Modified semi-closed rebreather diver course completed in Thailand

Koh Tao, Thailand - Big Blue Tech celebrates the graduation of Andrew Cavell from his TDI Semi Closed Rebreather Diver Course conducted over 4 dives around various dive sites on Koh Tao Island. The TDI Semi-Closed Rebreather Diver Course is designed to teach the student the safe diving and operation of a Semi-Closed Rebreather.

The semi-closed circuit rebreather (SCR) can be manufactured without the use of batteries or electronic components in a very reliable system. It’s only moving parts are the check valves in the mouthpiece and the demand valve override for deep inhalations. It can be simple, useful, and provide many of the benefits divers seek in rebreathers. With the use of Nitrox mixtures, the benefits of EAN use are retained with the added benefits of a properly designed SCR which includes:

• Quiet, reduced bubble operation
• Extended bottom time (due to efficient use of gas)
• Lighter, more comfortable diving systems
• All the physiological benefits of EAN (Nitrox)

Other advantages of the semi-closed circuit rebreather become obvious with use in each dives chosen environment. For example, the inspired air is moist, not-dry, helping to eliminate “cotton-mouth.” Also, the gas is warmer, reducing heat loss in cold-water diving. Buoyancy needs only be set once at depth. As the diver breathes, the system acts opposite to the lungs producing no change in buoyancy from inhalation to exhalation. This takes some getting used to for experienced divers.

Diving on the rebreather is a remarkable difference to normal open circuit scuba. Andrew’s first experience in the shallow training depths was commented as “that’s weird” when referring to the control of the buoyancy using your lungs. Because the unit uses a bag of air that you exhale and inhale from the exchange of gas from lungs to unit is different than experienced in normal scuba. In scuba diving when you exhale you descend and when you inhale you ascend. In a Semi-closed rebreather the movement is opposite.

During the open water dives do depths up to 30m Andrew found the marine life came much closer then ever before and that the air was not as dry as in normal scuba.

The rebreather which was used is a modified Drager Dolphin Semi-closed rebreather which has been adapted from it’s 4 litre tank which provided 69 hours of dive time to twin 6 litre tanks to get the increase gas and dive time while utilizing a full canister of soda lime. This rebreather also features the ability to bolt on a backplate and wing so technical divers can find it more comfortable and streamlined.

It is available in five configurations to suit your diving from the basic air/nitrox scuba version to the fully loaded nitrox, trimix and heliox open and closed circuit model with external active one and three cell ports. Each configuration is fully upgradeable to any other via a personal code, so you can upgrade as your diving progresses.

It uses a Buhlmann algorithm to calculate its decompression obligation, but you can adjust the algorithm across a variety of settings if you want to dive more conservatively than the default. Interestingly, if you miss a stop it doesn’t lock but carries on in a ‘best guess’ mode - especially useful when incidents occur. For calibration at the surface in closed-circuit mode there is a user-selectable oxygen percentage although most divers will probably choose to use pure oxygen. As with the majority of computers on the market it is automatically switched on by depth and/or pressure, and features an automatic, ambient light-sensing LCD for back-light illumination.

It is configurable for either automatic or manual set point changeovers with both set point and sensors being displayed while in the menus. The decompression algorithm uses the current PPO2 (partial pressure of oxygen) as a FiO2 (fraction of inspired oxygen) and will thus on-the-fly predict TTS (time to surface) and length of stop time.

Gases can be switched during a dive and there is a preset selection of gases that can be inputed - like setting favourite stations on a radio. As well as the obvious basic diving information, other useful displays include, ascent rate, milli-voltage readouts for all cells on demand, battery voltage, low battery warning and CNS tracking. The battery can be changed by the user and has a life expectancy of 360 hours.

Getting to grips with the Pursuit is straightforward. Disappointingly it only uses two buttons so there is a certain amount scrolling to be done. An open circuit comparison of the Pursuit’s algorithm in both air and nitrox mode over several dives showed that it was less conservative than the algorithms of both Suunto Vytec (set at one minute deep stop) and the VR3 by up to several minutes on longer and deeper dives - all computers were at factory default settings.

We tested the Pursuit on an open circuit dive using a 17/30 back gas, with 30 per cent travel and 80 per cent deco mixes to a dive to 64m for a bottom time of 20 minutes and found it cleared nine minutes before the Suunto Hel02.

