Printed ink curing

An ink-jet printing system (10) includes a generator (20) for in situ generation of a component of an inert atmosphere (an atmosphere that is depleted of oxygen). The system also includes a curing zone (16) in which the generated component (for example nitrogen or carbon dioxide) is distributable over ink that had been deposited on a substrate (12), and in which the ink is exposable to a curing agent (for example UV radiation).

BACKGROUND

Curable inks, and in particular ultraviolet-curable inks, may, in some situations, provide advantages over other types of inks. Ultraviolet-curable inks may enable rapid and precise printing on a wide variety of substrates or media. The substrates may include flexible or rigid substrates. The substrates may have porous or impermeable surfaces. Use of ultraviolet-curable inks instead of solvent-based inks may reduce the amount of volatile organic compounds that are released during printing, thus reducing or eliminating requirements for ventilation. Curing of ultraviolet-curable inks may be more rapid than drying of solvent-based inks. Ultraviolet-curable inks generally have a low viscosity and do not penetrate into the substrate. Therefore, printing with ultraviolet-curable ink may entail using a much smaller quantity of ink than would printing a similar area with solvent-based ink.

DETAILED DESCRIPTION

Printing with curable ink includes a curing step. In the curing step, ink that was deposited on the substrate is exposed to a curing agent. For example, when printing with an ultraviolet-curable ink, curing includes exposure to ultraviolet radiation. The curing causes polymerization of components of the ink. The cured ink may then be enduringly bound to the substrate.

A region of a printing system in which curing of deposited ink takes place may be referred to as a curing zone of the system. For example, a section of a substrate on which ink was deposited during a printing step may be transported to a curing zone of the system for curing of the deposited ink.

Oxygen molecules reacting with the deposited ink may interfere with polymerization of the ink.

In accordance with an example of a process for curing of ink deposited during printing, an inert atmosphere is generated for introduction into a curing zone of a printing system. The inert atmosphere is introduced to cover ink that is deposited on a substrate during a printing step (e.g. inkjet printing). For example, the deposited ink may include one or more ultraviolet-curable components. The ink that is covered by the inert atmosphere is cured by exposure to a curing agent, such as ultraviolet light. The curing zone may be partially or fully enclosed within a curing chamber.

An inert atmosphere, as referred to herein, is an atmosphere that is depleted of oxygen. Examples of gases that are suitable components of an inert atmosphere include an inert gas, nitrogen, water vapor, carbon dioxide, or another gas that does not interact with deposited ink and that does not include oxygen (O2) molecules. The inert atmosphere may prevent oxygen (O2) from the ambient atmosphere from diffusing into the deposited ink. Prevention of diffusion of atmospheric oxygen into the deposited ink may reduce or eliminate any inhibition of polymerization of the curable components that is caused by diffused oxygen. By reducing or eliminating the diffusion of atmospheric oxygen into the deposited ink, the deposited ink may be cured using less energy (e.g. in the form of ultraviolet radiation) than would be required without reduction of oxygen diffusion.

In accordance with an example of printed ink curing, the inert atmosphere is generated in situ. In situ generation refers herein to production of a gaseous component of the inert atmosphere from other materials, e.g. via a chemical reaction or via extraction from another material (e.g. ambient air, or from a provided fluid or liquid).

In situ generation of the inert atmosphere may enable maintaining a substantially uniform inert atmosphere throughout the curing process. Maintaining a substantially uniform inert atmosphere includes replenishing components of the inert atmosphere to replace any gaseous components that may flow or diffuse out of the curing zone.

For example, a component of an inert atmosphere may be generated in situ by operating a chemical generator. The generator may include a reaction chamber in which a suitable chemical reaction takes place to produce a component of the inert atmosphere. The generator may include an extraction device in which a component of the inert atmosphere is extracted from a mixture of components.

The generator may include a combustion chamber. Combustion of a flammable gas in a combustion chamber may generate one or more combustion products that may be utilized as components of an inert atmosphere. In addition, the combustion may generate heat that may be utilized to expedite the curing process. For example, heat that is generated by the combustion may be utilized to evaporate water or other components from the deposited ink.

For example, combustion of propane (C3H8) gas may produce water vapor, carbon dioxide, and heat via a reaction:
C3H8+5O2→3CO2+4H2O+heat.

