Abstract:
The present invention is directed to an apparatus and a method for monitoring the viscoelastic properties, of a liquid film (e.g. coating). The apparatus includes a substrate for supporting a liquid film and a T-bar probe that is partially submerged in the liquid film. The apparatus is designed to be attached to a conventional rheometer equipped with a means for effecting relative movement between the probe and the substrate and means for monitoring the resistance to movement of the probe in contact or partially submerged in the film to obtain a measurement of the solidification properties of the liquid film. This apparatus and method are particularly useful in comparing the effects of film formers, viscosity modifiers, solvents, and minerals on the drying rate of coatings at the early stage of film formation.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application is a continuation-in-part application of U.S. application Ser. No. 11/024,912, filed Dec. 20, 2004, which is incorporated herein by reference, and which claims the benefit, under 35 USC 119, of U.S. Provisional Application No. 60/531,740, filed Dec. 22, 2003. 
     
    
     BACKGROUND  
       [0002]     The present invention is directed to an apparatus and a method for monitoring the solidification properties, including the viscoelastic properties, of a solidifiable liquid film (e.g. coating).  
         [0003]     The performance of a liquid film, specifically a coating, depends on many variables, such as its viscosity, its elasticity, its surface tension and the rate of solvent evaporation. These variables must be optimized to achieve desirable characteristics, such as flow and leveling, anti-sag, anti-mounding, drying rate, pigment dispersion and other preferred characteristics. For example, after a liquid film is deposited to a substrate, the liquid film needs time to level. However, the liquid film must also dry quickly so as not to sag. Good flow and leveling characteristics often require low viscosity liquid films with Newtonian behavior while good anti-sag requires liquid films having high viscosity at low shear rates. The challenge when forming films is to control these competing properties to provide liquid films with the desired characteristics.  
         [0004]     The dryness of a liquid film on a substrate is often described as a surface phenomenon and is defined in many different ways, such as by viscosity. For example, the American Society for Testing and Materials (ASTM) describes the standard test method for measuring times of drying or curing of organic coatings using mechanical recorders in ASTM D5895-01. In this test a coating is applied to a glass strip and a stylus placed on the wet coating and moved either in a linear motion or in a 360° arc at a constant speed. Various drying times, e.g., set-to-touch time, and tack-free time, dry-hard time, and dry-through time, are visually determined by observing the track of the stylus on the glass slide. Unfortunately test results of this kind are quite subjective and difficult to accurately reproduce.  
         [0005]     Many other ways have been proposed to measure the dryness or the drying rate of a liquid film. For example, the dry-to-touch time is commonly used and is defined by the time from the application of a liquid film onto a surface to the time the film can be touched with an object (usually the hand of the tester) without the film being transferred from the surface to the object (hand). However, the dry-to-touch time is dependent upon many subjective criteria, such as how much pressure is applied, and is not consistently reproducible.  
         [0006]     Another method to determine the drying rate is scratching a coating that has been applied to a surface using a pencil or other sharp object (e.g. Tukon test) at certain elapsed times. Yet another method for measuring the relative drying rate is a gravimetric method that measures the amount of solvent loss from the liquid film.  
         [0007]     A drawback to the methods mentioned above is that they only measure properties related to the viscosity of the liquid film. In addition to the viscosity, solidifiable liquid films also exhibit elasticity that changes during the solidification process. A direct measurement of the viscoelastic properties (the viscosity and elastic properties of a liquid film) provides more accurate and detailed information of the solidification process of a liquid film.  
         [0008]     A frequently used technique to monitor the viscoelastic properties of a coating deposited on a substrate is the torsion braid analysis (J. Polymer Sci. Part C, No.35, pp 3-21 (1971)). The torsion braid analysis monitors decaying amplitude and frequency to determine the affect of a liquid film as it solidifies on a substrate. One problem with this analysis is that the restoring force or the elastic modulus of the substrate is so much stronger than that of the liquid film that it is very difficult to determine the relatively small effect of the liquid film on the total torque. In addition, this test is sensitive to such variables as non-uniform distribution of the coating on the substrate and irregular drying patterns, which reduce the accuracy and reproducibility of the test.  
