This invention relates to processes and equipment for converting moving substrates of indefinite length.
Moving substrates of indefinite length (viz., moving webs) can be converted in a variety of ways from one state or shape to another state or shape. Some converting processes produce considerable debris, or are carried out in the presence of airborne particulates or other contaminants, or may require a controlled environment when ordinary ambient air conditions might disrupt the converting process or pose a safety hazard. This can be a particular problem in dry converting operations, when static buildup may cause debris, particulates or other contaminants to adhere to the moving substrate. For example, optical-grade coatings on plastic films are especially sensitive to contamination, which may cause visible defects.
Typical controlled environments include clean rooms and the use of inert, low oxygen or saturated atmospheres. Clean rooms and special atmospheres require costly auxiliary equipment and large volumes of filtered air or specialty gases. For example, a typical clean room operation may require many thousands of liters per minute of filtered air.
The disclosed invention includes a process and apparatus for dry converting a moving substrate of indefinite length in a controlled environment using low volumes of filtered air or specialty gases. The disclosed process and apparatus utilize a close enclosure that envelopes the moving substrate during at least the converting operation, the close enclosure being supplied with one or more streams of conditioned gas flowing at a rate sufficient to reduce materially the close enclosure particle count. The invention thus provides in one aspect a process for dry converting a moving substrate of indefinite length comprising conveying the substrate through a dry converting station in a close enclosure while supplying the enclosure with one or more streams of conditioned gas flowing at a rate sufficient to reduce materially the particle count in the close enclosure.
The invention provides in another aspect an apparatus for converting a moving substrate of indefinite length comprising a dry converting station and substrate-handling equipment for conveying the substrate through the dry converting station, the substrate being enveloped in the dry converting station by a close enclosure supplied with one or more streams of conditioned gas flowing at a rate sufficient to reduce materially the particle count in the close enclosure.
The invention provides in yet another aspect a process for dry converting a moving substrate of indefinite length comprising conveying the substrate through a dry converting station in a close enclosure while supplying the enclosure with one or more streams of conditioned gas flowing at a rate sufficient to cause a material change in a physical property of interest for the atmosphere in the close enclosure.
The invention provides in yet another aspect an apparatus for converting a moving substrate of indefinite length comprising a dry converting station and substrate-handling equipment for conveying the substrate through the dry converting station, the substrate being enveloped in the dry converting station by a close enclosure supplied with one or more streams of conditioned gas flowing at a rate sufficient to cause a material change in a physical property of interest for the atmosphere in the close enclosure.
The above, as well as other advantages of the disclosed invention will become readily apparent to those skilled in the art from the following detailed description when considered in light of the accompanying drawing in which:
Like reference symbols in the various figures indicate like elements. The elements in the drawing are not to scale.
When used with respect to a flexible moving substrate or an apparatus conveying such substrates, the phrase “dry converting” refers to an operation carried out without applying or drying a wet coating on the substrate, wherein the operation changes the substrate's cleanliness state, surface energy, shape, thickness, crystallinity, elasticity or transparency. Dry converting may include, for example, operations such as cleaning (e.g., plasma treating or the use of tacky rolls), electrically priming (e.g., corona-treating), slitting, cutting into pieces, splitting (e.g., stripping into sheets), laminating, stretching (e.g., orienting), folding (e.g., corrugating), thermoforming, masking, demasking, vapor coating, heating or cooling.
When used with respect to an apparatus for converting a moving substrate or a component or station in such an apparatus, the phrase “dry converting station” refers to a device that carries out dry converting.
When used with respect to a moving substrate or an apparatus for converting such substrates, the words “downstream” and “upstream” refer respectively to the direction of substrate motion and its opposite direction.
When used with respect to an apparatus for converting a moving substrate or a component or station in such an apparatus, the words “leading” and “trailing” refer respectively to regions at which the substrate enters or exits the recited apparatus, component or station.
When used with respect to a moving substrate or an apparatus for converting such substrates, the word “width” refers to the length perpendicular to the direction of substrate motion and in the plane of the substrate.
