face="Arial">GLASS, MOLDERS, PLASTIC,
POTTERY AND ALLIED WORKERS, LOCAL 208.

Authorized Employee Representative.

OSHRC Docket No. 88-0348

DECISION

Before: FOULKE, Chairman: WISEMAN and MONTOYA, Commissioners.

BY THE COMMISSION:

Industrial Glass, a subsidiary of Tropicana Products, Inc., manufactures
glass bottles at its workplace in Bradenton, Florida. In its
manufacturing process, Industrial Glass melts sand and other ingredients
at a temperature of approximately 2100 Fahrenheit, feeds the molten
glass into molds, and then empties the molds onto a conveyor which
carries them through stations where the bottles are inspected and
tempered. The Industrial Glass employees who operate and maintain the
equipment used to manufacture glass bottles in the forming department
must work very near the tanks containing the molten glass and the hot
bottles on the conveyors, all of which radiate a large amount of heat.
The Secretary of Labor, acting through the Occupational Safety and
Health Administration ("OSHA"), issued a citation alleging that
Industrial Glass had violated section 5(a)(1) of the Occupational Safety
and Health Act of 1970 ("the Act"), 29 U.S.C. § 654(a)(1).[[1]] because
these employees were required to work in excessively high temperatures,
exposing them to the hazard of heat stress and to other heat-related
conditions.

Industrial Glass contested the citation, and a hearing was held before
former Commission Administrative Law Judge Joe D. Sparks. The judge
found that, although it was clear that temperatures near the machines
were very hot and that working there was uncomfortable, the Secretary
had failed to prove that the working conditions constituted a hazard.
The judge therefore vacated the citation. The judge's decision was
directed for review pursuant to section 12(j) of the Act, 29 U.S.C. §
661(j). Having fully reviewed the record in this case, we find that the
judge did not err in vacating the citation. We therefore affirm his
decision.

I. THE INDUSTRIAL GLASS OPERATION

There are three bottle-making plants at the Industrial Glass facility in
Bradenton. Plants I and 2 are housed in the same structure. while Plant
3 is in another building. In each of the three plants there are four
bottle-making machines or "shops." Each of the machines, called
"independent section machines," is approximately eight feet high and
twelve feet wide. There are eight-section machines, which produce 16
bottles at a time, and ten-section machines, which make 20 bottles at a
time. A platform four feet deep runs across the front of the machines
for the employees to stand on while they are working near the machines
and the conveyor belts.

The ingredients that go into the glass are melted in an overhead tank at
a temperature of approximately 2100 F. The molten glass is then led by
gravity to each of the machines, where "gobs" of molten glass are fed
into the molds. The machine puts two gobs into each mold to form a
"parason" (a gob with an air bubble in the center). At this stage, the
molten glass has cooled to approximately 1200 F. Compressed air is fed
into the mold to distribute the glass evenly inside the mold to form the
bottle. Then the mold opens and the formed bottle is pushed onto a
conveyor, which carries it through an inspection light, where the
operator checks for defects. The bottles come out of the molds onto the
conveyor at a temperature of approximately 900 F. By the time the
bottles reach the inspection light, the temperature has dropped to about
725 F. From the inspection light, the conveyor carries the bottles to an
oven called a "lehr,"where the bottles are "annealed" (alternately
heated and cooled slowly to temper them). When the bottles enter the
lehr, their temperature is about 600 F.

The plants Operate twenty-four hours a day, seven days a week. With some
exceptions, the employees involved in glassmaking work one shift for
seven days, rotate to the next shift for seven days, work the third
shift for seven days, and then have a week off. They therefore work
twenty-one straight days. Seven hourly employees are assigned to each
plant: four machine operators, one for each machine; two upkeep
mechanics, each of whom is responsible for two machines; and one floor
attendant, whose duties are to clean up throughout the plant and to
assist the operators and upkeep mechanics. There is also one supervisor,
who may spend approximately a third to half of his time on the floor of
the plant, but who is generally not involved in the physical operation
and maintenance of the machines.

The average tenure of the non-supervisory employees in Industrial
Glass's forming department, which is also known as the "hot end," is
over ten years. When a vacancy does occur, the company sometimes hires a
journeyman machine operator who has experience working in another glass
factory; but, more often, the company promotes from within. Employees
who have worked in the "cold end" or packaging department of the plant
may bid for the job based on seniority. An employee entering the forming
department starts as a floor attendant, the job that takes the least
training and has least exposure to the intense heat near the machines.
The floor attendant assists the operators and learns how to operate the
machines on his own. After learning this job, the floor attendant may be
promoted to apprentice operator, then to journeyman operator, and
finally to upkeep mechanic.

The operators' duties include keeping the machines running smoothly,
swabbing the molds with an oil-and-graphite lubricant to keep the
bottles from sticking to the molds, inspecting the bottles as they go
through the inspection light, taking a number of the bottles off the
conveyor for additional testing, and helping the upkeep mechanic when he
is working on the machine. The employees' activities vary substantially
from day to day and from machine to machine. Each employee receives a
15- minute break in the morning, a 20-minute lunch break, and a
15-minute break in the afternoon (or at corresponding times during other
shifts). If there is a jam or a major breakdown, an employee may have to
spend extended amounts of time at the hot machines and may have to work
through his break, although there is some dispute about how often this
occurs.

While the entire plant is hot, the heat varies from area to area. The
hottest area is near the machines because that is where the molten glass
and newly-made bottles are radiating the heat. Employees can, however,
obtain relief from the intense heat nearest the machines. For example,
the operator will frequently stand back several feet observing the
entire machine operating and watching for malfunctions, a practice
called "troubleshooting." An operator who begins to feel that he is
being affected by the heat can get the floor attendant or the upkeep
mechanic to relieve him. There are large fans, five or six feet in
height and width, throughout the plants, with at least one and sometimes
two fans per-machine. In addition, there are water fountains located
nearby, and there are drinks available from vending machines in the air-
conditioned break room.

II. THE INSPECTION AND THE CITATION

On August 26 and September 1, 1987, an OSHA industrial hygienist ("the
IH") inspected plants 1 and 2. During his initial visit, the IH took
readings at several different locations in the general area where the
employees worked to determine the Wet Bulb Globe Temperature ("WBGT"),
which combines air temperature, humidity, and air movement (which
affects cooling by evaporation). It is considered a better indicator of
the effects of heat on individuals than just the ambient air
temperature, which can be measured by a household thermometer, known as
a dry bulb thermometer [[2]]. The WBGT readings ranged from 83.4 to
101.2 F. The IH also took dry bulb readings, which ranged from 91 to 115 F.

The IH made his second visit to Industrial Glass in the late afternoon
because he had been told during his first visit that it was the hottest
time of day. He stayed about an hour and a half, during which time he
took WBGT readings in the vicinity of three different machines. Again,
his readings ranged from 83.4 to 101.2 F. During the two visits, he
observed the employees' activities and subsequently calculated an
estimate of how much energy was required to perform their duties.