         [0009]     German patent DE 19806905 provides another technique for measuring changes in the viscoelastic properties of a liquid film as it solidifies on a thin hard plate. The technique disclosed in DE 19806905 measures the viscoelastic properties by measuring the resonance frequency applied either in a torsional or flexural mode using a substrate, such as a rectangular plate, coated with a liquid film. The resultant force and the resonance frequency shift that occur as the liquid film dries are measured by a piezoelectric material and converted into loss (G″) and storage (G′) moduli.  
         [0010]     U.S. Pat. No. 4,799,453 and Japanese patent 63145943 describe apparatus that monitor film formation during curing by UV, oxidation, and evaporation of solvents. In these patents the solidification characteristics of the liquid film are electronically monitored by measuring the resistance to movement of a stylus through the liquid film as it solidifies. Although this technique improves the accuracy as compared to other techniques, such as the swab resistance test or testing the film surface with one&#39;s thumb, it monitors changes only in the hardness of the film as it dries.  
         [0011]     German patent DE 3420341 teaches a technique to measure the drying time of a liquid film by a rotating an object, such as a ball, on an inclined disc. The position of the ball placed eccentrically on a coated disc is monitored by a light detector. The inclined disc is rotated by a motor to keep the ball at the same position on the disc. The rotational speed of the disc necessary to maintain the ball in a stationary position is proportional to the viscosity of the liquid film. The viscosity is plotted as a function of time to provide a viscosity verses time measurement for the liquid film. In addition to requiring intricate and expensive equipment, this method only measures the viscosity or stickiness of the liquid film and does not measure other solidification properties, such as elasticity of the liquid film.  
         [0012]     In view of the above, it is apparent that there is a need for a means of reliably, consistently and accurately measuring the solidification properties of a liquid film on a substrate under laboratory conditions.  
       SUMMARY OF THE INVENTION  
       [0013]     The present invention provides an apparatus for reliably, consistently and accurately monitoring the solidification properties of a solidifiable liquid film. The present invention provides an accurate monitoring by minimizing the intrusion on the liquid film, thus mimicking the actual solidification process of a liquid film. By measuring the change in the viscosity and the elasticity with an apparatus, the present invention provides a consistently objective and reproducible method for monitoring the solidification properties of a liquid film.  
         [0014]     The article of the present invention comprises a substrate, such as a trough or plate, a probe mounted so as to contact a liquid film on the substrate, a means of effecting relative movement of the probe and the substrate so that the probe moves with respect to the substrate and contacts the film while the film is solidifying, and a means for monitoring the resistance to movement of the probe contacting the film to obtain a measurement of the solidification properties of the film.  
         [0015]     In another embodiment, the present invention is a process for measuring the viscoelastic properties of a liquid film on a substrate comprising the steps of contacting a probe with the liquid film, moving the probe relative to the substrate so that the probe moves with respect to the surface of the substrate and in contact with the film while the film is solidifying, and monitoring the change in the solidification properties of the film. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0016]      FIG. 1  is a side view of a preferred embodiment of an apparatus of the present invention.  
         [0017]      FIG. 1   a  is a side view of an embodiment of a reinforced T-bar probe (with a square configuration) of the present invention.  
         [0018]      FIG. 1   b  is a side view of another embodiment of a reinforced T-bar probe (with a slanted configuration) of the present invention.  
         [0019]      FIG. 1   c  is a side view of another embodiment of a reinforced T-bar probe (with a slanted configuration and having multiple support arms) of the present invention.  
         [0020]      FIG. 2  is a top view of a preferred embodiment of a probe and a trough.  
         [0021]      FIG. 3  provides a graphic representation of the viscoelastic properties verses time of a liquid carboxymethyl cellulose acetate butyrate (CMCAB ester) basecoat film in a 0.1 mm trough as more fully described in Example 1.  
         [0022]      FIG. 4  provides a graphic representation of the viscoelastic properties verses time of a liquid acrylic latex dispersion film in a 0.2 mm trough as more fully described in Example 2.  
         [0023]      FIG. 5  provides a graphic representation of the viscoelastic properties (complex viscosity, Eta*) verses time of the liquid acrylic latex dispersion film in a 0.2 mm trough as described in Example 2, with and without nitrogen flow. This is more fully described in Example 3.  
         [0024]      FIG. 6  provides a graphic representation of the viscoelastic properties (complex viscosity, Eta*) verses time of a lacquer solution film in a 0.1 mm trough and in a 0.2 mm trough as more fully described in Example 4.  
