FOR

SUPERCRITICAL FLUID CLEANING OF BANKNOTES AND SECURE

DOCUMENTS UTILIZING OZONE

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority to U.S. provisional application Serial No. 62/648,143, filed March 26, 2018, the disclosure of which is incorporated herein by reference in its entirety.

TECHNICAL FIELD

The present invention relates generally to the cleaning of secure documents such as banknotes without causing damage thereof. More specifically, the present invention relates to the use of supercritical fluids and/or ozone to clean secure documents or banknotes without damaging their visual data, inks, substrates or security features. The apparatus and process is also effective in disinfecting the secure documents or banknotes.

BACKGROUND OF THE INVENTION

High security documents such as banknotes have substrates formed from various materials. In the United States, paper currency is made from a non-woven combination of 75% cotton and 25% linen fibers. In most other countries, pulp-based substrates are used. Some countries, such as Canada, have used cotton and paper blended banknotes. In addition, countries such as Australia, New Zealand and Canada have issued banknotes having polymer substrates, e.g., substrates including biaxially oriented polypropylene. The substrate, which may include one or more plies of the substrate material, may include security features such as laminated polymer or paper security threads, planchettes, and watermarks formed directly into the substrate. For example, U.S. paper currency contains small segments of red and blue fibers scatered throughout for visual identification.

Banknotes also include visual data printed on the substrates. The visual data may include images such as portraits, authentication information such as serial numbers, or both. The inks used to print on the substrates may include special dry color pigments blended with oils and extenders and phosphor chips containing layered micro-interference layers. Such inks include Flexo inks, gravure inks, and thicker intaglio inks.

High security documents such as banknotes are generally formed on substrate materials that are frequently equipped with security elements, which are difficult to imitate and which permit even a layman to check the authenticity of the printed information or the document. Security elements can be, for example, windowed security threads, which are visible in certain areas on the surface of the banknote, applied foils, which have a transparent or metallized embossed hologram, blind embossings, so-called "latent images" produced by printing technology or by printing and embossing technology, which render different information from different viewing angles, prints containing optically variable pigments and producing different color effects depending on the viewing angles, and prints comprising metallic effect ink, which have metallic luster, for example, in a gold, silver or bronze tone. In addition to these unaided features, there are quasi-public security threads, fibers and inks, which fluoresce or phosphoresce under illumination with ultraviolet ("UV") or infrared ("IR") sources.

Other security features in paper currency include numeric watermarks, Guilloche patterns, which are narrow geometric paterns created by a geometric lathe or mathematically, microprinting, digital watermarks, magnetic inks and threads, demetalized security threads, holographic features, fluorescent inks, lenticular lens array security threads, and fluorescent and non-fluorescent security threads. High level covert security features include ENIGMA (De La Rue International) and M (Geiseke and Devrient). An important security feature in currency is the M feature, where "M" refers to "machine readable." The M feature is a colorless, inorganic oxide integrated into the paper substrate, the printing ink, security ink, or a security thread, without causing any change in the appearance of the banknote. The powdered M feature may be blown into the paper substrate in a trail to identify a particular banknote denomination. When exposed to a flash from a strong source of light, the M feature emits a band of light in a split second that rapidly disappears. This repeatable, characteristic light band of the banknote can be authenticated by a reading device. The central banks protect the security of the M feature by requiring the use of special sensors to recognize it.

As counterfeiters have become more sophisticated, the security features in such documents have had to become more advanced as well in order to prevent widespread fraud. As the substrates of such secure documents have become more advanced, the cost to produce them has also increased, thus making the replacement of worn currency quite expensive. Therefore, it is important that in addition to being secure, such documents must have a high level of durability.

Banknotes are removed from circulation for a variety of reasons. Based on one study, 81% of notes are removed because of soiling, 9% are removed because of damage caused by mechanical means, especially tearing, 5% are removed because of graffiti on the notes, 4% are removed because of general wear and tear, and 1% are removed because of damage to the security elements. Generally, 60% to 80% of all rejected bank notes result from to soiling.

Banknotes have a finite time in circulation due to soling and tearing of the notes in use by the public. For example, it takes about 4,000 double folds (first forward and then backward) before a U.S. paper bill will tear. Banknotes are handled in many ways during their usable life and experience a variety of mechanical stresses, as well as being brought into contact with substances that can dirty the notes, resulting in difficulty in their authentication and use. One of the major determinants of the banknote life, which is shortest for the lowest denominations, is soiling. Work by the Dutch National Bank has shown that the primary source of soiling is deposited sebum following contact with fingers, which sebum eventually oxidizes and becomes yellow. Further, a study by the Microbiology Department of Karachi University in Pakistan concluded that currency notes could also carry contaminants that cause diarrhea and urinary tract infections, in addition to skin burning and septicemic infection. One study found that 26% of notes contained high levels of bacteria, and 80% of notes had some traces of bacteria. An even more concerning finding was that pathogens, including bacteria and viruses, on banknotes have the potential to develop resistance to antibiotics, making the treatment of infectious diseases more difficult.

Such "dirty" money is not simply confined to developing nations. Some of the studies on contaminated currency emerging from the United States were equally revealing. In a recent survey conducted for the Department of Endocrinology at the Wright-Patterson Medical Center in Ohio, researchers collected 68 one-dollar notes from a concession stand at a high school sporting event and a grocery store check-out counter, and examined them for bacterial contamination. Only four bills (six percent) contained no detectable germs.

Given the huge amounts of banknotes in circulation for even small countries, determining the fitness of banknotes is not only of importance in cost control, but also poses a serious technical challenge in terms of processing speed and accuracy. Moreover, the extent of dirtiness of a banknote cannot easily be captured in objective rules. As a result, not only is accurate determination of the fitness of banknotes of interest from a cost point of view, but also cleaner notes are more secure and more attractive to the public. Studies have shown that soiling is one of the primary reasons for classifying banknotes unfit for circulation by banknote fitness sensors using both white light and specific wavelength sources. In order to improve durability and soil resistance of these substrates, it is known to use documents of value with a dirt-repellent and/or moisture resistant protective layer to extend the documents' lifetime and fitness for circulation. Such a protective layer typically contains cellulose ester or cellulose ether for the greater part and micronized wax for a lesser part, and is applied all over the banknotes. The micronized wax is dispersed by kneading or mixing with oil, an ink binder or a mixture thereof. The sheets freshly printed with the protective layer can be stacked without difficulties and without any black ink from one sheet staining the sheet below.

Another coating composition containing only a binder and no fillers has been applied to the banknote paper, which has a large surface area or high surface roughness due to its porosity. The composition is applied in a layer and has a thickness with a smooth surface, thus having little possibility for resulting dirt deposits. Further, the coating is thin enough not to impair the other stated properties of the paper.

A problem with this approach is that known protective layers do not last or wear well. Conventional protective layers comprising water-based lacquers usually fail to completely meet a demanding requirement profile. For example, very good dirt repellence and adhesion qualities contravene resistance to the penetration of liquid, and vice versa. Water-based lacquers, therefore, currently meet the high requirements for a protective layer in security printing, and in particular banknote printing, only if a second component in the form of a crosslinking agent is added.

