KR20210024898A - Take-up reel operator for thermal sublimation printer - Google Patents

Abstract

The present invention relates to a dye sublimation printer and, more specifically, to a ribbon take-up reel driving device for rotating a take-up reel. According to the present invention, the ribbon take-up reel driving device for a dye sublimation printer selectively drives a take-up reel gear axially coupled to a winding reel and comprises: a feed roller allowing a feed gear to be coupled to one side thereof, wherein both shafts thereof are supported on a frame; a swing lever rotating by the thrust of the feed roller, and having a leg coming in contact with the frame when rotating forwards; a swing gear provided on the other side of the swing lever to be always engaged with the feed gear and to be engaged or not engaged with the take-up reel gear depending on rotation of the swing lever; a link member allowing both shafts of a platen roller and the feed roller to penetrate both sides thereof; and a bracket with which one sidewall of the swing lever comes in contact when the swing lever rotates backwards.

Description

Dye-sublimation printer's ribbon take-up reel drive {TAKE-UP REEL OPERATOR FOR THERMAL SUBLIMATION PRINTER}

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

In a dye-sublimation printer, a thermal recording head (hereinafter referred to as'head') heats ink ribbons coated with three colors of yellow (Y), magenta (M), and cyan (C) to provide high-quality images on the recording medium. It is a device that allows you to print photos.

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

However, in the conventional dye-sublimation printer, the configuration of a driving device for controlling the transfer of the ribbon and the forward/reverse transfer of the recording medium is very complex, and it is difficult to control them simultaneously.

Registered Patent No. 1507064

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to provide a ribbon take-up reel driving device for a dye-sublimation printer capable of organically controlling the drive of the take-up reel gear.

In order to solve the above technical problem, the ribbon take-up reel driving device according to the present invention is a ribbon take-up reel driving device of a dye-sublimation printer that selectively drives a take-up reel gear shaft-coupled to a winding reel. A feed roller supported on and coupled to a feed gear on one side; A swing lever connected to the axis of the feed roller to rotate by the thrust of the feed roller, and to form a leg in contact with the frame during forward rotation; A swing gear provided on the other side of the swing lever, always engaged with the feed gear, and engaged or non-engaged with the take-up reel gear according to the rotation of the swing lever; Link members through which the axes of the feed roller and the platen roller pass through, respectively; And a bracket in which one side wall of the swing lever abuts when the swing lever rotates in reverse.

In addition, it is preferable that the link member has a first protruding bar that presses the leg downward.

In addition, it is preferable that the link member has a second protruding bar that abuts against the other side wall of the swing lever so as to maintain a shaft-to-shaft distance between the swing gear and the take-up reel gear when the swing gear rotates forward.

According to the present invention, it is possible to organically control the elevation of the platen roller and the drive of the take-up reel gear.

1 to 7 show the structure of a dye-sublimation printer according to the present invention.
8 and 9 show the descending and rising states of the pickup roller, respectively.
10 to 13 are sequentially showing the operating state of the dye-sublimation printer according to the present invention.

Hereinafter, the structure and operation of the take-up reel driving apparatus of the dye-sublimation printer 100 according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 7, the dye-sublimation printer 100 according to the present invention includes an ink ribbon R and a recording medium between a thermal printing head 140 and a platen roller 163 providing heat. In the state where (P) is in close contact, the dye applied to the ink ribbon is sublimated to form a predetermined image on the recording medium.

The printer 100 includes a frame F in which a bottom surface and both side walls are bent.

The frame (F) has an insertion groove into which the cartridge is inserted, wherein the cartridge includes a storage unit in which a recording medium is stacked and accommodated, a supply reel 111 on which an ink ribbon is wound, and an ink ribbon transferred from the supply reel. And a take-up reel gear 114 that is axially coupled to one side of the take-up reel 112 and the take-up reel to wind it up. Accordingly, the take-up reel gear 114 is driven to transfer the ink ribbon while winding the take-up reel 112.

The cartridge is provided with a locking member 113 on the side, and a fastening hole through which the locking member is fastened is formed in the frame (F).

