KR20220142138A - Card printer with forced circulation cooling structure - Google Patents

Abstract

The present invention relates to a card printer with a forced circulation cooling structure and, more specifically, to a card printer with a forced circulation cooling structure, which has a concise and simple structure, and can effectively perform a heat protection function while maintaining the clean inside of a card print, thereby improving durability and printing quality. To this end, the card printer with a forced circulation cooling structure according to the present invention comprises: a ribbon transfer unit which transfers and winds an ink ribbon of a printing ribbon supply roller to a printing ribbon winding roller; a film transfer unit which has a film moving motor to transfer and wind a middle transfer film of a transfer film supply roller to a transfer film winding roller; a printing head which is arranged at the transfer route intersecting point of the printing ribbon and the middle transfer film; a transfer means which transfers an overlay layer of the middle transfer film on the surface of a card; and a recovery heating roller. Built in a printer main body for the heat protection function is a card transfer means, which is provided to perform the transfer operation of a card. The forced circulation cooling structure comprises: a suction fan which is installed at one side of the printer main body to suck external air to the inner space; an exhaust fan which is installed at the other side of the printer main body to be spaced apart from the suction fan to discharge the inner air to the outside; a filtering means which is connected to the external air introduction side of the suction fan; and a cold air distribution box of which one side is connected to the exhaust side of the suction fan and the other side is arranged to face a cooling place.

Description

Card printer with forced circulation cooling structure {CARD PRINTER WITH FORCED CIRCULATION COOLING STRUCTURE}

The present invention relates to a card printer having a forced circulation cooling structure, and more particularly, to improve durability and print quality by keeping the inside of the card print clean while the structure is concise and simple, and effectively performing heat dissipation. It relates to a card printer having a forced circulation cooling structure.

In general, various types of cards, such as credit cards, transportation cards, membership cards, medical care cards, identification cards, etc. It is manufactured through a laminating process in which a lamination patch (also called a coating film, etc.) made of a transparent material is attached by a laminating device to protect it.

The conventional card printer printing method, which prints by directly attaching a printing ribbon to the surface of these various cards, has a limitation in that it cannot print up to the edge of the plastic card.

As a card printer to solve this drawback, a retransfer printer that prints using an intermediate transfer web or an intermediate transfer film in addition to a printing ribbon has been developed.

In this retransfer printer, the printed ribbon is not directly in contact with the plastic card, but the image printed on the intermediate transfer film is printed on the intermediate transfer film through the lamination process (retransfer) after the printing process is performed by the printing ribbon on the plastic card. It is intended to be laminated on

For example, Republic of Korea Patent Registration No. 10-1308536 discloses a retransfer color printer of an instantaneous direct heating method as shown in FIG. 1 .

The retransfer color printer according to Patent No. 10-1308536 has a base frame 10, a card transfer means 20, a printing ribbon supply roller 30, a printing ribbon winding roller 40, and a transfer film supply roller 50. , a transfer film winding roller 60 , a print head 70 , a transfer means 80 , and a head lifting means 90 .

The transfer means 80 is arranged on the transfer path of the card as shown in FIG. 1 and is configured to transfer the overlay layer of the intermediate transfer film (b) that has passed through the print head 70 to the surface of the card, the card ( c) is arranged to face the lower conveying roller 211 provided for the conveyance and is composed of a thermal transfer head for lamination that is instantaneously heated by the applied power.

In the retransfer color printer, the printing ribbon (a) wound on the printing ribbon supply roller 30 is unwound by the driving of the ribbon driving device (not shown) and is guided to the guide roller (d) and transferred to the printing ribbon winding roller 40 side. On the other hand, the intermediate transfer film (b) wound in the form of a roll on the transfer film supply roller 50 is driven by the film supply roller driving motor 51 and the film winding roller driving motor 61 to drive the transfer film winding roller 60. When the print head 70 is moved to the print roller 71 side by the operation of the print head driving device 72 in the process of being transferred to the side, the print ribbon (a) passing through the intersection of the print head 70 and the print roller 71 ), an image is printed on the overlay layer of the intermediate transfer film (b) through a transfer process.