Another problem relating to banknotes is that central banks need to replace worn and soiled notes at a cost to taxpayers. In the United States, the volume of notes manufactured is in the billions of notes per year (4-6 billion typically). The production of banknotes is costly, particularly so for the higher denominations, which have many security features that are both accessible to the public and machine readable by bill acceptors and the central banks using high speed sorters. Banknote sorters made by Geiseke and Devrient, De La Rue International and Toshiba typically process banknotes at rates of 10-40 banknotes/second and perform a number of diagnostics using sensors in the notes' travel path. These sensors are a combination of authentication sensors as well as note fitness sensors. The fitness sensors primarily use imaging and analysis of the captured images to determine if the banknote should be destroyed or returned to circulation.

The cost of replacing banknotes is significant as the higher denominations contain Level I, II and III security features for use by the public, commercial banks, single note acceptor devices and central banks. In the United States, for example, the currency replacement budget is $747 million and breaks down as follows:

$1 and $2 notes— 5.5 cents per note

$5 and $10 notes— 8.5 cents per note

$20 and $50 notes— 9.2 cents per note

$100 note— 12.5 cents per note

$100 note to be released in October 2013— 13 cents per note

With over 150 billion new banknotes being manufactured and printed every year around the world, the cost of replacement of unfit currency has approached $10 billion annually. In addition to the replacing the notes, there is a sizable waste disposal cost associated with the destruction of the shredded notes that are determined to be unfit. This amounts to about 150,000 tons of waste worldwide annually, based on total worldwide circulation of 150 billion notes. This is particularly problematic for polymer notes, which also pose larger environmental problems with respect to burning and landfill disposal.

Based on these facts, there is a need to employ a manner for cleaning banknotes, which are soiled but not tom or ripped, that does not attack the print and security features of the note. There is still a further need for a system that applies a certain class of fitness parameters to cause identified banknotes to be cleaned using a method that does not attack the print and security features before making a determination that they should either be returned to circulation or destroyed.

SUMMARY OF THE INVENTION

In general, in one aspect, the invention features a method for cleaning a secure instrument including a substrate, visual data and a security feature, including exposing the secure instrument to ozone sufficient to clean the substrate and not compromise the security feature and the visual data, where to clean the substrate includes to remove one or more substances from the substrate into the ozone or to chemically alter the one or more substances in or on the substrate such that exposing the secure instrument to a supercritical fluid removes the one or more substances.

Implementations of the invention may include one or more of the following features. The one or more substances may include contaminants, dirt, sebum, pathogens, or any combination of these. The exposing may further include flowing the ozone through and around the secure instrument. The method may further include exposing the secure instrument to the supercritical fluid at a temperature and a pressure and for a duration sufficient to additionally clean the substrate and not compromise the security feature and the visual data, where to additionally clean the substrate includes to remove the one or more substances or one or more additional substances from the substrate into the supercritical fluid. The supercritical fluid may include CO ₂ . The secure instrument may be exposed to the supercritical fluid subsequently to ozone. The secure instrument may be disposed in a chamber, where the secure instrument is exposed to the supercritical fluid in the chamber after the chamber is evacuated of ozone. The secure instrument may be exposed to ozone in a first chamber, where the secure instrument is exposed to the supercritical fluid in a second chamber separate from the first chamber. The secure instrument may be exposed to the supercritical fluid concurrently with ozone. The ozone may be dissolved in a solvent when combined with the supercritical fluid. The solvent may be ethanol. The secure instrument may be a banknote.

In general, in one aspect, the invention features an apparatus for cleaning one or more secure instruments, each secure instrument including a substrate, visual data and a security feature, including a chamber containing ozone sufficient to clean the substrate and not compromise the security feature and the visual data of the one or more secure instruments, and a structure for holding the one or more secure instruments in the chamber so that the ozone circulates through and around the one or more secure instruments to remove one or more substances from the substrate into the ozone or to chemically alter the one or more substances in or on the substrate such that exposing the secure instruments to a supercritical fluid removes the one or more substances.

Implementations of the invention may include one or more of the following features. The apparatus may further include an agitation mechanism for circulating the ozone through and around the one or more secure instruments in the chamber. The structure for holding the one or more secure instruments may include a tray. The chamber may further contain the supercritical fluid at a temperature and a pressure and for a duration sufficient to additionally clean the substrate and not compromise the security feature and the visual data of the one or more secure instruments, where to additionally clean the substrate includes to remove the one or more substances or one or more additional substances from the substrate into the supercritical fluid. The supercritical fluid may include CO ₂ . The apparatus may further include a fluid pump configured to combine ozone dissolved in a solvent with the supercritical fluid. The solvent may be ethanol. The apparatus may further include a second chamber containing the supercritical fluid at a temperature and a pressure and for a duration sufficient to additionally clean the substrate and not compromise the security feature and the visual data of the one or more secure instruments, where to additionally clean the substrate includes to remove the one or more substances or one or more additional substances from the substrate into the supercritical fluid, and a second structure for holding the one or more secure instruments in the second chamber so that the supercritical fluid circulates through and around the one or more secure instruments to remove the one or more substances or the one or more additional substances into the supercritical fluid. The one or more secure instruments may include one or more banknotes.

BRIEF DESCRIPTION OF THE DRAWINGS

The above-mentioned and other aspects, features and advantages can be more readily understood from the following detailed description with reference to the accompanying drawings, wherein:

FIG. 1 is a supercritical fluid phase diagram for carbon dioxide;

FIG. 2 is a flow chart showing the cleaning and sorting of banknotes in accordance with one embodiment of the present invention;

FIG. 3 is a flow chart showing the cleaning and sorting of banknotes in accordance with another embodiment of the present invention;

FIG. 4 is a flow chart showing the cleaning cycle of the present invention;

FIG. 5 is an exemplary high pressure supercritical fluid chamber;

FIG. 6 is a comparison of the same part of a U.S. $1 banknote before and after coating and oxidation with a sebum layer;

FIG. 7 shows the spectra for an uncirculated U.S. $1 banknote, the U.S. $1 banknote after the application of sebum, and the U.S. $1 banknote after supercritical fluid cleaning.

FIGS. 8 A and 8B show the reflectance spectra of banknotes coated with oxidized sebum both before and after supercritical C0 ₂ cleaning in accordance with the present invention; FIG. 9 shows the results of cleaning a 5 Euro note in accordance with the present invention;

FIG. 10 shows the diffuse reflection spectra of the bank note of FIG. 10A before and after cleaning with the supercritical fluid;

FIG. 11 shows the fluorescence spectra of security threads in banknotes both before and after cleaning in accordance with the present invention;

FIGS. 12A and 12B show the fluorescence spectra of security threads in banknotes both before and after cleaning in accordance with the present invention;

FIG. 13 shows the robustness of the UV excited emissive features in security fibers of a Russian Ruble;

FIG. 14 shows the robustness of the UV excited emissive security features in printing on a Chinese Yuan;

FIG. 15 shows the robustness of the UV excited emissive security features in printing on a British Pound before and after exposure to a supercritical fluid;

FIGS. 16A and 16B show the transient responses for a U.S. $1 note which is in circulation and which is not in circulation, respectively;

FIGS. 17A and 17B show the signals of the uncirculated note of FIG. 16B before and after cleaning with a supercritical fluid;

FIG. 18 shows a stack of U.S. $1 banknotes bound together with a strap;

FIG. 19 is an exemplary supercritical fluid cleaning chamber according to an embodiment of the invention;

FIGS. 20A and 20B is an exemplary supercritical fluid cleaning chamber according to another embodiment of the invention;

