Document ID: OSHA-H005C-2006-0870-1577
Agency: osha
Document Type: Supporting & Related Material
Title: 
Posted Date: 2015-08-07T04:00Z

CONTROL TECHNOLOGY AND EXPOSURE ASSESSMENT FOR

ELECTRONIC RECYCLING OPERATIONS

ELKTON FEDERAL CORRECTIONAL INSTITUTION

ELKTON, OHIO

    

REPORT DATE:

August 2008

FILE NO.:

EPHB 326-12a

PRINCIPAL AUTHORS:

Dan Almaguer, MS

G. Edward Burroughs, PhD, CIH, CSP

Alan Echt, MPH, CIH

David Marlow

U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES

Centers for Disease Control and Prevention

National Institute for Occupational Safety and Health

Division of Applied Research and Technology

4676 Columbia Parkway, R5

Cincinnati, Ohio  45226

SITES SURVEYED:	Unicor Recycling Operations

	Federal Correctional Institution

	Elkton, Ohio

NAICS:	562920

SURVEY DATE:	February 26 – March 2, 2007

	December 11 – 13, 2007

SURVEY CONDUCTED BY:	Dan Almaguer, MS

	Ed Burroughs, Ph.D., CIH, CSP

	Keith Crouch, Ph.D.

	Alan Echt, MPH, CIH

	Dave Marlow

	Amir Khan

								

DISCLAIMER

Mention of company names or products does not constitute endorsement by
the Centers for Disease Control and Prevention.

The findings and conclusions in this report do not necessarily reflect
the views of the National Institute for Occupational Safety and Health.

CONTENTS

Executive Summary	p 6

I.	Introduction	p 8

II.	Process Description	p 10

III.	Sampling and Analytical Methods	p 12

IV.	Occupational Exposure Limits and Health Effects	p 14

	A.	Inhalation Criteria	p 16

		Barium	p 17

		Beryllium	p 17

		Cadmium	p 18

		Lead	p 19

		Nickel	p 19

		Dust	p 20

		Yttrium	p 20

	B.	Surface Contamination Criteria	p 20

		Lead	p 21

		Beryllium	p 22

		Cadmium	p 22

		Nickel	p 22

		Barium	p 22

	C.	Noise Exposure Criteria	p 22

V.	Results	and Discussion	p 23

	A.	Bulk Material Sample Results	p 23

	B.	Surface Wipe Sample Results	p 24

	C.	Air Sample Results	p 24

	D.	Particle Size Sample Results	p 26

	E. 	Sound Level Measurements	p 27

	F.  	Air Flow Observations	p 28

VI.	Conclusions	p 29

Tables, Appendices and Figures

Table 1	Summary Statistics for Airborne Metal Measurements

Table 2 	Airborne Metal Measurements

Table 3 	Impactor Samples

Table 4 	Wipe Sample Results

Table 5	Composition of Bulk Dust Samples from the Glass Breaking
Operation

Table 6	Noise Exposure Measurements

Appendix A	Occupational Exposure Criteria for Metal/Elements

Appendix B	Metallic Composition of Bulk Dust Samples from the Glass
Breaking Operation

Appendix C	Metallic Composition of Wipe Samples 

Appendix D	Metallic Composition of Filter Samples 

Figure I	Diagram of the Unicor factory located within the FCI main
compound

Figure II 	Diagram of the Unicor facility in the Federal Satellite Low
(FSL)

Figure III	Diagram of the warehouse handling electronics recycling
operations

Figure IV	Diagram of the glass breaking operation within the FCI 

Figure V	Elkton Warehouse

Figure VI	Elkton Recycling Factory Disassembly Area

Figure VII	Glass Breaking Operation

Figure VIII	Filter Change Operation in Glass Breaking Operation Showing
High Dust Levels

Figure IX	Five cut particle size distribution from impactor data

Figure X	Three cut particle size distribution from impactor data

EXECUTIVE SUMMARY

Researchers from the National Institute for Occupational Safety and
Health (NIOSH) conducted a study of the recycling of electronic
components at the Federal Prison Industries facilities (aka, Unicor) in
Elkton, Ohio, to assess workers’ exposures to metals and other
occupational hazards, including noise, associated with these operations.
 An in-depth evaluation was conducted from February 26 to March 2, 2007,
and a follow-up survey was conducted from December 11 to 13, 2007, to
evaluate changes made in selected activities as a result of initial
recommendations. 

The electronics recycling operations at Elkton can be organized into
four production processes: a) receiving and sorting, b) disassembly, c)
glass breaking operations, and d) packaging and shipping.  A fifth
operation, cleaning and maintenance, was also addressed but is not
considered a production process per se.  It is known that lead (Pb),
cadmium (Cd), and other metals are used in the manufacturing of
electronic components and pose a risk to workers involved in recycling
of electronic components if the processes are not adequately controlled
or the workers are not properly trained and provided appropriate
personal protective clothing and equipment.  

Methods used to assess worker exposures to metals during this evaluation
included: personal breathing zone and area sampling for airborne metals;
particle size sampling; surface wipe sampling to assess surface
contamination; and bulk material samples to determine the composition of
settled dust.  Samples were analyzed for up to 31 metals with five
selected elements (barium, beryllium, cadmium, lead and nickel) given
emphasis.  Noise exposures were determined using personal dosimeters.  

The results of air sampling conducted during the February / March visit
indicated that the highest exposures occurred to workers during the
filter change-out maintenance operation. Airborne concentrations of Cd
and Pb measured during filter change-out showed an 8-hour time weighted
average of about 150 times the OSHA Permissible Exposure Limit (PEL) for
Cd and 15 times the OSHA PEL for Pb for one of the two workers.  Air
samples collected on a second worker showed airborne concentrations of
30 times the PEL for Cd and 4 times the PEL for Pb.  In both cases the
results showed that the Cd concentrations exceeded the assigned
protection factor for the powered air-purifying respirator being used by
the workers.  An over-exposure to Cd was also found during the weekly
clean-up operation.

Although beryllium is used in consumer electronics and computer
components, such as disk drive arms (beryllium-aluminum), electrical
contacts, switches, and connector plugs (copper-beryllium) and printed
wiring boards [Willis and Florig 2002, Schmidt 2002], most beryllium
“in consumer products is used in ways that are not likely to create
beryllium exposures during use and maintenance” [Willis and Florig
2002].  This may account for the fact that beryllium in this study was
measured in only two samples at levels above the detection limit of the
analytical method.  The removal and sorting of components seen here is
typical of a maintenance activity (components are removed from the cases
and sorted, rather than removed and replaced).  Other e-recycling
activities that include further processing, such as shredding of the
components, may produce higher exposures to beryllium but these
processes are not done at this facility.

Samples collected during routine daily glass breaking operations were
less than 20% of the OSHA PELs for both Cd and Pb.  Samples collected on
disassembly workers in the general factory area of all three buildings
ranged from non-detectable to 10% of the OSHA PEL for Cd and ranged from
non-detectable to 5% of the OSHA PEL for Pb.  Unless specified, results
of samples presented are for duration of sample and not calculated on an
8 hour time weighted average basis.

  

Lead, cadmium and other heavy metals were detected in the surface wipe
and bulk dust samples.  There are few established standards available
for wipe samples with which to compare these data. Most of the surfaces
tested for lead indicated levels exceeding the most stringent criteria.
The wipe sample results can not be used to determine when the
contamination occurred.  They only represent the surface contamination
present at the time the sample was collected.

Measurement of noise levels indicated several samples exceeding the REL
and TLV of 85 dBA.  One sample exceeded the PEL of 90 dBA and 3 other
samples exceeded 50% of the allowable dose requiring that those
employees be placed in a hearing conservation program.

As a result of the February/March 2007 survey, it was recommended that
the filter change operation be modified and that improved dust
suppression methods be used to reduce airborne concentrations.  Specific
recommendations (implemented prior to the second evaluation) include: 1)
the use of water spray to suppress dust during the filter change-out
operation; 2) the immediate bagging and disposal of used filters rather
than attempting to clean and re-use them; and 3) the use of HEPA vacuums
and wet mopping to remove dust from the floor and work surfaces.
Measurements made during the follow-up survey in December 2007 indicated
significant reductions in the levels of airborne contaminants during
this modified operation although respiratory protection during the
filter change operation continues to be necessary and other improvements
are needed.  These improvements are described in detail later in this
report.  

Recommendations resulting from this study include:

The respiratory protection program for this facility should be evaluated
for this operation in order to ensure that it complies with OSHA
regulations.  

Attention should be focused on practices to prevent accidental ingestion
of lead. 

Management should evaluate the feasibility of providing and laundering
work clothing for all workers in the recycling facility.

Change rooms should be equipped with separate storage facilities for
work clothing and for street clothes to prevent cross-contamination.   

A hearing conservation program must be implemented for workers in the
glass breaking operation.

All Unicor operations should be evaluated from the perspective of
health, safety and the environment in the near future. 

A comprehensive program is needed within the Bureau to assure both staff
and inmates a safe and healthy workplace.

I.	INTRODUCTION

Researchers from the National Institute for Occupational Safety and
Health (NIOSH) conducted a study of exposures to metals and other
occupational hazards associated with the recycling of electronic
components at the Federal Prison Industries (aka, Unicor) in Elkton,
Ohio.  The principal objectives of this study were:

1.	To measure full-shift, personal breathing zone exposures to metals
including barium, beryllium, cadmium, lead and nickel;  

2.	To evaluate contamination of surfaces in the work areas that could
permit skin contact or allow re-suspension of metals into the air;

To identify and describe the control technology and work practices in
use in operations associated with occupational exposures to metals, as
well as to determine additional controls, work practices, substitute
materials, or technology that can further reduce occupational exposures;

4.	To evaluate the use of personal protective equipment in operations
involved in the recycling of electronic components; and,

5.	To determine the size distribution of airborne particles for purposes
of toxicity and control.

Other objectives such as a preliminary evaluation of noise exposures and
visual observations of undocumented hazards, were secondary to those
listed above but are discussed as appropriate in this document.

An initial walk-through evaluation was conducted on November 29, 2006,
to observe processes and conditions in order to prepare for subsequent
testing.  An in-depth evaluation was conducted from February 26 to March
2, 2007, during which two full shifts of environmental monitoring were
conducted for the duration of normal plant operations.  An additional
two days of monitoring were conducted during cleaning and maintenance as
described later in Section II (Process Description) and Section III
(Sampling and Analytical Methods).  A follow-up survey was conducted
December 11 – 13, 2007, to evaluate changes made in the cleaning and
maintenance activities as a result of the recommendations contained in
Section VI (Conclusions and Recommendations).

Computers and their components contain a number of hazardous substances.
 Among these are “platinum in circuit boards, copper in transformers,
nickel and cobalt in disk drives, barium and cadmium coatings on
computer glass, and lead solder on circuit boards and video screens”
[Chepesiuk 1999].  The Environmental Protection Agency (EPA) notes that
“In addition to lead, electronics can contain chromium, cadmium,
mercury, beryllium, nickel, zinc, and brominated flame retardants”
[EPA 2008].  Schmidt [2002] linked these and other substances to their
use and location in the “typical” computer: lead used to join metals
(solder) and for radiation protection, is present in the cathode ray
tube (CRT) and printed wiring board (PWB).  Aluminum, used in structural
components and for its conductivity, is present in the housing, CRT,
PWB, and connectors.  Gallium is used in semiconductors; it is present
in the PWB.  Nickel is used in structural components and for its
magnetivity; it is found in steel housing, CRT and PWB.  Vanadium
functions as a red-phosphor emitter; it is used in the CRT.  Beryllium,
used for its thermal conductivity, is found in the PWB and in
connectors.  Chromium, which has decorative and hardening properties,
may be a component of steel used in the housing.  Cadmium, used in
Ni-Cad batteries and as a blue-green phosphor emitter, may be found in
the housing, PWB and CRT.  Cui and Forssberg [2003] note that cadmium is
present in components like SMD chip resistors, semiconductors, and
infrared detectors.  Mercury may be present in batteries and switches,
thermostats, sensors and relays [Schmidt 2002, Cui and Forssberg 2003],
found in the housing and PWB.  Arsenic, which is used in doping agents
in transistors, may be found in the PWB [Schmidt 2002].

Lee et al. [2004] divided the personal computer into three components,
the main machine, monitor, and keyboard.  They further divided the CRT
of a color monitor into the “(1) panel glass (faceplate), (2) shadow
mask (aperture), (3) electronic gun (mount), (4) funnel glass and (5)
deflection yoke.  Lee et al. [2004] note that panel glass has a high
barium concentration (up to 13%) for radiation protection and a low
concentration of lead oxide.  The funnel glass has a higher amount of
lead oxide (up to 20%) and a lower barium concentration.  They analyzed
a 14-in Philips color monitor by electron dispersive spectroscopy and
reported that the panel contained silicon, oxygen, potassium, barium and
aluminum in concentrations greater than 5% by weight, and titanium,
sodium, cerium, lead, zinc, yttrium, and sulfur in amounts less than 5%
by weight.  Analysis of the funnel glass revealed greater than 5%
silicon, oxygen, iron and lead by weight, and less than 5% by weight
potassium, sodium, barium, cerium, and carbon.  Finally, Lee et al.
[2004] noted that the four coating layers are applied to the inside of
the panel glass, including a layer of three fluorescent colors (red,
blue and green phosphors) that contain various metals, and a layer of
aluminum film to enhance brightness.

German investigators [BIA 2001, Berges 2008a] broke 72 cathode-ray tubes
using three techniques (pinching off the pump port, pitching the anode
with a sharp item, and knocking off the cathode) in three experiments
performed on a test bench designed to measure emissions from the
process.  Neither lead nor cadmium was detected in the total dust, with
one exception, where lead was detected at a concentration of 0.05
mg/cathode ray tube during one experiment wherein the researchers
released the vacuum out of 23 TVs by pinching off the pump port [BIA
2001, Berges 2008b].  They described this result as “sufficiently low
that a violation of the German atmospheric limit value of 0.1 mg/m3 need
not generally be anticipated” [BIA 2001].  The researchers noted that
“the working conditions must be organized such that skin contact with
and oral intake of the dust are excluded” [BIA 2001].

However, there are few articles documenting occupational exposures among
electronics recycling workers.  Sjödin et al. [2001] and
Pettersson-Julander et al. [2004] have reported potential exposures of
electronics recycling workers to flame retardants while they dismantled
electronic products, although no retardants were used in this facility. 
Recycling operations in the Elkton facility are limited to disassembly
and sorting tasks, with the exception of breaking CRTs and stripping
insulation from copper wiring.  Disassembly and sorting probably poses
less of a potential hazard to workers than tasks that disrupt the
integrity of the components, such as shredding or desoldering PWBs.

The process of greatest concern was the glass breaking operation
(described below) that releases visible emissions into the workroom
atmosphere.  Material safety data sheets and other information on
components of CRTs broken in this operation listed several metals,
including Pb, Cd, Be and Ni.  In addition, FOH investigators expressed a
particular interest in Ba.

II.	PROCESS DESCRIPTION 

The recycling of electronic components at the Elkton Federal
Correctional Institution (FCI) is done in three separate buildings: 1)
the main factory located within the FCI main compound; 2) the Federal
Satellite Low (FSL); and 3) the warehouse.  Diagrams of these work areas
are shown in Figures I, II and III, respectively, with an enlargement of
the glass breaking operation in Figure IV.  These figures provide a
general visual description of the layout of the work process, although
workers often moved throughout the various areas in the performance of
their tasks.  Photographs from these areas are also included and
identified below.  

The electronics recycling operations can be organized into four
production processes: a) receiving and sorting, b) disassembly, c) glass
breaking operations, and d) packaging and shipping.  A fifth operation;
cleaning and maintenance, will also be addressed but is not considered a
production process per se.

Incoming materials to be recycled are received at the warehouse (see
Figure III) where they are examined and sorted.  During this evaluation
it appeared that the bulk of the materials received were computers,
either desktop or notebooks, or related devices such as printers.  Some
items, notably notebook computers, could be upgraded and resold, and
these items were sorted out for that task.  

After electronic memory devices (e.g., hard drives, discs, etc.) were
removed and degaussed or shredded, computer central processing units
(CPUs), servers and similar devices were sent for disassembly; monitors
and other devices (e.g., televisions) that contain CRTs were separated
and sent for disassembly and removal of the CRT.  Printers, copy
machines and any device that could potentially contain toner, ink, or
other expendables were segregated and inks and toners were removed prior
to being sent to the disassembly area.  

In the disassembly process (see Figures I and II), external cabinets,
usually plastic, were removed from all devices and segregated.  Valuable
materials such as copper wiring and aluminum framing were removed and
sorted by grade for further treatment if necessary.  Components such as
circuit boards or chips that may have value or may contain precious
metals such as gold or silver were removed and sorted. With few
exceptions each of the approximately 85 workers in the main factory will
perform all tasks associated with the disassembly of a piece of
equipment into the mentioned components with the use of powered and
un-powered hand tools (primarily screwdrivers and wrenches), with a few
workers collecting the various parts and placing them into the proper
collection bin.  Work tasks including removing screws and other
fasteners from cabinets, unplugging or clipping electrical cables,
removing circuit boards, and using whatever other methods necessary to
break these devices into their component parts.  Essentially all
components currently are sold for some type of recycling.  