As another example, combustion of butane (C4H10) gas may produce water vapor, carbon dioxide, and heat via a reaction:
2C4H10+13O2→8CO2+10H2O+heat.

In situ generation of an inert atmosphere may be advantageous. For example, in situ generation of the inert atmosphere may enable efficient and relatively inexpensive maintenance of a substantially constant oxygen-depleted layer over the deposited ink. The inert atmosphere may be generated using a simple combustion chamber of a readily available gas such as butane or propane. The combustion chamber may provide heat that may be further utilized in evaporating water from the deposited ink.

In particular, examples of situ generation of an inert atmosphere may be advantageous when printing with an ultraviolet-curable ink that is water based (e.g. includes water as a solvent). In this case, a combustion product or otherwise heated component of an inert atmosphere may be introduced over the deposited ink. Introducing a heated component of the inert atmosphere may thus concurrently promote evaporation of the water as well as providing an oxygen-depleted layer over the ink so as to enable efficient ultraviolet curing of the ultraviolet-curable components of the ink. For example, separation of water vapor from one or more other heated generated components of the atmosphere may promote evaporation of water from the ink.

On the other hand, providing components of the inert atmosphere from a tank or similar container (without in situ generation) could require constant replenishing of the gas, leading to constant maintenance and resupply. Similarly, depleting oxygen from the vicinity of the deposited ink by maintaining a vacuum could require using a large amount of electrical or other energy.

FIG. 1is a schematic illustration of an example of a printing system for application of an example of printed ink curing. Printing system10is configured to print on a substrate12.

During a printing process, substrate12is transported relative to one or more components of printing system10. For example, substrate12may be transported by an appropriate transport system or mechanism, e.g. with a motion in a direction indicated by arrow13(henceforth, motion13). Motion13may represent a linear translational motion, a rotational motion (e.g. turning or a non-linear translation, e.g. about a cylinder), or another motion of substrate12. Substrate12may be transported by one or more moving platforms, conveyor belts, rollers, non-contact transport systems (e.g. based on flow of air or another fluid, or based on electromagnetic levitation), mechanical arms, or similar transport systems. Equivalently, one or more components of printing system10may be moved (e.g. translated) relative to substrate12, or both components of printing system10and substrate12may be moved concurrently or successively.

Motion13or operation of one or more components of a transportation system of printing system10may be controlled by a controller30.

Substrate12may include a sheet or object that is made of any material which may be printed on. Suitable materials may include, for example, paper, cardboard, wood, plastics, textiles, or metals. Substrate12may be flat or may be shaped in another manner (e.g. curved). Printing system10may be configured to print only on a substrate12whose size, shape, weight, or other property corresponds to a predetermined set of substrate properties.

Ink (or another deposited material, any such material being herein referred to as ink) may be deposited on substrate12by printhead14. Printhead14may include one or more nozzles or similar ink dispensing components that are configured to dispense ink on substrate12. Printhead14may include one or more separate printhead units. For example, each separate printhead unit may be configured to dispense a particular type (e.g. each particular type being characterized by a particular color, texture, or other property) of ink. Such separate printhead units may be operable separately from one another, or may be operable in a coordinated fashion.

Printhead14may include, or be connected to, one or more ink containers. For example, each of several ink containers may include a different type of ink. Each container may be refillable or replaceable.

Printhead14may be controlled so as to deposit ink on substrate12in accordance with programmed instructions. For example, a controller30that is operating in accordance with a driver application file may control printhead14in accordance with a content file. The content file may include a digital representation of an image or text that is to be printed on substrate12.

The deposited ink may include colorants (e.g. pigments and colorants) and other components that facilitate deposition or curing of the ink. The ink includes a carrier component that serves to facilitate delivery of the colorants to the surface of substrate12. The carrier may include a photo-initiator component that, when exposed to ultraviolet light, initiates polymerization of one or more liquid monomer components. The ink may include one or more water-based or organic solvents.

A region of substrate12on which ink was deposited by printhead14may be transported to curing zone16for curing. Curing zone16may include a plurality of separate curing sub-units. Each of the curing sub-units may have a separate function (e.g. providing curing radiation of different wavelengths, providing different curing agents), or may have identical function to one another. For example, one curing sub-unit may provide heat, one may provide an inert atmosphere, and one may provide ultraviolet curing radiation. As another example, one curing sub-unit may provide initial curing to fix or pin a printed image (e.g. to prevent dispersion of ink during subsequent steps of stages), while another may complete the curing.