FIG. 21 is a schematic diagram showing an ozone-assisted cleaning cycle of the present invention; FIG. 22 shows the results of cleaning a Nigerian 1000 naira note with utilization of ozone in accordance with the present invention;

FIG. 23 shows the results of cleaning certain 200, 500, and 1000 naira notes with utilization of ozone in accordance with the present invention;

FIG. 24A shows the location of the diffuse reflectance measurements performed on certain 200, 500, and 1000 naira notes taken before and after cleaning with utilization of ozone in accordance with the present invention;

FIG. 24B shows the diffuse reflectance spectrum associated with the measurements of FIG. 24A;

FIG. 25 shows diffuse reflectance measurements performed on certain 200 naira notes taken before and after cleaning with utilization of ozone in accordance with the present invention;

FIG. 26 shows diffuse reflectance measurements performed on straps of 100 certain 200, 500, and 1000 naira notes taken before and after cleaning with utilization of ozone in accordance with the present invention;

FIG. 27 shows diffuse reflectance measurement data on a per-note basis for certain 200, 500, and 1000 naira notes taken after cleaning with utilization of ozone in accordance with the present invention;

FIG. 28 shows soil sensor measurements performed on one hundred notes for each of 200, 500, and 1000 naira denominations taken before and after cleaning with utilization of ozone in accordance with the present invention;

FIG. 29A shows a first holding structure configured to hold banknotes during cleaning, including with ozone or an ozone pretreatment step, in accordance with the present invention; and FIG. 29B shows a second holding structure configured to hold banknotes during cleaning, including with ozone or an ozone pretreatment step, in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention provides for the cleaning of secure documents such as banknotes using supercritical fluids. More specifically, the present invention provides a method of cleaning secure documents and banknotes using supercritical fluids in a manner that does not damage or otherwise compromise their visual data, inks, substrates or the security features contained therein. The security features and visual data are not compromised if they remain recognizable to the public, or upon machine readable examination, for their intended purpose. The substances that can be removed from the substrates of secure documents include contaminants, dirt, sebum from users' hands, and pathogens including bacteria and viruses.

Such cleaning may also have the effect of disinfecting the banknotes. For example, in some instances, it may be desired to disinfect or decontaminate the banknotes from dangerous chemicals, including but not limited to pesticides, mercury, and the like. Banknotes containing these dangerous chemicals may need to be cleaned for hygienic and/or safety purposes, enabling individuals to handle the banknotes to handle the banknotes to determine, for example, if the banknotes are counterfeits.

In some instances, chemicals on the banknotes may result in banknotes that are unsafe for handling by humans prior to disinfection or decontamination. Accordingly, in one embodiment, supercritical fluid cleaning of the banknotes may be achieved when the banknotes are covered by a material that prevents human contact with the banknotes. The material covering the banknotes may be any material known to those skilled in the art that may be configured to withstand desired temperature and pressure values within a supercritical fluid cleaning chamber. For example, in one embodiment, the banknotes may be covered in shrink wrap during cleaning. The material covering the banknotes may include at least one opening therein. The opening may be any size, shape, or configuration such that it may be small enough to prevent human contact with the banknotes, but large enough to enable supercritical fluid to flow there through and around the banknotes for disinfection. In one embodiment, for example, the at least one opening may include a plurality of slits.

It is estimated that the use of supercritical fluid cleaning will allow for a 10% reduction in the number of banknotes that are replaced annually, while allowing a significant percentage of soiled banknotes to be returned to circulation, thus saving governments worldwide approximately $1 billion annually and reducing the environment impact associated with unfit banknotes. At a 10% reduction in banknote annual production, the estimated decrease in the carbon footprint is 10 ⁶ tons of equivalent CO2.

FIGS. 2 and 3 illustrate systems for cleaning banknotes and secure documents according to embodiments of the present invention. As illustrated in FIGS. 2 and 3, the systems may be configured to cooperate with at least one supercritical fluid for cleaning banknotes and secure documents. Generally, supercritical fluids mixed with other gases and additives including ionic liquids, are effective solvents for a variety of organics and have been used in a number of cleaning and extraction applications including pharmaceutical manufacturing, perfume production, and decaffeination. Accordingly, in the embodiments of the present invention, any supercritical fluid known to those skilled in the art may be employed, so long as the supercritical fluid may be configured to aid in cleaning banknotes and secure documents.

Examples of supercritical fluids that may be used alone or in combinations thereof include, but are not limited to, CO2, N2O, CO, and SF ₆ . In particular, CO2 may be a supercritical fluid used alone or in combination with trace amounts of other supercritical fluids, including, but not limited to, N2O, CO, and SF ₆ . For example, N2O creates a degree of solubility in the system that cannot be accomplished with CO2 alone, and SFr, may be particularly useful in a cleaning system because of its highly electronegative properties.

FIG. 1 illustrates the supercritical fluid phase diagram for carbon dioxide. As illustrated in FIG. 1, CO has a supercritical point at 72.9 atm and 304.25 K. When in the supercritical phase, the CO2 material has a density approaching that of the liquid but has the space filling properties of a gas-like substance. When exposed to CO2 in a supercritical state, many organic materials become soluble without chemical attack in certain regions of the phase diagram. In particular, the materials may be removed into the supercritical fluid when their free energy is lowered. In particular, oily substances such as sebum (including after oxidation or hydrolysis), which is a major contributor to banknote soiling, as well as other oils and contaminants, are soluble in supercritical CO2 and other supercritical fluid mixtures. An important point to note is that the banknotes, after this cleaning, are dry since CO2 sublimates at room temperature and pressure. In addition, CO2 as a supercritical cleaning agent has very low environmental impact as one of the lowest impact greenhouse gas components. Any environmental impact associated with the use of CO2 is minimal compared to the cost and negative environmental impact of disposing of unfit currency, e.g., by burning or in landfills. Further, CO2 can be recycled for reuse and recirculation in the cleaning system after filtering out contaminants.

Additives may be combined with supercritical fluids to enhance cleanliness and other properties of banknotes and secure documents during the cleaning process. The additives may include, but are not limited to, mixtures of oxalic acid and water, methanol and/or ethanol, aqueous citric acid solutions, ammonium zirconium carbonate (AZC), and combinations thereof. In addition, the amount of additive(s) combined with the supercritical fluid(s) may be any desired amount known to those skilled in the art so long as the amount of additive(s) enables a desired result to be achieved. In one embodiment, for example, the additive(s) may be approximately 10% by volume to the fluid phase of the supercritical fluid. The additive(s) combined with the supercritical fluid(s) during the banknote cleaning process may be chosen based on the state of the banknotes prior to cleaning and/or the desired state of the banknotes after cleaning. For example, if the banknotes to be cleaned include marks from writing implements (e.g., pens or markers), an additive may be chosen that includes a mixture of oxalic acid and water and/or methanol. Particularly, experiments have shown that saturated solutions of oxalic acid in water may be effective for removing gel pen markings; saturated solutions of oxalic acid in methanol or ethanol may be effective for removing permanent marker markings; and mixtures of oxalic acid with water/methanol may be effective for removing ball point pen markings, as well as gel pen markings and permanent marker markings.