The third production process to be evaluated was the glass breaking
operation where CRTs from computer monitors and TVs were sent for
processing.  This was an area of primary interest in this evaluation due
to concern from staff, review of process operations and materials
involved, and observations during an initial walk-through.  This was the
only process where local exhaust ventilation was utilized or where
respiratory protection was in universal use.  Workers in other locations
would wear eye protection and occasionally would voluntarily wear a
disposable respirator.  The local exhaust ventilation system consisted
of a large walk-in hood, approximately 8 ft high and 16 ft wide and 6 ft
deep, with 2 or 3 workers positioned toward the front.  Air was pulled
from behind the workers, past the work area where contaminant was
released, and through a filtration system.  The filtration system
consisted of a blanket filter, a bank of pocket filters, and a high
efficiency particulate air (HEPA) filter to remove progressively smaller
particles from the air before exhausting into a storage area behind the
hood.

Workers in the glass breaking operation wore powered air-purifying
respirators (PAPRs), (MB14-72 PAPR w/ Super Top Hood, Woodsboro, MD,
Global Secure Safety).  Respirators, work boots, gloves and coveralls
were donned and doffed in the changing area of the glass breaking room
(see Figure IV) where street shoes were stored during the work day and
the PPE was stored during off time.  CRTs that had been removed from
their cases were brought to this process area where they were placed on
a metal grid for breaking.  First the electron gun was removed by
tapping with a hammer to break it free from the tube.  Then a series of
hammer blows was used to break the funnel glass and allow it to fall
through the metal grid into large Gaylord boxes (cardboard boxes
approximately 3 feet tall designed to fit on a standard pallet)
positioned below the grid.  Finally, any internal metal framing or
lattice was removed before the panel glass was broken with a hammer and
also allowed to fall into a Gaylord box.  During the days of sampling
the glass breaking operation was in “normal production” with regard
to the number of CRTs broken.  (Various sources stated that “normal”
ranged from 250 to almost 800.)  The count was not recorded for the
March study, but during the December visit 442 and 265 monitors were
broken on the two days of sampling.  No count was made by the survey
team regarding the number of color vs monochrome monitors broken.

The final production process, packing and shipping, returned the various
materials segregated during the disassembly and glass breaking processes
to the warehouse to be sent to contracted purchasers of those individual
materials.  To facilitate shipment some bulky components such as plastic
cabinets or metal frames were placed in a hydraulic bailer to be
compacted for easier shipping.  Other materials were boxed or
containerized and removed for subsequent sale to a recycling operation.

In addition to monitoring routine daily activities in the four
production processes described above, environmental monitoring was
conducted to evaluate exposures during a weekly cleaning operation in
the glass breaking operation and during the replacement of filters in
the local exhaust ventilation system used for the glass breaking
operation.  The weekly cleaning involves all six workers in this area to
perform routine cleaning operations such as sweeping and vacuuming. 
This task, done only in the glass breaking operation and taking
approximately a half day, requires that all equipment in the area is
either vacuumed with a HEPA vacuum or wiped with a wet mop.  This same
procedure is used for all walls, work surfaces (including the exposed
surfaces of the blanket filter), and floors.  Any areas where dust might
accumulate are cleaned with one of these techniques.  During the initial
study dry sweeping was used to clean floors, but it was recommended that
this practice be replaced with the vacuuming or mopping and during the
second study that change was in place.  Workers wore their normal work
clothing during this procedure and the local exhaust ventilation system
was in operation.

The filter change operation is normally performed by two workers (three
were involved during the time of the second study because one was in
training) who wear disposable Tyvek coveralls, gloves and PAPRs while
they remove all three sets of filters, clean the system, and replace the
filters.  The filter change is a maintenance operation that occurs at
approximately monthly intervals during which the ventilation system is
shut down and all three sets of filters are removed and replaced (see
Figure IV).  Initially the blanket filter is vacuumed then removed. 
Then the pocket filters that are located behind the blanket filter are
removed and the containment structure for both is vacuumed.  Finally the
HEPA filters, which are in a separate structure downstream from the fan,
are removed and this area is vacuumed.  During the initial sampling
visit all filters were cleaned by vacuuming and/or by shaking to remove
dust, and re-installed.  The practice of replacing all filters as part
of this operation was implemented prior to the second sampling visit and
the entire process was wetted with a water spray prior to filter
removal.  This operation was of particular interest because of concern
expressed by management and workers and anticipation of elevated
exposures.

Subsequent to the initial monitoring of airborne particulate during the
filter change operation, modifications were made to the procedure used
for this process.  The recommended changes included: 1) the immediate
bagging and disposal of used filters rather than attempting to clean and
re-use them; 2) the use of a water spray to suppress dust during the
filter change operation; and 3) the use of HEPA vacuums and wet mopping
to remove dust from the floor and work surfaces.  The procedure was
modified by the addition of a “spray down” step in which all filters
were wetted with a water mist prior to removal, and the filters were
then immediately bagged in plastic for disposal rather than being
cleaned for re-use. 

III.	SAMPLING AND ANALYTICAL METHODS  

Methods used to assess worker exposures in this workplace evaluation
included: personal breathing zone and area sampling for airborne metals;
particle size sampling; surface wipe sampling to assess surface
contamination; and bulk material samples to determine the composition of
settled dust.  Material safety data sheets and background information on
CRTs and other processes in this operation listed several metals,
including Pb, Cd, Be and Ni.  Additionally, Federal Occupational Health
(FOH) personnel expressed specific interest in Ba.  

 filter (0.8 μm pore-size mixed cellulose ester filter) in a 3-piece,
clear plastic cassette sealed with a cellulose shrink band.  These
samples were subsequently analyzed for metals using inductively coupled
plasma spectroscopy (ICP) according to NIOSH Method 7300 [NIOSH 1994]
with modifications.  It is possible to determine both airborne
particulate as well as metals on the same sample by using a pre-weighed
filter (for both respirable and total particulate samples) and then
post-weighing that filter to determine weight gain before digesting for
metals analysis.  This analytical technique produces a measure for dust
and a measure of 31 elements, including the five of particular interest
mentioned above, and that information is appended to this report. 
Because Method 7300 is an elemental analysis, the laboratory report
describes the amount of the element present in each sample (μg/sample)
as the element, regardless of the compound in which the element was
present in the sample.

During the follow-up visit, sampling was conducted for respirable
particulates.  The respirable portion of a representative subset of
samples was separated for collection using 37 mm aluminum cyclones (Cat.
225-01-02, SKC Inc., Eighty Four, PA) at a flow rate of 2.5 L/min, and
analysis by weight, as specified in NIOSH method 0600 [NIOSH 1994]. 
This was done to determine the fraction of airborne contaminant in the
respirable size range. Those samples were analyzed using NIOSH Method
7300 [NIOSH 1994] like those above. 

μm aerodynamic diameter.  The sampling flow rate for these impactors
was 9 L/min, provided by a calibrated Leland Legacy™ sampling pump
(SKC, Inc., Eighty Four, PA) [Misra et al. 2002].  A 25-mm diameter, 0.8
μm pore size PVC filter was used on each stage of the impactor to
collect particles.  A 37-mm diameter, 5 μm pore size PVC filter was
used as a backup to collect all particles that were not impacted on the
previous four stages.  The impactor filters were analyzed by ICP in
accordance with NIOSH Method 7300 modified for microwave digestion
[NIOSH 1994].  During the follow-up study cyclones were used rather than
impactors to provide a measure of respirable fraction for metals and
total dust.

Bulk material samples were collected by gathering a few grams of settled
dust or material of interest and transferring this to a glass collection
bottle for storage and shipment.  These samples were analyzed for metals
using NIOSH Method 7300 [NIOSH 1994] modified for bulk digestion.  

host Wipes™ were sent to the laboratory to be analyzed for metals
according to NIOSH Method 7303 [NIOSH 1994]. Palintest wipes were
analyzed for beryllium using the Quantech Fluorometer (Model FM109515,
Barnstead International, Dubuque, Iowa) for spectrofluorometric analysis
by NIOSH Method 9110 [NIOSH 1994]. 

An initial assessment of noise levels during various tasks in all
operations was made during the first in-depth study using a hand held
sound level meter.  This brief sound-level survey was used to determine
where to target noise dosimetry during the follow-up study.  During the
follow-up study time weighted average noise exposures were determined
using personal dosimeters (Quest Technologies model Q300, Oconomowoc,
WI) capable of simultaneously logging sound pressure levels under three
sets of parameters.  For this evaluation data are reported using both
the OSHA and NIOSH parameters as follows:

	OSHA	NIOSH

Criteria (dB)	90	85

Exchange rate	5	3

Threshold	80	0

Weight	A	A

Time constant	Slow	Slow

All dosimeters and sound level meters were calibrated on-site prior to
use with a 110 dB source and data were downloaded to a laptop computer.

  

Observations regarding work practices and use of personal protective
equipment were recorded.  Information was obtained from conversations
with the workers and management to determine if the sampling day was a
typical workday to help place the sampling results in proper
perspective.  

A qualitative evaluation of the glass-breaking booth ventilation system
was performed during the initial site visit.  A smoke machine and smoke
tubes were used to study the air flow patterns in the glass break area. 
The area was separated into four areas (A, B, C and D; see Figure VII)
by transparent vinyl curtains hanging from ceiling to floor, and slit
vertically at about 6 inch intervals to permit personnel and apparatus
to pass through.  The ventilation system was intended to capture any
emissions of respirable dust, as well as larger airborne debris,
generated during the CRT breaking process.  No workers were present in
the glass breaking operation at the time of this smoke study.  Smoke was
released in all four areas in order to visually observe air flow
patterns.

OCCUPATIONAL EXPOSURE LIMITS AND HEALTH EFFECTS 

In evaluating the hazards posed by workplace exposures, NIOSH
investigators use mandatory and recommended occupational exposure limits
(OELs) for specific chemical, physical, and biological agents.
Generally, OELs suggest levels of exposure to which most workers may be
exposed up to 10 hours per day, 40 hours per week for a working lifetime
without experiencing adverse health effects. It is, however, important
to note that not all workers will be protected from adverse health
effects even though their exposures are maintained below these levels. A
small percentage may experience adverse health effects because of
individual susceptibility, a pre-existing medical condition, and/or
hypersensitivity (allergy). In addition, some hazardous substances may
act in combination with other workplace exposures, the general
environment, or with medications or personal habits of the worker to
produce health effects even if the occupational exposures are controlled
at the level set by the exposure limit. Combined effects are often not
considered in the OEL. Also, some substances can be absorbed by direct
contact with the skin and mucous membranes in addition to being inhaled,
thus contributing to the overall exposure. Finally, OELs may change over
the years as new information on the toxic effects of an agent become
available.

Most OELs are expressed as a time-weighted average (TWA) exposure. A TWA
refers to the average exposure during a normal 8- to 10-hour workday.
Some chemical substances and physical agents have recommended short-term
exposure limits (STEL) or ceiling values where there are health effects
from higher exposures over the short-term. Unless otherwise noted, the
STEL is a 15-minute TWA exposure that should not be exceeded at any time
during a workday, and the ceiling limit is an exposure that should not
be exceeded at any time, even instantaneously.

 

In the U.S., OELs have been established by Federal agencies,
professional organizations, state and local governments, and other
entities. Some OELs are mandatory, legal limits; others are
recommendations. The U.S. Department of Labor Occupational Safety and
Health Administration (OSHA) Permissible Exposure Limits (PELs) [29 CFR
1910 (general industry); 29 CFR 1926 (construction industry); and 29 CFR
1915, 1917 and 1918 (maritime industry)] are legal limits that are
enforceable in workplaces covered under the Occupational Safety and
Health Act and in Federal workplaces under Executive Order 12196 [NARA
2008]. NIOSH Recommended Exposure Limits (RELs) are recommendations that
are made based on a critical review of the scientific and technical
information available on the prevalence of hazards, health effects data,
and the adequacy of methods to identify and control the hazards.
Recommendations made through 1992 are available in a single compendium
[NIOSH 1992]; more recent recommendations are available on the NIOSH Web
site (http://www.cdc.gov/niosh). NIOSH also recommends preventive
measures (e.g., engineering controls, safe work practices, personal
protective equipment, and environmental and medical monitoring) for
reducing or eliminating the adverse health effects of these hazards. The
NIOSH Recommendations have been developed using a weight of evidence
approach and formal peer review process. Other OELs that are commonly
used and cited in the U.S. include the Threshold Limit Values (TLVs) ®
recommended by the American Conference of Governmental Industrial
Hygienists (ACGIH) ®, a professional organization [ACGIH 2008]. ACGIH®
TLVs® are considered voluntary guidelines for use by industrial
hygienists and others trained in this discipline “to assist in the
control of health hazards.” Workplace Environmental Exposure Levels
(WEELs) are recommended OELs developed by AIHA, another professional
organization. WEELs have been established for some chemicals “when no
other legal or authoritative limits exist” [AIHA 2007]. 

Employers should understand that not all hazardous chemicals have
specific OSHA PELs and for many agents, the legal and recommended limits
mentioned above may not reflect the most current health-based
information.  However, an employer is still required by OSHA to protect
their employees from hazards even in the absence of a specific OSHA PEL.
In particular, OSHA requires an employer to furnish employees a place of
employment that is free from recognized hazards that are causing or are
likely to cause death or serious physical harm [Occupational Safety and
Health Act of 1970, Public Law 91–596, sec. 5(a)(1)]. Thus, NIOSH
investigators encourage employers to make use of other OELs when making
risk assessment and risk management decisions to best protect the health
of their employees. NIOSH investigators also encourage the use of the
traditional hierarchy of controls approach to eliminating or minimizing
identified workplace hazards. This includes, in preferential order, the
use of: (1) substitution or elimination of the hazardous agent, (2)
engineering controls (e.g., local exhaust ventilation, process
enclosure, dilution ventilation) (3) administrative controls (e.g.,
limiting time of exposure, employee training, work practice changes,
medical surveillance), and (4) personal protective equipment (e.g.,
respiratory protection, gloves, eye protection, hearing protection). 

Both the OSHA PELs and ACGIH® TLVs® address the issue of combined
effects of airborne exposures to multiple substances [29 CFR
1910.1000(d)(1)(i), ACGIH 2008].  ACGIH® [2008] states:

When two or more hazardous substances have a similar toxicological
effect on the same target organ or system, their combined effect, rather
than that of either individually, should be given primary consideration.
 In the absence of information to the contrary, different substances
should be considered as additive where the health effect and target
organ or system is the same. That is, if the sum of

 			Eqn. 1

exceeds unity, the threshold limit of the mixture should be considered
as being exceeded (where C1 indicates the observed atmospheric
concentration and T1 is the corresponding threshold limit…).

A.  Exposure Criteria for Occupational Exposure to Airborne Chemical
Substances

The OELs for the five primary contaminants of interest, in micrograms
per cubic meter (µg/m3), are summarized and additional information
related to those exposure limits is presented below.

Occupational Exposure Limits for Five Metals of Primary Interest
(µg/m3)

	Barium (Ba)	Beryllium (Be)	Cadmium (Cd)	Lead (Pb)	Nickel (Ni)

REL	500 TWA	0.5 TWA	Lowest Feasible Concentration	50 TWA	15 TWA

PEL	500 TWA	2 TWA

5 (30 minute ceiling)

25 (peak exposure never to be exceeded)	5 TWA	50 TWA	1000 TWA

TLV	500 TWA	2 TWA

10 (STEL)	10 (total) TWA

2 (respirable) TWA	50 TWA	1500 TWA (elemental)

100 TWA (soluble inorganic compounds)

200 TWA (insoluble inorganic compounds

While this subset of five metals has been selected for consideration
through the body of this report because their presence was noted on
MSDSs or other information pertaining to CRTs and other processes at
this facility (beryllium, cadmium, lead and nickel) or due to the
interest expressed in barium exposures by FOH personnel, the
occupational exposure limits of all 31 metals quantified in this work
are listed in Appendix A.  Note that these limits refer to the
contaminant as the element (e.g., the TLVs®, beryllium and compounds,
as Be; cadmium and compounds, as Cd [ACGIH 2008]).  Additionally, the
OELs for dust and yttrium are presented here since these substances were
found at high levels.

Occupational Exposure Criteria for Barium (Ba)

The current OSHA PEL, NIOSH REL, and ACGIH® TLV® is 0.5 mg/m3 as a TWA
for airborne barium exposures (barium and soluble compounds, except
barium sulfate, as barium) [29 CFR 1910.1000, NIOSH 2005, ACGIH 2008]. 
There is no AIHA WEEL for barium [AIHA 2007].  Skin contact with barium,
and many of its compounds, may cause local irritation to the eyes, nose,
throat and skin, and may cause dryness and cracking of the skin and skin
burns after prolonged contact [Nordberg 1998].   

Occupational Exposure Criteria for Beryllium (Be)

The OSHA general industry standard sets a beryllium PEL of 2 µg/m3 for
an 8-hour TWA, a ceiling concentration of 5 µg/m3, not to exceed 30
minutes and a maximum peak concentration of 25 µg/m3, not to be
exceeded for any period of time [29 CFR 1910.1000].  The NIOSH REL for
beryllium is 0.5 µg/m3 for up to a 10-hour work day, during a 40-hour
workweek [NIOSH 2005].  The current TLV® is an 8-hr TWA of 2 µg/m3,
and a STEL of 10 µg/m3 [ACGIH 2008].  The ACGIH® published a notice of
intended changes for the beryllium TLV® to 0.05 μg/m3 TWA and 0.2
μg/m3 STEL based upon studies investigating both chronic beryllium
disease and beryllium sensitization [ACGIH 2008].  There is no AIHA WEEL
for beryllium [AIHA 2007].  Beryllium has been designated a known human
carcinogen by the International Agency for Research on Cancer [IARC
1993]. 

