KR102143126B1 - Label Laminating device - Google Patents

Abstract

The present invention relates to a label laminating device, which is manufactured in a square box type made of aluminum, and a pressurizing handle 20 is detachably attached to the upper part, and a temperature control display unit 40 on the front side and a power supply unit 50 on the rear side. ) And a user interface unit 70 is mounted, and a heat transfer unit 30 is connected to the lower surface by a support, and a body 10 in which a control Raspberry Pi 3B 60 is embedded therein; A pressurizing handle 20 which is fixed to the upper part of the body and is molded of an oval-shaped aluminum material to be gripped and pressurized by a user when transferring a name tag; A bolt 31 and a nut 32 fixed to the lower part of the body, a square plate 33 for diagonally inserting and fixing the bolt 31 and nut 32, and another on the square plate 33 It is fixed by bolts 34 and nuts 35 that are inserted and fixed diagonally, and a heat transfer heat unit having a heater for thermally transferring the name tag to the fabric in which the transparent thermal transfer film 400 is fixed on the name tag ( 30) and; The RED display unit 41 indicating the actual temperature detected from the temperature sensor 36 for detecting the temperature of the thermal transfer unit, the GREEN display unit 42 indicating the temperature set by the user, and the temperature setting button 43 are respectively A temperature control display unit 40 configured to control and display the temperature of the heat transfer unit by receiving a command from the raspberry pi 3B 60; A power supply unit 50 provided with a three-hole socket 51 for an AC 220V plug insert and a tumbler switch 52 to supply power to the heat transfer unit and the temperature control display unit; A label, characterized in that it includes a Raspberry Pi 3B (60) that controls the driving of the heat transfer unit, a temperature control display unit, and a power supply unit, and enables communication with a computer, which is an external device, through a user interface unit (70). By providing a laminating device, the conventional problem is solved, and even when ordering in small quantities and large quantities, not only label transfers such as name tags etc. quickly and accurately with a small number of workers, but also bubbles or bubbles on the color thermal transfer film and It prevents the quality of nameplates from being deteriorated due to the occurrence of an air layer, and also allows you to check the counted thermal transfer nameplate work through real-time mobile service, so it has a unique effect that can actively cope with the quantity of orders for a large number of labels such as school uniform name tags for the new school season. have.

Description

Label Laminating device {Label Laminating device}

The present invention relates to a label laminating apparatus, and more particularly, to a label laminating apparatus in which a label (name tag) can be easily transferred to fabrics such as school uniforms, uniforms, etc. quickly and accurately even with a large number of ordered name tags.

Conventionally, nameplates attached to school uniforms are inserted into a hard nameplate case made of synthetic resin, or a printed nameplate mount is inserted by thermal fusion with a thermoplastic resin film such as polyethylene film or PVC film, and silk printing. B. How to use a pad printing machine, and felt for sewing embroidery.

These badges require a lot of complicated processes in handling the large amount of school uniforms during the new semester, so there is a problem that they are absolutely short of labor and cannot be processed within a set time. In addition, during the manufacturing process or use of the nameplate, a bending phenomenon occurs due to thermal deformation of the transparent paper due to UV exposure. In addition, by printing using a harmful organic solvent such as thinner, the working environment is poor and harmful to the human body, and there is a problem in that it is not possible to accurately express the clarity of prints or elaborate pattern patterns.

In order to improve the above-described problem, a number of patents have been proposed, such as a method of manufacturing a name tag in Korean Patent Publication (B1) No. 10-0997521 (2010.12.01).

However, the above proposed patent also has the same flexibility and flexibility as the brushed cloth, and the manufacturing process of the name tag such as the surface treatment of the base material to have waterproofness at the same time is very complicated. There are limitations that cannot be solved.