Additives may also be chosen to strengthen the banknotes during cleaning. Generally, mechanical wear from handling and folding of banknotes may cause a network of cellulosic fibers on the banknotes to become porous, which may result in mechanically limp banknotes. Accordingly, at least one additive may be combined with the supercritical fluid(s) that may lead to cross-linking of cellulose, which may result in at least a partial reversal of banknote limpness. For example, in one embodiment, use of aqueous citric acid solutions with a supercritical fluid may result in cross-linking of cellulosic fibers on the banknotes by self- catalyzed esterification of cellulosic hydroxyl groups. In addition, or alternatively, ammonium zirconium carbonate (ACZ) may be used as an additive, since ACZ may be configured to cross link cellulosic fiber and also may be configured to act as a coupling agent to graft starch onto the cellulosic fibers (generally, grafted starch on fiber surfaces may improve the bonding capabilities of the fibers).

FIGS. 2 and 3 illustrate systems for cleaning banknotes according to embodiments of the present invention. As illustrated in each of the figures, the systems may each include a sorting machine, such as those used by central banks. Central banks use high speed sorting machines, which are fited with optical and mechanical inspection systems that investigate the banknotes to determine if they must be destroyed or can be sent back into circulation. In particular, such high speed sorting machines can be used to interrogate banknotes for both authenticity and fitness. The largest sorting machines operate at 40 banknotes per second and can have as many as 16 sensors to remove counterfeits and notes that are not fit for recirculation. Accordingly, the sorting machines of the present invention may include fitness sensors that may be configured to operate primarily on optical image analysis and examine a number of parameters including tears, tapes, graffiti and soiling. Other sensors may be used to determine banknote limpness as another metric for determining when the notes are fit or have to be replaced. In addition, banknotes may be authenticated to determine whether or not they are counterfeit using the notes' security features, including both public and machine readable security features. Authentication information, which may be machine readable, may also be alphanumeric or image data printed on the banknotes.

The fitness sensors may be configured to analyze incoming banknotes and select notes which are unfit due to soiling but are otherwise still viable in terms of limpness and lack of tears, rips and graffiti. These parameters for acceptable fitness characteristics can be determined and optimized by the specific central bank based on population trends and banknote acceptance metrics. In one embodiment, shown in FIG. 2, all banknotes may be cleaned in a supercritical fluid cleaning chamber and then sorted for either recirculation or destruction and/or shredding, depending on whether they meet the predetermined fitness criteria. As shown in FIG. 3, in another embodiment, banknotes that are fit but for their soil level can be routed to a supercritical fluid cleaning chamber.

Banknotes that are selected for cleaning may be placed in a chamber (e.g., FIG. 5), where supercritical C0 ₂ may be applied at an optimal pressure, temperature, and duration for the specific banknote denominations, designs and substrates to remove the soil deposits from the banknote. The required or optimal temperature, pressure and duration will depend on the liquid or liquids in the supercritical fluid, as well as any additions such as ionic fluids or other gases. FIGS. 2 and 3 illustrate that the cleaned banknotes may then be routed to a second sorting system, which accepts the supercritical fluid-cleaned notes and performs a fitness measurement to qualify those ready for reuse by the public from those that were not successfully cleaned. The latter may be sorted and separated for destruction and/or shredding.

The banknotes may be cleaned in the chamber individually or in stacks of multiple banknotes. Each stack of banknotes may include any number of banknotes known to those skilled in the art so long as each banknote in the stack is capable of being cleaned within the chamber. In one embodiment, for example, each stack of banknotes may include approximately 100 banknotes. The stacks of banknotes may be cleaned in the chamber individually or in bundles (i.e., multiple stacks at one time). For example, the chamber may be configured to clean a bundle that includes at least 5 stacks of banknotes.

Each stack of banknotes may include a securing mechanism. The securing mechanism may be any mechanism known to those skilled in the art that may be configured to maintain a desired number of banknotes together in a stack. The securing mechanism may further be any desired material, shape, size and/or configuration so long as the securing mechanism enables the stack of banknotes to be cleaned (either by removal of the securing mechanism or while the securing mechanism secures the stack of banknotes). For example, the securing mechanism may include, but is not limited to, a flexible, rigid, or elastic band, a strap, or a clip. FIG. 18 illustrates an example of a flexible band, which may be wrapped around a stack of banknotes and held together via any closure mechanism known to those skilled in the art, including, but not limited to adhesives.

In some embodiments the stacks of banknotes may be cleaned in the chamber with the securing mechanism thereon. Alternatively, in other embodiments, the securing mechanism may be removed prior to cleaning each stack. Accordingly, the embodiments of FIGS. 2 and 3 may be configured to cooperate with a banknote strapping machine (not shown) that may be configured to secure a stack of banknotes with a securing mechanism and/or remove a securing mechanism from a stack of banknotes.

The strapping machine may be any strapping machine known to those skilled in the art that may be configured to perform desired functions, including but not limited to, removing a securing mechanism from a stack of banknotes, securing a securing mechanism on a stack of banknotes and/or transitioning a stack of banknotes between the strapping machine and a system for cleaning banknotes. Additionally, the strapping machine may be configured to perform the desired functions without damaging features of the banknotes. For example, the strapping machine may be a commercially available product, such as an Easy-Banker money binder.

The strapping machine may include a removal mechanism for removing the securing mechanism from the stack of banknotes. The removal mechanism may include any securing mechanism removal features known to those skilled in the art, including, but not limited to, features that enable breaking, cutting, opening and/or pulling apart of the securing mechanism. In addition, or alternatively, in an embodiment where the securing mechanism is elastic, the removal mechanism may be configured to expand the securing mechanism and remove it from the stack of banknotes.

In addition, or alternatively, in one embodiment, the strapping machine may include a binding mechanism for securing a stack of banknotes with the securing mechanism. The binding mechanism may include any features known to those skilled in the art and configured for securing a stack of banknotes together with the securing mechanism. The features of the binding mechanism may include, but are not limited to, wrapping, tying and/or clasping. In addition, or alternatively, in one embodiment, a feature of the binding mechanism may enable expansion and placement of an expandable securing mechanism on the stack of banknotes.

As previously discussed, the strapping machine may be configured to cooperate with systems for cleaning banknotes, such as those depicted in the embodiments of FIGS. 2 and 3. For example, in the embodiments of FIGS. 2 and 3, the strapping machine may be configured to transfer a stack of banknotes to the supercritical fluid chamber where the banknotes may be cleaned. Alternatively, in the embodiment of FIG. 3, the strapping machine may be configured to transfer the stack of banknotes to the sorting machine.

In embodiments where stacks of banknotes may be cleaned with a securing mechanism thereon, the strapping machine may be configured to cooperate with the systems such that entire stacks of banknotes may be transitioned therebetween. Alternatively, or in addition, in embodiments where the securing mechanism is not on a stack of banknotes during cleaning, the strapping machine and the systems may be configured to cooperate such that at least one banknote at a time may be transitioned therebetween. For example, in one embodiment the banknotes may be transitioned individually. Alternatively, or in addition, the strapping machine may be configured to transition multiple banknotes at a time.

Banknotes that have been sorted or that are otherwise being subjected to the cleaning process of the present invention may be placed the supercritical fluid cleaning chamber. FIG. 19 illustrates an exemplary supercritical fluid cleaning chamber 10 according to an embodiment of the invention. As illustrated in FIG. 19, the supercritical fluid cleaning chamber 10 may include a chamber structure 12. Chamber structure 12 may be any structure know to those skilled in the art that may be configured to hold at least one banknote in a position that enables supercritical fluid to flow around the banknote.

