KR20220165979A - A laser label printer using a polygon mirror scanner and label printing method thereof - Google Patents

Abstract

The present invention relates to a laser label printer using a polygon scanner, comprising: a laser unit oscillating a carbon dioxide laser beam; a light condensing lens making the oscillated laser beam parallel or convergent; a polygon scanner unit arranged on an output side of the laser unit and the condensing lens, and receiving the carbon dioxide laser beam coming from the laser unit, and controlling the refractive angle of the incident carbon dioxide laser beam, and changing the horizontal or vertical displacement, and injecting the beam in a certain direction; and a label sheet on which a barcode, character, or image is printed. As the carbon dioxide laser beam is used to print on a label middle layer by penetrating the surface of the label sheet without giving a damage, the surface of label protects the barcode, character, or image, thereby printing without being removed by friction or chemical.

Description

Laser label printer using polygon mirror scanner and label printing method using same {A LASER LABEL PRINTER USING A POLYGON MIRROR SCANNER AND LABEL PRINTING METHOD THEREOF}

The present invention relates to a laser label printer using a polygon scanner, and more particularly, to a polygon mirror capable of printing at a higher speed than when using a galvanometer scanner, requiring no consumables, and capable of printing without being erased by friction and chemicals. It relates to a laser label printer using a scanner.

A label printer is a device capable of printing various information such as barcodes, names, addresses, and dates on label paper. Methods for printing on label paper include an inkjet (print) method, a thermal method, and a thermal transfer method. Currently, a method mainly used worldwide is known as a thermal transfer printer.

The inkjet method is a method of printing by applying ink to the outer surface of the label with an inkjet printer, and there is a problem that the printed contents are easily erased by friction.

The thermal method is a method in which the dye of the thermal paper melts when heated above the melting point with a dot-type heating element, and characters or pictures appear.

The thermal transfer method is a method of printing by melting the ribbon by applying heat to the printer head rather than heating the paper, so maintenance costs are high due to the use of a consumable ribbon, and there is a problem that the print contents are discolored or erased by friction or foreign substances. In particular, the ribbon used as consumables is made of PET (Poly-Ethylene-Terephthalate), which is harmful to the environment. Meanwhile, thermal transfer printers are classified into thermal printers and ribbon printers.

A thermal printer is a printer that prints characters or pictures by applying heat to paper. It uses special paper called 'thermal paper', which gives out color when heated. Unlike other printers, it does not require ink or toner, so there is no need to change ink or toner every time. Normal paper burns when heated to high temperatures, but the temperature used by thermal transfer printers is much lower. Representatively, there are thermal paper and tapes exclusively for label printers. Thermal paper is a type of paper on which a dye having a low melting point is applied on the paper in advance, and when heated above the melting point, the dye melts and the color comes out.

Ribbon printers have a separate ribbon under the tape for label printers, so there is a problem that the dye in the ribbon sticks to the tape during printing.

A laser label printer was developed to solve the problem of increasing consumable cost and erasing printed contents of the existing thermal transfer label printer, but the existing laser label printer had a problem in that its use was limited because it could only be used for special label paper. Therefore, it is necessary to develop a label printer that can be used for general-purpose label paper, has a high printing speed, does not erase printed contents, and does not require the cost of consumables.

1 shows the structure of a conventional galvanometer scanner.

Referring to FIG. 1, it can be seen that after mounting the mirror on the galvanometer, the X-Y axis scanning motor is controlled to mark the label paper.

In this case, there is a problem in that idle time for acceleration and deceleration occurs when the scanning motor is driven. Galvanometer scanners are suitable for high-power and low-speed processing, but as power consumption increases, efforts are being made to improve the speed.

Therefore, there is a need for a low-power and high-throughput scanner for use in laser printing, as well as a label printing method that is resistant to friction and chemicals after printing.

In addition, since conventional thermal printers print on the label surface, there is a problem of erasing when friction and chemicals contact the label surface after attaching the label, and the existing laser label printer has a galvanometer Because the scanner (Galvanometer Scanner) was used, there was a problem with the slow printing speed.

Therefore, the first problem to be solved by the present invention is to print on the intermediate layer of the label after the laser beam passes through the surface of the label paper without damage using a carbon dioxide laser beam, and the label surface serves to protect barcodes, characters, or images. , To provide a laser label printer using a polygon scanner capable of printing without being erased by friction and chemicals.

The second problem to be solved by the present invention is to provide a label printing method using a laser label printer capable of high-speed printing with low power compared to a laser label printer using a conventional galvanometer scanner.