Heat stress is caused by a combination of environmental heat and
metabolic heat. Environmental heat includes the air temperature, the
humidity, the air flow, and the radiant heat emanating from any hot
surfaces. Metabolic heat, the heat produced within the body, is
increased by physical activity. Because the IH believed after the
inspection that some of the employees were exposed to a combination of
metabolic and environmental heat that exceeded the threshold limit
values ("TLVs") recommended by the American Conference of Governmental
Industrial Hygienists ("ACGIH"), the Secretary issued a citation
alleging a violation of section 5(a)(1) of the Act. The citation alleged:

(a) Employees in the "hot end" of the glass plant were exposed to the
hazard of excessive heat stress during the performance of their duties
operating and maintaining the equipment used to manufacture glass
bottles. Typically, during the operation of the equipment the worker
rotates between his desk, the front end of the equipment and the back
side of the equipment.

(b) The Wet Bulb Globe Temperature Index (WBGT-IN) recorded during a
survey on September 1, 1987 from a low of 26.5 degrees Centigrade to a
high of 38.4 degrees Centigrade. Such exposures may lead to the
development of serious heat induced illnesses such as: heat stroke, heat
exhaustion, cramps and behavioral disorders, as correlated to guidelines
established by the American Conference of Governmental Industrial
Hygienists and the National Institute for Occupational Safety and Health.

(c) Among other methods, one feasible and acceptable abatement method to
correct this hazard is to provide shielding or barriers that are
radiant-reflecting or heat-absorbing, between the heat source and the
worker.

(d) Another method would be to limit exposure time by implementing a
work-rest regimen which requires mandatory, regularly scheduled breaks
for employees in the "hot end."

(e) A water supplementation schedule presented in such a way employees
are stimulated to drink five to seven ounces of liquid every fifteen to
twenty minutes will serve to augment any control measures used.

(f) Other considerations include physical fitness and acclimatization of
employees, as well as the type of clothing worn when working in hot
environmental conditions.

(g) Training of employees in the recognition and treatment of heat
related illness and the effects of non-occupational factors such as:
drugs, alcohol, and physical fitness is also recommended.

Ill. THE SECRETARY'S BURDEN OF PROOF

In order to prove it violation of section 5(a)(1), the Secretary must
establish that: (1) there was an activity or condition in the employer's
workplace that constituted a hazard to employees: (2) either the cited
employer or the employer's industry recognized that the activity or
condition was hazardous; (3) the hazard was causing or likely to cause
death or serious physical harm: and (4) there was a feasible means to
eliminate the hazard or materially reduce it. Coleco Indus. Inc., 14 BNA
OSHC 1961, 1963, 1991 CCH OSHD ¶ 29,200 p. 39.070(No. 84-546. 1991).

IV. EVIDENCE AS TO THE EXISTENCE OF A HAZARD

Much of the hearing was devoted to expert testimony. In addition to the
testimony of the IH, the Secretary presented Dr. Wilbur Spaul, a
consultant who holds a Ph.D. degree in public health and is a specialist
in industrial hygiene, concentrating in heat stress. The company
presented two expert witnesses of its own. The three outside experts and
the IH all agreed that heat stress is a combination of environmental or
ambient heat conditions (the heat in the air, the humidity, and the air
velocity) and the internal or metabolic heat Produced by the activity
being performed ("the workload"), less the cooling effects of evaporation.

A. THE SECRETARY'S EXPERT TESTIMONY

In addition to taking temperature measurements, the IH had estimated the
metabolic heat generated by the employees in performing their duties. To
do this, he observed the employees performing their jobs and estimated
their energy expenditure using tables in a booklet entitled Threshold
Limit Values and Biological Exposure Indices published by the ACGIH. The
IH stated that he considered the work to be light to moderate and
estimated the metabolic workload to he about 396 kilocalories ("Kcals")
per hour, which exceeded the limits for exposure to combined
environmental and metabolic heat contained in the ACGIH booklet.
Although the IH stated that he relied on his professional judgment and
his previous experience in making this kind of assessment, he admitted
that he had no actual training in workload assessment and that he had
performed such an evaluation only once before, in a case that had not
been litigated. After acknowledging that the employees had given him
widely varying estimates of the amounts of time spent performing various
chores, he admitted that the figure he arrived at was simply his
estimate of the energy being burned and that it may not be an accurate
reflection of the actual workload.

The consultant retained by the Secretary, Dr. Spaul, testified that he
went to Industrial Glass' plant and performed "a very brief field
evaluation," spending approximately an hour and a half in the forming
department, during which time he took temperature readings of his own.
His observations indicated that the operators divided their time
approximately equally at the operator's station, the operator's work
bench, and at the machine, where they check, adjust, and swab the
machine. Using a psychrometer to determine the WBGT, he took readings at
these three locations around machine number 8, plus readings in front of
the fan in that area. He also took readings at the same locations around
machine number 7, as well as readings in the break room and in the shade
outside the building. His measurements near the machines had a
particularly high globe reading, which indicates that there is a high
radiant heat load emanating from the machines and the bottles.

At the hearing, the expert presented an exhibit which displayed his
temperature measurements at these locations. That exhibit shows the air
temperature measured by a dry bulb, the air temperature measured by a
wet bulb, the temperature measured by the globe, air velocity, and the
WBGT reading, which is calculated by adding seven tenths of the wet bulb
reading to three tenths of the globe reading. His WBGT readings ranged
between 73.3 F in the break room to 104.4 F at the operator's station
next to machine number 7. He stated, however, that there are many
indexes that can be used to determine the likelihood that heat stress
will occur, and that he does not use WBGT readings when he is retained
by a company to evaluate the feasibility of engineering controls in its
plant because there are better indicators.

As part of his analysis, Dr. Spaul also estimated the energy being
expended by the employees to do the work. Using the operations performed
at the locations where he took temperature readings. he calculated a
time-weighted average of the environmental heat load and a one-hour
time-weighted average of the metabolic workload. First he estimated the
work-rest schedule of the operators, based on his observations of the
employees' activities during his visit to the plant and his subsequent
telephone conversations with the Industrial Glass safety director. He
estimated that, in a typical hour, the operators would spend twenty
minutes at the work bench, twenty minutes at the operator's station, and
twenty minutes at the machine. Relying on these estimates of the time
spent on each task, he created a 20-20-20 model and calculated the
one-hour time-weighted average WBGT readings for the areas around
machine number 7 and machine number 8, using the WBGT temperatures he
had taken around both machines. Based on his estimate of the work
activity, he calculated that the time-weighted average WBGT reading was
98.1 F around machine number 7 and 95.4 F around machine number 8.

After he had spoken to the Industrial Glass employees, Dr. Spaul checked
with the safety managers of other glass manufacturing plants to confirm
that the employees' estimates of the time spent doing each task sounded
reasonable. Based on these conversations, he calculated three other
one-hour time-weighted WBGT exposures for machine number 8, using
different estimates of how long the operator spent at each of the three
locations measured. Two of these calculations included a provision for
time spent by the operator near the fan. In each of his four sets of
calculations, the time estimates are in multiples of five minutes.