         [0025]      FIG. 7  provides a graphic representation of the viscoelastic properties (complex viscosity, Eta*) verses time of a CAB basecoat in a 0.1 mm trough and in a 0.2 mm trough as more fully described in Example 5.  
         [0026]      FIG. 8  provides a graphic representation of the viscoelastic properties (viscous (G″) and elastic (G′) moduli) verses time of a CAB basecoat in a 0.2 mm trough as more fully described in Example 5.  
         [0027]      FIG. 9  provides a graphic representation of the viscoelastic properties (viscous (G″) and elastic (G′) moduli) verses time of a CAB basecoat in a 0.1 mm trough as more fully described in Example 5.  
         [0028]      FIG. 10  provides a graphic representation of the viscoelastic properties verses time of a CAB refinish basecoat with the composition disclosed in Example 6 using the reinforced T-bar probe.  
         [0029]      FIG. 11  provides a graphic representation of the changes in viscoelastic properties of a hairspray with the composition disclosed in Example 7 using the reinforced T-bar probe.  
         [0030]      FIG. 12  provides a graphic representation of the changes viscoelastic properties of an OEM automotive metallic basecoat with the composition disclosed in Example 8 using the reinforced T-bar probe with the substrate set at three different temperatures.  
         [0031]      FIG. 13  provides a graphic representation of the changes in viscoelastic properties of the composition disclosed in Example 9 when using a reinforced T-bar probe set at two different gap levels.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0032]     The present invention may be understood more readily by reference to the following detailed description of the invention, including the appended figures referred to herein, and the examples provided therein. It is to be understood that this invention is not limited to the specific apparatus and processes described, as specific apparatus and processes and/or process conditions for measuring the viscoelastic properties and the solidification properties of liquids may, of course, vary depending on variable, such as the type of liquid being measured and the equipment available.  
         [0033]     It must also be noted that, as used in the specification and the appended claims, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise.  
         [0034]     Ranges may be expressed herein as from “about” or “approximately” one particular value and/or to “about” or “approximately” another particular value. When such a range is expressed, another embodiment includes from the one particular value and/or to the other particular value.  
         [0035]     By “comprising” or “containing” is meant that at least the named apparatus, element, or method step etc. must be present in the article or method, but does not exclude the presence of other materials, article, elements, or method steps, etc, even if the other such materials, articles, elements, or method steps etc. have the same function as what is named.  
         [0036]     It is also to be understood that the mention of one or more method steps does not preclude the presence of additional method steps or intervening method steps between those steps expressly identified.  
         [0037]     Viscosity refers to the resistance of a liquid to flow.  
         [0038]     Elasticity refers to the ability of a material, such as a liquid, to store part of the applied energy to it. The material may recover part of its deformation when the stress is removed (elastic recoil as in the case of rubber band).  
         [0039]     Viscoelasticity refers to both viscosity and elasticity being exhibited by a material, such as by a solidifiable liquid.  
         [0040]     The viscosity and elasticity values for the liquid films are expressed in relative terms as a function of the change over time in these values.  
         [0041]     Flow and leveling refer to the property of a liquid film, such as a coating, that determines how easily and uniformly the liquid spreads out after it is applied on a substrate.  
         [0042]     Sag resistance refers to the resistance of a solidifiable liquid film to dripping or downward flow due to gravity.  
         [0043]     Mound or mounding refers to bumps that form as a solidifiable liquid film solidifies on a substrate.  
         [0044]     Pigment wetting refers to the wetting of pigments by a liquid to uniformly disperse the pigments in a liquid film.  
         [0045]     Rheometer is an instrument that may be used to measure rheological properties (viscosity, elasticity, normal force and others) of liquids. A rheometer may have a means of moving a probe relative to a substrate, such as a motor, and a means of detecting resistance, such as a sensor, also herein referred to as a transducer.  
         [0046]     Dynamic oscillatory capability refers to the capability that a rheometer has to shear (or deform) a liquid film in an oscillatory fashion, which is a dynamic motion.  