When used with respect to an apparatus for converting a moving substrate or a component or station in such an apparatus, the phrase “web-handling equipment” refers to a device or devices that transport the substrate through the apparatus.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the phrase “control surface” refers to a surface that is generally parallel to a major face of the substrate and located sufficiently close to the substrate so that an atmosphere that may affect the substrate is present between the control surface and the substrate. A control surface may include for example an enclosure housing, a separate plate, the walls of a slit, or other surface having an appreciable area generally parallel to a major face of the substrate.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the word “overlying” refers to an apparatus, component or station that would be above the substrate if the substrate is envisioned in a horizontal orientation.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the word “underlying” refers to an apparatus, component or station that would be below the substrate if the substrate is envisioned in a horizontal orientation.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the word “headspace” refers to the distance from the substrate to an overlying nearby control surface measured perpendicular to the substrate if the substrate is envisioned in a horizontal orientation.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the word “footspace” refers to the distance from the substrate to an underlying nearby control surface measured perpendicular to the substrate if the substrate is envisioned in a horizontal orientation.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the phrase “close enclosure” refers to an enclosure whose average headspace plus average footspace throughout the enclosure is no greater than about 30 cm.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the phrase “conditioned gas” refers to gas that is different from the ambient air surrounding the apparatus in at least one property of interest.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the phrase “particle count” refers to the number of 0.5 μm or larger particles in a volume of 28.3 liters.
When used with respect to a physical property of interest (e.g., the particle count) for the atmosphere in an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the word “material” refers to at least a 50% reduction or increase in the property of interest compared to the ambient air surrounding the apparatus, component or station.
When used with respect to an enclosed apparatus for converting a moving substrate or an enclosed component or station in such an apparatus, the phrase “negative pressure” refers to pressure below that of the ambient air surrounding the apparatus, component or station, and the phrase “positive pressure” refers to a pressure above that of the ambient air surrounding the apparatus, component or station.
When used with respect to an apparatus for converting a moving substrate or a component or station in such an apparatus, the phrase “pressure gradient” refers to a pressure differential between an interior portion of the apparatus, component or station and that of the ambient air surrounding the apparatus, component or station.
A webline employing a slitter/cleaner in a close enclosure is shown in schematic side sectional view in
The slitter/cleaner components are enveloped by a close enclosure 10 formed by overlying housing 30 and underlying housing 32. Housings 30, 32 may conform closely to the shape of the slitter/cleaner components to provide a reduced interior atmosphere and reduced interior volume. A further close enclosure and transition zone formed by overlying control surface 25 and underlying control surface 26 is interconnected to close enclosure 10 and is connected to cabinet 33. Upper and lower manifolds 34 and 36 respectively may provide gas flows into or out of the apparatus (e.g., conditioned gas streams M1′U and M1′L) at a point downstream from the slitter/cleaner components. Conditioned gas streams M1′U and M1′L desirably differ from the ambient air by having a lower particle count, but may in addition or instead differ in another property of interest, e.g., a different chemical composition due to the absence or presence of one or more gases (including humidity) or a different temperature. Upper and lower manifolds 38 and 40 respectively may provide gas flows into or out of close enclosure 10 (e.g., withdrawn gas streams M4U and M4L).
The disclosed process and apparatus do not need to employ all the close enclosures shown in
If desired, conditioned gas streams could be injected (or gas could be withdrawn) at more or fewer locations than are shown in
A cleanroom could optionally surround the disclosed apparatus. However, this could be of a much lower classification and much smaller volume than that which might typically be used today. For example, the cleanroom could be a portable model using flexible hanging panel materials. Also, a variety of web support systems that will be familiar to those skilled in the art may be employed in the disclosed process and apparatus, including porous air tubes, air bars, and air foils.
In one embodiment of the disclosed process, a moving substrate of indefinite length has at least one major surface with an adjacent gas phase. The substrate is treated with an apparatus having a control surface in close proximity to a surface of the substrate to define a control gap between the substrate and the control surface. The control gap may be referred to as the headspace or footspace between the substrate and the nearby control surface.