John Adams commented, ‘I used the Pursuit and set it up to match the settings on my Vision electronics. It was used as a standalone computer (not plugged into any other cells) and in CCR mode. The Inspiration was set up with a diluent of 10/53 and gradient factors of 15/85. The gases in the bailout cylinders were 18/45 and 65 per cent nitrox. Setting up the Pursuit, once the correct system of tapping the contacts had been established, seemed logical and easy. I found it much easier to program than the VR3 and managed to do it without consulting the manual. This is an important point as I believe many UK divers would do the same. With the same gradient settings, I found the deco information matched fairly closely to that of the Vision and it was very easy and clear to read. Although I do personally prefer the slowly rising ceiling of the Vision, I wish their display had the lighting features and print size of the Pursuit. As I get older and my reading prescription changes - there must come a point where it is cheaper to buy the Pursuit than keep buying new prescription masks.’

For CCR users, Narked at 90 also provides various cell kits that can be directly linked to the Pursuit. One unit that may be of particular interest in the UK is the three-cell monitoring back-up kit (£267.06) that is specifically designed for the APD (Ambient Pressure Diving) Classic Inspiration and features what Narked at 90 claim to be the only detachable cell holder in the world. As a good demonstration of how closely the Pursuit matches the APD calculations see the picture of it in action (left). The photograph was taken during a dive where the maximum depth was 51.9m with just under an hour on the wreck. The Pursuit shows 10 minutes TTS and the Vision shows 12 minutes, which is pretty close after 90 minutes of elapsed dive time.

The Pursuit has user updateable firmware via an infrared interface and free software updates are provided for life. At well over the wrong side of a grand the Pursuit is not cheap but on par with other similar featured computers in the market.

A typical Self-Contained Underwater Breathing Apparatus, or scuba gear for short, usually consists of a tank containing compressed air and a mouthpiece used to regulate the flow of air from the tank into the lungs. But breathing air in this manner is extremely inefficient, especially while considering the applications of this particular apparatus. This is because the air you breathe out still contains a fair amount of oxygen.

Modern scuba gear use rebreathers to filter out the exhaled carbon dioxide gas and gather the oxygen, to recirculate it until it is consumed. By doing so, the underwater breathing process becomes more efficient, allowing professional divers to remain submerged for a longer time.

Basically, a rebreather has three roles. One is to remove the carbon dioxide gas from the exhaled air. This is done by pumping it through a chamber containing sodium hydroxide, which reacts with the carbon dioxide and forms calcium carbonate. Secondly, the rebreather must complement the amount of consumed oxygen with fresh one from the tank. The oxygen tanks may contain either pure oxygen or oxygen mixed with either nitrogen or helium.

Alternatively, the rebreather must control the oxygen concentration inside the breathing loop after the exhaled oxygen is combined with fresh oxygen, for an optimal oxygen delivery sequence.

Types of rebreathers:

Currently, there are three types of rebreather systems commercially available - oxygen rebreathers, semi-closed circuit and closed circuit ones. The oxygen rebreathers make use of pure oxygen tanks as the only source of breathing gas. They are generally disadvantaged by the facts that they cannot be used in decompression depths and may pose oxygen intoxication risks.

Semi-closed circuit rebreathers on the other hand, carry tanks containing oxygen mixed with another gas - nitrogen, helium - and enable divers to surpass decompression depths without any risk of suffering from oxygen intoxication. Closed-circuit rebreathers are a combination between the two, using both pure oxygen and oxygen mixed with various gases.

Besides being highly efficient in making use of the gas carried by a diver, rebreathers are also lighter than any other conventional scuba gear. The normal concentration of oxygen inside the atmospheric air is about 21 percent, while that of nitrogen is 78 percent. Since nitrogen is not as critical as oxygen, almost three quarters of the gas carried in conventional scuba tanks is dead weight. Also, less nitrogen is circulated through the system with the help of rebreathers, thus the effects of decompression are reduced to minimum.

Because they recycle oxygen and carbon dioxide is filtered through sodium hydroxide, very little or no gas is ever pumped into the water to produce the characteristic bubbles.

Source

Technical Diving International™ recently announced an agreement with Poseidon Diving Systems, to offer certification on its revolutionary Cis-Lunar Mk VI aCCR, and is offering active CCR instructors the opportunity to upgrade their teaching credentials to cover the automatic, sport-level unit. Instructor upgrades scheduled for NEC Birmingham Dive Show, and DEMA.

