Standard Operating Procedure for the Preparation of Lead-Containing Paint Films and Lead-in-Paint Diagnostic Test Materials


&EPA
United States
Environmental Protection
Agency
EPA600/R-10/070 August 2009 www.epa.gov/ord
T~ \ 1
Office of
Research and Development
National Exposure
Research Laboratory

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EPA/600/R-10/070 August 2009 www.epa.gov/ord
Standard Operating Procedure for the
Preparation of Lead-Containing Paint Films and
Lead-in-Paint Diagnostic Test Materials
Prepared by
Kristen Sorrell, David Binstock, Curtis Haas,
Cynthia Salmons, and William Gutknecht
Environmental and Industrial Sciences Division
RTI International
Research Triangle Park, NC 27709

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Disclaimer
The information in this document has been funded wholly or in part by the U. S. Environmental Protection
Agency (EPA) under EPA Contract No. EP-D-05-065 to Alion Science and Technology, Inc., and RTI
Subcontract No. SUB1174861RB. It has been subjected to the Agency's peer and administrative review.
Mention of trade names or commercial products does not constitute endorsement or recommendation for
use.

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Acknowledgments
This document was prepared under the direction of the Work Assignment Contracting Officer's
Representative, Ms. Sharon L. Harper, National Environmental Research Laboratory, U.S. Environmental
Protection Agency, Research Triangle Park, NC.
Special acknowledgment is given to Dr. Hunter Daughtrey, Alion Science and Technology, Inc., for his
support of this effort and careful review of this document.

