Certain types of printing systems are adapted for printing images on large-scale substrates, such as for museum displays, billboards, sails, bus boards, and banners. Some of these systems use so-called drop on demand ink jet printing. In these systems, a carriage which holds a set of print heads scans across the width of the substrate while the print heads deposit ink as the substrate moves.
Solvent based inks are sometimes used in these systems in which an infrared dryer is used to dry off the solvent after the ink is deposited onto the substrate. Systems using solvent based inks are able to print on flexible substrates such as PVC materials and reinforced vinyl. However, solvent based inks are typically considered to be unusable for printing on rigid substrates such as metals, glass, and plastics. Therefore, to print on rigid, as well as flexible substrates, radiation-curable inks such as UV-curable inks are often preferred. For these systems, the ink is deposited onto the substrate and then cured in a post-printing stage. For instance, after the deposition of the ink, the substrate moves to a curing station. The ink is then cured, for example, by exposing it to UV radiation. In other systems, the UV radiation source for curing is mounted directly on the same carriage that carries the set of print heads.
During the printing process, UV curable ink must be cured within a short time period after it has been deposited on the substrate, otherwise ink with positive dot gain may spread out and flow, or ink with negative dot gain may ball up. UV radiation sources mounted on the carriage are capable of emitting radiation at high enough energies to cure the ink within such time frames. However, a significant amount of power must be supplied to the UV radiation source to enable it to emit these high energies. Typical UV radiation sources are quite inefficient since most of the emitted radiation is unusable. A substantial percentage of the emitted radiation is not used because the source emits radiation with wavelengths over a spectrum which is much wider than the usable spectrum. In addition, to ensure that the required amount of radiation is transmitted to the ink, the carriage must scan across the substrate at moderate speeds, even though the print heads are capable of depositing ink onto the substrate at much higher carriage speeds.
It is desirable, therefore, to set (i.e. pre-cure) the ink rather than fully cure it as the ink is deposited on the substrate so that the ink does not spread or ball up, even though it is still in a quasi-fluid state (i.e. the ink is not completely hardened). Such an arrangement requires less power, and, therefore, facilitates using smaller UV radiation sources. In addition, a lower energy output requirement would allow the carriage to operate at a higher speed. Hence, images can be printed at a higher rate, resulting in a higher throughput.
The present invention implements an apparatus and method for setting radiation curable ink deposited on a substrate. Specifically, in one aspect of the invention, an ink jet printing system includes a UV energy source which emits pulsed UV radiation to polymerize a fluid that is deposited onto a substrate by one or more ink jet print heads. In some embodiments, the radiation emitted by the energy source is adjustable. The energy source is able to emit low energy UV radiation to set the fluid, as well as a higher energy UV radiation to cure the fluid. In certain embodiments, the fluid is first set and subsequently cured. The fluid can be an ink that is UV curable, or the fluid can be any other type of polymerizable fluid that does not necessarily contain a dye or pigment.
In some embodiments, the energy required to set the fluid or ink to a quasi-fluid, non-hardened state is between about 5% to 50% of the energy necessary to cure the fluid or ink to a hardened state. As such, since the cure energy is typically between about 200 mj/cm2 to 800 mj/cm2 for many polymerizable fluids, such as UV treatable inks, the set energy can be between about 10 mj/cm2 to 400 mj/cm2.
Embodiments of this aspect can also include one or more of the following features. The print heads can be positioned in a carriage which scans in a direction substantially traverse to the direction of movement of the substrate. In certain embodiments, the carriage is able to move bidirectionally. And in others, the energy source is moveable relative to the carriage in a direction substantially perpendicular to the traverse direction.
In some embodiments, the UV energy source is a pair of lamps mounted to a carriage of the printing system that scans across the substrate. The lamps can be moveable relative to the carriage. The system can also include a feedback system which controls the pulse rate of the UV energy source. In certain embodiments, the feedback system converts the pulse rate to pulses per inch of linear travel of the energy source.
