Processing, dyeing, and treating of materials, such as fabric and or a yarn, with a supercritical fluid.
Traditional dyeing of materials relies on a large quantity of water, which can be detrimental to the fresh water supply and also result in undesired chemicals entering into the wastewater stream. As a result, use of a supercritical fluid has been explored as an alternative to the traditional water dye processes. However, a number of challenges have been encountered with the use of a supercritical fluid (“SCF”), such as carbon dioxide (“CO2”), in a dyeing process. For example, the interaction of dye materials with a SCF, including the solubility, introduction, dispersion, circulation, deposition, and characterization of the interaction, have all posed problems to industrial-scale implementation of dyeing with a SCF. U.S. Pat. No. 6,261,326 (“'326 patent”) to Hendrix et. al, filed Jan. 13, 2000 and assigned to North Carolina State University attempts to address previously explored solutions to the SCF and dye material interactions. The '326 patent attempts to remedy the complications of the interaction with a separate preparation vessel for introducing the dye to a SCF and then transferring the solution of dye and SCF into a textile treatment system to dye a material. In the example of the '326 patent, the dye is introduced into the vessel containing the material to be dyed in conjunction with the SCF, which can increase the complexity of the process and componentry of the system.
Methods are directed to finishing a target material with a material finish in a supercritical fluid carbon dioxide environment. Variables of the process are manipulated in different sequences to achieve a more efficient transfer of the material finish to the target material. The variables include, time, pressure, heat, internal flow rate, and CO2 transfer within a pressure vessel. In an aspect, temperature is maintained above threshold values as pressure is decreased from an operating pressure to a transition pressure. The sequencing of variable manipulation allows for a greater uptake of material finish by the target material and less residual material finish deposited on surfaces of the system.
The present invention is described in detail herein with reference to the attached drawing figures, wherein:
Methods are directed to finishing a target material with a material finish in a supercritical fluid carbon dioxide environment. Variables of the process are manipulated in different sequences to achieve a more efficient transfer of the material finish to the target material. The variables include, time, pressure, heat, internal flow rate within a pressure vessel, and exchange of the working substance (e.g., CO2). In an aspect, temperature is maintained above threshold values as pressure is decreased from an operating pressure to a transition pressure. For example, the temperature and internal flow rates are maintained above respective threshold values until the density of the CO2 passes a level in which dyestuff comes out of solution with the CO2. The sequencing of variable manipulation allows for a greater uptake of material finish by the target material and less residual material finish deposited on surfaces of the system. As a result, additional aspects contemplate eliminating or reducing the use of a cleaning process between target material finishing processes.
Materials, such as textiles (i.e. fabric, cloth) and/or spooled materials (e.g., yarn, thread, filament, cord, string, ribbon, and other continuous length materials), may be treated with a material finish to achieve a desired result, such as water resistance, abrasion resistance, breathability, and/or appearance (e.g., coloration). For example, the materials may be dyed to achieve a desired look. Dye is a substance used to add or change a color of a material, such as a textile, in an exemplary aspect. In an additional aspect, dye is a material finish, such as a durable water repellent finish (i.e., hydrophobic), fire resistant finish, anti-microbial finish, hydrophilic finish, and the like. In further aspects, dye is not a fabric finish other than a colorant and in other aspects dye is a fabric finish other than a colorant, when specifically indicated as such. Therefore, as used herein, a dye or the processes of dyeing is not limited to color or the process of coloring. Instead dye or dyeing includes a material finish or the process of finishing the target material. Dye materials, which are also referred to as dyestuff, may be particles of coloration that are natural or synthetic in formation. Traditionally, dye, together with a number of processing chemistries, are applied to a material through an aqueous solution, which may have varied acidic or basic (e.g., pH) conditions to enhance and/or achieve the dyeing process. However, this traditional dye process consumes large quantities of water and potentially discharges chemicals from the dyeing process in to the wastewater stream.
Supercritical fluid (“SCF”) carbon dioxide (“CO2”) is a fluid state of CO2 that exhibits characteristics of both a gas and a liquid. SCF CO2 has liquid-like densities and gas-like low viscosities and diffusion properties. The liquid-like densities of SCF allows for SCF CO2 to dissolve dye material and chemistries for eventual dyeing of a material. The gas-like viscosity and diffusion properties can allow for a faster dyeing time and faster dispersion of dye material than in a traditional water-based process, for example.
While examples herein refer specifically to SCF CO2, it is contemplated that additional or alternative compositions may be used at or near a supercritical fluid phase. Therefore, while specific reference will be made to CO2 as a composition herein, it is contemplated that aspects hereof are applicable with alternative compositions and appropriate critical point values for achieving a SCF phase.
The use of SCF CO2 in a dyeing process may be achieved using commercially available machines, such as a machine offered by DyeCoo Textile Systems BV of the Netherlands (“DyeCoo”). A process implemented in a traditional system includes placing an undyed material that is intended to be dyed into a vessel capable of being pressurized and heated to achieve a SCF CO2. A powdered dyestuff that is not integrally associated with a textile (e.g., loose powder) is maintained in a holding container. The dyestuff holding container is placed in the vessel with the undyed material such that the dyestuff is not contacting the undyed material prior to pressurizing the vessel. For example, the holding container physically separates the dyestuff from the undyed material. The vessel is pressurized and thermal energy is applied to bring CO2 to a SCF (or near SCF) state, which causes the dyestuff to solubilize in the SCF CO2. In a traditional system, the dyestuff is transported from the holding container to the undyed material by the SCF CO2. The dyestuff is then diffused through the undyed material causing a dyeing of the undyed material until the SCF CO2 phase is ceased.
Aspects herein relate to a concept of dye equilibrium as a manner of controlling a dye profile that results on a material. For example, if a first material has a dye profile that may be described as a red coloration and a second material has a dye profile that may be described by an absence of coloration (e.g., bleached or white), the concept of equilibrium dyeing with SCF CO2 results in an attempted equalization between the two dye profiles such that at least some of the dyestuff forming the first dye profile is transferred from the first material to the second material. An application of this process includes using a sacrificial material having dyestuff contained thereon and/or therein (e.g., a dyed first material) that is used as a carrier for applying a specific dyestuff to a second material that is intended to be dyed by the dyestuff of the sacrificial material. For example, a first material and a second material may each have different resulting dye profiles from each other after a SCF CO2 process is applied while also having a different dye profile from their respective initial dye profiles (e.g., first dye profile and second dye profile). This lack of true equilibrium may be desired. For example, if the first material is the sacrificial material that is merely intended to be a dye carrier, the process may be carried out until the second material achieves a desired dye profile, regardless of the resulting dye profile for the first material, in an exemplary aspect.
Another example of a dyeing process using SCF CO2 may be referred to as an additive dyeing process. An example to aid in illustrating the additive dyeing process includes the first material having a dye profile that exhibits red coloration and the second material having a second dye profile that exhibits blue coloration. The SCF CO2 is effective to result in dye profiles on the first material and the second material (and/or a third material) that exhibit purple coloration (e.g., red+blue=purple).
