KR101846003B1 - transfer printing apparatus - Google Patents

Abstract

The present invention relates to an image transfer apparatus for fabric fabrics, which is capable of transferring excellent images onto a flame retardant fabric having a very high temperature characteristic, such as aramid or carbon fabric, by using high frequency induction heating and electric heater heating.
The present invention relates to an image forming apparatus for transferring a desired image to a transfer sheet placing table 20 for mounting a transfer sheet F, a transfer sheet feeding table 30 for conveying guidance and feeding of the transfer sheet F, The printing apparatus 40 includes a fabric receiving table 50 for receiving the fabric M, a fabric feeding table 60 for conveying and feeding the fabric M, a transfer sheet F, A printing device 70 for printing an image printed on the transfer sheet F on the fabric M and a tail winding 80 for winding the printed fabric S on which the transfer printing is performed .
In the present invention, transfer printing can be performed using a heating body (transfer roller) having a high-frequency induction heating as a main heat source and an electric heater as an auxiliary heat source, thereby reducing the amount of electricity consumed, So that it is possible to perform transfer printing of an excellent print image on the flame retardant textile fabric.

Description

Transfer printing apparatus for flame retardant textile fabrics

The present invention relates to a transfer device for a flame-retardant textile fabric, and more particularly, to a transfer device for a flame-retardant textile fabric, and more particularly to a transfer device for a high-temperature flame retardant textile fabric such as an aramid or carbon fabric using high frequency induction heating and electric heater heating. And to provide a transfer device for a flame-retardant fabrics fabric.

Transfer printing for textile fabric is a printing technique in which a desired image is printed on a transfer paper, the transfer paper is attached to the fabric, and heat is applied to the transfer paper to melt the printed pigment on the fabric.

In general transfer printing, a transferring device having a heating plate or a heating roller for heating at about 150 DEG C is used. In this process, a fabric material and a transfer sheet are put into a transfer device, and then the transfer sheet is pressed by a heating plate, Is rolled onto a transfer sheet.

In fabric fabrics, flame retardant fabric fabrics such as aramid or carbon fabrics have very high temperature characteristics, and therefore, transfer printing using conventional transfer devices is not possible.

A flame retardant fabrics fabric such as aramid or carbon fabrics have a very high temperature characteristic. Therefore, when a heating plate or a heating roller to which an electric heating furnace is applied, the heating temperature is about 150 ° C., a proper printed image can not be obtained. In the case of raising the temperature of the heating roller, the amount of electricity consumed is considerably increased, and in the case of the heating roller, a warping phenomenon occurs due to an increase in the heating temperature, so that uniform pressing on the transfer paper is not performed, And the like.

In addition, in the conventional transfer printing, the process of outputting an image to a transfer sheet using a printer and the process of transfer printing to a fabric are separately performed, thereby increasing the number of processes and the cost of distribution, which causes a rise in the printing unit price .

The present invention has been made to solve all the problems occurring in the transfer printing process for the flame-retardant fabric fabrics as described above. The present invention provides a heating member (transfer roller) that uses high frequency induction heating as a main heat source and an electric heater as an auxiliary heat source And the temperature of the heating body is increased to 200 ° C. to 250 ° C. while reducing the consumption of electric power by making it possible to carry out the transfer printing by using the transfer printing To provide a transfer device for a flame-retardant textile fabric.

Still another object of the present invention is to provide a transfer device for a flame-retardant fabric so that an image can be outputted to a transfer sheet and an image transferring process can be organically performed in a single transfer device, In the future.

According to an aspect of the present invention, there is provided an image forming apparatus including: a transfer sheet receiving table for receiving a bobbin on which a transfer sheet is wound; a transfer sheet feeding unit for conveying the transfer sheet placed on the transfer sheet placing table; A digital printing device configured by installing a printer between a landing roller for landing and a second feeding roller for forcibly feeding a transfer sheet, a conveying guide for conveying the fabric held by the fabric placing table, And a fourth feeding roller for forcibly feeding the transfer material and the fabric material. The transfer roller and the fourth feeding roller are provided between the lapping roller and the fourth feeding roller, A printing fabric having transfer printing via the printing apparatus, That is configured as a fabric take-up stand or the like for the mounting of the bobbin is taken to the technical features.