Chamber structure 12 may include a holding structure 14. The holding structure 14 may be any suitable size, shape, or configuration, and may include an interior portion configured to hold at least one banknote therein. For example, as illustrated in FIG. 19, the interior portion of the holding structure 14 may be configured to hold multiple stacks of banknotes at one time for cleaning. The holding structure 14 may be in the form of a capsule having rounded first and second ends l4a, l4b. Alternatively, the holding structure may be square, rectangular, circular, cylindrical, or any other desired shape. At least one of the first and second ends l4a, l4b of the holding structure 14 may be configured to transition between an open configuration (e.g., second end l4b in FIG. 19) and a closed configuration (e.g., first end l4a in FIG. 19). When the first and second ends l4a, l4b are in the closed configuration, the interior of the holding structure 14 may be configured to reach a desired temperature and pressure for supercritical fluid cleaning of banknotes therein.

FIG. 19 illustrates that the holding structure 14 may be seated on a base portion 16 of the chamber structure 12. The holding structure 14 may be removably or permanently attached to the base portion 16. In some embodiments, the base portion 16 may be fixed to a surface. Alternatively, as illustrated in FIG. 19, the base portion 16 may include wheels, or any other suitable device known to those skilled in the art that may be configured to enable the chamber structure 12 to transition across a surface between multiple locations.

Banknotes placed in the holding structure 14 may be positioned such that a supercritical fluid may flow around the banknotes. In some embodiments the banknotes may be positioned individually into the holding structure 14. Alternatively, the banknotes may be positioned in the holding structure 14 in stacks. The banknotes may also be positioned to enable ease of their placement in and removal from the holding structure 14. For example, in embodiments where the holding structure 14 has a relatively shallow depth (e.g., a device operator can reach an interior side of the first end l4a of the holding structure), the banknotes may be positioned directly on an interior surface of the holding structure 14. Alternatively, or in addition, the holding structure 14 may include a device therein for maintaining the banknotes in a desired position. For example, the holding structure 14 may include shelves for placement of the banknotes. Alternatively, or in addition, as illustrated in FIG. 19, the device for maintaining the banknotes in a desired position may be a basket 18. The basket 18 may any size, shape, or configuration such that it may be configured to fit within the holding structure 14 when the first and second ends l4a, l4b are in the closed configuration and such that it may be configured to enable supercritical fluid to flow around the banknotes therein. The basket 18 may additionally be of any desired material known to those skilled in the art and configured to maintain its structure under the required temperature and pressure conditions for supercritical fluid cleaning of the banknotes. For example, as illustrated in FIG. 19, the basket 18 may be a mesh.

FIG. 19 additionally illustrates that the basket 18 may include an interior portion 20 configured to hold at least one stack of banknotes. The banknotes may be stacked on top of each other and/or side by side. In one embodiment, the interior portion 20 of the basket 18 may include a single compartment. Alternatively, as illustrated in FIG. 19, the interior portion 20 of the basket 18 may include multiple compartments 24. The basket 18 may include any desired number of compartments 24 known to those skilled in the art so long as each compartment 24 may be sized and shaped to maintain at least one stack of banknotes therein and so long as supercritical fluid may be configured to flow throughout the basket 18 and around the banknotes.

The basket 18 may be configured to transition between an open configuration, enabling at least one stack of banknotes to be placed in or removed from the interior portion 20 of the basket 18, and a closed configuration, enabling supercritical fluid cleaning of the banknotes within the holding structure 14. For example, at least one wall of the basket 18 may be movable relative to an interior of the basket 18. FIG. 19 illustrates that a top wall 22 of the basket 18 may be movable relative to the interior portion 20 of the basket. Alternatively, or in addition, as illustrated in FIG. 19, a side wall 26 of the basket 18 may be movable relative to the interior portion 20. FIG. 19 illustrates that each compartment 24 in the basket 18 may include a corresponding side wall 26. In alternative embodiments, a single side wall may correspond to at least two compartments.

The basket 18 may be configured to transition in and out of the holding structure 14 to facilitate loading and unloading of stacks of banknotes therein. In some embodiments, the basket 18 may be separate from the holding structure 14. Alternatively, as illustrated in FIG. 19, the basket 20 may be integral with the holding structure 14 such that the basket 18 and the holding structure 14 may be configured to remain in contact upon removal of the basket 18 from the holding structure 14. FIG. 19 illustrates that the basket 18 may be able to transition in and out of the holding structure 14 via at least one rail 28. For example, the basket 18 may include at least one rail 28 attached thereto along a bottom wall and/or a side wall. Additionally, the interior of the holding structure 14 may include at least one corresponding rail (not shown) along which the at least one rail 28 on the basket 18 may slide. There may also be at least one stop located on the at least one rail 28 and configured to maintain the at least one rail 28 within the corresponding interior rail, preventing the basket 18 from separating from the holding structure 14.

FIGS. 21 A and 21B illustrate an exemplary supercritical fluid cleaning chamber 100 according to another embodiment of the invention. The embodiment of FIGS. 21 A and 21B may include many of the same features as discussed in the embodiment of FIG. 19. For example, the supercritical fluid chamber 100 of may include a chamber structure 112, which may include a holding structure 114 having a first end 1 l4a and a second end 1 l4b and a base portion 116. At least one of the first and second ends 1 l4a, 1 l4b may be configured to transition between an open configuration and a closed configuration. The supercritical fluid chamber 100 of FIGS. 21 A and 21 B may further include a basket 118 configured to maintain stacks of banknotes in a desired position within the holding structure 114.

In the embodiment of FIGS. 21 A and 21B, the basket 118 may not be integral with the holding structure. That is, the basket 118 may be configured to transition between a position within the holding structure 114 (FIG. 20B) and a position outside of the holding structure 114 (FIG. 20 A) in which the basket 118 is no longer in contact with the holding structure 114. Accordingly, the supercritical fluid chamber 100 may include any mechanisms known to those skilled in the art configured to aid in this transitioning.

For example, as illustrated in FIGS. 21 A and 21B, a cart 117 may be used to facilitate transitioning of the basket 118 in and out of the holding structure 114. The cart 117 may be sized, shaped, and configured to support the basket 118 with stacks of banknotes therein and may be movable relative to the chamber structure 112. The cart 117 may include a height that may be substantially the same as the height of the base portion 116 of the chamber structure 112 so that a device user does not have to vertically move the basket 118 as it is transitioned in and out of the holding structure 114. Additionally, the cart 117 and an interior portion 129 of the holding structure may each include at least one rail 128. A corresponding rail (not shown) may be located on a bottom surface of the basket 118 such that the basket 118 may be configured to slide along each of the interior surface 129 of the holding structure and a top surface of the cart 117 as the basket 118 is transitioned in and out of the holding structure 114.

The cleaning process in the supercritical fluid chamber may be further enhanced by the use of an agitation mechanism, which may apply ultrasonic waves through the supercritical fluid, agitate the banknotes (or the structures that hold them), or otherwise agitate the supercritical fluid.

In one embodiment, the banknotes have a thickness of 0.1 mm and can be held in holders or trays separated from each other by a distance of 0.5 mm. Based on this geometry, a supercritical fluid chamber having a volume on the order of 1 m ³ can clean over 1 million notes per day. Given that the United States processes 30 billion banknotes each year, supercritical fluid chambers having a volume on the order of 100 m ³ would be able to clean all processed U.S. currency, even without sorting the notes first.

