in the transport direction of the recording medium during printing while being separated from the ink ribbon. Since the sheet guide member is provided, there is no portion where the ink ribbon and the recording medium abut on the upstream side in the transport direction, and the back tension can be effectively applied to the ink ribbon. As a result, since the elongation generated in the ink ribbon is reliably absorbed by the back tension, it is possible to prevent generation of an untransferred portion due to wrinkles on the printing surface.
Further, since the recording medium is guided while being separated from the ink ribbon by the paper guide member, it is possible to prevent the ink ribbon from being wrinkled regardless of the strength of the recording medium. That is, since the wrinkles of the ink ribbon can be prevented regardless of the type of the recording medium, it is possible to provide a high-quality printed matter having no untransferred portion regardless of which recording medium is used. It becomes possible.

Further, in the printing apparatus, the sheet guide is based on a pressing position that presses the recording medium and the ink ribbon against the platen roller, and a thermal head that is movably disposed in the open position moves to the pressing position. The member separates the recording medium from the ink ribbon. That is, when the recording medium and the ink ribbon are sandwiched between the thermal head and the platen roller and printing is performed, the recording medium is guided by the sheet guide member while being separated from the ink ribbon.
As a result, when performing printing in which the ink ribbon stretches, the ink ribbon stretch is immediately absorbed by the action of the back tension, so that there is no wrinkle on the ink ribbon and there is no untransferred portion. It becomes possible to provide beautiful printed matter.

  Hereinafter, a printing apparatus according to the present invention will be described in detail with reference to the drawings based on a specific embodiment.

First, a printing apparatus according to the present embodiment and a schematic configuration of the printing apparatus will be described with reference to FIGS. 1 to 5.
As shown in FIGS. 1 to 5, the printing apparatus 1 includes a main body housing 2 including a frame 5 having side walls 3, 4 disposed on both left and right sides, and a horizontally long shape penetrating the side wall 3. A ribbon cassette 8 that is detachably mounted in the frame 5 by being fitted into the ribbon cassette hole 6 from the side, and a plurality of sheets 10 of recording media are stored in a stacked state, and the front side of the main body housing 2 is stored. The sheet tray 11 is fitted into the lower part from the front side.

In the main body housing 2, a head unit 16 is disposed on the upper side facing the ribbon cassette 8. The head unit 16 is provided with a long thermal head 15 in which a plurality of heating elements are arranged in a row at the front lower edge.
A ribbon cassette detection sensor 38 that detects presence / absence of the ribbon cassette 8 is disposed below the head unit 16. That is, the ribbon cassette detection sensor 38 is configured to output an OFF signal when the ribbon cassette 8 is not loaded, and to output an ON signal when the ribbon cassette 8 is loaded.
Here, the rear end portion of the head unit 16 is attached to each side wall 3, 4 of the frame 5 so as to be rotatable about a rotation shaft 17 on which each end edge portion is pivotally supported. A torsion spring 18 is attached to the rotary shaft 17, and one end of the torsion spring 18 is locked to the side wall 4, and the other end is hooked to the rear end 31 </ b> A of the side wall 31 of the head unit 16. The head unit 16 is urged clockwise in FIG. 4 about the rotation shaft 17 by a torsion spring 18 attached to the rotation shaft 17.
In addition, a reflective photosensor 36 in which an infrared light emitting diode and a phototransistor are incorporated is provided on the front side surface portion of the central portion in the longitudinal direction of the head unit 16.

A pair of cam members 21 and 22 fixed to a rotating shaft 20 whose both ends are pivotally supported by the upper end edges of the side walls 3 and 4 of the frame 5 are provided above the both end edges in the longitudinal direction of the head unit 16. Is provided. The cam members 21 and 22 are formed in a substantially rectangular shape when viewed from the side (see FIG. 4). The head unit 16 is formed so as to slide in contact with the upper end surface portion.
Here, a cam gear 21 </ b> A having a substantially arc shape is formed on the outer side surface of one cam member 21 in the front direction from the rear side edge. The cam gear 21 </ b> A is forward / reverse via a head motor 24 constituted by a stepping motor or the like disposed outside the rear edge of the side wall 4 and a first gear train 25 disposed on the inner surface of the side wall 4. Driven by rotation. Therefore, as shown in FIGS. 4 and 5, the posture control of the head unit 16 is performed based on the rotational drive of the head motor 24. More specifically, when the ribbon cassette 8 is attached / detached, the head motor 24 is reversely driven to rotate in the rearward direction so that the cam members 21 and 22 are positioned substantially horizontally. The drive is controlled so as to be away from 16. At this time, the head unit 16 is rotated upward by the torsion spring 18 so as to be positioned above the ribbon cassette 8 (see FIG. 4).
On the other hand, when printing on the paper 10, the head unit 16 is rotated downward in accordance with the transport state of the paper 10 by driving the head motor 24 to rotate forward (see FIG. 5). This point will be described in detail later.

