Thermal undersuits Most dry suits do not provide sufficient thermal insulation without suitable undergarments. The type of undergarment selected will depend on the environmental conditions, type of dry suit and the planned activity. The purpose of the undergarment is to maintain the wearer in
comfortable thermal balance, where the heat lost is balanced by the heat generated by the user. More insulation is needed for colder conditions and for less energetic activity. A balance of
thermal comfort with freedom of movement, minimal variation in buoyancy with depth, and minimal effects on
diver trim is one of the goals of undersuit selection for diving. For surface applications, thermal comfort with freedom of movement and minimum skin dampness from condensation is the target.
Moisture management using wicking textiles is often used. The principle of
layered clothing can be used to provide a wider range of insulation possibilities from a relatively small range of underwear items, however this can only be done before entering the water. Most dry suit underwear insulates mainly by a trapped layer of gas in the garment, and this is largely lost if the gas is replaced by water in a flooded suit, so as an approximation, insulation is proportional to the combined thickness of the undergarments. The layering principle shows that the option of two layers of undergarment in two thicknesses allows three levels of insulation to be selected. Thin only, thick only, and both layers. Some materials have better insulating properties than others when wet, and will keep the diver warmer if the suit leaks or floods. The best dry suit undergarment is the thinnest material that will provide the required insulation, by trapping air in the smallest spaces. These will require less air in the suit and thus less excess buoyancy for which weighting will be required. The moisture given off by the human skin, even when not exercising and sweating, will condense against the inside of the dry suit, and the way this condensate is handled by the underwear material will influence the comfort of the diver. If the underwear soaks up this moisture it will feel cold and clammy, particularly if this layer is against the skin. Materials which wick the moisture away from the skin and do not soak up the condensate will be more comfortable. A thin polypropylene layer against the skin will keep moisture away from the skin, and may keep the main undersuit clean. Early thermal undersuits for drysuits were commonly made from wool, as it retains its insulating properties better when wet than most other natural fibres. The fit of the underwear should allow the same range of movement as the suit itself, and together should allow the wearer to bend,
squat, kneel, climb a ladder, fin and reach all critical parts of equipment worn on the body. Underwear which is flexible and stretches, particularly at the joints, will allow the diver more freedom of movement, and is less likely to chafe, and for diving use, materials which resist compaction under light pressure will maintain a more even thickness in use, which will provide better insulation for the same overall volume. For cold-water use, especially diving under ice, the user will usually wear a thick undersuit. The thickness of undersuits varies and can be chosen by the wearer according to the water temperature.
Thinsulate is one of the preferred fabrics for diving undersuits. The hydrophobic qualities of Thinsulate help prevent water absorption which helps to maintain the insulating airspace even in the presence of free water. More recently,
aerogel material is being added to conventional undergarments to increase the insulating properties of those garments.
Polar fleece is a good insulator with good stretch, is lightweight, and dries quickly if it gets wet. It is also hypoallergenic and comfortable against the skin. Polyester liners can add to the insulation and will wick perspiration away from the skin.
Cotton absorbs moisture and saturates easily, and will then rapidly conduct heat away from the body, so it is not used. Most dry-suit underwear is full length, either as a one-piece or jacket and trousers, but a vest may be added for extra insulation on the torso, and a "Farmer John"
salopette style trousers with jacket is flexible and puts extra insulation where it is most useful. The dry suit manufacturer "Waterproof" has introduced an unusual style of suit liner for diving drysuits which is made of a compression resistant but light and flexible coarse nylon mesh, and attached to the inside of the trilaminate drysuit shell when in use, which maintains an air gap between the undersuit and the inner surface of the shell, and which keeps condensate that forms on the inside of the shell from contact with the undersuit, so the undersuit is more likely to remain dry. Neoprene dry suits are made from a foam-rubber sheet containing tiny air bubbles, which provide insulation by themselves, and can eliminate the need for an under-suit, or reduce the thickness needed for the under-suit fabric, but the bubbles in the neoprene are compressed and the insulation of the suit decreases with depth in the same way as for a wetsuit. Crushed neoprene provides the flexibility of neoprene with the consistent buoyancy and insulation of membrane suits, but is heavy like other neoprene suits and provides less insulation in shallow water than regular foamed neoprene. A neoprene wet suit can also be worn under a membrane dry suit for insulation and extra protection against condensation and leaks, but it will compress with depth, as will any flexible closed cell material.