In addition, a pickup motor and an idle gear 130 are provided. That is, the frame is provided with a pickup motor (M) driving in both directions, and an idle gear 130 through which the rotational force of the pickup motor is transmitted. A rotation protrusion ('130a' in FIG. 5) protruding inward and outward is provided on the circumferential surface of the idle gear. The rotation protrusion protrudes inward from the circumferential surface of the idle gear 130 and is coupled to the guide groove 152a of the pickup plate (see FIG. 1 ).

In addition, a pickup roller 120 having a shaft 121 parallel to the shaft 131 of the idle gear is provided, and both ends of the shaft 131 of the idle gear and the shaft 121 of the pickup roller are connected to each other. That is, the shaft 131 of the idle gear and the shaft 121 of the pickup roller have one side connected by the pickup lever 132, and the other side connected by the connecting member 133 and arranged in parallel (Figs. 2 and 2). 7).

In the idle gear, both shafts 131 are supported and fixed to the frame F, but in the pickup roller, both shafts 121 are only connected by the pickup lever 132 and the connecting member 133 to the frame F. Not fixed.

A pickup protrusion (see '132a' in FIG. 8) is formed on one side of the pickup lever 132. Therefore, the pickup lever 132 rotates along the axis 131 of the idle gear fixed according to the position of the pickup protrusion 132a, and the axis 121 of the pickup roller is rotated along the axis 131 of the idle gear according to the lever principle. 131).

Meanwhile, a slide plate 150 that slides along the bottom surface of the frame to advance or retreat is provided, and a pickup plate 152 is vertically formed on one side wall of the slide plate 150 (see FIG. 2 ).

On the outer surface of the pickup plate 152, a guide groove (152a) to which the rotation protrusion (130a) is constrained and guided is formed in a longitudinal direction, and a guide rail to which the pickup protrusion (132a) is guided (Fig. 8) '156') is formed.

In addition, there is provided a feed roller 170 for transferring the recording medium in both directions by transmitting the driving force of the feed motor M2 that is driven in both directions, the feed roller having both axes supported on the side walls of the frame, and the feed roller 170 ) On one side of the feed gear 171 is shaft-coupled.

It is provided on the outside of the feed gear 171, the shaft of the feed roller 170 is mounted in the mounting hole 181 to rotate the feed roller 170 around the axis, and a leg 184 is formed on one side, The other side is provided with a swing lever 180 on which a gear mounting portion 183 to which the swing gear 172 is axially coupled is formed. The swing lever 180 can rotate forward and backward by the thrust of the feed roller 170.

In addition, when the swing lever 180 rotates in a reverse direction (counterclockwise in FIG. 10), a bracket 176 is provided to which one side wall 185 contacts. That is, when the swing lever 180 rotates forward, the leg 184 abuts the frame F, and when the swing lever 180 rotates backward, the one side wall 185 abuts the bracket 176, so the rotation range only within that range. Is decided.

The swing gear 172 engages with the feed gear 171 at all times, and engages with the take-up reel gear 114 according to the rotation of the swing lever 180, and does not engage. Sometimes it does.

A pressure roller 179 is elastically supported under the bracket 176. That is, springs 175 are provided on both sides under the bracket 176, support brackets 174 are provided under the spring 175, and pressure rollers 176 are provided at both ends of the support bracket 174. A shaft hole (174a) is formed so that both shafts of) are fitted.

In addition, the feed roller 170 is fixed to the frame F and installed under the pressure roller 179. Therefore, when the recording medium enters the space between the feed roller 170 and the pressure roller 179, the pressure roller 179 rises, and at this time, the pressure roller 179 is fed by the spring 175. Pressing elastically in the direction of the roller 170 makes the recording medium in close contact.

In addition, the platen roller 163 is elastically supported on the upper portion of the platen plate 160.

Specifically, a hinge hole 161 is formed on one side of the platen plate 160, and the axis of the feed roller 170 passes through the hinge hole.

Therefore, the platen plate 160 can be hinged eccentrically along the axis of the feed roller 170.

When the lifter 151 enters the lower portion of the platen plate 160, the platen plate 160 rises while rotating along the axis of the feed roller 170. Conversely, when the lifter 151 retreats, the platen plate 160 rotates and returns to its original state.

Springs S1 are provided on both sides of the platen plate 160, and both axes of the platen roller 160 are supported by the springs S1.

