Turn pressure is the remaining gas pressure at which the dive will be turned, and either the exit from a penetration dive or the ascent will be started. Turn pressure usually refers to the bottom gas, but can also be based on the pressure in other cylinders if the supply of that gas is critical.
Arbitrary turn pressure The majority of recreational divers do not do penetration dives or dives exceeding the
no-decompression limit, and can safely ascend directly to the surface at any point of a dive. Such ascents do not use a large volume of gas, and these divers are commonly taught to start the ascent at a given remaining pressure in the cylinder, regardless of the depth, size of cylinder, or breathing rate expected, mainly because it is easy to remember and makes the dive leader's work simpler on group dives. The method originated in the non-adjustable reserve pressure cutoff provided by mechanical reserve cylinder valves which were in general use before the
submersible pressure gauge became a standard component of the scuba set. It may occasionally be insufficiently conservative, but is more often unnecessarily conservative, particularly on shallow dives with a large cylinder. Divers may be told to notify the dive leader at 80 or 100 bar and to return to the boat with not less than 50 bar or 700 psi or something similar remaining, but one of the reasons for having the 50 bar in reserve is to make the return to the boat safer, by allowing the diver to swim on the surface in choppy water while breathing off the regulator. This residual gas may also be well used for an extended or additional safety stop when the dive approached the no decompression limit, but it is good practice not to entirely use up the gas if it can safely be avoided, as an empty cylinder is easier to contaminate during handling, and the filling operator may be required to have any cylinder which does not register a residual pressure when presented for filling internally inspected to ensure that it has not been contaminated by water ingress.
Rule of thirds The rule of thirds is another such
rule of thumb. The basic rule generally only applies to diving in overhead environments, such as caves and wrecks, where a direct ascent to the surface is impossible and the divers must return the way they came, and no decompression stops are intended. If decompression is planned, the rule of thirds may be applied additional to decompression gas requirements. For divers following this rule, one third of the gas supply is used for the outward journey, one third for the return journey and one third is held in reserve in case of an emergency. The dive is turned when the first diver reaches one third of the starting pressure. However, when diving with a buddy with a higher breathing rate or a different volume of gas, it may be necessary to set one third of the buddy's gas supply as the remaining 'third'. This means that the turn point to exit is earlier, or that the diver with the lower breathing rate carries a larger volume of gas than would be required if both had the same breathing rate. Reserves are needed at the end of dives in case the diver has gone deeper or longer than planned and must remain underwater to do
decompression stops before being able to ascend safely to the surface. A diver without gas cannot do the stops and risks
decompression sickness. In an
overhead environment, where it is not possible to ascend directly to the surface, the reserve allows the diver to donate gas to an out-of-gas buddy, providing enough gas to let both divers exit the enclosure and ascend to the surface.
Half + 15 bar A different option for penetration dives is the "half + 15 bar" (half + 200 psi) method, in which the contingency gas for the stage is carried in the primary cylinders. Some divers consider this method to be the most conservative when multi-staging. If all goes to plan when using this method, the divers surface with stages nearly empty, but with all the contingency gas still in their primary cylinders. With a single stage drop, this means the primary cylinders will still be about half-full.
Rock bottom gas quantity calculations (metric system) "Rock bottom gas planning" refers to the methods of scuba gas quantity calculation based on a planned dive profile where a reasonably accurate estimate of the depths, times, and level of activity expected for each stage of the dive is available, so fairly rigorous calculations for gas mixtures and the appropriate quantities of each mixture are useful. Gas consumption depends on the ambient pressure, the breathing rate, and the duration of the dive sector under those conditions. Ambient pressure is a direct function of the depth. It is atmospheric pressure at the surface, plus hydrostatic pressure, at 1 bar per 10 m depth.
Respiratory minute volume Respiratory minute volume (RMV) is the volume of gas that is breathed by a diver in a minute. For a working commercial diver IMCA suggests RMV = 35 L/min. For emergencies IMCA suggests RMV = 40 L/min Decompression RMV is usually less as the diver is not generally working hard. IMCA, however, does not approve of the use of scuba for commercial diving, so these figures are intended for use with
scuba replacement equipment with surface supplied demand helmets and full-face masks, where the diver does not have to carry the primary breathing gas cylinders. Smaller values can be used for estimating dive times, The diver can use measured values for themself, but worst case values should be used to calculate critical pressures for turnaround or ascent and for rescue, as the RMV of a diver will usually increase with stress or exertion. Some divers calculate personal dive factors which are reasonably consistent values for multiples of resting gas consumption for different levels of work, such as decompressing, relaxed diving, sustained swimming, hard work etc. These factors can be used to estimate RMV.
Gas consumption rate Gas consumption rate (Q) on open circuit depends on
absolute ambient pressure (Pa) and RMV. Gas consumption rate: Q = Pa × RMV (litres per minute)
Available gas The available volume of gas in a cylinder is the volume which may be used before reaching a critical pressure, generally known as the reserve. The value chosen for reserve should be sufficient for the diver to make a safe ascent in sub-optimal conditions. It may require supply of gas to a second diver (buddy breathing) Available gas may be corrected to surface pressure, or specified at a given depth pressure. Available gas at ambient pressure: :Vavailable = Vset × (Pstart − Preserve)/Pambient Where: :Vset = volume of the cylinder set = sum of the volumes of the manifolded cylinders :Pstart = Starting pressure of the cylinder set :Preserve = Reserve pressure :Pambient = ambient pressure In the case of surface pressure: Pambient = 1 bar and the formula simplifies to: :Available gas at surface pressure: Vavailable = Vset × (Pstart − Preserve)
Available time The time a diver can work on the available gas (also called endurance) is: Available time = Available gas / RMV The Available gas and the RMV must both be correct for the depth, or both corrected to surface pressure.
