Diver Air Quality Compressor Operator Handling Course Completed in Thailand

Koh Tao, Thailand - Big Blue Tech completed a BSAC Compressor Operator course today for Divemaster Intern Dylan Thornton by BSAC Instructor Ash Dunn.

The BSAC Compressor Operator course is about teaching the proper handling, procedures and functions of divers air quality compressors and banked air systems.

Divers air quality compressors are not the same as compressors you use for filling tires or using a nail gun. The quality of the air has to be high to prevent any respiratory problems for the divers breathing it under pressure. With the quality of the air so important Dylan was also taught how to change the filters which have special chemicals inside to help remove toxins and moisture before being put into the scuba divers cylinder.

The course consists with a  morning of academic theory lessons and afternoon of practical hands on filling and then concludes with a written exam. Dylan progresses tomorrow on to his Gas Blender course where he will use his skills again to fill nitrox cylinders.

In addition to this the rest of the team have been busy servicing regulators and equipment in preperation for the start of the next tech course which starts bright and early tomorrow for 4 eager future technical divers.

Today Mark Slinn (intern) and Andy Cavell (intern) completed their TDI O2 Service Technician Course. This would be the most recent service and technician related course after completing their TDI Visual Inspections course last week.

The o2 Service Technician builds on servicing regulators and cylinders but to a “oxygen clean” level. The students began by stripping and cleaning an Scubapro Mk2 1st stage and R295 Second stage and cleaning it removing any source of hydrocarbons. After a full clean and inspection the regulators we re assembled and tested. After full assembly the regulators were marked and recorded to be used in future training when breathing oxygen underwater. You can read more about this unique course here.

As the internship progresses the interns will be required to attain the SDI Divemaster certification and later the TDI Technical Divemaster certification. Since they are already PADI Divemasters all they had to do was cross over their skills and fill the gaps in the training.

One of these gaps is the most unpleasant swim tests and “surface recovery” or “ditch and don” exercise. The swim test are similar to other organizations with slight differences and the ditch and don exercise is rarely in a divemaster program in any official capacity (although many introduce it). At lunch we hit the water to cover these skills and stamina tests. The ditch and don is described as sinking your scuba gear, freediving down to it and assembling it underwater in about 3m. There are more steps to it but that’s the general description.

All of them did really well except Mark. Mark is a former soldier from the Parachute Regiment and is considered rather tough, however a cold got in his way and he couldn’t get down. He spent the remainder of the day blowing his nose and generally moaning on the surface with the instructor. He’ll get another chance in a few days.

In the afternoon the students cleaned their lean decompression mix cylinder while Ash cleaned twin set in preparation for our epic diving adventure in January. Once the practical work was finished the students sat a written exam and put all the tools away to prepare for the TDI Compressor Operator Course (distinctive) tomorrow.

EDGE is pleased to announce an industry first:  Manufacturer support for Technical Divers using EDGE’s Highly Optimized Gear (HOG) branded Technical Diving regulators.

While other organizations strive to increase instructors selling techniques, TDI moves to educate their instructors with real skills or the professional diving environment.

In conjunction with TDI (Technical Divers International), EDGE Dive Gear is offering certified technical divers (from any agency) the opportunity to attend HOG Regulator Repair Clinics, to buy parts and get service support from their local EDGE and HOG Dealer.

Chris Richardson of EDGE, a Technical Diving Instructor since 1995, explained the decision by saying: “Technical divers trust in their skills and ability; and the performance of their equipment in extremely  demanding conditions. Yet many technical divers choose to service and maintain their own equipment. They buy parts through the grey market and teach themselves service techniques with a book bought online and internet forums.”

Richardson says that in today’s market, technical divers who want to maintain and repair their own equipment should be given the training and tools to do so, “in full understanding of the added responsibility this puts on their shoulders.”

He added that in his experience, a “significant number” of technical divers are not fully connected with their local dive store and this program is one way to reverse things. “The HOG Regulator Repair Clinics are aimed at pulling technical divers back into dive stores, and the purchase of the course can provide a strong incentive for the tech diver to reinvest in the store brand.”

Steve Lewis, Director Marketing and Corporate Communications for TDI, and an experienced instructor-trainer for TDI programs adds: “EDGE is certainly breaking with tradition. But in the real world, we have to face up to the solid fact that many tech divers are a special market segment and DO work on their own gear without training. What Richardson and EDGE propose is simply a program that will help our members maintain some control over the situation and turn a growing gray market into a profit center.”

