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Original
Halcyon PVR-BASC rebreather used in
the WKPP's exploration of Wakulla Springs
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What is a rebreather?
Divers considering use of the Halcyon RB80 should have a basic
understanding of general rebreather function. Since rebreathers
inherently increase the risk of any dive, individuals should
first consider whether their activity justifies the use of
a rebreather at all. Then divers should familiarize themselves
with the general risk of rebreathers and the specific risks
of the system under consideration. The following discussion
outlines very broad principles of rebreathers along with Halcyon
RB80 specifics.
A
rebreather is a device that captures and recirculates at
least part of a diver's exhalation, thereby allowing the
diver to rebreathe part of his previous breath. Since at
least some of the exhalation is recirculated and rebreathed,
gas duration is extended and overboard discharge is reduced.
Therefore, a rebreather may be thought of as a gas extension
device that simultaneously reduces bubble output.
Divers
should choose the simplest possible rebreather that meets
safety and dive objective requirements. Increased complexity
comes at the price of higher costs, more training requirements
and more components that are subject to failure. Only after
a risk/benefit analysis has been made in favor of the rebreather
should it be used. Possible benefits include a genuine operational
need for exhaust bubble reduction, extended duration requirements
that cannot be met with open circuit equipment, increased
thermal retention, and reduced dehydration.
Advantages
- Additional
time
- Gas management/extension
of available gas
- Hydration
- Heat
- Lack of
bubbles
- Decompression
efficiency
Disadvantages
- Elevated
risk
- Additional
complications
- Additional
effort
- Logistical
support
- Failures
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An
early version of the Halcyon Rebreather
is tested for breathing efficiency
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Common components
of a rebreather
(and how they function)
All rebreathers
have a breathing loop or circuit whose characteristics help
classify the type of unit. The extent to which the exhalation
is contained in the circuit determines whether the rebreather
has a fully closed circuit, semi-closed circuit, or open
circuit. If the entire exhalation is retained in the loop
or circuit, the rebreather is referred to as a Fully Closed
Circuit Rebreather (CCR). If a portion of the exhalation
is vented from the loop or circuit, the rebreather is referred
to as Semi-Closed Circuit Rebreather (SCCR). Finally, if
the entire exhalation is discharged into the environment
and dumped overboard with each breath, as with scuba, the
device is referred to as Open Circuit (OC). Regular dive
gear is a prime example of "open circuit" scuba. Regardless
of the circuit classification, all modern rebreathers share
a few common features such as:
- A
mouthpiece connected by two hoses for inhalation and exhalation
- A
carbon dioxide scrubber
- A
means of adding supply gas
- A counterlung
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1.
Breathing Loop or Circuit Classifications
As the terms imply, a "breathing loop or circuit" is a pathway
that allows at least some portion of a diver's exhalation to travel
back around to the diver's mouth to be inhaled again. As seen
in the simplified drawing, the loop consists of a mouthpiece,
two hoses, and a counter lung. One hose is for inhalation, and
the other for exhalation. One-way non-return valves are located
on each side of the mouthpiece ensuring that gas only travels
in one direction, and hence cannot bypass the carbon dioxide scrubber.
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RB80
Breathing Loop, as viewed from the back of the unit
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2.
Carbon Dioxide (CO2) Scrubber
A rebreather eliminates CO2 build-up by directing exhaled gas
through the loop to a scrubber, where it is neutralized. The scrubbed
exhalation gas travels through the loop toward the mouthpiece,
where supply gas is introduced. The method of supplying fresh
gas to the rebreather is another means of classification and may
be active or passive.
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Fitting
the screen over the scrubber media in the RB80 canister
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3.
Active or Passive Gas Addition
Because a semi-closed circuit rebreather allows part of the exhalation
to be discharged, supply gas must be added to make up the missing
volume of gas that was discharged or metabolized by the diver.
The most
common method for adding supply gas is active addition; the second
method is passive addition. While passive addition rebreathers,
such as the Halcyon RB80, have many benefits over active addition
rebreathers, they remain in the minority. If gas is continuously
added to the loop, regardless of the diver's breathing rate, then
the rebreather uses active addition. If, instead, supply gas is
only added in relation to what is required by the diver's Respiratory
Minute Volume (RMV) then it uses passive addition. Further description
of passive addition systems will be covered in the specific description
of the function of the RB80.
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RB80
Counterlung
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4.
Counterlung
All rebreathers must have a counterlung of some type. The counterlung
normally consists of two bags or bellows, one for discharge and
one for inhalation. Of course shape, location, and design all
have an impact on breathing resistance, just as counterlung placement
impacts performance as the diver moves through the range of horizontal
and vertical positions during a dive.
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