Patent Application
20150132575
The technical field generally relates to luminescent fibers that include a luminescent compound, articles including the luminescent fibers, and methods of forming the luminescent fibers. More particularly, the technical field relates to luminescent fibers that include an organic luminescent compound that retains luminescent properties after forming the luminescent fibers, articles including the luminescent fibers, and methods of forming the luminescent fibers.
Luminescent fibers are known for use in various authentication applications. For example, value documents such as banknotes and checks often include the luminescent fibers to provide one mechanism for authentication of the value documents. The luminescent fibers are generally incorporated in or on the value documents, often within substrate material of the value documents such as paper stock, and the luminescent fibers are generally difficult to remove or add to the substrate material after original production of the value documents.
Conventional luminescent fibers are dyed with organic luminescent dyes that emit radiation upon stimulation by UV or visible light, with the emitted radiation detected either by human or machine observation. Regenerated cellulose such as, but not limited to, cupro, lyocell, viscose, and modal, are commonly employed as the luminescent fibers due to excellent compatibility with paper stock. However, incorporation of conventional organic luminescent dyes into the fibers that include the regenerated cellulose while retaining luminescent properties of the luminescent dyes is often challenging. In particular, regeneration processes that are employed to form the regenerated cellulose often involve harsh processing conditions and employ compounds that denature the organic luminescent dyes. As a result, many luminescent dyes are coated on surfaces of the fibers that include the regenerated cellulose after production of the fibers. However, surface coatings are subject to wear and may exhibit breakdown or change of the luminescent properties due to environmental conditions such as humidity and pH. While inorganic pigments in particulate form have been incorporated into the fibers that include the regenerated cellulose, the inorganic pigments generally exhibit high abrasivity and generally must be present in high densities, both of which features modify the basic physical properties of the fibers that include the regenerated cellulose. Further, high loading of the inorganic pigments is generally required to achieve sufficiently high luminescent emissions.
Accordingly, it is desirable to provide luminescent fibers that include organic luminescent compounds that retain luminescent properties even when present under harsh conditions associated with regenerating cellulose such that the organic luminescent compounds can be incorporated within the fibers that include the regenerated cellulose, as opposed to only coating a surface of the fibers that include the regenerated cellulose. In addition, it is desirable to provide articles including the luminescent fibers and methods of forming the luminescent fibers. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
Luminescent fibers, articles including the luminescent fibers, and methods of forming the luminescent fibers are provided herein. In an embodiment, a luminescent fiber includes a regenerated cellulose and a luminescent polycyclic compound. The luminescent polycyclic compound includes a heterocyclic ring. The heterocyclic ring includes two nitrogen atoms therein.
In another embodiment, an article includes a substrate and luminescent fibers incorporated in the substrate. The luminescent fibers include a regenerated cellulose and a luminescent polycyclic compound. The luminescent polycyclic compound includes a heterocyclic ring. The heterocyclic ring includes two nitrogen atoms therein.
In another embodiment, a method of forming luminescent fibers includes combining a cellulose solution and a luminescent polycyclic compound to produce a fiber-forming composition. The luminescent polycyclic compound includes a heterocyclic ring. The heterocyclic ring includes two nitrogen atoms therein. The fiber-forming composition is spun to form the luminescent fibers.
The various embodiments will hereinafter be described in conjunction with the following drawing, wherein like numerals denote like elements, and wherein:
The following detailed description is merely exemplary in nature and is not intended to limit the various embodiments or the application and uses thereof. Furthermore, there is no intention to be bound by any theory presented in the preceding background or the following detailed description.
Luminescent fibers, articles including the luminescent fibers, and methods of forming the luminescent fibers are provided herein. The luminescent fibers include a regenerated cellulose and a luminescent polycyclic compound. As referred to herein, “regenerated cellulose” refers to cellulose that is chemically modified through various conventional processes for conversion into semi-synthetic polymer fibers that are generally known as rayon. As also referred to herein, “luminescent polycyclic compound” is a compound that has at least two identifiable cyclic groups that may or may not share common bonds within the ring structures. The luminescent polycyclic compound includes a heterocyclic ring that has two nitrogen atoms in the heterocyclic ring, i.e., the heterocyclic ring includes at least two nitrogen atoms as part of the ring structure in the heterocyclic ring. The luminescent polycyclic compound retains luminescent properties even when present under harsh conditions associated with regenerating cellulose. Without being bound to any particular theory, it is believed that the heterocyclic ring that includes the two nitrogen atoms provides excellent stability to the luminescent polycyclic compound and enables the luminescent polycyclic compound to retain luminescent properties even when exposed to harsh conditions, such as alkaline conditions, that are associated with regenerating cellulose. As such, the luminescent polycyclic compound may be combined in a cellulose solution during regeneration of the cellulose, prior to spinning, with the luminescent polycyclic compound being present throughout a bulk of the luminescent fibers after spinning, as opposed to only coating a surface of the luminescent fibers.
