KR20100021915A - Digital image high speed printing device of vertical-type textile printing - Google Patents

Abstract

The present invention relates to a vertical printing type digital image high-speed output device using a piezo jet, wherein the dye cartridge does not move, and the dye cartridge is moved at high speed by one width unit or a desired width unit while moving the dyestuff such as a fabric vertically. It is a vertical printing type digital image high-speed output device that can be continuously printed by increasing the productivity by the printing, and the heat generated in the dye cartridge by the high-speed printing is forced cooling.

In addition, the present invention is to be configured to be printed while moving the chlorine vertically at a high speed, so that the single-sided printing or double-sided printing, in the case of double-sided printing, the printing printing cartridge and the device on both sides based on the chlorine is installed in a symmetrical structure.

In addition, the present invention is a dry high-speed printing is possible because the wet printing device and the work process is unnecessary, there is no waste water, etc., there is an environment-friendly feature.

Description

DIGITAL IMAGE HIGH SPEED PRINTING DEVICE OF VERTICAL-TYPE TEXTILE PRINTING}

The present invention relates to a high-speed digital image printing device that prints vertically using a piezo jet. Specifically, the dye cartridge is installed horizontally, and the dyestuffs such as fabrics move vertically at a high speed by one width unit or desired. Productivity is greatly improved by making the single-sided or double-sided printing in the width unit to be continuous, and the heat generated in the dye cartridge by the high-speed printing is forced cooling to enable continuous printing.

In general, the process of actually outputting a digital image is prepared by using a computer and related software such as graphic editing programs such as CorelDraw, Photoshop, and illustrations, and then using a program for raster image processing (RIP). Computer graphics data is generated and then output (or printed or printed) to a large image output device.

The advantage of real-time printing using such a large-scale image output device is that the computer outputs the data edited to the printed object as it is, so that images or photographs can be expressed as originally intended rather than the manual printing method. You can make

That is, any bitmap or vector type image or graphic image or digital image (hereinafter referred to as 'image') that can be inputted to a computer, such as an image, a picture, a picture, a character, a figure, or the like can be directly output to the toxin. In addition, various directing effects by computer graphics software can be output as they are, contributing to the next step.

Meanwhile, in the case of a thermal print (bubble jet method) used for high-speed printing, a plurality of dye cartridges print a predetermined section or line by line while reciprocating in the width direction (orthogonal direction in which the fabric progresses) of the dyestuff. Since the printing speed is very slow, the efficiency is low, and since there is no proper means for cooling the high heat generated in the dye cartridge by the high speed printing, it is difficult to print (or print) for a long time, and the printing operation is performed for heat dissipation of the dye cartridge. There was a problem that productivity is greatly reduced because it is frequently interrupted during this process.

In addition, since the dye cartridge is reciprocated, it is difficult to accurately determine the initial dye injection position, which may cause an error in the speed control.If such an error occurs, the dye injection position is not accurate and the print focus is shifted so that the quality is greatly reduced. have. In the case of high-speed printing that supports bidirectional printing, there is a problem in that a print position error occurs and print quality is degraded due to the play of the joint.

In addition, there is a smooth operation of the servomotor and the injection limit of the nozzle, and because the cartridge is a moving structure, the precision and speed are low, the head can touch or rub, the head can be caught in the blood, and the blood can be torn. In severe cases, not only the cartridge is damaged but also the residues, bubbles, etc. due to the above-described phenomenon, there is a nozzle clogging phenomenon, there is a problem such as cleaning the dye residues by a separate cleaning means or by manual.

Textile printing, one of the dyeing methods of textile products, is a wet method of partially dyeing fabrics or fabrics that are dyes and dyeing them with a pattern. It is not possible to take a number of working processes including drying, which takes too much time and is complicated, resulting in poor productivity, and it takes up a lot of work space and requires a separate device to purify dyeing wastewater. have.

According to the present invention, the dye cartridge installed horizontally when printing is not moved, and printing of one width (full width or wide) or a desired width unit is carried out while the dyestuffs such as fabrics move at a high speed vertically (in a non-contact manner). The purpose of the present invention is to provide a digital image high speed output device of a vertical printing method that is greatly improved in productivity and environmentally friendly.

Another object of the present invention is to provide a digital printing device of the vertical printing method to print, while printing the high-speed moving of the chlorine vertically, which can be a single-sided printing or double-sided printing.

Another object of the present invention is to install a plurality of dye cartridges arranged by color, but the vertical printing that can output a digital image of a width (full width or wide width) or a desired width unit by removing the edge portion between the dye cartridges at high speed It is characterized by providing a high speed digital image output device.

Still another object of the present invention is to provide a vertical print type digital image high-speed output device capable of continuously outputting a cooling means in the dye cartridge part by forcibly cooling the heat generated in the dye cartridge part by a high speed output. .

Another object of the present invention is to provide a large-scale digital image high-speed output device equipped with a drying unit that can quickly dry the transported after being printed vertically by installing the electrothermal heater-type dryer on one side or both sides of the chlorine; There is a characteristic.

Still another object of the present invention is to allow the dye cartridge to move to one side (HOME) to allow the dye cartridge to move to the groove when the printing operation is stopped or completed, and moved to the home by a stopper moved by the moving means It is characterized by providing a high-speed output device for digital image output (hereinafter referred to as 'high speed output device') to prevent the evaporation, drying and clogging of the dye by allowing the nozzles of the dye cartridge to be closed respectively.

The high speed output device of the present invention continuously outputs a large digital image at a high speed on the surface of the chlorine that moves vertically, and the cartridge module of one width (full width or wide) unit is horizontally installed so that it does not move when printing. do.

Drive rollers and driven rollers installed on both sides of the high-speed output device allow the high speed printing of one width unit or desired width unit while driving the vertically constant speed (or driving speed controlled by the user or output program). An environmentally friendly digital image output device having greatly improved productivity by being continuously contactless is provided.

The present invention is a feed roller wound with the chlorinated object to be printed, a driving roller and driven roller for vertically conveying the tainted material, a servo motor and a power transmission means for rotating the drive roller, and one side of the tainted material (cross section) ) Or a printing unit that prints continuously on both sides (both sides) by one width unit or a desired width, a cartridge module composed of a plurality of dye cartridges and installed horizontally, and the cartridge module is printed on a printing unit and a groove (HOME) A moving means for moving, a dye supply source and an auxiliary dye supply source for supplying dye to the plurality of dye cartridges, a cooling unit having a predetermined volume formed on one side of the dye cartridge, and air forcibly supplied with air to the cooling unit. A nozzle stopper for sealing a supply source, a drying unit for drying the printed dyestuff, a nozzle of a dye cartridge moved to a home, and the furnace It comprises a moving means for moving the jingle, and a speed sensor and a controller for detecting the moving speed of the blood.

In addition, the dye cartridge is composed of a unitary dye chamber and a long nozzle, and a cooling chamber formed on one side of the dye chamber.

In addition, the dye cartridge is installed in a plurality of dye cartridges of short length in a zigzag form, but each of the adjacent dye cartridges are installed overlapping each other arranged without the nozzles spaced apart or overlapping, there is no edge portion that the image is not output, dye On one side and the other side of the yarn, the cooling chamber is formed in a zigzag shape and cooled to allow continuous output at high speed.

In addition, the dye cartridge, a plurality of short length of the dye cartridges are installed in an oblique form, but each of the adjacent dye cartridges are installed so that the nozzles are arranged without being spaced apart or overlapping, so that the edge portion where the image is not output is configured In this case, the cooling chamber may be zigzag on one side and the other side of the dye chamber.

The drying unit is installed horizontally in the discharged part after the chlorine is printed so that the dried chlorine can be quickly dried, the inlet is formed on one side of the body, 60 ℃ ~ 70 ℃ of the required to dry in the direction of the chlorine A heat dissipation hole for discharging hot air is formed, and a plurality of electric heaters and a temperature sensor for detecting a heating temperature are respectively installed in the body, and a fan motor provided with an intake fan is installed in the intake port so as to move vertically at high speed. The chlorine is almost completely dry.

