Radiation-Curable Coatings. Project Summary


 United States
 Environmental Protection
 Agency
Air and Energy Engineering
Research Laboratory
Research Triangle Park NC 27711
 Research and Development
EPA/600/S2-91/035 Sept. 1991
 Project Summary
 Radiation-Curable  Coatings
 S.A. Walata, III, and C.R. Newman
   This report evaluates radiation-cur-
 able coatings as a technology for re-
 ducing volatile organic compound (VOC)
 emissions from surface coating opera-
 tions. A survey of the literature  was
 conducted to assess the state of the
 technology and emissions from radia-
 tion-curable processes. The information
 collected from the literature was used
 to evaluate the engineering  and eco-
 nomic issues associated with radiation-
 curable systems and to identify the
 requirements for implementing the tech-
 nology and any problems arising from
 its use.
   Topics discussed in the report in-
 clude coating characteristics, potential
 VOC  reduction  capability,  potential
 health problems associated with the use
 of ultraviolet (UV) coatings, and the eco-
 nomic impacts of conversion to UV coat-
 ings. The report provides Information
 to permit an informed Judgement  on
 when and how to apply radiation-cur-
 able technologies for industrial applica-
 tion.
   This Project Summary was devel-
 oped by EPA's Air and Energy Engi-
 neering Research Laboratory, Research
 Triangle Park, NC, to announce key find-
 ings of the research project that Is fully
 documented In a separate report of the
 same title (see Project Report ordering
 Information at back).


Summary
  This report presents the results of an
evaluation of radiation-curable coatings as
a technology for reducing volatile organic
 compound (VOC) emissions from surface
 coating operations. A survey of the litera-
 ture was conducted to assess the state of
 the technology and emissions from radia-
 tion-curable processes. The data collected
 in the literature survey were used to evalu-
 ate  the engineering  and economic con-
 cerns  associated with  radiation-curable
 systems and to identify technical prob-
 lems.
   Radiation-curable coatings and inks are
 higher solids formulations than  conven-
 tional coatings and, consequently from an
 air pollution viewpoint, are considered to
 be well suited substitutes for solvent-based
 thermal-curable systems. The radiation
 source for these systems is either an ultra-
 violet (UV) light or an accelerated electron
 beam (EB). A radiation-cured surface coat-
 ing or printing process emits reduced lev-
 els of  VOC emissions  in comparison to
 solvent-based, thermal-curable processes
 due  to the solventless nature of most ra-
 diation-curable systems. Radiation-curable
 systems also require less energy to achieve
 a cured film and operate at lower tempera-
 tures than thermal-curable systems. This
 allows radiation-curable systems to be used
 on temperature sensitive substrates where
 they can save 75-90% in energy costs.
 The curing equipment for radiation-curable
 compounds typically require 50-75% less
 floor space than thermal-curing ovens.
 Higher production rates than thermal-cur-
 able  systems are potentially achievable
 due to the  rapid curing rates of radiation-
 curable systems. Four types of polymeriz-
 able  systems commonly  used   for
 radiation-curable applications are unsatur-
 ated  polyester resins, multifunctional acry-
                                                     Printed on Recycled Paper

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lates, thiol-polyene systems, and cationic
polymerized epoxides. The photoinrtiators
required for UV-curable systems form the
initiating radical by photocleavage,  hydro-
gen abstraction, or cationic photoinitiation.
   Radiation-curable systems have  sev-
eral characteristics which may limit imme-
diate applications in some  commercial
environments. Atmospheric oxygen has a
retarding effect on the curing rate of free
radical polymerization processes  due to
molecular oxygen's affinity for  free  radi-
cals. The presence of air in the radiation-
curable process can result in coatings with
tacky surfaces. Practical solutions to oxy-
gen  interference will differ between UV-
and EB-curing systems due to the inherent
differences in the way the two forms of
energy interact with the coating material.
UV energy tends to be strongly absorbed
at the surface of the coating. This gener-
ates  a higher proportion of free radicals at
the surface in relation  to  the rest  of the
coating. With proper formulation, UV-cur-
ing can be conducted  in  ambient  condi-
tions. The fairly uniform distribution of en-
ergy for EB-curable systems requires the
cure zone to be  kept  free of  oxygen by
blanketing with an inert gas. Due to the
higher solids content, radiation-curable for-
mulations have a higher viscosity than ther-
mal-curable systems. The high viscosity of
radiation-curable systems may restrict po-
tential application methods. The viscosity
problem  can be  minimized by adding a
reactive diluent or heat or by thinning with
an organic solvent. In addition, some early
radiation-curable systems were considered
toxic. Current materials, however,  have
been classified as only slightly toxic. Aery-
late materials used in radiation-curable sys-
tems are considered skin and eye irritants.
The  severity of the irritation depends on
the material being used.
   Cost per volume of coating formulation
has  been used traditionally to determine
whether radiation-curable systems are ac-
ceptable alternatives to conventional ther-
mal-curable systems. The cost differential
on this unit basis between radiation- and
thermal-curable systems is relatively large
in favor of thermal-curable systems. The
higher unit cost of radiation-curable sys-
tems results in the user's perception that
radiation-curable systems are not economi-
cally attractive alternative printing or coat-
ing processes. However, comparing the
costs of the two systems  on the basis of
cost per unit area of substrate coverage
better indicates the true cost of the coating
or printing process. Limited available data
on cost per area coated indicate the cost
differential to be in favor of radiation-cur-
able systems.
   Available data indicate that some mono-
mer emissions could be  present  in the
exhaust for processes using radiation-cur-
able systems. Additional  investigation  to
determine the quantity and composition of
emissions resulting from the use of radia-
tion-curable coatings and inks would de-
termine the extent of any problems. All
other potential  problems might  be ad-
dressed by good engineering and operat-
ing practices of the installed system.
  S. Walata and C. Newman are with Alliance Technologies Corp., Chapel Hill, NC 27514.
  Charles H. Darvln is the EPA Project Officer, (see below).
  The complete report, entitled "Radiation-Curable Coatings' (Order No. PB91-219550/
    AS; Cost: $15.00, subject to change)  will be available only from:
          National Technical Information Seivice
          5285 Port Royal Road
          Springfield, VA 22161
          Telephone: 703-487-4650
  The EPA Project Officer can be contacted at:
          Air and Energy Engineering Research Laboratory
          U.S. Environmental Protection Agency
          Research Triangle Park, NC 27711
  United States
  Environmental Protection
  Agency
         Center for Environmental Research
         Information
         Cincinnati, OH 45268
                  BULK RATE
            POSTAGE & FEES PAID
             EPA PERMIT NO. G-35
  Official Business
  Penalty for Private Use $300
  EPA/600/S2-91/035

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