“The process is as simple as the unit itself is to operate,” says vice-president of training and membership services, Sean Harrison. “Any active, Closed-Circuit Rebreather instructor can attend the one-day workshop and earn his or her Discovery [Cis-Lunar Mk VI] instructor certification.”

Harrison explains that the unit is aimed at a whole new market and is quite different to ‘mainstream’ closed-circuit rebreathers.

“Poseidon’s Discovery is a remarkable design,” Harrison says. “And the design is the key to our members currently teaching CCR to be able to upgrade to teach it with a minimum of fuss.”

The Mk VI offers all the features of CCR over open-circuit – extended dive times, quiet operation, warm, humid breathing gas, and delivery of ideal gas mixes during all phases of the dive. But the real attraction of Poseidon’s Discovery CCR centers on its ease of use and automated pre-dive tests and operations. It is the simplification and automation of the unit prep and operation that will appeal to sport divers; people who have considered CCR diving but have been put off by their perception that it is complex and not worth the effort for dives within sport diving limits.

The pre-dive procedures for Poseidon’s entry into the CCR market is no more complex than preparing open-circuit gear, due to the pre-packed canister and the Mk VI’s ability to perform all pre-dive tests automatically; from checking gas volumes and loop pressure tests, to calibration of its redundant oxygen sensors. Procedures during the dive are equally simple due to automated operation and no option to “fly the rig manually.” In the unlikely event of any failures in the automated systems, the unit bails out to open-circuit mode.

“The unit promises to bring all the benefits of CCR diving to the avid sport diver, someone who is interested in new concepts in diving but who is less focused on the technical side of things than the average CCR diver has been up to this point. We feel the Discovery will help to open up the CCR market more than any other unit on the market today.”

TDI will be offering upgrades through hands-on workshops to active CCR instructors and instructor-trainers at NEC Birmingham Dive Show, DEMA and other shows and special events in the coming months.

Underwater acoustic equipment supplier Reson has successfully demonstrated contraband and diver detection systems in UK ports.The multibeam sonar tracks divers and alerts operators to their presence on a geo-referenced map of the area.

Three separate demonstrations at Southampton, Falmouth and Chichester were conducted to test contraband detection using the SeaBat 7128 multibeam sonar system. These demos were staged in front of representatives from the Royal Navy, the Royal Netherlands Navy, and the US Navy.

During the demonstrations Reson was able to positively identify items as small as a brick at ranges above 30m, and at water depths of 7m to 20m. The detection of such small item at these ranges had not yet been achieved by even a modern naval minehunter.A fourth trial for the Royal Navy of the SeaBat 7112 multibeam sonar system was focusing on diver detection. Using the SeaBat 7112 system in conjunction with the SeaBat 7128 system for diver detection, Reson was able to detect targets at a long distance and make positive distinctions between divers and other targets.

The SeaBat 7128 multibeam forward looking sonar has high resolution and installation flexibility and is well suited for a variety of underwater imaging applications from a surface vessel in water up to 6,000m deep.

SeaBat 7112 multibeam sonar system for diver detection consists of a circular array and projector ensonifying a cylindrical volume of water up to 1,000m range. Designed to detect small targets such as divers with closed circuit re-breather equipment, the systems will track and alert operators of their presence on a geo-referenced map of the area.

Their stealth and extended bottom times have made rebreathers popular with military and technical divers for many years. Recently, lower prices and “user-friendly” designs have made rebreathers more attractive to recreational divers like you and me. Indeed, several models are aimed specifically at the recreational market.

Is this the future of diving? Are conventional open-circuit rigs bound for the oblivion of duck fins and two-hose regulators? Are you ready for rebreather diving? Are rebreathers ready for you?

Maybe, no, maybe and maybe. At least that’s my guess after spending most of a month studying and diving rebreathers. It turns out they have some very real, valuable advantages over open-circuit, tank-and-regulator systems. But they have some equally real and serious disadvantages too. If you have some unusual needs and are willing to make some sacrifices of time and money, a rebreather can be a godsend. But most divers, for most purposes, will continue to prefer open-circuit scuba for a long time to come.
Why You Might Want a Rebreather

Long dive times. The biggest advantage of a rebreather is gas efficiency. A single fill of a small gas cylinder or cylinders and CO2 scrubber can last for anywhere from one to six hours, depending on which rebreather it is. Unlike open-circuit scuba, your gas duration on a rebreather is nearly independent of depth, so you could, in theory, spend all that time on the bottom.