Occupational Exposure Criteria for Cadmium (Cd)

icroglobulin in urine (β2-M) [29 CFR 1910.1027 Appendix A]. An employee
whose biological testing results during both the initial and follow-up
medical examination are elevated above the following trigger levels must
be medically removed from exposure to cadmium at or above the action
level: (1) CdU level: above 7 μg/g creatinine, or (2) CdB level: above
10 μg/liter of whole blood, or (3) β2-M level: above 750 μg/g
creatinine and (a) CdU exceeds 3 μg/g creatinine or (b) CdB exceeds 5
μg/liter of whole blood [OSHA 2004].

The ACGIH® TLV® for cadmium and compounds as cadmium is 10 μg/m3  as
a TWA, and 2 μg/m3 TWA for the respirable fraction of airborne cadmium
and compounds, as cadmium  [ACGIH 2008].  The ACGIH® also published a
Biological Exposure Index® that recommends that cadmium blood level be
controlled at or below 5 μg/L and urine level to be below 5 μg/g
creatinine [ACGIH 2008].  There is no AIHA WEEL for cadmium [AIHA 2007].

In 1976, NIOSH recommended that exposures to cadmium in any form should
not exceed a concentration greater than 40 μg/m3 as a 10-hour TWA or a
concentration greater than 200 μg/m3 for any 15-minute period, in order
to protect workers against kidney damage and lung disease.  In 1984,
NIOSH issued a Current Intelligence Bulletin, which recommended that
cadmium and its compounds be regarded as potential occupational
carcinogens based upon evidence of lung cancer among a cohort of workers
exposed in a smelter [NIOSH 1984].  NIOSH recommends that exposures be
reduced to the lowest feasible concentration [NIOSH 2005].  This NIOSH
REL was developed using a previous NIOSH policy for carcinogens (29 CFR
1990.103). The current NIOSH policy for carcinogens was adopted in
September 1995. Under the previous policy, NIOSH usually recommended
that exposures to carcinogens be limited to the “lowest feasible
concentration,” which was a nonquantitative value. Under the previous
policy, most quantitative RELs for carcinogens were set at the limit of
detection (LOD) achievable when the REL was originally established. 
From a practical standpoint, NIOSH testimony provided in 1990 on
OSHA’s proposed rule on occupational exposure to cadmium noted that,
“NIOSH research suggests that the use of innovative engineering and
work practice controls in new facilities or operations can effectively
contain cadmium to a level of 1 μg/m3.  Also, most existing facilities
or operations can be retrofitted to contain cadmium to a level of 5
μg/m3 through engineering and work practice controls” [NIOSH 1990].  

Early symptoms of cadmium exposure may include mild irritation of the
upper respiratory tract, a sensation of constriction of the throat, a
metallic taste and/or cough. Short-term exposure effects of cadmium
inhalation include cough, chest pain, sweating, chills, shortness of
breath, and weakness.  Short-term exposure effects of ingestion may
include nausea, vomiting, diarrhea, and abdominal cramps [NIOSH 1989]. 
Long-term exposure effects of cadmium may include loss of the sense of
smell, ulceration of the nose, emphysema, kidney damage, mild anemia, an
increased risk of cancer of the lung, and possibly of the prostate
[NIOSH 1989, Thun et al. 1991, Goyer 1991]. 

Occupational Exposure Criteria for Lead (Pb)

 as an 8-hour TWA, with worker BLLs to be controlled to ≤ 30 µg/dL. A
national health goal is to eliminate all occupational exposures that
result in BLLs >25 µg/dL [DHHS 2000].  There is no AIHA WEEL for lead
[AIHA 2007].

Occupational exposure to lead occurs via inhalation of lead-containing
dust and fume and ingestion from contact with lead-contaminated
surfaces. Symptoms of lead poisoning include weakness, excessive
tiredness, irritability, constipation, anorexia, abdominal discomfort
(colic), fine tremors, and "wrist drop” [Saryan and Zenz 1994,
Landrigan et al. 1985, Proctor et al. 1991a].  Overexposure to lead may
also result in damage to the kidneys, anemia, high blood pressure,
impotence, and infertility and reduced sex drive in both genders. In
most cases, an individual's BLL is a good indication of recent exposure
to and current absorption of lead [NIOSH 1978].

Occupational Exposure Criteria for Nickel (Ni)

The NIOSH REL for nickel metal and other compounds (as nickel) is 15
µg/m3 based on its designation as a potential occupational carcinogen
[NIOSH 2005].  The ACGIH® TLV® for insoluble inorganic compounds of
nickel is 200 µg/m3 (inhalable fraction).  For soluble inorganic nickel
compounds the TLV® is 100 µg/m3 (inhalable fraction). The TLV® for
elemental nickel is 1,500 µg/m3 (inhalable fraction) [ACGIH 2008]. The
OSHA PEL for nickel is 1,000 µg/m3   TWA [29 CFR 1910.1000].  Metallic
nickel compounds cause allergic contact dermatitis [Proctor et al.
1991b].  NIOSH considers nickel a potential occupational carcinogen
[NIOSH 2005].  There is no AIHA WEEL for nickel [AIHA 2007].

Occupational Exposure Criteria for Dust

The maximum allowable exposure to airborne particulate not otherwise
regulated is established by OSHA at 15 mg/m3   for total and 5 mg/m3 
for the respirable portion [29 CFR 1910.1000].  A more stringent
recommendation of 10 mg/m3 inhalable and 3 mg/m3 respirable is presented
by the ACGIH® which feels that “even biologically inert insoluble or
poorly soluble particulate may have adverse health effects” [ACGIH
2008].  There is no AIHA WEEL for these substances [AIHA 2007].

Occupational Exposure Criteria for Yttrium (Y)

The NIOSH REL, OSHA PEL, and ACGIH® TLV® for yttrium and its
compounds, as Y, are all 1,000 µg/m3 [NIOSH 2005, 29 CFR 1910.1000,
ACGIH 2008].  Yttrium is used in color television phosphors when
combined with rare earth elements [Proctor et al. 1991c].  Exposure
occurs through inhalation [Proctor et al. 1991c].  While yttrium
compounds irritate the lungs of animals, no effects have been noted
among humans [Proctor et al. 1991c].  The ACGIH® TLV® is based upon
value is intended to minimize the potential for respiratory fibrosis,
reported in rats following intratracheal administration of a single,
very large dose” [ACGIH 2001].  A study of occupational exposures to
yttrium europium vanadate phosphor found no effects from exposure to the
yttrium at a mean yttrium concentration of 1.4 mg/m3 [Tebrock and Machle
1968].

B. Surface Contamination Criteria 

Occupational exposure criteria have been discussed above for airborne
concentrations of several metals.  Surface wipe samples can provide
useful information in two circumstances; first, when settled dust on a
surface can contaminate the hands and then be ingested when transferred
from hand to mouth; and second, if the surface contaminant can be
absorbed through the skin and the skin is in frequent contact with the
surface [Caplan 1993].  Although some OSHA standards contain
housekeeping provisions which address the issue of surface contamination
by mandating that surfaces be maintained as free as practicable of
accumulations of the regulated substances, there are currently no
surface contamination criteria included in OSHA standards [OSHA 2008]. 
The health hazard from these regulated substances results principally
from their inhalation and to a smaller extent from their ingestion;
those substances are by and large “negligibly” absorbed through the
skin [Caplan 1993].  NIOSH RELs do not address surface contamination
either, nor do ACGIH TLVs or AIHA WEELs.  Caplan [1993] stated that
“There is no general quantitative relationship between surface
contamination and air concentrations...” He also noted that, “Wipe
samples can serve a purpose in determining if surfaces are as ‘clean
as practicable’.  Ordinary cleanliness would represent totally
insignificant inhalation dose; criteria should be based on surface
contamination remaining after ordinarily thorough cleaning appropriate
for the contaminant and the surface.”  With those caveats in mind, the
following paragraphs present guidelines that help to place the results
of the surface sampling conducted at this facility in perspective. 

Surface Contamination Criteria for Five Metals of Primary Interest

Surface Contamination Criteria for Lead

Federal standards have not been adopted that identify an exposure limit
for lead contamination of surfaces in the industrial workplace. 
However, in a letter dated January 13. 2003 [Fairfax 2003], OSHA’s
Directorate of Compliance Programs indicated that the requirements of
OSHA’s standard for lead in the construction workplace [29 CFR
1926.62(h)(1), 1926.62(i)(2)(i) and 1926(i)(4)(ii)] interpreted the
level of lead- contaminated dust allowable on workplace surfaces as
follows:  a) All surfaces shall be maintained as ‘free as
practicable’ of accumulations of lead, b) The employer shall provide
clean change areas for employees whose airborne exposure to lead is
above the permissible exposure limit, c) The employer shall assure that
lunchroom facilities or eating areas are as free as practicable from
lead contamination, d) The OSHA Compliance Directive for the Interim
Standard for Lead in Construction, CPL 2-2.58 recommends the use of
HUD's acceptable decontamination level of 200 µg/ft2 for floors in
evaluating the cleanliness of change areas, storage facilities, and
lunchrooms/eating areas, e) In situations where employees are in direct
contact with lead-contaminated surfaces, such as, working surfaces or
floors in change rooms, storage facilities, lunchroom and eating
facilities, OSHA has stated that the Agency would not expect surfaces to
be any cleaner than the 200 µg/ft2 level, and f) For other surfaces,
OSHA has indicated that no specific level can be set to define how
"clean is clean" nor what level of lead contamination meets the
definition of "practicable." OSHA notes that “the term
‘practicable’ was used in the standard, as each workplace will have
to address different challenges to ensure that lead-surface
contamination is kept to a minimum.  It is OSHA’s view that a
housekeeping program which is as rigorous as ‘practicable’ is
necessary in many jobs to keep airborne lead levels below permissible
exposure conditions at a particular site” [Fairfax 2003]. Specifically
addressing contaminated surfaces on rafters, OSHA has indicated that
they must be cleaned (or alternative methods used such as sealing the
lead in place), as necessary to mitigate lead exposures. OSHA has
indicated that the intent of this provision is to ensure that employers
regularly clean and conduct housekeeping activities to prevent avoidable
lead exposure, such as would potentially be caused by re-entrained lead
dust. Overall, the intent of the "as-free-as-practicable" requirement is
to ensure that accumulation of lead dust does not become a source of
employee lead exposures. OSHA has stated that any method that achieves
this end is acceptable. 

In the United States, standards for final clearance following lead
abatement were established for public housing and facilities related to
children. However, no criteria have been recommended for other types of
buildings, such as commercial facilities.  One author has suggested
criteria based upon lead-loading values. Lange [2001] proposed a
clearance level of 1000 µg/ft2 for floors of non-lead free buildings
and 1100 µg/ft2 for lead-free buildings, and states that “no increase
in BLL should occur for adults associated or exposed within a commercial
structure” at the latter level.  These proposed clearance levels are
based on calculations that make a number of intentionally conservative
assumptions such as: a) Lead uptake following ingestion is 35%
absorption of lead in the gastrointestinal system, b) Fingers have a
total “touch” area of 10 cm2 and 100% of the entire presumed lead
content on all 10 fingers is taken up, c) The average ‘normal’
environmental lead dose (from ‘uncontaminated food/water/air) is 20
µg per day, d) The weight of the exposed person is 70 kg, and e) Daily
lead excretion is limited to an average of 48 µg.  Lange [2001] notes
that “use of the proposed values would provide a standard for
non-child-related premises (e.g. commercial, industrial, office)…”
but cautions that, “ Further investigation is warranted to evaluate
exposure and subsequent dose to adults from surface lead.”

Surface Contamination Criteria for Beryllium

 μg/100 cm2 during non-operational periods. The DOE also has release
criteria that must be met before beryllium-contaminated equipment or
other items can be released to the general public or released for use in
a non-beryllium area of a DOE facility.  These criteria state that the
removable contamination level of equipment or item surfaces does not
exceed the higher of 0.2 μg/100 cm2 or the level of beryllium in the
soil in the area of release.  Removable contamination is defined as
“beryllium contamination that can be removed from surfaces by
nondestructive means, such as casual contact, wiping, brushing, or
washing.”

Surface Contamination Criteria for Cadmium

Like lead and beryllium, cadmium poses serious health risks from
exposure.  Cadmium is a known carcinogen, is very toxic to the kidneys,
and can also cause depression.   However, OSHA, NIOSH, AIHA and ACGIH®
have not recommended criteria for use in evaluating wipe samples.  The
OSHA Cadmium standard [29 CFR 1910.1027] mandates that “All surfaces
shall be maintained as free as practicable of accumulations of
cadmium,” that, “all spills and sudden releases of material
containing cadmium shall be cleaned up as soon as possible,” and that,
“surfaces contaminated with cadmium shall, wherever possible, be
cleaned by vacuuming or other methods that minimize the likelihood of
cadmium becoming airborne.”

Surface Contamination Criteria for Nickel

NIOSH, OSHA, AIHA and ACGIH® have not established occupational exposure
limits for nickel on surfaces.

Surface Contamination Criteria for Barium

NIOSH, OSHA, AIHA and ACGIH® have not established occupational exposure
limits for barium on surfaces.

C.  Noise Exposure Criteria

The OSHA standard for occupational exposure to noise [29 CFR 1910.95]
specifies a maximum PEL of 90 dB(A) for a duration of 8 hours per day. 
The regulation, in calculating the PEL, uses a 5 dB time/intensity
trading relationship, or exchange rate.  This means that a person may be
exposed to noise levels of 95 dB(A) for no more than 4 hours, to 100
dB(A) for 2 hours, etc.  Conversely, up to 16 hours exposure to 85 dB(A)
is allowed by this exchange rate.  NIOSH, in its Criteria for a
Recommended Standard, proposed an REL of 85 dB(A) for 8 hours, 5 dB less
than the OSHA standard [NIOSH 1972].  The NIOSH 1972 criteria document
also used a 5 dB time/intensity trading relationship in calculating
exposure limits.  However, the 1998 revised criteria recommends a 3 dB
exchange rate, noting that it is more firmly supported by scientific
evidence [NIOSH 1998].  The ACGIH® also changed its TLV® in 1994 to a
more protective 85 dB(A) for an 8-hour exposure, with the stipulation
that a 3 dB exchange rate be used to calculate time-varying noise
exposures.  Thus, a worker can be exposed to 85 dB(A) for 8 hours, but
to no more than 88 dB(A) for 4 hours or 91 dB(A) for 2 hours.

In 1983, a hearing conservation amendment to the OSHA noise standard
took effect [29 CFR 1910.95(c)] that requires employers to “administer
a continuing, effective hearing conservation program” whenever
employee noise exposures equal or exceed an 8-hour TWA of 85 dBA or,
equivalently, a dose of fifty percent.  The requirements include noise
monitoring, audiometric testing, providing hearing protectors, training
workers, and recordkeeping.

RESULTS AND DISCUSSION

The initial work described here was conducted in early 2007 at the
Elkton FCI, Unicor Recycling Factory, Federal Satellite Low (FSL) and
Warehouse electronic components recycling operations.  Follow-up testing
was done at the FCI Unicor Recycling Factory only in December 2007, to
evaluate the effectiveness of improvements made in response to that
initial work.  During this testing, air, surface wipe, bulk dust and
noise samples were collected in locations where the various electronics
recycling operations were taking place or had taken place in the past. 
The primary purposes of this evaluation were to estimate the potential
exposures of inmates and/or staff to toxic substances generated during
the recycling of electronic components; and to recommend remedial
measures to reduce exposures if necessary.

A statistical summary of air sampling results is presented in Table 1
and results of personal breathing zone and area air sampling are shown
in Tables 2 and 3, with the former being total and the latter being
size-selective (impactor) data; surface wipe sample results are
contained in Table 4; bulk material sample results are presented in
Table 5; and noise measurements in Table 6.  As mentioned in Section III
above, all samples were analyzed for 31 metals due to the parameters of
the analytical method.  While the data in these tables present the
results of just the five metals of primary interest in this evaluation;
results of all analyses are contained in the appendices.   These data
indicate levels well below the occupational exposure limits of those
other metals, even when results for combined exposures as calculated by
Equation 1 are considered. 

A. Bulk Material Sample Results

Three bulk material samples of dust from the floor of the glass breaking
operation were collected in February 2007 during the filter change
operation.  These samples were analyzed for metals, and the composition
of all three samples was similar.   The results are presented in the
Table 5 for the metals of primary interest. Beyond those 5 metals, the
only metal present in these samples in significant concentration was
zinc, which was approximately 1% of all three.  The entire data set (all
31 metals) is presented in Appendix B.  

B. Surface Wipe Sample Results

The surface wipe sample results collected during both sampling visits in
the electronic recycling operations at the Elkton FCI are summarized
below and in Table 4, and the entire surface wipe sample data set is
contained in Appendix C.  Results of spectrofluorometric analysis for Be
confirmed ICP measurements.  Wipe samples were also collected by FOH
industrial hygienists, but from different locations and for different
purposes, and those data are not included in this report.

Recycling Factory

Wipe samples collected during the February / March study indicated no
beryllium (Be) detectable in the recycling factory; the limit of
detection was 0.03 μg/sq ft.  Most (10 of 14) of the surfaces tested
for lead (Pb) indicated levels exceeding the OSHA recommended 200 μg/sq
ft, with five above 1,000, and one above 10,000 μg/sq ft.  The highest
concentration of barium detected in a wipe sample was 150 μg/sq ft. 
Several of the Cd measurements were between 40 and 250 μg/sq ft. 
Nickel surface contamination was less than 250 μg/sq ft in 10 of 11
samples. Housekeeping practices that reduce surface dust levels and
engineering controls that reduce particulate release into the air should
reduce these levels in the future.