In particular, in the above patented technology, since the laminate that laminates the printing surface of the transfer printing paper during transfer is treated at a temperature of 180 to 200°C with only a heat press flat plate, the moisture of the fabric is rapidly transferred when the name tag is directly transferred to a fabric such as a school uniform. As it vaporizes, air bubbles are generated in the laminate laminated with the printing surface of the transfer printing paper, and the quality of the name tag is highly likely to be deteriorated.

Accordingly, the present invention solves all the above-described problems and proposes a completely new label laminating device.

Therefore, the present invention has been devised to overcome the above problems, and more specifically, a thermal transfer device including a heat transfer unit having a flat surface and a constant radius of curvature, a display unit for temperature control, a Raspberry Pi 3B, and a user interface unit. By implementing, it solves the conventional problems and transfers name tags quickly and accurately with a small number of workers even for large orders, and when transferring the name tags, bubbles are generated in the transparent thermal transfer film due to moisture vaporization of the fabric, resulting in poor quality of the name tags. The purpose of this is to provide a label laminating device capable of actively responding to the order quantity of school uniform name badges in the new school season by enabling confirmation of the counted nameplate warrior workload through real-time mobile service.

According to a feature of the present invention for achieving the above object, it is manufactured in a square box type made of aluminum, and the pressurizing handle 20 is detachable and attached, the temperature control display unit 40 on the front side and the power supply unit on the rear side. (50) and a user interface unit (70) is mounted, a heat transfer unit (30) is connected to the lower surface by a support, and a body (10) in which a control Raspberry Pi 3B (60) is built in; It is fixed to the upper part of the body, and at the upper part, when the user transfers the label, the pressing part 21 having a round oval shape that is in close contact with the palm and the support part 22 of the cylinder 22 connected to the pressing part is fixed to the body. A pressurizing handle 20 having a female threaded portion 23 formed to be fastened with the bolt 11; A bolt 31 and a nut 32 fixed to the lower part of the body, a square plate 33 for diagonally inserting and fixing the bolt 31 and nut 32, and another on the square plate 33 The thermal transfer heat unit 30 having a heater for thermally transferring the label attached to the transparent thermal transfer film 400 to the fabric and fixed by a bolt 34 and a nut 35 inserted and fixed diagonally. Wow; The RED display unit 41 indicating the actual temperature detected from the temperature sensor 36 detecting the temperature of the thermal transfer unit, the GREEN display unit 42 indicating the temperature set by the user, and the temperature setting button 43 are respectively A temperature control display unit 40 configured to control and display the temperature of the thermal transfer unit by receiving a command from a Raspberry Pi 3B (60); A power supply unit 50 provided with a three-hole socket 51 for an AC 220V plug insert and a tumbler switch 52 to supply power to the heat transfer unit and the temperature control display unit; It includes a Raspberry Pi 3B (60) that controls the driving of the heat transfer unit, the temperature control display unit, and the power supply unit, and enables communication with a computer, which is an external device, through the user interface unit 70. It provides a label laminating device characterized by.

According to another embodiment of the present invention, the thermal transfer heating unit 30 includes a 180° flat heating unit 37 of a certain standard and aluminum material, and a curvature heating unit 38 having a radius of curvature of 100 to 130°. It is molded and manufactured, and the flat heating part fixes the heat transfer transparent carrier film (300) with the printed name tag attached to the fabric, and then presses the pressure handle for 8 to 10 seconds at 150 to 165°C. Is attached, and the curvature heating unit, when the name tag is attached through the flat heating unit, protects the printed characters on the name tag and prevents air bubbles from occurring in the urethane-based or hot-melt-based transparent thermal transfer film. After fixing the name tag on the name tag, it is characterized in that the curvature heating part is gradually pressed from either side of the name tag for 8 seconds at 150° C. and laminated.

The label laminating apparatus according to an embodiment of the present invention can expect the following effects.