The card (c) is transferred between the lower and upper transfer rollers 211 and 212 arranged along the card transfer path by the operation of the card transfer means 20 together with the transfer of the printing ribbon (a) and the intermediate transfer film (b) and stacked It enters between the thermal transfer head 80 and the lower conveying roller 211 below it.

And, when the head elevating means 90 is lowered in the process of moving the intermediate transfer film (b) to the surface of the card that enters the lower portion of the thermal transfer head for lamination 80, the heating element of the thermal transfer head 80 for lamination ( 82) is in close contact with the card surface. At the same time, as the card is transferred by the transfer force of the lower transfer roller 211, the re-transfer process is naturally performed, and the overlay layer of the intermediate transfer film (b) is laminated (laminated) on the surface of the card (c).

As described above, the card c printed through the re-transfer process may be bent due to thermal deformation in the re-transfer process.

On the other hand, the card printer, such as the above-mentioned conventional retransfer color printer, has the advantage of significantly improving the print quality because the image printed on the intermediate transfer film is laminated on the plastic card, but has a structural feature with many components that emit heat during the operation process As a result, there is a limitation in that the deterioration of components due to poor heat dissipation leads to deterioration of durability.

More specifically, the conventional re-transfer color printer includes a print head 70 composed of a thermal transfer head to perform a printing process using a printing ribbon on an intermediate transfer film, and an image printed on the intermediate transfer film through re-transfer is plastic. Not only high heat is emitted from the thermal transfer head 80 for lamination, which is stacked on the card, but also there are many components that emit heat, such as the printing roller driving motor 74, the cam rotating motor 723, and the conveying roller driving motor 221. In the method of installing a heat dissipation fan, sufficient heat dissipation is not possible, which leads to malfunction and deterioration of durability due to deterioration of component parts and deterioration of printed ribbon and intermediate transfer film. Accordingly, in order to properly dissipate heat from each component that emits heat, a large number of cooling fans must be installed, which increases the overall volume, making it difficult to design a compact design and increase the manufacturing cost.

On the other hand, the conventional retransfer color printer has a heat dissipation structure in which internal heat is sucked and exhausted by installing a heat dissipation fan in the printer body. are introduced together. As such, the dust introduced into the printer body causes contamination such as adhered to cards, printing ribbons, intermediate transfer films, and the like, thereby acting as a factor for lowering print quality.

Korean Utility Model Patent Publication No. 20-1994-0026465 "Heat dissipation device for thermal transfer printer" Korean Patent Registration No. 10-0768730 "Printer with intermediate transfer film" Korean Patent Registration No. 10-1308536 "Retransfer color printer with instantaneous direct heating"

The present invention has been proposed in view of the above content, and while the structure is simple and simple, it is possible to improve durability and merchantability by effectively performing the heat dissipation action of various heat generating components, and to reduce the manufacturing cost. It is an object to provide a card printer having.

Another object of the present invention is to provide a card printer having a forced circulation cooling structure that can improve print quality by keeping the inside of the card print clean while effectively dissipating heat.

In order to achieve the above object, the card printer having a forced circulation cooling structure according to the present invention is a card printer having a forced circulation cooling structure, wherein the ink ribbon of the printing ribbon supply roller is transferred to the printing ribbon take-up roller and taken up. A ribbon transfer unit, a film transfer unit equipped with a film transfer motor for transferring and winding the intermediate transfer film of the transfer film supply roller to the transfer film take-up roller, a printhead disposed at the intersection of the transfer path of the printed ribbon and the intermediate transfer film, the middle A transfer means for transferring the overlay layer of the transfer film to the surface of the card, and a heating roller for restoration are provided, and a card transfer means for performing a card transfer operation is built into the printer body, while it is built into the printer body for heat dissipation. In the card printer having a forced circulation cooling structure, the forced circulation cooling structure comprises: a suction fan installed on one side of the printer body to suck outside air into an internal space; an exhaust fan installed on the other side of the printer body to be spaced apart from the suction fan to discharge the bet to the outside; filtering means connected to the outside air inlet side of the suction fan; and a cold air distribution box having one side connected to the exhaust side of the suction fan and the other side facing the cooling point.

