There are many situations where workers are required to wear personal
protective clothing (PPC), to protect against a primary hazard, such as heat
or chemicals. But the PPC can also create ergonomic problems and there
are important side effects which typically increase with rising protection
requirements. The most extensively studied side effect is that of increased
heat strain due to reduced heat and vapour transfer from the skin. Less
studied is the extra weight, bulk and stiffness of PPC garments which is
likely to increase the energy requirements of the worker, reduce the range of
movement and lead to impaired performance.
Current heat and cold stress standards assume workers are wearing light,
vapour permeable clothing. By failing to consider the metabolic effects of
actual PPC garments, the standards will underestimate heat production and
therefore current standards cannot be accurately applied to workers wearing
PPC. Information on the effect of the clothing on the wearer and the
interactions between PPC, wearer and environment is limited.
Data was collected to quantify the effect of PPC on metabolic load based on
the properties of the PPC for the EU THERMPROTECT project (GERD-CT-2002-00846). The main objective of the project was to provide data to allow
heat and cold stress assessment standards to be updated so that they need
no longer exclude specialised protective clothing.
The aim of this thesis was to investigate the effect of PPC and its properties
on energy consumption during work. For this purpose, the effects of a range
of PPC garments (Chapter 3), weight (Chapter 4), number of layers and
material friction (Chapter 5) and wet layers (Chapter 6) on energy
consumption whilst walking, stepping and completing an obstacle course
were studied. The impact of PPC on range of movement in the lower limbs
was also investigated (Chapter 7).
The main findings were; a) Increased metabolic cost of 2.4 - 20.9% when
walking, stepping and completing an obstacle course in PPC compared to a
control condition. b) An average metabolic rate increase of 2.7% per kg
increase in clothing weight, with greater increases with clothing that is
heavier on the limbs and in work requiring greater ranges of movement. c)
4.5 to 7.9% increase in metabolic cost of walking and completing an
obstacle course wearing 4 layers compared to a single layer control
condition of the same weight. d) Changes in range of movement in PPC due
to individual behavioural adaptations. e) Garment torso bulk is the strongest
correlate of an increased metabolic rate when working in PPC (r=0.828,
p<0.001). f) Garment leg bulk (r=0.615), lower sleeve weight (r=0.655) and
weight of the garment around the crotch (r=0.638) are also all positively
correlated with an increased metabolic rate. Total clothing weight and
clothing insulation had r values of 0.5 and 0.35 respectively.
Background: Protective clothing (PPC) can have negative effects on worker
performance. Currently little is known about the metabolic effects of PPC and previous
work has been limited to a few garments and simple walking or stepping. This study
investigated the effects of a wide range of PPC on energy consumption during different
activities. Hypothesis: Wearing PPC would significantly increase metabolic rate,
disproportionally to its weight, during walking, stepping and an obstacle course.
Methods: Measuring a person’s oxygen consumption during work can give an indirect,
but accurate estimate of energy expenditure (metabolic rate). Oxygen consumption was
measured during the performance of continuous walking and stepping, and an obstacle
course in 14 different PPC ensembles. Results: Increases in perceived exertion and in
metabolic rate (2.4–20.9%) when wearing a range of PPC garments compared to a
control condition were seen, with increases above 10% being significant (p<0.05). More
than half of the increase could not be attributed to ensemble weight.
History
School
Architecture, Building and Civil Engineering
Citation
DORMAN, L.E. and HAVENITH, G., 2009. The effects of protective clothing and its properties on energy consumption during different activities. European Journal of Applied Physiology 105, pp.463-470.