         [0000]     Discussion  
         [0047]     One embodiment of the present invention includes the discovery of a method to monitor changes in the viscoelastic properties of liquid films, specifically solidifiable liquid films such as coatings, with minimum disturbance of the liquid during solidification. Another embodiment of the present invention is directed to an apparatus for monitoring the viscoelastic properties of a liquid film (for example, over time as the liquid dries). The apparatus comprises a substrate, such as a trough or plate, preferably a flat plate, and a probe, such as a thin hard wire T-bar, preferably mounted on any conventional rheometer having dynamic oscillatory capability. The probe detects the resistance of the liquid film over time to provide the resistance to a sensing means that will measure the torque and the phase angle between the sinusoidal input signal from the sensor and the output signal from the probe as the liquid film solidifies. The torque and the phase angle are used to determine the complex viscosity (Eta*), the viscous modulus (G″) and the elastic modulus (G′). In a preferred embodiment, the probe is contacted with the liquid film immediately after the liquid film is introduced into the trough and remains in contact with the liquid film until the film becomes a solid.  
         [0048]     The invention is suitable for determining the viscoelastic properties and the solidifying properties of a large variety of different types of liquid films, including both convertible (the film capable of being re-dissolvable) and non-convertible films. Thus, for example, it is suitable for monitoring films which solidify as a consequence of being subjected to ultraviolet or infrared radiation or an electron beam, oxidation (e.g. films based on alkyd resins), heating (e.g. phenolic resins films), chemical reaction between reactive groups (e.g. epoxy resin based films), free radical formation (e.g. films which solidify after peroxide initiation), evaporation (i.e. films formed by removal of a liquid phase from a solution or emulsion), precipitation i.e. films of, for example, ink formed by changing the solvent balance of a solution so as to precipitate out a solid phase, etc. In a preferred embodiment the present invention is useful for films cured by oxidation and evaporation. Thus, the invention has many applications such as, for example, monitoring the drying of inks during printing, the curing of ultraviolet (U/V) curable (slow and fast) optical fiber coatings and the hardening of adhesives and paints. Also, the invention enables the influence of the substrate on the solidification properties of the film to be assessed.  
         [0049]     The film thickness may be varied by the depth of the trough. Depending on the application, the trough may be any suitable size, shape or configuration that allows for a probe to measure the solidification properties of a liquid film. The trough preferably provides a laboratory reproduction of an actual liquid film solidification process. For example, if a paint is the liquid film to be monitored, then the trough is preferably shallow having a depth ranging from about 0.005 mm to about 5 mm, preferably from about 0.01 mm to about 1 mm, more preferably from about 0.05 mm to about 0.3 mm and most preferably from about 0.1 mm to about 0.2 mm. The width should be wide enough to avoid any adverse effects from premature drying from the edges which may occur. In one embodiment, the width or the diameter (depending on whether the trough is square, rectangular, circular or other shape) of the trough ranges from about 2 mm to about 50 mm, preferably about 5 mm to about 30 mm, and more preferably from about 15 mm to about 25 mm. While these dimensions are provided for paints and other liquid films that are used as commercial coatings, it is within the scope of the present invention to modify the trough dimensions so that the liquid film or coating being tested mimics a liquid film or coating as it is typically used.  
         [0050]     The probe may be any mechanical device that is capable of contacting the liquid film and detecting the change in resistance as the probe is moved in the liquid film as the film solidifies. Preferably, the probe has sufficient surface area contacting the liquid film, so that it can detect the resistance, but be small enough so that the probe does not interfere with the solidification of the liquid film. It is also within the scope of the present invention to reinforce the cross-bar (horizontal bar) of the T-bar structure. For example, a preferred embodiment of the probe is a T-bar, as shown in  FIG. 1  (T-bar  20 ). Other examples of suitable probes may be any rod, paddle, knife edge, or the like, that can be contacted or submerged into the liquid film.  
         [0051]     Typically, the T-bar probe  20  of the present invention comprises a horizontal cross-bar that is contacted or submerged in the liquid film to be tested and a vertical member affixed to a horizontal disc that is used for mounting the T-bar probe structure onto the rheometer. In another aspect of the invention the probe is a reinforced T-bar probe that comprises at least one horizontal cross-bar that is contacted or submerged in the liquid film and at least one horizontal support bar that is affixed to a horizontal mounting disc which is used to attach the probe to the rheometer and at least one vertical reinforcement member that is used to attach the horizontal cross-bar to horizontal support bar on the mounting disc. The horizontal cross-bar is further secured to the horizontal support bar with at least one vertical support arm. The vertical support members may be arranged parallel to the vertical support arms or they may be arranged in a slanted configuration. Less wicking of the liquid film may be observed in a generally slanted configuration. The angle or degree of slanting can vary based on the probe dimensions and/or based the liquid medium to be tested.  