In yet other embodiments, the print heads are a non-moveable fixed array of print heads. The energy source includes a first UV energy source which sets the liquid and a second UV energy source which cures the liquid. The first energy source is positioned at a trailing end of the array and the second energy source is positioned adjacent to a trailing side of the first energy source
In another embodiment, the print heads include one or more series of print heads arranged in a non-moveable fixed array, and an equal number of setting energy sources. Each energy source is capable of setting the fluid and is positioned adjacent to a respective series of print heads. The energy source also includes a curing UV energy source which cures the fluid. The curing UV energy source is positioned at a trailing end of the array of print heads and the setting energy sources.
In yet another aspect, the invention implements a method and apparatus with a radiation source which emits a set energy sufficient to set the ink to a non-hardened, quasi-fluid state. The radiation source can emit continuous UV radiation or pulsed UV radiation. The set energy can be substantially less than a cure energy required to fully cure the ink to a hardened state. The set energy can be about 50% or less than the cure energy. The energy level of the radiation source can be adjustable from a low level to set the ink to a higher level to cure the ink.
Some embodiments of the invention may have one or more of the following advantages. The pulsed UV energy source is able to set and cure printed material with less heat since it generates less IR. When printing on certain substrates, for example those that are corrugated, continuous UV lamps produce a temperature gradient through the thickness of the substrate, thereby causing the substrate to warp. With pulsed UV energy sources, this temperature gradient is minimized and hence less warping occurs. Furthermore, with less heat being produced there is a smaller chance of a fire occurring.
In addition, because most of the energy produced by pulsed UV energy sources is usable, they are highly efficient. Unlike some continuous UV energy sources which have to remain ON, pulsed UV energy sources can be quickly turned OFF and ON since they require little or no warm up time. Hence, when the UV energy is not needed, for example, when the carriage is changing directions, the pulsed UV energy sources can be turned OFF. Another advantage of pulsed UV energy sources is that the amount of energy emitted over an area of printed material can be precisely controlled regardless how fast or slow the carriage scans across the substrate. That is, the amount of energy emitted from the pulsed UV energy sources can be quickly changed to accommodate varying speeds of the carriage.
The foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
A description of preferred embodiments of the invention follows.
Turning now to the drawings, there is shown in
The printing system 10 includes a base 12, a transport belt 14 which moves the substrate through the printing system, a rail system 16 attached to the base 12, and a carriage 18 coupled to the rail system 16. The carriage 18 holds a series of inkjet print heads and one or more radiation sources, such as UV radiation sources, and is attached to a belt 20 which wraps around a pair of pulleys (not shown) positioned on either end of the rail system 16. A carriage motor is coupled to one of the pulleys and rotates the pulley during the printing process. As such, when the carriage motor causes the pulley to rotate, the carriage moves linearly back and forth along the rail system 16.
The print heads and the UV radiation sources mounted to the carriage are illustrated in more detail in
Although certain regions of the image 30 are made with multiple layers of ink, and all four sets of the print heads 28 may simultaneously deposit ink onto the substrate 32, only one layer of ink is deposited at a given time on the portion of the substrate that is positioned beneath a respective set of print heads as the carriage scans across the substrate.
An alternative embodiment of the invention is illustrated in
A typical ink jet printing ink has a viscosity of about 10 centipoise. Thus, as shown in
Referring to
Note that the print heads 28 of the carriage 18a (
Recall that about 800 mj/cm2 is required to cure the ink and about 40 mj/cm2 is necessary to set the ink. Therefore, at first blush, for the printing system 10 using the carriage 18a, it would appear that the overlap regions 56 are exposed to about 200 mj/cm2 (5× of 40 mj/cm2) for carriage speeds of 60 inch/sec and 1200 mj/cm2 for carriage speeds of 10 inch/sec. Although 200 mj/cm2 is well below the amount of energy required to the cure the ink, 1200 mj/cm2 is well above the required cure energy. However, a 30× exposure of 40 mj/cm2 is not equivalent to a single exposure of 1200 mj/cm2.
This is best illustrated with reference to
With most UV radiation sources, much of the radiation transmitted by the source is unusable. For example, traditional glow bulbs emit energy from a wavelength of about 200 nm to about 420 nm (
Further, traditional glow bulbs, for example, mercury vapor lamps, require about 3000 volts to provide the required energy to cure the ink. But when the voltage supplied to traditional glow bulbs is reduced to provide the set energy (5% of the cure energy), the ends of the lamp cool initially and the plasma extinguishes at these ends. As such, the traditional glow bulb is unable to provide a uniform radiation source along its length for both curing and setting applications. LEDs, however, can be pulse-width modulated so that the ends of the radiation source do not extinguish which ensures that the radiation emitted by the LED radiation sources is uniform along the length of the radiation source regardless whether the radiation source is used to cure and/or to set the ink.