In order to achieve the first object of the present invention,

a laser unit oscillating a carbon dioxide laser beam; a condensing lens for collimating or converging the oscillated laser beam; It is disposed on the output side of the laser unit and the condensing lens, receives the carbon dioxide laser beam emitted from the laser unit, adjusts the refraction angle of the incident carbon dioxide laser beam to change the horizontal or vertical displacement, and scans in a predetermined direction. a polygon scanner unit; and a laser label printer using a polygon scanner including label paper on which barcodes, characters, or images are printed.

According to an embodiment of the present invention, the polygon scanner unit, having a plurality of reflective surfaces, polygon mirrors formed with different angles for reflecting the laser beam according to the angle change of the reflective surface; and a scan lens that refracts the constant-velocity light reflected from the polygon mirror in a scanning direction and corrects aberration to focus the light on a scanning surface on the label sheet.

In addition, the polygon scanner unit may form a different focus position according to the depth of the removal layer of the label paper.

According to another embodiment of the present invention, the label sheet, when the laser beam is projected, the projected portion reacts and disappears the removal layer; and a dark sheet attached to the lower side of the removal layer, not reacting to the laser beam, coated with color ink, or composed of a film of the color.

In order to achieve the second object, the present invention comprises: determining an Nth focal length of a laser beam corresponding to an Nth depth of the label sheet to form at least one of a barcode, a character, or an image on the label sheet; adjusting a divergence angle of the laser beam by controlling a polygon mirror based on the determined N-th focal length; irradiating the laser beam to the label sheet to remove the removal layer up to the N-th depth; determining whether the removal layer has been removed to a preset depth of at least one of a barcode, text, and image on the label sheet; and determining the N+1th focal length instead of the Nth focal length by proceeding to the step of determining the Nth focal length when the removal layer of the depth to be additionally removed remains as a result of the determination. It provides a label printing method using.

According to an embodiment of the present invention, the removal layer of the label paper is divided into at least one layer by applying color ink to the lower part of the transparent sheet with different ink according to the depth, and the laser beam emitted from the polygon scanner unit The removal layer may be removed to a set depth.

In addition, it is preferable to remove the removal layer by dividing the depth in steps to remove the removal layer to a predetermined depth by the laser beam emitted from the polygon scanner unit.

According to the present invention, using a carbon dioxide laser beam, the laser beam passes through the surface of the label paper without damaging it, and then prints on the label intermediate layer, and the label surface serves to protect barcodes, characters, or images, so that they are not erased by friction and chemicals. You can print without it.

In addition, according to the present invention, high-speed printing is possible with low power compared to a laser label printer using a conventional galvanometer scanner.

Furthermore, according to the present invention, since the lifetime of the laser used to print the label is 100,000 hours, the cost of consumables for the laser required for printing is hardly consumed.

1 shows the structure of a conventional galvanometer scanner.
2 shows an example of a laser label printer using a polygon scanner according to an embodiment of the present invention.
3 is a cross-sectional view of a label sheet used in a laser label printer according to an embodiment of the present invention.
4 is a cross-sectional view of a label sheet used in a laser label printer according to another embodiment of the present invention.
5 is a flowchart illustrating a method of printing a label using a laser label printer according to an embodiment of the present invention.

Hereinafter, preferred embodiments in which a person skilled in the art can easily practice the present invention will be described in detail with reference to the accompanying drawings. However, these examples are intended to explain the present invention in more detail, and it will be apparent to those skilled in the art that the scope of the present invention is not limited thereto.

The composition of the present invention for clarifying the solution to the problem to be solved by the present invention will be described in detail with reference to the accompanying drawings based on a preferred embodiment of the present invention, but the same reference numerals are assigned to the components of the drawings. For components, even if they are on other drawings, the same reference numerals have been assigned, and it is made clear in advance that components of other drawings can be cited if necessary in the description of the drawings. In addition, in the detailed description of the operating principle of the preferred embodiment of the present invention, if it is determined that the detailed description of known functions or configurations related to the present invention and other matters may unnecessarily obscure the subject matter of the present invention, A detailed description thereof is omitted.

In addition, throughout the specification, when a part is 'connected' to another part, it is not only 'directly connected', but also 'indirectly connected' with another element in between. include In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" or "comprising" excludes the presence or addition of one or more other components, steps, operations, or elements other than the recited components, steps, operations, or elements. I never do that.