Preferably, the suction fan is formed in an upper opening of one side of the printer body, the exhaust fan is formed at the other upper side of the printer body spaced apart from the suction fan, and the cold air distribution box is external air introduced into the suction fan. may be configured to form an arc-shaped cooling passage flowing toward the exhaust fan.

On the other hand, the cold air distribution box, a flange portion formed to seat the suction fan around the air inlet; a vertical duct part extending to the lower side of the air inlet in a sanggwang hyuk structure; a bent duct part extending to the other side under the vertical duct part; a first air outlet formed at an end of the curved duct to communicate with the inner space; a second air outlet formed at a lower portion of the vertical duct and communicating with the inner space; and a third air outlet which is inclinedly formed on one side of the vertical duct and communicates with the inner space.

The cooling flow path is a first arc-shaped cooling flow path formed so that the cold air ejected from the first air outlet flows toward the exhaust fan after passing through the print head, and the cold air ejected from the second air outlet connects the transfer means. A second arc-shaped cooling flow path formed to flow toward the exhaust fan after passing through, and a second arc-shaped cooling flow formed to flow toward the exhaust fan after passing through the film moving motor and the heating roller for restoration, the cold air ejected from the third air outlet A No. 3 cooling passage may be provided.

Preferably, the print head is disposed at a position facing the cold air blowing direction of the first air outlet, the transfer means is disposed on the second arc-shaped cooling passage under the print head, and the film moving motor is It is disposed at a position facing the cold air blowing direction of the third air outlet, and the heating roller for restoration is disposed on the third arc-shaped cooling passage below the film moving motor, the second arc-shaped cooling passage and the third arc-shaped cooling passage The cold air passing through may be configured to be exhausted after being merged in the first arc-type cooling passage.

The cold air distribution box is composed of a first cold air distribution box portion and a second cold air distribution box portion separated and formed in the longitudinal direction, and is detachable by a binding portion formed at opposite ends of the first and second cold air distribution box portions. can be combined.

The filtering means may include a filtering unit case having a through hole connected to the printer body, and a filtering filter installed at the bottom of the filtering unit case.

Preferably, the suction fan may be configured as a blower having a suction capacity larger than that of the exhaust fan.

According to the card printer having a forced circulation cooling structure according to the present invention, a plurality of U-shaped cooling passages are formed by two blowing fans, a filtration means and a cold air distribution box to effectively perform a cooling action, thereby improving durability. and power consumption can be reduced, as well as the simple and simple structure, which can improve productability and reduce manufacturing cost.

In addition, the card printer having a forced circulation cooling structure according to the present invention installs a suction fan with a suction fan having a larger suction capacity than an exhaust fan and includes a filtering means, so that outside air does not flow through a gap between the printer body and the like, and the filtering means is used. Only purified outside air that has passed through is introduced into the cooling air to keep the inside of the printer in a clean state.

1 is a schematic diagram showing the main components of a general retransfer printer;
2 is a perspective view showing an external structure of a card printer having a forced circulation cooling structure according to a first embodiment of the present invention;
3 is a perspective view showing a state in which the cover of one side of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention is removed;
4 is a perspective view showing the shape of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention, with the remaining parts removed except for the main part;
5 is a perspective view showing the main external structure of a card printer having a forced circulation cooling structure according to the first embodiment of the present invention;
6 is a front view for explaining the main part of a card printer having a forced circulation cooling structure according to the first embodiment of the present invention;
7 is a perspective view showing a filtering means and a distribution box portion of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention;
8 is an exploded perspective view showing the filtering means and the distribution box portion of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention;
9 is a view for explaining the effect of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

On the other hand, in each drawing, a detailed description of a configuration that can be easily recognized by a person skilled in the art from the general technology, and an action and effect thereof will be simplified or omitted. In addition, since the present invention is characterized by a card printer having a forced circulation cooling structure, the related parts will be mainly shown and described, and the description of the remaining parts will be simplified or omitted.

In addition, since the present invention is characterized by the forced circulation cooling structure of the card printer, the related parts will be shown and described, and the description of the remaining parts will be simplified or omitted. And the card printer having a forced circulation cooling structure according to the first embodiment of the present invention will be described based on an example applied to a re-transfer printer among types of card printers as shown in FIGS. 2 and 8 to 9c.

