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Posts tagged “advanced nitrox

TDI Advanced Nitrox and TDI Deco Procedures Course

Koh Tao, Thailand

Big Blue Tech celebrates the graudtaion of Arul Sakthi Sankar form his TDI Advanced Nitrox and Decompression Procedures course conducted by TDI Instructor Ash Dunn over 5 days on Koh Tao Island off the coast of Thailand.

The focus of these combined courses is to train students to be successful in technical diving. These classes are taught as if they are a small piece to a much larger picture, not as entry level technical diving. These courses build the foundation for sound technical diving. What you will learn will be utilized in higher level trimix courses.

This is not a course to learn or re-learn fundamental diving skills. Students will be held to a higher level of performance not found in many technical diving courses.

Students are taught and evaluated, not only on skill proficiency, but control, leadership, situational awareness, teamwork, and judgment. Successful students will have a finesse that few divers have. You will finish this class with the confidence, competence, and comfort to be able to complete dives at this level of training prior to receiving a c-card.

This course requires a minimum of 5 days with 10 or more dives and involves a minimum 40 hours of instruction. Expect to dive every day with lectures in the afternoon and evening for each day. The majority of dives will be conducted in shallow water for critical skill evaluation. However, each day will get deeper as the class progresses. The final day is reserved for experience dives that will be at depth with a real decompression obligation.
Course content will include, but not limited to: enriched air Nitrox usage, decompression mixtures, diving physics & physiology, dive tables, advanced decompression theory, oxygen exposure/management, team diving procedures, and contingency planning.

more pictures can be found on our facebook page at http://www.facebook.com/technicaldivingthailand

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Deco and Nitrox diving in Thailand

Technical Diver underwater during deco stop

Koh Tao, Thailand

Big Blue Tech Thailand celebrates the graduation of Phil Clegg and Paw Mac-Mullit from their TDI Advanced Nitrox and TDI Decompression Procedures course conducted over 4-5 days on Koh Tao Island by Technical Instructor Ash Dunn.

Koh tao has been struck recently by severe flooding, this flooding receded but the success of the course was in jeopardy as the seas were too rough to go diving in.

The conditions on the island improved, power was restored and the sun came out. This meant the course could being and the team headed out to sea for some deep technical diving.

The diving conditions proved hard and challenging putting the fortitude of each novice technical diver to test. The surface current was strong, visibility was limited and the skills had to be performed perfectly to the instructors demands.

In the end the students walked away from the course successfully having been challenged under the worst conditions Thailand has to offer. Thankfully the students remained to continue on to their TDI Trimix Course starting tomorrow which won’t be as severe conditions wise but just as challenging skill wise.

The focus of these combined courses is to train students to be successful in technical diving. These classes are taught as if they are a small piece to a much larger picture, not as entry-level technical diving. These courses build the foundation for sound technical diving. What you will learn will be utilized in higher level trimix courses. This is not a course to learn or re-learn fundamental diving skills. Students will be held to a higher level of performance not found in many technical diving courses.
Students are taught and evaluated, not only on skill proficiency, but control, leadership, situational awareness, teamwork, and judgment. Successful students will have a finesse that few divers have. You will finish this class with the confidence, competence, and comfort to be able to complete dives at this level of training prior to receiving a c-card.

This course requires a minimum of 5 days with 10 or more dives and involves a minimum 40 hours of instruction. Expect to dive every day with lectures in the afternoon and evening for each day. The majority of dives will be conducted in shallow water for critical skill evaluation. However, each day will get deeper as the class progresses. The final day is reserved for experience dives that will be at depth with a real decompression obligation.

Course content will include, but not limited to: enriched air Nitrox usage, decompression mixtures, diving physics & physiology, dive tables, advanced decompression theory, oxygen exposure/management, team diving procedures, and contingency planning.


Advancing your diving through Nitrox

Mixed oxygen scuba diving gas gives divers an enriched sensation

Koh Tao, Thailand

Big Blue Tech celebrates the graduation of Lin Wang and James Ferrie from their TDI Advanced Nitrox course conducted over 2 days with 4 dives off the coast of Thailand on Koh Tao Island by TDI Instructor Ash Dunn.While not a decompression diving course it is the vital foundation that other tec courses are built upon and certifies you to a maximum depth of 40 metres.