As shown in FIGS. 4 and 5, the head unit 16 has a ribbon guide member 28 that protrudes downward from the thermal head 15 along a rear edge that faces the thermal head 15. Is provided. The ribbon guide member 28 supports a cylindrical ribbon guide 28A formed to have substantially the same length as the thermal head 15 and both ends of the ribbon guide 28A, and is attached to the head unit 16 at the rear edge of the thermal head 15. And an attachment member 28B for fixing the ribbon guide member 28.
Therefore, as described above, when the head unit 16 is rotated based on the driving of the head motor 24, the ribbon guide member 28 is moved accordingly. That is, when the head unit 16 is rotated downward during printing, the ribbon guide member 28 is also inserted into the opening 46 of the ribbon cassette 8 (see FIG. 5). At this time, an ink ribbon 45 described later is pushed downward by the lower surface of the ribbon guide 28A.
Further, the upper side of the thermal head 15 is fixed to the lower surface of the front side portion of the top plate 33 in a side view crank shape that is laid across the side walls 31 of the head unit 16. The thermal head 15 is configured to be pressed against the platen roller 37 with a predetermined pressing force by a head spring 35 (see FIG. 6) during printing.

Here, the ribbon cassette 8 inserted into the ribbon cassette hole 6 will be described in detail with reference to the drawings.
As shown in FIGS. 1 and 7, the ribbon cassette 8 includes a substantially cylindrical ribbon storage portion 41, a substantially cylindrical winding storage portion 42 provided opposite to the ribbon storage portion 41, and a ribbon storage portion. 41, and a pair of left and right connecting portions 43 and 44 that connect the take-up storage portion 42, and is formed into a substantially rectangular shape. In the center of the ribbon cassette 8, a running path for the ink ribbon 45 having substantially the same width as the thermal head 15 is formed, and an opening 46 into which the long thermal head 15 and the ribbon guide member 28 are inserted from above. Is formed.
A ribbon spool 48 wound so that the printing surface of the ink ribbon 45 is on the outer side is rotatably stored in the ribbon storage portion 41, and the ink ribbon opened at the lower end edge on the opening 46 side. From the delivery port 41A, the ink ribbon 45 can be pulled out in the direction of the travel path and the take-up storage unit 42.
On the other hand, in the winding storage section 42, an ink ribbon inlet 42A through which the ink ribbon 45 passing through the travel path from the ribbon storage section 41 is drawn at the time of printing is opened at the lower end edge on the opening 46 side. A ribbon take-up spool 49 around which the ink ribbon 45 is taken up is rotatably accommodated in the take-up and storage unit 42. Since the leading end of the ink ribbon 45 drawn from the ink ribbon drawing port 42A is fixed to the outer peripheral surface of the ribbon take-up spool 49, it is drawn from the ribbon storage portion 41 and drawn from the ink ribbon drawing port 42A. The ink ribbon 45 is wound around a ribbon take-up spool 49 and stored.

Here, the ink ribbon drawing opening 42A of the take-up storage portion 42 is formed with a cutout portion 42C that is cut out in a substantially square shape at the center in the width direction of the side wall portion on the opening 46 side. In addition, an aluminum tape 42D as a reflecting member is attached to the back side wall portion facing the notch portion 42C of the ink ribbon drawing opening 42A.
A ribbon feed motor 65 constituted by a stepping motor or the like is disposed on the side wall 4, and the ribbon feed motor 65 powers the ribbon spool 48 and the ribbon take-up spool 49 via the third gear train 53. Can act. That is, by driving the ribbon feed motor 65, the ribbon spool 48 and the ribbon take-up spool 49 can be driven to rotate via the third gear train 53, and the ink ribbon 45 can be transported.