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Table of Contents
List of Figures	vii
List of Appendixes	vii
1.0 PRINCIPLE AND APPLICABILITY	1
2.0 SUMMARY OF THE METHOD	1
2.1	Stand-Alone Paint Films	1
2.1.1	Preparation	1
2.1.2	Performance	2
2.2	Method Diagnostic Test Materials	2
2.2.1	Preparation	2
2.2.2	Performance	2
3.0 DEFINITIONS, ACRONYMS, AND ABBREVIATIONS	2
4.0 HEALTH AND SAFETY WARNINGS	3
4.1	Safety with Paint Ingredients, Including Powdered Lead Compounds and Solvents	3
4.2	Safety with Ball Mill	3
4.3	Proper Disposal of Waste	3
5.0 EQUIPMENT, SUPPLIES, AND REAGENTS	3
5.1	Paint Mixing	3
5.1.1	Paint Ingredients	3
5.1.2	Equipment and Supplies for Mixing Paint Ingredients	4
5.1.3	Equipment and Supplies for Casting Paint Films	4
5.1.4	Supplies and Equipment for Preparing Test Kit Diagnostic Materials	4
5.2	Cleanup	5
5.3	Safety Equipment	6
6.0 QUALITY CONTROL AND QUALITY ASSURANCE	6
7.0 PROCEDURE FOR PREPARATION OF STAND-ALONE PAINT FILM	6
7.1	Selection of Components	6
7.2	Mixing Paint Ingredients in Ball Mill	8
7.3	Varying Recipes	9
7.4	Casting Paint into Films	9
7.5	Retrieval of Paint Film from Release Paper	10
7.6	Testing for Variability of Film Thickness	10
7.7	Cleaning	11
7.7.1	Ball Mill Jar and Grinding Media	11
7.7.2	Drawdown Rod and Drawdown Machine	11
8.0 PROCEDURE FOR PREPARATION OF LEAD METHOD DIAGNOSTIC
TEST MATERIALS	12
8.1	Selection of Components	12
8.1.1	Selection of Substrates	12
8.1.2	Selection of Leaded Paint Films	13
8.2	Cutting Paint Films into Desired Dimensions	13
8.3	Assembly of Test Pieces	13
8.4	Example of Preparation of Test Piece	17
9.0 DATA PROCESSING	18
9.1	Variability in Paint Film Thickness	18
9.2	Variability in Lead Concentration in Prepared Paint Films	18
9.3	Variability in Lead Concentration in Method Diagnostic Test Materials	18
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Table of Contents (cont'd.)
10.0 DATA AND RECORDS MANAGEMENT	18
11.0 WASTE MANAGEMENT	18
11.1	Mineral Spirits	18
11.2	Leaded Paint	18
12.0 REFERENCES	19
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List of Figures
Figure 1. Ball mill being covered with safety shield to prevent injury from rollers	3
Figure 2. Plot of paint film Pb concentrations versus Pb concentration in "wet" paint mixture	7
Figure 3. Ball mill jar with grinding media along with principal ingredients of paint	8
Figure 4. Using the wire-wound drawdown bar to cast a lead chromate paint film on release paper.. 10
Figure 5. Marked paint film being measured for thickness	11
Figure 6. Photograph of metal, wood, plaster, and masonry substrate materials ready for
preparation of diagnostic test materials	12
Figure 7. Paint film cutting apparatus and process	14
Figure 8. Placing leaded paint film on wood substrate coated with primer to serve as adhesive	14
Figure 9. Smoothing out paint film after allowing time for the primer to partially dry	15
Figure 10. Applying overcoat	16
Figure 11. Photographs of overcoated leaded paint films on wood, metal, masonry, and plaster
substrate pieces, along with bare substrate pieces	16
List of Appendixes
Appendix 1. Results of Analysis of Multiple Samples Taken from Cast Paint Films Needed
To Prepare All Planned Types of Coupons	A-1
Appendix 2. Summary of Results of Analysis of Each Type of Coupon Prepared	A-2
Appendix 3. 2008 EPA/ORD Specification Sheet	A-5
Appendix 4. Summary of Recipes Used To Make Paint Films for Preparation of 31 Types of
Diagnostic Test Kit Materials	A-8
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1.0 PRINCIPLE AND APPLICABILITY
Exposure to lead (Pb) may adversely impact children's brains, nervous systems, and many organs. An
estimated 310,000 U.S. children ages 1 to 5 have elevated blood leads. In the United States, the major
exposure pathway for children to Pb is from deteriorated Pb-based paint (LBP), Pb-contaminated house
dust, and residential soil. Approximately 40% of all U.S. housing units (about 38 million homes) have
some LBP.1 The Federal regulated Pb standard has been defined by the U.S. Department of Housing and
Urban Development (Title X of the Housing and Community Development Act, 19922) as equal to or
greater than 0.5% Pb by weight or 1.0 mg Pb/cm2. Homes built before 1978 are the most likely to contain
LBP. Each year, more than 10 million renovation activities occur in homes, child-care facilities and
schools potentially containing LBP. To reduce the exposures to Pb hazards during renovation, the U.S.
Environmental Protection Agency (EPA) promulgated the "Lead: Renovation, Repair, and Painting
Program; Final Rule" (RRP) in April 2008. The rule requires the use of inexpensive test kits. However, no
currently available commercial test kit can meet the performance requirements of no more than 5% false
negative results at levels greater than the Federal regulated level and no more than 10% false positive
results at levels less than the Federal regulated level.3 Additional goals for the test kit procedures are that
they should be inexpensive, take less than an hour per sample, and be easy to perform.
The simple, commercially produced test kits currently available for home testing for Pb in paint are very
sensitive but do not provide quantification of Pb to meet the specifications in the RRP. As noted in
Gutknecht et al., there are several field techniques already available for direct (in situ) quantitative
analysis of Pb in painted surfaces, including field-portable, X-ray fluorescence and portable laser
microprobe spectrometry.4 The instrumentation for these methods is relatively expensive and requires
extensive training. Additionally, there are numerous less expensive field methods available for
quantitatively measuring Pb in solution. These include electrochemical reduction/oxidation (anodic
stripping voltammetry), complexation (colorimetry), precipitation (gravimetry), orturbidimetry. However, to
apply these methods, paint first must be removed quantitatively from the surface and Pb quantitatively
solubilized from the paint. Grinding may be needed to facilitate solubilization.
There is a need for Pb-in-paint testing materials that will challenge current and new paint sampling
methods, Pb extraction methods, and Pb measurement methods. This standard operation procedure
(SOP) describes procedures for making challenging stand-alone, leaded paint films, as well as Pb-in-
paint diagnostic materials that simulate old paints on a variety of substrates. Users of this SOP should
evaluate the durability of the paint materials produced under their specific conditions of use. This is a
general use SOP and is intended to be used by trained technical workers.
2.0 SUMMARY OF THE METHOD
This SOP describes the preparation of stand-alone, leaded paint films prepared according to old paint
recipes. Further, this SOP describes the use of these paint films for the preparation of simulated old
paints on a variety of substrates. Substrates used included wood, steel, masonry, and plaster. The leaded
paint varied in pigment, color, and the presence of ions that have a potential for interfering with the Pb
measurement performed with different methods, including various types of test kits.
2.1 Stand-Alone Paint Films
2.1.1 Preparation
The process of making stand-alone paint films starts with mixing the ingredients of the material,
which for old, white paint recipes, consists of white Pb, zinc oxide, raw linseed oil, boiled linseed
oil, and mineral spirits. The recipe may be varied by using a different Pb pigment, for example,
lead chromate (yellow in color), a colorant such as red or black iron oxide, and metals that have
the potential for interfering with Pb measurement techniques, including old or new test kits. Once
the ingredients are selected, they are mixed in a ball mill. The homogenized mixture then is
spread across a special piece of release paper laid on a flat glass surface using a wire-wound bar
to control the thickness of the paint layer. The paint then is allowed to dry. Once dry, it is removed
from the release paper for chemical analysis to determine areal (mg/cm2) and mass (%) Pb
concentrations.
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2.1.2 Performance
Stand-alone paint films were prepared and analyzed for uniformity of thickness and variability in
areal concentration (mg Pb/cm2) and mass concentration (% Pb). The paint films were marked
off in 3 x 3-cm areas across a paint film, and the film was laid on a sheet of steel. An electronic
meter then was used to measure the thickness in micrometers of the paint at various locations on
a film. Appendix 1 presents thickness information for a number of paint films prepared using the
old paint recipes. The thickness usually varied less than 5% across a paint film that is
approximately 15 x 24 cm. Appendix 1 also presents Pb concentration data for a variety of paint
films. The areal concentration (mg Pb/cm2) usually varied by less than 10%.
2.2 Method Diagnostic Test Materials
2.2.1 Preparation
The stand-alone, leaded paint films are cut into appropriately sized pieces and then attached to a
variety of substrates, including wood, metal, masonry, and plaster, using commercially available,
oil-based primer. A second leaded paint film may be laid (attached with primer) over the first to
make a more challenging test material. These paint films then can be overcoated with one or
more layers of commercially available oil-based paint, followed by one or more layers of
commercially available water-based paint to simulate what one might expect for old dwelling
paint. As noted above, these diagnostic test materials can be made more challenging by adding
colorants such as red or black iron oxide. Also, metals that might interfere with a particular type of
measurement method can be added during the preparation of the stand-alone paint films. Test
samples having different combinations of these materials can be prepared to vary the analytical
challenge. Once the substrates are coated with the desired paint films and overcoats, they are
baked in a laboratory oven to harden the paint to simulate some degree of aging.
2.2.2 Performance
In a project performed for the EPA, 31 different combinations of substrate, leaded paint films, and
overcoats were prepared.5 A table is presented in Appendix 2 that shows the results of analysis
of representative samples or "coupons" of these materials. The variability of areal Pb
concentration (mg Pb/cm2) is generally less than 10%. Specification sheets were prepared for
each of the 31 types of diagnostic test materials, which were analyzed for 15 elements in addition
to Pb. Appendix 3 is an example of a specification sheet for a complex test material that
combined a layer of paint with Pb chromate; a layer of paint with white Pb, black iron oxide,
aluminum oxide, barium oxide, and magnesium oxide added; two overcoats of oil-based paint;
and four overcoats of water-based paints.
3.0 DEFINITIONS, ACRONYMS, AND ABBREVIATIONS
A number of acronyms and abbreviations are used in this SOP. These acronyms and their meanings are
as follows.
• EPA - U.S. Environmental Protection Agency
• ICP-OES - inductively coupled plasma-optical emission spectrometry
• LBP - lead-based paint
• Pb - elemental or ionic lead
• RRP - Lead; Renovation, Repair, and Painting Program; Final Rule
• RTI - RTI International
• SOP - standard operating procedure
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4.0 HEALTH AND SAFETY WARNINGS
4.1 Safety with Paint Ingredients, Including Powdered Lead Compounds and
Solvents
Weighing, mixing, and pouring of paint ingredients must be done in an approved chemical fume hood.
While mixing ingredients, the technician is to wear all specified personal safety equipment including a
lab coat/apron, dust mask, gloves, and safety glasses. Spilled materials are to be wiped up using
wetted paper towels and the towels placed into labeled, resealable bags. It's very important to
completely close the lid of the ball mill jar after filling it with the paint ingredients and before removing
it from the hood.
Note: Powdered white Pb (lead carbonate) and lead chromate are extremely hazardous.'1 8
4.2 Safety with Ball Mill
A cover (see Figure 1) should be made for the ball mill to protect the user from entanglement with the
rollers. Place the ball mill jar securely and evenly on the rollers and close the cover before turning on
the power to the mill. The rotation speed control dial position should be set before turning on power.
Figure 1. Ball mill being covered with safety shield to prevent injury from rollers.
4.3 Proper Disposal of Waste
Proper procedures for disposing of leaded and unleaded paint and paint cleanup solutions and
materials should be followed. Proper procedures for disposing of flammable materials (mineral spirits)
also should be followed. See Section 11.0 for more information on waste management.
5.0 EQUIPMENT, SUPPLIES, AND REAGENTS
5.1 Paint Mixing
5.1.1 Paint Ingredients
5.1.1.1 Basic Components
5.1.1.1.1 Boiled linseed oil, VWR Catalog No. EM-LX0305-3, or equivalent
5.1.1.1.2 Lead (III) chromate,9 VWR Catalog No. AA14125-22, or equivalent
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5.1.1.1.3	Mineral spirits, Klean-Strip Odorless,10 or equivalent
5.1.1.1.4	Raw linseed oil, VWR Catalog No. IC96012205, or equivalent
5.1.1.1.5	Lead carbonate, basic11 (white Pb), Aqua Solutions (Deer Park, TX), Catalog
No. L3200-500G, or equivalent
5.1.1.1.6	Zinc oxide, VWR Catalog No. AA44263-A1, or equivalent
5.1.1.2	Potential Test Kit Interferences
5.1.1.2.1	Aluminum oxide, VWR Catalog No. EM-AX0612-1, or equivalent
5.1.1.2.2	Barium carbonate, VWR Catalog No. BDH0218-500G, or equivalent
5.1.1.2.3	Magnesium carbonate, VWR Catalog No. JT2436-1, or equivalent
5.1.1.3	Example Colorants
5.1.1.3.1	Black iron oxide, VWR Catalog No. 100202-020, or equivalent
5.1.1.3.2	Red iron oxide, Hoover Color Corporation,12 Syn-OxHR-1201 RED, or
equivalent
5.1.2	Equipment and Supplies for Mixing Paint Ingredients
5.1.2.1	Balance, up to 400 g capacity, such as Fisher Scientific, Model S-400, or equivalent
5.1.2.2	Cylindrical alumina grinding media, U.S. Stoneware,131/2 x 1/2 in (1.27 x 1.27 cm),
94 pieces/lb, "for rapid dispersion of liquid based systems," or equivalent
5.1.2.3	Disposable beakers, 250 mL capacity, VWR Catalog No. 25384-154 or 400 mL
capacity, VWR Catalog No. 25384-156, or equivalent
5.1.2.4	Disposable spatulas, VWR Catalog No. 80081-188, or equivalent
5.1.2.5	Glass jar, 16 oz (500 mL) capacity, VWR Catalog No. 15900-064, for storing paint
between casts, or equivalent
5.1.2.6	One-liter Grinding mill jar, U.S. Stoneware,13 Size 0, or equivalent
5.1.2.7	Unitized ball mill, U.S. Stoneware,13 Model 764AVM, holds two jars, or equivalent
5.1.3	Equipment and Supplies for Casting Paint Films
5.1.3.1	Coating thickness gauge, Positector 6000 by Defelsko,14 or equivalent
5.1.3.2	Drawdown machine, Gardco,15 Item No. DP-1230A, or equivalent
5.1.3.3	Drawdown rod, Gardco,15 Wire Diameter 0.090 in (#90 [0.229 cm]), Item No. AP-1/2 x
90, or equivalent
5.1.3.4	Permanent marker, such as a Sharpie, or equivalent for labeling jars of paint and
paint films
5.1.3.5	Release paper by Leneta, Gardco,15 Item No. PC-RP-1K, or equivalent
5.1.3.6	Steel plate, needed under paint film to measure thickness, Gardco,15 Catalog No. PP-
02-06x12 (6 x 12 x 0.032 in [15.2 x 30.5 x 0.081 cm]), or equivalent
5.1.3.7	Syringe, Luer-slip plastic disposable, 50 mL capacity, VWR Catalog No. 660640764,
for spreading paint onto release paper, or equivalent
5.1.3.8	Tape for securing release paper to drawdown machine
5.1.4	Supplies and Equipment for Preparing Test Kit Diagnostic Materials
5.1.4.1 Supplies
5.1.4.1.1 Fired bricks, either standard size or pavers from local brick company
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5.1.4.1.2	Three-inch (7.6-cm) disposable paint rollers for application of primer and
overcoats, Shur-Line 3775-mm Trim Roller, or equivalent
5.1.4.1.3	Disposable plates (coated paper or plastic) to serve as trays for loading a roller
with paint
5.1.4.1.4	Oil-based paint for applying overcoats, Sherwin Williams17 ProMar 200, or
equivalent
5.1.4.1.5	Paint for coating metal to prevent formation of rust, Rust- Oleum18 Professional
Primer (Gray), or equivalent
5.1.4.1.6	Pine or oak boards from local lumberyard
5.1.4.1.7	Plaster for making moulds, USG Hobby Plaster, Plaster of Paris, United States
Gypsum Company,19 Chicago, IL, Plaster.com, or equivalent
5.1.4.1.8	Primer paint for attaching paint films to substrates, BEHR20 Premium Plus Oil-
Base, or equivalent
5.1.4.1.9	Smooth metal rod 1/4 to 3/8 in (0.64 to 0.95 cm) in diameter and about 6 in
(15.2 cm) long for smoothing out the paint pieces after their attachment to the substrate.
The paint roller handle (without the roller) will serve this purpose as well.
5.1.4.1.10	Steel or iron plating or sheeting from local hardware supplier, typically 1/32 to
1/16 in (0.079 to 0.16 cm) thick
5.1.4.1.11	Tray with flat bottom and sides at least 3/8 in (0.95 cm) high for casting plaster
5.1.4.1.12	Vented oven that can be set to 150 °C ± 5 °C for baking paints on substrates,
VWR Catalog No. 16000-212, or equivalent
5.1.4.1.13	Water-based paint for applying overcoats, Glidden21 Evermore Semi-gloss, or
equivalent
5.1.4.2 Equipment
5.1.4.2.1	Hacksaw or metal shears to cut metal substrate pieces
5.1.4.2.2	Hand-held or power saw to cut wood substrate pieces
5.1.4.2.3	Ruler and fine tip marker to draw out dimensions on substrates and paint films
5.1.4.2.4	Straightedge and pizza cutter to cut cast paint film into desired dimensions, or
specially made guide for cutting paint film (shown below in Figure 7)
5.1.4.2.5	Table saw or miter saw to cut plaster substrate pieces
5.1.4.2.6	Water-cooled masonry saw to cut masonry substrate pieces
5.2 Cleanup
5.2.1	Acetone, for cleaning glass surface of drawdown machine, VWR Catalog No. BDH 2002-
1GLP, or equivalent
5.2.2	Brass bristle brush for cleaning drawdown rods, VWR 101413-026, or equivalent
5.2.3	Two-liter graduated cylinder, VWR Catalog No. 24780-369, or equivalent for soaking
drawdown rods
5.2.4	Mineral spirits, Klean-Strip Odorless,10 or equivalent
5.2.5	Paper towels
5.2.6	Razor blade for scraping dried paint residue from drawdown machine
5.2.7	Scrub brush for cleaning ball mill jar, VWR 17170-005, or equivalent
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5.3 Safety Equipment
Safety equipment is required for protection from harm from various paint ingredients. Useful items
include the following.
5.3.1 Dust mask, VWR Catalog No. 56219-004, or equivalent
5.3.2 Eyewash bottle, VWR Catalog No. AA39980-KT, or equivalent
5.3.3 Gloves, VWR Catalog No. 40101-348, or equivalent
5.3.4 Laboratory apron, VWR Catalog No. 10845-016, or equivalent
5.3.5 Safety glasses, VWR Catalog No. 89032-944, or equivalent
Note: Paint ingredients must be handled in fume hood to avoid inhaling dust particles and solvent
fumes.
6.0 QUALITY CONTROL AND QUALITY ASSURANCE
6.1 Quality control activities to be practiced during the performance of this method include those that
follow.
6.1.1 Use only beakers, scoops, etc., dedicated to particular components when weighing paint
ingredients.
6.1.2 Use only reagent-grade ingredients for components, except mineral spirits.
6.1.3 Jars and grinding media must be cleaned thoroughly with mineral spirits between each
batch of paint.
6.1.4 Discard syringes after use.
6.1.5 Clean and dry drawdown rods thoroughly between each cast.
6.1.6 Use only clean glass jars to store paint between mixing and each cast.
6.2 The quality objectives for the leaded paint films are (1) a variability of less than ±10% in
thickness (jjm) as measured with an electronic thickness gauge and (2) a variability of less than 10%
in Pb concentration (mg/cm2) as measured by sampling and analysis using EPA Microwave Method
3051A,22 EPA "Standard Operating Procedure forthe Grinding and Extraction of Lead in Paint Using
Nitric Acid and a Rotor/Stator System Powered by a High-Speed Motor,"23 or an equivalent method
for extracting Pb from the paint, and measurement by inductively coupled plasma-optical emission
spectrometry(ICP-OES).24
6.3 The quality objective forthe Pb method diagnostic test materials is a variability of less than 10%
in Pb concentration (mg/cm2) as measured by sampling and analysis using EPA Method 3051 A,22
EPA "Standard Operating Procedure forthe Grinding and Extraction of Lead in Paint Using Nitric Acid
and a Rotor/Stator System Powered by a High-Speed Motor,"23 or an equivalent method for extracting
Pb from the paint, and measurement by ICP-OES.24
7.0 PROCEDURE FOR PREPARATION OF STAND-ALONE PAINT FILM
7.1 Selection of Components
The preparation of a paint films starts with selection of the components. The categories will be
• Pb pigment such as white Pb11 or lead chromate,9
• filler such as zinc oxide or titanium dioxide,
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• binder such as linseed oil,
• optional—colorants such as red iron oxide, and
• optional—potential measurement interferences such as barium carbonate.
The selection will be based on the intended use of the paint film. For example, one might select lead
chromate as the pigment because it is more difficult to dissolve than white Pb and red iron oxide to
serve as a potential interference with rhodizonate-based test kits that give a pink color on reaction
with Pb.25,26 The relative amounts of the components selected are based on literature sources27 28
and experience. A typical old paint recipe includes, by weight,
• 37% white Pb,
• 37% zinc oxide,
• 17% linseed oil (half raw, half boiled), and
• 9% mineral/petroleum spirits.
Following this basic recipe, the relative amounts of Pb pigment and zinc oxide can be varied to
achieve the desired Pb-in-paint film concentration (i.e., mg Pb/cm2). A large number of paint films
were produced and analyzed, as illustrated in Appendixes 1 and 4. From these results, a relationship
between the areal Pb concentration (mg Pb/cm ) in the final paint film and the percent white Pb in the
"wet" mix was determined.5 This relationship is shown in Figure 2.
% Pb by Wgt
Figure 2. Plot of paint film Pb concentrations (mg Pb/cm ) versus Pb concentration (% Pb) in
"wet" paint mixture (assuming white Pb = 80% Pb by weight).
To calculate, the amount of white Pb needed, first select the Pb-in-paint film concentration (mg/cm2)
desired. From the plot in Figure 2, determine the required percent Pb in the wet mix. The amount of
white Pb to be used is then calculated as
White Pb in wet paint mix (g) = (% Pb in wet paint mix/100) x 1.25 x total weight of wet paint mix (g),
where 1.25 is the weight ratio of white Pb to Pb.
Note: Recipes for amounts of each ingredient to use to achieve specific concentrations are listed
specifically in Appendix 4 in the batch/recipe table.
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7.2 Mixing Paint Ingredients in Ball Mill
The paint ingredients are mixed in the following manner.
7.2.1 Use safety equipment, including dust mask, safety glasses, gloves, and lab coat.
7.2.2 Place the containers of the ingredients (Pb pigment, zinc oxide, raw linseed oil, white
linseed oil, and mineral spirits) in a laboratory fume hood.
7.2.3 Fill the ball mill jar approximately half full with grinding media, as shown in Figure 3, and
place the ball mill jar with grinding media in the fume hood.
BOILI
Figure 3. Bali mill jar with grinding media along with principal ingredients of paint.
7.2.4 Place a clean 250-mL beaker on the top loading balance and tare the balance.
7.2.4.1 Carefully use a spatula dedicated to the Pb pigment to place the desired weight of the
Pb pigment into the beaker while still on the balance.
7.2.4.2 Very carefully transfer the Pb pigment into the ball mill over the grinding media.
7.2.4.3 Repeat this procedure with the zinc oxide using a clean beaker and spatula dedicated
to the zinc oxide.
7.2.4.4 Next, use a clean beaker and weigh out the required amount of raw linseed oil and
transfer this material to the ball mill jar.
7.2.4.5 Using another clean beaker, weigh out the required amount of boiled linseed oil and
transfer this material to the ball mill jar.
7.2.4.6 Finally, use another clean beaker and weigh out the required amount of mineral spirits
and transfer this material to the bali miii jar.
7.2.5 When all ingredients are in the jar, securely lock the lid into place.
7.2.6 Remove the closed jar from the fume hood and place it on its side on the rollers of the ball
mill (see Figure 1). Two jars can be placed on the ball mill at the same time, if desired.
7.2.6.1 Cover the ball mill rollers and jars with an approved safety cover.
7.2.6.2 The dial should be set to approximately 69 rpm (dial position 20). Turn on the ball mill
using the power switch located on the cord.
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7.2.6.3 Allow the jars to turn at this speed, with no interruption, for 96 h.
7.3 Varying Recipes (adding metals and pigments)
7.3.1 Lead chromate or some pigment other than white Pb may be used. If lead chromate is to
be added, it is added as a replacement for the white Pb, not in addition to it. It has been
determined that the mineral spirits need to be increased by 10 g when preparing a 81 Og mixture
to ensure even flow of the paint during the casting process when using lead chromate. Using lead
chromate will lead to a yellow paint film. Several recipes for lead chromate paint films are listed in
Appendix 4 in the batch/recipe table.
7.3.2 Chemicals that have the potential for interfering with the measurement may be added
(aluminum oxide, barium carbonate, magnesium carbonate). When using these compounds, the
weight of zinc oxide used is reduced by an amount equal to the weight of the added chemical.
Illustrative data are presented in Appendix 4.
7.3.3 Pigmentation can be achieved by adding materials like red iron oxide (Fe203), black iron
oxide (FeO), red Pb (lead tetraoxide, Pb304, 0r2PbO.PbO2), or chrome oxide green (Cr203) with
the white Pb. When using these compounds, the weight of zinc oxide used is reduced by an
amount equal to the weight of the added chemical. Illustrative data are presented in Appendix 4.
7.4 Casting Paint into Films
A paint film is cast as follows.
7.4.1 When 96 h have elapsed, turn off the ball mill and remove the protective cover.
7.4.2 Remove the jar from rollers and carefully unlock the lid.
7.4.3 Using caution, pour the paint into a glass jar leaving the grinding media in the ball mill jar.
Cap the glass jar. Be sure that this jar is clearly labeled with the batch number and other
important information, such as date of preparation and nominal Pb concentration. To help with
cleanup, it is recommended to wipe up spills on the side of the jar, etc., immediately. More
specifics on cleanup are presented in Section 7.7.
7.4.4 Set up and level a drawdown machine in a fume hood; allow 8 to 12 in (20 to 30 cm) of
open space on each side of the machine.
7.4.4.1 Place a sheet of release paper, positioned in "landscape," on the machine's flat glass
surface and secure with small pieces of tape at the top and bottom, taking care that the paper
is as flat as possible.
7.4.4.2 Lock the drawdown bar into place on the appropriate mechanism on the drawdown
machine and leave in the "open" position.
7.4.5 Using a syringe, draw up about 12 mL of paint from the glass jar. Spread this paint across
the release paper, approximately 1 in (2.5 cm) from the top. Paint will begin to spread slightly on
its own.
7.4.5.1 Put drawdown bar into the lowered position so that it touches the top of the paint and
steadily draw it down towards the bottom of the machine, spreading the paint evenly down
the release paper, as shown in Figure 4. The drawdown should take about 3 s. Do not be
concerned if a bit of the paint spills over onto the glass surface of the machine.
7.4.5.2 When reaching the bottom of the paper, pick up drawdown bar and remove it from the
machine, and place it in a 2-L graduated cylinder filled with mineral spirits.
7.4.5.3 Do not move the machine or paper at all, as this will create an uneven paint
distribution.
9