Of course, a rebreather does not make you immune to DCS and nitrogen narcosis. Those risks remain, though the more sophisticated closed-circuit rebreathers can adjust your gas mix to reduce the DCS risk. The advantage of the rebreather’s long duration for most of us is that you can make several dives on one fill of scrubber and cylinders.

Silence. Rebreathers exhaust few or no bubbles. You don’t hear that roar of exhaust bubbles, and neither do the fish. That allows you to get closer to marine life, which is why rebreathers are popular with professional photographers and some researchers. You won’t be rendered invisible, but you seem to be less alarming to most fish.

Warm, moist breathing gas. The chemical reaction in the CO2 scrubber actually warms and humidifies your breathing gas. Diving with a rebreather does not give you that cotton-mouth feeling and doesn’t chill you as much.

Optimum gas mixture. The more sophisticated rebreathers constantly monitor the partial pressure of oxygen in your breathing mix. They can keep your PPO2 constant regardless of depth or exertion, or alter it on the fly for needs like decompression. The benefit can be less nitrogen uptake and faster offgassing–in other words, more bottom time with less DCS risk. Rebreathers are not created equal, however, and the less-expensive designs do not have this ability.
Why You Might Want To Think Twice

A rebreather failure can go unnoticed. When open-circuit regulators fail, it’s immediately obvious. Either you get no air when you suck on the mouthpiece or (more likely) you get too much and a sudden rush of bubbles in your face.

When a rebreather fails, the signs, if any, are more subtle. You’re still able to inhale and exhale as before because you are just passing the same gas back and forth between your lungs and the breathing loop. The CO2 content in that gas may be rising and the O2 content may be falling, but this won’t be immediately apparent without gauges, monitors and alarms. Rebreather diving is like flying on instruments, not by the “seat of your pants.”

On the other hand, if you watch your instruments and detect the problem promptly, you’ll probably have more time to deal with it on a rebreather than you would on open circuit. You still have gas to breathe, and its oxygen and CO2 content do not change instantaneously.

A rebreather failure can be deadly. A rebreather is constantly mixing the gas in your breathing loop, removing carbon dioxide and adding oxygen. Either component in the wrong proportion is poisonous. Much of the design effort and much of the complexity of rebreathers goes into making that mixing function as accurate and reliable as possible. But it’s never going to reach the certainty of open circuit, where what you breathe is simply what went into the cylinder. An open-circuit “bailout” bottle and regulator is a good idea when diving with conventional gear, but it’s a must with a rebreather.

Cost, weight, bulk, convenience, etc. These minor factors all weigh against rebreathers. Though the cost to buy one is hardly minor, you’re often told that you’ll save money on each dive since you don’t have to refill tanks as often. But you do have to buy scrubber chemicals, and maintenance will cost more. And will that $60 two-tank dive boat give you a rebate if you don’t need to use its tanks? Probably not.

Rebreathers, including the bailout bottle, are generally bulkier and heavier than a single tank and regulator, and they don’t fit well into the tank-rack-and-bungee-cord gear station typical on dive boats. Air travel with cylinders can be a challenge and fills for oxygen and even nitrox can be harder to find, especially in remote locations.

The First Steps

Let’s say you’ve considered the pros and cons and decided you want to dive with a rebreather. What’s the drill?

First is making the decision of which rebreather to buy. Rebreathers differ considerably in not only price but capabilities, the great divide being whether they are closed-circuit or semiclosed-circuit in design.

Closed-circuit rebreathers have the lowest gas consumption, the best mixture control and, generally, the most capability, but are more complex and expensive. Semiclosed-circuit rebreathers are simple, robust and less expensive, with gas consumption rates somewhere between closed-circuit rebreathers and open-circuit scuba.

You might also consider such things as time and depth limits, backups to control devices and fail-safe mechanisms, warranties, how many units have already been in use and for how long, and more.