Part or all of curing zone16may be completely or partially enclosed in one or more curing chambers. Each curing chamber may have identical or different functions. For example, each curing chamber may enclose a different curing sub-unit.

Although printhead14and curing zone16are depicted inFIG. 1as separate structures, printhead14and curing zone16may be enclosed in a single housing. Components of printhead14and curing zone16may be arranged such that the components of printhead14and curing zone16are interspersed among one another. For example, printhead14may include a plurality of printhead units. Each of the printhead units may be associated with a separate curing subunit. For example, a region of a substrate that is being transported as indicated by arrow13may successively pass a first printhead unit, a first curing subunit, a second printhead unit, a second curing subunit, and so on.

Curing zone16includes one or more units or devices for creation or generation of a curing agent. The curing agent is applied to ink that had been previously deposited on substrate12by printhead14.

Curing zone16may include a lamp18. Lamp18includes one or more radiation generation units for generating a curing radiation. For example, the curing radiation may include radiation in one or more ultraviolet bands. In this case, lamp18may include one or more lamps that produce ultraviolet radiation. For example, lamp18may include an appropriate xenon or mercury discharge lamp.

Curing zone16is associated with combustion chamber20. In combustion chamber20, a combustible material may be burned. The combustible material or other material required for combustion (e.g. oxygen) may be provided by a container26. Container26may include one or more separate tanks or other containers for containing one or more components of the combustible material. Container26may include a tank for containing a gaseous component of the combustible material in compressed form. Container26may contain a volatile or other liquid component of the combustible material. Container26may include a powdered or other solid component of the combustible material. For example, the combustible material that is provided by container26may include propane or butane.

Sufficient oxygen may be provided (e.g. from container26or another source) may be provided to enable complete combustion of the combustible material. After complete combustion, the combustion products include only carbon dioxide and water vapor, with at most trace amounts of complex organic molecules.

One or more components of the combustible material may be conveyed from container26to combustion chamber20via material conduit27. For example, material conduit27may include a tube or pipe that is suitable for conveying one or more components of the combustible material. Conduit27may include a flow control device in the form of a pump, valve, filter, or other device that may be operated to control the flow of one or more components of the combustible material through conduit27. The flow control device may be operated automatically by a controller that is associated with printing system10, may be operated manually (e.g. remotely) by an operator of printing system10, or by a combination of automatic and manual controlling.

The combustible material may be combusted or burned in combustion chamber20. For example, a combustible gaseous material (e.g. gas, liquid, or solid) may be provided with oxygen (or other suitable gas) so as to enable combustion. The oxygen may be provided from the ambient atmosphere (e.g. via an intake vent or opening), or may be provided from a suitable tank or container, such as container26.

Combustion in combustion chamber20may be initiated spontaneously (e.g. upon exposure of the combustible material to oxygen), or may be initiated using a suitable combustion initiation mechanism. For example, a combustion initiation mechanism may include generation of a spark, exposure to a heated element (e.g. resistance wire), radiation (e.g. focused light or other electromagnetic radiation), exposure to a catalyst, or another suitable mechanism for initiating combustion.

Combustion chamber20may include a heat exchanger28. Heat exchanger28may be configured to heat a stream of a gas. The heated stream of gas may include a component of inert atmosphere24that is to be heated and conducted to curing zone16, or may include a stream of another gas that is to be heated. For example, the heated stream of gas may be directed to curing zone16so as to enable heating or drying of ink that had been deposited on substrate12. The heated stream of gas may be included within, or otherwise applied concurrently with, inert atmosphere24. In other cases, the heated stream of gas may be directed toward substrate12separately from (e.g. in a different subunit of curing zone16, or at a separate time from) application of inert atmosphere24.

Operation of one or more components of combustion chamber20may be controlled by controller30.

Combustion of the combustible material in combustion chamber20may yield one or more combustion products. For example, the combustion products may include a gaseous combustion product such as carbon dioxide gas or water vapor. One or more of the combustion products may be suitable for inclusion in an inert atmosphere24in curing zone16.