Using the three locations he had used in his calculations of WBGT
exposure, Dr. Spaul evaluated the tasks performed at each of the
positions and estimated the workload for each task, performing two sets
of calculations to account for the different estimates of the time spent
at each location doing the tasks performed there. He also did two sets
of workload calculations that allowed for time spent near the fan. His
calculations produced a range of energy burned between 190.5 and 312.5
Kcals per hour. When he completed these calculations, Dr, Spaul had four
one-hour time-weighted averages for metabolic and environmental heat, as
shown in the table below:

Operator's 	Work Bench 	Machine 	Fan 	WBGT 	Kcall/hr
Station 				(F) 	
20 min (98.4) 	20 min (92.4) 	20 min (95.5) 		95.4 	210 - 290
15 min (98-4) 	20 min (92.4) 	25 min (95.5) 	-- 	95.2 	212.5 - 312.5
15 min (98-4) 	20 min (92.4) 	20 min (95.5) 	5 min (86.3) 	94.4 	201.5 -
242.5
15 min (98.4) 	20 min (92.4) 	15 min (95.5) 	10 min (86.3) 	93.7 	190.5
- 250.5

Dr. Spaul then compared his environmental and metabolic heat quantities
with those in the graph in the ACGIH booklet and determined that all his
combined environmental and metabolic heat figures that he arrived at
exceeded the limits on the ACGIH graph. He therefore concluded that the
conditions at Industrial Glass exposed the operators to the hazard of
heat stress. Dr. Spaul testified that Occupational Exposure to Hot
Environments, Revised Criteria for a Recommended Standard, 1986 edition,
published by the National Institute of Occupational Safety and Health of
the Department of Health and Human Services ("NIOSH"), and the
Engineering Field Reference Manual published by the American Industrial
Hygiene Association ("AIHA") also indicated, based on his figures, that
the operators were exposed to the hazard of heat stress.

On cross-examination by the company. Dr. Spaul agreed that there is a
considerable amount of variation in the temperatures throughout the
forming department.  Dr. Spaul testified that he did observe employees
working at a number of locations where he did not take temperature
readings, including the water fountain, the weighing scale, and the
catwalk behind the machine. As a result, he could not say what levels of
hear the employees were exposed to at those locations.

Dr. Spaul stated that the company must have known that its employees
were exposed to a hazard because the employees complained to management
about the heat and because the company had provided certain controls to
limit heat exposure, such as insulation on the furnaces and melting
tanks, large fans, water fountains nearby, and electrolyte drinks
available in the vending machine in the air-conditioned break room. In
addition, electrolyte replacements tablets and drinks were available
from the nursing staff. Dr. Spaul expressed the view, however, that
these efforts were inadequate.

B. TESTIMONY BY THE COMPANY'S EXPERTS

The company presented two experts, Dr. Bertram Dinman and Dr. Stephen
Horvath, both of whom were consultants on the panel that reviewed the
NIOSH recommended standard and were contributors to Patty's Industrial
Hygiene and Toxicology, a widely-used treatise in the field. Dr. Dinman
is a physician who also holds a doctorate in occupational medicine and
has been a professor in the fields of public health, occupational
medicine, and industrial hygiene. He was an advisor to the military on
environmental hygiene, including heat stress, and for several years was
medical director, then vice president for health and safety of Alcoa,
which has many employees exposed to high temperatures in its aluminum
smelting operation. Dr. Horvath holds a pH.D. degree in medical science
from Harvard, where he conducted research on human reactions to
environmental stresses, including heat. He performed the same kind of
research for the military during World War II, and he was subsequently
on the faculties of a number of medical schools. He also worked for
Alcoa, where he and Dr. Kinmon worked together on the problems caused by
hot environments.

At Dr. Kinmon's suggestion, Industrial Glass had one of its senior
industrial engineers conduct a time motion study of an operator's
activities. He performed an 8-hour study, covering four hours on two
consecutive days, observing the operator of machine number 8, the same
machine observed by the Secretary's expert, and videotaping his
activities. He identified fourteen specific tasks that were performed
several times during the course of the study plus miscellaneous tasks
that were not repeated, all of which he pin into one category. Listing
these activities, he then used a stopwatch to measure how much time the
operator spent during the 8-hour period performing each task. He also
determined how many times each task was performed during the study.
Using this information, he was then able to determine the amount of time
spent, on the average, on each task per day and per hour.

The time motion study contains diagrams of the area where it was
conducted, identifying where each of the tasks was performed. It also
contains a breakdown of how many minutes were spent on each of the tasks
for each hour of the study and two composite typical hours. one with and
one without a break. The engineer admitted that averaging the times
would not give an accurate picture of the operator's activities, because
it eliminates the peaks and valleys of certain activities, but he stated
that he did not observe a great variance from hour to hour during the
periods studied. Throughout the study, there were the sort of minor
breakdowns and jams that occur routinely, and the machine did have a
breakdown on one of the days, requiring more activity close to the
machine, the source of the heat. In contrast to Dr. Spaul's 20-20-20
model, the fourteen specific tasks identified by Industrial Glass'
time/motion study required between 20 seconds and 3 minutes,10 seconds
per occurrence. and required a total of between 3 minutes and 1 hour, 40
minutes over the course of an 8-hour shift.

Both of the experts retained by Industrial Glass visited the plant. One
of them, Dr. Dinman, observed the operation for between four and five
hours, while the other, Dr. Horvath, observed the last three or four
hours of one shift and the first two hours of the next shift. Both
questioned the operators about their activities and satisfied themselves
that the conditions they were observing were typical. Each of them
studied the videotapes made during the time/motion study to help them
determine the precise motions involved in the activities of the operator.

Using the videotapes and the time/motion study, the experts each
performed a workload analysis similar to the one performed by Dr. Spaul.
They analyzed each task, breaking it down into its various motions,
determining the workload for each element of each task, then adding them
to get the workload for the entire task. The Kcals for each task were
multiplied by the minutes per hour spent performing that task, and those
products were then totaled. Dr. Dinman calculated the operator's
exertions as ranging from 132 to 167 Kcals/hour, while Dr. Horvath
calculated them at 136 to 138 Kcals/hour. Based on these figures, the
company's experts both concluded that the operator's actual metabolic
workload was substantially less than estimated by the IH and Dr. Spaul.
Both of them stated that, even if they accepted the Secretary's
temperature measurements and calculations of the environmental heat load
as correct. [[3]] the employees were not exposed to a total heat load
great enough to cause heat stress.

Explaining how he reach his conclusion, the first expert, Dr. Dinman,
stated that it is important to identify all locations where an employee
would work during the course of his job and to determine the
temperatures at each of those locations. He explained that, if the
temperatures vary from location to location, it is necessary to
determine how much time the employee spends in each location. Dr. Dinman
testified that the time/motion study was useful to determine the
locations where the employees worked, the amounts of time spent in each
location, and the metabolic heat generated by the employee's activities.

The other expert, Dr. Horvath, stated that a person's heart rate is an
indicator of how much he is exerting himself. While he was at the
Industrial Glass plant, Dr. Horvath took the pulse of the operator on a
number of occasions, comparing the rates after certain tasks with the
resting rate. The difference was so slight that he concluded that the
operator's duties were not strenuous. Dr. Horvath reinforced this
conclusion in the laboratory, where he and his staff copied the various
motions involved in some of the operator's tasks, measuring the carbon
dioxide produced. Even though the lab had highly sophisticated
equipment, he could not measure enough of an increase to be considered
significant.

Dr. Horvath stated that he had been involved in numerous time/motion
studies himself and could tell that the company's in-house study had
been carefully done.  Dr. Horvath noted that he considered the company's
study "informative," but he knowledge that a longer study would likely
have included a wider range of conditions and tasks not performed
frequently.  He did, however, have the benefit of a 12-day time/motion
study performed by another glass company which had retained him as a
consultant.  That company used the same kind of machinery as Industrial
Glass, and its employees' activities were similar.  He testified that
his preliminary analysis of that study produced a metabolic expenditure
very close to the figures he got in this case.