To get the maximum benefit of using rich nitrox mixes the course can be taught in conjunction with TDI Decompression Procedures Diver course.

Lin continues with her training tomorrow to start the TDI Decompression Procedures course.


Lefty Lean, Righty Rich, Advanced Nitrox in Thailand

Technical diving intern progresses through advanced nitrox use.

Koh Tao, Thailand

Big Blue Tech celebrates the graduation of James Foleher from the TDI Advanced Nitrox Course conducted over 3 days on Koh Tao island in Thailand by TDI Instructor James Thornton-Allan

The Advanced Nitrox course trains the diver to handle oxygen enriched air up to pure oxygen in combination with advanced dive planning to extend no decompression limits essentially diving deeper and longer then possible with normal scuba methods.

This is the first (1st) stage of training in the series of TDI’s tech diver development program. The objective of this course is to train the divers in the benefits, hazards and proper procedures for utilizing Enriched air nitrox twenty one (21%) percent through to one hundred (100%) percent oxygen for dives not requiring staged decompression. To a depth of forty (40) msw, one hundred thirty (130) fsw this course can be combined with Decompression Procedures at the discretion of your instructor but this course was not combined.

James moves on to his TDI Decompression Procedures course as the next step in his internship.


Advanced Nitrox Materials from TDI a Huge Hit

When you’ve been in the technical dive business as long as TDI™ has, you think you’ve seen everything, but the feedback the agency has been receiving since the launch of its new Advanced Nitrox materials has taken even the most seasoned staff members by surprise.

“I think when we launched the new Advanced Nitrox materials in the spring, it was a low-key affair because there were several other products released around the same time,” Steve Lewis admitted. “But during the past few months, we’ve been getting a steady stream of emails and phone calls from our instructors complimenting us on the quality of the book’s content and design. But the real story is the number of students who have made the effort to tell us how much they’ve enjoyed their course and how easy the book made the learning process for them.”

Lewis, Director Marketing and Corporate Communications for TDI™, said that his collection of positive emails and phone calls is growing daily.

“We produce this textbook in large numbers to begin with – I think we’re already getting into the third print run – because our Advanced Nitrox course is one of the foundation classes for our whole technical program. And it has been a strong program for TDI™ since we started operations in ’94; however, my guess is the number of calls and emails about the new manual and instructor guide outstrips feedback on any other program about two to one… and it’s all positive!”

Lewis said the TDI Advanced Nitrox Student Manual is at the core of the new materials and was completely rewritten and redesigned featuring new photographs and illustrations throughout. He said the contents was reviewed and radically updated for the 2009 copyright version.

“Of course the basic facts are unchanged and TDI™ Advanced Nitrox still covers the full spectrum of mixes up to and including pure oxygen. But the presentation of those facts and of topics such as dive planning, gas management and foundation skills has been changed to reflect the fact that the type of diver entering the technical side of diving today is very different to the person who signed up for a TDI™ class back in the mid-nineties.”

The TDI Advanced Nitrox Student Manual is part of a full library of educational materials from the leading technical dive training agency, Technical Diving International™. For more details about this growing organization, visit the website at www.TDISDI.com To find the nearest Technical Diving International facility, click on this link: TDI International Directory


TDI Advanced Nitrox Course Completed

The objective of this course is to train the divers in the benefits, hazards and proper procedures for utilising EAN 21 through to 100 percent oxygen for dives not requiring staged decompression To a depth of 40 msw.

Brian Wilcox, a computer programmer from Oregon, US joined us recently for an Advanced Nitrox Course to acomplish 2 goals. Get certified in the use of basic technical diving gear and also get certified to 40 while allowed to use multiple amounts of nitrox. This was a great alternative to about 4 different PADI courses to get the same result.

This course allowed brian to get into the mix quickly and combine it with his decompression procedures course that he decided to join shortly after. With over 100 logged dives and many years of diving experience Brian adapted to technical diving very quickly and excelled through not only the academic aspects of the course but also the in water differences.