2 is a perspective view showing the external structure of a card printer having a forced circulation cooling structure according to a first embodiment of the present invention, and FIG. 3 is a card printer having a forced circulation cooling structure according to the first embodiment of the present invention. It is a perspective view showing a state in which one side cover is removed, and FIG. 4 is a perspective view showing a state in which the remaining parts except for the main part of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention are removed. .

2 to 4, the card printer having a forced circulation cooling structure according to the first embodiment of the present invention has a forced circulation cooling structure inside the printer body 20, but the heat dissipation action of various heat generating components is reduced. It is characterized in that it is configured to improve the print quality by preventing the inflow of foreign substances into the inner space of the printer body 20 during the heat dissipation process.

To this end, the forced circulation cooling structure 100 includes a suction fan 110 and an exhaust fan 120 that form a flow of cooling air, a filtering means 130 that removes foreign substances such as dust contained in the incoming outdoor air, A cold air distribution box 140 is provided that directs the air flow towards the heat generating component from which the heat is emitted.

And, the forced circulation cooling structure can be applied to various card printers that print cards, but in this embodiment, the printing process of printing the primary print layer on the intermediate transfer film (b) by the printing ribbon (a), A plurality of heat generating components (print head 210, transfer means 220 ), a film moving motor 273, etc.) are required and will be described based on an example applied to a retransfer card printer that generates a relatively large amount of heat.

5 is a perspective view showing the main external structure of a card printer having a forced circulation cooling structure according to a first embodiment of the present invention, and FIG. 6 is a card printer having a forced circulation cooling structure according to the first embodiment of the present invention. 7 is a perspective view showing a filtering means and a distribution box portion of a card printer having a forced circulation cooling structure according to a first embodiment of the present invention, and FIG. 8 is a first embodiment of the present invention. An exploded perspective view showing the filtering means and the distribution box portion of a card printer having a forced circulation cooling structure according to an example, FIG. 9 is an explanation of the effects of the card printer having a forced circulation cooling structure according to the first embodiment of the present invention It is a drawing for

4 and 6, the suction fan 110 is a component that is installed on one side of the printer body 20 and sucks outside air into the inner space. have.

The exhaust fan 120 is a component that is installed on the other side of the printer body 20 to be spaced apart from the suction fan 110 and discharges the bet to the outside. It consists of a blower fan formed in the opening.

The aforementioned suction fan 110 and exhaust fan 120 select and install a known blower fan applied for cooling to various electric and electronic devices such as a computer, but the suction fan 110 has a suction capacity compared to the exhaust fan. It is important to select and install one with a large (blow capacity). The reason why the suction fan 110 has a larger suction capacity than that of the exhaust fan 120 is that the amount of outside air flowing into the inner space of the printer body 20 is greater than the amount of exhaust air exhausted by the exhaust fan 120 . in order to make it more As such, when the amount of inflow is large, negative pressure is not applied to the inner space of the printer body when the exhaust fan is operated, so outside air does not flow through gaps in the printer body, and only the outside air purified while passing through the filtering means 130 is used as cooling air. As it is used, dust and the like do not enter. Due to this, there is an advantage in that it is possible to prevent in advance the printing defects or malfunctions that may occur due to the adhesion of dust to the surface of the card, ink ribbon, intermediate transfer film, and roller.

The filtering means 130 is connected to the outside air inlet side of the suction fan 110 to filter foreign substances. The filtering unit case 131 is connected to the printer body 20 and has a plurality of through holes, and the filtering unit It consists of a filtration filter 132 installed at the bottom of the case 131.

The filter case 131 has a structure in which an elastic hook 131b is provided so as to be bound to a case coupled to the printer body to a plate-shaped filter case plate 131a having a plurality of through holes for the inflow of outside air.

The filtration filter 132 can be formed in various structures without any particular limitation as long as it can effectively remove foreign substances, but in this embodiment, the upper filtration filter 132a and the suction fan 110 that are in close contact with the inner surface of the filter case 131 . ) is composed of a lower filtration filter (132b) disposed under the upper filtration filter (132a) in contact with.