The present invention implements a thermal transfer device including a flat surface and a heat transfer unit having a constant radius of curvature, a temperature control display unit, a Raspberry Pi 3B, and a user interface unit,

It solves the conventional problem and prevents the quality of the name tag from being deteriorated due to the occurrence of bubbles in the transparent thermal transfer film due to moisture vaporization of the fabric when heat transfer of the name tag as well as the name tag transfer quickly and accurately with a small number of workers even for large orders. In addition, it has a unique effect of being able to actively cope with the number of orders for school uniform name tags in the new semester by being able to check the counted thermal transfer name tag work through real-time mobile service.

1 is a view showing a key component for a label manufacturing and laminating method according to a preferred embodiment of the present invention
Figure 2 is a flow chart showing the entire process for the label production and laminating method according to a preferred embodiment of the present invention
3 is a view showing a name media roll for label production and laminating method according to a preferred embodiment of the present invention
4 is a diagram showing a method of transferring a label with a flat and curvature thermal transfer device for a label manufacturing and laminating method according to a preferred embodiment of the present invention
Figure 5 is a view showing the direct printing of the name tag characters in a mirror type (Mirror Type) on the adhesive surface of the transparent thermal transfer film for the label production and laminating method according to a preferred embodiment of the present invention
6 is a diagram showing a thermal transfer ribbon output guide for a label manufacturing and laminating method according to a preferred embodiment of the present invention
7 is a block diagram showing the overall technical configuration of a label laminating device according to a preferred embodiment of the present invention
8 is a real photograph of a prototype showing a detailed configuration of a label laminating device according to a preferred embodiment of the present invention
9 and 10 are real photographs of a prototype showing another detailed configuration of FIG. 8

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, when adding reference numerals to the components of each drawing, it should be noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in the description of the present invention, when it is determined that detailed descriptions of related well-known configurations or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

First, a label manufacturing and laminating method using a label laminating device according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 6.

Referring to Figure 1, the technical component for the label production and laminating method according to an embodiment of the present invention, a color thermal transfer film (Color Thermal Transfer Film, 100) and a resin-based thermal transfer ribbon (Thermal Transfer Ribbon, 200). ), transparent carrier film (Transparent Carrier Film, 300) and urethane, hot melt-based transparent thermal transfer film (Transparent Thermal Transfer Film, 400).

Next, referring to Figs. 1 to 3, the label production and laminating method according to an embodiment of the present invention uses a color thermal transfer film (100) to suit the size of a name tag blog by Thomson. It has a first step (S100) of manufacturing a label media roll through (or Domusong) processing (see FIG. 3).

Here, the Thompson (or Domusong) processing refers to a method in which a knife is bent and inserted in the space between the laser cutting processing to suit the manufacturing size of labels such as name tags. In other words, after attaching the label processed by the Thompson method using the transparent carrier film 300 having an adhesive surface, it is to be moved to the desired position of the fabric so that it can be easily laminated.

In addition, the label media roll according to another embodiment of the present invention is manufactured according to a Pantone Number indicating a color, and the size of the label media roll in consideration of the size of a name tag (including a sign, etc.) is 1 Includes more that can be produced up to ~100cm wide.

Next, the produced label media roll according to an embodiment of the present invention includes a label editing program that is bundled software, a thermal transfer printer such as a label printer, a barcode printer, and a resin-based thermal transfer ribbon (TTR). It has a second step (S200) of printing the name tag of the individual using.

Here, the resin-based thermal transfer ribbon (TTR, Thermal Transfer Ribbon, 200) is a color-applied ink-paper type product, and varies from black to yellow, blue, green, matte silver, and mainly black and Use matte silver color. Black ribbon is mainly used for light colored thermal transfer film, and matte silver ribbon is used for dark colored thermal transfer film. There are various types such as wax, wax resin, resin, and wash care resin. Among them, in the embodiment of the present invention, printing is performed using the wash care resin, and printing can be performed using a label editing program, which is a bundle software described later, to print characters and various types of pictures. In addition, high-speed printing (2-8 inches per second) of a small amount of multiple products is possible, and hundreds to thousands of data can be printed at once with a single print using a database. In addition, a network-connected thermal printer can be printed easily with a label editing app (eg, bugallo) even with a smartphone.