Other features of LEDs make them highly desirable for use as UV radiation sources. For instance, LEDs weigh less, require less energy to operate, do not emit wasteful energy, and are physically smaller.
The above discussion has been directed to printing systems with a UV setting capability. However, as illustrated in
In another embodiment shown in
Although in certain embodiments continuous UV radiation sources, such as mercury arc lamps, are used to set the printing fluid or ink, in other embodiments the carriage 18 is provided with a Xenon flash tube to serve as the UV radiation source for setting the fluid. Further, the curing station can be a separate stand alone unit unattached to the base 12 or the carriage 18 of the printing system 10.
In another embodiment shown in
Referring further to
Although as mentioned earlier continuous UV radiation sources can be used to set the ink or fluid, since the carriage scans back and forth quite rapidly across the substrate, it is desirable in some situation to use a UV pulsed lamp, such as the Xenon flash lamp mentioned above, as the lamp 1012, which can be turned off and on at very high rates. In the illustrated embodiment, the Xenon flash lamp 1012 is connected to a pulse circuit 1030 shown in
The power supply 1036 provides a current to charge the capacitor 1040. When instructed, for example, by a controller 1100, the trigger 1034 triggers the lamp 1012 to release the energy stored in the capacitor 1040 in the form of a current pulse which is then shaped by the pulse forming network 1032 such that an energy spectrum with the appropriate characteristics, such as the optimum wavelength, is produced by the lamp 1012.
As shown in
For the sake of comparison, a 500 watt continuous UV radiation source, such as a mercury arc lamp must operate for 1 sec to produce 500 joules. By way of contrast, the Xenon lamp 1012 having a power output of 500,000 watts delivers 500 joules in one millisecond. Thus by emitting 10 pulses per second, ten times the energy can be delivered to the ink for setting and curing.
Another feature of the pulsed UV lamp 1012 is that it produces significantly less heat than continuous UV lamps. Because the lamp 1012 generates UV radiation in narrow pulses, and there is a cooling period between the pulses, the Xenon gas is excited to useful energy levels without being heated to vapor levels. Accordingly, a minimum amount of IR energy is generated.
The Xenon lamp 1012 and its associated circuitry and operation are described in greater detail in a Technical Paper entitled “Pulsed UV Curing,” by Louis R. Panico, published by Xenon Corporation, the contents of which are incorporated herein by reference in its entirety. The Xenon lamp 1012 can be of the type manufactured by Xenon Corporation of Woburn, Mass.
By pulsing the energy to the Xenon lamp 1012, the lamp can be turned on and off quickly to precisely control the pulse rate of the lamp 1012, and hence precisely control the amount of radiant energy transmitted to the ink that is deposited on the substrate.
This particular feature of the invention is illustrated by way of example of the velocity profiles 1050a and 1050b shown in
Further, in many applications, the carriage 18c begins to decelerate as the trailing side 1070 of the carriage 18c aligns with the edge 1083 of the substrate 32, for example, when the carriage moves from left to right. However, if the energy output of the trailing energy source 1084 is not reduced, for example, when a continuous UV lamp is employed, the amount of energy the edge region 1086 of the substrate 32 receives is higher since the UV exposure time there is greater.
In contrast, with the pulsed Xenon lamp 1012, the pulse rate can be reduced when the carriage 18c begins to decelerate in the region 1056 to ensure that these edge regions 1086 of the substrate 32 do not get overexposed to UV radiation. Further, as the trailing side 1088 of the trailing energy source 1084 aligns with the edge 1083 of the substrate, the lamp can be immediately turned off. Then as the substrate 32 advances through the printing system and as the now trailing side (previously leading) 1092 aligns with the edge 1083, the other lamp 1093 is turned on and its pulse rate increases to a steady rate once the trailing side 1094 of that lamp aligns with the edge 1083.