The course will be available from EDGE Dealers starting in November 2009. Instructors can be searched for at www.edge-gear.com or www.tdisdi.com

At DEMA show 2009, on Saturday, November 7, from 9 until 11 am at the Clarion Inn & Suites, EDGE and TDI will hold the first Instructor course. To become an instructor for the HOG Regulator clinic you must:

* Have attended six manufacturer’s clinics over last 5 years from any life support maufacturer
* Be a TDI, SDI or ERDI instructor in good standing (Crossovers available at DEMA)
* Have been employed at least six months full time as a scuba repair technician during the past five years

For more details, contact Chris Richardson at edgediving@gmail.com or Cris Merz at TDI (cris.merz@tdisdi.com). Course fees for this special workshop are $125 including registration, card and wall diploma.

Today Big Blue Tech and divers under instruction for their TDI Extended Range course leave Koh Tao island for the main land for 5 days of deep technical diving in Khao Sok National Park. In Khao Sok National Park resides a sunken village and buddhist temple which has become a popular attraction for technical divers since it’s discovery by Big Blue Tech in February of 2009.

This expedition takes 6 technical divers half way across thailand for true remote diving.

Today consisted of boosting o2, servicing regulators, emergency planning and loading of massive pile of technical diving equipment needed for such diving which is enough. One diver alone will be equiped with the following.

3 torches, 2 reels, 2 lift bags, 1 o2 at 200 bar, 1 nitrox and 1 twin set. Double bladder wing, spare mask, cutting tools, gloves and pockets.

With 6 of us diving and 1 for surface cover you can imagine the day has been very hot and sweaty while sorting out the logistics. However, on the up side all the work and planning gives these divers a unique experience unlike any other.

During this time there will be no news. We will be back in contact on the 24th of September.

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.

Here’s something you might consider adding to your “TO DO” list for the summer. The good folks at Gilboa Quarry in Ohio are organizing an attempt to set a new record for the most divers submerged at one time.

It’s being billed as your chance to be part of diving history, and sounds like it could be fun above and below the water!

Gilboa is one of the most unique and popular dive destinations in Ohio and you can find out more about it at  http://www.divegilboa.com It’s well-known by the sport and tech crowd and attracts divers from across state and much further afield. The quarry itself has a deep (technical deep) and shallow area, plenty to see and veruy comfortable surface facilities to feed, warm and entertain divers during surface intervals. And the staff are helpful and knowledgable.

The EVENT is set to take place on Saturday, July 18 with prizes and awards to be given out on Sunday the 19th.

There will be entertainment — as if diving with a thousand buddies is not entertainment enough — and lots of great prizes.

Admission Cost of $50.00 US for the 18th includes:
·    Certificate
·    T-Shirt
·    Dinner Saturday Evening
·    Entertainment
·    Free Parking

Prizes include:
·    Underwater Scooters
·    Gilboa Quarry Lifetime Season Pass which includes Parking and Camping
·    Dry Suits
·    Wet Suits
·    Computers
·    Regulators
·    Masks
·    Fins
·    Gear Bags
·    Dive Lights and much more…

To register for this event please fill out the Registration form to be found at:
http://www.divegilboa.com/images/pdfs/guinness_registration.pdf .

You must fill out and print this form. This is not an electronic submission. Please mail it along with your payment per the instructions on the bottom of the form. If you are a dive shop and need more copies of this form you can download the PDF and distribute.

Due to an immense amount of preparation for this special event please register ASAP. Your cooperation and timeliness is greatly appreciated.

Source

Twin tanks are increasingly sought after nowadays and many purchased with little or no thought. Twin-sets normally consist of two tanks, which are joined together using a manifold, which gives the user access to both tanks through a single regulator, although this isn’t always the case. There are three general ways of diving with twin tanks:

1. Diving Independents

This is where two tanks are mounted on your back but are run as separate systems. If you have a failure with one tank then you have lost that entire gas supply and cannot gain access to it but still have access to the remaining tank. Diving with independents involves additional task loading and superior gas management skills to ensure that you always have a gas supply available in the alternative tank to the one which you are breathing.

You must also be able to differentiate between which gauge and which regulator belongs to which tank. This is a less than optimal choice when compared to the third alternative.