The cold air distribution box 140 is a distribution means having one side connected to the exhaust side of the suction fan 110 and the other side facing the cooling point in order to guide the flow direction of the cold air together with the distribution function of the cold air. 110 ) is configured to form an arc-shaped cooling flow path through which the outside air flows toward the exhaust fan 120 .

More specifically, the cold air distribution box 140 is a flange portion 141 formed in a rectangular frame shape in which the suction fan is seated around the air inlet opposite to the suction fan 110, and extends downward from the flange portion 141. A vertical duct part 142 formed of a doe-sang-gwang-ha-hyeop structure (a structure that is wide at the top and narrow at the bottom), a curved duct part 143 extending to the other side in the direction of the exhaust fan 120 at the lower part of the vertical duct part 142 is formed.

And, the cold air distribution box 140 is formed at the end of the bent duct part 143, the first air outlet 144 formed in communication with the internal space of the printer body, the vertical duct part 144, and is formed at the bottom of the printer body ( 20) is provided with a second air outlet 145 communicating with the inner space, and a third air outlet 146 which is inclinedly formed on one side of the vertical duct 142 and communicates with the inner space of the printer body.

In addition, the cold air distribution box 140 is composed of a first cold air distribution box portion 140a and a second cold air distribution box portion 140b that are divided and separated in the longitudinal direction so that they can be manufactured quickly and conveniently through injection molding. . In addition, the first cold air distribution box unit 140a and the second cold air distribution box unit 140b are detachably coupled to each other by forming a plurality of binding portions 147 at opposite ends for easy assembly. Here, the binding part 147 is a conventional structure consisting of a hook-shaped locking protrusion and a protrusion insertion part having a fitting groove so that the locking protrusion is inserted.

In addition, the forced circulation cooling structure according to the present invention is configured to have a cooling flow path f of an appropriate amount while forming the movement path of cold air to have the shortest distance, thereby performing a rapid and appropriate cooling action, as well as the exhaust fan 120 ) and the capacity of the suction fan 110 are made to be as small as possible to reduce the manufacturing cost and at the same time to reduce the operating cost through the minimization of power consumption.

More specifically, the cooling flow path f is a first arc-shaped cooling flow path formed so that cold air ejected from the first air outlet 144 flows toward the exhaust fan 120 after passing through the print head 210 to be described later. (f1), the second arc-shaped cooling passage f2 formed so that the cold air ejected from the second air outlet 145 flows toward the exhaust fan 120 after passing through the transfer means 220 to be described later, and the third air It is composed of a third arc-shaped cooling flow path f3 formed so that the cold air ejected from the outlet 146 flows toward the exhaust fan 120 after passing through the film moving motor 273 and the restoration heating roller 285 .

In addition, the second arc-shaped cooling passage f2 and the third arc-shaped cooling passage f3 are the transfer means 220, the film moving motor 273 and the heating roller 285 for restoring heat exchanged cold air through the first arc-type cooling passage (f3). It is configured to be exhausted after being merged in the cooling passage f1. At this time, the third arc-shaped cooling passage f3 is connected to the second arc-shaped cooling passage f2, and the second arc-shaped cooling passage f2 is configured to be connected to the first arc-shaped cooling passage.

On the other hand, the card printer having a forced circulation cooling structure according to the present invention is provided with essential components for the printing process and the transfer process performed in the retransfer cart printer, but by the suction fan 110 and the exhaust fan 120 It is characterized in that it is configured to have an arrangement structure suitable for the forced circulation cooling structure, and the description of the detailed structure is omitted and the arrangement structure will be mainly described.

More specifically, the card printer having a forced circulation cooling structure according to the present invention transfers the ink ribbon (a) of the printing ribbon supply roller 261 to the printing ribbon take-up roller 262, and a ribbon moving motor ( (not shown) provided with a ribbon transfer unit 260 and a film transfer motor 273 for transferring and winding the intermediate transfer film (b) of the transfer film supply roller 271 to the transfer film take-up roller 272 A film transfer unit 270 is provided.

Here, the printing ribbon supply roller 261 and the printing ribbon winding roller 262 are arranged up and down inside the printer body 20 corresponding to the arrangement direction of the cartridge 30, FIGS. 2 and 3, and the printing ribbon supply The ink ribbon (a) drawn out from the roller 261 is configured to pass through the print head 210 .