Suspenders Some dry suits are provided with internally attached suspenders (
British English: braces), which when hooked over the shoulders, will hold the trouser section up while the top part of the suit has not been fully dressed into by the diver, this is also convenient if the suit is partly removed between dives for comfort. The suspenders also help to keep the trousers fully lifted if the torso of a membrane suit is a little long to provide enough space for the diver to bend the torso comfortably when in use. If the crotch hangs too low it encumbers the legs when finning, and increases the risk of the feet pulling out of the boots in an inversion.
Hoods The dry suit may also have an integral
hood, which seals water out around the wearer's face, and helps keep the wearer's head warm. The integral hood is often latex rubber that fits tightly around the head, but can also be made mainly from neoprene or membrane to allow an insulating cap to be worn under the hood. Care must be taken to avoid the hood making an airtight seal around either of the ears, as this could cause an
eardrum bursting outwards at depth. Separate hoods are generally neoprene wetsuit hoods with a flare at the bottom opening, worn over the neck seal. Some suits are made with an external "warm neck collar" around the base of the neck seal, which allows the flare of the hood to tuck in over the outside of the seal and under the collar. This can keep the neck significantly warmer, since the seal itself provides little insulation.
Helmets To provide more protection to the head against impact, to secure the airway, to fully isolate the diver from the water, and to permit easy communication with the surface and between divers, a rigid metal or
fibre-reinforced plastic diving helmet may be worn with the dry suit. This can be separate from the dry suit with its own watertight neck seal, or it can be clamped onto a neck ring attached to the suit, so that air can flow between the helmet and the suit.
Boots or socks Most commercial diving dry suits have heavy duty integral
boots. Sport diving suits may have lightweight integral boots or soft neoprene
booties. or heavy working boots may also be worn over integral socks of latex or neoprene or the same material as the rest of the suit. Boots which are stiff at the ankle make finning inefficient and are unsuitable for many diving applications where mobility is important. If the suit will be used by a diver who needs to fin efficiently on some dives and to walk on sharp surfaces on other dives, it is more effective to wear boots suited to the dive over a dry suit with integral socks. Latex rubber ankle seals are sometimes fitted in place of socks and can allow better foot control of
water skis and
surfboards. Survival suits may have neoprene socks of the same material as the suit, with tougher soles and ankle ties to keep them on the feet, as the "one-size fits all" socks must be too big for most users if they are to accommodate the few with larger feet.
Gloves, mitts, and three-finger mitts Dry suits may have wrist seals, permanently attached gloves or mitts, or removable dry gloves connected by attachment rings. Neoprene wetsuit gloves are pulled over the top of wrist seals. They are wet gloves and vary considerably in effectiveness depending on construction and fit. As they are not watertight they do not fail catastrophically when damaged, and are reasonably tough. Permanently attached gloves or mitts are unusual, It is more common for them to be connected by attachment rings. Either way, the absence of a wrist seal makes getting in and out of the suit much easier since there is no need for the suit to tightly seal around the wrists. It may be necessary to use a wrist strap to prevent loose gloves pulling off the hands when filled with air. Dry gloves can also be fitted over a wrist seal, which prevents leakage into the sleeves if the gloves are penetrated. Rubber or rubber coated stretch fabric dry gloves are the most effective at insulation while they remain dry inside, Insulation is provided by liner gloves worn underneath, which may be chosen to suit insulation and dexterity requirements. Full-hand diving mitts can be sometimes useful in extreme environments such as ice diving, but significantly reduce dexterity and grip. Dry gloves and mitts usually allow a dry insulating glove to be worn underneath. Three-finger mitts are a compromise between gloves and full mittens. In the three-finger mitts, the fingers are arranged with the index finger in a separate pocket to the other three fingers. This provides slightly better hand-grasping dexterity while still permitting heavy
insulation around the hands.
Attachment rings Attachment rings allow separate neck seals, gloves, and (less commonly) boots to be clipped to the suit with a watertight seal. On both commercial and recreational suits, "quick-change" rings have become common. These are glued to the suit, either during manufacture or as a retrofit. These systems form a watertight seal between the suit and components. Quick-change rings allow a diver to easily replace a damaged seal on the surface with no tools or adhesives, or to change attachments depending on conditions – for example, choosing between dry gloves and standard wrist seals. Different manufacturers' ring systems may be incompatible. Some styles of cuff ring allow dry gloves to be clipped on over a wrist seal. A seal breaker strand is worn under the cuff seal to allow the interior of the glove to equalise with the sleeve of the dry suit. If the glove is damaged underwater, the strand can be removed to prevent further water leakage into the suit.