Both of the experts presented by the company had worked for Alcoa, where
there were high levels of heat radiated by large amounts (750 pounds) of
molten aluminum.[[4]]  The temperature of the bottles coming out of the
molds is approximately the same as that of the molten aluminum with
which the two witnesses were familiar.  Both of the company's experts
had served on the panel which had developed the NIOSH recommendations
and were familiar with the studies underlying the figures and the
process by which figures had been decided.  Both were very critical of
the series of compromises involved in developing the recommendations,
asserting that there was little or no scientific basis for some of the
recommendations, particularly the conclusion, represented by the curve
on the graph, that continuous work at an energy expenditure below the
200-Kcal level exposes employees to heat stress.

C. THE NON-EXPERT EVIDENCE

The Secretary presented as witnesses a number of Industrial Glass
employees, who testified that they had experienced various ailments that
they attributed to the heat, including headaches, dizziness, nausea,
muscle cramps, and problems with their vision.  For example, the union
president testified that he had fainted twice.  The first occasion was
approximately ten years before the hearing, when he felt hot, went to
get a drink of water, and collapsed.  The second incident occurred about
a week before the hearing was held, while he was in the employees'
shower room talking to some other employees.  He felt weak and told the
other employees that he was going into the other room to lie down.  As
he started to go into the other room, he collapsed.  On both occasion's,
the company's nursing staff was called and treated him.  On the second
occasion, the nurse called an ambulance for him, but he refused to go to
the hospital. In general, the employees testified, they did not seek
treatment from the company's nursing staff or from a physician.  In
response to an OSHA subpoena, the nursing staff reviewed its records and
found only seven reported incidents in a 4 1/2 year period which might
be attributable to the heat.[[5]]

Some of the employees testified that, when they or other employees had
brought thermometers to the plant from home and had placed them around
the work area, some of the thermometers had hit their maximum readings,
and that one that was calibrated up to 180 F reached 160 F. [[6]]  There
was also testimony that the clothing of some employees had caught fire
from the heat.  A witness for the company, who had been an operator
himself, testified, however, that clothing cannot catch fire solely from
the heat; it can happen only if the clothes come into contact with the
hot glass when the bottles come out of the mold onto the conveyor.  In
his experience this occurs only rarely. [[7]]

V. ANALYSIS

As noted above, to prove a violation of section 5(a)(l), the Secretary
must show that the employees were exposed to a hazard in the workplace.
  The Secretary presented both expert and employee testimony addressing
this element.   Having reviewed the record, we find that the Secretary
has not established by a preponderance of the evidence that there was a
hazard present in the Industrial Glass forming department.

The citation identified the hazard as "excessive heat stress" (emphasis
added), perhaps in recognition that at least some amount of heat stress
is an inevitable part of this operation.  In her subsequent complaint,
the Secretary alleged: "Respondent violated § 5(a)(l) of the Act in that
it allowed its employees in the 'hot end' of the glass plant to be
exposed to excessive heat stress while operating and maintaining
equipment used to manufacture glass bottles."  The bulk of the evidence
the Secretary presented to prove that there was a hazard was the expert
testimony that the employees were exposed to a combination of
environmental and metabolic heat that was excessive because it exceeded
the limits permitted under the NIOSH, ACGIH, and AlHA documents, while
the company's primary evidence that there was no hazard is the testimony
of its two experts.  All three expert witnesses were highly qualified,
and the opinions of the company's experts are in direct conflict with
those presented by the Secretary's, making it difficult to evaluate the
voluminous evidence in this controversy.  Had the company not presented
such a strong rebuttal of the Secretary's case, we might have found the
testimony of the Secretary's expert that the employees were exposed to
the hazard of heat stress to be persuasive.

Two factors weigh heavily in our decision in favor of the company,
however: the eminence of its experts; and the fact that their testimony
was based on a time/motion study that identified four or five times as
many tasks as were assumed in the model relied on by the Secretary's
expert.  In view of the company's time/motion study, we simply cannot
give much weight to the portion of the Secretary's evidence that was
predicated on the assumption that the operators spent twenty minutes of
each hour at one location performing one task, twenty minutes at another
location performing another task, and twenty minutes in a third location
doing a third task.

It is clear from the record that the operator's duties are much more
varied than assumed by Dr. Spaul's -20-20-20 model and that, contrary to
the assumption by the Secretary's expert, an operator spends far more
time in locations that are removed from the bottles and the machines,
which are the source of the heat.  As Dr. Dinman testified, a study
which records the operator's minute-by-minute activities and analyzes
them job component by job component will be more precise than the rough
estimates relied on by the Secretary.[[8]]  Because we have no heat
measurements for these other locations, some of which are several feet
from the machines, we cannot determine what the temperatures are in
those locations.  Since we are not able to ascertain the levels of the
employees' heat exposure at each work station, we cannot make any
determination of their overall environmental heat exposure.

Even if we assume arguendo that exceeding the exposure limits set out in
NIOSH's recommended standard and in the ACGIH and AIHA publications
would prove that there was a hazard within the meaning of section
5(a)(1) based on the information in this record, we are unable to
determine whether an employee's total heat exposure would in fact exceed
those levels of heat exposure.  Because the testimony of the Secretary's
expert was based on temperature readings that did not accurately reflect
the movements of the employees around the forming department, the
Secretary has not carried her burden of establishing that the levels of
environmental heat were excessive.

We are also unable to give much weight to the calculations of metabolic
heat by the Secretary's expert, who testified that he frequently does
physiological workload assessments of the sort performed by Dr. Horvath
at the plant and in the laboratory, but conceded that he elected to use
the tables in this case because such assessments are time-consuming and
tedious.  Dr. Horvath testified that it was it mistake for the Secretary
to assume so few tasks.  The company has argued that the Secretary's
calculations of the employees' metabolic workload were based on
inadequate information because they assumed only three or four
activities.  The judge agreed with that argument and we do as well.  The
company's experts, working separately, both arrived at significantly
lower workload levels.  Given the more detailed information on which
their analyses were based and the more precise methods used to assess
the energy expenditure, we are inclined to give them more weight than
the calculations of the Secretary's expert.  We note that Dr. Spaul and
the IH both admitted that the employees gave them widely varying
estimates of they time they spent performing the different tasks on
which they based their metabolic heat estimates.  We therefore accept
the metabolic heat estimates of the company's experts rather than those
of the Secretary's expert and the IH.

The Secretary has emphasized that one of the company's experts testified
that the work done by an operator was about twice as strenuous as
driving a car.   For a number of reasons we are not certain exactly what
that testimony means or how much weight to give.

First, the witness also testified hat the figure given for driving a car
in the ASGIH booklet seemed much too high to him.[[9]]  In addition,
both parties presented evidence that there was a base figure for a body
at complete rest, although the figures presented by the Parties differ. 
Neither party, has explained whether "twice as strenuous" is calculated
by subtracting this base number first.  Then doubling the remainder, of
by doubling the actual figure for driving a car. The Secretary's reply
brief simply doubles the figure given in the ACGIH booklet, but it is
not at all clear to us that doubling is the proper way to make the
calculation.   The calculations in the NIOSH recommendation suggest that
the basal metabolism remains constant and that additions are made to
that figure depending on the activity and the position in which the
activity is performed.  The ACGIH document is not so clear, however, We
therefore do not know whether the calculation in the Secretary's brief
is correct.  Because we cannot determine on this record exactly what
"twice as strenuous" means, we do not know how much weight to accord
that statement.