The transfer film supply roller 271 and the transfer film winding roller 272 are vertically disposed in a direction facing the printing ribbon supply roller 261 and the printing ribbon winding roller 262 , and are drawn out from the transfer film supply roller 271 . The intermediate transfer film (b) is configured to be moved along a long movement path of an approximately 'D' shape via the print head 210 and the transfer means 220 . The film moving motor 273 is disposed in front of the cooling distribution box 142 to generate a rotational force for rotating the transfer film take-up roller 272, and is a film moving power transmission unit (not shown) composed of a plurality of gears. The rotational force is transmitted to the transfer film take-up roller 272 . As such, the film moving motor 273 has a relatively long moving path as the intermediate transfer film b passes through several devices, resulting in a large tensile load as well as a long operating time. It is important that the third air outlet 146 of the cooling distribution box 140 is disposed at a position facing the cold air ejection direction because an appropriate heat dissipation action is required to secure it.

The print head 210 is a component disposed at the intersection of the transfer paths of the printing ribbon (a) and the intermediate transfer film (b), and is composed of a thermal transfer head for lamination that is instantaneously heated by the applied power. Since the print head 210 continuously emits hot air of 70 to 200° C. during operation, it is important that the print head 210 faces the cold air ejection direction of the first air outlet 144 and is disposed below the exhaust fan 120 . Here, since the thermal transfer head is a device widely applied to card printers, a detailed description thereof will be omitted.

The transfer means 220 is arranged on the transfer path of the card (c) as shown in FIG. 6 and is configured to transfer the overlay layer of the intermediate transfer film (b) passing through the print head 210 to the surface of the card. , is provided with a transfer heating roller 222 that is disposed to face the lower transfer roller 282 provided for transfer of the card (c) and is instantaneously heated by the applied power. In addition, since the transfer means 220 continuously emits heat of 70 to 200° C. during operation, it is important to be disposed on the second arc-shaped cooling passage f2 below the print head 210 .

The card transfer means 280 is a component that transfers the cards loaded in the cartridge 30 so that the transfer process is performed, and discharges the card on which the transfer process is completed to the outside, including a card transfer motor, as is well known. A card transfer driving unit (not shown) and a restoration heating roller 285 for restoring the card by passing it through a card bent by thermal deformation in the transfer process are provided. At this time, the heating roller 285 for restoration is disposed on the third arc-shaped cooling passage f3 below the film moving motor 273 for effective heat dissipation.

On the other hand, non-explained reference numerals 21 to 24 of FIGS. 2 and 3 are components constituting the printer body 20 or supporting main components, 22 is an outer case, 22 is a support frame for supporting internal components, 23 is The ribbon transfer unit frame supporting the printing ribbon supply roller 261 and the printing ribbon take-up roller 262 of the ribbon transfer unit 260, 24 is the transfer film supply roller 271 and the transfer film winding of the film transfer unit 270 It is a film transfer unit frame supporting the roller (272).

In addition, the above-described outer case 21, the support frame 22, the ribbon conveying unit frame 23 and the film conveying unit frame 24 have not been described in detail with respect to the detailed shapes, but the above-described first arc-shaped cooling flow path f1 ), the second arc-shaped cooling passage f2 and the third arc-shaped cooling passage f3 are designed and formed. In addition, as shown in FIG. 2 , a plurality of slits are formed on the surface of the case where the exhaust fan is installed among the external case 21 .

In addition, the non-explained reference numeral r in FIGS. 5 and 6 is a guide roller installed on the transport path so that the printing ribbon (a) and the intermediate transfer film (b) are moved while maintaining tension.

Hereinafter, the operation of the card printer having the forced circulation cooling structure according to the first embodiment of the present invention will be briefly described.

As shown in FIG. 9, a ribbon transfer unit 260 including a print ribbon supply roller 261 and a print ribbon take-up roller 262 in the printer body 20, a transfer film supply roller 271, and a transfer film take-up Install the film transfer unit 270 including the roller 272 and the film movement motor 273, and install the print head 210 at the intersection of the transfer path of the printing ribbon (a) and the intermediate transfer film (b) .