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f
Figure 4. Using the wire-wound drawdown bar to cast a lead chromate paint film on release paper.
7.4.6 Label the paint film by writing with a permanent marker on the unused part of the release
paper or by placing a separate sheet of paper beside the drawdown machine, clearly indicating
the batch and film number. Do not attempt to write on the paint.
7.4.7 Allow paint to cure for at least 2 days before attempting to remove it from the paper.
7.5 Retrieval of Paint Film from Release Paper
The dry paint film is removed from the release paper as follows.
7.5.1 After a minimum of 48 h, remove the release paper from the machine by pulling up the
tape.
7.5.2 Carefully peel the paint film off of the release paper and place it on a clean sheet of
release paper, labeled with the batch and film number. If desired, this is an appropriate time to
label the paint film itself using a permanent marker
7.5.3 Place the film on the release paper in a folder, label the folder, and store it in a clean, dry
place.
7.6 Testing for Variability of Film Thickness
A quality control parameter is the variability in area thickness of the cast paint film measured in
micrometers using an electronic thickness meter. To measure the variability of a cast paint film,
perform the following steps.
7.6.1 Make a grid on the paint film (squares approximately 3x3 cm) using a ruler and an ink
pen. Or, if markings on the film are undesirable, use a gridded template.
7.6.2 Place the paint film on top of a steel plate.
7.6.3 Place the thickness gauge straight down, perpendicular to the steel plate, on the film and
allow the button on the bottom to be compressed. Do this in each square on the grid (see Figure
5).
7.6.4 The gauge will beep when it takes a measurement. Take three measurements before
recording to give the gauge time to come to a final value.
10