Below are some pictures from his course, accompanied by Cory Lewis and Christos Kardana who have opted to complete their Extended Range course after being certified as DSAT Tec Deep but missed some foundation skills. The extended range course gives them an additional 5m and much different skills.


Big Blue Tech – April in Review

April proved to be our busiest month with our biggest cavern course to date with 10 people on a 5 day exploration of the caves and cavers, an enrollment of 3 technical diving students at different stages progressing on to Trimix diving on the west coast and videography internships later. The arrival of new staff, Cory Lewis, to keep up with our nitrox distribution to the local diving community. All during this we had the arrival of “Golden Week” where 50 Japanese customers arrive for 3 weeks of diving on our boats, the overhall of all our compressors (7), Thai New Year, an electricity crisis and the renovation of the tech equipment room.

Unfortunately a few of our tech students hit a bit of trouble, Christos is still out of the water with some awful spider bite infection he got for passing out in the bushes in Khao Sok and John who picked up an ear infection for diving 5 times a day. However, this leaves room for some time off, with current courses on hold and no more planned until a CCR Megaladon Course in the end of May we’ve all decided to do some fun diving, relaxing, working on our tan and enjoying the island we all came here for.

Elsewhere on the island things have been busy. Mv Trident have been in and out of the harbour all month on technical wreck diving trips, PADI gave a discussion about how DSAT are changing their technical courses and another successful group of new instructors graduated from several different schools on the island.

We’ve got some pictures of Cory’s Tech course, he’s about 1/3 the way though and is only certified to dive in tech gear without anything too fancy. He’ll be joining the rest of the lads in mid May.


Surviving a Technical Dive

Though technical training standards have been well established by the American Nitrox Divers, Inc. (ANDI), International Association of Nitrox & Technical Divers (IANTD), Professional Scuba Association (PSA), Technical Diving International (TDI), and Professional Association of Diving Instructors (PADI) and are continuing to evolve. There is currently no set of agreed upon operational guidelines, i.e. guidelines used to direct diving operations, similar to those developed by the professional and commercial diving communities.

Originally presented in aquaCORPS Journal N6/Computing (93JUN), the guidelines which were compiled by technical diving pioneer Capt. Billy Deans/Key West Diver and dive technologist Michael Menduno with the help of many individuals throughout the community in response to the number of technical-level accidents that were occurring during that period. They are based on what are perceived as the best practices from the technical diving community drawing heavily on accident analysis techniques developed by the cave diving community, and were offered as a starting point for the development of “community consensus” guidelines for technical divers.

Now several years later, in light of the tremendous growth in technical diving, and with the majority of the recreational training agencies accepting enriched air Nitrox we felt it was necessary to update and republish these critical guidelines. Many people’s comments and suggestions for the development of these guidelines have been incorporated in this document.

Background
About twenty years ago in response to the then growing number of fatalities, the cave diving community developed a set of safety principles based on the then-new tool of accident analysis. Later refined by pioneer Sheck Exley and elucidated in his book Basic Cave Diving: A Blueprint for Survival (Exley, 1979, 1986), accident analysis is a means to rigorously dissect an accident into its constituent parts with the goal of determining what went wrong. Applying this tool to cave diving, it was discovered that most diving accidents could usually be attributed to a primary causal factor and typically one or more contributing factors. What’s more is that these factors could be boiled down into five basic cave diving safety principles: be trained, use a continuous guideline to the surface, manage your gas according to a thirds rule or better, don’t dive deep (on air), and carry at least three lights. A sixth principle, known as Eternal Vigilance, states: Anyone Can Die At Any Time On Any Cave Dive. Accident analysis of these resulting safety procedures have become the cornerstone of cave diving safety ever since.

