Cool Body
How Heat Stress Affects Worker Performance
BY BRUCE BAKER AND JOHN LADUE
NIOSH notes in its “Occupational Exposure
to Hot Environments” that although
workers can acclimate to different levels of
heat, each worker has an upper limit for
heat stress beyond which that worker can
become a heat casualty. Further, it has been
shown that a worker’s ability to focus attention
and the worker’s reaction times can be
dramatically reduced by even a two percent
dehydration level due to heat stress.
It’s accepted that some industries like
foundries, heavy machine manufacturing,
shipbuilding and a variety of others have
workplaces that subject employees to heat
stress. In temperatures as low as 80°F, the
human body compensates for heat levels in
the inner core by pumping blood to the skin
for cooling.
When combined with the fact that most
people (80 percent by some accounts) start
the day in a dehydrated state, heat stress is a major contributor to preventable accidents
and work related injury. Many types of businesses
encounter daily activity that can
cause heat stress in the people that work for
them, and do not even know it.
“We have always done things this way”
is a quote that is all too familiar when asked
why preventive measures were not taken to
prevent heat stress in the workplace.
The body releases heat in the following
way under normal circumstances:
• Sixty-five percent of the body’s heat is released
through radiation. This occurs when
ambient air temperature is lower than the
body’s skin temperature. Radiation is the
movement of heat energy from a warmer
object to a cooler object as heat radiates
from the Sun to the Earth.
• Convection accounts for approximately 10
percent of heat loss. Convection is the
transfer of heat energy from a warmer object or space to a cooler object or space
through differences in density and the
action of gravity.
• Approximately 23 percent of heat loss is
due to evaporation of perspiration from the
skin. Evaporation is the cooling of a surface
through the process of a liquid changing
to a vapor and leaving that surface.
• Conduction will add another 2 percent to
the heat loss total. Conduction is the transfer
of heat energy from a warmer object to
a cooler object through direct contact.
• When the ambient temperature of the surrounding
air is 95°F or higher, radiation,
convection, and conduction stop working.
Evaporation is all that is left to cool the
body. Protective clothing used by welders,
firefighters, racers and hazmat workers will
make the heat situation even worse.
A performance study by NASA using telegraph
key operators showed that in temperatures
of 80°F, the operator averages five
errors an hour and 19 mistakes after three
hours. At 90°F the operators made nine
mistakes per hour and 27 after three hours.
At 95°F the mistakes went to 60 in one hour
and 138 in three hours. Although errors made by telegraph key operators may not
be critical, this hot environment will produce
a proportional amount of errors regardless
of the task.
When a person is in a hot environment,
up to 48 percent of the blood is pumped by
the heart to the skin for cooling. The first
effect is to release heat, but water is also released
through perspiration. If an individual
loses 2 percent of body weight due to perspiration,
that person is considered to be in a
heat exhausted state.
A study by Wasterlund and Chaseling (1)
placed forest workers in a controlled environment,
where one group was properly hydrated
and the other dehydrated to an extent
of 1 percent of body weight loss. The test
included the time taken to debark and stack
2.4 cubic meters of plywood. They found a
12 percent decrease in productivity from the
dehydrated group.
Another study by Gopinthan et al (2) focused
on mental performance and the effects
of dehydration on the decision making
process and could be related to an increase
in work related accidents. The study concluded
that with 2 percent of body weight loss, visual motor tracking, short-term memory,
attention and arithmetic efficiency were
all impaired. In the extreme, the study notes
that a 23 percent reduction in reaction time
occurred with a 4 percent body fluid loss. At
the ambient temperature of 95°F, the body
no longer can keep up with its internal heat
generation levels, and inner core temperature
begins to rise. The only mechanism to
release body heat from the inner core is for
up to 48 percent of the body’s blood to be
pumped to the skin to create perspiration.
This creates two problems; blood loss to the
organs, muscles and brain. The second
problem is dehydration.
When the brain, muscles and major organs
are receiving half of the blood they normally
receive, the heart must work much
harder to try to deliver the same volume of
blood to those organs to keep them nourished
by beating up to 150 times a minute.