A first chamber may be positioned near a control surface, with the first chamber having a gas introduction device. A second chamber may be positioned near a control surface, the second chamber having a gas withdrawal device. The control surface and the chambers together define a region wherein the adjacent gas phases possess an amount of mass. At least a portion of the mass from the adjacent gas phases is transported through the gas withdrawal device by inducing a flow through the region. The mass flow can be segmented into the following components:
M1, M1′, M2, M3 and M4 are further illustrated in
In addition to gaps GC, G1 and G2, control of the atmosphere near the substrate may also be aided by using mechanical features, such as extensions 323 and 325 in
Mass flow through a close enclosure may be assisted by employing a suitable seal with respect to the moving substrate (viz., a “moving substrate seal”) at an upstream or downstream inlet or outlet of a close enclosure or connected chain of close enclosures. The seal may function as a sweep to prevent gas from entering or exiting the close enclosures. The seal could also include for example a forced gas, mechanical or retractable mechanical seal such as those shown in U.S. Pat. No. 6,553,689, or a pair of opposed nip rolls. A retractable mechanical sealing mechanism can allow passage of splices and other upset conditions. It may be desirable briefly to increase one or more nearby conditioned gas flow rates (or to decrease or switch one or more nearby gas withdrawal rates) to maintain the desired atmosphere near the seal. A pair of opposed nip rolls may be located for example, upstream or downs stream from the first or last dry converting station in a process.
By using a control surface in close proximity to the substrate surface, a supply of conditioned gas and a positive or small negative pressure gradient, a material particle count reduction may be obtained within a close enclosure. The pressure gradient, Δp, is defined as the difference between the pressure at the chamber's lower periphery, pc, and the pressure outside the chamber, po, wherein Δp=pc−po. Through appropriate use of conditioned gas and adjustment of the pressure gradient, particle count reductions of, for example, 50% or more, 75% or more, 90% or more or even 99% or more may be achieved. An exemplary pressure gradient is at least about −0.5 Pa or higher (viz., a more positive value). Another exemplary pressure gradient is a positive pressure gradient. As a general guide, greater pressures can be tolerated at higher moving substrate speeds. Greater pressures can also be tolerated when moving substrate seals are employed at the upstream and downstream ends of a series of interconnected close enclosures. Those skilled in the art will appreciate that the close enclosure pressure(s) may be adjusted based on these and other factors to provide a desirably low particle count within appropriate portions of the disclosed apparatus while avoiding undue substrate disturbance.
The disclosed process and apparatus may also substantially reduce the dilution gas flow, M1, transported through the chamber. The disclosed process and apparatus may, for example, limit M1 to an absolute value not greater than 0.25 kg/second/meter. M1 may be, for example, less than zero (in other words, representative of net outflow from the close enclosure) and greater than −0.25 kg/second/meter. In another exemplary embodiment, M1 may be less than zero and greater than −0.1 kg/second/meter. As is shown in the examples below, small negative enclosure pressures (which may correspond to slight positive M1 flows) can be tolerated. However, large negative enclosure pressures (which may correspond to large positive M1 flows) may cause adverse effects including dilution of mass in the adjacent gas phase, introduction of particles and other airborne contaminants, and introduction of uncontrolled ingredients, temperatures or humidity.
In one exemplary embodiment we control a process by appropriately controlling M1′ and M4. A deliberate influx of a conditioned gas stream (e.g., a clean, inert gas having a controlled humidity) can materially promote a clean, controlled atmosphere in the close enclosure without unduly increasing dilution. By carefully controlling the volume and conditions under which M1′ is introduced and M4 is withdrawn (and for example by maintaining a slight positive pressure in the close enclosure), flow M1 can be significantly curtailed and the close enclosure particle count can be significantly reduced. Additionally, the M1′ stream may contain reactive or other components or optionally at least some components recycled from M4.
The headspace or footspace may be substantially uniform from the upstream end to the downstream end and across the width of the close enclosure. The headspace or footspace may also be varied or non-uniform for specific applications. The close enclosure may have a width wider than the substrate and desirably will have closed sides that further reduce time-average mass flow per unit width from pressure gradients (M1). The close enclosure can also be designed to conform to different geometry material surfaces. For example, the close enclosure can have a radiused periphery to conform to the surface of a cylinder.
The close enclosure may also include one or more mechanisms to control the phase of the mass transported through the close enclosure thereby controlling phase change of the components in the mass. For example, conventional temperature control devices may be incorporated into the close enclosure to prevent condensate from forming on the internal portions of the close enclosure. Non-limiting examples of suitable temperature control devices include heating coils, electrical heaters, external heat sources and heat transfer fluids.