The Secretary has argued that one of the company's supervisors testified
that the work in the forming department was comparable to heavy
construction, which he had previously done.  A review of that testimony,
however, reveals that the witness was not referring to how strenuous the
work was.  What he said was that the heat was comparable to being on a
metal roof in the summer.  His testimony therefore does not contradict
that of the company's experts.

The Secretary has further asserted that the NIOSH, ACGIH, and AIHA
documents establish a maximum WBGT level of 86 F for employees
performing continuous light work at a level below 200 Kcals per hour. 
We find, however, that, even if we assume that exceeding this
recommended limit would he a hazard, the Secretary has not established
that the cited employees were performing "continuous work".   Although
the Secretary's expert testified that it was his impression that the
employees were under a continuous workload, the testimony of the
employees shows that, to the contrary, they do rest between activities,
and they can get away from the source of the heat even while they are
performing their duties.  The Secretary's expert may have believed that
the operators' activities placed them in the "continuous work" category,
but the record makes it clear that working without taking an official
break within the meaning of the employment contract is not the same as
working without pause or rest.  The employees did not engage in constant
action but took brief breaks between tasks and even rested momentarily
during a task.  We therefore find that Industrial Glass's employees did
not fall within the "continuous work" category as the Secretary claims.

We must note that we would be hesitant to hold that exceeding those
levels is, in and of itself, proof of exposure to a hazard.  The
Secretary asserts that they are the dominant guidelines on heat stress
and are followed by all professional industrial hygienists.  Dr. Spaul,
the Secretary's own expert witness, testified, however, that all three
documents were essentially copied from each other and that they all
contained a substantial safety margin.  While it would be very
appropriate for the Secretary to include a safety margin in an OSHA
standard, the presence of a safety margin in the documents she relied on
to prove a hazard here gives us reservations as to whether evidence that
the limits in the NIOSH document were exceeded would, in fact, prove
that there was a hazard.[[10]]  Furthermore, Dr. Horvath testified that
some of the work on which the NIOSH curves were based had subsequently
been discredited to a large extent, and both of the company's experts
testified that there was inadequate scientific information to support
some of the assumptions shown on the graphs in these documents.  We
therefore have considerable reservations about basing a violation of
section 5(a)(l) or those guidelines.  Because we are deciding this case
based on the insufficiency of the Secretary's evidence, however, we need
not decide whether a violation of section 5(a)(l) would have been
established if the Secretary had proved that the limits in the documents
had been exceeded. [[11]]

Having concluded that the Secretary failed to establish the presence of
a hazard by expert testimony, we must examine the other evidence
presented by the Secretary, namely the testimony of the employees. 
While the employee testimony regarding the difficulties they experienced
because of the hot working conditions troubles us because it clearly
shows that this is an uncomfortable working environment and that
employees do suffer from the effects of the heat, [[12]] the citation's
identification of the hazard as excessive heat stress suggests that the
Secretary recognizes that some degree of discomfort is inherent in the
job.  The testimony as to headaches, dizziness, nausea, fatigue, muscle
cramps, and even the two instances of fainting must be balanced against
the fact that many of the abatement measures sought by the Secretary
were already in place to one degree or another.

We note that Congress intended that an employer's duty to free its
workplace of hazards under section 5(a)(l) to be an achievable one. 
Nat'l Realty & Constr. Co. v. OSHRC, 489 F.2d 1257, 1265-66 (D.C. Cir.
1973).  Here, Industrial Glass had installed insulation on the melting
tanks.  Near every machine, there was at least one large blower and a
water cooler.  The company had moved the machines farther apart, which
reduced the concentration of heat.  There were electrolyte drinks
available to the employees, both through the nursing staff and in it
vending machine in the break room, which was air conditioned.  The
nurses also had electrolyte tablets available for any employee who
suffered from the effects of the heat.   Before a new employee was hired
for the forming department, the nursing staff took a medical history and
performed an assessment of the individual's medical fitness to work in a
hot environment.  If they did not find that the candidate was medically
suitable, they informed the personnel department.  There was also a de
facto acclimatization by virtue of the one-week orientation that was
part of a new employee's training.  There wits already established a
"buddy system" among the employees of watching out for each other and
relieving, an employee who began to be affected by the heat. Also, there
was testimony that, on at least one occasion the foreman sent an
employee home when he had difficulty with the heat rather than allow him
to be exposed to excessive heat.  We realize that these measures do not
absolutely guarantee that an employee will never suffer from exposure to
the heat, but the record shows that it is virtually impossible to
eliminate all exposure to high temperatures in this Job.[[13]]

We recognize, as the secretary apparently did, that the working
conditions in the forming department are, to some extent, an inevitable
part of this kind of work.  The employees who testified appear to have
considered the conditions to be uncomfortable rather than hazardous. The
employees who testified that they suffered various ailments from the
heat admitted that they did not seek any medical help, and the union
officer who fainted twice refused to go to the hospital even though an
ambulance had been called for him.  It therefore appears that the
employees considered the heat conditions to be more of a discomfort than
a health hazard.[[14]]  As noted above, the jobs in the forming
department, which involve higher pay, are considered desirable and are
highly sought after by Industrial Glass employees who work in the
packaging department.  They are filled on the basis of seniority unless
an experienced glassmaker is hired.

Accordingly, based on the expect testimony and the measures present in
the forming department to reduce employee exposure to heat and to
alleviate its effects, we conclude that the Secretary has failed to
prove by a preponderance of the evidence that the working conditions in
the forming department presented a hazard within the meaning of section
5(a)(1) of the Act.

VI. CONCLUSION

We recognize that excessive exposure to heat can be a hazard, but the
record in this case shows that the company has made an effort to
alleviate the effects of the hot working conditions in the forming
department.  We find here that the Secretary has failed to establish by
a preponderance of the evidence that the working conditions in the
forming department constituted a hazard that was likely to cause serious
harm to the health of the employees.  For these reasons, we conclude, as
the judge did, that the Secretary has failed to prove that Industrial
Glass committed a violation of section 5(a)(1) of the Act by exposing
its employees to the hazard of heat stress.

We therefore hold that the Secretary has failed to carry her burden of
proving that there was a heat stress hazard in the Industrial Glass
forming department.  Accordingly, we affirm the judge's decision
vacating the citation.

Edwin G. Foulke. Jr.
Chairman

Donald G. Wiseman
Commissioner

Velma Montoya
Commissioner

Dated: April 21, 1992

------------------------------------------------------------------------

SECRETARY OF LABOR,
Complainant,

v.

INDUSTRIAL GLASS,
Respondent, and

GLASS, MOLDERS, PLASTIC, POTTERY AND ALLIED WORKERS, LOCAL 208,

Authorized Employee Representative.

OSHRC Docket No. 88-348

APPEARANCES:

Stephen J. Simko, Jr., Esquire, Office of the Solicitor, U. S.
Department of Labor, Atlanta, Georgia, on behalf of complainant.

William B. deMeza, Esquire, Holland and Knight, Tampa, Florida, on
behalf of respondent.
Mr. John Ward, President, Glass Molders, Plastic, Pottery and Allied
Workers, Local 208, Bradenton, Florida, on behalf of the authorized
employee representative.