The conveying means for moving the cartridge module consisting of a plurality of dye cartridges to the printing or grooves, a pair of guide rods installed in parallel on both sides of the cartridge module, a servo motor provided in the body portion, and a rotating shaft of the servo motor It is composed of a drive belt coupled, a driven pulley axially installed on the bracket of the body portion, a belt wound around the drive pulley and the driven pulley, and an attachment for connecting the outer side of the belt and one side of the cartridge module. On both sides of the body, a proximity sensor is installed to stop the cartridge module moved to the printing or groove.

The cartridge module is formed with a plurality of coupling grooves are arranged to mount a plurality of color-specific dye cartridges in a row or zigzag form, one side of the coupling groove the support and the engaging portion holding the dye cartridge coupled to the coupling groove And a handle portion protruding from each other, one side of the coupling groove of the cartridge module is provided with a corresponding terminal to which the terminal of the cartridge module is connected, and a signal line connected to the corresponding terminal is connected to the controller.

In addition, a dye injection tube is installed in the dye chamber of the dye cartridge, and the dye injection tube is connected to the supply hose through a distribution pipe to supply dye, and an air injection tube, an air discharge pipe, and a temperature sensor are installed in the cooling chamber. In addition, the air injection pipe is connected to the supply hose through the distribution pipe is supplied with cooling air.

The controller of the present invention not only stores image data itself through a memory unit, but also independently edits and outputs a computer and a terminal connected to the controller through an input / output unit (or an input / output interface or an input / output porter). It is possible to print large size images at high speed by receiving print data from the connected device.

In the present invention, in the case of the double-sided printing structure in which the dye cartridges are installed on both sides of the tainted material, the symmetrical printing device and its peripheral devices are installed on both sides of the tainted material, and the controller can control the printing device of the symmetrical structure respectively or simultaneously. It is configured to be.

The high speed output device of the present invention is divided into a high speed output device of a single-sided printing method that prints only one side of a to-be-retained moving object vertically, and a high speed output device of a double-sided printing method to print each or both surfaces simultaneously of a high-speed moving device vertically. .

According to the present invention, one dye cartridge or a pair of symmetric dye cartridges are installed horizontally with respect to a space in which the dyes move vertically, and the fabric of the dyes is moved in a vertical direction in a non-contact manner close to the dye cartridge. Since the cross-section printing or the double-side printing of the width unit or the desired width unit is made in succession, there is an effect that the productivity is greatly improved.

In addition, the present invention has the effect that the high heat generated in the dye cartridge by high-speed output is forced cooling by the cooling means can be continuously output without a break so that the productivity is greatly improved.

In addition, the present invention has a plurality of dye cartridges are arranged in the same width or slightly larger than the fabric width without the edge portion arranged in the digital image of one width unit or the desired width unit has the effect of high-speed output.

In addition, the present invention is that the dye cartridge is moved to the home (HOME) by the moving means when the printing operation is stopped or completed, the nozzle stopper is moved by the moving means to close the nozzle of the dye cartridge, evaporation and drying of the dye and nozzle clogging This has the effect of being prevented.

In addition, the present invention is dried immediately after the flame retardant, but there is an effect that it is rapidly dried at a temperature of 60 ℃ ~ 70 ℃ by an electric heater and a dryer of the blowing fan method.

In addition, the present invention has the effect of flattening the tainted material by the pair of drive rollers and driven rollers, guide rollers.

In addition, the present invention is because the chlorine is moved vertically, so that the supply roller is installed on the floor or the ground, so even if the circumferential diameter of the supply roller is large and the weight increases, there is no effect on the printing.

In addition, the dye in the present invention has a degree of affinity and affinity for the fabric to be stained, the life of the output image is almost semi-permanent, and in the case of rotary printing or screen printing is severe contamination, but the present invention is a printing method using the piezo effect Therefore, there is an effect that can be environmentally friendly printing to prevent the contamination of pollution and environmental pollution.

In addition, the present invention can be printed on both sides to separate and print both sides of the chromosome in different images (patterns and patterns) and / or other colors, and the desired density and / or contrast can be set through the controller to add high-value fiber fabric It is a very useful invention that can produce such effects.

In describing the present invention, the same elements in the drawings are denoted by the same reference numerals as much as possible, and detailed descriptions of related well-known structures or functions will be omitted in order not to obscure the subject matter of the present invention.

In the present invention, the high-speed output of the salts include various fabrics, papers, textile papers, etc., and are referred to as "stains" for convenience of description.

The present invention is a vertical printing type digital image high speed output device (hereinafter referred to as 'high speed output device') is a high-speed output device of the vertical printing method of the cross-section printing only one side of the bleeding material that is moved vertically and high speed, both sides of the bleeding material moving vertically and high speed It is divided into high-speed output device of double-sided vertical printing method printing each or simultaneously.

1. Cross Section Vertical Printing  High speed output device.

1 is a schematic configuration diagram of a vertical printing type digital image high speed output device of the present invention (hereinafter, abbreviated as 'high speed output device') for printing a vertical moving moving object in cross section, and FIG. The cartridge module and its peripheral devices are installed on one side of 2) to print one side, that is, the cross-section, of the toner 2.

The high-speed output device 1 is a pair of drive rollers for pulling up and transporting the feed roller 3 on which the chlorine 2 of a predetermined width is wound, and the chlorine 2 of the feed roller 3. 4) and driven rollers 5, power transmission means 6 and servomotor 7 for rotating the drive rollers 4 at constant speed (or at a speed controlled by the controller), and the cartridge module 15. And a pair of guide rollers 8 and 9 for adjusting the transfer tension of the tainted substance 2 so that the printed tainted substance 2 can be unfolded flatly, and a pair of upper and lower pairs guiding the moving direction of the tainted substance 2. Guide rollers 10 and 10a, a speed sensor 11 for detecting a conveying speed of the chlorine 2, a dye chamber 12 and a dye chamber 12 of a predetermined volume (predetermined space) in which dyes are stored. And a plurality of dye cartridges 14 and a plurality of dye cartridges 14, each of which consists of a cooling chamber 13 of a predetermined volume (predetermined space) in which a cooling source such as air or cooling water circulates. Is a cartridge module 15, a printing unit 16 for continuously printing in one width unit or a desired width unit of the blood stain 2 by the cartridge module 15 positioned when printing, and a plurality of dyes necessary for printing. A dye pump for supplying each of the dye cartridge 14, the secondary dye supply source 17 and its supply hose 18 and the dye supply source (19) to the secondary dye supply source 17 so as to be naturally supplied for each color. 20 and its supply hose, an air pump 21 for supplying air for cooling to each cooling chamber 13, its supply hose 22, dye cartridge 14 and cartridge module ( 15), the air pump 21, the pump 20 of the dye supply source 19, the servo motors 7, 23, etc. can be controlled, and computers, various terminals, communication networks, communication interfaces, USB interfaces, etc. can be connected. The controller 24 having the input / output unit IO and the sensor input, the dye cartridge 14 and the controller ( A signal line 25 connecting the 24, a drying unit 26 for rapidly drying the printed salted material 2 with hot air at 60 ° C to 70 ° C, and a printing part 5 as long as it is not printed or as necessary. Moving means 28 and nozzles of the dye cartridge 14 to move to the one side groove 27 in which the nozzle stopper 30 is located and to the printing part 16 in which the tainted material 2 is located when printing. A plurality of cylinders 31 for sealing or opening the nozzle portion 14 of the dye cartridge 14 by moving the nozzle stopper 30 arranged in a plurality of moving plates 29 corresponding to the position, and the moving plate 29. ) And proximity sensors 32 and 33 for detecting that the cartridge module 15 moves to the printing unit 16 and the groove 27.

In the present invention, since the chlorine 2 is moved vertically, the feed roller 3 may be installed on the floor or the ground as shown in FIG. It does not cause any trouble. The supply roller (3) is installed on the top to achieve printing by the method in which the chlorine (2) is moved downwards vertically, but because the initial diameter of the feed roller (3) is large and heavy, in the present invention As shown in FIG. 1, it is preferable to install the supply roller 3 on the floor or the ground so that the tainted material 2 can be printed while being vertically moved upward.

In addition, the guide rollers 10 and 10a are installed at the upper and lower portions where the tainted substance 2 moves to guide the tainted substance 2 to move vertically, and the supply roller 3 is separated from one side of the guide roller 10. Installed, the chlorinated material 2 is drawn out to the guide roller 10 and moved vertically.