One then must also factor in a thickening of
the blood due to fluid loss (dehydration) and
one begins to understand why heart attacks
are a major by-product of heat stress.
When an employee performs heavy physical
work, fluid intake may not overcome the effects of sweat output. Employees who
perform duties in fully encapsulated protective
clothing may have increased sweat
rates of 2.25 liters per hour. Other studies
link job related accidents to “Orthostatic
intolerance.”
Carter et al (3) established that with a 3
percent dehydration state due to heat exposure,
subjects experienced a significant reduction
in cerebral blood flow velocity when
changing from a seated to standing position,
which can cause workers to lose consciousness.
This may lead one to believe that taking
fluids to hydrate the body is enough to
prevent heat-stress; however, it can take as
much as 24 hours for the body to absorb
enough fluid to fully rehydrate.
Work may need to be curtailed while
fluid is replaced, or the dehydration rate
must be slowed by using personal cooling
methods such as misting fans, ice vests or
active cooling products that pump cooled
fluid through tubing or a bladder sewn to a
garment that the employee wears under the
protective clothing.
Warning signs of heat exhaustion are;
heavy perspiration, fatigue and weakness, muscle and body ache, headache, nausea,
rapid heartbeat, confusion, loss of consciousness,
vomiting with or without loss of
consciousness.
Godek, Bartolozzi, et al (4) have shown
that fluid intake alone does not reduce core
body temperature. Action must be taken
to allow the worker to cool in addition to
taking fluid. The inner core temperature
will continue to rise for up to 30 minutes
after work is stopped, unless other means
are used to cool the blood that has been
pumped to the skin for cooling.
While conduction accounts for only 2
percent of heat loss under normal circumstances,
OSHA Technical Manual (Section
III: Chapter 4) considers how active
cooling products using water are useful in
preventing heat stress by using conduction
to enhance the body’s capacity to
cool. In fact, it has been demonstrated
that water is 28 times faster in cooling a
subject than cooled air.
These products slow the rate at which
the core body temperature rises by using
conduction to greatly increase the body’s
capacity to cool the blood that is pumped to the skin during times of elevated core temperatures.
In turn, this slows the fluid
loss caused by sweating. By using shirts
and vests that incorporate active cooling
on about 40 percent of the body surface,
the danger of heat stress can be greatly
reduced.
Education of employees is the most critical
element in reducing heat stress related
accidents in the workplace. Many workers
and supervisors feel the need to “get the
job done” in the toughest situations. When
they do not take into account the effects
that heat stress can have on the body, dangerous
events can take place. Reduction
in cognitive function, attention span, visual
motor tracking can all lead to mistakes that
could have tragic consequences. Policies
that allow workers to use products that help
prevent heat stress in the workplace will
greatly reduce heat stress related illness and
injury. Employee training and company
policies must help the employee decide that
they can protect themselves from heat
stress.
Reducing
heat stress will improve productivity and reduce
accidents at the work place.
FSM
Co-written by Bruce Baker and John LaDue of Shafer Enterprises, LLC / Cool
Shirt.net., developers of thermoregulation
and temperature therapy products for industry,
medical, military and sport activities.
More information on personal cooling can be
found on their website at www.coolshirt.net,
or call 1-800-345-3176.
1. Wasterlund DS, Chaseling J, Burstrom L:
The effect of fluid consumption on the forest
workers’ performance strategy. Appl Ergon
35:29-36, 2004.
2. Gopinathan PM, Pichan G, Sharma VM:
Role of dehydration in heat stress-induced variations
in mental performance. Arch Environ
Health 43:15-17, 1988.
3. Carter R 3rd, Cheuvront SN, Vernieuw CR,
Sawka MN: Hypohydration and prior heat stress
exacerbates decreases in cerebral blood flow
velocity during standing. J Appl Physiol
101:1744-1750, 2006.
4. Godek S, Bartolozzi A, Burkholder R, Sugarman
E, Dorshimer G: Core temperature and
percentage of dehydration in professional football
linemen and backs during preseason practice.
J Athl Train 41(1):8-17, 2006.
