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HAZARDS
INHERENT TO ENTERING CONFINED SPACES
Hazards,
such as electrical, thermal, chemical, mechanical, etc., are inherent
to specific types of equipment and the interactions among them. Examples
include high voltage (shock or corona discharge and the resulting burns),
radiation generated by equipment, defective design, omission of protective
features (no provision for grounding non-current-carrying conductive parts),
high or low temperatures, high noise levels, and high-pressure vessels
and lines (rupturing with resultant release of fragments, fluids, gases,
etc.). Inherent hazards usually cannot be eliminated without degrading
the system or equipment, or without making them inoperative. Therefore,
emphasis must be placed on hazard control methods. INDUCED
HAZARDS Induced hazards
arise and are induced from a multitude of incorrect decisions and actions
that occur during the actual construction process. Some examples are:
omission of protective features, physical arrangements that may cause
unintentional worker contact with electrical energy sources, oxygen-deficient
atmospheres created at the bottom of pits or shafts, lack of safety factors
in structural strength, and flammable atmospheres. EXAMINATION
OF TYPICAL CONFINED SPACES Following
are typical examples of confined workspaces in construction which contain
both inherent and induced hazards. Vaults
A variety of vaults are found on the construction jobsite. On
various occasions, workers must enter these vaults to perform a number
of functions. The restricted nature of vaults and their frequently below-grade
location can create an assortment of safety and health problems. Oxygen-Deficient
Atmosphere
One of the major problems confronting construction workers while
working in vaults is the ever-present possibility of an oxygen-deficient
atmosphere. Explosive
or Toxic Gases, Vapors, or Fumes
While working in an electrical vault, workers may be exposed
to the build-up of explosive gases such as those used for heating (propane).
Welding and soldering produce toxic fumes which are confined in the limited
atmosphere. Electrical
Shock
Electrical shock is often encountered from power tools, line
cords, etc. In many instances, such electrical shock results from the
fact that the contractor has not provided an approved grounding system
or the protection afforded by ground-fault circuit interrupters or low-voltage
systems. Purging
In some instances, purging agents such as nitrogen and argon
may enter the vault from areas adjacent to it. These agents may displace
the oxygen in the vault to the extent that it will asphyxiate workers
almost immediately. Materials
Falling In and On
A hazard normally considered a problem associated with confined
spaces is material or equipment which may fall into the vault or onto
workers as they enter and leave the vault. Vibration could cause the materials
on top of the vault to roll off and strike workers. If the manhole covers
were removed, or if they were not installed in the first place, materials
could fall into the vault, causing injury to the workers inside. Condenser
Pits
A common confined space found in the construction of nuclear
power plants is the condenser pit. Because of their large size, they are
often overlooked as potentially hazardous confined spaces. These below-grade
areas create large containment areas for the accumulation of toxic fumes,
gases, and so forth, or for the creation of oxygen-deficient atmospheres
when purging with argon, freon, and other inert gases. Other hazards will
be created by workers above dropping equipment, tools, and materials into
the pit. Manholes
Throughout the construction site, manholes are commonplace. As
means of entry into and exit from vaults, tanks, pits, and so forth, manholes
perform a necessary function. However, these confined spaces may present
serious hazards which could cause injuries and fatalities. A variety of
hazards are associated with manholes. To begin with, the manhole could
be a dangerous trap into which the worker could fall. Often covers are
removed and not replaced, or else they are not provided in the first place. Pipe
Assemblies
One of the most frequently unrecognized types of confined spaces
encountered throughout the construction site is the pipe assembly. Piping
of sixteen to thirty-six inches in diameter is commonly used for a variety
of purposes. For any number of reasons, workers will enter the pipe. Once
inside, they are faced with potential oxygen-deficient atmospheres, often
caused by purging with argon or another inert gas. Welding fumes generated
by the worker in the pipe, or by other workers operating outside the pipe
at either end, subject the worker to toxic atmospheres. The generally
restricted dimensions of the pipe provide little room for the workers
to move about and gain any degree of comfort while performing their tasks.
Once inside the pipe, communication is extremely difficult. In situations
where the pipe bends, communication and extrication become even more difficult.
