KR102077132B1 - Take-up reel operator for thermal sublimation printer - Google Patents

Abstract

The present invention relates to a ribbon take-up reel operator and, more specifically, to a ribbon take-up reel operator for rotating a take-up reel. According to the present invention, the ribbon take-up reel operator for a dye sublimation printer selectively operating a take-up reel gear connected to a winding reel by a shaft includes: a feed roller having both shafts supported on a frame, wherein a feed gear is connected to one side of the feed roller; a swing lever rotating around the shaft of the feed roller and having a swing protrusion on one side; a swing gear installed on the other side of the swing lever and engaged with the feed gear, wherein the swing gear is engaged or is not engaged with the take-up reel gear in accordance with the rotation of the swing lever; a slide plate moving forward and backward along the bottom surface of the frame; a guide bar integrated with the slide plate and guiding the swing protrusion; and a driving unit moving the slide plate forward and backward.

Description

TAKE-UP REEL OPERATOR FOR THERMAL SUBLIMATION PRINTER}

The present invention relates to a dye sublimation printer, and more particularly, to a ribbon take-up reel driving device for rotating a take-up reel.

In the dye sublimation printer, a thermal recording head (hereinafter referred to as a 'head') heats an ink ribbon coated with three colors of yellow (Y), magenta (M), and cyan (C) to produce a high-quality print medium. It is a device to print a photo.

Therefore, the ink ribbon and recording medium should be transported in close contact between the head and the platen roller to sublimate the dye of three colors, and the transfer of the ink ribbon and the forward and reverse transfer of the recording medium should be controlled according to each step. do.

However, the conventional dye sublimation printer has a very complicated configuration of a drive device for controlling ribbon transfer and forward and reverse transfer of a recording medium, and has difficulty in simultaneous control thereof.

Registered Patent No. 1507064

The present invention has been made to solve the above-described problems, an object of the present invention is to provide a ribbon take-up reel driving device of the dye sublimation printer that can organically control the driving of the take-up reel gear in accordance with the advance and fall of the slide plate In providing.

In order to solve the above technical problem, the ribbon take-up reel driving device of the dye sublimation printer selectively driving the take-up reel gear axially coupled to the take-up reel according to the present invention, both shafts are supported on the frame, and the feed gear is provided on one side. A feed roller coupled; A swing lever rotating around an axis of the feed roller and having a swing protrusion formed at one side thereof; A swing gear provided on the other side of the swing lever and constantly engaged with the feed gear, and engaged or non-engaged with the take-up reel gear according to the rotation of the swing lever; A slide plate moving along a bottom surface of the frame; A guide bar integrally formed with the slide plate and guiding the swing protrusion; And a driving part for advancing and retracting the slide plate.

In addition, the guide bar is preferably moved forward and backward with the slide plate in a state in which the swing projection is in contact with the bottom.

In addition, the bottom of the guide bar is preferably formed with an escape groove so that the swing protrusion can move upward.

In addition, the pickup plate is provided on one side wall of the slide plate, it is preferable that the guide groove is formed in the longitudinal direction on the outside of the pickup plate.

The drive unit may include a pickup motor that transmits a bidirectional driving force, and an idle gear having a rotational protrusion that transmits the driving force of the pickup motor and moves along the guide groove.

In addition, it is preferable that both of the idle gears are supported by the frame.

According to the present invention, it is possible to organically control the elevating of the pickup roller, the elevating of the platen roller, and the driving of the take-up reel gear as the slide plate moves forward and backward.

Therefore, the number of parts is greatly reduced, the structure is very simple, and the driving of the pick-up roller, platen roller and take-up reel gear can be controlled according to each step.

1 to 4 show the structure of the dye sublimation printer according to the present invention.
5 and 6 show the down and the up state of the pickup roller, respectively.
7 to 9 show the lifting structure of the platen roller.
10 and 11 show the rising and falling states of the platen roller, respectively.
12 to 14 show the operating state of the dye sublimation printer according to the present invention in order.

Hereinafter, with reference to the accompanying drawings will be described in detail the structure and operation of the dye sublimation printer according to the present invention.

1 to 4, the dye sublimation printer 1 according to the present invention includes an ink ribbon R and a recording medium between a thermal printing head 40 and a platen roller 63 that provide heat. The dye applied to the ink ribbon is sublimed in a state where P is in close contact to form a predetermined image on the recording medium.

The printer 1 includes a frame F in which a bottom surface and both side walls are bent.