In the present invention, the chlorine discharged after the printing and drying after the guide roller 10a is wound on the winding roller 3a which is rotated by the servo motor 7a and the power transmission means 6a which are controlled by the controller 24. By being wound up, deflection to the bottom is prevented.

Of course, instead of the servomotor 7a, the power transmission means 6a, and the winding roller 3a, a bucket, not shown, may be installed so as to contain the salted prints in the bucket.

The drying unit 26 is installed at the portion where the printed salted material 2 is discharged, and the body 35 has a rectangular cylindrical shape and is parallel to the printed portion 16.

An intake port 36 is formed at one side of the body 35, and one or more lines of parallel heat sinks 37 are formed at the other side of the body 35 in the longitudinal direction of the body 35. (35) Inside the plurality of heat transfer heaters 38 and evenly arranged at equal intervals and a temperature sensor 39 for detecting the heating temperature is installed, the inlet port 36 is provided with a fan motor 40 having an intake fan is provided Hot air of 60 ° C. to 70 ° C. required for rapid drying of the chlorine 2 is evenly discharged downward in the direction of the chlorine 2 through the heat dissipation hole 37, so that the chlorine 2 to be printed and transported is quickly dried. .

The conveying means 28 is a pair of guide rods 43 and 44 installed in parallel with a plurality of brackets 41 and 42 on both sides of the cartridge module 15 and the body 45 of the groove 27. Servo motor 23 to be installed in, the drive belt 46 coupled to the rotating shaft of the servo motor 23, the driven pulley 48 is installed on the shaft portion 45 bracket 47, the drive pulley ( 46) and an endless belt 49 wound around the driven pulley 48, and an attachment 50 connecting the outer side of the belt 49 to one side of the cartridge module 15.

Accordingly, when the servo motor 23 rotates in the clockwise direction of FIG. 2 by the controller 24, the driving pulley 46, the belt 49, and the driven pulley 48 rotate clockwise, and the belt 49 and The cartridge module 15 is connected to the attachment 50 so that the cartridge module 15 moves in the direction of the printing part 16 along the guide rods 42 and 44 fixed to the body 35 as shown in FIG. 3. do.

When the cartridge module 15 moving in the direction of the printing portion 16 approaches the proximity sensor 32 installed in the body 35, the proximity sensor 32 transmits an approach signal to the controller 24. ) Stops the servomotor 23, the cartridge module 15 stops on the printing part 16, and on one side thereof the printing object to be printed 2 is printed.

The controller 24 may not only store image data itself through the memory unit M, but also edit and output independently, and may be connected to the controller 24 through an input / output unit (IO) or a communication porter. It is possible to output large size images in high speed printing method by receiving printing data from a computer or connecting device such as various terminals.

On the other hand, the controller 24 operates the servomotor 7 so that the tainted material 2 moves forward at a high speed, and the plurality of dye cartridge 14 nozzles 14n operate according to the printing data and the control signal to print. This is done.

The controller 24 sets the data such as the length, the length of printing and the width of printing, the resolution, the number of printing cycles, and the like in part or all of the data through the setting unit S. It is transmitted and set through a computer or a terminal connected to the unit IO.

The control unit 24 stores various data necessary for printing in the memory unit M, and if necessary, reads image data (or printing data) from the memory unit M and outputs the printing of the same pattern again. It may be.

If necessary, after printing the printing data of various pattern patterns in the memory unit (M), it is possible to read or edit the necessary printing data to quickly print the printed matter 2 to one width or a desired width.

In the present invention, the dye cartridge 14 is configured to have the same width or slightly longer width as compared with the toxin 2.

For example, as shown in FIG. 11, a unitary dye cartridge having a long length (a width equal to or slightly longer than a blood stain), that is, cyan (C), magenta (M), yellow (Y) and black (K) colors, may be used. The dye cartridges 14b, 14c, 14d, and 14e are composed of an integrated dye chamber 12 and a cooling chamber 13 formed integrally on one side of the dye chamber 12. Because of the printing by the nozzle, there is no edge part where the image is not output.

In the case of the integrated dye cartridges 14b, 14c, 14d and 14e, the intermediate middle of the dye chamber 12 and the cooling chamber 13 is connected to the dye chamber 12 and the cooling chamber 13 by connecting members, respectively. It is preferable to prevent structural weakening, and the lower part of the connection member is connected to each other is composed of one dye chamber (12).

In the case of the cooling chamber 13, it can be configured as an integrated unit consisting of a single space, like the dye chamber 12, but for a more effective cooling comprises a plurality of separate cooling chambers, the cooling air flows into each cooling chamber and Emissions result in faster response to cooling air flow, resulting in more efficient cooling.

In addition, the dye cartridge 14 of the present invention is installed in a zigzag form of a short length dye chamber 12 as shown in Figure 12, each adjacent dye chamber 12 is installed so that the overlap (one side or both sides overlap) nozzles 14n are arranged so as to be arranged without being spaced apart or overlapped in the longitudinal direction, so that the edge portion where the image is not output is eliminated, and a dye cartridge of the same length or slightly longer length as the width of the dye 2 is formed. When the dye cartridge 14 of this configuration is installed in the cartridge module 15 by color, and configured to supply colors by color, for example, cyan (C), magenta (M), yellow (Y) and black (K) dyes, respectively. High speed output is achieved. The cooling chamber 13 is formed in a zigzag form on one side and the other side of the dye chamber 12 of the dye cartridges 14b, 14c, 14d, and 14e.

10 is a dye supply source 19, a supply hose 18, and a dye injection tube to naturally supply dyes necessary for printing to the dye chambers 12 of the dye cartridges 14b, 14c, 14d, and 14e. An air pump 21, a supply hose 22, a distribution pipe 65, and air, which are connected to the 61 and the distribution pipe 62, supply air for cooling to the respective cooling chambers 13. The injection pipe 63 and the air discharge pipe 64 are connected and installed.

In addition, the dye cartridge 14 of the present invention, as shown in Figure 13 is installed a short length of the dye cartridge 14 in the inclined type (of course the dye cartridge in the same direction), but each of the adjacent dye cartridges 14 overlap (one side or both sides) And the nozzles 14n are arranged without being spaced or overlapped so that the edge portion where the image is not output is eliminated. The dye cartridge is constructed, and the dye cartridge of this configuration is installed in the cartridge module 15 by color to supply the colors, for example, cyan (C), magenta (M), yellow (Y) and black (K) dyes. When configured, high speed output is achieved. Then, the cooling chamber 13 is formed in a zigzag form on one side and the other side of the dye chamber 12 of the dye cartridge 14.

14 shows an embodiment of the present invention dye cartridge 14, the cartridge module 15 is formed with a plurality of coupling grooves 52 are arranged to mount a plurality of dye cartridges 14 for each color On one side of the coupling groove 52, the support portion 53, which protrudes upward from the upper or upper edge portion of the dye cartridge 14 coupled to the coupling groove 52, prevents the position of the dye cartridge 14 from protruding upward. The engaging portion 54 and the handle portion 55 are protruded from the top of the finger portion 53.

The dye cartridge 14 is composed of a case 56, a separator 57, an upper cover 58, and the like, and a terminal 59 for controlling the nozzle 14n is formed on an outer side surface of the dye chamber 12. The terminal 59 is connected to a corresponding terminal 60 installed at one side of the coupling groove 52 of the cartridge module 15 and through a signal line 25 (or a data bus) connected to the corresponding terminal 60. Is connected to the controller 24.

A dye injection tube 61 is installed in the dye chamber 12 of the dye cartridge 14, and the dye injection tube 61 is connected to the supply hose 18 through a distribution tube 62, and thus an auxiliary dye. Injection of dyes of a certain height through the source 17 is naturally achieved.

An air injection pipe 63, an air discharge pipe 64, and a temperature sensor 51 are installed in the cooling chamber 13, and the air injection pipe 63 is supplied to the supply hose 18 through a distribution pipe 65. Therefore, the cooling air of the air pump 21 is forced into the cooling chamber 13, so that high heat of 40 ° C to 60 ° C is cooled and maintained at 10 ° C to 30 ° C, thereby enabling continuous high speed output.

