Radiant energy – Photocells; circuits and apparatus – With circuit for evaluating a web – strand – strip – or sheet
Reexamination Certificate
1998-11-20
2001-02-20
Ham, Seungsook (Department: 2878)
Radiant energy
Photocells; circuits and apparatus
With circuit for evaluating a web, strand, strip, or sheet
C356S446000, C356S429000
Reexamination Certificate
active
06191430
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to monitoring of coatings applied to webs or sheets. More particularly, this invention relates to a method of monitoring the drying speed of these coatings.
2. Description of the Prior Art
Application of coatings to sheets or webs of material is a common process in a number of different industries. Particularly in the paper industry, coatings, containing components such as clay, latex, or CaCO
3
, are used to affect the absorption, stability, gloss, printability or other characteristics of the underlying web or sheet. In other industries, such as plastic, the coating may be the most important part of the product (i.e. photographic coating).
In an on-line setting, coatings are typically applied using numerous types of coating devices (i.e. coaters). Typically, these devices hold the coating in liquid form, suspended in a solvent, such as water, to ease application and improve bonding to the base sheet. A blade or knife is used to spread the coating along the base sheet as it moves past the coating device. The coating device is followed by one or more drying devices (i.e. dryers) which evaporate the solvent out of the coating, using heat and/or moving air, leaving a sold or semisolid coating layer behind on the base sheet.
The speed at which the coating dries can be a critical factor in coating quality and the quality of the final sheet product, as well as a factor in mill or plant efficiency, and the amount energy used during the coating application process. Factors which effect coating drying speed include the mill environment, coater settings, dryer settings, base sheet properties, as well as the quantity and type of components in the coating. Further, the type and amount of solvent—which evaporates and/or is absorbed by the base sheet upon drying of the coating—also effects the drying time of the coating.
As the reader is likely aware, the quality of applied coatings is important for a number of reasons. Visible variations in quality and uniformity of a coated sheet are clearly something which should be avoided. Further, non-visible variations can be critical where an applied coating is to be used as the base for further processing, such as printing. Lastly, a coating may provide mechanical durability and protection against environmental factors such as moisture, heat or sunlight.
The speed at which a coating dries effects coating quality and final sheet quality in a number of ways. When the sheet is wet, the heat in the dryers is absorbed by the coating as the coating solvent proceeds through a state change from a liquid to a vapor. Once the coating or coating surface is dry (i.e. most of the coating solvent has evaporated) however, the excess heat is no longer absorbed by the coating solvent. Rather, it is absorbed by the base material and coating, which may burn or crack easily in their dry state. If, on the other hand, the coating dries too slowly, the coating may be smeared or stick to manufacturing line components, or other sections of the sheet (i.e. if the sheet is rolled while the coating is still wet). Thus, monitoring drying speed can be used to improve overall coating and final product quality, as well as prevent product waste.
Monitoring coating drying speed has another advantage as well. It can reduce the amount of wasted energy and increase dryer lifetime by allowing unneeded drying devices to be turned off or selected drying devices to be set at lower temperature settings, when the coating dries prior to the end of a section of coating dryers. Turning off unneeded dryers in fact, is one method of preventing the sheet from being burned or otherwise damaged due to the excessive heat in the dryers.
Currently, temperature sensors are used to monitor when a coating is dry in many sheet mills and plants. Typically, the temperature sensors are located in or near the dryers following the coater, and register an increase in sheet temperature when the coating is dry. Due to the harsh temperature in these drying environments, thermocouples or other rugged temperature devices are preferred to measure temperature within the dryers. Unfortunately, thermocouples are a relatively slow temperature-measuring device compared with the speed at which the sheet is moving past the dryers. Using temperature to monitor the drying speed of the coatings is also disadvantageous because once the temperature sensors register the increase in sheet temperature, damage to the sheet may have already occurred due to over-drying.
While remotely-located IR temperature sensors have also been used, these types of sensors are not very accurate, and their readings depend on surface emmisivity, which changes during drying.
Ideally, monitoring of drying speed would be accomplished by monitoring the location of one or more “gel points” of the coating. The gel point defines the time at which particular coating components form semisolid networks of solid aggregates, as the coating solvent evaporates from the applied coating layer. When most or all the primary coating components have reached this gel point, the coating is effectively considered to be dry.
Currently, no device exists to monitor the gel point of coatings on sheets or webs of material.
SUMMARY OF THE INVENTION
The present invention addresses the need for a means and apparatus to monitor the drying speed of coatings on a web or sheet of material, utilizing a coating's gel point. In the Applicant's system, a sensor is used to compare specular and diffused radiation reflected from the coating. In a particularly preferred embodiment, the specular and diffused radiation are used in ratio to locate the gel point.
In an on-line system, with the gel point known, coating drying speed can be increased or decreased, coating composition may be altered, or coating or drying device settings may be changed to suit the designer's needs. The designer's choice of actions may be based on such factors such as coating or final product quality or uniformity, or mill efficiency.
In an off-line system, the gel point may be used to compare the drying time of different coating formulations or base materials, develop drying or coating device configurations, or troubleshoot coating problems.
A system implementing the Applicant's method may be achieved by directing a beam of radiation from a radiation source at a measurement location on the coating, and providing a first and second radiation detectors which examine the coating at the measurement location. One of the radiation detectors is situated to collect specular radiation, while the other radiation detector is situated to collect only diffused radiation. The ratio of these two values is used to determine the location of the gel point relative to the measurement location, or in an off-line system, to produce characterization curves of the ratio of these two values for a monitored drying coating.
One object of the invention is to provide a non-contacting method for monitoring the drying speed, gel point and drying characteristics of a coating.
A further object of the invention is to provide a simple, compact, coating condition-measuring sensor with improved accuracy and speed.
An even further object of the invention is to provide a multi-sheet characteristic measurement system which includes measurement of coating gel point.
A further object of the present invention is to provide a system for the lab investigation (i.e. off-line) of different types of coatings, their drying speeds, and drying characteristics.
Further advantages of the Applicant's system will become apparent upon reading of the detailed description to follow.
REFERENCES:
patent: 4945253 (1990-07-01), Frohardt
patent: 5640244 (1997-06-01), Hellstrom et al.
Belotserkovsky Edward
Dahlquist John A.
Ebert Anthony E.
Ham Seungsook
Honeywell International
Pyo Kevin
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