Then there’s training. A prerequisite will be nitrox certification since rebreathers either use nitrox or, in effect, mix it on the fly. Following that, virtually every rebreather manufacturer will require you to take a rebreather training course lasting four or five days. The cost of this will be extra, normally at least $500. Part of the curriculum covers in-water skills like how to interpret gauges and monitors and how to switch to backup systems. Another part is training in assembly and disassembly, servicing and maintenance of your particular unit.

Because you will have to be trained by an instructor certified in your particular make and model, you may have to travel to another city and stay there for five days or so for your training course.

Meanwhile, you will start to assemble a special tool and spare parts kit. You’ll probably want one or more spare oxygen monitors and various solenoids and sensors for the more complex units. Also gas analyzers and flow-rate test devices, depending on the unit. Add to that mouthpieces, batteries, O-rings, tie-wraps, silicone grease, etc.

A Day on the Water

Even more than open-circuit, a rebreather dive begins before you get wet and ends after you’re dry. Predive and postdive care for the rebreather are essential every time and can’t be skipped. Expect to spend an extra half-hour on each end of the dive.

Here’s generally what to expect, keeping in mind that each rebreather is different and requires its own procedure.

Predive

* Fill cylinder(s). Most semiclosed-circuit rebreathers use a single cylinder of nitrox. You’ll have to decide in advance which nitrox mix you’ll use so the bypass valve orifice can be matched to it. Most closed-circuit rebreathers use two cylinders, of oxygen and a diluent (usually air, though other gases may be options). In either case, but especially when using nitrox, you will analyze the gas yourself to make certain what is in the cylinder. If your bailout system uses a separate cylinder, you may need to refill that also.

# Fill scrubber canister. Different rebreathers use slightly different types of CO2 absorbent and different granule sizes, but all of it looks a lot like cat litter. You buy it in large plastic jugs or buckets, which you must keep tightly sealed because exposure to air causes the absorbent to react and become used up.You’ll pour the absorbent into the canister, tapping the canister occasionally to make sure the absorbent settles and completely fills the canister. Because the absorbent dust is caustic, you should wear gloves and a breathing mask. Then you’ll close and seal the canister and the absorbent bottle or bucket. Many divers do this job at home before the dive trip to minimize the mess.
# Assemble the rebreather. Here, semiclosed- and closed-circuit rebreathers differ considerably. In general, though, you will attach the counterlung (or lungs) to the absorbent canister and install them in the frame of the rebreather. You will test the one-way valves in the breathing hoses and attach them to the counterlungs. You will install the cylinder(s) and check their valves. All this can involve a dozen hose connections.If you have an oxygen monitor and other electronics, you will test them. If you have a constant-flow semiclosed rebreather, you will need to check the flow rate of the orifice.

You will then test the entire unit for air leaks and water leaks. Leaks are potentially serious. You have so little gas on board that you can’t afford to lose any. If water leaks cause the unit to flood, it will become extremely negative. And water in the CO2 scrubber causes a reaction with the absorbent known as a “caustic cocktail”–a nasty mouthful that can chemically burn your lips, mouth and throat.

As should be obvious, this assembly process is both complicated and critical. You need plenty of time and plenty of space to work, and you should use a checklist to prompt your memory. Don’t expect to assemble your rebreather between the dive briefing and the “pool’s open!” call.
# Into the water. Waddling across the deck in a rebreather has been justly compared to carrying double tanks, but once you’re in the water most of the difficulty ceases. Several differences to open-circuit diving will strike you immediately, though.One is that you can’t simply drop the mouthpiece into the water, because water would fill the breathing loop and the scrubber canister. There is a valve on the mouthpiece that you have to remember to close before you take it out of your mouth.

Another is that you can’t affect your buoyancy by inhaling or exhaling, because the same amount of air just passes back and forth between your lungs and the rebreather and never changes volume or buoyancy. If you’re used to exhaling to get below the surface, this won’t work.

As you descend, increasing pressure will collapse the counterlungs just as it collapses BCs and dry suits. Some rebreathers automatically add more gas to the breathing loop, others require you to add it manually. When you suck on the mouthpiece and get no air, you push on a dry suit-type valve to reinflate the breathing loop.

You need to be stingy when inflating your BC or clearing your mask because gas used for that is gas lost from a much smaller total supply. For the same reason, you need to watch your gauges closely and you and your buddy need to be vigilant for air leaks.