The controller 24 adjusts the blowing pressure of the air pump 21 based on the temperature detection signal input from the temperature sensor 51. That is, when the temperature input from the temperature sensor 51 is higher than the set temperature range, the air pump 21 is accelerated. On the contrary, when the temperature input from the temperature sensor 51 is lower than the set temperature range, the air pump is accelerated. It is controlled to maintain constant temperature in a predetermined range while decelerating (21).

In the present invention, the supply hose (18) 22 and the signal line 25 is a coiled structure or a cable tray (or cable tie) to allow the cartridge module 15 to sufficiently move to the printing portion 16 and the groove 27. Structure, which is a technology used in other industries, and thus detailed description thereof will be omitted.

The speed sensor 11 detects the transfer speed of the tainted substance 2 and inputs it to the controller 24 so that the tainted substance 2 can move at a constant speed so that the rotational speed of the driving roller 4 is controlled. Likewise, it may be installed between the supply roller 3 and the guide roller 10, or may be installed near the guide rollers 8 and 9 as shown in FIG.

The controller 24 compares and determines the feed signal input from the speed sensor 11 and the preset reference feed signal through the setting unit S of the controller 24, so that the feed speed of the tainted substance 2 is within the reference feed speed range. The servo motor 7 is controlled to be transferred to.

In the high speed output device 1 of the present invention, a plurality of dye cartridges 14 are arranged in the printing unit 16 for each of the basic colors, and the output image signal is transmitted to the dye cartridge 14 by the controller 24 to be tainted. Productivity is greatly improved by making high speed printing of one width | variety (total width) unit or a desired width unit be made in succession at once in the cross section of (2).

The dye cartridge 14 generates a large amount of heat by the high speed output, but is forcedly cooled by the cooling air flowing into the cooling chamber 13, thereby preventing deterioration of the printing quality of the chlorine 2 and high speed output of the large digital image. Will be able to continue.

In the present invention, the dye cartridge 14 is a color dye supplied from the dye supply source 19 and the auxiliary dye supply source 17, as shown in Figures 2 to 4, such as cyan (C), magenta (M), yellow ( The dye cartridge 14, to which Y) and black (K) dyes are supplied, is arranged in the width direction of the dye solution 2, and is connected to the auxiliary dye supply source 17 and the supply hose 18, and the dye continues to be consumed. The dye supply through the supply hose 18 is continuously supplied to a certain height by the natural atmospheric pressure, the secondary dye supply source 17 is a basic color dye from the dye supply source 19 by the dye pump 20 and the hose Each is supplied.

The auxiliary dye supply source 17 is installed in the upper and lower limit sensor (not shown), the dye is supplied in a certain amount, the dye of the auxiliary dye supply cylinder 17 is a dye cartridge (at a certain height through the supply hose 18 by natural atmospheric pressure) 14).

Piezo jet dye cartridge 14 shown as an example of the present invention is installed in a detachable structure in the coupling groove 52 of the cartridge module 15, one by one for each of the basic colors C, M, Y, K or , Or a plurality of basic colors C, M, Y, and K.

For example, the dye cartridge 14 to which the cyan (C), magenta (M), yellow (Y) and black (K) dyes are supplied is composed of one structure for each color and installed in the orthogonal direction of the toxin 2. A dye for each color, which is configured to be able to print one width of the dye 2, or which is supplied with cyan (C), magenta (M), yellow (Y), and black (K) dyes, each of which is composed of a plurality of dyes. The cartridge 14 is installed in the orthogonal direction of the toner 2.

The dye cartridge 14 is installed in the orthogonal direction of the chlorine (2), the dye chamber 12 is formed on one side, the cooling chamber 13 is formed on the other side, the controller (below the dye chamber 12) The ceramic head and the nozzle of the piezo effect which are controlled by 24) are comprised.

In the present invention, when printing is not finished or printing is stopped due to breakdown or failure, the servo motor 23 is rotated by the moving means 28, so that the cartridge module 15 moves to the groove 27, When the sensor 33 senses the approach of the cartridge module 15 and inputs it to the controller 24, the servomotor 23 is stopped and the moving plate 29 and the nozzle cap are moved by the moving means 31 as shown in FIG. 9. Since the 30 moves to block the nozzle 14n, clogging of the nozzle 14n and drying and evaporation of the dye are prevented.

When the high speed output of the large digital image is started or resumed, as shown in FIG. 8, the moving plate 29 and the nozzle cap 30 are reversely moved by the moving means 31 to expose the nozzle 14n, and the servo is exposed. As the motor 23 rotates in reverse, the cartridge module 15 moves to the printing unit 16 as shown in FIG. 3 to start high-speed printing.

In the present invention, as shown in Figs. 4, 7 and 10, between the chlorine 2 and the nozzle 14n are separated by 2 mm to 5 mm to enable high-speed printing without physical contact.

In the present invention, the cooling water or the liquid refrigerant may be circulated to the cooling chamber 13 to obtain a better cooling effect, but there is a problem of dew condensation caused by condensation. In the present invention, the dye cartridge is circulated by cooling the cold air or cold cooled air. By cooling (14), condensation is prevented and cooling efficiency is excellent.

The dye has a degree of texture and affinity for the chlorine (2), the life of the output image is almost semi-permanent, and in the case of rotary printing or screen printing, the contamination is severe, but the present invention is a printing method using the piezo effect, environmental pollution This is avoided.

In the present invention, the number of the dye cartridges 14 having the respective colors is the number that can cover the width of the dye 2, and can be appropriately added or subtracted.

The controller 24 receives the edited image by a computer and controls one or more dye cartridges 14 so that a digital image of one width unit or a desired width unit can be output at high speed.

In the high speed output device 1 of the present invention, since the dye cartridge 14 is fixed and the dye is directly injected and controlled by the control signal of the controller 24, the dye dispensing position is very accurate and the printing quality is excellent.

The present invention can be used to print or print the printed matter, such as a large banner or advertising fabric dry dyeing the dye, and the print output is not only capable of outputting the designed picture or photo as it is, photo, image, picture, There is no restriction on the insertion of logos, the number of colors and colors is free, and the quality of printed matter is clean and luxurious.

2. Double sided vertical Printing  High speed output device.

FIG. 15 is a schematic configuration diagram of a vertical printing type digital image high speed output device of the present invention (hereinafter, abbreviated as 'high speed output device') for printing a vertically moving moving object in cross section, and FIG. On the basis of (2), the cartridge module and its peripheral devices are symmetrically installed on both sides to print each side or both sides of the dye 2 at the same time.

The high-speed output device 1 is a pair of drive rollers for pulling up and transporting the feed roller 3 on which the chlorine 2 of a predetermined width is wound, and the chlorine 2 of the feed roller 3. 4) and driven roller 5, power transmission means 6 and servomotor 7 for rotating the drive roller 4 at constant speed (or at a speed controlled by the controller), cartridge module 15, 15a. Guide rollers (8) (9) for adjusting the transfer tension of the tainted material (2) so that the printed tainted material (2) can be unfolded while passing through), and up and down to guide the moving direction of the tainted material (2). A pair of guide rollers 10 and 10a, a speed sensor 11 for detecting a conveying speed of the chlorine 2, and a dye chamber 12 and 12a of a predetermined volume (predetermined space) in which dyes are stored. And a plurality of dye cartridges 14 and 14a adjacent to the dye chambers 12 and 12a and composed of cooling chambers 13 and 13a of a predetermined volume (predetermined space) through which a cooling source such as air or cooling water circulates. Plural dye cartridges 14 The cartridge modules 15 and 15a in which 14a are arranged by color and the cartridge modules 15 and 15a positioned when printing are continuously printed in one width unit or a desired width unit. Auxiliary dye supply source (17) (17a) and its supply hose (18) for supplying the printing unit (16) and (16a) and the dyes necessary for printing to each of the plurality of dye cartridges (14) (14a), respectively, to be naturally supplied by color. 18a, the dye pumps 20 and 20a for supplying the dyes from the dye supply sources 19 and 19a to the auxiliary dye supply sources 17 and 17a, their supply hoses, and air for cooling. ) To the respective cooling chambers 13 and 13a, the air pumps 21 and 21a, the supply hoses 22 and 22a, the dye cartridges 14 and 14a and the cartridge module 15 ( 15a), air pumps 21, 21a, dye pumps 19, 19a, pumps 20, 20a, servo motors 7, 23, 23a, and the like, and control computers and various terminals or communications. Network, communication interface, USB interface A controller 24 having an input / output unit IO and a sensor input so as to belong thereto, signal lines 25 and 25a connecting the dye cartridges 14 and 14a and the controller 24, and the salted blood The nozzle section 30, 30a of the drying part 26 (26a) which dries (2) rapidly by hot air of 60 degreeC-70 degreeC, and the printing part 5, 5a while not printing or if necessary. At the nozzle position of the moving means 28 and 28a and the dye cartridges 14 and 14a, which are moved to one side grooves 27 and 27a, which are located at the time of printing. Correspondingly, the nozzle stoppers 30 and 20a arranged in large numbers on the movable plates 29 and 29a and the movable plates 29 and 29a are moved to move the nozzles 14n of the dye cartridges 14 and 14a. A plurality of cylinders 31 and 31a for sealing or opening, and a proximity module 32 for detecting the movement of the cartridge modules 15 and 15a to the printing parts 16 and 16a and the grooves 27 and 27a. 32a, 33, and 33a.