Optionally, depending upon the composition of the gas phase composition, the withdrawn gas stream (M4) may be vented or filtered and vented after exiting the close enclosure. The gas phase composition may flow from one or more of the close enclosures to a subsequent processing location, e.g., without dilution. The subsequent processing may include such optional steps as, for example, separation or destruction of one or more components in the gas phase. The collected vapor stream may contain particulate matter which can be filtered prior to the separation process. Separation processing may also occur internally within the close enclosure in a controlled manner. Suitable separation or destruction processes will be familiar to those skilled in the art.
It is desirable to avoid airflow patterns that might unduly disturb the substrate.
Upper and lower manifolds 720 and 722 respectively may provide gas flows into or out of the upstream end of close enclosure 700 (e.g., conditioned gas streams M1′U and M1′L). Upper and lower manifolds 724 and 726 respectively may provide gas flows into or out of the upstream end of close enclosure 700 (e.g., withdrawn gas streams M4U and M4L). The pressures inside the enclosure can be characterized by P1, P2, P13, P23, P3 and P4. The ambient air pressure outside close enclosure 700 is given by Patm.
The disclosed process and apparatus typically will utilize a web handling system to transport a moving substrate of indefinite length through the apparatus. Those skilled in the art will be familiar with suitable material handling systems and devices. Those skilled in the art will also appreciate that a wide variety of substrates may be employed, including, for example, a polymer, woven or non-woven material, fibers, powder, paper, a food product, pharmaceutical product or combinations thereof. The disclosed process and apparatus may also be used, for example to clean or prime a substrate prior to the application of a coating, as described in copending U.S. Patent Application Serial No. (Attorney docket number 55752US018), filed even date herewith and entitled “COATING PROCESS AND APPARATUS”, the disclosure of which is incorporated herein by reference.
In operation, exemplary embodiments of the disclosed apparatus can significantly reduce the particle count in the atmosphere surrounding a moving web. Exemplary embodiments of the disclosed apparatus may also capture at least a portion of a vapor component from a substrate (if present) without substantial dilution and without condensation of the vapor component. The supplied conditioned gas may significantly reduce the introduction of particulates into portions of the apparatus surrounding the substrate and thus may reduce or prevent product quality problems in the finished product. The relatively low air flow may significantly reduce disturbances to the substrate and thus may further reduce or prevent product quality problems.
A single close enclosure was constructed to illustrate the effect of certain variables.
Downstream process 924 has movable underlying control surface 926, overlying control surface 928 equipped with ambient gas inlet 930 and vacuum outlet 932, and underlying and overlying web slot pieces 926 and 928. These web slot pieces are spaced apart a distance hB1. Underlying web slot piece 926 is spaced apart from web 14 a distance hB2. These web slot pieces have length l3. Through appropriate regulation of the flows through inlet 930 and outlet 932, process 924 can simulate a variety of devices.
For purposes of this example close enclosure 900 was used with an uncoated web and was not connected at either its upstream or downstream ends to another close enclosure. Thus the surrounding room, with a defined ambient pressure of zero, lies upstream from transition zone 908 and downstream from process 924. The room air temperature was about 20° C.
Particle counts were measured using a MET ONE™ Model 200L-1-115-1 Laser Particle Counter (commercially available from Met One Instruments, Inc.), to determine the number of 0.5 μm or larger particles in a volume of 28.3 liters, at a 28.3 liters/min flow rate. Pressures were measured using a Model MP40D micromanometer (commercially available from Air-Neotronics Ltd.). Oxygen levels were measured using a IST-AIM™ Model 4601 Gas Detector (commercially available from Imaging and Sensing Technology Corporation). Gas velocities were evaluated using a Series 490 Mini Anemometer (commercially available from Kurz Instruments, Inc.).
Upper and lower distribution manifolds 920 and 922 were connected to a nitrogen supply and the flow rates adjusted using DWYER™ Model RMB-56-SSV flow meters (commercially available from Dwyer Instruments, Inc.). Vacuum outlet 932 was connected to a NORTEC™ Model 7 compressed air driven vacuum pump (commercially available from Nortec Industries, Inc.). The flow rate was adjusted using a pressure regulator and a DWYER Model RMB-106 flow meter (commercially available from Dwyer Instruments, Inc.).