Wipe sample data collected during the second visit did not appear to be
different than that discussed above.  The analytical limit of detection
for Be was 0.1 μg/sq ft which did produce detectable Be on most of the
wipe samples during this study.  (Analytical instrumentation had been
adjusted to improve sensitivity for 24 elements at the cost of
eliminating measurements for Al, Sb, Ca, Li, Mg, K and Ti.) 
Modifications in the procedures for changing filters in the GBO were not
expected to produce lower surface contamination, and no reduction was
seen.

FSL Building

Wipe samples collected in the FSL also did not indicate metals on work
surfaces at levels of concern.  No Be was detected here.  All Pb samples
were below the OSHA recommended level.  Surface measurements of Cd and
Ni were below levels of immediate concern.  No samples were collected in
the FSL during the December study.

Warehouse

Surface wipe samples were not collected in the warehouse as part of this
work.

C. Air Sample Results

Air measurements were collected during both normal and non-routine
operations in the areas identified, including the glass breaking
operation.  Data presented here and in Table 2 are for the duration of
the samples rather than for an 8-hour time weighted average since the
concentrations of contaminants are so low.  Measurements made during
non-routine operations showed significant exposures and are discussed
below and presented at the bottom of Table 2.  The full data set of all
31 metals is presented in Appendix D.

Recycling Factory 

Twenty-five samples were collected in the Unicor recycling factory for
airborne metals during the February study and an additional twenty in
December, including measurements made in the glass breaking operation
during normal production operations.  These data can be identified by
date in Table 2, but the magnitudes of the exposures were not generally
different by date.  Measurements in the GBO during other operations are
discussed below.  Measurements during routine operations revealed that
barium concentrations ranged between 0.1 and 4.3 μg/m3 and were
unremarkable.  Beryllium levels also were very low, with one of 25
samples being above the LOD of 0.07 μg/m3, and that sample was 0.08
μg/m3.  Cd and Ni, likewise, were found at low levels ranging up to 1
and 0.6 μg/m3, respectively.  Lead was the metal found in highest
quantity, with concentrations ranging up to 18 μg/m3, but only 5
samples were >5 μg/m3 (10% of the occupational exposure limits). 

FSL Building

Airborne metal concentrations in the FSL were generally lower than those
in the factory. In the 12 samples collected in this location, Ba ranged
up to 1 μg/m3, all Be concentrations were below 0.07 μg/m3, Cd ranged
from 0.1 to 0.5 μg/m3, and all Ni measurements were <1 μg/m3.  Even
the lead samples were all below 1 μg/m3 except one which the NIOSH
investigator suspected was compromised based on visual observations and
analytical results.  No samples were collected in the FSL during the
December study.

Warehouse

μg/m3, all Be samples were below the LOD, Cd ranged from <0.1 to 0.4
μg/m3, and all Pb and Ni measurements were at or below the LOD.  No
samples were collected in the warehouse during the December study. 

Glass Breaking Operation- Filter Cleaning and Maintenance Operation

One non-routine operation evaluated was the weekly cleaning of the glass
breaking operation.  During the first in-depth study one of four samples
collected during this procedure indicated an exposure to 23 μg/m3 for
Cd for a 79-minute sample.  Assuming no additional exposure to Cd during
the shift (based on visual observations of work tasks during that time)
results in an 8-hour TWA exposure of 3.8 μg/m3 which is above the
Action Level of 2.5 μg/m3, but below the PEL of 5 μg/m3.

The filter change operation in the glass breaking operation, discussed
in the Process Description (Section II), was the task of most concern
regarding exposures of workers to toxic metals.  Visual observations
indicated, and measurements confirmed, very high levels of airborne dust
and metals during this operation (see Figure IV).  Airborne
concentrations of Cd and Pb in excess of their respective occupational
criteria were documented; the amount of Cd detected exceeded the
assigned protection factor of the powered air purifying respirators
(PAPRs) being used by the workers (see further discussion below). 
Task-based airborne Ba concentrations ranged from 1 to 460 μg/m3.  No
Be was measured (LOD = 0.02 μg/m3) in any samples.  One 128-minute
sample for Ni measured 25 g/m3, resulting in an 8-hr TWA exposure of
6.7 μg/m3 (assuming no further exposure), less than the applicable
OELs.  Other Ni measurements ranged from a 113 minute area sample to a
114 minute personal sample of 0.3 to 7 μg/m3 Ni, respectively,
resulting in 8-hr TWAs of 0.07 μg/m3 to 1.7 μg/m3, below relevant
OELs.

Lead measurements ranged up to 2,700 μg/m3 and Cd measurements ranged
up to 2,400 μg/m3, but when TWA exposures were calculated for these
workers those exposures became 860 and 760 μg/m3 Pb and Cd (samples
ECMFF 03A&B) and 220 and 170 μg/m3 Pb and Cd (samples ECMFF 04A&B). 
These 8-hr TWA measurements indicate exposures above the REL, TLV and
PEL of 50 g/m3 for lead and the PEL of 5 μg/m3 for cadmium.  Both
workers’ 8-hr TWA exposures to cadmium exceeded the maximum use
concentration assumed for the PAPRs used by these workers (the assigned
protection factor of 25 multiplied by the OSHA PEL of 5 μg/m3).  The
respirators provided adequate protection against the measured exposures
to lead.

 

μg/m3 were 3.5 and 6.1 μg/m3, respectively.  The former exceeds the
OSHA Action level for cadmium of 2.5 μg/m3, while the latter exceeds
the PEL of 5 μg/m3.  Measurements of respirable Cd were below the TLV
of 2 μg/m3 for that entity.  Comparing the geometric means of the
8-hour TWA personal breathing zone cadmium exposures shows the reduction
achieved by the change in work practices.  The geometric mean of the two
8-hour cadmium TWAs from the March sampling date was 357 μg/m3.  The
geometric mean of the four 8-hour cadmium TWAs from the December
sampling was 0.375 μg/m3.  This indicates a reduction of 99.9%.

D. Particulate Size Sampling Results (Impactor Data)

Figures V and VI show the relative concentrations of metals in eleven
sets of impactor data, excluding the filter change operation, as a
function of particle size.  The first figure displays all five
particle-size cuts measured using these samples, showing the sum of the
metals measured for each size range for each sample.  The significant
information here is that the mass of metals on the backup filters was,
in most instances, greater than the sum of the metals on all stages. 
The second figure is an enlargement showing just the mid-three cut
points and confirming that the mass of metals is similar regardless of
particle size.  Given that the mass of a particle is proportional to the
square of that particle’s radius, these data would indicate a very
large portion of particles are in the small size ranges.

 

Impactor sampling data tend to confirm that seen with other air
samples.  The first two sets of impactor data in Table 3 (ECMFF 5 & 6)
were taken during the filter change operation in the glass breaking
exhaust system and correspond to the samples for total metals taken
during that procedure.  These indicate airborne levels of Cd and Pb
above the occupational exposure limits with little Ba, Be, and Ni.
Samples ECMFF 5(a – e) combined also indicated a total of 4,500
g/m3 of Y (occupational exposure limit is 1,000 g/m3 per Appendix
I) during a five-hour period and 19,000 g/m3 for metals in the air
(data not shown in attached tables).  Time weighted average exposures
for both Y and dust would be exceeded for this sample.

 

The third and fourth impactors (ECMHF 5 and 6), taken during the weekly
cleaning of the glass breaking operation, indicate generally higher
levels of metals than during normal operations but are in general an
order of magnitude lower than the samples collected during the filter
change operation.

 

Impactor samples collected during the two days of normal production in
February, in the glass breaking operation and elsewhere, again tend to
confirm the samples for total metals in that there were generally
measurable levels of Ba, Cd, Pb and Ni (Be was below the limit of
detection in most samples) but at levels much below the occupational
exposure limits.

During the follow-up study cyclones were used rather than impactors to
provide a measure of respirable fraction for metals and total dust. 
These data indicate levels below all occupational exposure limits,
including respirable Cd.  

Sound level measurements

Spot measurements of noise made with a hand-held sound pressure meter in
February 2007, suggested the need for a more comprehensive noise study. 
That was done during the December visit and is described here.

The data collected with noise dosimeters is presented in Table 6 for the
9 sets of data collected.  Five personal and 2 area samples were
collected in the GBO and 2 area samples were collected in the
disassembly area where the February measurements had indicated a lower
potential for overexposure.  On each day of sampling, each sample is
described, and the start and stop times are presented along with the
sample duration (run time).  Following that, the mean sound pressure
level for the duration of the run (TEST AVERAGE DB) and the time
weighted average sound pressure level for an eight hour day (TWA DB) is
shown.  Sound pressure levels are in dB, A weighted, slow response and
presented for both the OSHA and NIOSH criteria.  Time weighted
calculations assume no exposure during the un-sampled time.  For the
first day of sampling, two sets of samples are shown because the
dosimeters were stopped during lunch and restarted after lunch.  This
resulted in two separate samples.  During the second and third days the
dosimeters were not stopped during the lunch break. The technique was
modified for the second day for the workers’ convenience.  Several of
the noise samples exceeded the REL and TLV of 85 dBA.

The OSHA noise standard [29 CFR 1910.95] instructs the employer to
calculate the allowable noise dose from more than one sample as follows:

When the daily noise exposure is composed of two or more periods of
noise exposure of different levels, their combined effect should be
considered, rather than the individual effect of each. If the sum of the
following fractions: C(1)/T(1) + C(2)/T(2) C(n)/T(n) exceeds unity,
then, the mixed exposure should be considered to exceed the limit value.
Cn indicates the total time of exposure at a specified noise level, and
Tn indicates the total time of exposure permitted at that level.

This means that, using the OSHA exchange values, one of the three
samples collected on December 11, 2007 exceeded the allowable dose to
document an overexposure to the PEL of 90 dBA.  Using the allowable
doses in Appendix B to the OSHA noise standard, and rounding, sample
E2CST-2 resulted in a dose of 1.37 (137% of the allowable dose).  The
other two samples collected that day exceeded 50% of their allowable
dose, requiring the employees represented by that sample to be placed in
a hearing conservation program.

Noise doses on the second and third days were less than 50% of the
allowable dose, except for sample E2CSW-2.  That sample was collected on
a worker breaking glass.  That individual was exposed at a level of 90.6
dBA for 345 minutes of an allowable dose at 91 dB of 420 minutes, or 82%
of the allowable dose.

Air Flow Observations

Smoke was released from the smoke machine in all four areas of the glass
breaking operation (see Figure VII).  In area A, the staging area, all
smoke released traveled through the curtain s and was captured by the
ventilation hood.  Some of the smoke released close to area B moved
first through curtain t and room B before passing through curtain s and
being captured. There were two major recirculation zones in area A, as
indicated by the circular patterns in the diagram adjacent to the
entrance jet (4 straight arrows).

In area B (changing room), all smoke released traveled through curtain s
and was captured by the ventilation system.  The air flow was
subjectively described as weak by visual observation in the back of area
B (nearest the door), but strong and direct near curtain s.  A slight
tendency of the air near curtain t to flow in to area A first was noted
in the back half of area B.

No smoke released in area C flowed back behind curtain s, even when the
jet of smoke was directed at the curtain from C back towards area A. The
hood in this area was a walk-in type, with three glass breaking
stations.  Visible airborne emissions from glass breaking were removed
quickly from the point of release by the air flow, and were apparently
captured by the booth ventilation.

Area D was normally occupied by workers only during ventilation system
maintenance.  No smoke released in area D migrated to any other area,
but was captured efficiently by the ventilation system.

Smoke released in the booth confirmed the apparent capture effectiveness
of the exhaust hood in two of the three glass breaking stations.  The
station on the right side of the booth, however, exhibited some back
flow within the booth when smoke was released at the level of the
grille.  Smoke released at this point traveled first toward the
ventilation inlet at the back of the booth, but subsequently, a small
portion of the smoke was seen to travel back along the ceiling and the
right side wall toward and beyond the front of the booth.  Workers would
be present along this path, both beside the breaking station (the normal
work position for the glass breakers), and in front of the booth, where
coordinators handled full and empty Gaylord boxes.

Only this qualitative assessment of air flow was conducted, no
quantitative air flow measurements were made.

CONCLUSIONS AND RECOMMENDATIONS

g/m3 for lead and the PEL of 5 μg/m3for cadmium for two workers
during the filter change operation.  Both workers’ 8-hr TWA exposures
to cadmium exceeded the maximum use concentration assumed for the PAPRs
used by these workers (the assigned protection factor of 25 multiplied
by the OSHA PEL of 5 μg/m3).  The respirators provided adequate
protection against the measured exposures to lead.   Additional testing
in December 2007 indicated marked improvements in control and reductions
in excess of 99% in airborne exposures to metals during the filter
change operations in the GBO.  However, air sampling revealed exposures
that exceeded the OSHA Action Level and PEL for cadmium during the
filter change operation, even after that process was modified to improve
control.  

The results of air sampling clearly indicate that the highest exposures
occurred among workers involved in the glass breaking operations. These
operations involve three distinct processes: the filter change-out
maintenance operation which occurs about once a month; a weekly cleaning
process, and routine glass breaking which occurs on a daily basis.  The
highest potential exposures were measured among the workers involved in
the filter change-out maintenance operation.  The second highest exposed
group is those same workers during the routine daily glass breaking
operations.  Samples collected for the routine operation showed
detectable concentrations were less than 20% of the OSHA PELs for both
Cd and Pb.  

Smoke tests indicated the ventilation system appears to capture dust
before worker exposure can occur, except possibly at the right hand
breaking station.  Air sampling tends to confirm these observations.  No
corrective measures were attempted during this study, but it appears
that extending the overhead push jet to the right so that this jet is
continuous across the front face of the hood may correct the backflow
condition. It appeared that dust could migrate from the glass breaking
booth to adjacent work areas and in particular to the area where workers
changed to and from protective clothing and respirators. Workers in the
glass breaking operation were also overexposed to noise.  

Disassembly workers as a group, including those in the FSL, had lower
potential exposures during routine day-to-day operations as do workers
in the warehouse.  Samples collected on disassembly workers in the
general factory area of all three buildings ranged from non-detectable
to 10% of the OSHA PEL for Cd and ranged from non-detectable to 5% of
the OSHA PEL for Pb.

The data collected during the filter change maintenance operation showed
that airborne concentrations during this once per month maintenance
operation exceeded the OSHA PELs for cadmium and lead.  Although the two
workers performing the filter change-out operation wore respiratory
protection, the Cd concentrations detected exceeded the assigned
protection factor of the powered air purifying respirator (PAPR) being
used.  Modifications to the process resulted in a reduction in exposures
that exceeded 99%.  There were not enough samples to test for
statistical significance.

While overexposures were documented in the filter change operation only,
modifications can be made to improve operations in general.  Based on
the data presented above, the following recommendations are made.  These
recommendations are divided into 3 categories, described as programmatic
issues, procedural issues, and housekeeping issues.    

Programmatic issues:

The respiratory protection program for this facility should be evaluated
for this operation in order to ensure that it complies with OSHA
regulation 1910.134.  

Based upon the air sampling results during filter changing and weekly
clean-up, a regulatory assessment should be performed with respect to
OSHA regulations found at 29 CFR 1910.1025 (Lead) and 29 CFR 1910.1027
(Cadmium).

Because of the noise levels found in the glass breaking operation,
engineering controls should be designed or selected using noise
reduction as a criterion.

Until noise in the glass breaking operation can be reduced through
engineering controls, a hearing conservation program including noise
monitoring, audiometric testing, providing hearing protectors, training
workers, and recordkeeping must be implemented for workers in the glass
breaking operation.

Training of workers should be scheduled and documented in the use of
techniques for dust suppression, the proper use of local ventilation,
personal protection equipment (e.g., coveralls, respirators, gloves) and
hazard communication.

Frequently while conducting the on-site work, NIOSH researchers observed
tasks being conducted in a manner which appeared to be biomechanically
taxing.  Tasks should be evaluated to determine there are excesses in
repetitive stress trauma and if modifications in procedures or equipment
would provide benefit to this workplace.

Heat stress should be evaluated during hot weather (e.g., the summer
months).  Heat exposures above recommended limits were measured at a
similar BOP facility during the summer, and it is recommended that
appropriate measurements be taken at Elkton to prevent this problem.

All Unicor operations, including but not limited to recycling should be
evaluated from the perspective of health, safety and the environment in
the near future. 

A program should be established within the Bureau of Prisons to assure
that these issues are adequately addressed by competent trained and
certified individuals.  While a written program to address these issues
is necessary at each facility, adequate staffing with safety and health
professionals is required to ensure its implementation.  One indication
of adequate staffing is provided by the United States Navy, which states
“Regions/Activities with more than 400 employees shall assign, at a
minimum, a full time safety manager and adequate clerical support”
[USN 2005].  That document also provides recommended hazard-based
staffing levels for calculating the “number of professional personnel
needed to perform minimum functions in the safety organization.”

A comprehensive program is needed within the Bureau which provides
sufficient resources, including professional assistance, to assure each
facility the assets needed to assure both staff and inmates a safe and
healthy workplace.

This facility is a Federal prison, and the workers are Federal
prisoners.  The Belmont Report [HEW 1979] notes that, “…under prison
conditions they [prisoners] may be subtly coerced or unduly influenced
to engage in research activities for which they would not otherwise
volunteer.”  Although we did not observe this, Elkton managers should
ensure that prisoners are not unduly influenced to perform work which is
considered unsafe or unhealthy.