In other words, when the lifter 151 enters the lower portion of the platen plate 160, the platen roller 163 rises to bring the recording medium into close contact with the head 140.

In particular, the present invention is provided with a link member 190 connecting both axes of the feed roller 170 and the platen roller 163. That is, a through hole 191 through which the axis of the feed roller 170 passes and a through hole 192 through which the axis of the platen roller 163 passes are formed in the link member 190.

The link member 190 is provided with a pair of protruding bars 193a and 193b, and the first protruding bar 193a formed at the lower portion serves to press the leg 184 of the swing lever 180 downward. In addition, the second protruding bar 183b formed on the upper part contacts the other side wall of the swing lever to maintain the shaft distance between the swing gear 171 and the take-up reel gear 114. That is, the swing lever 180 swings by the thrust of the feed roller 170, and when the swing lever 180 rotates in a forward direction (clockwise in FIG. 10) by the feed roller 170, a swing gear 171 is engaged with the take-up reel gear 114. In particular, during printing, the feed roller 170 is continuously rotated for transport of the recording medium, and the swing gear by the thrust of the feed roller 170 (171) is strongly adhered to the take-up reel gear (114). In this way, when the swing gear 171 is in close contact with the take-up reel gear 114 more than necessary, rotation of the take-up reel gear 114 is not smooth. As a result, the ink ribbon cannot be accurately wound around the take-up reel 112.

In this embodiment, when the swing gear 171 and the take-up reel gear 114 are engaged, the second protruding bar (183b) is provided to prevent a stronger close contact than necessary, that is, to maintain the shaft distance between the two gears. It abuts against the other side wall of the swing lever and serves as a stopper. Therefore, in this embodiment, when the swing gear 171 and the take-up reel gear 114 are engaged, the shaft-to-shaft distance is accurately maintained so that the take-up reel gear 114 can rotate smoothly.

8 and 9 show the operating state of the pickup roller.

Referring to FIG. 8, on the inner surface of the pickup plate 152, a two-stage guide rail 156 through which the pickup protrusion 132a is guided is formed, and the guide rail 156 includes the pickup protrusion 132a on the upper side. It includes an upper rail 156a to be positioned, a lower rail 156b to place the pickup protrusion 132a at the bottom, and an inclined rail 156c having an inclined surface to connect the upper rail and the lower rail.

When the pickup plate 152 is retracted and located at the rear of the frame (F), the pickup protrusion (132a) is located on the upper rail (156a), and accordingly, the shaft 121 at the other end of the pickup lever 132 The connected pickup roller 120 is in a down state. As described above, when the pickup roller 120 is in a down state, it is in close contact with the upper portion of the recording medium accommodated in the recording medium storage unit, so that the recording medium can be supplied to the front.

When the pickup plate 152 advances, the pickup protrusion 132a passes through the inclined rail 156c from the upper rail 156a and is positioned on the lower rail 156b as shown in FIG. 9. Accordingly, the pickup lever 132 rotates around the axis of the idle gear (see '131' in FIG. 2), and the other end of the pickup lever 132 rises by the lever principle. Accordingly, the pickup roller 120 to which the shaft 121 is connected to the other end of the pickup lever 132 is in an UP state. In this way, when the pickup roller 120 is in the up state, the recording medium cannot be supplied forward because it does not come into close contact with the upper portion of the recording medium accommodated in the recording medium storage unit. In addition, since the pickup roller 120 is raised, it does not interfere with the transfer of the recording medium to the rear side in the rewinding step to be described later.

Hereinafter, an operating state and a printing method of the dye-sublimation printer according to the present invention will be described.

The printing method of the dye-sublimation printer according to the present invention is a pickup in which the pickup roller 120 is down (see Fig. 8), and the pickup roller is rotated forward in a state in which the pickup roller is in close contact with the upper surface of the recording medium to transfer the recording medium to the front. Steps, a rewinding step of reversely rotating the feed roller 170 to transfer the recording medium to the rear, and the feed roller 170 forwardly rotating to transfer the recording medium to the front and at the same time transferring the ribbon to form an image. And a printing step and a rewinding correction step of correcting the length of the ribbon because it is longer than the length of the recording medium.

Meanwhile, hereinafter, the front side refers to the direction in which the feed roller is located, and the rear side refers to the direction in which the pickup roller is located.