Suit inflation Dry suits for diving are usually equipped with an inflation valve (or inlet valve) and at least one exhaust valve (or dump valve, or outlet valve). Survival suits and other dry suits designed for wear on the surface have no inflation or dump valves as suit squeeze and achieving neutral buoyancy are not relevant. The inflation valve allows the diver to compensate for gas compression in the suit on descent. Suit gas compression squeezes the suit uncomfortably onto the diver's body, especially where the suit folds, it hinders the diver's freedom of movement, reduces thermal insulation through compression of insulating garments and interferes with buoyancy control. Environmentally sealed suits, which are sealed to the helmet, automatically equalise from the breathing gas, and will also inflate from the breathing gas if inverted.
Suit inflation gas supply Compensating gas is supplied from a breathing gas
cylinder, a small, dedicated suit inflation cylinder, or the umbilical of a surface-supplied diver. Normally, the gas used for dry suit inflation on scuba is air from the primary breathing cylinder.
Helium-based
gas mixes such as
trimix or
heliox are avoided for suit inflation because of helium's high
thermal conductivity. Nitrox blends from a
decompression cylinder have essentially the same thermal conductivity as air but oxygen rich mixes introduce a fire hazard when out of the water. Using a small (1-2 litre), dedicated cylinder for suit inflation avoids these complications; usually this will contain air but
argon may be used instead. Argon has a low thermal conductivity, which improves insulation by approximately 20% compared to air, without adding any further bulk or weight. However, the accidental breathing of pure argon results in rapid unconsciousness and probable death. Consequently, argon cylinders must be clearly marked to prevent the accidental attachment of a breathing regulator or have valves that cannot accept a breathing regulator. To gain the full benefit of argon the suit must be flushed with argon before the dive to remove the air.
Inflation valve An inflation valve is fitted to diving dry suits to admit gas to compensate for compression during descent. This is not necessary when the suit is sealed directly to a diving helmet, as the demand valve will automatically feed gas into the suit if the internal pressure difference drops. The spring-loaded push-button inflation valve is usually mounted over the chest for easy access, and is manually operated by the diver during descent to maintain the loft of the undergarments for insulation and to prevent discomfort from suit squeeze. Descent rate may also be adjusted by controlling suit volume and thereby buoyancy. Gas is supplied to the valve through a low-pressure hose, which can be connected and disconnected under pressure and underwater. Like the dump valves, most dry suits use inflation valves made by Apeks or SI Tech AB.
Inflation hose inflation hose with CEJN connector (right) used for some dry suits There are two types of low-pressure hose connections commonly used for suit inflation. These are the standard Seatec style quick release coupler, fitted with an internal
Schrader valve, as also used on most diving buoyancy compensators, and the CEJN connector which allows a higher flow rate due to a larger bore through the non-return valve in the connector. This valve can allow a dangerously fast inflation rate if it jams open, and is also more likely to free-flow when disconnected. These hose connectors use incompatible valve fittings, but it is usually possible to swap the fitting on the inflator valve to accept the alternative hose end fitting. Both types of BCD and dry suit low pressure inflator hoses are supplied with a standard fitting for connection to a
scuba regulator first stage low-pressure port.