An insertion groove into which a cartridge is inserted is formed in the frame. The cartridge includes an accommodating portion 10 in which recording media are stacked and received, a supply reel 11 on which an ink ribbon is wound, and an ink ribbon conveyed from the supply reel. And a take-up reel gear 14 which is axially coupled to one side of the take-up reel. Therefore, the take-up reel gear 14 is driven to transfer the ink ribbon onto the take-up reel 12.

The cartridge is provided with a locking member 13 on the side, and the fastening hole for locking the locking member is formed in the frame (F).

Further, as a driving unit for advancing and sliding the slide plate, a pickup motor and an idle gear are provided. That is, the frame is provided with a pickup motor (M) for driving in both directions, the idle gear 30 to which the rotational force of the pickup motor is provided. One side of the idle gear is provided with a rotary projection (30a) protruding from the circumferential surface.

In addition, a pickup roller 20 having a shaft 21 parallel to the shaft 31 of the idle gear is provided, and the shaft 31 of the idle gear and the shaft 21 of the pickup roller are connected at both ends. That is, the shaft 31 of the idle gear and the shaft 21 of the pickup roller are connected to one side by the pickup lever 32, the other side is connected in parallel by the connecting member 33.

The idle gear has both shafts 31 supported and fixed to the frame F, but the pickup roller has both shafts 21 connected to the frame F only by the pickup lever 32 and the connecting member 33. It is not fixed (see enlarged view in FIG. 4).

Pickup projections 32a are formed at one side of the pickup lever 32. Accordingly, the pickup lever 32 rotates along the shaft 31 of the idle gear in which the pick-up projection 32a is fixed, and the shaft 21 of the pick-up roller is the shaft of the idle gear by the lever principle. 31) swinging around.

On the other hand, the slide plate 50 is provided to slide along the bottom surface of the frame to move forward or backward, the pickup plate 52 is formed on one side wall of the slide plate 50 vertically.

The outer surface of the pickup plate 52 is formed with a guide groove 52a in which the rotary protrusion 30a is constrained and guided in the longitudinal direction, and a guide rail in which the pickup protrusion 32a is guided on the inner surface of FIG. 5. '56') is formed.

One side of the slide plate 50 is provided with a guide bar 53, the guide bar 53 and the pickup plate 52 is formed integrally on the same side of the slide plate 50, respectively, the front side and It is formed on the rear side and does not interfere with each other. In addition, when viewed in a plan view, the guide bar 53 is formed on the outside, and the pickup plate 52 is formed on the inside, and spaced at regular intervals therebetween so that they are formed in parallel.

An escape groove 54 is formed at the bottom of the guide bar 53.

In addition, the driving force of the feed motor (not shown) which is driven in both directions is transmitted is provided with a feed roller 70 for transferring the recording medium in both directions, the feed roller is supported on both frames of the feed roller, one side of the feed roller The feed gear 71 is axially coupled.

It is provided on the outside of the feed gear 71, the shaft of the feed roller 70 is mounted in the mounting hole 81 to rotate about the axis, a swinging projection 82 is formed on one side, the other side of the swing gear ( A swing lever 80 having a gear mounting portion 83 to which 72 is axially coupled is provided.

The swing gear 72 is always engaged with the feed gear 71, and may also be engaged with the take-up reel gear 14 according to the rotation of the swing lever 80. Sometimes.

The swing protrusion 82 is in contact with the bottom of the guide bar 53. When the swing protrusion 82 is positioned in the escape groove 54 of the guide bar by the advance of the guide bar, the swing lever 80 Is rotated about the axis of the feed roller 70 so that the swing gear 72 meshes with the take-up reel gear 14. When the swing gear 72 and the take-up reel gear 14 are engaged as described above, the driving force of the feed motor drives the feed roller 70 and simultaneously rotates the rotational force of the feed gear 71 through the swing gear 72. Transferring to the take-up reel gear 14, the take-up reel 12 is rotated to transfer the ink ribbon.

5 and 6, a guide rail 56 having two stages in which a pickup protrusion 32a is guided is formed on an inner surface of the pickup plate 52, and the guide rail 56 is a pickup protrusion 32a. And an upper rail 56a for placing the upper portion, a lower rail 56b for placing the pickup protrusion at a lower portion thereof, and an inclined rail 56c having an inclined surface to connect the upper rail and the lower rail.

When the pick-up plate 52 is retracted and positioned at the rear of the frame, the pick-up protrusion 32a is positioned on the upper rail 56a, and thus the pick-up roller having the shaft 21 connected to the other end of the pick-up lever 32 is located. Reference numeral 20 is in the DOWN state. As such, when the pickup roller 20 is in the down state, the pickup roller 20 may be in close contact with the upper portion of the recording medium accommodated in the accommodating part 10 to supply the recording medium forward (FIG. 5).