  In addition, the ribbon cassette 8 is fitted into the ribbon cassette hole 6 opened in the side wall 3, so that the connecting portions 43 and 44 are disposed in proximity to the platen roller 37. At this time, the ink ribbon delivery port 41A of the ribbon storage unit 41, that is, the end edge of the opening 46 on the ribbon storage unit 41 side is positioned below the upper edge of the platen roller 37 in the vertical direction. In FIG. 4, it is disposed in the main body housing 2 downwardly to the right. Therefore, as shown in FIG. 4, the ink ribbon 45 in the opening 46 of the ribbon cassette 8 mounted in the main body housing 2 is substantially parallel to a plane connecting the thermal head 15 and the lower end of the ribbon guide member 28. become.

Next, a schematic configuration of the ink ribbon 45 housed in the ribbon cassette 8 described above will be described with reference to FIG.
As shown in FIG. 8, the ink ribbon 45 is repeatedly formed in a predetermined order on the long transparent base film 71 based on the transport direction during printing of the ink used for color printing on one sheet 10. Has been placed.
More specifically, the base film 71 is provided with three primary color inks for use in printing an image or the like in full color. That is, in order of conveyance during printing, a color primary color ink Y that colors “yellow”, a color primary color ink M that colors “magenta”, and a color primary color ink C that colors “cyan” are arranged.
Further, behind the color primary color inks Y, M, and C, an overcoat ink OP that is colorless and transparent and that protects a printing surface of an image or the like printed with the color primary color inks Y, M, and C is disposed. The overcoat ink OP contains a predetermined amount of an ultraviolet absorber. Accordingly, by covering the printing surface of the color primary color inks Y, M, and C with the overcoat ink OP, the ultraviolet ray contained in the natural light can be absorbed by the ultraviolet ray absorbent. As a result, it is possible to prevent image degradation (for example, color change) caused by ultraviolet rays contained in natural light.

  Then, a predetermined gap is provided in the vicinity of the end edge portion in the transport direction during printing of the color primary color ink Y, the color primary color ink M, the color primary color ink C, and the overcoat ink OP. The positioning mark 72 is 2 to 3 mm. Further, a print end position detection mark 81 is provided between the rear end side edge portion in the transport direction of the overcoat ink OP and the positioning mark 72 positioned on the front end side of the color primary color ink Y. It is arranged with a gap.

Thus, as described later, when the positioning mark 72 passes the front side of the aluminum tape 42D, the passage can be detected by the reflection type photosensor 36, so that each color primary color ink Y, M, C is detected. And cueing of the overcoat ink OP can be performed.
Further, when the print end position detection mark 81 passes the front side of the aluminum tape 42D, the passage can be detected by the reflective photosensor 36. As a result, the ink ribbon 45 for one sheet 10, that is, one set of ink composed of the color primary color ink Y, the color primary color ink M, the color primary color ink C, and the overcoat ink OP shown in FIG. Can be detected.

Here, the schematic configuration of the printing apparatus 1 will be described again in detail. As shown in FIG. 4, the main body housing 2 is rotated above the front end of the paper tray 11 while pressing the uppermost portion of the paper 10 stored in the paper tray 11, so that the paper 10 is fed one by one. A paper feed roller 55 for conveyance is provided. On the downstream side in the transport direction of the paper feed roller 55, a paper feed roller 56 that transports the paper 10 to a position near the platen roller 37 to a printing start position, and a pinch roller 57 that is pressed against the paper feed roller 56 and is rotatably provided. And are provided. A leading edge detection switch 58 that detects the leading edge of the sheet 10 supplied by the sheet feeding roller 55 is provided in the vicinity of the upstream side in the transport direction of the sheet feeding roller 56.
Therefore, in the printing apparatus 1 according to the present embodiment, when printing on the paper 10, first of all the paper 10 stored in the paper tray 11 by the paper feed roller 55, one sheet positioned on the uppermost surface. The paper 10 is conveyed to the paper feed roller 56 and the pinch roller 57. At this time, the leading end of the sheet 10 conveyed by the sheet feeding roller 55 is detected by the leading end detection switch 58, and the rotation of the sheet feeding roller 56 is started based on the detection signal of the leading end detection switch 58. Thus, the paper 10 fed by the paper feed roller 55 is conveyed to a printing mechanism such as the platen roller 37 and the thermal head 15 based on the rotation of the paper feed roller 56 and the pinch roller 57.