As before, it is contemplated that the first and second materials may achieve a common dye profile when the equilibrium dye process is allowed to mature. In additional aspects, it is contemplated that the first material and the second material result in different dye profiles from each other, but the resulting dye profiles are also different from the initial dye profile for each respective material. Further, it is contemplated that the first material may be a sacrificial dye transfer material while the second material is the material for which a target dye profile is desired. Therefore, the SCF CO2 dye process may be performed until the second material achieves the desired dye profile regardless of the resulting dye profile of the first material. Further yet, it is contemplated that a first sacrificial material dye carrier having a first dye profile (e.g., red) and a second sacrificial dye carrier having a second dye profile (e.g., blue) may be placed into the system to cause a desired dye profile (e.g., purple) on a third material, in an exemplary aspect. As can be appreciated, any combination and number of materials, dye profiles, and other contemplated variables (e.g., time, SCF CO2 volume, temperature, pressure, material composition, and material type) may be altered to achieve results contemplated herein.
Aspects herein contemplate dyeing (e.g., treating with material finishes) of one or more materials using SCF CO2. The concept of two or more materials used in conjunction with each other is contemplated in aspects hereof. Further, the use of one or more materials having integral dyestuff that are not intended for traditional post-processing utilization (e.g., apparel manufacturing, shoe manufacturing, carpeting, upholstery), which may be referred to as sacrificial material or as dye carriers, are contemplated as being introduced in the system. Further, it is contemplated that any dye profile may be used. Any combination of dye profiles may be used in conjunction with one another to achieve any desired dye profile in one or more materials. Additional features and process variable for disclosed methods and systems will be provided herein.
Achieving a desired dye profile on a material may be influenced by a number of factors. For example, if there are 50 kg of a first material (e.g., spooled or rolled material) and 100 kg of a second material, the resulting dye profile per weight of the first material may be expressed as 1/3 the original color/intensity/saturation of the first dye profile when the second material original dye profile is absent of dye. Alternatively, with the same proportions of material but the original second dye profile having a comparable saturation/intensity as the first dye profile, but with a different coloration, the first dye profile may be expressed as 1/3X+1/3Y where X is the original first dye profile and Y is the original second dye profile (i.e. weight of the first material/weight of all materials). From the second material perspective using the two previous examples, the resulting dye profiles may be (2/3X)/2 for the first example and (2/3X+2/3Y)/2 (i.e. [weight of the first material/weight of all materials]*[weight of the first material/weight of the second material]). The previous examples are for illustration purposes only as it is contemplated that a number of additional factors are also relevant, such as yardage per kilogram, material composition, dye process length, temperature, pressure, time, material porosity, material density, winding tension of the material, and other variables that may be represented by an empirical value(s). However, the preceding is intended to provide an understanding of the intended equilibrium dyeing process to supplement the aspects provided herein. As such, the provided examples and values are not limiting but merely exemplary in nature.
Referring now to
The second material 102 has a first surface 120, a second surface 122, and a plurality of dye material 108. The dye material 108, which may be a composition/mixture of dyestuffs, is depicted as granular elements for discussion purposes; however, in actuality the dye material 108 may not be individually identifiable at the macro level from the underlying substrate of a material. Also, as will be discussed hereinafter, it is contemplated that the dyestuff may be integral with the material. Integral dyestuff is dyestuff that is chemically or physically bonded with the material. Integral dyestuff is compared to non-integral dyestuff, which is dyestuff that is not chemically or physically coupled with a material. An example of a non-integral dyestuff includes dry powdered dyestuff sprinkled and brushed on the surface of a material such that the dyestuff is removed with minimal mechanical effort.
At
With respect to
The spooled material may be a continuous yarn-like material that is effective for use in weaving, knitting, braiding, crocheting, sewing, embroidering, and the like. Non-limiting examples of spooled material include yarn, thread, rope, ribbon, filament, and cord. It is contemplated that the spooled material may be wound about a spool (e.g., conical or cylindrical) or the spooled material may be wound about itself without a secondary support structure helping form the resulting wound shape. The spooled material may be organic or synthetic in nature. The spooled material may be a plurality of individual collections of material or a singular collection of material.
In
As such,
Referring now to
At
With respect to
The second material 1104 has a first surface 1124 and a second surface 1126. The second material also is depicted as having a second dye profile with dye material 1114. The dye material 1114 may be dyestuff transferred by the SCF CO2 having passed through the first material 1102 and/or it is dyestuff associated with the second material 1104 in a previous operation, in an exemplary aspect.
As such,
Further, as will be provided herein, aspects contemplate a dyestuff integral to a material. A dyestuff is integral to a material when it is physically or chemically bonded with the material, in an example. In another example, dyestuff is integral to the material when the dyestuff is homogenized on the material. The homogenization of dyestuff is in contrast to a material on which dyestuff is applied in a non-uniform manner, such as if a dyestuff is merely sprinkled or otherwise loosely applied to the material. An example of integral dyestuff with a material is when dyestuff is embedded and maintained within the fibers of a material, such as when dyestuff perfuses a material.
The term “perfuse,” as used herein, is to coat, permeate, and/or diffuse surface finishes, such as dyestuff over and/or throughout a material. The perfusing of a material with dyestuff occurs in a pressure vessel, such as an autoclave, as is known in the art. Further, the SCF and dyestuff dissolved in the SCF may be circulated within the pressure vessel with a circulation pump, as is also known in the art. The circulation of SCF within the pressure vessel by a pump causes the SCF to pass through and around a material within the pressure vessel to cause dissolved dyestuff to perfuse the material. Stated differently, when a target material is perfused with SCF CO2 having dyestuff (e.g., finish material) dissolved therein, the dyestuff is deposited on one or more portions of the target material. For example, a polyester material, when exposed to the conditions suitable for forming SCF CO2, may “open” up allowing for portions of the dyestuff to remain embedded with the polyester fibers forming the polyester material. Therefore, adjusting the heat, pressure, circulation flow, and time affects the SCF, the dyestuff, and the target material. The variables all taken in combination, when the SCF CO2 perfuses the target material, a deposit of dyestuff throughout the material may occur.
In the example depicted in
As depicted in
While the spooled material 207 and the second material 209 are depicted on a common material holding element 204, it is contemplated that the spooled material 207 is on a first holding element and the second material 209 is on a second holding element that is different from the first holding element, in an exemplary aspect.
While only two materials are depicted in
In the example depicted in
As depicted in
While the first material 1207 and the second material 1209 are depicted as having a similar volume of material, it is contemplated that the first material 1207 may have a substantially greater volume of material than the second material 1209, which may serve as a sacrificial material in an exemplary aspect. Further, while the first material 1207 and the second material 1209 are depicted on a common holding element, it is contemplated that the first material 1207 is on a first holding element and the second material 1209 is on a second holding element that is different from the first holding element, in an exemplary aspect.
While only two materials are depicted in
As has been illustrated in
The SCF CO2 allows the polyester to be dyed with a modified dispersed dyestuff. This occurs because the SCF CO2 and/or the conditions causing the SCF state of CO2 result in the polyester fibers of the materials to swell, which allows the dyestuff to diffuse and penetrate the pore and capillary structures of the polyester fibers. It is contemplated that reactive dye may similarly be used when one or more of the materials is cellulosic in composition. In an exemplary aspect, the first material 1206 and the second material 1208 are formed from a common material type such that dyestuff is effective for dyeing both materials. In an alternative aspect, such as when one of the materials is sacrificial in nature as a dye carrier, the dyestuff may have a lower affinity for the sacrificial material than the target material, which could increase the speed of SCF CO2 dyeing. An example may include the first material being cellulosic in nature and the second material being a polyester material and the dyestuff associated with the first material being a dispersed dye type such that the dyestuff has a greater affinity for the polyester material (in this example) over the first material. In this example, a reduced dyeing time may be experienced to achieve a desired dye profile of the second material.