In the present invention, since the chlorinated material 2 is moved vertically, the supply roller 3 may be installed on the floor or the ground as shown in FIG. It does not cause any trouble. The supply roller (3) is installed on the top to achieve printing by the method in which the chlorine (2) is moved downwards vertically, but because the initial diameter of the feed roller (3) is large and heavy, in the present invention As shown in FIG. 15, it is preferable to install the feed roller 3 on the floor or the ground so that the tainted material 2 can be printed while being vertically moved upward.

In addition, the guide rollers 10 and 10a are installed at the upper and lower portions where the tainted substance 2 moves to guide the tainted substance 2 to move vertically, and the supply roller 3 is separated from one side of the guide roller 10. Installed, the chlorinated material 2 is drawn out to the guide roller 10 and moved vertically.

In the present invention, the chlorine discharged after the printing and drying after the guide roller 10a is wound on the winding roller 3a which is rotated by the servo motor 7a and the power transmission means 6a which are controlled by the controller 24. By being wound up, deflection to the bottom is prevented.

Of course, instead of the servomotor 7a, the power transmission means 6a, and the winding roller 3a, a bucket, not shown, may be installed so as to contain the salted prints in the bucket.

The drying units 26 and 26a are installed at the portion where the printed salted substances 2 are discharged, and the bodies 35 and 35a are rectangular cylindrical and parallel to the printed portions 16 and 16a. .

One inlet 36 or 36a is formed at one side of the body 35 or 35a, and one line or one in the longitudinal direction of the body 35 or 35a is to the other side of the body 35 or 35a. More than one row of heat dissipation holes 37 and 37a are formed, and the plurality of heat transfer heaters 38 and 38a arranged evenly at equal intervals inside the body 35 and 35a and the temperature sensor 39 for detecting the heating temperature. (39a) is installed, the inlet port (36, 36a) is provided with fan motors (40, 40a) with an intake fan is installed, the hot air of 60 ° C ~ 70 ° C required for rapid drying of the chlorine (2) 37) (37a) is discharged evenly downward in the direction of the chlorine (2), so that the chlorine (2) to be printed and transported is quickly dried.

The conveying means 28, 28a is a pair of guide rods 43, 43a which are installed in parallel with a plurality of brackets 41, 41a, 42, 42a on both sides of the cartridge module 15, 15a. (44) (44a), the servo motors (23) and (23a) provided in the body parts (45) and (45a) of the grooves (27) and (27a) are coupled to the rotating shafts of the servomotors (23) and (23a). Drive belts 46 and 46a, driven parts 48 and 48a which are axially mounted to the body parts 45 and 45a and brackets 47 and 47a, and drive pulleys 46 and 46a and driven pulleys. Attachments 50 for connecting the endless belts 49 and 49a which are wound around the 48 and 48a and the outer one side of the belts 49 and 49a and one side of the cartridge modules 15 and 15a. ) 50a.

Accordingly, when the servo motors 23 and 23a rotate in the clockwise direction of FIG. 16 by the controller 24, the driving pulleys 46 and 46a, the belts 49 and 49a, and the driven pulleys 48 and 48a are rotated. It rotates in a clockwise direction, and the belts 49 and 49a and the cartridge modules 15 and 14a are connected by attachments 50 and 50a so that the cartridge modules 15 and 15a are fixed to the body 35. The guide rods 42, 42a, 44 and 44a are moved in the direction of the printing portions 16 and 16a as shown in FIG.

When the cartridge modules 15 and 15a moving in the direction of the printing parts 16 and 16a approach the proximity sensors 32 and 32a installed in the bodies 35 and 35a, the proximity sensors 32 and 32a are moved. Since the access signal is transmitted to the controller 24, the controller 24 stops the servomotors 23 and 23a so that the cartridge modules 15 and 15a stop at the printing portions 16 and 16a. On one side is a print object (2).

The controller 24 may not only store image data itself through the memory unit M, but also edit and output independently, and may be connected to the controller 24 through an input / output unit (IO) or a communication porter. It can print high-speed images in high-speed printing method by receiving printing data from a computer or connecting device such as various terminals.

In the case of performing the single-sided printing, the one side cartridge module 15 or 15a is moved to the printing unit 16 or 16a for printing, and in the case of the double-sided printing, both cartridge modules 15, 15a are printed in the printing unit ( 16) (16a) are moved to print each.

At this time, in the case of double-sided printing, both sides of the dye 2 can be separated or printed in different images (patterns and patterns) and / or different colors, respectively, and the desired density and / or contrast can be set through the controller. Thus, it is possible to produce high value-added fiber fabrics.

On the other hand, the controller 24 operates the servomotor 7 so that the dye 2 moves vertically at a high speed, and the dye cartridges 14, 14a and the nozzles 14n are moved in accordance with the printing data and the control signal. In operation, printing occurs.

The controller 24 sets the data such as the length, the length of printing and the width of printing, the resolution, the number of printing cycles, and the like in part or all of the data through the setting unit S. It is transmitted and set through a computer or a terminal connected to the unit IO.

The control unit 24 stores various data necessary for printing in the memory unit M, and if necessary, reads image data (or printing data) from the memory unit M and outputs the printing of the same pattern again. It may be.

If necessary, after printing the printing data of various pattern patterns in the memory unit (M), it is possible to read or edit the necessary printing data to quickly print the printed matter 2 to one width or a desired width.

In the present invention, the dye cartridges 14 and 14a have the same width or a slightly longer width as compared with the chloride 2.

For example, as shown in FIG. 11, a unitary dye cartridge having a long length (a width equal to or slightly longer than a blood stain), that is, cyan (C), magenta (M), yellow (Y) and black (K) colors, may be used. The dye cartridges 14b, 14c, 14d, and 14e are composed of an integrated dye chamber 12 and a cooling chamber 13 formed integrally on one side of the dye chamber 12. Because of the printing by the nozzle, there is no edge part where the image is not output.

In the case of the integrated dye cartridges 14b, 14c, 14d and 14e, the intermediate middle of the dye chamber 12 and the cooling chamber 13 is connected to the dye chamber 12 and the cooling chamber 13 by connecting members, respectively. It is preferable to prevent structural weakening, and the lower part of the connection member is connected to each other is composed of one dye chamber (12).

In the case of the cooling chamber 13, it can be configured as an integrated unit consisting of a single space, like the dye chamber 12, but for a more effective cooling comprises a plurality of separate cooling chambers, the cooling air flows into each cooling chamber and Emissions result in faster response to cooling air flow, resulting in more efficient cooling.