Inert atmosphere24includes one or more combustion products that are produced in combustion chamber20. A component of inert atmosphere24may be conveyed from combustion chamber20to curing zone16via combustion product conduit22.

Combustion product conduit22may include one or more tubes or pipes that are suitable for conducting a gaseous combustion product from combustion chamber20to curing zone16. Combustion product conduit22may include a blower, fan, pump, or other device for facilitating transport of a gaseous combustion product from combustion chamber20to curing zone16.

Combustion product conduit22may include one or more separation devices or units for separating a combustion product that is formed in combustion chamber20from one or more other combustion products. For example, a separation device may include a semi-permeable membrane that enables one combustion product to pass while blocking another. A separation device may be based on inertia (e.g. centrifugal force) or other mechanical effects, adsorption or absorption, electromagnetic separation, thermal properties, chemical or molecular forces, or on other properties, forces, reactions, or phenomena.

One or more of the separated combustion products may be conveyed to form a component of inert atmosphere24in curing zone16. In accordance with some examples of printed ink curing, two or more separated combustion products may be conveyed concurrently to curing zone16. In this case, inert atmosphere24may include a plurality of gaseous components. In other examples of printed ink curing, two or more separated combustion products may be conveyed provided separately to curing zone16. For example, each separated component may be conveyed to a separate subunit of curing zone16, or may be provided at different times to a single subunit of curing zone16.

Curing zone16may be provided with an atmosphere distribution unit23for forming inert atmosphere24. Atmosphere distribution unit23may include an arrangement of one or more conduits, tubes, pipes, nozzles, or openings for distributing components of inert atmosphere24within curing zone16. For example, atmosphere distribution unit23may be configured to distribute components of inert atmosphere24so as to form a layer of oxygen-depleted gas. The formed layer of oxygen-depleted gas may cover ink that had been previously deposited on substrate12by printhead14. Atmosphere distribution unit23may be configured to introduce additional components into inert atmosphere24, e.g. in addition to combustion products that were produced by combustion in combustion chamber20. For example, one or more additional components may be extracted from the ambient atmosphere or from a tank or similar container.

Atmosphere distribution unit23may be configured to, or may include a component that is configured to, direct heated gas (e.g. a component of inert atmosphere24, air, or another gas) toward substrate12.

Atmosphere distribution unit23may include a mechanism or system for recycling one or more components of inert atmosphere24. Atmosphere distribution unit23may include an air knife mechanism or similar mechanism to inhibit outflow of components of inert atmosphere24from a region of curing zone16in which a curing agent is applied. Such a mechanism for inhibiting outflow may enable reducing the quantity of combustible material that is required for formation of inert atmosphere24.

Atmosphere distribution unit23may include, or cooperate with, one or more sensors for monitoring a current state of inert atmosphere24. For example, a sensor may be configured to sense a current quantity (e.g. density) of one or more components of inert atmosphere24. A sensor may be configured to sense a temperature, flow rate, pressure, humidity or dryness, or other property of inert atmosphere24or of a component of inert atmosphere24.

Operation of atmosphere distribution unit23, of lamp18, or of one or more other components of curing zone16may be controlled by controller30.

For example, a flow of carbon dioxide at a flow rate of about 1.5 liters per second to about 3.0 liters per second has been experimentally found to be sufficient to enable complete curing of a layer of deposited ink.

For example, butane may be provided (e.g. from container26) to combustion chamber20at a rate of about 0.035 moles per second (corresponding to about 2 grams per second) to produce carbon dioxide at a rate of about 0.14 moles per second (corresponding to a production rate of about 6.28 grams per second of carbon dioxide). This production rate corresponds approximately to a flow rate of 1.6 liters per second of carbon dioxide gas at a temperature of about 180° C. On the assumption of continuous consumption of butane at the aforementioned rate, monthly consumption of butane may be approximately 5000 kilograms. The cost of 5000 kilograms of butane per month may be comparable to, or may be less than, the additional monthly cost that would be required to provide electricity for ultraviolet curing in the absence of a generated inert atmosphere. Similarly, the cost of 5000 kilograms of butane per month may be comparable to, or may be less than, the additional monthly cost that would be required to provide components of an inert atmosphere in the absence of in situ generated components of the inert atmosphere (e.g. the components, such as carbon dioxide, being either purchased or extracted from the ambient air).