  A guide piece 59 for guiding the printed paper in the discharge direction is provided above the paper feed roller 55. Further, on the oblique upper side of the paper feed roller 55 in the discharge direction, there are a discharge roller 61 that conveys the paper 10 that has been conveyed along the guide piece 59, and a pinch roller 62 that is pressed against the discharge roller 61 and can rotate. Is provided.

  A platen roller 37 is disposed at a position facing the thermal head 15 on the downstream side in the transport direction of the paper feed roller 56. The platen roller 37 has a cylindrical core material whose peripheral surface is covered with rubber, and is arranged to be rotatable based on the driving of the paper feed roller 56. In this respect, since the platen roller 37 can rotate forward and backward, the sheet 10 conveyed by the sheet feed roller 56 and the pinch roller 57 can be conveyed to the printing start position by rotating the platen roller 37 in a predetermined direction. . Further, when printing on the paper 10 is performed, the paper 10 is pressed against the thermal head 15 by rotating in a direction opposite to the predetermined direction, and the paper discharge direction (in FIG. (Left direction).

A sheet guide member 60 that guides the sheet 10 that has passed through the upper surface of the platen roller 37 is disposed on the downstream side in the transport direction of the platen roller 37. The paper guide member 60 is longer than the width of the paper 10, that is, the width of the ink ribbon 45 and the ribbon guide member 28, and a paper guide 60 </ b> A formed in a cylindrical shape and a fixing member to which both ends of the paper guide 60 </ b> A are fixed. 60B and a support member 60C that supports the fixing member 60B so as to be slidable in the vertical direction.
A spring member 60D that urges the fixing member 60B upward is disposed below the fixing member 60B inside the support member 60C.
Therefore, as shown in FIG. 4, in a state where the head unit 16 is not in contact with the paper guide member 60, the paper guide 60 </ b> A is positioned above the conveyance path through which the paper 10 is conveyed. On the other hand, when the head unit 16 moves downward, the paper guide member 60 is pushed down as the head unit 16 moves. At this time, the paper guide 60A pushes the paper 10 downward (see FIG. 5). This point will be described in detail later.

Next, a control system of the printing apparatus 1 configured as described above will be described with reference to FIG.
As shown in FIG. 9, the control system of the printing apparatus 1 is configured with a control circuit unit 110 as a core. The control circuit unit 110 includes a CPU 111, a ROM 112, a CGROM 113, a RAM 114, and an input / output circuit (I / O) 115, which are connected to each other via a bus line 116.

Here, the ROM 112 stores various programs, such as a program for conveying a sheet 10 (to be described later) to a printing start position and controlling the head motor 24 to rotate and controlling the head unit 16 to rotate up and down. Various programs necessary for controlling the printing apparatus 1 such as a print control program are stored.
The CPU 111 performs various calculations based on various programs stored in the ROM 112.

Further, dot pattern data corresponding to each character is stored in the CGROM 113, and the dot pattern data is read from the CGROM 113 as necessary, and is transferred onto the paper 10 via the thermal head 15 based on the dot pattern data. A dot pattern is printed.
The RAM 114 temporarily stores various calculation results calculated by the CPU 111, and is provided with various memory areas such as a text memory, an image buffer, and a print buffer.

The input / output circuit (I / 0) 115 includes a host PC 117 as an external control unit, a head drive circuit 119 that drives the thermal head 15, and a motor drive circuit that drives a paper feed motor 51 that carries the paper 10 and the like. 120, a motor drive circuit 121 that drives a head motor 24 that performs pressure bonding and release of the thermal head 15 by rotating the head unit 16 in the vertical direction, and a motor that drives a ribbon feed motor 65 that reciprocates the ink ribbon 45 A drive circuit 122 is connected.
Further, the input / output circuit (I / 0) 115 includes a leading end detection switch 58 for detecting the leading end portion of the paper 10 fed by the paper feeding roller 55, each positioning mark 72 for the ink ribbon 45, and a print end position. A reflection type photo sensor 36 that detects the detection mark 81, a ribbon cassette detection sensor 38 that detects whether the ribbon cassette 8 is mounted, and the like are connected.

