Ice diving

Procedures

Whether ice diving inherently constitutes technical diving is debated within the recreational diving community. For the professional diver it is a high risk environment requiring additional safety measures.

Ice diving is a team diving activity because each diver's lifeline requires a line tender. This person is responsible for paying out and taking in line so that the diver does not get tangled, and for rope signal communications with the diver. Professional teams will also require a stand-by diver and diving supervisor

Under some circumstances a guide line can be used as a reference for the divers to find the hole after the dive or in an emergency in a similar way to cave diving or wreck penetration instead of a lifeline. In these cases the divers should be competent in procedures for diving with a guideline.

Polar diving experience has shown that buoyancy control is a critical skill affecting safety.

Typical procedure for a scuba dive under ice:

Equipment

Since diving under the ice takes place in cold climates, there is typically a large amount of equipment required. Besides each person's clothing and exposure-protection requirements, including spare mitts and socks, there is basic scuba gear, back-up scuba gear, tools to cut a hole in the ice, snow removal tools, safety gear, some type of shelter, lines, and refreshments required.

The diver can use a weight harness, integrated weight buoyancy control device, or a weight belt with two buckles on it so the weights can not be accidentally released which would cause a run-away ascent into the ice sheet.

Dry suits with adequate thermal undergarments are standard environmental protection for ice diving, though in some cases thick wetsuits may suffice. Hoods, boots and gloves are also worn. Full-face masks can provide more protection for the divers' facial skin.

Exposure suits

Because of the water temperature (between 4 °C and 0 °C in fresh water, approximately -1.9 °C for normal salinity sea water), exposure suits are mandatory.

Some consider a dry suit mandatory; however, a thick wetsuit may be sufficient for hardier divers. A wetsuit can be pre-heated by pouring warm water into the suit. A hood and gloves (recommended three-finger mitts or dry gloves with rings) are necessary, and dry suit divers have the option of using hoods and gloves that keep their head and hands dry. Some prefer to use a full face diving mask to essentially eliminate any contact with the cold water. The biggest drawback to using a wet suit is the chilling effect on the diver caused by the water evaporating from the suit after a dive. This can be reduced by using a heated shelter.

Scuba equipment

A diving regulator suitable for cold-water is used. All regulators have a risk of freezing and free flowing, but some models fare better than others. Environmentally sealed regulators avoid contact between the surrounding water and the moving parts of the first stage by isolating them in an antifreeze fluid (e.g. Poseidon) or by siting the moving parts behind a diaphragm and transmitting the pressure through a pushrod (e.g. Apeks).

Although there is no universally accepted standard, at least one agency recommends the use of two non-freezing regulators arranged as follows: primary first stage with primary second stage, BCD inflation hose, and submersible pressure gauge (SPG); secondary first stage with secondary second stage (octopus), dry suit inflation hose, and SPG, although only one SPG is needed for a single cylinder or manifolded twins.

The two first stages are mounted on independently closable valves, as a first stage freeze free-flow can only be stopped by shutting off the air supply from the cylinder until the valve has thawed out. The second regulator is there to supply the remaining gas when the first regulator is shut off. A second-stage isolation valve used in conjunction with a first-stage overpressure relief valve may be effective as a quick method to manage demand valve free-flow.

Redundant systems usually typically comprise double cylinders with a primary and alternate regulator. Each of the second stages is supplied its own first stage, which can be shut down at the cylinder valve in an emergency, such as a free flow. The diver’s buoyancy compensator is on a different first stage to the dry suit so if there is an issue with one the diver can still control his buoyancy.

Some divers use a primary regulator on a 7-foot hose and a secondary on a necklace, this is useful when it may be necessary for the divers to swim in single file. the reason for the primary being on a long hose is to ensure the donated regulator is known to be working.

Buoyancy and weighting

Surface team.

Hazards

Hazards of ice diving include the The specific diving environment of penetration diving, and some hazards that are more specific to the low temperature and overhead environment.