When the pickup plate 52 is advanced, the pickup protrusion 32a passes through the inclined rail 56c from the upper rail 56a and is positioned on the lower rail 56b. Accordingly, the pickup lever 32 rotates about the axis 31 of the idle gear, and the other end of the pickup lever 32 is raised by the lever principle. Therefore, the pickup roller 20 in which the shaft 21 is connected to the other end of the pickup lever 32 is in an up state. As such, when the pickup roller 20 is in the up state, the pickup roller 20 does not come into close contact with the upper portion of the recording medium accommodated in the accommodating part 10, and thus the recording medium cannot be supplied forward (FIG. 6).

7 to 9, the platen plate 60 is provided to rotate about an axis of the feed roller 70. That is, a hinge hole 61 through which the shaft of the feed roller 70 penetrates is formed at one side of the platen plate 60 so as to hinge the platen plate 60 to the shaft of the feed roller 70. The platen roller 63 is supported at the side.

In addition, one end is connected to the shaft of the feed roller 70, the other end is provided with a pair of supporting plates (see '73' of Figure 10) connected to the shaft of the platen roller 63. That is, the platen roller 63 is not fixedly installed on the top of the platen plate 60, but is movable to rotate about the axis of the feed roller 70 by the pair of support plates 73. Will be installed.

In addition, a pair of first springs S1 are provided at both sides of the platen plate 60, and the first springs elastically support both shafts of the platen roller 63.

Therefore, the platen roller 63 is provided above the platen plate 60, but is elastically movable in the vertical direction by the first spring S1.

During printing, the platen plate 60 is rotated to closely adhere the platen roller 63 to the lower part of the head 40 while forming a gap smaller than the thickness of the recording medium, and when the recording medium enters through the gap. The plate 60 is fixed, but to allow the platen roller 63 to move downward in correspondence with the thickness of the recording medium. At this time, in a state where the recording medium is positioned between the platen roller 63 and the head 40, the first spring S1 elastically presses the platen roller 63 in the head direction, thereby recording medium and ink ribbon. Is adhered to the head to improve the image quality.

The front end of the slide plate 50 is provided with a lifter 51 for entering the lower portion of the platen plate 60 to rotate and raise the platen plate about the axis of the feed roller 70. An inclined surface 51a is formed at the tip of the lifter 51 to facilitate entry into the lower portion of the platen plate 60. In addition, the bottom surface of the platen plate 60 is formed with a protrusion 64 in contact with the lifter 51, in this embodiment the protrusion 64 is formed to be round. In addition, the protrusion may be formed to be inclined instead of round.

In addition, a second spring S2 having one end connected to the platen plate 60 is provided. The second spring is composed of a torsion spring in this embodiment, and the other end is located in the frame.

The platen plate 60 is always subjected to an elastic pressure downward by the second spring (S2). Therefore, when the lifter 51 enters the lower portion of the platen plate 60, the platen plate rises about the axis of the feed roller 70, and the second spring S2 is elastically deformed. Therefore, when the lifter 51 retreats, the platen plate 60 rotates about the axis of the feed roller 70 by the elastic restoring force of the second spring, and the platen roller 63 descends.

10 and 11, the operation of raising and lowering the platen roller 63 under the head 40 will be described.

10 illustrates a state in which the lifter 51 enters the lower portion of the platen plate 60. As shown in the drawing, when the lifter 51 enters the lower portion of the platen plate 60 by advancing the slide plate 50, the platen plate rotates about the axis of the feed roller 70 and the platen roller 63. Will rise. At this time, the gap between the heat generating element 41 formed in the head 40 is formed close to the gap, the gap is smaller than the thickness of the recording medium.

On the other hand, the ink ribbon is mounted on the lower part of the head, and in this state, when the recording medium enters between the head 40 and the platen roller 63, the platen roller 63 moves to the first spring S1. Elastically moves downward. Accordingly, the image is formed in the state in which the ink ribbon R and the recording medium P are elastically in close contact with the heat generating element 41 by the elastic force of the first spring.

Next, referring to FIG. 11, when the lifter 51 is retracted from the lower side of the platen play 60 due to the retraction of the slide plate 50, the platen plate (by the second spring S2). One side of the 60 is rotated about the axis of the feed roller 70 so that the platen roller 63 is lowered. Therefore, the gap formed between the platen roller 63 and the head 40 is opened.