The transfer device for a flame-retardant textile fabric according to the present invention can perform transfer printing by using a heating body (transfer roller) having a high-frequency induction heating as a main heat source and an electric heater as an auxiliary heat source, The temperature of the sieve body can be raised to 200 to 250 ° C to transfer a good print image onto the flame retardant fabric fabric, and the temperature of the heating body can be controlled flexibly, The process of outputting the image to the transfer sheet and the process of transferring the image to the cloth can be performed organically in a single transfer apparatus, thereby reducing the number of process steps and the cost of the transfer, thereby enabling economical transfer printing. This is a very beneficial invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a transfer device for a flame-retardant textile fabric according to the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]
3 is a cross-sectional view for explaining a configuration of a fabric stand and a cloth feeder according to the present invention.
FIG. 4 is a cross-sectional view illustrating a configuration of a digital printing apparatus according to the present invention. FIG.
5 is a sectional view for explaining a configuration of a printing apparatus according to the present invention;
6 is a perspective view showing an installation state of a transfer roller according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals as much as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

1 is a block diagram of a transfer device 10 for a flame retardant fabric according to the present invention. The transfer device 10 shown in FIG. 1 includes a transfer sheet holder 20, a transfer sheet F, A digital printing device 40 for outputting an image to the transfer paper F, a fabric holder 50 for loading the fabric F, M, a printing base 70 for printing an image outputted to the transfer sheet F on the fabric M, a printing base 70 for winding the printed printing fabric And a fabric reel 80. The detailed construction of each component according to the present invention is as follows.

2 is a reference view for explaining the constitution of the transfer receiving table 20 and the transfer sheet feeding table 30 according to the present invention. As shown in the figure, the transfer sheet receiving table 20 includes a bobbin A transfer frame mounting shaft 22 which is spaced apart from the bottom surface so as to be spaced apart from the bottom surface is provided in the support frame 21 installed on the bottom surface and the transfer sheet F is wound on the transfer sheet mounting shaft 22 So that the bobbin can be rotatably mounted.

The transfer paper sheet supply unit 30 is a unit for guiding the transfer of the transfer paper F placed on the transfer paper table 20 to the digital printing apparatus 40, A plurality of guide rollers 32 and 33 are provided on the front side of the fixing frame 31 on the side where the transfer paper is drawn and the first feeding motor D1 is driven on the rear side And a roller (34).

The first feeding roller 34 is composed of a pair of upper and lower feeding rollers 341 and 342 which are connected to each other. The first feeding roller 34 is connected to the rotation shaft of the first feeding roller 341 and the first driving motor D1) are connected by drive transmission means (belt, belt pulley, chain and chain sprocket, etc.) and drive gears (not shown) interlocking with the rotation shafts of the feed rollers 341, The feeding rollers 341 and 342 are driven in the reverse direction to forcibly transfer the transfer sheet F drawn between the feeding rollers 341 and 342. [

3 is a reference diagram for explaining the configuration of the digital printing apparatus 40 according to the present invention. As shown in the figure, the digital printing apparatus 40 includes an output table 42 provided on the output base 41, A landing roller 44 for stably landing the transfer sheet F supplied from the transfer sheet feeding table 30 on the upper side of the output table 42 is provided on the side of the output table 42 A second feeding roller 45 for forcibly feeding the transfer sheet F to the rear side (the side from which the transfer sheet is discharged) of the sheet feeding roller 40 is driven by the second driving motor D2, A printer 46 with an ink jet nozzle 461 facing downward is provided between the first and second feeding rollers 45 so that a desired image can be output to the transfer sheet F. The rear of the printer 46 A blowing fan 47 and a cooling cooler 48 are provided in the region of the transfer paper F, Dry the output dye is configured to be line.

The second feeding roller 44 is composed of a pair of upper and lower feeding rollers 441 and 442 which are connected to each other. The second feeding roller 44 is connected to the rotation shaft of the one feeding roller 441 and the second driving motor D2 are connected by drive transmission means (belt and belt pulley, chain and chain sprocket, etc.), drive gears (not shown) interlocking with the rotation shafts of the feed rollers 441, The respective feeding rollers 441 and 442 are driven in the reverse direction to forcibly feed the transfer sheet F drawn in between the feeding rollers 441 and 442.

4, there is shown a reference diagram for explaining the configuration of the fabric receiving table 50 and the fabric feeding table 60 according to the present invention. As shown in the figure, the fabric receiving table 50 includes a bobbin A far end mounting shaft 52 spaced apart from the bottom face at a predetermined distance is provided in a support frame 51 installed on the bottom face so that the fabric M is wound on the far end mounting shaft 52 So that the bobbin can be rotatably mounted.