In addition, the dye cartridge 14, 14a of the present invention is installed in a zigzag form of a short length dye chamber paper 12 as shown in Figure 12, but overlapping each other dye chambers 12 (one side or both sides overlap) The nozzles 14n are arranged so that the nozzles 14n are arranged without being spaced apart or overlapped in the longitudinal direction, so that the edge portion where the image is not outputted is eliminated, and the dye having the same length or slightly longer length as the width of the chlorine 2 The cartridge is constructed, and the dye cartridges 14 and 14a of such a configuration are installed in the cartridge modules 15 and 15a by color, for example, by colors, such as cyan (C), magenta (M), yellow (Y) and black. High-speed output is achieved by configuring each of the (K) dyes to be supplied. The cooling chamber 13 is formed in a zigzag form on one side and the other side of the dye chamber 12 of the dye cartridges 14b, 14c, 14d, and 14e.

10 is a dye supply source 19, a supply hose 18, and a dye injection tube to naturally supply dyes necessary for printing to the dye chambers 12 of the dye cartridges 14b, 14c, 14d, and 14e. An air pump 21, a supply hose 22, a distribution pipe 65, and air, which are connected to the 61 and the distribution pipe 62, supply air for cooling to the respective cooling chambers 13. The injection pipe 63 and the air discharge pipe 64 are connected and installed.

In addition, the present invention dye cartridge 14, 14a is installed in the oblique type (dye cartridge of the same direction) of the short length of the dye cartridge 14 as shown in Figure 13 but overlap each other dye cartridge 14 ( One or both sides are installed so that the nozzles 14n are arranged without being spaced or overlapped so that the edge portion where the image is not output is eliminated. A dye cartridge of a long length is constructed, and the dye cartridge of this configuration is installed in the cartridge module 15, 15a by color, for example, by color, such as cyan (C), magenta (M), yellow (Y) and black ( K) High-speed output is achieved by configuring each dye to be supplied. Then, the cooling chamber 13 is formed in a zigzag form on one side and the other side of the dye chamber 12 of the dye cartridge 14.

16 to 21, the cartridge modules 15 and 15a are installed in a symmetrical structure around the tainted object 2, and the cartridge modules 15 and 15a are provided with grooves 27 and 27a and a printing portion ( The nozzles of the dye cartridges 14 and 14a are moved by moving the moving means 28 and 28a for moving to the 16 and 16a, and the moving plates 29 and 29a provided with the nozzle caps 30 and 30a, respectively. A plurality of cylinders 31 and 31a for sealing or opening the portion 14n are provided in a symmetrical structure, respectively.

In the discharge port direction of the printing parts 16 and 16a, a pair of drying parts 26 and 26a for rapidly drying the printed dyestuffs 2 with hot air at 60 ° C to 70 ° C are referred to the pickling material 2. It is installed on both sides in symmetrical structure.

The cartridge modules 15 and 15a have integral dye cartridges 14b, 14b ', 14c, 14c', 14d, 14d ', 14e and 14e', or short length dye cartridges 14b. 14b ', 14c, 14c', 14d, 14d ', 14e, 14e', or dye cartridges 14, 14a and cartridge modules 15, 15a consisting of warp dye cartridges. ) Is installed in a symmetrical structure.

22 illustrates an embodiment of the dye cartridge 14 and 14a of the symmetrical structure of the present invention. The cartridge modules 15 and 15a of the symmetrical structure are provided with a plurality of color-specific dye cartridges 14 and 14a. A plurality of coupling grooves 52 and 52a are arranged to be mounted, and the upper side of the dye cartridges 14 and 14a coupled to the coupling grooves 52 and 52a on one side of the coupling grooves 52 and 52a. Alternatively, the pressurized portions 53 and 53a protruding upward from the upper edge portions to prevent the positional deviation of the dye cartridges 14 and 14a, and the catching portions 54 are disposed on the upper portions of the edge portions 53 and 53a. 54a and the handles 55 and 55a are formed to protrude.

The dye cartridges 14 and 14a are composed of cases 56 and 56a, separators 57 and 57a, top covers 58 and 58a, and outer sides of the dye chambers 12 and 12a. The terminals 59 and 59a for controlling the nozzle 14n are configured, and the terminals 59 and 59a are installed at one side of the coupling grooves 52 and 52a of the cartridge modules 15 and 15a. It is connected to the corresponding terminal 60, 60a, and is connected to the controller 24 via signal lines 25, 25a (or a data bus) connected to the corresponding terminal 60, 60a.

Dye injection pipes 61 and 61a are installed in the dye chambers 12 and 12a of the dye cartridges 14 and 14a, and the dye injection pipes 61 and 61a are distribution pipes 62 and 62a. Is connected to the supply hose (18) (18a), so that the dye injection of a certain height is naturally achieved through the auxiliary dye supply (17) (17a).

The air injection pipes 63 and 63a, the air discharge pipes 64 and 64a, and the temperature sensors 51 and 51a are installed in the cooling chambers 13 and 13a, and the air injection pipes 63 and 63a are provided. Is connected to the supply hoses 18 and 18a through the distribution pipes 65 and 65a. Therefore, the cooling air of the air pumps 21 and 21a is forced into the cooling chambers 13 and 13a and 40 ° C. High heat of ~ 60 ℃ is maintained at 10 ℃ ~ 30 ℃ to enable continuous high speed output.

The controller 24 adjusts the blowing pressure of the air pumps 21 and 21a based on the temperature detection signal input from the temperature sensors 51 and 51a. That is, when the temperature input from the temperature sensors 51 and 51a is higher than the set temperature range, the air pumps 21 and 21a are accelerated, and conversely, the temperature input from the temperature sensors 51 and 51a is set. When the temperature is lower than the temperature range, the air pumps 21 and 21a are decelerated to maintain constant temperature in a predetermined range.

In the present invention, the supply hoses 18, 18a, 22, 22a and the signal lines 25, 25a are provided with the cartridge modules 15, 15a having the printing parts 16, 16a and the grooves 27 ( 27a) is a coiled structure or a cable tray (or cable tie) structure to be sufficiently moved to, and the detailed description is omitted because it is a technology used in other industries.

The speed sensor 11 detects the feed rate of the tainted substance 2 and inputs it to the controller 24 so that the tainted substance 2 can move at a constant speed so that the rotational speed of the driving roller 4 is controlled. Likewise, it may be installed between the feed roller 3 and the guide roller 10, or may be installed near the guide rollers 8 and 9 as shown in FIG.

That is, the controller 24 compares and determines the feed signal input from the speed sensor 11 and the preset reference feed signal through the setting unit S of the controller 24, so that the feed rate of the tainted material 2 is transferred to the reference feed. The servomotor 7 is controlled to be transported in the speed range.

In the high speed output device 1 of the present invention, a plurality of dye cartridges 14 and 14a are arranged for each of the basic colors in the printing unit 16 and 16a, and an output image signal is output by the controller 24 to the corresponding dye cartridge ( 14) 14a, so that the high speed printing of one width (total width) unit or desired width unit is successively carried out at the same time on the cross section of the to-be-contaminated material 2, and productivity is greatly improved.

The dye cartridge 14 (14a) is a large amount of heat is generated by the high-speed output, but is forcedly cooled by the cooling air flowing into the cooling chamber (13) (13a) to prevent the deterioration of print quality of the chlorine (2) High speed output of large digital images can be continued.

In the present invention, the dye cartridge 14 (14a) is a color dye supplied from the dye source (19) (19a) and the auxiliary dye source (17) (17a), such as cyan (C), magenta (M), yellow ( Dye cartridges 14 and 14a to which Y) and black (K) dyes are supplied are arranged in the width direction of the dye solution 2, and auxiliary dye supply sources 17, 17a, hoses 18, 18a, and the like. Even though the dye is continuously consumed, the dye supply is continuously supplied at a predetermined height by natural atmospheric pressure through the supply hoses 18 and 18a, and the dye pump 20 is supplied to the auxiliary dye supply sources 17 and 17a. Basic color dyes are supplied from the dye supply source 19 by 20a and a hose, respectively.

The auxiliary dye supply sources (17) and (17a) are provided with upper and lower limit sensors (not shown) to supply a certain amount of dye, and the dyes of the auxiliary dye supply containers (17) and (17a) are supplied by natural atmospheric pressure to the supply hoses (18) and (18a). It is supplied to the dye cartridge 14 (14a) at a predetermined height through the).

Piezo jet dye cartridge 14, 14a of the present invention shown as an example of the present invention is installed in the coupling groove 52, 52a of the cartridge module 15, 15a in a detachable structure, the basic color C, One for each M, Y, or K, or a plurality of basic colors C, M, Y, and K.