Next, in the printing apparatus 1 according to the present embodiment, the movement of the sheet 10 and the operation of each mechanism when printing on the sheet 10 will be described in detail with reference to the drawings.
First, when a print start signal is received from the host PC 117 connected to the printing apparatus 1, the CPU 111 rotates the paper feed motor 51 in a predetermined direction, thereby supplying the paper feed roller 55 and the paper feed roller 55 via the second gear train 52. The paper feed roller 56 is driven to rotate. As a result, among the sheets 10 stacked on the sheet tray 11, the uppermost sheet 10 is fed to the printing apparatus 1.
At this point, the head unit 16 is positioned above, and the thermal head 15 is not in pressure contact with the platen roller 37 (see FIG. 4).

The paper 10 fed by driving the paper feed roller 55 is first transported to a position where the rear end of the paper 10 is pinched by the paper feed roller 56 and the pinch roller 57 (hereinafter referred to as a print start position).
Here, after the paper 10 is fed by the paper feed roller 55, it is conveyed above the leading edge detection switch 58. At this time, when the leading edge of the paper 10 is detected by the leading edge detection switch 58, the CPU 111 starts to rotate the paper feed roller 56. At this time, the conveyance of the sheet 10 by the sheet feeding roller 55 is continued. Therefore, when the sheet 10 is sandwiched between the sheet feeding roller 56 and the pinch roller 57, the sheet feeding motor 51, the sheet feeding roller 56, and the pinch roller 57 Thus, the platen roller 37 is conveyed between the upper surface and the thermal head 15 lower surface.
Further, since the head unit 16 is located above, there is a sufficient space between the platen roller 37 and the thermal head 15 and does not hinder the conveyance of the paper 10 to the printing start position.

The paper 10 that has passed between the thermal head 15 and the platen roller 37 is conveyed to the printing start position. At this time, since the paper guide member 60 is positioned above, the paper 10 passes under the paper guide 60A and between the fixed members 60B.
When the print start position is reached, the CPU 111 stops driving the paper feed motor 51 and stops the conveyance of the paper 10.
That is, as shown in FIG. 4, when the paper 10 is conveyed to the printing start position, the rear end of the paper 10 is sandwiched between the paper feed roller 56 and the pinch roller 57, and further below the paper guide 60A. Thus, the sheet 10 is positioned between the fixing members 60B.

After transporting the paper 10 to the print start position, the CPU 111 drives the head motor 24 to move the head unit 16 from above to below.
As shown in FIG. 6, the head motor 24 (see FIG. 1) is rotationally driven in the forward direction for a predetermined time (predetermined number of steps), and the cam gear 21A is rotated about the rotation angle via the first gear train 25 (see FIG. 1). When the cam members 21 and 22 are slid on the head unit 16 by rotating clockwise by 55 degrees, the head unit 16 is rotated downward by a predetermined angle. As a result, the thermal head 15 is lowered to the vicinity of the platen roller 37, and the reflective photosensor 36 provided on the front surface portion of the head unit 16 is provided with an aluminum tape 42 </ b> D provided in the winding storage portion 42 of the ribbon cassette 8. Opposite to.
Therefore, when the head motor 24 is driven and the head unit 16 is rotated to this position and stopped, the ribbon feeding motor 65 is driven to convey the ink ribbon 45 at a constant speed, thereby the reflection type. A positioning mark 72 and a print end position detection mark 81 corresponding to each ink (color primary color ink Y, color primary color ink M, color primary color ink C, overcoat ink OP) can be detected via the photosensor 36. It becomes.

  In the state of FIG. 6, after the positioning mark 72 is detected by the reflective photosensor 36 and the head of the ink is set, the CPU 111 moves the head unit 16 further downward. As a result, the thermal head 15 and the ribbon guide member 28 disposed at the rear edge of the thermal head 15 are inserted into the opening 46 of the ribbon cassette 8, and the thermal head 15 and the ribbon guide member 28 are ink ribbons. Press 45 down. At this time, the paper 10 is held together with the ink ribbon 45 by the thermal head 15 and the platen roller 37.

