The present invention relates generally to a method and apparatus for transfer lamination and more specifically to a method and apparatus in which a transfer film is coated for a subsequent use during a transfer lamination process.
Transfer lamination is a process by which a layer of material is applied to a substrate. Applied materials can include metals, such as, for example, a hologram.
Generally, transfer lamination involves bonding a transfer film having a application layer, e.g., a metallized layer such as a hologram, to a paper substrate, stripping the film from the substrate leaving the application layer, and then applying a coating to the layer to facilitate printing. As will be appreciated, this process typically involves multiple, separate steps.
In particular, the transfer film is coated in an initial step with a breakaway layer that allows the film to be stripped from the substrate while leaving the application layer and the breakaway layer on the substrate. After the film is coated, the application layer is applied, e.g., the film is metallized. Once the film has been metallized, an adhesive is applied and the film is then bonded to the substrate and the film/substrate is cured typically in an oven. Once removed from the oven, the film is stripped away and the substrate is coated and placed again in the oven to complete the process.
A drawback to this method is that the breakaway layer is applied to the transfer film in a step separate from the transfer lamination process. As will be apparent, each manufacturing step has associated costs and it is generally desirable to reduce such costs through a simplified process with as few manufacturing steps as reasonably necessary.
Moreover, the film used in the transfer of the application layer is typically discarded, or reused only a limited number of times, after it is stripped from the substrate due to the costs of reuse/recycling.
Used transfer film also presents disposal and recycling problems as such films are generally manufactured from polyesters such as polyethylene terephthalate, (“PET”), which are not easily recycled/remanufactured. In particular, plastic films are difficult to remanufacture in that individual characteristics of potentially remanufactured products vary considerably. Likewise, the variety of extruded resins in such films pose significant recycling challenges.
These challenges are evidenced by the fact that presently only about 4.5% of all waste plastic film is recycled in the United States and plastic film makes up approximately 3.1% of all landfilled municipal solid waste. In view of the above, it is desirable to have a transfer film that can be used a large number of times.
As such, a need exists for a method and apparatus for transfer lamination which provides an ease of manufacture and cost savings currently unavailable with known processes. A need also exists for a transfer lamination process that does not require the disposal and/or recycling of a transfer film after a limited number of laminations. As discussed in detail herein, the present invention addresses these needs.
It is an object of the present invention to provide a method and apparatus for transfer lamination.
It is an additional object of the present invention to provide a method and apparatus for transfer lamination which provides an ease of manufacture and cost savings currently unavailable with known processes.
It is another object of the present invention to a provide method and apparatus for transfer lamination in which a transfer film need not be discarded or recycled after a single lamination.
It is an additional object of the present invention to provide a method and apparatus for transfer lamination which provides an ease of manufacture and cost savings through the inline coating of a transfer film for reuse while it is in use in a transfer lamination process.
It is another object of the present invention to provide a method and apparatus for transfer lamination in which a transfer film does not need to be discarded or recycled after a single lamination as it is coating for reuse during a transfer lamination process.
It is an object of the present invention to provide a method and apparatus for transfer lamination in which a breakaway layer may be easily applied to a transfer film.
It is yet another object of the present invention to provide a method and apparatus for transfer lamination in which a breakaway layer is easily applied to a transfer film through an inline process in which the film is bonded to a substrate prior to application of the breakaway layer.
It is an additional object of the present invention to provide a method and apparatus for transfer lamination in which a breakaway layer is applied to a transfer film through an inline process in which the film is bonded to a substrate prior to application of the breakaway layer resulting in a breakaway layer superior to that produced through known offline processes.
An embodiment of the inventive method of transfer lamination involves metallizing a first side of a film and then bonding the metallized first side to a substrate. Then a breakaway coating is applied to a second side of the film after it has been bonded to the substrate. The bonded film/substrate is then cured. The film is subsequently stripped away leaving metal from the film deposited on the substrate. The application of the breakaway coating is performed as an inline part of the transfer lamination process.
Another embodiment of the invention involves a method for transfer lamination which includes bonding a metallized first side of a film to a substrate and applying a breakaway coating to a second side of the film after it has been bonded to the substrate. The bonded film and substrate are then cured in a first zone of an oven. The film is then removed from the substrate leaving metal from the film deposited on the substrate. The substrate is then coated to facilitate printing on said metallized substrate and cured again in a second zone of the oven. The application of the breakaway coating is performed as an inline part of the transfer lamination process.
Another embodiment of the invention involves a system for transfer lamination of a substrate. The system includes a bonding station for bonding a metallized first side of a film to a substrate and a first coating station for applying a breakaway coating to a second side of the film after it has been bonded to the substrate. The system further includes a curing station for curing the bonded film and substrate a stripping station for removing the film from the substrate.
These and other objects, features and advantages of the present invention will become apparent in light of the detailed description of the best mode embodiment thereof, as illustrated in the accompanying drawings.
Referring to
After a side of the film has been coated with the breakaway layer, typically a polymer such as an acrylate or urethane, the film is metallized. The metallization step is also offline from the transfer lamination process and involves placing the coated film in a relatively large metallizer where metals are vacuum deposited on the coated film.