And, the transfer means 220 including the heating roller 222 for transfer between the ribbon transfer unit 260 and the film transfer unit 270, and the card transfer means 280 including the heating roller 285 for restoration. install the back In this assembly process, the cold air distribution box 140 is installed, the suction fan 110 and the filtering means 130 are installed thereon, and then the exhaust fan 120 is installed to be spaced apart to form a forced circulation cooling structure 100 . prepare

After assembling the main components of the card printer as described above, when the printing card c is stacked and accommodated in the cartridge 30 and inserted into the cartridge accommodating part 25, the card printing preparation is completed.

In this state, when the operator operates the operation button (not shown), the printing ribbon (a) and the intermediate transfer film (b) are moved according to the operation mechanism of the retransfer printer, and the print head 210 prints on the intermediate transfer film. The process is performed, and the printing process is performed while the image printed on the intermediate transfer film is printed on the plastic card by the re-transfer action by the transfer heating roller 222 .

At this time, the print head 210 for performing the printing process by the thermal transfer method, the film moving motor 273 to which a large tensile load is applied, the transfer heating roller 222 for performing the re-transfer process by the thermal transfer method, and the banded card Since the heating roller 285 for restoration restored by passing through it is heated to about 70 to 200° C. during its operation, relatively high heat is released, but an effective heat dissipation action is performed by the forced circulation cooling structure 100 .

If the heat dissipation action of the forced circulation cooling structure 100 will be described in more detail, the inside of the printer body 20 by the suction force of the suction fan 110 due to the operation of the exhaust fan 120 and the suction fan 110 . The outside air introduced into the space performs a cooling action while moving along a relatively short movement path of an approximately 'U' shape through three cooling passages f1, f2, and f3.

At this time, the outside air ejected through the first air outlet 144 of the cold air distribution box 140 is supplied to the opposing print head 210 to perform a cooling action while exchanging heat, and by the suction force of the exhaust fan 120, the first It is discharged to the outside of the card printer while forming the arc-shaped cooling passage f1.

Outside air blown out through the second air outlet 145 of the cold air distribution box 140 is moved along the outer periphery by the transfer film winding roller 272, and the second arc-shaped cooling flow path f2 by the suction force of the exhaust fan 120 ) is supplied to the transfer heating roller 222 of the transfer means 220 while forming and heat exchange is performed to perform a cooling action. Subsequently, the air heat-exchanged on the second arc-shaped cooling passage f2 is discharged to the outside of the card printer along the first arc-shaped cooling passage f1.

And the external air blown out through the third air outlet 146 of the cold air distribution box 140 performs a cooling action of the film moving motor 273 disposed to face the third arc type by the suction force of the exhaust fan 120 . While forming the cooling passage (f3) while moving toward the heating roller 285 for restoration performs a cooling action. The heat exchange air used for cooling the restoration heating roller 285 passes through the second arc-shaped cooling passage f2 and then is discharged to the outside of the card printer along the first arc-shaped cooling passage f1.

As described above, in the forced circulation cooling structure 100 according to the present invention, even in the case of a re-transfer card printer equipped with a plurality of high-heating components, only two blowing fans composed of the suction fan 110 and the exhaust fan 120 are used. cooling can be performed. In particular, while moving along three short cooling paths (f1, f2, f3) having a 'U' shape, it is possible to improve durability and print quality by effectively performing a cooling action, and to minimize the capacity of the blower fan, so consumption It has the advantage of saving power.

In addition, the suction fan 110 has a larger suction capacity than that of the exhaust fan 120, so that when the exhaust fan is operated, negative pressure is not applied to the inner space of the printer body 20, so the outside air is discharged through a gap in the printer body. Only the purified outside air that has passed through the filtering means 130 without being introduced is introduced into the cooling air. As a result, the problem of contamination of the card surface, ink ribbon, intermediate transfer film, and roller surface due to foreign substances is fundamentally solved, so there is an advantage in that printing defects or malfunctions can be prevented in advance.

Although the configuration and operation of a card printer having a forced circulation cooling structure according to an embodiment of the present invention described above has been described, this is an example and those of ordinary skill in the art do not deviate from the technical spirit of the present invention. It will be understood that substitutions and variations of some of the embodiments described above are possible within the scope.