Numerous other analysis of sport diving accidents have been conducted following the early cave diving work. In 1989, Mano and Shibayama published a study titled Aspects of Recent Scuba Diving Accidents (Mano and Shibayama, 1989), which analyzed 264 fatalities and 319 incidents of decompression illness and arterial gas embolism. According to the authors, over 45% of sport diving fatalities that occurred were due to reckless diving or lack of technique. Most appear to have been preventable. In another study, Chowdhury, in affiliation with the National Underwater Data Center (Chowdhury, 1989) conducted an analysis of wreck diving accidents. His conclusions were that 73% of the accidents involving wreck penetration were due to the lack of a continuous guideline, while 42% of the fatalities that occurred external to a wreck were due to out of gas emergencies.

In 1990, the late Sheck Exley revisited his earlier work in a paper published in Underwater Speleology. Based on the recent trends in accidents, Exley concluded that perhaps too much emphasis was being placed on the basic cave diving principles in light of more recent tools and techniques being employed by cave divers (e.g., mix technology), and that an expanded list of safety recommendations should be developed.

Exley’s conclusions provided motivation for the original paper. Our approach was to attempt to identify and address the factors that could potentially result in diver injury or death, building on the cave diving safety principles and practices from the community. The resulting guidelines are organized into seven categories: Requirements, Training, Gas Supply, Gas Mix, Decompression, Equipment, and Operations.

Requirements
The generalized requirements for conducting technical dives were aptly summarized in the form of the acronym AKTEE.

These are:

Attitude:
Why are you doing this? A proper attitude is essential to conducting technical dives safely. There is no room for recklessness or machismo.

Knowledge:
Without the proper knowledge, there are no options when problems occur.

Equipment:
Every dive requires an appropriate set of tools.

Training:
Skills must become second natural part of muscle memory.

Experience:
Experience is exposure and environmental specific and takes time to build. Extensive wreck diving experience does not qualify a diver for cave diving and visa versa.

Note that the more challenging the dive and the further the dive goes beyond mainstream sport diving limits, the more risk the diver must accept. No amount of training or equipment will completely mitigate this risk.

Training
Technical training is an ongoing process similar to training for an athletic season or fight training. Continual practice is the key. Completing a formal course is a good first step, but is only a starting point. It does not in itself prepare you to make the dive. Technical diving is a discipline and a “mind-set” it’s not just a card.

1. Always be prepared and trained for the dive you plan to conduct. Perform a risk assessment. Ask yourself if you, and your partner, meet the AKTEE criteria and if the dive is worth the risks involved. If the answer is no to either question, call the dive.

2. Review and practice emergency procedures frequently so that they become second nature.

Gas Supply
Ensuring adequate gas supply is the major constraint factor in self-contained diving and represents the single largest risk factor. In particular, planning and carrying adequate gas reserves is critical.

3. Always dive an appropriately redundant breathing system (minimally first and second stage redundancy) in an overhead environment, or when diving in open water beyond 130 f/ 40 m. Second stage redundancy and a dive partner is an acceptable redundant system in open water no-stop diving (recreational diving) to 130 f/40 m in good conditions though an independent redundant system is recommended for dives deeper than 60 f/18 m and/or in less than ideal conditions.

4. Pre-plan and calculate the gas required to conduct the dive (Gas requirements = planned consumption plus required reserves) and dive your plan. Gas calculations should be based on the most conservative breathing rates of you and your partner. Always dive your bottom gas using at least the Rule of Thirds [Turn the dive when one third of your gas is exhausted, leaving two thirds for the exit and reserve] in an overhead environment, or a suitable equivalent in open water, depending on the operation. There should be sufficient reserves for the dive team to exist safely in the event one diver suffers a catastrophic gas loss. For extended open water dives, the consensus seems to be to reach your first decompression stop with one third of your bottom gas remaining.

5. Plan at least a 33% reserve (1.5 x planned usage) for your decompression gas. Depending on the operation, decompression cylinders should be equipped with redundant regulators.

6. When possible, carry all the gas you will need for the dive unless it can be reliably staged, depending on the operation and environment. Note that the ability to reliably stage gas is one of the major differences between cave and wreck diving. In open water diving the goal is to be self-sufficient, to the maximum extent possible. Based on an analysis of gas logistics, the self-sufficiency breakeven point for extended open water dives appears to be about 250-300 f/77-92 m for a two-person team, depending on the duration of the dive. Open water dives beyond this require an extensive support team and effective communications.