In addition, as the resin-based thermal transfer ribbon (TTR, Thermal Transfer Ribbon, 200) used in the printer according to an embodiment of the present invention, a urethane-based or PVC-based film, which is a type of color thermal transfer film, may be used. In an embodiment of the present invention, it may include printing using a resin-based wash care resin that is safe for dry cleaning and does not scratch.

In addition, the thermal transfer printer according to an embodiment of the present invention is capable of printing both black and white and color, and any one of a label printer and a barcode printer is used for small printing of A4 paper or less, and more than A4 paper such as logos and photos. For large-sized color printing, the thermal transfer printer includes one of a solvent printer and a UV printer.

Next, a clothing object to thermally transfer a transparent carrier film (Transparent Carrier Film) 300, which is a thermal transfer material that has adhesive strength to remove and transfer the name tag label printed by the thermal transfer printer according to an embodiment of the present invention, and withstands high temperatures well. The third step (S300) of attaching the name tag label by attaching it to the position of and pressing the heating part at 150 to 165°C for 8 to 10 seconds with a flat thermal transfer device, cooling for 10 to 20 seconds, and then removing the transparent carrier film (S300) Has.

As described above, in the present invention, by using the transparent carrier film 300 for thermal transfer, a label such as a printed name tag can be quickly and accurately moved and attached to a desired location by a user.

Finally, in the embodiment of the present invention, after the third step, after fixing a transparent thermal transfer film 400 of urethane-based or hot-melt-series on the nameplate to protect printed characters or patterns, , A fourth step (S400) of laminating at 150 to 165°C for 8 to 10 seconds with a thermal transfer device with a thermal transfer device having a curvature radius of 100 to 130°.

Here, the reason why the radius of curvature of the heating part of the thermal transfer device is formed to be 100 to 130° is, when the name tag is transferred to the fabric using the thermal transfer device having a high temperature, color thermal transfer film and transparent thermal transfer This is to prevent bubbles from occurring between the films, resulting in poor quality of labels such as name tags. In other words, by using the thermal transfer device to gradually press from one side of the name tag along a certain curved surface first, an effect of removing air bubbles or air layers generated between the thermal transfer films can be achieved.

In addition, after the fourth step according to an embodiment of the present invention, in order to give a fabric feel, covering the desired fabric pattern and pressing once more for 8 to 10 seconds at 150 to 165°C using a heat transfer device having a flat heating part. Include.

Here, the use of the heat transfer device in which the heating unit is flat is to be prepared in case the edge portion of the name tag is not completely transferred by the heating unit of the thermal transfer device having the radius of curvature.

Meanwhile, referring to FIGS. 4 and 5, the label manufacturing and laminating method according to another embodiment of the present invention is a mirror type on the adhesive surface of the transparent thermal transfer film 400. ), directly printing the text of a label, such as a name tag, and attaching it to the location of the fabric desired by the user, and then laminating by pressing the heating unit at 150 to 165°C for 8 to 10 seconds with a flat thermal transfer device.

Here, printing in the mirror type refers to printing in a reversed image, such as when a label, such as a name tag, is turned over. In other words, by printing characters in reverse in the same way that the seal is engraved on the adhesive surface of a transparent thermal transfer film (400), separate labels such as printed name tags are separated and moved to the attachment position. Thermal transfer adhesion to fabric is possible without the need for a carrier film. This mirror-type printing process can reduce the process of using the conventional carrier film, so even for a large quantity of orders such as a small number of products, school uniforms for the new semester, etc., order quantity quickly and accurately through simple manpower and simple process without additional skilled technical manpower. It has a unique feature that can be processed within a period of time. In addition, after attaching the label, such as the name tag printed in the mirror type, to the fabric, it is transferred to the thermal transfer device and cooled for 10 to 20 seconds, and after cooling, the liner on the back side of the adhesive side of the transparent thermal transfer film is removed. do. Characters such as a name tag can be printed on the adhesive surface of the transparent thermal transfer film, and an easily detachable liner is integrally formed on the back surface of the printed adhesive surface. In addition, the object to be thermally transferred with the transparent thermal transfer film can be used not only for clothing such as school uniforms, but also for felt, Lycora, blended, plastic, and the like.