First, the pickup step will be described. When the pickup motor M is driven, the driving force of the pickup motor is transmitted to the idle gear 130 through the reduction gear. The rotation protrusion 130a formed on one side of the idle gear 130 is constrained by the guide groove 152a in the longitudinal direction, and the idle gear and the rotation protrusion 130a rotate (clockwise in FIG. 5) and the guide groove (152a) is moved to the rear side of the shaft 131 of the idle gear. Accordingly, the pickup plate 152 is also retracted to the rear side.

On the other hand, when the pickup plate 152 is retracted to the rear side, the pickup protrusion 132a of the pickup lever is located on the upper rail of the guide rail formed inside the pickup plate 152. With this operation, the pickup lever 132 rotates around the axis 131 of the idle gear to lower the pickup roller 120 (see FIG. 8). The pickup roller 120 lowered in this way is in close contact with the upper portion of the recording medium stacked in the receiving portion, and the driving force of the pickup motor is transmitted through the idle gear 130 and the pickup gear 122, thereby lowering the pickup roller 120. Is to supply the recording medium to the front.

At this time, as shown in FIG. 10, since the platen plate 160 is in contact with the bottom surface of the frame F, the platen roller 163 is also in a lowered state, and accordingly, the head 140 and the platen The rollers 163 are spaced apart.

In addition, one side wall 185 of the swing lever is in contact with the bracket 176, and the legs 184 are spaced apart from the bottom surface of the frame.

At this time, the first protruding bar 193a is in contact with the upper portion of the leg 184 of the swing lever, and the second protruding bar 193b does not contact the other side wall of the swing lever 180.

With this operation, the swing gear 172 and the take-up reel gear 114 are in a state in which the engagement is released.

Therefore, when the pickup roller 120 supplies the recording medium to the front in the pickup step, the platen roller 163 descends, so that the recording medium does not come in close contact with the head 140, so that the recording medium cannot be printed. In addition, since the take-up reel gear 114 is not driven, only the recording medium is supplied forward while the ink ribbon is not transferred.

Next, the rewinding step will be described. When the pickup motor M is driven in the opposite direction to the pickup step, the idle gear and the rotation protrusion 130a rotate counterclockwise in FIG. 5, and the rotation protrusion 130a is located on the front side of the axis 131 of the idle gear. It is located, and the guide groove 152a also moves to the front side. That is, counterclockwise rotation of the rotation protrusion 130a advances the pickup plate 152. In this way, due to the advance of the pickup plate 152, the pickup protrusion 132a is located on the lower rail 156b among the guide rails. Accordingly, the pickup lever 132 rotates around the axis 131 of the idle gear to raise the pickup roller 120 (see FIG. 9).

Further, the slide plate 150 integrally formed with the pickup plate 152 advances, but advances only until the lifter 151 enters the lower portion of the platen plate 160. Therefore, the platen roller 163 maintains a lowered state under the head 140 (see FIG. 11).

In addition, since the swing lever 180 is not rotated about the axis of the feed roller 170, the swing gear 172 and the take-up reel gear 114 are still not engaged.

Therefore, when the feed roller 170 transfers the recording medium to the rear (printing start point) by the rewinding step, the pickup roller 120 rises, and the platen roller 163 also maintains a descending state. There is no interference when transported to the rear.

In addition, since the take-up reel gear 114 is not driven because the swing gear 172 and the take-up reel gear 114 are not engaged, only the recording medium is transferred to the rear, that is, to the printing start point while the ink ribbon is not transferred. .

The front end of the recording medium transferred to the printing start point is engaged between the feed roller 170 and the pressure roller 179.

Next, the printing step will be described. The pickup motor (M) is driven to further rotate the idle gear (30) counterclockwise. Therefore, rotation of the rotation protrusion 130a further advances the pickup plate 160. In this way, even if the pickup plate 152 is further rotated, the pickup protrusion 132a is still located on the lower rail. Therefore, the lift of the pickup roller 120 is maintained.

When the pickup plate 152 is further advanced as described above, the slide plate 150 integrally formed therewith also advances further, whereby the lifter 151 enters the lower portion of the platen plate 160 and the feed roller 170 The platen roller 163 is raised around the axis of (see FIG. 12). At this time, the head 140 and the platen roller 163 are in elastic contact with each other.