In an embodiment and as shown in
The luminescent fiber includes regenerated cellulose and a luminescent polycyclic compound. Any conventional regenerated cellulose may be suitable for the luminescent fiber, and the regenerated cellulose may include rayon. Examples of suitable regenerated cellulose include, but are not limited to, those chosen from the group of cupro, lyocell, viscose, modal, or combinations thereof. The aforementioned examples of regenerated cellulose differ by mode of manufacture and various requirements of the cellulose that is subject to regeneration (e.g., lignin-containing or lignin-free), and the various examples of the regenerated cellulose have different physical properties. In all embodiments, the regenerated cellulose is formed by first forming a cellulose solution through conventional techniques. For example, cupro may be formed through the cuprammonium method using an ammoniac copper hydroxide to dissolve the cellulose and form a cellulose solution. As another example, lyocell may be formed through the lyocell process using n-methylmorpholine n-oxide to dissolve the cellulose and form a cellulose solution. As yet another example, viscose may be formed by treating cellulose with sodium hydroxide and carbon disulfide to form a cellulose solution. Viscose is particularly suitable for the luminescent fibers 14 when the luminescent fibers 14 are to be included in articles 10 that have the substrate 12 that includes paper, since the luminescent fiber that includes viscose is highly compatible with customary paper stocks based on cellulose and printable by various printing processes, such as offset, so that there are no problems with using such luminescent fibers 14 for marking papers, specifically value documents.
In the aforementioned techniques, due to the compounds employed to regenerate the cellulose, the cellulose is regenerated under harsh conditions that destroy luminescent properties of various conventional organic luminescent compounds. In particular, the cellulose is generally regenerated under alkaline conditions and at basic pH. However, the luminescent polycyclic compounds described herein are capable of withstanding the harsh regenerating conditions while retaining luminescent properties, thereby enabling the luminescent polycyclic compound to be combined with the cellulose solution prior to spinning. In embodiments, the luminescent fiber is formed by combining the cellulose solution and the luminescent polycyclic compound to produce a fiber-forming composition, followed by spinning the fiber-forming composition. The luminescent polycyclic compound may be combined with the cellulose at any time prior to spinning the fiber-forming composition to form the luminescent fibers 14. In this regard, the cellulose may be regenerated in the cellulose solution in the presence of the luminescent polycyclic compound to form the fiber-forming composition prior to spinning, i.e., the luminescent polycyclic compound may be present in the cellulose solution at the same time as other compounds that are employed to regenerate the cellulose. After spinning, the luminescent fibers 14 are cut to a desired size. Dimensions of the resulting luminescent fibers 14 are not particularly limited. However, in embodiments, the luminescent fibers 14 have an average nominal diameter of from about 3.3 to 28 dtex, and may have a length of from about 2 to 6 mm.
The luminescent polycyclic compound includes at least two identifiable cyclic groups that may or may not share common bonds within the ring structures. At least one of the cyclic groups is a heterocyclic ring that includes two nitrogen atoms as part of the ring structure. As alluded to above, it is believed that the heterocyclic ring that includes two nitrogen atoms provides excellent stability to the luminescent polycyclic compound and enables the luminescent polycyclic compound to retain luminescent properties even when exposed to harsh conditions, such as alkaline conditions, that are associated with regenerating the cellulose. Examples of suitable heterocyclic rings that may be included in the luminescent polycyclic compound include unsaturated six-membered nitrogen heterocycles such as, pyrazine, pyrimidine and pyridazine, each of which exhibit excellent stability and have stable aromatic rings. All rings in the luminescent polycyclic compound may be heterocyclic, or the luminescent polycyclic compound may have a combination of carbon rings and heterocyclic rings.
In embodiments, the luminescent polycyclic compound is a luminescent bicyclic compound that includes the heterocyclic ring and one additional ring. Examples of suitable luminescent bicyclic compounds include, but are not limited to, substituted or unsubstituted quinoline or substituted or unsubstituted quinazolinone. In embodiments, the luminescent polycyclic compound emits radiation in the visible and/or infrared spectrum. Commercially available luminescent polycyclic compounds that include organic derivatives of quinazolinone are sold under the tradename Lumilux® by Honeywell International, Inc. Specific examples of suitable Lumilux® products are Lumilux® Yellow CD 792 and Lumilux® CD394. In embodiments, the luminescent polycyclic compound is present in the luminescent fiber in an amount of at least about 1 weight %, such as from about 1 to about 5 weight %, based on the total weight of the luminescent fiber.
As alluded to above, the luminescent polycyclic compound retains luminescent properties despite being present during regeneration of the cellulose under harsh conditions. Luminescence may be measured in accordance with a lightfastness test whereby a round cuvette (Ø5 cm) is filled with luminescent fibers 14. The luminescent fibers 14 are irradiated using conventional sun simulation equipment, such as a Hönle SOL 2 unit (sun light behind window class). Fluorescent intensity may be determined under irradiation from a 366 nm UV lamp, with a Luminancemeter from Minolta employed to determine fluorescent intensity in the visible green to yellow spectrum. In embodiments, the luminescent fibers 14 exhibit at least 85% retention of relative intensity in the visible green to yellow spectrum after an irradiation time of 35 hours using the Hönle SOL 2 unit. Furthermore, the luminescent fibers 14 that include the luminescent polycyclic compounds described herein also exhibit excellent chemical resistance to various agents, such as hydrochloric acid, sulfuric acid, ethanol, acetone, and xylene, as determined by retention of fluorescent intensity after exposure to the aforementioned agents. Further still, the luminescent fibers 14 that include the luminescent polycyclic compounds described herein also exhibit excellent thermal stability, as determined by retention of fluorescent intensity after a duration of 30 minutes in an oven at 120° C. internal ambient temperature.