Procedural issues:

The modifications to the filter change-out practice should be adopted as
standard operating procedure for this process, including: 1) the
immediate bagging and disposal of used filters rather than attempting to
clean and re-use them; 2) the use of a water spray to suppress dust
during the filter change operation; and 3) the use of HEPA filtered
vacuums and wet mopping to remove dust from the floor and work surfaces.
When using wet methods to help control dust, care needs to be taken to
assure that the wet methods do not introduce any potential electrical or
other safety hazard.

The use of an alternative method (e.g., static pressure drop) should be
investigated to determine frequency of filter change.  The manufacturer
of this system may have guidelines in this regard.

Workers performing the filter change operation must continue to utilize
respiratory protection as part of a comprehensive respiratory protection
program. The PAPRs used provide adequate protection for the modified
filter change operation.

Because the facility already provides uniforms to its workers,
management should evaluate the feasibility of providing and laundering
work clothing for all workers in the recycling facility, instead of the
current practice of providing disposable clothing for glass breaking
workers only.  Contaminated work clothing must be segregated from other
clothes and laundered in accordance with applicable regulations.

Change rooms should be modified to provide separate storage facilities
for protective work clothing and equipment and for street clothes that
prevent cross-contamination.   

The use of alternative methods to break cathode-ray tubes should be
investigated by Elkton management.  Lee et al. [2004] present different
methods to separate panel glass from funnel glass in CRT recycling (sec
2.1) and for removing the coatings from the glass (sec 2.2).  The hot
wire and vacuum suction methods (supplemented with local exhaust
ventilation) described by Lee et al. may produce fewer airborne
particulates than breaking the glass with a hammer. The authors [Lee et
al. 2004] describe a commercially-available method in which an
electrically-heated wire is either manually or automatically wound
around the junction of the panel and funnel glass, heating the glass. 
After heating the glass for the necessary time, cool (e.g., room
temperature) air is directed at the surface, fracturing the
glass-to-glass junction using thermal shock.  The separated panel and
funnel glass can then be sorted by hand.  They also describe a method
wherein a vacuum-suction device is moved over the inner surface of the
panel glass to remove the loose fluorescent coating [Lee et al. 2004]. 
The vacuum used must be equipped with HEPA filtration.  Industrial
central vacuum systems are available; they may cost less in the long run
than portable HEPA vacuum cleaners. These modifications may also reduce
the noise exposure to glass breakers.

German authorities [BG/BIA 2001] have issued a set of best-practices for
dismantling CRTs.  Their recommendations include the use of a closed
cleaning cabinet that incorporates 300 air changes per hour to control
emissions.

Housekeeping:

Due to the levels of surface contamination of lead measured in the
recycling facility, special attention should be focused on hygiene
practices to prevent accidental ingestion of lead. Workers should wash
their hands before eating, drinking, or smoking.

Given the concentrations of lead and cadmium detected in the bulk dust
samples surface wipe samples and air measurements, periodic industrial
hygiene evaluations and facility inspections are recommended to confirm
that exposures are maintained below applicable occupational exposure
limits. 

Daily and weekly cleaning of work areas by HEPA-vacuuming and wet
mopping should be continued.  The BG/BIA guidelines [2001] recommend
daily cleaning of tables and floors with a type-H vacuum cleaner.  Type
H is the European equivalent of a HEPA vacuum, where the H class
requires that the filter achieve 99.995% efficiency, where 90% of the
test particles are smaller than 1.0 um and pass the assembled appliance
test, 99.995% efficiency where 10% of the particles are smaller than 1.0
um, 22% below 2.0 um, and 75% below 5.0 um. While some surface
contamination was measured in work areas, this would be much greater if
it were not for the good housekeeping practices in effect in all
locations observed.  Other practices not observed during the time of
this evaluation, but which have been observed at other facilities should
be discouraged; these include the use of compressed air to clean parts
or working surfaces, and the consumption of food, beverage or tobacco in
the workplace.

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.pdf

Accessed May 12, 2008.

Willis HH, Florig HK [2002]. Potential exposures and risks from
beryllium-containing products. Risk Anal. 22:1019–1033.

Table 1

Summary Statistics for Airborne Metal Measurements*  

 

	Ba	Be	Cd	Pb	Ni

g/m3	g/m3	g/m3	g/m3	g/m3

	25 samples taken in the FCI Unicor factory

	Ar. Mean	0.54	0.02	0.18	2.73	0.18

	Ar. St Dev	0.90	0.02	0.19	4.13	0.15

	Geo Mean	0.29	0.02	0.12	1.24	0.12

	GSD	2.70	2.11	2.42	3.65	2.78

	12 samples taken in the Federal Satellite Low

	Ar. Mean	0.41	0.02	0.20	1.53	0.54

	Ar. St Dev	0.23	0.02	0.13	3.50	0.15

	Geo Mean	0.36	0.01	0.16	0.59	0.52

	GSD	1.62	1.76	1.90	3.14	1.37

	3 samples taken in the Warehouse

	Ar. Mean	0.23	0.19	0.41	1.17	0.45

	Ar. St Dev	0.06	0.55	0.54	1.20	0.39

	Geo Mean	0.23	0.02	0.27	0.71	0.32

	GSD	1.26	1.00	2.08	2.00	1.49

	4 samples taken in the GBO during the weekly cleaning procedure; LEV
was operating;

Ar. Mean	1.00	0.05	8.05	3.11	0.50

	Ar. St Dev	0.58	0.00	10.37	2.06	0.00

	Geo Mean	0.88	0.05	2.59	2.55	0.50

	GSD	1.75	1.00	10.06	2.13	1.00

	7 samples taken in the GBO during filter change operation; LEV not
operating; 

Ar. Mean	120.57	0.01	941.75	1177.50	10.50

	Ar. St Dev	162.82	0.00	1018.46	1039.76	9.85

	Geo Mean	33.65	0.01	412.89	900.47	7.79

	GSD	8.79	1.00	11.42	8.93	4.72

	The following samples were taken during the second site visit 

	Ba	Be	Cd	Pb	Ni	Particulate

	g/m3	g/m3	g/m3	g/m3	g/m3	g/m3

10 samples taken during normal operations

Ar. Mean	0.61	0.01	0.29	1.33	0.12	415.37

Ar. St Dev	0.57	0.00	0.36	2.59	0.05	216.01

Geo Mean	0.30	0.01	0.10	0.40	0.11	344.83

GSD	4.30	1.22	5.33	4.11	1.70	2.10

10 samples taken during normal operation, respirable fractions

Ar. Mean	0.08	0.01	0.02	0.15	0.04	66.49

Ar. St Dev	0.08	0.00	0.00	0.10	0.02	31.76

Geo Mean	0.04	0.01	0.02	0.13	0.03	58.59

GSD	4.54	1.30	1.30	1.89	1.92	1.79

3 samples taken during filter change operations

Ar. Mean	1.97	0.01	7.04	0.31	0.17	188.27

Ar. St Dev	1.57	0.00	6.32	0.00	0.12	44.82

Geo Mean	1.32	0.01	3.35	0.31	0.14	184.81

GSD	3.59	1.26	6.84	1.00	2.00	1.26

3 samples taken during filter change operations, respirable fractions

Ar. Mean	0.38	0.01	0.07	0.31	0.05	173.50

Ar. St Dev	0.14	0.00	0.05	0.00	0.03	77.35

Geo Mean	0.37	0.01	0.06	0.31	0.04	161.49

GSD	1.46	1.49	2.48	1.00	1.92	1.61

*Ar. Mean = arithmetic mean

 Ar. St Dev = arithmetic standard deviation 

 Geo Mean = geometric mean

 GSD = geometric standard deviation

 All “non-detected” samples were set at half the limit of detection
for statistical calculations.

 

Table 2 –Airborne Metal Measurements

	Area / 

Sample ID	Building	Date	Personal	Sample Description	Sample Duration	Ba
Be	Cd	Pb	Ni

Minutes	g/M3	g/M3	g/M3	g/M3	g/M3

	The following 25 samples were taken in the FCI Unicor factory

	ECMTFT1	FCI	2/27/2007	A	Worker stripping copper	393	0.1	<0.03	<0.6	<0.4
<0.08

	ECMTFT2	FCI	2/27/2007	P	Worker stripping copper	291	0.2	<0.05	<0.1	0.6
0.1

	ECMTFT3	FCI	2/27/2007	A	Monitor tear-down between 	379

4th & 5th work station from back

0.2	<0.04	<0.1	0.8	0.3

	ECMTFT4	FCI	2/27/2007	A	Material disassembly, front 1/2	20	<0.5	<0.07
<1	<8	<1

	ECMTFT5	FCI	2/27/2007	P	Orderly	281	0.3	<0.05	<0.1	1.3	0.2

	ECMTFT6	FCI	2/27/2007	P	Material disassembly, 3rd table from back	255
0.2	<0.05	<0.1	0.8	0.2

	ECMTFT7	FCI	2/27/2007	P	Material disassembly, Table 7 from back	256	0.3
<0.05	0.1	1.8	0.3

	ECMTFT8	FCI	2/27/2007	P	Material disassembly, Table 6 from front	164
0.2	0.08	<0.1	1.5	0.3

	ECMTFT11	FCI	2/27/2007	P	Coordinator	423	0.4	<0.01	0.2	2.7	0.1

	ECMTFT12	FCI	2/27/2007	A	Glass breaking	420	0.2	<0.01	<0.1	1	<0.02

	ECMTFT13	FCI	2/27/2007	P	Intake	238	<0.1	<0.01	<0.1	<0.1	<0.03

	ECMWFT1	FCI	2/28/2007	A	Glass breaker	208	1.4	<0.06	0.2	9.5	<0.1

	ECMWFT2	FCI	2/28/2007	P	Glass breaker	305	1.7	<0.01	0.6	8.9	0.1

	ECMWFT3	FCI	2/28/2007	P	Glass breaking, feeder	258	1.4	<0.01	0.3	7.5
0.2

	ECMWFT4	FCI	2/28/2007	P	Glass breaking, coordinator	412	4.3	<0.01	0.8
18	0.4

	ECMWFT5	FCI	2/28/2007	A	Monitor disassembly, 4th bench from back	395
0.3	<0.03	0.2	1.1	0.2

	ECMWFT6	FCI	2/28/2007	A	Monitor disassembly, 8th bench from back	400
0.2	<0.03	0.1	0.8	<0.1

	ECMWFT7	FCI	2/28/2007	P	Intake area, forklift driver	332	0.2	<0.03	0.1
0.5	0.1

	ECMWFT8	FCI	2/28/2007	A	Intake area, near weigh station	408	0.2	<0.03
0.1	0.7	0.1

	ECMWFT9	FCI	2/28/2007	A	Copper stripping area	390	0.1	<0.03	<0.1	0.4
<0.1

	ECMWFT10	FCI	2/28/2007	P	Worker stripping copper	300	0.1	<0.04	<0.1
<0.6	<0.1

	ECMWFT11	FCI	2/28/2007	P	Monitor disassembly, 8th bench from back	289
0.2	<0.05	0.1	1.2	0.2

	ECMWFT12	FCI	2/28/2007	P	Monitor disassembly, 2nd bench from back	283
0.2	<0.05	0.1	1.1	0.1

	ECMWFT13	FCI	2/28/2007	P	Monitor disassembly, 4th bench from back	280
0.5	<0.05	0.3	2.3	0.6

	ECMWFT14	FCI	2/28/2007	P	Monitor disassembly, material handler	251	0.3
<0.05	0.1	1.2	0.2

The following 12 samples were taken in the Federal Satellite Low

	ELMTF-P1	FSL	2/27/2007	P	Disassembly worker	207	<0.5	<0.02	0.1	0.7	0.7

	ELMTF-P2	FSL	2/27/2007	P	Disassembly worker	203	<0.5	<0.02	0.1	<0.4	0.5

	ELMTF-P3	FSL	2/27/2007	P	Disassembly worker	198	<0.5	<0.03	<0.1	0.9	0.6

	ELMTF-T1	FSL	2/27/2007	A	Area sample north	369	<0.5	<0.02	0.1	<0.3	0.3

	ELMWF-A11	FSL	2/28/2007	A	North FSL area	392	0.3	<0.04	0.2	<0.5	0.5

	ELMWF-A12	FSL	2/28/2007	A	Area - Central FSL	395	0.6	<0.03	0.2	0.7	0.7

	ELMWF-A13	FSL	2/28/2007	A	Area  south FSL (suspect tampering)	398	1
<0.03	0.3	12.6	0.6

	

g/M3	g/M3	g/M3	g/M3	g/M3

ELMWF-P11	FSL	2/28/2007	P	Bailer (metal)	187	0.5	0.07	0.3	<0.5	0.7

	ELMWF-P12	FSL	2/28/2007	P	Bailer (plastic cardboard)	286	0.5	<0.02	0.1
0.5	0.4

	ELMWF-P13	FSL	2/28/2007	P	Worker on line 1 (north)	284	0.2	<0.02	0.2
0.7	0.5

	ELMWF-P14	FSL	2/28/2007	P	Worker on central line	287	0.5	<0.02	0.5	0.9
0.7

	ELMWF-P15	FSL	2/28/2007	P	Orderly	280	0.3	<0.02	0.2	0.5	0.3

The following 6 samples were taken in the warehouse

EWMTF1	WHSE	2/27/2007	P	Orderly	253	0.2	<0.1	<0.1	<2	<1

	EWMTF2	WHSE	2/27/2007	P	General worker	247	0.13	<0.1	<0.1	<2	<1

	EWMWF03	WHSE	2/28/2007	P	Clean-up, sweeping	307	0.2	<0.02	0.4	0.3	0.1

	EWMWF04	WHSE 	2/28/2007	P	De-gaussing, grinding	202	0.2	<0.02	0.4	<0.3
0.2

	EWMWF05	WHSE	2/28/2007	P	Work on floor	338	0.3	<0.02	0.3	0.5	0.1

	EWMWF06	WHSE	2/28/2007	A	Area sample, middle of warehouse	381	0.2	<0.02
0.1	<0.3	0.1

The following 4 samples were taken in the GBO during the weekly cleaning
procedure; LEV was operating;

ECMHF1	FCI / GBO	3/1/2007	P	GBO worker doing weekly cleaning	79	1.8	<0.1
23.3	5.7	<1

	ECMHF2	FCI / GBO	3/1/2007	P	GBO worker doing weekly cleaning	72	0.66
<0.1	4.7	2.02	<1

	ECMHF3	FCI / GBO	3/1/2007	A	In change area during weekly cleaning	67	<1
<0.1	0.1	<2	<1

	ECMHF4	FCI / GBO	3/1/2007	A	In breaking area during weekly cleaning	64
1.02	<0.1	4.1	3.7	<1

	The following 7 samples were taken in the GBO during the filter change
maintenance operation; LEV not operating; 

	ECMFF04B	FCI / GBO	3/2/2007	P	Worker doing filter change	91	5	<0.02	18
25	3

	ECMFF07	FCI / GBO	3/2/2007	A	On computer monitor at desk of clerk,	113
1	<0.02	3	6	0.3

	ECMFF01	FCI / GBO	3/2/2007	A	BZ level, near HEPA filter	318	15	<0.02	31
71	0.5

	ECMFF02	FCI / GBO	3/2/2007	A	BZ level in right GBO station	322	63	<0.02
27	360	3

	ECMFF03A	FCI / GBO	3/2/2007	P	Worker doing filter change	128	460	<0.02
2,400	2700	25

	ECMFF03B	FCI / GBO	3/2/2007	P	Worker doing filter change	90	150	<0.02
650	760	7

	ECMFF04A	FCI / GBO	3/2/2007	P	Worker doing filter change	114	150	<0.02
690	890	7

	about 20 ft from GBO

The following samples were taken during the second site visit and
include measurements for airborne particulate;

Area / 

Sample ID	Building	Date	Personal	Sample Description

Ba	Be	Cd	Pb	Ni	Particulate *

E2CMTR-01	FCI	12/11/2007	P	Feeding monitors	281	0.15	<0.02	<0.03	0.31
0.02	85.6 R

E2CMTR-02	FCI	12/11/2007	P	Glass breaking	286	0.22	<0.02	<0.03	0.29
<0.08	59.0 R

E2CMTT-01	FCI	12/11/2007	P	Glass breaking	267	1.02	<0.03	0.65	3.26	0.13
490

E2CHTT-02	FCI	12/11/2007	P	Feeding monitors	283	1.66	<0.02	0.98	8.17
0.17	722

E2CMTM-01	FCI	12/11/2007	P	Moving product	285

<0.07

E2CMTT-03	FCI	12/11/2007	P	Moving product	284	0.08	<0.02	<0.05	<0.23
0.15	223

E2CMWT-01	FCI	12/12/2007	P	Moving product	237	0.08	<0.03	<0.06	<0.28
0.11	199

E2CMWT-02	FCI	12/12/2007	P	Moving product	224	0.99	<0.03	<0.06	0.31	0.15
467

E2CMWT-03	FCI	12/12/2007	P	Feeding monitors	240	1.03	<0.03	0.64	0.31
0.21	654

E2CMWT-04	FCI	12/12/2007	P	Copper stripping	239	0.04	<0.03	<0.06	<0.28
<0.14	70.3