To prevent the sebum that is stripped from the banknotes from coating the chamber or re-depositing on the banknotes, and to prevent the supercritical CO2 from saturating with the sebum that is in solution, a trapping material may be provided to remove the sebum from the supercritical CO2. While many trapping agents may be employed to strip the sebum from the supercritical CO2 solution, fumed silica is preferably employed. The trapping material helps to prevent saturation of the supercritical fluid, and may be a high surface area material to which the contaminants may attach. Fumed silica is a synthetic, amorphous, colloidal silicon dioxide. It is produced by the vapor hydrolysis of chlorosilanes, such as silicon tetrachloride, in a hydrogen-oxygen flame at 1800 °C. In the combustion process, molten spheres of amorphous silica are formed. Fumed silica is a white fluffy powder, consisting of spherically shaped primary particles, ranging in average from 7 to 40 nanometers in diameter, with a surface area of 400 to 50 square meters per gram. Primary particles do not exist in isolation; they form aggregates and agglomerates. Technical properties of the fumed silica are not just determined by the primary particles, but also by the agglomerate size distribution. The fumed silica does not have a clearly defined agglomerate size. The particle size distribution becomes wider as the average primary particle size increases and the tendency to form agglomerates is reduced.

During the cleaning process, all of the CO2 employed is preferably captured to prevent its release into the environment. The captured CO2 is further recycled for use in subsequent cleaning processes to reduce the overall environmental impact of the cleaning process. The cleaning process of the present invention minimizes the impact on the environment by reducing the thousands of tons of shredded currency that must be disposed of in a landfill or through burning.

FIG. 4 illustrates the cleaning cycle of the present invention. In an alternate embodiment, a cleaning system may be provided in a cash storage vault that is capable of supporting a supercritical fluid state inside the vault to clean banknotes stored within it. This can be implemented with banknotes that have yet to be processed, yielding a higher yield of notes fit for recirculation after the standard processing by the central bank. Such a supercritical fluid cleaning chamber vault can also be implanted at commercial banks, which may receive a rebate for undertaking this step.

Testing was performed on banknotes using a high pressure supercritical fluid chamber. An exemplary chamber is illustrated in FIG. 5, which shows a $20 banknote inside it with CO2 in the supercritical phase. The chamber was made of 3/4 aluminum with an observation window made of 1" plexiglass polymer. The chamber was constructed from cold drawn round seamless mechanical tubing (MT-1018) with threaded top and bottom end caps constructed of cold finished AISI C1018 steel bars. The assembled chamber had a diameter of 6.75" and a length of approximately 12.75". The diameter was 5.875", leaving a wall thickness of 0.4375". The chamber had a dual 1/4 (npt) threaded fittings machined into the cylinder wall before the cleaning chamber for filling an purging and a second set of 1/4 (npt) threads in the top cover for installation of a pressure monitor and a safety release valve. The fabricated components were coated with 0.0001"-0.0003" of electroless-nickel plating for corrosion resistance. The chamber could be operated at temperatures in the range of 25 C and 60 C and at pressures up to 2000 psi, at a duration of 30 minutes to 12 hours. In addition, the chamber could be immersed in an aqueous ultrasonic bath to enhance the cleaning process.

The testing described herein was performed on all notes at the same temperature and pressure. In short, the testing showed that sebum, coffee, and motor oil were removed from the banknotes without compromising the notes' security features. Moreover, in one test, a U.S. $1 note having one colony of micrococcus luteus, a skin bacteria, and 234 colonies of yeast (fungus) was cleaned and disinfected using the method of the present invention, and none of the pathogens remained on the note.

In testing the cleaning process of the present invention, banknotes were coated with a sebum material primarily composed of 18% free fatty acids, 37.8% beef tallow, and 18.3% lanoline. After being coated, the notes were placed in a temperature controlled chamber for 8 days at 90 °C and 65% relative humidity to simulate accelerated aging and circulation of the banknote. After oxidation takes place, the sebum developed a yellowish color, which along with the index matching effects, resulted in a soiled note resembling what is found in circulating currency. For example, FIG. 6 illustrates a side by side comparison of the same part of a new U.S. $1 banknote before and after coating and oxidation with a sebum layer.

Once the notes were soiled, they were cleaned using supercritical C0 ₂ at 50 °C and 1600 psi for 3 to 8 hours. Characterization was aimed at determining the survivability of various ambient light security features viewed under UV light, and machine readable features such as magnetic and high level covert features such as ENIGMA (De La Rue International) and M (Gieseke and Devrient) before and after the cleaning process. The removal of sebum was studied by measuring the diffuse reflectance spectrum and UV features were characterized before and after using a calibrated fluorimeter. In addition, porosity was measured using a photoporousimeter, developed in-house, which allowed for the determination of relative changes caused by the super critical CO2 cleaning process on U.S. banknotes. Pulp based banknotes from the U.S., Europe, and China, as well as polymer banknotes made of biaxial oriented polypropylene coated with an inorganic opacity layer prior to printing, were all tested using these methods. Experiments were performed on a number of banknotes with a focus on U.S. banknotes made from paper which is approximately 75% cotton and 25% linen fibers and printed by the United States Bureau of Engraving and Printing.

Results of the cleaning process can be seen in FIG. 7. FIG. 7 illustrates images of a U.S. $1 banknote before sebum treatment, after sebum treatment, and after cleaning with supercritical CO2 at 50 C for 8 hours with ultrasonic agitation. It is important to note that U.S. banknotes include a sebum-like dip which results in a yellowish coloring of banknotes, even when they are brand new. Accordingly, cleaning may not look as efficient at removing all of the sebum as it really is, because of the limitation of the U.S. banknotes. Based on these results, the supercritical CO2 cleaning process effectively removed oxidized sebum from U.S. banknotes. The process removes on the order of 20% of the deposited sebum layer and appears to preferentially remove moieties responsible for absorption in the 500 nm to 650 nm region, which are likely to be the larger fatty acid components of the mixture.

The results of the cleaning in this manner can also be seen in the graphs of FIGS. 8A and 8B. Thus, it can be seen that the process disclosed herein cleans a substantial amount of soil from the notes, as evidenced by the nearly 10% increase in the reflectance of the note across the near ultraviolet and visible spectrums. Such cleaning not only enhances the cleanliness and appearance of the note, but also increases the machine readability of the security features on the note.

As seen in FIG. 9, the overall results shown on a 5 Euro note demonstrate clear results of the cleaning process. The left side of the image shows the piece of the note which was cleaned using supercritical CO2 at 1600 psi and 55 C for 8 hours. Before cleaning, the note was coated with Bey sebum and stored at 90 C and 70% relative humidity for nine days. As another demonstration of the effectiveness of supercritical cleaning of banknotes, the process was tested on banknotes soiled with motor oil (e.g., Shell ASE 20). The data in FIG. 10 shows the diffuse reflection spectra before and after cleaning.

The key to the viability for recycling of soiled banknotes using these cleaning techniques is dry removal of the oxided oils and other contaminants while maintaining the integrity and usefulness of the important and costly public and machine-readable security features of the banknotes. Optical studies of all the banknotes revealed that no changes in the quality or contrast of the printing were observed after cleaning, including the flexographic, gravure and intaglio and optically variable inks.