Gas Mix
Mix technology is a tool designed to improve underwater safety and performance when properly applied. The most critical factor in special mix diving is oxygen management due to the risk of a CNS toxicity convulsion.

7. Always dive the safest possible mix(es) for the dive you plan to conduct.

8. Always analyze and label your gas and regulators before making the dive. Make sure that you know what you are breathing. Use a contents tag that specifies the type of gas and maximum operating depth. Any cylinder or regulator carrying a potentially hyperoxic gas (PO2=1.6+ at any depth during the dive) should also ideally have touch ID capability for zero visibility conditions (see below).

9. Maintain your PO2s at or below 1.45 atm during the working phase of the dive and anytime more than light work is being done, boosting oxygen levels to a maximum of 1.6 atm with care, during resting decompression. The community standard today is to run travel and bottom mix at about 1.2-1.45 atm, depending on conditions and the operation and PO2s of 1.4 -1.6 atm are generally treated as a caution zone. Take regular air breaks, as a safety hedge every 20-25 minutes when breathing oxygen. If air is not available, the lowest FO2 travel gas should be used. Some trainers take breaks during the decompression phase of the dive whenever the CNS index exceeds 80%. Note that the CNS indices being used today are just guidelines and are not necessarily supported by hard data. As succinctly summarized by Terry Billingsley (Hamilton, 1985): CNS toxicity is like sand beside the road. If you stay on the road, you won’t get into trouble.

10. Just Say No to nitrox mixes ( like air) beyond about 180-200 f/55-61 m or less, depending on the operation and environment. In particular, keep equivalent narcotic depths (END) as shallow as operationally and economically feasible, preferably 150 f/46 m or less. Note that ANDI limit s nitrox (air and EAN) exposures to 165 f/ 50 m. PSA allow s very short non-working exposures to 240 f/ 72 m and deeper under the supervision of two instructors per student.

Decompression
Decompression illness is not an accident. It happens and will continue to happen as a predictable part of diving.

11. Always use appropriate and reliable decompression methods and tools for the dive you’re planning to conduct and be conservative. Carry bailout tables for gas loss scenarios.

12. Utilize a hyperoxic mix for decompression (e.g., oxygen and/or suitable EAN mixes) whenever possible when conducting a staged decompression exposure. Oxygen at 10 and 20 f/3 and 6 m stop is preferred in some circles [Air, and to a lesser extent EAN mixes, have been regarded as inefficient at reducing decompression risk (Vann, 1992)], though EAN 80 (80% O2, 20% N2) has grown in popularity as it is thought to reduce CNS toxicity risk and can be used at 30 f/ 9 m. Note just as it is recommended that divers make a safety stop on no-stop dives, some individuals prefer to treat the first (deepest) stop on a mix dive in the same manner and make a couple minute safety stop at least 10 f/3 m deeper than required.

13. Limit oxygen decompression to 20 f/6 m or less (max. PO2=1.6 atm) and use care. The diver breathing a decompression mix or oxygen should avoid anything that would increase the likelihood of CNS oxygen toxicity, or specifically, anything that might raise the diver’s C02 level. Use an oxygen regulator guard to prevent the accidental use of pure oxygen at depth. Color coding and labeling are insufficient safeguards.

14. Plan for and always be prepared to deal with decompression illness (DCI). In particular, have plenty of oxygen immediately available for treatment after any diving operation and know how to use it. Many people believe that low-cost portable on-site chambers will eventually become the order of the day.

Equipment
Your equipment is your life support system which allows you to survive in a physiologically hostile environment. Second only to breathing equipment in importance, safety lines and a decompression line system are critical to diver safety.

15. Always use the best possible equipment that is well-maintained and appropriate for the dive you plan to conduct and the environment. Redundancy on all essential subsystems is key. In particular, always carry appropriate emergency equipment and know how to use it, for example: three lights (overhead environment), a decompression reel and lift bags (open water) surface signaling device (open water) and a bail-out bottle when diving as a team of one.