E2CMWT-05	FCI	12/12/2007	P	Glass breaking	233	0.82	<0.03	0.45	0.31	<0.14
519

E2CMWR-01	FCI	12/12/2007	P	Feeding monitors	233	0.05	<0.02	<0.04	<0.21
<0.10	73.0 R

E2CHWR-02	FCI	12/12/2007	P	Feeding monitors	239	0.11	<0.02	<0.04	<0.20
<0.10	81.5 R

E2CMWR-03	FCI	12/12/2007	P	Moving product	231	0.04	<0.02	<0.04	<0.21
<0.10	113 R

E2CMWR-04	FCI	12/12/2007	P	Disassembly	240	<0.02	<0.02	<0.04	<0.20	<0.10
30.1 R

E2CMWR-05	FCI	12/12/2007	P	Disassembly	229	<0.02	<0.02	<0.04	<0.21	0.06
52.2 R

E2CMWM-01	FCI	12/12/2007	P	Feeding monitors	235

<0.09

E2CMWM-03	FCI	12/12/2007	A	Disassembly area	162

<0.12

E2CMWT-06	FCI	12/12/2007	P	Disassembly	244	0.35	<0.03	<0.05	0.31	0.15
394

E2CMWR-06	FCI	12/12/2007	P	Disassembly	105	<0.01	<0.01	<0.02	<0.12	0.01
23.2 R

	The following 6 samples were taken during filter change operations

	E2CMHT-01	FCI	12/13/2007	A	On top of HEPA filters	304	0.31	<0.02	0.37
0.31	0.12	179

E2CMHT-02	FCI	12/13/2007	P	Filter change	215	2.19	<0.02	7.83	0.31	0.08
148.8

E2CMHT-03	FCI	12/13/2007	P	Filter change	225	3.42	<0.03	12.93	0.31	0.31
237 8

E2CMHR-02	FCI	12/13/2007	A	Center exhaust hood face, 6.5 Ft. high	307
0.25	<0.01	0.08	0.31	0.02	169 R

E2CMHR-03	FCI	12/13/2007	P	Filter change	220	0.37	<0.02	<0.04	0.31	<0.11
98.5 R

E2CMHR-04	FCI	12/13/2007	P	Filter change	229	0.53	<0.02	0.11	0.31	0.07
253 R

	*R indicates respirable fraction

						

Table 3 –Impactor Samples

Sample ID	Description	Location	Date	Particle Size	Ba	Be	Cd	Pb	Ni	TOTAL 

	Cut point	METALS

m)	g/m3	g/m3	g/m3	g/m3	g/m3	g/m3

													

ECMFF 5A	Five hour personal sample on 	FCI	3/2/07	2.5 	83	<0.03	388	560
3.7	7,100

ECMFF 5B	worker doing filter change 		1.0	75	<0.03	330	359	2.9	6,500

ECMFF 5C	in GBO			0.50	6	<0.03	13	19	<0.1	410

ECMFF 5D				0.25	42	<0.03	131	96	0.8	2,900

ECMFF 5E				Filter	4	<0.03	4	2	0.1	2,200

	Total metal per sample			210	<0.03	866	1037	7.6	19,000

										

ECMFF 6A	Two hour personal sample on 	FCI	3/2/07	2.5 	22	<0.01	50	114
0.7	1,900

ECMFF 6B	worker doing filter change 		1.0	2	<0.01	1	7	<0.04	82

ECMFF 6C	in GBO			0.50	0.3	<0.01	0.03	2	<0.04	13

ECMFF 6D				0.25	0.1	<0.01	0.02	0	<0.04	8

ECMFF 6E				Filter	0.1	<0.01	0.01	<0.1	0.01	540

	Total metal per sample			24	<0.01	51	123	0.8	2,500

										

ECMHF 5A	Two hour personal sample on 	FCI	3/1/07	2.5 	0.5	<0.02	3	5	0.1
62

ECMHF 5B	worker doing clean-up  		1.0	<0.04	<0.02	0.1	4	<0.1	16

ECMHF 5C	in glass breaking area/room			0.50	<0.02	<0.02	<0.02	5	<0.1	15

ECMHF 5D				0.25	<0.02	<0.02	<0.02	3	<0.1	13

ECMHF 5E				Filter	<0.4	<0.02	<0.02	<0.3	<0.1	1,600

	Total metal per sample			0	<0.02	3	16	0.1	1,700

										

ECMHF 6A	Two hour personal sample on 	FCI	3/1/07	2.5 	0.1	<0.06	<0.1
<0.8	<0.1	31

ECMHF 6B	worker doing clean-up  		1.0	0.1	<0.06	0.3	24	<0.1	59

ECMHF 6C	in glass breaking area/room			0.50	<0.05	<0.06	<0.1	7	<0.1	31

ECMHF 6D				0.25	<0.05	<0.06	<0.1	12	<0.1	35

ECMHF 6E				Filter	1	<0.06	<0.1	<0.5	0.1	2,500

	Total metal per sample			1	<0.06	0.3	43	0.1	2,700

										

ECMTFS 2A	On table 1, front half		FCI	2/27/07	2.5 	0.3	<0.03	0.05	6	0.4
70

ECMTFS 2B				1.0	0.0	<0.03	<0.05	11	<0.06	27

ECMTFS 2C				0.50	<0.02	<0.03	<0.05	4	<0.06	17

ECMTFS 2D				0.25	<0.02	<0.03	<0.05	3	<0.06	13

ECMTFS 2E				Filter	0.3	<0.03	<0.05	<0.2	0.1	1,000

	Total metal per sample			1	<0.03	0.05	23	0.4	1,200

Table 3 –Impactor Samples (continued)

SampleID	Description	Location	Date	Particle Size	Ba	Be	Cd	Pb	Ni	TOTAL 

	Cut point	METALS

				 (m)	g/m3	g/m3	g/m3	g/m3	g/m3	g/m3

													

					

ECMTFS 3A	3rd funnel breaker		FCI	2/27/07	2.5 	2	<0.02	1	25	0.2	260

ECMTFS 3B				1.0	1	<0.02	0.2	6	<0.06	50

ECMTFS 3C				0.50	1	<0.02	0.1	5	<0.06	31

ECMTFS 3D				0.25	0.1	<0.02	<0.04	1	<0.06	11

ECMTFS 3E				Filter	1	<0.02	0.1	0.3	<0.06	840

	Total metal per sample			5	<0.02	2	37	0.2	1,200

										

ECMTFS 4A	Panel breaker		FCI	2/27/07	2.5 	8	<0.01	10	44	0.7	750

ECMTFS 4B				1.0	1	<0.01	0.1	3	<0.03	25

ECMTFS 4C				0.50	0.1	<0.01	<0.01	5	<0.03	11

ECMTFS 4D				0.25	0.1	<0.01	<0.01	4	<0.03	9

ECMTFS 4E				Filter	<0.02	<0.01	0.01	<0.1	<0.03	500

	Total metal per sample			9	<0.01	10	56	0.7	1,300

										

ECMTFS 6A	Intake area		FCI	2/27/07	2.5 	0.1	0.01	<0.03	1	0.1	19

ECMTFS 6B				1.0	0.01	0.01	<0.03	1	0.03	8

ECMTFS 6C				0.50	0.01	0.01	<0.03	1	0.03	6

ECMTFS 6D				0.25	0.01	0.01	<0.03	3	0.03	9

ECMTFS 6E				Filter	0.1	0.01	0.01	0	0.01	630

	Total metal per sample			0.2	0.07	0.01	6	0.2	670

ECMWFS 7A	Area sample, 		FCI	2/28/07	2.5 	2.1	0.005	0.4	19	0.2	180

ECMWFS 7B	glass breaking booth			1.0	0.2	0.005	<0.001	1	0.02	12

ECMWFS 7C				0.50	0.1	0.005	0.01	0	0.02	8

ECMWFS 7D				0.25	0.03	0.005	<0.001	0	0.02	4

ECMWFS 7E				Filter	0.1	0.005	0.01	<0.1	0.01	350

	Total metal per sample			2.5	0.02	0.4	21	0.3	550

										

ECMWFS 8A	Glass breaker		FCI	2/28/07	2.5 	2.3	0.01	0.5	13	0.1	200

ECMWFS 8B				1.0	1.5	0.01	0.2	8	0.1	110

ECMWFS 8C				0.50	0.4	0.01	0.03	1	0.03	20

ECMWFS 8D				0.25	0.2	0.01	<0.01	1	0.03	8

ECMWFS 8E				Filter	0.5	0.01	0.05	0.4	0.01	460

	Total metal per sample			4.9	0.03	1	24	0.2	800

					

Table 3 –Impactor Samples (continued)

Sample ID	Description	Location	Date	Particle Size	Ba	Be	Cd	Pb	Ni	TOTAL 

	Cut point	METALS

				 (m)	g/m3	g/m3	g/m3	g/m3	g/m3	g/m3

													

	

ECMWFS 9A	Glass breaking feeder		FCI	2/28/07	2.5 	1.2	0.01	0.2	10	0.1	97

ECMWFS 9B				1.0	0.3	0.01	0.04	3	<0.03	24

ECMWFS 9C				0.50	0.1	0.01	<0.01	1	<0.03	8

ECMWFS 9D				0.25	0.1	0.01	<0.01	1	<0.03	6

ECMWFS 9E				Filter	0.2	0.01	0.01	<0.1	0.01	560

	Total metal per sample			1.7	0.03	0.3	15	0.2	700

									

EWMTF 3A	Area sample, warehouse, 	W	2/27/07	2.5 	0.2	0.01	<0.01	5	<0.03
60

EWMTF 3B	location 2 (see diagram)		1.0	0.02	0.01	<0.01	5	<0.03	16

EWMTF 3C				0.50	0.01	0.01	<0.01	3	<0.03	9

EWMTF 3D				0.25	0.01	0.01	<0.01	0.3	<0.03	6

EWMTF 3E				Filter	0.1	0.01	<0.01	<0.1	<0.03	490

	Total metal per sample			0.4	0.06	<0.01	14	<0.03	590

										

EWMTF 4A	Area sample, warehouse,	W	2/27/07	2.5 	0.1	0.01	<0.01	1	<0.03
28

EWMTF 4B	 location 1 (see diagram)		1.0	0.1	0.01	<0.01	1	<0.03	10

EWMTF 4C				0.50	0.01	0.01	<0.01	1	<0.03	7

EWMTF 4D				0.25	0.01	0.01	<0.01	1	<0.03	7

EWMTF 4E				Filter	0.1	0.01	<0.01	<0.1	<0.03	560

	Total metal per sample			0.3	0.06	<0.01	4	<0.03	610

										

										

*Total metals per sample, and total metals per stage are sums of all 31
metals quantified rather than the five metals listed in this table	

Table 4 –Wipe Sample Results

				Results in ug/sq ft		

Sample ID	Location	Date	Sample description	Ba	Be	Cd	Pb	Ni

The following samples were taken in the FCI Unicor Factory

ECMTW1	FCI	2/28/2007	On steel work bench, copper stripping	44	<0.3	25
360	43

ECMTW2	FCI	2/28/2007	On work bench, smooth rubber, far end	56	<0.3	13
3,000	110

ECMTW3	FCI	2/28/2007	On work bench, cardboard cover, far end	17	<0.3	2
150	21

ECMTW4	FCI	2/28/2007	On work bench, rough rubber, near end	120	<0.3	56
660	260

ECMTW5	FCI	2/28/2007	On work bench, smooth rubber near end	150	<0.3	33
670	240

ECMTW6	FCI	2/28/2007	On gray desk top in weigh station	3	<0.3	2	24	<4

ECMTW7	FCI	3/1/2007	Charger bench in change room	72	<0.3	70	1,200	6

ECMTW8	FCI	3/1/2007	Outside of locker door in change room	<0.7	<0.3	<0.7
4	<4

ECMTW9	FCI	3/1/2007	Back of aluminum bench in change room	<0.7	<0.3	1	11
<4

ECMTW10	FCI	3/1/2007	Front of aluminum bench in change room	90	<0.3	9
1,400	7

ECMTW11	FCI	3/1/2007	Right side of I-beam in breaking room	100	<0.3	350
580	7

ECMTW12	FCI	3/1/2007	Back of inlet jet at top front of hood, right side,

			breaking room	35	<0.3	44	330	<4

ECMTW13	FCI	3/1/2007	Floor in breaking room adjacent to change room	590
<0.3	30	10,200	66

ECMTW14	FCI	3/1/2007	Floor, middle of entry room to glass breaking	190
<0.3	11	2,100	15

The following samples were taken in the Federal Satellite Low

ELMTF-W1	FSL	2/28/2007	End of shift, on Table 1 north	12	<0.3	4	21	4

ELMTF-W2	FSL	2/28/2007	End of shift, on Table 1 central	28	<0.3	8	77	93

ELMTF-W3	FSL	2/28/2007	End of shift, table 3 south	27	<0.3	13	36	45

ELMTF-W4	FSL	2/28/2007	Bailer 1	130	<0.3	17	120	160

ELMTF-W5	FSL	2/28/2007	Bailer 2	55	<0.3	5	100	290

ELMWF-W11	FSL	3/1/2007	Bailer (metal)	66	<0.3	10	57	110

ELMWF-W12	FSL	3/1/2007	Bailer (plastic)	37	<0.3	4	72	40

ELMWF-W13	FSL	3/1/2007	Table 1, north	25	<0.3	8	190	200

ELMWF-W14	FSL	3/1/2007	Table 1 south	20	<0.3	4	180	240

ELMWF-W15	FSL	3/1/2007	Table 3, central	26	<0.3	167	86	120

  



Table 4 –Wipe Sample Results (Continued)

The following samples were taken in the FCI Unicor Factory during the
second site visit

	

Sample ID	          Date	            Description			Ba	Be	Cd	Pb	Ni

E2CMTW-01		12/11/2007		ADP north end on computer desk top			<0.2	<0.1
<0.9	<4	<3

		near doors to recycle operations

E2CMTW-02	12/11/2007	ADP south end on computer desk top			0.2	0.1	<0.9
3.6	<3

			near doors to recycle operations

E2CMTW-03	2/11/2007		Recycle room south end work			202.5	0.1	24.2	170.9
55.7

			bench top near doors to ADP

E2CMTW-04		12/11/2007	Recycle room north end work bench top		63.2	0.2
22.3	310.3	102.2

		near doors to ADP

E2CMTW-05		12/11/2007	Recycle room north end work bench			249.0	0.1	63.2
505.4	260.1

			top middle of disassembly area	

E2CMTW-06		12/11/2007	Recycle room south end work bench			4.6	0.1	3.2
22.3	15.8

		top middle of disassembly area

E2CMTW-07		12/11/2007	Recycle room outside double door to glass		8.0	0.1
4.6	36.2	4.5

				breaking room on top of order desk

E2CMTW-08		12/11/2007	Recycle clerk station near			3.3	0.1	1.8	8.4	7.7

		glass breaking room

E2CMTW-09		12/12/2007	Filter room on top of HEPA filter			193.2	<0.1
371.6	1202.1	10.2

E2CMTW-10		12/12/2007	Glass breaking table			249.0	<0.1	399.5	1202.1
13.0

E2CMTW-11		12/12/2007	Change room on top of lockers			26.0	0.2	32.5
133.8	12.1

Table 5

Composition of Bulk Dust Samples from the Glass Breaking Operation

February 2007

___________________________________________________________________   

    Sample	          	 Ba	  Be               Cd	Pb        	Ni	          

ECMFB01		   670	<0.1	240            14000	   60	 

ECMFB02		   650	<0.1	240            14000	   40	 

ECMFB03		   860	<0.1	350              9100        79	

___________________________________________________________________ 

The data are presented in milligram of metal per kg of dust (mg/kg).  