FIG. 2is a schematic illustration of an example of a controller for a printing system such as the printing system shown inFIG. 1.

Controller30includes a processor32. For example, processor32may include one or more processing units, e.g. of one or more computers. Some or all components of processor32may be incorporated in a printer of printing system10, or of a computer that is associated with printing system10. Processor32may be configured to operate in accordance with programmed instructions stored in memory36. Processor32may be capable of executing an application for controlling a system printed ink curing.

Processor32may communicate with memory36. Memory36may include one or more volatile or nonvolatile memory devices. Memory36may be utilized to store, for example, programmed instructions for operation of processor32, data or parameters for use by processor32during operation, or results of operation of processor32

Processor32may communicate with data storage device34. Data storage device34may include one or more fixed or removable nonvolatile data storage devices. For example, data storage device34may include a computer readable medium for storing program instructions for operation of processor32. In this example, the programmed instructions may take the form of printhead control module38for controlling operation of printhead14, combustion control module40for controlling operation of combustion chamber20, curing control module42for controlling operation of one or more components of curing zone16, or transport control module44for controlling motion13. It is noted that data storage device34may be remote from processor32. In such cases data storage device34may be a storage device of a remote server storing printhead control module38, combustion control module40, curing control module42, or transport control module44in the form of an installation package or packages that can be downloaded and installed for execution by processor32. Data storage device34may be utilized to store data or parameters for use by processor32during operation, or results of operation of processor32.

In operation, processor32may execute a method for controlling a printing system for application of an example of printed ink curing.

FIG. 3is a flowchart depicting an example of a method for control of a printing system for application of an example of printed ink curing.

Printer control method100may be executed by a processor of a controller of printer system for application of an example of printed ink curing. Printer control method100may be executed upon a request or command that is issued by a user, or automatically issued by another application.

It should be understood with respect to the flowchart that the division of the illustrated method into discrete operations represented by blocks of the flowchart has been selected for convenience and clarity only. Alternative division of the illustrated method into discrete operations is possible with equivalent results. Such alternative division of the illustrated method into discrete operations should be understood as representing other examples of the illustrated method.

Similarly, it should be understood that, unless indicated otherwise, the illustrated order of execution of the operations represented by blocks of the flowchart has been selected for convenience and clarity only. Operations of the illustrated method may be executed in an alternative order, or concurrently, with equivalent results. Such reordering of operations of the illustrated method should be understood as representing other examples of the illustrated method.

In accordance with an example of controlling a printer system for printed ink curing, a computer program application stored in a computer-readable medium (e.g., register memory, processor cache, RAM, ROM, hard drive, flash memory, CD ROM, magnetic media, etc.) may include code or executable instructions that when executed may instruct or cause a controller or processor to perform methods discussed herein, such as an example of a method for controlling a printer system for printed ink curing. The computer-readable medium may be a non-transitory computer-readable media including all forms and types of computer-readable media except for a transitory, propagating signal.

Printer control method100includes operating a printhead of a printing system (block110). Operating the printhead may include determining when ink has been deposited on a substrate by inkjet printing. In particular, operating the printhead may include determining when a curable ink, such as ultraviolet-curable ink, has been deposited on the substrate.

Printer control method100includes operating a combustion chamber (block120). Operating the combustion chamber may include causing a combustible material to be combusted in the combustion chamber. Operating the combustion chamber may include controlling delivery of a combustion product to the curing chamber. Operating the combustion chamber may include monitoring production of a combustion product.

Printer control method100includes transporting the substrate relative to one or more components of the printing system (block130). Transporting the substrate may include causing each region of the substrate on which ink had been deposited to be transported to the curing zone. Transporting the substrate may include moving one or more components of the printing system relative to the substrate. Transporting the substrate may include ensuring that the substrate is exposed to the curing agent for a sufficient period of time.

Printer control method100includes curing deposited ink, e.g. by operating one or more components of a curing zone (block140). Curing may include operating a curing chamber. Curing may include forming an inert atmosphere in the curing zone. Forming the inert atmosphere may include controlling delivery and dispersal of one or more combustion products within the curing zone. Curing may include causing heat or heated gas to be delivered to the curing zone. Curing may include controlling application of a curing agent, such as operation of a lamp such as an ultraviolet lamp. Curing may include monitoring formation of the inert atmosphere, or of application of the curing agent.