2 shows an example of a laser label printer using a polygon scanner according to an embodiment of the present invention. Referring to FIG. 2 , the laser label printer according to the present embodiment is composed of a laser unit 200, a condensing lens 210, a polygon scanner unit 220, and a label sheet 230. Meanwhile, the polygon scanner unit 220 includes a polygon mirror 221 and a scan lens 222.

The laser label printer according to an embodiment of the present invention is controlled by a driving scanning motor that rotates a polygon mirror at a constant speed and high speed to mark label paper. In case of using a mirror mounted on a galvanometer and using a polygon mirror, when using a polygon mirror, there is no idle time due to the constant speed and high-speed rotation of the scanning motor, and the printing speed is fast. there is

The laser unit 200 oscillates a laser beam and sends the oscillated laser beam to a condensing lens 210 that makes the oscillated laser beam collimate or converge.

The laser unit 200 may use a fiber laser and a carbon dioxide laser.

The fiber laser uses a fiber laser source, has a wavelength of 1064 nm, and generates a laser with high photoelectric speed and low cost. On the other hand, the carbon dioxide fiber laser uses a gas laser source with an infrared wavelength of 10.64 μm, and the laser active medium is powered by air or water cooling, and gas discharge is performed.

Since the fiber laser uses low power, according to an embodiment of the present invention, it is preferable that the laser unit 200 generates and outputs a carbon dioxide laser that consumes high power. According to the embodiment of the present invention, it was confirmed through experiments that the carbon dioxide laser can print on all commercial label papers compared to the fiber laser.

The condensing lens 210 parallelizes or converges the laser beam oscillated by the laser unit 200 . It is preferable to amplify and strengthen the laser beam incident through the condensing lens 210 .

The polygon scanner unit 220 is disposed on the output side of the laser unit 200 and the condensing lens 210, receives the CO ₂ laser light emitted from the laser unit 200, and adjusts the refraction angle of the incident CO ₂ laser light. By changing the horizontal or vertical displacement, the laser light is scanned in a predetermined direction of the label paper 230 .

The polygon mirror 221 has eight reflective surfaces arranged at regular intervals, and a polygon mirror driver (not shown) supports and rotates the polygon mirror 221 . Meanwhile, in the present embodiment, the polygon mirror is configured to have eight reflective surfaces, but the number of reflective surfaces is not limited thereto and may be variously modified.

The polygon mirror 221 having a plurality of reflective surfaces is rotated at high speed by the polygon mirror driving unit, and different angles for reflecting the laser light are formed according to the angle change of the reflective surfaces. As a result, the laser light reflected in different directions from the reflective surface of the rotating polygon mirror 221 is scanned in a specific direction to form a line-shaped laser beam as a whole.

The scan lens 222 is a device that refracts light of constant velocity reflected from the polygon mirror 221 in a scanning direction and corrects aberration to focus the light on the scanning surface on the label paper 230.

The scan lens 222 is disposed on the output side of the polygon mirror 221 and changes the path of the CO ₂ laser light so that the CO ₂ laser light emitted through the polygon mirror 221 is incident on the label sheet 230 in a vertical direction. let it

Meanwhile, the polygon scanner unit 220 may change the position of the focal point according to the label paper layer. When the position of the focal point is different, it is possible to lose a layer disposed at a specific depth of the label paper 230 .

In order to adjust the divergence angle, there are a method of adjusting the distance between the two lenses and a method of electrically adjusting the curvature of the lens. However, the change rate of adjusting the distance between the lenses and adjusting the curvature of the lenses is low due to mechanical limitations. According to an embodiment of the present invention, it is preferable to adjust the focal position of the laser beam by adjusting the divergence angle of the laser beam in the polygon mirror 221 .

The label sheet 230 is a sheet on which at least one of a barcode, text, or image is printed. By projecting a laser beam onto the label paper 230, the removal layer is destroyed, and the color expressed on the dark sheet is revealed to prevent barcodes, characters, or images from being damaged.

3 is a cross-sectional view of a label sheet used in a laser label printer according to an embodiment of the present invention.

The label paper 230 used in the laser label printer according to an embodiment of the present invention includes a protective film 31, a color layer 32, a transparent sheet 33, a removal layer 34, a dark sheet 35, a cancer It is composed of a sheet protective film 36 and a mucosal layer 37.

The protective film 31 is attached to the top of the color layer 32 to protect the color layer 32, and prevents the color expressed on the color layer 32 from being erased or discolored by external friction.

The protective film 31 is preferably made of a film-based transparent material, and may be made of any one of PET (polyethylene terephthalate), OPP (polypropylene oriented film, oriented polypropylene), and PP (polypropylene). . In addition, it is not limited to the above material, but it is okay to use a film of other similar transparent materials that can be provided on the upper surface of the label paper 230, and all such simple material changes will fall within the scope of the present invention.