_DECISION AND ORDER_


SPARKS, Judge:     Respondent, Industrial Glass, contests a citation for
the serious violation of section 5(a) (1) [[1]] of the Occupational
Safety and Health Act ("Act") for allowing its employees in the Forming
Department to be exposed to excessive heat stress while operating and
maintaining equipment used to manufacture glass bottles. The case was
ably tried and briefed by counsel, and extensive testimony and
documentary evidence were received into the record.

I.

Industrial Glass is a division of Tropicana Products, Inc., which
operates several facilities located on 214 acres of land in Bradenton,
Florida. Industrial Glass manufactures glass bottles in various sizes in
three glass plants in Bradenton, where approximately 400 glass unit
workers are employed (Tr. 28- 29).

The Forming Department in Plant 2 contains four independent sections
("I.S.") glass making machines called "5 Shop," "6 Shop," "7 Shop," and
"8 Shop" (Tr. 97-98, 773).  Employees in the Forming Department work
seven-day rotating shifts. They work one shift seven straight days and
then rotate to another shift or off duty. Industrial Glass runs three
shifts each day, seven days a week. Shifts are 8:00 a.m. to 4:00 p.m.,
4:00 p.m. to 12:00 a.m., and 12:00 a.m. to 9:00 a.m. Plant 2 employs
seven hourly employees per shift: four operators, two upkeep mechanics,
and one floor attendant (Tr. 26-27, 783, 824-825).

Plant 2 shops produce between 100 and 294 bottles per minute (Tr. 39).
To produce the glass bottles, the raw sand batch and glass cullet
mixture is melted in the tank above the I.S. machine. The glass at that
point is between 2000 and 2100 degrees Fahrenheit. The molten glass
drops down and is sheared into gobs through the feeder into the molds.
Two gobs drop into each mold. The gob is formed into a parason, a gob
with a bubble in it, and a finish, the part of the bottle where the
bottle where the cap is attached. The bottle is now upside down. Air is
blown on the outside to form and cool the glass. The glass is then
inverted into the mold. The mold closes around it and compressed air is
blown into the bottle to form it. The mold then opens and the bottle is
pushed onto the conveyor and proceeds down the inspection light and the
lehr. The lehr performs annealing, a gradual cooling of the glass. The
glass is molded at about 1200 degrees Fahrenheit. When it is placed on
the conveyor, its temperature is between 700 and 900 degrees Fahrenheit.
The smaller bottles are cooler. The largest bottle made on these
machines is a 1.75-liter liquor bottle. The temperature of this bottle
is about 850 degrees Fahrenheit coming onto the conveyor. At the
inspection light, the temperature of the bottle drops to 725 degrees
Fahrenheit; and, when entering the lehr, the bottle temperature is 600
degrees Fahrenheit (Tr. 775-783, 800-801).

The operators' duties include observation of the operation of the glass
making machine, quality control checks by testing bottles, swabbing the
molds with graphite oil front and back (doping), assisting on clearing
jam ups and helping the upkeep men to change molds and repair machines
if needed. Operators usually work 1.5 to 5 feet from the molds (Tr. 40-46).

The upkeepmen's duties include working on and repairing machine
breakdowns, changing molds, fixing defects in the glass, working on the
tanks that melt the glass, repairing and maintaining the feeders and
relieving operators for breaks. Each upkeep person is responsible for
two machines. Duties require these employees to be next to the machines
(T. 59-61, 259-260).

The floor attendants' duties are to clean glass from underneath the
machines, keep glass off of the floor, keep the barrels dumped out, and
see to the needs of the operators and upkeep people. Their work often
requires the floor attendants to work close to the machines (Tr. 287-288).

Forming Department employees receive two 15-minute breaks and a
20-minute lunch break during each eight-hour shift (Tr. 107).The break
room is air conditioned (Tr. 104).

Industrial Glass employs four registered nurses who work on the plant
premises. The nurses do not work the 12:00 a.m. to 8:00 a.m. shift or
any weekend shifts (Tr. 26-27). Industrial Glass does not have
physicians on the premises but uses doctors on call in the community for
medical conditions and accidents or injuries (Tr. 149).

OSHA Industrial Hygienist Byron Blanke began his inspection of
Industrial Glass' facilities on August 26, 1987, pursuant to a complaint
received in his office (Tr. 368). Blanke took temperature measurements
at several locations throughout the facilities. He returned to the
facilities on September 1, 1987, and took additional readings (Tr.
368-371). As a result of Blank's inspection, Industrial Glass was issued
a citation for the violation of § 5(a)(1) on January 13, 1988.

II.

In order to establish a section 5(a)(1) violation, the Secretary must
prove: (1) the employer failed to render its workplace free of a hazard,
(2) the hazard was recognized either by the cited employer or generally
within the employer's industry, (3) the hazard was causing or was likely
to cause death or serious physical harm, and (4) there was a feasible
means by which the employer could have eliminated or materially reduced
the hazard.

The Duriron Co., 83 OSAHRC 22/A2, 11 BNA OSHC 1405, 1407, 1983 CCH OSHD
¶ 26,527 (No. 77-2874, 1983), affirmed 750 F.2d 28 (6th Cir. 1984).

The Secretary alleges that Industrial Glass failed to render Plant 2
free of excessive heat in the Forming Department, where operators,
upkeep mechanics, and floor attendants were exposed. Industrial Glass
contends that while conditions in the Forming Department may have been
uncomfortable, they did not rise to the level of a recognized hazard
likely to cause death or serious injury. If excessive heat exposure did
exist, Industrial Glass' employees were put at a significant risk.

Exposure to excessive heat can result in heat exhaustion and heat
stroke. At high temperatures, the body circulates great amounts of blood
to the skin in an effort to eliminate heat through perspiration. As a
result, less blood is circulated to the body's vital organs, including
the brain. Heat exhaustion can lead to dizziness, nausea, and eventual
collapse. If not treated promptly, a person suffering from neat
exhaustion could suffer brain damage.

Beyond heat exhaustion is heat stroke.... [D]uring heat stroke the body
stops sweating, making it impossible to eliminate heat. The body
temperature may rise to a dangerously high level and cause death.

Id. at 1406.

Several Industrial Glass employees testified as to the conditions in the
Forming Department. They established that, although their union contract
since 1983 had called for a heat relief break in addition to the
morning, lunch, and afternoon break, operators did not start receiving a
heat relief break until one and a half months before the August, 1988,
hearing. Upkeep mechanics and floor attendants were still not receiving
heat relief breaks at the time of the hearing (Ex. C-1, C-2; Tr. 64,
187, 215, 317). The employees also testified that at one time the
employees in the Forming Department started bringing in various home
thermometers, including baking and pool thermometers, and hung them
around the work area. The thermometers were eventually taken down by
supervisory personnel, but not before the employees observed readings of
140 to 160 F. (Tr. 118, 190-191, 219-225, 269).

Several employees related instances where they experienced discomfort
which they attributed to the excessive heat. John Ward, an upkeep
mechanic and union representative, testified that just two weeks prior
to the hearing, he fainted due to the heat after working six and a half
to seven hours in front of the machines (Tr. 73-74):

I was talking to several of my committee members in the shower room. I
had a bad headache, I was sweating, I was burning up, I got severe pains
in the back of my head, and I told them I was going to lay down. I
started into the other room in the shower room to lay down and I
couldn't see. And I ended up on the floor.