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Figure 5. Marked paint film being measured for thickness.
7.6.5 Measurements are displayed in micrometers and should be recorded appropriately in a
laboratory notebook.
7,7 Cleaning
It is extremely important to thoroughly clean jars, grinding media, drawdown bars and machines, etc.,
between each batch and each film casting to ensure accuracy in film preparation.
7.7.1 Ball Mill Jar and Grinding Media
After emptying the paint into a glass jar and setting it aside, the grinding media will still be in the
ball mill jar. To clean the jar and media, do the following.
7.7.1.1 Fill the ball mill jar with mineral spirits until it just covers the grinding media, which will
be approximately half full.
7.7.1.2 Secure the lid on the jar and roll on the ball mill for 15 min, being sure to use the
safety cover.
7.7.1.3 After 15 min, pour the mineral spirits and paint residue into a disposable, 400-mL
beaker and discard this waste into an appropriate flammable materials waste container.
7.7.1.4 Again, fill the jar half-way with mineral spirits and roll on the ball mill for another
15 min.
7.7.1.5 Pour the mineral spirits and paint residue into the disposable beaker and discard this
waste into an appropriate flammable materials waste container.
7.7.1.6 By either pouring or using a gloved hand, remove the grinding media from the ball mill
jar and place it in a quart container, cover the media with mineral spirits, and cap the
container. Before reusing, remove and allow to dry.
7.7.1.7 Fill the ball mill jar with soapy water and scrub the inside with a scrub brush. The lid of
the jar should also be cleaned using soapy water. Discard the wash water down the drain.
7.7.1.8 After washing, the jar and lid should be allowed to air dry before the next use.
7.7.2 Drawdown Rod and Drawdown Machine
7.7.2.1 Immediately after drawing down paint with the drawdown rod, place the rod into a 2-L
graduated cylinder that contains mineral spirits.
7.7.2.1.1 Allow it to soak for approximately 10 min.
11

-------
7.7.2.1.2 Working in the hood, remove the rod from the mineral spirits and use a brass
brush to scrub between the wire wound around the rod. Do this over paper towels to
capture drips.
7.7.2.1.3 After scrubbing with the brush, use gloved hands to wash the rod with soapy
water to clean off the mineral spirits.
7.7.2.1.4 Place the rod on paper towels and allow it to air dry.
7.7.2.2 After removing the release paper holding the film, use a razor blade to scrape off any
dried paint that is on the glass surface of the drawdown machine.
7.7.2.2.1 Using a paper towel dipped in acetone, wipe the glass surface to remove any
remaining paint residue. Do this until surface appears completely clear. If any tape is left
on the surface, remove this as well. Be sure that the glass surface is clean and dry before
placing another piece of release paper on it.
8.0 PROCEDURE FOR PREPARATION OF LEAD METHOD
DIAGNOSTIC TEST MATERIALS
8.1 Selection of Components
The components of the Pb method diagnostic test materials include a substrate, one or more leaded
paint films, and one or more overcoats of oil-based and/or water-based, nonleaded paint. The leaded
paints may vary in composition as described in Section 7.1.
8.1.1 Selection of Substrates
Four common substrates found in old dwellings are (1) wood, (2) metal, (3) masonry, and (4)
plaster. Figure 6 shows examples of each of these types of substrates.
Figure 6. Photograph of metal, wood, plaster, and masonry substrate materials ready for
preparation of diagnostic test materials.
8.1.1.1 Wood substrates for the method diagnostic materials can be prepared by cutting
typical dwelling wood types like pine and oak into the desired dimensions.
8.1.1.2 Typically, the metal plate or sheeting found in old houses will be made of iron.
8.1.1.2.1 Iron plate or sheeting can be acquired from various sources, such as hardware
supply stores.
12