         [0052]     For paint applications, a preferred T-bar has a diameter in the range from about 0.01 mm to about 2 mm, preferably from about 0.025 to about 0.3 mm and more preferably from about 0.05 to 0.1 mm. The length of the T-bar ranges from about 2 mm to about 50 mm, preferably about 5 to about 20 mm, and more preferably from about 10 to about 15 mm. The cross-section of T-bar wire can vary and is not limited to a circular cross-section. The T-bar should have enough rigidity not to be effected by the dynamic properties of the liquid film, such as high carbon steel, stainless steel, tungsten carbide and the like. While these dimensions are provided for the present invention, specifically the use of a rheometer and the monitoring of solidification properties of paints and other coatings, it is within the scope of the present invention to modify the probe dimensions to suit the liquid film to be tested.  
         [0053]     The dimensions of the reinforced T-bar probe may vary over a wide range depending on the liquid medium tested. The cross-section of the probe can also vary and is not limited to a circular cross-section and it may in fact have a rectangular cross-section. For example, in paint applications, if the horizontal cross-bar of the probe has a circular cross-section then the diameter is in the range from about 0.01 mm to about 2 mm, or from about 0.025 mm to about 0.3 mm, or from about 0.05 mm to 0.1 mm. For non-circular embodiments, the width of the horizontal cross-bar is typically from about 0.125 mm to about 0.2 mm. The length of the horizontal cross-bar of the probe ranges from about 2 mm to about 50 mm, from about 5 mm to about 20 mm, or from about 10 mm to about 15 mm. The thickness is of the horizontal cross-bar of the probe ranges from about 0.02 mm to about 0.3 mm.  
         [0054]     The solidification of a liquid film is sensitive to the thickness of the liquid film. In a preferred embodiment the thickness of the film is uniform in the portion of the film being measured. Therefore, precise control of the liquid film thickness is preferred. The film thickness may be varied by the depth of the trough. In a preferred embodiment the film is deposited, such as by pouring, injecting or pipetting, into the trough and the top surface of the trough is leveled to provide a consistent film thickness. The liquid film may be leveled by any means, such as by drawing a flat edge (e.g., glass slide edge) across the top of the trough to smooth and substantially level surface of the liquid film or injecting a precise amount of liquid to spread out by itself. A probe is then contacted with the liquid film. In a preferred embodiment one end of the probe is submerged into the liquid film to a point just above the bottom of the trough. The probe should not contact the bottom of the trough. The gap between the bottom of the trough (substrate) and the bottom portion of the probe will depend on variables such as, the type and size of the probe and the depth of the liquid film being monitored and the shape of the trough. The typical gap between the bottom of the trough (the substrate) and the bottom part of the probe (shown in  FIG. 1  as a T-bar  20 ) is in the range of about 0.01 mm to about 0.1 mm depending on the thickness of the probe (T-bar  20 ), size and depth of the trough and the liquid film thickness. With the reinforced T-bar probe embodiments of the invention (shown in  FIGS. 1   a ,  1   b  and  1   c ) the gap between the bottom of the trough and the bottom of the probe is also in the range of about 0.01 mm to about 0.1 mm; for example, the gap is about 0.05 mm.  
         [0055]     The solidification rate of a liquid film may be sensitive to the liquid film thickness, humidity, temperature and air flow rate. Therefore, in a preferred embodiment a controlled environmental chamber is desirable to provide constant humidity, temperature and gas flow rate to the liquid film.  
         [0056]     The probe may be mounted on any suitable means. In a preferred embodiment, the probe is mounted on a rheometer that also comprises a means of either moving the probe relative to the substrate or moving the substrate relative to the probe and a monitoring means, such as a transducer. The probe may be moved in any manner that will provide resistance that can be measured. In a preferred embodiment the probe is moved in an oscillating manner relative to the substrate to measure the resistance of the liquid film and the phase angle between input and output signals as the film dries. Any means may be used to accomplish this movement, such as a motor or other mechanical means. The resistance detected by the probe can be measured by any suitable means including a transducer or other electronic sensor. From the resistance and the phase angle, the relative viscosity and elasticity of the liquid film can be determined and plotted over the time the film solidifies.  