2. Diving Twin Tanks with a non-isolating manifold

This time the two tanks are joined via a manifold which takes the form of a permanentely open connection running between the two tanks. This enables you to gain access to the contents of either tank via either pillar valve. This has the benefit of avoiding the duplication of gauges and eliminates the need to keep swapping regulators. However, your twin cylinders are now effectively just a single larger tank. This deprives you of the redundancy which can be achieved by running two separate systems, since one failure can affect your entire gas supply. Consequently, in many failure modes this arrangement is less safe than independent cylinders and cannot be advocated except when diving in less than demanding environments such as when a single cylinder would equally suffice.

3. Diving Twin Tanks with an Isolation manifold

This is without a doubt the best of the three options since it has all the benefits of both the previous systems and none of the disadvantages. It enables you to gain access to the contents of both tanks through one regulator and read the total gas supply off one gauge.

If you suffer a failure in one tank then you should normally still be able to gain access to the contents of both tanks through one pillar valve.

If there is a worst case scenario, such as the failure of a main tank O-ring (highly unlikely) then you can “isolate” one tank from the other by turning a handle, which is in the middle of the manifold, this will protect half your gas supply.

This retains the redundancy which is lost by using a non-isolating type manifold. See the section on “manifolds” below for additional considerations.

Twin tanks should always be mounted with the manifold uppermost, such that you can reach over your shoulder and turn your own valves on or off whilst in the water. This ensures that you can use the manifold’s full functionality at all times.

Sometimes you see tanks inverted, this is a distinct no-no, since you will then need a cage guard to protect the manifold. This is something which is subject to entanglement and an added unnecessary complication which makes access to the valves harder, completely defeating the idea of turning the set upside down in the first place. In addition, all hoses must be custom made.

You also occasionally see remote valve winders (known as “slob-knobs”), which consist of a handle on the end of a long hose-like type connector. These are attached to the pillar valves and isolation manifold and allow you to turn these pieces of equipment on or off without reaching behind you. Unfortunately they are subject to corrosion and, should they fail or seize, make it impossible to operate the valves either directly or remotely.

Simply owning an isolation manifold is not enough, you also need to know how to use it properly. See the “Valve Drill” link for training with an Isolation manifold. The chance of a failure is highly unlikely but the options available to resolve or minimize the impact are greater than the alternative equipment types.

Cylinder Size

Cylinders should be of the same size and dimensions if they are to be “twinned” up. Twin sets normally consist of either twin 7’s, 10’s, 12’s or 15 litre cylinders.

Twin 7’s are generally used for the types of dives, which fall within the “normal” club type diving description. i.e. under 35 metres, not involving any mandatory decompression stops. One twin set is normally only sufficient for one dive.

Twin 10’s have a greater volume and are suitable for moderate club diving, which involves some degree of decompression for a single dive. They may be unsuitable if you wish to use them without a gas fill/top-up for a full day’s normal club diving i.e. two dives under 35 metres with no stage decompression stops. This is due to their reduced volume compared to diving twin 12’s. You may have to support their weight on your back whilst sitting down and waiting to enter the water due to their reduced height.

Twin 12’s are normally suitable for a full day’s moderate club diving (two dives), which involve limited decompression stops for the first dive. They may only be sufficient for one dive if it is to a greater depth/for a greater time with a lengthy decompression. Twin 12’s seem to represent the best choice for the average diver.

Twin 15’s tend not to be used, due to their size, weight and the amount of drag that the diver has to suffer, unless he has some form of motorized propulsion available. These are only normally used for over 70 metre-ish trimix dives with multiple stages.

Alloy

The choice of tank depends on the suit you wear due to their buoyancy characteristics. If you are diving in a wetsuit then aluminium cylinders represent the best choice since they won’t cause you to be over weighted - obviously this is only the norm if you are in foreign climes. If you dive in a dry suit then steel tanks will remove some of the weight from around your waist, this is the reality for British divers.

Manifolds
As has already been discussed, using an isolating manifold is the only real choice, but there are a number of further considerations:

Barrel O-Rings Vs Facing O-Rings

This consideration is about the way in which the manifold is sealed against the two pillar valves.

Barrel O-ring systems have an O-ring(s) which seal around the exterior of the isolation manifold insert and the surrounding interior of the pillar valve. In contrast, Facing O-ring systems use an O-ring which is trapped much like a DIN fitting. That is to say, it is trapped between two parallel vertical surfaces.

Barrel O-rings are more tolerant of movement within the manifold and are less likely to be forced out of position, which would cause a gas leak. The editor was present on two occasions when a twin set fell from a great height due to a lapse of attention by the owner, landing on the manifold. On both occasions, the barrel style manifold successfully kept the gas supply intact, in spite of there being considerable mis-alignment. This testifies to the resilience of this design.