Estimation of gas requirement for a dive sector Calculation of gas requirement for a dive can be broken up into simpler estimates for gas requirement for sectors of the dive, and then added together to indicate the requirement for the entire dive. A dive sector should be at a constant depth, or an average depth can be estimated. This is used to get the sector ambient pressure (Psector). The duration of the sector (Tsector) and RMV of the diver for the sector (RMVsector) must also be estimated. If the sector gas volume requirements (Vsector) are all calculated at surface pressure, they can later be added directly. This reduces the risk of confusion and error. Once these values have been chosen they are substituted in the formula: Vsector = RMVsector × Psector × Tsector This is the free volume of the gas at atmospheric pressure. The pressure change (δPcyl) in the cylinder used to store this gas depends on the internal volume of the cylinder (Vcyl), and is calculated using
Boyle's law: δPcyl = Vsector × Patm/Vcyl (Patm - 1 bar)
Minimum functional pressure Breathing gas regulators will work efficiently down to a cylinder pressure slightly above the designed interstage pressure. This pressure may be called minimum functional cylinder pressure. It will vary with depth as the nominal interstage pressure is additional to the ambient pressure. This does not mean that all the remaining gas is unobtainable from a cylinder; rather that the regulator will deliver some of it less efficiently than the designed work of breathing, and the rest only when the ambient pressure is reduced. In most regulator designs the diver will have to overcome a larger cracking pressure to open the demand valve, and flow rate will be reduced. These effects increase as the interstage pressure decreases. This can provide the diver with a warning that gas supply from that cylinder will immanently cease. However, in at least one regulator design, once the interstage pressure has been sufficiently reduced, the inflatable second stage servo-valve will deflate and effectively lock open the demand valve, allowing the residual gas to escape until the cylinder pressure has dropped to approximately equal the ambient pressure, at which point flow will stop until the ambient pressure is reduced by ascending to shallower depth. A value of 10 bar interstage pressure plus ambient pressure is a suitable estimate for minimum functional pressure for most planning purposes. This value will vary with the depth, and a regulator that has stopped delivering breathing gas may deliver a little more gas as the ambient pressure decreases, allowing a few more breaths from the cylinder during ascent if the gas is used up during the dive. The amount of gas available in this way depends on the internal volume of the cylinder.
Critical pressures Critical pressures (Pcritical or Pcrit) are pressures that must not be dropped below during a given part of a planned dive as they provide gas for emergencies.
Reserve pressure is an example of a critical pressure. This is also known as '
, or ' as this indicates the amount of gas required to safely ascend with allowances for specific contingencies listed in the dive plan. Critical pressures may also be specified for the start of the dive and for turnaround where direct ascent is not possible or not desirable. These can be called '
or ', and '
or '.
Calculation of critical pressures Critical pressures are calculated by adding up all the volumes of gas required for the parts of the dive after the critical point, and for other functions such as suit inflation and buoyancy control if these are supplied from the same set of cylinders, and dividing this total volume by the volume of the cylinder set. A minimum functional pressure is added to this value to give the critical pressure. Example: Critical pressure of descent:
This dive should not be attempted if less than 176 bar is available. Note that no allowance has been made for contingencies.
Effect of temperature change on pressure The temperature of the gas should be taken into account when checking critical pressures. Critical pressures for ascent or turnaround will be measured at ambient temperature and do not require compensation, but critical pressure for descent may be measured at a temperature considerably higher than the temperature at depth. Pressure should be corrected to the expected water temperature using
Gay-Lussac's law. P2 = P1 × (T2/T1) Example: Pressure correction for temperature: The cylinders are at about 30°C, water temperature is 10°C, critical pressure for descent (P1) is 176 bar at 10°C
Estimating gas quantities for contingencies The basic problem with estimating a gas allowance for contingencies is to decide what contingencies to allow for. This is addressed in the
risk assessment for the planned dive. A commonly considered contingency is to share gas with another diver from the point in the dive where the maximum time is needed to reach the surface or other place where more gas is available. It is likely that both divers will have a higher than normal RMV during an assisted ascent as it is a stressful situation, and it is prudent to take this into account. For occupational divers the values should be chosen according to recommendations of the code of practice in use, but if a higher value is chosen it is unlikely that anyone would object. Recreational divers are advised by the training agencies to use values which the agency considers appropriate and unlikely to lead to litigation, which are generally conservative and based on published experimental data, but the divers may have the discretion to use RMV values of their own choice, based on personal experience and informed acceptance of risk. The procedure is identical to that for any other multi-sector gas consumption calculation, except that two divers are involved, doubling the effective RMV. To check whether the bail-out cylinder has adequate gas (for one diver) in case of an emergency at the planned depth, critical pressure should be calculated based on the planned profile and should allow change-over, ascent and all planned decompression. Example: Emergency gas supply: A dive is planned to 30 m which requires 6 minutes decompression at 3 m. For emergencies IMCA recommends assuming RMV = 40 L/min
Gas matching Gas matching is the calculation of reserve and turn pressures for divers using different cylinder volumes or with different gas consumption rates on the same dive, allowing each diver to ensure that sufficient gas is retained to allow for foreseeable contingencies where divers may need to share gas, based on each diver's cylinder volumes, and both divers' individual gas consumption rates. It is standard practice to turn the dive immediately on starting emergency gas sharing, so matched gas volumes only apply from the turning point. Up to that point only the diver's own consumption under the expected conditions need be considered. == Gas quantities for rebreathers ==