At a block 304, the pressure vessel may be pressurized. In an exemplary aspect, the materials are loaded into the pressure vessel and then the pressure vessel is sealed and pressurized. In order to maintain inserted CO2 in the SCF phase, the pressure, in an exemplary aspect, is raised above the critical point (e.g., 73.87 bar).
Regardless of how the pressure vessel is brought to pressure, at a block 306, SCF CO2 is introduced into the pressure vessel. This SCF CO2 may be introduced by transitioning CO2 maintained in the pressure vessel from a first state (i.e., liquid, gas, or solid) into a SCF state. As know, the state change may be accomplished by achieving a pressure and/or temperature sufficient for a SCF phase change. It is contemplated that one or more heating elements are engaged to raise the internal temperature of the pressure vessel to a sufficient temperature (e.g., 304 K, 30.85 C). One or more heating elements may also heat the CO2 as (or before) it is introduced into the pressure vessel, in an exemplary aspect.
At a block 308, the SCF CO2 is passed through each of the plurality of spooled materials and the second material. While the SCF CO2 passes through the materials, which may have different dye profiles, dyestuffs is transferred between the materials and perfuse the material(s). In an exemplary aspect, the dyestuff is dissolved in the SCF CO2 such that the SCF CO2 serves as a solvent and carrier for the dyestuff. Further, because of the temperature and pressure of the SCF CO2, the materials may alter (e.g., expand, open, swell), temporarily, to be more receptive to dyeing by the dyestuff.
It is contemplated that the passing of SCF CO2 is a cycle in which the SCF CO2 is passed through the materials multiple times, such as in a closed system with a circulation pump, in an exemplary aspect. It is this circulation that may help achieve the dyeing. In an aspect, the SCF is circulated through the materials for a period of time (e.g., 60 minutes, 90 minutes, 120 minutes, 180, minutes, 240 minutes) and then the SCF CO2 is allowed to change state (e.g., to a liquid CO2) by dropping temperature and/or pressure. After changing state of the CO2 from SCF state, the dyestuff is no longer soluble in the non-SCF CO2, in an exemplary aspect. For example, dyestuff may be soluble in SCF CO2, but when the CO2 transitions to liquid CO2, the dyestuff is no longer soluble in the liquid CO2.
At a block 310, the plurality of spooled materials and the second material are extracted from the pressure vessel. In an exemplary aspect, the pressure within the pressure vessel is reduced to near atmospheric pressure and the CO2 is recaptured from the pressure vessel for potential reuse in subsequent dyeing operations. In an example, a securing apparatus securing the materials may be moved out of the vessel after a desired dye profile is achieved for one or more of the materials.
While specific steps are discussed and depicted in
As previously discussed, it is contemplated that the material finish of the sacrificial material may be a colorant (e.g., dyestuff), a hydrophilic finish, a hydrophobic finish, and/or an anti-microbial finish. As will be illustrated in
At a block 404, carbon dioxide is introduced into the pressure vessel. The CO2 may be in a liquid or gas state when it is introduced. Further, it is contemplated that the pressure vessel is enclosed at the time of the CO2 introduction to maintain the CO2 within the pressure vessel. The pressure vessel may be at atmospheric pressure when the CO2 is introduced. Alternatively, the pressure vessel may be above or below atmospheric pressure when the CO2 is introduced.
At a block 406, the pressure vessel is pressurized allowing the introduced CO2 to achieve a SCF (or near) state. Additionally, it is contemplated that thermal energy is applied to (or within) the pressure vessel to aid in achieving the SCF state of the CO2. As discussed hereinabove, the state diagram of
At a block 408, the plurality of spooled materials are perfused with at least a portion of the material finish from the sacrificial material. The material finish is transferred to the plurality of spooled materials by way of the SCF CO2. As discussed previously, the SCF CO2 serves as a transportation mechanism for the material finish from the sacrificial material to the plurality of spooled materials. This may be assisted by circulating, such as by a circulation pump, the SCF within the pressure vessel so that it perfuses both the sacrificial material and the plurality of spooled materials. It is contemplated that the material finish may dissolve, at least partially, within the SCF allowing for their release from being bound with the sacrificial material to being deposited on/within the plurality of spooled materials. To ensure consistent application of the material finish to the plurality of spooled materials, the material finish may be integral to the sacrificial material, which ensures the intended amount of material finish is introduced within the pressure vessel. The transfer of the material finish may continue until a sufficient amount of the material finish perfuses the spooled materials.
While specific reference in
While a first and a second sacrificial material are discussed, any number of sacrificial materials may be provided. Further, it is contemplated that a quantity of the first sacrificial material and a quantity of the second sacrificial material are different depending on a desired amount of each material finish desired to be applied to the spooled material. Further, it is contemplated that the sacrificial materials will also maintain a portion of the material finish from the other materials within the pressure vessel. Therefore, it is contemplated the volume of all materials, include sacrificial, are considered when determining a quantity of surface finish to be inserted in the pressure vessel.
At a block 504, the pressure vessel is pressurized such that CO2 within the pressure vessel achieves a SCF state therein. The SCF is then effective to administer the material finish of the first sacrificial material and the second material finish of the second material to the spooled material, as depicted in a block 506.
While specific reference in
In this illustrated example, the last turn of the first material 1206 exposes a surface that is in direct contact with a surface of the first turn of the second material 1208. Stated differently, the depicted series rolling of winding 1300 allows for a limited, but available, direct contact between the first material 1206 and the second material 1208. This direct contact can be distinguished over alternative aspects in which a dye carrier or the dyestuff is physically separate from the material to be dyed. As such, the direct contact between the materials to be dyed and having the dyestuff may reduce dyeing time and reduce potential cleaning and maintenance times, in an exemplary aspect.
While only two materials are depicted in
At a block 512, the pressure vessel may be pressurized. In an exemplary aspect, the materials are loaded into the pressure vessel and then the pressure vessel is sealed and pressurized. In order to maintain inserted CO2 in the SCF phase, the pressure, in an exemplary aspect, is raised above the critical point (e.g., 73.87 bar).
Regardless of how the pressure vessel is brought to pressure, at a block 514, CO2 is introduced (or recirculated) into the pressure vessel. This CO2 may be introduced by transitioning CO2 maintained in the pressure vessel from a first state (i.e., liquid, gas, or solid) into a SCF state. As know, the state change may be accomplished by achieving a pressure and/or temperature sufficient for a SCF phase change. It is contemplated that one or more heating elements are engaged to raise the internal temperature of the pressure vessel to a sufficient temperature (e.g., 304 K, 30.85 C). One or more heating elements may also (or alternatively) heat the CO2 as (or before) it is introduced into the pressure vessel, in an exemplary aspect. The introduction of CO2 may occur during pressurization, prior to pressurization, and/or subsequent to pressurization.
At a block 516, the SCF CO2 is passed through the first material and the second material. In an exemplary aspect, the SCF CO2 is pumped into a beam about which one or more of the materials are wound. The SCF CO2 is expelled from the beam into the materials. While the SCF CO2 passes through the materials, which may have different dye profiles, dyestuffs is transferred between the materials and perfuse the material(s). In an exemplary aspect, the dyestuff is dissolved in the SCF CO2 such that the SCF CO2 serves as a solvent and carrier for the dyestuff. Further, because of the temperature and pressure of the SCF CO2, the materials may alter (e.g., expand, open, swell), temporarily, to be more receptive to dyeing by the dyestuff.