         [0057]     Referring now to  FIG. 1 , the solidification properties of a solidifiable liquid may be measured using apparatus  10  which comprises a T-bar mount  12  and a transducer  24  which measures the rheological properties of the liquid film  14 . The liquid film  14  is supported by substrate  16  having a trough  18 . The shape and dimensions of the trough  18  can vary and are not limited to a circular shape. A T-bar  20 , functioning as a probe, is mounted to the rheometer and is partially submerged in the liquid film  14 . The T-bar may penetrate the liquid film  14 , so long as the T-bar does not contact the substrate  16 . A motor  22  provides movement between the T-bar  20  and the substrate  16  and a transducer  24  measures the resistance to the movement of the probe to the liquid film as the film solidifies. The position of the probe  20  in the liquid film may be adjusted by changing the position of the transducer  24  head to which the probe is connected.  
         [0058]     With the reinforced T-bar probe  120 , as illustrated in  FIG. 1   a , there is a horizontal cross-bar  132  that is submerged in the liquid film to be tested and a mounting disc  134  that is used to attach the probe  120  to the rheometer. Affixed to the mounting disc  134  is a horizontal support arm  135 . The horizontal cross-bar  132  is attached to the horizontal support arm  135  with two vertical reinforcement members  136 . In this embodiment of the invention, there are three vertical support arms  138  arranged in between the vertical reinforcement members  136 . The vertical reinforcement members  136  and the vertical support arms  138  can be arranged parallel to each other generally creating a square or rectangular shape as shown in  FIG. 1   a . However, the vertical reinforcement members can be arranged in a slanted configuration see for example  FIGS. 1   b  and  1   c.    
         [0059]      FIG. 1   b  shows another embodiment of a reinforced T-bar probe  220  of the present invention. In this embodiment, the horizontal cross-bar  232  is attached to the mounting disc  234  with two vertical reinforcement members  236  which are arranged in a slanted configuration. This embodiment also includes one vertical support arm  238  that is arranged in between the vertical reinforcement members  236 . The vertical reinforcement members  236  and the vertical support arms  238  are attached to horizontal support bar  235  that is affixed to the mounting disc  234 .  
         [0060]      FIG. 1   c  shows another embodiment of a reinforced T-bar probe  320  with a slanted configuration. In this embodiment of the present invention there are multiple vertical support arms. The horizontal cross-bar  332  is attached to the mounting disc  334  with two vertical reinforcement members  336 . This embodiment also includes three vertical support arms  338  that are arranged in between the vertical reinforcement members  336 . The vertical reinforcement members  336  and the vertical support arms  338  are attached to horizontal support bar  335  that is attached to the mounting disc  334  which is used to attach the probe to the rheometer.  
         [0061]      FIG. 2  provides a top view of the T-bar  20  contacting the liquid film  14  in trough  18 . The means for effective relative movement between the probe and the substrate is preferably in an oscillating manner with minimal disturbance to the liquid film as it solidifies. In a preferred embodiment, the trough has sufficient distance between the T-bar and the edges of the trough so that any premature drying that may occur at the edges does not touch the oscillating T-bar.  
         [0062]     This invention can be further illustrated by the following examples of preferred embodiments thereof, although it will be understood that these examples are included merely for purposes of illustration and are not intended to limit the scope of the invention unless otherwise specifically indicated.  
       EXAMPLES  
       [0063]     In the following examples, the drying rate was measured either with the nitrogen gas flow over the coated plate in a closed chamber or in open air at ambient temperature between 24-26° C.  