If you work unusually hard–if you have to swim against a current, for example–your body will take oxygen out of the breathing loop faster than normal. Closed-circuit systems and passive semiclosed-circuit systems will sense this and add extra oxygen. Active semiclosed systems will not, however. In that case you must remember to “purge the breathing loop” by exhaling this oxygen-poor gas through your nose so the rebreather replaces it with richer gas.

At the beginning of an ascent on a semi-closed-circuit rebreather, you must also purge the loop to enrich your breathing mixture. Otherwise, as pressure drops, the partial pressure of oxygen may become too low. Closed- circuit systems add oxygen automatically.

Also, as you ascend and the counterlungs expand, the rebreather will vent gas. This is the only time the rebreather purposely dumps a significant amount of gas, and the reason that “sawtooth” profiles are especially wasteful. You will probably find that the rebreather does not vent gas fast enough and you become increasingly buoyant, so you’ll need to manually dump from your BC, your dry suit or from the rebreather.

Postdive
If you are planning another dive that day and have enough gas and scrubber time left, all you need to do is turn the rebreather off during your surface interval. It’s a good idea, though, to check the breathing loop for water inside.

If this is your last dive for a few days, you will need to disassemble and clean the rebreather thoroughly. The warm, moist environment inside the breathing loop is perfect for growing bacteria, so it must be disinfected with whatever solution the manufacturer recommends, then rinsed well and dried. Drying the inside of the breathing loop, with its baffles and corrugated hoses, can be very difficult.

If you are diving again tomorrow, however, you need only disinfect the mouthpiece and corrugated hoses.

The used CO2 absorbent must also be dumped and the scrubber canister must be thoroughly cleaned and dried. Electronics and oxygen sensors have their own care requirements. Plan on spending an hour on postdive maintenance at first, although you will get faster with experience.

Long-Term Maintenance

Each cylinder has a first and a second stage regulator which requires annual service. These are normally just ordinary open-circuit regulators that can be serviced by your local dive shop. Cylinders need to be hydro tested and visually inspected like any others.

Oxygen sensors have a life span and need to be replaced, usually every 12 to 24 months, depending on how much they are used. (They deplete themselves in air about half as fast as when diving.) After diving, some divers remove them from the rebreather and seal them to extend their life.

Computer controls have batteries that must be replaced occasionally.

Some manufacturers recommend that the whole unit receive a thorough inspection and overhaul every year.
Rebreathers: How They Work

All rebreathers are built around the principle of a one-way breathing loop. One hose takes your exhaled breath to the CO2 scrubber, and another brings it back (without the CO2) to your mouth.

On each side of the scrubber there is a counterlung, just a flexible bag that expands and contracts to accommodate the on/off nature of your breathing. The counterlung on the exhalation side usually has a relief valve to vent excess gas from the system. The counterlung on the inhalation side has an input valve where more oxygen or nitrox is added.

Add a mouthpiece with a valve to prevent flooding, a one-way valve in each breathing hose so your breath circulates the right way, and some other bits and pieces and you’ve got a basic rebreather.

How many gases are injected into the inhalation counterlung, and how the injection is controlled, determine whether it’s semiclosed-circuit or closed-circuit.

Semiclosed-circuit rebreathers have the simplest gas control mechanism. Basically, it is just a fixed orifice, an opening that permits a constant flow rate into the breathing loop. Any excess above what your body consumes is vented to the water in a stream of small bubbles, which is why the system is called “semiclosed.”

The simplest semiclosed-circuit rebreathers constantly add nitrox from a single cylinder. The Dräger Dolphin and Ray are popular examples. They are called “mass flow” or “active” semiclosed-circuit rebreathers–active because the unit is always injecting fresh gas. The orifice, which controls the flow rate, must be selected before the dive to match the nitrox mix chosen. This type of rebreather is all on or all off: Whenever the cylinder valve is turned on, gas flows into the breathing loop at the rate determined by the orifice. Manual addition valves and some other plumbing may complicate the picture, but that’s the essence.

“Passive” semiclosed-circuit rebreathers inject gas only on demand. Various mechanisms to trigger the gas injection may be used, but they are mechanical. For example, a system of ratchets and levers measures the volume of a counterlung, and when it gets below a certain size (because your body has removed that much oxygen from the breathing loop), it triggers a valve to inject more gas. Passive systems use less gas than active ones, but the actual content of the gas mix in the breathing loop may be more variable.