It is contemplated that the passing of SCF CO2 is a cycle in which the SCF CO2 is passed through the materials multiple times, such as in a closed system with a circulation pump, in an exemplary aspect. It is this circulation that may help achieve the dyeing. In an aspect, the SCF is circulated through the materials for a period of time (e.g., 60 minutes, 90 minutes, 120 minutes, 180, minutes, 240 minutes) and then the SCF CO2 is allowed to change state (e.g., to a liquid CO2) by dropping temperature and/or pressure. After changing state of the CO2 from SCF state, the dyestuff is no longer soluble in the non-SCF CO2, in an exemplary aspect. For example, dyestuff may be soluble in SCF CO2, but when the CO2 transitions to liquid or gas CO2, the dyestuff may no longer be soluble in the liquid or gas CO2. It is further contemplated that the CO2 is circulated internally (e.g., passed through a material holder or a beam) and/or the CO2 is circulated as a recapture process to reduce lost CO2 during phase changes (e.g., depressurization).
At a block 518, the first material and the second material are extracted from the pressure vessel. In an exemplary aspect, the pressure within the pressure vessel is reduced to near atmospheric pressure and the CO2 is recaptured from the pressure vessel for potential reuse in subsequent dyeing operations. In an example, a beam having the materials wound thereon may be moved out of the vessel after a desired dye profile is achieved for one or more of the materials.
While specific steps are discussed and depicted in
In the alternative, the second starting position of
In both the first and the second starting positions, the multiple materials are wound, in one manner or another, about one or more holding devices for positioning in a common pressure vessel, as depicted at a block 1406.
At a block 1408 the pressure vessel is pressurized to at least 73.87 bar. This pressurization may be accomplished by injection of atmospheric air and/or CO2 until the internal pressure of the pressure vessel reaches the desired pressure, such as at least the critical point pressure of CO2. For example, CO2 is inserted into the pressure vessel with a pump until the appropriate pressure is achieved within the pressure vessel.
At a block 1410, SCF CO2 is passed through the first material and the second material to cause a change in a dye profile for at least one of the first material or the second material. The dye transfer may be continued until the dyestuffs perfuse the materials(s) sufficiently to achieve a desired dye profile. An internal recirculating pump is contemplated as being effective to cycle the SCF CO2 through the beam and wound materials multiple times to achieve the equilibrium dyeing, in an exemplary aspect. This internal recirculating pump may be adjusted to achieve a desired flow rate of the SCF CO2. The flow rate provided by the internal recirculating pump may be affected by the amount of material, the density of material, the permeability of the material, and the like.
At a block 1412, the first material and the second material are extracted from the pressure vessel such that color profiles (e.g., dye profile) of the materials are different relative to the color profiles of the materials as existed at blocks 1402, 1403, or 1404. Stated differently, upon completion of the SCF CO2 passing through the materials, the dye profiles of at least one of the materials changes to reflect that it has been dyed by SCF CO2.
While specific reference in
The process of using SCF CO2 in a material dyeing or finishing application relies on manipulation of multiple variables. The variables include time, pressure, temperature, quantity of CO2, and flow rate of the CO2, rate of change for one or more variables over time (e.g., change in pressure per minute, change in temperature per minute), and exchange of CO2. Further, there are multiple cycles in the process in which one or more of the variables may be manipulated to achieve a different result. Three of those cycles include a pressurizing cycle, a perfusing cycle (also referred to as a “dyeing cycle”), and a depressurizing cycle. In an exemplary scenario, CO2 is introduced into a sealed pressure vessel with the temperature and the pressure increasing such that the CO2 is elevated to at least the critical point of 304 K and 73.87 bar. In this traditional process, the second cycle of perfusing (e.g., dyeing) the material-to-be-finished occurs. A flow rate of a recirculating pump may be set and maintained and a time is established for the dyeing cycle. Finally, at the depressurization cycle in a traditional process, the flow rate may be stopped, the application of thermal energy ceases, and the pressure is reduced, all substantially simultaneously or at varied intervals to transition the CO2 from SCF to gas. For example, the temperature may be maintained or at least maintained above a threshold level during the depressurization cycle while pressure is reduced. The temperature is maintained until, in an example, the density of the CO2 changes to a point that no longer supports maintaining the dyestuff in solution with the CO2. At which point, the temperature may also decrease. This delayed temperature decrease may increase collection of dyestuff by the target material that is more receptive to dyestuff perfusion at elevated temperatures. Therefore, maintaining the elevated temperature during the transition of the CO2 density may reduce deposition of dyestuff onto the pressure vessel components as the target material remains a more attractive target for the dyestuff coming out of solution from the CO2.
Improvements over a traditional process are able to be realized by adjusting the different variable. In particular, adjusting the sequence and timing of the variable changes during a cycle provides better results. For example, a traditional process may cause the material finish (e.g., dyestuff) to coat the inner surfaces of the pressure vessel. The coating of the pressure vessel is inefficient and undesired as it represents material finish that was not perfused through the intended material and requires subsequent cleaning to ensure the material finish is not perfused into a subsequent material for which it is not intended. Stopping the flow rate at the initiation of the third cycle causes the CO2 and the material finishes dissolved therein to become stagnate within the pressure vessel. As CO2 transitions from SCF to gas, the material finish in this stagnant environment may not find a suitable host to attach as the material finish comes out of solution with the CO2 at the phase change. Therefore, the pressure vessel itself may become the target of the surface finish as opposed to the target material. Manipulation of the variables may allow for the material finish to favor adhering/bonding/coating the intended target material as opposed to the pressure vessel itself.
In the third cycle (e.g., depressurization cycle), it is contemplated that the flow rate is maintained or at least not ceased until the CO2 changes from the SCF to gas state. For example, if the pressure within the pressure vessel is operating at 250 bar during the perfusing cycle, the CO2 may stay in SCF state in the third cycle until the pressure is reduced below 73.87 bar. As a result, when the second cycle is completed, instead of stopping the flow of CO2 or significantly reducing the flow rate of CO2 within the pressure vessel, the flow rate is maintained through at least a portion of the third cycle. In an additional concept, the flow rate of the CO2 is maintained until the pressure reduces below 73.87 bar. Additionally or alternatively, it is contemplated that the flow rate is maintained above a threshold until the CO2 passes a defined density at which the dyestuff comes out of solution with the CO2.
At least two different scenarios for the third cycle are contemplated. The first scenario is a sequence where the third cycle of the process initiates at the reduction in temperature of the CO2. For example, the second cycle may be operating at 320 K, in an exemplary aspect, at the completion of the second cycle, the temperature is allowed to decline from the operating temperature of 320 K. While a traditionally process may also stop the flow of CO2 within the pressure as the temperature begins to decline, it is contemplated that instead the flow rate is maintained, at some level, until at least the temperature falls below the critical temperature of CO2, 304 K/30.85 C. In this example, the CO2 may remain in the SCF until the temperature falls below 304 K/30.85; therefore, the flow rate is maintained to circulate the CO2 and deposit material finishes therein around and/or through the target material. In this first scenario, the pressure may be maintained at the operating pressure (or above 73.87 bar) until the CO2 changes from SCF to another state (e.g., liquid if above 73.87 bar). Alternatively, the pressure may also be allowed to drop at the commencement of the third cycle, but the flow is maintained until at least the CO2 changes to a different state and/or a defined CO2 density is achieved.