Table 6

Noise Exposure Measurements

Date:	12/11/07

Sample I D:	E2CST - 2

	E2CST - 3

	E2CST - 1

Description:	Glass breaking

Glass breaking

Sweeper in GBO

	Dosimeter serial no.	QC9040064

	QC9050002

QC9040070

	Test Started	9:53:19AM

	8:59:02AM

	  9:27:35AM

Test Stopped	11:04:47AM

	 10:06:51AM

	11:10:15AM

Test Run Time	1:11

	1:07

	1:42

	OSHA	NIOSH

OSHA	NIOSH

OSHA	NIOSH

	TEST AVG (DB)	92.5	95.6

90.5	93.1

91.6	93.2

	TWA (DB)	78.8	87.3

76.4	84.6

80.4	86.5

Date:	12/11/07

Sample I D:	E2CST - 2

	E2CST - 3

	E2CST - 1

Description:	Glass breaking

Glass breaking

Sweeper in GBO

	Dosimeter serial no.	QC9040064

	QC9050002

QC9040070

 

	Test Started	12:53:38PM

	11:57:06AM

	 1:01:48PM

Test Stopped	   3:52:59PM

	2:58:05PM

	  3:59:16PM

Test Run Time	2:59

	3:01

	2:57

	OSHA	NIOSH

OSHA	NIOSH

OSHA	NIOSH

	TEST AVG (DB)	97.7	99.4

93.4	96.0

91.0	92.1

	TWA (DB)	90.6	95.1

86.3	91.8

83.9	87.8

	Date:	12/12/07

Sample I D:	E2CSW - 2

	E2CSW - 3

	E2CSW - 1

	E2CSW- 4

	Description:	Glass breaking

	Area sample - CRT disassembly

	Cleaner - GBO

	Area sample - CRT disassembly

	Dosimeter serial no.	QC9040064

	QC9050002

QC9040070

QC9040061

Test Started	 8:44:41AM

	   8:09:14AM

	  8:47:10AM

	  9:17:50AM

Test Stopped	2:30:29PM

	 1:47:18PM

	  2:35:28PM

	  2:42:33PM

	Test Run Time	5:45

	5:38

	5:48

	5:24

OSHA	NIOSH

OSHA	NIOSH

OSHA	NIOSH

OSHA	NIOSH

TEST AVG (DB)	90.6	94.1

75.8	86.9

85.9	88.8

61.5	76.8

TWA (DB)	88.3	92.6

73.3	85.4

83.6	87.4

58.7	75.1

	Date:	12/13/07

Sample I D:	E2CSW - 9

	E2CSW - 10

	Description:	Area - in GBO near feed window

	Area - in GBO, left side of hood

	Dosimeter serial no.	QC9040064	 	 	QC9040070

	Test Started	 8:43:23AM

	  8:49:38AM

	Test Stopped	  1:56:41PM

	  2:03:22PM

	Test Run Time	5:13

	5:14

	 	OSHA	NIOSH

OSHA	NIOSH

TEST AVG (DB)	67.4	79.2

68.2	77.5	 

	TWA (DB)	64.4	77.3

65.1	75.7	 

	

Appendix A

Occupational Exposure Criteria for Metal/Elements

 

Appendix B

Metallic Composition of Bulk Dust Samples from the Glass Breaking
Operation

Concentrations are in mg/kg (ppm by weight)

	Sample #:	ECMFB01	    ECMFB02       ECMFB03                            
       

	Al	480	480		1100

	Sb	8.8	5.4		21

	As	<6	<6		<6

	Ba	670	650		860

	Be	<0.1	<0.1		<0.1

	Cd	240	240		350

	Ca	1100	910		1700

	Cr	13	14		24

	Co	<0.5	<0.5		0.9

	Cu	15	15		29

	Fe	2000	2000		2500

	La	12	16		13

	Pb	14000	14000		9100

	Li	0.5	0.5		1.4

	Mg	150	150		300

	Mn	43	43		41

	Mo	<2	<2		<2

	Ni	60	40		79

	P	57	68		82

	K	460	450		690

	Se	<10	16		<10

	Ag	<0.2	<0.2		<0.2

	Sr	190	180		240

	Te	4	<4		15

	Tl	<4	8.6		<4

	Sn	26	15		18

	Ti	10	10		13

	V	<0.3	<0.3		<0.3

	Y	6500	5700		3500

	Zn	15000	14000		9000

	Zr	<7	7.4		0

_______________________________________________________________________
Appendix C

Metallic Composition of Wipe Samples

Concentrations are in ug/sq foot

Sample ID	ECMTW1	ECMTW10	ECMTW11	ECMTW12	ECMTW13	ECMTW14	ECMTW2	ECMTW3
ECMTW4	ECMTW5	ECMTW6	ECMTW7	ECMTW8	ECMTW9	EWMWW05	EWMWW06	EWMWW07
EWMWW08	EWMWW09	EWMWW10

Al	320	350	33	11	440	430	250	270	340	270	240	190	240	4.8	1300	260	180
290	200	270

Sb	8.4	2	2	2	4.2	2.1	19	12	12	35	2	2	2	2	21	3.9	2	8.4	2	2

As	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5	5

Ba	4.7	9.7	11	3.8	63	20	6	1.8	13	48	0.33	7.7	0.08	0.08	89	3.2	1.5	51	1.7
0.41

Be	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03	0.03
0.03	0.03	0.03	0.03	0.03	0.03

Cd	2.7	0.94	38	4.7	3.2	1.2	1.4	0.24	6	3.5	0.17	7.5	0.07	0.11	6	0.18	0.09
0.33	0.07	0.07

Ca	520	280	230	220	1100	810	520	270	600	620	290	100	100	300	14000	100
100	1700	100	100

Cr	2.5	0.78	0.61	0.02	2.5	0.6	2.7	0.74	3.3	10	0.02	1.9	0.02	0.02	18	0.53
0.18	3.6	0.67	0.2

Co	0.27	0.06	0.06	0.06	0.1	0.06	0.35	0.06	0.22	0.58	0.06	0.06	0.06	0.06
2	0.06	0.06	0.19	0.06	0.06

Cu	69	2.2	1.1	0.49	11	4.3	33	8.9	45	170	1.2	1.7	0.3	0.03	110	2.7	1.1	170
1.7	1.9

Fe	490	110	53	24	720	300	1100	83	590	440	47	140	3.6	0.9	5800	90	50	560
60	36

La	0.3	0.3	0.38	0.3	0.73	0.3	0.86	0.3	0.54	0.46	0.3	0.3	0.3	0.3	3.2	0.3
0.3	0.3	0.3	0.3

Pb	39	150	62	35	1100	230	320	16	71	72	2.6	130	0.47	1.2	110	3.8	1	8.7	1.6
0.96

Li	0.29	0.12	0.11	0.05	0.35	0.31	0.83	0.17	1.3	1.4	0.16	0.08	0.04	0.04
2.6	0.12	0.06	1.7	0.12	0.08

Mg	60	29	13	8.4	81	56	120	43	100	87	46	14	44	7	2200	38	13	500	29	32

Mn	8	2.3	1.3	0.52	12	5.6	290	8.1	92	35	2	2.1	0.68	0.04	160	2.6	1.1	11
1.1	1.2

Mo	0.39	0.3	0.3	0.3	0.3	0.3	0.32	0.3	0.54	0.57	0.3	0.3	0.3	0.3	3.8	0.3
0.3	0.62	0.3	0.3

Ni	4.6	0.76	0.78	0.4	7.1	1.6	12	2.3	28	26	0.4	0.65	0.4	0.4	31	1.1	0.4
7.6	0.4	0.4

P	30	4.9	6.5	5.3	17	17	12	3.4	16	1	4.7	3.3	1	1	190	7.6	12	7.3	9.3	3.1

K	76	59	13	11	160	100	120	34	110	140	58	18	15	18	1900	120	140	240	160	61

Se	2	2	2.4	2	2	2	2	2	2	2	2	2	2	2	2	2	2	2	2	2

Ag	0.17	0.04	0.02	0.02	0.1	0.11	1.7	0.47	1.1	0.83	0.03	0.02	0.02	0.02
2.6	0.15	0.03	2.3	0.07	0.05

Sr	2	5.1	4.3	1.6	30	13	2.6	0.69	11	3.1	0.26	2.2	0.1	0.61	35	0.19	0.1	3.4
0.41	0.1

Te	0.5	0.5	0.5	0.5	0.5	0.5	0.6	0.5	0.5	0.5	0.5	0.5	0.5	0.5	1.4	0.5	0.5
0.5	0.5	0.5

Tl	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10	10

Sn	7.6	2	2	2	3	2	470	27	92	100	2	2	2	2	21	6	2	8.5	2	2

Ti	2	1.3	0.81	0.35	6.2	3.9	2.5	1.4	9.2	17	0.74	0.98	0.38	0.07	40	1.3
0.53	9.5	0.94	0.72

V	0.03	0.03	0.02	0.02	0.15	0.1	0.29	0.05	0.15	0.17	0.02	0.02	0.02	0.02
2.2	0.04	0.02	0.26	0.03	0.03

Y	3.5	5.3	260	35	32	7.8	5.1	0.29	4.6	2.8	0.41	46	0.2	0.81	14	0.56	0.09
0.23	0.11	0.06

Zn	94	22	620	98	200	47	950	72	630	1200	32	140	9	9	910	26	9	320	9	9

Zr	0.6	0.6	0.6	0.6	1.1	1.2	0.61	0.6	1	1.2	0.6	0.6	0.6	0.6	3.1	0.6	0.6
1.1	0.6	0.6

Underline  =  <LOD (Limit of detection)		

Appendix C (Continued)

Metallic Composition of Wipe Samples

Concentrations are in ug/sq foot

These samples were collected during the second site visit

Sample ID	E2CMTW-01	E2CMTW-02	E2CMTW-03	E2CMTW-04	E2CMTW-05	E2CMTW-06
E2CMTW-07	E2CMTW-08	E2CMTW-09	E2CMTW-10	E2CMTW-11

As	<9	13.0	<9	<9	<9	<9	<9	11.1	15.7	13.9	<9

Ba	<0.2	0.2	201.9	63.0	248.2	4.5	8.3	3.3	192.6	248.2	25.9

Be	<0.1	0.1	0.1	0.2	0.1	0.1	0.1	0.1	<0.1	<0.1	0.2

Cd	<0.9	<0.9	24.1	22.2	63.0	3.1	4.6	1.8	370.4	398.2	32.4

Cr	0.3	0.6	14.3	43.9	69.8	8.1	3.1	2.2	23.5	21.7	6.0

Co	<0.6	<0.6	9.1	4.6	11.1	1.8	<0.6	<0.6	2.0	1.1	2.7

Cu	<0.5	<0.5	82.4	1203.8	879.7	16.7	16.7	6.0	<0.5	21.3	10.2

Fe	<60	9.3	2778.0	4352.2	10093.4	537.1	398.2	92.6	453.7	2963.2	518.6

La	<0.5	<0.5	<0.5	<0.5	<0.5	<0.5	<0.5	<0.5	6.2	<0.5	0.9

Pb	<4	3.6	170.4	309.3	503.7	22.2	36.1	8.3	1198.2	1198.2	133.3

Mn	<2	7.1	73.2	148.2	583.4	18.5	12.0	4.7	13.0	28.7	16.7

Mo	<2	<2	<2	11.1	10.2	<2	<2	<2	<2	<2	<2

Ni	<3	<3	55.6	101.9	259.3	15.7	4.4	7.7	10.2	13.0	12.0

P	<200	<200	<200	259.3	1944.6	<200	213.0	185.2	250.0	416.7	379.7

Se	<10	<10	14.8	<10	<10	<10	<10	<10	<10	<10	<10

Ag	<0.2	0.2	3.0	6.5	10.2	0.8	0.4	<0.2	<0.2	0.3	0.5

Sr	<0.3	<0.3	19.4	19.4	51.9	1.9	4.5	0.3	128.7	212.1	14.8

Te	<4	<4	<4	<4	<4	<4	<4	<4	<4	<4	<4

Tl	<20	<20	<20	<20	<20	<20	<20	<20	<20	<20	<20

Sn	<20	<20	157.4	379.7	407.4	<20	<20	<20	<20	18.5	<20

V	<0.2	<0.2	0.4	1.4	1.2	0.6	0.3	<0.2	<0.2	<0.2	0.2

Y	0.3	0.5	5.7	12.0	41.7	2.3	4.1	1.2	1203.8	1111.2	86.1

Zn	<100	287.1	2092.8	2926.2	10982.4	175.9	120.4	<100	5333.8	10982.4	83.3

Zr	<20	<20	<20	<20	<20	<20	<20	<20	<20	<20	<20

Appendix D

Metallic Composition of Filter Samples

<LOD	Underline		                                          Concentrations
are in g/m3



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	0.20	0.12	0.04	0.03	0.20	0.25	1.13	0.46	0.28	0.51	0.68	0.35	0.19	0.63

Mo	0.25	0.07	0.07	0.09	0.35	0.27	4.86	0.35	0.40	0.39	0.62	0.48	0.33	0.35

Ni	0.08	0.08	0.02	0.03	0.11	0.27	1.46	0.25	0.16	0.27	0.29	0.14	0.10	0.15

P	2.54	0.75	0.70	0.87	3.51	2.69	48.62	3.55	4.02	3.93	6.19	4.82	3.34	3.51

K	0.85	0.85	0.30	0.29	1.17	0.99	16.21	1.77	1.34	2.62	2.06	3.37	1.11	1.76

Se	1.69	0.50	0.47	0.58	2.34	2.15	32.41	2.36	2.68	2.62	4.13	3.21	2.23
2.34

Ag	0.03	0.01	0.01	0.01	0.05	0.04	0.65	0.05	0.05	0.05	0.08	0.06	0.04	0.05

Sr	0.03	0.14	0.06	0.01	0.06	0.07	0.32	0.15	0.07	0.16	0.10	0.58	0.04	0.13

Te	0.42	0.12	0.12	0.14	0.58	0.45	8.10	0.59	0.67	0.65	1.03	0.80	0.56	0.59

Tl	0.68	0.20	0.19	0.23	0.94	0.72	12.97	0.95	1.07	1.05	1.65	1.28	0.89
0.94

Sn	0.76	0.22	0.21	0.26	1.05	0.81	14.59	1.06	1.21	1.18	1.86	1.44	1.00
1.05

Ti	0.08	0.08	0.03	0.01	0.14	0.13	0.16	0.24	0.11	0.25	0.25	0.27	0.09	0.19

V	0.03	0.01	0.01	0.01	0.04	0.03	0.49	0.04	0.04	0.04	0.06	0.05	0.03	0.04

Y	0.06	5.74	1.61	0.01	0.14	0.11	0.32	0.52	0.12	0.18	0.78	12.20	0.14	0.15

Zn	1.35	10.73	3.50	0.40	2.10	2.60	7.94	5.79	5.50	7.72	8.25	25.68	2.89
8.43

Zr	0.34	0.10	0.09	0.12	0.47	0.36	6.48	0.47	0.54	0.52	0.83	0.64	0.45	0.47

Sample ID	ECMWFT12	ECMWFT13	ECMWFT14	ECMWFT2	ECMWFT3	ECMWFT4	ECMWFT5
ECMWFT6	ECMWFT7	ECMWFT8	ECMWFT9	ECMFF 5BE	ECMFF 6E	ECMHF 5E

Al	3.29	8.78	2.92	4.78	5.92	10.91	3.46	2.24	2.27	1.41	0.86	28.74	1.74
5.28

Sb	0.61	0.59	0.66	0.49	0.57	0.65	0.42	0.41	0.42	0.41	0.43	0.43	0.11	0.26

As	0.85	0.83	0.93	0.68	0.80	0.91	0.59	0.58	0.59	0.58	0.60	1.44	0.36	0.85

Ba	0.24	0.50	0.25	1.66	1.37	4.29	0.31	0.21	0.19	0.16	0.09	4.45	0.15	0.40

Be	0.05	0.05	0.05	0.04	0.05	0.05	0.03	0.03	0.03	0.03	0.03	0.03	0.01	0.02

Cd	0.15	0.30	0.09	0.58	0.32	0.82	0.15	0.09	0.06	0.07	0.06	3.88	0.01	0.02

Ca	26.81	54.58	31.87	22.46	46.66	54.57	32.91	17.38	18.48	18.26	10.36
1364.94	348.13	1022.15

Cr	0.11	0.11	0.12	0.09	0.10	0.12	0.08	0.07	0.08	0.07	0.08	0.45	0.10	0.27

Co	0.07	0.07	0.08	0.07	0.07	0.08	0.05	0.05	0.05	0.05	0.05	0.04	0.01	0.03

Cu	0.28	0.94	0.13	0.10	0.11	0.16	0.17	0.08	0.08	0.08	0.09	0.76	0.53	0.38

Fe	13.40	55.77	13.28	9.76	18.21	31.18	15.19	11.59	13.44	7.80	6.22	6.47
0.71	1.70

La	0.04	0.06	0.04	0.03	0.03	0.04	0.03	0.02	0.03	0.02	0.03	0.01	0.00	0.01

Pb	1.12	2.25	1.22	8.88	7.51	18.19	1.10	0.79	0.50	0.67	0.43	2.30	0.11
0.26

Li	1.22	1.19	1.33	0.98	1.14	1.30	0.84	0.83	0.84	0.83	0.86	1.44	0.36	0.85

Mg	1.46	4.51	1.73	1.37	2.85	3.51	2.03	1.16	1.76	1.16	0.48	7.76	1.74	5.20

Mn	0.44	1.54	0.42	0.21	0.44	0.84	0.50	0.41	0.40	0.23	0.24	0.22	0.02	0.06

Mo	0.37	0.36	0.40	0.29	0.34	0.39	0.25	0.25	0.25	0.25	0.26	0.29	0.07	0.17

Ni	0.11	0.63	0.19	0.11	0.16	0.36	0.22	0.07	0.08	0.13	0.08	0.10	0.01	0.03

P	3.66	3.56	3.98	2.93	3.41	3.90	2.53	2.48	2.52	2.49	2.59	718.39	181.17
545.14

K	1.58	3.80	1.59	2.54	2.73	4.81	1.94	1.32	1.34	1.24	0.95	2.16	0.18	0.43

Se	2.44	2.37	2.66	1.95	2.28	2.60	1.69	1.66	1.68	1.66	1.73	1.72	0.25	0.60

Ag	0.05	0.05	0.05	0.04	0.05	0.05	0.03	0.03	0.03	0.03	0.03	0.03	0.01	0.02

Sr	0.11	0.26	0.12	0.59	0.50	1.05	0.16	0.11	0.08	0.07	0.04	1.14	0.20	0.61

Te	0.61	0.59	0.66	0.49	0.57	0.65	0.42	0.41	0.42	0.41	0.43	0.72	0.18	0.43

Tl	0.97	0.95	1.06	0.78	0.91	1.04	0.68	0.66	0.67	0.66	0.69	1.01	0.25	0.60

Sn	1.10	1.90	1.20	0.88	1.02	1.17	0.76	0.75	0.76	0.75	0.78	1.44	0.36	0.85

Ti	0.19	0.38	0.23	0.18	0.31	0.42	0.24	0.15	0.15	0.14	0.09	0.19	0.04	0.12

V	0.04	0.04	0.04	0.03	0.03	0.04	0.03	0.02	0.03	0.02	0.03	0.04	0.01	0.03

Y	0.19	0.28	0.17	47.84	13.66	66.26	0.17	0.12	0.13	0.12	0.08	22.99	0.04
0.01

Zn	10.97	18.98	4.91	86.90	29.59	119.53	5.15	3.56	2.69	2.57	1.55	67.53
0.12	0.17

Zr	0.49	0.47	0.53	0.39	0.46	0.52	0.34	0.33	0.34	0.33	0.35	0.57	0.14	0.34

Sample ID	ECMTFS 4E	ELMTF-P1	ELMTF-P2	ELMTF-P3	ELMTF-T1	ELMTF-T2
ELMTF-T3	ELMWF-A11	ELMWF-A12	ELMWF-A13	ELMWF-P11	ELMWF-P12	ELMWF-P13
ELMWF-P14	ELMWF-P15