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8.1.1.2.2 The metal plate can be cut to the desired dimensions using a hacksaw or metal
cutting shears.
8.1.1.2.3 It has been found that the steel can rust if it is not stainless. To prevent this,
paint both sides of the metal with a light coat of anti-rust coating such as Rust-Oleum
Professional Primer.18
8.1.1.3 Masonry substrate is made from bricks. The brick is cut into the desired dimensions
using a water-cooled masonry saw equipped with a diamond-tipped saw blade.
8.1.1.4 The plaster is a greater challenge. To make the plaster, purchase the type of plaster
mix made for making castings.
8.1.1.4.1 Mix up the plaster with water according to the instructions on the container.
8.1.1.4.2 Pour the wet plaster into a tray with a flat bottom and sides that are at least 3/8
in (0.95 cm) high.
8.1.1.4.3 Quickly shake the tray to smooth out the surface of the plaster and/or smooth it
with a small trowel because it begins setting quickly.
8.1.1.4.4 Allow the plaster to dry for 24 h and then gently remove the slab of plaster from
the tray.
8.1.1.4.5 Using a table saw or skill saw, cut the plaster slab into pieces of the desired
dimensions.
8.1.2 Selection of Leaded Paint Films
The leaded paint films are chosen to challenge the Pb testing method at various levels of
complexity. Variables are the desired type of Pb pigment, the concentration of the Pb, the
absence or presence of colorants, and the absence or presence of potentially interfering agents,
such as certain trace metals.
8.2 Cutting Paint Films into Desired Dimensions
8.2.1 Once the type of leaded paint film is chosen, the films cast as described above are cut to
the desired dimensions. This may be done using a ruler and a fine-tipped marking pen to first
draw out the dimensions of the desired paint pieces across a cast film. The paint may be cut with
a pizza cutter (or a scalpel or hobby knife), using a straightedge as a guide.
8.2.2 If large numbers of films are to be cut, a guide system may be built. One such system is
shown in Figure 7. It is composed of two pieces of plastic constructed with slots. One piece has
the slots separated by the desired length of the film piece and the other has the slots separated
by the desired width of the film piece.
8.2.2.1 The film is laid on a cutting board and one of the pieces is laid over the film. A pizza
cutter is run through the slots.
8.2.2.2 Then, the second piece of plastic is laid down, with the slots perpendicular to the slots
of the first cut. Again, the pizza cutter is run through the slots.
8.2.2.3 The final result is several pieces of paint cut to the desired size. If the paint pieces are
5x7 cm, then about nine pieces of paint are cut from one cast paint film.
8.3 Assembly of the Test Pieces
A test piece consists of the substrate with one or more layers of leaded paint film and overcoats. The
assembly is as follows.
8.3.1 Place the wood, metal, or masonry on a flat surface. [Plaster is discussed in Section 8.3.2.]
8.3.1.1 Pour a small amount of well-mixed primer onto a disposable plate and then use the
roller to apply a thin layer of oil-based paint primer on the substrate.
13

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Figure 7. Paint film cutting apparatus and process: (1) Paint film is laid on cutting board; (2) the
first template is placed in guide holes to make vertical cuts, leaving 2-cm-wide strips for film
analysis; (3) the second template is placed in guide holes to make horizontal cuts; (4) the process
leaves six to nine, 5 x 7-cm film pieces for preparation of coupons and 2-cm pieces for analysis.
8.3.1.2 Carefully lay a piece of the leaded paint on the coated substrate, taking care to center
the paint piece as shown in Figure 8.
I
m

\
Figure 8. Placing leaded paint film on wood substrate coated with primer to serve as adhesive.
8.3.1.3	Using a small metal rod, very carefully and gently roll/push it across the paint piece to
push the paint piece into the partially dry primer and smooth out any wrinkles as shown in
Figure 9.
8.3.1.4	After drying for 24 h, perform any additional smoothing needed.
14

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Figure 9. Smoothing out paint film after allowing time for the primer to partially dry.
8.3.1.5 Allow the primer to dry for a total of 2 days.
8.3.2 In the case of plaster substrate, the first layer of primer will soak quickly into the plaster
and not be a suitable adhesive for the paint piece. In this case, apply a coating of primer on the
plaster and allow it to dry for 2 days. Then apply another coating of the primer for attachment of
the paint piece.
8.3.2.1 If a second leaded paint film is to be attached, coat the paint piece on the substrate
with a thin layer of primer and carefully place the second paint film over the first paint film.
8.3.2.2 Using a small metal rod, very carefully and gently roll/push it across the paint piece to
push the paint piece into the partially dry primer and smooth out any wrinkles.
8.3.2.3 After drying for 24 h, perform any additional smoothing needed.
8.3.2.4 Allow the primer to dry for a total of 2 days.
8.3.3 If overcoating the paint piece with oil-based paint, pour a small amount of well-mixed,
nonleaded, oil-based paint onto a disposable plate and use a roller to overcoat the paint film as
shown in Figure 10. Make every effort to make a smooth and uniform coating.
8.3.3.1 Allow the oil-based coating to dry for 2 days.
8.3.3.2 Repeat the previous two steps for each coating of oil-based paint desired.
8.3.3.3 If overcoating the paint piece or the oil-based overcoats with water-based paint, pour
a small amount of well-mixed, nonleaded, water-based paint onto a disposable plate and use
a roller to overcoat the previously applied paint film. Make every effort to make a smooth and
uniform coating.
8.3.3.4 Allow the water-based coating to dry for 1 day.
8.3.3.5 Repeat the previous two steps for each coating of water-based paint desired.
8.3.4 With the test piece fully assembled, place the piece in a vented oven for 24 h at 40 °C and
then 48 h at 150 ± 5 °C to harden the paint as an approximation of the hardening that occurs with
paints over many years of aging.
8.3.5 The plaster substrate may crack when samples are taken for analysis. To minimize the
potential for cracking and breaking, a thin piece of wood is glued to the back of the piece after
baking.
15

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Figure 10. Applying overcoat.
Figure 11 shows completed test pieces or coupons and bare substrates.
Figure 11. Photographs of overcoated leaded paint films on wood, metal, masonry, and plaster
substrate pieces, along with bare substrate pieces. Note backing board on finished plaster piece
to minimize potential for breaking.

-------
8.4 Example of Preparation of Test Piece
In one EPA project, 31 different combinations of substrate, type of leaded paint films, and type and
number of overcoats were prepared.5 The following describes the preparation of one of the more
complex combinations.
8.4.1 Place a 10 x 8 x 2-cm piece of pine wood on a flat surface.
8.4.1.1 Using a small roller, coat the top of the piece with a thin layer of white primer.
8.4.1.2 Carefully lay down a 7 x 5-cm piece of paint film prepared with lead chromate at 0.4
mg Pb/cm2.
8.4.1.3 Smooth the paint film out as needed with a smooth metal rod (repeat after 24 h).
8.4.1.4 Allow this combination to dry for 2 days.
8.4.2 Using a small roller, coat the paint film and the primed wood with a thin layer of white
primer.
8.4.2.1 Carefully lay down a 7 x 5-cm piece of paint film prepared with white Pb at 0.8 mg
Pb/cm2 and doped with aluminum oxide, barium carbonate, and magnesium carbonate (as
potential measurement interferences), and black iron oxide (as a colorant).
8.4.2.2 Smooth the paint film out as needed with a smooth metal rod (repeat after 24 h).
8.4.2.3 Allow this combination to dry for 2 days.
8.4.3 Using a small roller, coat this combination with a uniform layer of oil-based white paint.
8.4.3.1 Allow this combination to dry for 2 days.
8.4.3.2 Using a small roller, coat this combination with a second, uniform layer of oil-based
white paint.
8.4.3.3 Allow this combination to dry for 2 days.
8.4.4 Using a small roller, coat this combination with a uniform layer of water-based white paint.
8.4.4.1 Allow this combination to dry for 1 day.
8.4.4.2 Using a small roller, coat this combination with a second, uniform layer of water-
based white paint.
8.4.4.3 Allow this combination to dry for 1 day.
8.4.4.4 Using a small roller, coat this combination with a third, uniform layer of water-based
white paint.
8.4.4.5 Allow this combination to dry for 1 day.
8.4.4.6 Using a small roller, coat this combination with a fourth, uniform layer of water-based
white paint.
8.4.4.7 Allow this combination to dry for 1 day.
8.4.5 Bake this piece for one day at 40 °C in a vented oven to remove volatiles.
8.4.5.1 Bake this piece for 2 days at 150 ± 5 °C in a vented oven to harden the paint such
that it better represents old, hard paints found in old dwellings.
This combination presents numerous challenges, including
• lead chromate, which is a fairly insoluble form of Pb;
• two layers of leaded paint;
17