The second scenario, while similar to the first, relies on the third cycle being initiated by a decline in pressure. For example, if the operating pressure within the pressure vessel to perfuse the material is 250 bar, the third cycle is initiated when the pressure drops. While a traditional process may cease the flow rate of the CO2 at this point, it is contemplated that instead the flow rate is maintained or not ceased simultaneously. Instead, at the third cycle, the CO2 is subject to flow until the pressure drops below at least 73.87 bar to ensure circulation of the CO2 having dissolved material finishes contained therein the entirety of time the CO2 is at a SCF state. The temperature may also be dropped simultaneously with the pressure decline or it may be maintained until a certain pressure or CO2 density is achieved. It is contemplated that some dyestuff (e.g., surface finishes) may come out of solution with the CO2 prior to the CO2 transitioning from the SCF state. Therefore, the transition pressure at which other variable are adjusted may instead be based on the density of the CO2 (e.g., 500 Kg/m3).
In an exemplary aspect, the third cycle initiates with the pressure dropping and the temperature dropping toward the CO2 critical point, but the flow rate of the CO2 is maintained, at least in part, until the CO2 has transitioned from the SCF state. While specific temperatures and pressures are listed, it is contemplated that any temperature or pressure may be used. Further, instead of relying on the CO2 achieving a particular temperature or pressure, a time may be used for when to reduce or cease the CO2 flow rate, in an exemplary aspect.
Manipulation of the variable is not limited to the third cycle. It is contemplated that a higher equilibrium saturation of surface finish may be achieved by adjusting the variables in the first and second cycles. For example, the flow rate may begin before the CO2 transitions from a first state (e.g., gas or liquid) to a SCF state. It is contemplated that as CO2 transitions into a SCF state, the material finish that is to-be-dissolved in the SCF is exposed to a non-stagnate pool of CO2 allowing an for an equilibrium of solution to occur sooner, in an exemplary aspect. Similarly, it is contemplated that the thermal energy is applied to the pressure vessel internal volume before the introduction of CO2 and/or before the pressurization of the CO2 begins. As the transfer of thermal energy may slow the process because of thermal mass of the pressure vessel, it is contemplated that the addition of the thermal energy occurs, in an exemplary aspect prior to the application of pressure. As such, it is contemplated that manipulation of variables during the pressurization cycle may allow the dyestuff to dissolve in the CO2 at a faster rate. For example, the rate of pressure increase relative to temperature increase during the pressurization cycle may be manipulated through temperature hold periods, which can enhance the dyestuff dissolving in the CO2, for example.
Additionally, the manipulation of variables may further affect the resulting dyeing process of the target material. For example, at certain cycles (e.g., dyeing cycle) an increase of flow rate may increase color levelness (e.g., uniformity of finish deposition on the target material) and at certain cycles (e.g., depressurization cycle) a decrease in flow rate can improve color fastness (e.g., bond strength of material finish with the target material). Further yet, the flow rate in certain cycles (e.g., pressurization cycle) may be varied to enhance solubility results of the dyestuff in the CO2. Further yet, the permeability of the target material may affect variables, such as flow rate. For example, a higher permeability material (e.g., knit) may use a lower flow rate to achieve a sufficient degree of color levelness while also achieving a sufficient degree of color fastness relative to a lower permeability material (e.g., tightly woven). As such, the process variable may adjust based on the material characteristics as well as degree of dyeing results tolerated.
In further support of the general processes provided above, specific examples are provided hereinafter.
At a block 512, CO2 is introduced into the pressure vessel. As discussed herein, the CO2 may be introduced in any state, such as a gaseous state to the enclosed pressure vessel. At a block 514, an internal temperature of the pressure vessel is increased to an operating temperature. For example, it is contemplated that the pressure vessel may have a pre-heated temperature, such as 80-90 Celsius in an exemplary aspect, from which the pressure vessel is further heated. The operating temperature may be within a range of 100-125 Celsius in an aspect. The operating temperature may be around 110 Celsius in an aspect. The operating temperature may depend on the target material composition (e.g., synthetic materials). As discussed herein, a temperature within a range of 100-125 Celsius allows for a polyester target material to open up pores for physically capturing a finishing material without melting the polyester, in an exemplary aspect. In an exemplary aspect, the temperature is at least a glass transition temperature of the target material. This temperature (e.g., 60-70 Celsius for polyester) allows hydrophobic polymers of a hydrophobic material to be opened to diffusion of dispersed finish materials. Further, the operating temperature should be sufficient for the CO2 to achieve (or nearly achieve) a SCF state.
At a block 516, a pump mechanism is activated to increase a flow rate above a zero flow rate for internal circulation of CO2. For example, prior to the CO2 achieving SCF state, the pump is activated to circulate the CO2 as it achieves a SCF state and begins dissolving a finishing material contained within the pressure vessel.
At a block 518, a pressure of the pressure vessel internal cavity is increased to an operating pressure. The operating pressure is sufficient to achieve a SCF state for the CO2 when at the operating temperature. In an exemplary aspect, the operating pressure is below 300 bar. In an exemplary aspect, the operating pressure is in a range of 225-275 bar. In an exemplary aspect, the operating pressure is 250 bar.
At a block 1512, the target material is perfused with a finishing material. The finishing material is transported to the target material as the finishing material is dissolved in the SCF CO2 and circulated by the pump controlling the flow rate of the CO2. The perfusing of the target material allows for the infiltration and maintaining of the finishing material by the target material. The perfusing of the target material may continue for a predetermined time, such as 30, 45, 60, 75, 90, 120, 150, 180 minutes, in an exemplary aspect.
At a block 1514, the pressure is reduced from the operating pressure to a transition pressure while maintaining the temperature above a threshold temperature and also while maintaining the flow rate above a threshold rate. The transition pressure may be any pressure from atmospheric pressure up to the operating pressure. In an aspect, the transition pressure is in a range of 225-100 bar. In an aspect the transition pressure is 200 bar, 150 bar, or 100 bar. The threshold temperature may be determined based on the target material. For example, if the target material the threshold temperature may be 100 Celsius. The threshold flow rate is a non-zero rate. Stated differently, the CO2 is circulated as the pressure reduces from the operating pressure to the threshold pressure. As discussed herein, efficiencies are achieved by maintaining the temperature and/or the flow rates above threshold levels while the pressure is decreasing from the operating pressure. For example, as the dissolved material finish in the CO2 begins to precipitate from the CO2 as the density of the CO2 transitions from the operating values, the circulation and or maintained temperature allow for a great uptake of the material finish by the target material than if the flow rate and/or the temperature are decreased below the threshold levels prior to the precipitation phase, in an exemplary aspect.
At the pressurization cycle 1808 CO2 is filled into the pressure vessel. The pressure vessel may be preheated to a starting temperature, such as 50-90 Celsius in an exemplary aspect. However, it is contemplated that the vessel may not be preheated or it may be heated to a different starting temperature in exemplary aspects. The pressure within the vessel may start at atmospheric pressure in an exemplary aspect. The pressure in the pressurization cycle 1808 may be increased to a threshold pressure, such as 250 bar. However any pressure threshold above the critical point pressurization of CO2 is contemplated. As will be discussed hereinafter, the pressurization threshold may be less than 310 bar to achieve process efficiency in time to pressurization and energy required to achieve such pressurization. Upon achieving a threshold pressure, the pressurization cycle 1808 may transition to the dyeing/treatment cycle 1810, in an exemplary aspect. It is further contemplated that the transition from pressurization cycle 1808 to dyeing/treatment cycle 1810 may occur after another variable, including a preset time, is achieved.