”형상을 갖는 제1 열전사 필름 간격조정 쇠(540a) 및“

”형상을 갖는 제2 열전사 필름 간격조정 쇠(540b)와, 상기 제1/제2 열전사 필름 간격조정 쇠에는 제1 열전사 필름 가이드 홈(541a,541b) 및 제2 열전사 필름 가이드 홈(542a,542b)이 각각 구비되는 열전사 필름 출력가이드(500)가 더 포함된다.Meanwhile, referring to FIG. 6, the thermal transfer printer according to a preferred embodiment of the present invention includes zinc or zinc in order to quickly and accurately print a name tag or pattern pattern on the thermal transfer film (TTF) at high speed. An iron plate 510 plated with nickel, a ruler 520 with a scale of 5 mm on the upper portion of the iron plate, and a first neodymium magnet 542a of a square having a certain standard and gauss at the center of the iron plate, and A groove 530 having a predetermined depth in which the second neodymium magnet 542b can move, and the “unified” with the magnets 542a and 542b

“The first thermal transfer film gap adjustment bracket (540a) having a shape and“

”The shape of the second thermal transfer film spacing adjustment bracket 540b, and the first/second thermal transfer film spacing adjustment brackets include first thermal transfer film guide grooves 541a and 541b and a second thermal transfer film guide groove A thermal transfer film output guide 500 provided with 542a and 542b, respectively, is further included.

Hereinafter, a label laminating apparatus according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 7 to 10.

First, referring to FIG. 7, the core technical configuration means of the present invention are, largely, a body 10 and a pressurizing handle 20 for transfer, a heat transfer heat unit 30 having a constant radius of curvature, and a heat transfer heat unit A temperature control display unit 40 for controlling the temperature, a power supply unit 50 having a switch, a Raspberry Pi 3B (60) capable of controlling the label laminating device and communicating with an external device, and connectable to external devices. It consists of a user interface unit (70).

7 and 8, the body 10 according to a preferred embodiment of the present invention is manufactured in a square box type made of aluminum, and the pressing handle 20 is fixed on the upper side, and the front side is A temperature control display unit 40 is positioned, and the power supply unit 50 and a user interface unit 70 are positioned on the rear surface of the display unit. In addition, the heat transfer unit 30 is located under the body, and the Raspberry Pi 3B 60 is installed inside the body.

In addition, with reference to FIGS. 7 and 8, the pressing handle 20 according to an embodiment of the present invention is a means for grasping and pressing by hand when a user transfers a label such as a name tag to a fabric such as a school uniform. , It is molded of aluminum and fixed at the upper portion of the body 10, the pressing portion 21 in close contact with the palm has a round oval shape, and the supporting portion 22 connected to the pressing portion is a cylinder in its lower part. A female threaded portion 23 is formed so as to be fastened with the bolt 11 fixed to the body 10.

In addition, with reference to FIGS. 7 to 10, the thermal transfer heat unit 30 according to an embodiment of the present invention uses a transparent thermal transfer film 400 to which a label such as the printed name tag is attached. As a heater means for thermal transfer by fixing it in a position, a bolt 31 and a nut 32 fixed to the lower portion of the body, but located under the body 10, the bolt 31, and It is fixed by a square plate 33 for inserting and fixing the nut 32 diagonally, and a bolt 34 and a nut 35 that are inserted and fixed diagonally to the square plate 33. In addition, a temperature sensor 36 for detecting the temperature of the thermal transfer unit 30 is embedded in the thermal transfer unit and is connected to the Raspberry Pi 3B 60.