Ward was treated by a staff nurse. He did not consult a physician
regarding this incident so there was no confirmation that his distress
was attributable to excessive heat in the workplace (Tr. 124-125).

Ronald Sykes worked as a floor attendant for Industrial Glass for six
months, including the summer of 1987. He described the conditions as
follows (Tr. 189):

Well, especially this time of year, it's real hot. Once in a while,
you'd have a kind of dizzy spell. Like, you know, it would be so hot,
you would just have to back away and just stop for a while . . .  You
were always soaked with sweat or something in there . . . . Once in a
while maybe, .you know, depending on, I guess, the humidity or whatever,
just different things, dizziness, stuff like that.

Sykes never went to the staff nurses or sought medical treatment with
regard to any of the symptoms he mentioned (Tr. 192). The company
provided water, fans and an air conditioned break room, but the
environment near the machines was extremely hot.

The testimony of the employees establishes that the heat in the Forming
Department at times was oppressive but standing alone, does not prove
that the heat was so excessive as to excessive injury. The thermometers
that the employees brought in were for home use and not calibrated to
the degree of accuracy necessary to establish their readings. Helen
Heatherington, a staff nurse for Industrial Glass for eight years,
testified that employees from the Forming Department sought treatment
from the nursing staff less frequently than employees from other
departments (Tr. 175). A medical record review prepared by the head
nurse, Edna Davis, for the period from January 1984 to June 1988,
disclosed that a total of five employees came to) the nurses a total of
seven times complaining of symptoms that may have been heat related (Ex.
C- 12). None of these employees ever consulted a physician with regards
to their complaints, and no medical evidence exists that could support
the employees contentions that their complaints were caused by excessive
heat. As Industrial Glass pointed out at the hearing and in its
posthearing brief, symptoms of heat stress are similar to symptoms of
other ailments, including the flu and hangovers.

Turning from the employee witnesses' testimony, then, it is necessary to
evaluate the testimony of the expert witnesses, who sought to calculate
the amount of heat stress present in the Forming Department. The
standard instrument for testing heat stress is the Wet Bulb Globe
Thermometer ("WBGT"). The WBGT takes into account humidity and air
movement (the natural wet bulb reading ("NWB")), and air velocity and
air temperature (the black globe reading ("GLOBE")] (Ex. C-6, pp. 3,150;
Tr. 464). The calculation for WBGT for indoors is (Ex. C-22, p.5):

WBGT = 0.7 NWB + 0.3 GLOBE

On September 1, 1987, Compliance Officer Blanke took eight measurements
in the Forming Department, which ranged from a low of 83.4 F. to a high
of 101.2 F. for WBGT (Ex. C-15). Dr. Wilbur Spaul, the Secretary's
expert witness, who holds a Ph.D. in Environmental Health Sciences,
visited Plant 2 on June 15, 1988, and took his own WBGT measurements
(Tr.469). Dr. Spaul was knowledgeable, conscientious and convincing. His
testimony was defective only in that he did not make or was not allowed
to make, the detailed investigative findings as was respondent's expert
witnesses. Spaul calculated that the average 'WBGT for machine No. 8 was
4 F. based on a one-hour time-weighted average (Tr. 507, 510)

Dr. Spaul spoke with Steven Looby, the safety manager for Industrial
Glass, who informed Spaul that during an average hour, operators spent
20 minutes at the operators' work station on the platform, 20 minutes at
the test stand, and another 20 minutes in the general area of the
machine (Tr. 506). Based upon Looby's estimate and his conversations
with employees, Dr. Spaul concluded that operators were under a
continuous workload (Tr. 490). Dr. Spaul also called several glass
plants and spoke with the safety managers to get their estimates of
their operators' work/rest schedules (Tr. 493). Although information
from these sources was helpful, it is not afforded the weight given to
the time and motion studies offered by respondent and relied upon by its
expert witnesses.

Dr. Spaul used three guidelines in making his calculations after
ascertaining the WBGT; (1) the American Conference of Governmental
Industrial Hygienists ("ACGIH"), Threshold Limit Values and Biological
Indices for 1986-1987 (Ex. C-4); (2) National Association for
Occupational Safety and Health ("NIOSH"), "Criteria for a Recommended
Standard . . . Occupational Exposure to Hot Environments: Revised
Criteria 1986" (Ex. C-6); and (3) American Industrial Hygiene
Association ("AIHA"), "Engineering Field Reference Manual" (Ex. R-9: Tr.
473-479). Respondent's expert witnesses questioned the reliability of
the guidelines, contending there were inadequate studies to support the
conclusions but no reasonable alternative was suggested. They are
endorsed by the leading organizations in the field.

Dr.Spaul testified that heat stress is calculated by adding metabolic
heat to environmental heat, then subtracting the heat lost through
evaporation (Tr. 471- 473). Metabolic workload is calculated in
kilocalories per hour ("Kcal/hr"). AIHA, ACGIH, and NIOSH define light
work as work up to 200 Kcal/hr (Ex. C-4, p. 70). Dr. Spaul determined
that the average level of energy required to perform the operators' job
was 200 Kcal/hr (Tr. 518-525). His actual readings ranged from 190
Kcal/hr to over 300 Kcal/hr (Ex. C-22, p. 13; Tr. 490, 492, 495, 510, 519).

ACGIH and NIOSH have established the maximum WBGT to which employees may
safely be exposed at any metabolic workload above 200 Kcal/hr. The
maximum WBGT for a continuous workload of 200 Kcal/hr is 86 F. (Ex. C-4,
p. 72, figure 1). Based upon his calculations of the WBGT and the
metabolic workload, Dr. Spaul concluded that the operators in Industrial
Glass' Forming Department were exposed to excessive heat (Tr. 469). The
weakness in Dr. Spaul's conclusions results from the underlying
determination that employees were under a continuous light workload
requiring energy use of 200 Kcal/hr.

Industrial Glass presented two expert witnesses, Dr. Bertram Dinman, a
Clinical Professor of occupational Medicine, and Dr. Stephen Horvath, a
Professor of biomedical Engineering (Tr. 673, 840).. Both men have had
and distinguished careers and are highly regarded in the field of heat
effects on the human work capacity. They separately evaluated
unimpeached time and motion studies which had been made on employees in
the Forming Department (Tr. 857). They observed two shifts for four or
five hours on two different shifts (Tr. 696). They also reviewed a
videotape of an employee operating an I.S. machine (Ex. R-2; Tr. 693,
696-697, 765). Dinman and Horvath calculated a total hour-by-hour
metabolic workload by determining that an operator performs 15 separate
tasks in his or her job, and assessing the metabolic workload for each
of the 15 tasks. The individual workload components were time-weighted
and totaled (Tr. 695-702). The greater weight given to the testimony of
Drs. Dinman and Horvath is directly attributable to the greater
probativeness of the evidence upon which they based their conclusions.

Dr. Dinman found that the operators' metabolic workload ranged from 132
to 167 Kcal/hr. Dr. Horvath calculated the workload to be 136 to 138
Kcal/hr. Both concluded that the metabolic workload was mild (Tr. 857).
Dinman and Horvath concluded that employees in the Forming Department
were not exposed to excessive heat.