Further, as the head unit 16 moves downward, the ribbon guide member 28 also moves downward, so that the ribbon guide 28A pushes down the ink ribbon 45, the attachment member 28B contacts the paper guide member 60, and pushes down the paper guide 60A ( (See FIG. 5). Accordingly, the sheet 10 located below the sheet guide 60A and between the fixing members 60B is also pushed down by the lower surface of the sheet guide 60A.
That is, as shown in FIG. 5, there is no overlap between the conveyance path from the ribbon spool 48 to the thermal head 15 and the conveyance path of the paper 10, and the paper 10 and the ink ribbon 45 are the thermal head 15 and the platen roller 37. It abuts only at the portion sandwiched between.
There is no portion that contacts the upstream side in the transport direction of the paper 10, and the paper 10 does not press the ink ribbon 45 on the upstream side in the transport direction, so that the back tension of the ribbon spool 48 is effectively applied to the ink ribbon 45. be able to. As a result, even if the base film 71 is stretched due to the influence of heating by the thermal head 15, the stretch of the base film 71 can be absorbed, and the diameter of the ribbon spool 48 and the thermal head 15 can be absorbed. On the road, the ink ribbon 45 is not loosened and wrinkles are not generated.

Thus, after moving the head unit 16 downward, the ribbon feed motor 65 is driven to transport the ink ribbon 45 and the paper feed motor 51 is driven to transport the paper 10 in the discharge direction. At this time, by controlling the heat generation mode of the thermal head 15 based on the print data corresponding to each ink stored in the RAM 114, the ink (color primary color inks Y, M, C, etc.) arranged on the ink ribbon 45 is controlled. The overcoat ink OP) can be thermally transferred.
As described above, the elongation generated in the ink ribbon 45 by being heated by the thermal head 15 is absorbed by the back tension of the ribbon spool 48, so that when the thermal head 15 and the platen roller 37 are pressed, " That is, when the ink is thermally transferred from the ink ribbon 45 to the paper 10, there is no portion that causes transfer failure, and it is possible to always provide a high-quality printed matter.
The paper 10 fed from the paper tray 11 is first transported to the printing end position while being printed with the color primary color ink Y. When the paper 10 is conveyed to the printing end position, printing with the color primary color ink Y is completed.

When the paper 10 is conveyed to the printing end position, the CPU 111 drives the head motor 24 and moves the head unit 16 upward.
Then, the paper 10 that has been printed with the color primary color ink Y is conveyed again to the printing start position in order to perform printing with the color primary color ink M. Since this point is the same as that of the color primary color ink Y described above, detailed description thereof is omitted. After that, when the paper 10 is positioned at the print start position, the head unit 16 is moved downward, and is conveyed to the print end position while performing printing with the color primary color ink M. Also in this case, since only the print data and ink used are different from those in the case of the color primary color ink Y described above, and the operation of each mechanism is the same, detailed description thereof will be omitted.
When printing with the color primary color ink M is completed, the color primary color ink C and the overcoat ink OP are subsequently printed on the paper 10 in this order, which is the same as in the case of printing with the color primary color ink Y. In these cases, detailed description is omitted.
When the paper 10 that has been printed with the overcoat ink OP is conveyed to the printing end position, the paper 10 is discharged outside the printing apparatus 1 by the discharge roller 61 and the pinch roller 62.

As described above in detail, in the printing apparatus 1 according to the present embodiment, the paper guide 60A exists between the ink ribbon 45 and the paper 10 on the upstream side in the transport direction, so that the ink ribbon 45 and the paper 10 come into contact with each other. There is no. That is, since the paper 10 does not press the ink ribbon 45, the back tension of the ribbon spool 48 can be effectively applied to the ink ribbon 45. As a result, the elongation of the ink ribbon 45 generated by heating the ink ribbon 45 with the thermal head 15 at the time of printing can be reliably absorbed by the back tension of the ribbon spool 48, and therefore, between the ribbon spool 48 and the thermal head 15. It is possible to prevent the ink ribbon 45 from being loosened and prevent the ink ribbon 45 from being wrinkled.
Furthermore, since the paper 10 is guided while being separated from the ink ribbon 45 by the paper guide member 60, the action of the back tension on the ink ribbon 45 does not vary regardless of the strength of the paper 10. Absent. That is, no matter what paper 10 is used, wrinkles can be prevented from occurring on the ink ribbon 45, and a beautiful printed matter with no untransferred portion can be provided.