Also depicted in
The slope of pressurization, temperature, and/or flow rate changes during one or more cycles is also variable. For example, it is contemplated that temperature is increased at a rate to achieve maximum time at the desired temperature for the dyeing/treatment cycle 1810 to allow the thermal mass of the material to be treated to equalize to benefit the perfusing and acceptance of the finishing material. For example, if the target material is polyester or other long-chain polymer, achieving a temperature above 100 Celsius may result in the pores of the polyester opening sufficient for the material finish to be perfused and maintained by the polyester. If an internal portion of the polyester material has yet to reach the 100 Celsius temperature as dissolved finishing material is being perfused through the polyester material, the adhesion of the finishing material may be hindered at portions of the polyester material, in an exemplary aspect. Similarly, it is contemplated that various rates of pressurization may be established. For example, as will be discussed in the depressurization cycle 1812, a 5 bar per minute rate may be used to achieve a desired precipitation of the finishing material from the CO2, in an exemplary aspect. The pressurization rate may also be manipulated to achieve a specified pressurization cycle 1808 duration.
The dyeing/treatment cycle 1810 may equate to the second cycle in the above description of the CO2 processing methodology. The duration of the dyeing/treatment cycle 1810 may be established based on a number of potential variables. For example, the duration may be established based on the type of target material, the characteristics of the material (e.g., permeability, density), the material finish to be applied (e.g., coloration, saturation of coloration, chemistry of finishing material, type of finishing material), flow rate of the CO2, the temperature, the pressure, and the like.
As depicted in
In the example depicted in
In an exemplary aspect, once the pressure achieves a defined pressure (e.g., 200 bar) that also causes the finishing material to fully precipitate out of the CO2, in an exemplary aspect, the temperature may then be reduced, as depicted in the cycle 1814. Further, it is contemplated that the flow rate 1806 may be changed at the initiation of the cycle 1814. Additionally, it is contemplated that the flow rate 1806 may be changed upon the pressure/temperature/density achieving a predefined level, in an exemplary aspect.
The depressurization cycle 1812 provides other combination of variables to achieve different results. For example, it is contemplated that the pressure if reduced to a predefined threshold for recapture of the CO2 and then the pressure is reduced to atmosphere with a loss of CO2 to the environment. This rapid depressurization may occur after the finishing material has precipitated out of the CO2 and the CO2 has transitioned to a gaseous or liquid state.
The following is a listing of exemplary variable settings for the pressurization, dyeing, and depressurization cycles that may be implemented to achieve aspects provided herein. Each row represents a variation in the variables to achieve a CO2 dyeing process for a particular target material and/or dyestuff. However, the values provided are not limiting.
Exemplary Condition 1—See
Exemplary Condition 2—See
Exemplary Condition 3—See
Exemplary Condition 4—See
Exemplary Condition 5—See
Exemplary Condition 6—See
Exemplary Condition 7—See
Exemplary Condition 8—See
Exemplary Condition 9—See
Exemplary Condition 10—See
Exemplary Condition 11—See
Exemplary Condition 12—See
Pressurization: Starting Temp: 80-90 Celsius, Pressure: 188-250 Bar, Flow rate: 90-130 m3/hr.
Exemplary Condition 13—See
Exemplary Condition 14—See
Exemplary Condition 15—See
Depressurization: Starting Temp: 110-120 Celsius, Ending Pressure: 100-150 Bar, Flow rate: 90-130 m3/hr.
Exemplary Condition 16—See
Exemplary Condition 17—See
Exemplary Condition 18—See
Exemplary Condition 19—See
As can be appreciated, variations in the combinations of variables, the timing of the variables, and the thresholds for each variable may be adjusted to achieve a result. For example, as the characteristics of the target material change, as the quantity and type of dyestuff change, the variables may be manipulated. The above-provided exemplary conditions are representative, but not limiting. Instead, combinations of variables may be combined as needed. A table is reproduced in
As provided herein, a sacrificial material may be used as a transport vehicle to introduce the material finish (e.g., dyestuff) intended to be perfused through the target material. In an exemplary aspect, the material finish is soluble in CO2 SCF allowing the SCF to dissolve the material finish to perfuse the material. SCF is non-polar; therefore, the chemistry of material finishes that are operable in a CO2 SCF processing system are chemistries that dissolve in a non-polar solution. For example, dyestuff suitable for dyeing a polyester material may dissolve in CO2 SCF, but not dissolve in water. Further, the dyestuff suitable for dyeing polyester may not have the appropriate chemistry to bond with a different material, such as an organic material like cotton. Therefore, it is contemplated that an organic material (e.g., cotton) is soaked in the material finish to be applied to a polyester material. The soaked organic material serves as the carrier material into the pressure vessel. When the CO2 SCF process is performed, the material finish is dissolved by the CO2 SCF and perfused through the polyester material. The organic material, which would require a different chemistry for material finish bonding, does not maintain the material finish and therefore the intended amounts of the material finish are available for the perfusing the target material.
In an example, a cotton material is used as a transport vehicle for dyestuff to dye a polyester material. In this example, 150 kg of polyester is desired to be dyed in a CO2 SCF process. If 1% of total target weight represents the amount of dyestuff needed to achieve a desired coloration. Then 1.5 kg of dyestuff is needed to be perfused into the polyester to achieve the desired coloration. The 1.5 kg of dyestuff may be diluted in an aqueous solution with 8.5 kg of water. Therefore, the dyestuff in solution is 10 kg. Because the dyestuff has a chemistry suitable for dissolving in a non-polar CO2 SCF, the dyestuff is merely suspended in the water as opposed to dissolved in the water, in this exemplary aspect. Cotton is highly absorbent. For example, cotton may be able to absorb up to 25 times its weight. Therefore, in order to absorb the 10 kg of dyestuff solution, a 0.4 kg portion of cotton (10/25=0.4) may serve as the carrier. However, it is contemplated that a larger portion of cotton may be used to achieve the transport of the dyestuff solution. In an exemplary aspect, a 30% absorption by weight of the cotton is contemplated. In the example above using 30% by weight absorption, the cotton is 33.3 kg to carry the 10 kg of dyestuff solution. It should be understood that the solution amount, dyestuff amount, and absorption amount may be adjusted to achieve the desired amount of material to be included in the pressure vessel for the dyeing process.
As applied to specific material finishing examples, it is contemplated that a material having different bonding chemistry needs than the target material (e.g., cotton to polyester) is submerged or otherwise soaked with a material finish solution. The soaked carrier material is then placed in the pressure vessel. The soaked carrier may be placed on a support structure or wrapped around the target material. The process of CO2 SCF finishing may be initiated. The CO2 SCF passes around and through the carrier material and dissolves the material finish for perfusing the target material with the material finish. At the completion of the material finish application, the CO2 is transitioned from the SCF state to a gaseous or liquid state (in an exemplary aspect). The material finish, which does not have a bonding chemistry for the carrier material, is attracted to and maintained by the target material, in an exemplary aspect. Therefore, at the completion of the finish process, the material finish is applied to the target material and the carrier material is void of appreciable quantities of the material finish, in an exemplary aspect.
As provided herein, density of CO2 affects a dissolution rate of dyestuff in SCF CO2. Changing of temperature and/or pressure affects the density of CO2, therefore, adjustments of the variables in the process affect the ability of the SCF CO2 to have dyestuff dissolve therein. The density of CO2 may be calculated using a number of techniques known to one of ordinary skill in the art. In an exemplary aspect, a method is provided by: R. Stryjek, J. H. Vera, PRSV: An Improved Peng—Robinson Equation of State for Pure Compounds and Mixtures; The Canadian Journal of Chemical Engineering, 64, April 1986. Other methods may also be implemented.