Industrial Glass attacks Dr. Spaul's calculations as invalid and
inaccurate. Industrial Glass notes that Inspector Blanke and Dr. Spaul
measured temperatures only at selected points around the I.S. machines,
and that Spaul only Calculated the metabolic workload for operators,
ignoring the exposures of upkeep mechanics and floor attendants.
Industrial Glass also points out that Dr. Spaul calculated his
time-weighted averages based on rough estimates given by Looby, safety
managers at other glass plants, with no showing that their I.S. machines
or employee tasks are similar to those of Industrial Glass. While Dinman
and Horvath identified 15 separate tasks performed by the operators,
Spaul broke down the operators' tasks into only three categories (Ex.
-22, pp. 9-11). However, it is concluded that Dr. Spaul's testimony is
not convincing only because the facts upon which he relied were inferior
in quality and quantity than those available to respondent's experts.

There is much evidence that employees suffered severe heat discomfort,
especially during the summertime. Although heat is necessary in the
glass making industry, evidence is lacking that respondent did
everything possible to alleviate those conditions. But the Secretary has
not carried her burden of proof on the essential element that a hazard
did in fact exist. Looked at together, it is evident that Industrial
Glass' expert testimony was much more specific and comprehensive; and,
therefore, more accurate and creditable, than that of the Secretary. The
Secretary did not prove that employees in Industrial Glass' Forming
Department were exposed to excessive heat so as to establish a hazard
under section 5(a)(l). Industrial Glass was, therefore, not in violation
of section 5 (a) (l).

The foregoing constitutes the findings of fact in this case.

_CONCLUSIONS OF LAW_

1. Respondent is subject to the Act and this proceeding.

2. Respondent did not violate section 5(a)(l) of the Act.

_ORDER_

The citation and complaint are dismissed.

Dated this 29th day of March, 1989.

JOE D. SPARKS
Judge



FOOTNOTES:

[[1]] Section 5(a)(1) provides "Each employer shall furnish to each of
his employees employment and a place of employment which are free from
recognized hazards that are causing or likely to cause death or serious
physical harm to his employees."

[[2]] In contrast to a household, or dry bulb thermometer, a wet bulb
thermometer has a bulb that is covered by a saturated cloth. This
reading is affected by the rate of evaporation, which is determined by
humidity and air velocity. Another type of device, the global
thermometer, is set in a matte black metal sphere and measures radiant
heat. All the global temperatures taken by the IH and the Secretary's
expert were higher than the other readings at the same locations,
indicating that there is a great deal of radiant heat in the forming
department.

[[3]] They did, however, question the Secretary estimates of the
employees exposure to environmental heat because the time motion study
showed that the employees were not limited to three or four locations.

[[4]] Dr. Horvath noted that one of the difficulties in making an
accurate measurement of an individual's heat exposure in a situation
like this with a high level of radiant heat is that one side of the
person may be exposed to a low level of heat while the other side is
exposed to a great deal of heat radiating from the source.

[[5]] Both of the incidents involving the union president fell outside
the period surveyed by the nursing staff.

[[6]] Dr. Horvath cast doubt on these readings, however, because he
stated that the thermometers should be shielded from radiant heat
sources in order to get an accurate reading of the air temperature. He
testified that, depending on where the thermometer was placed, heat
radiating at it from all sides could give an artificially high reading.

[[7]] The citation alleged the hazard of heat stress. It does not
mention burns. While there is some evidence that in employee is more
likely to be inattentive and bring his clothing into contact with the
bottles if he is suffering the effects of the heat, we cannot say that
the citation covers the situation described.

[[8]]The Secretary has argued that a time motion study based on four
hours per day over two days is hardly likely to give an accurate
reflection of all the conditions under which an operator will work. We
agree. All of the experts were in agreement that a study covering a much
longer period would have been more desirable. The company's. time motion
study is, however, the best evidence we have. It is certainly more
accurate than the estimates relied on by the Secretary's consultant who
admitted that he would prefer to base his evaluation on observation of
the operator's activities for a minimum of five days rather than on his
observation for only 1 1/2-hours.

[[ 9]] In the table of energy expenditure, a substantial range is given
for activities such as lying at ease, sitting at ease, and casual
walking, but a single figure is given for driving a car. It seems to us,
however, that the level of energy expended driving an automobile can
vary greatly, depending on the type of automobile and the road. For
example, it seems unlikely that the same amount of energy would he
required to drive a car with automatic transmission and cruise control
along a straight, flat interstate highway as would he required to drive
a standard shift car along a windy mountain road or in city traffic
during rush hour. Given these potentially large differences in the
amount of energy required to operate different automobiles under
different conditions, we cannot say with any confidence that the parties
were talking about the same activity. We also note that, on the table of
energy expenditures in the AIHA Engineering Field Reference Manual, on
which the Secretary relies. The value given for sitting at ease is
substantially higher than the values given for both mechanical typing
and electrical typing Because we do not understand this seeming
incongruity, we do not know how much authority we can attribute to the
contents of this table.

[10] In 1972, NIOSH recommended that OSHA adopt a standard governing
exposure to heat, and a panel appointed by OSHA endorsed that
recommendation in 1974. Nevertheless, OSHA has not adopted a heat stress
regulation but has relied here on the NIOSH criteria and on guidelines
issued by two private organizations of industrial hygienists. The
essence of the Secretary's allegation is that the heat exposure limits
set out in those documents were exceeded and that the employees were
therefore exposed to the hazard of heat stress. The NIOSH standard,
however, does not have the force and effect of law; failure to comply
with it is not in and of itself illegal.

[[11]] Contrary to the Secretary's assertion, the Commission's decision
in The Duriron Co., 11 BNA OSHC 1405, 1407 n. 2. 1983-84 CCH OSHR
26,527, p. 33,798 n. 2 (No. 77-2847.1983), aff'd, 750 F.2d 28 (6th Cir.
1984) does not require a difference result. In that case the Commission
found the existence of a hazard based upon evidence other than exceeding
the limits, in the NIOSH document and was careful to state that the
document was considered only for the purpose of establishing that the
employers industry had recognized that heat stress was a hazard. Here,
the Secretary has attempted to prove that exceeding the limits set in
the documents constituted a hazard.

[[12]] The company presented evidence that the effects of heat-related
conditions resemble symptoms caused by the flu, viruses, or other
ailments. We are inclined, however, to believe that the employees'
complaints are more likely than not the result of their very hot working
conditions.

[[13]]One of the abatement measure proposed by the Secretary in the
citation was a required drinking program for employees in which they
would drink water every fifteen to twenty minutes. We note that the
company's time motion study shows that the employee studied went to the
water fountain to get a drink three times an hour in hours he did not
get a break and twice an hour when he did have a break during the hour.
It would therefore appear that this measure is in effect already in place.

[[14]]Although this evidence is not controlling it does constitute
evidence from the individuals who are most familiar with and most
affected by the cited working conditions. See General Motors Corp. 11
BNA OSHC 2062.2066 1984-x5 CCH OSHD 26.961 pp 34.611-12 (No.
78-1443.1984). aff'd. 764 f.2d 32 (1st Cir. 1985). We therefore accord
these views some weight and consider them together with the other
evidence on the question of whether the Secretary proved that there was
a hazard.

[[1]] Section 5(a)(1) of the Act, 29 U.S.C. 654(a)(1), provides:

Each employer shall furnish to each of his employees employment and a
place of employment which are free from recognized hazards that are
causing or are likely to cause death or serious physical harm to his
employees.