Here, the temperature sensor 36 is connected to the Raspberry Pi 3B 60 to display the temperature sensed by the temperature sensor on the RED display unit 41 of the temperature control display unit 40 to be described later. This is to do.

In addition, the thermal transfer heating unit 30 according to an embodiment of the present invention uses a certain standard and aluminum material, and has a 180° flat heating unit 37 and a curvature heating unit 38 having a radius of curvature of 100 to 130°. ).

Here, the flat heating unit 37 according to an embodiment of the present invention is a uniform, uniform, etc. of clothing objects for thermal transfer of a thermal transfer transparent carrier film 300 to which a label such as a printed name tag is attached. After fixing at the desired location by the user, the name tag is firstly attached by pressing for 8 to 10 seconds at a temperature of 150 to 160°C. In addition, the curvature heating unit 38 is a means for laminating once more in order to protect printed characters or patterns such as name tags to be thermally transferred by molding and manufacturing the radius of curvature of the heat transfer unit at 100 to 130°. In the use of the curvature heating unit 38 according to the embodiment of, a urethane-based or hotmelt-based transparent thermal transfer film 400 is fixed on the nameplate and then transferred. In order to prevent the occurrence of bubbles or air layers in the yarn film 100 and the transparent thermal transfer film 400 to cause poor label quality such as name tags, first name tags along a certain curved surface through the curvature heating unit 38 Air bubbles or air layers can be prevented by gradually pressing them from either side of the.

In addition, with reference to FIGS. 7 and 8, the temperature control display unit 40 according to an embodiment of the present invention is a means for setting control and displaying the temperature of the thermal transfer heating unit 30, and the raspberry pi (Raspberry Pi) It is driven by the command of 3B (60), the RED display unit 41 indicating the actual temperature detected from the sensor 36 that detects the temperature of the thermal transfer unit 30 and the temperature set by the user. The indicated GREEN display unit 42 and the temperature setting button 43 are provided, respectively.

In addition, with reference to FIGS. 7 and 8, the power supply unit 50 according to an embodiment of the present invention is a means for supplying power to the label laminating device according to an embodiment of the present invention, and is for an AC 220V plug insert. A three-hole socket 51 is provided, and a tumbler switch 52 is provided next to the socket.

In addition, with reference to FIGS. 7 and 8, the Raspberry Pi 3B 60 according to an embodiment of the present invention includes the thermal transfer heating unit 30, a temperature control display unit 40, and a power supply unit ( 50) is a means for controlling the drive and enabling communication with a computer, which is an external device, by controlling the temperature of the heater built in the heat transfer unit 30 and controlling the power supply unit 50 The thermal transfer unit controls the power supplied to the heating unit 30 on/off, and controls the driving of the temperature control display unit 40. In addition, it is a means for enabling communication with a computer, which is an external device, through the user interface unit 70.

Here, the Raspberry Pi 3B according to an embodiment of the present invention is the latest model of a single board computer, and has a data processing speed compared to the first generation Raspberry Pi computer by mounting an ARM Cortex-53 quad core, which is a 64-bit processor. It is characterized by being 10 times faster. In addition, unlike the prior art, which had to be additionally installed, WiFi and Bluetooth wireless communication functions are installed on the computer board from the beginning. In addition, it is 2.5 times faster than the first-generation Raspberry Pi in single-thread processing, and the NEON video codec processing performance is 20 times faster.

In addition, with reference to FIGS. 7 and 8, the user interface unit 70 according to an embodiment of the present invention is a means that is connected to an external device, a computer, and connects to an app installed on a smart phone, and the Raspberry Pi Pi) The control of 3B (60) makes it possible to easily check the data from the outside of the large amount of name tag order order processing and name tag thermal transfer processing data.