Another feature of the present invention is that the security features on the bank notes are either totally unaffected or weakly diminished by the cleaning process. Notably, the magnetic inks, fluorescence of UV active features, holograms, metalized and de-metalized threads, and optically variable inks all remain intact and functioning after the cleaning process. As shown in FIG. 11, the fluorescence of the security thread in a U.S. $20 note is wholly unaffected. In addition, the fluorescence of the thread in a U.S, $5 note is slightly reduced after extreme exposure to supercritical CO2; however, the performance is not degraded so as to impair the visual and machine verification process. FIGS. 12A and 12B show the fluorescence of security threads in various banknotes, namely U.S. $5, U.S. $10, U.S. $20, U.S. $50, U.S. $100, and 50 Rupee notes, both before and after cleaning by exposure to supercritical CO2.

In addition to emissive security threads, polymeric security fibers such as those typically found in many of the world's banknotes were examined. For example, the effects of the cleaning process on the fibers in the Russian Ruble were studied. The data shown in FIG. 13 illustrates the robustness of the UV excited emissive features to the cleaning process with respect to the security fibers in the Russian 100 Ruble banknote. Long UV excited emissive security features are also often printed on a banknote as well using lithographic, flexographic, gravure, and intaglio methods. Examples of this are the Yuan, the Euro, and the British Pound. Printed emissive features in these, as well as other currencies, were studied, and results showed most of them to be highly robust as illustrated by the data for the Chinese Yuan in FIG. 14.

Experiments with the UK banknotes, which have a two color UV emissive pattern, revealed that these pigments were partially dissolved away. Experiments using only thermal exposure confirmed that this was either the result of dissolution or reaction with the CO2, and not the thermal degradation of the fluorophore or phosphor. FIG. 15 illustrates the pattern before and after exposure to super critical CO2 at 50 C for 8 hours and the spectral changes that occurred. It is clear from the resilience of the Chinese Yuan example that inks can be formulated to be resilient to the process of cleaning, but that some of the existing ink bases are not.

As previously discussed, machine-readable security features play an important role in banknote security. The most common machine readable security features are based on magnetic and capacitance and are most often utilized in single note acceptor applications from automated teller machines to bill changers and vending machines.

The magnetic inks utilized in a number of banknotes, and particularly the U.S. banknotes and European notes, were found to be robust and unchanged by the supercritical fluid cleaning process at 50 C and for up to 16 hours. Capacitive machine readable features such as those used in security threads, which rely on metallization, also survived testing up to 16 hours.

In addition to the machine-readable features, which are used in the public domain and by commercial banks, central banks employ one or more covert features that are typically read at rates of up to 40 banknotes/sec on high speed sorters. These features are only known to the central banks, the enforcement authorities, and the companies that supply them. One of these technologies is the over thirty year old M-feature, which was developed by Sigreid Otto of Geiseke and Devrient. This security feature proved to be resilient to the supercritical fluid cleaning process as it is based on an inorganic material. Like most of the emissive inks, the key to maintaining its robustness is in the proper choice of the base material if it is in a printed format. The various Enigma security feature signatures from De La Rue International were tested and found to be robust and unchanged after the cleaning process for 16 hours at 50 C.

Another important parameter used to determine the fitness of banknotes is limpness. When banknotes have been in circulation, the mechanical wear from folds, handling, and use in bill acceptors, results in a loss of mechanical elasticity that leads to the notes becoming limp. This "limpness" has been shown to be directly related to changes in the porosity of the banknote with mechanical wear. The porosity of the banknotes increases with use and manifests itself in a lower effective elastic constant. Limpness is measured in automated sorting environments using acoustics and ultrasonic reflection.

The porosity of banknotes was measured to determine the effects of supercritical CO2 and elevated temperatures on the substrate. Supercritical CO2 could cause swelling of the fiber network which could have a hysteresis and leave the banknotes more porous. It is also possible that since paper is a non-equilibrium network, that the relaxed, post-supercritical CO2 treatment could be compacted relative to the initial state.

The measurements were made using a home built transient gas diffusion device with Ar as the transport species. The Ar gas was optically detected on the other side of the note. The system utilized a solenoid valve to create a burst of Ar, which was then detected as it diffused through the network. In effect, the delay time was a measure of the void fraction-tortuosity product. FIGS. 16A and 16B illustrate the transient responses for a U.S. $1 note, which is in circulation and one that has not been circulated, respectively. The figures demonstrate that the uncirculated note has lower porosity resulting in both a diminished signal and a longer delay relative to the pulse of Ar shown in the yellow trace. FIGS. 17A and 17B illustrate the signals of the uncirculated note before and after supercritical CO2 cleaning and that the process has no effect on the porosity, and hence the limpness, of the note.

In addition to performing tests on individual banknotes, tests were performed on stacks of banknotes. Each of the stacks of banknotes included approximately 100 banknotes bound together with a strap (see, e.g., FIG. 18). Before and after cleaning of a stack of banknotes, the soil level on the face and the back of each banknote in the stack was tested using a DLR banknote integrated diffuse reflectance soiling sensor. Generally, for any banknote, the diffuse reflectance value inversely relates to the soil level of the banknote. For example, the higher the diffuse reflectance value, the lower the soil level and the cleaner the banknote.

The method of cleaning banknotes disclosed herein may also be used to clean and restore other materials that may include images, paint textures, print, or combinations thereof without compromising the integrity of the images, paint textures, and print. The materials may be ones where restoration is desired including, but not limited to documents and artwork, such as paintings. Like the method for cleaning the banknotes, supercritical fluid, such as CO2, may be used to remove substances, including but not limited to, contaminants, dirt, sebum, and pathogens from the material without destroying any images, paint textures, or print that may be on the material.

In addition to the aforementioned embodiments, the method and apparatus of cleaning banknotes and other materials disclosed herein may utilize ozone during the cleaning process. Ozone has been described for use in laundry systems and textile bleaching processes. In one embodiment of the present invention, the method includes an ozone treatment step alone. In another embodiment of the present invention, the method includes an initial ozone treatment step prior to a supercritical fluid cleaning process. The initial ozone treatment may be a pretreatment step, in which the banknotes are pretreated with ozone prior to supercritical fluid cleaning of the banknotes. Additionally, the initial ozone treatment step may be a first step of a two-step banknote cleaning process, in which the first step is an oxidation step and the second step includes supercritical fluid cleaning.

In one embodiment, a single chamber is utilized for both the ozone treatment step and the supercritical fluid cleaning step. In such an embodiment, to clean the banknotes or other materials, the chamber may be filled first with ozone, the ozone may then be evacuated from the chamber, and then the chamber may be filled with the supercritical fluid. In one embodiment, the supercritical fluid cleaning step may be performed for a duration of one hour or less when an initial ozone treatment step is utilized, and the overall process (initial ozone treatment and supercritical fluid cleaning) may be performed in under 2.5 hours. In another embodiment, the initial ozone treatment step may be performed for a duration of one hour, and the supercritical fluid cleaning step may be performed for a duration of more than one hour. This overall process may be an exclusively dry process.