One of these examples is shown on the left (Scubapro). The arrows run straight through the middle of each pillar at a 90 degree angle to emphasize the extent of the misalignment present in the middle section. Please see the recommendation on Scubapro Manifolds below before buying this product

Ideally barrel O’ring designs should have two O’rings on each side of the isolator since this provides some degree of redundancy. The first O’ring will also prevent a build up of dirt and salt next to the second O’ring, helping to keep it in pristine condition.

Balanced Valves Vs Unbalanced Valves

If a pillar valve is balanced, then it should be just as easy to close the valve as open it. Unbalanced valves are easier to open than they are to shut and should consequently be avoided.

Valves tend to operate by screwing a widget in and out by turning the knob’s spindle. A balanced valve either has a groove cut into the the widget’s threads to allow gas to equalise quickly from one side to the other (MDE) or a small hole (Scubapro). Unbalanced valves rely an the gas equalising by migrating along the threads which is normally somewhat slower…effectively you will find that the greater pressure inside the tank will aid opening a valve (easier) and inhibit closing it (stiffer).

It may be possible to “balance” an “unbalanced” valve by using a hack-saw to cut a groove within the valve internals, this is not recommended unless you know what you are doing!

Rubber Knobs

These are more often called “tactile handles” in dive shop speak. These are far easier to grip than normal hard plastic knobs and far more resilient. The option of using solid brass handles may at first glance seem like a good option, but in fact they transfer shocks from the handle to the shaft of the valve and can cause the valve to seize preventing opening or closure; this is an additional problem of hard plastic knobs. In comparison rubber knobs will absorb a lot of the impact, resisting damage to the valve.

The rubber handle must have a metal insert to stop the thread being stripped through use.

Tank Bands

These are used to hold the two cylinders together.

Cam band (webbing) systems are suitable for independent cylinders but completely inappropriate if the tanks are manifolded in any way, since the tanks aren’t held rigid. The subsequent movement stresses the connections between the manifold itself and the pillar valves.

There are a number of stainless steel bands available. They generally look like strips of stainless steel, which have been formed in the shape of a figure eight with a bolt through the middle. This bolt is tightened to hold the tanks in place.

There are certain things to avoid:

Sharp edges on the bands, which will cut into the tanks’ paint work and encourage corrosion.

Spot welds, which are not as strong as continuous (seam) welding.

D Rings on the lower (and upper) bands which can easily become entangled during a dive, this entanglement is then difficult to clear. Band mounted D Rings offer nothing but problems to the diver since they are so difficult to reach during a dive.

Low marine-grade stainless steel.

Bands, which warp under stress.

Bands, which are too narrow and do not hold the tanks rigidly aligned

Cylinder Boots

Cylinder boots, whilst maybe offering the benefit of greater stability to the single tank diver, offer little if nothing to the twin set diver. Twin sets are inherently far more stable when stood upright, they can only move forwards or backwards. Sets can be easily rigged whilst leant against a boat side/wall etc and one hand is usually enough to stabilize it whilst putting it on.

All in all, when you consider the scope for corrosion with cylinder boots, you are really better off without them. For further information including a picture of tank corrosion, see the relevant section under Which Tanks? Single Cylinders

Buoyancy

Obviously a larger form of buoyancy is needed for a twin set due to the additional weight. A 55lb wing should be sufficient for your needs, even if you carry 2-3 decompression cylinders, provided they are of the “right” type and you are properly weighted.

A 35lb wing represents the minimum lift you should consider but future flexibility and the ability to carry stages with this sized wing would be limited.

Deep down you want the best, so that’s why we spared no expense in stocking top of the line equipment. For details about our CCR Units please contact us, Rebreathers are only rented for courses.

For The Student

During your course you will use Apeks XTX series regulators, double bladder wings and a soft harness for the perfect fit. These are provided to you as part of your course and we don’t charge extra for equipment.

For The Diver

We are fully stocked to rent everything from deco regs to reels, from spare masks to lift bags, twin sets to o2 bail outs. All these things can be rented at your leisure and can be arranged whenever you like. We simply ask that if you break something, you fix it.

Computers

We primarily use Suunto Vytecs with 3 gas modes for our diving. They’re inexpensive, reliable and perfect for our diving. We have access to VR3 computer for those doing their Trimix course and CCR Courses.

Suppliers

At this time we only use OMS, Halcyon and Apeks gear for rental, sales and service.