Nitrox
Calculator v2.2
The
Nitrox Calculator v2.2
is an extremely useful desktop software tool to help you
calculate your Nitrox Tables. It calculates your percentages
whether your in Salt Water or Fresh Water in Feet or Metric.
Choose your Oxygen Percentage, Your PO2, Desired Depth,
ATA, EAD and the Nitrox Calculator will provide you with
the Best Mix.
Whether
your just a beginner diver or an Advanced Scuba Diver you'll
need this program!
GET
IT TODAY AND MAKE YOUR
NEXT NITROX DIVE SIMPLE!
ONLY $9.95
Next
time you go Scuba Diving bring it with you on your
Laptop or pre-calculate your Nitrox dive at home.
NITROX
CALCULATOR v2.2
Only
$.9.95
AS
SEEN ON AND PUBLISHED BY:
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Nitrox
Calculator |
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Updated Version 2.2 |
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Build Date: 2007.02.14 |
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File Size: 1.2 Meg |
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OS: win95, win98, win2000, ME, XP,
Vista |
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Uninstall: YES |
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Support By: Email |
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File Type: Desktop Exe |
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Price: $9.95 |
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Delivery Type: Email Download |
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Delivery Time: Within 24 Hours |
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About
Nitrox
Nitrox has become a common term in recreational diving.
Nitrox is a mixture of Nitrogen and Oxygen in different
percentages. The two most common mixtures are 36% and 32%.
Tech Divers will usually go over the 40% mark for recreational
diving mixtures.
Benefits
of Nitrox
In short, the correct nitrox mix can be safer than
air for the diver and requiring less decompression time.
However, we need to qualify that; by correct I mean the
most appropriate mix for your dive and it's safer provided
you follow the guidelines for its use.
 Nitrox
provides faster off-gassing than air during decompression.
It may be used to reduce the length of the decompression
penalty by following a nitrox decompression schedule, or
it may be used as padding to increase the safety factor
by following an air decompression schedule. This is similar
to the use of pure oxygen during decompression.
Limitations or problems using Nitrox
Bear
in mind the risk of acute Oxygen Toxicity with Nitrox is
no greater than that with air. The difference is the changed
priority between Nitrogen and Oxygen. On Air, Nitrogen Narcosis
is generally the governing factor in choosing a maximum
depth for most sport divers.
Reports
A considerable
amount of Nitrox users have commented about how refreshed
they feel after using Nitrox while Scuba Diving. I the Editor
(Avid Scuba Diver ) of this content can vouch for this unusual
feeling of refreshment compared to normal air dives.
How
long has nitrox been around?
Quite
a while. The early history of nitrox is really the history
of research into oxygen toxicity.
The
toxic effect of enriched oxygen mixtures were first demonstrated
by Paul Bert in 1878. He discovered that high partial pressures
of oxygen were directly responsible for causing convulsions.
In 1899,
Lorrain Smith demonstrated that animals breathing moderately
increased partial pressures of oxygen over a long period
develop pulmonary problems. For example, a partial pressure
of about 0.8 bar breathed for more than 4 days produced
severe lung problems and could be fBarl. In 1903, Hill and
Macleod noted that resistance to pulmonary damage in individuals
varied enormously.
Between
1910 and 1912 various experiments were carried out using
nitrox including riding a bike while breathing nitrox10
and a dive to 100 fsw (30 msw) using a surface supplied
50:50 nitrogen-oxygen mixture. These may have been the first
experiments in which the effects or nitrox were observed
in man.
During
the 1930's a great number of experiments were carried with
individuals breathing PO2's in the range of 2 to 4 Bar -
even one of breathing up to 7 Bar (Haldane (the younger)
in 1941). When taken overall these experiments demonstrated
the enormous variation in susceptibility. Some people were
okay after an hour while others convulsed within minutes.
One even convulsed after switching back to air (which he
did because his lips were twitching). In 1933, Shilling
and Adams noted the extreme variation in CNS O2 toxicity
tolerance although they erroneously concluded that man should
have ample warning of the onset of symptoms. It was discovered
that prior to the onset of CNS O2 toxicity there is a loss
of respiratory control where breathing may become jerky
and irregular and then change to become prolonged and laboured.
They also noted that the effect varied enormously between
individuals. In 1939, Lambertson developed the first nitrox
rebreather.
In Haldane's
experiments some subjects said they could taste the oxygen
at 5 to 7 Bar. Dr Kenneth Donald, author of Oxygen and the
Diver, breathed O2 at 10 Bar for 25 to 30 seconds along
with Haldane and another man. Only Haldane thought he might
have tasted something.
Experiments
with cats in 1944 showed that repeated CNS O2 hits produced
symptoms similar to that of neurological damage but the
effects apparently disappeared a few weeks after the exposures
were stopped. The cats also appeared to develop a tolerance
to the high partial pressures during the experiments but
this also returned to normal after a few weeks break.
Between
1942 and 1945 the Royal Navy carried out extensive work
on oxygen poisoning in divers. The experiments are documented
in Kenneth Donald's book. His conclusions were that diving
on pure O2 deeper than 25 fsw (7.6 msw) is a pure gamble.
He found that tolerance is reduced underwater (compared
to dry experiments) and that the variation in symptoms,
even for the same person, makes the onset impossible to
predict.
In the
1950's Rev Lanphier worked on producing O2 exposure tables
for the US Navy. He reached many of the same conclusions
as Dr Donald but there were some discrepancies. Despite
experimental evidence from Dr Donald's experiments to the
contrary, Rev Lanphier concluded that oxygen was more toxic
when breathed as part of a nitrox mixture. Experiments by
other researchers have supported the conclusion that nitrogen
has no effect on oxygen toxicity. However, Lanphier's conclusions
were the basis of the US Navy's exposure tables in 1959,
and for many years after that.
Rev
Lanphier also tried to find a way of predicting CO2 retainers
but could not find one. He realised that breathing resistance
at depth, due to higher gas density, may increase CO2 levels.
A higher CO2 level in the body would increase the risk of
O2 toxicity, however, the fact that divers are breathing
out an increased level of CO2 cannot be used to infer the
arterial and body CO2 levels. Thus it does not immediately
follow that nitrox divers are at an increased O2 toxicity
risk due to CO2 retention.
The
work to find out if divers adapt and become CO2 retainers
continued through the 1960's and is still continuing today.
Dr Donald's opinion is that there is no conclusive evidence
that divers adapt and become less sensitive to the carbon
dioxide breathing stimulus.
A major
step was taken in 1970 when Dr Morgan Wells of the National
Oceanic and Atmospheric Administration (NOAA) began experimenting
with nitrox. He recognised the advantages of nitrox for
the type of diving that NOAA divers were carrying out. Dr
Wells was responsible for the (now) standard nitrox I (published
in 1978) and nitrox II (published in 1990) mixes. It is
largely as a consequence of NOAA's decision that we have
nitrox in the recreational diving scene today.
Dick
Rutkowski formed the International Association of Nitrox
Divers (IAND) in 1985 to teach nitrox to sport divers. In
1992 the name was changed to the International Association
of Nitrox and Technical Divers (IANTD). The T was added
when the European Association of Technical Divers merged
with IAND. Prior to founding IAND, Dick Rutkowski worked
for Dr Wells and was director of the diver training at NOAA.
This was the first organisation to offer international training
to recreational scuba divers.
In 1987
or 1988 Ed Betts, who had previously been with Dick Rutkowski
at IAND, formed the second organisation for recreational
nitrox training: American Nitrox Divers Inc. (ANDI).
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