Once the coated film has been metallized, it is bonded to a substrate in a third step, represented by reference number 30. In this step, the coated and metallized film is placed within a transfer lamination apparatus and the film is bonded via pressurized bonding with an adhesive to the substrate. Once bonded, the film/substrate typically are cured typically in an oven. The film is then stripped away from the substrate when it emerges from the oven leaving the metal and breakaway layer on the substrate. The metallized substrate may then be coated and cured again in the oven resulting in the end product.
As stated, the above-recited steps of coating the film with a breakaway layer, metallizing the coated film and then using the metallized, coated film in a transfer lamination process, are separate from one another. As will be readily appreciated, the greater number of steps in the manufacture of a product, the higher the associated manufacturing costs and degree of manufacturing difficulty.
Turning now to
The transfer film 70 has been coated with a breakaway layer on a first side which is to be bonded to the substrate 80. The film 70 has also been previously metallized in a separate process. For the present discussion, the film is described as being new, i.e., no side has been previously coated with a breakaway layer. Alternatively, however, the breakaway later present on the first side could also be the result of the inventive process, that is, the film may have been previously used and inline coated as described herein.
As the substrate 80 is unwound and travels in direction A, an adhesive/glue is applied by an applicator 90. The adhesive allows the film 70 and substrate 80 to be securely bonded. After the application of the adhesive, the film 70 encounters an idler roller 100, which changes the path of the film and guides it toward a bonding station.
In particular, the film 70 and substrate 80 are bonded through pressure bonding which is accomplished at a bonding station, e.g. rollers 110. Although rollers are depicted, it will be apparent that other means of bonding whether pressurized or not may be employed including the use of a pressurizing chamber instead of rollers.
Once the transfer film 70 has been bonded to the substrate 80, a first intermediate product 120 is formed. This intermediate product 120 includes the transfer film 70 with the substrate 80 bonded to the first side of the film 70. A second opposite side of the transfer film 130 remains uncoated.
As shown, this second, uncoated side 130 is then passed through a gravure coating station 140. At the gravure station 140 a roller running in a coating bath (not shown) effectively deposits a coating onto the uncoated side 130 as it passes between the coating roller and a pressure roller (not shown). The gravure coating station 140 applies a breakaway layer 150 to the uncoated side 130 eliminating the need to coat the side 130 in a separate step prior to reuse in the present lamination process.
The inline coating of the uncoated side 130 of the film 70 is an important aspect of the present invention. By providing a breakaway layer 150 to the transfer film 70 during the lamination process, a normally separate manufacturing step is avoided facilitating the convenient, cost-effective reuse of the film 70. This simplified, streamlined process provides a cost savings and ease of manufacture that is presently unknown in the art.
Moreover, it has been found that the inline coating of intermediate product 120, i.e., the film 70 bonded to the substrate 80 is superior to offline coating. In particular, it is easier to apply a breakaway layer 150 to a film 70 that is supported by a relatively rigid substrate 80 than it is to coat an unbonded flexible film. Applying a breakaway layer to the bonded intermediate product 120 results in a potentially more uniform layer as well due to this enhanced rigidity.
The simplified, cost effective manufacturing process increases the probability that the film 70 will be reused multiple times as the inline application of the breakaway layer is convenient and results in a potentially better, more uniform layer to be metallized.
While the present invention contemplates use of a gravure process, it will be appreciated that other coating methods for the inline application of the breakaway layer may be employed. Such methods may include reverse roll coating and the like as long as they can effectively apply the breakaway layer.
Returning now to
Once this coating has been applied, the second intermediate product 200 is directed toward a second curing station, in this example, a second zone of oven 160 where it is placed to further cure. The result of this second curing process is the end product, which is collected at a collection station, e.g., a roll 230.
Turning now to
The metallized film is then bonded to a substrate, generally paper, in a second step 310. Importantly, a breakaway layer is then applied to a second side of the transfer film at step 320 so that, as discussed above, the film may be easily and inexpensively reused.
The bonded film/substrate is then cured at step 330. This process is generally accomplished through the use of a multi-zone oven.
Once the film/substrate has been cured, the film is removed from the substrate at step 340. At this point, the substrate is coated with the breakaway layer and the metal layer. The film with its pre-coated side, can then be reused beginning with metallization step 300. Optionally, the substrate may be coated for printing in an additional, subsequent step and then cured again in the oven.
Moreover, it may also be possible to reuse the previously used side of the film. That is, one could strip the remaining material off the used side and recoat it with a breakaway layer. Alternatively, one could simply apply a breakaway layer over any residual material on the previously used side.
In sum, the present invention is a method and apparatus for transfer lamination which, through the inline coating of a transfer film, provides an ease of manufacture and cost savings currently unavailable with known processes. The inventive method and apparatus also does not necessitate the disposal and/or recycling of a transfer film after a limited number of uses and provides an easily applied and potentially superior breakaway coating.
Although this invention has been shown and described with respect to the detailed embodiments thereof, it will be understood by those of skill in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed in the above detailed description, but that the invention will include all embodiments falling within the scope of this disclosure.
This application claims the benefit of U.S. Provisional Application Ser. No. 61/186,531, filed on Jun. 12, 2009, herein incorporated by reference in its entirety.
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