Hereinafter, the operating state and printing method of the dye sublimation printer according to the present invention.

The printing method of the dye sublimation printer according to the present invention includes a pickup step of forwarding the recording medium by rotating the pickup roller forward while the pickup roller is in close contact with the upper portion of the recording medium, and rotating the feed roller backward to reverse the recording medium. And a rewinding step of forwarding the feed roller, and a printing step of forwardly rotating the feed roller to transfer the recording medium and simultaneously feeding the ribbon to form an image.

First, the pick-up step will be described with reference to FIG. As shown, when the pickup motor (M) rotates in the reverse direction, the driving force of the pickup motor is transmitted to the idle gear (30) via the reduction gear (G). The rotating protrusion 30a formed at one side of the idle gear 30 is constrained to the guide groove 52a in the longitudinal direction, and the guide gear 52a of the idle gear rotates while the idle gear and the rotating protrusion 30a rotate. The rear side of the shaft 31 is moved. As a result, the pickup plate 52 also retreats to the rear side.

On the other hand, when the pickup plate 52 retreats to the rear side, the pickup projection 32a of the pickup lever is located on the upper rail 56a of the guide rail 56 formed inside the pickup plate 52 (see FIG. 5). In this operation, the pickup lever 32 rotates about the shaft 31 of the idle gear to lower the pickup roller 20. The lowered pickup roller 20 is in close contact with the upper portion of the recording medium stacked on the accommodating part 10, and the driving force of the pickup motor is transmitted through the idle gear 30 and the pickup gear 22 to lower the pickup roller. 20 is to feed the recording medium forward.

In addition, since the guide bar 53 also moves backward with the pickup plate 52, the swing protrusion 82 is located at the bottom of the guide bar 53. Therefore, the swing lever 80 is rotated counterclockwise around the axis of the feed roller 70 so that the swing gear 72 and the take-up reel gear 14 are disengaged.

At this time, the slide plate 50 formed integrally with the pickup plate 52 is also reversed. Therefore, the lifter 51 retreats from the bottom of the platen plate 60, so the platen roller 63 rotates about the axis of the feed roller 70 and descends (see FIG. 11 (a)).

Therefore, when the pickup roller 20 feeds the recording medium forward in the pick-up step, the platen roller 63 is lowered so that the recording medium is not in close contact with the head 40 so that printing is not performed, and the take-up reel gear Since 14 is not driven, only the recording medium is fed forward while the ink ribbon is not transferred.

Next, the rewinding step will be described with reference to FIG. 13. As shown in the drawing, when the pickup motor is rotated in the forward direction, the rotary protrusion 30a is located at the front side of the shaft 31 of the idle gear, and the guide groove 52a is also moved to the front side. That is, the counterclockwise rotation of the rotary protrusion 30a advances the pickup plate 52. In particular, it can be seen that the rotary projection (30a) is located in the lower portion of the guide groove (52a). As such, the pickup protrusion 32a is positioned on the lower rail 56b of the guide rail due to the advancement of the pickup plate 52. Accordingly, the pickup lever 32 rotates about the shaft 31 of the idle gear to raise the pickup roller 20 (see FIG. 6).

In addition, the slide plate 50 integrally formed with the pickup plate 52 is advanced, but only until the lifter 51 enters the lower portion of the platen plate 60. Therefore, the platen roller 63 maintains the lowered state under the head 40 (see Fig. 11 (a)).

In addition, the guide bar 53 is also advanced along with the pickup plate 52, but the swing projection 82 is in the state before being escaped to the escape groove (54). Therefore, since the swing lever 80 does not rotate about the axis of the feed roller 70, the swing gear 72 and the take-up reel gear 14 are still not engaged.

Therefore, when the feed roller 70 transfers the recording medium to the rear (printing start point) by the rewinding step, the pickup roller 20 rises and the platen roller 63 also keeps falling, so that the recording medium There is no interference when transported backwards.

In addition, since the swing gear 72 and the take-up reel gear 14 are not engaged and the take-up reel gear 14 is not driven, only the recording medium is transferred to the rear, that is, the print start point, while the ink ribbon is not transferred. .

The front end of the recording medium conveyed to the printing start point is engaged with the feed roller 70.

Finally, the printing step will be described with reference to FIG. 14. As shown, the pick-up motor is driven to further rotate the idle gear 30 counterclockwise so that the rotary projection 30a is positioned above the guide groove 52a. Therefore, the rotation of the rotary protrusion 30a further advances the pickup plate 60. In this way, even if the pickup plate 52 is further charged, the pickup protrusion 32a is still positioned at the lower rail 56b. Therefore, the rise of the pickup roller 20 is maintained (see FIG. 6).