The fabric feeder 60 is for guiding the feeding of the fabric M mounted on the fabric resting stand 50 and transferring the same to the printing apparatus 70. The fabric feeder 60 is provided on the side of the fixing frame 61 A plurality of guide rollers 62 and 63 are provided on the front side of the stationary frame 61 on the side where the cloth is drawn and a third feed roller 63 driven by the third drive motor D3 is provided on the rear side (64).

The third feeding roller 64 is composed of a pair of upper and lower feeding rollers 641 and 642 which are connected to each other. The third feeding roller 64 is connected to the rotation shaft of the one feeding roller 641 and the third driving motor D3 are connected by drive transmission means (belt and belt pulley, chain and chain sprocket, etc.), and drive gears (not shown) interlocking with the rotation shafts of the feed rollers 641, The feeding rollers 641 and 642 are driven in the reverse direction to force the fabric M drawn between the feeding rollers 641 and 642 to be fed.

5 is a reference view for explaining the configuration of the printing apparatus 70 according to the present invention. As shown in the figure, the printing apparatus 70 includes a printing table 71, A laminating roller 73 is provided on the side where the transfer paper and the cloth are drawn so that the transfer paper F and the cloth material M passing through the digital printing apparatus 40 and the cloth feeding table 50 are joined together, And a fourth feeding roller 74 driven by a fifth driving motor D5 is provided on the rear side of the printing table 72 (the side where the transfer paper and the cloth are discharged) And a transfer roller 75 driven by a fourth driving motor D4 is installed in the area between the lapping roller 73 and the fourth feeding roller 74 A detection sensor 77 is provided around the transfer roller 75 to sense the temperature of the transfer roller 75 and apply it to the control device A control device 76 for controlling the driving of the transfer roller 75 is provided on the upper side of the printing table 72 and a cooling water circulating device 78 is provided on one side of the printing base 71, And a cooling cooler 79 is installed on the rear side of the transfer roller 75 (in the direction in which the transferred transfer paper and the fabric are discharged) to dry the dye printed on the fabric M.

The fourth feeding roller 74 is composed of a pair of upper and lower feeding rollers 741 and 742 that are connected to each other. The fourth feeding roller 74 is connected to the rotation shaft of the one feeding roller 741 and the fifth driving motor D5 are connected by drive transmission means (belt and belt pulley, chain and chain sprocket, etc.) and drive gears (not shown) interlocking with the rotation shafts of the feed rollers 741, The feeding rollers 741 and 742 are driven in the reverse direction to forcibly transfer the transfer sheet F and the cloth M drawn between the feeding rollers 741 and 742. [

The cloth winding table 80 transfers the final printed fabric S transferred and transferred to the cloth M by thermal fusion of the image outputted to the transfer cloth F via the printing device 70, A fabric take-up shaft 82 which is spaced apart from the bottom surface so as to be spaced apart from the bottom surface is provided in the support frame 81 that is placed on the bottom surface, And the sixth drive motor D6 and the far-end winding shaft 82 provided on the support frame 81 are connected to each other by drive transmission means (belt, belt pulley, chain and chain sprocket, etc.) The printing cloth S is wound on the bobbin fixed to the original-end winding shaft 82 while the original-winding shaft 82 is rotated by driving the driving motor D6.

6 is a perspective view showing an installation state of the transfer roller 75 according to the present invention. As shown in the figure, a hollow support shaft 751 supported by a support bracket B fixed to a print table 72 A heating roller 752 having a heating coil (not shown) heated by external input electricity is rotatably mounted on the outer peripheral surface of the heating roller 752 and a cover roller 753 of a material having excellent thermal conductivity is disposed on the outer peripheral surface of the heating roller 752 And a high frequency transmission coil 754 is provided between the heating roller 752 and the cover roller 753 to receive the high frequency generated in the high frequency generating device provided inside the control device 76.