In this state, when the driving force of the feed motor M2 is transmitted to the feed roller 170 and rotates, the swing lever 180 connected to the shaft of the feed roller 170 is also applied to the feed roller 170 by the thrust of the feed roller 170. It rotates clockwise around the axis of ). With this operation, the swing gear 172 is finally engaged with the take-up reel gear 114.

Therefore, when the feed roller 170 rotates by the drive of the feed motor, the recording medium engaged with the feed roller 170 and the pressure roller 179 is transferred while passing between the head 140 and the platen roller 163, and this Together, the take-up reel gear 114 rotates and conveys the ink ribbon while winding it around the take-up reel 112.

In other words, by raising the platen roller 163, the ribbon and the recording medium P are in close contact with the heating element formed under the head 140, and in this state, the recording medium and the ink ribbon are transferred at a constant speed while the ink ribbon The dye is sublimated to form an image on the recording medium.

Therefore, in the printing step, the pickup roller 120 and the platen roller 163 are in an elevated state, and the swing gear 172 and the take-up reel gear 114 are engaged. In this state, when the feed roller 170 is rotated, the recording medium and the ink ribbon are transferred forward.

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

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

In particular, rewinding correction is required in the rewinding step after the printing step. This is because the length of the ink ribbon is longer than the length of the recording medium.

The rewinding correction step will be described with reference to FIG. 13. As shown, a space is formed between the platen roller 163 and the head 140 in order to transfer the recording medium to the rear side after the printing step. The lifter 151 is retracted to lower the platen plate 160 and the platen roller 163 to be spaced apart from the head 140. Here, the slide plate is retracted to retract the lifter 151. Specifically, when the idle gear 130 is rotated in the same direction as the pickup step (clockwise in Fig. 5) by driving the pickup motor (M), the idle Since the rotation protrusion 130a of the gear is constrained to the guide groove 152a of the pickup plate, the pickup plate 152 is moved to the rear side of the shaft of the idle gear 130. Since the pickup plate 152, the slide plate 150, and the lifter 151 are integrally formed, when the pickup plate is moved to the rear, the lifter is also retracted (see FIG. 2).

In addition, the swing lever 180 rotates counterclockwise about the axis of the feed roller 170 so that the engagement of the swing gear 171 and the take-up reel gear 114 is released.

Therefore, when the recording medium is transferred to the rear side, the ink ribbon does not transfer (see Fig. 13(a)).

As described above, when the recording medium is transferred to the printing start point and then the feed motor is driven, the swing lever 180 rotates clockwise by the thrust of the feed roller 170, and the swing gear 171 and the take-up reel gear 114 ) Are joined. By winding the ink ribbon in such an operation, it is possible to correct the difference in length between the recording medium and the ink ribbon. At this time, since the platen roller 163 maintains the lowered state, it is not printed on the recording medium. In particular, while the second protruding bar 193b of the link member contacts the other side wall of the swing lever 180, overswing of the swing lever 180 is prevented. Therefore, it is possible to maintain the shaft distance between the swing gear 171 and the take-up reel gear 114 (see Fig. 13 (b)).

100: dye sublimation printer
112: winding reel
114: take-up reel gear
120: pickup roller
130: idle gear
130a: rotating protrusion
140: head
150: slide plate
151: lifter
152: pickup plate
160: platen plate
163: platen roller
170: feed roller
171: feed gear
172: swing gear
180: swing lever
184: leg
190: link member
193a: first protruding bar
193b: second protruding bar

Claims (2)

In the ribbon take-up reel driving device of a dye-sublimation printer selectively driving a take-up reel gear shaft-coupled to a winding reel,
Both shafts are supported by the frame, a feed roller to which a feed gear is coupled to one side;
A swing lever connected to the axis of the feed roller to rotate by the thrust of the feed roller, and to form a leg in contact with the frame during forward rotation;
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;
Link members through which the axes of the feed roller and the platen roller pass through, respectively; And
A ribbon take-up reel driving device comprising: a bracket against which one side wall of the swing lever abuts when the swing lever rotates in reverse.
The method of claim 1,
The link member is a ribbon take-up reel driving device, characterized in that the first protruding bar is formed to press the leg downward.

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