       Example 1  
       [0064]     A 0.1 mm deep and 23 mm diameter circular trough was filled with approximately 0.1 ml of a coating formulation (a metallic basecoat containing carboxymethyl cellulose acetate butyrate, a cellulose ester available from Eastman Chemical Company in Kingsport, Tenn., under the tradename CMCAB) using a syringe. The trough was immediately scrapped to form a uniform surface by using the edge of a glass slide, and the T-bar probe (0.28 mm×15 mm, diameter×length) lowered to 0.05 mm gap and then the dynamic mechanical analyzer (ARES® available from TA Instruments in New Castle, Del.) was run at 100% strain and 25 rad/sec frequency. Changes in viscoelastic properties; Eta* (complex viscosity), G′(elastic modulus) and G″ (viscous modulus) with time are illustrated in  FIG. 3 . The torque on the probe is small, especially during the early stage of the drying. To detect such a low torque, a high sensitivity transducer (e.g. 100 FRT on ARES from TA Instruments) should be used. The test should be stopped before the viscosity becomes too high to avoid damaging the probe  
       Example 2  
       [0065]     A 0.2 mm deep and 23 mm diameter circular trough was injected with 0.1 ml of an acrylic latex dispersion using a syringe. The solution was spread evenly within the trough by using the edge of a glass slide or a stainless steel spatula. The T-bar probe (0.28 mm×15 mm, diameter×length) was lowered to 0.05 mm gap and the oven door which closes the trough and the T-bar was closed. The dynamic mechanical analyzer (ARES® from TA Instrument) was then started without purge gas. The dynamic test was conducted with 100% strain and 25 rad/sec frequency at ambient temperature. The complex viscosity and the moduli (elastic and viscous) are plotted in  FIG. 4 .  
       Example 3  
       [0066]     The same test described in Example 2 was conducted with a nitrogen purge with 4 standard cubic feet per hour flow rate in the closed oven. The complex viscosity is plotted together with the result from example 2 in  FIG. 5 .  
       Example 4  
       [0067]     A 0.1 mm deep and 23 mm diameter circular trough was filled with 0.05 ml of a clear CAB lacquer solution having the following formulation: cellulose acetate butyrate a base coat available from Eastman Chemical Company, Kingsport, Tenn. under the tradename CAB 381-0.5 in 10 weight percent, acrylic resin available from Rohm and Haas, Philadelphia, Pa., under the tradename Parloid B-66 in 7.7 weight percent, a plasticizer available from Solutia, Inc. in Saint Louis, Mo., under the tradename Santicizer 160 (Plasticizer) in 2 weight percent, methyl ethyl ketone 7.5 weight percent, n-butyl alcohol 11 weight percent, toluene 16 weight percent, methyl amyl ketone (MAK) in 9 weight percent, Tecsol C available from Eastman Chemical Company in 12.5 weight percent, and n-butyl acetate 23.5 weight percent. The solution was evenly spread by using the edge of a glass slide, which results in a layer approximately 120 μm thick. The T-bar probe (0.28 mm×15 mm, diameter×length) was lowered to 0.05 mm gap, and then the dynamic mechanical analyzer (ARES® from TA Instrument) started at 100% strain and 25 rad/sec frequency. The same sample was tested on a 0.2 mm deep trough with 0.1 ml of solution which was equivalent to a wet film approximately 240 μm thick. The results are plotted in  FIG. 6 .  
       Example 5  
       [0068]     A 0.2 mm deep and 23 mm diameter circular trough was filled with 0.1 ml of a metallic basecoat based on cellulose acetate butyrate (CAB 381-2 from Eastman Chemical Company) having the following formulation: CAB 381-2 5.33 weight percent, polyester resin (Duramac 5776 from Eastman Chemical Company) 6.79 weight percent, polyester resin with thixotropic properties (Duroftal PE9125SCA/50SNAX from UCB Company) 2.72 weight percent, melamine (Resimine HF480 from UCB company) 0.36 weight percent, wax dispersion (VP715A from Lubra Print) 0.57 weight percent, aluminum flake 3.23 weight percent and solvent 81%. The solvent is composed of n-butyl acetate contained in CAB 381-2 solution, n-butyl propionate contained in the metallic flake solution, PMA (propylene glycol monomethyl ether acetate) contained in Duramac 5776 and unknown solvent contained in Duroftal PE9125SCA/50SNAX. The metallic basecoat was evenly spread by using the edge of a glass slide. The T-bar probe (0.28 mm×15 mm, diameter×length) is lowered to 0.05 mm above the bottom of the substrate, the oven door was closed and then the dynamic mechanical analyzer (ARES® from TA Instrument) was run at 100% strain and 1 rad/sec frequency. The test was conducted with a nitrogen purge with 4 standard cubic feet per hour flow rate in the closed oven. The same solution sample was tested on a 0.1 mm deep trough. The viscosity changes as a function of drying time are plotted in  FIG. 7 , and the corresponding changes in elastic modulus (G′) and viscous modulus (G″) are plotted in  FIG. 8  for 0.2 mm trough and  FIG. 9  for 0.1 mm trough.  