16. Always use a continuous guideline when diving in an overhead environment, and/or a decompression line system when conducting extended and/or deep open water dives. Note that conducting multi-level extended range open water hangs without a safety line home can be problematic and difficult. They require skills and practice to perform without compromising effective decompression, particularly when using hyperoxic decompression mixes where depth control is critical.

Note that the original set of guidelines (1993) included the following point; If possible, wear breathing equipment that allows you to survive an underwater convulsion/loss of consciousness, such as a full face mask system or retaining strap. The use of full face masks is growing and will likely become a standard for many technical diving applications due to their many advantages.

In practice this point has not stood up in the field. Technical divers have not embraced full face mask technology, nor have FFMs become a standard. This may change when rebreathers finally hit the market and/or when an effective mask is developed for technical diving applications. In the meantime practice the effective and conservative use of oxygen management in order to avoid a CNS hit.

Operations
Technical dives are operations: a project or venture involving planning, preparation, organizational structure, the use of proper equipment, teamwork, competent execution, and the capacity to respond to emergencies effectively and immediately. Diver safety is always the first priority. In terms of support requirements, technical dives fall somewhere in between recreational dives and commercial operations. Note that all dives are operations. In the case of traditional *recreational diving, the requirements are minimal.

17. Pre-plan all aspects of the dive you intend to conduct and dive your plan. Design your operation with the goal of being able to provide effective and immediate assistance to a diver in distress at any point in the dive. In particularly be prepared for the worst, and always have plenty of oxygen on hand and know how to use it. Above all, if you’re not prepared to do it right, don’t do it.

18. Always dive as a team, using surface support personnel, and when appropriate, in-water support divers, whenever possible. In particular, designate an operations manager, who is responsible for overseeing diver safety and record keeping. Note that the buddy system is not reliable enough for technical diving. A team approach based on individual self-sufficiency and competency is required, though an team of one is acceptable in some circumstances, depending on the operation and environment. Above all, always honor rule number one of team diving: anyone can “call” the dive at any time for any reason (anyone can die just as easily).

19. Utilize an effective communications system between the dive and support team whenever possible. In the future, wireless communications systems will likely become commonplace.

20. Stay within your “comfort zone” during all phases of the dive.

21. Remember: YOU, and YOU ALONE, are responsible for your own safety. Never permit overconfidence or peer pressure to allow you to rationalize compromising safety procedures. It could ruin your whole day.#

*Definition:
Technical diving is a discipline that uses special methods and equipment to improve diver safety and performance enabling the user to conduct dives in environments and perform tasks beyond the scope of traditional recreational diving i.e. no-stop dives in an open-water environment to 130 f/40, Europe limited decompression dives to 50 m/165 f.

For more information about technical diving, contact us at info@bigbluetech.net


Full Day Trip – Nitrox

Big Blue Tech conducted this seasons first Sail Rock full day trip taking us over 2 hours away from Koh Tao wil food, sun, drinks and 3 dives.

Today was, however more about nitrox diving then anything else as we trained up the interns on the use and methods of enriched air nitrox.

Many would later continue on to their deep course and the upcoming wrck trip, but for today it was a great chance to relax and feel like students again.

Returning to Shore we were met by other members of the technical team who decided to have a day off and enjoy the sunset soaking in the sea, having a beer and floating in their BCD’s. Otherwise called a “Beer Float”

By the way Emily, you are actually topless in that picture.. just to clarify that.


PADI Enriched Air and Deep Diver Specialty Course

Big Blue Tech has been busy again with the completion of a PADI Enriched Air and Deep Diver Specialty Course. Although this course is not specifically technical diving it is a great introduction to it and is a prerequisite for further more challenging diving.

Because of the amount it was also a pleasure to be able to take a boat to ourselves and park at South West Pinnacle for the duration of the morning for 2 back to back dives on nitrox. Later diving was completed again Chumphon pinnacle.

With another great group completed some progressed on to technical diving while others went back to their divemaster internship or fun diving on nitrox.

Below are some pictures from the event.