For example, the dye cartridges 14 and 14a, to which cyan (C), magenta (M), yellow (Y) and black (K) dyes are supplied, have one structure for each color to be orthogonal to the salts 2. The cyan (C), magenta (M), yellow (Y), and black (K) dyes, each of which is provided in a direction to be configured to be able to print one width of the to-be-contaminated material 2 or each of which is provided in a plurality, The dye cartridges 14 and 14a for each color are arranged in the orthogonal direction of the toxin 2.

The dye cartridge 14 (14a) is installed in the orthogonal direction of the chlorine (2), the dye chamber 12 (12a) is formed on one side, the cooling chamber 13 (13a) is formed on the other side, Below the dye chambers 12 and 12a, a piezo effect ceramic head and a nozzle under the control of the controller 24 are formed.

On the other hand, in the present invention, when printing is not finished or printing is stopped due to breakdown or failure, etc., the servo motors 23 and 23a are rotated as shown in FIG. 15) 15a moves to the grooves 27 and 27a, and when the proximity sensors 33 and 33a sense the approach of the cartridge modules 15 and 15a and input them to the controller 24, the servo motor 23 (23a) is stopped, the moving plate 29 and 29a and the nozzle cap 30 (30a) by the moving means 31, 31a as shown in Fig. 20 to block the nozzle (14n) nozzle Blocking of (14n) or drying and evaporation of dyes are prevented, and the same applies to the cartridge module and its peripheral devices that are symmetrically installed based on the contaminant (2) in the case of simultaneous printing.

When the high speed output of the large digital image is started or resumed, as shown in FIG. 21, the moving plates 29 and 29a and the nozzle caps 30 and 30a are reversed by the moving means 31 and 31a. The nozzle 14n is exposed, the servomotors 23 and 23a are reversely rotated, and the cartridge modules 15 and 15a move to the printing parts 16 and 16a so that high speed printing starts, The same applies to the cartridge module and its peripheral devices that are symmetrically installed with respect to the toxin 2.

24 is a circuit block diagram of the controller 24 shown as an example of the present invention.

Data such as the length of the tainted material 2, the length of the printed matter and the width of the printed matter, the resolution, the number of repeated prints, etc. are appropriately set at the input of the control unit C, which is constituted by the CPU, and the operating time and the A setting unit (S) consisting of a keypad capable of setting a feeding speed, etc., and a reset part for resetting in case of a controller abnormality, a speed sensor (11) for detecting a feeding speed of the tainted substance (2), Proximity sensors 32, 32a, 33, 33a for detecting the approach of the cartridge module 15, 15a, and temperature sensors 39, 39a for sensing the temperature of the dryer 26, 26a, and And temperature sensors 51 and 51a for sensing the temperatures of the cooling chambers 13 and 13a, various image data (or print data), edit data, image editing programs, and various operation programs and control programs necessary for high-speed output. Memory unit M, etc., and an input / output unit (IO: or communication unit) for exchanging data with a computer or various terminals. Interface) is connected.

The data of the memory unit M is read and updated by the control unit C and used for high-speed output, and newly created or input data, correction data, operation data, etc., through a computer and various terminals are input / output unit ( Input and / or input / output via IO (or communication interface).

The output of the control unit C includes data such as the type of the blood 2 and the set value (control value) such as the output width and length, the current value, the operation state of the high speed output device 1, the basic image and the edited image. And the display unit D on which the image output position and the like are displayed, the servo motors 7 and 7a for rotating the driving roller 4, and the cartridge modules 15 and 15a. Servo motors 23 and 23a moving to the grooves 27 and 27a, and electrothermal heaters 38 installed inside the dryers 26 and 26a so as to generate hot air necessary for quick drying of the contaminant 2. (38a) and fan motors (40) and (40a), dye pumps (20) and (20a) for supplying color dyes to auxiliary dye supply sources (17) and (17a), and respective cooling chambers (13) and (13a). Air pumps 21 (21a) for supplying cooling air, cylinders (31) (31a) for moving the nozzle caps (30) (30a), and various abnormalities occur, sensor malfunctions, failures, or transfer speeds of the contaminated material Abnormal sound or light or sound It is connected to each of the alarm unit (AL) which emits an alarm light.

The display unit D includes a power indicator for displaying a power supply state, various sensors 11, 32, 32 a, 33, 33 a, 39, 39 a, 51, 51 a, actuators, and the like. It includes an operation indicator to indicate that it is in operation, an alarm lamp to inform various abnormal conditions and various data display parts, and it is composed of one or a combination of liquid crystal display (LCD), seven segment, or light emitting diode, and of course, depending on the situation The display may be configured to facilitate the use.

In the present invention, the chlorine 2 and the nozzle 14n are separated by 2 mm to 5 mm to enable high speed printing without physical contact.

In the present invention, by circulating the cooling water or the liquid refrigerant to the cooling chamber (13) (13a) can obtain a better cooling effect, but there is a problem of dew condensation caused by the condensation phenomenon, in the present invention circulates cold air or cold cooled air By cooling the dye cartridge 14 (14a) to prevent the condensation phenomenon, the cooling efficiency is excellent.

The dye has a degree of texture and affinity for the chlorine (2), the life of the output image is almost semi-permanent, and in the case of rotary printing or screen printing, the contamination is severe, but the present invention is a printing method using the piezo effect, environmental pollution This is avoided.

In the present invention, the number of the dye cartridges 14 and 14a having the respective colors is the number that can cover the width of the salt 2, and of course, it can be appropriately added or subtracted.

The controller 24 receives the edited image by a computer and controls one or more dye cartridges 14 and 14a to output digital images of one width unit or a desired width unit at high speed.

In the high speed output device 1 of the present invention, since the dye cartridges 14 and 14a are fixed, and dye is directly injected and controlled by the control signal of the controller 24, the dye spraying position is very accurate and the printing quality is high. great.

The present invention can be used to print or print the printed matter, such as a large banner or advertising fabric dry dyeing, and the print output is not only capable of outputting the designed picture or photo as it is, but also photograph, image, picture, There is no restriction on the insertion of logos, the number of colors and colors is free, and the quality of printed matter is clean and luxurious.

In the present invention, since the chlorinated material 2 is moved vertically, the feed roller 3 may be installed on the floor or the ground, so that the chlorine wound diameter of the feed roller 3 is large and the weight does not interfere with printing.

In addition, the dye in the present invention has a degree of affinity and affinity for the fabric to be stained, the life of the output image is almost semi-permanent, and in the case of rotary printing or screen printing is severe contamination, but the present invention is a printing method using the piezo effect Therefore, environmentally friendly printing is possible, which prevents pollution and environmental pollution.

In addition, the present invention can be printed on both sides by a double-sided symmetric structure, it is possible to separate the printing on both sides of the blood (2) in different images (patterns and patterns) and / or other colors, the desired density through the controller 24 And / or the contrast can be set to produce a high value-added fiber fabric.

As described above, the present invention can be variously substituted, modified, and changed without departing from the technical spirit of the present invention by those skilled in the art. It is not limited to the accompanying drawings.

1 is a schematic configuration diagram of a cross-section printing high speed output device shown as an example of the present invention.

2 is a plan view showing a state in which the cartridge module of the present invention, the cross-section print type high-speed output device moves to the groove.

3 is a plan view showing a state in which the cartridge module of the present invention, the cross-section printing high speed output device moved to the printing unit.

4 is a high speed printing state diagram of the cross-section printing high speed output device of the present invention.

Figure 5 is a side configuration of the cartridge module of the present invention in the cross-section printing high speed output device moved to the printing unit

Figure 6 is a side configuration diagram of the nozzle plug closed state in the dye cartridge moved to the groove of the cross-section printing method of the present invention.

7 is a side configuration diagram of a state in which the cartridge module of the present invention cross-section printing high speed output device moved to the printing unit.

8 is a side configuration diagram of the nozzle cap of the present invention in the cross-section printing method of the high speed output in the reverse movement state.

9 is a side configuration diagram of the nozzle stopper of the present invention in the cross section printing method of the high speed printing.

10 is a hose connection state of the cartridge module of the present invention.