The color layer 32 is attached to the top of the removal layer 34 and is a layer in which a preset color among various colors is expressed.

A method of expressing a preset color on the color layer 32 is to apply a preset color ink to a film-based material or deposit a preset color on a film-based material to express a preset color on a film-based material. can do.

The color layer 32 should be provided by thinning the color so that it is expressed lightly in a preset color. That is, if the color layer 32 is provided thickly, even if the color layer 32 reacts by laser beam projection or forms a barcode, text, or image, the color expressed on the dark sheet 35 is not visible.

Therefore, the color is diluted by mixing ink of a preset color with a water-soluble liquid, or the thickness of the applied color layer 32 is adjusted so that the color layer 32 expresses a light color. At this time, the color layer 32 should be provided with a color, thickness, and concentration sufficient to reveal the color of the dark sheet 35 .

The transparent sheet 33 is made of a film-based transparent material that does not react to the laser beam and is provided on the upper side of the removal layer 34 to prevent dust or foreign substances from penetrating into the removal layer 34, and is removed by friction or the like. Layer 34 is prevented from being damaged.

The film-based transparent material of the transparent sheet 33 is made of any one of PET (polyethylene terephthalate, polyethyleneterephthalate), OPP (polypropylene oriented film, oriented polypropy-lene), and PP (polypropylene).

The removal layer 34 is a layer that is removed in response to a laser beam, and is provided by depositing aluminum or the like on the lower portion of the transparent sheet 33 or by applying silver color ink to the lower portion of the transparent sheet. In addition, it can be provided in various ways.

When the laser beam is projected, the projected portion of the removal layer 34 reacts and disappears, so that the color expressed in the dark sheet 35 below is visible. Therefore, the removal layer 34 is eliminated by the laser beam so that certain portions are transparent and the remaining portions are opaque, thereby forming barcodes, characters, images, and the like on the label paper 230 .

The dark sheet 35 is attached to the lower side of the removal layer 34 and does not react to laser beams and is made of ink or film-based material expressing a predetermined color.

The dark sheet 35 is formed and used as a black ink or film series, but the present invention is not limited thereto, and the dark sheet 35 expresses a preset color among various colors such as blue, red, or yellow. ), so that barcodes, characters, images, etc. visible on the label paper 230 can be expressed not only in black but also in other preset colors.

The adhesive layer 37 is attached to the lower side of the dark sheet protective film 36, and since an adhesive material is applied, the label sheet 230 can be easily attached to a predetermined wrapping paper or product.

By providing the dark sheet protective film 36 between the dark sheet 35 and the adhesive layer 37, even if the label sheet 230 is removed from the packaging or product, the dark sheet 35 is not damaged and the label sheet is placed in an accurate position. 230 can be reattached.

4 is a cross-sectional view of a label sheet used in a laser label printer according to another embodiment of the present invention.

Comparing FIG. 3 and FIG. 4, the color layer of the label paper 230 of FIG. 4 is removed, and the removal layer 34 of FIG. 3 is removed to the same depth, while the removal layer 34 of FIG. 4 is removed ( 44), it can be seen that the removal layer 44 has been removed to various depths.

Since the polygon scanner unit 220 according to an embodiment of the present invention can change the position of the focal point according to the depth of the label paper, it is possible to lose the removal layer 44 to a specific depth of the label paper when the position of the focal point is different. Do. More specifically, the focal position of the laser beam may be adjusted by adjusting the divergence angle of the laser beam.

The removal layer 44 of the label paper 230 shown in FIG. 4 may be divided into at least one layer. When the color ink is applied to the lower part of the transparent sheet 43 with different inks according to the depth and divided into several layers, the depth is determined by the laser beam emitted from the polygon scanner unit 220 to remove the removal layer 44. It can be made to have various colors.

Referring to FIG. 4, when the removal layer 44 is removed once with a laser beam, the removal layer is removed by a distance d, when the removal layer is removed twice, the removal layer is removed by a distance 2d, and when the removal layer is removed three times. When is removed, it can be seen that the removal layer at a distance of 3d is removed and the dark sheet 45 is exposed.

When removing the removal layer 45, it is preferable to remove the removal layer 45 step by step instead of removing it to a preset depth (distance d, 2d, or 3d) all at once. When the ink is applied by dividing the depth and the removal layer is removed, since the ink of the corresponding depth can be exposed, various colors can be expressed.