       Example 6  
       [0069]     A 0.2 mm deep and 23 mm diameter circular trough was filled with 10 drops of a CAB refinish basecoat formulation using a 1-ml disposable Samco® transfer pipette (Samco Scientific Corporation, San Fernando, Calif.). The formulation contains polyester resin (78% total solution) in 3.9 percent, acrylic resin (40% total solution) in 21.8 percent, melamine in 0.7 percent, flow aid in 0.7 percent, silicone additive (10% total solution) in 0.3%, wax additive (5% total solution) in 7.3%, aluminum flake dispersion (35% total solution) in 9.1 percent, cellulose acetate butyrate (CAB 381 from Eastman Chemical Company, Kingsport, Tenn. in 10% total solution) in 32.5 percent and solvent blend in 23.7 percent. The solvent blend is composed of a 20/30/10/20/20 mixture of methyl isobutyl ketone, methyl amyl ketone, toluene, isobutyl alcohol, and acetone. The solution was spread evenly within the trough by using the edge of a glass slide. A T-bar probe with rectangular cross-section (0.15 mm×0.23×15 mm, height×width×length) was lowered to 0.05 mm gap. The dynamic test was conducted on a stress-controlled rheometer (AR 2000® from TA Instruments, New Castle, Del.) with 100% strain and 25 rad/sec frequency at ambient temperature. The complex viscosity and the moduli are plotted in  FIG. 10 .  
       Example 7  
       [0070]     A 0.2 mm deep and 24 mm diameter circular trough mounted on the Peltier heating surface of the rheometer (AR 2000® from TA Instruments, New Castle, Del.) was filled with 10 drops of a hairspray formulation using a 1-ml disposable Samco® transfer pipette (Samco Scientific Corporation, San Fernando, Calif.). The formulation contains an acrylates copolymer (from National Starch and Chemical Company, Bridgewater, N.J.) in 7.7 wt % (without propellant) in ethanol/water aerosol having 55% VOC (volatile organic compound). The solution was spread evenly within the trough and the excess material was removed with the edge of a glass slide. A reinforced T-bar probe (as illustrated in  FIG. 1   c ) having a square cross-section (0.15 mm×0.15 mm×15 mm, thickness×width×length) was lowered to into the trough so that a 0.05 mm gap was formed. The dynamic test was conducted on the stress-controlled rheometer with 100% strain and 25 rad/sec frequency at ambient temperature. The complex viscosity in a unit of Poise was converted to a real viscosity by using a predetermined calibration factor. The unitless tan (delta) is the ratio of G″ to G′. The change in complex viscosity (Eta*) and tan (delta) is illustrated in  FIG. 11 .  
       Example 8  
       [0071]     A reinforced T-bar probe and a circular trough were used in these studies. The temperature of the circular trough as described in Example 7 was preset at 15° C., 25° C. and 35° C. The trough was filled with 10 drops of an OEM automotive metallic basecoat using a 1-ml disposable Samco® transfer pipette (Samco Scientific Corporation, San Fernando, Calif.). The basecoat formulation is a polyester-melamine cross-linked system containing a cellulose acetate butyrate (CAB 381-20 from Eastman Chemical Company), wax dispersion, aluminum flakes and n-butyl acetate as solvent. The solution was spread evenly within the trough and the excess material was removed with a knife edge (Precision Gage &amp; Tool Co, Dayton Ohio). The same dynamic test as in Example 7 was conducted at three different substrate temperatures. The complex viscosity (Eta*) in an arbitrary unit is illustrated in  FIG. 12 .  
       Example 9  
       [0072]     Example 9 was conducted using the reinforced T-bar under the same testing conditions and using same materials as described in Example 8; however, the tests were conducted with the reinforced T-bar set a two different gap levels (0.05 mm and 0.1 mm) and the trough temperature was set at 25° C. The changes in tan (delta), which represents the ratio of G″ to G′, for the two gap levels are illustrated in  FIG. 13 . The changes in tan (delta) measured at two different probe positions may reflect that the viscoelastic properties of the thin film are different at different locations of the film as it dries.