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• the presence of potential measurement interferences, Al, Ba, and Mg plus Fe from the
colorant;
• the second layer of leaded paint being black, which has the potential for interfering with
visualization of a Pb-caused color change; and
• multiple layers of oil-based and water-based over the leaded-paint layers, which add
the challenge of relatively thick, multilayered paint.
9.0 DATA PROCESSING
9.1 Variability in Paint Film Thickness
The variability in paint film thickness is measured using an electronic thickness gauge. The average
and standard deviation are calculated using either software such as Excel or an advanced calculator.
The variability or uncertainty in the value of thickness (jjm) is not to exceed ±10%.
9.2 Variability in Lead Concentration in Prepared Paint Films
The average value and the variability in the Pb concentration are determined for each film based on
the analysis of aliquots taken from that film. The average and standard deviation are calculated using
either software such as Excel or an advanced calculator. The variability or uncertainty in the value of
Pb concentration (mg/cm2) thickness is not to exceed ±10%.
9.3 Variability in Lead Concentration in Method Diagnostic Test Materials
The average value and the variability in the Pb concentration are determined for each film based on
the analysis of aliquots taken from the method diagnostic test materials. The average and standard
deviation are calculated using either software such as Excel or an advanced calculator. The variability
or uncertainty in the value of Pb concentration (mg/cm2) should not exceed ±10%.
10.0 DATA AND RECORDS MANAGEMENT
Keeping complete records will help ensure accuracy in making paint films. Activities to be performed
include those that follow.
10.1 Maintain all records in a bound notebook or on a form prepared specifically for recording
information pertinent to this SOP. The forms shall be maintained in a binder.
10.2 Each paint batch and each paint film are to be given an identifying name or number that is
recorded.
10.3 Each block or piece of method diagnostic test material is to be given an identifying name or
number that is recorded.
11.0 WASTE MANAGEMENT
There are several forms of waste generated during the operation of this SOP. Each is dealt with as
follows.
11.1 Mineral Spirits
Leftover mineral spirits used for cleaning should be contained in labeled, flammable waste containers
until they can be disposed of by hazardous waste personnel.
11.2 Leaded Paint
Any excess Pb-containing paint that is not cast into a film should be kept in labeled, closed containers
until it can be disposed of by hazardous waste personnel. Any unused pieces of leaded paint film
18

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should be kept in labeled, closed containers until they can be disposed of by hazardous waste
personnel.
12.0 REFERENCES
(1)	D.E. Jacobs, R.P. Clickner, J.Y. Zhou, S.M. Viet, D.A. Marker, J.W. Rodgers, D.C. Zeldin, P. Broene,
and W. Friedman. 2002. The prevalence of lead-based paint hazards in U.S. housing. Environmental
Health Perspectives, 110(10):A599-A606.
(2)	Title X of the Housing and Community Development Act, Residential Lead-Based Paint Hazard
Reduction Program Act of 1992. Public Law 102-550.
(3)	USEPA. 2008. Lead; Renovation, Repair, and Painting Program; Final Rule. Federal Register. April
22. (pp.21691-21769). U.S. EPA, 40 CFR Part 745, EPA-HQ-2005-0049.
(4)	Gutknecht, W.F., S.L. Harper, W. Winstead, K. Sorrell, D.A. Binstock, C.A. Salmons, C. Haas, M.
McCombs, W. Studabaker, C. Wall, and C. Moore. 2009. Rapid new methods for paint collection and
lead extraction. Journal of Environmental Monitoring, 11, 166-173.
(5)	Gutknecht, W.F., D.A. Binstock, K. Sorrell, C.M. Haas, M. McCombs, C.A. Salmons, W. Winstead,
W. Studabaker, C. Moore, and C.V. Wall. 2008. "Lead Paint Test Kit Development, Refinements, and
Test Materials." National Exposure Research Laboratory, National U.S. Environmental Protection
Agency: Research Triangle Park, NC 27711.
(6)	Warren, C. 2000. "Brush with Death. A Social History of Lead Poisoning." The Johns Hopkins
University Press: Baltimore, MD.
(7)	Troesken, W. 2006. "The Great Water Pipe Disaster." The MIT Press: Cambridge, MA.
(8)	Hernberg, S. Lead Poisoning in Historical Perspective. 2000. American Journal of Industrial
Medicine, 38(3):244-254.
(9)	ASTM (American Society for Testing and Materials) D211-67. 2006. Standard Specification for
Chrome Yellow and Chrome Orange Pigments. The American Society for Standards and Materials:
West Conshohocken, PA.
(10)	Klean-Strip, Memphis, TN, www.kleanstrip.com.
(11)	ASTM (American Society for Testing and Materials) D 81-87. Reapproved 2003. Standard
Specification for Basic Carbonate White Lead Pigment. ASTM International, West Conshohocken,
PA.
(12)	Hoover Color Corporation, Hiwassee, VA, www.hoovercolor.com.
(13)	U.S. Stoneware, East Palestine, OH, www.usstoneware.com.
(14)	Defelsko, Ogdensburg, NY, www.defelsko.com.
(15)	Gardco-The Paul N. Gardner Company, Inc., Pompano Beach, FL, www.qardco.com.
(16)	Shur-Line, Huntersville, NC, www.shurline.com.
(17)	Sherwin-Wlliams, Cleveland, OH, www.sherwin-williams.com.
(18)	Rust-Oleum, Vernon Hill, IL, www.rust-oleum.com.
(19)	United States Gypsum Company (subsidiary of USG Corporation), USG Headquarters, Chicago, IL,
www.usq.com.
(20)	BEHR, Santa Ana, CA, www.behr.com.
(21)	Glidden by ICI Paints in North America, Cleveland, OH, www.qlidden.com.
19

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(22)	USEPA. 2007. Method 3051 A, Microwave Assisted Acid Digestion of Sediments, Sludges, Soils, and
Oils, Revision 1. U.S. Environmental Protection Agency: Washington, DC. Web site:
http://www.epa.gov/epawaste/hazard/testmethods/sw846/pdfs/3051a.pdf. Last accessed 01/12/09.
(23)	USEPA. 2009. "Standard Operating Procedure for the Grinding and Extraction of Lead in Paint Using
Nitric Acid and a Rotor/Stator System Powered by a High-Speed Motor." National Exposure
Research Laboratory, U.S. Environmental Protection Agency: Research Triangle Park, NC.
(24)	Binstock, D.A., D.L. Hardison, P.M. Grohse, and W.F. Gutknecht. 1991. "Standard Operating
Procedures for Lead in Paint by Hotplate- or Microwave-Based Acid Digestion and Atomic
Absorption or Inductively Coupled Plasma Emission Spectrometry," EPA 600/8-91/213. U.S.
Environmental Protection Agency: Research Triangle Park, NC. Available from NTIS (NTIS #PB92-
114172).
(25)	USEPA. 1993. "Investigation of Test Kits for Detection of Lead in Paint, Soil, and Dust," EPA 600/R-
93/085. Atmospheric Research and Exposure Assessment Laboratory: U.S. Environmental
Protection Agency: Research Triangle Park, NC.
(26)	ASTM (American Society for Testing and Materials) E1753 - 04. 2004. Standard Practice for Use of
Qualitative Chemical Spot Test Kits for Detection of Lead in Dry Paint Films. The American Society
for Standards and Materials: West Conshohocken, PA.
(27)	The Chemical Formulary. 1936. Ed. H. Bennett, Chemical Publishing Co.: New York, NY. Vol. 3.
pp.24-25.
(28)	Gutknecht, W.F., D.A. Binstock, K. Sorrell, C.M. Haas, M. McCombs, C.A. Salmons, W. Wnstead,
W. Studabaker, C. Moore, and C.V. Wall. 2007. "Development and Preparation of Performance
Evaluation Materials (PEM's) Suitable for In-situ Test Methods used to Evaluate Intact Paint Films for
Lead." RTI Subcontract No. SUB 1174861RB, Alion Science and Technology, USEPA Contract EP-
D-05-065, Office of Pollution Prevention and Toxics, U.S. Environmental Protection Agency:
Washington, DC.
20

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APPENDIX 1
Results of Analysis of Multiple Samples Taken from Cast Paint Films Needed To Prepare
All Planned Types of Coupons
Batch
Nominal Pb Conc.a (mg/cm^)
and Film Description
No.d Films
Prepared
Color
Overall Thickness0
(Mm)
Pb Cone.
(mg/cm2)
Pb Cone,
by wt (%)
n =
19
Blank
8
White
101.9 ± 9.5 (9.4%)
Blank
Blank
8
39
0.4 White Pb
11
White
107.2 ± 7.3 (6.8%)
0.391 ± 0.027 (6.97%)
1.21 ± 0.02 (1.3%)
12
35
0.8 White Pb
24
White
102.5 ±6.2 (6.1%)
0.808 ± 0.051 (6.25%)
2.56 ± 0.06 (2.3%)
12
41
1.0 White Pb
8
White
100.7 ± 5.1 (5.1%)
1.02 ± 0.05 (4.7%)
3.07 ±0.03 (0.9%)
8
29
1.2 White Pb
6
White
100.9 ±4.0 (3.9%)
1.31 ± 0.06 (4.4%)
4.07 ±0.05 (1.1%)
8
45
2.0 White Pb
6
White
100.8 ± 7.3 (7.3%)
1.98 ±0.12 (6.2%)
6.16 ± 0.11 (1.7%)
8
46
0.4 Lead Chromate
16
White
99.7 ± 6.7 (6.8%)
0.378 ± 0.028 (7.42%)
1.24 ± 0.03 (2.7%)
20
37
0.8 Lead Chromate
19
White
98.6 ± 6.1 (6.2%)
0.763 ± 0.056 (7.39%)
2.41 ± 0.02 (0.8%)
12
49
0.4 White Pb with Al, Ba, Mg
15
White
103.2 ±6.0 (5.8%)
0.358 ± 0.027 (7.64%)
1.21 ± 0.02 (1.4%)
12
50
0.8 White Pb with Al, Ba, Mg
11
White
102.4 ±6.8 (6.6%)
0.784 ± 0.096 (12.3%)
2.60 ±0.05 (1.8%)
12
53
0.4 White Pb with Black Iron Oxide
8
Black
88.0 ±6.0 (6.8%)
0.406 ± 0.050 (12.25%)
1.20 ±0.02 (1.3%)
8
54
0.8 White Pb with Black Iron Oxide
8
Black
89.5 ±6.9 (7.7%)
0.765 ± 0.045 (5.82%)
2.55 ±0.04 (1.5%)
8
55
0.4 White Pb with Red Iron Oxide
6
Red
101.5 ± 6.2 (6.1%)
0.364 ± 0.012 (3.39%)
1.24 ±0.02 (1.4%)
8
56
0.8 White Pb with Red Iron Oxide
8
Red
99.2 ±6.5 (6.6%)
0.734 ± 0.026 (3.53%)
2.45 ±0.04 (1.5%)
8
51
0.4 White Pb with Al, Ba, Mg, Black Iron Oxide
18
Black
90.2 ±6.9 (7.7%)
0.358 ± 0.033 (9.35%)
1.19 ± 0.01 (0.6%)
12
52
0.8 White Pb with Al, Ba, Mg, Black Iron Oxide
12
Black
88.5 ±6.4 (7.3%)
0.747 ± 0.046 (6.18%)
2.66 ±0.04 (1.3%)
12
aConc. = concentration
bNo. = number
cThickness tested on all films.

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APPENDIX 2
Summary of Results of Analysis of Each Type of
Coupon Prepared
Type3
No. Coupons Made
n =
Average Pb (mg/crr^)
Average Pb by wt (%)
A
18
6
Blank
Blank
B
18
6
0.341 ±0.014(4.11%)
0.359 ±0.023 (6.41%)
C
18
6
0.759 ±0.017 (2.24%)
1.018 ±0.063 (6.19%)
D
18
6
0.955 ± 0.050 (5.24%)
1.141 ±0.078 (6.84%)
E
18
6
1.167 ±0.069 (5.91%)
1.369 ±0.140 (10.2%)
F
18
6
1.917 ± 0.136 (7.09%)
1.973 ± 0.080 (4.05%)
G
18
6
0.744 ± 0.051 (6.85%)
1.021 ± 0.100 (9.78%)
H
18
6
1.196 ±0.040 (3.34%)
0.980 ± 0.059 (6.02%)
1
18
6
0.741 ± 0.034 (4.59%)
0.851 ± 0.053 (6.23%)
J
18
6
1.115 ±0.079 (7.09%)
0.946 ±0.113 (12.0%)
K
18
12
0.716 ±0.067 (9.36%)
1.555 ±0.101 (6.50%)
L
18
6
1.147 ±0.052 (4.53%)
1.162 ± 0.048 (4.13%)
M
18
6
0.701 ± 0.034 (4.85%)
1.463 ±0.065 (4.41%)
N
18
6
1.164 ±0.115 (9.88%)
1.355 ± 0.027 (1.99%)
0
18
7
0.821 ±0.114(13.9%)
0.421 ± 0.093 (22.1%)
P
18
7
1.322 ± 0.056 (4.24%)
0.660 ± 0.098 (14.9%)
Q
18
6
0.658 ± 0.038 (5.78%)
0.617 ± 0.088 (14.3%)
R
18
6
1.143 ±0.085 (7.44%)
0.858 ±0.123 (14.3%)
S
18
6
0.675 ± 0.031 (4.59%)
0.908 ±0.143 (15.7%)
T
18
6
1.08 ± 0.07 (6.54%)
0.829 ± 0.069 (8.32%)
U
18
6
0.699 ± 0.044 (6.29%)
0.898 ± 0.059 (6.57%)
V
18
6
1.134 ±0.098 (8.64%)
0.853 ± 0.054 (6.33%)
w
16
8
0.734 ± 0.045(6.13%)
0.494 ±0.062 (12.6%)
X
16
6
1.078 ± 0.061 (5.66%)
0.646 ±0.066 (10.22%)
Y
18
6
1.061 ± 0.084 (7.92%)
0.666 ± 0.063 (9.46%)
z
16
5
0.717 ± 0.072 (10.0%)
0.523 ± 0.033 (6.31%)
AA
16
6
1.062 ± 0.090 (8.47%)
0.825 ± 0.080 (9.70%)
AB
18
6
1.018 ±0.044 (4.32%)
0.776 ± 0.023 (2.96%)
AC
16
6
0.696 ± 0.064 (9.20%)
0.387 ± 0.054 (14.0%)
AD
16
6
1.03 ±0.10 (9.71%)
0.644 ± 0.050 (7.76%)
AE
18
6
0.945 ±0.112 (11.9%)
0.641 ± 0.073 (11.4%)
aSee pages A-3 and A-4
or details of types of coupons (Summary of ORD 2008 Lead-in-Paint Diagnostic Paint Materials ).
A-2

-------
Summary of ORD 2008 Lead-in-Paint Diagnostic Paint Materials5
Type
Diagnosis
Substrate
No. Films
and Pb
Compound3
White
Overlayers
No. and
Type"
Chemical
Interferences
Al, Ba, Mqc
Chemical
Interference
Fec'd
Pb
Film
Colorsd
Areal Pbe
(mg/cm2)
A
Sensitivity, accuracy,
and precision
Wood
1 non-Pb
102L


White
<0.0004
B
Sensitivity, accuracy,
and precision
Wood
1 w
102L


White
0.341 ± 0.014
(4.11%)
C
Sensitivity, accuracy,
and precision
Wood
1 w
102L


White
0.759 ± 0.017
(2.24%)
D
Sensitivity, accuracy,
and precision
Wood
1 w
102L


White
0.955 ± 0.050
(5.24%)
E
Sensitivity, accuracy,
and precision
Wood
1 w
102L


White
1.167 ± 0.069
(5.91%)
F
Sensitivity, accuracy,
and precision
Wood
1 w
102L


White
1.917± 0.136
(7.09%)









G
Accuracy and
precision (A & P) with
form of Pb
Wood
1c
102L


Yellow
0.744 ± 0.051
(6.85%)
H
A & P with form of Pb
Wood
2c
20 2L


Yellow
1.196 ± 0.040
(3.34%)









1
A & P with multiple
layers
Wood
1 w
20 4L


White
0.741 ± 0.034
(4.59%)
J
A & P with multiple
layers
Wood
2w
30 4L


White
1.115 ± 0.079
(7.09%)









K
A & P with substrate
effects
Steel
1 w
102L


White
0.716 ± 0.067
(9.36%)
L
A & P with substrate
effects
Steel
2w
20 2L


White
1.147 ± 0.052
(4.53%)
M
A & P with substrate
effects
Masonry
1 w
102L


White
0.701 ± 0.034
(4.85%)
N
A & P with substrate
effects
Masonry
2w
20 2L


White
1.164 ± 0.115
(9.88%)
0
A & P with substrate
effects
Plaster
1 w
102L


White
0.821 ±0.114
(13.89%)
P
A & P with substrate
effects
Plaster
2w
20 2L


White
1.322 ± 0.056
(4.24%)









Q
A & P with chemical
interferences
Wood
1 w
102L
Y

White
0.658 ± 0.038
(5.78%)
R
A & P with chemical
interferences
Wood
2w
20 2L
Y

White
1.143 ± 0.085
(7.44%)









S
A & P with color
interferences
Wood
1 w
102L

Y
Red
0.675 ± 0.031
(4.59%)
T
A & P with color
interferences
Wood
2w
20 2L

Y
Red
1.08 ± 0.07
(6.54%)
U
A & P with color
interferences
Wood
1w
102L

Y
Black
0.699 ± 0.044
(6.29%)
V
A & P with color
interferences
Wood
2w
20 2L

Y
Black
1.134 ± 0.098
(8.64%)









A-3

-------
Summary of ORD 2008 Lead-in-Paint Diagnostic Paint Materials5 (cont'd.)