Somewhat more complicated self-mixing semiclosed-circuit rebreathers add oxygen and a diluent separately through fixed orifices or (in the case of the diluent) a demand valve. They also may use less gas, but may be subject to larger variations in the oxygen content of the gas mix.

Fully closed-circuit rebreathers aim to control exactly the oxygen content in your breathing gas. They add only the gas you need, when you need it, and don’t waste any. Thus, no bubbles most of the time and a longer gas duration. This fine control of gas addition comes from some electronic wizardry. Normally, sensors analyze the oxygen content of the breathing loop and inform a computer, which adds oxygen or diluent as needed to maintain a preselected “set point” for the oxygen partial pressure. Redundancy (often three oxygen sensors and two computers) makes the wiring and plumbing diagrams confusing, but again the concept is fairly simple.

Are You Ready for a Rebreather?

You need to look not only within the rebreather but within yourself. Some personality types are more suited than others to the demands of using and caring for a rebreather. And some people probably shouldn’t even consider it.

Are you comfortable with “nuts and bolts”? Rebreathers are more complex than open-circuit setups, and you will have to be self-sufficient for assembly, cleaning, maintenance and a lot of the repair, since the chances of your local dive shop having a specialist are slim. Even the simplest rebreather typically has all the parts of your open-circuit setup, plus a lot more. All those parts, and the connections between them (there are 50 or more O-rings in a typical rebreather), must have regular maintenance.

Are you self-disciplined? Predive, during the dive and postdive you have to make up your mind to follow procedures and checklists exactly. Filling the scrubber canister and assembling the breathing loop before the dive involve steps that must be followed precisely and tests that can’t be skipped. The same care must be taken when disassembling and cleaning the rebreather after the dive. And during the dive you have to watch gauges more closely than on open circuit. Are you meticulous about maintenance of your open-circuit gear, for example, or do you “hose it and go”?

Do you accept responsibility for your safety? You have to take the attitude that the correct operation of your rebreather depends on you alone. The idea that the manufacturer, the instructor or someone else is responsible may be gratifying to your heirs but will not save your life in the event of a failure. Are you comfortable letting the boat crew or your dive buddy set up your open-circuit gear for you, or do you insist on doing it yourself?

Can you resist temptation? Rebreathers promote what might be called “mission creep.” Many of them are capable of dives far beyond the training of most recreational divers. Units that can change the gas mix during the dive are especially suited for decompression diving. It’s human nature to “see what this baby will do,” but rebreather training is not technical training. You will learn how to operate the unit, but not the specific disciplines of tech diving like deep diving and cave penetration, for example. “Mission creep” can take the apparently innocuous form of adding other nontechnical but demanding equipment too soon. Using a complex camera rig can distract you from monitoring your rebreather carefully, for example.

The MV Trident usually operates out of Koh Tao and considering the distance we had to travel to get to these wreck sites the boys decided to take the boat to Koh Samui, so we all made our way there to join the boat.

That afternoon had us assembling our equipment pumping tanks and generally settling in for the week ahead. That evening around 7.00pm we slipped the lines and we were on our way and motored all night and into mid morning before we arrived at our first mark. We arrived on the position all very excited with most of us in the wheelhouse glued to the sounder looking for the big red lump protruding from the normally flat sandy bottom of the Gulf.

The shot went down and not long after a diver followed it to tie on and shoot a bag if it was a wreck worth diving or he would just surface if it was a pile of junk and we would move on. We all waited anxiously, some guys even got into their equipment hoping to be one of the first to dive this, hopefully, virgin wreck. After what seemed like hours the lift bag appeared and it was time to get kitted up and go take a look at it.

We had a full boat of divers, consisting of 6 Open Circuit divers and 5 Closed Circuit divers (1 Sentinel, 1 Inspo-Deep Pursuit Hybrid, 1 Meg, 1 Hammerhead Meg, 1 Pelagian). We were arranged into buddy teams and our team consisted of 3 CCR divers as we had all dived together previously on another wreck diving trip in the Philippines the year before and were comfortable diving with each other. We met up at the downline at 6 meters and went through our checks before descending down the wreck below. It was later identified as a Japanese Coastal Tanker the Kinrei Maru by the Japanese crockery, size and configuration and more importantly it was not far from the location where the US Submarine the USS Hammerhead had marked her as sunk… Continued