In the printing apparatus 1 according to the present embodiment, the paper guide member 60 also moves downward in conjunction with the downward movement of the head unit 16 during printing, and moves to separate the paper 10 from the ink ribbon 45. Let Thereby, the back tension of the ribbon spool 48 can be effectively applied to the ink ribbon 45 at the time of printing in which the thermal head 15 is heated and the ink ribbon 45 is stretched most.
That is, since the elongation generated in the ink ribbon 45 can be immediately absorbed by the back tension of the ribbon spool 48, the occurrence of wrinkles on the ink ribbon 45 can be reliably prevented. Thereby, the non-transferred part resulting from the wrinkles of the ink ribbon 45 does not occur on the printed paper 10, and a printed matter on which beautiful printing is performed can be stably provided.

In addition, this invention is not limited to the said Example, Of course, various improvement and deformation | transformation are possible within the range which does not deviate from the summary of this invention.
For example, in this embodiment, the ribbon guide member 28 attached to the head unit 16 moves downward and comes into contact with the paper guide member 60, so that the paper 10 is pushed down so as to be separated from the ink ribbon 45. However, the present invention is not limited to such a mode that follows the movement of the head unit 16.
In this regard, it is also possible to adopt a mode in which the sheet guide member 60 is independently controlled by another drive source. For example, a drive motor that moves the paper guide member 60 and a motor drive circuit that performs drive control of the drive motor may be provided, and the paper guide member 60 may be moved based on the drive of the drive motor.
More specifically, in this case, based on the fact that the paper 10 is conveyed to the print start position, the drive motor is driven to move the paper guide member 60 downward. Accordingly, as in the above-described embodiment, the ink ribbon 45 and the paper 10 can be prevented from coming into contact with each other on the upstream side in the transport direction during printing, so that wrinkles can be reliably prevented from occurring on the ink ribbon 45. .

  In this embodiment, the printing apparatus performs full-color printing by using an ink ribbon having a plurality of single-color inks and performing printing with each single-color ink a plurality of times. However, the present invention is not limited to this. Absent. That is, any printing apparatus that performs printing on a recording medium using an ink ribbon may be used, and may be a printing apparatus that performs monochromatic printing.

1 is a perspective view illustrating a schematic configuration of a printing apparatus and a ribbon cassette according to the present embodiment. It is a perspective view which shows the state which mounted | wore the ribbon cassette with the printing apparatus. It is a top view which shows the state which mounted | wore the ribbon cassette with the printing apparatus. In a printing apparatus, it is a sectional side view of an AA section in case a head unit is located above. In a printing apparatus, it is a sectional side view of an AA section in case a head unit is pressure-bonded to a platen roller. It is a principal part expanded sectional side view which shows a head unit part. It is a lower side perspective view which shows schematic structure of a ribbon cassette. It is a top view which shows an example of the ink ribbon accommodated in a ribbon cassette. 2 is a block diagram illustrating a control configuration of the printing apparatus. FIG.

DESCRIPTION OF SYMBOLS 1 Printing apparatus 8 Ribbon cassette 10 Paper 15 Thermal head 16 Head unit 37 Platen roller 28 Ribbon guide member 45 Ink ribbon 51 Paper feed motor 55 Paper feed roller 56 Paper feed roller 57 Pinch roller 60 Paper guide member 62 Pinch roller 65 Ribbon feed motor 71 Base Film Y, M, C Color primary color ink OP Overcoat ink

Claims (1)

A recording medium;
A thermal head in which a plurality of heating elements are arranged;
An ink ribbon coated with ink to be thermally transferred to a recording medium;
Sheet conveying means for conveying the recording medium;
Ribbon transport means capable of transporting the ink ribbon;
A platen roller against which the recording medium and the ink ribbon are pressed by the thermal head;
The upstream side in the conveying direction of the recording medium during printing, the recording medium while away from the ink ribbon, have a sheet guide member for guiding,
The thermal head is movably disposed between a pressing position for pressing the recording medium and the ink ribbon against the platen roller, and an opening position for opening the recording medium and the ink ribbon.
The printing apparatus according to claim 1, wherein the sheet guide member is moved by the movement of the thermal head and separates the recording medium from the ink ribbon based on the movement of the thermal head to the pressing position .

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