Electrical shock is another problem to which the worker is exposed. Ungrounded
tools and equipment or inadequate line cords are some of the causes. As
well, heat within the pipe run may cause the worker to suffer heat prostration. Ventilation
Ducts
Ventilation ducts, like pipe runs, are very common at the construction
site. These sheet metal enclosures create a complex network which moves
heated and cooled air and exhaust fumes to desired locations in the plant.
Ventilation ducts may require that workers enter them to cut out access
holes, install essential parts of the duct, etc. Depending on where these
ducts are located, oxygen deficiency could exist. They usually possess
many bends, which create difficult entry and exit and which also make
it difficult for workers inside the duct to communicate with those outside
it. Electrical shock hazards and heat stress are other problems associated
with work inside ventilation ducts. Tanks
Tanks are another type of confined workspace commonly found in
construction. They are used for a variety of purposes, including the storage
of water, chemicals, etc.
Tanks require entry for cleaning and repairs. Ventilation is always a
problem. Oxygen-deficient atmospheres, along with toxic and explosive
atmospheres created by the substances stored in the tanks, present hazards
to workers. Heat, another problem in tanks, may cause heat prostration,
particularly on a hot day. Since electrical line cords are often taken
into the tank, the hazard of electrical shock is always present. The nature
of the tank's structure often dictates that workers must climb ladders
to reach high places on the walls of the tank. Sumps
Sumps are commonplace. They are used as collection places for
water and other liquids. Workers entering sumps may encounter an oxygen-deficient
atmosphere. Also, because of the wet nature of the sump, electrical shock
hazards are present when power tools are used inside. Sumps are often
poorly illuminated. Inadequate lighting may create an accident situation. Containment
Cavities
These large below-grade areas are characterized by little or
no air movement. Ventilation is always a problem. In addition, the possibility
of oxygen deficiency exists. As well, welding and other gases may easily
collect in these areas, creating toxic atmospheres. As these structures
near completion, more confined spaces will exist as rooms are built off
the existing structure. Electrical
Transformers
Electrical transformers are located on the jobsite. They often
contain a nitrogen purge or dry air. Before they are opened, they must
be well vented by having air pumped in. Workers, particularly electricians
and power plant operators, will enter these transformers through hatches
on top for various work-related reasons. Testing for oxygen deficiency
and for toxic atmospheres is mandatory. Heat
Sinks
These larger pit areas hold cooling water in the event that there
is a problem with the pumps located at the water supply to the plant--normally
a river or lake--which would prevent cooling water from reaching the reactor
core. When in the pits, workers are exposed to welding fumes and electrical
hazards, particularly because water accumulates in the bottom of the sink.
Generally, it is difficult to communicate with workers in the heat sink,
because the rebar in the walls of the structure deaden radio signals. UNUSUAL
CONDITIONS Confined
Space Within a Confined Space
By the very nature of construction, situations are created which
illustrate one of the most hazardous confined spaces of all--a confined
space within a confined space. This situation appears as tanks within
pits, pipe assemblies or vessels within pits, etc. In this situation,
not only do the potential hazards associated with the outer confined space
require testing, monitoring, and control, but those of the inner space
also require similar procedures. Often, only the outer space is evaluated.
When workers enter the inner space, they are faced with potentially hazardous
conditions. A good example of a confined space within a confined space
is a vessel with a nitrogen purge inside a filtering water access pit.
Workers entering the pit and/or the vessel should do so only after both
spaces have been evaluated and proper control measures established. Hazards
In One Space Entering Another Space
During an examination of confined spaces in construction, one often encounters
situations which are not always easy to evaluate or control. For instance,
a room or area which classifies as a confined space may be relatively
safe for work. However, access passages from other areas outside or adjacent
to the room could, at some point, allow the transfer of hazardous agents
into the "safe" one. One such instance would be a pipe coming
through a wall into a containment room. Welding fumes and other toxic
materials generated in one room may easily travel through the pipe into
another area, causing it to change from a safe to an unsafe workplace.
A serious problem with a situation such as this is that workers working
in the "safe" area are not aware of the hazards leaking into
their area. Thus, they are not prepared to take action to avoid or control
it.
OSHA
29 CFR 1926.21 (Safety and Health Training Requirements)
Training
Roster
Training
Acknowledgement
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