In an exemplary aspect, the temperature and pressure may be used to estimate a density of the CO2 in terms of Kg/m3. For example, operating at a temperature of 110 Celsius (e.g., 383 K) and 250 bars results in the CO2 having a density of 525 Kg/m3. As will be discussed, it is contemplated that a dyeing cycle of the process may operate at a relatively constant temperature, such as 100-120 Celsius (373-393 K) and a pressure of about 250 bars. With these temperature and pressure settings, the density of the SCF CO2 may range from 566-488 Kg/m3.
SCF CO2 acts as a solvent. The solubility of the SCF CO2 varies based on the density of the SCF CO2, such that when temperature is maintained relatively constant the solubility of the SCF CO2 increases with the density. Because density increases with pressure when temperature remains constant, the solubility of the CO2 increases with pressure.
In addition to manipulation of pressure to affect solubility of CO2, it is contemplated that temperature may be changed while maintaining the pressure relatively constant in the dyeing cycle of the processes provided herein. However, the relative trend between density and temperature is more complex. At a constant density, solubility of CO2 will increase with temperature. However, close to the critical point of the CO2, the density can drop sharply with a slight increase in temperature; therefore, close to the critical temperature, solubility often drops with increasing temperature, then rises again.
Further, it is contemplated that both the temperature and the pressure may be manipulated within the dyeing cycle of the process to affect the solubility by way of the CO2 density to achieve a desired dissolution of a material finish, such as dyestuff.
In an exemplary aspect, the material placed within a pressure vessel to be treated by SCF CO2 is a polyester-based material that may limit the manipulation of temperature and therefore changes in the density of CO2 may be limited. For example, above 120 Celsius, polyester may approach or exceed a transition temperature that causes a change in the feel, look, and/or structure of the polyester. However, to achieve acceptable solubility characteristics of the CO2, the pressure may be manipulated to achieve a sufficient density of the CO2. Therefore, in exemplary aspects, the temperature is maintained below 120 Celsius to limit unintended effects on the material to be finished.
Because increasing pressure and/or temperature consumes resources, such as energy, that reduces the efficiency of the material finishing/dyeing process, aspects herein limit the pressure and or temperature to a range that is sufficient to achieve solubility of the material finish and also sufficient for interaction with the material being finished. In an exemplary aspect, sufficient temperature and pressure is 100-125 Celsius and a pressure less than 300 bars. In an exemplary aspect, the temperature is 100-115 Celsius and 225-275 bars, which allows for a sufficient CO2 density to dissolve a multi-chemistry dyestuff and open the fibers of a polyester material for dyestuff permeation without negatively affecting the polyester of the to-be-finished material and without utilizing excessive energy resources trying to achieve a higher pressure. For example, a pressure of 310 bars and a temperature of 110 may also be executed to dye a polyester material; however, the 310 bar pressure consumes additional energy to achieve, which increases the cost and potential time of treating the material in a SCF CO2 process.
Previously, a density above 600 Kg/m3 was needed to achieve a sufficient solubility for a dyestuff to treat a material in the system. If the density of the CO2 was below this value, the provided dyestuff would not dissolve in the CO2 and therefore would not perfuse the material to-be-treated. For example, such as system may be disclosed in Supercritical Fluid Technology In Textile Processing: An Overview; Ind. Eng. Chem. Res. 2000, 39, 4514-41512. In the above system, a single dye chemistry is explored being dissolved at a CO2 density exceeding 600 Kg/m3 and utilization of the CO2 in the range of 566-488 Kg/m3 would not be sufficient to dissolve the explored dyestuff of that system. Therefore, to save energy, improve efficiency, and limit unintended effects on the material being finished, aspects herein contemplate limiting the density below 600 Kg/m3.
Further, it is contemplated that aspects hereof are configured for flexibility of finish material to be applied. For example, aspects contemplate a multi-chemistry dyestuff being applied to the target material by SCF CO2. Because there are multiple chemistries (e.g., multiple colors, multiple finishes, combinations of coloration and finishes, etc.), the various unique chemistries may have different CO2 densities at which they dissolve. Therefore, the chemistries are selected, in an exemplary aspect, to dissolve at the CO2 in the range of 566-488 Kg/m3, in an exemplary aspect. An exemplary aspect contemplates a multi-chemistry finish, such as a three (or more) color dyestuff combination. While the unique chemistries of the dyestuff dissolve in CO2 at different CO2 densities, each of the chemistries are soluble within the parameters of the system, such as a density of the CO2 in the range of 566-488 Kg/m3. In an exemplary aspect the multiple chemistry finishes are an unrefined dyestuff that is soluble in CO2 at a density in the range of 566-488 Kg/m3.
The resulting feel (also referred to as “hand”) of a material after finishing is an important criteria to consider when performing a finishing operation. In an exemplary aspect, it is contemplated that the material resulting from a SCF CO2 finishing process should have a similar feel (or hand) to that of a material finished in a water-based process. Therefore, it is contemplated that the variables achieving different CO2 densities may further be constrained based on their effect on the hand of the finished material. For example, processing at a temperature less than 110 Celsius provides, in an exemplary aspect, a better hand to the material than at temperatures above 110 Celsius. As provided above, a polyester material may have a transitional temperature near 120 Celsius (or any temperature above 110 Celsius) and the encroachment on that transitional temperature for a period of time during the CO2 process cycle changes the processed material's hand/feel. In yet a further aspect, operating at 100 Celsius for a polyester material results in a hand similar to that of a water-based dyeing process. Therefore, in exemplary aspects, CO2 operations at 100 Celsius may be selected to result in a hand feel similar to that of a material finished in a water-based solution.
Efficiencies at the precipitation of the finishing material realized in the processes described hereinabove allow for, in exemplary aspects, operating the CO2 processes in a repeated manner without interviewing cleaning of the system between target material runs. For example, allowing the finishing material to precipitate as it is being perfused through the target material as opposed to when it is stagnant in proximity to the pressure vessel or other components therein limits the amount of finishing material maintained by the system (e.g., on the vessel walls, on the holding member of the target material) following the depressurization cycle (e.g., depressurization cycle 1812 of
Therefore, it is contemplated that a series of cycles in a pressure vessel may include the insertion of a first target material into the pressure vessel, a first pressurization cycle, a first dyeing/treatment cycle, a first depressurization cycle, removal of the first target material, insertion of a second target material, a second pressurization cycle, a second dyeing/treatment cycle, a second depressurization cycle, and removal of the second target material. Absent from this sequence of event is the insertion of a sacrificial cleaning material and cycles of pressurization—dyeing/treatment/cleaning—depressurization with the sacrificial material. The elimination of these steps in the process saves, time, energy, and the sacrificial cleaning material.
A sacrificial cleaning material may be a material of similar composition to that of the target material. However, a lesser quantity of the sacrificial material may be used than the target material. For example, the target material may be 100-200 Kg of material. The sacrificial cleaning material may be less than 100 Kg of material. Further, while the cycles of treatment for a target material are selected to achieve a desired finish on the target material, the cycles of a cleaning process are instead selected to reduce the residual finishing material on the system surfaces regardless of the sacrificial cleaning material finish outcome. Another distinction between a sacrificial cleaning material and a target material is that additional finishing materials are not generally included in the CO2 process involving the sacrificial cleaning material. Further, inclusion of nominal finishing materials at a concentration disproportionate (e.g., 1-20%) of that used in connection with a target material could still be considered a sacrificial cleaning material, in exemplary aspects. Therefore, a sacrificial cleaning material can be distinguished from a target material as the finish of the material is not the primary purpose of the inclusion of the sacrificial cleaning material in the pressure vessel, in exemplary aspects.