The following Examples are intended to illustrate the luminescent fibers 14 as described herein, and are not to be viewed as limiting.
Fibers are prepared in accordance with the following procedure:
A cellulose solution was prepared by treating cellulose with sodium hydroxide and carbon disulfide to form the cellulose solution in accordance with conventional viscose fiber preparation techniques. Prior to spinning the cellulose solution into fibers, the following luminescent compounds shown in TABLE I were added to the cellulose solution in an amount of 3 weight %, based on the total weight of the cellulose solution.
After combining the aforementioned luminescent compounds of Examples A-C into the cellulose solution, the cellulose solution is spun to form luminescent fibers 14. The luminescent fibers 14 of Example C also failed to exhibit luminescent properties, although it is believed that the failure of Example C to exhibit luminescent properties is due to excessive solubility of the luminescent compound under the harsh alkaline and acid conditions of the cellulose spinning procedure, and is not associated with destruction of the luminescent compound. The luminescent compound of Comparative Example A was not combined into the cellulose solution. Luminescent compounds in the benzoxazinone class have exhibited no fluorescent effect after including in cellulose solutions due to destruction of the benzoxazinone class luminescent compounds under the harsh conditions within the cellulose solutions during viscose preparation. It is believed that benzoxazinone class compounds are destroyed because the heterocyclic ring only includes a single nitrogen atom. The viscose fibers of Comparative Example A were prepared by first spinning the viscose fibers and then reactive dyeing the viscose fibers with the benzothiazole class reactive dye.
Chemical resistance of the luminescent fibers 14 is then tested in various solutions as listed below in TABLE II. However, because the luminescent fibers 14 of Example C failed to exhibit luminescence after spinning, Example C was not tested for chemical resistance.
To test for chemical resistance, approximately 20 ml of short-cut fibers were deposited in a 50 ml beaker. Solutions, as indicated in TABLE II, were then added in different trials to the 50 ml beaker in a sufficient amount to cover the fibers. The fibers were agitated with a glass stick to eliminate air bubbles and to make sure all fibers were wetted with the solvent. Then the fibers were allowed to stand for 30 min at room temperature in the solvent. After this time the fibers were separated (by a nutsch or sieve). The fibers in contact with water based chemicals were rinsed with water and then dried on air under room temperature. Chemical resistance was determined by retention of fluorescent intensity in the yellow to green visible spectrum after exposure to the aforementioned solutions and after irradiation with UV or visible light. TABLE III shows the intensity of fluorescence for Examples A and B, as well as Comparative Example A, indicated on a scale of 0 to 4 with 4 representing a retention of original fluorescent intensity, 3 representing a minor change in fluorescent intensity, 2 representing a considerable change in fluorescent intensity (less than 50% reduction in original intensity), 1 representing a major change in fluorescent intensity (more than 50% reduction in original intensity), and 0 representing total loss in fluorescent intensity, all as determined through visual inspection.
The luminescent fibers 14 that were tested for chemical resistance, as described above, were also tested for temperature resistance, as determined by retention of fluorescent intensity after a duration of 30 minutes in an oven at 120° C. internal temperature. Examples A and B, as well as Comparative Example A, all exhibited fluorescent intensity of 4 as measured in accordance with the methodology described above.
Lightfastness was also tested by filling a round cuvette (Ø5 cm) with luminescent fibers 14 prepared in accordance with Examples A and B, and also viscose fibers with a reactive dyeing of the luminescent compound of Comparative Example A. The luminescent fibers 14 were irradiated using a Hönle SOL 2 unit (sun light behind window class). Fluorescent intensity was determined under irradiation from a 366 nm UV lamp, with a Luminancemeter from Minolta employed to determine fluorescent intensity. Example A exhibited about a +1% retention of fluorescent intensity after an irradiation time of 35 hours using the Hönle SOL 2 unit, indicating that Example A not only retained its original fluorescent intensity, but actually exhibited increased fluorescent intensity after irradiation for 35 hours. Although this result was not investigated in detail, it is assumed that under irradiation the bleaching of the viscose is faster than the deterioration of the fluorescent compound. The whiter the viscose, the more intense the fluorescence. Example B exhibited about a −12% retention of fluorescent intensity after an irradiation time of 35 hours using the Hönle SOL 2 unit. Comparative Example A exhibited a substantial retention of fluorescent intensity after an irradiation time of 35 hours using the Hönle SOL 2 unit.
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims.
This application claims the benefit of U.S. Provisional Application No. 61/904,216, filed Nov. 14, 2013.
| Number | Date | Country | |
|---|---|---|---|
| 61904216 | Nov 2013 | US |