5 is a flowchart illustrating a method of printing a label using a laser label printer according to an embodiment of the present invention.

In step 510, the laser label printer determines the Nth focal length of the laser corresponding to the Nth depth to form barcodes, characters, images, and the like.

In step 520, the laser label printer adjusts the divergence angle of the laser beam by controlling the polygon mirror based on the Nth focal length determined in step 510.

In order to adjust the divergence angle, there are a method of adjusting the distance between the two lenses and a method of electrically adjusting the curvature of the lens. However, the change rate of adjusting the distance between the lenses and adjusting the curvature of the lenses is low due to mechanical limitations. According to an embodiment of the present invention, it is preferable to adjust the focal position of the laser beam by adjusting the divergence angle of the laser beam in the polygon mirror 221 .

In step 530, the laser label printer irradiates the label paper with a laser beam to remove a part of the removal layer (depth of the distance d).

In step 540, the laser label printer determines whether or not the removal layer has been completed to a preset depth of barcodes, characters, images, etc. on the label sheet.

As a result of the determination, if there is an additional layer to be removed at a depth to be lost, step 550 is performed to correspond to the N+1th depth.

In step 550, the laser label printer determines the N+1 th focal length of the laser corresponding to the N+1 th depth of the label paper, and proceeds to step 510.

Referring back to FIG. 4 , when the removal layer 44 is removed once with a laser beam, the removal layer is removed by a distance d, and when the removal layer is removed twice, the removal layer is removed by a distance of 2d, and is removed three times. It can be seen that when the layer is removed, the dark sheet 45 is exposed by removing the removed layer at a distance of 3d.

As described above, the present invention has been described by specific details such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , Those skilled in the art in the field to which the present invention belongs can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and it will be said that not only the claims to be described later, but also all modifications equivalent or equivalent to these claims fall within the scope of the spirit of the present invention. .

200: laser unit 210: condensing lens
220: polygon scanner unit 221: polygon mirror
222: scan lens 230: label paper
31, 41: protective film 32: color layer
33, 43: transparent sheet 34, 44: removal layer
35, 45: Ammicite 36, 46: Ammicite protective film
37, 47: mucosal layer

Claims (7)

a laser unit oscillating a carbon dioxide laser beam;
a condensing lens for collimating or converging the oscillated laser beam;
It is disposed on the output side of the laser unit and the condensing lens, receives the carbon dioxide laser beam emitted from the laser unit, adjusts the refraction angle of the incident carbon dioxide laser beam to change the horizontal or vertical displacement, and scans in a predetermined direction. a polygon scanner unit; and
A laser label printer using a polygon scanner that includes labels on which barcodes, characters, or images are printed. According to claim 1,
The polygon scanner unit,
a polygon mirror having a plurality of reflective surfaces and having different angles for reflecting the laser beam according to changes in angles of the reflective surfaces; and
A laser label printer using a polygon scanner including a scan lens that refracts light at a constant velocity reflected from the polygon mirror in a scanning direction, corrects aberration, and focuses the light on a scanning surface on a label sheet. According to claim 2,
The polygon scanner unit is a laser label printer using a polygon scanner, characterized in that the position of the focus is formed differently according to the depth of the removal layer of the label paper. According to claim 2,
The label paper,
a removal layer in which the projected portion reacts and disappears when the laser beam is projected; and
A laser label printer using a polygon scanner that includes a dark sheet attached to the lower side of the removal layer, does not react to the laser beam, and is coated with color ink or composed of a film of the color. determining an N-th focal length of a laser beam corresponding to an N-th depth of the label paper to form at least one of a barcode, a character, or an image on the label paper;
adjusting a divergence angle of the laser beam by controlling a polygon mirror based on the determined N-th focal length;
irradiating the laser beam to the label sheet to remove the removal layer up to the N-th depth;
determining whether the removal layer has been removed to a preset depth of at least one of a barcode, text, and image on the label sheet; and
As a result of the determination, if the layer to be removed at a depth to be additionally removed remains, proceed to the step of determining the Nth focal length and determine the N+1th focal length instead of the Nth focal length. Label printing method used. According to claim 5,
The removal layer of the label paper is divided into at least one layer by applying color ink to the lower part of the transparent sheet according to the depth, and removing the removal layer to a preset depth by a laser beam emitted from the polygon scanner unit. Label printing method using a characterized laser label printer. According to claim 6,
Removing the removal layer to a predetermined depth by the laser beam emitted from the polygon scanner unit is a label printing method using a laser label printer, characterized in that to remove the removal layer by dividing the depth step by step.

Images