Scouring is a process of preparing a target material for eventual finishing by the SCF process. For example, scouring removes oils and oligomers from the target material. The oils and oligomers, if allowed to remain in association with the target material, can affect a dyeing process. Therefore, the oils and oligomers are traditionally removed in a water-based scouring process prior to dyeing of the target material. Aspects herein use a SCF environment to scour a target material, such as a rolled good or a spooled good. A SCF scouring process reduces water usage and potential environmental impact as a result of the waterless implementation provided by a SCF, such as SCF CO2.
SCF scouring uses an operating environment similar to that provided above with respect to the SCF dyeing implementations. For example, a pressure vessel, such as an autoclave, may be used to pressurize and heat a gas to achieve a SCF state. Unlike dyeing, however, scouring is focused on removing elements (e.g., oligomers, oils) from the target material rather than introducing elements (e.g., dyestuff) to the target material. As such, some of the elements of the system may be utilized differently for scouring rather than dyeing. For example, a pump system that introduces and captures CO2 from within the pressure vessel may be used during the scouring process to extract CO2 and elements removed from the target material. This pump system is referred to herein as an external pump as the external pump is effective to circulate material (e.g., CO2) between the internal pressure vessel and an external location, such as a CO2 reservoir and filter. Aspects contemplate extracting CO2 having scoured elements, such as oligomers and oils, from the pressure vessel to the external location. The extracted CO2 may be filtered or otherwise treated to remove the extracted scoured elements from the CO2. Additionally, it is contemplated that a surfactant may be added to the processes to aid in the bonding between the SCF CO2 and the oligomers and/or oils. Additionally, it is contemplated that a sacrificial material is included with the target material such that the scoured elements, once removed from the target material, have a greater affinity for the sacrificial material allowing the scoured elements to transfer from the target material to the sacrificial material.
At a block 1604, CO2 is introduced within the pressure vessel. An external pump may transmit the CO2 from an external source, such as a holding tank, to the internal volume of the pressure vessel. The CO2 may be in any state, such as gas or liquid as it is introduced. The CO2 is brought to at least a SCF state at a block 1606. As previously discussed herein, the CO2 may be heated and pressurized to prescribed levels to achieve a sufficient scour operation.
The target material is perfused with the SCF CO2 at a block 1608. Unlike SCF dyeing of the target material, the perfusing of the target material with SCF CO2 in the scouring process has intent to remove unwanted elements from the target material. In some example, the pressure vessel may also include a surfactant or other material that aids in the bonding of the scoured elements with the SCF CO2. The surfactant or other materials are selected from those materials that will have a known or no impact on subsequent dyeing (e.g., finishing) of the target material. An internal pump may be activated to circulate the SCF CO2 in order to perfuse the target material, in a manner similarly described above with respect to the SCF dyeing of a material.
At a block 1610, the SCF CO2 is exchanged from the pressure vessel while maintaining the pressure vessel in a condition to achieve a SCF state of the CO2. An external pump may be activated to cause the exchange. The external pump may remove a quantity CO2 that is passed through one or more traps or filters effective to remove the scoured elements from the CO2. The external pump may reintroduce CO2 (the same or different CO2) within the pressure vessel. As such, the exchange of CO2 allows for a scrubbing of the working CO2 to extract the scoured elements from the pressure vessel. The exchange of the CO2 containing the scoured elements prevents, in some examples, the scoured elements from accumulating on the pressure vessel during the scouring process.
At a block 1612, scoured elements are removed from the extracted CO2. The CO2 may pass through a trap or filter processes to remove the oligomers and/or oils from the CO2. This allows the CO2 to be recycled and eventually introduced back into the pressure vessel. As such, the method of
A pressurization phase of the scouring process is initiated, as depicted at a block 1708. A scouring phase of the scouring process is initiated at a block 1710. A depressurization phase of the scouring is initiated within the pressure vessel at a block 1712. As provided herein, the various phases of the scouring process may be adjusted based on the material, conditions, or other factors.
Without removing the target material from the pressure vessel, in an exemplary aspect, the dyeing steps 1704 may be performed following the completion of the scouring steps 1702. In an alternative aspect, the target material may be removed from the pressure vessel to introduce a finishing material (e.g., dyestuff). Once the finishing material is introduced to the target material (e.g., a sacrificial material having the dyestuff placed in contact with the target material), the target material may be repositioned in the pressure vessel for the dyeing steps 1704 to be completed. Therefore, it is contemplated that a transition from a SCF scouring to a SCF dyeing process may be achieved with minimal disruption and substantially continuous in nature.
At a block 1714, finishing material is introduced into the pressure vessel with the target material. The finishing material may be introduced in any manner contemplated herein for dyeing. At a block 1716, a pressurization phase of the dyeing process is initiated within the pressure vessel. At a block 1718, a dyeing phase of the dyeing process is initiated within the pressure vessel. At a block 1720, a depressurization phase of the dyeing process is initiated within the pressure vessel. At a block 1722, the target material is removed from the pressure vessel.
Therefore, it is contemplated that any combination and value of variables may be applied during the SCF scouring process. For example, the temperature, pressure, flow rate, time, and external pump may all be adjusted during each of the cycles to achieve a degree of scouring appropriate for a target material and subsequent process, such as dyeing of the target material. Further yet, the variables discussed with respect to SCF dyeing herein may equally apply to SCF scouring. For example, the combinations of variables for pressurization cycle of SCF dyeing may be applied in some aspects of pressurization cycle of the SCF scouring; combinations of variables for dyeing cycle of SCF dyeing may be applied in some aspects of the scouring cycle of the SCF scouring; and combinations of variables for the depressurization cycle of SCF dyeing may be applied in some aspects of the depressurization cycle of SCF scouring.
It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.
While specific elements and steps are discussed in connection to one another, it is understood that any element and/or steps provided herein is contemplated as being combinable with any other elements and/or steps regardless of explicit provision of the same while still being within the scope provided herein. Since many possible embodiments may be made of the disclosure without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.
This application is a continuation of U.S. Nonprovisional application Ser. No. 15/048,634, entitled Supercritical Fluid Material Finishing, filed Feb. 19, 2016 (the “634 Application”), now U.S. Pat. No. 10,480,123. The '634 application claimed the benefit of U.S. Provisional Applications: (1) U.S. Provisional Patent Application 62/119,015, entitled Dyeing of Spooled Material with a Supercritical Fluid, filed on Feb. 20, 2015; (2) U.S. Provisional Patent Application 62/119,010 entitled Equilibrium Dyeing of Rolled Material with a Supercritical Fluid, filed on Feb. 20, 2015; (3) U.S. Provisional Patent Application 62/135,680, entitled Supercritical Fluid Treatment Process Variable Manipulation, filed on Mar. 19, 2015; and (4) U.S. Provisional Patent Application 62/296,980, entitled Supercritical Fluid Material Finishing, filed on Feb. 18, 2016. The entireties of the aforementioned applications are incorporated by reference herein.
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Number | Date | Country | |
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20200056330 A1 | Feb 2020 | US |
Number | Date | Country | |
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62296980 | Feb 2016 | US | |
62135680 | Mar 2015 | US | |
62119015 | Feb 2015 | US | |
62119010 | Feb 2015 | US |
Number | Date | Country | |
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Parent | 15048634 | Feb 2016 | US |
Child | 16661688 | US |