11 is a block diagram of the integrated dye cartridge shown in an example of the present invention.

12 is a block diagram of a zigzag dye cartridge shown in an embodiment of the present invention.

13 is a block diagram of an inclined dye cartridge shown in an embodiment of the present invention.

14 is a cross-sectional view of the dye cartridge bonded state of the present invention.

15 is a schematic configuration diagram of a double-sided printing method of the high speed output device shown as an example of the present invention.

Fig. 16 is a plan view of the cartridge module of the present invention in the double-sided printing method of the high speed printing device moved to the groove.

17 is a plan view showing the state in which the cartridge module of the present invention double-sided printing method high-speed output device moved to the printing unit.

18 is a high speed printing condition of the double-sided printing method of the present invention.

19 is a side configuration diagram of a state in which the cartridge module of the present invention double-sided printing method high-speed output device moved to the printing unit

20 is a side configuration diagram of a nozzle stopper in a dye cartridge moved to the groove of the double-sided printing method of the present invention.

21 is a side configuration diagram of a state in which the cartridge module of the present invention double-sided printing high speed output device moved to the printing unit.

22 is a cross-sectional view of the dye cartridge combined state of the present invention double-sided printing method.

23 is a circuit block diagram of a controller according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

(1)-high speed output device (2)-blot

(3)-supply roller (3a)-reel roller

(4)-driven roller (5)-driven roller

(6) (6a)-Power Transmission Means (7) (7a) (23) (23a)-Servo Motor

(8) (9) (10) (10a)-Guide Roller (11)-Speed Sensor

(12) (12a)-dye chamber (13) (13a)-cooling chamber

(14) (14a)-dye cartridge (14n) (14n`)-nozzle

(15) (15a)-Cartridge module (16) (16a)-Printed parts

(17) (17a)-Auxiliary Dye Source (18) (18a) (22) (22a)-Supply Hose

(19) (19a)-dye source (20) (20a)-dye pump

(21) (21a)-Air Pump (24)-Controller

(25) (25a)-Signal Line (26) (26a)-Dry Section

(27) (27a)-HOME

(29) (29a)-Move Plate (30) (30a)-Nozzle Stopper

(31) (31a)-cylinder (32) (32a) (33) (33a)-proximity sensor

(35) (35a)-Body (36) (36a)-Intake

(37) (37a)-heat sink (38) (38a)-heat heater

(39) (39a) (51) (51a)-Temperature sensor (40) (40a)-Fan motor

(41) (41a) (42) (42a) (47) (47a)-bracket (43) (43a) (44) (44a)-guide rod

(45) (45a)-Body (46) (46a)-Drive Belt

(48) (48a)-Passive Pulley (49) (49a)-Belt

(50) (50a)-attachment (52) (52a)-engagement groove

(53) (53a)-Banji Section (54) (54a)-Hanging Section

(55) (55a)-Handle (56) (56a)-Case

(57) (57a)-Isolation Plate (58) (58a)-Top Cover

(59) (59a)-terminal (60) (60a)-correspondence terminal

(61) (61a)-dye injection pipe (62) (62a) (65) (65a)-dispensing pipe

(63) (63a)-Air injection pipe (64) (64a)-Air discharge pipe

(C)-control part (S)-setting part

(IO)-I / O (M)-Memory

Claims (11)

Chlorine supply roller, A pair of upper and lower guide rollers for vertically transporting the chlorine of the chlorine supply roller; A driving roller and a driven roller installed on the chlorine supply roller to move the chlorine vertically; Servo motor and power transmission means for rotating the drive roller, The printing part which continuously prints the said salt to a desired width, Cartridge module consisting of a plurality of dye cartridges constituting the printing unit, Moving means for moving the cartridge module to the printing unit and the groove (HOME), Dye supply source and auxiliary dye supply source for supplying dye to the plurality of dye cartridges, Cooling unit formed on one side of the dye cartridge, An air supply source for forcibly supplying air to the cooling unit; Drying unit for drying the chlorine, Nozzle stopper for sealing the nozzle of the dye cartridge moved to the groove, Moving means for moving the nozzle stopper, Velocity sensor for detecting the moving speed of the salt, And a controller for controlling them, Vertical print type digital image high speed output device. Chlorine supply roller, A pair of upper and lower guide rollers for vertically transporting the chlorine of the chlorine supply roller; A driving roller and a driven roller installed on the chlorine supply roller to move the chlorine vertically; Servo motor and power transmission means for rotating the drive roller, A pair of symmetrical printing parts which continuously print the said salts to a desired width, Cartridge module consisting of a plurality of dye cartridges constituting the pair of symmetrical printing, A pair of symmetric moving means for moving the cartridge module to the printing unit and the groove (HOME), A pair of dye sources and a pair of auxiliary dye sources for supplying dye to the plurality of dye cartridges, Cooling units respectively formed on one side of the pair of dye cartridges, A pair of air supply sources for forcibly supplying air to the cooling unit, A pair of symmetric drying units for drying the chlorides, Nozzle stopper for sealing the nozzle of the dye cartridge moved to the groove, Moving means for moving the nozzle stopper, Velocity sensor for detecting the moving speed of the salt, And a controller for controlling them, Vertical print type digital image high speed output device. The method according to claim 1 or 2; The dye cartridge is provided with a plurality of dye cartridges of short length in a zigzag form, but each of the adjacent dye cartridges is overlapped with each other so that nozzles are arranged without being spaced or overlapped so that there is no edge portion, one side and the other side of the dye chamber. Vertical print type digital image high-speed output device formed by forming a cooling chamber on the surface. The method according to claim 1 or 2; The dye cartridge is a vertical printing type digital image high-speed output device, characterized in that the length of the integrated dye chamber and the nozzle, and the cooling chamber formed on one side of the dye chamber is formed integrally. The method according to claim 1 or 2; The dye cartridge is provided with a plurality of dye cartridges having a short length in an inclined manner, but each neighboring dye cartridges are overlapped with each other so that the nozzles are arranged without being spaced or overlapped so that there is no edge portion, and one side of the dye chamber and Vertical printing type digital image high speed output device by forming a cooling chamber on the other side. The method according to claim 1 or 2; The drying unit has an intake port formed in the upper part of the body, a heat dissipation hole is formed in the lower part of the body, and a plurality of electric heaters and a temperature sensor for detecting a heating temperature are respectively installed in the body, and a fan motor having an intake fan is provided in the intake port. Vertical printing digital image high-speed output device, characterized in that installed. The method according to claim 1 or 2; The conveying means includes a pair of guide rods installed in parallel on both sides of the upper surface of the cartridge module, a servo motor installed in the body portion, a driving belt coupled to the rotation shaft of the servo motor, and a driven shaft mounted on the bracket of the body portion. Vertical print type digital image comprising a pulley, a belt wound around the driving pulley and a driven pulley, an attachment connecting the outer side of the belt and one side of the cartridge module, and a proximity sensor installed on both sides of the body part. High speed output device. The method according to claim 1 or 2; The cartridge module is formed with a plurality of coupling grooves are arranged to mount a plurality of dye cartridges for each color, one side of the coupling groove protrudes the support and the engaging portion and the grip portion for supporting the upper portion of the dye cartridge coupled to the coupling groove And a corresponding terminal to which a terminal of the cartridge module is connected at one side of the coupling groove of the cartridge module, and a signal line connected to the corresponding terminal is connected to a controller. The method according to claim 1 or 2; A dye injection tube is installed in the dye cartridge of the dye cartridge, and the dye injection tube is connected to the dye supply hose through a distribution tube, and an air injection tube, an air discharge tube, and a temperature sensor are installed in the cooling chamber. Vertical print type digital image high speed output device, characterized in that connected to the air supply hose through the distribution pipe. The method according to claim 1 or 2; The controller not only stores the image data itself through the memory unit, but also independently edits and outputs the data, and receives the printing data from a connection device such as a computer or a terminal connected to the controller through an input / output unit to receive a high speed image of a large image. Vertical flat digital image high-speed output device characterized in that the output can be achieved. The method according to claim 1 or 2; The printing device is a vertical printing type digital image high-speed output device, characterized in that the chlorine is wound on the winding roller rotated by the servo motor and the power transmission means after the printing.

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