The temperature sensor 77 installed close to the cover roller 753 transmits the sensed temperature information to the controller 76 to display the temperature of the cover roller 753 through the display window, Both ends of the support shaft 751 are connected to a cooling water circulation device 78 provided in the printing base 71 and the cooling water is circulated through the support shaft 751 under the control of the control device 76. [

A driving means 756 composed of a belt pulley or a chain sprocket is installed on the driving shaft of the fourth driving motor D4 by fixing and securing driven means 755 comprising a belt pulley or a chain sprocket to the heating roller 752 The driven roller 752 can be driven to rotate on the support shaft 751 by driving the fourth drive motor D4 by connecting the driven means 755 and the driving means 756 by a power transmitting means comprising a belt or a chain .

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. And will be apparent to those skilled in the art.

10: Transfer device 20: Transfer paper holder
30: Transfer paper supply unit 40: Digital printing device
50: Fabric holder 60: Fabric feeder
70: printing device 80: printing fabric spool

Claims (2)

A transfer sheet receiving table 20 having a transfer sheet mounting shaft 22 for receiving a bobbin around which a transfer sheet F is wound, a plurality of transfer sheet guide rollers 20 for conveying the transfer sheet F stuck to the transfer sheet receiving table 20, And a first feeding roller 34 for feeding a transfer sheet F passing through the transfer sheet guide rollers 32 and 33 is provided so as to be driven by the first driving motor D1, A landing roller 44 for stably landing the transfer sheet F supplied from the transfer sheet feeding table 30 on the upper surface of the output table 42 is provided on the side of the feeding table 30 and the output table 42, A second feeding roller 45 for forcibly feeding the transfer sheet F is provided on the rear side of the output table 42 so as to be driven by the second driving motor D2 and the landing roller 44, A printer 46 with the ink jet nozzle 461 facing downward is provided between the printer 45 and the printer 46, A digital printing apparatus 40 constituted by installing a blowing fan 47 and a cooling cooler 48 for drying the dyestuff output from the fabric and a fabric mounting shaft 52 for mounting the fabric fabric M, And a fabric guide rollers 52 and 53 for guiding the conveyance of the fabric M placed on the fabric resting stand 50. The fabric rollers 52 and 53 pass through the fabric guide rollers 52 and 53, A third feeding roller 54 for feeding the first printing medium P and a third feeding roller 54 driven by the third driving motor D3, a digital printing device 40 on the side of the printing table 72, A laminating roller 73 for laminating the transfer material F and the fabric material M via the belt 50 is provided and the transfer sheet F and the fabric material M The fourth feed roller 74 is provided to be driven by the fifth drive motor D5. The fourth drive roller D5 drives the lapping roller 73 and the fourth The transfer roller 75 driven by the fourth drive motor D4 is provided in the area between the transfer roller 75 and the transfer roller 74 and the temperature of the transfer roller 75 is sensed around the transfer roller 75, A control device 76 for controlling the driving of the transfer roller 75 is provided on one side of the upper surface of the printing table 72 and a control device 76 for controlling the driving of the transfer roller 75 is provided on the rear side of the transfer roller 75 A fabric take-up shaft 82 capable of fixing a bobbin for winding a print fabric S transferred and printed via the printing apparatus 70, a cooling device 79 having a cooling cooler 79 mounted thereon, And a raw-end wind-up table (80) constituted by connecting a raw-end wind-up shaft (82) and a sixth drive motor (D6) by drive transmission means, the transfer device (10)
The transfer roller 52 provided on the printing table 72 is provided with a heating coil which is heated by external input electricity to a hollow supporting shaft 751 supported by a supporting bracket B fixed to the printing table 72 And a cover roller 753 having a good thermal conductivity is disposed to surround the outer circumferential surface of the heating roller 752. The heating roller 752 and the cover roller 753 are disposed to surround the outer circumferential surface of the heating roller 752, Frequency transmission coil 754 is installed between the control unit 76 and the control unit 76 so as to receive the high frequency generated by the high frequency generating unit provided inside the control unit 76. Both ends of the support shaft 751 are connected to the cooling water circulation unit And the cooling water is circulated through the support shaft 751 under the control of the controller 76. The temperature sensor 77 installed close to the cover roller 753 senses the sensed temperature information And transmits it to the control device 76, The temperature of the cover roller 753 is displayed and the driven unit 755 including the belt pulley or the chain sprocket is installed and fixed to the heating roller 752. The belt drive pulley The driving means 756 comprising the chain sprocket is provided and the driven means 755 and the driving means 756 are connected to each other by power transmission means comprising a belt or a chain so that the heating roller 752 Is rotatably driven on the support shaft (751). ≪ IMAGE > delete

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