In another embodiment of the present invention using ozone, ozone may be dissolved in a fluid, e.g., a carrier fluid. The fluid may be an industry -accepted solvent, such as ethanol or the like. This fluid may be injected into, or otherwise used in conjunction with, the supercritical fluid during the cleaning process, such as through the use of a fluid pump. In the embodiments of the present invention making use of ozone, it is preferable that CO2 is utilized as, or as part of, the supercritical fluid.

An additive cleaning unit may be utilized to concentrate oxygen from air and to use discharge to produce ozone at levels of 360 grams/hr. The ozone may be fed into a supercritical fluid cleaning unit or chamber capable of holding between 120,000-150,000 banknotes. The banknotes may be cleaned in strap form with 100 banknotes per strap. The ozone may be subsequently passivated and rendered nontoxic through use of a catalytic unit that purges the gas from the banknote volume.

Ozone serves to disinfect, sanitize, and/or sterilize banknotes and other materials disclosed herein, removing or chemically altering substances, including but not limited to, odors, contaminants, dirt, sebum, and pathogens from the relevant material, where chemically altering a substance includes but is not limited to oxidation. By chemically altering substances in the relevant material, removal of the substances from the material through a subsequent supercritical fluid cleaning process is improved. Additionally, use of ozone is safer, more environmentally friendly, and more efficient than other chemical means of disinfection. Furthermore, like the supercritical fluids used in the present invention, ozone does not destroy images, paint textures, or print on the banknotes and other materials and security features disclosed herein that are subjected to the cleaning process of the present invention. The banknotes subjected to the cleaning process of the present invention may include paper-based banknotes and polymer-based banknotes.

FIG. 21 is a schematic diagram showing an ozone-assisted cleaning cycle of the present invention. An ozone generator, such as an additive cleaning unit, may be included in the cleaning system for providing ozone to a container holding the banknotes and other materials disclosed herein. During treatment of the banknotes with ozone, soiling agents disposed in or on said banknotes are oxidized, and then the banknotes may be removed from the container. In the subsequent or simultaneous supercritical fluid cleaning step, oxidation products of the ozone treatment are removed in addition to remaining contaminants, including oily substances such as sebum.

As seen in FIG. 22, the overall results shown on a Nigerian 1000 naira note demonstrate clear results of the cleaning process utilizing ozone. The top half of the image shows the piece of the note which has been cleaned using an ozone treatment process, while the bottom half of the image shows the piece of the note that has not been subjected to a cleaning process. FIG. 23 also provides images of certain 200, 500, and 1000 naira notes, depicted both before and after being subjected to a cleaning process utilizing ozone of the present invention.

Diffuse reflectance measurements in the 400 nm to 700 nm spectral range were performed on certain banknotes before and after being subjected to a cleaning process utilizing the ozone treatment of the present invention by a DataColor 650 Colorimeter. FIG. 24A shows the location of the diffuse reflectance measurements on certain 200, 500, and 1000 naira notes. The locations on the portrait sides of the notes were chosen specifically on the color tinted area to see the effects of the cleaning process on these parts of the notes, which were already faded on most notes. The locations on the back sides of the notes were intentionally chosen to be on the unprinted part of the notes, as this permits evaluation of cleaning directly on the paper. FIG. 24B shows a diffuse reflectance spectrum of these notes before and after being subjected to a cleaning process utilizing ozone of the present invention.

Moreover, FIG. 25 shows results of further diffuse reflectance measurements performed on certain 200 naira notes, where 20 notes were selected with 10 being in good condition and 10 being in soiled condition. A clean, low-circulation note was also analyzed. Diffuse reflectance measurement results at 500 nm are illustrated in FIG. 25. The results indicate a significant cleaning effect resulted from utilizing a cleaning process of the present invention. Entire straps of 100 certain 200, 500, and 1000 naira notes were also evaluated with regards to diffuse reflectance measurements, as illustrated in FIG. 26. These results reflect properties of cleaning entire straps of banknotes.

FIG. 27 shows diffuse reflectance measurement data on a per-note basis for certain 200, 500, and 1000 naira notes. The notes in each strap were ordered according to their initial diffuse reflectance-based cleanliness and numbered from 1 to 100, where number 1 was assigned to the most soiled note in the respective strap and number 100 was assigned to the cleanest note in said strap. The plots of FIG. 27 show the increased reflectance, i.e., improved cleanliness, of each note in the strap. The analysis was performed with respect to the back sides of the notes, where the measurements were not subject to the ink-based variability associated with the front sides of the notes, as the measurements were performed on the unprinted parts of the back sides of the notes. The red horizontal lines on these plots show the average level of increased reflectance, i.e., improved cleanliness, for the dirtiest half of the strap note population.

As a first point on the results reflected in FIG. 27, this data demonstrates that initially clean notes will not show a significant change in reflectance. This is illustrated in the examined 1000 naira notes, which had several clean notes (numbers 87 through 100), as well as the examined 500 naira notes, as the initially-cleaner notes (numbers 70 through 100) show increasingly smaller reflectance change. The 200 naira notes, on the contrary, did not have initially-clean notes in the strap set. Relatedly, as a second point, each of the three strap sets had its own initial soiling distribution and average soiling levels of notes. The 500 naira notes set was initially much cleaner overall than the other two notes sets. This explains, for example, why the best cleaning results, i.e., a 10-12% increase in reflectance/cleanliness, are demonstrated by notes from different parts of the spectrum for the different denominations, specifically the dirtiest half in the 200 naira notes set, the third dirtiest quarter in the 1000 naira notes set, and a flatter scatter of data points in the 500 naira notes set where the best values fell in the 5-7% range. The average level of increased reflectance for the dirtiest half of the strap note population was 5.0% for the 200 naira notes set, 4.4% for the 500 naira notes set, and 4.9% for the 1000 naira notes set.

In addition to diffuse reflectance measurements, a second set of measurements was performed using a De La Rue Cobra sorting machine with a soil sensor. This machine processed notes at 10 notes/s and provided a sorting environment assessment measurement of soil levels before and after a cleaning process of the present invention. Soil sensor measurements were viewed with diffuse reflectance measurements as a reference measurement. FIG. 28 shows the distribution of one hundred notes for each of the 200, 500, and 1000 naira denominations before and after a cleaning process of the present invention using the soil sensor. The black bars indicate results before cleaning, the red bars indicate results after cleaning, and the blue bars indicate a value obtained from a clean, low-circulation banknote of the respective denomination.

FIGS. 29A and 29B respectively show first and second holding structures for holding banknotes during cleaning, including but not limited to cleaning with ozone or with an ozone pretreatment step. The banknotes in the holding structures may be strapped in bundles. The first and second holding structures may be used together, such as by placing one or more of the first holding structures in the second holding structure. The first and/or second holding structures may hold banknotes, be placed in a chamber, and subjected to an ozone treatment process and/or a supercritical fluid cleaning process. Banknotes placed in the first and/or second holding structures may be positioned such that ozone and/or a supercritical fluid may flow around, through, and between the banknotes.

The embodiments and examples above are illustrative, and many variations can be introduced to them without departing from the spirit of the disclosure or from the scope of the appended claims. For example, elements and/or features of different illustrative and exemplary embodiments herein may be combined with each other and/or substituted with each other within the scope of this disclosure. The objects of the invention, along with various features of novelty which characterize the invention, are pointed out with particularity in the claims annexed hereto and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and the specific objects attained by its uses, reference should be had to the accompanying drawings and descriptive matter in which there is illustrated a preferred embodiment of the invention.