Another particular feature of the invention is that the pulse rate of the Xenon lamp 1012 is specified in pulses per unit length of linear travel (for example, pulses per inch). That is regardless how fast the carriage 18c scans or shuttles across the substrate 32, the amount of energy a given area of the printed image receives is the same, if so desired.
The precise control of the pulse rate of the lamp 1012 is provided by a feedback system 1101 shown in
The encoder 1102 can be linear encoder that generates encoder data, such as “ticks” per inch of linear travel, for example, along the rail 16, or it can be a rotary encoder which rolls along the rail 16 but nonetheless provides the same encoder data. In either case, the encoder data is transmitted to the divider 1104 that is under the direction of the controller 1100. The divider takes the ticks per inch and divides it by a number N which can be a fixed number or is a variable that is specified by the operator. Hence, the divider 1104 can be programmable. This information is transmitted to the pulse circuit 1030 so that it pulses at a particular rate. The pulse circuit 1030 also receives instructions from the controller 1100 as to which energy source 1002 or 1004 should be operating. An on-board timer of the controller 1100 enables it to instruct the divider 1104 and the pulse circuit 1030 to reduce or increase the pulses per second as the carriage 18c decelerates or accelerates so that the pulses per inch of travel generated by the lamps 1012 remains a constant if desired. Accordingly, the pulse rate (pulses/sec) of the lamp 1012 can be related to the speed of the carriage 18c so that the lamp 1012 transmits the same amount of energy per unit area of the substrate regardless at what speed the carriage 18c travels. Thus, if the carriage 18c moves at 60 inches/sec and the lamp 1012 emits energy at 60 pulses/sec, then the lamp 1012 effectively emits energy at 1 pulse/inch of motion. Further, if the carriage slows down to 30 inches/sec, for example, to print images with higher quality and/or when the carriage 18 decelerates as discussed above, then the feedback system 1101 can automatically instruct the pulse circuit 1030 to reduce the pulse rate of the lamp 1012 to 30 pulses/sec so that the effective pulse rate of the lamp 1012 remains at 1 pulse/inch. Of course, an operator can also vary the amount of energy transmitted per unit area by either increasing or decreasing the pulse rate of the lamp 1012.
In an alternative embodiment shown in
With such an arrangement, as the carriage 18d moves from left to right (as indicated by arrow A) the trailing energy source 2008, positioned in a retracted state, emits a sufficient amount of UV energy to set the ink deposited onto the substrate and the leading energy source 2006, moved to an extended state, fully cures the ink which was set in a previous pass. Subsequently, after moving in the direction A, the energy source 2006 moves to a retracted state, the energy source 2008 moves to an extended state, the substrate 32 moves an incremental amount in the direction C, and the carriage 18d reverses its direction and moves in the direction B. As the carriage 18d moves in the direction B, the energy source 2006 sets the presently deposited ink, and the energy source 2008 now moved to an extended state cures the ink deposited and set in a previous pass.
Note that the distance the energy sources 2006 and 2008 are extended can be shorter than d1 or greater than d2 in certain embodiments. The distance the energy sources 2006 and 2008 are extended determines the length of time between when the ink is set and when it is cured. Thus, the time period between the setting and the curing processes is longer when the energy sources 2006 and 2008 are extended to d2 than when extended to d1.
Up to now, the described embodiments of the invention include a series of print heads and UV energy sources mounted to a moveable carriage 18. The carriage 18 can move either bidirectionally or only in one direction. In some applications, however, it is desirable to have a non-moving fixed array of print heads. For example, in
In yet another embodiment, shown in
While this invention has been particularly shown and described with references to preferred embodiments thereof, 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 scope of the invention encompassed by the appended claims. There can be one or more sets of print heads, and each print head can include one or more print heads. The print heads for each color can be arranged together or they can be intermingled with the print heads for the other colors.
This application claims the benefit of U.S. Provisional Application No. 60/326,691, filed Oct. 2, 2001, and is a continuation-in-part of U.S. application Ser. No. 09/834,999, filed Apr. 13, 2001 is now U.S. Pat. No. 6,457,823. The entire contents of the above applications are incorporated herein by reference.
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Number | Date | Country | |
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20030035037 A1 | Feb 2003 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 09834999 | Apr 2001 | US |
Child | 10172761 | US |