Therefore, the Raspberry Pi 3B 60 according to an embodiment of the present invention controls the temperature of a heater built in the flat heating unit 37 and the curvature heating unit 38 of the thermal transfer heating unit 30, and , The temperature control display unit 40 can be driven and communicated with a computer as an external device.

The above description is merely illustrative of the technical spirit of the present invention, and those of ordinary skill in the art to which the present invention pertains will be capable of various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10: body 11,31,34: bolt
20: pressing handle 21: pressing portion
22: support portion 23: female threaded portion
30: heat transfer part 32,35: nut
33: square plate 36: temperature sensor
37: flat heating unit 38: curvature heating unit
40: temperature control display unit 41: RED display unit
42: GREEN display 43: temperature setting button
50: power supply
51: 3-prong socket for AC 220V plug insert
52: tumbler switch 60: raspberry pi 3B
70: User interface unit
100: color thermal transfer film 200: thermal transfer ribbon
300: transparent carrier film 400: transparent thermal transfer film
500: thermal transfer ribbon output guide 510: galvanized steel sheet
520: ruler 530: groove
540a,540b: 1st/2nd thermal transfer film spacing adjustment bracket
541a,541b: first/second thermal transfer film guide groove
542a, 542b: 1st/2nd neodium magnet

Claims (3)

It is manufactured in a square box type made of aluminum, and the pressurizing handle 20 is detached and attached, and the temperature control display unit 40 on the front side and the power supply unit 50 and the user interface unit 70 are mounted on the rear side, On the lower surface, the heat transfer unit 30 is connected by a support, and a body 10 in which a control raspberry pi 3B 60 is embedded;
It is fixed to the upper part of the body, and at the upper part, when the user transfers the label, the pressing part 21 having a round oval shape in close contact with the palm and the support part 22 of the cylinder 22 connected to the pressing part is fixed to the body. A pressurizing handle 20 having a female threaded portion 23 formed to be fastened with the bolt 11;
A bolt 31 and a nut 32 fixed to the lower part of the body, a square plate 33 for diagonally inserting and fixing the bolt 31 and nut 32, and another on the square plate 33 The thermal transfer heat unit 30 having a heater for thermally transferring the label attached to the transparent thermal transfer film 400 to the fabric and fixed by a bolt 34 and nut 35 inserted and fixed diagonally. Wow;
The RED display unit 41 indicating the actual temperature detected from the temperature sensor 36 for detecting the temperature of the thermal transfer unit, the GREEN display unit 42 indicating the temperature set by the user, and the temperature setting button 43 are respectively A temperature control display unit 40 configured to control and display the temperature of the heat transfer unit by receiving a command from a Raspberry Pi 3B (60);
A power supply unit 50 provided with a three-hole socket 51 for an AC 220V plug insert and a tumbler switch 52 to supply power to the heat transfer unit and the temperature control display unit;
It includes a Raspberry Pi 3B (60) that controls the driving of the heat transfer unit, a temperature control display unit, and a power supply unit, and enables communication with a computer, which is an external device, through the user interface unit 70. Label laminating device, characterized in that.
delete According to claim 1,
The thermal transfer heating unit 30 is molded and manufactured into a 180° flat heating unit 37 and a curvature heating unit 38 having a radius of curvature of 100 to 130° using a certain standard and aluminum material,
The flat heating unit attaches the name tag by fixing the heat transfer transparent carrier film 300 to which the printed name tag is attached to the fabric, and then pressing the pressure handle for 8 to 10 seconds at 150 to 160°C,
When the name tag is attached through the flat heating part, the curvature heating unit fixes the urethane-based or hot-melt-based transparent thermal transfer film on the name tag to protect the printed character of the label and prevent bubbles from occurring in the film. After that, a label laminating device, characterized in that laminating by gradually pressing from one side of the nameplate for 8-10 seconds at 150 ~ 160 ℃ with the curvature heating unit.

Images