Close enclosure 900 was adjusted so that le=156.2 cm, we=38.1 cm, he1=4.45 cm, he2=0.95 cm, h1a=0.46 cm, h1b=0.23 cm, i1=7.62 cm, h2a=1.27 cm, h2b=0.13 cm, i2=3.8 cm, hB1=0.46 cm, hB2=0.23 cm, l3=2.54 cm and V=0. The enclosure pressure was adjusted by varying the flow rates M1′U and M1′L and the rate of gas withdrawal at outlet 932, using sample port B (see
Example 1 was repeated using an 18 m/minute web velocity V. The particle count results are shown in
Using the method of Example 1, a −0.5 Pa enclosure pressure was obtained in close enclosure 900 by adjusting the flow rates M1′U and M1′L to 24 liters/min and by adjusting the rate of gas withdrawal at outlet 932 to 94 liters/min. In a separate run, a +0.5 Pa enclosure pressure was obtained by adjusting the flow rates M1′U and M1′L to 122 liters/min and by adjusting the rate of gas withdrawal at outlet 932 to 94 liters/min. The respective particle counts were 107,889 at −0.5 Pa, and only 1 at +0.5 Pa. For each run the enclosure pressure above the substrate was measured at several points along the length of close enclosure 900 using holes 2, 5, 8, 11 and 14 (see
In a comparison run, pressure measurements were made at varying points inside and outside a TEC™ air flotation oven (manufactured by Thermal Equipment Corp.) equipped with a HEPA filter air supply set to maintain a −0.5 Pa enclosure pressure. The upper and lower flotation air bar pressures were set to 250 Pa. The make-up air flowed at 51,000 liters/min (equivalent to about 7.5 air changes/minute for a 6800 liter oven capacity, not taking into account equipment inside the oven). The ambient room air particle count was 48,467. The particle count measured approximately 80 centimeters inside the oven was 35,481. The particle counts at several other positions were measured as shown in
Using the general method of Example 1, the M1′U and M1′L flow rates were set at 122 liters/min and the rate of gas withdrawal at outlet 932 was set at 94 liters/min. The web slot height h1a was adjusted to values of 0, 0.46, 0.91, 1.27, 2.54 and 3.81 cm. The ambient air particle count was 111,175.
Using the general method of Example 1 and a 23 cm wide polyester film substrate moving at 0, 6 or 18 m/min, the M1′U and M1′L flow rates and the rate of gas withdrawal at outlet 932 were adjusted to obtain varying enclosures pressures. The ambient air particle count was 111,175. The enclosure particle count was measured as a function of web speed and enclosure pressure. The results are shown in
From the above disclosure of the general principles of the disclosed invention and the preceding detailed description, those skilled in this art will readily comprehend the various modifications to which the disclosed invention is susceptible. Therefore, the scope of the invention should be limited only by the following claims and equivalents thereof.
This application is a continuation of allowed U.S. patent application Ser. No. 10/810065 filed on Mar. 26, 2004, which is a continuation-in-part of and claims priority to U.S. patent application Ser. No. 10/421,195, filed Apr. 23, 2003, which in turn is a continuation-in-part of and claims priority to U.S. patent application Ser. No. 09/960,131, filed Sep. 21, 2001 (now U.S. Pat. No. 6,553,689 B2), which in turn claims priority to U.S. Provisional Application Ser. Nos. 60/235,214, filed Sep. 24, 2000, 60/235,221, filed Sep. 24, 2000, and 60/274,050, filed Mar. 7, 2001, all of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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60235214 | Sep 2000 | US | |
60235221 | Sep 2000 | US | |
60274050 | Mar 2001 | US |
Number | Date | Country | |
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Parent | 10810065 | Mar 2004 | US |
Child | 11565353 | Nov 2006 | US |
Number | Date | Country | |
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Parent | 10421195 | Apr 2003 | US |
Child | 10810065 | Mar 2004 | US |
Parent | 09960131 | Sep 2001 | US |
Child | 10421195 | Apr 2003 | US |