Exhaust valves The exhaust valve (or dump valve, often an ) allows the diver to vent expanding gas from the suit during ascent to maintain buoyancy control in the same way that a
buoyancy compensator must be vented during ascent to avoid an uncontrolled (or runaway) buoyant ascent, missed decompression stops,
decompression sickness,
arterial gas embolism or
pulmonary barotrauma. Configurations may vary but adjustable over-pressure automatic vents (
auto-dump valves) are generally on the sleeve at the left shoulder, clear of the harness or buoyancy compensator, and non-adjustable over-pressure vents at the left wrist, where they can be raised quickly to dump, and occasionally also at the ankles, to automatically dump in the event of an inversion. Adjustable valves can be pre-set or set to suit the undergarments during or after the descent, and in most situations can be left at this setting throughout the dive, but may be closed after surfacing to retain more gas for buoyancy and insulation, An auto-dump valve is a two stage valve to reduce inward leakage of water. The inner valve is generally a mushroom type elastomer non-return valve, with a low opening pressure differential, which will close automatically when there is no suit gas flowing out. This serves to prevent water ingress when the valve is manually opened by pressing down on the outer cover to compress the adjustable spring and open the pressure relief valve. The outer valve is an adjustable pressure relief valve which can be manually opened by pressing it with the hand against the spring preload, or opens automatically when internal pressure overcomes the preload setting. Spring tension is adjusted by screwing the outer cover further down to increase opening pressure difference, and unscrewing to reduce pressure difference. The rotation of the cover has stops at both ends, and clicks every few degrees of turn, so the user can judge the setting. Non-adjustable valves are similar but do not have the adjustment facility and can be more compact. Most dry suit dump valves are manufactured by
Apeks and SI Tech and may be relabeled by suit manufacturers, though
Northern Divers and
Mares manufacture their own valves.The SI Tech valve has a different size gasket to the Apeks glued to the suit, so they are not interchangeable. Maintenance is mostly rinsing in fresh water after a dive, and most minor leaks can be fixed by soaking the valve mechanism and flushing with fresh water. Environmentally sealed suits used for diving in contaminated water have a watertight seal to the helmet, rely on the helmet exhaust valve to release air from the suit, and may not have a separate exhaust valve on the suit itself. This is common for free-flow helmets and was part of the
standard diving dress system. Most, but not all, dry suits from the 1950s and the early 1960s came without dedicated vents; venting was achieved by raising an arm and lifting one of the wrist seals or placing a finger in the neck seal. Several manufacturers back then attached a rubber venting tube closed with a stopper to the chest area of valveless dry suits, enabling the latter to be completely deflated before entering the water or inflated in the water to make the suit buoyant if required. Some mid-twentieth-century divers installed
duckbill valves, also known as spear valves or flutter valves, which were designed to release excess air from the interior of their otherwise valveless dry suits at the head, shoulders or ankles. Surface-use dry suits do not normally have exhaust valves, but the wearer may vent excess air by crouching down and hugging the legs while slipping a finger under the neck seal. During ascent, the diver has several things to monitor and do, so an adjustable automatic exhaust valve which provides hands-free operation helps reduce this task loading.
Zipper and seal protection Some suits are provided with a flap which can be closed over the outside of the zipper to protect it from being damaged by contact with the diver's equipment or the environment. these flaps may be held in place by velcro or a non-watertight outer zipper. These flaps are almost always fitted to zippers fitted diagonally across the front of the suit, and less often to rear-entry cross-shoulder zippers. Cuff and collar extensions to the shell may be fitted to protect the seals from abrasion and tears. This is particularly useful on suits used for activities like rescue, where the environment may be rough on the suit.
The P-valve For commercial divers or technical divers who may spend many hours in a dry suit underwater, it is not practical to have to climb back on board the ship in order to open a waterproof relief zipper and urinate. The P-valve is a urinal built into the suit, which enables a diver to urinate at any time without having to get out of the water, while keeping him or her dry and clean inside the suit. Risks involved with the use of the P-valve can include
urinary tract infection,
pneumaturia and
genital squeeze. Divers expecting the need to urinate in dry suits can also use an adult
diaper, which soaks up and retains the urine.
Watertight relief zippers may be fitted which allow urination when out of the water without removing the suit. but these are a potential source of leaks and an additional expense.
Cargo pockets Pockets are a convenient storage for small items of equipment and tools that may be needed on a dive, or on surface dry suits, during work. They are often used by scuba divers who use back inflation buoyancy control devices without integral pockets, and are often simply glued to the suit in the position chosen by the diver. Various styles and capacities are used. The usual positions are on the thighs. Forward position is more ambidextrously accessible, but can make boarding a small boat over the gunwale difficult or impossible, the sides of the thighs is more streamlined and better for boat entry, but makes it difficult to reach into the pocket with the opposite hand. Chest pockets are also sometimes used. Pockets may alternatively be mounted on shorts, a tunic, or protective overalls worn over the dry suit, or be integral parts of the buoyancy compensator. They usually cause additional drag underwater, and should drain rapidly while climbing out of the water.
"Bio-seals" To reduce the contact with latex seals in divers with a latex allergy, a soft elastomer band called a "Bio-seal" can be worn under the latex contact area. These may also reduce friction with the seal and improve watertightness.
Active heating For applications where passive heating is insufficient, active heating can be used. One of the earliest systems was the tube suit, a set of underwear with a complicated labyrinth of tubes which carried heated water supplied from the surface or the lockout submersible through an additional hose in the diver's umbilical. Other active heating systems use electrical heating elements in an undersuit layer, or internal pockets containing hot-packs, sealed plastic bags containing materials which emit latent heat during a phase change. ==Associated equipment==