Therefore, it should be understood that the protection scope of the present invention extends to the invention described in the claims and their equivalents.

100: forced circulation cooling structure 110: suction fan
120: exhaust fan 130: filtration means
140: cold air distribution box 141: flange part
142: vertical duct part 143: curved duct part
144: first air outlet 145: second air outlet
146: third air outlet 210: print head
220: transfer means 222: heating roller for transfer
260: ribbon transfer unit 270: film transfer unit
273: film transfer motor 280: card transfer means
285: restoration heating roller a: printing ribbon
b: intermediate transfer film f: cooling flow path
f1: arc type 1 cooling path f2: arc type 2 cooling path
f3: arc 3 cooling path

Claims (6)

In the card printer having a forced circulation cooling structure,
A film transfer unit equipped with a film transfer motor that transfers and winds the ink ribbon of the printing ribbon supply roller to the print ribbon take-up roller, and transfers and winds the intermediate transfer film of the transfer film supply roller to the transfer film take-up roller, printing A card transfer means provided with a printhead disposed at the intersection of the transfer path of the ribbon and the intermediate transfer film, a transfer means for transferring the overlay layer of the intermediate transfer film to the surface of the card, and a heating roller for restoration, and performing a transfer operation of the card In the card printer having a forced circulation cooling structure that is built into the printer body and is built into the printer body for heat dissipation,
The forced circulation cooling structure,
a suction fan installed on one side of the printer body to suck outside air into the internal space;
an exhaust fan installed on the other side of the printer body to be spaced apart from the suction fan to discharge the bet to the outside;
filtering means connected to the outside air inlet side of the suction fan; and
and a cold air distribution box having one side connected to the exhaust side of the suction fan and the other side facing the cooling point.
According to claim 1,
The suction fan is formed in the upper opening of the printer body,
The exhaust fan is formed on the other upper side of the printer body spaced apart from the suction fan,
The cold air distribution box is configured to form an arc-shaped cooling passage through which the outside air introduced into the suction fan flows toward the exhaust fan.
3. The method of claim 2,
The cold air distribution box,
a flange portion formed to seat the suction fan around the air inlet;
a vertical duct part extending to the lower side of the air inlet in a sanggwang hyuk structure;
a bent duct part extending to the other side under the vertical duct part;
a first air outlet formed at an end of the curved duct to communicate with the inner space;
a second air outlet formed at a lower portion of the vertical duct and communicating with the inner space; and
The card printer having a forced circulation cooling structure, comprising a; a third air outlet formed to be inclined at one side of the vertical duct portion and communicated with the inner space.
4. The method of claim 3,
The cooling flow path is a first arc-shaped cooling flow path formed so that the cold air ejected from the first air outlet flows toward the exhaust fan after passing through the print head, and the cold air ejected from the second air outlet connects the transfer means. A second arc-shaped cooling flow path formed to flow toward the exhaust fan after passing through, and a second arc-shaped cooling flow formed to flow toward the exhaust fan after passing through the film moving motor and the heating roller for restoration, the cold air ejected from the third air outlet A No. 3 cooling passage is provided;
The print head is disposed at a position facing the cold air blowing direction of the first air outlet, the transfer means is disposed on the second arc-shaped cooling passage below the print head, and the film moving motor is configured to operate the third air It is disposed at a position facing the cold air ejection direction of the outlet, and the heating roller for restoration is disposed on the third arc-shaped cooling passage below the film moving motor, passing through the second arc-shaped cooling passage and the third arc-type cooling passage. The card printer having a forced circulation cooling structure, characterized in that the cold air is exhausted after being merged in the first arc-type cooling passage.
4. The method of claim 3,
The cold air distribution box is composed of a first cold air distribution box portion and a second cold air distribution box portion separated and formed in the longitudinal direction, and is detachable by a binding portion formed at opposite ends of the first and second cold air distribution box portions. A card printer having a forced circulation cooling structure, characterized in that it is combined.
According to claim 1,
The filtration means includes a filtration unit case having a through hole connected to the printer body, and a filtration filter installed at the bottom of the filtration unit case,
The suction fan is a card printer having a forced circulation cooling structure, characterized in that it is composed of a blower having a larger suction capacity than the exhaust fan.

Images