Regulator freezing

When air expands during pressure reduction in a regulator, the temperature drops and heat is absorbed from the surroundings. There are two possible ways for a regulator to freeze and free-flow.

First stage freeze

Air from the diving cylinder is subjected to a dramatic reduction in pressure - as much as 220 bar from a full 230 bar cylinder at the surface - when passing through the regulator first stage. This lowers the temperature of the air, and heat is absorbed from the components of the regulator. As these components are largely metal and therefore good conductors of heat energy, the regulator body will cool quickly to a temperature lower than the surrounding medium. When immersed in water during a dive, the water surrounding the regulator is cooled and, if this water is already very cold, it can freeze.

If the water in direct contact with the pressure transfer mechanism (diaphragm or piston and the spring balancing the internal pressure) of the regulator freezes, the mechanism will be locked in the position at which the freezing takes place, as the ice will prevent the movement required to close. Since the cooling takes place during flow through the regulator, it is common for the freezing to occur when the first stage valve is open, and this will freeze the valve open, allowing a continuous flow through the first stage. This will cause the inter-stage pressure to rise until the second stage opens to relieve the excess pressure, the pressure relief valve on the first stage opens, or a low pressure hose or fitting bursts. All of these effects will allow the flow through the first stage to continue, so the cooling will continue, and this will keep the ice causing the problem frozen. To break the cycle it is necessary to stop the gas flow or expose the ice to a heat source capable of melting it. While underwater, it is unlikely to find a heat source to thaw the ice and stopping the flow is only option. Clearly the flow will stop when the pressure in the cylinder drops to ambient, but this is undesirable as it means total loss of the breathing gas. The other option is to close the cylinder valve, shutting off the pressure at the source. Once this is done, the ice will normally melt as heat from the surrounding water is absorbed by the slightly colder ice, and once the ice has melted, the regulator will function again.

This freezing can be avoided by preventing water from coming into direct contact with cooled moving parts of the regulator mechanism, or by increasing the heat flow from the surrounding environment so that freezing does not occur. Both strategies are used in regulator design.

Second stage freeze

A similar effect occurs with the second stage. Air which has already expanded and cooled through the first stage expands again and cools further at the demand valve of the second stage. This cools the components of the second stage and water in contact with them may freeze. Metal components around the moving parts of the valve mechanism allow heat transfer from the surrounding slightly warmer water, and from exhaled air from the diver, which is considerably warmer than the surroundings.

A second stage freeze is also likely to happen with the valve open, causing a free flow, which may precipitate a first stage freeze if not immediately stopped. If the flow through the frozen second stage can be stopped before the first stage freezes, the process can be halted. This may be possible if the second stage is fitted with a shutoff valve, but if this is done, the first stage must be fitted with an overpressure valve, as closing the supply to the second stage disables its secondary function as an overpressure valve.

Factors increasing the risk of regulator freeze

Precautions to reduce risk of regulator freezing

Procedures for managing a regulator freeze

Protocol for a regulator freeze often includes aborting the dive.

Low pressure inflator freeze

It is possible for the dry suit or BCD inflation valve to freeze while inflating, for similar reasons to regulator freeze. If this happens it can cause a runaway ascent if it is not dealt with immediately. If possible the low pressure inflator hose should be disconnected before it freezes onto the valve, while dumping air to control buoyancy. Excessive dumping of air may leave the diver too negative so it is preferable to have at least two controllable buoyancy systems, such as a dry suit and BCD, preferably supplied from different first stages. If the dry suit inflation valve freezes open it may allow water to leak into the suit once disconnected, so this usually results in aborting the dive.

Most inflator problems can be avoided by keeping gear maintained and dry before the dive, using a low flow rate for inflation and avoiding long bursts, and having warm water at the dive site to thaw gear since ambient air temperature is usually well below freezing and this usually causes BCD issues before the dive.

Training

Training includes learning about how ice forms, how to recognize unsafe ice conditions, dive site preparation, equipment requirements, and safety drills.

Other skills required by the ice diver include: