Divers face specific physical and health risks when they go underwater with scuba or other diving equipment, or use high pressure breathing gas. Some of these factors also affect people who work in raised pressure environments out of water, for example in caissons. This article lists hazards that a diver may be exposed to during a dive, and possible consequences of these hazards, with some details of the proximate causes of the listed consequences. A listing is also given of precautions that may be taken to reduce vulnerability, either by reducing the risk or mitigating the consequences. A hazard that is understood and acknowledged may present a lower risk if appropriate precautions are taken, and the consequences may be less severe if mitigation procedures are planned and in place.
A hazard is any agent or situation that poses a level of threat to life, health, property, or environment. Most hazards remain dormant or potential, with only a theoretical risk of harm, and when a hazard becomes active, and produces undesirable consequences, it is called an incident and may culminate in an emergency or accident. Hazard and vulnerability interact with likelihood of occurrence to create risk, which can be the probability of a specific undesirable consequence of a specific hazard, or the combined probability of undesirable consequences of all the hazards of a specific activity. The presence of a combination of several hazards simultaneously is common in diving, and the effect is generally increased risk to the diver, particularly where the occurrence of an incident due to one hazard triggers other hazards with a resulting cascade of incidents. Many diving fatalities are the result of a cascade of incidents overwhelming the diver, who should be able to manage any single reasonably foreseeable incident. The assessed risk of a dive would generally be considered unacceptable if the diver is not expected to cope with any single reasonably foreseeable incident with a significant probability of occurrence during that dive. Precisely where the line is drawn depends on circumstances. Commercial diving operations tend to be less tolerant of risk than recreational, particularly technical divers, who are less constrained by occupational health and safety legislation.
Decompression sickness and arterial gas embolism in recreational diving are associated with certain demographic, environmental, and dive style factors. A statistical study published in 2005 tested potential risk factors: age, gender, body mass index, smoking, asthma, diabetes, cardiovascular disease, previous decompression illness, years since certification, dives in last year, number of diving days, number of dives in a repetitive series, last dive depth, nitrox use, and drysuit use. No significant associations with decompression sickness or arterial gas embolism were found for asthma, diabetes, cardiovascular disease, smoking, or body mass index. Increased depth, previous DCI, days diving, and being male were associated with higher risk for decompression sickness and arterial gas embolism. Nitrox and drysuit use, greater frequency of diving in the past year, increasing age, and years since certification were associated with lower risk, possibly as indicators of more extensive training and experience.[1]
Statistics show diving fatalities comparable to motor vehicle accidents of 16.4 per 100,000 divers and 16 per 100,000 drivers. Divers Alert Network 2014 data shows there are 3.174 million recreational scuba divers in America, of which 2.351 million dive 1 to 7 times per year and 823,000 dive 8 or more times per year. It is reasonable to say that the average would be in the neighbourhood of 5 dives per year.[2]
Near drowning is the survival of a drowning event involving unconsciousness or water inhalation and can lead to serious secondary complications, including death, after the event.[3][4]
Inhalation of liquid (water), usually causing laryngospasm and suffocation caused by water entering the lungs and preventing the absorption of oxygen leading to cerebral hypoxia.[3]
Use of an alternative regulator which can be easily reached if the dislodged primary is difficult to reach.[9]
Complications can occur up to 72 hours after a non-fatal drowning incident, and may lead to a serious condition or death.
Physiological responses to contaminants in the lung due to inhalation of liquid.
Exudation of liquid into the lungs (pulmonary edema) over the hours following aspiration of liquid, which reduces the ability to exchange air and can lead to a person "drowning in their own body fluid".
Aspiration of vomit can have a similar effect.
Prompt and appropriate medical treatment after near drowning, including a medical observation period.
Use of breathing equipment in an underwater environment
Hazard
Consequences
Cause
Avoidance and prevention
Oxygenpartial pressure in the breathing gas is too low to sustain normal activity or consciousness.
Some breathing gas mixtures for deep diving such as trimix and heliox are hypoxic at shallow depths, and do not contain enough oxygen to maintain consciousness, or sometimes life, at or near the surface.[13]
Internal corrosion of full cylinder standing for a long time can potentially use up some of the oxygen in the contained gas before the diver uses the cylinder.[15][16]
Analysis of oxygen fraction of gas before use, particularly if cylinder has been stored for a long time.
Loss of breathing gas supply.
May result in drowning, occasionally asphyxia without water aspiration.
Equipment failure: Several modes are possible.
Closing and jamming of the cylinder valve by rolloff on something overhead (rotation of the knob to close the valve by friction when dragged along in contact with a surface), or by kelp when pushing through dense kelp.[9]
Rupture of a bursting disc overpressure protection on a cylinder valve (a thin metal membrane calibrated to fail if the pressure exceeds a safe value for the cylinder).[18]
Rupture of a regulator hose or loss of the end component, leaving an open hose end.[18]
Unrecoverable free flow of a second stage (valve jammed open, allowing gas to escape even when not needed by the diver).
Freezing of a first stage regulator, locking the valve mechanism open, and consequent free flow of the demand valve due to excessive interstage pressure.
O-ring failure at the connection of a regulator to a cylinder valve.
Appropriate maintenance and servicing of equipment.[5]
Inspection of the external condition, and testing of the function of equipment before use.[5]
Use only of equipment in good working condition.[5]
Connection and mounting of equipment to minimise risk of damage.
Avoidance of damage to equipment during dives.
Use of two fully independent breathing gas supplies.[19]
The buddy system, when correctly followed, allows the diver's buddy to supply breathing gas in an emergency.[9]
"H" or "Y" type cylinder valves or manifolded twin cylinders with two cylinder valves allow the dysfunctional supply to be closed to prevent total loss, and the other regulator to be used for the remaining gas supply. (frequently used to mitigate regulator freezing in cold water)
Dual independent cylinders ensure that if one cylinder supply fails there is another available.[5]
Use of DIN connections can reduce the risk of catastrophic O-ring failure.[20]
Emergency free ascent may be possible, and is generally more survivable than drowning.
Running out of breathing gas because of poor gas monitoring discipline.[21]
Appropriate maintenance and servicing of equipment.[18]
Inspect external condition and test function before use. (specifically test the seal of exhaust valves and possible leaks in the second stage casing and mouthpiece before opening the cylinder valve).[24]
Use equipment only if it is in good working condition.[5]
Contaminated air supplied by a compressor that sucked in products of combustion, often its own engine's exhaust gas. Aggravated by increased partial pressure due to depth.
Adequate precautions to ensure that intake is in uncontaminated air when operating breathing air compressors.[25]
Periodical air quality testing of compressors.
Use of compressor output filter containing "Hopcalite" catalyst to convert possible carbon monoxide contamination to less hazardous carbon dioxide.
Test air quality before use (portable carbon monoxide analysers are available and may be worth using in places where air quality is questionable).
Air contaminated with carbon monoxide is often contaminated by substances having a smell or taste. Air smelling or tasting of exhaust fumes should not be breathed.
Oil getting into the air and partially oxidising in the compressor cylinder, like in a diesel engine, due to worn seals and use of unsuitable oils, or an overheated compressor.[25]
Adequate maintenance of the compressor.
Use of correct oil rated for breathing air compressor lubrication.[25]
Ensure compressor running temperature is within manufacturer's specifications.
Ensure adequate supply of cooling air to compressor.
Compressor should not be run when ambient temperatures exceed manufacturer's limits.
Re-inhaling carbon dioxide-laden exhaled gas due to excessive dead space in breathing apparatus.
Shallow breathing—not exchanging sufficient air during a breathing cycle.
Minimise the volume of any enclosed spaces through which the diver breathes. For example, this can happen with diving with a large "bubblehead" helmet.
Avoiding breathing shallow (low volume) breaths.
The scrubber of a diving rebreather, fails to absorb enough of the carbon dioxide in recirculated breathing gas. This can be due to the scrubber absorbent being exhausted, the scrubber being too small, or the absorbent being badly packed or loose, causing "tunneling" and "scrubber breakthrough" when the gas emerging from the scrubber contains excessive carbon dioxide.
Adequate maintenance of rebreathers.
Correct packing and assembly of scrubber canisters.[29]
Pre-use inspection and testing of rebreathers using an appropriate checklist.
Use of correct scrubber absorbent material.
Use of absorbent that is of good working quality.
Discard absorbent after use.
Use of carbon dioxide monitoring instruments.
Adequate training in the recognition of hypercapnia before using a rebreather.
Bail-out to open circuit if carbon dioxide levels get too high.
Filling of cylinders with compressed air taken from an area of raised concentration of carbon dioxide.
Siting the compressor air intake in an area of fresh air and ducting it to the compressor.
Passing intake air through a carbon dioxide scrubber element before compression.
Periodical air quality testing of compressors.
Breathing the wrong gas
Consequences depend on the circumstances, but may include oxygen toxicity, hypoxia, nitrogen narcosis, anoxia, and toxic effects of gases not intended for breathing. Death or serious injury is likely.
The wrong gas was put in a cylinder.
A cylinder was marked or labelled incorrectly.
A correctly labelled cylinder was mistaken by the user.
The diver unintentionally switches to the wrong gas during a dive.
Cylinders should be filled by competent people.[17]
Clear instructions, preferably written, for the composition of the gas to be mixed will reduce the risk of filling with the wrong gas.
Clear, unambiguous and legible labels indicating maximum operating depth and cylinder contents, applied in a way that the user will be able to positively identify the gas at the time when it is to be used can prevent confusion and inadvertent use of the wrong gas.[9]
Analysing gas after filling, before accepting delivery, and before use (before the dive) may detect errors in labelling or composition in time to take corrective action.[17]
Procedures designed to positively identify the gas may be used when switching mixes.[9]
Valves that change gas mixes may be fitted with a positive interlock preventing accidental or inadvertent switching, and may include a method of confirming the gas connected by feel.
Displacement of demand valve (DV) from the diver's mouth.
Inability to breathe until demand valve is replaced. This should not normally be a major problem as techniques for DV recovery are part of basic training. Nevertheless, it is an urgent problem and may be exacerbated by loss of the mask and/or disorientation.
Unconscious diver releases grip on mouthpiece.[30]
DV is forcibly knocked or pulled from the diver's mouth by impact with surroundings or another diver.
Use of full face mask reduces risk of loss of DV as it is strapped to the head and can not be dropped if the diver loses consciousness.[6]
Adequate training and practice of DV recovery skills.
Use of an alternative air source such as octopus DV or bailout cylinder, which can be used if the primary DV is not immediately accessible.
Mounting the alternative air source and DV so that it is easily accessible in an emergency and protected from damage when not in use.
Caustic cocktail
Disruption of breathing by watery suspension/solution containing scrubber absorbent medium.
Aspiration of water contaminated by scrubber medium.
Leakage of water into the breathing loop of a rebreather, which dissolves alkaline material used to chemically remove carbon dioxide from exhaled air. This contaminated water may move further along the breathing loop and reach the diver's mouth, where it may cause choking, and in the case of strong alkalis, caustic corrosion of the mucous membranes.
Prevent ingress of water to rebreather by:
checking before use that the unit does not leak,
closing the dive/surface valve when the mouthpiece is not in the diver's mouth.
Prevent creation of caustic cocktail by:
use of less soluble and less alkaline scubber media,
design using water traps and drainage arrangements (on some rebreather designs),
introducing a semi-permeable membrane to block water from the scrubber.
Avoid aspiration of water from loop by recognising the characteristic gurgling sounds and increased breathing resistance, and taking appropriate action by bailing out or draining the set if possible.
In the event of caustic cocktail reaching the mouth, bail out to alternative gas supply and rinse mouth with ambient water.
Exposure to a pressurised environment and pressure changes
Cold water in the outer ear passage, chilling the inner ear, particularly severe if the eardrum is ruptured.
Use of a hood to keep the head covered. Water leaking into the hood will warm up before entering the external auditory opening and will be reasonably warm before reaching the eardrum, and will soon reach body temperature if flushing is minimised.
Pressure difference over eardrum
Burst or stretched eardrum: The eardrum is stretched due to a pressure difference between the outer and middle ear spaces. If the eardrum stretches sufficiently, it may rupture, which is more painful. Water entering the middle ear may cause vertigo when the inner ear is cooled. Contaminants in the water may cause infection.[31]
The pressure in the middle ear not equalizing with external (ambient) pressure, usually due to failure to clear the Eustachian tube.[31]
Ears can be equalized early and often during the descent, before the stretching is painful. The diver can check if the ears will clear on the surface as a precondition for diving.[31]
Reversed ear may be caused by the outer ear passage being blocked and the pressure remaining low, while the middle ear pressure increases by equalising with ambient pressure through the eustachian tubes, causing a pressure differential and stretching the eardrum, which may eventually rupture.[32]
The hood should not make an airtight seal over the outside ear opening.
Sealed earplugs should never be worn while diving.[32]
Pressure difference between paranasal sinus and ambient pressure.
Sinus squeeze: Damage to the sinuses usually resulting in pain, and often burst blood vessels and nosebleed.[33]
Obstruction to the sinus ducts leading to pressure differences between the interior of the sinus and the external pressure.[33]
Do not dive with conditions such as the common cold or allergies that cause nasal congestion.[33]
Localised low pressure in the diving mask.
Mask squeeze: Squeeze damage to blood vessels around the eyes.[34]
Caused by local low pressure in the air space inside a diving half-mask. Ambient pressure increase during descent not balanced inside mask air space.
Mask squeeze can be avoided by allowing air into the mask through the nose whenever the pressure difference is noticeable.
A fullface mask will automatically equalise through the demand valve.
Air filled eyes-only goggles can not be equalised and are not suitable for diving.
Suit squeeze injury (usually restricted to bruising and minor abrasion) to skin.[34]
Volume of air in a drysuit reduces as pressure increases with depth.
Skin may be pinched by folds in a drysuit as the air inside is compressed.
Modern drysuits have a low pressure air hose connection and valve to inflate the drysuit from the cylinder. Adding sufficient air to maintain the bulk of the undersuit will prevent suit squeeze and stabilize buoyancy of the suit.
Pressure difference between lung gas contents and ambient pressure
Lung squeeze: Lung damage.
Free diving to extreme depth.
It can be avoided by limiting free diving depth to capacity of lungs to compensate,[35] and by training exercises to increase compliance of chest cavity.[citation needed]
Rupture or supply pressure failure of a surface supply hose with simultaneous failure of the non-return valve.[35]
Maintenance and pre-dive tests of non-return valves on the helmet or full face mask.
Helmet squeeze, with the old standard diving dress. (This can not happen with scuba or where there is no rigid pressure-tight helmet)
In severe cases much of the diver's body could be mangled and compacted inside the helmet; however, this requires substantial pressure difference, or by a sudden considerable increase in depth, as when the diver falls off a cliff or wreck and descends faster than the air supply can keep up with the pressure increase.
A non-return valve in the air supply line to the helmet failing (or absent on the earliest models of this type of diving suit), accompanied by a failure of the air compressor (on the surface) to pump enough air into the suit for the gas pressure inside the suit to remain equal to the outside pressure of the water, or a burst air supply hose.
Appropriate maintenance and daily pre-use testing of non-return valves.
A sudden large increase in ambient pressure due to sudden depth increase, when the air supply can not compensate fast enough to prevent compression of the air in the suit.
The squeeze due to depth changes was more likely when the air supply was powered by men. Motorised compressors are usually able to supply air much faster, so an adequate air reservoir on the compressor should prevent this problem.
The diver may be prevented from sinking too deep by minimizing slack in the lifeline or umbilical.
The diver may work at neutral buoyancy when there is a risk of falling off a structure, or may clip on to the structure, but this presents a hazard of entrapment.
Any gas space inside a tooth due to decay or poor quality fillings or caps may allow tissue inside the tooth to be squeezed into the gap causing pain.
Tooth squeeze may be avoided by ensuring good dental hygiene and that all fillings and caps are free of air spaces.
Suit compression.
Loss of buoyancy may lead to:
Uncontrolled descent.
Inability to achieve neutral buoyancy.
Inability to surface due to insufficient buoyancy.
Difficulty in controlling depth and ascent rate. This can be critical when decompression is required, and oxygen-rich breathing gases are used.
Buouyancy loss due to compression of foam neoprene wet or drysuit material.
Use of buoyancy compensator with volume appropriate to expected buoyancy variation during dive.
Use of appropriate ballast weight for dive profile and equipment in use.
Use of inflation system for replacing lost volume in drysuits.
Excessive weighting makes buoyancy control more difficult and loss of control more likely.
Adequate training and practice of buoyancy control skills.
Pressure changes during ascent
Hazard
Consequences
Cause
Avoidance and prevention
Lung overpressure: Pressure in lungs exceeds ambient pressure.
Pulmonary barotrauma (Lung overexpansion injury)—rupture of lung tissue allowing air to enter tissues, blood vessels, or spaces between or surrounding organs:
Sinus overpressure injury is commonly restricted to rupture of mucous membrane and small blood vessels, but can be more serious and involve bone damage.[citation needed]
Blockage of the sinus's duct, preventing trapped air in a sinus from equalising with the pharynx.
Not diving with nasal congestion, e.g. Hay fever, or the common cold.
Checking before a dive to ensure that sinuses and middle ears will equalise without undue effort.
Systemic decongestants have been used successfully, but may have undesirable side-effects, and there is a risk that they will wear off before surfacing. Topical decongestants do not usually have sufficient lasting effect.
Middle ear overpressure
Injury (reversed ear) of eardrum stretching or bursting outwards due to expansion of air in the middle ear.
Blocked Eustachian tube fails to allow pressure to equalise middle ear with the upper airway.
Overpressure within a cavity in a tooth, usually under a filling or cap.
Gas may find its way into a cavity in the tooth or under a filling or cap during a dive and become trapped. During ascent, this gas will exert pressure inside the tooth.
Good dental hygiene, and maintenance of dental repairs to prevent or remove potential gas traps.
Suit and BC expansion
Loss of buoyancy control—uncontrolled ascent.
Expansion of neoprene suit material, gas content of dry suits and buoyancy compensators increasing buoyancy of the diver.
Automatic dump valves in dry suits.
Monitoring of buoyancy on a continuous basis when in mid-water, and manually adjusting volume of buoyancy compensator when necessary.
Appropriate training and practice to develop good buoyancy control skills to suit the equipment in use.
Ability to recover from inversion in dry suit.
Maintaining the minimum air volume for adequate liner bulk maintenance in a dry suit, as this prevents excessive buoyancy shifts. This implies use of the buoyancy compensator for buoyancy control, not the suit.
Minimizing weighting to what is actually necessary, so compensatory air volume is minimized. This reduces the magnitude and rate of buoyancy change with pressure change.
History of heavy smoking
Risk of increased severity of decompression illness
Data from a 2000 analysis of decompression illness records suggest that smokers with DCI tend to present with more severe symptoms than non-smokers.
Don't smoke.
Breathing gases at high ambient pressure
Hazard
Consequences
Cause
Avoidance and prevention
Medium to long term exposure to high partial pressures (>c1.3 bar) of inert gas (usually N2 or He) in the breathing gas.
Decompression sickness ("the bends"): Injury due to gas bubbles expanding in the tissues and causing damage, or gas bubbles in the arterial circulation causing emboli and cutting off blood supply to tissues downstream of the blockage.
Gas dissolved in tissues under pressure during the dive according to Henry's Law coming out of solution and forming bubbles if the ascent and decompression is too fast to allow safe elimination of the gas by diffusion into the capillaries and transport to the lungs where it can diffuse into the respiratory gas. Although rare, decompression sickness is possible in free-diving (breathhold diving) when many deep dives are done in succession. (See also taravana).
Decompress to suit the dive profile and gas mixtures used.
Use appropriate ascent rates and decompression stops.
Oxygen-rich gas mixtures may be used to accelerate decompression.
Use depth control aids to maintain correct decompression depth.
Avoid dehydration and hypothermia.
Maintain cardiovascular fitness.
Short term (immediate onset) exposure to high partial pressure (>c2.4 bar) of nitrogen in the breathing gas:
The most dangerous aspects of narcosis are the loss of decision-making ability and focus, and impaired judgement, multi-tasking and coordination.
Other effects include vertigo, and visual or auditory disturbances, exhilaration, giddiness, extreme anxiety, depression, or paranoia, depending on the individual diver.
A high partial pressure of nitrogen in the nerve tissues. (other gases may also have narcotic effect, to varying degrees).
Related to the increased solubility of gases in body tissues at elevated pressure.[39]: 308
Breathing gas with too high a partial pressure of oxygen, risk becomes significant at partial pressures exceeding 1.6 bar (partial pressure depends upon proportion of oxygen in the breathing gas, and depth).
Signs of pulmonary toxicity begin with inflammation of the upper airways.
Temporarily reduced lung capacity.
Acute respiratory distress syndrome.
Breathing gas at too high a partial pressure of oxygen, Risk is significant at a partial pressure in excess of 0.5 atmospheres pressure for long periods and increases with higher partial pressure even for shorter exposures.
Not normally a risk for recreational divers due to short exposures.
Limit use of rich nitrox mixtures and pure oxygen for accelerated decompression.
Limit exposure by calculating Oxygen Toxicity Units for pre-existing and planned exposures and keeping below recommended limits.
Most likely to be encountered in recompression treatment for decompression illness.
The compression effects may occur when descending below 500 feet (150 m) at rates greater than a few metres per minute, but reduce within a few hours once the pressure has stabilised.
The effects from depth become significant at depths exceeding 1,000 feet (300 m) and remain regardless of the time spent at that depth.[42]
The susceptibility of divers to HPNS varies over a wide range depending on the individual, but has little variation between different dives by the same diver.[42]
Exposure to cold water during a dive, and cold environment before or after a dive, wind chill.[46]
Hypothermia: Reduced core temperature, shivering, loss of strength, reduced level of consciousness, loss of consciousness, and eventually death.
Loss of body heat to the water or other surroundings. Water carries heat away far more effectively than air. Evaporative cooling on the surface is also an effective mechanism of heat loss, and can affect divers in wet diving suits while travelling on boats.[46]
Diving suits are available that are suited to a wide range of water temperature down to freezing.[47] The appropriate level of insulation for the conditions will reduce heat loss.
In extreme conditions and when helium-based mixtures are in use as breathing gas, heated suits may be necessary.[46]
On the surface, wind chill can be avoided by staying out of the wind, staying dry, and suitable protective clothing.[46]
Some parts of the body, particularly the head,[47] are more prone to heat loss and insulation of these areas is correspondingly important.
Stinging skin rash, local swelling and inflammation, sometimes extremely painful, occasionally dangerous or even fatal[46]
Some species of jellyfish (free swimming cnidaria) have stinging cells that are toxic to humans, and will inject venom on contact with the skin.[46]
Avoid contact with jellyfish tentacles.
Protective clothing such as exposure suits, lycra skins, or overalls is effective.[46]
Stingrays
A deep puncture or laceration that leaves venom in the wound.
Defensive reaction of a sting ray when disturbed or threatened, by lashing out with the venomous spine on the tail.
Stingrays can usually be avoided by not poking about on the bottom where they may be hiding, partly or completely buried under a thin layer of sand.
The risk is usually greater when wading, when the wader may inadvertently step on a buried ray.
Rays are usually very shy and will usually swim away when approached. Risk of injury may be avoided by not molesting or threatening the animals when seen, and by staying a safe distance from the tail.
Tropical reef environment
Reef rash: General or localised stinging or inflammation of the skin. may include allergic reactions.
A generic term for the various cuts, scrapes, bruises and skin conditions that result from diving in tropical waters. This may include sunburn, mild jellyfish stings, sea lice bites, fire coral inflammation and other skin injuries that a diver may get on exposed skin.
A full-body exposure suit can prevent direct skin to environment contact.
Fish and invertebrates with venomous spines.
Puncture wounds with venom injection. Often extremely painful and may be fatal in rare cases.
Found only in parts of the Pacific Ocean from Japan to Australia.
The octopus is unlikely to be aggressive, and is not likely to bite unless handled. However it can be well camouflaged against the reef and difficult to see, so not contacting the reef is the most reliable way to avoid contact.
Lacerations and punctures by teeth, brute force tearing of tissues. Possibility of drowning.
Risk factors are proximity or entry to water, and low light. Launching ranges are 4m forwards out of water and 2m above water surface. Running speed is up to 11 km/h.[49]
Found worldwide in tropical seas and fresh water.
Consult local information on risk.
Stay out of waters and surroundings known to be inhabited by crocodiles.
This tropical Indo-Pacific fish is very territorial during breeding season and will attack and bite divers.[50]
Keep a lookout for the fish and move away if they act aggressively. Since his territory and nest is roughly cone-shaped[51][50] move to the side instead of ascending.
Bite wounds, bruising and crushing injuries. [citation needed]
The Giant grouperEpinephelus lanceolatus can grow very big in tropical waters, where protected from attack by sharks. There have been cases of very large groupers trying to swallow humans.[52][53][54][55][56]
Get local information on risk.
Stay clear of very large specimens.
Do not attempt to feed the fish, they may take more than is offered.
Exposure to ultrasound in excess of 120 dB may lead to hearing loss. Exposure in excess of 155 dB may produce heating effects that are harmful to the human body, and it has been calculated that exposures above 180 dB may lead to death.[citation needed]
It is said that some naval anti-frogman defences use powerful ultrasound.[citation needed] Also used for long-range communication with submarines.[citation needed] Most high power sonar is used for submarine detection and target acquisition.[citation needed]
Keep out of armed forces areas.
Avoid large naval ships' anti-submarine warfare sonar.
Leptospirosis infection (Weil's disease) is commonly transmitted to humans by allowing water that has been contaminated by animal urine to come in contact with unhealed breaks in the skin, the eyes, or with the mucous membranes. Outside of tropical areas, leptospirosis cases have a relatively distinct seasonality with most of them occurring in spring and autumn.
Avoid diving in contaminated water.
Analyse water before diving if presence of contaminants is suspected, but type and concentration is not known.
If it is necessary, and depending on risk:
A watertight drysuit with dry gloves and integral dry hood, and positive pressure full face diving mask will provide acceptable protection in some circumstances.[57]
Surface supplied equipment with heavy duty full environmentally sealed dry suit with integral boots and gloves, and helmet sealed to suit, with either free flow air supply or series exhaust valve system will provide more protection.
Gas reclaim systems can provide the greatest security to ingress of contaminants.[58] The gas need not actually be reclaimed if it is not economically desirable, the systems are used so that there are no potential leaks though underwater exhaust openings.
Protective overalls may be worn over the drysuit to protect it from puncture damage.
Appropriate decontamination procedures may be used after the dive.
The diver should breathe from the diving air supply when surfaced in environments where air quality is uncertain.
Schistosomiasis (bilharzia) is a parasitic disease caused by several species of trematodes or "flukes" of the genus Schistosoma. Snails serve as the intermediary agent between mammalian hosts. This disease is most commonly found in Asia, Africa, and South America, especially in areas where the water contains numerous freshwater snails, which may carry the parasite. The parasitic larvae enter through unprotected skin and further mature within organ tissues.
A safe exit point and alternatives may be planned for taking into account forecasts for weather and tidal conditions.
Abandonment at surface after a boat dive
Diver lost at sea on the surface after a dive, with risk of exposure, drowning and dehydration.
Diver separated from boat cover due to poor visibility at surface or strong underwater currents.
Diver left behind due to inaccurate check by boat crew.
Diver unable to return to unattended boat.
Boat crew may use a positive check system to identify that each diver is on board after a dive.
Divers may carry a yellow flag or surface marker buoy to attract attention.
Divers may carry a personal submersible EPIRB or vhf radio.
Divers may carry a signalling mirror and/or sound signalling device.
Diving from unattended boats only when a safe shore exit is feasible.
Inability to return to shore or to exit the water.
Diver lost at sea after a shore dive.
Big breaking waves make it unsafe to approach the shore.
Currents move the diver away from a safe exit.
Weather conditions make the sea too rough to safely exit.
Local knowledge, good weather forecasts, plan alternative exits.
EPIRB, marker buoy, flares, die markers, signalling light, mirror, whistle or other means of signalling distress and indicating position to rescuers.
Good buoyancy aids and exposure suit to provide protection while rescue is awaited.
Notification before the dive of someone on shore of the expected time of return, so they can notify the rescue organisations if the divers do not return within a reasonable time.
Silt
Sudden loss of underwater visibility (silt out), which can cause disorientation and a diver getting lost under an overhead.
Stirring up silt or other light loose material, either by natural water movement or by diver activity, often due to poor trim and finning skills.
Appropriate trim, buoyancy and propulsion techniques.
Training and skills for diving in zero visibility and silting risk areas.
Use of distance line when it is possible to end up under an overhead.
Entrapment hazards such as nets, lines, kelp, unstable structures or terrain, and confined spaces.
Diver trapped underwater and may run out of breathing gas and drown. Inappropriate response due to panic is possible.
Snagging on lines, nets, wrecks, debris or in caves.
Entrapment by collapse of terrain or structure, either directly or by obstructing the exit route.
Carrying at least one effective line cutting implement, more in high risk areas.
Diving with a buddy who is capable of helping to free the trapped diver and will stay close enough to notice.
Training in wreck diving and cave diving techniques.[23]
Use of low snag equipment configurations (avoid dangling gear and snap hooks that can snag on lines).
Overhead environment (cave, wreck or ice, where direct ascent to the surface is obstructed)
Diver may get lost and be unable to identify the way out, and may run out of breathing gas and drown.[23]
Inappropriate response due to panic is possible.
Getting lost in wrecks and caves or under ice where there is no direct route to the surface, often due to not using a distance line, or losing it in darkness or bad visibility, but sometimes due to the line breaking.[23]
Differential pressure hazards (Pressure difference other than hydrostatic, causing strong water flow, usually towards the hazard)[46]
Diver may get drawn into moving machinery or trapped against an intake opening, and may be directly injured or unable to escape and may run out of breathing gas and drown.
Inappropriate response due to panic is possible.
Getting too close to propellers, thrusters or intakes on operational vessels, outlets and sluices in dams, locks or culverts, failure of lockout tagout and permit to work systems, Previously unknown or changed flow in caves.
Appropriate training and dive planning.
Correct use of lockout-tagout and permit to work systems[7]
Impact against the bottom terrain or underwater structures, which can dislodge equipment such as mask or DV, roll off a cylinder valve, snag and damage equipment or cause impact trauma to the diver. Severity can vary from annoyance to fatal.
It is also possible to get wedged into a small gap and trapped, or caught up on nets or lines in the water.
In an overhead environment the diver may be unable to get back against a strong current.
Disorientation or vertigo caused by tumbling in strong eddies or vortices
Strong water movement carrying the diver along and into contact with rigid objects fixed in place.
Strong water movement creating so much drag on the diver that progress upcurrent is severely restricted.
Strong water movement past an obstacle may throw off vortices due to flow instability
Strong currents and surge may often be avoided by planning the time of the dive.
Divers may stay a safe distance from the bottom terrain during drift dives.
Drift divers may tow a surface marker buoy to identify their positions to the boat.
Loss of equipment, temporary loss of breathing gas.
Uncontrolled transportation by surf surge onto rocks or other hard obstacles.
Tumbling in breaking wave causing vertigo.
Strong turbulence in breaking wave may pull equipment from diver, particularly mask and demand valve, occasionally fins.
Avoidance of strong surf transits.
Minimising time in surf zone.
Secure attachment of equipment.
Protection of mask and demand valve security by holding them in place in high turbulence.
Low visibility and darkness. (in conjunction with other hazards)
Inability to read instruments to monitor depth, time, ascent rate, decompression schedule, gas pressure, and to navigate. These are not dangerous in themselves, but may result in the diver getting lost, swimming into an entrapment hazard or under an overhang, violating a decompression obligation, or running out of breathing gas.
Lack of light or absorption of light by turbidity.
A dive light can provide light if the visibility is sufficient.
In zero visibility special precautions must be taken.
It is usually preferable to use surface-supplied equipment with voice communications, as the diver can not get lost, and the surface team can monitor depth, time, breathing gas and decompression obligations.
Navigation and work must be done by feel.
High altitude
Increased risk of decompression sickness—Reduced ambient pressure can induce bubble formation or growth in saturated tissues.
Heart attack, with high risk of death as direct consequence, or by drowning as indirect consequence.
Angina with severe pain and severely reduced physical strength and endurance, and reduced situational awareness, which increase the risk of further deterioration of the incident
Exertion beyond the capacity of the unhealthy heart.
Periodical medical examination for diving fitness, and discussion of medical history with provider.[clarification needed]
Possibility of venous gas bubbles shunting into arterial circulation and causing emboli
Otherwise low-risk venous gas bubbles formed during decompression may shunt through PFO during anomalous pressure differential episode such as coughing, Valsalva manoeuver, or exertion while holding the breath.
Screening for PFO for high risk divers
Conservative decompression and ascent
Avoidance of exercise which is likely to induce shunting during ascent
Difficulty in breathing, particularly difficulty in exhaling adequately during ascent, with reduced physical work capacity, can seriously reduce ability to cope with a relatively minor difficulty and precipitate an emergency.
constriction of lung passages, increasing work of breathing.
Reduced ability to respond effectively to emergencies
Muscular cramps
Illness, lifestyle, lack of exercise.
Training and exercise, particularly swimming and finning exercise using diving equipment
Diver behaviour and competence
Hazard
Consequences
Cause
Avoidance and prevention
Inadequate learning of critical safety skills.
Inability to deal with minor incidents, which consequently may develop into major incidents.
Inadequate demonstration and assessment of skills by instructor.
Ineffective skills taught, due to inappropriate training standard, or misinterpretation of training standard.
Insufficient correct repetition of skills during training.
Quality assurance by training agency
Inadequate practical competence in critical safety skills.
Inability to deal with minor incidents, which consequently may develop into major incidents.
Insufficient practice of skills during training.
Insufficient practice of skills after training.
Clear standards for competence in assessment criteria of training programme.
Quality assurance by training agency.
Post training practice of vital skills by the diver.
Periodical re-assessment of skills by a competent assessor.
Overconfidence.
Diving in conditions beyond the diver's competence, with high risk of accident due to inability to deal with known environmental hazards.
Over-optimistic self-assessment of personal competence by the diver.
Insufficient information due to inadequate training.
Objective assessment and accurate feedback during training.
Realistic training standards and competence level descriptions.
Inadequate strength or fitness for the conditions
Inability to compensate for difficult conditions even though well versed at the required skills.
Over-exertion, overtiredness, stress injuries or exhaustion.
Underestimating severity of conditions.
Overestimating fitness and strength.
Conditions deteriorate during the dive.
Excessive task loading.
Use of equipment that requires greater exertion than the diver can produce.
Experience and familiarity with local conditions.
Use of weather and tide forecasts when planning dives.
Maintaining fitness to dive by adequate exercise.
Use of equipment and techniques that reduce physical exertion required.
Gradual buildup of task-loading to develop appropriate skills and fitness.
Training with equipment in benign conditions before using in severe conditions.
Peer pressure
Inability to deal with reasonably predictable incidents in a dive.
Divers may be pressurised into undertaking dives beyond their competence or fitness.
Divers may be pressurised into diving with unsuitable buddies, often by dive professionals who should know better.
Objective and accurate knowledge of the diver's capabilities.
Recognising and accepting responsibility for possible consequences of exerting or submitting to peer pressure.
Diving with an incompetent buddy
Injury or death while attempting to deal with a problem caused by the buddy.
The buddy may get into difficulty due to inattention or incompetence, and require a rescue that is hazardous to the rescuer.
The buddy may get into difficulty and mishandle the situation or panic, creating an incident that is hazardous to both divers.
Diving with a buddy is known to be competent and who can be trusted to behave responsibly.[62]
Training to deal with emergencies and rescue.
Carrying equipment to be independent of the buddy in most emergencies.
In some circumstances it may be safer to dive without a buddy.[63]
Overweighting
Difficulty in neutralising and controlling buoyancy.
Uncontrolled descent.
Inability to establish neutral buoyancy.
Inefficient swimming.
High gas consumption.
Poor trim.
Kicking up silt.
Difficulty in ascent
Inability to control depth accurately for decompression
Carrying more weight than needed. Recreational divers do not usually need more weight than is needed to remain slightly negative after using all the gas carried. Professional divers may need to be heavy at the bottom to provide stability to work.
Establish and use the correct amount of weight for the circumstances of the dive, taking into account:
Density of water (sea or fresh).
Buoyancy of equipment (mainly exposure suit).
Buoyancy change of cylinders as gas is used up.
Tasks of the dive.
Capacity of buoyancy compensator to neutralise buoyancy at depth and provide positive buoyancy at the surface.
Use surface supply equipment or a lifeline if it is necessary to dive heavy.
Underweighting
Difficulty in neutralising and controlling buoyancy.
Inability to achieve neutral buoyancy, particularly at decompression stops.
Not carrying sufficient weight. Divers need to be able to remain neutral at 3m depth at the end of a dive when the gas has been used up.
Diving under the influence of drugs or alcohol, or with a hangover
Inappropriate or delayed response to contingencies.[64]
reduced ability to deal timeously with problems, leading to greater risk of developing into an accident.
Increased risk of hypothermia.
Increased risk of decompression sickness.
Use of drugs that alter mental state or physiological responses to environmental conditions.
Avoid use of substances that are known or suspected to reduce the ability to respond appropriately to contingencies.
Use of inappropriate equipment and/or configuration
Snagging on lift bag as it begins ascent, and being dragged up with it.
Precautions can be taken to reduce risk if diver snagging on bag or load. These include the use of a rigid extension pipe to fill parachute-style bags, allowing the diver to remain at a safe distance.[69]
Loss of breathing gas.
Using up breathing air to fill lift bag.
Use of an independent air cylinder dedicated to bag filling, rather than filling from the breathing gas cylinder(s).[5]
Marking lift bag or load with a surface marker buoy before lifting.
Ensuring that lift takes place when surface vessels and structures are clear of the area.[5]
Buoyant assisted lifting, where the lift bag is insufficient volume to lift the load without assistance from a crane or winch.[69]
Staged lifting, where the load is lifted in stages, a short distance at a time.[69][5]
Adequate training and use of suitable rigging equipment and lift bag size and style. Attachment to suitable lift points, taking trim and stability into account.[5][69]
Lifting, moving, aligning and lowering heavy objects
Crushing trauma
Getting caught in pinch points between objects with great inertia and relative movement
Use appropriate tools, rigging, PPE, and procedures
deadman anchors and tie-backs to limit movement
pullers, levers and guide-bars to align object
avoid getting any part of the body between or under heavy objects
maintain clear communications
use of helmet video or observation ROV can help remote operators understand the underwater scenario
The dive platform and support equipment
Hazard
Consequences
Cause
Avoidance and prevention
Anchoring patterns
Getting caught under catenary sag causing entrapment and/or crushing trauma
Diving in close vicinity to mooring chain in a seaway or wind. Chain lifting under tension and dropping on diver in pinch zone
Physical restraint from entering danger zone by way of limited umbilical length and underwater tending.
Remain above chain at all times when near pinch zone if necessary to work in the area.
Avoid diving near chains when weather conditions are likely to cause lifting.
Avoid diving near chains in low visibility.
Thrusters on dynamically positioned diving support vessels
Diver sucked into water flow through thruster, causing physical trauma, entanglement, umbilical or other life support damage
Pressure differences cause diver or equipment to be entrained in water flow towards the hazard
Physical restraint from entering danger zone by way of limited umbilical length and underwater tending from bell, stage, or other points.
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