White







No. Films
and Pb
Overlayers
No. and
Chemical
Interferences
Chemical
Interference
Pb
Film
Areal Pbe
Type
Diagnosis
Substrate
Compound3
TVPeb
Al, Ba, Mgc
Fec'd
Colorsd
(mg/cm2)

A & P with all





Yellow,
0.734 ± 0.045
W
potential interferences
Steel
1c 1w
30 4L
Y
Y
Black
(6.13%)

A & P with all





Yellow,
1.078 ± 0.061
X
potential interferences
Steel
1c 1w
30 4L
Y
Y
Black
(5.66%)

A & P with all





Yellow,
1.061 ± 0.084
Y
potential interferences
Steel
1c 1w
30 4L
Y
Y
Black
(7.92%)

A & P with all





Yellow,
0.717 ± 0.072
Z
potential interferences
Masonry
1c 1w
30 4L
Y
Y
Black
(10.04%)

A & P with all





Yellow,
1.062 ± 0.090
AA
potential interferences
Masonry
1c 1w
30 4L
Y
Y
Black
(8.47%)

A & P with all





Yellow,
1.018 ± 0.044
AB
potential interferences
Masonry
1c 1w
30 4L
Y
Y
Black
(4.32%)

A & P with all





Yellow,
0.696 ± 0.064
AC
potential interferences
Plaster
1c 1w
30 4L
Y
Y
Black
(9.20%)

A & P with all





Yellow,
1.03± 0.10
AD
potential interferences
Plaster
1c 1w
30 4L
Y
Y
Black
(9.71%)

A & P with all





Yellow,
0.945 ±0.112
AE
potential interferences
Plaster
1c 1w
30 4L
Y
Y
Black
(11.9%)
aPb compounds: 1 w = 1 white Pb film, 2w = 2 white Pb films; 1c = 1 lead chromate film, 2c = lead chromate films
bOverlayers: 10 = 1 oil-based paint overcoat; 2L = 2 water-base paint overcoats
°Chemical interferences: Elements Al, Ba, Mg added to paint film; red or black iron oxide added for color.
dColors and sources: Red iron oxide added to paint film for red color; black iron oxide added to paint film for black color; yellow from lead
chromate.
eMean + standard deviation for n=6, except K (n=12), Z (n=5), and O and P (n=7). Paint extracted using EPA 3051a and analyzed by
ICP-OES.
A-4

-------
APPENDIX 3
2008 EPA/ORD SPECIFICATION SHEET
Lead-in-Paint Diagnostic Test Material: Type AA
•	Substrate Masonry
•	Source of Material	Date of Preparation:
Synthetic-	10-2-08
Layers- Primer Paint
Lead Chromate Paint Film (0.4 mg/cm2)
Oil-based Paint
White Lead Paint Film with Al, Ba, Mg and Black Iron Oxide (0.8
mg/cm2)
2 Oil-based Paint Overcoats
4 Water-based Paint Overcoats
•	Target Concentration
•	Verification Analysis
Procedure
Preliminary- Paint Film. Four aliquots (each 2.98cm2)
from each of 3 paint films digested
by EPA Method 3051 and analyzed
by ICP-AES for Pb.
	Sampling Points for Paint Films
I p <
, ^'
"!4.
?cm
24.3 cm
A-5
1.2 mg/cm2
Results (mean ± 1 Std. Dev.)
n=12
Pb (mg/cm2) Pb (%)
1.12±0.04 3.90±0.03

-------
Final-	Paint Film on Masonry Substrate.	Pb (ma/cm2) Pb (%)
Two aliquots paint,	n=6
each 1.61 cm2, from each of 3	1.06±0.09 0.825±0.080
masonry blocks collected with
^"square chisel, digested by EPA Method 3051
and analyzed by ICP-AES for Pb.
Sampling Points for Masonry Substrate-based Coupon
0
If)
01
9 cm
Masonry Substrate: 9 cm x 9.5 cm
Paint Film: 5 cm x 7 cm
• References:
1.	Binstock, D.A., D.L. Hardison, P.M. Grohse, and W.F. Gutknecht. Standard Operating
Procedure for Lead in Paint by Hotplate- or Microwave-based Acid Digestion and
Atomic Absorption or Inductively Coupled Plasma Emission Spectrometry, EPA 600/8-
91/213. U.S. EPARTP, NC 1991.
2.	U.S. EPA SW-846 Method 3051. Microwave Assisted Acid Digestion of Sediments,
Sludges, Soils, and Oils. 1994.
A-6

-------
Table of Multielement Values8
(Mean ± Standard Deviation)
Type AA
Element
Mg/g
mg/cm2
Al
4590 ± 330
0.593 ± 0.043
Ba
1350 ±23
0.174 ±0.003
Be
<2
<0.0003
Ca
3.66 ± 0.07%
4.73 ± 0.09
Cd
2.09 ±0.07
0.00027 ± 0.000009
Cr
1480 ±19
0.191 ±0.002
Cu
<4
<0.0005
Fe
1.42 ±0.04%
1.83 ±0.05
Mg
4500 ± 203
0.581 ± 0.026
Mn
116 ± 1
0.015 ±0.00009
Mo
<2
<0.0003
Ni
<8
<0.001
Pb
8070 ± 260
1.04 ±0.03
Sr
28.8 ±0.1
0.004 ± 0.00002
V
3580 ± 68
0.462 ± 0.009
Zn
19.8 ±0.8%
25.6 ±1.0
an = two aliquots paint, each 1.61 cm , from two different blocks, collected with 1/2-in (1.27 cm) square chisel,
digested by EPA Method 3051, and analyzed by ICP-OES.
A-7

-------
APPENDIX 4
Summary of Recipes Used To Make Paint Films for Preparation of
31 Types of Diagnostic Test Kit Materials
Batch
Nominal Pb Cone, (mg/cm2)
and Film Description
Total
wt (g)
Ingredient Weights (g)
White
Pb
Lead
Chromate
ZnO
Boiled
Linseed
Oil
Raw
Linseed
Oil
Mineral
Spirits
Al203
BaCOs
MgC03
Black
Iron
Oxide
Red
Iron
Oxide
19
Blank
810
0
—
600
70
70
70
—
—
—
—
—
39
0.4 White Pb
810
10.5
—
589.5
70
70
70
—
—
—
—
—
35
0.8 White Pb
810
22
—
578
70
70
70
—
—
—
—
—
41
1.0 White Pb
810
27
—
573
70
70
70
—
—
—
—
—
29
1.2 White Pb
810
35
—
565
70
70
70
—
—
—
—
—
45
2.0 White Pb
810
54
—
546
70
70
70
—
—
—
—
—
46
0.4 Lead Chromate
820
—
14
586
70
70
80
—
—
—
—
—
37
0.8 Lead Chromate
820
—
26
574
70
70
80
—
—
—
—
—
49
0.4 White Pb with Al, Ba, Mg
810
10.5
—
431
70
70
70
65.2
37.6
55.8
—
—
50
0.8 White Pb with Al, Ba, Mg
810
22
—
419.4
70
70
70
65.2
37.6
55.8
—
—
53
0.4 White Pb with Black Iron
Oxide
810
10.5
—
524.5
70
70
70
—
—
—
65
—
54
0.8 White Pb with Black Iron
Oxide
810
22
—
513
70
70
70
—
—
—
65
—
55
0.4 White Pb with Red Iron
Oxide
810
10.5
—
468
70
70
70
—
—
—
—
121.5
56
0.8 White Pb with Red Iron
Oxide
810
22
—
456.5
70
70
70
—
—
—
—
121.5
51
0.4 White Pb with Al, Ba, Mg,
Black Iron Oxide
810
10.5
—
365.9
70
70
70
65.2
37.6
55.8
65
—
52
0.8 White Pb with Al, Ba, Mg,
Black Iron Oxide
810
22
—
354.4
70
70
70
65.2
37.6
55.8
65
—
Method: Ball mill 69 rpm, 1 -L jar, roll for 96 h.

-------

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United States
Environmental Protection
Agency
Office of Research and Development (8101R)
Washington, DC 20460
STANDARD
POSTAGE & FEES PAID
EPA
PERMIT NO. G-35
Official Business
Penalty for Private Use
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