As the pickup plate 52 is further advanced as described above, the slide plate 50 integrally formed therewith is further advanced, so that the lifter 51 enters the lower portion of the platen plate 60 to feed the roller 70. The platen roller 63 is raised about its axis.

At the same time, as the slide plate 50 moves forward, the swing protrusion 82 is positioned in the escape groove 54 formed at the bottom of the guide bar 53. In this state, when the driving force of the feed motor is transmitted to the feed roller 70 and rotates, the swing lever 80 rotates about the axis of the feed roller 70 by the torque of the feed gear 72. As such, the swing lever 80 may be rotated only when the swing protrusion 82 is positioned in the escape groove 54 of the guide bar. In this operation, the swing gear 72 is finally engaged with the take-up reel gear 14.

Therefore, as the feed roller 70 rotates by driving the feed motor, the recording medium is transferred between the head 40 and the platen roller 63, and together with the take-up reel gear 14, the ink ribbon is wound up. It is conveyed while winding around (12).

In other words, the platen roller 63 is raised to bring the ink ribbon R and the recording medium P into close contact with the heating element 41 formed in the lower portion of the head 40. In this state, the recording medium and the ink ribbon The dye is sublimed in the ink ribbon while being transported at a constant speed to form an image on the recording medium.

Therefore, in the printing step, the pickup roller 20 and the platen roller 63 are raised, and the swing gear 72 and the take-up reel gear 14 are engaged with each other. When the feed roller 70 is rotated in this state, the recording medium and the ink ribbon are transferred forward.

In addition, the dye sublimation printer must sublimate each dye onto the recording medium while transferring ink ribbons coated with three colors of dye such as cyan, magenta, and yellow.

Therefore, the rewinding step and the printing step are repeated three times to form a single image.

On the other hand, at one side of the housing portion that is accommodated in the frame or recording medium is provided with sensors (e1 ~ e3) for detecting the position of the slide plate. The sensor can be applied to a variety of known means such as a light emitting sensor or a pressure contact sensor. In addition, the slide plate 50 is provided with a detection unit 55 for detecting the position by the sensor.

1: dye sublimation printer
10: storage part 11: supply reel
12: Winding reel 13: Locking member
14: take-up reel gear 20: pickup roller
30: idle gear 30a: rotating projection
32: pickup lever 32a: pickup projection
33: connecting member 40: head
41: heating element 50: slide plate
51: lifter 52: pickup plate
52a: guide groove 53: guide bar
54: escape groove 55: detector
56: guide rail 60: platen plate
61: hinge hole 63: platen roller
64: projection 70: feed roller
71: feed gear 72: swing gear
80: swing lever 81: mounting hole
82: swing protrusion 83: gear mounting portion

Claims (6)

In the ribbon take-up reel driving device of the dye sublimation printer for selectively driving the take-up reel gear axially coupled to the take-up reel,
A feed roller having both shafts supported by the frame and having a feed gear coupled to one side thereof;
A swing lever rotating around an axis of the feed roller and having a swing protrusion formed at one side thereof;
A swing gear provided at the other side of the swing lever and constantly engaged with the feed gear, and engaged or non-engaged with the take-up reel gear according to the rotation of the swing lever;
A slide plate moving along a bottom surface of the frame;
A guide bar integrally formed with the slide plate and guiding the swing protrusion; And
And a driving part for advancing and retracting the slide plate.
Pickup plate is provided on one side wall of the slide plate, the ribbon take-up reel driving device of the dye sublimation printer, characterized in that the guide groove is formed in the longitudinal direction on the outside of the pickup plate.

The method of claim 1,
The guide bar is a ribbon take-up reel driving device of the dye sublimation printer, characterized in that the swing protrusion is advanced with the slide plate in contact with the bottom.
The method of claim 2,
A ribbon take-up reel driving device of the dye sublimation printer, characterized in that the bottom of the guide bar is formed with an escape groove so that the swing projection can move upward.
delete The method of claim 1,
The drive unit,
Pick-up motor that delivers bidirectional driving force,
The driving force of the pickup motor is transmitted, the ribbon take-up reel driving device of the dye sublimation printer, characterized in that it comprises an idle gear provided with a rotating projection to move along the guide groove.
The method of claim 5,
The idle gear is a ribbon take-up reel driving device of the dye sublimation printer, characterized in that both shafts are supported on the frame.

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