Al	1.68	3.97	4.10	4.25	2.53	3.79	3.07	4.60	7.06	10.71	4.76	3.82	5.04
5.26	3.60

Sb	0.10	0.36	0.37	0.39	0.27	0.27	0.27	0.53	0.52	0.50	0.53	0.35	0.35	0.36
0.36

As	0.34	1.20	1.24	6.44	0.90	0.90	0.90	1.77	1.72	1.67	1.76	1.16	1.17	1.20
1.20

Ba	0.15	0.29	0.32	0.89	0.26	0.36	0.21	0.34	0.59	0.95	0.51	0.45	0.25	0.45
0.35

Be	0.01	0.02	0.02	0.03	0.02	0.02	0.02	0.04	0.03	0.03	0.07	0.02	0.02	0.02
0.02

Cd	0.01	0.11	0.06	0.04	0.06	0.08	0.08	0.19	0.24	0.27	0.26	0.09	0.18	0.50
0.16

Ca	318.17	32.49	29.85	29.60	18.07	30.71	21.68	24.75	46.48	85.37	26.43
27.76	26.94	38.27	22.80

Cr	0.10	0.94	0.62	0.71	0.39	0.54	0.45	0.72	0.90	0.84	0.95	0.64	0.66	0.61
0.47

Co	0.01	0.04	0.04	0.04	0.03	0.04	0.03	0.05	0.05	0.05	0.14	0.03	0.04	0.04
0.04

Cu	0.17	0.52	0.72	0.68	0.33	0.67	0.23	0.58	1.48	1.84	0.65	0.60	0.59	1.20
0.59

Fe	0.68	19.25	38.56	28.31	21.68	36.13	14.45	33.59	68.86	61.94	31.71
30.07	42.17	49.04	49.20

La	0.00	0.01	0.01	0.01	0.01	0.01	0.01	0.02	0.02	0.02	0.05	0.01	0.01	0.01
0.01

Pb	0.10	0.66	0.37	0.93	0.27	0.49	0.41	0.53	0.71	12.55	0.53	0.50	0.67
0.87	0.48

Li	0.34	1.20	1.24	1.29	0.90	0.90	0.90	1.77	1.72	1.67	1.76	1.16	1.17	1.20
1.20

Mg	1.68	2.29	2.24	2.45	1.36	2.62	1.54	1.77	3.79	7.03	2.11	2.66	2.34	3.35
2.04

Mn	0.01	0.43	0.51	0.53	0.34	0.61	0.32	0.57	1.22	1.09	0.72	0.61	0.52	0.84
0.86

Mo	0.07	0.24	0.25	0.26	0.18	0.18	0.18	0.35	0.34	0.33	0.35	0.23	0.23	0.24
0.24

Ni	0.01	0.66	0.49	0.58	0.30	0.48	0.14	0.46	0.65	0.62	0.65	0.38	0.47	0.73
0.28

P	171.06	3.25	2.49	2.57	1.81	3.07	1.81	3.54	3.44	4.18	3.52	2.43	2.34
2.75	2.40

K	0.19	3.13	2.86	2.70	1.81	4.52	2.08	3.18	4.99	12.22	3.70	3.24	2.69	4.66
2.76

Se	0.24	0.84	3.23	2.83	0.63	2.26	0.63	1.24	1.29	2.68	1.66	0.81	0.82	0.84
1.15

Ag	0.01	0.02	0.04	0.09	0.05	0.05	0.03	0.07	0.07	0.13	0.07	0.06	0.04	0.10
0.07

Sr	0.19	0.26	0.35	0.40	0.31	0.56	0.26	0.51	1.31	0.80	0.39	0.38	0.36	0.73
1.32

Te	0.17	0.60	0.62	0.64	0.45	0.45	0.45	0.88	0.86	0.84	0.88	0.58	0.59	0.60
0.60

Tl	0.24	0.84	0.87	0.90	0.63	0.63	0.63	1.24	1.21	1.17	1.23	0.81	0.82	0.84
0.84

Sn	0.34	1.20	1.24	1.29	0.90	0.90	0.90	1.77	1.72	21.76	1.76	1.16	1.17
1.20	1.20

Ti	0.03	0.24	0.30	0.49	0.25	0.42	0.22	0.41	0.93	0.75	0.41	0.37	0.41	0.55
0.83

V	0.01	0.04	0.04	0.04	0.03	0.03	0.03	0.05	0.05	0.05	0.07	0.03	0.04	0.04
0.04

Y	0.00	0.01	0.01	0.03	0.03	0.03	0.02	0.07	0.07	0.40	0.11	0.05	0.02	0.04
0.05

Zn	0.07	4.81	7.09	11.33	3.70	5.33	2.35	6.54	8.61	10.88	11.10	8.67	8.67
10.05	4.08

Zr	0.14	0.48	0.50	0.51	0.36	0.36	0.36	0.71	0.69	0.74	1.76	0.46	0.47	0.48
0.48

Appendix D

Metallic Composition of Filter Samples

Concentrations are in g/m3

Sample ID	E2CMTR-01	E2CMTR-02	E2CMTT-01	E2CHTT-02	E2CMTT-03	E2CMWT-01
E2CMWT-02	E2CMWT-03	E2CMWT-04	E2CMWT-05	E2CMWR-01	E2CHWR-02

Date	12/11/07	12/11/07	12/11/07	12/11/07	12/11/07	12/12/07	12/12/07
12/12/07	12/12/07	12/12/07	12/12/07	12/12/07

Al	<0.86	<0.84	<1.26	<1.18	<1.17	<1.42	<1.51	<1.39	<1.41	<1.44	<1.04
<1.02

Sb	<0.34	<0.34	<0.50	<0.47	<0.47	<0.57	<0.60	<0.56	<0.56	<0.58	<0.42
<0.41

As	<0.60	<0.59	<0.88	<0.83	<0.82	<0.99	<1.05	<0.97	<0.98	<1.01	<0.73
<0.71

Ba	0.15	0.22	1.02	1.66	0.08	0.08	0.99	1.03	0.04	0.82	0.05	0.11

Be	<0.02	<0.02	<0.03	<0.02	<0.02	<0.03	<0.03	<0.03	<0.03	<0.03	<0.02
<0.02

Cd	<0.03	<0.03	0.65	0.98	<0.05	<0.06	<0.06	0.64	<0.06	0.45	<0.04	<0.04

Ca	5.13	3.29	10.67	14.21	15.27	14.06	16.57	23.67	5.34	18.74	3.23	4.58

Cr	<0.17	<0.17	0.34	<0.24	<0.23	<0.28	<0.30	<0.28	<0.28	<0.29	<0.21
<0.20

Co	<0.04	<0.04	<0.06	<0.06	<0.06	<0.07	<0.08	<0.07	<0.07	<0.07	<0.05
<0.05

Cu	0.04	0.08	0.19	0.20	0.11	0.18	0.18	0.35	0.11	0.19	<0.03	0.05

Fe	<1.71	<1.68	6.53	11.84	4.93	10.79	18.07	16.71	2.95	6.92	<2.09	<2.04

La	<0.009	<0.008	<0.013	<0.012	<0.012	<0.014	<0.015	<0.014	<0.014	<0.014
<0.010	<0.010

Pb	0.31	0.29	3.26	8.17	<0.23	<0.28	0.31	0.31	<0.28	0.31	<0.21	<0.20

Li	<0.009	<0.008	<0.013	<0.012	<0.012	<0.014	<0.015	<0.014	<0.014	<0.014
<0.010	<0.010

Mg	0.28	0.16	0.67	1.11	0.80	0.50	0.66	1.39	0.31	0.88	<0.10	<0.10

Mn	<0.04	0.05	0.09	0.40	0.11	0.12	0.18	0.24	<0.07	0.14	<0.05	<0.05

Mo	<0.26	<0.25	<0.38	<0.36	<0.35	<0.43	<0.45	<0.42	<0.42	<0.43	<0.31
<0.31

Ni	0.02	<0.08	0.13	0.17	0.15	0.11	0.15	0.21	<0.14	<0.14	<0.10	<0.10

P	<0.86	<0.84	<1.26	<1.18	<1.17	<1.42	<1.51	<1.39	<1.41	<1.44	<1.04
<1.02

K	0.27	0.26	1.23	2.01	0.56	<0.43	1.01	2.09	<0.42	1.44	<0.31	<0.31

Se	<2.57	<2.53	<3.77	<3.55	<3.52	<4.26	<4.52	<4.18	<4.22	<4.32	<3.13
<3.06

Ag	<0.009	<0.008	<0.013	<0.012	<0.012	<0.014	<0.015	<0.014	<0.014	<0.014
<0.010	<0.010

Sr	0.06	0.07	0.41	0.50	0.04	0.31	0.30	0.56	0.34	0.58	0.01	0.05

Te	<0.34	<0.34	<0.50	<0.47	0.05	<0.57	<0.60	<0.56	0.47	0.83	<0.42	<0.41

Tl	<0.43	<0.42	<0.63	<0.59	<0.59	<0.71	<0.75	<0.70	<0.70	<0.72	<0.52
<0.51

Sn	<0.60	<0.59	<0.88	<0.83	<0.82	<0.99	1.08	<0.97	<0.98	<1.01	<0.73
<0.71

Ti	0.02	<0.01	0.05	0.08	0.07	0.18	0.11	0.18	0.18	0.12	<0.01	<0.01

V	<0.02	<0.02	<0.03	<0.02	<0.02	<0.03	<0.03	<0.03	<0.03	<0.03	<0.02
<0.02

Y	0.33	0.75	40.18	59.22	0.27	0.33	28.62	20.89	<0.03	25.94	0.16	0.35

Zn	1.0	1.8	63.9	65.0	1.4	2.0	39.0	38.8	0.8	43.1	0.4	1.1

Zr	<0.09	<0.08	<0.13	<0.12	<0.12	<0.14	<0.15	<0.14	<0.14	<0.14	<0.10
<0.10

Appendix D (Continued)

Sample ID	E2CMWR-03	E2CMWR-04	E2CMWR-05	E2CMWT-06	E2CMWR-06	E2CMHT-01
E2CMHT-02	E2CMHT-03	E2CMHR-02	E2CMHR-03	E2CMHR-04

Date	12/12/07	12/12/07	12/12/07	12/12/07	12/12/07	12/13/07	12/13/07
12/13/07	12/13/07	12/13/07	12/13/07

Al	<1.03	<1.01	<1.04	<1.36	<0.58	<0.78	2.98	5.80	<0.54	<1.09	<1.06

Sb	<0.41	<0.40	<0.42	<0.54	<0.23	<0.31	<0.63	<0.59	<0.22	<0.44	<0.42

As	<0.72	<0.70	<0.73	<0.95	<0.41	<0.54	<1.10	<1.04	<0.38	<0.77	<0.74

Ba	0.04	<0.02	<0.02	0.35	<0.01	0.31	2.19	3.42	0.25	0.37	0.53

Be	<0.02	<0.02	<0.02	<0.03	<0.01	<0.02	<0.02	<0.03	<0.01	<0.02	<0.02

Cd	<0.04	<0.04	<0.04	<0.05	<0.02	0.37	7.83	12.93	0.08	<0.04	0.11

Ca	3.40	2.71	3.13	62.45	0.64	4.51	25.07	38.63	3.81	4.81	6.22

Cr	<0.21	<0.20	<0.21	<0.27	<0.12	<0.16	0.38	0.43	<0.11	<0.22	<0.21

Co	<0.05	<0.05	<0.05	<0.07	<0.03	<0.04	<0.08	<0.07	<0.03	<0.05	<0.05

Cu	0.10	0.43	0.20	1.29	0.06	0.06	0.33	0.48	0.13	0.11	0.19

Fe	<2.06	<2.01	<2.09	10.05	<1.16	2.18	12.85	26.75	1.63	<2.19	<2.11

La	<0.010	<0.010	<0.010	<0.014	<0.006	<0.008	<0.016	0.030	<0.005	<0.011
<0.011

Pb	<0.21	<0.20	<0.21	0.31	<0.12	0.31	0.31	0.31	0.31	0.31	0.31

Li	<0.010	<0.010	<0.010	<0.014	<0.006	<0.008	<0.016	<0.015	<0.005	<0.011
<0.011

Mg	<0.10	<0.10	<0.10	1.63	<0.06	0.18	1.44	2.38	0.27	0.13	0.27

Mn	<0.05	0.71	0.20	0.26	<0.03	<0.04	0.33	0.56	0.14	<0.05	<0.05

Mo	<0.31	<0.30	<0.31	<0.41	<0.17	<0.23	<0.47	<0.45	<0.16	<0.33	<0.32

Ni	<0.10	<0.10	0.06	0.15	0.01	0.12	0.08	0.31	0.02	<0.11	0.07

P	<1.03	<1.00	<1.04	<1.36	<0.58	<0.78	<1.57	49.04	<0.54	<1.09	4.64

K	<0.31	<0.30	<0.31	1.00	<0.17	0.64	4.70	5.50	0.87	0.51	1.16

Se	<3.09	<3.01	<3.13	<4.07	<1.74	<2.33	<4.70	<4.46	<1.63	<3.28	<3.17

Ag	<0.010	<0.010	<0.010	<0.014	<0.006	<0.008	<0.016	<0.015	<0.005	<0.011
<0.011

Sr	0.08	<0.01	1.25	0.90	0.70	0.16	1.02	1.63	1.03	0.12	0.24

Te	<0.41	<0.40	1.31	<0.54	<0.23	<0.31	<0.63	<0.59	<0.22	<0.44	<0.42

Tl	<0.52	<0.50	<0.52	<0.68	<0.29	<0.39	<0.78	<0.74	<0.27	<0.55	<0.53

Sn	<0.72	<0.70	<0.73	<0.95	<0.41	<0.54	<1.10	<1.04	<0.38	<0.77	<0.74

Ti	0.05	<0.01	0.56	0.50	<0.01	0.03	0.15	0.28	0.50	<0.01	0.02

V	<0.02	<0.02	<0.02	<0.03	<0.01	<0.02	<0.03	<0.03	<0.01	<0.02	<0.02

Y	0.39	<0.02	<0.02	0.09	<0.01	7.70	104.96	178.31	2.34	1.86	3.27

Zn	1.0	0.1	0.4	4.1	0.0	17.8	234.8	386.2	6.5	5.4	9.0

Zr	<0.10	<0.10	<0.10	<0.14	<0.06	<0.08	<0.16	<0.15	<0.05	<0.11	<0.11

Figure I	Diagram of the Unicor factory located within the FCI main
compound

(See Figure IV for more detail of Glass Breaking Operation)

 

Figure II 	Diagram of the Unicor facility in the Federal Satellite Low
(FSL)

 



Figure III	Diagram of the warehouse handling electronics recycling
operations

 

Figure IV	Diagram of the glass breaking area within the FCI 



Figure V – Elkton Warehouse Showing Storage Areas with Boxes of Items
to be Recycled

Figure VI – Overview of Elkton Recycling Factory Disassembly Area

Figure VII – Electron Gun Removal in Glass Breaking Operation

Figure VIII – Filter Change Operation in Glass Breaking Area

 Showing Large Amount of Visible Dust

Figure X – Three cut particle size distribution from impactor data

 

 This report documents the study conducted at Elkton, Ohio.  Other NIOSH
field studies were conducted at Federal correctional facilities in
Lewisburg, Pennsylvania and Marianna, Florida

 On March 20, 1991, the Supreme Court decided the case of International
Union, United Automobile, Aerospace & Agricultural Implement Workers of
America, UAW v. Johnson Controls, Inc., 111 S. Ct. 1196, 55 EPD 40,605. 
It held that Title VII forbids sex-specific fetal protection policies. 
Both men and women must be protected equally by the employer.

 OSHA PELs, unless otherwise noted, are TWA concentrations that must not
be exceeded during any 8-hour workshift of a 40-hour work-week [NIOSH
1997].  NIOSH RELs, unless otherwise noted, are TWA concentrations for
up to a 10-hour workday during a 40-hour workweek [NIOSH 1997].  ACGIH®
TLVs®, unless otherwise noted, are TWA concentrations for a
conventional 8-hour workday and 40-hour workweek [ACGIH 2008]

 71 minutes at 92.5 dBA/318 minutes allowed at 93 dBA + 179 minutes at
97.7 dBA/156 minutes allowed at 98 dBA = 1.37, or 137% of the allowable
dose.

 67 min at 90.5dbA/420 minutes allowed at 91 dBA + 181 minutes at 93.4
dBA/318 minutes allowed at 93 dBA = 0.73, or 73% of allowable dose; and
102 minutes at 91.6 dBA/306 minutes allowed at 92 dBA +  177 minutes at
91 dBA/420 minutes allowed at 91 dBA = 0.75, or 75% of the allowable
dose.

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